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原生动物的细胞骨架蛋白及其功能组件 总被引:1,自引:0,他引:1
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。 相似文献
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采用GFP标记技术研究钙调蛋白在活细胞中与细胞周期相关的分布 总被引:6,自引:0,他引:6
采用融合绿色荧光蛋白 (GFP)和钙调蛋白 (CaM)的方法来研究钙调蛋白在细胞周期不同阶段的分布 .首先 ,发现CaM在细胞内的分布随细胞周期的不同而改变 .CaM在G1期主要分布于细胞质中 ,在S期开始向细胞核内转移 ,并于G2期高度集中于细胞核内 .其次 ,G2期细胞核内的CaM似乎与有丝分裂的启动有关 ,因为此时抑制CaM的活性可同时抑制核膜破裂及染色质凝缩 .最后 ,发现在进入有丝分裂后 ,CaM主要集中于纺锤体靠近两极的地方 .此时 ,抑制CaM的活性会引起纺锤体结构的破坏 .同时讨论了CaM的这些特异性分布与细胞周期调控之间的关系 . 相似文献
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核纤层普遍存在于高等真核细胞的细胞核中,向外与内层核膜上的蛋白结合,向内与染色质的特定区段结合,其主要成分是核纤层蛋白。核纤层蛋白主要参与细胞核的形状和大小的维持、核膜的组织、DNA的复制及有丝分裂。近年来的研究表明,核纤层蛋白与许多人类疾病密切相关。目前,核纤层蛋白在人类的各种组织和细胞中已有比较系统的研究,并且呈组织特异性及发育时序性表达。本文将就核纤层的最新研究进展做一综述。 相似文献
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在高等动物细胞开放式有丝分裂过程中,细胞核膜会发生高度有序的周期性去组装和装配的动态变化。近年的研究结果表明是LEM家族蛋白成员通过与BAF因子相互作用介导了内核膜、核纤层蛋白以及染色体之间的相互作用。LEM蛋白、核纤层蛋白以及BAF因子直接相互作用形成的三元复合体在结构与功能上是相互依赖的,在此结构与功能上组成的网络体系是形成细胞核的一些基本生物学过程的重要条件。该复合体在调控有丝分裂M期后期和末期染色体的正常分离、有丝分裂后核膜的重组装,细胞分裂间期细胞核及核膜形态维持,调控DNA复制和DNA损伤修复,调节基因表达和信号通路以及逆转录病毒感染等方面发挥着重要的生物学功能。并且LEM蛋白相关基因的异常对核纤层疾病和肿瘤的发生发展具有重要的影响。文章主要针对LEM蛋白家族成员的结构以及功能研究进展进行了详细的综述。 相似文献
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我们的前期研究发现:被微管抑制剂nocodazole抑制在第一次有丝分裂中期的小鼠受精卵在加入6-DMAP处理后核膜重新出现,并且父、母本的基因组未发生融合,分别形成了类似雌、雄原核的两个细胞核,它们共存于卵细胞质中,我们把这种特殊的胚胎称之为PM胚胎(post-mitoticembryo)。本研究表明:在去除抑制剂3h后未能形成核膜的胚胎进一步卵裂,而形成核膜的PM胚胎培养24h未见进一步发育。此外,我们采用免疫荧光染色观察PM胚胎核膜重现过程中核纤层蛋白B的动力学变化,结果显示:在加入6-DMAP后核纤层蛋白B在染色体周围逐渐聚集,约3h后核膜完全形成,此时核纤层蛋白B在染色体周围的聚集达到最高峰。文中还对6-DMAP诱导核膜形成的机制进行了探讨。 相似文献
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以增强UV-B(10.08 kJ.m-2.d-1)辐射后的小麦根尖细胞为材料,采用间接免疫荧光标记技术,利用激光共聚焦扫描显微镜,观察分析小麦根尖分裂期细胞Ran蛋白在分裂周期的分布及形态变化。研究结果显示,正常细胞中,Ran蛋白在细胞分裂间期主要定位于核膜周边,在后期定位于赤道板上和纺锤体上,末期又回到子细胞核膜周边;增强UV-B辐射处理后,在细胞分裂间期和前期有点状荧光分布在核膜的周围;中期和后期点状荧光分布在细胞质中;在末期部分点状荧光又回到核膜的周围,部分仍分散在核内,且出现落后染色体、染色体桥、不均等分裂等染色体畸变类型和异常分裂现象。 相似文献
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早老症(Hutchinson-Gilford Progeria Syndrome,HGPS)是一种早发而严重的过早老化性疾病.它是由于编码A/C型核纤层蛋白的LMNA基因发生点突变而引起.这个突变激活了基因11号外显子上一个隐蔽的剪接位点,产生了一种被截短了50个氨基酸的A型核纤层蛋白.然而,一个广泛分布于核膜上结构蛋白的突变,如何引起HGPS患者的早老表现,目前还不太清楚.最近研究发现,HGPS患者的细胞核结构与功能发生了各种异常,主要表现在:progerin蓄积与核变形、细胞核机械性质的改变、组蛋白修饰方式与外遗传控制的改变、基因表达调控异常、p53信号传导通路激活和基因组不稳定等方面.目前存在机械应激假说和基因表达失控假说两种假说解释HGPS的发病机制.对于HGPS患者,尚无有效的临床干预措施,但有学者提出了一些治疗策略,如应用法尼基化的抑制剂、反义寡核苷酸和RNA干扰方法.HGPS被认为是研究正常衰老机制的一个模型.对HGPS深入研究将有助于阐明A型核纤层蛋白和核膜的正常生理功能,及其在生理衰老和疾病中的作用. 相似文献
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范丽菲 《中国生物化学与分子生物学报》2013,29(5):448-456
Rif(Rho in filopodia)作为Rho小G蛋白家族的一员在调节细胞骨架形态方面有多种作用,可以同时介导压力纤维(stress fibers)和丝状伪足(filopodia)结构的形成.为了进一步研究Rif分子的功能, 通过蛋白质组学的方法在高表达内源性Rif蛋白的HeLa细胞中寻找其新的相互作用蛋白.通过分析,发现了Rif与输出蛋白5(exportin 5)等几个核质蛋白存在潜在的相互作用.实验证明,Rif与输出蛋白5的相互作用是核苷酸依赖性的,并且这种相互作用可以将细胞质中存在的输出蛋白5转运回细胞核内.这些发现揭示了小G蛋白Rif可能作为核质大分子运输载体的新功能. 相似文献
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Providing a stable physical connection between the nucleus and the cytoskeleton is essential for a wide range of cellular functions and it could also participate in mechanosensing by transmitting intra- and extra-cellular mechanical stimuli via the cytoskeleton to the nucleus. Nesprins and SUN proteins, located at the nuclear envelope, form the LINC (linker of nucleoskeleton and cytoskeleton) complex that connects the nucleus to the cytoskeleton; underlying nuclear lamins contribute to anchoring LINC complex components at the nuclear envelope. Disruption of the LINC complex or loss of lamins can result in disturbed perinuclear actin and intermediate filament networks and causes severe functional defects, including impaired nuclear positioning, cell polarization and cell motility. Recent studies have identified the LINC complex as the major force-transmitting element at the nuclear envelope and suggest that many of the aforementioned defects can be attributed to disturbed force transmission between the nucleus and the cytoskeleton. Thus mutations in nesprins, SUN proteins or lamins, which have been linked to muscular dystrophies and cardiomyopathies, may weaken or completely eliminate LINC complex function at the nuclear envelope and result in impaired intracellular force transmission, thereby disrupting critical cellular functions. 相似文献
12.
KASH 'n Karry: the KASH domain family of cargo-specific cytoskeletal adaptor proteins 总被引:1,自引:0,他引:1
Starr DA Fischer JA 《BioEssays : news and reviews in molecular, cellular and developmental biology》2005,27(11):1136-1146
A diverse family of proteins has been discovered with a small C-terminal KASH domain in common. KASH domain proteins are localized uniquely to the outer nuclear envelope, enabling their cytoplasmic extensions to tether the nucleus to actin filaments or microtubules. KASH domains are targeted to the outer nuclear envelope by SUN domains of inner nuclear envelope proteins. Several KASH protein genes were discovered as mutant alleles in model organisms with defects in developmentally regulated nuclear positioning. Recently, KASH-less isoforms have been found that connect the cytoskeleton to organelles other than the nucleus. A widened view of these proteins is now emerging, where KASH proteins and their KASH-less counterparts are cargo-specific adaptors that not only link organelles to the cytoskeleton but also regulate developmentally specific organelle movements. 相似文献
13.
The cytoskeleton is connected to the nuclear interior by LINC (linker of nucleoskeleton and cytoskeleton) complexes located in the nuclear envelope. These complexes consist of SUN proteins and nesprins present in the inner and outer nuclear membrane respectively. Whereas SUN proteins can bind the nuclear lamina, members of the nesprin protein family connect the nucleus to different components of the cytoskeleton. Nesprin-1 and -2 can establish a direct link with actin filaments, whereas nesprin-4 associates indirectly with microtubules through its interaction with kinesin-1. Nesprin-3 is the only family member known that can link the nuclear envelope to intermediate filaments. This indirect interaction is mediated by the binding of nesprin-3 to the cytoskeletal linker protein plectin. Furthermore, nesprin-3 can connect the nucleus to microtubules by its interactions with BPAG1 (bullous pemphigoid antigen 1) and MACF (microtubule-actin cross-linking factor). In contrast with the active roles that nesprin-1, -2 and -4 have in actin- and microtubule-dependent nuclear positioning, the role of nesprin-3 is likely to be more passive. We suggest that it helps to stabilize the anchorage of the nucleus within the cytoplasm and maintain the structural integrity and shape of the nucleus. 相似文献
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The nuclear envelope has traditionally been thought of as a barrier that separates the nucleoplasm from the cytoplasm in eukaryotic cells. Increasing evidence shows that the nuclear envelope also links the inside of the nucleus to the cytoskeleton. Here we discuss recent papers showing that this link occurs through complexes of lamins on the inner aspect of the inner nuclear membrane, transmembrane proteins of the inner nuclear membrane called SUNs and large nesprin isoforms localized specifically to the outer nuclear membrane. These discoveries have implications for nuclear positioning, nuclear migration and pathogenesis of inherited diseases that are caused by mutations in nuclear envelope proteins. 相似文献
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The novel SUN-domain family of nuclear envelope proteins interacts with various KASH-domain partners to form SUN-domain-dependent 'bridges' across the inner and outer nuclear membranes. These bridges physically connect the nucleus to every major component of the cytoskeleton. SUN-domain proteins have diverse roles in nuclear positioning, centrosome localization, germ-cell development, telomere positioning and apoptosis. By serving both as mechanical adaptors and nuclear envelope receptors, we propose that SUN-domain proteins connect cytoplasmic and nucleoplasmic activities. 相似文献
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Subcellular mobility, positioning, and directional movement of the nucleus in a certain site of the cell or cenocyte and, less frequently, intercellular translocation of the nucleus accompany the cell and tissue differentiation, change of their functions, and the organism growth and development and its response to stress, plant–microbial interactions, symbiosis, and many other processes in plants and animals. The nucleus movement is performed and directed through the interaction between dynamic cytoskeleton components and nucleus by means of signal-binding proteins, including motor and linker. The cell responds to the external signal by mobilization and polar reconstruction of the cytoskeleton components, as a result of which the nucleus displacement by means of actomyosin or microtubule mechanisms in cooperation with dynein and kinesin occurs. In plants, the actomyosin mechanism is involved in the nucleus migration; it allows the nucleus to move rapidly and over significant distances in response to environmental stimuli. An important role in the nucleus translocation belongs to the linker complexes of the proteins that are inserted in the nuclear envelope, that connect and transmit signals from the plasmalemma to the cytoplasm and nucleoplasm, and that provide the skeletal basis for many subcellular compartments. Changes in the protein composition, conformational modifications of the proteins, and displacement of linkers from the nuclear envelope result in the nucleus detachment from the cytoskeleton, and change in the form, mechanical rigidity, and positioning of the nucleus. 相似文献
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In the cytosol, actin polymers, intermediate filaments and microtubules can anchor to cell surface adhesions and interlink to form intricate networks. This cytoskeleton is anchored to the nucleus through LINC (links the nucleoskeleton and cytoskeleton) complexes that span the nuclear envelope and in turn anchor to networks of filaments in the nucleus. The metazoan nucleoskeleton includes nuclear pore-linked filaments, A-type and B-type lamin intermediate filaments, nuclear mitotic apparatus (NuMA) networks, spectrins, titin, 'unconventional' polymers of actin and at least ten different myosin and kinesin motors. These elements constitute a poorly understood 'network of networks' that dynamically reorganizes during mitosis and is responsible for genome organization and integrity. 相似文献
18.
Starr DA 《Molecular bioSystems》2007,3(9):583-589
In most eukaryotic cells, the nucleus is localized to a specific location. This highlight article focuses on recent advances describing the mechanisms of nuclear migration and anchorage. Central to nuclear positioning mechanisms is the communication between the nuclear envelope and the cytoskeleton. All three components of the cytoskeleton-microtubules, actin filaments and intermediate filaments-are involved in nuclear positioning to varying degrees in different cell types. KASH proteins on the outer nuclear membrane connect to SUN proteins on the inner nuclear membrane. Together they transfer forces between the cytoskeleton and the nuclear lamina. Once at the outer nuclear membrane, KASH proteins can interact with the cytoskeleton. Nuclear migrations are a component of many cellular migration events and defects in nuclear positioning lead to human diseases, most notably lissencephaly. 相似文献
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Hyungsuk Lee William J Adams Patrick W Alford Megan L McCain Adam W Feinberg Sean P Sheehy Josue A Goss Kevin Kit Parker 《Experimental biology and medicine (Maywood, N.J.)》2015,240(11):1543-1554
Mechanical stresses on the myocyte nucleus have been associated with several diseases and potentially transduce mechanical stimuli into cellular responses. Although a number of physical links between the nuclear envelope and cytoplasmic filaments have been identified, previous studies have focused on the mechanical properties of individual components of the nucleus, such as the nuclear envelope and lamin network. The mechanical interaction between the cytoskeleton and chromatin on nuclear deformability remains elusive. Here, we investigated how cytoskeletal and chromatin structures influence nuclear mechanics in cardiac myocytes. Rapid decondensation of chromatin and rupture of the nuclear membrane caused a sudden expansion of DNA, a consequence of prestress exerted on the nucleus. To characterize the prestress exerted on the nucleus, we measured the shape and the stiffness of isolated nuclei and nuclei in living myocytes during disruption of cytoskeletal, myofibrillar, and chromatin structure. We found that the nucleus in myocytes is subject to both tensional and compressional prestress and its deformability is determined by a balance of those opposing forces. By developing a computational model of the prestressed nucleus, we showed that cytoskeletal and chromatin prestresses create vulnerability in the nuclear envelope. Our studies suggest the cytoskeletal–nuclear–chromatin interconnectivity may play an important role in mechanics of myocyte contraction and in the development of laminopathies by lamin mutations. 相似文献
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