植物钾营养高效分子遗传机制

钾是植物生长发育所必需的矿质营养元素之一。不同种类植物的钾营养效率存在差异,已有证据表明这种差异是受遗传基因控制的。植物细胞依靠细胞膜上的各种钾转运体和通道蛋白吸收和转运钾离子,这些膜蛋白的活性调控是植物钾营养效率调控的关键和基础。本文对植物钾营养高效性状分子遗传机制以及相关基因的分子功能和调控机制的研究进展进行了简要评述,并讨论了改善作物钾营养高效性状的可能途径。     

植物钾营养性状的遗传潜力

钾是植物生长发育所必需的大量元素 ,是与氮、磷并列的植物营养的“三大要素”之一。不同植物种类或同种类植物的不同品种之间钾营养效率的差异非常显著 ,这为植物钾营养性状的遗传改良提供了科学依据。     

植物钾营养性状的遗传潜力v

钾是植物生长发育所必需的大量元素,是与氮、磷并列的植物营养的“三大要素”之一。不同植物种类或同种类植物的不同品种之间钾营养效率的差异非常显著,这为植物钾营养性状的遗传改良提供了科学依据     

植物钾营养高效与膜运系统的关系

HKT1和HAK1等转运子介导钾离子的高亲和吸收以及K^ /Na^ 共运转,从而可能增强Na^ 替代K^ 能力,KAT1和KST1等离子通道介导钾离子的累积和转运,从而调节气孔细胞的渗透压,控制气孔运动,阐述了植物生物膜上离子转运机制和钾营养高效机理的某种可能的关系,这些转运子和通道的高效表达可能与植物钾营养高效有很大的相关性。     

植物钾营养高效与膜转运系统的关系(英)

HKT1和HAK1等转运子介导钾离子的高亲和吸收以及K+/Na+共运转,从而可能增强Na+替代K+的能力;KAT1和KST1等离子通道介导钾离子的累积和转运,从而调节气孔细胞的渗透压,控制气孔运动。阐述了植物生物膜上离子转运机制和钾营养高效机理的某种可能的关系。这些转运子和通道的高效表达可能与植物钾营养高效有很大的相关性。     

植物钾吸收基因及其遗传转化的研究进展

综述了近年来已分离和克隆的与植物钾离子吸收有关的基因及其在遗传转化方面的研究进展,对应用生物工程技术改良植物的钾营养性状进行了讨论。     

植物对钾营养的吸收、运转和胁迫反应的研究进展

钾营养研究是植物营养研究中的重要内容之一.对植物中钾的吸收和转运、钾转运系统、低钾胁迫和缺钾时的生理表现等方面做了详细的综述,并提出了解决钾肥供需矛盾的措施.     

拟南芥耐低钾突变体的筛选及遗传分析

利用乙酰甲基磺酸（ＥＭＳ）诱变方法,以幼苗根在重力作用下的弯曲生长为指标、筛选得到了拟南芥（Ａrabidopsis thaliana)耐低钾突变体。经过对突变体杂交后代的遗传分析证明,其中两株突变体的耐低钾性状为隐性单基因突变所致。鉴定、分离与植物耐低钾性状连锁的基因将有可能与对培育钾高效作物品种有重要意义。     

植物高效吸收和利用磷营养的遗传学研究进展

近些年来 ,人们对植物营养性状的遗传学背景日益了解 ,特别是磷素营养。随着分子生物学的快速发展 ,磷素营养的研究已深入到分子水平并且取得了可喜的成绩。本文从植物体内调控磷吸收利用的相关QTLs定位 ,缺磷诱导的基因表达 ,植物体内的磷调控系统 ,磷转运子及与磷有关的突变体的研究作一概括。     

植物高效吸收和利用磷营养的遗传学研究进展

近些年来,人们对植物营养性状的遗传学背景日益了解,特别是磷素营养。随着分子生物学的快速发展,磷素营养的研究已深入到分子水平并且取得了可喜的成绩。本文从植物体内调控磷吸收利用的相关QTLs定位,缺磷诱导的基因表达,植物体内的磷调控系统,磷转运子及与磷有关的突变体的研究作一概括。     

植物Shaker K+通道的研究进展

钾离子通道是植物钾离子吸收的重要途径之一。Shaker K+家族通道是K+通道中最早发现、且研究最深入的K+通道家族。近年来,已从多种植物或同种植物的不同组织器官中分离得到多个Shaker K+钾离子通道基因,如AKT1,AtKC1,QsAKT1,GORK,AKT2等。从结构、表达部位、生理功能和调控等方面介绍了植物Shaker K+通道的研究进展。     

Multiple genes, tissue specificity, and expression-dependent modulationcontribute to the functional diversity of potassium channels in Arabidopsis thaliana.

K+ channels play diverse roles in mediating K+ transport and in modulating the membrane potential in higher plant cells during growth and development. Some of the diversity in K+ channel functions may arise from the regulated expression of multiple genes encoding different K+ channel polypeptides. Here we report the isolation of a novel Arabidopsis thaliana cDNA (AKT2) that is highly homologous to the two previously identified K+ channel genes, KAT1 and AKT1. This cDNA mapped to the center of chromosome 4 by restriction fragment length polymorphism analysis and was highly expressed in leaves, whereas AKT1 was mainly expressed in roots. In addition, we show that diversity in K+ channel function may be attributable to differences in expression levels. Increasing KAT1 expression in Xenopus oocytes by polyadenylation of the KAT1 mRNA increased the current amplitude and led to higher levels of KAT1 protein, as assayed in western blots. The increase in KAT1 expression in oocytes produced shifts in the threshold potential for activation to more positive membrane potentials and decreased half-activation times. These results suggest that different levels of expression and tissue-specific expression of different K+ channel isoforms can contribute to the functional diversity of plant K+ channels. The identification of a highly expressed, leaf-specific K+ channel homolog in plants should allow further molecular characterization of K+ channel functions for physiological K+ transport processes in leaves.     

Regulation of potassium transport in leaves: from molecular to tissue level

Over millions of years, plants have evolved a sophisticated network of K+ transport systems. This Botanical Briefing provides an overview of K+ transporters in various leaf tissues (epidermis, mesophyll, guard cells and vascular system) at both the cellular and organelle levels. Despite the tremendous progress in our knowledge of genes encoding K+ transport systems in plants, understanding has not developed of coordinated functioning and operation of these genes or proteins in the context of whole plant physiology and plant-environment interaction. This Botanical Briefing is aimed at filling that gap by analysing electrophysiological and molecular evidence for mechanisms coordinating K+ transport between various leaf cells and tissues in changing environments.     

Regulation of K+ channel activities in plants: from physiological to molecular aspects

Plant voltage-gated channels belonging to the Shaker family participate in sustained K+ transport processes at the cell and whole plant levels, such as K+ uptake from the soil solution, long-distance K+ transport in the xylem and phloem, and K+ fluxes in guard cells during stomatal movements. The attention here is focused on the regulation of these transport systems by protein-protein interactions. Clues to the identity of the regulatory mechanisms have been provided by electrophysiological approaches in planta or in heterologous systems, and through analogies with their animal counterparts. It has been shown that, like their animal homologues, plant voltage-gated channels can assemble as homo- or heterotetramers associating polypeptides encoded by different Shaker genes, and that they can bind auxiliary subunits homologous to those identified in mammals. Furthermore, several regulatory processes (involving, for example, protein kinases and phosphatases, G proteins, 14-3-3s, or syntaxins) might be common to plant and animal Shakers. However, the molecular identification of plant channel partners is still at its beginning. This paper reviews current knowledge on plant K+ channel regulation at the physiological and molecular levels, in the light of the corresponding knowledge in animal cells, and discusses perspectives for the deciphering of regulatory networks in the future.     

Novel p-type ATPases mediate high-affinity potassium or sodium uptake in fungi

Fungi have an absolute requirement for K+, but K+ may be partially replaced by Na+. Na+ uptake in Ustilago maydis and Pichia sorbitophila was found to exhibit a fast rate, low Km, and apparent independence of the membrane potential. Searches of sequences with similarity to P-type ATPases in databases allowed us to identify three genes in these species, Umacu1, Umacu2, and PsACU1, that could encode P-type ATPases of a novel type. Deletion of the acu1 and acu2 genes proved that they encoded the transporters that mediated the high-affinity Na+ uptake of U. maydis. Heterologous expressions of the Umacu2 gene in K+ transport mutants of Saccharomyces cerevisiae and transport studies in the single and double Deltaacu1 and Deltaacu2 mutants of U. maydis revealed that the acu1 and acu2 genes encode transporters that mediated high-affinity K+ uptake in addition to Na+ uptake. Other fungi also have genes or pseudogenes whose translated sequences show high similarity to the ACU proteins of U. maydis and P. sorbitophila. In the phylogenetic tree of P-type ATPases all the identified ACU ATPases define a new cluster, which shows the lowest divergence with type IIC, animal Na+,K(+)-ATPases. The fungal high-affinity Na+ uptake mediated by ACU ATPases is functionally identical to the uptake that is mediated by some plant HKT transporters.     

Structure of a plasma membrane H+-ATPase gene from the plant Arabidopsis thaliana

Physiological and biochemical studies have suggested that the plant plasma membrane H+-ATPase controls many important aspects of plant physiology, including growth, development, nutrient transport, and stomata movements. We have started the genetic analysis of this enzyme by isolating both genomic and cDNA clones of an H+-ATPase gene from Arabidopsis thaliana. The cloned gene is interrupted by 15 introns, and there is partial conservation of exon boundaries with respect to animal (Na+/K+)- and Ca2+-ATPases. In general, the relationship between exons and the predicted secondary and transmembrane structure of different ATPases with phosphorylated intermediate support a somewhat degenerate correspondence between exons and structural modules. The predicted amino acid sequence of the plant H+-ATPase is more closely related to fungal and protozoan H+-ATPases than to bacterial K+-ATPases or to animal (Na+/K+)-, (H+/K+)-, and Ca2+-ATPases. There is evidence for the existence of at least three isoforms of the plant H+-ATPase gene. These results open the way for a molecular approach to the structure and function of the plant proton pump.