Nature Communications (Aug 2024)

Chromosome-scale pearl millet genomes reveal CLAMT1b as key determinant of strigolactone pattern and Striga susceptibility

  • Hendrik N. J. Kuijer,
  • Jian You Wang,
  • Salim Bougouffa,
  • Michael Abrouk,
  • Muhammad Jamil,
  • Roberto Incitti,
  • Intikhab Alam,
  • Aparna Balakrishna,
  • Derry Alvarez,
  • Cristina Votta,
  • Guan-Ting Erica Chen,
  • Claudio Martínez,
  • Andrea Zuccolo,
  • Lamis Berqdar,
  • Salim Sioud,
  • Valentina Fiorilli,
  • Angel R. de Lera,
  • Luisa Lanfranco,
  • Takashi Gojobori,
  • Rod A. Wing,
  • Simon G. Krattinger,
  • Xin Gao,
  • Salim Al-Babili

DOI
https://doi.org/10.1038/s41467-024-51189-w
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 12

Abstract

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Abstract The yield of pearl millet, a resilient cereal crop crucial for African food security, is severely impacted by the root parasitic weed Striga hermonthica, which requires host-released hormones, called strigolactones (SLs), for seed germination. Herein, we identify four SLs present in the Striga-susceptible line SOSAT-C88-P10 (P10) but absent in the resistant 29Aw (Aw). We generate chromosome-scale genome assemblies, including four gapless chromosomes for each line. The Striga-resistant Aw lacks a 0.7 Mb genome segment containing two putative CARLACTONOIC ACID METHYLTRANSFERASE1 (CLAMT1) genes, which may contribute to SL biosynthesis. Functional assays show that P10CLAMT1b produces the SL-biosynthesis intermediate methyl carlactonoate (MeCLA) and that MeCLA is the precursor of P10-specific SLs. Screening a diverse pearl millet panel confirms the pivotal role of the CLAMT1 section for SL diversity and Striga susceptibility. Our results reveal a reason for Striga susceptibility in pearl millet and pave the way for generating resistant lines through marker-assisted breeding or direct genetic modification.