Genome-Wide Distribution, Organisation and Functional Characterization of Disease Resistance and Defence Response Genes across Rice Species

Abstract

<div><p>The resistance (R) genes and defense response (DR) genes have become very important resources for the development of disease resistant cultivars. In the present investigation, genome-wide identification, expression, phylogenetic and synteny analysis was done for R and DR-genes across three species of rice viz: <i>Oryza sativa ssp indica cv 93-11</i>, <i>Oryza sativa ssp japonica</i> and wild rice species, <i>Oryza brachyantha</i>. We used the <i>in silico</i> approach to identify and map 786 R -genes and 167 DR-genes, 672 R-genes and 142 DR-genes, 251 R-genes and 86 DR-genes in the <i>japonica</i>, <i>indica</i> and <i>O</i>. <i>brachyanth</i> a genomes, respectively. Our analysis showed that 60.5% and 55.6% of the R-genes are tandemly repeated within clusters and distributed over all the rice chromosomes in <i>indica</i> and <i>japonica</i> genomes, respectively. The phylogenetic analysis along with motif distribution shows high degree of conservation of R- and DR-genes in clusters. <i>In silico</i> expression analysis of R-genes and DR-genes showed more than 85% were expressed genes showing corresponding EST matches in the databases. This study gave special emphasis on mechanisms of gene evolution and duplication for R and DR genes across species. Analysis of paralogs across rice species indicated 17% and 4.38% R-genes, 29% and 11.63% DR-genes duplication in <i>indica</i> and <i>Oryza brachyantha</i>, as compared to 20% and 26% duplication of R-genes and DR-genes in <i>japonica</i> respectively. We found that during the course of duplication only 9.5% of R- and DR-genes changed their function and rest of the genes have maintained their identity. Syntenic relationship across three genomes inferred that more orthology is shared between <i>indica</i> and <i>japonica</i> genomes as compared to <i>brachyantha</i> genome. Genome wide identification of R-genes and DR-genes in the rice genome will help in allele mining and functional validation of these genes, and to understand molecular mechanism of disease resistance and their evolution in rice and related species.</p></div