High Temperatures Cause Male Sterility in Rice Plants with Transcriptional Alterations During Pollen Development

Overview

Journal Plant Cell Physiol

Publisher Oxford University Press

Specialties Biology
Cell Biology

Date 2009 Oct 8

PMID 19808807

Citations 99

Authors

Makoto Endo

Tohru Tsuchiya

Kazuki Hamada

Shingo Kawamura

Kentaro Yano

Masahiro Ohshima

Atsushi Higashitani

Masao Watanabe

Makiko Kawagishi-Kobayashi

Affiliations

Soon will be listed here.

Abstract

Plant male reproductive development is highly organized and sensitive to various environmental stressors, including high temperature. We have established an experimental procedure to evaluate high temperature injury in japonica rice plants. High temperature treatment (39 degrees C/30 degrees C) starting at the microspore stage repeatedly reduced spikelet fertility in our system. Morphological observations revealed that pollen viability in plants exposed to high temperatures was lower than that in control plants. Most pollen grains in high temperature-treated plants displayed a normal round shape and stained reddish purple with Alexander's reagent; however, the pollen grains were very poorly attached and displayed limited germination on the stigma. To investigate gene regulatory mechanisms in the anther in high temperature environments, DNA microarray analysis was performed by comparing non-treated samples with samples treated with 2-4 d of high heat. Genes responsive to high temperatures were identified from clustering of microarray data. Among these, at least 13 were designated as high temperature-repressed genes in the anther. Expression analyses revealed that these genes were expressed specifically in the immature anther mainly in the tapetum at the microspore stage and down-regulated after 1 d of high temperature. The expression levels of Osc6, OsRAFTIN and TDR, which are tapetum-specific genes, were unaffected by high temperatures. These results suggest that not all tapetal genes are inhibited by increased temperatures and the tapetum itself is not degraded in such an environment. However, high temperatures may disrupt some of the tapetum functions required for pollen adhesion and germination on the stigma.

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