Molecular regulation mechanism of anther abortion in cotton under high temperature stress

Working group session: 
Functional Genomics
Presentation type: 
poster
Authors: 
Min, Ling; Zhang, Xianlong; Zhu, Longfu; Tu, Lili; Deng, Fenglin; Li, Yaoyao; Hu, Qin ; Yuan, Daojun; Gao, Wenhui; Wu, Yuanlong; Ding, Yuanhao; Liu, Shiming; Yang, Xiyan
Presenter: 
Min, Ling
Correspondent: 
Zhang, Xianlong
Abstract: 
Male reproduction in flowering plants is highly sensitive to high temperature (HT). To investigate molecular mechanisms of the response of cotton anthers to HT, a relatively complete comparative transcriptome analysis was performed during anther development of Gossypium hirsutum ‘84021’ and ‘H05’ under normal temperature and HT. Totally, 4599 differentially expressed genes (DEGs) were screened; the DEGs were mainly related to epigenetic modifications, carbohydrate metabolism, and plant hormone signaling. Detailed studies showed that deficiency in S-ADENOSYL-L-HOMOCYSTEINE HYDROLASE1 (SAHH1) and the inhibition of methyltransferases contributed to genome-wide hypomethylation in ‘H05’, and the increased expression of histone constitution genes contributed to DNA stability in ‘84021’. Furthermore, HT induced expression of CASEIN KINASE I (GhCKI) in ‘H05’, coupled with the suppression of starch synthase activity, decreases in the glucose level during anther development, and increases in the indole-3-acetic acid (IAA) level in late-stage anthers. The same changes also were observed in Arabidopsis GhCKI overexpression lines, and GhCKI activates the accumulation of abscisic acid (ABA) in Arabidopsis buds, thereby disturbing the balance of reactive oxygen species (ROS) and eventually disrupting tapetal PCD, leading to anther abortion or indehiscence. These results suggest that GhCKI, sugar, and auxin may be key regulators of the anther response to HT stress. Moreover, PHYTOCHROME-INTERACTING FACTOR GENES (PIFs), which are involved in linking sugar and auxin and are regulated by sugar, might positively regulate IAA biosynthesis in the cotton anther response to HT. Additionally, exogenous IAA application revealed that high background IAA may be a disadvantage for late-stage cotton anthers during HT stress. Overall, the linking of HT, sugar, PIFs, and IAA, together with our reported data on GhCKI, may provide dynamic coordination of plant anther responses to HT stress.