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An updated reference genome sequence and annotation reveals gene losses and gains underlying naked mole-rat biology
Dustin Sokolowski, Mihai Miclăuș, Alexander Nater, Mariela Faykoo-Martinez, Kendra Hoekzema, Philip C. Zuzarte, Simon Monis, Sana Alvi, Jason Erdmann, Archana Lal Erdmann, Kumaragurubaran Rathnakumar, Jonathan Bayerl, DongAhn Yoo, Nadia Karimpour, Kyra Ungerleider
bioRxiv (Cold Spring Harbor Laboratory) · 2024 · ▲ 10 citations
Abstract
The naked mole-rat (NMR; Heterocephalus glaber ) is a eusocial subterranean rodent with a highly unusual set of physiological traits that has attracted great interest amongst the scientific community. However, the genetic basis of most of these traits has not been elucidated. To facilitate our understanding of the molecular mechanisms underlying NMR physiology and behaviour, we generated a long-read chromosomal-level genome assembly of the NMR. This genome was subsequently annotated and incorporated into multiple whole genome alignments in the Ensembl database. Our long-read assembly identified thousands of repeats and genes that were previously unassembled in the NMR and improved the results of routinely used short-read sequencing-based experiments such as RNA-seq, snRNA-seq, and ATAC-seq. We identified several spermatozoa related gene losses that may underlie the unique degenerative sperm phenotype in NMRs ( IRGC , FSCB , AKAP3 , MROH2B , CATSPER1 , DCDC2C , ATP1A4 , TEKT5 , and ZAN ), and an additional gene loss related to the established NK-cell absence in NMRs (PILRB). We resolved several tandem duplications in genes related to pathways underlying unique NMR adaptations including hypoxia tolerance, oxidative stress, and nervous system protection ( TINF2 , TCP1 , KYAT1 ). Lastly, we describe our ongoing efforts to generate a reference telomere(definition)-to-telomere assembly in the NMR which includes the resolution of complex gene families. This new reference genome should accelerate the discovery of the genetic underpinnings of NMR physiology and adaptation.
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- DOI
- 10.1101/2024.11.26.625329
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- 2026-07-07 MST
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APA
Sokolowski, D., Miclăuș, M., Nater, A., Faykoo-Martinez, M., Hoekzema, K., Zuzarte, P.C., Monis, S., Alvi, S., Erdmann, J., Erdmann, A.L., Rathnakumar, K., Bayerl, J., Yoo, D., Karimpour, N., Ungerleider, K., Hou, H., Martin, F.J., Hourlier, T., Clarke, Z.A., & Lischer, H.E.L. (2024). An updated reference genome sequence and annotation reveals gene losses and gains underlying naked mole-rat biology. <em>bioRxiv (Cold Spring Harbor Laboratory)</em>. https://doi.org/10.1101/2024.11.26.625329
Vancouver
Sokolowski D, Miclăuș M, Nater A, Faykoo-Martinez M, Hoekzema K, Zuzarte PC, et al. An updated reference genome sequence and annotation reveals gene losses and gains underlying naked mole-rat biology. bioRxiv (Cold Spring Harbor Laboratory). 2024. doi:10.1101/2024.11.26.625329.
BibTeX
@unpublished{dustin2024Anupda,
title = {An updated reference genome sequence and annotation reveals gene losses and gains underlying naked mole-rat biology},
author = {Dustin Sokolowski and Mihai Miclăuș and Alexander Nater and Mariela Faykoo-Martinez and Kendra Hoekzema and Philip C. Zuzarte and Simon Monis and Sana Alvi and Jason Erdmann and Archana Lal Erdmann and Kumaragurubaran Rathnakumar and Jonathan Bayerl and DongAhn Yoo and Nadia Karimpour and Kyra Ungerleider and Huayun Hou and Fergal J. Martin and Thibaut Hourlier and Zoe A. Clarke and Heidi E. L. Lischer and Dragoș-Vasile Leordean and Yiyue Jiang and Trevor J. Pugh and Ewan St. John Smith and Leanne Haggerty},
journal = {bioRxiv (Cold Spring Harbor Laboratory)},
year = {2024},
doi = {10.1101/2024.11.26.625329},
}
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