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GNI-A1 mediates trade-off between grain number and grain weight in tetraploid wheat

Author:
Golan, Guy, Ayalon, Idan, Perry, Aviad, Zimran, Gil, Ade-Ajayi, Toluwanimi, Mosquna, Assaf, Distelfeld, Assaf, Peleg, Zvi
Source:
Theoretical and applied genetics 2019 v.132 no.8 pp. 2353-2365
ISSN:
0040-5752
Subject:
Triticum turgidum subsp. dicoccoides, alleles, durum wheat, florets, gene pool, grain yield, introgression, mutation, quantitative trait loci, spikelets, tetraploidy, transactivators, yield components
Abstract:
KEY MESSAGE: Wild emmer allele of GNI-A1 ease competition among developing grains through the suppression of floret fertility and increase grain weight in tetraploid wheat. Grain yield is a highly polygenic trait determined by the number of grains per unit area, as well as by grain weight. In wheat, grain number and grain weight are usually negatively correlated. Yet, the genetic basis underlying trade-off between the two is mostly unknown. Here, we fine-mapped a grain weight QTL using wild emmer introgressions in a durum wheat background and showed that grain weight is associated with the GNI-A1 gene, a regulator of floret fertility. In-depth characterization of grain number and grain weight indicated that suppression of distal florets by the wild emmer GNI-A1 allele increases weight of proximal grains in basal and central spikelets due to alteration in assimilate distribution. Re-sequencing of GNI-A1 in tetraploid wheat demonstrated the rich allelic repertoire of the wild emmer gene pool, including a rare allele which was present in two gene copies and contained a nonsynonymous mutation in the C-terminus of the protein. Using an F₂ population generated from a cross between wild emmer accessions Zavitan, which carries the rare allele, and TTD140, we demonstrated that this unique polymorphism is associated with grain weight, independent of grain number. Moreover, we showed, for the first time, that GNI-A1 proteins are transcriptional activators and that selection targeted compromised activity of the protein. Our findings expand the knowledge of the genetic basis underlying trade-off between key yield components and may contribute to breeding efforts for enhanced grain yield.
Agid:
6536024