Na+/H+逆向转运蛋白和植物耐盐性

Na⁺H⁺逆向转运蛋白对植物耐盐起着重要作用 ,它利用质膜H⁺ATPase或液泡膜H⁺ATPase及Ppiase泵H+产生的驱动力把Na⁺排出细胞或在液泡中区隔化以消除Na⁺的毒害。主要讨论植物中Na⁺H⁺逆向转运蛋白研究在分子水平的最新进展.     

锰离子转运蛋白的发现及功能机制研究进展

锰是维持人体健康的必需微量元素。锰缺乏或过量均可促发系列重大疾病发生。机体或细胞锰离子的稳态维持受多个锰离子转运蛋白的调控。近年,三个关键的锰离子转运蛋白SLC39A8、SLC39A14和SLC30A10相继被发现,这些基因突变可直接导致锰代谢异常所致的人类遗传病;同时,相关基因敲除或转基因模式动物模型不仅能够模拟人类锰代谢异常的症状,而且可深入研究这些锰离子转运蛋白在器官和细胞内的功能及其分子调控机制,从而开启了锰稳态调控研究的崭新征程。此外,有研究提示二价金属转运蛋白1(DMT1)、膜铁转运蛋白(FPN)、转铁蛋白/转铁蛋白受体系统(TF/Tf R)、TMEM165、分泌型Ca2+通道1(SPCA1)及ATP13A2等膜蛋白也可能参与细胞锰离子转运,使得锰离子的稳态调控变得更为复杂。现就锰转运蛋白的发现及功能机制研究的国内外进展作系统性综述,为后续研究提供新思路。     

铁代谢蛋白在肾脏的表达与功能

最近的研究证实,肾小管细胞具有能力表达包括转铁蛋白受体1(transferrin receptor-1,TfR1)、二价金属离子转运蛋白1(divalent metal transporter-1,DMT1)、膜铁转运蛋白1(ferroportin-1,FPN1)、铁调节蛋白(iron regulatory protein,IRP)和铁调素(hepcidin,Hepc)在内的几乎所有铁代谢蛋白.这些蛋白质的存在以及相关研究显示肾脏可能具有排出多余铁的功能,因此对体铁平衡起有十分重要的作用.     

表面等离激元共振生物传感器研究整合素蛋白αⅡbβ3与RGD多肽的特异结合

整合素蛋白α_Ⅱbβ₃是血小板上的一种钙依赖性膜受体,其胞外结构域可与含有RGD序列的肽链特异结合.通过将含有NTA-DOGS的磷脂单分子层膜转移到50 nm厚的金膜上,制备了一种含有NTA头部的表面等离激元共振(SPR)传感器敏感膜.设计并合成了含有6个组氨酸和RGD基团的His-tagged短肽P1,并利用SPR生物传感器,对整合素蛋白与含有RGD配基的支撑平面膜的特异相互作用以及Ca²⁺、Mn²⁺对该相互作用的影响进行了研究.结果表明,NTA敏感膜能很好地将P1锚定在支撑平面膜表面,并能够保证P1维持一个有效的定向.将Ca²⁺从低结合位点去除或加入Mn²⁺都能够增加整合素蛋白的配基结合活性.二价阳离子对整合素蛋白配基结合能力的调节作用,可能在整合素发挥其生理功能的过程中具有重要的意义.     

骨骼肌内质网Ca2+泵转运Ca2+的结构基础

Ca²⁺泵(Ca²⁺-ATPase)是调节细胞内Ca²⁺浓度的重要蛋白质之一. Ca²⁺泵在转运Ca²⁺的过程中经历一系列构象变化. 其中,E1状态为外向的Ca²⁺高亲和状态,E2状态则为内向的Ca²⁺低亲和状态. 目前,骨骼肌内质网Ca²⁺泵转运Ca²⁺过程中的几个中间状态,包括E1-2Ca²⁺,E1-ATP,E1-P-ADP,E2-Pi和E2状态的三维晶体结构已经解析. 介绍这几种状态的晶体结构,并分析Ca²⁺泵在执行功能过程中结构与功能的关系.     

鸡二价金属转运蛋白1 cDNA的克隆与序列分析

鸡二价金属转运蛋白1（divalent metal transporter 1, DMT1）在动物胃肠道锰吸收过程中起重要作用.根据哺乳动物Dmt1同源蛋白氨基酸序列的保守性设计引物，应用3′RACE(rapid amplification of cDNA ends)技术，扩增并克隆获得鸡小肠Dmt1 cDNA 3′端1 289bp和1 092bp的2种片段，发现其3′端翻译区和非翻译区存在差异. 根据鸡Dmt1 cDNA 3′端片段的测序结果设计引物，扩增获得1个与3′端片段部分重叠的鸡Dmt1 cDNA 5′端907 bp片段，并对其进行了克隆测序. 根据鸡小肠Dmt1 3′RACE片段和5′RACE片段序列信息进行拼接，从而获得鸡小肠Dmt1 cDNA全序列信息.结果表明，鸡小肠Dmt1 cDNA有2种形式，1种全长为1 972个核苷酸，其中5′非翻译区为104个核苷酸，编码区1 695个核苷酸，3′非翻译区为173个核苷酸，编码1个含564个氨基酸残基的蛋白质；另1种形式为1 775个核苷酸，其中5′非翻译区为104个核苷酸，编码区1 593个核苷酸，3′非翻译区为78个核苷酸，编码1个含530个氨基酸残基的蛋白质.据鸡Dmt1 cDNA推测出的2种形式蛋白质的氨基酸序列与人、大鼠和小鼠的Dmt1蛋白具有高度同源性，它们的同源性分别为82%、82%、80%,和 84%、84%、83%. 对推测氨基酸序列进行疏水性和跨膜区分析表明，Dmt1蛋白为1种跨膜整合蛋白，具有膜转运蛋白糖基化位点和底物结合位点的保守序列.     

膜铁转运蛋白1，铁调素的靶分子？

膜铁转运蛋白1是重要的跨膜铁输出分子,主要分布于十二指肠和单核巨噬系统的细胞膜上,参与机体的肠铁吸收和巨噬细胞对铁的再循环等过程。铁调素是调节机体铁代谢平衡的激素,机体通过肝脏分泌的铁调素对铁转运相关蛋白的表达进行调控,从而实现机体自身的铁稳态。最新研究显示,铁调素的靶分子可能是膜铁转运蛋白1,它通过直接的作用引起膜铁转运蛋白1的内化(internalization)、降解,从而调节其在细胞膜上的表达量,进而控制肠铁吸收和巨噬细胞对铁的再循环过程,以维持机体的铁稳态。     

Na-K-Cl协同转运蛋白研究进展

Na-K-Cl协同转运蛋白是一类膜蛋白,负责转运Na、K、Cl离子进出上皮细胞与非上皮细胞。Na-K-Cl介导的转运过程是电中性的,多数情况下是1Na:1K:2Cl(乌贼轴突中是2Na:1 K:3Cl),其活性被布美他尼(bumetanide)和呋塞米(furosemide)所抑制。迄今为止,Na-K-Cl协同转运蛋白被鉴定出来两个同源异构体:NKCC1和NKCC2。NKCC1存在于多个组织中,含有NKCC1的上皮大多数属于分泌上皮,而且会有Na-K-Cl协同转运蛋白位于基底膜外侧;NKCC2只存在于肾脏,位于上皮细胞致密班的顶膜上。Na-K-Cl协同转运蛋白的调控在不同的细胞和组织中是不同的。Na-K-Cl协同转运蛋白的活性会受激素刺激和细胞体积变化的影响;有些组织中,这种调控作用(尤其是NKCC1亚基)是通过特定的激酶使该转运蛋白自身发生氧化/硝化、磷酸化/去磷酸化来实现的;蛋白过表达在Na-K-Cl协同转运蛋白的激活中也起重要作用。     

Na-K-Cl协同转运蛋白研究进展

Na-K-Cl协同转运蛋白是一类膜蛋白,负责转运Na、K、Cl离子进出上皮细胞与非上皮细胞。Na-K-Cl介导的转运过程是电中性的,多数情况下是1Na：1K：2C1（乌贼轴突中是2Na：1K：3C1）,其活性被布美他尼（bumetanide）和呋塞米（furosemide）所抑制。迄今为止,Na-K-Cl协同转运蛋白被鉴定出来两个同源异构体：NKCCl和NKCC2。NKCCl存在于多个组织中,合有NKCCl的上皮大多数属于分泌上皮,而且会有Na-K-Cl协同转运蛋白位于基底膜外侧;NKCC2只存在于肾脏,位于上皮细胞致密斑的顶膜上。Na-K-Cl协同转运蛋白的调控在不同的细胞和组织中是不同的。Na-K-Cl协同转运蛋白的活性会受激素刺激和细胞体积变化的影响;有些组织中,这种调控作用（尤其是NKCCl亚基）是通过特定的激酶使该转运蛋白自身发生氧化／硝化、磷酸化／去磷酸化来实现的;蛋白过表达在Na-K-Cl协同转运蛋白的激活中也起重要作用。     

马利亚霉菌(Mariannaeasp.) HJ合成金属硒化物及机理研究

[背景] 金属硒化物因其优异的光电和催化特性,近年来在半导体、电化学及抗癌等领域成为了研究热点。相较于传统的化学还原法,生物合成金属硒化物具有环境友好、耗能较低等优势。然而,目前有关生物合成金属硒化合物的微生物资源较少且相关合成机理尚不明晰。[目的] 利用马利亚霉菌（Mariannaea sp.） HJ合成了3种金属硒化物并对其合成机理进行了初步探索。[方法] 利用X射线衍射（X-Ray Diffraction,XRD）和傅里叶转换红外线光谱（Fourier Transform Infrared Spectroscopy,FTIR）对菌株HJ合成的金属硒化物进行了初步的表征,考察了纳米材料合成过程中总巯基含量、总抗氧化性能及自由基含量变化,并且验证了转运蛋白DMT1在金属硒化物合成中所起的关键性作用。[结果] XRD结果表明菌株HJ能够在Bi³⁺、Pb²⁺、Co²⁺与SeO₃^2-作用下分别合成Bi₄Se₃、PbSe和CoSe₂纳米颗粒,其合成的最优pH条件分别为6.0、7.0、8.0。FTIR结果表明,合成的金属硒化物表面含有氨基、羧基、羟基等官能团。3种金属硒化物的合成反应体系与空白对照组相比,总巯基含量明显下降,而总抗氧化性能却有所提高,这表明巯基等酶促体系或氨基酸金属蛋白类的非酶促体系可能参与了SeO₃^2-的还原过程。苄基异硫脲盐酸盐屏蔽实验表明,转运蛋白DMT1在SeO₃^2-转运和金属硒化物分泌过程中起到关键作用。此外,Bi³⁺、Pb²⁺和Co²⁺的加入使得菌株HJ产生氧化应激反应,在胞外分泌了大量的过氧化氢、羟基自由基和超氧自由基,而上述自由基可通过诱导热激效应的方式增强金属离子或纳米颗粒的转运过程。[结论] 利用马利亚霉菌（Mariannaeasp.） HJ合成了Bi₄Se₃、PbSe和CoSe₂纳米颗粒,为研究金属硒化物的生物合成及机理提供了一定的理论参考。     

The iron transporter DMT1

Divalent metal transporter 1 (DMT1) is the first mammalian transmembrane iron transporter to be identified. In 1997, parallel experiments from two groups provided compelling evidence of its function. Fleming and colleagues identified mutations in DMT1 (formerly known as Nramp2 and DCT1) in mice and rats with defects in intestinal iron absorption and red blood cell iron utilization. Gunshin and co-workers (H Gunshin, B MacKenzie, UV Berger, Y Gunshin, MF Romero, WF Boron, S. Nussberger, JL Gollan, MA Hediger, Cloning and characterization of a mammalian proton-coupled metal-ion transporter, Nature 388 (1997) 482-488.) isolated DMT1 through an expression cloning strategy looking for mRNAs that stimulated iron uptake by Xenopus oocytes. Taken together, these data indicate that the twelve transmembrane domain protein DMT1 transfers iron across the apical surface of intestinal cells and out of transferrin cycle endosomes. Human DMT1 may be a good target for pharmacological intervention in patients with iron overload disorders attributable to increased iron absorption.     

Ontogenic changes in lactoferrin receptor and DMT1 in mouse small intestine: implications for iron absorption during early life.

It has been proposed that lactoferrin receptor (LfR) may be involved in intestinal iron transport during early life. However, it is known that iron homeostasis is regulated by divalent metal transporter 1 (DMT1; Nramp2/DCT1) in the adult small intestine. To address the hypothesis that LfR may play a role as an alternative iron transport pathway during early life, we used immunohistochemistry (IHC) to examine the localization of mouse LfR (mLfR) and DMT1. In addition to studying the localization and abundance of LfR and DMT1 on the apical membrane, intestinal brush-border membrane vesicles (BBMV) were isolated during the first 3 postnatal weeks (postnatal day (PD) 0, 5, 10, and 20). We found that mLfR is expressed in fetal mice as early as gestational days (GD) 13.5, 15.5, and 18.5. A 34 kD band for mLfR was detected at PD 0 through PD 20 in total intestine homogenate. However, mLfR protein did not appear in the BBMV preparations until PD 5 and was highly expressed at PD 10. By IHC, DMT1 protein was minimally observed at PD 0 and PD 5, but by PD 10 DMT1 was predominantly localized in the apical membrane of the maturing intestine. BBMV fractionation revealed 50-120 kD protein bands for DMT1. In these BBMV preparations, the apical-membrane-associated 120 kD band for DMT1 increased in abundance with age. However, in the corresponding total homogenates, only the deglycosylated form of DMT1 (50 kD) was identified. These results indicate that DMT1 is mislocalized during late gestation, minimally expressed during early life, and predominantly expressed in its deglycosylated form until PD 20. The immunolocalization and abundant protein expression of mLfR suggest that accrual of iron from Lf may be the principal iron uptake pathway at this age. In conclusion, our findings support the notion that until the development-dependent expression of DMT1 in the intestine is induced, mLfR may serve as an alternative iron uptake pathway.     

Iron uptake and Nramp2/DMT1/DCT1 in human bronchial epithelial cells

The capacity of natural resistance-associated macrophage protein-2 [Nramp2; also called divalent metal transporter-1 (DMT1) and divalent cation transporter-1 (DCT1)] to transport iron and its ubiquitous expression make it a likely candidate for transferrin-independent uptake of iron in peripheral tissues. We tested the hypothesis that non-transferrin-bound iron uptake by airway epithelial cells is associated with Nramp2/DMT1/DCT1 and that exposure to iron can increase Nramp2/DMT1/DCT1 mRNA and protein expression and transport of this metal. Exposure of BEAS-2B cells to ferric ammonium citrate (FAC) resulted in a decrease in Fe(3+) concentration in the supernatant that was dependent on time and initial iron concentration. In the presence of internalized calcein, FAC quenched the fluorescent signal, indicating intracellular transport of the metal. The Nramp2/DMT1/DCT1 mRNA isoform without an iron-response element (IRE) increased with exposure of BEAS-2B cells to FAC. RT-PCR demonstrated no change in the mRNA for the isoform with an IRE. Similarly, Western blot analysis for the isoform without an IRE confirmed an increased expression of this protein after FAC exposure, whereas the isoform with an IRE exhibited no change. Finally, immunohistochemistry revealed an increase in the isoform without an IRE in the rat lung epithelium after instillation of FAC. Comparable to mRNA and protein increases, iron transport was elevated after pretreatment of BEAS-2B cells with iron-containing compounds. We conclude that airway epithelial cells increase mRNA and expression of the Nramp2/DMT1/DCT1 without an IRE after exposure to iron. The increase results in an elevated transport of iron and its probable detoxification by these cells.     

Modulation of DMT1 Activity by Redox Compounds

Iron(II) exacerbates the effects of oxidative stress via the Fenton reaction. A number of human diseases are associated with iron accumulation including ischemia-reperfusion injury, inflammation and certain neurodegenerative diseases. The functional properties and localization in plasma membrane of cells and endosomes suggest an important role for the divalent metal transporter DMT1 (also known as DCT1 and Nramp2) in iron transport and cellular iron homeostasis. Although iron metabolism is strictly controlled and the activity of DMT1 is central in controlling iron homeostasis, no regulatory mechanisms for DMT1 have been so far identified. Our studies show that the activity of DMT1 is modulated by compounds that affect its redox status. We also show that both iron and zinc are transported by DMT1 when expressed in Xenopus laevis oocytes. Radiotracer uptake and electrophysiological measurements revealed that H₂O₂ and Hg²⁺ treatments result in substantial inhibition of DMT1. These findings may have a profound relevance from a physiological and pathophysiological standpoint. Present address for D.T.: Department of Neurology, Cecil B. Day Laboratory for Neuromuscular Research, Massachusetts General Hospital, Harvard Medical School, Charlestown, MA 02129, USA     

Two isoforms of a divalent metal transporter (DMT1) in Schistosoma mansoni suggest a surface-associated pathway for iron absorption in schistosomes

We describe two homologues of the mammalian divalent metal transporter (DMT1) for Schistosoma mansoni, a pathogenic intravascular parasite of humans. Schistosomes have a high nutritional and metabolic demand for iron. Nucleotide sequences of the parasite homologues, designated SmDMT1A and -B, are identical in all but the 5'-regions. The predicted amino acid sequences share at least 60% identity with DMT1 (=Nramp2) of humans, mice, and rats, and at least 55% identity with Nramp1 from mice, humans and Caenorhabditis elegans. SmDMT1A is expressed in differentiating eggs, miracidia, cercariae, schistosomula, and adults, whereas SmDMT1B is expressed in all but the miracidium and occurs at lower levels than SmDMT1A in differentiating eggs and cercariae. An iron-responsive element, present at the 3'-untranslated region of many DMT1 molecules, is not present in schistosome mRNAs studied here. A Western blot analysis of adult worm preparations using a homologous rabbit serum raised against a schistosome DMT1 peptide and a heterologous serum raised against mammalian DMT1, revealed a band approximating 115 kDa. By immunofluorescence microscopy, the schistosome DMT1s localize primarily to the tegument. Iron uptake assays demonstrated that SmDMT1s were able to rescue yeast growth in ferrous iron-transport deficient yeast (fet3fet4). The results suggest that schistosomes express molecules for ferrous iron transport in their tegument, suggesting trans-tegumental transport as one means of iron acquisition for these parasites.     

Correlation between the expression of divalent metal transporter 1 and the content of hypoxia-inducible factor-1 in hypoxic HepG2 cells

Transferrin and transferrin receptor are two key proteins of iron metabolism that have been identified to be hypoxia-inducible genes. Divalent metal transporter 1 (DMT1) is also a key transporter of iron under physiological conditions. In addition, in the 5' regulatory region of human DMT1 (between -412 and -570), there are two motifs (CCAAAGTGCTGGG) that are similar to hypoxia-inducible factor-1 (HIF-1) binding sites. It was therefore speculated that DMT1 might also be a hypoxia-inducible gene. We investigated the effects of hypoxia and hypoxia/re-oxygenation on the expression of DMT1 and the content of HIF-1alpha in HepG2 cells. As we expected, a very similar tendency in the responses of the expression of HIF-1alpha, DMT1+IRE (iron response element) and DMT1-IRE proteins to chemical (CoCl(2)) or physical hypoxia was observed. A highly significant correlation was found between the expression of DMT1 proteins and the contents of HIF-1 in hypoxic cells. After the cells were exposed to hypoxia and subsequent normoxia, no HIF-1alpha could be detected and a significant decrease in DMT1+IRE expression (P<0.05), but not in DMT1-IRE protein (versus the hypoxia group), was observed. The findings implied that the HIF-1 pathway might have a role in the regulation of DMT1+IRE expression during hypoxia.     

Regulation of divalent metal transporter expression in human intestinal epithelial cells following exposure to non-haem iron

A number of regulatory factors including dietary iron levels can dramatically alter the expression of the intestinal iron transporter DMT1. Here we show that Caco-2 cells exposed to iron for 4h exhibited a significant decrease in plasma membrane DMT1 protein, though total cellular DMT1 levels were unaltered. Following biotinylation of cell surface proteins, there was a significant increase in intracellular biotin-labelled DMT1 in iron-exposed cells. Furthermore, iron-treatment increased levels of DMT1 co-localised with LAMP1, suggesting that the initial response of intestinal epithelial cells to iron involves internalisation and targeting of DMT1 transporter protein towards a late endosomal/lysosomal compartment.     

Dynamic traffic through the recycling compartment couples the metal transporter Nramp2 (DMT1) with the transferrin receptor

Nramp2 (natural resistance-associated macrophage protein 2, also called DMT1 and Slc11a2) is a proton-dependent cation transporter, which plays a central role in iron homeostasis. To study the subcellular distribution and dynamics of the transporter, we generated a construct encoding the long splice variant of Nramp2 (isoform II) tagged with the hemagglutinin epitope on a predicted extracellular loop. Cells stably transfected with this construct revealed the presence of Nramp2 in both the plasma membrane and in an endomembrane compartment. By labeling the exofacial epitope with a pH-sensitive fluorescent indicator, we were able to establish that this variant of Nramp2 resides in a vesicular compartment with an acidic lumen (pH 6.2) and that acidification was maintained by vacuolar-type ATPases. Dual labeling experiments identified this compartment as sorting and recycling endosomes. Kinetic studies by surface labeling with 125I-labeled antibodies established that the fraction of endomembrane Nramp2 was approximately equal to that on the cell surface. The two components are in dynamic equilibrium: surface transporters are internalized continuously via a clathrin and dynamin-dependent process, whereas endosomal Nramp2 is recycled to the plasmalemma by a phosphatidylinositol 3-kinase-dependent exocytic process. Depletion of cholesterol had no discernible effect on Nramp2 internalization, suggesting that rafts or caveolae are not essential. Because the pH at the cell surface and in endosomes differs by >or=1 unit, the rates of transport of Nramp2 at the surface and in endomembrane compartments will differ drastically. Their subcellular colocalization and parallel trafficking suggest that Nramp2 and transferrin receptors are functionally coupled to effect pH-dependent iron uptake across the endosomal membrane.     

Molecular evidence for the role of a ferric reductase in iron transport

Duodenal cytochrome b (Dcytb) is a haem protein similar to the cytochrome b561 protein family. Dcytb is highly expressed in duodenal brush-border membrane and is implicated in dietary iron absorption by reducing dietary ferric iron to the ferrous form for transport via Nramp2/DCT1 (divalent-cation transporter 1)/DMT1 (divalent metal-transporter 1). The protein is expressed in other tissues and may account for ferric reductase activity at other sites in the body.