面包小麦中多基因家族TaHKT 2;1的特征及其基因成员在植物钠（Na⁺）和钾（K⁺）状态中的作用

Characterization of the multigene family TaHKT 2;1 in bread wheat and the role of gene members in plant Na(+) and K(+) status.

作者信息

Ariyarathna H A Chandima K, Ul-Haq Tanveer, Colmer Timothy D, Francki Michael G

机构信息

State Agricultural Biotechnology Centre, Murdoch University, Murdoch 6150, Western Australia.

出版信息

BMC Plant Biol. 2014 Jun 11;14:159. doi: 10.1186/1471-2229-14-159.

DOI:10.1186/1471-2229-14-159

PMID:24920193

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4079177/

Abstract

BACKGROUND

A member of the TaHKT2;1 multigene family was previously identified as a Na(+) transporter with a possible role in root Na(+) uptake. In the present study, the existing full-length cDNA of this member was used as a basis to query the International Wheat Genome Survey Sequence to identify all members of the TaHKT2;1 family. Individual TaHKT2;1 genes were subsequently studied for gene and predicted protein structures, promoter variability, tissue expression and their role in Na(+) and K(+) status of wheat.

RESULTS

Six TaHKT2;1 genes were characterized which included four functional genes (TaHKT2;1 7AL-1, TaHKT2;1 7BL-1, TaHKT2;1 7BL-2 and TaHKT2;1 7DL-1) and two pseudogenes (TaHKT2;1 7AL-2 and TaHKT2;1 7AL-3), on chromosomes 7A, 7B and 7D of hexaploid wheat. Variability in protein domains for cation specificity and in cis-regulatory elements for salt response in gene promoters, were identified amongst the functional TaHKT2;1 members. The functional genes were expressed under low and high NaCl conditions in roots and leaf sheaths, but were down regulated in leaf blades. Alternative splicing events were evident in TaHKT2;1 7AL-1. Aneuploid lines null for each functional gene were grown in high NaCl nutrient solution culture to identify potential role of each TaHKT2;1 member. Aneuploid lines null for TaHKT2;1 7AL-1, TaHKT2;1 7BL-1 and TaHKT2;1 7BL-2 showed no difference in Na(+) concentration between Chinese Spring except for higher Na(+) in sheaths. The same aneuploid lines had lower K(+) in roots, sheath and youngest fully expanded leaf but only under high (200 mM) NaCl in the external solution. There was no difference in Na(+) or K(+) concentration for any treatment between aneuploid line null for the TaHKT2;1 7DL-1 gene and Chinese Spring.

CONCLUSIONS

TaHKT2;1 is a complex family consisting of pseudogenes and functional members. TaHKT2;1 genes do not have an apparent role in controlling root Na(+) uptake in bread wheat seedlings under experimental conditions in this study, contrary to existing hypotheses. However, TaHKT2;1 genes or, indeed other genes in the same chromosome region on 7AL, are candidates that may control Na(+) transport from root to sheath and regulate K(+) levels in different plant tissues.

摘要

背景

TaHKT2;1多基因家族的一个成员先前被鉴定为一种钠转运体，可能在根系钠吸收中发挥作用。在本研究中，以该成员现有的全长cDNA为基础，查询国际小麦基因组调查序列，以鉴定TaHKT2;1家族的所有成员。随后对各个TaHKT2;1基因进行了研究，分析其基因和预测的蛋白质结构、启动子变异性、组织表达以及它们在小麦钠和钾状态中的作用。

结果

鉴定出6个TaHKT2;1基因，其中包括六倍体小麦7A、7B和7D染色体上的4个功能基因（TaHKT2;1 7AL-1、TaHKT2;1 7BL-1、TaHKT2;1 7BL-2和TaHKT2;1 7DL-1）和2个假基因（TaHKT2;1 7AL-2和TaHKT2;1 7AL-3）。在功能性TaHKT2;1成员中，发现了阳离子特异性蛋白质结构域的变异性以及基因启动子中盐响应顺式调控元件的变异性。这些功能基因在根和叶鞘的低和高NaCl条件下均有表达，但在叶片中表达下调。TaHKT2;1 7AL-1中存在明显的可变剪接事件。使每个功能基因缺失的非整倍体系在高NaCl营养液培养中生长，以确定每个TaHKT2;1成员的潜在作用。除叶鞘中钠含量较高外，TaHKT2;1 7AL-1、TaHKT2;1 7BL-1和TaHKT2;1 7BL-2缺失的非整倍体系与中国春小麦在钠浓度上没有差异。相同的非整倍体系在根、叶鞘和最年轻的完全展开叶片中的钾含量较低，但仅在外部溶液中高（200 mM）NaCl条件下如此。TaHKT2;1 7DL-1基因缺失的非整倍体系与中国春小麦在任何处理下的钠或钾浓度均无差异。

结论

TaHKT2;1是一个由假基因和功能成员组成的复杂家族。与现有假设相反，在本研究的实验条件下，TaHKT2;1基因在控制面包小麦幼苗根系钠吸收方面没有明显作用。然而，TaHKT2;1基因或7AL染色体同一区域的其他基因确实是可能控制钠从根向叶鞘运输并调节不同植物组织中钾水平的候选基因。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/9bd5/4079177/43fa4b3107fe/1471-2229-14-159-1.jpg

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面包小麦中多基因家族TaHKT 2;1的特征及其基因成员在植物钠（Na⁺）和钾（K⁺）状态中的作用

Characterization of the multigene family TaHKT 2;1 in bread wheat and the role of gene members in plant Na(+) and K(+) status.

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出版信息

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RESULTS

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