The NLR-Annotator Tool Enables Annotation of the Intracellular Immune Receptor Repertoire.

Burkhard Steuernagel,Simon G Krattinger,Agnieszka I Witek,Christopher J Ridout,Ricardo H Ramirez-Gonzalez,Beat Keller,Cristobal Uauy,Brande B.H Wulff,Ksenia V Krasileva,Henk-Jan Schoonbeek,Jonathan D.G Jones,Kamil Witek,Inderjit Yadav,Erin Baggs,Guotai Yu

doi:10.1104/pp.19.01273

Abstract

Disease resistance genes encoding nucleotide-binding and leucine-rich repeat (NLR) intracellular immune receptor proteins detect pathogens by the presence of pathogen effectors. Plant genomes typically contain hundreds of NLR-encoding genes. The availability of the hexaploid wheat (Triticum aestivum) cultivar Chinese Spring reference genome allows a detailed study of its NLR complement. However, low NLR expression and high intrafamily sequence homology hinder their accurate annotation. Here, we developed NLR-Annotator, a software tool for in silico NLR identification independent of transcript support. Although developed for wheat, we demonstrate the universal applicability of NLR-Annotator across diverse plant taxa. We applied our tool to wheat and combined it with a transcript-validated subset of genes from the reference gene annotation to characterize the structure, phylogeny, and expression profile of the NLR gene family. We detected 3,400 full-length NLR loci, of which 1,560 were confirmed as expressed genes with intact open reading frames. NLRs with integrated domains mostly group in specific subclades. Members of another subclade predominantly locate in close physical proximity to NLRs carrying integrated domains, suggesting a paired helper function. Most NLRs (88%) display low basal expression (in the lower 10 percentile of transcripts). In young leaves subjected to biotic stress, we found up-regulation of 266 of the NLRs To illustrate the utility of our tool for the positional cloning of resistance genes, we estimated the number of NLR genes within the intervals of mapped rust resistance genes. Our study will support the identification of functional resistance genes in wheat to accelerate the breeding and engineering of disease-resistant varieties.

Highlights

Disease resistance genes encoding nucleotide-binding and leucine-rich repeat (NLR) intracellular immune receptor proteins detect pathogens by the presence of pathogen effectors
Heritable genetic variation for disease resistance is often controlled by dominant Resistance (R) genes encoding intracellular immune receptors with nucleotide-binding and leucine-rich repeat (NLR) domains (Kourelis and van der Hoorn, 2018)
These motifs had been defined based on manual curation of a training set of known NLR sequences by Jupe et al (2012) and mainly resemble the substructures of NLR protein domains described in other studies (Supplemental Fig. S1)

Summary

Introduction

Disease resistance genes encoding nucleotide-binding and leucine-rich repeat (NLR) intracellular immune receptor proteins detect pathogens by the presence of pathogen effectors. We applied our tool to wheat and combined it with a transcript-validated subset of genes from the reference gene annotation to characterize the structure, phylogeny, and expression profile of the NLR gene family. Heritable genetic variation for disease resistance is often controlled by dominant Resistance (R) genes encoding intracellular immune receptors with nucleotide-binding and leucine-rich repeat (NLR) domains (Kourelis and van der Hoorn, 2018). Some NLRs contain an integrated domain, which has been proposed to act as a decoy to the intended effector pathogenicity target (Cesari et al, 2014; Sarris et al, 2016; Baggs et al, 2017)

Methods

Results

Discussion

Conclusion