loading page

Chromosome-level genome assembly of five Emberiza species reveals the genomic characteristics and intrinsic drivers of adaptive radiation
  • +4
  • Tingli Hu,
  • Haohao Ma,
  • yongxuan xiao,
  • Ruolei Sun,
  • Chunlin Li,
  • Lei Shan,
  • Baowei Zhang
Tingli Hu
Anhui University School of Life Sciences
Author Profile
Haohao Ma
Anhui University School of Life Sciences
Author Profile
yongxuan xiao
Anhui University School of Life Sciences
Author Profile
Ruolei Sun
Anhui University School of Life Sciences
Author Profile
Chunlin Li
Anhui University School of Life Sciences
Author Profile
Lei Shan
Nanjing Normal University School of Life Sciences
Author Profile
Baowei Zhang
Anhui University

Corresponding Author:[email protected]

Author Profile

Abstract

not-yet-known not-yet-known not-yet-known unknown Emberiza buntings (Aves: Emberizidae) exhibit extensive diversity and rapid diversification within the Old World, particularly in the eastern Palearctic, making them valuable models for studying rapid radiation among sympatric species. Despite their ecological and morphological diversity, there remains a significant gap in understanding the genomic underpinnings driving their rapid speciation. To address this gap, we assembled high-quality chromosome-level genomes of five representative Emberiza species (E. aureola, E. pusilla, E. rustica, E. rutila, and E. spodocephala). Comparative genomic analysis revealed distinct migration-related evolutionary adaptations in their genomes, including variations in lipid metabolism, oxidative stress response, locomotor ability, and circadian regulation. These changes may facilitate the rapid occupation of emerging ecological niches and provide opportunities for species diversification. Additionally, these five species exhibited abnormal abundances of long terminal repeat retrotransposons (LTRs), comprising over 20% of their genomes, with insertion times corresponding to their divergence (~2.5 million years ago). The presence of LTRs influenced genome size, chromosomal structure, and single-gene expression, suggesting their role in promoting the rapid diversification of Emberiza species. These findings offer valuable insights into the adaptive radiation of Emberiza and establish a robust theoretical foundation for further exploration of the patterns and mechanisms underlying their diversification.
Submitted to Molecular Ecology Resources
Submission Checks Completed
Assigned to Editor
Reviewer(s) Assigned
22 Jun 2024Review(s) Completed, Editorial Evaluation Pending
18 Jul 2024Reviewer(s) Assigned
01 Oct 2024Editorial Decision: Revise Minor
28 Oct 20241st Revision Received
29 Oct 2024Submission Checks Completed
29 Oct 2024Assigned to Editor
29 Oct 2024Review(s) Completed, Editorial Evaluation Pending