Complex Interplay of Tandem, Segmental, Whole Genome Duplication, and Re-organization Drives Expansion of SAUR Gene Family in Brassicaceae.

IF 1.6 4区生物学 Q4 BIOCHEMISTRY & MOLECULAR BIOLOGY

Biochemical Genetics Pub Date : 2025-07-02 DOI:10.1007/s10528-025-11167-3

Richa Shukla, Ekta Pokhriyal, Sandip Das

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引用次数: 0

Abstract

Members of the SAUR, small auxin upregulated RNA, gene family initially identified as auxin inducible, mediate diverse developmental and adaptive processes in plants. Inspite of their importance, identification and analysis of homologs from Brassica juncea, a major oilseed crop, is lacking. Additionally, investigations into organisational complexity and evolutionary past across Brassicaceae remain to be investigated. The present study was therefore designed to identify members of the SAUR gene family in B. juncea, reconstruct phylogenetic relationship, and analyse the history of expansion of the SAUR gene family across Brassicaceae. Genome-wide in-silico analysis allowed us to identify 237 SAUR genes in the allotetraploid B. juncea (AABB genome), which are distributed in a clustered manner among all 18 chromosomes of the B. juncea genome. Comparative analysis with the diploid parents- B. rapa (AA) and B. nigra (BB) revealed conserved organisation pattern. A striking feature of SAUR genes is intronless nature of most members. Comparative analysis revealed ten clusters of tandemly arrayed genes (TAGs) in Arabidopsis thaliana; two of these clusters were lost, and 33 clusters that are orthologous to the rest of A. thaliana clusters were identified from B. juncea genome. Organisational complexity revealed the presence of putative bidirectional promoters between some SAUR genes. Phylogenetic reconstruction shows several SAUR genes of A. thaliana and B. juncea forming separate clades, indicating lineage-specific expansion. Inclusion of homologs from across Brassicaceae allowed us to perform comparative synteny analysis and hypothesize local duplications being responsible for the tandem organisation, and segmental duplications as driving mechanism for large-scale expansion. The present study allowed us to catalog homologs of the SAUR gene family in B. juncea. This study thus forms the foundation for functional characterization involving transcriptional regulation, generation, and analysis of reverse genetic models toward understanding their role in plant growth and development.

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串联、片段、全基因组复制和重组的复杂相互作用推动了十字花科SAUR基因家族的扩展。

SAUR是生长素上调小RNA，最初被确定为生长素诱导基因家族的成员，介导植物的多种发育和适应过程。尽管同源物具有重要的意义，但作为主要油料作物的芥菜同源物的鉴定和分析仍然缺乏。此外，对十字花科组织复杂性和进化历史的调查仍有待调查。因此，本研究旨在鉴定芥菜SAUR基因家族成员，重建系统发育关系，并分析SAUR基因家族在芸苔科植物中的扩展历史。通过全基因组的计算机分析，我们从同种四倍体芥菜（AABB基因组）中鉴定出237个SAUR基因，这些基因以群集的方式分布在芥菜基因组的全部18条染色体中。与二倍体亲本B. rapa （AA）和B. nigra （BB）的比较分析显示其保守的组织模式。SAUR基因的一个显著特征是大多数成员无内含子。比较分析揭示了拟南芥（Arabidopsis thaliana）中10个串联排列的基因簇（tag）；从juncea基因组中鉴定出33个与其他拟南芥簇同源的簇。组织复杂性揭示了一些SAUR基因之间存在假定的双向启动子。系统发育重建显示，拟南芥和芥菜的几个SAUR基因形成了不同的分支，表明谱系特异性扩展。同源物的加入使我们能够进行比较合成分析，并假设局部复制是串联组织的原因，片段复制是大规模扩张的驱动机制。本研究使我们能够对juncea中SAUR基因家族的同源物进行分类。因此，本研究为功能表征奠定了基础，包括转录调控、生成和反向遗传模型分析，以了解它们在植物生长和发育中的作用。

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来源期刊

Biochemical Genetics 生物-生化与分子生物学

CiteScore

3.90

自引率

0.00%

发文量

133

审稿时长

4.8 months

期刊介绍： Biochemical Genetics welcomes original manuscripts that address and test clear scientific hypotheses, are directed to a broad scientific audience, and clearly contribute to the advancement of the field through the use of sound sampling or experimental design, reliable analytical methodologies and robust statistical analyses. Although studies focusing on particular regions and target organisms are welcome, it is not the journal’s goal to publish essentially descriptive studies that provide results with narrow applicability, or are based on very small samples or pseudoreplication. Rather, Biochemical Genetics welcomes review articles that go beyond summarizing previous publications and create added value through the systematic analysis and critique of the current state of knowledge or by conducting meta-analyses. Methodological articles are also within the scope of Biological Genetics, particularly when new laboratory techniques or computational approaches are fully described and thoroughly compared with the existing benchmark methods. Biochemical Genetics welcomes articles on the following topics: Genomics; Proteomics; Population genetics; Phylogenetics; Metagenomics; Microbial genetics; Genetics and evolution of wild and cultivated plants; Animal genetics and evolution; Human genetics and evolution; Genetic disorders; Genetic markers of diseases; Gene technology and therapy; Experimental and analytical methods; Statistical and computational methods.