DNA methylation networks underlying mammalian traits

Haghani, Amin; Li, Caesar Z.; Robeck, Todd R.; Zhang, Joshua; Lu, Ake T.; Ablaeva, Julia; Acosta-Rodríguez, Victoria A.; Adams, Danielle M.; Alagaili, Abdulaziz N.; Almunia, Javier; Aloysius, Ajoy; Amor, Nabil; Ardehali, Reza; Arneson, Adriana; Baker, C. Scott; Banks, Gareth; Belov, Katherine; Bennett, Nigel C.; Black, Peter McL.; Blumstein, Daniel T.; Bors, Eleanor K.; Breeze, Charles E.; Brooke, Robert T.; Brown, Janine L.; Carter, Gerald G.; Caulton, Alex; Cavin, Julie M.; Chakrabarti, Lisa; Chatzistamou, Ioulia; Chavez, Andreas S.; Chen, Hao; Cheng, Kaiyang; Chiavellini, Priscila; Choi, Oi-Wa; Clarke, Shannon; Cook, Joseph A.; Cooper, Lisa Noelle; Cossette, Marie‐Laurence; Day, Joanna; DeYoung, Joseph; DiRocco, Stacy; Dold, Christopher; Dunnum, Jonathan L.; Ehmke, Erin; Emmons, Candice K.; Emmrich, Stephan; Erbay, Ebru; Erlacher-Reid, Claire; Faulkes, Chris G.; Fei, Zhe; Ferguson, Steve; Finno, Carrie J.; Flower, Jennifer E.; Gaillard, Jean‐Michel; Garde, Eva; Gerber, Livia; Gladyshev, Vadim N.; Goya, Rodolfo G.; Grant, Megan; Green, Carla B.; Hanson, M. Bradley; Hart, Daniel W.; Haulena, Martin; Herrick, Kelsey E S; Hogan, Andrew N.; Hogg, Carolyn J.; Hore, Timothy A.; Huang, Taosheng; Belmonte, Juan Carlos Izpisúa; Jasinska, Anna J.; Jones, Gareth; Jourdain, Eve; Kashpur, Olga; Katcher, Harold L.; Katsumata, Etsuko; Kaza, Vimala; Kiaris, Hippokratis; Kobor, Michæl S.; Kordowitzki, Paweł; Koski, William R.; Krützen, Michael; Kwon, Soo Bin; Larison, Brenda; Lee, Sang-goo; Lehmann, Marianne; Lemaître, Jean‐François; Levine, Andrew J.; Li, Xinmin; Li, C.; Lim, Andrea R.; Lin, David T.S.; Lindemann, D.; Liphardt, Schuyler; Little, Tom J.; Macoretta, Nicholas; Maddox, Dewey; Matkin, Craig O.; Mattison, Julie A.; McClure, Matthew W.; Mergl, June; Meudt, Jennifer J.; Montano, Gisele A.; Mozhui, Khyobeni; Munshi‐South, Jason; Murphy, William J.; Naderi, Asieh; Nagy, Martina; Narayan, Pritika; Nathanielsz, Peter W.; Nguyen, Ngoc Bich; Niehrs, Christof; Batsaikhan, Nyamsuren; O’Brien, Justine K.; O’Tierney-Ginn, Perrie; Odom, Duncan T.; Ophir, Alexander G.; Osborn, S. B.; Ostrander, Elaine A.; Parsons, Kim M.; Paul, Kimberly C.; Pedersen, Amy B.; Pellegrini, Matteo; Peters, Katharina J.; Petersen, Jessica L; Pietersen, Darren William; Pinho, Gabriela Medeiros de; Plassais, Jocelyn; Poganik, Jesse R.; Prado, Natalia A.; Reddy, Pradeep; Rey, Benjamin; Ritz, Beate; Robbins, Jooke; Rodríguez, Magdalena; Russell, Jennifer; Rydkina, Elena; Sailer, Lindsay L.; Salmon, Adam B.; Sanghavi, Akshay; Schachtschneider, Kyle M.; Schmitt, Dennis; Schmitt, Todd L.; Schomacher, Lars; Schook, Lawrence B.; Sears, Karen E.; Seifert, Ashley W.; Shafer, Aaron B. A.; Shindyapina, Anastasia V.; Simmons, Melanie; Singh, Kavita; Sinha, Indranil; Slone, Jesse; Snell, Russell G.; Soltanmohammadi, Elham; Spangler, Matthew L; Spriggs, Maria; Staggs, Lydia; Stedman, Nancy; Steinman, Karen J.; Stewart, Donald T.; Sugrue, Victoria J.; Szladovits, Balázs; Takahashi, Joseph S.; Takasugi, Masaki; Teeling, Emma C.; Thompson, Michael J.; Bonn, William Van; Vernes, Sonja C.; Villar, Diego; Vinters, Harry V.; Vu, Ha; Wallingford, Mary C.; Wang, Nan; Wilkinson, Gerald S.; Williams, Robert W.; Yan, Qi; Yao, Mingjia; Young, Brent G.; Zhang, Bohan; Zhang, Zhihui; Zhao, Yang; Zhao, Peng; Zhou, Wanding; Zoller, Joseph A.; Ernst, Jason; Seluanov, Andrei; Gorbunova, Vera; Yang, Xia; Raj, Ken; Horvath, Steve

doi:10.1126/science.abq5693

Cited by 48 publications

(19 citation statements)

References 89 publications

(54 reference statements)

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“…Throughout the aging process, such epigenetic changes are progressively lost, increasing the noise in the system, and contributing to a progressive loss of cellular identities that menaces the functional integrity of complex tissues and potentially enhances the risk of carcinogenesis coupled to an increase in tumor heterogeneity and phenotypic plasticity [ 42 ]. The most common (but still imperfect) technology to measure epigenetic shifts consists in bisulfite pyrosequencing to detect DNA methylation patterns that can be bioinformatically deconvoluted as “biological clocks” and be associated to the risks of developing specific diseases [ 43 ].…”

Section: Common Superior Causes Of Aging and Cancermentioning

confidence: 99%

Aging and cancer

Montégut,

López-Otín,

Kroemer

2024

Mol Cancer

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Aging and cancer exhibit apparent links that we will examine in this review. The null hypothesis that aging and cancer coincide because both are driven by time, irrespective of the precise causes, can be confronted with the idea that aging and cancer share common mechanistic grounds that are referred to as ‘hallmarks’. Indeed, several hallmarks of aging also contribute to carcinogenesis and tumor progression, but some of the molecular and cellular characteristics of aging may also reduce the probability of developing lethal cancer, perhaps explaining why very old age (> 90 years) is accompanied by a reduced incidence of neoplastic diseases. We will also discuss the possibility that the aging process itself causes cancer, meaning that the time-dependent degradation of cellular and supracellular functions that accompanies aging produces cancer as a byproduct or ‘age-associated disease’. Conversely, cancer and its treatment may erode health and drive the aging process, as this has dramatically been documented for cancer survivors diagnosed during childhood, adolescence, and young adulthood. We conclude that aging and cancer are connected by common superior causes including endogenous and lifestyle factors, as well as by a bidirectional crosstalk, that together render old age not only a risk factor of cancer but also an important parameter that must be considered for therapeutic decisions.

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Section: Common Superior Causes Of Aging and Cancermentioning

confidence: 99%

Aging and cancer

Montégut,

López-Otín,

Kroemer

2024

Mol Cancer

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“…The vast majority of our epigenetic clocks are based on CpGs that map to the respective genome. Although our R package doesn’t directly contain genome annotation files, CpG genome annotations for many hundreds of species (including non-mammalian species) are available on the Mammalian Methylation Consortium’s GitHub page 12,13 (Horvath, S., Lu, A.T., Li, C.Z., Haghani, A., Arneson, A., Ernest, J. & Mammalian, M.C.…”

Section: Ewasmentioning

confidence: 99%

“…These spanned 59 tissue types and were sourced from 185 mammalian species representing 19 taxonomic orders. Remarkably, the age range of these samples extends from prenatal stages right up to a venerable 139 years, as seen in the bowhead whale (Balaena mysticetus) 12,13 . We published numerous epigenetic clocks tailored to specific species and tissue types 14–38 .…”

Section: Introductionmentioning

confidence: 98%

MammalMethylClock R package: software for DNA Methylation-Based Epigenetic Clocks in Mammals

Zoller,

Horvath

2023

Preprint

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Epigenetic clocks are prediction methods that relate cytosine methylation levels at specific genomic sites to chronological age, accounting for nuances such as genome mapping information and possibly life history traits such as age at sexual maturity. Defined as multivariate regression models, these DNA methylation-based biomarkers have gained prominence in species conservation efforts and preclinical studies. Once built, these models predict an individual's age from their tissue sample's methylation profile, with great potential for aging research, disease risk prediction, gauging intervention impacts. Through the collaborative efforts of our Mammalian Methylation Consortium, we've described epigenetic clocks for numerous mammalian species. Our R package includes the utility for implementing these pre-existing mammalian clocks. Overall, we present software tools and a dedicated R package called MammalMethylClock, designed for the construction and assessment of epigenetic clocks.

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“…The Mammalian Methylation Consortium used the mammalian methylation array, which measures DNA methylation levels in 37 492 CpGs, including those flanking DNA sequences that are highly conserved across mammals ( Arneson et al 2022 ). The consortium successfully profiled over 15 000 samples from 348 mammalian species ( Haghani et al 2023 , Lu et al 2023 ) and published many epigenetic clocks tailored to specific species and tissue types [see the software’s GitHub page ( https://github.com/jazoller96/mammalian-methyl-clocks/tree/main ) or the “getClockDatabase()” function for a list of references for all of the clocks included in this software]. In the following, we present the R software tools and the accompanying statistical techniques pivotal for the development, assessment, and application of these epigenetic clocks.…”

Section: Introductionmentioning

confidence: 99%

MammalMethylClock R package: software for DNA methylation-based epigenetic clocks in mammals

Zoller,

Horvath

2024

Bioinformatics

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Motivation Epigenetic clocks are prediction methods based on DNA methylation levels in a given species or set of species. Defined as multivariate regression models, these DNA methylation-based biomarkers of age or mortality risk are useful in species conservation efforts and in preclinical studies. Results We present an R package called MammalMethylClock for the construction, assessment, and application of epigenetic clocks in different mammalian species. The R package includes the utility for implementing pre-existing mammalian clocks from the Mammalian Methylation Consortium. Availability The source code and documentation manual for MammalMethylClock, and clock coefficient .csv files that are included within this software package, can be found on Zenodo at https://doi.org/10.5281/zenodo.10971037. Supplementary information Supplementary data are available at Bioinformatics online.

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DNA methylation networks underlying mammalian traits

Cited by 48 publications

References 89 publications

Aging and cancer

Aging and cancer

MammalMethylClock R package: software for DNA Methylation-Based Epigenetic Clocks in Mammals

MammalMethylClock R package: software for DNA methylation-based epigenetic clocks in mammals

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