细胞肥大过程中hhLIM的亚细胞定位变化及其对细胞骨架的影响

hhlim (humanheartlim)是从人胎心cDNA文库中筛选克隆的一个新基因 ,作为LIM家族的新成员参与心肌肥大的发生发展过程 .为了进一步研究hhLIM在心肌肥大发生过程中的作用 ,以C2C12细胞为研究对象 ,以心肌肥大强效刺激因子内皮素 1(ET 1)为诱导因素 ,探讨hhLIM与肌动蛋白的相互作用及其影响细胞骨架的分子机制 .RT PCR、Western印迹和细胞免疫荧光分析结果表明 ,心肌肥大刺激因子ET 1在诱导心肌肥大标志基因BNP和肌动蛋白表达的同时 ,使hhLIM蛋白在C2C12细胞胞核与胞质之间进行重新定位 .激光共聚焦显微镜观察结果显示 ,hhLIM与肌动蛋白在胞质中共定位 .蛋白分步提取、鉴定及hhLIM与F肌动蛋白结合与沉降实验证明 ,hhLIM多存在于细胞骨架及其相关蛋白部分 ,在体外可与F肌动蛋白共结合 .这些结果表明 ,胞质中的hhLIM作为细胞骨架相关蛋白与肌动蛋白相互作用 .进一步研究hhLIM与细胞骨架的关系时发现 ,hhLIM过表达可使C2C12细胞的骨架变成致密网状纤维并使其对细胞松弛素导致的细胞骨架解聚产生一定的抵抗作用 ,抑制hhLIM表达则使细胞骨架稀疏 ,结构模糊 .提示hhLIM参与细胞骨架组织及重构的机制与其结合并稳定F肌动蛋白有关 .     

钙调蛋白结合蛋白通过调节细胞骨架稳定性影响肿瘤细胞运动能力

轻链钙调蛋白结合蛋白（light-chain Caldesmon,l-CaD）是一种重要的肌动蛋白结合蛋白,普遍存在于众多非肌肉细胞中。体外研究证明,l-CaD能通过与肌动蛋白的结合起到促进原肌动蛋白（G-actin）聚合、稳定肌动蛋白纤维（F-actin）结构的作用。在磷酸化作用下,l-CaD能从肌动蛋白纤维上脱离并促进肌动蛋白纤维的解聚。该研究拟考察l-CaD在细胞内对细胞肌动蛋白骨架的调节作用,阐明l-CaD对细胞运动能力的影响,作者将天然低表达l-CaD的人源性乳腺癌细胞MCF-7作为细胞模型,在MCF-7胞内以基因转染的方式高表达外源野生型l-CaD及其磷酸化突变株A1234-CaD（不可磷酸化CaD）、D1234-CaD（完全磷酸化CaD）。首先,通过激光共聚焦扫描,探讨了l-CaD对细胞骨架重排的调节;其次,通过细胞迁移transwell阵列,检测了l-CaD对细胞迁移能力的影响;最后,在单细胞层次上测定了细胞基底牵张力、胰酶刺激下的细胞基底脱附能力,并进一步检测了l-CaD对细胞迁移子过程中细胞伸张、收缩的影响。研究结果显示,l-CaD在胞内对细胞骨架的形成有显著的调控作用。非磷酸化l-CaD主要富集在细胞骨架上,增强了细胞骨架的强度,导致细胞基底牵张力以及对胰酶的耐受性增强,但对细胞的迁移能力有显著的抑制作用;磷酸化l-CaD跟细胞骨架结合能力很弱,对细胞的运动能力没有显著影响。通过磷酸化,l-CaD起到了一个“蛋白开关”的作用,通过控制细胞骨架的解聚、重排来调节细胞的运动能力。     

α辅肌动蛋白的结构和功能

α辅肌动蛋白是近年来在细胞骨架与细胞运动研究中的热点蛋白 .目前发现有α辅肌动蛋白 1、2、3和 4四种类型 ,呈细胞或组织特异性分布 .这四种蛋白的共同结构特征是在细胞内均为反向平行的二聚体 ,并具有N末端肌动蛋白结合结构域 (ABD)、血影蛋白样中央重复结构域和C末端“EF手”结构域 .作为细胞骨架中一种重要的肌动蛋白交联蛋白 ,α辅肌动蛋白通过与其相关蛋白包括整合素 (integrins)、钙粘素 (cadherin)以及细胞信号传导通路中的信号分子等的协同作用 ,在稳定细胞粘附、调节细胞形状及细胞运动中发挥着重要作用 .因此 ,肿瘤的发生、发展和恶化与α辅肌动蛋白的结构、功能密切相关 .本文结合本实验室的研究工作 ,综述了α辅肌动蛋白家族成员的结构、功能及其与肿瘤发生的相关性 .     

高血压相关基因hrg-1在血管平滑肌细胞再分化过程中的表达及功能

研究高血压相关基因hrg 1表达与血管平滑肌细胞 (VSMC)再分化的关系及其在细胞生物学行为调节方面的作用 .采用血清饥饿培养和全反式维甲酸诱导使处于增殖状态的去分化型VSMC再分化 ,观察细胞再分化过程中HRG 1表达变化 ,并探讨其功能 .在血清饥饿和维甲酸诱导VSMC再分化过程中 ,hrg 1基因表达显著上调 ,其表达活性在诱导 2 4h达高峰之后 ,一直维持在较高水平上 ,且其表达量和变化规律与细胞收缩蛋白SMα肌动蛋白和SM2 2α相类似 .免疫共沉淀和免疫双荧光染色结果证实 ,HRG 1抗体可与SMα肌动蛋白共沉淀 ,且两者在同一细胞共定位 .用HRG 1表达质粒转染去分化型VSMC可显著抑制其迁移能力 .结果提示 ,HRG 1在胞质中以与SMα肌动蛋白相互缔合的方式存在 ,其表达与VSMC分化有关 ,该蛋白通过参与细胞骨架构成而调节VSMC收缩与迁移     

微图案技术研究MSCs几何形状对YAP定位的影响

已有研究证明,一些物理因素,如基底的硬度、几何约束等对干细胞的凋亡、增殖及分化有影响.转录因子YAP已被证实在胞外力学刺激通过细胞骨架向细胞核内传递过程中起着非常重要的作用.本研究通过微图案技术控制骨髓间充质干细胞(MSCs)的几何形状,探讨了相同面积下,7种几何形状的MSC单细胞中YAP定位情况.结果显示,当微图案限制细胞的生长时,这种几何约束促进YAP出核.进一步观察发现,在细胞骨架肌动蛋白纤维束较明显、收缩性较强的细胞内,YAP核定位仍较明显;反之,丝状肌动蛋白(F-Actin)排列松散的几何结构细胞中,YAP出核,主要定位在细胞质.通过用不同几何图案限制细胞铺展,进一步证实了细胞的几何约束可以通过肌动蛋白收缩性对YAP活性进行调控,肌动蛋白骨架对YAP的胞质、胞核转移有分子开关的作用.     

钙调蛋白结合蛋白及其磷酸化对癌细胞迁移能力的影响研究

轻链钙调蛋白结合蛋白(light-chain caldesmon,l-CaD)是一种肌动蛋白结合蛋白,它通过与肌动蛋白结合而稳定胞内微丝结构,在磷酸化作用下则能从微丝上脱离.在众多非转移性癌细胞以及永生化的正常细胞系中,l-CaD的表达量很低甚至没有,但在高迁移活性的转移性癌细胞中,l-CaD表达量显著上升,因此l-CaD可能是维持转移性癌细胞高迁移能力的重要因素.为了探索l-CaD如何调节转移性癌细胞迁移活性及其所处地位,以人源转移性乳腺癌细胞MDAMB-231作为载体,一方面,在胞内高表达外源野生型l-CaD及其磷酸化突变株,干扰胞内l-CaD的磷酸化进程,从而考察l-CaD磷酸化对细胞迁移的调节,另一方面,利用siRNA技术,抑制l-CaD在MDAMB-231细胞内的表达量,检测l-CaD对转移性癌细胞迁移活性的总体影响.通过细胞骨架荧光染色、细胞迁移小室、单细胞层次上的牵张力测定以及细胞基底脱黏附能力测定,结果显示:a.阻断MDAMB-231胞内l-CaD的磷酸化进程将显著抑制细胞的迁移能力,细胞骨架调整受阻,基底牵张力增加,细胞基底脱附能力下降;b.l-CaD表达抑制的MDAMB-231细胞失去了完...     

hhLIM的表达及其在F肌动蛋白交联中的作用

为进一步研究hhLIM的功能及其与F肌动蛋白(F-actin)之间的相互关系,利用PCR扩增hhlim基因并将其克隆到pGEX-3X表达质粒上,重组表达质粒转化宿主菌得到稳定表达的可溶性产物,表达产物经Glutathione-Sepharose亲和纯化得到纯度达90%的融合蛋白GST -hhLIM.进而研究其在F肌动蛋白交联中的作用,以鬼比环肽和细胞松弛素处理C2C12细胞,诱导细胞骨架聚合和解聚.荧光显微镜下观察, hhLIM的分布变化与细胞骨架的形态学变化具有相关性.Western印迹证实,hhLIM主要作为细胞骨架相关蛋白而分布于F肌动蛋白组分中,肌动蛋白交联实验显示,hhLIM蛋白与F肌动蛋白具有较高的亲和力,具有促进F肌动蛋白纤维的交联并将其捆聚成束的作用.结果表明,hhLIM是一种F肌动蛋白交联蛋白,通过将F肌动蛋白纤维捆聚成束而参与骨架重构     

VASP在切应力诱导的内皮细胞骨架重排中的变化

目的:探讨不同强度的稳定层流切应力对内皮细胞骨架肌动蛋白相关蛋白VASP表达、磷酸化和分布影响规律及其机制.方法:采用平行板流动腔模型,刺激培养HUVECs.免疫荧光双标显示层流下细胞中肌动蛋白重排与VASP分布变化之间的规律.RT-PCR检测VASP mRNA表达;Western blot监测VASP表达及磷酸化水平.结果:10 dyn/cm2剪切24 h后,细胞延长、长轴重排、形成顺流场排列的粗大肌动蛋白纤维丝;VASP沿肌动蛋白纤维分布,在其末端汇聚成明显的点状;10 dyn/cm2剪切1 h诱导VASPmRNA表达增加;24 h内VASP反复磷酸化、总表达量增加2 h达高峰后恢复,8 h后再次升高;cAMP抑制剂H89显著抑制切应力诱导VASP表达增加及磷酸化.结论:切应力通过cAMP/cAK途径磷酸化VASP,发挥骨架调节蛋白作用,介导血液流动引起的内皮细胞骨架重组、形态改变.     

活细胞结构力学与荧光张力检测探针

微观力学效应决定着细胞形态结构变化,胞内动力蛋白、肌球蛋白和驱动蛋白等马达分子,构成了细胞微丝微管骨架结构组装的原始驱动力.而以细胞骨架结构为支架的力学感受器,也反馈性调节着细胞力学信号及其生物学效应,组成细胞结构调控必不可缺的力学基础,两者协同调控了机体生理和病理活动.本文从生物微观力学效应和信号入手,介绍了一种基于荧光共振能量转移(FRET)原理的活细胞结构力学检测新技术,将微观结构力学变化转换为光学信号,并采用克隆技术将其插入α辅肌动蛋白、β肌动蛋白及血影蛋白等骨架及相关蛋白质,观察活细胞、组织甚至动物整体水平结构力学变化,为癌细胞侵袭转移、分裂增殖、细胞极化、反分化以及太空失重等生物物理医学研究探寻新的途径.     

肌动蛋白相关蛋白2/3复合体的结构、功能与调节

微丝参与了细胞形态维持及细胞运动等多种重要的细胞过程。微丝由肌动蛋白单体组装而成 ,肌动蛋白相关蛋白 2 / 3(Arp2 /Arp3,Arp2 / 3)复合体在微丝形成过程中起重要作用。Arp2 / 3复合体由 7个亚单位组成 ,在细胞内受到多种核化促进因子的调节 ,并与这些因子协同作用来调节肌动蛋白的核化。Arp2 / 3复合体结构、功能及调节的研究对于阐明微丝形成机制及细胞骨架与某些信号分子的关系有重要意义。     

H2-Calponin 在食管鳞癌中的表达及其与食管磷癌预后的关系

目的:探讨H_2-Calponin在食管磷癌组织中的表达及其与食管磷癌患者临床病理特征及预后的相关性。方法:利用免疫组织化学染色技术检测73例食管磷癌及相应癌旁组织中H_2-Calponin的表达情况,并分析其与食管磷癌患者临床病理参数及预后的关系。结果:H_2-calponin在食管磷癌组织中的阳性表达率为95.8%(70/73),显著高于癌旁组织(35.8%,24/67),差异具有统计学意义(p0.0001)。H_2-calponin的表达与食管癌患者的性别、年龄、肿瘤大小、浸润深度及淋巴结转移均无显著相关性,但与AJCC分期显著相关(P0.05)。H_2-calponin的表达水平影响食管癌患者预后及生存期。结论:H_2-Calponin在食管磷癌组织中呈高表达并可预示食管磷癌预后不良。     

Cytoskeletal tension regulates both expression and degradation of h2-calponin in lung alveolar cells

Calponin is an actin filament-associated regulatory protein, and its h2 isoform is expressed in lung alveolar epithelial cells under postnatal upregulation during lung development corresponding to the commencement of respiratory expansion. Consistent with this correlation to mechanical tension, the expression of h2-calponin in alveolar cells is dependent on substrate stiffness and cytoskeleton tension. The function of h2-calponin in the stability of actin cytoskeleton implicates a role in balancing the strength and compliance of alveoli. An interesting finding is a rapid degradation of h2-calponin in lung after prolonged deflation, which is prevented by inflation of the lung to the in situ expanded volume. Decreasing mechanical tension in cultured alveolar cells by reducing the dimension of culture matrix reproduced the degradation of h2-calponin. Inhibition of myosin II ATPase also resulted in the degradation of h2-calponin in alveolar cells, showing a determining role of the tension in the actin cytoskeleton. Alveolar cells statically cultured on silicon rubber membrane build high tension in the cytoskeleton corresponding to a high expression of h2-calponin. Chronic cyclic stretching of cells on the membrane did not increase but decreased the expression of h2-calponin. This finding suggests that when cellular structure adapts to the stretched dimension, cyclic relaxations periodically release cytoskeleton tension and lower the total amount of tension that the cell senses over time. Therefore, the isometric tension, other than tension dynamics, determines the expression of h2-calponin. The tension regulation of h2-calponin synthesis and degradation demonstrates a novel mechanical regulation of cellular biochemistry.     

Role of H2-calponin in regulating macrophage motility and phagocytosis

The actin cytoskeleton plays a major role in cell motility that is essential for the function of phagocytes. Calponin is an actin-associated regulatory protein. Here we report the finding of significant levels of the h2 isoform of calponin in peripheral blood cells of myeloid lineage. To study the functional significance, h2-calponin gene (Cnn2) interrupted mice were constructed. Germ line transmission of the Cnn2-flox-neo allele was obtained in chimeras from two independent clones of targeted embryonic stem cells. The insertion of the neo(R) cassette into intron 2 of the Cnn2 gene resulted in a significant knockdown of h2-calponin expression. Removing the frt-flanked neo(R) cassette by FLP1 recombinase rescued the knockdown effect. Cre recombinase-induced deletion of the loxP-flanked exon 2 eliminated the expression of h2-calponin protein. H2-calponin-free mice showed reduced numbers of peripheral blood neutrophils and monocytes. H2-calponin-free macrophages demonstrated a higher rate of proliferation and faster migration than that of h2-calponin-positive cells, consistent with a faster diapedesis of peripheral monocytes and neutrophils. H2-calponin-free macrophages showed reduced spreading in adhesion culture together with decreased tropomyosin in the actin cytoskeleton. The lack of h2-calponin also significantly increased macrophage phagocytotic activity, suggesting a novel mechanism to regulate phagocyte functions.     

h2-Calponin is regulated by mechanical tension and modifies the function of actin cytoskeleton

Calponin is an extensively studied actin-binding protein, but its function is not well understood. Among three isoforms of calponin, h2-calponin is found in both smooth muscle and non-muscle cells. The present study demonstrates that epidermal keratinocytes and fibroblast cells express significant amounts of h2-calponin. The expression of h2-calponin is cell anchorage-dependent. The levels of h2-calponin decrease when cells are rounded up and remain low when cells are prevented from adherence to a culture dish. h2-calponin expression resumes after the floating cells are allowed to form a monolayer in plastic dish. Cell cultures on polyacrylamide gels of different stiffness demonstrated that h2-calponin expression is affected by the mechanical properties of the culture matrix. When cells are cultured on soft gel that applies less traction force to the cell and, therefore, lower mechanical tension in the cytoskeleton, the level of h2-calponin is significantly lower than that in cells cultured on hard gel or rigid plastic dish. Force-expression of h2-calponin enhanced the resistance of the actin filaments to cytochalasin B treatment. Keratinocyte differentiation is accompanied by a mechanical tension-related up-regulation of h2-calponin. Lowering the tension of actin cytoskeleton by inhibiting non-muscle myosin II ATPase decreased h2-calponin expression. In contrast to the mechanical tension regulation of endogenous h2-calponin, the expression of h2-calponin using a cytomegalovirus promotor was independent of the stiffness of culture matrix. The results suggest that h2-calponin represents a novel manifestation of mechanical tension responsive gene regulation that may modify cytoskeleton function.     

Ectopic expression of H2AX protein promotes TrkA-induced cell death via modulation of TrkA tyrosine-490 phosphorylation and JNK activity upon DNA damage

We previously reported that TrkA overexpression causes accumulation of γH2AX proteins in the cytoplasm, subsequently leading to massive cell death in U2OS cells. To further investigate how cytoplasmic H2AX is associated with TrkA-induced cell death, we established TrkA-inducible cells stably expressing GFP-tagged H2AX. We found that TrkA co-localizes with ectopically expressed GFP-H2AX proteins in the cytoplasm, especially at the juxta-nuclear membranes, which supports our previous results about a functional connection between TrkA and γH2AX in TrkA-induced cell death. γH2AX production from GFP-H2AX proteins was significantly increased when TrkA was overexpressed. Moreover, ectopic expression of H2AX activated TrkA-mediated signal pathways via up-regulation of TrkA tyrosine-490 phosphorylation. In addition, suppression of TrkA tyrosine-490 phosphorylation under a certain condition was removed by ectopic expression of H2AX, indicating a functional role of H2AX in the maintenance of TrkA activity. Indeed, TrkA-induced cell death was highly elevated by ectopic H2AX expression, and it was further accelerated by DNA damage via JNK activation. These all results suggest that cytoplasmic H2AX could play an important role in TrkA-mediated cell death by modulating TrkA upon DNA damage.     

Developmentally regulated expression of calponin isoforms and the effect of h2-calponin on cell proliferation

h2-calponin is found in both smooth muscle and nonmuscle cells, and its function remains to be established. Western blots with specific monoclonal antibodies detected significant expression of h2-calponin in the growing embryonic stomach and urinary bladder and the early pregnant uterus. Although the expression of h1-calponin is upregulated in the stomach and bladder during postnatal development, the expression of h2-calponin is decreased to low levels in quiescent smooth muscle cells. To investigate a hypothesis that h2-calponin regulates the function of the actin cytoskeleton during cytokinesis, a smooth muscle-originated cell line (SM3) lacking calponin was transfected to express either sense or antisense h2-calponin cDNA and the effects on the rates of cell proliferation were examined. Both stable and transient sense cDNA-transfected cells had a significantly decreased proliferation rate compared with the antisense cDNA-transfected or nontransfected cells. Immunofluorescence microscopy showed that the force-expressed h2-calponin was associated with actin-tropomyosin microfilaments. The number of binuclear cells was significantly greater in the sense cDNA-transfected culture, in which h2-calponin was concentrated in a nuclear ring structure formed by actin filaments. The results suggest that h2-calponin may regulate cytokinesis by inhibiting the activity of the actin cytoskeleton.     

A mouse bone marrow stromal cell line, TBR-B, shows inducible expression of smooth muscle-specific genes

We established an in vitro culture system which mimicked the differentiation pathway of smooth muscle cell, using TBR-B, a bone marrow stromal cell line derived from transgenic mice harboring temperature-sensitive SV40 large T-antigen gene. TBR-B cells have the potential to express smooth muscle-specific genes including h1-calponin, h-caldesmon, SM22alpha and alpha-actin, only after cultured in the differentiation medium for 2 weeks. The differentiation state of TBR-B was well controlled by using different culture medium. Using this cell line, we also found that ascorbic acid is a potent factor inducing the expression of h1-calponin and alpha-actin. TBR-B cells will serve as a useful tool for elucidating the regulatory mechanisms of smooth muscle-specific gene expression, and for identifying compounds that regulate the differentiation state of vascular smooth muscle cells.     

Myoendothelial gap junctional signaling induces differentiation of pulmonary arterial smooth muscle cells

Myoendothelial gap junctions are involved in regulating systemic arterial smooth muscle cell phenotype and function, but their role in the regulation of pulmonary arterial smooth muscle cell (PASMC) phenotype is unknown. We therefore investigated in cocultured pulmonary arterial endothelial cells (PAECs) and PASMCs whether myoendothelial gap junctional signaling played a role in PAEC-dependent regulation of PASMC phenotype. Rat PAECs and PASMCs were cocultured on opposite sides of a porous Transwell membrane that permitted formation of heterotypic cell-cell contacts. Immunostaining showed expression of the gap junctional protein connexin 43 (Cx43) on projections extending into the membrane from both cell types. Dye transfer exhibited functional gap junctional communication from PAECs to PASMCs. PASMCs cocultured with PAECs had a more contractile-like phenotype (spindle shape and increased expression of the contractile proteins myosin heavy chain, H1-calponin, and α-smooth muscle cell-actin) than PASMCs cocultured with PASMCs or cocultured without direct contact with PAECs. Transforming growth factor (TGF)-β1 signaling was activated in PASMCs cocultured with PAECs, and the PASMC differentiation was inhibited by TGF-β type I receptor blockade. Inhibition of gap junctional communication pharmacologically or by knock down of Cx43 in PAECs blocked TGF-β signaling and PASMC differentiation. These results implicate myoendothelial gap junctions as a gateway for PAEC-derived signals required for maintaining TGF-β-dependent PASMC differentiation. This study identifies an alternative pathway to paracrine signaling to convey regulatory signals from PAECs to PASMCs and raises the possibility that dysregulation of this direct interaction is involved in the pathogenesis of hypertensive pulmonary vascular remodeling.     

A unique downregulation of h2-calponin gene expression in Down syndrome: a possible attenuation mechanism for fetal survival by methylation at the CpG island in the trisomic chromosome 21.

To understand the effect of trisomic chromosome 21 on the cause of Down syndrome (DS), DNA methylation in the CpG island, which regulates the expression of adjacent genes, was investigated with the DNAs of chromosome 21 isolated from DS patients and their parents. A methylation-sensitive enzyme, BssHII, was used to digest DNAs of chromosome 21, and the resulting DNA fragments were subjected to RLGS (restriction landmark genomic scanning). Surprisingly, the CpG island of the h2-calponin gene was shown to be specifically methylated by comparative studies with RLGS and Southern blot analysis. In association with this methylation, h2-calponin gene expression was attenuated to the normal level, although other genes in the DS region of chromosome 21 were expressed dose dependently at 1.5 times the normal level. These results and the high miscarriage rate associated with trisomy 21 embryos imply that the altered in vivo methylation that attenuates downstream gene expression, which is otherwise lethal, permits the generation of DS neonates. The h2-calponin gene detected by the RLGS procedure may be one such gene that is attenuated.