Abstract
SummaryThe enhancement of heat stress tolerance in crops is an important challenge for food security to facilitate adaptation to global warming. In Arabidopsis thaliana, the transcriptional regulator DNA polymerase II subunit B3‐1 (DPB3‐1)/nuclear factor Y subunit C10 (NF‐YC10) has been reported as a positive regulator of Dehydration‐responsive element binding protein 2A (DREB2A), and the overexpression of DPB3‐1 enhances heat stress tolerance without growth retardation. Here, we show that DPB3‐1 interacts with DREB2A homologues in rice and soya bean. Transactivation analyses with Arabidopsis and rice mesophyll protoplasts indicate that DPB3‐1 and its rice homologue OsDPB3‐2 function as positive regulators of DREB2A homologues. Overexpression of DPB3‐1 did not affect plant growth or yield in rice under nonstress conditions. Moreover, DPB3‐1‐overexpressing rice showed enhanced heat stress tolerance. Microarray analysis revealed that many heat stress‐inducible genes were up‐regulated in DPB3‐1‐overexpressing rice under heat stress conditions. However, the overexpression of DPB3‐1 using a constitutive promoter had almost no effect on the expression of these genes under nonstress conditions. This may be because DPB3‐1 is a coactivator and thus lacks inherent transcriptional activity. We conclude that DPB3‐1, a coactivator that functions specifically under abiotic stress conditions, could be utilized to increase heat stress tolerance in crops without negative effects on vegetative and reproductive growth.
Highlights
There is increasing evidence of global warming, and it has been reported that the increased temperature will have negative effects on crop yields during the 21st century (Intergovernmental Panel on Climate Change, Working Group II, 2014)
Arabidopsis DNA polymerase II subunit B3-1 (DPB3-1) interacts with Dehydration-responsive element binding protein 2A (DREB2A) homologues in rice and soya bean
We reported that DPB3-1 interacts with the N-terminal region of DREB2A and functions as a positive regulator of DREB2A under heat stress conditions (Sato et al, 2014)
Summary
There is increasing evidence of global warming, and it has been reported that the increased temperature will have negative effects on crop yields during the 21st century (Intergovernmental Panel on Climate Change, Working Group II, 2014). Many previous studies have reported the negative effects of heat stress on plant growth and reproduction at physiological and molecular levels. Several studies have reported that high temperature (28– 30 °C) induces stem elongation or leaf elevation in some plants, such as Arabidopsis thaliana and potato; this results in a decrease in total biomass or yield (Foreman et al, 2011; Patel and Franklin, 2009; Singh et al, 2013)
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