A CCCH-type zinc finger nucleic acid-binding protein quantitatively confers resistance against rice bacterial blight disease

Bacterial blight is a devastating disease of rice (Oryza sativa) caused by Xanthomonas oryzae pv oryzae (Xoo). Zinc finger proteins harboring the motif with three conserved cysteine residues and one histidine residue (CCCH) belong to a large family. Although at least 67 CCCH-type zinc finger protein genes have been identified in the rice genome, their functions are poorly understood. Here, we report that one of the rice CCCH-type zinc finger proteins, C3H12, containing five typical CX(8)-CX(5)-CX(3)-H zinc finger motifs, is involved in the rice-Xoo interaction. Activation of C3H12 partially enhanced resistance to Xoo, accompanied by the accumulation of jasmonic acid (JA) and induced expression of JA signaling genes in rice. In contrast, knockout or suppression of C3H12 resulted in partially increased susceptibility to Xoo, accompanied by decreased levels of JA and expression of JA signaling genes in rice. C3H12 colocalized with a minor disease resistance quantitative trait locus to Xoo, and the enhanced resistance of randomly chosen plants in the quantitative trait locus mapping population correlated with an increased expression level of C3H12. The C3H12 protein localized in the nucleus and possessed nucleic acid-binding activity in vitro. These results suggest that C3H12, as a nucleic acid-binding protein, positively and quantitatively regulates rice resistance to Xoo and that its function is likely associated with the JA-dependent pathway.     

An Arabidopsis gene isolated by a novel method for detecting genetic interaction in yeast encodes the GDP dissociation inhibitor of Ara4 GTPase.

The Arabidopsis Ara proteins belong to the Rab/Ypt family of small GTPases, which are implicated in intracellular vesicular traffic. To understand their specific roles in the cell, it is imperative to identify molecules that regulate the GTPase cycle. Such molecules have been found and characterized in animals and yeasts but not in plants. Using a yeast system, we developed a novel method of functional screening to detect interactions between foreign genes and identified this Rab regulator in plants. We found that the expression of the ARA4 gene in yeast ypt mutants causes exaggeration of the mutant phenotype. By introducing an Arabidopsis cDNA library into the ypt1 mutant, we isolated a clone whose coexpression overcame the deleterious effect of ARA4. This gene encodes an Arabidopsis homolog of the Rab GDP dissociation inhibitor (GDI) and was named AtGDI1. The expression of AtGDI1 complemented the yeast sec19-1 (gdi1) mutation. AtGDI1 is expressed almost ubiquitously in Arabidopsis tissues. The method described here indicates the physiological interaction of two plant molecules, Ara4 and GDI, in yeast and should be applicable to other foreign genes.     

Drosophila fear of intimacy encodes a Zrt/IRT-like protein (ZIP) family zinc transporter functionally related to mammalian ZIP proteins

Zinc is essential for many cellular processes, and its concentration in the cell must be tightly controlled. The Zrt/IRT-like protein (ZIP) family of zinc transporters have recently been identified as the main regulators of zinc influx into the cytoplasm; however, little is known about their in vivo roles. Previously, we have shown that fear of intimacy (foi) encodes a putative member of the ZIP family that is essential for development in Drosophila. Here we demonstrate that FOI can act as an ion transporter in both yeast and mammalian cell assays and is specific for zinc. We also provide insight into the mechanism of action of the ZIP family through membrane topology and structure-function analyses of FOI. Our work demonstrates that Drosophila FOI is closely related to mammalian ZIP proteins at the functional level and that Drosophila represents an ideal system for understanding the in vivo roles of this family. In addition, this work indicates that the control of zinc by ZIP transporters may play a critical role in regulating developmental processes.     

逆境相关植物锌指蛋白的研究进展

锌是植物必需的营养元素,锌指蛋白因其具有指状结构特征且能结合Zn2 而得名,植物锌指蛋白包含特有的QALGGH保守结构,可能涉及调控植物特有的生物学功能。人们已经从拟南芥(Arabidopsis thaliana)、矮牵牛(Petunia hybrida Vilm)、水稻(Oryza sativa)、大豆(Glycine max)、棉花(Gossypium hirsutum)等植物中克隆了许多编码锌指蛋白的基因,并对其结构及功能进行了研究。利用转基因技术,将一些与逆境胁迫相关的锌指蛋白基因在目标植物中过量表达后,能对植物起到增强抗逆性的作用,说明锌指蛋白在增强植物逆境抗性方面有着广阔的应用前景。     

酵母和植物的锌转运系统及其调控

锌是所有生物体必需的微量元素之一, 是多种蛋白的辅酶并参与催化生物体内的一些重要生化反应。生物体为了维持细胞内适当的锌浓度以保证其正常功能而进化出了复杂的锌转运及调控系统。本文主要论述酵母和植物中的锌转运系统及其调控, 以及锌吸收的分子标记和QTL位点分析。     

酵母和植物的锌转运系统及其调控

锌是所有生物体必需的微量元素之一,是多种蛋白的辅酶并参与催化生物体内的一些重要生化反应。生物体为了维持细胞内适当的锌浓度以保证其正常功能而进化出了复杂的锌转运及调控系统。本文主要论述酵母和植物中的锌转运系统及其调控,以及锌吸收的分子标记和QTL位点分析。     

Zinc deficiency and its inherited disorders -a review

Zinc is an essential trace element required by all living organisms because of its critical roles both as a structural component of proteins and as a cofactor in enzyme catalysis. The importance of zinc in human metabolism is illustrated by the effects of zinc deficiency, which include a diminished immune response, reduced healing and neurological disorders. Furthermore, nutritional zinc deficiency can be fatal in newborn or growing animals. While zinc deficiency is commonly caused by dietary factors, several inherited defects of zinc deficiency have been identified. Acrodermatitis enteropathica is the most commonly described inherited condition found in humans. In several of the few cases that have been reported, this disorder is associated with mutations in the hZIP4 gene, a member of the SLC39 family, whose members encode membranebound putative zinc transporters. Mutations in other members of this family or in different genes may account for other cases of acrodermatitis in which defects in hZIP4 have not been detected. Another inherited form of zinc deficiency occurs in the lethal milk mouse, where a mutation in ZnT4 gene, a member of the SLC30 family of transmembrane proteins results in impaired secretion of zinc into milk from the mammary gland. A similar disorder to the lethal milk mouse occurs in humans. In the few cases studied, no changes in ZnT4 orthologue, hZnT4, were detected. This, and the presence of several minor phenotypic differences between the zinc deficiency in humans and mice, suggests that the human condition is caused by defects in genes that are yet to be identified. Taking into account the fact that there are no definitive tests for zinc deficiency and that this disorder can go undiagnosed, plus the recent identification of multiple members of the SCL30 and SLC39, it is likely that mutations in other genes may underlie additional inherited disorders of zinc deficiency.     

CCCH型锌指蛋白研究进展

锌指蛋白是一类生物体中广泛存在的具有典型锌指结构特征的超蛋白家族,几乎参与了生物体生长发育的各个阶段。根据锌指蛋白的结构及功能特点,锌指蛋白主要分为9大类,其中CCCH型锌指蛋白相比其它几类来说较少,约占所有锌指蛋白的0.8%,在植物、动物、微生物中都有发现。CCCH型锌指蛋白包含一个或多个由3个半胱氨酸和一个组氨酸组成的能与锌离子结合的基序。综述了CCCH型锌指蛋白的定义、结构、表达、作用方式和功能。     

胡杨锌指蛋白基因克隆及其结构分析

锌指蛋白属于核转录因子家族,在原核生物与真核生物基因转录调控中发挥作用。分析了耐盐锌指蛋白Alfin-1基因在苜蓿与拟南芥中的保守性后,设计了一对引物。以胡杨水培叶片为材料,从总RNA中通过RT-PCR分离得到一个锌指蛋白基因,其cDNA长924bp。分析其氨基酸序列表明,存在一个典型的Cys2/His2锌指结构,从第556位开始有一个富含G的启动子结合位点GTGGGG。由于具有相同功能的转录因子在结构和DNA结合区的氨基酸序列上具有保守性,因此,从结构分析上可以推测该基因与Alfin-1在功能上是有一定的相关性。     

Functional expression of the human hZIP2 zinc transporter

Zinc is an essential nutrient for humans, yet we know little about how this metal ion is taken up by mammalian cells. In this report, we describe the characterization of hZip2, a human zinc transporter identified by its similarity to zinc transporters recently characterized in fungi and plants. hZip2 is a member of the ZIP family of eukaryotic metal ion transporters that includes two other human genes, hZIP1 and hZIP3, and genes in mice and rats. To test whether hZip2 is a zinc transporter, we examined (65)Zn uptake activity in transfected K562 erythroleukemia cells expressing hZip2 from the CMV promoter. hZip2-expressing cells accumulated more zinc than control cells because of an increased initial zinc uptake rate. This activity was time-, temperature-, and concentration-dependent and saturable with an apparent K(m) of 3 microM. hZip2 zinc uptake activity was inhibited by several other transition metals, suggesting that this protein may transport other substrates as well. hZip2 activity was not energy-dependent, nor did it require K(+) or Na(+) gradients. Zinc uptake by hZip2 was stimulated by HCO(3)(-) treatment, suggesting a Zn(2+)-HCO(3)(-) cotransport mechanism. Finally, hZip2 was exclusively localized in the plasma membrane. These results indicate that hZip2 is a zinc transporter, and its identification provides one of the first molecular tools to study zinc uptake in mammalian cells.     

植物对重金属锌耐性机理的研究进展

Zn是植物必需的营养元素,同时也是一种常见的有毒重金属元素.由于长期的环境选择和适应进化,植物相应对Zn~(2+)产生了耐性,可减轻或避免Zn~(2+)的毒害.植物对锌耐性机制有:菌根和细胞膜对Zn~(2+)吸收的阻止和控制,其中控制Zn~(2+)的细胞膜跨膜转运器主要有(ZIP)类、阳离子扩散促进器(CDF)类和B-type ATPase (HMA)类;金属硫蛋白(MTs)、植物螯合素(PCs)和有机酸等Zn~(2+)螯合物质的体内螯合解毒;体内区室化分隔以及通过抗氧化系统和渗透调节物质的代谢调节等.本文从生理和分子水平上综述了植物对Zn~(2+)耐性机理的研究进展,并在此基础上提出目前存在的问题和今后研究的重点领域,为该领域的相关研究提供资料和借鉴.     

Phylogenetic analysis of the plant-specific zinc finger-homeobox and mini zinc finger gene families

Zinc finger-homeodomain proteins (ZHD) are present in many plants; however, the evolutionary history of the ZHD gene family remains largely unknown. We show here that ZHD genes are plant-specific, nearly all intronless, and related to MINI ZINC FINGER ( MIF ) genes that possess only the zinc finger. Phylogenetic analyses of ZHD genes from representative land plants suggest that non-seed plant ZHD genes occupy basal positions and angiosperm homologs form seven distinct clades. Several clades contain genes from two or more major angiosperm groups, including eudicots, monocots, magnoliids, and other basal angiosperms, indicating that several duplications occurred before the diversification of flowering plants. In addition, specific lineages have experienced more recent duplications. Unlike the ZHD genes, MIF s are found only from seed plants, possibly derived from ZHD s by loss of the homeodomain before the divergence of seed plants. Moreover, the MIF genes have also undergone relatively recent gene duplications. Finally, genome duplication might have contributed substantially to the expansion of family size in angiosperms and caused a high level of functional redundancy/overlap in these genes.     

PCR方法检测水稻中存在G蛋白基因家族

ＰＣＲ方法检测水稻中存在Ｇ蛋白基因家族陈忠英,王钧（中国科学院上海植物生理研究所,２００００３２）关键词Ｇ蛋白;聚合酶链式反应（ＰＣＲ）;水稻苗;ＤＮＡ序列分析植物细胞对各种外源和内源的刺激,如光、重力、病原、激素等都有灵敏复杂的反应,但对植物信息传...     

真菌中锌簇蛋白的结构和功能

锌簇家族蛋白即Zn₂Cys₆类锌指蛋白,是真菌中特有的一类蛋白,它们属于转录因子类,广泛参与真菌中初级和次级代谢、胁迫应答和细胞分裂等生命活动的调控。锌簇蛋白主要包括N端的DNA结合结构域、中间的调节结构域和C端的酸性区域,其中DNA结合结构域包含锌指基序并负责结合靶基因的启动子。目前已经解析了多个锌簇家族转录因子DNA结合结构域的三维结构,并发现该家族中一些蛋白能够参与调控多个基因的表达,但缺乏对其结构、动力学和功能关系的全面分析。本文综合分析了不同锌簇蛋白与DNA结合的结构特征,总结其结构域与功能的关系,指出锌簇蛋白研究的重要方向,旨在为锌簇家族蛋白的深入研究提供思路。     

A novel family of cys-rich membrane proteins mediates cadmium resistance in Arabidopsis

Cadmium (Cd) is a widespread pollutant that is toxic to plant growth. However, only a few genes that contribute to Cd resistance in plants have been identified. To identify additional Cd(II) resistance genes, we screened an Arabidopsis cDNA library using a yeast (Saccharomyces cerevisiae) expression system employing the Cd(II)-sensitive yeast mutant ycf1. This screening process yielded a small Cys-rich membrane protein (Arabidopsis plant cadmium resistance, AtPcrs). Database searches revealed that there are nine close homologs in Arabidopsis. Homologs were also found in other plants. Four of the five homologs that were tested also increased resistance to Cd(II) when expressed in ycf1. AtPcr1 localizes at the plasma membrane in both yeast and Arabidopsis. Arabidopsis plants overexpressing AtPcr1 exhibited increased Cd(II) resistance, whereas antisense plants that showed reduced AtPcr1 expression were more sensitive to Cd(II). AtPcr1 overexpression reduced Cd uptake by yeast cells and also reduced the Cd contents of both yeast and Arabidopsis protoplasts treated with Cd. Thus, it appears that the Pcr family members may play an important role in the Cd resistance of plants.