Transcriptome Analysis of Flowering Time Genes Under Drought Stress in Maize Leaves

Overview

Journal Front Plant Sci

Date 2017 Mar 17

PMID 28298916

Citations 28

Authors

Kitae Song

Hyo Chul Kim

Seungho Shin

Kyung-Hee Kim

Jun-Cheol Moon

Jae Yoon Kim

Byung-Moo Lee

Affiliations

Soon will be listed here.

Abstract

Flowering time is an important factor determining yield and seed quality in maize. A change in flowering time is a strategy used to survive abiotic stresses. Among abiotic stresses, drought can increase anthesis-silking intervals (ASI), resulting in negative effects on maize yield. We have analyzed the correlation between flowering time and drought stress using RNA-seq and bioinformatics tools. Our results identified a total of 619 genes and 126 transcripts whose expression was altered by drought stress in the maize B73 leaves under short-day condition. Among drought responsive genes, we also identified 20 genes involved in flowering times. Gene Ontology (GO) enrichment analysis was used to predict the functions of the drought-responsive genes and transcripts. GO categories related to flowering time included reproduction, flower development, pollen-pistil interaction, and post-embryonic development. Transcript levels of several genes that have previously been shown to affect flowering time, such as , transcription factor , and , were significantly altered by drought conditions. Furthermore, we also identified several drought-responsive transcripts containing CH zinc finger, CCCH, and NAC domains, which are frequently involved in transcriptional regulation and may thus have potential to alter gene expression programs to change maize flowering time. Overall, our results provide a genome-wide analysis of differentially expressed genes (DEGs), novel transcripts, and isoform variants expressed during the reproductive stage of maize plants subjected to drought stress and short-day condition. Further characterization of the drought-responsive transcripts identified in this study has the potential to advance our understanding of the mechanisms that regulate flowering time under drought stress.

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