Comprehensive Meta-analysis of QTL and Gene Expression Studies Identify Candidate Genes Associated with Resistance in Maize

Overview

Journal Front Plant Sci

Date 2023 Aug 3

PMID 37534296

Authors

Niranjan Baisakh

Eduardo A Da Silva

Anjan K Pradhan

Kanniah Rajasekaran

Affiliations

Soon will be listed here.

Abstract

Aflatoxin (AF) contamination, caused by , compromises the food safety and marketability of commodities, such as maize, cotton, peanuts, and tree nuts. Multigenic inheritance of AF resistance impedes conventional introgression of resistance traits into high-yielding commercial maize varieties. Several AF resistance-associated quantitative trait loci (QTLs) and markers have been reported from multiple biparental mapping and genome-wide association studies (GWAS) in maize. However, QTLs with large confidence intervals (CI) explaining inconsistent phenotypic variance limit their use in marker-assisted selection. Meta-analysis of published QTLs can identify significant meta-QTLs (MQTLs) with a narrower CI for reliable identification of genes and linked markers for AF resistance. Using 276 out of 356 reported QTLs controlling resistance to infection and AF contamination in maize, we identified 58 MQTLs on all 10 chromosomes with a 66.5% reduction in the average CI. Similarly, a meta-analysis of maize genes differentially expressed in response to (a)biotic stresses from the to-date published literature identified 591 genes putatively responding to only infection, of which 14 were significantly differentially expressed (-1.0 ≤ Log2Fc ≥ 1.0; ≤ 0.05). Eight MQTLs were validated by their colocalization with 14 resistance-associated SNPs identified from GWAS in maize. A total of 15 genes were physically close between the MQTL intervals and SNPs. Assessment of 12 MQTL-linked SSR markers identified three markers that could discriminate 14 and eight cultivars with resistance and susceptible responses, respectively. A comprehensive meta-analysis of QTLs and differentially expressed genes led to the identification of genes and makers for their potential application in marker-assisted breeding of -resistant maize varieties.

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