ABC转运蛋白结构及在植物病原真菌中的功能研究进展

ABC(ATP-binding cassette)转运蛋白是最大的膜转运蛋白超家族之一,其主要功能是利用ATP水解产生的能量将底物进行逆浓度梯度运输.所有生物体都含有大量ABC蛋白.ABC蛋白位于细胞的不同空间,如细胞膜、液泡、线粒体和过氧化物酶体.通常,ABC转运蛋白由跨膜结构域(TMD)和核苷酸结合结构域(NBD)组成,分别与底物和ATP结合.NBD执行与ATP结合和水解,是ABC转运蛋白的动力引擎,TMD识别特异性配体.大多数ABC转运蛋白最初是通过研究生物体耐药性而被发现的,包括多效耐药(PDR)和多药耐药(MDR).本文对ABC转运蛋白的结构及作用机制,以及植物病原真菌中ABC转运蛋白功能的研究进展进行综述.     

介导多药耐药的ABC转运蛋白超家族与MTX耐药性的关系研究

细胞耐药性的产生是导致肿瘤化疗失败的重要因素, 尤其是多药耐药是目前研究的一个重点。ABC转运蛋白超家族成员介导药物的外排, 与多药耐药密切相关。为了解该家族成员与MTX耐药的相关性, 进一步探讨MTX的耐药机制, 应用SuperArray基因芯片对MTX耐药前后编码ABC转运蛋白超家族成员的mdr1、mrp1、mrp2、mrp3、mrp5、mrp6和abcg2 7个基因进行检测, 并对MRP1和MRP5蛋白表达进行了验证。结果显示, 与MTX耐药性相关的ABC转运蛋白超家族成员主要为多药耐药相关蛋白, 其中mrp1和mrp5呈现高表达, 并且, 在MTX抗性细胞中, MRP5在mRNA及蛋白水平的表达均明显增强, 提示其在MTX耐药机制中起重要作用, 可能为潜在的药物作用靶点。     

乳腺癌耐药蛋白的研究进展

乳腺癌耐药相关蛋白(BCRP/ABCG2)是新近发现的ATP结合盒(Adenosine triphosphate-binding cassette,ABC)膜转运蛋白超家族成员。它作为细胞膜上的药物排出泵,可以将一系列细胞毒药物转运至胞外从而介导肿瘤细胞多药耐药。在很多血液肿瘤和实体瘤中均检测到ABCG2表达。ABCG2在肿瘤的多药耐药上发挥重要作用。本文对ABCG2的发现、基因表达特征、与造血干细胞分化的关系、转运底物及其耐药逆转和临床意义等方面的研究进展进行综述。     

ABC转运蛋白研究的新进展

ABC转运蛋白主要包括P-糖蛋白、多药耐药相关蛋白和乳腺癌耐药蛋白,它们属于同一家族,具有保守的功能结构域和多样化的生物学功能。ABC转运蛋白部分成员的过表达与肿瘤细胞的多药耐药性（MDR）密切相关,是导致化疗失败的主要原因。随着对MDR机制认识的深入,针对多药耐药蛋白的特异结构域已设计出多种形式的MDR逆转药物。近年来发现,ABC转运蛋白广泛存在于多种正常的组织和器官,参与药物和内、外源毒素的吸收、分布和排泄,行使解毒和防御保护的作用。因此,通过转植ABC转运蛋白基因有可能降低经济鱼类、虾等水产品中有毒污染物的积累。     

肿瘤多药耐药性中的ABC转运蛋白及其调节

ABC转运蛋白是一类利用ATP水解能量,逆浓度方向将一系列化合物转运通过膜结构的膜蛋白,这一类蛋白能转运离子,糖,氨基酸,维生素,多肽,多糖,激素,脂类及生物异源物质.P-糖蛋白(P-gp)、多药耐药相关蛋白(MRP)和乳腺癌耐药蛋白(BCRP)等ABC转运蛋白还具有转运抗癌药物的能力,因此对化疗的有效性有负面的影响.近年来,许多研究涉及到如何逆转由ABC转 运蛋白引起的肿瘤多药耐药性.本文概述了近年来在蛋白水平,mRNA水平或DNA水平上对ABC转运蛋白调控的研究.     

P-糖蛋白结构及作用机制

ABC (ATP-binding cassette) 转运蛋白广泛存在于各种生物体细胞中,例如细菌的内层细胞浆膜和真核生物的细胞膜和细胞器膜.其利用与ATP的结合和水解供能进行底物的跨膜转运,其中一部分ABC转运蛋白能转运多种疏水性分子.P-糖蛋白隶属于ABC转运蛋白超家族,是研究最为透彻的一员,主要功能是防止机体对外来有害物质的摄入.P-糖蛋白(P-glycoprotein)由4 个基本结构域组成,2 个跨膜区和2 个位于细胞浆内的核苷酸结合区.核苷酸结合区参与ATP的结合和水解,而各由6 个α 跨膜螺旋组成的2个跨膜区联合构成了底物跨膜转运的通道.P 糖蛋白能转运多种不同结构的底物,包括脂类、胆汁酸、多肽和外源性化学物质,这对机体的生存至关重要,但同时也存在不利的一面,包括干扰了药物的运输,从而导致了多药耐药现象的产生.本文就P-糖蛋白的分子结构和作用机制的最新研究进展进行综述.     

半枝莲新克罗烷型二萜成分逆转肿瘤多药耐药活性研究

肿瘤细胞对化疗药物产生耐药性是肿瘤治疗失败的重要因素。其中,以P-糖蛋白(P-gp)为代表的ABC转运蛋白超家族异常表达引起的药物外排是产生多药耐药(MDR)的主要机制之一。本研究中,我们采用现代分离纯化方法,从半枝莲中分离并鉴定得到了6个已知的新克罗烷型二萜化合物:scutebarbatine Y(1)、scutebarbatine B(2)、suctebartine F(3)、clerdinin B(4)、scutellin A(5)、scutehennanine D(6)。其中,化合物4为首次从半枝莲中分离得到。体外逆转肿瘤多药耐药活性评价发现化合物1、2、3、6在20μM时,与阿霉素(Adr)联用可以逆转HepG2/Adr细胞对阿霉素的耐药性,逆转倍数(RI)范围为14.04～39.42;蛋白印迹分析结果表明,与HepG2敏感株相比,HepG2/Adr耐药细胞P-糖蛋白表达显著提高,可能是其产生耐药性的主要因素;荧光结果显示,该系列化合物能够明显促进阿霉素在HepG2/Adr细胞中的积累;但化合物不影响P-糖蛋白的表达。以上结果显示化合物1、2、3和6可能是通过抑制P-糖蛋白的外排功能来逆转肿瘤细胞多药耐药的。     

半分子转运蛋白ABCG2的肿瘤多药耐药性研究及其应用

肿瘤常对临床上传统使用的多种化学治疗显示其内源性或获得性的药物耐受性即多药耐药性(multidrug resistance,MDR)．这种多药耐药性主要是由一类称为ABC(ATP-binding cassette)转运体蛋白超家族的跨膜蛋白引起的,它们结合并利用水解ATP提供的能量来转运药物,导致肿瘤细胞呈现抗药性．半分子转运蛋白ABCG2是近年来才发现的可归于ABC转运体大家族中的一个新成员,在肠、肝、胎盘和血脑屏障等部位大量表达,与全分子转运蛋白如P-gp (P-glycoprotein)和多药耐药蛋白(multi-drug resistance protein,MRP)相似,可以主动地把具有不同化学结构和作用于细胞内不同靶位点的化疗药物泵出胞外,从而引起肿瘤对多种抗癌药物(包括最新开发的药物)产生抗性．最近的一些十分有趣的研究还表明,ABCG2可能与干细胞分化状态和保护干细胞发育过程中免受周围环境的影响有关,而且还发现,它在侧群骨髓和神经干细胞内大量存在,因此,ABCG2可能在基因治疗中作为选择性的蛋白质标记正受到研究者们的极大关注．同时,ABCG2的单核苷酸多态性影响其结合并转运不同的底物/药物．鉴于ABCG2在肿瘤抗药性研究中的重要性以及它的一些新功能的初步研究表明,对ABCG2的生物学功能和作用机理以及在医学实践中的应用研究必将受到更大的关注．主要阐述了半分子ABC转运蛋白ABCG2的发现、重要的生化特性和生理功能及其相关的新研究进展和问题．     

P-糖蛋白对结肠癌多药耐药的影响

结肠癌是常见的消化道恶性肿瘤。对术后患者以及无法采用手术治疗的患者,临床多采用化疗、放疗等综合性治疗方法。随着大量化疗药物在临床的广泛使用,结肠癌多药耐药性成为化疗失败的最主要原因。研究表明,P-糖蛋白(P-glycoprotein, P-gp)作为ATP结合盒(ABC)转运蛋白超家族成员之一,与多种肿瘤的多药耐药相关,其介导的多药耐药已经成为目前研究的热点。本文旨在通过对P-糖蛋白的结构、耐药机制以及逆转P-糖蛋白介导的结肠癌多药耐药新发现进行阐述,引导读者对P-糖蛋白在结肠癌多药耐药中的作用有更深入的了解。     

灵芝酸T提高多药耐药性肿瘤细胞对阿霉素敏感性的初步研究

本文分析并探讨了灵芝酸T提高多药耐药性肿瘤细胞(KB-A-1/Dox)对阿霉素敏感性的效果及可能的机理。结果表明:灵芝酸T在较高浓度下对阿霉素敏感型和耐药型肿瘤细胞均表现出细胞毒性并诱导细胞凋亡,IC50约为50μg/mL;经5μg/mL灵芝酸T处理后,阿霉素对多药耐药性肿瘤细胞作用的IC50值减少到0.103μg/mL,与阿霉素对照组的IC502.294μg/mL相比,细胞毒性增加了22.3倍,逆转了肿瘤细胞对阿霉素的多药耐药性。同时灵芝酸T处理可使多药耐药性肿瘤细胞内阿霉素和Rhodamin123含量分别增加40%、20%。以上结果提示灵芝酸T能提高多药耐药性肿瘤细胞对阿霉素的敏感性。     

Salinomycin overcomes ABC transporter-mediated multidrug and apoptosis resistance in human leukemia stem cell-like KG-1a cells

Leukemia stem cells are known to exhibit multidrug resistance by expression of ATP-binding cassette (ABC) transporters which constitute transmembrane proteins capable of exporting a wide variety of chemotherapeutic drugs from the cytosol. We show here that human promyeloblastic leukemia KG-1a cells exposed to the histone deacetylase inhibitor phenylbutyrate resemble many characteristics of leukemia stem cells, including expression of functional ABC transporters such as P-glycoprotein, BCRP and MRP8. Consequently, KG-1a cells display resistance to the induction of apoptosis by various chemotherapeutic drugs. Resistance to apoptosis induction by chemotherapeutic drugs can be reversed by cyclosporine A, which effectively inhibits the activity of P-glycoprotein and BCRP, thus demonstrating ABC transporter-mediated drug resistance in KG-1a cells. However, KG-1a are highly sensitive to apoptosis induction by salinomycin, a polyether ionophore antibiotic that has recently been shown to kill human breast cancer stem cell-like cells and to induce apoptosis in human cancer cells displaying multiple mechanisms of drug and apoptosis resistance. Whereas KG-1a cells can be adapted to proliferate in the presence of apoptosis-inducing concentrations of bortezomib and doxorubicin, salinomycin does not permit long-term adaptation of the cells to apoptosis-inducing concentrations. Thus, salinomycin should be regarded as a novel and effective agent for the elimination of leukemia stem cells and other tumor cells exhibiting ABC transporter-mediated multidrug resistance.     

Multidrug transport by the ABC transporter Sav1866 from Staphylococcus aureus

Sav1866 is an ATP-binding cassette (ABC) protein from the pathogen Staphylococcus aureus and is a homologue of bacterial and human multidrug ABC transporters. Recently, the three-dimensional crystal structure of Sav1866 was determined at 3.0 A resolution [Dawson, R. J., and Locher, K. P. (2006) Nature 443, 180-185]. Although this structure is frequently used to homology model human and microbial ABC multidrug transporters by computational methods, the ability of Sav1866 to transport multiple drugs has not been described. We obtained functional expression of Sav1866 in the drug-sensitive, Gram-positive bacterium Lactococcus lactis Delta lmrA Delta lmrCD lacking major endogenous multidrug transporters. Sav1866 displayed a Hoechst 33342, verapamil, tetraphenylphosphonium, and vinblastine-stimulated ATPase activity. In growing cells, Sav1866 expression conferred resistance to Hoechst 33342. In transport assays in intact cells, Sav1866 catalyzed the translocation of amphiphilic cationic ethidium. Additionally, Sav1866 mediated the active transport of Hoechst 33342 in membrane vesicles and proteoliposomes containing purified and functionally reconstituted protein. Sav1866-mediated resistance and transport were inhibited by the human ABCB1 and ABCC1 modulator verapamil. This work represents the first demonstration of multidrug transport by Sav1866 and suggests that Sav1866 can serve as a well-defined model for studies on the molecular bases of drug-protein interactions in ABC transporters. Our methods for the overexpression, purification, and functional reconstitution of Sav1866 are described in detail.     

Multidrug resistance ABC transporters

Clinical multidrug resistance is caused by a group of integral membrane proteins that transport hydrophobic drugs and lipids across the cell membrane. One class of these permeases, known as multidrug resistance ATP binding cassette (ABC) transporters, translocate these molecules by coupling drug/lipid efflux with energy derived from the hydrolysis of ATP. In this review, we examine both the structures and conformational changes of multidrug resistance ABC transporters. Together with the available biochemical and structural evidence, we propose a general mechanism for hydrophobic substrate transport coupled to ATP hydrolysis.     

Structure-function analysis of multidrug transporters in Lactococcus lactis

The active extrusion of cytotoxic compounds from the cell by multidrug transporters is one of the major causes of failure of chemotherapeutic treatment of tumor cells and of infections by pathogenic microorganisms. A multidrug transporter in Lactococcus lactis, LmrA, is a member of the ATP-binding cassette (ABC) superfamily and a bacterial homolog of the human multidrug resistance P-glycoprotein. Another multidrug transporter in L. lactis, LmrP, belongs to the major facilitator superfamily, and is one example of a rapidly expanding group of secondary multidrug transporters in microorganisms. Thus, LmrA and LmrP are transport proteins with very different protein structures, which use different mechanisms of energy coupling to transport drugs out of the cell. Surprisingly, both proteins have overlapping specificities for drugs, are inhibited by the same set of modulators, and transport drugs via a similar transport mechanism. The structure-function relationships that dictate drug recognition and transport by LmrP and LmrA represent an intriguing area of research.     

The homodimeric ATP-binding cassette transporter LmrA mediates multidrug transport by an alternating two-site (two-cylinder engine) mechanism

The bacterial LmrA protein and the mammalian multidrug resistance P-glycoprotein are closely related ATP-binding cassette (ABC) transporters that confer multidrug resistance on cells by mediating the extrusion of drugs at the expense of ATP hydrolysis. The mechanisms by which transport is mediated, and by which ATP hydrolysis is coupled to drug transport, are not known. Based on equilibrium binding experiments, photoaffinity labeling and drug transport assays, we conclude that homodimeric LmrA mediates drug transport by an alternating two-site transport (two-cylinder engine) mechanism. The transporter possesses two drug-binding sites: a transport-competent site on the inner membrane surface and a drug-release site on the outer membrane surface. The interconversion of these two sites, driven by the hydrolysis of ATP, occurs via a catalytic transition state intermediate in which the drug transport site is occluded. The mechanism proposed for LmrA may also be relevant for P-glycoprotein and other ABC transporters.     

Overexpression,purification, and functional characterization of ATP-binding cassette transporters in the yeast,Pichia pastoris

The ATP-binding cassette (ABC) transporter superfamily is a large gene family that has been highly conserved throughout evolution. The physiological importance of these membrane transporters is highlighted by the large variety of substrates they transport, and by the observation that mutations in many of them cause heritable diseases in human. Likewise, overexpression of certain ABC transporters, such as P-glycoprotein and members of the multidrug resistance associated protein (MRP) family, is associated with multidrug resistance in various cells and organisms. Understanding the structure and molecular mechanisms of transport of the ABC transporters in normal tissues and their possibly altered function in human diseases requires large amounts of purified and active proteins. For this, efficient expression systems are needed. The methylotrophic yeast Pichia pastoris has proven to be an efficient and inexpensive experimental model for high-level expression of many proteins, including ABC transporters. In the present review, we will summarize recent advances on the use of this system for the expression, purification, and functional characterization of P-glycoprotein and two members of the MRP subfamily.     

ABC transporters as multidrug resistance mechanisms and the development of chemosensitizers for their reversal

One of the major problems related with anticancer chemotherapy is resistance against anticancer drugs. The ATP-binding cassette (ABC) transporters are a family of transporter proteins that are responsible for drug resistance and a low bioavailability of drugs by pumping a variety of drugs out cells at the expense of ATP hydrolysis. One strategy for reversal of the resistance of tumor cells expressing ABC transporters is combined use of anticancer drugs with chemosensitizers. In this review, the physiological functions and structures of ABC transporters, and the development of chemosensitizers are described focusing on well-known proteins including P-glycoprotein, multidrug resistance associated protein, and breast cancer resistance protein.     

Overexpression, purification, and functional characterization of ATP-binding cassette transporters in the yeast, Pichia pastoris

The ATP-binding cassette (ABC) transporter superfamily is a large gene family that has been highly conserved throughout evolution. The physiological importance of these membrane transporters is highlighted by the large variety of substrates they transport, and by the observation that mutations in many of them cause heritable diseases in human. Likewise, overexpression of certain ABC transporters, such as P-glycoprotein and members of the multidrug resistance associated protein (MRP) family, is associated with multidrug resistance in various cells and organisms. Understanding the structure and molecular mechanisms of transport of the ABC transporters in normal tissues and their possibly altered function in human diseases requires large amounts of purified and active proteins. For this, efficient expression systems are needed. The methylotrophic yeast Pichia pastoris has proven to be an efficient and inexpensive experimental model for high-level expression of many proteins, including ABC transporters. In the present review, we will summarize recent advances on the use of this system for the expression, purification, and functional characterization of P-glycoprotein and two members of the MRP subfamily.     

Sterol transport by the human breast cancer resistance protein (ABCG2) expressed in Lactococcus lactis

The human breast cancer resistance protein (BCRP, also know as ABCG2, MXR, or ABCP) is one of the more recently discovered ATP-binding cassette (ABC) transporters that confer resistance on cancer cells by mediating multidrug efflux. In the present study, we have obtained functional expression of human BCRP in the Gram-positive bacterium Lactococcus lactis. BCRP expression conferred multidrug resistance on the lactococcal cells, which was based on ATP-dependent drug extrusion. BCRP-mediated ATPase and drug transport activities were inhibited by the BCRP-specific modulator fumitremorgin C. To our knowledge these data represent the first example of the functional expression of a mammalian ABC half-transporter in bacteria. Although members of the ABCG subfamily (such as ABCG1 and ABCG5/8) have been implicated in the transport of sterols, such a role has not yet been established for BCRP. Interestingly, the BCRP-associated ATPase activity in L. lactis was significantly stimulated by (i) sterols including cholesterol and estradiol, (ii) natural steroids such as progesterone and testosterone, and (iii) the anti-estrogen anticancer drug tamoxifen. In addition, BCRP mediated the efflux of [3H]estradiol from lactococcal cells. Our findings suggest that BCRP may play a role in the transport of sterols in human, in addition to its ability to transport multiple drugs and toxins.     

Bacterial multidrug resistance mediated by a homologue of the human multidrug transporter P-glycoprotein

Most ATP-binding cassette (ABC) multidrug transporters known to date are of eukaryotic origin, such as the P-glycoproteins (Pgps) and multidrug resistance-associated proteins (MRPs). Only one well-characterized ABC multidrug transporter, LmrA, is of bacterial origin. On the basis of its structural and functional characteristics, this bacterial protein is classified as a member of the P-glycoprotein cluster of the ABC transporter superfamily. LmrA can even substitute for P-glycoprotein in human lung fibroblast cells, suggesting that this type of transporter is conserved from bacteria to man. The functional similarity between bacterial LmrA and human P-glycoprotein is further exemplified by their currently known spectrum of substrates, consisting mainly of hydrophobic cationic compounds. In addition, LmrA was found to confer resistance to eight classes of broad-spectrum antibiotics, and homologs of LmrA have been found in pathogenic bacteria, supporting the clinical and academic value of studying this bacterial protein. Current studies are focused on unraveling the mechanism by which ABC multidrug transporters, such as LmrA, couple the hydrolysis of ATP to the translocation of drugs across the membrane. Recent evidence indicates that LmrA mediates drug transport by an alternating two-site transport mechanism.