Litcius/Paper detail

Flagellin and mannitol modulate callose biosynthesis and deposition in soybean seedlings

Sara Sangi, Geovanna Vitória Olimpio, Fernanda Silva Coelho, Camilla Ribeiro Alexandrino, Maura Da Cunha, Clícia Grativol

2023Physiologia Plantarum14 citationsDOI

Abstract

Callose is a polymer deposited on the cell wall and is necessary for plant growth and development. Callose is synthesized by genes from the glucan synthase-like family (GSL) and dynamically responds to various types of stress. Callose can inhibit pathogenic infection, in the case of biotic stresses, and maintain cell turgor and stiffen the plant cell wall in abiotic stresses. Here, we report the identification of 23 GSL genes (GmGSL) in the soybean genome. We performed phylogenetic analyses, gene structure prediction, duplication patterns, and expression profiles on several RNA-Seq libraries. Our analyses show that WGD/Segmental duplication contributed to expanding this gene family in soybean. Next, we analyzed the callose responses in soybean under abiotic and biotic stresses. The data show that callose is induced by both osmotic stress and flagellin 22 (flg22) and is related to the activity of β-1,3-glucanases. By using RT-qPCR, we evaluated the expression of GSL genes during the treatment of soybean roots with mannitol and flg22. The GmGSL23 gene was upregulated in seedlings treated with osmotic stress or flg22, showing the essential role of this gene in the soybean defense response to pathogenic organisms and osmotic stress. Our results provide an important understanding of the role of callose deposition and regulation of GSL genes in response to osmotic stress and flg22 infection in soybean seedlings.

Topics & Concepts

CalloseBiologyTurgor pressureBiotic stressCell wallBotanyAbiotic stressGeneOsmotic shockGene familyGene expressionCell biologyBiochemistryLegume Nitrogen Fixing SymbiosisSoybean genetics and cultivationPlant-Microbe Interactions and Immunity