The generation of sheath blight (ShB)-resistant transgenic rice plants through the expression of
Arabidopsis
NPR1
gene is a significant development for research in the field of biotic stress. However, to our knowledge, regulation of the proteomic and metabolic networks in the ShB-resistant transgenic rice plants has not been studied. In the present investigation, the relative proteome and metabolome profiles of the non–transformed wild-type and the
AtNPR1-
transgenic rice lines prior to and subsequent to the
R. solani
infection were investigated. Total proteins from wild type and transgenic plants were investigated using two-dimensional gel electrophoresis (2-DE) followed by mass spectrometry (MS). The metabolomics study indicated an increased abundance of various metabolites, which draws parallels with the proteomic analysis. Furthermore, the proteome data was cross-examined using network analysis which identified modules that were rich in known as well as novel immunity-related prognostic proteins, particularly the mitogen-activated protein kinase 6, probable protein phosphatase 2C1, probable trehalose-phosphate phosphatase 2 and heat shock protein. A novel protein, 14–3–3GF14f was observed to be upregulated in the leaves of the transgenic rice plants after ShB infection, and the possible mechanistic role of this protein in ShB resistance may be investigated further.
Sheath blight, caused by the necrotrophic fungal pathogen Rhizoctonia solani, is a serious and destructive disease of the rice. In order to improve sheath blight resistance, we developed three different kinds of transgenic rice lines. The first transgenic line overexpresses the rice chitinase gene (OsCHI11); the second contains the Arabidopsis NPR1 (AtNPR1) gene and, the third has pyramided constructs with both the genes (OsCHI11 and AtNPR1). This is a comparative study between the single-gene transgenic lines and the double gene transgenic in terms of their ability to activate the plant defense system. Rice plants of each individual construct were screened via PCR, Southern hybridization, activity assays, and expression analysis. The best transgenic lines of each construct were chosen for comparative study. The fold change in qRT-PCR and activity assays revealed that the pyramided transgenic rice plants show a significant upregulation of defense-related genes, PR genes, and antioxidant marker genes as compared to the single transgene. Simultaneous co-expression of both the genes was found to be more efficient in tolerating oxidative stress. In R. solani (RS) toxin assay, mycelial agar disc bioassay, and in vivo plant bioassay, pyramided transgenic plant lines were more competent at restricting the pathogen development and enhancing sheath blight tolerance as compared to single gene transformants.
Antimicrobial Peptides (AMPs) have diverse structures, varied modes of actions, and can
inhibit the growth of a wide range of pathogens at low concentrations. Plants are constantly under
attack by a wide range of phytopathogens causing massive yield losses worldwide. To combat these
pathogens, nature has armed plants with a battery of defense responses including Antimicrobial
Peptides (AMPs). These peptides form a vital component of the two-tier plant defense system. They
are constitutively expressed as part of the pre-existing first line of defense against pathogen entry.
When a pathogen overcomes this barrier, it faces the inducible defense system, which responds to
specific molecular or effector patterns by launching an arsenal of defense responses including the
production of AMPs. This review emphasizes the structural and functional aspects of different
plant-derived AMPs, their homology with AMPs from other organisms, and how their
biotechnological potential could generate durable resistance in a wide range of crops against
different classes of phytopathogens in an environmentally friendly way without phenotypic cost.
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