扣带素——调节血管内皮细胞屏障功能的新靶点

正血管内皮细胞间连接最顶端的紧密连接是构成旁细胞屏障的重要结构。紧密连接由跨膜蛋白和胞浆蛋白组成,其中胞浆蛋白作为桥梁连接跨膜蛋白和细胞骨架蛋白,因此在决定紧密连接结构的完整性中发挥了重要的作用。然而目前,关于血管内皮中特异性表达的重要胞浆蛋白的研究仍十分有限。扣带素(cingulin)是1988年发现的一种紧密连接胞浆蛋白,已有研究表明cingulin在上皮细胞中参与调控紧密连接跨膜蛋白的表达以及细胞的增殖能力。然而,cingulin在血管内皮中的作用     

原生动物的细胞骨架蛋白及其功能组件

目前在原生动物中发现了许多新的细胞骨架蛋白,如中心元蛋白、副鞭毛杆蛋白等。深入研究发现,原生动物的细胞骨架在细胞的模式形成,细胞核的遗传中也具有重要作用。从功能组件角度着眼研究细胞骨架的功能,将有助于了解细胞骨架的进化机制。     

细胞骨架相关蛋白SM22α与肿瘤

平滑肌22α（smooth muscle 22 alpha,SM22α）蛋白是一种细胞骨架相关蛋白,其在种属间的高度同源性和进化上的高度保守性提示了其重要的生物学意义。最新研究发现,SM22α在多种肿瘤组织中表达异常,该蛋白除可通过与肌动蛋白相互作用参与细胞骨架重构外,还可作为信号分子参与细胞生长,细胞外基质降解和血管生成。其作为一种新型抑癌基因,在肿瘤发生、发展中的作用日益成为人们关注的焦点。本文就SM22α的结构特征、表达特点及其与肿瘤的关系进行综述。     

细胞骨架相关蛋白SM22α与肿瘤

平滑肌22α(smooth muscle 22 alpha,SM22α)蛋白是一种细胞骨架相关蛋白,其在种属间的高度同源性和进化上的高度保守性提示了其重要的生物学意义.最新研究发现,SM22α在多种肿瘤组织中表达异常,该蛋白除可通过与肌动蛋白相互作用参与细胞骨架重构外,还可作为信号分子参与细胞生长,细胞外基质降解和血管生成.其作为一种新型抑癌基因,在肿瘤发生,发展中的作用日益成为人们关注的焦点.本文就SM22α的结构特征、表达特点及其与肿瘤的关系进行综述.     

埃兹蛋白:生物学特征及其在肿瘤转移中的作用

埃兹蛋白(ezrin)是埃兹蛋白、根蛋白和膜突蛋白(ezrin-radixin-moesin,ERM)家族成员之一,主要参与上皮细胞中细胞骨架与胞膜之间的连接,具有维持细胞形态和运动、连接黏附分子及调节信号转导等功能。近年来的研究发现,埃兹蛋白在肿瘤细胞中的表达异常,提示其在肿瘤的浸润、转移机制中发挥重要作用。     

细胞骨架--肌动蛋白纤维

20世纪60年代以来的研究发现,真核细胞质中存在着由蛋白纤维构成的复杂网络状结构——细胞骨架(cytoskeleton)。另外,植物细胞中也有细胞骨架成分。     

新型细胞骨架分隔丝的结构和功能研究进展

细胞骨架是细胞内的蛋白纤维网状结构,包括人们熟知的微管、微丝和中间纤维.目前研究表明分隔丝(septin filaments)是一类在真核生物中广泛分布的蛋白纤维,逐渐被认为是一种新型细胞骨架结构.分隔丝由可结合GTP的分隔丝蛋白单体(Septin)聚合形成异源复合体,进一步组装成纤维丝.分隔丝可形成纤维束,环状或笼状等结构,并与细胞膜或其他细胞骨架成分发生相互作用.在细胞内,分隔丝参与胞质分裂、细胞迁移、神经元发育和免疫等重要生理及病理过程.分隔丝结构或功能的异常与多种人类疾病如肿瘤等密切相关.本文将从分隔丝的结构、组装调控、功能及与人类疾病的关系等方面综述近年的研究进展.     

核膜血影重复蛋白研究进展

核膜血影重复蛋白(Nesprins)连接细胞核与多种细胞骨架和(/或)细胞器,在细胞核与细胞骨架定位、质-核间物质运输和动力传导、核膜构建、细胞迁移、锚定和极性建立等过程中发挥重要作用.本文综述核膜血影重复蛋白的发现、编码基因、结构、功能以及与相关疾病的关系研究现状,并展望潜在的未来研究动向.     

肌浆网钙泵蛋白的结构和功能及其蛋白单体的特性

肌浆网是细胞钙平衡的主要调节单位之一,是胞浆钙离子浓度异常的重要研究对象。肌浆网结构组成简单,便于分离纯化,是理想的生物膜研究模型。本文介绍了肌浆网钙泵蛋白的分子结构、钙转运分子机制和钙泵蛋白的聚集状态及磷脂结构与钙转运的关系。     

蝙蝠葛碱拮抗缓激肽引起的钙稳态改变 及细胞骨架蛋白的异常磷酸

为研究蝙蝠葛碱 (dauricine , Dau) 拮抗缓激肽 (bradykinin , BK) 诱导的 Alzheimer 样钙稳态失衡及细胞骨架蛋白异常磷酸化的作用,采用双波长荧光分光光度计测定细胞内钙离子浓度 ([Ca2+] i) ,用 MTT 法检测细胞代谢水平,用免疫组织化学方法观察 tau 蛋白表达和磷酸化 . 结果表明,Dau (3 μmol/L , 6 μmol/L) 可抑制 BK 诱导的 [Ca2+]i 升高,保护 BK 引起的神经元代谢降低,拮抗 BK 引起的 tau 蛋白异常磷酸化和聚集 . 结果提示： Dau 可拮抗 BK 诱导的 Alzheimer 样钙稳态失衡及细胞骨架蛋白异常磷酸化的作用 .     

Crystal structure of the CCTgamma apical domain: implications for substrate binding to the eukaryotic cytosolic chaperonin

The chaperonin containing TCP-1 (CCT, also known as TRiC) is the only member of the chaperonin family found in the cytosol of eukaryotes. Like other chaperonins, it assists the folding of newly synthesised proteins. It is, however, unique in its specificity towards only a small subset of non-native proteins. We determined two crystal structures of mouse CCTgamma apical domain at 2.2 A and 2.8 A resolution. They reveal a surface patch facing the inside of the torus that is highly evolutionarily conserved and specific for the CCTgamma apical domain. This putative substrate-binding region consists of predominantly positively charged side-chains. It suggests that the specificity of this apical domain towards its substrate, partially folded tubulin, is conferred by polar and electrostatic interactions. The site and nature of substrate interaction are thus profoundly different between CCT and its eubacterial homologue GroEL, consistent with their different functions in general versus specific protein folding assistance.     

Sequential ATP-induced allosteric transitions of the cytoplasmic chaperonin containing TCP-1 revealed by EM analysis

The eukaryotic cytoplasmic chaperonin containing TCP-1 (CCT) is a hetero-oligomeric complex that assists the folding of actins, tubulins and other proteins in an ATP-dependent manner. To understand the allosteric transitions that occur during the functional cycle of CCT, we imaged the chaperonin complex in the presence of different ATP concentrations. Labeling by monoclonal antibodies that bind specifically to the CCTalpha and CCTdelta subunits enabled alignment of all the CCT subunits of a given type in different particles. The analysis shows that the apo state of CCT has considerable apparent conformational heterogeneity that decreases with increasing ATP concentration. In contrast with the concerted allosteric switch of GroEL, ATP-induced conformational changes in CCT are found to spread around the ring in a sequential fashion that may facilitate domain-by-domain substrate folding. The approach described here can be used to unravel the allosteric mechanisms of other ring-shaped molecular machines.     

Gene duplication and the evolution of group II chaperonins: implications for structure and function

Chaperonins are multisubunit protein-folding assemblies. They are composed of two distinct structural classes, which also have a characteristic phylogenetic distribution. Group I chaperonins (called GroEL/cpn60/hsp60) are present in Bacteria and eukaryotic organelles while group II chaperonins are found in Archaea (called the thermosome or TF55) and the cytoplasm of eukaryotes (called CCT or TriC). Gene duplication has been an important force in the evolution of group II chaperonins: Archaea possess one, two, or three homologous chaperonin subunit-encoding genes, and eight distinct CCT gene families (paralogs) have been described in eukaryotes. Phylogenetic analyses indicate that while the duplications in archaeal chaperonin genes have occurred numerous times independently in a lineage-specific fashion, the eight different CCT subunits found in eukaryotes are the products of duplications that occurred early and very likely only once in the evolution of the eukaryotic nuclear genome. Analyses of CCT sequences from diverse eukaryotic species reveal that each of the CCT subunits possesses a suite of invariant subunit-specific amino acid residues ("signatures"). When mapped onto the crystal structure of the archaeal chaperonin from Thermoplasma acidophilum, these signatures are located in the apical, intermediate, and equatorial domains. Regions that were found to be variable in length and/or amino acid sequence were localized primarily to the exterior of the molecule and, significantly, to the extreme tip of the apical domain (the "helical protrusion"). In light of recent biochemical and electron microscopic data describing specific CCT-substrate interactions, our results have implications for the evolution of subunit-specific functions in CCT.     

Review: nucleotide-dependent conformational changes of the chaperonin containing TCP-1

Current biochemical and structural studies on the conformational changes induced by the nature of nucleotide bound to the chaperonin containing testis complex polypeptide 1 (CCT) are examined to see how consistent the data are. This exercise suggests that the biochemical and structural data are in good agreement. CCT clearly appears as a folding nano-machine fueled by ATP. A careful comparison of the biochemical and structural data, however, highlights a number of points that remain to be carefully documented in order to better understand the nature of the conformational changes in CCT that yield folded target proteins. Special effort should be made to clearly answer the points listed at the end of this review in order to obtain the dynamic sequence of events yielding folded proteins in the eukaryotic cytoplasm similar to what has been obtained for prokaryotes.     

The interaction network of the chaperonin CCT

The eukaryotic cytosolic chaperonin containing TCP-1 (CCT) has an important function in maintaining cellular homoeostasis by assisting the folding of many proteins, including the cytoskeletal components actin and tubulin. Yet the nature of the proteins and cellular pathways dependent on CCT function has not been established globally. Here, we use proteomic and genomic approaches to define CCT interaction networks involving 136 proteins/genes that include links to the nuclear pore complex, chromatin remodelling, and protein degradation. Our study also identifies a third eukaryotic cytoskeletal system connected with CCT: the septin ring complex, which is essential for cytokinesis. CCT interactions with septins are ATP dependent, and disrupting the function of the chaperonin in yeast leads to loss of CCT-septin interaction and aberrant septin ring assembly. Our results therefore provide a rich framework for understanding the function of CCT in several essential cellular processes, including epigenetics and cell division.     

The 'sequential allosteric ring' mechanism in the eukaryotic chaperonin-assisted folding of actin and tubulin

Folding to completion of actin and tubulin in the eukaryotic cytosol requires their interaction with cytosolic chaperonin CCT [chaperonin containing tailless complex polypeptide 1 (TCP-1)]. Three-dimensional reconstructions of nucleotide-free CCT complexed to either actin or tubulin show that CCT stabilizes both cytoskeletal proteins in open and quasi-folded conformations mediated through interactions that are both subunit specific and geometry dependent. Here we find that upon ATP binding, mimicked by the non-hydrolysable analog AMP-PNP (5'-adenylyl-imido-diphosphate), to both CCT-alpha-actin and CCT- beta-tubulin complexes, the chaperonin component undergoes concerted movements of the apical domains, resulting in the cavity being closed off by the helical protrusions of the eight apical domains. However, in contrast to the GroE system, generation of this closed state does not induce the release of the substrate into the chaperonin cavity, and both cytoskeletal proteins remain bound to the chaperonin apical domains. Docking of the AMP-PNP-CCT-bound conformations of alpha-actin and beta-tubulin to their respective native atomic structures suggests that both proteins have progressed towards their native states.     

The eukaryote chaperonin CCT is a cold shock protein in Saccharomyces cerevisiae

The eukaryotic Hsp60 cytoplasmic chaperonin CCT (chaperonin containing the T-complex polypeptide-1) is essential for growth in budding yeast, and mutations in individual CCT subunits have been shown to affect assembly of tubulin and actin. The present research focused mainly on the expression of the CCT subunits, CCTalpha and CCTbeta, in yeast (Saccharomyces cerevisiae). Previous studies showed that, unlike most other chaperones, CCT in yeast does not undergo induction following heat shock. In this study, messenger ribonucleic acid (mRNA) and protein levels of CCT subunits following exposure to low temperatures, were examined. The Northern blot analysis indicated a 3- to 4-fold increase in mRNA levels of CCTalpha and CCTbeta genes after cold shock at 4 degrees C. Interestingly, Western blot analysis showed that cold shock induces an increase in the CCTalpha protein, which is expressed at 10 degrees C, but not at 4 degrees C. Transfer of 4 degrees C cold-shocked cells to 10 degrees C induced a 5-fold increase in the CCTalpha protein level. By means of fluorescent immunostaining and confocal microscopy, we found CCTalpha to be localized in the cortex and the cell cytoplasm of S. cerevisiae. Localization of CCTalpha was not affected at low temperatures. Co-localization of CCT and filaments of actin and tubulin was not observed by microscopy. The induction pattern of the CCTalpha protein suggests that expression of the chaperonin may be primarily important during the recovery from low temperatures and the transition to growth at higher temperatures, as found for other Hsps during the recovery phase from heat shock.     

Structure of eukaryotic prefoldin and of its complexes with unfolded actin and the cytosolic chaperonin CCT

The biogenesis of the cytoskeletal proteins actin and tubulin involves interaction of nascent chains of each of the two proteins with the oligomeric protein prefoldin (PFD) and their subsequent transfer to the cytosolic chaperonin CCT (chaperonin containing TCP-1). Here we show by electron microscopy that eukaryotic PFD, which has a similar structure to its archaeal counterpart, interacts with unfolded actin along the tips of its projecting arms. In its PFD-bound state, actin seems to acquire a conformation similar to that adopted when it is bound to CCT. Three-dimensional reconstruction of the CCT:PFD complex based on cryoelectron microscopy reveals that PFD binds to each of the CCT rings in a unique conformation through two specific CCT subunits that are placed in a 1,4 arrangement. This defines the phasing of the CCT rings and suggests a handoff mechanism for PFD.     

Upregulation of cytosolic chaperonin CCT subunits during recovery from chemical stress that causes accumulation of unfolded proteins.

The chaperonin containing TCP-1 (CCT) is a molecular chaperone consisting of eight subunit species and assists in the folding of actin, tubulin and some other cytosolic proteins. We examined the stress response of CCT subunit proteins in mammalian cultured cells using chemical stressors that cause accumulation of unfolded proteins. Levels of CCT subunit proteins in HeLa cells were coordinately and transiently upregulated under continuous chemical stress with sodium arsenite. CCT subunit levels in several mammalian cell lines were also upregulated during recovery from chemical stress caused by sodium arsenite or a proline analogue, L-azetidine-2-carboxylic acid. Several unidentified proteins that were newly synthesized and associated with CCT were found to increase concomitantly with CCT subunits themselves and known substrates during recovery from the stress. These results suggest that CCT plays important roles in the recovery of cells from protein damage by assisting in the folding of proteins that are actively synthesized and/or renatured during this period.