Association of glycosphingolipids with intermediate filaments of mesenchymal, epithelial, glial, and muscle cells.

We reported recently that two glycosphingolipids (GSLs), globoside (Gb4) and ganglioside GM3, colocalized with vimentin intermediate filaments of human umbilical vein endothelial cells. To determine whether this association is unique to endothelial cells or to vimentin, we analyzed a variety of cell types. Double-label immunofluorescent staining of fixed, permeabilized cells, with and without colcemid treatment, was performed with antibodies against glycolipids and intermediate filaments. Globoside colocalized with vimentin in human and mouse fibroblasts, with desmin in smooth muscle cells, with keratin in keratinocytes and hepatoma cells, and with glial fibrillary acidic protein (GFAP) in glial cells. Globoside colocalization was detected only with vimentin in MDCK and HeLa cells, which contain separate vimentin and keratin networks. GM3 ganglioside also colocalized with vimentin in human fibroblasts. Association of other GSLs with intermediate filaments was not detected by immunofluorescence, but all cell GSLs were detected in cytoskeletal fractions of metabolically labelled endothelial cells. These observations indicate that globoside colocalizes with vimentin, desmin, kertain and GFAP, with a preference for vimentin in cells that contain both vimentin and keratin networks. The nature of the association is not yet known. Globoside and GM3 may be present in vesicles associated with intermediate filaments (IF), or bound directly to IF or IF associated proteins. The prevalence of this association suggests that colocalization of globoside with the intermediate filament network has functional significance. We are investigating the possibility that intermediate filaments participate in the intracellular transport and sorting of glycosphingolipids.     

Intermediate filament protein partnership in astrocytes.

Intermediate filaments are general constituents of the cytoskeleton. The function of these structures and the requirement for different types of intermediate filament proteins by individual cells are only partly understood. Here we have addressed the role of specific intermediate filament protein partnerships in the formation of intermediate filaments in astrocytes. Astrocytes may express three types of intermediate filament proteins: glial fibrillary acidic protein (GFAP), vimentin, and nestin. We used mice with targeted mutations in the GFAP or vimentin genes, or both, to study the impact of loss of either or both of these proteins on intermediate filament formation in cultured astrocytes and in normal or reactive astrocytes in vivo. We report that nestin cannot form intermediate filaments on its own, that vimentin may form intermediate filaments with either nestin or GFAP as obligatory partners, and that GFAP is the only intermediate filament protein of the three that may form filaments on its own. However, such filaments show abnormal organization. Aberrant intermediate filament formation is linked to diseases affecting epithelial, neuronal, and muscle cells. Here we present models by which the normal and pathogenic functions of intermediate filaments may be elucidated in astrocytes.     

Dynamic organisation of intermediate filaments and associated proteins during the cell cycle

Intermediate filaments, which form the structural framework of both the cytoskeleton and the nuclear lamina in most eukaryotic cells, have been found to be highly dynamic structures. A continuous exchange of subunit proteins at the filament surface and a stabilisation of soluble subunits by chaperone-type proteins may modulate filament structure and plasticity. Recent studies on the cell cycle-dependent interaction of intermediate filaments with associated proteins, and a detailed analysis of intermediate filament phosphorylation in defined subcellular locations at various stages of mitosis, have brought new insights into the molecular mechanisms involved in the mitotic reorganisation of intermediate filaments. Some of these studies have allowed new speculations about the possible cellular functions of cytoplasmic intermediate filaments, and increased our understanding of the specific functions of the lamins and the lamina-associated membrane proteins in the post-mitotic reassembly of the nucleus.     

人体肝癌细胞和HeLa细胞中等纤维的比较研究

本文用兔抗角蛋白抗体、豚鼠抗波形纤维蛋白抗体和抗角蛋白单抗AE1的间接免疫荧光抗体法比较了两个人体肝癌细胞系(BEL-7402和BEL-7404)和HeLa细胞中等纤维的分布式样,同时用SDS-PAGE法分析了上述细胞的中等纤维抽提物的多肽组成。结果表明:三种上皮细胞均含有两套不同类型的中等纤维系统:角蛋白纤维和波形纤维。但是,人体肝癌细胞和HeLa细胞的中等纤维分布式样和角蛋白多肽组成均有明显的差别。其中最明显的差别是HeLa细胞具有丰富的桥粒-张力纤维复合物和分子量为40 kd的角蛋白多肽,而在两个人体肝癌细胞系中看不到。     

Intermediate filament systems are collapsed onto the nuclear surface after isolation of nuclei from tissue culture cells

Standard procedures for the biochemical isolation and purification of tissue culture cell nuclei are very similar to recently described methods for the preparation of detergent-resistant cytoskeletons. But the latter in addition to extracted nuclei contain cytoplasmic filament systems. We, therefore, investigated the distribution of these filamentous systems during nuclear isolation both by immunofluorescence microscopy and by SDS-gel electrophoresis. The intermediate filaments copurify with each single isolated nucleus. The majority of the filaments is collapsed onto isolated nuclei and still constitutes a filamentous system. This can be shown by partially unfolding the collapsed filament systems.     

Detection of dense intra- and perinuclear 10 nm filament systems by whole mount and embedment-free electron microscopy in several species of the green algal order Dasycladales

Summary In contrast to the immense body of evidence supporting the occurrence of intermediate filament (IF) proteins in the animal kingdom, there is only limited information on their distribution in plants. Nevertheless, a number of immunocytochemical and electron microscopical observations indicate that particularly in higher plant cells IFs contribute to the construction of the cyto- and karyoskeleton. Here we show by whole mount electron microscopy of the giant nuclei extruded together with adhering cytoplasm from the rhizoids of some species of the algal order Dasycladales that cytoplasmic 10 nm filament networks also occur in unicellular, mononucleated green organisms of early evolutionary origin. The filament systems were associated with the residual nuclear envelope which consisted of a dense arrangement of pore complexes suspended by a meshwork of short 5 to 6 nm filaments; structurally it was very similar to the nuclear envelopes obtained from mammalian cells. When the Dasycladales nuclei were processed side by side with mouse skin fibroblasts, the algal filament systems were physically almost indistinguishable from the mammalian vimentin filament network. Embedment-free thin sections of rhizoids have not only confirmed the existence of the perinculear 10 nm filaments and their seamless association with the nuclear envelope, but have demonstrated the existence of an extensive intranuclear meshwork of 10 nm filaments. The latter were morphologically indistinguishable from the perinuclear 10 nm filaments and seem to be connected to these via the nuclear envelope to form a continuum. Among a variety of antibodies directed against mammalian IF proteins, only polyclonal anti-mouse lamin B antibodies decorated the cytoplasmic filaments of the Dasycladales cells. Surprisingly, none of the antibodies decorated the thinner filaments of the nuclear envelope, which possibly represent the nuclear lamina. In accord with this observation, one anti-lamin B antibody recognized in Western blot analysis of a urea extract ofAcetabularia acetabulum rhizoids three polypeptides with M_rs of approximately 47,000, 64,000, and 76,000. The proteins did not react with the -IFA antibody. Since the Dasycladales have a fossil record of nearly 600 million years — an extant genus, Acicularia, also investigated here, evolved about 170 million years ago -, the molecular characterization of the subunit proteins of their cytoplasmic filament systems might throw further light on the evolution and biological role of IFs.Dedicated to Professor Sir Henry Harris on the occasion of his 70th birthday     

Cytoskeleton-associated plectin: in situ localization, in vitro reconstitution, and binding to immobilized intermediate filament proteins

The association and interaction of plectin (Mr 300,000) with intermediate filaments and filament subunit proteins were studied. Immunoelectron microscopy of whole mount cytoskeletons from various cultured cell lines (rat glioma C6, mouse BALB/c 3T3, and Chinese hamster ovary) and quick-frozen, deep-etched replicas of Triton X-100-extracted rat embryo fibroblast cells revealed that plectin was primarily located at junction sites and branching points of intermediate filaments. These results were corroborated by in vitro recombination studies using vimentin and plectin purified from C6 cells. Filaments assembled from mixtures of both proteins were extensively crosslinked by oligomeric plectin structures, as demonstrated by electron microscopy of negatively stained and rotary-shadowed specimens as well as by immunoelectron microscopy; the binding of plectin structures on the surface of filaments and cross-link formation occurred without apparent periodicity. Plectin's cross-linking of reconstituted filaments was also shown by ultracentrifugation experiments. As revealed by the rotary-shadowing technique, filament-bound plectin structures were oligomeric and predominantly consisted of a central globular core region of 30-50 nm with extending filaments or filamentous loops. Solid-phase binding to proteolytically degraded vimentin fragments suggested that plectin interacts with the helical rod domain of vimentin, a highly conserved structural element of all intermediate filament proteins. Accordingly, plectin was found to bind to the glial fibrillar acidic protein, the three neurofilament polypeptides, and skin keratins. These results suggest that plectin is a cross-linker of vimentin filaments and possibly also of other intermediate filament types.     

The beaded filament of the eye lens: an unexpected key to intermediate filament structure and function

In 1959, an unusual filamentous polymer, now called the beaded filament, was described in the lens of the eye. The constituent proteins, assembly properties and functions of the beaded filament have been elusive. The recent publication of the sequences for two major lens filament proteins (CP49 and filensin) and the reconstitution in vitro of structures closely resembling beaded filaments, suggests that the beaded filament is related structurally to intermediate filaments (IFs). The association of the lenticular chaperones, the alpha-crystallins, with the filament contributes to the characteristic beaded morphology, as well as giving important clues to the function of this unusual filament in the lens. These recent results have several implications for IF function and assembly.     

Effect of pepstatin A on structure and polymerization of intermediate filament subunit proteins in vitro

Pepstatin A, a pentapeptide aspartyl protease inhibitor, can interact with intermediate filament (IF) subunit proteins and induce their polymerization in the absence of salt into long filaments with a rough surface and a diameter of 15-17 nm. This polymerization appears to be driven primarily by non-ionic interactions between pepstatin A and polymerization-competent forms of IF proteins, resulting in a composite filament. Proteolytic fragments of vimentin, lacking portions of only the head domain or of both the head and tail domains, failed to copolymerize with pepstatin A into long filaments under these conditions. Rather, these peptides, as well as control proteins like bovine serum albumin, were found to decorate pepstatin A polymers (filaments, ribbons, and sheets) by sticking to their surfaces. In addition to the electron microscopy experiments, UV difference spectra, ultracentrifugation, and SDS-PAGE analysis of in vitro cleavage products of vimentin obtained with HIV-1 protease all provided independent evidence for a direct association of pepstatin A with IF subunit proteins, with subsequent alterations in the IF subunit protein conformation. These data show that non-ionic interactions can substitute for the effect of salt and effectively drive the higher-order polymerization of IF subunit proteins.     

Nucleus-associated intermediate filaments from chicken erythrocytes

Chicken erythrocyte nuclei prepared by isolation in isotonic KCl and Nonidet P-40 detergent were found to contain numerous attached filaments with a mean diameter of 11.0 nm. In polypeptide content and solubility properties, they resembled the vimentin type of intermediate filament found in cells of mesenchymal origin. Examination of their association with the nucleus suggests that more than a simple membrane attachment is involved.     

In vitro assembly properties of mutant and chimeric intermediate filament proteins: insight into the function of sequences in the rod and end domains of IF

The factors and mechanisms regulating assembly of intermediate filament (IF) proteins to produce filaments with their characteristic 10 nm diameter are not fully understood. All IF proteins contain a central rod domain flanked by variable head and tail domains. To elucidate the role that different domains of IF proteins play in filament assembly, we used negative staining and electron microscopy (EM) to study the in vitro assembly properties of purified bacterially expressed IF proteins, in which specific domains of the proteins were either mutated or swapped between a cytoplasmic (mouse neurofilament-light (NF-L) subunit) and nuclear intermediate filament protein (human lamin A). Our results indicate that filament formation is profoundly influenced by the composition of the assembly buffer. Wild type (wt) mouse NF-L formed 10 nm filaments in assembly buffer containing 175 mM NaCl, whereas a mutant deleted of 18 NH2-terminal amino acids failed to assemble under similar conditions. Instead, the mutant assembled efficiently in buffers containing CaCl2 > or = 6 mM forming filaments that were 10 times longer than those formed by wt NF-L, although their diameter was significantly smaller (6-7 nm). These results suggest that the 18 NH2-terminal sequence of NF-L might serve two functions, to inhibit filament elongation and to promote lateral association of NF-L subunits. We also demonstrate that lengthening of the NF-L rod domain, by inserting a 42 aa sequence unique to nuclear IF proteins, does not compromise filament assembly in any noticeable way. Our results suggests that the known inability of nuclear lamin proteins to assemble into 10 nm filaments in vitro cannot derive solely from their longer rod domain. Finally, we demonstrate that the head domain of lamin A can substitute for that of NF-L in filament assembly, whereas substitution of both the head and tail domains of lamins for those of NF-L compromises assembly. Therefore, the effect of lamin A "tail" domain alone, or the synergistic effect of lamin "head" and the "tail" domains together, interferes with assembly into 10-nm filaments.     

Differences of expression of cytoskeletal proteins in cultured rat hepatocytes and hepatoma cells

Cytoskeletal elements, enriched in intermediate-sized filaments and insoluble in buffers of high salt concentrations and Triton X-100, were isolated from various cultures of rat hepatocytes and hepatoma cells, and their proteins were studied by one- and two-dimensional gel electrophoresis and immunofluorescence microscopy. The cells examined included several permanent cell lines (MH₁C₁, HTC, hepatoma 72/22, clone 12 from Gunn rat hepatocytes, and cell clones from normal rat hepatocytes), as well as freshly dissociated hepatocytes that were cultured and allowed to attach to substratum for increasing periods of time, beginning at 24 h after removal of the liver from the animal. Filaments containing vimentin, which were not found in hepatocytes grown in liver tissue, were detected in most of the cultured hepatocytes and hepatoma cells, except in MH₁C₁ cells, and were shown to be newly synthesized during the first days of primary culture. Maintenance of expression of filaments containing proteins immunologically related to epidermal prekeratin (‘cytokeratins’) was observed in all cells examined but HTC cells. Detailed comparison of the cytokeratin polypeptides present in various hepatocyte and hepatoma cell cultures showed that, in some of the cultured epithelial liver cells, cytokeratins are expressed which are identical with, or similar to, those of normal hepatocytes grown in the liver. On the other hand, differences in cytokeratin polypeptides were also found among different hepatocyte-derived cell cultures. Changes of expression of cytoskeletal proteins were found to occur even in cloned cell populations, and cells positive for certain cytokeratins could be seen next to other cells that were negative.The results demonstrate that profound changes of cytoskeletal composition, especially concerning intermediate filament protein patterns, can occur during culturing in vitro. Moreover, we show that different intermediate filament proteins can be expressed in different hepatocyte-derived cell cultures and that changes of cytoskeletal composition can occur in a given cell population, without obvious effects on cell growth rate and cell morphology. During culturing of hepatocytes and hepatoma cells, there seems to be a general tendency to induce the production of vimentin filaments as well as to maintain the production of cytokeratins similar to the hepatocyte-specific cytokeratins in liver tissue. However, the demonstrated exceptions speak against a role of these filament proteins as prerequisites for the growth of an epithelial cell in vitro. Rather, the presence of filaments containing certain cytokeratins and of desmosomes in epithelial cells growing in vitro seems to reflect the synthesis of specific differentiation markers which may be lost, independently, in some cells during culturing.     

Intermediate filaments: structure, regulation of expression and possible function

New data are reviewed on intermediate filaments, i.e. on one of the cytoskeleton components. Structural proteins of intermediate filaments, their enzymatic modification, filament-associated proteins and the peculiarities of filament assembly are dealt with. The regularities of expression of intermediate filament proteins in normal tissues are analysed, as well as during differentiation and cultured cell growth. In the final part of the paper possible functions of intermediate filaments are discussed.     

Intermediate filaments exchange subunits along their length and elongate by end-to-end annealing

Actin filaments and microtubules lengthen and shorten by addition and loss of subunits at their ends, but it is not known whether this is also true for intermediate filaments. In fact, several studies suggest that in vivo, intermediate filaments may lengthen by end-to-end annealing and that addition and loss of subunits is not confined to the filament ends. To test these hypotheses, we investigated the assembly dynamics of neurofilament and vimentin intermediate filament proteins in cultured cells using cell fusion, photobleaching, and photoactivation strategies in combination with conventional and photoactivatable fluorescent fusion proteins. We show that neurofilaments and vimentin filaments lengthen by end-to-end annealing of assembled filaments. We also show that neurofilaments and vimentin filaments incorporate subunits along their length by intercalation into the filament wall with no preferential addition of subunits to the filament ends, a process which we term intercalary subunit exchange.     

Brain postsynaptic densities: the relationship to glial and neuronal filaments

Preparations of isolated brain postsynaptic densities (PSDs) contain a characteristic set of proteins among which the most prominent has a molecular weight of approximately 50,000. Following the suggestion that this major PSD protein might be related to a similarly sized component of neurofilaments (F. Blomberg et al., 1977, J. Cell Biol., 74:214- 225), we searched for evidence of neurofilament proteins among the PSD polypeptides. This was done with a novel technique for detecting protein antigens in SDS-polyacrylamide gels (immunoblotting) and an antiserum that was selective for neurofilaments in immunohistochemical tests. As a control, an antiserum against glial filament protein (GFAP) was used because antisera against GFAP stain only glial cells in immunohistochemical tests. They would, therefore, not be expected to react with PSDs that occur only in neurons. The results of these experiments suggested that PSDs contain both neuronal and also glial filament proteins at higher concentrations than either synaptic plasma membranes, myelin, or myelinated axons. However, immunoperoxidase staining of histological sections with the same two antisera gave contradictory results, indicating that PSDs in intact brain tissue contain neither neuronal or glial filament proteins. This suggested that the intermediate filament proteins present in isolated PSD preparations were contaminants. To test this possibility, the proteins of isolated brain intermediate filaments were labeled with 125I and added to brain tissue at the start of a subcellular fractionation schedule. The results of this experiment confirmed that both neuronal and glial filament proteins stick selectively to PSDs during the isolation procedure. The stickiness of PSDs for brain cytoplasmic proteins indicates that biochemical analysis of subcellular fractions is insufficient to establish a given protein as a synaptic junctional component. An immunohistochemical localization of PSDs in intact tissue, which has now been achieved for tubulin, phosphoprotein I, and calmodulin, appears to be an essential accessory item of evidence. Our findings also corroborate recent evidence which suggests that isolated preparations of brain intermediate filaments contain both neuronal and glial filaments.     

An electron microscopic study of the interaction in vitro of vimentin intermediate filaments with vesicles prepared from Ehrlich ascites tumor cell lipids

The interaction of intermediate filaments prepared from pure, delipidated vimentin with vesicles obtained from Ehrlich ascites tumor (EAT) cell lipids was studied employing sucrose density gradient centrifugation in combination with electron microscopy. In negative stain electron microscopy, preformed vimentin filaments were seen in lateral association with lipid vesicles; end-on contacts of filaments with liposomes were rarely detected. When the reaction of filaments with vesicles was carried out at 0 degree C, sucrose density gradient equilibrium centrifugation of the reaction products led to the banding of relatively light filament-vesicle meshworks in clear separation from free filaments and free vesicles. With certain vimentin and lipid preparations, occasionally partial breakdown of the filaments during centrifugation and banding of vesicle-free fragments in denser regions of the sucrose gradients was observed. However, when the reaction mixtures were incubated at 37 degrees C prior to sucrose gradient analysis, all filaments were released from vesicles and totally fragmented during centrifugation. Electron microscopy showed unraveling of the filament fragments into subfilament strands. Employing lipid vesicles labeled with [3H]cholesterol, a low but significant amount of radioactivity was found to be associated with the fragments in a non-vesicular form. Filament reconstitution experiments performed in the presence of EAT cell lipids revealed an inhibitory effect of vesicles on filament assembly, particularly at lower temperatures. The mechanical labilization of the filament structure by lipid vesicles might play a role in the redistribution of intermediate filaments in the course of certain cellular processes involving turnover and fragmentation of intracellular membrane systems.     

Assembly of keratin onto PtK1 cytoskeletons: evidence for an intermediate filament organizing center

Purified keratin, solubilized in 8 M of urea, was added to Triton X-100-extracted PtK1 cells in 5 mM PIPES buffer. The buffer conditions induced assembly of keratin filaments which appear to associate with nuclei of extracted cells. These keratin fibers extend beyond the original margin of the cells and frequently form bridges between adjacent cells. Electron microscopy shows that keratin filaments associate closely with the surface of the nucleus. We suggest that the site of association between keratin and the nucleus may represent an intermediate filament organizing center.     

Reorganization of the system of intermediate filaments and detection of the organization centers after centrifugation of cells attached to a substrate

Cultured pig kidney epithelial cells were centrifuged at 20,000 gav so that the centrifugation force was oriented parallel to the substrate, fixed and processed for indirect immunofluorescent staining with tubulin and vimentin antibodies. After a 2 hour centrifugation vimentin filaments aggregated in the centripetal parts of the cells (probably, because of their association with floating lipid vesicles). Microtubule-organizing centers were found near the centripetal poles of the nuclei, which migrated in the direction of the centrifugal force. The distribution of the cytoplasmic microtubules did not change during centrifugation. The staining of the cultures one hour after centrifugation revealed vimentin-containing spots with radiating intermediate filaments in most of the cells. These spots were localized near the cell nuclei; double immunofluorescent staining with tubulin and vimentin antibodies showed that their position was identical to that of the microtubule-organizing centers. Similar foci of vimentin filaments were seen in the cells after a 3-4 hour centrifugation. Probably, these structures participate in organizing the intermediate filament cytoskeleton in cells.     

Microinjection of intermediate filament proteins into living cells with and without preexisting intermediate filament network

Human cells grown in monolayer culture were microinjected with intermediate filament subunit proteins. In fibroblasts with a preexisting vimentin network, injected porcine glial fibrillary acidic protein (GFAP) co-localized with the vimentin network within 24 hours. Phosphorylated GFAP variants were found to become dephosphorylated concomitantly with their incorporation into filamentous structures. After microinjection of either porcine GFAP or murine vimentin into human carcinoma cells lacking cytoplasmic intermediate filaments, we observed that different types of filament networks developed. Whereas vimentin was incorporated into short filaments immediately after injection, GFAP was found to aggregate into rodlike structures. This may indicate a differential filament forming ability of these intermediate filament proteins in vivo.