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Description
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Centromeres are essential for chromosome segregation, yet their organisation and evolution remain poorly understood in holocentric species, where kinetochore activity is distributed along entire chromosomes1,2. While monocentric centromeres are often structured by megabase-sized satellite arrays3–5, the role of repetitive DNA in holocentric systems remains enigmatic. Here, we analyse the dynamics of centromeric Tyba satellite DNA repeats and transposable elements across a chromosome-scale pangenome comprising 52 long-read genome assemblies from 20 Rhynchospora species6,7, a plant genus with repeat-based holocentromeres8,9. We identify over 4.6 million monomers of the Tyba satellite repeat, arranged into 43,400 discrete arrays that span all chromosomes. CENH3 ChIP-seq confirms Tyba as the universal centromeric marker across the genus, showcasing the conservation of the same centromeric DNA over 40 million years. We show that Tyba arrays function as modular centromeric units whose number and spacing, but not size, scale with chromosome length. Tyba sequence diversity recapitulates species phylogeny, while higher-order repeat formation and antagonism with transposable elements shape array turnover. A novel synteny-aware algorithm reveals rapid gain, loss, and rearrangement of arrays across homologous chromosomes. Using cytogenetics and polymer simulations, we demonstrate that inter-array spacing governs chromatin loop length and chromatid thickness, linking repeat-based holocentromere organisation directly to chromosome mechanics. Our findings uncover a scalable, modular logic for holocentromere function and establish a framework for understanding the plasticity of repeat-based centromere evolution and genome architecture in eukaryotes.
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