51 results
Blank
Environment
PROJECT NUMBER • 2019-176
PROJECT STATUS:
COMPLETED

NCCP: Determination of the susceptibility of silver perch, Murray cod and rainbow trout to infection with CyHV-3

This research sought to build on the experimental evidence regarding non-target species susceptibility to CyHV-3. Three species which had been previously tested, but for which additional evidence would be needed to confirm non-susceptibility included Rainbow Trout, Silver Perch and Murray Cod. 
ORGANISATION:
CSIRO Australian Animal Health Laboratory
TAGS
Invasive Species
Health And Safety
Disease
Commercial Species
Bycatch
SPECIES
Silver Perch
European Carp
Murray Cods
Trouts
Environment
PROJECT NUMBER • 2019-163
PROJECT STATUS:
COMPLETED

NCCP: Understanding the genetics and genomics of carp strains and susceptibility to CyHV-3

To assess the risk that rapid resistance to CyHV-3 might develop, we undertook an extension to the integrated modelling with the objectives of defining what exactly is “resistance” in the context of viral biocontrol, and to elucidate the mechanisms (pathways) by which it might develop....
ORGANISATION:
CSIRO Australian Animal Health Laboratory
TAGS
Modelling
Invasive Species
Health And Safety
Genomics
Disease
SPECIES
European Carp
People
Industry
PROJECT NUMBER • 2019-089
PROJECT STATUS:
COMPLETED

Evaluation of point of care (POC) tests for White Spot Syndrome Virus (WSSV)

The CSIRO Australian Centre for Disease Preparedness (ACDP) Fish Diseases Laboratory (AFDL), in collaboration with Biosecurity Queensland, conducted a laboratory-based evaluation of commercially available point-of-care (POC) tests designed to detect white spot syndrome virus (WSSV) in the field. The...
ORGANISATION:
CSIRO Australian Animal Health Laboratory
TAGS
Wild Catch
White Spot Disease
Rac Qld
Profitability
Productivity
SPECIES
Black Tiger Prawn
Banana Prawns
Industry
Industry
Environment
PROJECT NUMBER • 2017-135
PROJECT STATUS:
COMPLETED

NCCP: essential studies on cyprinid herpesvirus 3 (CyHV-3) prior to release of the virus in Australian waters

This project, undertaken by CSIRO, aimed to determine the most important form of transmission of CyHV-3 to Cyprinus carpio (common carp). This was addressed through experiments to determine: (1) The relative amounts of virus in the skin and mucus of infected fish vs shed...
ORGANISATION:
CSIRO Australian Animal Health Laboratory
TAGS
Modelling
Invasive Species
Disease
Animal Health
SPECIES
European Carp

Identification of differentially expressed innate immune genes in the New Zealand paua (Haliotis iris) and the Australian hybrid abalone (H. laevigata X H. rubra) upon immersion challenge with the abalone herpesvirus-1 (HaHV)

Project number: 2017-117
Project Status:
Completed
Budget expenditure: $121,127.00
Principal Investigator: Serge Corbeil
Organisation: CSIRO Australian Animal Health Laboratory
Project start/end date: 30 Apr 2018 - 29 Sep 2019
Contact:
FRDC
TAGS
Rac Vic
Rac Tas
Rac Sa
Rac Nsw
Disease
SPECIES
Paua
Abalone

Need

Abalone viral ganglioneuritis (AVG) has occurred in Victorian abalone for several years beginning from 2005/6. Later on several genetic variants of the causative agent, abalone herpesvirus (HaHV) (previously called AbHV) associated with disease outbreaks were discovered in Tasmanian processing plants.
All Australian abalone species tested to date have been shown to be susceptible to HaHV infection and to the disease it causes (Corbeil et al., 2016, Diseases of Aquatic Organisms 119:101-106). In addition, a recent study revealed that the New Zealand paua (H. iris) is resistant to AVG when challenged with the virus via intra-muscular injection and immersion (Corbeil et al., 2017, Journal of Invertebrate Pathology 146:31-35). The mechanism(s) of protection present in the paua are not known but are possibly based on innate immune genes that are expressed in paua but not expressed (or are absent) in Australian abalone species.
Identifying the mechanisms of protection would provide a knowledge based platform that could lead to the development of hybrid abalone possessing resistance traits and/or to the development of immunotherapeutic molecules that could protect Australian abalone species.
This project aims to address this knowledge gap and is relevant to all jurisdictions with abalone fisheries. Access to bio-secure aquarium facilities provides CSIRO-AAHL with a unique capability to investigate what genetic factors influence disease resistance in paua (exotic species), and carry out molecular gene characterisation.

Objectives

1. Define the time-line of an anti-viral response in the paua and Australian hybrid abalone for the first-time, utilising real-time PCR, and a set of known anti-viral effector genes.
2. Through mRNA sequencing and genomic analysis, identify early genes expressed in paua and Australian hybrid abalone upon HaHV immersion challenge.
3. Establish an immune signature in the early response of the host to the virus that differs between the paua and Australian hybrid abalone, to determine key immune players in HaHV resistance.

Final report

ISBN: 978-1-925994-03-2
Authors: Serge Corbeil (CSIRO) Karla Helbig (LaTrobe University)
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Final Report • 2020-02-01 • 921.41 KB
2017-117-DLD.pdf

Summary

This project was carried out by scientists from AAHL CSIRO (Dr Serge Corbeil) and from LaTrobe University (Drs Karla Helbig and Subir Sarker). After discovering the existence of an abalone species (Päua - Haliotis iris) resistant to AVG our research team based in Geelong and Melbourne undertook (2018) to expose the AVG resistant päua and the AVG susceptible greenlip x blacklip hybrid abalone to HaHV-1 (the etiological agent of AVG) and look for differential gene expression between species. Cutting edge sequencing technology and bio-informatic analysis allowed us to investigate the gene expression of the animals at the molecular level. This approach led to pinpoint abalone genes that are likely to play a role in the protection against AVG in päua. Furthermore, the identification of these genes may facilitate (if applicable) the use of a gene silencing technology such as the CRISPR system in vitro and in vivo to improve immune response to AVG. A breeding program strategy could also eventually be implemented to increase resistance to AVG in susceptible abalone species.
Blank
PROJECT NUMBER • 2016-404
PROJECT STATUS:
COMPLETED

Aquatic Animal Health and Biosecurity Subprogram: Strategic planning, project management and adoption

This report is about the activities of the FRDC’s Aquatic Animal Health and Biosecurity Subprogram (AAHBS) for the period 2016-2020. In the period 2016-20, AAHBS has managed 27 projects concerned with aquatic animal health and biosecurity. AAHBS also provided advice on other aquatic...
ORGANISATION:
CSIRO Australian Animal Health Laboratory
TAGS
Health And Safety
Fisheries Management
Disease
Biosecurity
Animal Health
View Filter

Research

Category

Product Type

Species

Organisation