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最近的基因组重测序揭示了COBRA基因家族在杨树非生物胁迫和木材形成中的作用。

Recent genome resequencing paraded COBRA- gene family roles in abiotic stress and wood formation in Poplar.

作者信息

Sajjad Muhammad, Ahmad Adeel, Riaz Muhammad Waheed, Hussain Quaid, Yasir Muhammad, Lu Meng-Zhu

机构信息

State Key Laboratory of Subtropical Silviculture, College of Forestry and Biotechnology, Zhejiang A & F University, Hangzhou, China.

State Key Laboratory of Cotton Biology, Institute of Cotton Research, Chinese Academy of Agricultural Sciences, Anyang, Henan, China.

出版信息

Front Plant Sci. 2023 Sep 15;14:1242836. doi: 10.3389/fpls.2023.1242836. eCollection 2023.

DOI:10.3389/fpls.2023.1242836
PMID:37780503
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10540467/
Abstract

A cell wall determines the mechanical properties of a cell, serves as a barrier against plant stresses, and allows cell division and growth processes. The COBRA- (COBL) gene family encodes a putative glycosylphosphatidylinositol (GPI)-anchored protein that controls cellulose deposition and cell progression in plants by contributing to the microfibril orientation of a cell wall. Despite being studied in different plant species, there is a dearth of the comprehensive global analysis of COBL genes in poplar. Poplar is employed as a model woody plant to study abiotic stresses and biomass production in tree research. Improved genome resequencing has enabled the comprehensive exploration of the evolution and functional capacities of PtrCOBLs (Poplar COBRA-Like genes) in poplar. Phylogeny analysis has discerned and classified PtrCOBLs into two groups resembling the COBL family, and group I genes possess longer proteins but have fewer exons than group II. Analysis of gene structure and motifs revealed PtrCOBLs maintained a rather stable motif and exon-intron pattern across members of the same group. Synteny and collinearity analyses exhibited that the evolution of the COBL gene family was heavily influenced by gene duplication events. PtrCOBL genes have undergone both segmental duplication and tandem duplication, followed by purifying selection. Promotor analysis flaunted various phytohormone-, growth- and stress-related cis-elements (e.g., MYB, ABA, MeJA, SA, AuxR, and ATBP1). Likewise, 29 Ptr-miRNAs of 20 families were found targeting 11 PtrCOBL genes. PtrCOBLs were found localized at the plasma membrane and extracellular matrix, while gene ontology analysis showed their involvement in plant development, plant growth, stress response, cellulose biosynthesis, and cell wall biogenesis. RNA-seq datasets depicted the bulk of PtrCOBL genes expression being found in plant stem tissues and leaves, rendering mechanical strength and rejoinders to environmental cues. PtrCOBL2, 3, 10, and 11 manifested the highest expression in vasculature and abiotic stress, and resemblant expression trends were upheld by qRT-PCR. Co-expression network analysis identified PtrCOBL2 and PtrCOBL3 as hub genes across all abiotic stresses and wood developing tissues. The current study reports regulating roles of PtrCOBLs in xylem differentiating tissues, tension wood formation, and abiotic stress latency that lay the groundwork for future functional studies of the PtrCOBL genes in poplar breeding.

摘要

细胞壁决定细胞的机械特性,作为抵御植物胁迫的屏障,并支持细胞分裂和生长过程。COBRA-(COBL)基因家族编码一种假定的糖基磷脂酰肌醇(GPI)锚定蛋白,该蛋白通过影响细胞壁微纤丝的排列方向来控制植物中的纤维素沉积和细胞进程。尽管已在不同植物物种中对其进行了研究,但杨树中COBL基因的全面全球分析仍然匮乏。杨树被用作研究树木非生物胁迫和生物量生产的模式木本植物。改进的基因组重测序技术使得对杨树中PtrCOBLs(杨树类COBRA基因)的进化和功能能力进行全面探索成为可能。系统发育分析已识别出PtrCOBLs并将其分为两组,类似于COBL家族,且第一组基因的蛋白质更长,但外显子比第二组少。基因结构和基序分析表明,同一组内的PtrCOBL成员间保持着相当稳定的基序和外显子 - 内含子模式。共线性和同线性分析表明,COBL基因家族的进化受到基因复制事件的严重影响。PtrCOBL基因经历了片段重复和串联重复,随后是纯化选择。启动子分析显示了各种与植物激素、生长和胁迫相关的顺式元件(如MYB、ABA、MeJA、SA、AuxR和ATBP1)。同样,发现20个家族的29个Ptr-miRNA靶向11个PtrCOBL基因。发现PtrCOBLs定位于质膜和细胞外基质,而基因本体分析表明它们参与植物发育、植物生长、胁迫反应、纤维素生物合成和细胞壁生物发生。RNA测序数据集表明,大部分PtrCOBL基因在植物茎组织和叶片中表达,赋予机械强度并响应环境信号。PtrCOBL2、3、10和11在维管系统和非生物胁迫中表现出最高表达,qRT-PCR也支持类似的表达趋势。共表达网络分析确定PtrCOBL2和PtrCOBL3为所有非生物胁迫和木材发育组织中的枢纽基因。本研究报道了PtrCOBLs在木质部分化组织、张力木形成和非生物胁迫潜伏期的调节作用,并为杨树育种中PtrCOBL基因的未来功能研究奠定了基础。

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