Biological clocks as age estimation markers in animals: a systematic review and meta-analysis.

Le Clercq, LS ; Kotzé, A ; et al.

In: Biological reviews of the Cambridge Philosophical Society, Jg. 98 (2023-12-01), Heft 6, S. 1972-2011

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Various biological attributes associated with individual fitness in animals change predictably over the lifespan of an organism. Therefore, the study of animal ecology and the work of conservationists frequently relies upon the ability to assign animals to functionally relevant age classes to model population fitness. Several approaches have been applied to determining individual age and, while these methods have proved useful, they are not without limitations and often lack standardisation or are only applicable to specific species. For these reasons, scientists have explored the potential use of biological clocks towards creating a universal age-determination method. Two biological clocks, tooth layer annulation and otolith layering have found universal appeal. Both methods are highly invasive and most appropriate for post-mortem age-at-death estimation. More recently, attributes of cellular ageing previously explored in humans have been adapted to studying ageing in animals for the use of less-invasive molecular methods for determining age. Here, we review two such methods, assessment of methylation and telomere length, describing (i) what they are, (ii) how they change with age, and providing (iii) a summary and meta-analysis of studies that have explored their utility in animal age determination. We found that both attributes have been studied across multiple vertebrate classes, however, telomere studies were used before methylation studies and telomere length has been modelled in nearly twice as many studies. Telomere length studies included in the review often related changes to stress responses and illustrated that telomere length is sensitive to environmental and social stressors and, in the absence of repair mechanisms such as telomerase or alternative lengthening modes, lacks the ability to recover. Methylation studies, however, while also detecting sensitivity to stressors and toxins, illustrated the ability to recover from such stresses after a period of accelerated ageing, likely due to constitutive expression or reactivation of repair enzymes such as DNA methyl transferases. We also found that both studied attributes have parentally heritable features, but the mode of inheritance differs among taxa and may relate to heterogamy. Our meta-analysis included more than 40 species in common for methylation and telomere length, although both analyses included at least 60 age-estimation models. We found that methylation outperforms telomere length in terms of predictive power evidenced from effect sizes (more than double that observed for telomeres) and smaller prediction intervals. Both methods produced age correlation models using similar sample sizes and were able to classify individuals into young, middle, or old age classes with high accuracy. Our review and meta-analysis illustrate that both methods are well suited to studying age in animals and do not suffer significantly from variation due to differences in the lifespan of the species, genome size, karyotype, or tissue type but rather that quantitative method, patterns of inheritance, and environmental factors should be the main considerations. Thus, provided that complex factors affecting the measured trait can be accounted for, both methylation and telomere length are promising targets to develop as biomarkers for age determination in animals.

Titel:	Biological clocks as age estimation markers in animals: a systematic review and meta-analysis.
Autor/in / Beteiligte Person:	Le Clercq, LS ; Kotzé, A ; Grobler, JP ; Dalton, DL
Link:	Full Text Finder (Volltext)
Zeitschrift:	Biological reviews of the Cambridge Philosophical Society, Jg. 98 (2023-12-01), Heft 6, S. 1972-2011
Veröffentlichung:	London, Cambridge University Press., 2023
Medientyp:	academicJournal
ISSN:	1469-185X (electronic)
DOI:	10.1111/brv.12992
Schlagwort:	Humans Animals Ecology Karyotyping Aging Biological Clocks
Sonstiges:	Nachgewiesen in: MEDLINE Sprachen: English Publication Type: Meta-Analysis; Systematic Review; Journal Article; Research Support, Non-U.S. Gov't Language: English [Biol Rev Camb Philos Soc] 2023 Dec; Vol. 98 (6), pp. 1972-2011. <i>Date of Electronic Publication: </i>2023 Jun 25. MeSH Terms: Aging* ; Biological Clocks* ; Humans ; Animals ; Ecology ; Karyotyping References: Adalsteinsson, B. T., Gudnason, H., Aspelund, T., Harris, T. B., Launer, L. J., Eiriksdottir, G., Smith, A. V. & Gudnason, V. (2012). Heterogeneity in white blood cells has potential to confound DNA methylation measurements. PLoS One 7, e46705. ; Adams, D. M. & Blanchong, J. A. (2020). Precision of cementum annuli method for aging male white-tailed deer. PLoS One 15, e0233421. ; Adams, L. & Watkins, S. G. (1967). Annuli in tooth cementum indicate age in California ground squirrels. The Journal of Wildlife Management 31, 836. ; Ahnlund, H. (1976). Age determination in the European badger, Meles meles L. Zeitschrift fur Saugetierkunder 41, 119-125. ; Anastasiadi, D. & Piferrer, F. (2020). A clockwork fish. Age-prediction using DNA methylation-based biomarkers in the European seabass. Molecular Ecology Resources 20, 387-397. ; Anchelin, M., Murcia, L., Alcaraz-Pérez, F., García-Navarro, E. M. & Cayuela, M. L. (2011). Behaviour of telomere and telomerase during aging and regeneration in zebrafish. PLoS One 6, e16955. ; Andergassen, D., Smith, Z. D., Kretzmer, H., Rinn, J. L. & Meissner, A. (2021). Diverse epigenetic mechanisms maintain parental imprints within the embryonic and extraembryonic lineages. Developmental Cell 56, 2995-3005.e4. ; Anderson, J. A., Johnston, R. A., Lea, A. J., Campos, F. A., Voyles, T. N., Akinyi, M. Y., Alberts, S. C., Archie, E. A. & Tung, J. (2021). High social status males experience accelerated epigenetic aging in wild baboons. eLife 10, e66128. ; Angelier, F., Vleck, C. M., Holberton, R. L. & Marra, P. P. (2013). Telomere length, non-breeding habitat and return rate in male American redstarts. Functional Ecology 27, 342-350. ; Ansorge, H. & Suchentrunk, F. (2001). Aging steppe polecats (Mustela eversmanni) and polecats (Mustela putorius) by canine cementum layers and skull characters. Wissenschaftliche Mitteilungen des Niederösterreichischen Landesmuseums 14, 79-106. ; Apfelbeck, B., Haussmann, M. F., Boner, W., Flinks, H., Griffiths, K., Illera, J. C., Mortega, K. G., Sisson, Z., Smiddy, P. & Helm, B. (2019). Divergent patterns of telomere shortening in tropical compared to temperate stonechats. Ecology and Evolution 9, 511-521. ; Arneson, A., Haghani, A., Thompson, M. J., Pellegrini, M., Kwon, S. B., Vu, H., Maciejewski, E., Yao, M., Li, C. Z., Lu, A. T., Morselli, M., Rubbi, L., Barnes, B., Hansen, K. D., Zhou, W., et al. (2022). A mammalian methylation array for profiling methylation levels at conserved sequences. Nature Communications 13, 1-13. ; Arthur, S. M., Cross, R., Paragi, T. F. & Krohn, W. B. (1992). Precision and utility of cementum annuli for estimating ages of fishers. Wildlife Society Bulletin 20, 402-405. ; Asghar, M., Bensch, S., Tarka, M., Hansson, B. & Hasselquist, D. (2015). Maternal and genetic factors determine early life telomere length. Proceedings of the Royal Society B: Biological Sciences 282, 20142263. ; Ashapkin, V. V., Kutueva, L. I. & Vanyushin, B. F. (2020). Quantitative analysis of DNA methylation by bisulfite sequencing. Methods in Molecular Biology 2138, 297-312. ; Attwood, J. T., Yung, R. L. & Richardson, B. C. (2002). DNA methylation and the regulation of gene transcription. Cellular and Molecular Life Sciences 59, 241-257. ; Aubert, G. & Lansdorp, P. M. (2008). Telomeres and aging. Physiological Reviews 88, 557-579. ; Aydinonat, D., Penn, D. J., Smith, S., Moodley, Y., Hoelzl, F., Knauer, F. & Schwarzenberger, F. (2014). Social isolation shortens telomeres in African Grey parrots (Psittacus erithacus erithacus). PLoS One 9, e93839. ; Azorit, C., Analla, M., Hervas, J., Carrasco, R. & Muñoz-Cobo, J. (2002). Growth marks observation: preferential techniques and teeth for ageing of Spanish red deer (Cervus elaphus hispanicus). Anatomia, Histologia, Embryologia 31, 303-307. ; Bae, J., Bertucci, E. M., Bock, S. L., Hale, M. D., Moore, J., Wilkinson, P. M., Rainwater, T. R., Bowden, J. A., Koal, T., PhamTuan, H. & Parrott, B. B. (2021). Intrinsic and extrinsic factors interact during development to influence telomere length in a long-lived reptile. Molecular Ecology 31, 6114-6127. ; Baerlocher, G. M., Mak, J., Röth, A., Rice, K. S. & Lansdorp, P. M. (2003). Telomere shortening in leukocyte subpopulations from baboons. Journal of Leukocyte Biology 73, 289-296. ; Baerlocher, G. M., Rice, K., Vulto, I. & Lansdorp, P. M. (2007). Longitudinal data on telomere length in leukocytes from newborn baboons support a marked drop in stem cell turnover around 1 year of age. Aging Cell 6, 121-123. ; Baitchman, E. J. & Kollias, G. V. (2000). Clinical anatomy of the North American river otter (Lontra canadensis). Journal of Zoo and Wildlife Medicine 31, 473-483. ; Balistreri, C. R., Candore, G., Accardi, G., Colonna-Romano, G. & Lio, D. (2013). NF-κB pathway activators as potential ageing biomarkers: targets for new therapeutic strategies. Immunity and Ageing 10, 1-16. ; Barrett, E. L. B., Burke, T. A., Hammers, M., Komdeur, J. & Richardson, D. S. (2013). Telomere length and dynamics predict mortality in a wild longitudinal study. Molecular Ecology 22, 249-259. ; Bauch, C., Becker, P. H. & Verhulst, S. (2014). Within the genome, long telomeres are more informative than short telomeres with respect to fitness components in a long-lived seabird. Molecular Ecology 23, 300-310. ; Bauch, C., Boonekamp, J. J., Korsten, P., Mulder, E. & Verhulst, S. (2021). High heritability of telomere length and low heritability of telomere shortening in wild birds. Molecular Ecology 31, 6308-6323. ; Bauch, C., Gatt, M. C., Granadeiro, J. P., Verhulst, S. & Catry, P. (2020). Sex-specific telomere length and dynamics in relation to age and reproductive success in Cory's shearwaters. Molecular Ecology 29, 1344-1357. ; Bauch, C., Gatt, M. C., Verhulst, S., Granadeiro, J. P. & Catry, P. (2022). Higher mercury contamination is associated with shorter telomeres in a long-lived seabird - a direct effect or a consequence of among-individual variation in phenotypic quality? Science of the Total Environment 839, 156359. ; Bauer, C. M. C. M., Graham, J. L. J. L., Abolins-Abols, M., Heidinger, B. J. B. J., Ketterson, E. D. E. D. & Greives, T. J. T. J. (2018). Chronological and biological age predict seasonal reproductive timing: an investigation of clutch initiation and telomeres in birds of known age. The American Naturalist 191, 777-782. ; Beal, A. P., Kiszka, J. J., Wells, R. S. & Eirin-Lopez, J. M. (2019). The bottlenose dolphin epigenetic aging tool (BEAT): a molecular age estimation tool for small cetaceans. Frontiers in Marine Science 6, 561. ; Beirne, C., Delahay, R., Hares, M. & Young, A. (2014). Age-related declines and disease-associated variation in immune cell telomere length in a wild mammal. PLoS One 9, e108964. ; Belant, J. L., Etter, D. R., Friedrich, P. D., Cosgrove, M. K., Williams, B. W. & Scribner, K. T. (2011). Comparison of techniques for sex determination of American martens. Journal of Wildlife Management 75, 256-260. ; Bell, J. T., Tsai, P. C., Yang, T. P., Pidsley, R., Nisbet, J., Glass, D., Mangino, M., Zhai, G., Zhang, F., Valdes, A., Shin, S. Y., Dempster, E. L., Murray, R. M., Grundberg, E., Hedman, A. K., et al. (2012). Epigenome-wide scans identify differentially methylated regions for age and age-related phenotypes in a healthy ageing population. PLoS Genetics 8, e1002629. ; Bender, H. S., Murchison, E. P., Pickett, H. A., Deakin, J. E., Strong, M. A., Conlan, C., McMillan, D. A., Neumann, A. A., Greider, C. W., Hannon, G. J., Reddel, R. R. & Graves, J. A. M. (2012). Extreme telomere length dimorphism in the Tasmanian devil and related marsupials suggests parental control of telomere length. PLoS One 7, e46195. ; Bird, A. (2007). Perceptions of epigenetics. Nature 447, 396-398. ; Bize, P., Criscuolo, F., Metcalfe, N. B., Nasir, L. & Monaghan, P. (2009). Telomere dynamics rather than age predict life expectancy in the wild. Proceedings of the Royal Society B: Biological Sciences 276, 1679-1683. ; Blévin, P., Angelier, F., Tartu, S., Ruault, S., Bustamante, P., Herzke, D., Moe, B., Bech, C., Gabrielsen, G. W., Bustnes, J. O. & Chastel, O. (2016). Exposure to oxychlordane is associated with shorter telomeres in Arctic breeding kittiwakes. Science of the Total Environment 563, 125-130. ; Bors, E. K., Baker, C. S., Wade, P. R., O'Neill, K. B., Shelden, K. E. W., Thompson, M. J., Fei, Z., Jarman, S. & Horvath, S. (2021). An epigenetic clock to estimate the age of living beluga whales. Evolutionary Applications 14, 1263-1273. ; Bowen, W. D., Sergeant, D. E. & Oritsland, T. (1983). Validation of age estimation in the harp seal, Phoca groenlandica, using dentinal annuli. Canadian Journal of Fisheries and Aquatic Sciences 40, 1430-1441. ; Bradley, R. J. & Safran, R. J. (2014). Conceptual revision and synthesis of proximate factors associated with age-related improvement in reproduction. Ethology 120, 411-426. ; Brandenburg, J. (2016). Persistent effects of early life exposure to polycyclic aromatic hydrocarbons on DNA methylation in birds. Masters dissertation: McGill University, Montreal. https://escholarship.mcgill.ca/concern/theses/xd07gw307. ; Brelsford, A., Milá, B. & Irwin, D. E. (2011). Hybrid origin of Audubon's warbler. Molecular Ecology 20, 2380-2389. ; Brook, C. E., Ranaivoson, H. C., Andriafidison, D., Ralisata, M., Razafimanahaka, J., Héraud, J. M., Dobson, A. P. & Metcalf, C. J. (2019). Population trends for two Malagasy fruit bats. Biological Conservation 234, 165-171. ; Brown, P., Green, C., Sivakumaran, K. P., Stoessel, D. & Giles, A. (2011). Validating otolith annuli for annual age determination of common carp. Transactions of the American Fisheries Society 133, 190-196. ; Brümmendorf, T. H., Mak, J., Sabo, K. M., Baerlocher, G. M., Dietz, K., Abkowitz, J. L. & Lansdorp, P. M. (2002). Longitudinal studies of telomere length in feline blood cells: implications for hematopoietic stem cell turnover in vivo. Experimental Hematology 30, 1147-1152. ; Buddhachat, K., Kriangwanich, W., Kumoun, S., Brown, J. L., Chailangkarn, S., Somgird, C., Thitaram, C., Prasitwattanaseree, S. & Nganvongpanit, K. (2017). Telomeric attrition with increasing age in short- (Chihuahua dog) and long- (Asian elephant) life span animals. Kafkas Universitesi Veteriner Fakultesi Dergisi 23, 643-649. ; Burraco, P., Comas, M., Reguera, S., Zamora-Camacho, F. J. & Moreno-Rueda, G. (2020). Telomere length mirrors age structure along a 2200-m altitudinal gradient in a Mediterranean lizard. Comparative Biochemistry and Physiology Part A: Molecular & Integrative Physiology 247, 110741. ; Caccavo, J. A., Raclot, T., Poupart, T., Ropert-Coudert, Y. & Angelier, F. (2021). Anthropogenic activities are associated with shorter telomeres in chicks of Adélie penguin (Pygoscelis adeliae). Polar Biology 44, 1391-1399. ; Cailliet, G. M. (1990). Elasmobranch age determination and verification: an updated review Elasmobranch age determination and verification: an updated review. In Elasmobranchs as Living Resources: Advances in the Biology, Ecology, Systematics, and the Status of Fisheries. National Oceanic and Atmospheric Administration Technical Report 90, pp. 157-165. NOAA, Seattle, USA. ; Campana, S. E. (2001). Accuracy, precision and quality control in age determination, including a review of the use and abuse of age validation methods. Journal of Fish Biology 59, 197-242. ; Cantrell, B., Friedman, S., Lachance, H., Bernier, C., Murdoch, B., Frattini, S., Talenti, A., Crepaldi, P. & McKay, S. (2020). A novel understanding of global DNA methylation in bobcat (Lynx rufus). Genome 63, 125-130. ; Carroll, E. L., Bruford, M. W., DeWoody, J. A., Leroy, G., Strand, A., Waits, L. & Wang, J. (2018). Genetic and genomic monitoring with minimally invasive sampling methods. Evolutionary Applications 11, 1094-1119. ; Casey, G. A. & Webster, W. A. (1975). Age and sex determination of striped skunks (Mephitis mephitis) from Ontario, Manitoba, and Quebec. Canadian Journal of Zoology 53, 223-226. ; Cavalli, G. & Heard, E. (2019). Advances in epigenetics link genetics to the environment and disease. Nature 571, 489-499. ; Cerchiara, J. A., Risques, R. A., Prunkard, D., Smith, J. R., Kane, O. J. & Boersma, P. D. (2017). Magellanic penguin telomeres do not shorten with age with increased reproductive effort, investment, and basal corticosterone. Ecology and Evolution 7, 5682-5691. ; Cesare, A. J. & Reddel, R. R. (2010). Alternative lengthening of telomeres: models, mechanisms and implications. Nature Reviews Genetics 11, 319-330. ; Chaney, R. C., Blemings, K. P., Bonner, J. & Klandorf, H. (2003). Pentosidine as a measure of chronological age in wild birds. Auk 120, 394-399. ; Charpentier, M. J. E., Tung, J., Altmann, J. & Alberts, S. C. (2008). Age at maturity in wild baboons: genetic, environmental and demographic influences. Molecular Ecology 17, 2026-2040. ; Chédin, F. (2011). The DNMT3 family of mammalian de novo DNA methyltransferases. Progress in Molecular Biology and Translational Science 101, 255-285. ; Cherdsukjai, P., Buddhachat, K., Brown, J., Kaewkool, M., Poommouang, A., Kaewmong, P., Kittiwattanawong, K. & Nganvongpanit, K. (2020). Age relationships with telomere length, body weight and body length in wild dugong (Dugong dugon). PeerJ 8, e10319. ; Christensen-Dalsgaard, S. N., Aars, J., Andersen, M., Lockyer, C. & Yoccoz, N. G. (2010). Accuracy and precision in estimation of age of Norwegian Arctic polar bears (Ursus maritimus) using dental cementum layers from known-age individuals. Polar Biology 33, 589-597. ; Clark, S. T., Odell, D. K. & Lacinak, C. T. (2000). Aspects of growth in captive killer whales (Orcinus orca). Marine Mammal Science 16, 110-123. ; Cleal, K., Norris, K. & Baird, D. (2018). Telomere length dynamics and the evolution of cancer genome architecture. International Journal of Molecular Sciences 19, 1-17. ; Clerc, M., Fenton, A., Babayan, S. A. & Pedersen, A. B. (2019). Parasitic nematodes simultaneously suppress and benefit from coccidian coinfection in their natural mouse host. Parasitology 146, 1096-1106. ; Clutton-Brock, T. & Sheldon, B. C. (2010). Individuals and populations: the role of long-term, individual-based studies of animals in ecology and evolutionary biology. Trends in Ecology and Evolution 25, 562-573. ; Cocci, P., Mosconi, G., Bracchetti, L., Nalocca, J. M., Frapiccini, E., Marini, M., Caprioli, G., Sagratini, G. & Palermo, F. A. (2018). Investigating the potential impact of polycyclic aromatic hydrocarbons (PAHs) and polychlorinated biphenyls (PCBs) on gene biomarker expression and global DNA methylation in loggerhead sea turtles (Caretta caretta) from the Adriatic Sea. Science of the Total Environment 619, 49-57. ; Cook, P. E., Hugo, L. E., Iturbe-Ormaetxe, I., Williams, C. R., Chenoweth, S. F., Ritchie, S. A., Ryan, P. A., Kay, B. H., Blows, M. W. & O'Neill, S. L. (2006). The use of transcriptional profiles to predict adult mosquito age under field conditions. Proceedings of the National Academy of Sciences 103, 18060-18065. ; Cossette, M.-L., Stewart, D. T., Haghani, A., Zoller, J. A., Shafer, A. B. A. & Horvath, S. (2022). Epigenetics and Island-mainland divergence in an insectivorous small mammal. Molecular Ecology 32, 152-166. ; Craighead, J. J., Craighead, F. C. & McCutchen, H. E. (1970). Age determination of grizzly bears from fourth premolar tooth sections. The Journal of Wildlife Management 34, 353. ; Cram, D. L., Monaghan, P., Gillespie, R., Dantzer, B., Duncan, C., Spence-Jones, H. & Clutton-Brock, T. (2018). Rank-related contrasts in longevity arise from extra-group excursions not delayed senescence in a cooperative mammal. Current Biology 28, 2934-2939.e4. ; Criscuolo, F., Dobson, F. S. & Schull, Q. (2021). The influence of phylogeny and life history on telomere lengths and telomere rate of change among bird species: a meta-analysis. Ecology and Evolution 11, 12908-12922. ; Criscuolo, F., Zahn, S. & Bize, P. (2017). Offspring telomere length in the long lived Alpine swift is negatively related to the age of their biological father and foster mother. Biology Letters 13, 20170188. ; Crowe, D. M. (1972). The presence of annuli in bobcat tooth cementum layers. The Journal of Wildlife Management 36, 1330. ; Crowe, D. M. & Strickland, M. D. (1975). Dental annulation in the American badger. Journal of Mammalogy 56, 269-272. ; Dalton, S. R. & Bellacosa, A. (2012). DNA demethylation by TDG. Epigenomics 4, 459-467. ; Dantzer, B. & Fletcher, Q. E. (2015). Telomeres shorten more slowly in slow-aging wild animals than in fast-aging ones. Experimental Gerontology 71, 38-47. ; Dantzer, B., van Kesteren, F., Westrick, S. E., Boutin, S., McAdam, A. G., Lane, J. E., Gillespie, R., Majer, A., Haussmann, M. F. & Monaghan, P. (2020). Maternal glucocorticoids promote offspring growth without inducing oxidative stress or shortening telomeres in wild red squirrels. Journal of Experimental Biology 223, jeb212373. ; de la Iglesia, G. (2018). Telomere length as a biomarker for stress in eastern bluebird nestlings (Sialis sialis) reared in urban habitats. Masters dissertation: Western Carolina University: Cullowhee. http://libres.uncg.edu/ir/wcu/listing.aspx?id=23338. ; de Lange, T., Shiue, L., Myers, R. M., Cox, D. R., Naylor, S. L., Killery, A. M. & Varmus, H. E. (1990). Structure and variability of human chromosome ends. Molecular and Cellular Biology 10, 518-527. ; De Paoli-Iseppi, R., Deagle, B. E., McMahon, C. R., Hindell, M. A., Dickinson, J. L. & Jarman, S. N. (2017b). Measuring animal age with DNA methylation: from humans to wild animals. Frontiers in Genetics 8, 2010-2017. ; De Paoli-Iseppi, R., Deagle, B. E., Polanowski, A. M., McMahon, C. R., Dickinson, J. L., Hindell, M. A. & Jarman, S. N. (2019). Age estimation in a long-lived seabird (Ardenna tenuirostris) using DNA methylation-based biomarkers. Molecular Ecology Resources 19, 411-425. ; De Paoli-Iseppi, R., Polanowski, A. M., McMahon, C., Deagle, B. E., Dickinson, J. L., Hindell, M. A. & Jarman, S. N. (2017a). DNA methylation levels in candidate genes associated with chronological age in mammals are not conserved in a long-lived seabird. PLoS One 12, 1-20. ; Degrandi, T. M., Barcellos, S. A., Costa, A. L., Garnero, A. D. V., Hass, I. & Gunski, R. J. (2020). Introducing the bird chromosome database: an overview of cytogenetic studies in birds. Cytogenetic and Genome Research 160, 199-205. ; Del Re, A. C. (2013). compute.es: Compute Effect Sizes. R Package. Electronic file available at https://cran.r-project.org/package=compute.es Accessed 31.10.2022. ; Denham, J., Stevenson, K. & Denham, M. M. (2019). Age-associated telomere shortening in thoroughbred horses. Experimental Gerontology 127, 110718. ; Dietz, R., Heide-Jørgensen, M. P., Härkönen, T., Teilmann, J. & Valentin, N. (1991). Age determination of European harbour seal, Phoca vitulina L. Sarsia 76, 17-21. ; Divljan, A., Parray-Jones, K. & Wardle, G. M. (2006). Age determination in the grey-headed flying fox. Journal of Wildlife Management 70, 607-611. ; Dorado-Correa, A. M., Zollinger, S. A., Heidinger, B. & Brumm, H. (2018). Timing matters: traffic noise accelerates telomere loss rate differently across developmental stages. Frontiers in Zoology 15, 1-8. ; Double, M. C., Dawson, D., Burke, T. & Cockburn, A. (1997). Finding the fathers in the least faithful bird: a microsatellite-based genotyping system for the superb fairy-wren Malurus cyaneus. Molecular Ecology 6, 691-693. ; Dunshea, G., Duffield, D., Gales, N., Hindell, M., Wells, R. S. & Jarman, S. N. (2011). Telomeres as age markers in vertebrate molecular ecology. Molecular Ecology Resources 11, 225-235. ; Dutra, L., Souza, F., Friberg, I., Araújo, M., Vasconcellos, A. & Young, R. (2020). Validating the use of oral swabs for telomere length assessment in dogs. Journal of Veterinary Behavior 40, 16-20. ; Earle, R. D. & Kramm, K. R. (1980). Techniques for age determination in the Canadian porcupine. The Journal of Wildlife Management 44, 413. ; Eastwood, J. R., Hall, M. L., Teunissen, N., Kingma, S. A., Hidalgo Aranzamendi, N., Fan, M., Roast, M., Verhulst, S. & Peters, A. (2019). Early-life telomere length predicts lifespan and lifetime reproductive success in a wild bird. Molecular Ecology 28, 1127-1137. ; Eisenberg, D. T. A., Tackney, J., Cawthon, R. M., Cloutier, C. T. & Hawkes, K. (2017). Paternal and grandpaternal ages at conception and descendant telomere lengths in chimpanzees and humans. American Journal of Physical Anthropology 162, 201-207. ; Erdem, E., Özbaşer, F. T., Gürcan, E. K. & Soysal, M. I. (2021). The morphological and morphometric characteristics of Alabadem pigeons. Turkish Journal of Veterinary and Animal Sciences 45, 372-379. ; Fairlie, J., Holland, R., Pilkington, J. G., Pemberton, J. M., Harrington, L. & Nussey, D. H. (2016). Lifelong leukocyte telomere dynamics and survival in a free-living mammal. Aging Cell 15, 140-148. ; Faul, F., Erdfelder, E., Buchner, A. & Lang, A. G. (2009). Statistical power analyses using GPower 3.1: Tests for correlation and regression analyses. Behavior Research Methods 41, 1149-1160. ; Fick, L. J., Fick, G. H., Li, Z., Cao, E., Bao, B., Heffelfinger, D., Parker, H. G., Ostrander, E. A. & Riabowol, K. (2012). Telomere length correlates with life span of dog breeds. Cell Reports 2, 1530-1536. ; Fitz-James, M. H. & Cavalli, G. (2022). Molecular mechanisms of transgenerational epigenetic inheritance. Nature Reviews Genetics 23, 325-341. ; Fohringer, C., Hoelzl, F., Allen, A. M., Cayol, C., Ericsson, G., Spong, G., Smith, S. & Singh, N. J. (2022). Large mammal telomere length variation across ecoregions. BMC Ecology and Evolution 22, 1-10. ; Foley, N. M., Hughes, G. M., Huang, Z., Clarke, M., Jebb, D., Whelan, C. V., Petit, E. J., Touzalin, F., Farcy, O., Jones, G., Ransome, R. D., Kacprzyk, J., O'Connell, M. J., Kerth, G., Rebelo, H., et al. (2018). Growing old, yet staying young: the role of telomeres in bats' exceptional longevity. Science Advances 4, eaao0926. ; Foley, N. M., Petit, E. J., Brazier, T., Finarelli, J. A., Hughes, G. M., Touzalin, F., Puechmaille, S. J. & Teeling, E. C. (2020). Drivers of longitudinal telomere dynamics in a long-lived bat species, Myotis myotis. Molecular Ecology 29, 2963-2977. ; Friesen, C. R., Wapstra, E. & Olsson, M. (2021). Of telomeres and temperature: measuring thermal effects on telomeres in ectothermic animals. Molecular Ecology 31, 6069-6086. ; Froy, H., Bird, E. J., Wilbourn, R. V., Fairlie, J., Underwood, S. L., Salvo-Chirnside, E., Pilkington, J. G., Bérénos, C., Pemberton, J. M. & Nussey, D. H. (2017). No evidence for parental age effects on offspring leukocyte telomere length in free-living Soay sheep. Scientific Reports 7, 9991. ; Froy, H., Underwood, S. L., Dorrens, J., Seeker, L. A., Watt, K., Wilbourn, R. V., Pilkington, J. G., Harrington, L., Pemberton, J. M. & Nussey, D. H. (2021). Heritable variation in telomere length predicts mortality in Soay sheep. Proceedings of the National Academy of Sciences of the United States of America 118, e2020563118. ; Garde, E., Frie, A. K., Dunshea, G., Hansen, S. H., Kovacs, K. M. & Lydersen, C. (2010). Harp seal ageing techniques-teeth, aspartic acid racemization, and telomere sequence analysis. Journal of Mammalogy 91, 1365-1374. ; Gomes, N. M. V., Ryder, O. A., Houck, M. L., Charter, S. J., Walker, W., Forsyth, N. R., Austad, S. N., Venditti, C., Pagel, M., Shay, J. W. & Wright, W. E. (2011). Comparative biology of mammalian telomeres: hypotheses on ancestral states and the roles of telomeres in longevity determination. Aging Cell 10, 761-768. ; Gomez, A., Karlgren, M., Edler, D., Bernal, M. L., Mkrtchian, S. & Ingelman-Sundberg, M. (2007). Expression of CYP2W1 in colon tumors: regulation by gene methylation. Pharmacogenomics 8, 1315-1325. ; Gopalan, S., Carja, O., Fagny, M., Patin, E., Myrick, J. W., McEwen, L. M., Mah, S. M., Kobor, M. S., Froment, A., Feldman, M. W., Quintana-Murci, L. & Henn, B. M. (2017). Trends in DNA methylation with age replicate across diverse human populations. Genetics 206, 1659-1674. ; Goren, A. D., Brodie, P. F., Spotte, S., Ray, G. C., Kaufman, H. W., Gwinnett, A. J., Sciubba, J. J. & Buck, J. D. (1987). Growth layer groups (GLGs) in the teeth of an adult beluga whale (Delphinaptherus leucas) of known age: evidence for two annual layers. Marine Mammal Science 3, 14-21. ; Gosselink, T. E., van Deelen, T. R., Warner, R. E. & Joselyn, M. G. (2003). Temporal habitat partitioning and spatial use of coyotes and red foxes in east-Central Illinois. The Journal of Wildlife Management 67, 90. ; Gourichon, L. & Parmigiani, V. (2016). Preliminary analysis of dental cementum of Lama guanicoe for the estimation of age and season at death: studies of modern specimens and further archaeological applications. Journal of Archaeological Science: Reports 6, 856-861. ; Graham, J. L. (2018). Reproductive timing in a changing world: understanding mechanisms and costs associated with reproductive timing decisions. Doctoral Thesis: North Dakota State University of Agriculture and Applied Science Fargo. https://hdl.handle.net/10365/27478. ; Grau, G. A., Sanderson, G. C. & Rogers, J. P. (1970). Age determination of raccoons. The Journal of Wildlife Management 34, 364. ; Gregory, T. R. (2023). Animal genome size database. Electronic file available at http://www.genomesize.com Accessed 8.5.2023. ; Greider, C. W. & Blackburn, E. H. (1985). Identification of a specific telomere terminal transferase activity in tetrahymena extracts. Cell 43, 405-413. ; Grimsdell, J. J. R. (1973). Age determination of the African buffalo, Syncerus caffer Sparrman. African Journal of Ecology 11, 31-53. ; Grue, H. & Jensen, B. (1979). Review of the formation of incremental lines in tooth cementum of terrestrial mammals. Danish Review of Game Biology 11, 1-48. ; Grunst, M. L., Grunst, A. S., Pinxten, R. & Eens, M. (2020). Anthropogenic noise is associated with telomere length and carotenoid-based coloration in free-living nestling songbirds. Environmental Pollution 260, 114032. ; Guevara, E. E., Lawler, R. R., Staes, N., White, C. M., Sherwood, C. C., Ely, J. J., Hopkins, W. D. & Bradley, B. J. (2020). Age-associated epigenetic change in chimpanzees and humans: chimpanzee epigenetic age. Philosophical Transactions of the Royal Society B: Biological Sciences 375, 20190616. ; Guo, F., Li, X., Liang, D., Li, T., Zhu, P., Guo, H., Wu, X., Wen, L., Gu, T. P., Hu, B., Walsh, C. P., Li, J., Tang, F. & Xu, G. L. (2014). Active and passive demethylation of male and female pronuclear DNA in the mammalian zygote. Cell Stem Cell 15, 447-459. ; Haddaway, N. R., Page, M. J., Pritchard, C. C. & McGuinness, L. A. (2022). PRISMA2020: an R package and Shiny app for producing PRISMA 2020-compliant flow diagrams, with interactivity for optimised digital transparency and open synthesis. Campbell Systematic Reviews 18, e1230. ; Hannum, G., Guinney, J., Zhao, L., Zhang, L., Hughes, G., Sadda, S. V., Klotzle, B., Bibikova, M., Fan, J. B., Gao, Y., Deconde, R., Chen, M., Rajapakse, I., Friend, S., Ideker, T., et al. (2013). Genome-wide methylation profiles reveal quantitative views of human aging rates. Molecular Cell 49, 359-367. ; Hansen, E., Skotnes, T., Bustnes, J. O., Helander, B., Eulaers, I., Sun, J., Covaci, A., Bårdsen, B. J., Zahn, S., Criscuolo, F. & Bourgeon, S. (2022). Telomere length in relation to persistent organic pollutant exposure in white-tailed eagle (Haliaeetus albicilla) nestlings from Sweden sampled in 1995-2013. Environmental Research 208, 112712. ; Hartmann, N., Reichwald, K., Lechel, A., Graf, M., Kirschner, J., Dorn, A., Terzibasi, E., Wellner, J., Platzer, M., Rudolph, K. L., Cellerino, A. & Englert, C. (2009). Telomeres shorten while Tert expression increases during ageing of the short-lived fish Nothobranchius furzeri. Mechanisms of Ageing and Development 130, 290-296. ; Hatase, H., Sudo, R., Watanabe, K. K., Kasugai, T., Saito, T., Okamoto, H., Uchida, I. & Tsukamoto, K. (2008). Shorter telomere length with age in the loggerhead turtle: a new hope for live sea turtle age estimation. Genes and Genetic Systems 83, 423-426. ; Haussmann, M. F. & Vleck, C. M. (2002). Telomere length provides a new technique for aging animals. Oecologia 130, 325-328. ; Haussmann, M. F., Vleck, C. M. & Nisbet, I. C. T. (2003). Calibrating the telomere clock in common terns, Sterna hirundo. Experimental Gerontology 38, 787-789. ; Heidinger, B. J., Blount, J. D., Boner, W., Griffiths, K., Metcalfe, N. B. & Monaghan, P. (2012). Telomere length in early life predicts lifespan. Proceedings of the National Academy of Sciences of the United States of America 109, 1743-1748. ; Higgs, D. M., Souza, M. J., Wilkins, H. R., Presson, J. C. & Popper, A. N. (2002). Age- and size-related changes in the inner ear and hearing ability of the adult zebrafish (Danio rerio). Journal of the Association for Research in Otolaryngology 3, 174-184. ; Hiller, T. L. & Tyre, A. J. (2014). Comparison of two age-estimation techniques for cougars. Northwestern Naturalist 95, 77-82. ; Hoelzl, F., Cornils, J. S., Smith, S., Moodley, Y. & Ruf, T. (2016a). Telomere dynamics in free-living edible dormice (Glis glis): the impact of hibernation and food supply. Journal of Experimental Biology 219, 2469-2474. ; Hoelzl, F., Smith, S., Cornils, J. S., Aydinonat, D., Bieber, C. & Ruf, T. (2016b). Telomeres are elongated in older individuals in a hibernating rodent, the edible dormouse (Glis glis). Scientific Reports 6, 36856. ; Hohn, A. A. (1980). Age determination and age related factors in the teeth of Western North Atlantic bottlenose dolphins. Scientific Reports of the Whales Research Institute 32, 39-66. ; Høie, H., Andersson, C., Folkvord, A. & Karlsen, Ø. (2004). Precision and accuracy of stable isotope signals in otoliths of pen-reared cod (Gadus morhua) when sampled will a high-resolution micromill. Marine Biology 144, 1039-1049. ; Hong, S. R., Shin, K. J., Jung, S. E., Lee, E. H. & Lee, H. Y. (2019). Platform-independent models for age prediction using DNA methylation data. Forensic Science International: Genetics 38, 39-47. ; Horn, T., Gemmell, N. J., Robertson, B. C. & Bridges, C. R. (2008). Telomere length change in European sea bass (Dicentrarchus labrax). Australian Journal of Zoology 56, 207-210. ; Horn, T., Robertson, B. C. & Gemmell, N. J. (2010). The use of telomere length in ecology and evolutionary biology. Heredity 105, 497-506. ; Horn, T., Robertson, B. C., Will, M., Eason, D. K., Elliott, G. P. & Gemmell, N. J. (2011). Inheritance of telomere length in a bird. PLoS One 6, e17199. ; Horvath, S. (2013). DNA methylation age of human tissues and cell types. Genome Biology 14, 3156. ; Horvath, S., Haghani, A., Macoretta, N., Ablaeva, J., Zoller, J. A., Li, C. Z., Zhang, J., Takasugi, M., Zhao, Y., Rydkina, E., Zhang, Z., Emmrich, S., Raj, K., Seluanov, A., Faulkes, C. G., et al. (2022a). DNA methylation clocks tick in naked mole rats but queens age more slowly than nonbreeders. Nature Aging 2, 46-59. ; Horvath, S., Haghani, A., Peng, S., Hales, E. N., Zoller, J. A., Raj, K., Larison, B., Robeck, T. R., Petersen, J. L., Bellone, R. R. & Finno, C. J. (2022b). DNA methylation aging and transcriptomic studies in horses. Nature Communications 13, 1-13. ; Horvath, S., Haghani, A., Zoller, J. A., Fei, Z., Bérubé, M. & Robbins, J. (2022c). DNA methylation age studies of humpback whales. bioRxiv 2022.08.15.503952. https://doi.org/10.1101/2022.08.15.503952. ; Horvath, S., Haghani, A., Zoller, J. A., Raj, K., Sinha, I., Robeck, T. R., Black, P., Couzens, A., Lau, C., Manoyan, M., Ruiz, Y. A., Talbott, A., Belov, K., Hogg, C. J. & Sears, K. E. (2022d). Epigenetic clock and methylation studies in marsupials: opossums, Tasmanian devils, kangaroos, and wallabies. GeroScience 44, 1825-1845. ; Horvath, S., Lu, A. T., Haghani, A., Zoller, J. A., Li, C. Z., Lim, A. R., Brooke, R. T., Raj, K., Serres-Armero, A., Dreger, D. L., Hogan, A. N., Plassais, J. & Ostrander, E. A. (2022e). DNA methylation clocks for dogs and humans. Proceedings of the National Academy of Sciences of the United States of America 119, e2120887119. ; Horvath, S. & Raj, K. (2018). DNA methylation-based biomarkers and the epigenetic clock theory of ageing. Nature Reviews Genetics 19, 371-384. ; Horvath, S., Zoller, J. A., Haghani, A., Jasinska, A. J., Raj, K., Breeze, C. E., Ernst, J., Vaughan, K. L. & Mattison, J. A. (2021a). Epigenetic clock and methylation studies in the rhesus macaque. GeroScience 43, 2441-2453. ; Horvath, S., Zoller, J. A., Haghani, A., Lu, A. T., Raj, K., Jasinska, A. J., Mattison, J. A. & Salmon, A. B. (2021b). DNA methylation age analysis of rapamycin in common marmosets. GeroScience 43, 2413-2425. ; Ibáñez-Álamo, J. D., Pineda-Pampliega, J., Thomson, R. L., Aguirre, J. I., Díez-Fernández, A., Faivre, B., Figuerola, J. & Verhulst, S. (2018). Urban blackbirds have shorter telomeres. Biology Letters 14, 20180083. ; Ineson, K. M., O'Shea, T. J., Kilpatrick, C. W., Parise, K. L. & Foster, J. T. (2020). Ambiguities in using telomere length for age determination in two North American bat species. Journal of Mammalogy 101, 958-969. ; Isermann, D. A., Wolter, M. H. & Breeggemann, J. J. (2010). Estimating black crappie age: an assessment of dorsal spines and scales as nonlethal alternatives to otoliths. North American Journal of Fisheries Management 30, 1591-1598. ; Ito, G., Yoshimura, K. & Momoi, Y. (2017). Analysis of DNA methylation of potential age-related methylation sites in canine peripheral blood leukocytes. Journal of Veterinary Medical Science 79, 745-750. ; Ito, H., Udono, T., Hirata, S. & Inoue-Murayama, M. (2018). Estimation of chimpanzee age based on DNA methylation. Scientific Reports 8, 1-5. ; Izzo, C. (2010). Patterns of telomere length change with age in aquatic vertebrates and the phylogenetic distribution of the pattern among jawed vertebrates. Doctoral Thesis: University of Adelaide, Adelaide. https://hdl.handle.net/2440/63477. ; Izzo, C., Bertozzi, T., Gillanders, B. M. & Donnellan, S. C. (2014). Variation in telomere length of the common carp, Cyprinus carpio (Cyprinidae), in relation to body length. Copeia 2014, 87-94. ; Izzo, C., Hamer, D. J., Bertozzi, T., Donnellan, S. C. & Gillanders, B. M. (2011). Telomere length and age in pinnipeds: the endangered Australian sea lion as a case study. Marine Mammal Science 27, 841-851. ; Jarman, S. N., Polanowski, A. M., Faux, C. E., Robbins, J., De Paoli-Iseppi, R., Bravington, M. & Deagle, B. E. (2015). Molecular biomarkers for chronological age in animal ecology. Molecular Ecology 24, 4826-4847. ; Jasinska, A. J., Haghani, A., Zoller, J. A., Li, C. Z., Arneson, A., Ernst, J., Kavanagh, K., Jorgensen, M. J., Mattison, J. A., Wojta, K., Choi, O. W., DeYoung, J., Li, X., Rao, A. W., Coppola, G., et al. (2022). Epigenetic clock and methylation studies in vervet monkeys. GeroScience 44, 699-717. ; Johansson, Å., Enroth, S. & Gyllensten, U. (2013). Continuous aging of the human DNA methylome throughout the human lifespan. PLoS One 8, 67378. ; Jones, M. J., Goodman, S. J. & Kobor, M. S. (2015). DNA methylation and healthy human aging. Aging Cell 14, 924-932. ; Jones, O. R., Scheuerlein, A., Salguero-Gómez, R., Camarda, C. G., Schaible, R., Casper, B. B., Dahlgren, J. P., Ehrlén, J., García, M. B., Menges, E. S., Quintana-Ascencio, P. F., Caswell, H., Baudisch, A. & Vaupel, J. W. (2014). Diversity of ageing across the tree of life. Nature 505, 169-173. ; Juola, F. A., Haussmann, M. F., Dearborn, D. C. & Vleck, C. M. (2006). Telomere shortening in a long-lived marine bird: cross-sectional analysis and test of an aging tool. The Auk 123, 775-783. ; Kagiwada, S., Kurimoto, K., Hirota, T., Yamaji, M. & Saitou, M. (2013). Replication-coupled passive DNA demethylation for the erasure of genome imprints in mice. EMBO Journal 32, 340-353. ; Kamler, J. F. & Macdonald, D. W. (2006). Longevity of a wild bat-eared fox. African Journal of Wildlife Research 36, 199-200. ; Kang, H. (2021). Sample size determination and power analysis using the Gpower software. Journal of Educational Evaluation for Health Professions 18, 1-12. ; Karere, G. M., Mahaney, M. C., Newman, D. E., Riojas, A. M., Christensen, C., Birnbaum, S., VandeBerg, J. L. & Cox, L. (2019). Diet-induced leukocyte telomere shortening in a baboon model for early stage atherosclerosis. Scientific Reports 9, 1-9. ; Kärkkäinen, T., Laaksonen, T., Burgess, M., Cantarero, A., Martínez-Padilla, J., Potti, J., Moreno, J., Thomson, R. L., Tilgar, V. & Stier, A. (2021). Population differences in the length and early-life dynamics of telomeres among European pied flycatchers. Molecular Ecology 31, 5966-5978. ; Kärkkäinen, T., Teerikorpi, P., Panda, B., Helle, S., Stier, A. & Laaksonen, T. (2019). Impact of continuous predator threat on telomere dynamics in parent and nestling pied flycatchers. Oecologia 191, 757-766. ; Kasuya, T. & Matsui, S. (1984). Age determination and growth of the short-finned pilot whale off the Pacific coast of Japan. Scientific Reports of the Whales Research Institute Tokyo 35, 57-92. ; Kazda, A., Zellinger, B., Rössler, M., Derboven, E., Kusenda, B. & Riha, K. (2012). Chromosome end protection by blunt-ended telomeres. Genes and Development 26, 1703-1713. ; Kenyon, K. W. & Fiscus, C. H. (1963). Age determination in the Hawaiian monk seal. Journal of Mammalogy 44, 280. ; Kerepesi, C., Meer, M. V., Ablaeva, J., Amoroso, V. G., Lee, S. G., Zhang, B., Gerashchenko, M. V., Trapp, A., Yim, S. H., Lu, A. T., Levine, M. E., Seluanov, A., Horvath, S., Park, T. J., Gorbunova, V., et al. (2022). Epigenetic aging of the demographically non-aging naked mole-rat. Nature Communications 13, 1-10. ; Kim, K. S. & Sappington, T. W. (2013). Microsatellite data analysis for population genetics. In Microsatellites: Methods in Molecular Biology (Volume 1006, ed. S. Kantartzi), pp. 271-295. Humana Press, Totowa. ; Kimura, M. (1980). Variability in techniques of counting dentinal growth layer groups in a tooth of a known-age dolphin, Tursiops truncatus. Reports of the International Whaling Commission, Special Issue 3, 161-163. ; Kingsmill, E. (1962). An investigation of criteria for estimating age in the marsupials Trichosurus vulpecula kerr and Perameles nasuta geoffroy. Australian Journal of Zoology 10, 597-616. ; Kipling, D. & Cooke, H. J. (1990). Hypervariable ultra-long telomeres in mice. Nature 347, 400-402. ; Kirby, R., Alldredge, M. W. & Pauli, J. N. (2017). Environmental, not individual, factors drive markers of biological aging in black bears. Evolutionary Ecology 31, 571-584. ; Klevezal, G. A. & Pucek, Z. (1987). Bisoniana XCIII. Growth layers in tooth cement and dentine of European bison and its hybrids with domestic cattle. Acta Theriologica 32, 115-128. ; Klevezal, G. A. & Stewart, B. S. (1994). Patterns and calibration of layering in tooth cementum of female northern elephant seals, Mirounga angustirostris. Journal of Mammalogy 75, 483-487. ; Kordowitzki, P., Haghani, A., Zoller, J. A., Li, C. Z., Raj, K., Spangler, M. L. & Horvath, S. (2021). Epigenetic clock and methylation study of oocytes from a bovine model of reproductive aging. Aging Cell 20, e13349. ; Kujoth, C. C., Hiona, A., Pugh, T. D., Someya, S., Panzer, K., Wohlgemuth, S. E., Hofer, T., Seo, A. Y., Sullivan, R., Jobling, W. A., Morrow, J. D., Van Remmen, H., Sedivy, J. M., Yamasoba, T., Tanokura, M., et al. (2005). Medicine: mitochondrial DNA mutations, oxidative stress, and apoptosis in mammalian aging. Science 309, 481-484. ; Kurdyukov, S. & Bullock, M. (2016). DNA methylation analysis: choosing the right method. Biology 5, 3. ; Lachance, H., Cantrell, B., Friedman, S., Mckay, S. & Yee, R. (2015). Genome-wide epigenetic survey of Vermont bobcat (Lynx rufus) and fisher (Martes pennanti). In 74th Annual Conference of the Northeast Association of Fish and Wildlife Agencies. Northeast Association of Fish and Wildlife Agencies, Vermont. ; Larison, B., Pinho, G. M., Hagani, A., Zoller, J. A., Li, C. Z., Finno, C. J., Farrell, C., Kaelin, C. B., Barsh, G. S., Wooding, B., Robeck, T. R., Maddox, D., Pellegrini, M. & Horvath, S. (2021b). Epigenetic models predict age and aging in plains zebras and other equids. bioRxiv 2021.03.29.437607. https://doi.org/10.1101/2021.03.29.437607. ; Larison, B., Pinho, G. M., Haghani, A., Zoller, J. A., Li, C. Z., Finno, C. J., Farrell, C., Kaelin, C. B., Barsh, G. S., Wooding, B., Robeck, T. R., Maddox, D., Pellegrini, M. & Horvath, S. (2021a). Epigenetic models developed for plains zebras predict age in domestic horses and endangered equids. Communications Biology 4, 1-9. ; Larter, N. C. & Allaire, D. G. (2016). Longevity and mortality of boreal woodland caribou (Rangifer tarandus caribou) of the dehcho region, northwest territories. Canadian Field-Naturalist 130, 222-223. ; Laws, R. M. (1952). A new method of age determination for mammals. Nature 169, 972-973. ; Laws, R. M. (1958). Growth rates and ages of crabeater seals, Lobodon carcinophagus. Proceedings of the Zoological Society of London 130, 275-288. ; Le Clercq, L. S., Dalton, D. L. & Kotzé, A. (2018). Molecular age estimation based on promotor CpG methylation using methylation sensitive PCR. In Poster Presented at: 9th Annual Research Symposium of the National Zoological Gardens of South Africa. SANBI, Pretoria. https://doi.org/10.13140/RG.2.2.11352.21768. ; Lee, W. W., Nam, K. H., Terao, K. & Yoshikawa, Y. (2002). Age-related telomere length dynamics in peripheral blood mononuclear cells of healthy cynomolgus monkeys measured by flow FISH. Immunology 105, 458-465. ; Lemaître, J. F., Rey, B., Gaillard, J. M., Régis, C., Gilot-Fromont, E., Débias, F., Duhayer, J., Pardonnet, S., Pellerin, M., Haghani, A., Zoller, J. A., Li, C. Z. & Horvath, S. (2022). DNA methylation as a tool to explore ageing in wild roe deer populations. Molecular Ecology Resources 22, 1002-1015. ; Leonida, S. R. L., Bennett, N. C., Leitch, A. R. & Faulkes, C. G. (2020). Patterns of telomere length with age in African mole-rats: new insights from quantitative fluorescence in situ hybridisation (qFISH). PeerJ 8, e10498. ; Lewin, N., Treidel, L. A., Holekamp, K. E., Place, N. J. & Haussmann, M. F. (2015). Socioecological variables predict telomere length in wild spotted hyenas. Biology Letters 11, 20140991. ; Liebl, A. L., Wesner, J. S., Russell, A. F. & Schrey, A. W. (2021). Methylation patterns at fledging predict delayed dispersal in a cooperatively breeding bird. PLoS One 16, e0252227. ; Linck, E., Freeman, B. G. & Dumbacher, J. P. (2020). Speciation and gene flow across an elevational gradient in New Guinea kingfishers. Journal of Evolutionary Biology 33, 1643-1652. ; Lind, M. I. & Spagopoulou, F. (2018). Evolutionary consequences of epigenetic inheritance. Heredity 121, 205-209. ; Linhart, S. B. (1973). Age determination and occurrence of incremental growth lines in the dental cementum of the common vampire bat (Desmodus rotundus). Journal of Mammalogy 54, 493-496. ; Little, T. J., O'Toole, A. N., Rambaut, A., Chandra, T., Marioni, R. & Pedersen, A. B. (2020). Methylation-based age estimation in a wild mouse. bioRxiv 2020.07.16.203687. https://doi.org/10.1101/2020.07.16.203687. ; Liu, L., Bailey, S. M., Okuka, M., Muñoz, P., Li, C., Zhou, L., Wu, C., Czerwiec, E., Sandler, L., Seyfang, A., Blasco, M. A. & Keefe, D. L. (2007). Telomere lengthening early in development. Nature Cell Biology 9, 1436-1441. ; Lockyer, C. H. (1993). A report on patterns of deposition of dentine and cement in teeth of pilot whales, genus Globicephala. In Reports of the International Whaling Commission, Special Issue (Volume 14), pp. 137-161. IWC, Impington, UK. ; Lockyer, C. H., Hohn, A. A., Doidge, W. D., Heide-Jørgensen, M. P. & Suydam, R. (2007). Age determination in belugas (Delphinapterus leucas): a quest for validation of dentinal layering. Aquatic Mammals 33, 293-304. ; Lombaard, L. J. (1971). Age determination and growth curved in the black-backed jackal Canis mesomelas Schreber, 1775 (Carnivora: Canidae). Annals of the Transvaal Museum 27, 135-169. ; Low, W. A. (1970). The influence of aridity on reproduction of the collared peccary (Picotyles tajacu (Linn)) in Texas. Doctoral Thesis: University of British Columbia, Vancouver. http://hdl.handle.net/2429/34781. ; Low, W. A. & Cowan, I. M. (1963). Age determination of deer by annular structure of dental cementum. The Journal of Wildlife Management 27, 466. ; Lowe, R., Barton, C., Jenkins, C. A. C. A., Ernst, C., Forman, O., Fernandez-Twinn, D. S. D. S., Bock, C., Rossiter, S. J. S. J., Faulkes, C. G. C. G., Ozanne, S. E. S. E., Walter, L., Odom, D. T., Mellersh, C. & Rakyan, V. K. V. K. (2018). Ageing-associated DNA methylation dynamics are a molecular readout of lifespan variation among mammalian species. Genome Biology 19, 1-8. ; Lowe, R., Danson, A. F., Rakyan, V. K., Yildizoglu, S., Saldmann, F., Viltard, M., Friedlander, G. & Faulkes, C. G. (2020). DNA methylation clocks as a predictor for ageing and age estimation in naked mole-rats, Heterocephalus glaber. Aging 12, 4394-4406. ; Lund, T. C., Glass, T. J., Tolar, J. & Blazar, B. R. (2009). Expression of telomerase and telomere length are unaffected by either age or limb regeneration in Danio rerio. PLoS One 4, e7688. ; Lundsgaard, N. U., Cramp, R. L. & Franklin, C. E. (2022). Early exposure to UV radiation causes telomere shortening and poorer condition later in life. Journal of Experimental Biology 225, jeb243924. ; Macchi, F., Edsinger, E. & Sadler, K. C. (2022). Epigenetic machinery is functionally conserved in cephalopods. BMC Biology 20, 1-23. ; Mäkinen, H., Viitaniemi, H. M., Visser, M. E., Verhagen, I., van Oers, K. & Husby, A. (2019). Temporally replicated DNA methylation patterns in great tit using reduced representation bisulfite sequencing. Scientific Data 6, 1-7. ; Marker, L. L. & Dickman, A. J. (2003). Morphology, physical condition, and growth of the cheetah (Acinonyx jubatus jubatus). Journal of Mammalogy 84, 840-850. ; Marker, L. L., Dickman, A. J., Jeo, R. M., Mills, M. G. L. & Macdonald, D. W. (2003). Demography of the Namibian cheetah, Acinonyx jubatus jubatus. Biological Conservation 114, 413-425. ; Marks, S. A. & Erickson, A. W. (1966). Age determination in the black bear. The Journal of Wildlife Management 30, 389-410. ; Marsh, H., Heinsohn, G. E. & Marsh, L. M. (1984). Breeding cycle, life history and population dynamics of the dugong, Dugon dugon. Australian Journal of Zoology 32, 767-788. ; Mayne, B., Berry, O. & Jarman, S. (2021b). Optimal sample size for calibrating DNA methylation age estimators. Molecular Ecology Resources 21, 2316-2323. ; Mayne, B., Espinoza, T., Roberts, D., Butler, G. L., Brooks, S., Korbie, D. & Jarman, S. (2021a). Nonlethal age estimation of three threatened fish species using DNA methylation: Australian lungfish, Murray cod and Mary River cod. Molecular Ecology Resources 21, 2324-2332. ; Mayne, B., Korbie, D., Kenchington, L., Ezzy, B., Berry, O. & Jarman, S. (2020a). A DNA methylation age predictor for zebrafish. Aging 12, 24817-24835. ; Mayne, B., Mustin, W., Baboolal, V., Casella, F., Ballorain, K., Barret, M., Vanderklift, M. A., Tucker, A. D., Korbie, D., Jarman, S. & Berry, O. (2022). Age prediction of green turtles with an epigenetic clock. Molecular Ecology Resources 22, 2275-2284. ; Mayne, B., Tucker, A. D., Berry, O. & Jarman, S. (2020b). Lifespan estimation in marine turtles using genomic promoter CpG density. PLoS One 15, e0236888. ; Mbizah, M. M., Steenkamp, G. & Groom, R. J. (2016). Evaluation of the applicability of different age determination methods for estimating age of the endangered African wild dog (Lycaon pictus). PLoS One 11, e0164676. ; McCarthy, T. M., Fuller, T. K. & Munkhtsog, B. (2005). Movements and activities of snow leopards in southwestern Mongolia. Biological Conservation 124, 527-537. ; McClintock, B. (1941). The stability of broken ends of chromosomes in Zea mays. Genetics 26, 234-282. ; McCutchen, H. E. (1969). Age determination of pronghorns by the incisor cementum. The Journal of Wildlife Management 33, 172. ; McEwen, L. M., Goodman, S. J., Kobor, M. S. & Jones, M. J. (2017). The DNA methylome: an interface between the environment, immunity, and ageing. In: The Ageing Immune System and Health pp. 35-52. Springer, Cham. ; McKevitt, T. P., Nasir, L., Devlin, P. & Argyle, D. J. (2002). Telomere lengths in dogs decrease with increasing donor age. Journal of Nutrition 132, 1604S-1606S. ; McKevitt, T. P., Nasir, L., Wallis, C. V. & Argyle, D. J. (2003). A cohort study of telomere and telomerase biology in cats. American Journal of Veterinary Research 64, 1496-1499. ; Mclaren, I. (1958). The biology of the ringed seal (Phoca hispida Schreber) in the eastern Canadian Arctic. Bulletin of the Fisheries Research Board of Canada 118, 1-97. ; Meillère, A., Brischoux, F., Ribout, C. & Angelier, F. (2015). Traffic noise exposure affects telomere length in nestling house sparrows. Biology Letters 11, 20150559. ; Mensà, E., Latini, S., Ramini, D., Storci, G., Bonafè, M. & Olivieri, F. (2019). The telomere world and aging: analytical challenges and future perspectives. Ageing Research Reviews 50, 27-42. ; Merlin, C. & Liedvogel, M. (2019). The genetics and epigenetics of animal migration and orientation: birds, butterflies and beyond. The Journal of Experimental Biology 222, jeb191890. ; Meyer, B. S., Moiron, M., Caswara, C., Chow, W., Fedrigo, O., Formenti, G., Haase, B., Howe, K., Mountcastle, J., Uliano-Silva, M., Wood, J., Jarvis, E. D., Liedvogel, M. & Bouwhuis, S. (2023). Sex-specific changes in autosomal methylation rate in ageing common terns. Frontiers in Ecology and Evolution 11, 20. ; Miller, F. L. (1974). Age determination of caribou by annulations in dental cementum. The Journal of Wildlife Management 38, 47. ; Mitchell, B. (1967). Growth layers in dental cement for determining the age of red deer (Cervus elaphus L.). The Journal of Animal Ecology 36, 279. ; Miura, S. (1985). Horn and cementum annulation as age criteria in Japanese serow. The Journal of Wildlife Management 49, 152. ; Molbert, N., Angelier, F., Alliot, F., Ribout, C. & Goutte, A. (2021). Fish from urban rivers and with high pollutant levels have shorter telomeres: telomeres and contamination in fish. Biology Letters 17, 20200819. ; Morin, P. A., Nestler, A., Rubio-Cisneros, N. T., Robertson, K. M. & Mesnick, S. L. (2005). Interfamilial characterization of a region of the ZFX and ZFY genes facilitates sex determination in cetaceans and other mammals. Molecular Ecology 14, 3275-3286. ; Morselli, M., Bennett, R., Shaidani, N.-I., Horb, M., Peshkin, L. & Pellegrini, M. (2023). Age-associated DNA methylation changes in Xenopus frogs. Epigenetics 18, 2201517. ; Moyzis, R. K., Buckingham, J. M., Crams, L. S., Dani, M., Deavent, L. L., Jones, M. D., Meyne, J., Ratliff, R. L. & Wu, J.-R. (1988). A highly conserved repetitive DNA sequence, (TTAGGG)n, present at the telomeres of human chromosomes. Proceedings of the National Academy of Sciences 85, 6622-6626. ; Myrick, A. C. J., Hohn, A. A., Sloan, P. A., Makoto, K. & Stanley, D. D. (1983). Estimating age of spotted and spinner dolphins (Stenella attenuata and Stenella longirostris) from teeth. NOAA Technical Memorandum NMFS, SWFC-30. ; Nakanishi, N., Ichinose, F., Higa, G. & Izawa, M. (2009). Age determination of the iriomote cat by using cementum annuli. Journal of Zoology 279, 338-348. ; Newham, E., Gill, P. G., Robson Brown, K., Gostling, N. J. & Schneider, P. (2021). A robust, semi-automated approach for counting cementum increments imaged 1 with X-ray computed tomography. PLoS One 16, e0249743. ; Nicholson, W. S., Hill, E. P. & Briggs, D. (1985). Denning, pup-rearing, and dispersal in the gray fox in east-Central Alabama. The Journal of Wildlife Management 49, 33. ; Nilsen, F. M., Parrott, B. B., Bowden, J. A., Kassim, B. L., Somerville, S. E., Bryan, T. A., Bryan, C. E., Lange, T. R., Delaney, J. P., Brunell, A. M., Long, S. E. & Guillette, L. J. (2016). Global DNA methylation loss associated with mercury contamination and aging in the American alligator (Alligator mississippiensis). Science of the Total Environment 545, 389-397. ; Noguera, J. C. & Velando, A. (2021). Telomerase activity can mediate the effects of growth on telomeres during post-natal development in a wild bird. Journal of Experimental Biology 224, jeb242465. ; Noren, S. R. & Edwards, E. F. (2007). Physiological and behavioral development in delphinid calves: implications for calf separation and mortality due to tuna purse-seine sets. Marine Mammal Science 23, 15-29. ; Oganesian, L. & Karlseder, J. (2011). Mammalian 5′ C-rich telomeric overhangs are a mark of recombination-dependent telomere maintenance. Molecular Cell 42, 224-236. ; Ohsumi, S., Kasuya, T. & Nishiwaki, M. (1965). Accumulation rate of dentinal growth layers in the maxillary tooth of the sperm whale. Scientific Reports The Whales Research Institute 17, 15-34. ; Olivier, G. C. & Greyling, F. J. (1991). Criteria for age assessment of blesbok. South African Journal of Wildlife Research 21, 1-5. ; Olsen, M. T., Robbins, J., Bérubé, M., Rew, M. B. & Palsbøll, P. J. (2014). Utility of telomere length measurements for age determination of humpback whales. NAMMCO Scientific Publications 10, 1-17. ; Olsson, M., Pauliny, A., Wapstra, E., Uller, T., Schwartz, T. & Blomqvist, D. (2011). Sex differences in sand lizard telomere inheritance: paternal epigenetic effects increases telomere heritability and offspring survival. PLoS One 6, e17473. ; Olsson, M., Wapstra, E. & Friesen, C. R. (2018). Evolutionary ecology of telomeres: a review. Annals of the New York Academy of Sciences 1422, 5-28. ; Ooi, S. K. T. & Bestor, T. H. (2008). The colorful history of active DNA demethylation. Cell 133, 1145-1148. ; Oosthuizen, W. H. (1997). Evaluation of an effective method to estimate age of Cape fur seals using ground tooth sections. Marine Mammal Science 13, 683-693. ; Østbye, E., Lauritzen, S.-E. E., Østbye, K. & Wiig, Ø. (2006). Holocene brown bear (Ursus arctos L.) from Norwegian caves. Boreas 35, 296-316. ; Owen, R. (1840). Odontography, or, A Treatise on the Comparative Anatomy of the Teeth: Their Physiological Relations, Mode of Development, and Microscopic Structure in the Vertebrate Animals, Edition (Volume 1). Balliere, London, UK. https://doi.org/10.5962/bhl.title.16281. ; Palm, W. & de Lange, T. (2008). How shelterin protects mammalian telomeres. Annual Review of Genetics 42, 301-334. ; Panasiak, L., Dobosz, S. & Ocalewicz, K. (2020). Telomere dynamics in the diploid and triploid rainbow trout (Oncorhynchus mykiss) assessed by Q-FISH analysis. Genes 11, 1-12. ; Panasiak, L., Szubert, K., Polonis, M. & Ocalewicz, K. (2022). Telomere length variation does not correspond with the growth disturbances in the rainbow trout (Oncorhynchus mykiss). Journal of Applied Genetics 63, 133-139. ; Parolini, M., Romano, A., Khoriauli, L., Nergadze, S. G., Caprioli, M., Rubolini, D., Santagostino, M., Saino, N. & Giulotto, E. (2015). Early-life telomere dynamics differ between the sexes and predict growth in the barn swallow (Hirundo rustica). PLoS One 10, e0142530. ; Parrott, B. B. & Bertucci, E. M. (2019). Epigenetic aging clocks in ecology and evolution. Trends in Ecology and Evolution 34, 767-770. ; Parrott, B. B., Bowden, J. A., Kohno, S., Cloy-McCoy, J. A., Hale, M. D., Bangma, J. T., Rainwater, T. R., Wilkinson, P. M., Kucklick, J. R. & Guillette, L. J. (2014). Influence of tissue, age, and environmental quality on DNA methylation in Alligator mississippiensis. Reproduction 147, 503-513. ; Pauli, J. N., Whiteman, J. P., Marcot, B. G., McClean, T. M. & Ben-David, M. (2011). DNA-based approach to aging martens (Martes americana and M. caurina). Journal of Mammalogy 92, 500-510. ; Pauliny, A., Larsson, K. & Blomqvist, D. (2012). Telomere dynamics in a long-lived bird, the barnacle goose. BMC Evolutionary Biology 12, 1-8. ; Pauliny, A., Wagner, R. H., Augustin, J., Szép, T. & Blomqvist, D. (2006). Age-independent telomere length predicts fitness in two bird species. Molecular Ecology 15, 1681-1687. ; Payan, P., Borelli, G., Boeuf, G. & Mayer-Gostan, N. (1998). Relationship between otolith and somatic growth: consequence of starvation on acid-base balance in plasma and endolymph in the rainbow trout Oncorhynchus mykiss. Fish Physiology and Biochemistry 19, 35-41. ; Pekelharing, C. J. (1970). Cementum deposition as an age indicator in the brush-tailed possum, Trichosurus vulpecula Kerr (Marsupiala). Australian Journal of Zoology 18, 71-76. ; Penzhorn, B. L. (1982). Age determination in Cape mountain zebras Equus zebra zebra in the Mountain Zebra National Park. Koedoe 25, 89-102. ; Pérez-Barberìa, F. J., Duff, E. I., Brewer, M. J. & Guinness, F. E. (2014). Evaluation of methods to age Scottish red deer: the balance between accuracy and practicality. Journal of Zoology 294, 180-189. ; Perez-Barberia, F. J. & Fernandez-Lopez, J. M. (1996). Using cementum annuli to estimate Cantabrian chamois age. The Journal of Wildlife Management 60, 62-67. ; Pérez-Pereira, N., López-Cortegano, E. & García-Dorado, A. (2022). Prediction of fitness under different breeding designs in conservation programs. Animal Conservation 26, 86-102. ; Pires, A. E., Caldeira, I. S., Petrucci-Fonseca, F., Viegas, I., Viegas, C., Bastos-Silveira, C. & Requicha, J. F. (2020). Dental pathology of the wild Iberian wolf (Canis lupus signatus): the study of a 20th century Portuguese museum collection. Veterinary and Animal Science 9, 100100. ; Plot, V., Criscuolo, F., Zahn, S. & Georges, J. Y. (2012). Telomeres, age and reproduction in a long-lived reptile. PLoS One 7, e40855. ; Poganik, J. R., Zhang, B., Baht, G. S., Kerepesi, C., Yim, S. H., Lu, A. T., Haghani, A., Gong, T., Hedman, A. M., Andolf, E., Pershagen, G., Almqvist, C., White, J. P., Horvath, S. & Gladyshev, V. N. (2023). Biological age is increased by stress and restored upon recovery. Cell Metabolism 35, 807-820. ; Polanowski, A. M., Robbins, J., Chandler, D. & Jarman, S. N. (2014). Epigenetic estimation of age in humpback whales. Molecular Ecology Resources 14, 976-987. ; Prado, N. A., Brown, J. L., Zoller, J. A., Haghani, A., Yao, M., Bagryanova, L. R., Campana, M. G., Maldonado, J. E., Raj, K., Schmitt, D., Robeck, T. R. & Horvath, S. (2021). Epigenetic clock and methylation studies in elephants. Aging Cell 20, e13414. ; Qi, H., Kinoshita, K., Mori, T., Matsumoto, K., Matsui, Y. & Inoue-Murayama, M. (2021). Age estimation using methylation-sensitive high-resolution melting (MS-HRM) in both healthy felines and those with chronic kidney disease. Scientific Reports 11, 1-10. ; Quirici, V., Guerrero, C. J., Krause, J. S., Wingfield, J. C. & Vásquez, R. A. (2016). The relationship of telomere length to baseline corticosterone levels in nestlings of an altricial passerine bird in natural populations. Frontiers in Zoology 13, 1-11. ; R Core Team (2020). R: A Language and Environment for Statisitical Computing. R Foundation for Statistical Computing, Vienna https://www.r-project.org/. ; Raj, K., Szladovits, B., Haghani, A., Zoller, J. A., Li, C. Z., Black, P., Maddox, D., Robeck, T. R. & Horvath, S. (2021). Epigenetic clock and methylation studies in cats. GeroScience 43, 2363-2378. ; Rausch, R. A. & Pearson, A. M. (1972). Notes on the wolverine in Alaska and the Yukon territory. The Journal of Wildlife Management 36, 249-268. ; Rautenbach, I. L. (1970). Ageing criteria in the springbok, Antidorcas marsupialis (Zimmermann, 1780) (Artiodactyla: Bovidae). Annals of the Transvaal Museum 27, 83-133. ; Reichenbacher, B., Sienknecht, U., Küchenhoff, H. & Fenske, N. (2007). Combined otolith morphology and morphometry for assessing taxonomy and diversity in fossil and extant killifish (Aphanius, Prolebias). Journal of Morphology 268, 898-915. ; Reichert, S., Rojas, E. R., Zahn, S., Robin, J. P., Criscuolo, F. & Massemin, S. (2015). Maternal telomere length inheritance in the king penguin. Heredity 114, 10-16. ; Reimers, E. & Nordby, O. (1968). Relationship between age and tooth cementum layers in Norwegian reindeer. The Journal of Wildlife Management 32, 957. ; Remot, F., Ronget, V., Froy, H., Rey, B., Gaillard, J. M., Nussey, D. H. & Lemaitre, J. F. (2021). Decline in telomere length with increasing age across nonhuman vertebrates: a meta-analysis. Molecular Ecology 31, 5917-5932. ; Rey, O., Eizaguirre, C., Angers, B., Baltazar-Soares, M., Sagonas, K., Prunier, J. G. & Blanchet, S. (2020). Linking epigenetics and biological conservation: towards a conservation epigenetics perspective. Functional Ecology 34, 414-427. ; Roast, M. J., Eastwood, J. R., Aranzamendi, N. H., Fan, M., Teunissen, N., Verhulst, S. & Peters, A. (2022). Telomere length declines with age, but relates to immune function independent of age in a wild passerine. Royal Society Open Science 9, 212012. ; Robeck, T. R., Fei, Z., Haghani, A., Zoller, J. A., Li, C. Z., Steinman, K. J., Dirocco, S., Staggs, L., Schmitt, T., Osborn, S., Montano, G., Rodriguez, M. & Horvath, S. (2021a). Multi-tissue methylation clocks for age and sex estimation in the common bottlenose dolphin. Frontiers in Marine Science 8, 1318. ; Robeck, T. R., Fei, Z., Lu, A. T., Haghani, A., Jourdain, E., Zoller, J. A., Li, C. Z., Steinman, K. J., DiRocco, S., Schmitt, T., Dold, C. & Horvath, S. (2021b). Multi-species and multi-tissue methylation clocks for age estimation in toothed whales and dolphins. Communications Biology 4, 642. ; Robeck, T. R., Haghani, A., Fei, Z., Lindemann, D. M., Russell, J., Herrick, K. E. S., Montano, G., Steinman, K. J., Katsumata, E., Zoller, J. A. & Horvath, S. (2023). Multi-tissue DNA methylation aging clocks for sea lions, walruses and seals. Communications Biology 6, 359. ; Robinette, W. L. & Archer, A. L. (1971). Notes on aging criteria and reproduction of Thomson's gazelle. African Journal of Ecology 9, 83-98. ; Rohatgi, A. (2022). Webplotdigitizer: Version 4.6. https://automeris.io/WebPlotDigitizer. ; Rolandsen, C. M., Solberg, E. J., Heim, M., Holmstrøm, F., Solem, M. I. & Saether, B.-E. (2008). Accuracy and repeatability of moose (Alces alces) age as estimated from dental cement layers. European Journal of Wildlife Research 54, 6-14. ; Romano, A., De Giorgio, B., Parolini, M., Favero, C., Possenti, C. D., Iodice, S., Caprioli, M., Rubolini, D., Ambrosini, R., Gianfranceschi, L., Saino, N. & Bollati, V. (2017). Methylation of the circadian clock gene in the offspring of a free-living passerine bird increases with maternal and individual exposure to PM10. Environmental Pollution 220, 29-37. ; Román-Palacios, C., Medina, C. A., Zhan, S. H. & Barker, M. S. (2021). Animal chromosome counts reveal a similar range of chromosome numbers but with less polyploidy in animals compared to flowering plants. Journal of Evolutionary Biology 34, 1333-1339. ; Rosell, F., Zedrosser, A. & Parker, H. (2010). Correlates of body measurements and age in Eurasian beaver from Norway. European Journal of Wildlife Research 56, 43-48. ; RStudio Team (2021). RStudio: Integrated Development Environment for R. IDE, Boston http://www.rstudio.com/. ; Rust, L. B., Danil, K., Melin, S. R. & Wilkerson, B. (2019). Accuracy and precision of age determination using growth layer groups for California Sea lions (Zalophus californianus) with known ages. Marine Mammal Science 35, 1355-1368. ; Saino, N., Albetti, B., Ambrosini, R., Caprioli, M., Costanzo, A., Mariani, J., Parolini, M., Romano, A., Rubolini, D., Formenti, G., Gianfranceschi, L. & Bollati, V. (2019). Inter-generational resemblance of methylation levels at circadian genes and associations with phenology in the barn swallow. Scientific Reports 9, 1-16. ; Saino, N., Ambrosini, R., Albetti, B., Caprioli, M., De Giorgio, B., Gatti, E., Liechti, F., Parolini, M., Romano, A., Romano, M., Scandolara, C., Gianfranceschi, L., Bollati, V. & Rubolini, D. (2017). Migration phenology and breeding success are predicted by methylation of a photoperiodic gene in the barn swallow. Scientific Reports 7, 45412. ; Saino, N., Rubolini, D., Ambrosini, R., Romano, M., Scandolara, C., Fairhurst, G. D., Caprioli, M., Romano, A., Sicurella, B. & Liechti, F. (2015). Light-level geolocators reveal covariation between winter plumage molt and phenology in a trans-Saharan migratory bird. Oecologia 178, 1105-1112. ; Salmón, P., Nilsson, J. F., Nord, A., Bensch, S. & Isaksson, C. (2016). Urban environment shortens telomere length in nestling great tits, Parus major. Biology Letters 12, 20160155. ; Salomons, H. M., Mulder, G. A., Van De Zande, L., Haussmann, M. F., Linskens, M. H. K. & Verhulst, S. (2009). Telomere shortening and survival in free-living corvids. Proceedings of the Royal Society B: Biological Sciences 276, 3157-3165. ; Sánchez-Montes, G., Martínez-Solano, Í., Díaz-Paniagua, C., Vilches, A., Ariño, A. H. & Gomez-Mestre, I. (2020). Telomere attrition with age in a wild amphibian population. Biology Letters 16, 20200168. ; Sareisian, L. (2014). Global DNA methylation and persistent organic pollutants in ringed seals (Phoca hispida) from Svalbard and the Baltic Sea. Masters dissertation: University of Oslo, Oslo. http://urn.nb.no/URN:NBN:no-46760. ; Sato, A., Fairbanks, L. A., Lawson, P. T. & Lawson, G. W. (2005). Effects of age and sex on hematologic and serum biochemical values of vervet monkeys (Chlorocebus aethiops sabaeus). Contemporary Topics in Laboratory Animal Science 44, 29-34. ; Saunders, P. A. & Veyrunes, F. (2021). Unusual mammalian sex determination systems: a cabinet of curiosities. Genes 12, 1170. ; Saxon, A. & Higham, C. F. W. (1968). Identification and interpretation of growth rings in the secondary dental cementum of Ovis aries L. Nature 219, 634-635. ; Schachtschneider, K. M., Schook, L. B., Meudt, J. J., Shanmuganayagam, D., Zoller, J. A., Haghani, A., Li, C. Z., Zhang, J., Yang, A., Raj, K. & Horvath, S. (2021). Epigenetic clock and DNA methylation analysis of porcine models of aging and obesity. GeroScience 43, 2467-2483. ; Schaetzlein, S., Lucas-Hahn, A., Lemme, E., Kues, W. A., Dorsch, M., Manns, M. P., Niemann, H. & Rudolph, K. L. (2004). Telomere length is reset during early mammalian embryogenesis. Proceedings of the National Academy of Sciences of the United States of America 101, 8034-8038. ; Scheffer, V. B. (1950). Growth layers on the teeth of pinnipedia as an indication of age. Science 112, 309-311. ; Schuler, K. L., Baker, B. B., Mayer, K. A., Perez-Heydrich, C., Holahan, P. M., Thomas, N. J. & White, C. L. (2018). Refining aging criteria for northern sea otters in Washington State. Journal of Fish and Wildlife Management 9, 208-221. ; Schwarzer, G., Carpenter, J. R. & Rücker, G. (2015). Meta-Analysis with R. Springer, Cham.. ; Scott, G. G., Sis, R. F., Levy, B. M., Stott, G. G., Sis, R. F. & Levy, B. M. (1980). Cemental annulation as an age criterion in the common marmoset (Callithrix jacchus). Journal of Medical Primatology 9, 274-285. ; Scott, N. M., Haussmann, M. F., Elsey, R. M., Trosclair, P. L. & Vleck, C. M. (2006). Telomere length shortens with body length in Alligator mississippiensis. Southeastern Naturalist 5, 685-692. ; Secor, D. H., Trice, T. M. & Hornick, H. T. (1995). Validation of otolith-based ageing and a comparison of otolith and scale-based ageing in mark-recaptured Chesapeake Bay striped bass, Morone saxatilis. Fishery Bulletin 93, 186-190. ; Seibt, K. D., Häussler, S., Vecchio, D., DeCarlo, E., Ceciliani, F. & Sauerwein, H. (2019). Comparison of telomere lengths in leukocytes and in nasal and vaginal epithelial cells from water buffaloes (Bubalus bubalis) of different ages. Research in Veterinary Science 124, 328-333. ; Sen, G. L., Reuter, J. A., Webster, D. E., Zhu, L. & Khavari, P. A. (2010). DNMT1 maintains progenitor function in self-renewing somatic tissue. Nature 463, 563-567. ; Sfeir, A. J., Chai, W., Shay, J. W. & Wright, W. E. (2005). Telomere-end processing: the terminal nucleotidesof human chromosomes. Molecular Cell 18, 131-138. ; Sharma, A., Singh, D., Malik, S., Gupta, N. J., Rani, S. & Kumar, V. (2018). Difference in control between spring and autumn migration in birds: insight from seasonal changes in hypothalamic gene expression in captive buntings. Proceedings of the Royal Society B: Biological Sciences 285, 20181531. ; Sharma, V., Sharma, C. P., Sharma, V., Goyal, S. P. & Gupta, S. K. (2021). Fast and cost-effective age estimation in Bengal tiger and Asiatic lion: applicability of cementum analysis method. bioRxiv 2021.09.27.461978. https://doi.org/10.1101/2021.09.27.461978. ; Shay, J. W. & Wright, W. E. (2019). Telomeres and telomerase: three decades of progress. Nature Reviews Genetics 20, 299-309. ; Sherley, R. B., Abadi, F., Ludynia, K., Barham, B. J., Clark, A. E. & Altwegg, R. (2014). Age-specific survival and movement among major African penguin Spheniscus demersus colonies. Ibis 156, 716-728. ; Short, R., Williams, D. D. & Bowden, D. M. (1987). Cross-sectional evaluation of potential biological markers of aging in pigtailed macaques: effects of age, sex, and diet. Journals of Gerontology 42, 644-654. ; Simide, R., Angelier, F., Gaillard, S. & Stier, A. (2016). Age and heat stress as determinants of telomere length in a long-lived fish, the Siberian sturgeon. Physiological and Biochemical Zoology 89, 441-447. ; Simpson, C. D. (1983). Tooth Replacement, Growth, and Ageing Criteria for the Zambezi Bushbuck, Tragelaphus Scriptus Ornatus Pocock. National Museums and Monuments of Rhodesia. Harare, Zimbabwe. ; Simpson, C. D. & Elder, W. H. (1969). Tooth cementum as an index of age in greater kudu (Trageluphus strepsireros). Artioldia 4, 1-10. ; Smith, J. R. (1975). Age determination of the woodchuck, Marmota monax, by annulations in dental cementum and in the periosteal zone of bones. Doctoral Thesis: Eastern Kentucky University, Richmond, United States of America. ; Smith, L. E., Jones, M. E., Hamede, R., Risques, R., Patton, A. H., Carter, P. A. & Storfer, A. (2020). Telomere length is a susceptibility marker for Tasmanian devil facial tumor disease. EcoHealth 17, 280-291. ; Smuts, G. L., Anderson, J. L. & Austin, J. C. (1978). Age determination of the African lion (Panthera leo). Journal of Zoology 185, 115-146. ; Snir, S., vonHoldt, B. M. & Pellegrini, M. (2016). A statistical framework to identify deviation from time linearity in epigenetic aging. PLoS Computational Biology 12, e1005183. ; Soler, J. J., Ruiz Castellano, C., Martínez-de la Puente, J., Tomás, G., Ruiz-Rodríguez, M. & Figuerola, J. (2015). Telomere dynamics in parasitic great spotted cuckoos and their magpie hosts. Journal of Evolutionary Biology 28, 1610-1617. ; Soler, J. J., Ruiz-Castellano, C., Figuerola, J., Martín-Vivaldi, M., Martínez-de la Puente, J., Ruiz-Rodríguez, M. & Tomás, G. (2017). Telomere length and dynamics of spotless starling nestlings depend on nest-building materials used by parents. Animal Behaviour 126, 89-100. ; Sørheim, V. C. (2020). Telomere dynamics during nestling development in bluethroats (Luscinia s. svecica). Masters dissertation: University of Oslo, Oslo. ; Soulsbury, C. D., Lipponen, A., Wood, K., Mein, C. A., Hoffman, J. I. & Lebigre, C. (2018). Age- and quality-dependent DNA methylation correlate with melanin-based coloration in a wild bird. Ecology and Evolution 8, 6547-6557. ; Spiers, H., Hannon, E., Wells, S., Williams, B., Fernandes, C. & Mill, J. (2016). Age-associated changes in DNA methylation across multiple tissues in an inbred mouse model. Mechanisms of Ageing and Development 154, 20-23. ; Spinage, C. A. (1976). Incremental cementum lines in the teeth of tropical African mammals. Journal of Zoology 178, 117-131. ; Spurgin, L. G., Bebbington, K., Fairfield, E. A., Hammers, M., Komdeur, J., Burke, T., Dugdale, H. L. & Richardson, D. S. (2018). Spatio-temporal variation in lifelong telomere dynamics in a long-term ecological study. Journal of Animal Ecology 87, 187-198. ; Starr, M. E. & Saito, H. (2014). Sepsis in old age: review of human and animal studies. Aging and Disease 5, 126-136. ; Statham, A. & Csárdi, G. (2008). RSeqMeth: Package for Analysis of Sequenom EpiTYPER Data. Sydney. https://github.com/cran/RSeqMeth. ; Stewart, R. E. A., Stewart, B. E., Stirling, I. & Street, E. (1996). Counts of growth layer groups in cementum and dentine in ringed seals (Phoca hispida). Marine Mammal Science 12, 383-401. ; Stier, A., Hsu, B. Y., Marciau, C., Doligez, B., Gustafsson, L., Bize, P. & Ruuskanen, S. (2020). Born to be young? Prenatal thyroid hormones increase early-life telomere length in wild collared flycatchers. Biology Letters 16, 20200364. ; Stirling, I., Archibald, W. R. & DeMaster, D. (1977). Distribution and abundance of seals in the eastern Beaufort Sea. Journal of the Fisheries Research Board of Canada 34, 976-988. ; Stubbs, T. M., Bonder, M. J., Stark, A. K., Krueger, F., von Meyenn, F., Stegle, O., Reik, W., Bolland, D., Butcher, G., Chandra, T., Clark, S. J., Corcoran, A., Eckersley-Maslinc, M., Field, L., Frising, U. C., et al. (2017). Multi-tissue DNA methylation age predictor in mouse. Genome Biology 18, 1-14. ; Suarez-Bregua, P., Rosendo, S., Comesaña, P., Sánchez-Ruiloba, L., Morán, P., Planas, M. & Rotllant, J. (2021). Dynamic changes in DNA methylation during seahorse (Hippocampus reidi) postnatal development and settlement. Frontiers in Zoology 18, 1-10. ; Sudyka, J., Arct, A., Drobniak, S., Dubiec, A., Gustafsson, L. & Cichoń, M. (2014). Experimentally increased reproductive effort alters telomere length in the blue tit (Cyanistes caeruleus). Journal of Evolutionary Biology 27, 2258-2264. ; Sugrue, V. J., Zoller, J. A., Narayan, P., Lu, A. T., Ortega-Recalde, O. J., Grant, M. J., Bawden, C. S., Rudiger, S. R., Haghani, A., Bond, D. M., Hore, R. R., Garratt, M., Sears, K. E., Wang, N., Yang, X. W., et al. (2021). Castration delays epigenetic aging and feminizes DNA methylation at androgen-regulated loci. eLife 10, e64932. ; Tackney, J., Cawthon, R. M., Coxworth, J. E. & Hawkes, K. (2014). Blood cell telomere lengths and shortening rates of chimpanzee and human females. American Journal of Human Biology 26, 452-460. ; Tanabe, A., Shimizu, R., Osawa, Y., Suzuki, M., Ito, S., Goto, M., Pastene, L. A. L. A., Fujise, Y. & Sahara, H. (2020). Age estimation by DNA methylation in the Antarctic minke whale. Fisheries Science 86, 35-41. ; Thomas, C. & Zapico, S. C. (2017). Role of telomeres in aging. In Mechanisms Linking Aging, Diseases and Biological Age Estimation, First Edition (ed. S. C. Zapico), pp. 141-149. CRC Press. Boca Raton, USA. ; Thomas, D. C. (1977). Metachromatic staining of dental cementum for mammalian age determination. The Journal of Wildlife Management 41, 207. ; Thompson, M. J., von Holdt, B., Horvath, S. & Pellegrini, M. (2017). An epigenetic aging clock for dogs and wolves. Aging 9, 1055-1068. ; Thompson, R. F., Suzuki, M., Lau, K. W. & Greally, J. M. (2009). A pipeline for the quantitative analysis of CG dinucleotide methylation using mass spectrometry. Bioinformatics 25, 2164-2170. ; Tilstra, J. S., Clauson, C. L., Niedernhofer, L. J. & Robbins, P. D. (2011). NF-κB in aging and disease. Aging and Disease 2, 449-465. ; Tissier, M. L., Bergeron, P., Garant, D., Zahn, S., Criscuolo, F. & Réale, D. (2022). Telomere length positively correlates with pace-of-life in a sex- and cohort-specific way and elongates with age in a wild mammal. Molecular Ecology 31, 3812-3826. ; Tricola, G. M., Simons, M. J. P., Atema, E., Boughton, R. K., Brown, J. L., Dearborn, D. C., Divoky, G., Eimes, J. A., Huntington, C. E., Kitaysky, A. S., Juola, F. A., Lank, D. B., Litwa, H. P., Mulder, E. G. A., Nisbet, I. C. T., et al. (2018). The rate of telomere loss is related to maximum lifespan in birds. Philosophical Transactions of the Royal Society B: Biological Sciences 373, 20160445. ; Trivedi, A. K., Sur, S., Sharma, A., Taufique, S. T., Gupta, N. J. & Kumar, V. (2019). Temperature alters the hypothalamic transcription of photoperiod responsive genes in induction of seasonal response in migratory redheaded buntings. Molecular and Cellular Endocrinology 493, 110454. ; Ujvari, B., Biro, P. A., Charters, J. E., Brown, G., Heasman, K., Beckmann, C. & Madsen, T. (2017). Curvilinear telomere length dynamics in a squamate reptile. Functional Ecology 31, 753-759. ; Ujvari, B. & Madsen, T. (2009). Short telomeres in hatchling snakes: erythrocyte telomere dynamics and longevity in tropical pythons. PLoS One 4, e7493. ; Van Aarde, R. J. (1985). Age determination of Cape porcupines, Hystrix africaeaustralis. African Zoology 20, 232-236. ; van Eck, N. J. & Waltman, L. (2017). Citation-based clustering of publications using CitNetExplorer and VOSviewer. Scientometrics 111, 1053-1070. ; van Lieshout, S. H. J., Bretman, A., Newman, C., Buesching, C. D., Macdonald, D. W. & Dugdale, H. L. (2019). Individual variation in early-life telomere length and survival in a wild mammal. Molecular Ecology 28, 4152-4165. ; Van Lieshout, S. H. J., Sparks, A. M., Bretman, A., Newman, C., Buesching, C. D., Burke, T., Macdonald, D. W. & Dugdale, H. L. (2021). Estimation of environmental, genetic and parental age at conception effects on telomere length in a wild mammal. Journal of Evolutionary Biology 34, 296-308. ; Van Nostrand, F. C. & Stephenson, A. B. (1964). Age determination for beavers by tooth development. The Journal of Wildlife Management 28, 430. ; Vedder, O., Moiron, M., Bichet, C., Bauch, C., Verhulst, S., Becker, P. H. & Bouwhuis, S. (2022). Telomere length is heritable and genetically correlated with lifespan in a wild bird. Molecular Ecology 31, 6297-6307. ; Vedder, O., Verhulst, S., Bauch, C. & Bouwhuis, S. (2017). Telomere attrition and growth: a life-history framework and case study in common terns. Journal of Evolutionary Biology 30, 1409-1419. ; Venegas, D., Marmolejo-Valencia, A., Valdes-Quezada, C., Govenzensky, T., Recillas-Targa, F. & Merchant-Larios, H. (2016). Dimorphic DNA methylation during temperature-dependent sex determination in the sea turtle Lepidochelys olivacea. General and Comparative Endocrinology 236, 35-41. ; Vernasco, B. J., Dakin, R., Majer, A. D., Haussmann, M. F., Brandt Ryder, T. & Moore, I. T. (2021). Longitudinal dynamics and behavioural correlates of telomeres in male wire-tailed manakins. Functional Ecology 35, 450-462. ; Vernasco, B. J. & Watts, H. E. (2022). Telomere length predicts timing and intensity of migratory behaviour in a nomadic songbird. Biology Letters 18, 20220176. ; Viblanc, V. A., Criscuolo, F., Sosa, S., Schull, Q., Boonstra, R., Saraux, C., Lejeune, M., Roth, J. D., Uhlrich, P., Zahn, S. & Dobson, F. S. (2022). Telomere dynamics in female Columbian ground squirrels: recovery after emergence and loss after reproduction. Oecologia 199, 301-312. ; Viciano, J., López-Lázaro, S. & Tanga, C. (2022). Post-mortem dental profile as a powerful tool in animal forensic investigations-a review. Animals 12, 2038. ; Viitaniemi, H. M., Verhagen, I., Visser, M. E., Honkela, A., Van Oers, K., Husby, A. & Meyer, M. (2019). Seasonal variation in genome-wide DNA methylation patterns and the onset of seasonal timing of reproduction in great tits. Genome Biology and Evolution 11, 970-983. ; Voillemot, M., Hine, K., Zahn, S., Criscuolo, F., Gustafsson, L., Doligez, B. & Bize, P. (2012). Effects of brood size manipulation and common origin on phenotype and telomere length in nestling collared flycatchers. BMC Ecology 12, 1-8. ; Wada, K., Ohtaishi, N. & Hachiya, N. (1978). Determination of age in the Japanese monkey from growth layers in the dental cementum. Primates 19, 775-784. ; Walleser, L. R., Crimmins, S. M. & Roberts, N. M. (2016). Estimating the age of male gray wolves (Canis lupus) using baculum measurements. Canadian Field-Naturalist 130, 212-215. ; Watson, R. L., Bird, E. J., Underwood, S., Wilbourn, R. V., Fairlie, J., Watt, K., Salvo-Chirnside, E., Pilkington, J. G., Pemberton, J. M., McNeilly, T. N., Froy, H. & Nussey, D. H. (2017). Sex differences in leucocyte telomere length in a free-living mammal. Molecular Ecology 26, 3230-3240. ; Webb, S. J. N., Schapiro, S. J., Sherwood, C. C., Raghanti, M. A. & Hopkins, W. D. (2020). Neutrophil to lymphocyte ratio (NLR) in captive chimpanzees (Pan troglodytes): the effects of sex, age, and rearing. PLoS One 15, e0244092. ; Wei, T., Nie, J., Larson, N. B., Ye, Z., Eckel-Passow, J. E., Robertson, K. D., Kocher, J. P. A. & Wang, L. (2021). CpGtools: a python package for DNA methylation analysis. Bioinformatics 37, 1598-1599. ; White, P. A. & Belant, J. L. (2016). Individual variation in dental characteristics for estimating age of African lions. Wildlife Biology 22, 71-77. ; Whittemore, K., Vera, E., Martínez-Nevado, E., Sanpera, C. & Blasco, M. A. (2019). Telomere shortening rate predicts species life span. Proceedings of the National Academy of Sciences of the United States of America 116, 15122-15127. ; Wilbourn, R. V., Froy, H., McManus, M. C., Cheynel, L., Gaillard, J. M., Gilot-Fromont, E., Regis, C., Rey, B., Pellerin, M., Lemaître, J. F. & Nussey, D. H. (2017). Age-dependent associations between telomere length and environmental conditions in roe deer. Biology Letters 13, 20170434. ; Wilbourn, R. V., Moatt, J. P., Froy, H., Walling, C. A., Nussey, D. H. & Boonekamp, J. J. (2018). The relationship between telomere length and mortality risk in non-model vertebrate systems: a meta-analysis. Philosophical Transactions of the Royal Society B: Biological Sciences 373, 20160447. ; Wilkinson, G. S., Adams, D. M., Haghani, A., Lu, A. T., Zoller, J., Breeze, C. E., Arnold, B. D., Ball, H. C., Carter, G. G., Cooper, L. N., Dechmann, D. K. N., Devanna, P., Fasel, N. J., Galazyuk, A. V., Günther, L., et al. (2021). DNA methylation predicts age and provides insight into exceptional longevity of bats. Nature Communications 12, 1615. ; Wilson, V. J., Schmidt, J. L. & Hanks, J. (1984). Age determination and body growth of the common duiker Sylvicapra grimmia (Mammalia). Journal of Zoology 202, 283-297. ; Wittwer-Backofen, U., Gampe, J. & Vaupel, J. W. (2004). Tooth cementum annulation for age estimation: results from a large known-age validation study. American Journal of Physical Anthropology 123, 119-129. ; Wong, P. B. Y. (2017). Conservation and biological senescence in polar bears: telomeres and inuit traditional knowledge. Doctoral Thesis: University of Toronto, Toronto. https://hdl.handle.net/1807/79501. ; Wright, P. G. R., Mathews, F., Schofield, H., Morris, C., Burrage, J., Smith, A., Dempster, E. L. E. L. & Hamilton, P. B. P. B. (2018). Application of a novel molecular method to age free-living wild Bechstein's bats. Molecular Ecology Resources 18, 1374-1380. ; Wright, W. E., Piatyszek, M. A., Rainey, W. E., Byrd, W. & Shay, J. W. (1996). Telomerase activity in human germline and embryonic tissues and cells. Developmental Genetics 18, 173-179. ; Wu, P., Takai, H. & De Lange, T. (2012). Telomeric 3′ overhangs derive from resection by Exo1 and apollo and fill-in by POT1b-associated CST. Cell 150, 39-52. ; Yoneda, M. (1982). Growth layers in dental cementum of Saguinus monkeys in South America. Primates 23, 460-464. ; Yuan, X., Ishibashi, S., Hatakeyama, S., Saito, M., Nakayama, J. I., Nikaido, R., Haruyama, T., Watanabe, Y., Iwata, H., Iida, M., Sugimura, H., Yamada, N. & Ishikawa, F. (1999). Presence of telomeric G-strand tails in the telomerase catalytic subunit TERT knockout mice. Genes to Cells 4, 563-572. ; Zapata, S. C., Perea, R. G., Beltran, J. F., Ferreras, P. & Delibes, M. (1997). Age determination of Iberian lynx (Lynx pardinus) using canine radiograph and cementum annuli enumeration. Zeitschrift fur Saugetierkunde 62, 119-123. ; Zapico, S. C. & Ubelaker, D. H. (2016). Relationship between mitochondrial DNA mutations and aging. Estimation of age-at-death. The Journals of Gerontology Series A: Biological Sciences and Medical Sciences 71, 445-450. ; Zhang, G. (2015). Bird sequencing project takes off. Nature 522, 34. ; Zhang, Q., Han, X., Hao, X., Ma, L., Li, S., Wang, Y. & Du, W. (2018). A simulated heat wave shortens the telomere length and lifespan of a desert lizard. Journal of Thermal Biology 72, 94-100. ; Zhang, W., Klinkebiel, D., Barger, C. J., Pandey, S., Guda, C., Miller, A., Akers, S. N., Odunsi, K. & Karpf, A. R. (2020). Global DNA hypomethylation in epithelial ovarian cancer: passive demethylation and association with genomic instability. Cancers 12, 764. ; Zhao, Z., Pan, X., Liu, L. & Liu, N. (2014). Telomere length maintenance, shortening, and lengthening. Journal of Cellular Physiology 229, 1323-1329. ; Zhdanova, N. S., Minina, J. M., Karamysheva, T. V., Rubtsov, N. B. & Londono-Vallejo, J. A. (2010). The structure of long telomeres in chromosomes of the Iberian shrew. Russian Journal of Genetics 46, 1084-1086. ; *Zhu, X.-M., Xiao, H. & Wu, J.-Y. (1992). Age determination of Goitred gazelle (Gazella subgutturosa). Zoological Research 13, 95-99. ; Zoller, J. A., Parasyraki, E., Lu, A. T., Haghani, A., Niehrs, C. & Horvath, S. (2022). DNA methylation clocks for clawed frogs reveal evolutionary conservation of epigenetic ageing. bioRxiv 2022.08.02.502561. https://doi.org/10.1101/2022.08.02.502561. Contributed Indexing: Keywords: age determination; animals; biological clocks; biomarker; epigenetics; meta-analysis; methylation; otoliths; telomeres; tooth layers Entry Date(s): Date Created: 20230625 Date Completed: 20231107 Latest Revision: 20231111 Update Code: 20231215

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