Sexual reproduction relies on meiotic chromosome pairing to form bivalents, a process that is complicated in polyploids owing to the presence of multiple subgenomes1. Uneven ploidy mostly results in sterility due to unbalanced chromosome pairing and segregation during meiosis. However, pentaploid dogroses (Rosa sect. Caninae; 2n = 5x = 35) achieve stable sexual reproduction through a unique mechanism: 14 chromosomes form bivalents and are transmitted biparentally, while the remaining 21 chromosomes are maternally inherited as univalents2,3. Despite being studied for over a century, the role of centromeres in this process has remained unclear. Here we analyse haplotype-resolved chromosome-level genome assemblies for three pentaploid dogroses. Subgenome phasing revealed a bivalent-forming subgenome with two highly homozygous chromosome sets and three divergent subgenomes lacking homologous partners, therefore explaining their meiotic behaviour. Comparative analyses of chromosome synteny, phylogenetic relationships and centromere composition indicate that the subgenomes originated from two divergent clades of the genus Rosa. Pollen genome analysis shows that subgenomes from different evolutionary origins form bivalents, supporting multiple origins of dogroses and highlighting variation in subgenome contributions. We reveal that bivalent-forming centromeres are enriched with ATHILA retrotransposons, contrasting with larger tandem-repeat-based centromeres mainly found in univalents. This centromere structural bimodality possibly contributes to univalent drive during female meiosis. Our findings provide insights into the unique reproductive strategies of dogroses, advancing our understanding of genome evolution, centromere diversity and meiotic mechanisms in organisms with asymmetrical inheritance systems.

• MeSH
• centromera * genetika   metabolismus   MeSH
• chromozomy rostlin genetika   MeSH
• fylogeneze MeSH
• genom rostlinný genetika   MeSH
• haplotypy genetika   MeSH
• meióza * genetika   MeSH
• polyploidie * MeSH
• pyl genetika   cytologie   MeSH
• retroelementy genetika   MeSH
• syntenie genetika   MeSH
• Publikační typ
• časopisecké články MeSH
• Názvy látek
• retroelementy MeSH

In most studied eukaryotes, chromosomes are monocentric, with centromere activity confined to a single region. However, the rush family (Juncaceae) includes species with both monocentric (Juncus) and holocentric (Luzula) chromosomes, where centromere activity is distributed along the entire chromosome length. Here, we combine chromosome-scale genome assembly, epigenetic analysis, immuno-FISH and super-resolution microscopy to study the transition to holocentricity in Luzula sylvatica. We report repeat-based holocentromeres with an irregular distribution of features along the chromosomes. Luzula sylvatica holocentromeres are predominantly associated with two satellite DNA repeats (Lusy1 and Lusy2), while CENH3 also binds satellite-free gene-poor regions. Comparative repeat analysis suggests that Lusy1 plays a crucial role in centromere function across most Luzula species. Furthermore, synteny analysis between L. sylvatica (n = 6) and Juncus effusus (n = 21) suggests that holocentric chromosomes in Luzula could have arisen from chromosome fusions of ancestral monocentric chromosomes, accompanied by the expansion of CENH3-associated satellite repeats.

• MeSH
• centromera * genetika   MeSH
• chromozomy rostlin * genetika   MeSH
• DNA rostlinná genetika   MeSH
• genom rostlinný MeSH
• hybridizace in situ fluorescenční MeSH
• molekulární evoluce MeSH
• repetitivní sekvence nukleových kyselin genetika   MeSH
• satelitní DNA * genetika   MeSH
• syntenie MeSH
• Publikační typ
• časopisecké články MeSH
• práce podpořená grantem MeSH
• Názvy látek
• DNA rostlinná MeSH
• satelitní DNA * MeSH