四膜虫细胞的核骨架及类中间纤维

采用非树脂包埋去包埋剂超薄切片结合选择性生抽提方法显示,原生动物四膜虫细胞大核具有发达的核骨架纤维网络,核周是一层完整的核纤层结构,在四膜虫细胞小核中,亦存在核骨架和核纤层。四膜虫细胞皮层中存在水下溶性纤维网架,其中含有类中间纤维蛋白组分,４９ＫＤ蛋白。     

衣藻(Chlamydomonas sp)中间纤维及核纤层存在的证实(简报)

衣藻(Chlamydomonas sp)是属于绿藻门的最低等单细胞植物,为典型的真核生物。迄今以衣藻为材料所作的有关细胞骨架方面的研究多集中在微管蛋白(tubulin)。C.J.Miller等曾以衣藻(Chlamydomonas reinhardtii)全蛋白与几种中间纤维抗体进行免疫印迹实验有阳性反应,但是衣藻中是否存在中间纤维与核纤层是不清楚的问题。衣藻中间纤维与核纤层的形态研究更未见报道。目前认为中间纤维-核纤     

PtK2细胞的核骨架—核纤层—中间纤维体系

本文用选择性系列抽提的方法结合整装细胞电技术和ＤＧＤ包埋－去包埋超薄切片技术,在电镜下清晰地显示了ＰｔＫ细胞的核骨架－核纤层－中间纤维绵精细结构。处于分裂中期的细胞经抽提后看到,染色体残３余与中间纤维仍然保持一定的联系。用免疫荧光技术对提提后的ＰｔＫ２细胞进行分析结果表明：其中间纤维能同时与ＡＥ１和ＡＥ３反应;能一ＬａｍｉｎＢ反应的单抗可以特异地定位于其核周,而ＬａｍｉｎＡ（Ｃ）的单抗除了与其核纤     

北京鸭B淋巴细胞的中间纤维—核纤层—核内骨架体系

以北京鸭腔上囊为实验材料,应用细胞分级抽提方法与非树脂包埋－去包埋剂的电镜制样技术相结合,显示出Ｂ细胞中相互连结的中间纤维－核纤层－核内骨架体系的超结构及其分布,中间纤维交织成网络状,纤维直径在９－１１ｎｍ,其成份是分子量为６７ｋＤ,等电点约为６．２的波形蛋白,核纤民支呈片层状结构环绕在核区周围,其主要成份是分子量为６７ｋＤ,等电点偏酸性的Ｌａｍｉｎ Ｂ。核内骨架由粗细不一的纤维形成网络结构,其上     

PtK2细胞的核骨架—核纤层——中间纤维体系

本文用选择性系列抽提的方法结合整装细胞电镜技术和DGD包埋-去包埋超薄切片技术,在电镜下清晰地显示了PtK 2细胞的核骨架-核纤层-中间纤维体系的精细结构。处于分裂中期的细胞经抽提后可以看到,染色体残余与中间纤维仍然保持一定的联系。用免疫荧光技术对抽提后的PtK 2细胞进行分析结果表明:其中间纤维能同时与AE1和AE3反应;能与Lamin B反应的单抗可以特异地定位于其核周,而Lamin A(C)的单抗除了与其核纤层蛋白有很强的反应外还与中间纤维有交叉反应。此外,在分裂期细胞中可以看到Lamin A(C)可能与染色体能特异结合;与HeLa细胞不一样。PtK 2细胞的核骨架成份不能与280kD的核骨架蛋白单抗反应。双向电泳结果显示出PtK 2细胞的核骨架-核纤层-中间纤维体系的组成成份与HeLa细胞相比有较大的差异,而且这种差异主要反映在核骨架组份上,TdR的处理也能导致其组份发生变化。     

鼠胚成纤维细胞中间丝—核纤层—核骨架结构体系的研究

本文以１２．５天小鼠胚胎成纤维细胞为材料,使用择性抽提和整装细胞电镜制技术,显示了鼠胚成纤维细胞的中间丝－核纤层－核内架（ＩＦ－Ｌ－ＮＭ）结构体系。细胞质中有非常发达的中间丝,有的纤丝结合为束状存在,纤丝沿着核呈一定方向平行排列。细胞中也可以观察到核纤层和核骨架结构,但同胞质中间丝相比,核骨架不发达。整装细胞电镜制样使观察到的ＩＦ－Ｌ－ＮＭ更具有真实感和立体感,应用音接免疫荧光技术检测细胞内的中间     

植物细胞中间纤维角蛋白性质的分析

角蛋白是植物细胞中间纤维的主要。应用选择性抽提和生物化学技术,分离纯化了豌豆根尖细胞５８、５２ｋＤ、白菜叶５２ｋＤ和胡萝卜悬浮细胞６４ＫＤ角蛋白,测定了它们的氨基酸组成,结果表明上述角蛋白与动物细胞中间纤维角蛋白 氨基酸组成有较大的相似性。比较了动、植物细胞角蛋白肽谱、结果显示它们之间存在较大的差异,但是植物细胞嶂角蛋白肽谱比较一致,这提示它们属于同一蛋白家族,为植物中间纤维及其蛋白 存在提供了新     

核纤层蛋白与核纤层病的研究进展

核纤层蛋白(lamin)是中间纤维蛋白家族的重要成员,其多聚体组成的网格状结构紧贴于核膜内侧,在维持细胞核的正常及有丝分裂过程中发挥着重要的作用。近年来,大量研究表明编码核纤层蛋白的基因尤其是lamin A编码基因(LMNA)突变会引起一系列的疾病,即核纤层病(lami-nopathy)。该文就核纤层蛋白和核纤层病的关系进行综述,有助于读者了解核纤层蛋白的重要性,也为核纤层病的治疗提供线索。     

小鼠胚胎干细胞（ES—M13）核骨架—核纤层—中间纤维结构体系的研究

本文使用细胞的选择性抽提、ＤＧＤ包埋去包埋电镜制样、免疫荧光和免疫印迹技术研究了小鼠胚胎干细胞（ＥＳ－Ｍ１３）的核骨架－核纤层－中间纤维结构体系。在电镜下可以看到,ＥＳ细胞存在精细发达的核骨架结构,核骨架纤维同核纤层结构相连接,细胞质中有许多直径为１０ｎｍ的中间纤维单丝,细胞质中有许多直径为１０ｎｍ的中间纤维单丝,在免疫荧光分析中,使用角蛋白单克隆抗体有阳性反应,细胞质区域可以看到较强的荧光,没有     

Intermediate vimentin filaments and their role in intracellular organelle distribution

Intermediate filaments (IF) represent one of three main cytoskeletal structures in most animal cells. The human IF protein family includes about 70 members divided into five main groups. The characteristic feature of IF is that in various cells and tissues they are formed by proteins of different groups. Structures of all IF proteins follow a unique scheme: a central α-helical part is flanked at the N and C ends by positively charged polypeptide chains devoid of a clear secondary structure. The central part is highly conserved for all proteins in all animals, whereas the N and C termini strongly differ both in size and amino acid composition. This review covers the broad spectrum of recent investigations of IF structure and diverse functions. Special attention is paid to the regulatory mechanisms of IF functions, mainly to phosphorylation by different protein kinases whose role is well studied. The review gives examples of hereditary diseases associated with mutations of some IF proteins, which point to an important physiological role of these cytoskeletal structures.     

Intermediate filament structure: 1. Analysis of IF protein sequence data

Amino acid sequence data for intermediate filament proteins have been analysed with a view to identifying structurally invariant segments and determining their likely secondary structure. The sequences in these segments have also been analysed for periodic distributions of particular types of residue. The results support the classification of intermediate filament proteins into three main groups and also reinforce the concept of a molecular structure with a central domain of coiled-coil segments, together with essentially non-helical N-terminal and C-terminal domains of variable size and composition. Regions exhibiting the greatest homology between the three types of IF chain are identified and significant variation in charged residue disposition along the length of individual chains is noted. The conservation in all IF protein chains of specific sites of coiled-coil rope interruption are discussed in terms of the probable molecular structure. Stabilizing ionic interactions between coiled-coil chain segments have been investigated quantitatively as a function of the relative chain stagger. In all cases and calculations favour ropes in which the constituent chains are in-register and parallel rather than antiparallel.     

Intermediate filament structure: 2. Molecular interactions in the filament

Molecules of intermediate filament (IF) proteins contain a central rod domain in which the two constituent chains have a predominantly α-helical conformation and are coiled around one another to form segments of two-strand rope. Possible interactions between the two long segments, termed 1B and 2 were investigated by a technique successfully employed in studies of the modes of association of collagen molecules by Miller and coworkers. Prominent maxima were found in all of the six possible modes of association between the rod domain segments in individual IF proteins and certain maxima were found to be common to all IF. The surface lattice of the IF from α-keratin has been determined and possible bonding arrangements between the rod-domain segments are catalogued. A systematic search was carried out for combinations of interaction maxima which were consistent with the dimensions of the surface lattice. By the further application of stereochemical constraints, models for the topological arrangement of the rod-domain segments on the surface lattice were derived and these are illustrated and discussed.     

Semiquantitative Postembedding Characterization of Intermediate Filaments in Central Nervous System Lesions Using Immunoelectron Microscopy

Standardized postembedding immunoelectron microscopy was performed to demonstrate glial fibrillary acidic protein (GFAP) and vimentin in individual intermediate filaments to determine the diagnostic value of demonstrating ultrastructural and immunophenotypic characteristics of intermediate filaments in routine brain biopsy specimens. Dual expression of GFAP and vimentin was observed in the astroblastoma and astrocytes of Alexander's disease. The antigen availability for vimentin, however, was too low to allow reliable assessment of the GFAP:vimentin ratio in individual intermediate filaments and/or filament bundles. In meningioma, only vimentin positive intermediate filaments were found. GFAP positive intermediate filaments were present in all other specimens except the oligodendroglial components of the mixed glioma, which were devoid of intermediate filaments. GFAP positivity in the filamentous periphery and electron-dense core of Rosenthal fibers was demonstrated. Technical and tissue processing factors had a significant effect on particle density values obtained for individual specimens. Although the number, distribution, and density of glial intermediate filaments varies in different astroglial entities, correlation of particle density values determined by immunoelectron microscopy with relative GFAP concentrations in different lesions requires utmost caution. Nevertheless, application of the postembedding approach to routinely fixed biopsy specimens indicated an association of different entities with the exclusive presence of GFAP and/or vimentin in individual intermediate filaments, thus emphasizing the diagnostic value of intermediate filament typing for pathological characterization.     

Chasing Coiled Coils: Intermediate Filaments in Plants

The cytoskeleton's structurally most resilient components, the intermediate filaments (IFs), have attracted the interest of cell biologists for more than two decades. IFs form extensive networks in many animal cells, and are thought to provide considerable tensile strength to the cells and tissues. In fact, the term “cytoskeleton” has originally been coined for the insoluble fibrous remains of detergent extracted animal cells. Nevertheless, cells can survive quite well without an IF network, and even without the subunit proteins that build the 10 nm wide polymeric filaments. Hence, the vital function of these cytoskeletal components is still hotly debated. Against this background, it may be premature to start suggesting functions for IFs in plants. Yet this is exactly what quite a number of researchers have begun to do. Because much recent evidence supports the idea of a plant IF cytoskeleton, it seems timely to examine this evidence and discuss its impact on our current understanding of IF function.     

Intermediate filament proteins immunologically related to desmin in astrocytes: A study of chicken spinal cord by two-dimensional gel electrophoresis and immunoblotting

Co-migration experiments by two-dimensional SDS-PAGE using chicken spinal cord extracts and desmin purified from chicken gizzard showed that desmin is not present in spinal cord. However, by the immunoblotting procedure, desmin antibodies recognized 3 spinal cord antigens with different molecular weights and isoelectric points than desmin and the glial fibrillary acidic (GFA) protein. These antigens which also reacted with GFA protein antibodies were not identified in chicken gizzard extracts. The reactivity of the antigens with a monoclonal antibody recognizing an epitope common to most intermediate filament proteins (1) suggests that immunostaining of astrocytes with desmin antibodies (2, 3) is due to the presence of new intermediate filament proteins immunologically related to desmin.Special issue dedicated to Dr. Paola S. Timiras     

Motile Properties of Vimentin Intermediate Filament Networks in Living Cells

The motile properties of intermediate filament (IF) networks have been studied in living cells expressing vimentin tagged with green fluorescent protein (GFP-vimentin). In interphase and mitotic cells, GFP-vimentin is incorporated into the endogenous IF network, and accurately reports the behavior of IF. Time-lapse observations of interphase arrays of vimentin fibrils demonstrate that they are constantly changing their configurations in the absence of alterations in cell shape. Intersecting points of vimentin fibrils, or foci, frequently move towards or away from each other, indicating that the fibrils can lengthen or shorten. Fluorescence recovery after photobleaching shows that bleach zones across fibrils rapidly recover their fluorescence. During this recovery, bleached zones frequently move, indicating translocation of fibrils. Intriguingly, neighboring fibrils within a cell can exhibit different rates and directions of movement, and they often appear to extend or elongate into the peripheral regions of the cytoplasm. In these same regions, short filamentous structures are also seen actively translocating. All of these motile properties require energy, and the majority appear to be mediated by interactions of IF with microtubules and microfilaments.     

Intermediate filaments regulate astrocyte motility.

Intermediate filaments (IFs) compose, together with actin filaments and microtubules, the cytoskeleton and they exhibit a remarkable but still enigmatic cell-type specificity. In a number of cell types, IFs seem to be instrumental in the maintenance of the mechanical integrity of cells and tissues. The function of IFs in astrocytes has so far remained elusive. We have recently reported that glial scar formation following brain or spinal cord injury is impaired in mice deficient in glial fibrillary acidic protein and vimentin. These mice lack IFs in reactive astrocytes that are normally pivotal in the wound repair process. Here we show that reactive astrocytes devoid of IFs exhibit clear morphological changes and profound defects in cell motility thereby revealing a novel function for IFs.     

Intermediate Filaments of Schwann Cells

Abstract: Intermediate filaments were prepared from distal stumps of rabbit sciatic nerve 5 weeks after nerve section, at which time Schwann cells account for 85–90% of the cell area. A polypeptide of molecular weight 58,000 was the main component of this fraction. An antiserum raised in guinea pig against this polypeptide stained all cells present in the distal stump, as well as Schwann cells and 3T3 cells in culture. The identity of the molecular weight 58,000 polypeptide obtained from distal stumps with vimentin was proved with one and two-dimensional sodium dodecyl sulfate pol yacrylamide gel electrophoresis and with immunoautoradiography. It is concluded that the intermediate filament subunit of undifferentiated Schwann cells is vimentin. The possibility that Schwann cells in normal nerve may have another type of intermediate filament besides vimentin cannot be ruled out.