外源GA3影响牡丹花芽DNA甲基化水平和 相关酶基因的表达分析

doi:10.3864/j.issn.0578-1752.2018.18.012

摘要/Abstract

摘要：

【目的】外施赤霉素（GA）是生产上辅助解除牡丹花芽休眠进行反季节盆花生产的常用手段,赤霉素如何发挥作用解除牡丹花芽休眠是未解的科学问题,本文旨在明确赤霉素是否通过表观遗传方式参与内休眠调控。【方法】从DNA甲基化入手,以4年生‘鲁菏红’为材料,500 mg·L^-1的GA₃处理花芽,并在处理后0.5、1、3和5 d后取健壮顶芽,CTAB法提取花芽DNA,HPLC技术测定GA₃处理后牡丹花芽DNA甲基化水平的变化;利用转录组分析结合RACE技术得到牡丹3种DNA甲基转移酶基因PsCMT、PsMET、PsDRM和DNA去甲基化酶基因PsROS1的序列,生物信息学方法比对基因序列并分析可能的结构域,MEGA 5.0构建系统发育树;以Actin为内参,利用qPCR方法分析其组织表达特性和对GA₃的响应。【结果】3种DNA甲基转移酶基因（Dnmts）的开放阅读框长短不一,PsCMT、PsMET、PsDRM开放阅读框长度分别为1 118、1 056、2 175 bp,编码的氨基酸数目分别为372、351、724。3种DNA甲基转移酶均有甲基转移酶结构域。而DNA去甲基化酶基因PsROS1的序列较长,开放阅读框为6 636 bp,编码2 211个氨基酸。PsROS1上存在保守的DNA糖基化结构域。系统发育分析表明,牡丹中的PsCMT和PsDRM蛋白与葡萄的VvCMT2蛋白亲缘关系最近,PsMET和PsROS1与大部分木本植物聚为一支,与烟草等距离较远。PsCMT、PsMET、PsDRM在牡丹初花期的各个组织（根、茎、叶、苞片、萼片、花瓣、雄蕊、心皮）中均有表达,其中在牡丹根中表达量较高,而PsROS1在心皮中表达量最高。GA₃处理5 d,牡丹花芽迅速萌动,60 d时萌动率为97.5%,成花率为92.5%;对照20 d时才有少量花芽萌动,至60 d时萌动率仅为23.1%。GA₃显著降低了牡丹花芽DNA甲基化水平（P<0.01）,从处理前的38.9%降至处理5 d时的28.7%;GA₃处理提高了PsCMT和PsROS1的表达水平,降低了PsDRM的表达水平,而PsMET的表达水平差异不显著。【结论】GA₃处理通过诱导PsROS1表达、抑制PsDRM表达导致了DNA低甲基化,进而促进了牡丹休眠解除,可能是赤霉素发挥作用的一种重要方式。

关键词: 牡丹, DNA甲基转移酶, PsROS1, 赤霉素, DNA甲基化, 休眠解除

Abstract:

【Objective】 Application of exogenous gibberellin (GA) is a commonly method to break floral bud dormancy in the anti-season production of tree peony. However, the mechanism of how gibberellin plays a role in breaking dormancy of tree peony is an unsolved problem. The objective of this study is to clarify whether GA participates in dormancy regulation through epigenetic mode. 【Method】 In this study, 4-year-old ‘Luhehong’ was used as material, and 500 mg·L^-1exogenous GA₃was applied. Terminal buds were harvested and DNA was extracted at 0.5, 1, 3 and 5 d after GA₃applied. The DNA of peony floral buds was extracted using CTAB method and DNA methylation level of floral buds was analyzed by HPLC technology. Three types of DNA methyltransferase genes, PsCMT, PsMET and PsDRM, and one DNA demethylase gene PsROS1 were obtained using RACE amplification based on transcriptome analysis. Bioinformatics method was performed to analyze gene sequences and possible domains, and MEGA 5.0 was used to construct phylogenetic tree. Using Actin as reference gene, the tissue expression characteristics and response to GA₃ of these genes were analyzed by qPCR method. 【Result】The open reading frame (ORF) of the three DNA methyltransferases (Dnmts) varies in length. The ORF length of PsCMT, PsMET and PsDRM is 1 118, 1 056 and 2 175 bp, respectively. The number of amino acids encoded is 372, 351 and 724, respectively. All three DNA methyltransferases have methyltransferase domains. The DNA demethylase gene PsROS1 has a long sequence with an ORF of 6 636 bp and encodes 2 211 amino acids, and there is a conserved DNA glycosylation domain in PsROS1. Phylogenetic analysis indicated that the PsCMT and PsDRM proteins in peony were closely related to the VvCMT2 protein of grape, PsMET and PsROS1 were grouped with most woody plants and located far away from tobacco. PsCMT, PsMET and PsDRM were expressed in all tissues (roots, stems, leaves, bracts, sepals, petals, stamens, carpels) at the early flowering stage of peony, and the expression level of PsCMT, PsMET and PsDRM was higher in the root of peony than that of other tissues, while the expression level of PsROS1 was the highest in carpels. Application of GA₃ dramatically accelerated buds sprouting and flowering. Bud sprouting could be observed 5 d after GA₃application, and the germinating rate of bud was 97.5% with a 92.5% flowering rate after 60 d of GA₃application. But in the control group, only a few buds germinated at 20 d, and the germinating rate was only 23.1% at 60 d. GA₃significantly decreased the DNA methylation level of peony bud (P<0.01), from 38.9% before treatment to 28.7% at 5 d after treatment. GA₃ treatment increased the expression of PsCMT and PsROS1, decreased the expression level of PsDRM, but there was no significant difference in PsMET expression. 【Conclusion】GA₃ treatment induces PsROS1 expression and inhibits PsDRM expression, which leads to DNA hypomethylation and thus promotes dormancy release of peony, which may be an important way for gibberellin to play its role.

Key words: Paeonia suffruticosa, DNA methyltransferase, PsROS1, gibberellin, DNA methylation, dormancy release

张涛, 司福会, 张玉喜, 盖树鹏. 外源GA₃影响牡丹花芽DNA甲基化水平和相关酶基因的表达分析[J]. 中国农业科学, 2018, 51(18): 3561-3569.

Tao ZHANG, FuHui SI, YuXi ZHANG, ShuPeng GAI. Effect of Exogenous Gibberellin on DNA Methylation Level and Expression of Related Enzyme Genes in Tree Peony Floral Buds[J]. Scientia Agricultura Sinica, 2018, 51(18): 3561-3569.

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引物名称Primers name	引物序列Primers sequence (5′-3′)	用途Purpose
PsMET 5′	GCCAGTACCCTTCACGTATCGATAATAAC	RACE
PsCMT 5′	GATTCATTCCTGATTTGGGTTTCTGG	RACE
ActinF	GAGAGATTCCGTTGCCCTGA	qPCR
ActinR	CTCAGGAGGAGCAACCACC	qPCR
PsMBD5F	CGACAAGAACAATAACATAGGC	qPCR
PsMBD5R	GGTGGTCCCTTTGAGTTGTC	qPCR
PsMETF	GCTGCTTTGTACTCCAGGCCC	qPCR
PsMETR	CTGGTGGCATTCAAGAAGTCG	qPCR
PsCMTF	TTGAATCAGGGAGTGGTAATGTG	qPCR
PsCMTR	TTCTTCGCCGACCCTGTTG	qPCR
PsDRMF	GAGTTTAGAGTTCCCAAGCGAG	qPCR
PsDRMR	GCTCTCATCCTTTCCGTCATC	qPCR
PsROS1F	CAACAACTCCGACGCCAGATGCT	qPCR
PsROS1R	CTCTACTTCAGCATCTGGCGT	qPCR

外源GA₃影响牡丹花芽DNA甲基化水平和相关酶基因的表达分析

Effect of Exogenous Gibberellin on DNA Methylation Level and Expression of Related Enzyme Genes in Tree Peony Floral Buds

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