Characterization and identification of novel reduced height (RHT-1) alleles in wheat

Abstract

Since their introduction in the 1960s, the semi-dwarfing Reduced Height (Rht-1) genes in wheat have been incorporated into the majority of modern wheat varieties. Their popularity has been driven by their positive impact on yield. The two most common semi-dwarfing alleles, Rht-B1b and Rht-D1b, reduce height ~20% and increase yield ~6% compared to tall varieties. Their shorter stature makes them less susceptible to lodging under increased water and nitrogen inputs compared to tall wheat varieties. Despite their prevalence, the exact mechanism by which Rht-B1b/Rht-D1b increase yields is still unknown. Furthermore, very little research has been done to characterize their impact on bread making and end use quality. Finally, beyond Rht-B1b and Rht-D1b, there is very little allelic diversity available to wheat breeders. The objectives of this research were to investigate the impact of Rht-B1b on photosynthesis, characterize the impact of Rht-B1b/Rht-D1b on bread making and dough rheology, and to identify and test novel Rht-1 alleles created using EMS mutagenesis. In regards to photosynthesis: we found Rht-B1b reduces flag leaf photosynthetic rate (18%) and chlorophyll A content (23%) compared to the tall wildtype at anthesis. In regards to end use quality: we found Rht-B1b/Rht-D1b decrease total grain protein content (2%) but increase gluten index (21%), bake mixing time, and bake mixing tolerance compared to the tall lines. Increased gluten index and mixing time in the semi-dwarfing lines was shown to be associated with increased high molecular weight glutenins. In regards to developing novel alleles: we identified three nonsense Rht-1 alleles and characterized their impact on coleoptile length, gibberellin responsiveness, and DELLA/GID1 interaction. Further research will be needed to investigate their impact on agronomic traits and found that each abolished GID1 interaction in the absence but not the presence of Gibberellic acid. Overall this dissertation provides new insight on the impact of the semi-dwarfing alleles on wheat growth and development, wheat milling and baking properties and increases the available allelic diversity through the introduction of three new Rht-1 nonsense alleles.