Genome Biology (Mar 2022)

The spinach YY genome reveals sex chromosome evolution, domestication, and introgression history of the species

  • Xiaokai Ma,
  • Li’ang Yu,
  • Mahpara Fatima,
  • William H. Wadlington,
  • Amanda M. Hulse-Kemp,
  • Xingtan Zhang,
  • Shengcheng Zhang,
  • Xindan Xu,
  • Jingjing Wang,
  • Huaxing Huang,
  • Jing Lin,
  • Ban Deng,
  • Zhenyang Liao,
  • Zhenhui Yang,
  • Yanhong Ma,
  • Haibao Tang,
  • Allen Van Deynze,
  • Ray Ming

DOI
https://doi.org/10.1186/s13059-022-02633-x
Journal volume & issue
Vol. 23, no. 1
pp. 1 – 30

Abstract

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Abstract Background Spinach (Spinacia oleracea L.) is a dioecious species with an XY sex chromosome system, but its Y chromosome has not been fully characterized. Our knowledge about the history of its domestication and improvement remains limited. Results A high-quality YY genome of spinach is assembled into 952 Mb in six pseudo-chromosomes. By a combination of genetic mapping, Genome-Wide Association Studies, and genomic analysis, we characterize a 17.42-Mb sex determination region (SDR) on chromosome 1. The sex chromosomes of spinach evolved when an insertion containing sex determination genes occurred, followed by a large genomic inversion about 1.98 Mya. A subsequent burst of SDR-specific repeats (0.1–0.15 Mya) explains the large size of this SDR. We identify a Y-specific gene, NRT1/PTR 6.4 which resides in this insertion, as a strong candidate for the sex determination or differentiation factor. Resequencing of 112 spinach genomes reveals a severe domestication bottleneck approximately 10.87 Kya, which dates the domestication of spinach 7000 years earlier than the archeological record. We demonstrate that a strong selection signal associated with internode elongation and leaf area expansion is associated with domestication of edibility traits in spinach. We find that several strong genomic introgressions from the wild species Spinacia turkestanica and Spinacia tetrandra harbor desirable alleles of genes related to downy mildew resistance, frost resistance, leaf morphology, and flowering-time shift, which likely contribute to spinach improvement. Conclusions Analysis of the YY genome uncovers evolutionary forces shaping nascent sex chromosome evolution in spinach. Our findings provide novel insights about the domestication and improvement of spinach.

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