The genomics of ecological flexibility, large brains, and long lives in capuchin monkeys revealed with fecalFACS.
Joseph D OrkinMichael J MontagueDaniela Tejada-MartinezMarc de ManuelJavier Del CampoSaul Cheves HernandezAnthony Di FioreClaudia FontsereJason A HodgsonMareike C JaniakLukas F K KudernaEsther LizanoMaria Pia MartinYoshihito NiimuraGeorge H PerryCarmen Soto ValverdeJia TangWesley C WarrenJoão Pedro de MagalhãesShoji KawamuraTomas Marques-BonetRoman J KrawetzAmanda Dawn MelinPublished in: Proceedings of the National Academy of Sciences of the United States of America (2021)
Ecological flexibility, extended lifespans, and large brains have long intrigued evolutionary biologists, and comparative genomics offers an efficient and effective tool for generating new insights into the evolution of such traits. Studies of capuchin monkeys are particularly well situated to shed light on the selective pressures and genetic underpinnings of local adaptation to diverse habitats, longevity, and brain development. Distributed widely across Central and South America, they are inventive and extractive foragers, known for their sensorimotor intelligence. Capuchins have among the largest relative brain size of any monkey and a lifespan that exceeds 50 y, despite their small (3 to 5 kg) body size. We assemble and annotate a de novo reference genome for Cebus imitator Through high-depth sequencing of DNA derived from blood, various tissues, and feces via fluorescence-activated cell sorting (fecalFACS) to isolate monkey epithelial cells, we compared genomes of capuchin populations from tropical dry forests and lowland rainforests and identified population divergence in genes involved in water balance, kidney function, and metabolism. Through a comparative genomics approach spanning a wide diversity of mammals, we identified genes under positive selection associated with longevity and brain development. Additionally, we provide a technological advancement in the use of noninvasive genomics for studies of free-ranging mammals. Our intra- and interspecific comparative study of capuchin genomics provides insights into processes underlying local adaptation to diverse and physiologically challenging environments, as well as the molecular basis of brain evolution and longevity.
Keyphrases
- single cell
- resting state
- genome wide
- climate change
- white matter
- functional connectivity
- cerebral ischemia
- single molecule
- gene expression
- multiple sclerosis
- human health
- drosophila melanogaster
- optical coherence tomography
- risk assessment
- bone marrow
- mesenchymal stem cells
- cell therapy
- case control
- transcription factor
- subarachnoid hemorrhage