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Sorghum qTGW1a encodes a G-protein subunit and acts as a negative regulator of grain size

Guihua Zou, Guowei Zhai, Song Yan, Sujuan Li, Lengbo Zhou, Yanqing Ding, Heqin Liu, Zhipeng Zhang, Jianqiu Zou, Liyi Zhang, Junping Chen, Zhanguo Xin, Yuezhi Tao

2020Journal of Experimental Botany29 citationsDOIOpen Access PDF

Abstract

Grain size is a major determinant of grain yield in sorghum and other cereals. Over 100 quantitative trait loci (QTLs) of grain size have been identified in sorghum. However, no gene underlying any grain size QTL has been cloned. Here, we describe the fine mapping and cloning of one grain size QTL. From an F8 recombinant inbred line population derived from a cross between inbred lines 654 and LTR108, we identified 44 grain size QTLs. One QTL, qTGW1a, was detected consistently on the long arm of chromosome 1 in the span of 4 years. Using the extreme recombinants from an F2:3 fine-mapping population, qTGW1a was delimited within a ~33 kb region containing three predicted genes. One of them, SORBI_3001G341700, predicted to encode a G-protein γ subunit and homologous to GS3 in rice, is likely to be the causative gene for qTGW1a. qTGW1a appears to act as a negative regulator of grain size in sorghum. The functional allele of the putatively causative gene of qTGW1a from inbred line 654 decreased grain size, plant height, and grain yield in transgenic rice. Identification of the gene underlying qTGW1a advances our understanding of the regulatory mechanisms of grain size in sorghum and provides a target to manipulate grain size through genome editing.

Topics & Concepts

Quantitative trait locusBiologySorghumGeneGeneticsPopulationPositional cloningCandidate geneAlleleGrain sizeInbred strainAgronomyPhenotypeDemographyMetallurgySociologyMaterials scienceGenetic Mapping and Diversity in Plants and AnimalsBioenergy crop production and managementWheat and Barley Genetics and Pathology