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Accumulation of Large Lineage-Specific Repeats Coincides with Sequence Acceleration and Structural Rearrangement in Plantago Plastomes.

Jie WangShenglong KanJiali KongLiyun NieWeishu FanYong Lin RenWayne Gerald ReeveJeffrey P MowerZhi-Qiang Wu
Published in: Genome biology and evolution (2024)
Repeats can mediate rearrangements and recombination in plant mitochondrial genomes and plastid genomes. While repeat accumulations are linked to heightened evolutionary rates and complex structures in specific lineages, debates persist regarding the extent of their influence on sequence and structural evolution. In this study, 75 Plantago plastomes were analyzed to investigate the relationships between repeats, nucleotide substitution rates, and structural variations. Extensive repeat accumulations were associated with significant rearrangements and inversions in the large inverted repeats (IRs), suggesting that repeats contribute to rearrangement hotspots. Repeats caused infrequent recombination that potentially led to substoichiometric shifting, supported by long-read sequencing. Repeats were implicated in elevating evolutionary rates by facilitating localized hypermutation, likely through DNA damage and repair processes. This study also observed a decrease in nucleotide substitution rates for loci translocating into IRs, supporting the role of biased gene conversion in maintaining lower substitution rates. Combined with known parallel changes in mitogenomes, it is proposed that potential dysfunction in nuclear-encoded genes associated with DNA replication, recombination, and repair may drive the evolution of Plantago organellar genomes. These findings contribute to understanding how repeats impact organellar evolution and stability, particularly in rapidly evolving plant lineages.
Keyphrases
  • dna damage
  • genome wide
  • dna repair
  • oxidative stress
  • single cell
  • high resolution
  • dna methylation
  • amino acid
  • single molecule