AI Article Synopsis
- - The study focuses on the mitochondrial genome of 39 diploid potato varieties, revealing important genetic insights that could enhance potato breeding and contribute to global food security.
- - Researchers identified a candidate open reading frame (ORF137) potentially related to cytoplasmic male sterility (CMS) in potatoes, which is a significant trait in plant breeding.
- - By analyzing gene content and sequence evolution, the study highlights the genetic diversity between wild and cultivated diploid potatoes, using advanced sequencing techniques to map out their mitochondrial DNA.
Article Abstract
We report the mitochondrial genome of 39 diploid potatoes and identify a candidate ORF potentially linked to cytoplasmic male sterility in potatoes. Potato (Solanum tuberosum L.) holds a critical position as the foremost non-grain food crop, playing a pivotal role in ensuring global food security. Diploid potatoes constitute a vital genetic resource pool, harboring the potential to revolutionize modern potato breeding. Nevertheless, diploid potatoes are relatively understudied, and mitochondrial DNA can provide valuable insights into key potato breeding traits such as CMS. In this study, we examine and assemble the mitochondrial genome evolution and diversity of 39 accessions of diploid potatoes using high-fidelity (HiFi) sequencing. We annotated 54 genes for all the investigated accessions, comprising 34 protein-coding genes, 3 rRNA genes, and 17 tRNA genes. Our analyses revealed differences in repeats sequences between wild and cultivated landraces. To understand the evolution of diploid maternal lineage inheritance, we conducted phylogenetic analysis, which clearly distinguished mitochondrial from nuclear gene trees, further supporting the evidence-based of clustering between wild and cultivated landraces accessions. Our study discovers new candidate ORFs associated with CMS in potatoes, including ORF137, which is homologous to other CMS in Solanaceae. Ultimately, this work bridges the gap in mitochondrial genome research for diploid potatoes, providing a steppingstone into evolutionary studies and potato breeding.
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| http://dx.doi.org/10.1007/s00299-024-03326-4 | DOI Listing |
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