苋菜IRT1基因克隆、序列及表达分析

通过对镉超积累苋菜品种天星米铁转运蛋白基因( IRT1)的克隆、序列及表达分析,旨在为植物修复镉污染土壤奠定基础.依据同源克隆原理,通过RACE技术克隆苋菜IRT1基因及生物信息学方法分析基因序列结构和功能,Northern杂交研究基因表达.苋菜IRT1基因cDNA全长1135 bp,包含完整的阅读框,编码322个氨基酸.苋菜IRT1蛋白与已知铁转运蛋白相似性在53.70％-63.04％,具有铁转运蛋白典型的功能结构特征,即N端含有1个信号肽、氨基酸序列上具有完整的ZIP家族功能结构域( Pfam:Zip)和7个跨膜结构域(TMs).苋菜IRT1蛋白还具有1个COG0428超级家族(转运二价金属离子功能)、2个蛋白激酶C磷酸化位点和2个酪蛋白Ⅱ磷酸化位点.低铁胁迫时苋菜根中IRT1基因表达量增加,加镉处理没有改变IRT1基因表达量.因此,推断苋菜IRT1基因是ZIP家族的一员,具有转运二价金属离子功能,将基因在GenBank中注册,序列号为:GU363501,命名为AmIRT1.     

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。     

亚铁氧化酶Hephaestin的研究进展

Hephaestin(HP)作为铜蓝蛋白的同系物,是近年来发现的铁转运蛋白。HP具有一个位于羧基末端的跨膜结构域,主要分布于肠、肾、肺、皮肤、肝、胎盘等组织。目前已知HP在肠上皮细胞中与ferroportin1协同作用介导铁的跨膜转运。HP属亚铁氧化酶家族成员,具有亚铁氧化酶的活性,参与体内铁代谢。HP的表达可受铁、铜及锌等金属离子的调节。     

鼠伤寒沙门菌感染巨噬细胞铁稳态相关基因mRNA表达谱

用荧光定量PCR法检测鼠RAW264.7巨噬细胞感染与未感染鼠伤寒沙门菌后18种铁穗态相关基因的表达,评估宿主与病原体相互作用中铁稳态效应。研究显示,活的鼠伤寒沙门菌感染巨噬细胞1 h后可以诱导转铁蛋白受体表达,引起细胞内动态铁池相关基因的mRNA水平上长。基因表达分析显示,沙门菌通过诱导铁氧还原酶(Steap3)、铁膜转运蛋白(Dmt1)、铁调节因子Tfr2/Hfe以及铁调节蛋白(Irp1和Irp2)的表达主动吸收铁,而经铁转运蛋白(Fpn1)的铁外流并无明显改变。沙门菌在感染后1h积极地驱动了转铁蛋白介导的铁吸收程序。     

膜铁转运蛋白Ferroportin 1的研究进展

膜铁转运蛋白Ferroportin 1(2000年发现)在细胞铁的输出中起重要作用。它在成熟的十二指肠绒毛上皮细胞基底面、脾和肝的巨噬细胞、胎盘的合体滋养层细胞等都有表达。经序列分析显示Ferroportin 1具有十个跨膜结构域、一个还原酶位点和一个基底定位信号位点。此外,Ferroportin 1 mRNA转录在5’非翻译区包含一个铁反应元件。本文对Ferroportin 1的目前研究进行了综述,并阐述了其医学应用前景。     

单核巨噬细胞铁代谢相关蛋白的表达调控

人类机体的铁代谢表现为受限制的对外界铁的吸收和有效的机体内的铁的再循环利用,单核巨噬细胞系统通过吞噬衰老的红细胞,储存和释放铁,在机体铁的循环再利用方面起到了重要的作用。因此,单核巨噬细胞系统对整个机体铁稳态的维持非常重要。近年来,随着转铁蛋白受体1(transferrin receptor1,TfR1)、铁蛋白(ferritin,Fn)、二价金属离子转运蛋白1(divalent metal transporter1,DMT1)、膜铁转运蛋白1(ferroportin1,FPN1),以及铁调素(hepcidin)等在单核巨噬细胞系统中功能和调控机制研究的不断深入,日益加深了人们对单核巨噬细胞系统的铁代谢过程和调控机制的了解。该文综述了铁水平、NO以及炎症等因素对单核巨噬细胞系统TfR1、Fn、DMT1、FPN1、hepcidin等蛋白表达的调控及其机制研究的最新进展。     

MPTP诱导小鼠黑质区铁摄取和DMT1表达增加

铁在帕金森病(Parkinson‘s disease,PD)的发病机制中起着非常关键的作用,为了探讨PD中铁升高的机制,本实验观察了1-甲基4-苯基—1,2,3,6-四氢吡啶(MPTP)处理小鼠黑质(substantia nigra,SN)内铁摄取及新的铁转运蛋白二价金属离子转运蛋白1(DMT1)的表达变化。结果表明：(1)MPTP处理组小鼠SN内铁染色增高,注射MPTP7d组明显高于3d组。(2)MPTP处理组小鼠,酪氨酸羟化酶(TH)免疫阳性细胞数目显著减少。(3)MPTP处理组小鼠,“-IRE”型DMT1表达在各组中均增加,而“ IRE”型DMT1仅在MPTP处理后7d才出现变化。上述结果提示,这种新发现的哺乳动物跨膜铁转运蛋白表达增加可能是引起MPTP处理小鼠SN中铁升高的关键因素,铁的升高进一步导致DA神经元的死亡。     

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.     

小肠铁释放机制及相关疾病研究进展

铁是生物体必需的微量元素。铁缺乏和铁过载均会导致铁代谢紊乱相关疾病,因此有关机体铁水平稳态的调节机制已成为了目前铁代谢领域的研究热点。小肠吸收细胞是调节肠铁吸收、肠铁释放,以及维持机体铁稳态的重要部位。最新的研究表明,铁从小肠吸收细胞基底端释放入血液循环,主要是由膜铁转运蛋白（ferroportin1,Fp1）介导,并在膜铁转运辅助蛋白（haphaestin,Hp）和铜蓝蛋白（ceruloplasmin,Cp）的参与下完成。其中Fp1在小肠铁释放过程中起着至关重要的作用。本文重点阐述铁释放相关蛋白Fp1的作用机制及其调节机制,并详细介绍Fp1基因突变导致的铁代谢相关疾病方面的最新研究讲展。     

胎盘铁转运蛋白Zyklopen研究进展

Zyklopen（ZP）作为铜蓝蛋白的同系物,是近年来发现的铁转运蛋白.ZP具有一个位于羧基末端的跨膜结构域,在胎盘大量表达,也分布于脑、肾、视网膜、乳腺、睾丸等组织,但目前还不清楚ZP在这些组织中的功能.ZP具有亚铁氧化酶的活性,细胞内缺铜会引起ZP蛋白表达减少.在胎盘中,ZP可能通过将二价铁离子氧化为三价铁离子,帮助三价铁与胎儿循环系统中的转铁蛋白相结合,从而参与铁从母体到胎儿的转运过程.     

Expression of iron-related proteins during infection by bovine herpes virus type-1

Bovine herpesvirus 1 (BHV-1), a dsDNA animal virus, is an economically important pathogen of cattle and the aetiological agent of many types of disease. The efficient replication of a DNA virus is strictly dependent on iron since this metal plays a crucial role in the catalytic center of viral ribonucleotide reductase. Consequently, iron metabolism is an important area for virus/host interaction and a large body of evidence suggests that viral infection is potentially influenced by the iron status of the host. The aim of the present study was to address the effects of BHV-1 on iron metabolism in Madin-Darby bovine kidney (MDBK) cells at different times of post-infection. For this purpose, cell viability, iron regulatory proteins (IRPs) activity and levels, transferrin receptor 1 (TfR-1), ferritin expression and LIP were evaluated. Our data demonstrate that a productive BHV-1 infection in MDBK cells determines an overall decrease of IRPs RNA-binding activity without affecting their expression. As consequence of this modulation, an increased ferritin mRNA translation and a decreased TfR-1 mRNA translation were also observed. Moreover, the LIP level was decreased following viral infection. These results are consistent with the hypothesis that by reducing the iron up-take and by enhancing the sequestration of free iron, animal cells will limit the iron availability for virus proliferation. Therefore, the results presented herein support the view that iron metabolism could be critical for the interaction between DNA viruses, such as BHV-1, and mammalian cells. Delineation of the interplay among pathogen and host may provide new antimicrobial agents.     

Alterations in renal iron metabolism caused by a copper/zinc-superoxide dismutase deficiency

Abstract

Copper/zinc-superoxide dismutase knockout (SOD1 KO) mice have been extensively used as an experimental animal model of pathology associated with oxidative stress. The mice spontaneously develop mild chronic hemolytic anaemia (HA). We previously reported that the kidneys of these types of mice contain massive amounts of iron. In this study, to clarify the role of the kidney for iron metabolism under HA, changes in the levels of expression and functions of iron-related proteins were examined. In SOD1 KO mice kidneys, protein levels of iron transporters, the iron-responsive element (IRE)-binding activity of IRP1 and the levels of phosphorylation of IRP1 are all increased. These findings indicate that oxidative stress caused by a SOD1 deficiency probably enhances the phosphorylation of and the conversion of IRP1 to the IRE-binding form, which may accelerate the reabsorption of iron by renal tubular cells. Kidney could play an important role in iron homeostasis under conditions of HA.     

A Northwestern blotting approach for studying iron regulatory element-binding proteins

At least two proteins binding to iron regulatory elements (IRE) in mRNA are known, designated as iron regulatory proteins (IRP) 1 and 2. Their binding activity is widely studied by electrophoretic mobility shift assays (EMSA), which resolves one or two bands depending on the species. We used Northwestern blotting to resolve this EMSA complex into four components, and identified two other IRE-binding peptides present in HepG2 cell extracts. We designate these six peptide bands A to F on Northwestern blots, ranging in apparent molecular weight from 111 to 37 kDa. Band C is lost when cells are preloaded with iron or when leupeptin (but not several other protease inhibitors) is included in the extraction buffer. Band E is also lost with leupeptin but increases with iron loading. Binding of all bands is sensitive to iron in vitro. Two-dimensional electrophoresis reveals additional processing, especially indicating charge variants of band C. Northwestern bands A and B both react with an antibody to IRP-1 on parallel Western blots. We conclude that cellular processing can produce multiple IRE-binding species that may be involved in a more complex regulation of iron metabolism than generally appreciated. The Northwestern approach should facilitate studies of processing and binding requirements of proteins and peptides that recognize the IRE sequence. (Mol Cell Biochem 268: 67–74, 2005)     

Ferroportin 1 is expressed basolaterally in rat kidney proximal tubule cells and iron excess increases its membrane trafficking

Ferroportin 1 (FPN1) is an iron export protein expressed in liver and duodenum, as well as in reticuloendothelial macrophages. Previously, we have shown that divalent metal transporter 1 (DMT1) is expressed in late endosomes and lysosomes of the kidney proximal tubule (PT), the nephron segment responsible for the majority of solute reabsorption. We suggested that following receptor mediated endocytosis of transferrin filtered by the glomerulus, DMT1 exports iron liberated from transferrin into the cytosol. FPN1 is also expressed in the kidney yet its role remains obscure. As a first step towards determining the role of renal FPN1, we localized FPN1 in the PT. FPN1 was found to be located in association with the basolateral PT membrane and within the cytosolic compartment. FPN1 was not expressed on the apical brush‐border membrane of PT cells. These data support a role for FPN1 in vectorial export of iron out of PT cells. Furthermore, under conditions of iron loading of cultured PT cells, FPN1 was trafficked to the plasma membrane suggesting a coordinated cellular response to export excess iron and limit cellular iron concentrations.     

低氧与铁代谢相关蛋白

氧和铁这两种元素对生命活动十分重要. 低氧诱导因子(hypoxia-inducible factors, HIFs)作为转录因子,参与一系列靶基因的表达调控以适应低氧. 铁参与 DNA合成、氧气运输、代谢反应等多种细胞活动,过量游离铁会通过Haber-Weiss或 Fenton反应产生毒性自由基. 细胞通过与铁吸收、存储和利用有关的多种铁代谢相 关蛋白之间的协同作用来维持铁稳态. 与铁稳态相关的一些基因是HIFs的靶基因或 者间接受低氧调控,包括转铁蛋白、转铁蛋白受体、二价金属转运体1、铁调素、膜 铁转运蛋白、血浆铜蓝蛋白、铁蛋白等,而胞内铁浓度的改变能影响HIFs的表达. 本文就低氧与铁代谢相关蛋白的关系,尤其是低氧对铁代谢相关蛋白的调节作一综 述.     

Iron and the heart: A paradigm shift from systemic to cardiomyocyte abnormalities

Iron is a key micronutrient for the human body and participates in biological processes, such as oxygen transport, storage, and utilization. Iron homeostasis plays a crucial role in the function of the heart and both iron deficiency and iron overload are harmful to the heart, which is partly mediated by increased oxidative stress. Iron enters the cardiomyocyte through the classic pathway, by binding to the transferrin 1 receptor (TfR1), but also through other routes: T-type calcium channel (TTCC), divalent metal transporter 1 (DMT1), L-type calcium channel (LTCC), Zrt-, Irt-like Proteins (ZIP) 8 and 14. Only one protein, ferroportin (FPN), extrudes iron from cardiomyocytes. Intracellular iron is utilized, stored bound to cytoplasmic ferritin or imported by mitochondria. This cardiomyocyte iron homeostasis is controlled by iron regulatory proteins (IRP). When the cellular iron level is low, expression of IRPs increases and they reduce expression of FPN, inhibiting iron efflux, reduce ferritin expression, inhibiting iron storage and augment expression of TfR1, increasing cellular iron availability. Such cellular iron homeostasis explains why the heart is very susceptible to iron overload: while cardiomyocytes possess redundant iron importing mechanisms, they are equipped with only one iron exporting protein, ferroportin. Furthermore, abnormalities of iron homeostasis have been found in heart failure and coronary artery disease, however, no clear picture is emerging yet in this area. If we better understand iron homeostasis in the cardiomyocyte, we may be able to develop better therapies for a variety of heart diseases to which abnormalities of iron homeostasis may contribute.     

Differential regulation of estrogen in iron metabolism in astrocytes and neurons

Previous studies have demonstrated an effect of estrogen on iron metabolism in peripheral tissues. The role of estrogen on brain iron metabolism is currently unknown. In this study, we investigated the effect and mechanism of estrogen on iron transport proteins. We demonstrated that the iron exporter ferroportin 1 (FPN1) and iron importer divalent metal transporter 1 (DMT1) were upregulated and iron content was decreased after estrogen treatment for 12 hr in primary cultured astrocytes. Hypoxia-inducible factor-1 alpha (HIF-1α) was upregulated, but HIF-2α remained unchanged after estrogen treatment for 12 hr in primary cultured astrocytes. In primary cultured neurons, DMT1 was downregulated, FPN1 was upregulated, iron content decreased, iron regulatory protein (IRP1) was downregulated, but HIF-1α and HIF-2α remained unchanged after estrogen treatment for 12 hr. These results suggest that the regulation of iron metabolism by estrogen in astrocytes and neurons is different. Estrogen increases FPN1 and DMT1 expression by inducing HIF-1α in astrocytes, whereas decreased expression of IRP1 may account for the decreased DMT1 and increased FPN1 expression in neurons.     

厌氧氨氧化细菌Candidatus Kuenenia stuttgartiensis铁的吸收利用研究进展

铁是影响微生物生长代谢的关键元素,它与蛋白质结合,起催化、氧化还原或调节作用。厌氧氨氧化(ANAMMOX)细菌的生长代谢严重依赖铁,尤其是含铁蛋白。ANAMMOX细菌的厌氧生活方式和厌氧氨氧化体的存在使其对铁代谢的模式不同于其他微生物。弄清ANAMMOX细菌的铁吸收代谢模式,可为获得其纯培养物奠定基础,有利于促进其在环境领域中的应用。在这里,我们将现有铁吸收、利用和代谢的观点、与ANAMMOX细菌的基因组信息和有限的生化生理数据结合起来,提出ANAMMOX细菌可能的铁利用途径,为后续的生理生化研究提供参考。