窖蛋白-1与乳腺癌

 窖蛋白(caveolin)是分子量为21～24 kD的整合膜蛋白,是胞膜窖(caveolae)的标志性结构分子.目前已克隆并鉴定出窖蛋白基因家族的3个成员：窖蛋白-1,窖蛋白-2和窖蛋白-3.其中窖蛋白-1参与细胞内的许多生命活动,如胆固醇的运输,细胞膜的组装,细胞信号传导,细胞周期调控,细胞转化和肿瘤形成.窖蛋白-1还可以与转录因子相互作用,调节相关基因的表达,抑制肿瘤发生.另外,在乳腺癌、前列腺癌、胃癌、肝癌等多种恶性肿瘤中均发现窖蛋白-1的异常;近年来发现,窖蛋白-1与乳腺上皮细胞转化和乳腺癌发生密切相关.本文概括介绍了窖蛋白-1的结构特点、窖蛋白-1介导的信号通路及与乳腺癌发生的关系方面的研究进展.     

基质金属蛋白酶-2和p185HER-2/neu蛋白在卵巢癌中的研究进展

基质金属蛋白酶-2(Matrix Metalloproteinase-2,MMP-2)是基质金属蛋白酶家族的重要成员,能降解明胶蛋白和Ⅳ型、V型胶原,在细胞外基质的降解过程中起着关键作用,能够促进肿瘤细胞发生侵袭和转移。p185HER-2/neu蛋白是一种相对分子质量185×103的跨膜糖蛋白,由HER-2/neu基因编码,属于酪氨酸激酶受体家族,p185HER-2/neu蛋白在人类多种癌症中存在扩增及过量表达,并与肿瘤的侵袭性表型及生存期短密切相关。就基质金属蛋白酶-2和p185HER-2/neu蛋白的生物学特性,与卵巢癌侵袭转移和预后的关系及MMP-2和p185HER-2/neu蛋白的研究情况等予以综述。     

窖蛋白-1在细胞增殖和肝再生中的作用

窖蛋白-1(caveolin-1,Cav-1)是组成胞膜窖(caveolae)的主要功能蛋白.作为质膜上的独立结构,胞膜窖参与多种细胞活动,如胆固醇运输、信号转导以及细胞膜的组装等.通常,窖蛋白-1可以通过其N端的窖蛋白脚手架区(caveolin scaffolding domain,CSD)寡聚细胞外信号激酶(Erk1/2)的上游蛋白,抑制Erk1/2的活化,从而抑制细胞增殖和肿瘤转移.新近研究表明,窖蛋白-1通过促进甘油三酯的储存和利用而对肝再生起重要的调控作用.因此,窖蛋白-1可能是调控肝实质细胞增殖的关键蛋白.     

飞燕草素通过Wnt/β-catenin信号通路抑制乳腺癌的机制研究

为研究飞燕草素对乳腺癌MDA-MB-231细胞Wnt/β-catenin信号通路的影响。免疫组化检测裸鼠乳腺肿瘤组织和肺组织转移瘤Ki-67及乳腺肿瘤组织蛋白水解酶超家族基质金属蛋白酶-7(matrix metallopeptidase 7,MMP-7)的表达水平;Western blot检测移植瘤Wnt/β-catenin通路β-联蛋白(β-catenin)、磷酸糖原合成酶激酶-3β(glycogen synthase kinase-3β,GSK-3β)及通路下游细胞周期相关蛋白cyclinD1、原癌基因c-myc和MMP-7的蛋白水平表达,体内外实验发现飞燕草素不仅能抑制裸鼠异种移植瘤生长及乳腺癌肿瘤组织和肺组织转移瘤Ki-67表达还可以明显降低乳腺癌MDA-MB-231细胞Wnt/β-catenin信号通路β-catenin和p-GSK-3β下游靶基因c-myc、cyclin D1和MMP-7蛋白的表达。本研究证实飞燕草素能通过抑制Wnt/β-catenin信号通路,发挥抑制乳腺癌的作用。     

Cavins: 胞膜窖相关蛋白新视野

胞膜窖 (Caveolae) 是细胞膜内陷形成的一种特殊的脂筏结构,含有丰富的胆固醇和鞘磷脂,并在调节细胞信号转导中发挥重要作用。大量的研究显示caveolae相关蛋白窖蛋白 (Caveolins) 在维持caveolae的结构及其功能的调节中发挥重要作用。然而,最近研究发现caveolae的形成同样需要另一类蛋白家族cavins蛋白家族的参与。此外,cavins蛋白家族成员之一cavin-1能够与caveolins主要成员窖蛋白-1 (Caveolin-1) 相互作用参与调节caveolae的结构和功能。文中将就近年来cavins与caveolins的关系及其在调节caveolae中的作用进行综述。     

基质金属蛋白酶抑制剂-4在大肠杆菌中的克隆与表达

基质金属蛋白酶抑制剂4(tissueinhibitorofmetalloproteinase4,TIMP4)为心脏特异性表达,在心脏代谢和肿瘤转移、侵袭过程中具有重要作用。为进一步研究其功能和作用机理,以PCR方法扩增人基质金属蛋白酶抑制剂4不含信号肽的表达序列,测序鉴定正确后,构建原核重组表达质粒pMALc2TIMP4,转化大肠杆菌,IPTG诱导阳性克隆,大量表达重组蛋白。细菌经超声破碎后,其上清中的重组蛋白经SDSPAGE初步鉴定分子量大小与理论值一致,为以后基质金属蛋白酶抑制剂4的研究创造了条件 。     

膜型基质金属蛋白酶-1的结构、功能与调节

膜型基质金属蛋白酶（membrane-type matrix metalloproteinase,MT-MMP）是一类基质金属蛋白酶家族的新成员,MT1-MMP是第一个鉴别出的膜型基质金属蛋白酶,它直接或间接降解细胞外基质中的多种成分,并对黏附分子有调节作用,被认为是MMP家族中与肿瘤侵袭关系最密切的酶,具有独特的结构、功能与调节机制.     

转化生长因子-β对基质金属蛋白酶及其组织抑制因子调控的研究进展

基质金属蛋白酶 (MMPs) 及其组织抑制因子 (TIMPs) 参与调控胞外基质 (ECM) 的降解与重建,二者的协同作用以及表达的动态平衡保证组织的生理/病理形态结构建成,并完成生长、分化、维持、降解的往复周期. 转化生长因子-β(TGF-β)通过对MMPs和TIMPs家族成员因细胞类型而异的基因表达调控作用,表现出调节ECM重建的生物学效应. TGF-β可通过激活Smad通路、促分裂原活化蛋白激酶 (MAPK) 通路,以及刺激激活蛋白-1(AP-1)复合体的形成,完成对MMPs和TIMPs基因表达的调控功能.     

乳腺浸润性导管癌中PTTG与MMP-2和MMP-9的表达及相关性

垂体瘤转化基因(PTTG)具有促进体外细胞转化和体内致瘤的能力,在乳腺癌组织中高表达,并与乳腺癌的复发和淋巴结转移有关.但PTTG能否通过调节基质金属蛋白酶(MMP-2、MMP-9)调控乳腺癌的侵袭与转移尚不清楚.本研究证明,PTTG可能因促进乳腺癌细胞中MMP-2、MMP-9分泌而在乳腺癌细胞侵袭、转移中发挥重要作用.免疫组织化学PV 9000通用型两步法显示,60例乳腺浸润性导管癌组织中,PTTG、MMP-2和MMP-9表达定位于肿瘤细胞胞浆,阳性率与周围正常乳腺组织相比,差异均具有统计学意义(P0.05).三者阳性表达均与淋巴结转移及TNM分期有关(P0.05);与患者年龄、肿瘤大小等无关(P0.05).乳腺浸润性导管癌中PTTG分别与MMP-2、MMP-9的表达呈正相关(P0.05).小RNA干扰技术干扰乳腺癌细胞株MDA-MB-231中的PTTG,Western印迹结果显示,干扰组与对照组相比,PTTG、MMP-2和MMP-9蛋白的表达水平明显下降.Transwell侵袭实验显示,干扰组肿瘤细胞体外侵袭能力明显降低(P0.01).本研究表明,PTTG可能通过促进乳腺癌细胞中MMP-2、MMP-9分泌,促进乳腺癌细胞的侵袭、转移.     

基质金属蛋白酶及其组织抑制剂研究进展

基质金属蛋白酶家族是细胞外基质降解过程中的重要酶类,组织金属蛋白酶抑制剂是基质金属蛋白酶的天然抑制物。研究证实,细胞外基质中基质金属蛋白酶及其组织抑制剂的失衡与多种病理机制有关,尤其与肿瘤的侵袭和转移密切相关。本就基质金属蛋白酶及其组织抑制剂的性质、结构以及功能进行了综述。     

Comparative analysis of caveolins in mouse and tammar wallaby: Role in regulating mammary gland function

Recent studies using the mouse showed an inverse correlation between the Caveolin 1 gene expression and lactation, and this was regulated by prolactin. However, current study using mammary explants from pregnant mice showed that while insulin (I), cortisol (F) and prolactin (P) resulted in maximum induction of the β-casein gene, FP and IFP resulted in the downregulation of Caveolin 1. Additionally, IF, FP and IFP resulted in the downregulation of Caveolin 2. Immunohistochemistry confirmed localisation of Caveolin 1 specific to myoepithelial cells and adipocytes. Comparative studies with the tammar wallaby showed Caveolin 1 and 2 had 70–80% homology with the mouse proteins. However, in contrast to the mouse, Caveolin 1 and 2 genes showed a significantly increased level of expression in the mammary gland during lactation. The regulation of tammar Caveolin 1 and 2 gene expression was examined in mammary explants from pregnant tammars, and no significant difference was observed either in the absence or in the presence of IFP.     

Caveolin internalization by heat shock or hyperosmotic shock

We investigated the cellular localization of caveolin, a landmark protein of caveolae, by indirect immunofluorescence after heat shock or hyperosmotic shock. Caveolin was internalized to the perinucleus by heat shock (43 degrees C) and relocalized in the plasma membrane after recovery of NIH3T3 cells at 37 degrees C for 4 h. The caveolin internalization was also observed after cells were exposed to hyperosmotic shock. Caveolin disappeared from detergent-insoluble complexes in the heat-shocked cells, but alkaline phosphatase was still there, suggesting that their responses to heat shock are quite different even though both of them were enriched in detergent-insoluble complexes of normal cells. Caveolin was internalized by the actin depolymerizer cytochalasin D, but not by the tubulin depolymerizer nocodazole. In addition, cellular exposure to hydrogen peroxide caused caveolin internalization along with disintegrated microfilaments and intact microtubules. Since cellular exposure to heat shock showed disintegrated microfilaments but intact microtubules, caveolin internalization might be due to depolymerized microfilaments. When cells were exposed to heat shock and allowed to recover for 4 h, actin depolymerization and caveolin internalization were not induced by a second heat shock, suggesting that some heat shock protein(s) might prevent actin depolymerization and caveolin internalization.     

Multiparametric image analysis reveals role of Caveolin1 in endosomal progression rather than internalization of EGFR

Endosomes constitute a central layer in the regulation of growth factor signaling. We applied flow cytometry, confocal microscopy and automated image quantification to define the role of Caveolin1 (Cav1) in epidermal growth factor (EGF) receptor (i) internalization and (ii) endosomal trafficking. Antisense-downregulation of Cav1 did not affect internalization of EGF:EGFR-complexes from the plasma membrane. Instead, Cav1-knockdown had a profound effect on endosomal trafficking and caused a shift in EGF vesicle distribution towards Rab7-negative compartments at late timepoints. Moreover, image quantification with single-endosome resolution revealed that EGF:Cav1-complexes undergo a maturation pattern reminiscent of late endosomes. Our data suggest a model in which Caveolin1 acts upon EGF endosomes internalized via the Clathrin-pathway and functions at the transition from early to late endosomes.     

下调窖蛋白-1表达抑制小鼠肝癌H22细胞侵袭能力

窖蛋白-1在不同肿瘤中发挥作用不同. 本研究以小鼠肝癌细胞H22为研究对象 ,观察下调窖蛋白-1表达对H22细胞侵袭能力的影响,并探讨其可能的分子机制. 利用RT－PCR和Western印迹法检测了窖蛋白-1在H22及小鼠正常肝细胞IAR20中的 表达.结果显示,窖蛋白 1在H22中的表达高于其在IAR20中的表达,提示窖蛋白 -1高表达可能与H22细胞恶性表型有关. RNA干扰和凝集素印记实验结果显示,窖 蛋白-1－siRNA能够有效抑制窖蛋白－1mRNA和蛋白表达,并抑制细胞表面N－聚糖 β1,6GlcNAc分支形成. Transwell细胞迁移和侵袭实验结果显示,与未转染组和 siRNA 对照组比较,转染窖蛋白-1 siRNA的H22细胞迁移和侵袭数目明显减少. 本研究证明,下调窖蛋白－1表达可抑制H22细胞表面N 聚糖β1,6GlcNAc分支形 成,从而抑制细胞迁移和侵袭能力.     

TC10 Is Regulated by Caveolin in 3T3-L1 Adipocytes

Background

TC10 is a small GTPase found in lipid raft microdomains of adipocytes. The protein undergoes activation in response to insulin, and plays a key role in the regulation of glucose uptake by the hormone.

Methodology/Principal Findings

TC10 requires high concentrations of magnesium in order to stabilize guanine nucleotide binding. Kinetic analysis of this process revealed that magnesium acutely decreased the nucleotide release and exchange rates of TC10, suggesting that the G protein may behave as a rapidly exchanging, and therefore active protein in vivo. However, in adipocytes, the activity of TC10 is not constitutive, indicating that mechanisms must exist to maintain the G protein in a low activity state in untreated cells. Thus, we searched for proteins that might bind to and stabilize TC10 in the inactive state. We found that Caveolin interacts with TC10 only when GDP-bound and stabilizes GDP binding. Moreover, knockdown of Caveolin 1 in 3T3-L1 adipocytes increased the basal activity state of TC10.

Conclusions/Significance

Together these data suggest that TC10 is intrinsically active in vivo, but is maintained in the inactive state by binding to Caveolin 1 in 3T3-L1 adipocytes under basal conditions, permitting its activation by insulin.     

Induction of caveolin during adipogenesis and association of GLUT4 with caveolin-rich vesicles

Caveolae, also termed plasmalemmal vesicles, are small, flask-shaped, non-clathrin-coated invaginations of the plasma membrane. Caveolin is a principal component of the filaments that make up the striated coat of caveolae. Using caveolin as a marker protein for the organelle, we found that adipose tissue is the single most abundant source of caveolae identified thus far. Caveolin mRNA and protein are strongly induced during differentiation of 3T3-L1 fibroblasts to adipocytes; during adipogenesis there is also a dramatic increase in the complexity of the protein composition of caveolin-rich membrane domains. About 10- 15% of the insulin-responsive glucose transporter GLUT4 is found in this caveolin-rich fraction, and immuno-isolated vesicles containing GLUT4 also contain caveolin. However, in non-stimulated adipocytes the majority of caveolin fractionates with the plasma membrane, while most GLUT4 associates with low-density microsomes. Upon addition of insulin to 3T3-L1 adipocytes, there is a significant increase in the amount of GLUT4 associated with caveolin-rich membrane domains, an increase in the amount of caveolin associated with the plasma membrane, and a decrease in the amount of caveolin associated with low-density microsomes. Caveolin does not undergo a change in phosphorylation upon stimulation of 3T3-L1 adipocytes with insulin. However, after treatment with insulin it is associated with a 32-kD phosphorylated protein. Caveolae thus may play an important role in the vesicular transport of GLUT4 to or from the plasma membrane. 3T3-L1 adipocytes offer an attractive system to study the function of caveolae in several cellular trafficking and signaling events.     

Caveolin; different roles for insulin signal?

Caveolae, discovered by electron microscope in the 1950s, are membrane invaginations that accommodate various molecules that are involved in cellular signaling. Caveolin, a major protein component of caveolae identified in 1990s, has been known to inhibit the function of multiple caveolar proteins, such as kinases, which are involved in cell growth and proliferation, and thus considered to be a general growth signal inhibitor. Recent studies using transgenic mouse models have suggested that insulin signal may be exempted from this inhibition, which rather requires the presence of caveolin for proper signaling. Caveolin may stabilize insulin receptor protein or directly stimulate insulin receptors. Other studies have demonstrated that caveolae provide the TC10 complex with cellular microdomains for glucose transportation through Glut4. These findings suggest that caveolin plays an important role in insulin signal to maintain glucose metabolism in intact animals. However, the role of caveolin in insulin signal may differ from that in other transmembrane receptor signals.     

Caveolin is an inhibitor of platelet-derived growth factor receptor signaling

Caveolin is a major structural component of caveolae and has been implicated in the regulation of the function of several caveolae-associated signaling molecules. Platelet-derived growth factor (PDGF) receptors and caveolin were colocalized in the same subcellular fraction after sucrose density gradient fractionation of fibroblasts. Additionally, we found that the PDGF receptors interacted with caveolin in NIH3T3 fibroblast cells. We then examined whether caveolin directly binds to PDGF receptors and inhibits kinase activity using a recombinant PDGF receptor overexpressed in insect cells and peptides derived from the scaffolding domain of caveolin subtypes. We found the peptide from caveolin-1 and -3, but not -2, inhibited the autophosphorylation of PDGF receptors in a dose-dependent manner. Similarly, caveolin-1 and -3 peptides directly bound to PDGF receptors. Mutational analysis using a series of truncated caveolin-3 peptides (20-, 17-, 14-, and 11-mer peptides) revealed that at least 17 amino acid residues of the peptide were required to inhibit and directly bind to PDGF receptors. Thus, our findings suggest that PDGF receptors directly interact with caveolin subtypes, leading to the inhibition of kinase activity. Caveolin may be another regulating factor of PDGF-mediated tyrosine kinase signaling.     

Interaction of peptides spanning the transmembrane domain of caveolin‐1 with model membranes

Caveolin‐1 has an atypical membrane‐spanning domain comprising of 34 residues. Caveolin‐1 targets to lipid droplets under certain conditions, where they are involved in signaling and cholesterol balance. In the present study, membrane association of synthetic peptides corresponding to the membrane‐spanning domain of caveolin‐1 has been investigated to obtain an insight into the topology of transmembrane region in the lipid bilayer and the effect of truncations in this sequence, as observed in the targeting to lipid droplets, by using model membranes. Fluorescence studies revealed strong association of the peptide corresponding to the membrane‐spanning domain of caveolin‐1 with anionic lipids as compared with zwitterionic lipids, which is consistent with the location of this domain in the cytoplasmic side of the plasma membrane. Association of a short 9 residue peptide corresponding to the C‐terminus of caveolin‐1 membrane‐spanning domain with lipid vesicles revealed the importance of this region for association with model membranes. Our investigations indicate that the peptide corresponding to the membrane‐spanning domain of caveolin‐1 does not span the lipid bilayer. We propose that both caveolin scaffolding domain and transmembrane segment of caveolin‐1 contribute to the strong association with the plasma membrane rendering the protein highly detergent resistant. Copyright © 2012 European Peptide Society and John Wiley & Sons, Ltd.