高分子量激肽原富含组氨酸区域抑制细胞伸展的机制分析

活化型高分子量激肽原 (activehighmolecularweightkininogen ,HKa)是组织培养板上体外连接蛋白 (vitronectin ,VN)促使细胞伸展的潜在抑制物 ,已证实轻链的富含组氨酸区域 (histidine richdomain ,HRD)是HKa抗细胞伸展的活性区域 .HK的重组HRD (r HRD)能够促使成纤维细胞伸展 .通过基于HRD序列的选择肽分析 ,定位了HRD的细胞伸展序列 .5个肽中的 3个能够使TIG 3细胞伸展 .P 1肽引起的细胞伸展能够被可溶性P 5肽或HKa所抑制 .P 2肽不能抑制P 1或P 5肽引起的细胞伸展 .r HRD以及 3种肽介导的细胞伸展能够被RGD合成肽以及抗αvβ3或α5β1整合素抗体所抑制 .结果提示 ,选择肽引起的细胞伸展是由整合素介导的 ,尽管此区域不含有RGD序列     

白介素-1 β通过JNK/p38信号-转导通路调控肾系膜细胞表达α-平滑肌肌动蛋白

为探讨细胞内丝裂素原活化蛋白激酶（MAPK）家族各亚类信号转导通路在炎症性细胞因子白介素－1β（IL－1β）对大鼠肾系膜细胞（rMC)表型标志物α-平滑肌肌动蛋白（α－SMA）表达及其分布中的调控作用,以IL－1β（10ng/ml)刺激体外培养的rMC,用电穿孔基因转染及免疫杂交法观察IL－1β对α－SMA基因启动子活性及蛋白表达的作用,并用共聚焦荧光显微镜及透射电镜观察IL－1β刺激前后细胞内α-SMA及微丝的分布变化。通过应用PD98059和SB203580特异阻断ERK和p38通路、共转染显性失活JNKK基因特异阻断JNK通路,观察阻断对IL－1β刺激所致α-SMA表达或启动子活性的影响。结果显示,IL－1β刺激6h可明显上调α－SMA启动子活性,在1－2d内显著促进其蛋白合成;IL－1β刺激24h后,细胞内α-SMA及微丝在细胞核周的分布增加。阻断ERK通路对IL－1β诱导的α-SMA表达无明显影响;阻断JNK及p38通路均可使IL－1β诱导的α－SMA表达明显受抑;阻断p38通路的作用比阻断JNK通路更强,而且对基础状态的α-SMA表达也有抑制作用。上述结果提示,IL－1β可刺激rMC发生表型转化,其表型标志物α－SMA可通过基因转录增强而增加蛋白表达,在细胞内的分布向核周转位积聚。JNK及p38通路是介导IL－1β刺激rMC α-SMA表达的主要信号转导途径,而ERK通路不影响IL－1β的这一作用。     

整合素活化及其介导的黏着斑成熟与肿瘤转移

整合素是一类由α和β两个亚基组成的异源二聚体单次跨膜细胞黏附分子,通过与其对应配体相互作用,介导细胞与细胞、细胞与胞外基质之间的黏附,同时可以将细胞外信号传递至胞内,并招募一系列胞内蛋白与整合素胞内段结合,在细胞膜上形成超分子结构,激活下游信号。整合素的活化进程伴随着其胞外结构域由折叠构象转变为伸展构象以及胞内结构域的彼此分离。在细胞迁移过程中,整合素参与黏着斑的形成,连接胞外基质和细胞骨架,传递胞内-胞外的力学信号驱使细胞迁移。肿瘤微环境介导的整合素活化可促进多种类型细胞向肿瘤部位迁移,共同实现血管生成及肿瘤转移。本文对整合素的活化过程,其介导黏着斑动态变化引发的细胞迁移及对肿瘤转移的影响进行综述。     

RhoA-Rho激酶信号转导通路参与TGF-β1诱导的血管外膜成纤维细胞表型转化为肌成纤维细胞(英文)

血管外膜成纤维细胞表型转化为肌成纤维细胞是血管重塑的重要病理特征。本研究旨在探讨小分子G蛋白RhoA及其下游Rho激酶信号通路在转化生长因子β1(transforming growth factor β1,TGF-β1)诱导的血管外膜成纤维细胞/肌成纤维细胞表型转化中的作用。用10ng/mLTGF-β1诱导体外培养的大鼠胸主动脉外膜成纤维细胞表型转化为肌成纤维细胞,使用亲和沉淀法检测RhoA活性、使用免疫印迹检测RhoA、Rho激酶蛋白表达和Rho激酶活性;使用免疫印迹和免疫细胞化学检测肌成纤维细胞标记蛋白的表达。结果显示,TGF-β1上调体外培养的血管外膜成纤维细胞RhoA蛋白表达和RhoA活性。TGF-β1增加Rho激酶下游底物肌球蛋白磷酸酶目标亚单位的磷酸化,但不改变Rho激酶的蛋白表达,提示TGF-β1增加Rho激酶活性。腺病毒Ad-N19RhoA-hrGFP感染和Rho激酶特异性抑制剂Y27632都呈剂量依赖性地抑制TGF-β1诱导的肌成纤维细胞标记分子α平滑肌肌动蛋白和钙结合蛋白Calponin的蛋白表达。本研究证明RhoA-Rho激酶信号通路参与了TGF-β1诱导的血管外膜成纤维细胞/肌成纤维细胞表型转化。     

整合素去活化的调控机制

整合素(integrin)是一类重要的细胞表面黏附分子,是由α和β两个亚基通过非共价键组成的异源二聚体,对于免疫反应、免疫细胞的组织定位、凝血、组织愈伤、癌细胞转移以及组织和器官的发育等都至关重要。整合素的功能依赖于对其配体结合的亲和性及其所介导的信号转导的动态调控,整合素活化受阻或是过度活化都会引发多种疾病。目前,对整合素的活化机制的了解比较深入,研究发现,整合素活化的最终步骤是由talin和kindlin等胞内调控蛋白结合β亚基胞内段引起的;但是对于调控整合素去活化的机制了解较少。该文重点介绍了负调控整合素活化的蛋白分子及相关分子机制。     

整合素αVβ3与病毒感染

整合素αvβ3是一类表达于细胞表面的跨膜糖蛋白粘附分子,由α和β两种Ⅰ型膜蛋白亚单位以非共价键形式连接形成异源二聚体分子。整合素αvβ3可表达于多种细胞,细胞外信号通过不同分子可与其发生相互作用,经整合素αvβ3将细胞外信号传递至细胞内,引起钙离子、Pyk2和磷脂酰肌醇-3(PI-3)激酶等细胞内信号发生变化。整合素αvβ3在血管生成、胚胎发育、肿瘤转移、免疫应答等多种生理和病理过和中发挥着重要的作用。近几年,整合素αvβ3与病毒感染的相关研究进展迅速,本文就整合素αvβ3与病毒感染作一综述。1整合素αvβ3概述1·1整合素αv…     

RhoA蛋白和cAMP对人前列腺癌细胞株PC-3形态的影响(简报)

小G蛋白RhoA是细胞内信号转导的重要成分,参与对细胞的多种功能活动的调控。溶血磷脂酸(lysophosphatidicacid,LPA)与多种细胞的G蛋白偶连受体结合而发挥作用,除刺激细胞增殖外,还通过活化RhoA,诱导细胞骨架改变。cAMP是经典的第二信使,其下游激酶PKA可抑制RhoA活性,因此,cAMP在许多细胞活动中对RhoA有拮抗作用。本实验采用人前列腺癌细胞株PC-3,以绿色荧光蛋白(GreenFluorescentProtein,GFP)分别和不同RhoA结构(野生型RhoA、RhoA63L和RhoA188A)的cDNA共同转染细胞,在显微镜下(200倍视野)观察记录未转染细胞和转染细胞在LPA和cAMP作用下的形态变化,研究RhoA和cAMP/PKA介导的信号转导在调控癌细胞形态改变中的作用。     

整合素介导的细胞信号转导研究进展

整合素是细胞表面重要的受体,介导细胞-细胞和细胞-细胞外基质(extracellular matrix,ECM)的粘附。整合素通过与ECM配体结合可活化特定的信号转导途径,引起细胞发生反应,包括形态改变、伸展、迁移、增殖、分化、存活等,从而决定了与细胞粘附相关的多种生物学功能。因此,对整合素介导的信号转导过程的认识将有助于人们对细胞粘附机制和功能的理解。     

噬菌体展示技术构建和表达抗人整合素β1单链Fv抗体

整合素（Integrins）是细胞膜蛋白的组成成分,它们是一类细胞粘附分子,并与形态形成的调节密切相关。整合素在细胞与细胞之间,细胞与基质之间的粘附中发挥着重要的作用。本研究通过选择使用鼠抗人整合素β1抑止性单克隆抗体和刺激性单克隆抗体,利用噬菌体展示,成功地构建了单链Fv抗体（scFv）,并对其与整合素β1的结合,选择最佳的可溶性抗体的生产条件等诸方面,进行了应用性研究,同时,也应用链转换（Chain shuffling）试图改变抗体亲和力进行了探索性的试验。     

骨桥蛋白趋化和趋触作用对FAK和ILK磷酸化修饰的影响

为探讨可溶性(趋化作用)或锚定(趋触作用)形式的骨桥蛋白(OPN)与整合素相互作用对下游信号分子黏着斑激酶(FAK)和整合素偶联激酶(ILK)磷酸化修饰的影响,分别用包被于培养瓶上锚定型或加在培养液中的可溶性OPN刺激血管平滑肌细胞(VSMC)后,观察FAK和ILK的磷酸化及FAK与ILK相互作用的变化。结果显示,包被于培养瓶上的OPN通过趋触作用促进VSMC黏附和伸展,接种45min时,黏附细胞数达对照组的2.4倍(P<0.05);OPN的趋触及趋化作用均可诱导FAK磷酸化、ILK去磷酸化并抑制FAK与ILK结合;转染可表达整合素β3亚单位胞内区的表达质粒pEGFP-C3-β3CD能阻断OPN与整合素相互作用所引发的FAK磷酸化及ILK去磷酸化。研究结果表明,OPN的趋触和趋化作用对整合素下游信号分子FAK和ILK的影响是一致的,且这些作用是由整合素β3亚单位胞内区所介导的。     

特异性下调葡萄糖调节蛋白78表达对肝细胞癌侵袭和转移能力的影响

为了研究特异性下调葡萄糖调节蛋白(Grp)78对肝细胞癌侵袭和转移能力的影响。通过小干扰RNA(siRNA)技术特异性下调人肝细胞癌细胞株BEL7402中Grp78的表达,并应用Transwell法和划痕法对肝细胞癌侵袭、转移能力的改变进行分析,应用免疫沉淀技术和GST-pulldown技术分别对黏着斑激酶(FAK)的磷酸化水平和小GTPase RhoA的活性进行研究,应用免疫印迹技术检测E-钙黏着蛋白、N-钙黏着蛋白和波形蛋白的表达。结果发现,Transwell实验和划痕实验结果显示特异性下调Grp78表达可以抑制肝细胞癌的侵袭和转移,免疫沉淀结果显示特异性下调Grp78表达可以降低FAK的磷酸化水平,GST-pulldown实验结果表明特异性下调Grp78表达可以上调RhoA的活性。免疫印迹实验结果表明特异性下调Grp78可以下调N-钙黏着蛋白、波形蛋白的表达,上调E-钙黏着蛋白的表达。结果表明特异性下调Grp78在体外可以抑制肝细胞癌的侵袭和转移,这种抑制作用是通过FAK脱磷酸化和抑制肿瘤的上皮-间叶转化实现的。     

RhoA在上皮性卵巢癌细胞中的表达与侵袭性的相关性

培养上皮性卵巢癌细胞H08910PM、H08910及正常卵巢上皮细胞HOSEA 3种细胞.对3种细胞分别采用免疫细胞化学法检测RhoA的表达、Transwell小室体外侵袭试验测定体外侵袭能力、与人脐静脉内皮细胞HUVEC建立细胞共培养系统测定血管形成能力.结果表明,RhoA在H08910PM细胞中表达最强,在H08910中次之,在HOSEA中最弱;3种细胞的侵袭能力以H08910PM最强,H08910较弱,HOSEA无侵袭能力;H08910PM的血管形成能力最强,H08910其次,HOSEA无血管形成能力(P<0.01).Pearson相关分析结果显示,RhoA表达水平分别与细胞侵袭能力及血管形成能力呈正相关(P<0.05).RhoA在上皮性卵巢癌细胞中表达水平越高,细胞体外侵袭及血管形成能力随之更强.RhoA可能作为重要因子参与上皮性卵巢癌的侵袭转移过程.     

Accurate and reproducible measurements of RhoA activation in small samples of primary cells

Rho GTPase activation is essential in a wide variety of cellular processes. Measurement of Rho GTPase activation is difficult with limited material, such as tissues or primary cells that exhibit stringent culture requirements for growth and survival. We defined parameters to accurately and reproducibly measure RhoA activation (i.e., RhoA-GTP) in cultured primary keratinocytes in response to serum and growth factor stimulation using enzyme-linked immunosorbent assay (ELISA)-based G-LISA assays. We also established conditions that minimize RhoA-GTP in unstimulated cells without affecting viability, allowing accurate measurements of RhoA activation on stimulation or induction of exogenous GTPase expression.     

Inhibitory role of RhoA on senescence-like growth arrest by a mechanism involving modulation of phosphatase activity

Recently, negative effects of phosphatase in tumorigenesis and metastasis have been suggested in various tumor types. In this study, we showed that RhoA activation modulated phosphatase during senescence-like arrest in human prostate cancer cells. Under senescence-inducing condition, decreased Erk phosphorylation was detected in caRhoA-transfected cells and inactivation of Erk, but not p38, prevented doxorubicin-induced cell senescence. Cells were induced to senescence by inhibition of phosphatase activity (VHR, MKP3, or PP2A) without additional cellular stress. Of interest, caRhoA prevented doxorubicin-induced decrease of phosphatase. Thus, we postulate that RhoA signaling may protect cells against cellular senescence by maintaining phosphatase activity and Erk dephosphorylation.     

ROCK与动脉粥样硬化

Rho相关的卷曲螺旋型蛋白激酶（Rho—associated,coiled-coil containing protein kinase,ROCK）是ras同源家族RhoA（ras homolog family memberA）T游的靶蛋白之一,主要功能是调节肌动蛋白细胞骨架的活动,如细胞粘附、细胞运动、细胞迁移及细胞收缩。实验及临床研究表明R0cK可能与多种心血管疾病如高血压、肺动脉高压、动脉粥样硬化以及脑血管疾病有着很大相关性。此篇综述将总结近期对于RhoA／ROCK通路在调控血管功能中的关键作用并探讨其对于动脉粥样硬化相关疾病的潜在治疗价值。     

Partially Purified RhoA-Stimulated Phospholipase D Activity Specifically Binds to Phosphatidylinositol 4,5-Bisphosphate

Abstract: Phosphatidylinositol 4,5-bisphosphate (PIP₂) is absolutely required for the ADP-ribosylation factor-stimulated phospholipase D (PLD) activity. In the present study, partially purified rat brain PLD was found to be activated by another PLD activator, RhoA, when PIP₂, but not other acidic phospholipids, was included in vesicles comprising phosphatidylethanolamine (PE) and the PLD substrate phosphatidylcholine (PC) (PE/PC vesicles), demonstrating the absolute requirement of PIP₂ for the RhoA-stimulated PLD activation, too. It is interesting that the RhoA-dependent PLD activity in the partially purified preparation was drastically decreased after the preparation was incubated with and separated from PE/PC vesicles containing PIP₂. The PLD activity was extracted by higher concentrations of NaCl from the vesicles containing PIP₂ that were incubated with and then separated from the partially purified PLD preparation. These results demonstrate that RhoA-dependent PLD binds to PE/PC vesicles with PIP₂. The degree of binding of the RhoA-dependent PLD activity to the vesicles was totally dependent on the amount of PIP₂ in the vesicles and correlated well with the extent of the enzyme activation. Furthermore, it was found that a recombinant peptide of the pleckstrin homology domain of β-adrenergic receptor kinase fused to glutathione S-transferase, which specifically binds to PIP₂, inhibited the PIP₂-stimulated, RhoA-dependent PLD activity in a concentration-dependent manner. From these results, it is concluded that in vitro rat brain PLD translocates to the vesicles containing PIP₂, owing to its specific interaction with PIP₂, to access its substrate PC, thereby catalyzing the hydrolysis of PC. PLD appears to localize exclusively on plasma membranes of cells and tissues. An aminoglycoside, neomycin, that has high affinity for PIP₂ effectively extracted the RhoA-dependent PLD activity from rat brain membranes. This indicates that PIP₂ serves as an anchor to localize PLD on plasma membranes in vivo.     

The small GTPase RhoA is crucial for MC3T3‐E1 osteoblastic cell survival

Prolongation of cell survival through prevention of apoptosis is considered to be a significant factor leading to anabolic responses in bone. The current studies were carried out to determine the role of the small GTPase, RhoA, in osteoblast apoptosis, since RhoA has been found to be critical for cell survival in other tissues. We investigated the effects of inhibitors and activators of RhoA signaling on osteoblast apoptosis. In addition, we assessed the relationship of this pathway to parathyroid hormone (PTH) effects on apoptotic signaling and cell survival. RhoA is activated by geranylgeranylation, which promotes its membrane anchoring. In serum‐starved MC3T3‐E1 osteoblastic cells, inhibition of geranylgeranylation with geranylgeranyl transferase I inhibitors increased activity of caspase‐3, a component step in the apoptosis cascade, and increased cell death. Dominant negative RhoA and Y27632, an inhibitor of the RhoA effector Rho kinase, also increased caspase‐3 activity. A geranylgeranyl group donor, geranylgeraniol, antagonized the effect of the geranylgeranyl tranferase I inhibitor GGTI‐2166, but could not overcome the effect of the Rho kinase inhibitor. PTH 1‐34, a potent anti‐apoptotic agent, completely antagonized the stimulatory effects of GGTI‐2166, dominant negative RhoA, and Y27632, on caspase‐3 activity. The results suggest that RhoA signaling is essential for osteoblastic cell survival but that the survival effects of PTH 1‐34 are independent of this pathway. J. Cell. Biochem. 106: 896–902, 2009. © 2009 Wiley‐Liss, Inc.     

thoA介导的细胞骨架在肿瘤发生发展中的作用

RhoA是Ras超家族中具有GTP酶活性的一种小G蛋白分子。RhoA在肿瘤组织的高表达与肿瘤的恶性程度密切相关。另外,RhoA的酶活性通过信号通路参与和调节微丝（microfilament,MF）和微管（microtubule,MT）细胞骨架的重排。新近研究表明,活性RhoA调控细胞骨架改变,进而诱导细胞癌变及肿瘤细胞增殖、入侵、转移、屏障功能和凋亡等多种生命活动。因此,研究RhoA介导的细胞骨架在肿瘤发生发展中的作用具有重要意义。该文结合作者的最新研究成果,对RhoA及其分子机制作一综述。     

The emergence of ECM mechanics and cytoskeletal tension as important regulators of cell function

The ability to harvest and maintain viable cells from mammalian tissues represented a critical advance in biomedical research, enabling individual cells to be cultured and studied in molecular detail. However, in these traditional cultures, cells are grown on rigid glass or polystyrene substrates, the mechanical properties of which often do not match those of the in vivo tissue from which the cells were originally derived. This mechanical mismatch likely contributes to abrupt changes in cellular phenotype. In fact, it has been proposed that mechanical changes in the cellular microenvironment may alone be responsible for driving specific cellular behaviors. Recent multidisciplinary efforts from basic scientists and engineers have begun to address this hypothesis more explicitly by probing the effects of ECM mechanics on cell and tissue function. Understanding the consequences of such mechanical changes is physiologically relevant in the context of a number of tissues in which altered mechanics may either correlate with or play an important role in the onset of pathology. Examples include changes in the compliance of blood vessels associated with atherosclerosis and intimal hyperplasia, as well as changes in the mechanical properties of developing tumors. Compelling evidence from 2-D in vitro model systems has shown that substrate mechanical properties induce changes in cell shape, migration, proliferation, and differentiation, but it remains to be seen whether or not these same effects translate to 3-D systems or in vivo. Furthermore, the molecular “mechanotransduction” mechanisms by which cells respond to changes in ECM mechanics remain unclear. Here, we provide some historical context for this emerging area of research, and discuss recent evidence that regulation of cytoskeletal tension by changes in ECM mechanics (either directly or indirectly) may provide a critical switch that controls cell function.