A QTL on the Short Arm of Wheat (Triticum Aestivum L.) Chromosome 3B Affects the Stability of Grain Weight in Plants Exposed to a Brief Heat Shock Early in Grain Filling

Overview

Journal BMC Plant Biol

Publisher Biomed Central

Specialty Biology

Date 2016 Apr 23

PMID 27101979

Citations 27

Authors

Hamid Shirdelmoghanloo

Julian D Taylor

Iman Lohraseb

Huwaida Rabie

Chris Brien

Andy Timmins

Peter Martin

Diane E Mather

Livinus Emebiri

Nicholas C Collins

Affiliations

Soon will be listed here.

Abstract

Background: Molecular markers and knowledge of traits associated with heat tolerance are likely to provide breeders with a more efficient means of selecting wheat varieties able to maintain grain size after heat waves during early grain filling.

Results: A population of 144 doubled haploids derived from a cross between the Australian wheat varieties Drysdale and Waagan was mapped using the wheat Illumina iSelect 9,000 feature single nucleotide polymorphism marker array and used to detect quantitative trait loci for heat tolerance of final single grain weight and related traits. Plants were subjected to a 3 d heat treatment (37 °C/27 °C day/night) in a growth chamber at 10 d after anthesis and trait responses calculated by comparison to untreated control plants. A locus for single grain weight stability was detected on the short arm of chromosome 3B in both winter- and autumn-sown experiments, determining up to 2.5 mg difference in heat-induced single grain weight loss. In one of the experiments, a locus with a weaker effect on grain weight stability was detected on chromosome 6B. Among the traits measured, the rate of flag leaf chlorophyll loss over the course of the heat treatment and reduction in shoot weight due to heat were indicators of loci with significant grain weight tolerance effects, with alleles for grain weight stability also conferring stability of chlorophyll ('stay-green') and shoot weight. Chlorophyll loss during the treatment, requiring only two non-destructive readings to be taken, directly before and after a heat event, may prove convenient for identifying heat tolerant germplasm. These results were consistent with grain filling being limited by assimilate supply from the heat-damaged photosynthetic apparatus, or alternatively, accelerated maturation in the grains that was correlated with leaf senescence responses merely due to common genetic control of senescence responses in the two organs. There was no evidence for a role of mobilized stem reserves (water soluble carbohydrates) in determining grain weight responses.

Conclusions: Molecular markers for the 3B or 6B loci, or the facile measurement of chlorophyll loss over the heat treatment, could be used to assist identification of heat tolerant genotypes for breeding.

Citing Articles

The Genetics and Breeding of Heat Stress Tolerance in Wheat: Advances and Prospects.

Zheng Y, Cai Z, Wang Z, Maruza T, Zhang G Plants (Basel). 2025; 14(2).

PMID: 39861500 PMC: 11768744. DOI: 10.3390/plants14020148.

Effects of Heat Stress during Anthesis and Grain Filling Stages on Some Physiological and Agronomic Traits in Diverse Wheat Genotypes.

Mirosavljevic M, Mikic S, Zupunski V, Abdelhakim L, Trkulja D, Zhou R Plants (Basel). 2024; 13(15).

PMID: 39124201 PMC: 11314375. DOI: 10.3390/plants13152083.

Genome-wide association study for seedling heat tolerance under two temperature conditions in bread wheat (Triticum aestivum L.).

Fu C, Zhou Y, Liu A, Chen R, Yin L, Li C BMC Plant Biol. 2024; 24(1):430.

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Natural variation and genetic loci underlying resistance to grain shattering in standing crop of modern wheat.

Emebiri L, Hildebrand S Mol Genet Genomics. 2023; 298(5):1211-1224.

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Meta-QTLs, ortho-MQTLs, and candidate genes for thermotolerance in wheat ( L.).

Kumar S, Singh V, Saini D, Sharma H, Saripalli G, Kumar S Mol Breed. 2023; 41(11):69.

PMID: 37309361 PMC: 10236124. DOI: 10.1007/s11032-021-01264-7.

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