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双孔通道TPK1基因编码液泡K+电导,并在K+稳态中发挥作用。

The two-pore channel TPK1 gene encodes the vacuolar K+ conductance and plays a role in K+ homeostasis.

作者信息

Gobert Anthony, Isayenkov Stanislav, Voelker Camilla, Czempinski Katrin, Maathuis Frans J M

机构信息

Department of Biology Area 9, University of York, York YO10 5DD, United Kingdom.

出版信息

Proc Natl Acad Sci U S A. 2007 Jun 19;104(25):10726-31. doi: 10.1073/pnas.0702595104. Epub 2007 Jun 11.

DOI:10.1073/pnas.0702595104
PMID:17563365
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1965580/
Abstract

The Arabidopsis thaliana genome contains five genes that encode two pore K+ (TPK) channels. The most abundantly expressed isoform of this family, TPK1, is expressed at the tonoplast where it mediates K+ -selective currents between cytoplasmic and vacuolar compartments. TPK1 open probability depends on both cytoplasmic Ca2+ and cytoplasmic pH but not on the tonoplast membrane voltage. The channel shows intrinsic rectification and can be blocked by Ba2+, tetraethylammonium, and quinine. TPK1 current was found in all shoot cell types and shows all of the hallmarks of the previously described vacuolar K (VK) tonoplast channel characterized in guard cells. Characterization of TPK1 loss-of-function mutants and TPK1-overexpressing plants shows that TPK1 has a role in intracellular K+ homeostasis affecting seedling growth at high and low ambient K+ levels. In stomata, TPK1 function is consistent with vacuolar K+ release, and removal of this channel leads to slower stomatal closure kinetics. During germination, TPK1 contributes to the radicle development through vacuolar K+ deposition to provide expansion growth or in the redistribution of essential minerals.

摘要

拟南芥基因组包含五个编码双孔钾离子(TPK)通道的基因。该家族中表达量最高的异构体TPK1,在液泡膜上表达,介导细胞质和液泡区室之间的钾离子选择性电流。TPK1的开放概率取决于细胞质钙离子和细胞质pH值,而不取决于液泡膜电压。该通道表现出固有整流特性,可被钡离子、四乙铵和奎宁阻断。在所有地上部细胞类型中均发现了TPK1电流,并且该电流具有先前在保卫细胞中所描述的液泡钾离子(VK)液泡膜通道的所有特征。对TPK1功能缺失突变体和过表达TPK1的植物的表征表明,TPK1在细胞内钾离子稳态中发挥作用,在高和低环境钾离子水平下均影响幼苗生长。在气孔中,TPK1的功能与液泡钾离子释放一致,去除该通道会导致气孔关闭动力学变慢。在种子萌发过程中,TPK1通过液泡钾离子沉积促进胚根发育,以提供扩展生长或参与必需矿物质的重新分配。

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