Panicle transcriptome of high-yield mutant indica rice reveals physiological mechanisms and novel candidate regulatory genes for yield under reproductive stage drought stress.

BACKGROUND: Reproductive stage drought stress (RDS) is a major global threat to rice production. Due to climate change, water scarcity is becoming an increasingly common phenomenon in major rice-growing areas worldwide. Understanding RDS mechanisms will allow candidate gene identification to generate novel rice genotypes tolerant to RDS. RESULTS: To generate novel rice genotypes that can sustain yield under RDS, we performed gamma-irradiation mediated mutation breeding in the drought stress susceptible mega rice variety, MTU1010. One of the mutant MM11 (MTU1010 derived mutant11) shows consistently increased performance in yield-related traits under field conditions consecutively for four generations. In addition, compared to MTU1010, the yield of MM11 is sustained in prolonged drought imposed during the reproductive stage under field and in pot culture conditions. A comparative emerged panicle transcriptome analysis of the MTU1010 and MM11 suggested metabolic adjustment, enhanced photosynthetic ability, and hormone interplay in regulating yield under drought responses during emerged panicle development. Regulatory network analysis revealed few putative significant transcription factor (TF)-target interactions involved in integrated signalling between panicle development, yield and drought stress. CONCLUSIONS: A gamma-irradiate rice mutant MM11 was identified by mutation breeding, and it showed higher potential to sustain yield under reproductive stage drought stress in field and pot culture conditions. Further, a comparative panicle transcriptome revealed significant biological processes and molecular regulators involved in emerged panicle development, yield and drought stress integration. The study extends our understanding of the physiological mechanisms and candidate genes involved in sustaining yield under drought stress.

Characterization of AKR4C15, a Novel Member of Aldo-Keto Reductase, in Comparison with Other Rice AKR(s).

Environmental stresses often cause a rapid and excessive accumulation of reactive oxygen species (ROS), the toxicity of which is further amplified by downstream aldehyde production. Aldo-keto reductase (AKR) is a group of enzymes metabolizing aldehyde/ketone to the corresponding alcohol using NADPH as the cofactor. In this study, OsI_20197 (AKR4C15), a novel member of AKR4 subfamily C, was isolated and biochemically characterized. Kinetic studies on bacterially-expressed recombinant AKR4C15 revealed that the enzyme was capable of metabolizing a wide variety of aldehydes but clearly exhibited a preference for three carbon compounds, i.e. methylglyoxal, malondialdehyde and glyceraldehyde. In comparison with His-tagged proteins of AKR4C9 from Arabidopsis and several other rice AKR(s): OsI_04426, OsI_04428, OsI_04429, and OsI_15387, AKR4C15 was the one capable of most efficiently metabolizing MDA and had the highest value of catalytic efficiency, which was higher than the value of AKR4C9, approximately, by 30-fold; while its capability of metabolizing MG was on par with AKR4C9, OsI_04426 and OsI_04428 (AKR4C14); and was considerably higher than the activity of OsI_04429 and OsI_15387. In vivo research on transgenic Arabidopsis seedlings ectopically-expressing AKR4C15 showed that the levels of both MDA and MG were also significantly lower than the levels in wild-type seedlings under both normal and stress conditions, emphasizing the role of AKR4C15 in MG and MDA metabolism. In conclusion, AKR4C15, together with OsI_04426 and AKR4C14, may play protective roles against small reactive aldehydes and medium-chain aldehydes.