Establishment of the 'imbibed seed piercing' method for Agrobacterium-mediated transformation of jute and flax bast fibre crops via phloem-specific expression of the β-glucuronidase Gene

Abstract

Jute (Corchorus capsularis) and flax (Linum usitatissimum) have been established as important sources of bast fibres (phloem fibres) worldwide. These long and lustrous natural fibres are used for various commercial and industrial purposes and hold immense future prospects. To meet the worldwide demand for bast fibres, improvement in the production and quality of jute and flax is essential. Molecular breeding is an expeditious approach for varietal improvement and requires an efficient gene transformation system. The available methods for jute and flax transformation are highly specific to species and variety, requiring a long time and rigorous preparation of media, explants, and screening procedures. In this study, we used a fast and stable method for Agrobacterium tumefaciens-mediated transformation of jute (variety JRC321) and flax (variety FT-897), known as the ‘imbibed seed piercing’ method (ISPM), where seeds were used as explants. A phloem-specific Arabidopsis sucrose-proton H+ symporter 2 (AtSUC2) promoter-driven gus gene (β-glucuronidase) was used for the assessment of genetic transformation of jute and flax plants. Transformed seedlings were selected following three consecutive selection pressure tests conducted at two-week intervals using kanamycin-supplemented culture media. Transgene integration was verified using Southern blotting and PCR-based molecular characterization of jute and flax plants. The gus gene expression levels in the transgenic jute and flax tissue samples were analysed by semi-quantitative and quantitative RT-PCR. The GUS protein expression in transgenic plant tissues was confirmed by the development of blue colour in the histochemical GUS assay. Blue colouration was observed only in phloem cells of the tested plant tissues. Transgenic progeny plants of subsequent generations followed the 3:1 transgene segregation pattern and exhibited phloem-specific GUS expression. This fast, easy, and stable ISPM could also be applied to other fibre producing industrial crops and could form a part of a modern CRISPR/Cas9-based genome editing tool by efficiently delivering CRISPR vectors in jute and flax plants.