Epigenetic changes to gene pathways linked to male fertility in ex situ black-footed ferrets

Stavi R Tennenbaum; Robyn Bortner; Colleen Lynch; Rachel Santymire; Adrienne Crosier; Jenny Santiestevan; Paul Marinari; Budhan S Pukazhenthi; Pierre Comizzoli; Melissa T R Hawkins; Jesús E Maldonado; Klaus-Peter Koepfli; Bridgett M vonHoldt; Alexandra L DeCandia

doi:10.1111/eva.13634

Epigenetic changes to gene pathways linked to male fertility in ex situ black-footed ferrets

Evol Appl. 2024 Jan 26;17(1):e13634. doi: 10.1111/eva.13634. eCollection 2024 Jan.

Authors

Stavi R Tennenbaum¹, Robyn Bortner², Colleen Lynch³, Rachel Santymire^{4

5}, Adrienne Crosier⁶, Jenny Santiestevan⁵, Paul Marinari⁶, Budhan S Pukazhenthi⁵, Pierre Comizzoli⁵, Melissa T R Hawkins⁷, Jesús E Maldonado⁸, Klaus-Peter Koepfli^{5

9}, Bridgett M vonHoldt¹, Alexandra L DeCandia^{8

10}

Affiliations

¹ Ecology and Evolutionary Biology Princeton University Princeton New Jersey USA.
² U.S. Fish & Wildlife Service National Black-Footed Ferret Conservation Center Carr Colorado USA.
³ Riverbanks Zoo and Garden Columbia South Carolina USA.
⁴ Biology Department Georgia State University Atlanta Georgia USA.
⁵ Center for Species Survival Smithsonian's National Zoo and Conservation Biology Institute Front Royal Virginia USA.
⁶ Center for Animal Care Sciences Smithsonian's National Zoo & Conservation Biology Institute Front Royal Virginia USA.
⁷ Division of Mammals, Department of Vertebrate Zoology National Museum of Natural History Washington DC USA.
⁸ Center for Conservation Genomics Smithsonian's National Zoo and Conservation Biology Institute Washington DC USA.
⁹ Smithsonian-Mason School of Conservation George Mason University Front Royal Virginia USA.
¹⁰ Biology Georgetown University Washington DC USA.

Abstract

Environmental variation can influence the reproductive success of species managed under human care and in the wild, yet the mechanisms underlying this phenomenon remain largely mysterious. Molecular mechanisms such as epigenetic modifiers are important in mediating the timing and progression of reproduction in humans and model organisms, but few studies have linked epigenetic variation to reproductive fitness in wildlife. Here, we investigated epigenetic variation in black-footed ferrets (Mustela nigripes), an endangered North American mammal reliant on ex situ management for survival and persistence in the wild. Despite similar levels of genetic diversity in human-managed and wild-born populations, individuals in ex situ facilities exhibit reproductive problems, such as poor sperm quality. Differences across these settings suggest that an environmentally driven decline in reproductive capacity may be occurring in this species. We examined the role of DNA methylation, one well-studied epigenetic modifier, in this emergent condition. We leveraged blood, testes, and semen samples from male black-footed ferrets bred in ex situ facilities and found tissue-type specificity in DNA methylation across the genome, although 1360 Gene Ontology terms associated with male average litter size shared functions across tissues. We then constructed gene networks of differentially methylated genomic sites associated with three different reproductive phenotypes to explore the putative biological impact of variation in DNA methylation. Sperm gene networks associated with average litter size and sperm count were functionally enriched for candidate genes involved in reproduction, development, and its regulation through transcriptional repression. We propose that DNA methylation plays an important role in regulating these reproductive phenotypes, thereby impacting the fertility of male ex situ individuals. Our results provide information into how DNA methylation may function in the alteration of reproductive pathways and phenotypes in artificial environments. These findings provide early insights to conservation hurdles faced in the protection of this rare species.

Keywords: DNA methylation; Mustela nigripes; conservation; infertility; reproduction; sperm.