An epigenetic clock to estimate the age of living beluga whales

An epigenetic clock to estimate the age of living beluga whales

Abstract DNA methylation data facilitate the development of accurate molecular estimators of chronological age or “epigenetic clocks.” We present a robust epigenetic clock for the beluga whale, Delphinapterus leucas, developed for an endangered population in Cook Inlet, Alaska, USA. We used a custom...

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Bibliographic Details
Main Authors: Eleanor K. Bors, C. Scott Baker, Paul R. Wade, Kaimyn B. O'Neill, Kim E. W. Shelden, Michael J. Thompson, Zhe Fei, Simon Jarman, Steve Horvath
Format: Article
Language:English
Published: Wiley 2021-05-01
Series:Evolutionary Applications
Subjects:
aging
Alaska
cetaceans
conservation biology
Cook Inlet
DNA methylation
Online Access:https://doi.org/10.1111/eva.13195
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spelling doaj-b16a65bbb9a24e6b91265d88bb6e48af2021-05-17T12:54:01ZengWileyEvolutionary Applications1752-45712021-05-011451263127310.1111/eva.13195An epigenetic clock to estimate the age of living beluga whalesEleanor K. Bors0C. Scott Baker1Paul R. Wade2Kaimyn B. O'Neill3Kim E. W. Shelden4Michael J. Thompson5Zhe Fei6Simon Jarman7Steve Horvath8Marine Mammal Institute Oregon State University Newport OR USAMarine Mammal Institute Oregon State University Newport OR USAMarine Mammal Laboratory Alaska Fisheries Science Center National Marine Fisheries Service National Oceanographic and Atmospheric Administration Seattle WA USAMarine Mammal Institute Oregon State University Newport OR USAMarine Mammal Laboratory Alaska Fisheries Science Center National Marine Fisheries Service National Oceanographic and Atmospheric Administration Seattle WA USAMolecular, Cell and Developmental Biology University of California Los Angeles Los Angeles CA USADepartment of Biostatistics School of Public Health University of California‐Los Angeles Los Angeles CA USASchool of Biological Sciences University of Western Australia Perth WA AustraliaDepartment of Biostatistics School of Public Health University of California‐Los Angeles Los Angeles CA USAAbstract DNA methylation data facilitate the development of accurate molecular estimators of chronological age or “epigenetic clocks.” We present a robust epigenetic clock for the beluga whale, Delphinapterus leucas, developed for an endangered population in Cook Inlet, Alaska, USA. We used a custom methylation array to measure methylation levels at 37,491 cytosine–guanine sites (CpGs) from skin samples of dead whales (n = 67) whose chronological ages were estimated based on tooth growth layer groups. Using these calibration data, a penalized regression model selected 23 CpGs, providing an R2 = 0.92 for the training data; and an R2 = 0.74 and median absolute age error = 2.9 years for the leave one out cross‐validation. We applied the epigenetic clock to an independent dataset of 38 skin samples collected with a biopsy dart from living whales between 2016 and 2018. Age estimates ranged from 11 to 27 years. We also report sex correlations in CpG data and describe an approach of identifying the sex of an animal using DNA methylation. The epigenetic estimators of age and sex presented here have broad applications for conservation and management of Cook Inlet beluga whales and potentially other cetaceans.https://doi.org/10.1111/eva.13195agingAlaskacetaceansconservation biologyCook InletDNA methylation
collection DOAJ
language English
format Article
sources DOAJ
author Eleanor K. Bors
C. Scott Baker
Paul R. Wade
Kaimyn B. O'Neill
Kim E. W. Shelden
Michael J. Thompson
Zhe Fei
Simon Jarman
Steve Horvath
spellingShingle Eleanor K. Bors
C. Scott Baker
Paul R. Wade
Kaimyn B. O'Neill
Kim E. W. Shelden
Michael J. Thompson
Zhe Fei
Simon Jarman
Steve Horvath
An epigenetic clock to estimate the age of living beluga whales
Evolutionary Applications
aging
Alaska
cetaceans
conservation biology
Cook Inlet
DNA methylation
author_facet Eleanor K. Bors
C. Scott Baker
Paul R. Wade
Kaimyn B. O'Neill
Kim E. W. Shelden
Michael J. Thompson
Zhe Fei
Simon Jarman
Steve Horvath
author_sort Eleanor K. Bors
title An epigenetic clock to estimate the age of living beluga whales
title_short An epigenetic clock to estimate the age of living beluga whales
title_full An epigenetic clock to estimate the age of living beluga whales
title_fullStr An epigenetic clock to estimate the age of living beluga whales
title_full_unstemmed An epigenetic clock to estimate the age of living beluga whales
title_sort epigenetic clock to estimate the age of living beluga whales
publisher Wiley
series Evolutionary Applications
issn 1752-4571
publishDate 2021-05-01
description Abstract DNA methylation data facilitate the development of accurate molecular estimators of chronological age or “epigenetic clocks.” We present a robust epigenetic clock for the beluga whale, Delphinapterus leucas, developed for an endangered population in Cook Inlet, Alaska, USA. We used a custom methylation array to measure methylation levels at 37,491 cytosine–guanine sites (CpGs) from skin samples of dead whales (n = 67) whose chronological ages were estimated based on tooth growth layer groups. Using these calibration data, a penalized regression model selected 23 CpGs, providing an R2 = 0.92 for the training data; and an R2 = 0.74 and median absolute age error = 2.9 years for the leave one out cross‐validation. We applied the epigenetic clock to an independent dataset of 38 skin samples collected with a biopsy dart from living whales between 2016 and 2018. Age estimates ranged from 11 to 27 years. We also report sex correlations in CpG data and describe an approach of identifying the sex of an animal using DNA methylation. The epigenetic estimators of age and sex presented here have broad applications for conservation and management of Cook Inlet beluga whales and potentially other cetaceans.
topic aging
Alaska
cetaceans
conservation biology
Cook Inlet
DNA methylation
url https://doi.org/10.1111/eva.13195
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