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。     

真核生物锌转运体及其活性的调控

真核生物的锌内稳态是由其众多特异转运体协同转运来实现的。有两个锌转运体家族ZIP和CDF被相继发现。ZIP家族的主要功能是摄取锌,而CDF家族成员主要参与锌的外排及锌在细胞内的区室化以达到解毒或贮存的目的。锌可在转录水平和翻译水平调控两类转运体的活性以维持锌在细胞和生物体水平的内稳态。     

细菌锌离子调控体系与感染北大核心CSCD

锌(Zn)是生命体不可或缺的微量元素,对细菌和宿主同等重要。细菌体内锌离子稳态的维持依赖锌离子转运和调控体系。宿主通过限制锌离子或高锌离子中毒来控制细菌感染。为了在宿主体内生存,细菌必须表达高亲和力的锌离子转运系统,如ZnuABC,以获取足够的锌离子。由于锌与细菌大量的代谢和毒性通路密切相关,在细菌建立感染的过程中尤为重要,因此通过抑制锌离子转运系统来影响锌离子的稳态,将成为一个非常有发展前途的新型抗菌策略。     

植物锌铁转运蛋白ZIP基因家族的研究进展

金属离子对植物的正常发育至关重要,但过量又会中毒.植物体内的自动调节平衡机制会调节金属离子的吸收和运输,从而控制金属离子的含量.锌铁调控蛋白ZIP( ZRT,IRT-like protein)家族是广泛存在于植物中的转运蛋白,具有Ca2+、Fe2+、Mn2+及Zn2+等多种金属元素的转运功能.了解ZIP转运体在植物中如何发挥离子转运功能,从分子水平认识金属离子缺乏或过量积累的机理有重要意义.综述拟南芥、水稻、大麦、苜蓿和玉米ZIP家族成员及其研究进展.     

锌指类基因调控蛋白──生物无机化学和分子生物学发展的新领域

生命必需元素锌,除了以锌酶的形式,参与生物体的各类代谢过程外,近年来发现,锌还以各种锌蛋白的结构方式,包括锌指、锌纽、锌带和锌簇等,参与生物体的基因转录、复制及蛋白质的合成等各种基因调节和控制过程．联想到金属硫蛋白在锌的体内平衡中所扮演的角色,很有可能锌是通过金属硫蛋白和锌指类蛋白的逐级调控,成为生物体生长发育的调控中心．癌基因和人免疫缺陷病毒（HIV）的许多调节蛋白也具有锌指类结构,这给癌症和爱滋病的治疗提供了新思路．     

锌指类基因调控蛋白—生物无机化学和分子生物学发…

生命必需元素锌,除了以锌酶的形式,参与生物体的种类代谢过程外,近年来发现,锌还以各种锌蛋白的结构方式,包括锌指、锌纽、锌带和锌簇等,参与生物体的基因转录、复制及蛋白质的合成等各种基因调节和控制过程,联想到金属硫蛋白在锌的体内平衡中所扮演的角色,很有可能锌是通过金属硫蛋白和锌指类蛋白的逐级调控,成为生物体生长发育的调控中心,癌基因和人免疫缺陷病毒（ＨＩＶ）的许多调节蛋白也具有锌指类结构,这给癌症和受     

拟南芥的钾转运系统

从结构、功能和调控方面介绍模式植物拟南芥中钾转运系统的研究进展。     

游离锌离子和锌转运体-8在小鼠胰岛β细胞中的定位

目的观察游离锌离子和锌转运体-8(zinc transporter-8,ZNT-8)在小鼠胰腺定位,探讨游离锌离子和ZNT-8与胰岛素分泌的关系。方法应用金属自显影(AMG)染色技术显示小鼠胰腺中游离锌离子的定位,应用RT-PCR和免疫组织化学ABC法分别在mRNA水平和蛋白水平检测ZNT-8在小鼠胰腺内的表达,应用免疫荧光双标技术证明ZNT-8在小鼠胰岛β细胞内与胰岛素的共存。结果小鼠胰腺外分泌组织和胰岛均含有游离锌离子;在胰岛中,游离锌离子均匀分布在包括β细胞分布区在内的各个区域。胰腺组织表达ZNT-8 mRNA,ZNT-8主要表达于胰腺内分泌部胰岛中;在胰岛β细胞中,ZNT-8与胰岛素共存。结论游离锌离子在小鼠胰岛β细胞的存在及ZNT-8在小鼠胰岛β细胞中与胰岛素的共存提示ZNT-8可能通过参与胰岛β细胞内游离锌离子的转运而调节胰岛素的分泌。     

细菌金属离子外排系统及金属稳态调控

铁、铜、锌、锰等金属离子是各类生物体生存和增殖所必需的微量元素,可影响生物体内蛋白酶活性、免疫反应、生理过程和抗感染机制。细菌感染过程中,宿主可通过限制或提高体内环境中金属离子的浓度来抑制细菌增殖,与此同时,细菌进化出各种转运系统以适应宿主体内金属离子水平的变化。由于不同细菌的金属离子外排系统在结构和生化特性上存在变异,它们呈现出独特的金属离子外排模式。本文根据现有文献报道及本团队研究结果,对铁、铜、锌和锰离子的细菌外排系统进行讨论和总结,旨在综述目前对细菌金属离子稳态调控机制研究进展的认识,为深入理解细菌金属稳态调控相关机制提供参考。     

嗜盐耐盐微生物抗盐胁迫相关离子转运蛋白研究进展

离子转运蛋白在维持细胞内pH稳态、离子动态平衡等方面发挥着重要作用。钠离子转运体和钾离子转运体在嗜盐耐盐微生物中广泛存在,其"保钾排钠"机制是微生物抗盐胁迫的两大策略之一。近年来,嗜盐耐盐微生物中许多新型钠、钾离子转运体被陆续发现,如RDD蛋白、UPF0118蛋白、DUF蛋白和KimA蛋白等;Fe³⁺、Mg²⁺等其他金属离子的转运蛋白也被证实可通过影响微生物胞内相容性溶质的合成起到渗透调节的作用。本文综述了嗜盐耐盐微生物中抗盐胁迫相关的各类离子转运蛋白,分析其分子结构和工作机理,并对这些蛋白在农业方面的应用进行了展望。继续发现新的离子转运蛋白,探究抗盐胁迫相关离子转运蛋白的结构和机理,解析各转运系统的协同作用及分子调控机制,将进一步加深对嗜盐耐盐微生物抗盐胁迫调控的认识,并为盐碱地农作物的改良等提供新的思路。     

Zinc uptake and radial transport in roots of Arabidopsis thaliana: a modelling approach to understand accumulation

Background and Aims

Zinc uptake in roots is believed to be mediated by ZIP (ZRT-, IRT-like proteins) transporters. Once inside the symplast, zinc is transported to the pericycle, where it exits by means of HMA (heavy metal ATPase) transporters. The combination of symplastic transport and spatial separation of influx and efflux produces a pattern in which zinc accumulates in the pericycle. Here, mathematical modelling was employed to study the importance of ZIP regulation, HMA abundance and symplastic transport in creation of the radial pattern of zinc in primary roots of Arabidopsis thaliana.

Methods

A comprehensive one-dimensional dynamic model of radial zinc transport in roots was developed and used to conduct simulations. The model accounts for the structure of the root consisting of symplast and apoplast and includes effects of water flow, diffusion and cross-membrane transport via transporters. It also incorporates the radial geometry and varying porosity of root tissues, as well as regulation of ZIP transporters.

Key Results

Steady-state patterns were calculated for various zinc concentrations in the medium, water influx and HMA abundance. The experimentally observed zinc gradient was reproduced very well. An increase of HMA or decrease in water influx led to loss of the gradient. The dynamic behaviour for a change in medium concentration and water influx was also simulated showing short adaptation times in the range of seconds to minutes. Slowing down regulation led to oscillations in expression levels, suggesting the need for rapid regulation and existence of buffering agents.

Conclusions

The model captures the experimental findings very well and confirms the hypothesis that low abundance of HMA4 produces a radial gradient in zinc concentration. Surprisingly, transpiration was found also to be a key parameter. The model suggests that ZIP regulation takes place on a comparable timescale as symplastic transport.     

Zinc transport via ZNT5-6 and ZNT7 is critical for cell surface glycosylphosphatidylinositol-anchored protein expression

Glycosylphosphatidylinositol (GPI)-anchored proteins play crucial roles in various enzyme activities, cell signaling and adhesion, and immune responses. While the molecular mechanism underlying GPI-anchored protein biosynthesis has been well studied, the role of zinc transport in this process has not yet been elucidated. Zn transporter (ZNT) proteins mobilize cytosolic zinc to the extracellular space and to intracellular compartments. Here, we report that the early secretory pathway ZNTs (ZNT5–ZNT6 heterodimers [ZNT5-6] and ZNT7–ZNT7 homodimers [ZNT7]), which supply zinc to the lumen of the early secretory pathway compartments are essential for GPI-anchored protein expression on the cell surface. We show, using overexpression and gene disruption/re-expression strategies in cultured human cells, that loss of ZNT5-6 and ZNT7 zinc transport functions results in significant reduction in GPI-anchored protein levels similar to that in mutant cells lacking phosphatidylinositol glycan anchor biosynthesis (PIG) genes. Furthermore, medaka fish with disrupted Znt5 and Znt7 genes show touch-insensitive phenotypes similar to zebrafish Pig mutants. These findings provide a previously unappreciated insight into the regulation of GPI-anchored protein expression and protein quality control in the early secretory pathway.     

Cloning and characterization of a novel mammalian zinc transporter, zinc transporter 5, abundantly expressed in pancreatic beta cells

Intracellular homeostasis for zinc is achieved through the coordinate regulation of specific transporters engaged in zinc influx, efflux, and intracellular compartmentalization. We have identified a novel mammalian zinc transporter, zinc transporter 5 (ZnT-5), by virtue of its similarity to ZRC1, a zinc transporter of Saccharomyces cerevisiae, a member of the cation diffusion facilitator family. Human ZnT-5 (hZnT-5) cDNA encodes a 765-amino acid protein with 15 predicted membrane-spanning domains. hZnT-5 was ubiquitously expressed in all tested human tissues and abundantly expressed in the pancreas. In the human pancreas, hZnT-5 was expressed abundantly in insulin-containing beta cells that contain zinc at the highest level in the body. The hZnT-5 immunoreactivity was found to be associated with secretory granules by electron microscopy. The hZnT-5-derived zinc transport activity was detected using the Golgi-enriched vesicles prepared from hZnT-5-induced HeLa/hZnT-5 cells in which exogenous hZnT-5 expression is inducible by the Tet-on gene regulation system. This activity was dependent on time, temperature, and concentration and was saturable. Moreover, zinc at a high concentration (10 mm) inhibited the growth of yeast expressing hZnT-5. These results suggest that ZnT-5 plays an important role for transporting zinc into secretory granules in pancreatic beta cells.     

Evidence for a zinc uptake transporter in human prostate cancer cells which is regulated by prolactin and testosterone.

The glandular epithelial cells of the human prostate gland have the unique capability and function of accumulating the highest zinc levels of any soft tissue in the body. Zinc accumulation in the prostate is regulated by prolactin and testosterone; however, little information is available concerning the mechanisms associated with zinc accumulation and its regulation in prostate epithelial cells. In the present studies the uptake and accumulation of zinc were determined in the human malignant prostate cell lines LNCaP and PC-3. The results demonstrate that LNCaP cells and PC-3 cells possess the unique capability of accumulating high levels of zinc. Zinc accumulation in both cell types is stimulated by physiological concentrations of prolactin and testosterone. The studies reveal that these cells contain a rapid zinc uptake process indicative of a plasma membrane zinc transporter. Initial kinetic studies demonstrate that the rapid uptake of zinc is effective under physiological conditions that reflect the total and mobile zinc levels in circulation. Correspondingly, genetic studies demonstrate the expression of a ZIP family zinc uptake transporter in both LNCaP and PC-3 cells. The rapid zinc uptake transport process is stimulated by treatment of cells with physiological levels of prolactin and testosterone, which possibly is the result of the regulation of the ZIP-type zinc transporter gene. These zinc-accumulating characteristics are specific for prostate cells. The studies support the concept that these prostate cells express a unique hormone-responsive, plasma membrane-associated, rapid zinc uptake transporter gene associated with their unique ability to accumulate high zinc levels.