Considerations for Maintaining Family Diversity in Commercially Mass-Spawned Penaeid Shrimp: A Case Study on Penaeus monodon

Considerations for Maintaining Family Diversity in Commercially Mass-Spawned Penaeid Shrimp: A Case Study on Penaeus monodon

Skewed family distributions are common in aquaculture species that are highly fecund, communally (mass) spawned, and/or communally reared. The magnitude of skews pose challenges for maintaining family-specific genetic diversity, as increased resources are required to detect individuals from underrep...

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Main Authors: Andrew Foote, David Simma, Mehar Khatkar, Herman Raadsma, Jarrod Guppy, Greg Coman, Erika Giardina, Dean Jerry, Kyall Zenger, Nick Wade
Format: Article
Language:English
Published: Frontiers Media S.A. 2019-11-01
Series:Frontiers in Genetics
Subjects:
selective breeding
family skewing
genetic diversity
parentage assignment
single nucleotide polymorphisms
mass spawners
Online Access:https://www.frontiersin.org/article/10.3389/fgene.2019.01127/full
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author Andrew Foote
Andrew Foote
Andrew Foote
David Simma
David Simma
Mehar Khatkar
Mehar Khatkar
Herman Raadsma
Herman Raadsma
Jarrod Guppy
Jarrod Guppy
Greg Coman
Greg Coman
Erika Giardina
Erika Giardina
Dean Jerry
Dean Jerry
Kyall Zenger
Kyall Zenger
Nick Wade
Nick Wade
spellingShingle Andrew Foote
Andrew Foote
Andrew Foote
David Simma
David Simma
Mehar Khatkar
Mehar Khatkar
Herman Raadsma
Herman Raadsma
Jarrod Guppy
Jarrod Guppy
Greg Coman
Greg Coman
Erika Giardina
Erika Giardina
Dean Jerry
Dean Jerry
Kyall Zenger
Kyall Zenger
Nick Wade
Nick Wade
Considerations for Maintaining Family Diversity in Commercially Mass-Spawned Penaeid Shrimp: A Case Study on Penaeus monodon
Frontiers in Genetics
selective breeding
family skewing
genetic diversity
parentage assignment
single nucleotide polymorphisms
mass spawners
author_facet Andrew Foote
Andrew Foote
Andrew Foote
David Simma
David Simma
Mehar Khatkar
Mehar Khatkar
Herman Raadsma
Herman Raadsma
Jarrod Guppy
Jarrod Guppy
Greg Coman
Greg Coman
Erika Giardina
Erika Giardina
Dean Jerry
Dean Jerry
Kyall Zenger
Kyall Zenger
Nick Wade
Nick Wade
author_sort Andrew Foote
title Considerations for Maintaining Family Diversity in Commercially Mass-Spawned Penaeid Shrimp: A Case Study on Penaeus monodon
title_short Considerations for Maintaining Family Diversity in Commercially Mass-Spawned Penaeid Shrimp: A Case Study on Penaeus monodon
title_full Considerations for Maintaining Family Diversity in Commercially Mass-Spawned Penaeid Shrimp: A Case Study on Penaeus monodon
title_fullStr Considerations for Maintaining Family Diversity in Commercially Mass-Spawned Penaeid Shrimp: A Case Study on Penaeus monodon
title_full_unstemmed Considerations for Maintaining Family Diversity in Commercially Mass-Spawned Penaeid Shrimp: A Case Study on Penaeus monodon
title_sort considerations for maintaining family diversity in commercially mass-spawned penaeid shrimp: a case study on penaeus monodon
publisher Frontiers Media S.A.
series Frontiers in Genetics
issn 1664-8021
publishDate 2019-11-01
description Skewed family distributions are common in aquaculture species that are highly fecund, communally (mass) spawned, and/or communally reared. The magnitude of skews pose challenges for maintaining family-specific genetic diversity, as increased resources are required to detect individuals from underrepresented families, or reliably determine relative survival as a measure of family performance. There is limited understanding of family skews or changes in family proportion of communally reared shrimp under commercial rearing conditions and particularly how this may affect genotyping strategies to recover family performance data in breeding programs. In this study, three separate batches of shrimp, Penaeus monodon, were communally spawned and reared, and then sampled as larvae when ponds were stocked at 30 days of culture (DOC) and as juveniles from commercial ponds during harvest at 150 DOC. A total of 199 broodstock contributed to the 5,734 progeny that were genotyped with a custom multiplex single nucleotide polymorphism (SNP) panel, and family assignments were cross-referenced using two parentage assignment methods, CERVUS and COLONY. A total of 121 families were detected, with some families contributing up to 11% of progeny at 30 DOC and up to 18% of progeny at harvest. Significant changes were detected for 20% of families from 30 to 150 DOC, with up to a 9% change in relative contribution. Family skew data was applied in several models to determine the optimal sample size to detect families, along with the ability to detect changes in relative family contribution over time. Results showed that an order of magnitude increase in sampling was required to capture the lowest represented 25% of families, as well as significantly improve the accuracy to determine changes in family proportion from 30 to 150 DOC. Practical measures may be implemented at the hatchery to reduce family skews; a cost-effective measure may be to address the initial magnitude differences in viable progeny produced among families, by pooling equal quantities of hatched larvae from each family. This study demonstrates the relationships between skews in families under commercial conditions, the ability to accurately detect families, and the balance of sampling effort and genotyping cost in highly fecund species such as shrimp.
topic selective breeding
family skewing
genetic diversity
parentage assignment
single nucleotide polymorphisms
mass spawners
url https://www.frontiersin.org/article/10.3389/fgene.2019.01127/full
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spelling doaj-4c730eead58648cba8f98a5777cf6aac2020-11-25T01:33:52ZengFrontiers Media S.A.Frontiers in Genetics1664-80212019-11-011010.3389/fgene.2019.01127468547Considerations for Maintaining Family Diversity in Commercially Mass-Spawned Penaeid Shrimp: A Case Study on Penaeus monodonAndrew Foote0Andrew Foote1Andrew Foote2David Simma3David Simma4Mehar Khatkar5Mehar Khatkar6Herman Raadsma7Herman Raadsma8Jarrod Guppy9Jarrod Guppy10Greg Coman11Greg Coman12Erika Giardina13Erika Giardina14Dean Jerry15Dean Jerry16Kyall Zenger17Kyall Zenger18Nick Wade19Nick Wade20ARC Research Hub for Advanced Prawn Breeding, James Cook University, Townsville, QLD, AustraliaCentre for Sustainable Tropical Fisheries and Aquaculture, College of Science and Engineering, James Cook University, Townsville, QLD, AustraliaAquaculture Program, CSIRO Agriculture and Food, Queensland Bioscience Precinct, St. Lucia, QLD, AustraliaARC Research Hub for Advanced Prawn Breeding, James Cook University, Townsville, QLD, AustraliaCentre for Sustainable Tropical Fisheries and Aquaculture, College of Science and Engineering, James Cook University, Townsville, QLD, AustraliaARC Research Hub for Advanced Prawn Breeding, James Cook University, Townsville, QLD, AustraliaSydney School of Veterinary Science, Faculty of Sciences, University of Sydney, Camden, NSW, AustraliaARC Research Hub for Advanced Prawn Breeding, James Cook University, Townsville, QLD, AustraliaSydney School of Veterinary Science, Faculty of Sciences, University of Sydney, Camden, NSW, AustraliaARC Research Hub for Advanced Prawn Breeding, James Cook University, Townsville, QLD, AustraliaCentre for Sustainable Tropical Fisheries and Aquaculture, College of Science and Engineering, James Cook University, Townsville, QLD, AustraliaARC Research Hub for Advanced Prawn Breeding, James Cook University, Townsville, QLD, AustraliaAquaculture Program, CSIRO Agriculture and Food, Queensland Bioscience Precinct, St. Lucia, QLD, AustraliaARC Research Hub for Advanced Prawn Breeding, James Cook University, Townsville, QLD, AustraliaSeafarms Group Ltd., Flying Fish Point, QLD, AustraliaARC Research Hub for Advanced Prawn Breeding, James Cook University, Townsville, QLD, AustraliaCentre for Sustainable Tropical Fisheries and Aquaculture, College of Science and Engineering, James Cook University, Townsville, QLD, AustraliaARC Research Hub for Advanced Prawn Breeding, James Cook University, Townsville, QLD, AustraliaCentre for Sustainable Tropical Fisheries and Aquaculture, College of Science and Engineering, James Cook University, Townsville, QLD, AustraliaARC Research Hub for Advanced Prawn Breeding, James Cook University, Townsville, QLD, AustraliaAquaculture Program, CSIRO Agriculture and Food, Queensland Bioscience Precinct, St. Lucia, QLD, AustraliaSkewed family distributions are common in aquaculture species that are highly fecund, communally (mass) spawned, and/or communally reared. The magnitude of skews pose challenges for maintaining family-specific genetic diversity, as increased resources are required to detect individuals from underrepresented families, or reliably determine relative survival as a measure of family performance. There is limited understanding of family skews or changes in family proportion of communally reared shrimp under commercial rearing conditions and particularly how this may affect genotyping strategies to recover family performance data in breeding programs. In this study, three separate batches of shrimp, Penaeus monodon, were communally spawned and reared, and then sampled as larvae when ponds were stocked at 30 days of culture (DOC) and as juveniles from commercial ponds during harvest at 150 DOC. A total of 199 broodstock contributed to the 5,734 progeny that were genotyped with a custom multiplex single nucleotide polymorphism (SNP) panel, and family assignments were cross-referenced using two parentage assignment methods, CERVUS and COLONY. A total of 121 families were detected, with some families contributing up to 11% of progeny at 30 DOC and up to 18% of progeny at harvest. Significant changes were detected for 20% of families from 30 to 150 DOC, with up to a 9% change in relative contribution. Family skew data was applied in several models to determine the optimal sample size to detect families, along with the ability to detect changes in relative family contribution over time. Results showed that an order of magnitude increase in sampling was required to capture the lowest represented 25% of families, as well as significantly improve the accuracy to determine changes in family proportion from 30 to 150 DOC. Practical measures may be implemented at the hatchery to reduce family skews; a cost-effective measure may be to address the initial magnitude differences in viable progeny produced among families, by pooling equal quantities of hatched larvae from each family. This study demonstrates the relationships between skews in families under commercial conditions, the ability to accurately detect families, and the balance of sampling effort and genotyping cost in highly fecund species such as shrimp.https://www.frontiersin.org/article/10.3389/fgene.2019.01127/fullselective breedingfamily skewinggenetic diversityparentage assignmentsingle nucleotide polymorphismsmass spawners

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