Two-factor ANOVA of SSH and RNA-seq Analysis Reveal Development-associated Pi-starvation Genes in Oilseed Rape

Overview

Journal Planta

Specialty Biology

Date 2019 Jun 6

PMID 31165231

Citations 3

Authors

Zhong-Wei Zhang

Ling-Yang Feng

Jian-Hui Wang

Yu-Fan Fu

Xin Cai

Chang-Quan Wang

Jun-Bo Du

Ming Yuan

Yang-Er Chen

Pei-Zhou Xu

Ting Lan

Guang-Deng Chen

Lin-Tao Wu

Yun Li

Jin-Yao Hu

Shu Yuan

Affiliations

Soon will be listed here.

Abstract

The 5-leaf-stage rape seedlings were more insensitive to Pi starvation than that of the 3-leaf-stage plants, which may be attributed to the higher expression levels of ethylene signaling and sugar-metabolism genes in more mature seedlings. Traditional suppression subtractive hybridization (SSH) and RNA-Seq usually screen out thousands of differentially expressed genes. However, identification of the most important regulators has not been performed to date. Here, we employed two methods, namely, a two-round SSH and two-factor transcriptome analysis derived from the two-factor ANOVA that is commonly used in the statistics, to identify development-associated inorganic phosphate (Pi) starvation-induced genes in Brassica napus. Several of these genes are related to ethylene signaling (such as EIN3, ACO3, ACS8, ERF1A, and ERF2) or sugar metabolism (such as ACC2, GH3, LHCB1.4, XTH4, and SUS2). Although sucrose and ethylene may counteract each other at the biosynthetic level, they may also work synergistically on Pi-starvation-induced gene expression (such as PT1, PT2, RNS1, ACP5, AT4, and IPS1) and root acid phosphatase activation. Furthermore, three new transcription factors that are responsive to Pi starvation were identified: the zinc-finger MYND domain-containing protein 15 (MYND), a Magonashi family protein (MAGO), and a B-box zinc-finger family salt-tolerance protein. This study indicates that the two methods are highly efficient for functional gene screening in non-model organisms.

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