4.7 Article

The genome of the recretohalophyte Limonium bicolor provides insights into salt gland development and salinity adaptation during terrestrial evolution

Journal

MOLECULAR PLANT
Volume 15, Issue 6, Pages 1024-1044

Publisher

CELL PRESS
DOI: 10.1016/j.molp.2022.04.011

Keywords

development; evolution; genome; Limonium bicolor; salinity adaptation; salt gland

Funding

  1. National Natural Science Research Foundation of China (NSFC) [32170301, 31770288, 31600200]
  2. MOE Layout Foundation of Humanities and Social Sciences [21YJAZH108]
  3. Shandong Provincial Bohai Granary Science and Technology Demonstration Project [2019BHLC004]

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In this study, a high-quality assembled genome of sea lavender (Limonium bicolor) was reported, providing molecular insights into the absence of trichomes in this species and confirming the key genes involved in salt gland development. Additionally, a whole-genome duplication event in the sea lavender genome was identified, which may contribute to its adaptation to high salinity. This study offers profound information on plant salt tolerance mechanisms and may facilitate the engineering of salt-tolerant crops.
Halophytes have evolved specialized strategies to cope with high salinity. The extreme halophyte sea lavender (Limonium bicolor) lacks trichomes but possesses salt glands on its epidermis that can excrete harmful ions, such as sodium, to avoid salt damage. Here, we report a high-quality, 2.92-Gb, chromosome-scale L. bicolor genome assembly based on a combination of Illumina short reads, singlemolecule, real-time long reads, chromosome conformation capture (Hi-C) data, and Bionano genome maps, greatly enriching the genomic information on recretohalophytes with multicellular salt glands. Although the L. bicolor genome contains genes that show similarity to trichome fate genes from Arabidopsis thaliana, it lacks homologs of the decision fate genes GLABRA3, ENHANCER OF GLABRA3, GLABRA2, TRANSPARENT TESTA GLABRA2, and SIAMESE, providing a molecular explanation for the absence of trichomes in this species. We identified key genes (LbHLH and LbTTG1) controlling salt gland development among classical trichome homologous genes and confirmed their roles by showing that their mutations markedly disrupted salt gland initiation, salt secretion, and salt tolerance, thus offering genetic support for the long-standing hypothesis that salt glands and trichomes may share a common origin. In addition, a whole-genome duplication event occurred in the L. bicolor genome after its divergence from Tartary buckwheat and may have contributed to its adaptation to high salinity. The L. bicolor genome resource and genetic evidence reported in this study provide profound insights into plant salt tolerance mechanisms that may facilitate the engineering of salt-tolerant crops.

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