Biochemical and immunological identification of cytokeratin proteins present in hepatocytes of mammalian liver tissue

Hepatocytes of mammalian liver are known to contain intermediate-sized filaments of tonofilament morphology. Unlike many other epithelial cells, including cultured hepatocytes and hepatoma cells, hepatocytes present in normal liver tissue have been reported not to react, in significant intensity, with various preparations of antibodies to human and bovine epidermal prekeratin [2,6]. We have therefore examined, by biochemical and immunological methods, the cytoskeletal composition of hepatocytes grown in the body.Cytoskeletal preparations from hepatocytes of mouse and rat liver tissue resistant to high salt buffer and Triton X-100 are enriched in tangles of intermediate filaments and contain, besides some residual microfilamentous actin, a characteristic set of polypeptides. One- and two-dimensional gel electrophoresis reveals the presence of two major cytokeratin components, which appear as ‘pairs’ of isoelectric variants (component A, M_r 55 000, apparent pI values, 6.40 and 6.45; component D, M_r 49000, apparent pI values 5.43 and 5.38), and five minor components (M_r range from 41000 to 53 000), most of them also as ‘pairs’ of polypeptides slightly different in isoelectric pH value. These polypeptide patterns are very similar in mouse and rat liver although some minor but significant differences have been noted between the two species. The polypeptide patterns of liver cytoskeletons are also similar to—but clearly not identical with—the cytoskeletal protein patterns observed in other epithelial tissues and cells, including various lines of cultured rat hepatocytes and hepatoma cells.Guinea pig antibodies raised against individual cytokeratin proteins of mouse liver and against certain prekeratin polypeptides present in desmosome-attached tonofilaments of bovine muzzle are described which differ from previously described prekeratin antibodies. These prekeratin antibodies not only react with filament bundles of the prekeratin type present in many cultured epithelial cells (e.g. murine HEL, human HeLa, rat kangaroo PtK2) and various epithelial tissues, but also allow the detection of the cytokeratin components present in parenchymal cells of liver and pancreas of various species, man included. Immunofluorescence microscopy on frozen sections of liver using these antibodies reveals a novel structure, i.e. a three-dimensional filament meshwork extending throughout the whole cytoplasm of the hepatocyte, with higher intensity of staining in pericanalicular regions.The results show that parenchymal cells of normal liver and pancreas contain filaments of the cytokeratin type that are related to but not identical with epidermal prekeratin. The hepatocyte filaments appear to be different from prekeratin-type filaments present in epidermis and several other epithelial cells, both in some antigenic determinants exposed and in polypeptide composition. Our findings support the concept of the existence of a family of intermediate filament proteins, cytokeratins, containing many different polypeptides that are expressed in different epithelial cells in certain characteristic subsets in a cell type-specific mode.     

Vimentin and keratin intermediate filament systems in cultured PtK2 epithelial cells are interrelated.

Certain cultured epithelial cells contain separate vimentin and keratin-type intermediate filament networks. The intracellular injection of monoclonal antibodies directed against either vimentin or keratin filaments into PtK2 cultured epithelial cells specifically disrupted the organization of both filament types. Neither antibody had any effect when injected into cells which, while containing vimentin or keratin filaments, lacked the specific filament type which that antibody recognized. These experiments suggest that keratin and vimentin filament networks are associated in some way with one another.     

Cross-reactivity of antibodies specific for flagellar tektin and intermediate filament subunits

Monoclonal antibodies specific for each of the flagellar tektins were prepared and used to determine whether structures similar to tektin filaments are present in cells lacking cilia or flagella. This analysis was performed by double-label immunofluorescence microscopy of several cell lines and by immunoblots of protein fractions. Two of the four anti-tektin antibodies, the antibodies 3-7-1 and 3-10-1, which bind different epitopes of the C-tektin, label 3T3, HeLa, PtK2, and BHK-21 cells as well as myotubes. The antibody 3-7-1 stains intermediate filament structures in the cells and binds vimentin or desmin in preparations of cytoskeletal proteins; whereas the antibody 3-10-1 stains nuclear envelopes in the cells and binds lamin A and C in preparations of cytoskeletal proteins or nuclear lamina. Structural similarities between the C-tektin and intermediate filament proteins probably are extended to more than two epitopes because polyclonal antibodies anti-vimentin and anti-desmin bind to C-tektin. These polyclonal antibodies also bind to A-tektin. The cross-reaction of monoclonal and polyclonal antibodies binding to epitopes in tektin and intermediate filament components and the existence of a high content of alpha-helical structure in the tektin subunits (Linck, R. W., and G. L. Langevin, 1982, J. Cell Sci., 58:1-22) indicate that tektin and intermediate filaments are homologous in several parts of their structure.     

Constitutive aggregates of intermediate-sized filaments of the vimentin and cytokeratin type in cultured hepatoma cells and their dispersal by butyrate

Cloned hepatoma cells ($\text{72}\text{22}$) derived from the liver of a rat treated with the carcinogen, diethylnitrosamine, exhibit a genetically stable, large, acentric, juxtanuclear, hyaline aggregate of loosely packed intermediate-sized (7–11 nm) filaments, interspersed with variable but minor amounts of microtubules, polyribosomes and membranous structures. Immunofluorescence microscopy shows that the these filaments react specifically with antibodies to bovine prekeratin and to murine vimentin. The aggregates contain aster-like foci common to the arrangement of both tonofilament-like and vimentin-containing intermediate-sized filaments, although both filament systems show different fibrillar patterns in other cytoplasmic regions. While the cytokeratin filament system is not significantly altered during exposure to colcemid, the vimentin in the abnormal aggregate is rearranged during such treatment into extensive and complex perinuclear ‘whorls’ of filaments. Treatment of the cells with butyrate results in a markedly flattened, hepatocyte-like morphology, a reappearance of typical actin-containing ‘cables’, and a progressive disintegration of the filament aggregate concomitant with a normal display of filaments of both the cytokeratin and vimentin type. The results show that (i) some cells contain aggregates consisting of two different types of intermediate-sized filaments oriented onto a common focal center; (ii) such an abnormal filament arrangement is clonally stable; (iii) the vimentin-type filaments contained in such aggregates are still susceptible to the action of antimitotic drugs and can be rearranged into characteristic perinuclear whorls; and (iv) this abnormal aggregate of intermediate filaments can be reverted to normal patterns upon treatment of the cells with butyrate.     

Intermediate filament proteins in nonfilamentous structures: Transient disintegration and inclusion of subunit proteins in granular aggregates

The intermediate filament cytoskeleton of cultured bovine kidney epithelial cells and human HeLa cells changes dramatically during mitosis. The bundles of cytokeratin and vimentin filaments progressively unravel into protofilament-like threads of 2–4 nm diameter, and intermediate filament protein is included in numerous, variously sized (2–15 μm) spheroidal aggregates containing densely stained granular particles of 5–16 nm diameter. We describe these mitotic bodies in intact cells and in isolated cytoskeletons. In metaphase to anaphase of normal mitosis and after colcemid arrest of mitotic stages, many cells contain all their detectable cytokeratin and vimentin material in the form of such spheroidal aggregate bodies, whereas in other mitotic cells such bodies occur simultaneously with bundles of residual intermediate filaments. In telophase, the extended normal arrays of intermediate filament bundles are gradually reestablished. We find that vimentin and cytokeratins can be organized in structures other than intermediate filaments. Thus, at least during mitosis of some cell types, factors occur that promote unraveling of intermediate filaments into protofilament-like threads and organization of intermediate filament proteins into distinct granules that form large aggregate bodies. Some cells, at least certain epithelial and carcinoma cells, may contain factors effective in structural modulation and reorganization of intermediate filaments.     

Direct demonstration of the presence of two immunologically distinct intermediate-sized filament systems in the same cell by double immunofluorescence microscopy: Vimentin and cytokeratin fibers in cultured epithelial cells

The epithelial derived cell lines PtK2 and HeLa were characterized by double immunofluorescence microscopy using purified antibodies against vimentin and prekeratin. The results show that both cell types express simultaneously two immunologically distinct intermediate-sized filaments. Use of colcemid-treated cells confirms that the vimentin fibers and not the keratin-related fibers are rearranged into coils around the nucleus. In some cells staining of fibrous fragments is observed, which are perhaps involved in the synthesis or breakdown of this class of filaments. The concept that growing cells derived from differentiated cell types express not only the intermediate-sized filament system typical of the differentiated cell type but in addition contain intermediate-sized filaments of the vimentin type is discussed.     

Occurrence of two different intermediate filament proteins in the same filament in situ within a human glioma cell line : An immunoelectron microscopical study

Intermediate filament systems of an established glioma cell line have been characterized by double immunofluorescence microscopy and by immunoelectron microscopy using two antibodies, one of which recognizes glial fibrillary acid protein (GFA) but not vimentin, and the second which recognizes vimentin but not GFA. The results show that glioma cells express two immunologically distinct IF polypeptides which are found in the same 10-nm filaments. Juxtanuclear caps formed after exposure of the cells to colcemid consisted of intermediate filaments composed of both GFA and vimentin. In immunoelectron microscopy both untreated cells and cells treated with colcemid show discontinuous labelling when only a single antibody is used, but continuous labelling when both antibodies are used simultaneously.     

Expression of desmin cDNA in PtK2 cells results in assembly of desmin filaments from multiple sites throughout the cytoplasm.

The assembly of intermediate filaments into a cytoplasmic network was studied by microinjecting into the nuclei and cytoplasms of PtK2 cells, plasmids that contained a full length desmin cDNA and an RSV promoter. Immunofluorescence was used to monitor the expression of desmin and its integration into the cells' vimentin intermediate filament network. We found that the expressed desmin co-localized with filaments of vimentin just as it does with fluorescently labelled desmin is microinjected into the cytoplasm of PtK2 cells. As early as two hours after microinjection of the plasmids, small discrete dots and short fragments of desmin could be detected throughout the cytoplasm of the cells. This initial distribution of desmin was superimposed on the filamentous pattern of vimentin in the cells. At 8 hours after microinjection of the plasmids, some of the desmin was present in long filaments that were coincident with vimentin filaments. By 18 hours, most of the desmin was in a filamentous network co-localizing with vimentin. There was no indication that desmin assembly began in the perinuclear region and proceeded toward the cell periphery. In some cells, excessively high levels of desmin were expressed. In these cases, overexpression led to clumping of desmin filaments as well as to an accumulation of diffusely distributed desmin protein in the center of the cells. This effect was apparent at approximately 18 hours after introduction of the plasmid. The native vimentin filaments in such cells were also aggregated around the nucleus, co-localizing with desmin. The microtubule networks in all injected cells appeared normal; microtubules were extended in typical arrays out to the periphery of the cells.     

Immuno-electron microscopical identification of the two types of intermediate filaments in established epithelial cells

The intermediate filament systems of the established epithelial cell lines HeLa and PtK₂ have been characterized by electron microscopy using indirect immunoferritin labelling. The results provide a direct ultrastructural confirmation of the proposal based on indirect immunofluorescence microscopy, that vimentin and cytokeratin fibrils constitute two distinct 10 nm filament systems in much of the cell body. In agreement both with classical histology and with the finding that cytokeratins are typically present in many epithelial tissues, demosome-attached 10 nm filaments (tonofilaments) were found to be of the cytokeratin type. Vimentin, but not cytokeratin filaments were translocated into juxtanuclear caps after exposure of the cells to colcemid. Regions of the cytoplasm where the two distinct systems form mixed bundles were identified and both side-by-side arrangements and the occurrence of vimentin fibers in a sheath-like structure around a cytokeratin filament core are described. Our results emphasize that the two systems interact but differ in their organization and control.     

A γ-tubulin that associates specifically with centrioles in HeLa cells and the basal body complex in Chlamydomonas

γ-Tubulin is a putative component of microtubule initiating material. To further explore its subcellular distribution in plant and animal cells, we have raised a polyclonal antibody, Rb27, directed towards a conserved region (EEFATEGTDRKDVFFY) of the γ-tubulin molecule. Immunoblotting of cell protein extracts with Rb27 reveals a polypeptide band of M_r 49 kD in HeLa and a 58 kD band in Chlamydomonas. Although these polypeptides are comparable in size to forms of γ-tubulin detected previously in mammalian and plant protein extracts by other antibodies to γ-tubulin, by immunofluorescence microscopy Rb27 gives localization patterns not previously seen. It localizes specifically with the centrioles in HeLa cells and with the basal body complex in Chlamydomonas. Other γ-tubulin antibodies label pericentriolar material. Because of the similarities in the size of the polypeptides recognized by our and other γ-tubulin antibodies, and a restricted co-localization with known microtubule-organizing centres in evolutionarily distant organisms, we propose that Rb27 recognizes a novel conserved γ-tubulin isotype.     

Architecture and polypeptide composition of HeLa cytoskeletons: Modification of cytoarchitectural polypeptides during mitosis

Substrate-attached asynchronous HeLa cells were extracted with Triton X-100 and analysed by electron microscopy and two-dimensional gel electrophoresis. Such Triton cytoskeletons showed actin filament bundles, microtubules, intermediate filaments, and actin networks in the substrate-associated lamellae, and contained around 90 polypeptides (48 basic, 42 acidic; 52% of total actin, 99% of vimentin, 41% of α-actinin and 30% of β-tubulin).Cytoskeletons produced by further extraction in high and low salt buffers (L-H-L) showed only intermediate filaments, the nucleus and residual actin, and contained a total of 19 polypeptides (13 acidic, 6 basic). Of these, 12 corresponded to abundant acidic proteins in the 47,000 to 70,000 M_r region as determined by staining with Coomassie blue and labelling with a mixture of ¹⁴C-labelled amino acids. Using L-H-L extracted cytoplasts, and employing an actin depolymerising protein from slime moulds, seven abundant acidic IEF³ polypeptides were shown to be present in these intermediate filament-enriched, substrate-attached cytoplast cytoskeletons. These polypeptides (L-H-L cytoplast polypeptides) corresponded to vimentin (IEF 26, 54,000 M_rmr) and six polypeptides (IEF 12, 68,000 M_r; IEF 24, 56,000 M_r; IEF 31, 50,000 M_r; IEF 35, 49,000 M_r; IEF 36, 48,500 M_r and IEF 46, 43,500 M_r) not previously reported as present in cytoskeletons. Peptide analysis showed that these were not related as products of modification or proteolysis.Labelling of mitotic and interphase cells with [³⁵S]methionine followed by one-dimensional peptide map analysis showed that IEF 24, 26 (vimentin), 31 and 36 are preferentially modified during mitosis. These modifications correspond to phosphorylations of IEF 26 (vimentin) and 31, and to an unknown type for IEF 24. IEF 36 is phosphorylated in interphase to yield IEF 37, and the latter is further phosphorylated in mitosis. These results suggest that modification of the L-H-L cytoplast polypeptides may be important in the reorganization of cytoskeletal elements that takes place during cell division.     

Intermediate filaments of the vimentin-type and the cytokeratin-type are distributed differently during mitosis

Immunofluorescence microscopy has been used to follow the rearrangement of intermediate-sized filaments during mitosis in rat kangaroo PtK2 cells. These epithelial cells express two different intermediate filament systems: the keratin-related tonofilament-like arrays typical of epithelial cells, and the vimentin-type filaments characteristic of mesenchymal cells in vivo, and of many established cell lines. The two filament systems do not appear to depolymerize extensively during mitosis, but show differences in their organization and display which may indicate different functions. The most striking rearrangements have been seen with the vimentin filaments, and in particular in prometaphase a transient cage-like structure of vimentin fibers surrounding the developing spindle is formed. In metaphase, this cage disappears, and vimentin fibers are found in an elliptical band surrounding the chromosomes and the interzone. In telophase, these bands separate, usually breaking first on the side closest to where the cleavage furrow has started to form. Double label experiments with tubulin and vimentin antibodies have indicated that the microtubules and the chromosomes are contained within the thick crescents of vimentin filaments and suggest that the vimentin intermediate filaments may be involved in the orientation of the spindle and/or the chromosomes during mitosis. In contrast, extensive arrays of cytokeratin filaments are present throughout mitosis on the substrate-attached side of the cell and also in other cellular areas, although they are usually not present in the spindle region. Thus the cytokeratin filaments probably continue to play a cytoskeletal role during mitosis and may be responsible for the flat shape that certain epithelial cells such as PtK2 cells continue to maintain during mitosis.     

Specific types of prosomes are associated to subnetworks of the intermediate filaments in PtK1 cells.

Prosomes are small ribonucleoprotein (RNP) particles of unique morphology in the electron microscope but of variable protein and RNA composition, depending on the differentiation state of the cells studied. They were initially observed as subcomplexes of untranslated mRNP. In previous studies, we found that prosomes are associated to the intermediate filaments (IF) of cytokeratin type in HeLa and PtK1 cells. Here we have studied in detail the association of prosomal antigens with the IF networks in PtK1 cells. Contrary to our earlier conclusions, in these cells the vimentin fibers also carry prosomes which, thus, distribute in between the two types of networks. During the selective collapse of the IF induced by acrylamide, and upon recovery after the withdrawal of the drug, no dissociation of the prosome and IF networks of cytokeratin- and vimentin-type could be observed. These data show that even in a dynamic situation, prosome and IF antigens do not dissociate, indicating strongly that they are located on one and the same structure. Furthermore, the differential distribution of specific prosomal antigens between both types of intermediate filament networks indicates that prosomes do not ubiquitously populate the intermediate filaments but occupy subnetworks of either vimentin or cytokeratin type.     

Taxol induces concomitant hyperphosphorylation and reorganization of vimentin intermediate filaments in 9l rat brain tumor cells

Taxol, a microtubule stabilizing agent, has been extensively investigated for its antitumor activity. The cytotoxic effect of taxol is generally attributed to its antimicrotubule activity and is believed to be cell cycle dependent. Herein, we report that taxol induces hyperphosphorylation and reorganization of the vimentin intermediate filament in 9L rat brain tumor cells, in concentration- and time-dependent manner. Phosphorylation of vimentin was maximum at 10⁻⁶ M of taxol treatment for 8 h and diminished at higher (10⁻⁵ M) concentration. Enhanced phosphorylation of vimentin was detectable at 2 h treatment with 10⁻⁶ M taxol and was maximum after 12 h of treatment. Taxol-induced phosphorylation of vimentin was largely abolished in cells pretreated with staurosporine and bisindolymaleimide but was unaffected by H-89, KT-5926, SB203580, genistein, and olomoucine. Thus, protein kinase C may be involved in this process. Hyperphosphorylation of vimentin was accompanied by rounding up of cells as revealed by scanning electron microscopy. Moreover, there was a concomitant reorganization of the vimentin intermediate filament in the taxol-treated cells, whereas the microtubules and the actin microfilaments were less affected. Taken together, our data demonstrate that taxol induces hyperphosphorylation of vimentin with concomitant reorganization of the vimentin intermediate filament and that this process may be mediated via a protein kinase C signaling pathway. J. Cell Biochem. 68:472–483, 1998. © 1998 Wiley-Liss, Inc.     

Immunolocalization of the 110,000 molecular weight cytoskeletal protein of intestinal microvilli

The core structures of microvilli from absorptive cells of the intestinal epithelium are primarily composed of calmodulin (M_r 16,000), actin (M_r 43,000), villin (M_r 95,000) and a protein of M_r 110,000. We have isolated this protein and raised antibodies against it. The antibodies interact specifically with villin and M_r 110,000 polypeptides present in isolated microvilli or brush borders. However, after absorption on an immobilized villin preparation, these antibodies still immunoprecipitate the M_r 110,000 protein but not villin. Thus, these two proteins appear to share some antigenic determinants but also contain other determinants specific for each protein. Immunolocalization studies have been performed using specific antibodies against the M_r 110,000 protein. Immunofluorescent studies on thin frozen sections of intestinal cells show that this protein is located in the brush border and at the basolateral faces of these polarized cells. Immunoferritin studies on rat brush borders demembranated with the detergent Triton X-100 show the association of the M_r 110,000 protein with core filaments of microvilli, as well as with some filaments localized in the terminal web network.Using sealed, right-side-out vesicles prepared from pig intestinal mucosa in the presence of Ca²⁺ and Mg²⁺, a polypeptide of M_r 140,000 was found to be a major component of the Triton X-100 insoluble pellet. This protein is a minor component of an equivalent pellet obtained from isolated microvilli prepared in the presence of EDTA. The significance of this M_r 140,000 polypeptide associated with the core residue of intestinal microvilli is discussed.     

Localization of vimentin and desmin in BHK21/C13 cells and in baby hamster kidney

Specific antibodies against the intermediate filament protein subunits, desmin and vimentin, were used to characterize the fibroblastic tissue culture cell line BHK21/C13 and the cells comprising baby hamster kidney (BHK). The BHK21/C13 cells have previously been shown to contain desmin and vimentin by biochemical techniques. The results from double immunofluorescence analysis show that both immunologically distinct intermediate filament subunit proteins are expressed simultaneously within the same BHK21/C13 cell, and that the filamentous patterns are very similar, if not superimposable even in cells treated with colchicine. There are some cells that may contain vimentin only. Double immunofluorescence on cryostat sections of BHKs and preparations of dissociated kidney cells demonstrate that the cells, most likely smooth muscle, comprising the blood vessel walls contain vimentin and desmin simultaneously. The simultaneous expression of vimentin and desmin is not a phenomenon which is restricted to tissue culture cells. Thus, the simultaneous presence of these two intermediate filament proteins within the BHK21/C13 cell may not be the result of growth in tissue culture.     

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.     

Microtubule initiation at kinetochores and centrosomes in lysed mitotic cells. Inhibition of site-specific nucleation by tubulin antibody

A lysed cell system was developed to determine whether tubulin antibody can block the nucleation of exogenous tubulin at kinetochores and centrosomes. Mitotic PtK2 cells were pretreated with colcemid to remove all endogenous microtubules and were lysed with Triton X-100 in PIPES-EGTA-Mg++ buffer. This procedure left centrosomes, chromosomes, and kinetochores intact as determined by electron microscopy of thin-sectioned cells. Exposure of the lysed cells to phorphocellulose-purified tubulin dimers at 37 degrees C in the presence of 1 mM GTP resulted in site-specific nucleation of microtubules at centrosomes and kinetochores. Treatment of the lysed cell preparations with tubulin antibody before subsequent exposure to the exogenous tubulin resulted in almost complete blockage of microtubule nucleation, especially at kinetochores. Pretreatment of the lysed cell preparations with control antibody or buffer without antibody had no effect on the ability of centrosomes and kinetochores to initiate microtubule assembly. The implications of these results with respect to the molecular composition of centrosomes and kinetochores are discussed.     

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.     

Cytoskeleton association and virion incorporation of the human immunodeficiency virus type 1 Vif protein.

The human immunodeficiency virus type 1 (HIV-1) Vif protein has an important role in the regulation of virus infectivity. This function of Vif is cell type specific, and virions produced in the absence of Vif in restrictive cells have greatly reduced infectivity. We show here that the intracellular localization of Vif is dependent on the presence of the intermediate filament vimentin. Fractionation of acutely infected T cells or transiently transfected HeLa cells demonstrates the existence of a soluble and a cytoskeletal form and to a lesser extent the presence of a detergent-extractable form of Vif. Confocal microscopy suggests that in HeLa cells, Vif is predominantly present in the cytoplasm and closely colocalizes with the intermediate filament vimentin. Treatment of cells with drugs affecting the structure of vimentin filaments affect the localization of Vif accordingly, indicating a close association of Vif with this cytoskeletal component. The association of Vif with vimentin can cause the collapse of the intermediate filament network into a perinuclear aggregate. In contrast, analysis of Vif in vimentin-negative cells reveals significant staining of the nucleus and the nuclear membrane in addition to diffuse cytoplasmic staining. In addition to the association of Vif with intermediate filaments, analyses of virion preparations demonstrate that Vif is incorporated into virus particles. In sucrose density gradients, Vif cosediments with capsid proteins even after detergent treatment of virus preparations, suggesting that Vif is associated with the inner core of HIV particles. We propose a model in which Vif has a crucial function as a virion component either by regulating virus maturation or following virus entry into a host cell possibly involving an interaction with the cellular cytoskeletal network.