WRKY transcription factor (TF) family regulates many functions in plant growth and development and also during biotic and abiotic stress. In this study, 101
WRKY
TF gene models in
indica
and
japonica
rice were used to conduct evolutionary analysis, gene structure analysis, and motif composition. Co-expression analysis was carried out first by selecting the differentially expressing genes that showed a significant change in response to the pathogens from Rice Oligonucleotide Array Database (ROAD). About 82 genes showed responses to infection by
Magnaporthe oryzae
or
Xanthomonas oryzae
pv.
oryzae
. Co-expression gene network was constructed using direct neighborhood and context associated inbuilt mode in RiceNetv2 tool. Only 41 genes showed interaction with 2299 non-
WRKY
genes. Variations exist in the structure and evolution of
WRKY
genes among
indica
and
japonica
genotypes which have important implications in their differential roles including disease resistance.
WRKY
genes mediate a complex networking and co-express along with other
WRKY
and non-
WRKY
genes to mediate resistance against fungal and bacterial pathogens in rice.
In plants, pathogen resistance is brought about due to the binding of certain transcription factors (TF) proteins to the cis-elements of certain target genes. These cis-elements are present up-stream in the motif of the promoters of each gene. This ensures the binding of a specific transcription factor to a specific promoter, therefore regulating the expression of that gene. Therefore, the study of each promoter sequence of all the rice genes would help identify the target genes of a specific transcription factor. Rice 1kb upstream promoter sequences of 55,986 annotated genes were analyzed using the Perl program algorithm to detect WRKY13 binding motifs (bm). The resulting genes were grouped using gene ontology and gene set enrichment analysis. Gene with more than 4 TFbm in their promoter was selected. Nine genes reported to have a role in rice disease resistance were selected for further analysis. Cis-acting regulatory element analysis was carried out to find the cis-elements and to confirm the presence of the corresponding motifs in the promoter sequences of these genes. The 3D structure of WRKY13 TF and the corresponding nine genes were built and the interacting residues were determined. The binding capacity of WRKY13 to the promoter of these selected genes was analyzed using docking studies. WRKY13 was also considered for docking analysis based on the prior reports of autoregulation. Molecular dynamic simulations provided more details regarding the interactions. Expression data revealed the expression of the genes that helped to provide the mechanism of interaction. Further co-expression network drew light on the interaction of these selected diseases resistance-related genes with WRKY13 TF protein. This study suggests the target downstream genes that are regulated by WRKY13 TF. The molecular mechanism involving the gene network regulated by WRKY13 TF in disease resistance against rice fungal pathogens is explored.
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