Repository logo
 

Cycles of satellite and transposon evolution in Arabidopsis centromeres.

Accepted version
Peer-reviewed

Loading...
Thumbnail Image

Change log

Abstract

Centromeres are critical for cell division, loading CENH3 or CENPA histone variant nucleosomes, directing kinetochore formation and allowing chromosome segregation1,2. Despite their conserved function, centromere size and structure are diverse across species. To understand this centromere paradox3,4, it is necessary to know how centromeric diversity is generated and whether it reflects ancient trans-species variation or, instead, rapid post-speciation divergence. To address these questions, we assembled 346 centromeres from 66 Arabidopsis thaliana and 2 Arabidopsis lyrata accessions, which exhibited a remarkable degree of intra- and inter-species diversity. A. thaliana centromere repeat arrays are embedded in linkage blocks, despite ongoing internal satellite turnover, consistent with roles for unidirectional gene conversion or unequal crossover between sister chromatids in sequence diversification. Additionally, centrophilic ATHILA transposons have recently invaded the satellite arrays. To counter ATHILA invasion, chromosome-specific bursts of satellite homogenization generate higher-order repeats and purge transposons, in line with cycles of repeat evolution. Centromeric sequence changes are even more extreme in comparison between A. thaliana and A. lyrata. Together, our findings identify rapid cycles of transposon invasion and purging through satellite homogenization, which drive centromere evolution and ultimately contribute to speciation.

Description

Journal Title

Nature

Conference Name

Journal ISSN

0028-0836
1476-4687

Volume Title

Publisher

Springer Nature

Rights and licensing

Except where otherwised noted, this item's license is described as Attribution 4.0 International
Sponsorship
Leverhulme Trust (RPG-2019-259)
European Research Council (681987)
Biotechnology and Biological Sciences Research Council (BB/S006842/1)
Biotechnology and Biological Sciences Research Council (BB/S020012/1)
BBSRC (BB/V003984/1)
This work was supported by BBSRC grants BB/S006842/1, BB/S020012/1 and BB/V003984/1, European Research Council Consolidator Award ERC-2015-CoG-681987, Marie Curie International Training Network ‘MEICOM’ and Human Frontier Science Program award RGP0025/2021 to IRH; EMBO long term postdoctoral fellowship ALTF224-2022 to RB; Human Frontiers Science Program (HFSP) Long-Term Fellowship (LT000819/2018-L) to FAR; Max Planck Society to DW; ERA-CAPS 1001G+ grant to MNo and DW; Royal Society awards UF160222, URF\R\221024, RGF/R1/180006 and RGF/EA/201030 to AB; European Research Council Award ERC HOW2DOBLE 101041354 to PYN; Czech Science Foundation grant number 21-03909S to ML; a BBSRC DTP Studentship to NG; a Broodbank Fellowship to MN; and grant PID2022-136893NB-I00 from the Ministerio de Ciencia e Innovación of Spain/Agencia Estatal de Investigación/10.13039/501100011033/FEDER, EU, to CAB.