核桃n -乙酰5 -羟色胺甲基转移酶基因家族全基因组鉴定及花芽发育过程中多种功能的表征

IF 6.6 2区 环境科学与生态学 Q1 ENVIRONMENTAL SCIENCES Current Opinion in Environmental Sustainability Pub Date : 2022-04-15 eCollection Date: 2022-01-01 DOI:10.3389/fpls.2022.861043
Kai Ma, Ruiqiang Xu, Yu Zhao, Liqun Han, Yuhui Xu, Lili Li, Juan Wang, Ning Li
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引用次数: 0

摘要

褪黑素作为一种重要的生长刺激因子、应激保护因子和发育调节剂,广泛介导植物的多种发育动态。N-乙酰5-羟色胺甲基转移酶(ASMT)是催化植物褪黑素生物合成的最后一步的关键酶,在植物褪黑素调节网络中发挥着重要作用。ASMT的研究有助于理解植物褪黑素生物合成的机制。然而,AMST基因目前在大多数植物中是不具特征的。在这项研究中,我们利用生物信息学对富含褪黑素的植物核桃中的JrASMT基因家族进行了表征。还进行了系统发育、基因结构、保守基序、启动子元件、相互作用蛋白和miRNA分析。ASMT家族的扩展和分化发生在植物地化开始之前。ASMT基因在双子叶植物中分化较多。46个ASMT基因在核桃的10条染色体上呈簇状分布。四个JrASMT基因在核桃内部和种间均具有同源关系。Cis调控元件表明,JrASMT主要由光和激素诱导,靶向切割miRNA172和miR399可能是抑制JrASMT表达的重要途径。转录组数据显示,13个JrASMT在核桃芽发育的不同时期有差异表达。WGCNA表明,JrASMT1/10/13/23与调控细胞命运和表观遗传学修饰的基因在核桃雌花蕾早期生理分化过程中共表达。JrASMT12/28/37/40在核桃花蕾形态分化过程中高表达,与核桃花蕾胁迫能力的改变有关,并被预测参与核桃脱落酸、水杨酸和细胞分裂素的调控网络。qRT-PCR验证了差异表达分析的结果,进一步提供了三个在核桃花蕾发育中具有不同表达谱的JrASMT基因。本研究探讨了植物ASMT基因家族的进化关系和核桃JrASMT的功能特征。它为进一步了解褪黑素在植物发育调控中的复杂机制提供了有价值的视角。
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Walnut N-Acetylserotonin Methyltransferase Gene Family Genome-Wide Identification and Diverse Functions Characterization During Flower Bud Development.

Melatonin widely mediates multiple developmental dynamics in plants as a vital growth stimulator, stress protector, and developmental regulator. N-acetylserotonin methyltransferase (ASMT) is the key enzyme that catalyzes the final step of melatonin biosynthesis in plants and plays an essential role in the plant melatonin regulatory network. Studies of ASMT have contributed to understanding the mechanism of melatonin biosynthesis in plants. However, AMST gene is currently uncharacterized in most plants. In this study, we characterized the JrASMT gene family using bioinformatics in a melatonin-rich plant, walnut. Phylogenetic, gene structure, conserved motifs, promoter elements, interacting proteins and miRNA analyses were also performed. The expansion and differentiation of the ASMT family occurred before the onset of the plant terrestrialization. ASMT genes were more differentiated in dicotyledonous plants. Forty-six ASMT genes were distributed in clusters on 10 chromosomes of walnut. Four JrASMT genes had homologous relationships both within walnut and between species. Cis-regulatory elements showed that JrASMT was mainly induced by light and hormones, and targeted cleavage of miRNA172 and miR399 may be an important pathway to suppress JrASMT expression. Transcriptome data showed that 13 JrASMT were differentially expressed at different periods of walnut bud development. WGCNA showed that JrASMT1/10/13/23 were coexpressed with genes regulating cell fate and epigenetic modifications during early physiological differentiation of walnut female flower buds. JrASMT12/28/37/40 were highly expressed during morphological differentiation of flower buds, associated with altered stress capacity of walnut flower buds, and predicted to be involved in the regulatory network of abscisic acid, salicylic acid, and cytokinin in walnut. The qRT-PCR validated the results of differential expression analysis and further provided three JrASMT genes with different expression profiles in walnut flower bud development. Our study explored the evolutionary relationships of the plant ASMT gene family and the functional characteristics of walnut JrASMT. It provides a valuable perspective for further understanding the complex melatonin mechanisms in plant developmental regulation.

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来源期刊
Current Opinion in Environmental Sustainability
Current Opinion in Environmental Sustainability ENVIRONMENTAL SCIENCES-ENVIRONMENTAL SCIENCES
CiteScore
13.80
自引率
2.80%
发文量
52
审稿时长
6-12 weeks
期刊介绍: "Current Opinion in Environmental Sustainability (COSUST)" is a distinguished journal within Elsevier's esteemed scientific publishing portfolio, known for its dedication to high-quality, reproducible research. Launched in 2010, COSUST is a part of the Current Opinion and Research (CO+RE) suite, which is recognized for its editorial excellence and global impact. The journal specializes in peer-reviewed, concise, and timely short reviews that provide a synthesis of recent literature, emerging topics, innovations, and perspectives in the field of environmental sustainability.
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