Map-Based Cloning of Seed Dormancy1-2 Identified a Gibberellin Synthesis Gene Regulating the Development of Endosperm-Imposed Dormancy in Rice.

Natural variation in seed dormancy is controlled by multiple genes mapped as quantitative trait loci in major crop or model plants. This research aimed to clone and characterize the Seed Dormancy1-2 (qSD1-2) locus associated with endosperm-imposed dormancy and plant height in rice (Oryza sativa). qSD1-2 was delimited to a 20-kb region, which contains OsGA20ox2 and had an additive effect on germination. Naturally occurring or induced loss-of-function mutations of the gibberellin (GA) synthesis gene enhanced seed dormancy and also reduced plant height. Expression of this gene in seeds (including endospermic cells) during early development increased GA accumulation to promote tissue morphogenesis and maturation programs. The mutant allele prevalent in semidwarf cultivars reduced the seed GA content by up to 2-fold at the early stage, which decelerated tissue morphogenesis including endosperm cell differentiation, delayed abscisic acid accumulation by a shift in the temporal distribution pattern, and postponed dehydration, physiological maturity, and germinability development. As the endosperm of developing seeds dominates the moisture equilibrium and desiccation status of the embryo in cereal crops, qSD1-2 is proposed to control primary dormancy by a GA-regulated dehydration mechanism. Allelic distribution of OsGA20ox2, the rice Green Revolution gene, was associated with the indica and japonica subspeciation. However, this research provided no evidence that the primitive indica- and common japonica-specific alleles at the presumably domestication-related locus functionally differentiate in plant height and seed dormancy. Thus, the evolutionary mechanism of this agriculturally important gene remains open for discussion.

Quantitative trait locus and haplotype analyses of wild and crop-mimic traits in U.S. weedy rice.

Conspecific weeds retained characteristics from wild ancestors and also developed crop mimicries for adaptation and competitiveness. This research was conducted to identify quantitative trait loci (QTL) associated with the wild and crop-mimic traits and to determine haplotype variants for QTL-rich regions in U.S. weedy rice. An F2 population from the cross between a cultivated (EM93-1) and a U.S. weedy (US1) rice line was evaluated for six wild and eight crop-mimic traits in a greenhouse to identify the QTL. A core collection of 27 U.S. weedy red rice lines and 14 AA-genome wild rice lines were determined for the haplotype variants. A total of 49 QTL were identified, with 45 collocated as clusters on 14 genomic segments. The number of haplotypes across the 14 segments was lower in the weedy (6.1 ± 2.4) than in the wild (7.5 ± 1.8) rice sample. Both samples shared ~50% haplotypes (wild-like). The EM93-1-like haplotypes accounted for a greater proportion (30 ± 26%) of the haplotypes in the weedy than in the wild (7 ± 10%) rice. Based on haplotype patterns for the 14 QTL cluster regions, 26 of the 28 red rice lines were clustered into two groups corresponding to the black-hull awned and straw-hull awnless morphological types, respectively. The QTL analysis demonstrated that conspecific weed-crop differentiation involved many genomic segments with multiple loci regulating natural variation for adaptation and competitiveness. The haplotype analysis revealed that U.S. weedy rice retained large blocks of linkage disequilibrium for the multiple loci from the wild relatives and also incorporated haplotypes from cultivars.