Genome-wide Characterization of the Gene Family in Tomato () and Their Relatedness to Disease Resistance

Overview

Journal Front Genet

Date 2022 Dec 22

PMID 36544493

Authors

Sehrish Bashir

Nazia Rehman

Fabia Fakhar Zaman

Muhammad Kashif Naeem

Atif Jamal

Aurelien Tellier

Muhammad Ilyas

Gustavo Adolfo Silva Arias

Muhammad Ramzan Khan

Affiliations

Soon will be listed here.

Abstract

Nucleotide-binding leucine-rich-repeat receptors (NLR), the largest group of genes associated with plant disease resistance (R), have attracted attention due to their crucial role in protecting plants from pathogens. Genome-wide studies of NLRs have revealed conserved domains in the annotated tomato genome. The 321 genes identified in the tomato genome have been randomly mapped to 12 chromosomes. Phylogenetic analysis and classification of NLRs have revealed that 211 genes share full-length domains categorized into three major clades (CNL, TNL, and RNL); the remaining 110 NLRs share partial domains and are classified in CN, TN, and N according to their motifs and gene structures. The cis-regulatory elements of NLRs exhibit the maximum number of these elements and are involved in response to biotic and abiotic stresses, pathogen recognition, and resistance. Analysis of the phylogenetic relationship between tomato NLRs and orthologs in other species has shown conservation among Solanaceae members and variation with . Synteny and Ka/Ks analyses of and orthologs have underscored the importance of conservation and diversification from ancestral species millions of years ago. RNA-seq data and qPCR analysis of early and late blight diseases in tomatoes revealed consistent expression patterns, including upregulation in infected compared to control plants (with some exceptions), suggesting the role of NLRs as key regulators in early blight resistance. Moreover, the expression levels of NLRs associated with late blight resistance ( and ) suggested that they regulate resistance to . These findings provide important fundamental knowledge for understanding evolution and diversity and will empower the broader characterization of disease resistance genes for pyramiding through speed cloning to develop disease-tolerant varieties.

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