Identification, validation and candidate gene analysis of major QTL for Supernumerary spikelets in wheat.

BACKGROUND: The number of spikelets per spike is a key trait that affects the yield of bread wheat (Triticum aestivum L.). Identification of the QTL for spikelets per spike and its genetic effects that could be used in molecular assistant breeding in the future. RESULTS: In this study, four recombinant inbred line (RIL) populations were generated and used, having YuPi branching wheat (YP), with Supernumerary Spikelets (SS) phenotype, as a common parent. QTL (QSS.sicau-2 A and QSS.sicau-2D) related to SS trait were mapped on chromosomes 2 A and 2D through bulked segregant exome sequencing (BSE-Seq). Fourteen molecular markers were further developed within the localization interval, and QSS.sicau-2 A was narrowed to 3.0 cM covering 7.6 Mb physical region of the reference genome, explaining 13.7 - 15.9% the phenotypic variance. Similarly, the QSS.sicau-2D was narrowed to 1.8 cM covering 2.4 Mb physical region of the reference genome, and it explained 27.4 - 32.9% the phenotypic variance. These two QTL were validated in three different genetic backgrounds using the linked markers. QSS.sicau-2 A was identified as WFZP-A, and QSS.sicau-2D was identified a novel locus, different to the previously identified WFZP-D. Based on the gene expression patterns, gene annotation and sequence analysis, TraesCS2D03G0260700 was predicted to be a potential candidate gene for QSS.sicau-2D. CONCLUSION: Two significant QTL for SS, namely QSS.sicau-2 A and QSS.sicau-2D were identified in multiple environments were identified and their effect in diverse genetic populations was assessed. QSS.sicau-2D is a novel QTL associated with the SS trait, with TraesCS2D03G0260700 predicted as its candidate gene.

Identification and Genome-Wide Association Analysis for Fusarium Crown Rot Resistance in Wheat.

Fusarium crown rot (FCR) is a fungal disease and severely decreases wheat production worldwide. Tibetan semiwild wheat, Yunnan hulled wheat, Xinjiang rice wheat, and Sichuan white wheat are four subspecies landraces endemic to western China and have rich genetic diversity in response to biotic and abiotic stresses. Here, a natural population, including 209 wheat accessions of four subspecies, was evaluated for FCR resistance. he genome-wide association study was performed using the wheat 55K single-nucleotide polymorphisms (SNPs). The results showed that the disease index (DI) ranged from 16.88 to 85.00, while six accessions showed moderate to high resistance (DI ≤ 30). Genome-wide association analysis identified 10 stable loci for FCR resistance on chromosomes 1B, 2A (5), 5A, 7A, 7B, and 7D. Four major loci-Qfcr.sicau.2A-1, Qfcr.sicau.2A-3, Qfcr.sicau.5A, and Qfcr.sicau.7D-explained 6.01 to 14.48, 9.76 to 13.11, 8.19 to 10.29, and 5.76 to 12.21% phenotypic variation, respectively. Quantitative trait loci (QTL) pyramiding analysis of these four major loci revealed that accessions with four resistance haplotypes could significantly decrease FCR severity by 9.35 to 31.61% compared with those without or with one to three resistance haplotypes. One kompetitive allele-specific PCR (KASP) marker each was successfully developed for Qfcr.sicau.2A-1 and Qfcr.sicau.7D. The KASP marker of Qfcr.sicau.2A-1 was used to genotype in an F6 recombinant inbred line population. The result showed that the lines carrying the resistance allele reduced FCR severity by 17.78%, demonstrating the importance of Qfcr.sicau.2A-1 in resistance breeding programs. Our findings provide valuable QTL and breeder-friendly PCR-based markers for applications in FCR resistance breeding programs. Our study also proved that gene pyramiding of major loci could enhance FCR resistance.