In silico analysis of the LRR receptor-like serine threonine kinases subfamily in Morus notabilis

Q3 Agricultural and Biological Sciences

Plant Omics Pub Date : 2016-09-20 DOI:10.21475/POJ.09.05.16.PNE126

A. Zambounis, Fotis Psomopoulos, Ioannis Ganopoulos, E. Avramidou, F. Aravanopoulos, A. Tsaftaris, P. Madesis

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引用次数: 4

Abstract

Mulberries are important trees crops for orchards and agroforestry systems, which are plagued by many phytopathogenic fungal species. Leucine rich repeats (LRRs) receptor-like serine threonine kinases (LRR-RSTK) subfamily plays an important role in plant defense-related reactions against fungal attacks. In the present study, we mined this subfamily on Morus notabilis, a mulberry species whose relevant annotated genome assembly has recently become publicly available. Our aim was to decipher in silico the expansion and phylogeny of these genes, their homology relationships against their orthologous in woody angiosperm plant species, and the existence of positive selective pressures acting upon their LRRs. This subfamily was found to be quite abundant and diverged, comprising by 142 annotated gene members and containing a range of conserved functional domains in their C-termini, whilst their LRRs number ranged from one to 17 repeats. A phylogenetic investigation revealed 12 distinct clades based on their diverse structural profiles, mainly as a result of the fused functional domains at their C-termini. The interspecific expansion of these M. notabilis LRR-RSTKs has been investigated by a homology analysis across 12 other woody angiosperm species, showing that the highest proportion of homologous best BLAST hits observed primarily in Prunus persica, Malus domestica and Theobroma cacao. Using a series of maximum likelihood analyses, extensive episodes of positive selective pressures acting across the LRRs were observed. This overall evidence supports a potential crucial role of this diverged LRR-RSTK subfamily as a surveillance mechanism of M. notabilis against fungal attacks by providing rapidly evolving ligand-binding specificities.

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桑树LRR受体样丝氨酸苏氨酸激酶亚家族的计算机分析

桑葚是果园和农林复合系统中重要的乔木作物，受到许多植物病原真菌种类的困扰。富亮氨酸重复序列(LRRs)受体样丝氨酸苏氨酸激酶(LRR-RSTK)亚家族在植物抵抗真菌攻击的防御反应中起重要作用。在本研究中，我们在桑树种桑(Morus notabilis)上挖掘了这个亚科，该物种的相关注释基因组组装最近已经公开。我们的目的是破译这些基因的扩展和系统发育，它们与木本被子植物物种中同源基因的同源关系，以及作用于它们的lrr的正选择压力的存在。该亚家族非常丰富且分化，由142个带注释的基因成员组成，在其c端含有一系列保守的功能域，而其lrr数在1到17个重复之间。一项系统发育调查显示，基于它们不同的结构特征，12个不同的分支主要是由于它们的c端融合了功能域。通过对其他12种木本植物的同源性分析，研究了M. notabilis LRR-RSTKs的种间扩展，结果表明，在桃李(Prunus persica)、家槐(Malus domestica)和可可(Theobroma可可)中，同源最佳BLAST命中比例最高。使用一系列最大似然分析，观察到广泛的正选择压力作用于lrr。这一总体证据支持了LRR-RSTK亚家族的潜在关键作用，通过提供快速进化的配体结合特异性，作为M. notabilis抵抗真菌攻击的监测机制。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Plant Omics 生物-植物科学

CiteScore

1.30

自引率

0.00%

发文量

审稿时长

6 months

期刊介绍： Plant OMICS is an international, peer-reviewed publication that gathers and disseminates fundamental and applied knowledge in almost all area of molecular plant and animal biology, particularly OMICS-es including: Coverage extends to the most corners of plant and animal biology, including molecular biology, genetics, functional and non-functional molecular breeding and physiology, developmental biology, and new technologies such as vaccines. This journal also covers the combination of many areas of molecular plant and animal biology. Plant Omics is also exteremely interested in molecular aspects of stress biology in plants and animals, including molecular physiology.