Effective Strategies for Enhancing Tolerance to High-Temperature Stress in Rice during the Reproductive and Ripening Stages

Temperatures that extend beyond normal levels of tolerance cause severe stress to plants, especially during thereproductive and grain filling/ripening stages. Heat stress leads to serious yield losses in many crop plants, including rice (Oryzasativa). In view of the current scenario of global climate change, frequent fluctuations and a significant increase in average temperatureswill pose challenges to protecting those yields. Therefore, elucidating the molecular mechanisms that make crop plants more tolerant ofheat, particularly in organs at the reproductive stage, is of utmost importance. Precise molecular information will be helpful for themanipulation and exploration of relevant genes for use in crop improvement programs. In this review, we highlight recent progress inresearch on the molecular responses to high temperatures in pollen and seed and provide a perspective on the development of heattolerance in rice cultivars. The responsible mechanism is a very complex phenomenon that involves several biochemical andphysiological changes, molecular responses, and a series of signal transductions. Improving our understanding requires detailedknowledge at various omics levels. Recent technological advancements have accelerated genomics, transcriptomics, and proteomicsstudies in rice, a model crop plant. Here, we discuss those technological and omics approaches being taken to investigate the heattolerance mechanism, particularly in rice. In addition, we address the tools being used to identify key genes and QTLs that can then beutilized for molecular breeding and biotechnology. KCI Citation Count: 0