Intermediate filaments: a family of homologous structures

Cytokeratin expression in squamous metaplasia of the human uterine cervix

The expression of cytokeratin polypeptides in squamous metaplasia of the human uterine cervix was investigated by immunocytochemical labeling with polypeptide-specific antibodies against cytokeratins. Immunofluorescence microscopic examination of cervical tissues using various monoclonal antibodies indicated that squamous cervical metaplasia expresses a unique set of cytokeratin polypeptides, this being distinctively different from that expressed by all of the normal epithelial elements of the exo- and endocervix. The development of metaplastic foci was accompanied by the expression of cytokeratin polypeptide no. 13, which is commonly detected in stratified epithelia, and by a reduction in the level of polypeptide no. 18, which is typical of simple epithelia. The 40-kilodalton cytokeratin (no. 19) described by Moll et al., which is abundant in the columnar and reserve cells of the endocervix, was found throughout the metaplastic lesions. Only in 'well-differentiated' metaplasias did we detect polarity of cytokeratin expression reminiscent of the staining patterns in the exocervix. This was manifested by the exclusive labeling of the basal cell layer(s) with antibodies KB 8.37 and KM 4.62, which stain the basal cells of the exocervix. Furthermore, a comparison of cervical metaplasia with squamous areas occurring within endometrial adenocarcinomas pointed to a close similarity in the cytokeratin expression of the two. We discuss the use of cytokeratins as specific markers of squamous differentiation, the relationships between squamous metaplasia and cervical neoplasia, and the involvement of reserve cells in the metaplastic process.

Expression of glial filament protein (GFP) in nerve sheaths and non-neural cells re-examined using monoclonal antibodies, with special emphasis on the co-expression of GFP and cytokeratins in epithelial cells of human salivary gland and pleomorphic adenomas

We describe two novel monoclonal antibodies specific for glial filament protein (GFP), i.e., GF12.23 and GF12.24 (both IgG2a]. These cross-react over a broad range of species with epitopes located in the alpha-helical rod domain typical of all intermediate filament (IF) proteins. These monoclonal antibodies were used, in conjunction with other monoclonal GFP antibodies, rabbit antiserum to GFP, and various antibodies to other cytoskeletal proteins, to examine the occurrence of GFP in cells outside of the central nervous system of rodents, cows, and humans. We detected some scattered GFP-containing cells in the neural sheaths in some species but not in others, and we obtained different results when comparing the rabbit antisera with the monoclonal GFP antibodies. In the enteric glia of rats, we observed GFP-positive cells with all of the antibodies used, whereas in human intestine, the various monoclonal antibodies showed no reaction with any intestinal cells. Similarly, no GFP was detected in surface cells of the lens of cows and rats using any of the GFP antibodies, whereas some reaction was seen in murine lens tissue. We were also unable to detect GFP-positive cells in human, bovine, or rat liver with any of the monoclonal antibodies, which is in contrast to the reactivity of the rabbit GFP antisera with some stellate perisinusoidal cells of rat but not bovine or human liver. The possible reasons for the discrepancies between the different species and the different antibody preparations used are discussed. In addition, using double-label immunofluorescence microscopy, we showed that normal human parotid glands contain a certain type of epithelial cell that co-expresses cytokeratins and desmosomal proteins with GFP. The histological distribution of these GFP-positive cells suggests that they represent a subset of the myoepithelial cells present in this tissue. Cells co-expressing cytokeratins and GFP - in some cases, apparently together with vimentin as the third IF protein present - were also identified in tumors derived from this salivary-gland epithelium, i.e., pleomorphic adenomas, in which GFP-positive cells were relatively frequent in the myxoid and chondroid components, thus confirming the work of other investigators. Possible implications for the concept of histogenesis of these tumor cells are discussed, as are possible mechanisms resulting in the co-expression of IF proteins.

Monoclonal antibodies to various acidic (type I) cytokeratins of stratified epithelia. Selective markers for stratification and squamous cell carcinomas

We determined the reactivity of two monoclonal antibodies to cytokeratins that are typically expressed in certain stratified epithelia and several human squamous cell carcinomas using immunoblotting techniques and immunofluorescence microscopy. Antibody KS 8.12 reacted specifically with cytokeratin polypeptides nos. 13 and 16, and stained noncornified squamous epithelia in a rather uniform way. The examination of diverse human carcinomas showed all squamous cell carcinomas to be positively stained with this antibody, whereas all adenocarcinomas were negative. Another antibody, KK 8.60, reacted with polypeptides nos. 10 and 11, and uniformly stained the suprabasal layers of the epidermis. In several noncornified squamous epithelia (e.g., tongue, exocervix), in thymus reticulum epithelial cells, and in moderately and well differentiated squamous cell carcinomas this antibody exhibited a nonuniform labeling pattern that allowed the detection of individual cytokeratin-10/11-positive cells scattered throughout the tissue. It is concluded that antibodies KS 8.12 and KK 8.60 represent specific molecular probes for the definition of certain stages of squamous differentiation in normal development as well as in pathological processes such as squamous metaplasia and carcinogenesis. We propose the use of these antibodies in the differential diagnosis of carcinomas and their metastases.

Phenotypic analysis of cultured melanoma cells. Expression of cytokeratin-type intermediate filaments by the M5 human melanoma cell line

Expression of intermediate filament (IF) isotypes was studied in six human and two murine melanoma cell lines. With one exception, these lines expressed IFs only of the vimentin type; neurofilament peptides, desmin and GFAP were not detected. However, the M5 human melanoma line also expressed extensive cytokeratin tonofilament arrays, as visualized by immunofluorescence with a panel of eleven monoclonal antibodies and hetero-antisera to cytokeratins; only the keratin 19-specific antibody BA16 did not react. By 2 D gel electrophoresis, five major keratin peptides were detected (keratins 7, 8, 13, 17 and 18), and an additional 57 kD peptide was detected on immunoblots with several antikeratin antibodies. Also observed in M5 cells was focal collapse of tonofilament arrays in mitotic cells. All the melanoma lines tested were positive for S100; M5 and two other cell lines were also positive for the 220-240 kD neuroectoderm-associated cell-surface differentiation antigen defined by monoclonal antibody UJ 127:11. In all the melanoma cell lines, secretion of extracellular matrix proteins (fibronectin, laminin and collagen type IV) was sparse or absent, and all were negative for the epithelial cell markers HMG-1 and HMG-2. Co-expression of keratin and vimentin by a melanoma cell line is discussed in the light of recent controversy concerning expression of cytokeratins by other neoplasms of putative neuroectodermal origins.

The identification of myoepithelial cells in human salivary glands. A review and comparison of light microscopical methods

Myoepithelial cells have frequently been implicated in salivary gland tumour histogenesis. A major problem has been the reliable identification of these cells at the light microscopical level, both in tumours and in normal salivary glands. Many methods have been advocated, often with comparatively little evaluation in normal human tissue and with limited comparison between techniques. This paper reviews the application of histological staining techniques, enzyme histochemistry and immunocytochemistry with antibodies to actin, myosin and keratins. The only reliable method was immunocytochemistry with an antibody to smooth muscle myosin, with immunofluorescence on frozen tissue and immunoenzyme labelling on methacarn-fixed/paraffin-processed material. Formalin fixation did not permit successful staining. Monoclonal antibodies to specific keratin polypeptides may prove to be a useful label of myoepithelial cells but at the present time the available cytokeratin antibodies preferentially stain duct cell populations.

Antigenic interrelationship between the 40-kilodalton cytokeratin polypeptide and desmoplakins

We describe here antigenic cross-reactivity between the human 40-kilodalton cytokeratin polypeptide [Moll et al] and components of bovine desmosomal plaque, namely desmoplakins I and II. This relationship was revealed by an antibody (KM 4.62), raised against cytoskeletal preparation of cultured human breast adenocarcinoma cells (MCF-7) and selected by immunoblotting and immunofluorescent labeling. In cultured human cells that contain the 40-kD cytokeratin, antibody KM 4.62 labeled arrays of filaments throughout the cytoplasm. This antibody labeled the basal layer of nonkeratinizing squamous epithelia as well as various simple (normal and malignant) epithelia and epithelial elements of the thymus. In liver tissue, labeling was obtained only in bile ducts and canaliculi but not in the hepatocytes. In bovine cells and tissues, on the other hand, immunofluorescent labeling with antibody KM 4.62 was strictly confined to desmosomes. This was verified by double immunolabeling with both antibody KM 4.62 and specific cytokeratin or desmosomal antibodies. Immunoblotting analysis indicated that the former antibody reacts specifically with the high molecular weight components of the bovine desmosomal plaque, namely desmoplakins I and II. These immunochemical results suggest that bovine desmoplakins share same structural relationship with the human acidic, 40-kD cytokeratin.

Maintenance of desmosomes in mouse hepatocytes after drug-induced rearrangement of cytokeratin filament material. Demonstration of independence of desmosomes and intermediate-sized filaments

The distribution of desmosomes and cytokeratin filaments (tonofilaments) in hepatocytes of normal mice and those intoxicated with griseofulvin was studied by immunofluorescence microscopy. Treatment with griseofulvin over prolonged periods of time resulted in the dissociation of cytokeratin filaments from the plasma membrane and the inclusions of cytokeratin material in typical cytoplasmic aggregates, i.e. "Mallory bodies". However, such hepatocytes still displayed typical desmosomal arrays, including rather regularly spaced desmosomes along the bile canaliculi. These observations show that, in this tissue, desmosomes are able to maintain their characteristic positions along the plasma membrane after disconnection of the intermediate filament cytoskeleton. This indicates that maintenance of desmosomal integrity and position is independent of desmosome anchorage to tonofilaments. The results are discussed in relation to current concepts of desmosome formation and turnover.

Patterns of expression and organization of cytokeratin intermediate filaments

Cytokeratins are a large multigene family comprising two polypeptide types, i.e. acidic (type I) and basic (type II) ones, which are distinguished on the basis of immunological, peptide mapping, mRNA hybridization, and primary amino acid sequence data. The acidic (type I) cytokeratins can be subdivided into at least two different subtypes on the basis of their carboxy-terminal sequences. Considerable interspecies conservation of sequences exists, even extending to the 3'-non-coding mRNA regions. Different pairs of type I and II cytokeratins show different resistance to dissociation in urea. Sequence differences of the type I cytokeratins containing functional domains may be an explanation of the observed preference of co-expression with certain type II cytokeratins. The distribution of the different type I and II cytokeratins in normal epithelia and in carcinomas is differentiation related and can be used for cell typing and identification. The cell type-specific expression of cytokeratin polypeptides is recognized at both the protein and the mRNA level. The building block of cytokeratin IFs is a heterotypic tetramer, consisting of two type I and two type II polypeptides arranged in pairs of laterally aligned coiled coils. This principle of tetrameric organization is thought to be generally applicable to IFs.

Antineurofilament antibody: an increased incidence in murine chronic measles encephalitis and the use of rat sciatic nerve sections as substratum

Virus-associated autoimmune phenomena were investigated in the HNT-C57BL/6 chronic measles encephalitic mouse system. The incidence of serum antineurofilament autoantibodies was studied by an indirect immunofluorescence procedure using a FITC-conjugated goat anti-mouse immunoglobulin. Transversely cut cryostat sections of rat sciatic nerve post-treated with 1% Triton X-100 was used as substratum and had the advantages of increased reliability and reproducibility of neurofilament (NF) antibody titrations compared to the previously described longitudinal spinal cord sections. An increased incidence of anti-NF autoantibody was observed in sera from acutely, subacutely, chronically and asymptomatically infected mice compared to uninfected or mock-infected mice suggesting an association between the appearance of anti-NF antibody and HNT measles virus infection of the CNS.

Synthesis of cytoskeletal and contractile proteins by cultured IMR-90 fibroblasts

Models of the assembly of cytoskeletal and contractile proteins of eukaryotic cells require quantitative information about the rates of synthesis of individual component proteins. We applied the dual isotope technique of Clark and Zak (1981, J. Biol. Chem., 256:4863-4870) to measure the synthesis rates of cytoskeletal and contractile proteins in stationary and growing cultures of IMR-90 fibroblasts. Fibroblast proteins were labeled to equilibrium with [14C]leucine over several days, at the end of which there was a 4-h pulse with [3H]leucine. Fractional synthesis rates (percent per hour) were calculated from the 3H/14C ratio of cell protein extracts or protein purified by one- or two-dimensional polyacrylamide gel electrophoresis and the 3H/14C ratio of medium-free leucine. The average fractional synthesis rate for total, SDS- or urea-soluble; Triton-soluble; and cytoskeletal protein extracts in stationary cells each was approximately 4.0%/h. The range of values for the synthesis of individual proteins from total cell extracts or cytoskeletal extracts sliced from one-dimensional gels was similar, though this range was greater than that for major proteins of Triton-soluble protein extracts. Three specific cytoskeletal proteins--actin, vimentin, and tubulin--were synthesized at similar rates that were significantly slower than the average fractional synthesis rate for total protein. Myosin, on the other hand, was synthesized faster than average. Synthesis rates were the same for beta-and gamma-actin and polymerized (cytoskeletal extract) vs. Triton-soluble actin. The same was true for alpha- and beta-tubulin and two different forms of vimentin. Synthesis rates were uniformly higher in growing cells, though the same pattern of differential rates was observed as for stationary cells. Synthesis rates in growing cells were higher than the rate necessary to maintain the growth rate, even for those cytoskeletal proteins being synthesized slowly. Therefore, there appears to be some turnover of these cytoskeletal elements even during growth. We conclude that proteins in cytoskeletal extracts may have nonuniform rates of synthesis, but at least one important subclass of cytoskeletal proteins that comprise filament subunits have the same synthesis rates.

Schwann cells cultured from adult rats contain a cytoskeletal protein related to astrocyte filaments

Cells that bound antibody to the astrocyte intermediate filament protein were cultured from adult rat sciatic nerve. The antigen was intracellular, finely filamentous, and formed perinuclear caps in response to colchicine, all properties of intermediate filaments. Cytoskeletal proteins of these cultures were separated by SDS-gel electrophoresis, transferred to nitrocellulose paper, and shown to bind the glial-specific antiserum to a protein of 50,000 daltons. All the cells that bound this serum had a Schwann cell surface antigen, Ran-1, whereas fibroblasts from the nerve had Thy-1 surface antigen and did not contain the astrocyte filament antigen. These results prove that some Schwann cells from adult nerve, in contrast to fibroblasts or immature Schwann cells, have an intermediate filament protein that shares antigenic determinants with, or may be identical to, the astrocyte filament protein.

Loop arrays in mouse brain demonstrated with antisera to cytokeratins and monoclonal antibodies to several classes of intermediate filaments: strain differences and developmental expression

Some monoclonal antibodies raised against mouse brain antigens display a novel loop array apparently localized within the cytoplasm of neurons in fresh frozen sections of adult mouse brain. By indirect immunofluorescence, these loops are detectable in the cerebral cortex, thalamus, brainstem, and are particularly striking in association with pyramidal neurons of the hippocampus. The loops are also seen with polyclonal antibodies to the cytokeratin class of intermediate filaments. The antibodies which react with these loops also react with ependymal cells. Western blot analysis of crude insoluble cytoskeletal components of mouse brain with antibodies of cytokeratins confirm the presence of reactive bands in the range of 40-60 kdalton, appropriate in molecular weight for this class of cytoskeletal filaments. This evidence suggests that the loops share antigenic determinants with non-neural cytokeratins. During development, immunoreactive structures are first seen as small punctate or curvilinear profiles, which change into a loop array at approximately 14 days postnatal age in several mouse strains. However, in 8 of 15 different mouse strains, these immature punctate profiles remain without morphological alteration to loops throughout adult age. The F1 crosses between strains with and without the loops develop loops, but on average they are of smaller size than in the positive parent.

Interaction in vitro of the neurofilament triplet proteins from porcine spinal cord with natural RNA and DNA

Neurofilaments were isolated from porcine spinal cord and separated into their subunit proteins (68 Kd NFP, 145 Kd NFP, 200 Kd NFP) by ion exchange chromatography on DEAE-cellulose in 6 M urea. The individual proteins were reacted with total rRNA from Ehrlich ascites tumor cells and the reaction products analysed by sucrose gradient centrifugation at low ionic strength and in the presence of EDTA. All three proteins interacted with rRNA with a preference for 18S rRNA. Competition experiments with native and heat-denatured calf thymus DNA showed that the affinities of the 68 Kd and 145 Kd NFPs were considerably higher for denatured DNA than for rRNA and that native DNA was only a weak competitor. The binding of the 200 Kd NFP to rRNA was unaffected by native and by denatured DNA. When denatured DNA was reacted with a mixture of the 68 Kd and 145 Kd NFPs, the two proteins interacted independently with the nucleic acid, giving rise to two different populations of deoxyribonucleoprotein particles. This segregation is the result of the cooperative interaction of the neurofilament proteins with single-stranded DNA. It could not be observed with rRNA or bacteriophage MS2 RNA. The results clearly show that the 68 Kd and 145 Kd NFPs are single-stranded RNA- and DNA-binding proteins, whereas the 200 Kd NFP seems to be only a single-stranded RNA-binding protein.

The use of antibodies to intermediate filament proteins in the differential diagnosis of lymphoma versus metastatic carcinoma

Forty-nine cases encompassing 16 different types of malignant lymphoma were examined for their intermediate filament protein (IFP) type by indirect immunofluorescence microscopy of cryostat sections. In all cases, vimentin was shown to be the only IFP type detectable in these tumours. Lymphomas are negative for keratin and desmin, which are characteristic for benign and malignant epithelial or muscular tissues respectively. In addition, eighteen cases are described in which antibodies to intermediate filament proteins were used successfully to distinguish between lymphoma and metastatic carcinoma where differential diagnosis was difficult or impossible on the basis of routine histology.

Chromatin proteins share antigenic determinants with neurofilaments

Antigenic determinants common to distinct proteins may be unambiguously identified by the use of monoclonal antibodies. Some monoclonal antibodies to mammalian neurofilaments have recently been shown to cross-react with the neurofibrillary tangles found at high density in the brains of senile dements with Alzheimers disease (SDAT). Here, we show that these antibodies also cross-react with chromatin proteins, including the linker histones H1 and H1(0). Elevated levels of histone H1(0) have also been reported in SDAT brains.

Glial filaments are a major brain fraction in infantile neuronal ceroid-lipofuscinosis

Extremely severe gliosis develops at the end stage of infantile neuronal ceroid-lipofuscinosis (INCL), a fatal encephalopathy characterized by accumulation of autofluorescent storage material in the brain and other tissues followed by a terminal subtotal neuronal and myelin loss. A major fraction of highly enriched intermediate filaments was obtained with a density gradient centrifugation method from INCL brain tissue, whereas the storage material represented only a minor fraction. SDS-polyacrylamide gel electrophoresis of the filament fraction showed a major protein with molecular weight of 51 kD and three to four polypeptides of 40-48 kD identified as glial fibrillary acidic protein (GFAP) and its degradation products by the immunoblotting technique with monoclonal antibodies against GFAP. Immunization experiments with the isolated INCL glial filament fraction produced antibodies reacting only with GFAP but not with other types of intermediate filament proteins, furthermore indicating a high content of GFAP in the isolated fraction. No significant amounts of vimentin or other types of intermediate filament proteins could be detected. These results document the extremely high content of glial filaments at the terminal stage of INCL and suggest that INCL brain may serve as a good human model for studies on the composition of glial filaments in vivo and on the pathogenesis of gliosis.

Distinctive structural and cytoskeletal properties of the long-surviving neurons in cell cultures of embryonic spinal cord

A distinctive population of neurons survives for longer than 3 months in cell cultures of chick or rat spinal cord. These neurons form a minor proportion (1%) of the neurons initially developing in the cultures, but are the only ones to survive longer than 30 days in vitro. In addition to their longevity, they share important morphological and cytoskeletal characteristics, which render them distinctive as a group even in early cultures which contain numerous other neurons of short-term viability. Each long-surviving neuron projects one neurite of great length relative to its other neurites, or to those of the shorter-lived neurons, and the length of this neurite is maintained constant for many weeks in vitro. This well-defined morphological feature may indicate the lineage(s) of these neurons. Structurally these cells are very different to the shorter-lived neurons. They are rich in neurofilaments and contain very few microtubules, whereas the shorter-lived neurons contain few neurofilaments but many microtubules. These differences in cytoskeleton coincide exactly with the distinction between limited and prolonged survival in vitro, and the possibility is considered that cytoskeletal stability in the presence of numerous small inflows of calcium might underlie "hardiness" in vitro. The state of development of the long-lived neurons is considered in the context of their shared features, and it is suggested that they may provide a model in which the regulation of development of neuronal function can be analysed.

Differential control of cytokeratins and vimentin synthesis by cell-cell contact and cell spreading in cultured epithelial cells

The expression of cytokeratins and vimentin was investigated in Madin-Darby bovine epithelial cells (MDBK) in culture under conditions of varied cell spreading and cell-cell contact. When extensive cell-cell contact was achieved by seeding cells at high density in monolayer, or in suspension culture in which multicellular aggregates formed, the cells synthesized high levels of cytokeratins and low levels of vimentin. In contrast, in sparse monolayer and suspension cultures where cell-cell contact was minimal, the cells synthesized very low levels of cytokeratins. The level of vimentin synthesis was high in sparse monolayer culture and was low in both sparse and dense suspension cultures. The ratio of cytokeratin to vimentin synthesis was not affected during the cell cycle, or when cell growth was inhibited by ara C and in serum-starvation-stimulation experiments. The variations in the synthesis of cytokeratins and vimentin under the various culture conditions were also reflected at the level of mRNA activity in a cell-free in vitro translation system and as determined by RNA blot hybridization with cDNA to vimentin and cytokeratins. The results suggest that control of cytokeratin synthesis involves cell-cell contact, characteristic of epithelia in vivo, while vimentin synthesis responds to alterations in cell spreading.

Transient change of organization of vimentin filaments during mitosis as demonstrated by a monoclonal antibody

A monoclonal antibody specific for vimentin is described which, by immunofluorescence and immunoelectron microscopy, decorates fibrillar and/or granular structures in mitotic and early postmitotic cells but does not react with vimentin filaments of interphase stages of various cultured cells (rat vascular smooth muscle-derived cell line RVF-SM; SV40-transformed human fibroblasts; bovine kidney epithelial cells of line MDBK). These observations indicate that the organization of vimentin filaments varies during the cell cycle, undergoing a perimitotic change of filament organization. These changes of vimentin filaments are described in relation to those reported for cytokeratin filaments of various epithelial and carcinoma cells. The possible functional implications of filament protein rearrangements both during the cell cycle and in cell differentiation processes are discussed.

Heterotypic tetramer (A2D2) complexes of non-epidermal keratins isolated from cytoskeletons of rat hepatocytes and hepatoma cells

Cytoskeletal residues obtained after extraction of rat liver and cultured rat hepatoma cells (line MH1C1) were used to isolate cytokeratin subunit complexes by solubilization in low salt buffer containing 4 M-urea. Alternatively, the complexes were prepared by solubilization of total cytoskeletal proteins in 9.5 M-urea or 6 M-guanidinium hydrochloride (Gu . HCl), followed by separation using reversed phase high pressure liquid chromatography and dialysis first against either 9.5 M-urea or 6 M-Gu . HCl and then against buffers containing either 4 M-urea or 2 M-Gu . HCl, respectively. The complexes contained only two cytokeratin polypeptides in a 1 : 1 ratio as demonstrated by electrophoresis and isoelectric focusing, i.e. components A (Mr 55,000; isoelectric point in 9.5 M-urea, pH 6.4) and D (Mr 49,000; isoelectric point, pH 5.38) which were separated from each other at urea concentrations higher than 7 M. The complex had a sedimentation coefficient S25,w of 4.96 S in 2 M-Gu . HCl. Sedimentation equilibrium analysis gave an average Mr value of 207,000 which was interpreted as a tetramer containing two chains each of A and D. This complex was also directly demonstrated by gel electrophoresis under non-dissociating conditions. Using dimethyl suberimidate to cross-link the complex in solution of 4 M-urea or 2 M-Gu . HCl, we identified covalently linked heterodimers of A and D, and a tetrameric unit containing equal amounts of A and D which was the largest cross-link product obtained. This complex was similar to the tetrameric complex of rat and human vimentin formed under the same conditions. The constituents of the cross-linked products were identified by two-dimensional ("diagonal") gel electrophoresis, involving the cleavage of the bis(amidine) cross-links after the initial separation in the first dimension. Identical cross-link products were recognized when cytokeratin filaments were used. By electron microscopy the complexes appeared as threads of 2 to 3 nm diameter with a mean length of approximately 48 nm. On dialysis to low salt buffer, the complexes formed 2 to 3 nm protofilaments, intertwisted 3 to 4 nm protofilaments and typical 7 to 11 nm intermediate-sized filaments. Complexes formed from equivalent cytokeratins of other species such as man and cow, as well as heterologous recombinations such as human component A mixed with bovine component D and vice versa, showed the same characteristics.(ABSTRACT TRUNCATED AT 400 WORDS)

Vimentin intermediate filaments in cultures of human meningiomas

Monolayer cultures of six human meningiomas and meningeal cells from a human foetus were examined by indirect immunofluorescence with a human autoantibody to intermediate filaments and with a monoclonal antibody to vimentin intermediate filaments. No difference could be demonstrated in the staining of an intricate fibrillar network in cultures of transitional, fibroblastic, psammomatous and sarcomatous meningiomas compared to those of human foetal meninges. Many meningotheliomatous meningioma cells showed staining of distinctive 'whorls' of intermediate filaments, an observation less frequently seen in fetal meningeal cells or in meningiomas of other histological types. Meningioma cells, pretreated with vinblastine, showed staining of rearranged filaments whose conformation and compactness varied from cell to cell. A striking observation frequently seen in transitional and psammomatous meningiomas was the staining of thick intermediate filament 'bands' bridging two contiguous meningioma cells. Immunoblotting experiments confirmed the presence of vimentin intermediate filaments in the cultured meningioma cells.

A monoclonal antibody against vimentin: characterization

A monoclonal antibody was developed using rat cerebral cortex astrocytes purified in vitro as the antigenic material. Screening was done by labeling antibodies bound to cerebellum slices with fluorescent tagged secondary antibodies. The monoclonal antibody (RBA1) bound to intracellular filaments in all cells examined in culture. The coloration of tissue sections by RBA1 was identical to that described for polyclonal antibodies against the intermediate filament protein vimentin. In the brain this included binding to meninges, blood vessels, ependymal cells, choroid plexus lining cells and a subpopulation of astrocytes. The latter included Bergman glial fibers, white matter astrocytes and tanycytes. Müller cells in the retina and fibroblast-like cells in the skin, tongue and intestine were RBA1-positive. In immunoblots in which purified vimentin and desmin were run on SDS and transferred to nitrocellulose paper, RBA1 bound to vimentin but not desmin. When cultured astrocyte proteins were blotted, the antibody bound to both GFAP and vimentin, but no GFAP staining was observed in any of the tissue section staining. Purified vimentin blocked tissue and cultured cell binding of the antibody. Therefore RBA1 is considered to be an antibody specific for the intermediate filament protein vimentin.

Proteolytic modification of acidic and basic keratins during terminal differentiation of mouse and human epidermis

Keratins from the living cell layers of human and neonatal mouse epidermis (prekeratins) have been compared to those from the stratum corneum (SC keratins). Human and mouse epidermis contained four prekeratins, two of each keratin subfamily: type II basic (pI 6.5-8.5; human 68 kDa, 60.5 kDa and mouse 67 kDa, 60 kDa) and type I acidic (pI 4.7-5.7; human 57 kDa, 51 kDa and mouse 58 kDa, 53 kDa,). While all four were present in equal amounts in adult human epidermis, two (67 kDa basic, 58 kDa acidic) were more prominent in neonatal mouse epidermis. Preliminary results with cell fractions (basal, spinous and granular) indicated that quantitative differences were a function of morphology, basal cells containing the smaller member of each subfamily and granular cells the larger. Mouse stratum corneum extracts contained four keratins (three in human): type II neutral-acidic (pI 5.7-6.7; human 65 kDa and mouse 64 kDa, 62 kDa) and type I acidic (pI 4.9-5.4; human 57.5 kDa, 55 kDa and mouse 58.5 kDa, 57.5 kDa). In both species, one-dimensional and two-dimensional peptide mapping (with V8 protease and trypsin respectively) indicated that while all four prekeratins were distinct gene products, similarities existed in the type II basic and the type I acidic keratin subfamilies. A strong homology also existed between type II SC keratins and the larger basic (type II) prekeratin (human 68 kDa and mouse 67 kDa) and between type I SC keratins and the larger acidic (type I) prekeratin (human 57 kDa and mouse 58 kDa). These results indicate a precursor-product relationship within each keratin subfamily, between SC keratins and the prekeratins abundant in the adjacent granular layer. This differentiation-related keratin processing was similar in mouse and human epidermis, and may represent a widespread phenomenon amongst keratinising epithelia.

Intermediate filaments, microtubules and microfilaments in epidermis of sea urchin tube foot

Tube foot epidermal cells of the sea urchin Strongylocentrotus purpuratus were examined by transmission electron microscopy and fluorescence microscopy to identify the chemical nature of prominent bundles of cytoplasmic filaments. Cross sections revealed filaments of roughly 7-8 nm in diameter closely packed into dense bundles. These bundles, in turn, were each surrounded by a loose sheath of microtubules. The filament size and negative reaction with the fluorescent F-actin binding drug NBD-phallacidin indicated that they were not actin. Indirect immunofluorescence microscopy of whole tissues and frozen sections revealed a strong reaction of the filaments with a monoclonal antibody prepared against porcine stomach desmin. In SDS-polyacrylamide gels of whole tube foot protein, a band of apparent molecular weight around 50 000 daltons reacted with the anti-desmin monoclonal antibody. The combined data provide evidence that the epidermal filament bundles are related to vertebrate intermediate filaments, but further biochemical studies will be necessary to assign them to a particular class of filament proteins.

Molecular identity, distribution and heterogeneity of glial fibrillary acidic protein: an immunoblotting and immunohistochemical study of Schwann cells, satellite cells, enteric glia and astrocytes

Glial fibrillary acidic protein has been firmly established as the predominant component of astrocyte intermediate filaments. It has also been detected immunohistochemically in the glial cells of the enteric nervous system and some Schwann cells in the P.N.S. The molecular identity of this GFAP immunoreactivity in the P.N.S. has so far not been investigated. This study compares GFAP in the C.N.S. and P.N.S. of adult rats both immunochemically and immunohistochemically. Using SDS polyacrylamide gel electrophoresis combined with immunoblotting, and a polyclonal antiserum to brain GFAP, we show that the peripheral GFAP immunoreactivity resides in a polypeptide with a molecular weight of 49 kd, which is identical to that of rat brain GFAP. Furthermore, we find that this GFAP reactivity can be detected immunohistochemically in Schwann cells in a wide variety of nerves in the P.N.S. and in some satellite cells in both sensory and sympathetic ganglia, in addition to enteric glia. The pattern of distribution of GFAP filaments in Schwann cells suggests that, in the nerves surveyed, they may be expressed by most or all non-myelin forming Schwann cells but not by myelin-forming Schwann cells. We also show, using a monoclonal antibody to GFAP (anti-GFAP-3) in both immunohistochemical and immunoblotting studies, that the GFAP found in most peripheral glia is not identical to that of astrocytes since it lacks an antigenic determinant, defined by this monoclonal antibody, which is present in astrocytes. An exception to this finding is seen in the myenteric plexuses where immunohistochemically detectable GFAP is found in some, but not all, of the enteric glia, using the monoclonal antibody. Thus, the results suggest that GFA polypeptides may be a heterogeneous group, that share some common determinants and a common molecular weight, and show a widespread and complex distribution in the glia of both the C.N.S. and P.N.S.

Identification of a calcium-regulated insulinoma cell phosphoprotein as an islet cell keratin

This report describes the cytoskeleton nature of a 60,000-mol-wt protein, P60, previously shown to undergo Ca2+ influx-induced phosphorylation concomitant with insulin release in hamster insulinoma cells. Four lines of evidence suggest that P60 is an intermediate filament protein of the keratin class. (a) As previously described (Schubart, U.K., 1982, J. Biol. Chem. 257:12231-12238), Triton X-100-insoluble cytoskeletons are enriched for P60; (b) these cytoskeletons contain 7-11-nm filaments as determined by negative staining; (c) immunoblot analysis revealed that all proteins detected in the insulinoma cell cytoskeletons are recognized by a monoclonal antibody that interacts with a common determinant in all intermediate filament proteins; and (d) P60 was shown, by its identical migration on two-dimensional electrophoresis and by its immunologic relatedness, to be analogous to a known keratin present in HeLa cells. An antibody specific for P60, as judged by immunoblotting, was developed in a rabbit. In indirect immunofluorescence studies on insulinoma cells, this anti-P60 antibody produced a filamentous staining pattern. The antibody also permitted the identification of P60 in normal pancreatic islets as determined both by immunoblotting of hamster islet proteins resolved by two-dimensional electrophoresis and by indirect immunofluorescence microscopy on cryostat sections of hamster pancreas. In addition, the antibody recognized an antigen in the epithelial layer of pancreatic exocrine ducts, as determined by indirect immunofluorescence. The data have implications for the embryonic origin of pancreatic islets. Together with the phosphorylation data, these findings suggest that this islet cell cytokeratin may be involved in the regulation of insulin release.

Antibodies to cytokeratin filaments in patients with alcoholic liver disease

Previous studies have suggested that cytoskeletal elements in an altered form in vivo (alcoholic hyalin , AH) are targets for an autoimmune reaction in alcoholic liver disease (ALD). In this study we assayed autoantibodies to cytoskeletal cytoskeletal cytokeratin filaments, intermediate filaments of epithelial cells, by indirect immunofluorescence technique (IIF) using cultured human amnion epithelial cells and PtK 2 cells as targets. Sera from 20 patients with ALD, 38 patients with urogenital cancer, 22 patients with renal diseases, and from 18 healthy controls were studied. Patients with ALD had a significantly increased prevalence of cytokeratin filament autoantibodies using both PtK 2 cells (69%) and human amnion epithelial cells (69%) as substrate, as compared to other groups. The antibodies were mainly of IgA and IgM class and could be demonstrated in all forms of ALD. Interestingly, cytoskeleton antibodies have previously been observed in diseases of viral and "autoimmune" origin.

Accessibility and cross-linking of native neurofilaments to chemical reagents

Native neurofilaments were submitted to cross-linking reactions with bifunctional reagents (DMA, DMS and DSS) and to chemical reactions with sterically bulky reagents such as EEDQ and DTAF , as well as a glutaraldehyde-activated gel. The 160K and 70K neurofilament proteins reacted slightly more than the 210K neurofilament protein with DMS and DSS. The accessibility of the three neurofilaments to the other chemical reagents was identical. These results were unexpected since neurofilament antibodies seem to react preferentially with 210K protein which is at the periphery of the filament, whereas the 70K protein, which is the backbone of the filament, is probably buried inside the filament. In the same way, it has been shown that the side of the 210K proteins are probably able to cross link the neurofilaments with non covalent and covalent bridges. Using different cross link reagents, we did not observe a characteristic reactivity of the 210K protein towards the different chemicals. We conclude that the three neurofilament proteins are equally exposed to the different sterically bulky reagent and that part of the polypeptide chain of the 70K and the 160K proteins are located at the outside of the filament.

Monoclonal antibody to intermediate filament proteins in astrocytes

A monoclonal antibody was developed using rat astrocytes purified in vitro as the starting antigenic material. Selection of the monoclonal was on the basis of astrocyte binding specificity in brain sections using indirect immunofluorescence techniques. The antibody (RBA2) that was chosen was specific for astrocytes in that it did not stain neurons or oligodendrocytes in frozen brain sections. It did, however, show binding to vascular smooth muscle and meningeal cells. The antigenic determinant(s) was determined to be on filaments of the intermediate-size class in cultured astrocytes and fibroblasts. From analysis of binding patterns in various tissues and in immunoblots, it was found that RBA2 cross-reacted strongly with glial fibrillary acidic protein (GFAP) and desmin. There was a weaker cross-reactivity to a vimentin-associated component. It is proposed that this antibody can be used as an astrocyte and blood vessel marker in brain sections, a vimentin marker in cultures and as a probe of intermediate filament composition and distribution.

Large scale isolation, purification, and partial characterization of the intermediate filament-specific, Ca2+-activated proteinase from porcine kidney and Ehrlich ascites tumor cells: a comparative study

The Ca2+-activated, neutral thiol proteinase specific for intermediate filament subunit proteins was isolated at large scale from the postribosomal supernatant of a low-ionic-strength extract of porcine kidney and Ehrlich ascites tumor (EAT) cells, respectively. The purification procedure encompassed DEAE-Sephacel ion exchange chromatography of the material precipitating between 23 and 55% (NH4)2SO4 saturation, followed by hydroxylapatite chromatography and activated thiol Sepharose 4B covalent chromatography. On the average, 25 mg of 62% pure enzyme was obtained from 500 g frozen kidney and 55 mg of 51% pure enzyme from 500 g EAT cells within a week. Both enzyme preparations were free of Ca2+-independent proteolytic activities and indistinguishable with respect to their physicochemical and functional properties; their catalytic properties were indistinguishable from those of enzyme purified to homogeneity on arginine methylester Sepharose 4B. Because of this identity, porcine kidney proves to be an inexpensive source for the Ca2+-activated proteinase which had previously been isolated and purified at small scale from EAT cells (W.J. Nelson and P. Traub, (1983) J. Biol. Chem. 257, 5544-5553). Despite a 38% protein contamination, the partially purified enzyme from porcine kidney is useful for the in vitro study of structure-function relationships of intermediate filaments and their subunit proteins. During affinity chromatography of the partially purified proteinase from EAT cells on arginine methylester Sepharose 4B, a 100-kDa protein was purified which has a high affinity for arginine residues. It also occurs in porcine kidney, although at a considerably lower concentration. Its cellular localization and function remain to be determined.

Antibodies to intermediate filament proteins in the diagnosis and classification of human tumors

Immunohistochemistry of intermediate filaments (IF) is a new and important way to evaluate the epithelial, mesenchymal, muscular, glial, or neural differentiation in tumors. This is based on the stable cell-type-specific expression of IF proteins in normal and neoplastic tissues. Immunohistochemical studies with antibodies to intermediate filaments have also given new perspectives in the histogenesis and biologic nature of many tumors. This article reviews both the recent findings and the authors' experience in the use of intermediate filament antibodies in tumor diagnosis and classification.

Immunocytochemical studies of Alzheimer neuronal perikarya with intermediate filament antisera

Isolated neuronal perikarya from the brains of patients with Alzheimer's disease were examined in indirect immunofluorescence microscopy with different types of specific antisera against the subunit proteins of cytoskeletal intermediate filaments. From 30 to 50% of the neurofibrillary tangles were stained with antisera against each of the neurofilament triplet proteins, but not with antisera against glial fibrillary acidic protein, vimentin, desmin or cytokeratin. Polyacrylamide gel electrophoresis of Alzheimer perikaryal fractions showed polypeptide patterns markedly similar to control neuronal fractions. Our results thus suggest either that the Alzheimer neurofibrillary tangles and the antigenic neurofilament triplet protein fractions may contain related antigenic determinants or that unaffected perikaryal neurofilament material is associated with the tangles.

Cessation of cytokeratin expression in a rat hepatoma cell line lacking differentiated functions

Intermediate-sized filaments (IF) of diameter 7-11 nm occur in the cytoplasm of most cells of vertebrates and their constituent proteins are abundant in most cell types. Expression of IF proteins depends on the route of cell differentiation and five major subclasses of IF proteins have been distinguished: of these, cytokeratins are typical of epithelial cells whereas vimentin occurs in mesenchymally derived cells and some other non-epithelial cells. When epithelial cells are grown in culture this restriction of IF expression is often lost and they begin to synthesize vimentin in addition to cytokeratin, although examples of maintenance of the cell-type-specific expression of only cytokeratin have also been reported. No IFs have been detected in mammalian germ cells or in pre-morula stages of mouse embryogenesis, and the first IF proteins identified in murine blastocysts are cytokeratins of trophectodermal cells. We report here that a dedifferentiated rat hepatoma cell clone, which has become resistant to the action of the glucocorticoid hormone analogue dexamethasone and has lost various liver-specific functions, also stops all synthesis of IF proteins, without obvious consequences for growth and proliferation. The existence of such cells devoid of IF supports the notion that such filaments are not involved in basic cellular functions necessary for growth and proliferation but are related to special functions of the differentiated cell.

Intermediate-size filaments in a germ cell: Expression of cytokeratins in oocytes and eggs of the frog Xenopus

Vitellogenic oocytes and eggs of the frog Xenopus laevis contain intermediate-size filaments that are resistant to extractions in high-salt buffers and Triton X-100 and are specifically stained with antibodies to cytokeratins. Gel electrophoresis of cytoskeletal proteins from Xenopus oocytes shows a specific enrichment of three polypeptides designated components 1 [Mr, 56,000; IEP (pI obtained by two-dimensional gel electrophoresis in the presence of 9.5 M urea), ca. 5.9], 2 (Mr, 46,000; IEP, 5.38), and 3 (Mr, 42,000; IEP, ca. 5.3). The same three cytoskeletal polypeptides are found in eggs and early embryos, in intestinal mucosa of adult frogs, and in cultured kidney epithelial cells. They are different from amphibian vimentin and desmin and from the keratins present in the epidermis of adult frogs. Peptide mapping and immunoblotting experiments indicate that Xenopus cytokeratin component 1 is related to cytokeratin A of higher vertebrates but is different from the two smaller cytoskeletal polypeptides 2 and 3. Incorporation of [35 S]methionine shows that all three polypeptides are synthesized in both oocytes and embryos. Our observations show that maternal storage is not only restricted to proteins serving basic cellular functions but also can extend to proteins related to a specific form of cell differentiation (i.e., epithelial formation) in the early embryo. The data suggest that mechanisms of epithelial differentiation in Xenopus embryogenesis are different from those of early mammalian embryos in which no such intermediate-size-filament storage pool has been detected.

The fibrillar substructure of keratin filaments unraveled

We show that intermediate-sized filaments reconstituted from human epidermal keratins appear unraveled in the presence of phosphate ions. In such unraveling filaments, up to four "4.5-nm protofibrils" can be distinguished, which are helically twisted around each other in a right-handed sense. Lowering the pH of phosphate-containing preparations causes the unraveling filaments to further dissociate into "2-nm protofilaments." In addition, we find that reconstitution of keratin extracts in the presence of small amounts of trypsin yields paracrystalline arrays of 4.5-nm protofibrils with a prominent 5.4-nm axial repeat. Limited proteolysis of intact filaments immobilized on an electron microscope grid also unveils the presence of 4.5-nm protofibrils within the filament with the same 5.4-nm axial repeat. These results, together with other published data, are consistent with a 10-nm filament model based on three distinct levels of helical organization: (a) the 2-nm protofilament, consisting of multi-chain extended alpha-helical segments coiled around each other; (b) the 4.5-nm protofibril, being a multi-stranded helix of protofilaments; and (c) the 10-nm filament, being a four-stranded helix of protofibrils.

Change of cytokeratin filament organization during the cell cycle: selective masking of an immunologic determinant in interphase PtK2 cells

The organization of intermediate-sized filaments (IF) of the cytokeratin type was studied in cultures of PtK2 cells in which typical IF structures are maintained during mitosis, using a monoclonal antibody (KG 8.13). This antibody reacts, in immunoblotting experiments, with the larger of the two major cytokeratin polypeptides present in these cells but, using standard immunofluorescence microscopy procedures, does not react with the cytokeratin filaments abundant in interphase cells, in striking contrast to various antisera and other monoclonal cytokeratin antibodies. In the same cell cultures, however, the antibody does react with cytokeratin filaments of mitotic and early postmitotic cells. The specific reaction with cytokeratin filaments of mitotic cells only is due to the exposure of the specific immunologic determinant in mitosis and its masking in interphase cells. Treatment of interphase cells with both Triton X-100 as well as with methanol and acetone alters the cytokeratin filaments and allows them to react with this monoclonal antibody. A similar unmasking was noted after treatment with buffer containing 2 M urea or low concentrations of trypsin. We conclude that the organization of cytokeratin, albeit still arranged in typical IF, is altered during mitosis of PtK2 cells.

Proteolysis of vimentin and desmin by the Ca2+-activated proteinase specific for these intermediate filament proteins

The degradation of vimentin and desmin by the Ca2+-activated proteinase specific for these intermediate filament proteins proceeds in two stages in the form of a limited proteolysis. At first, the reaction is very rapid, with the stepwise and complete removal of a peptide (ca. 9,000 daltons) from the N-terminal of vimentin and desmin. This results in the production of a characteristic "staircase" of degradation products, as seen in two-dimensional polyacrylamide gel electrophoresis. The second stage of proteolysis is characterized by the accumulation of peptides which are resistant to further proteolysis; this is due not to product inhibition but to the fact that these peptides are not substrates for the proteinase and therefore do not protect the latter from inactivation (autodigestion). In vitro phosphorylation of the substrates does not affect proteinase activity, probably because the phosphorylation site is located towards the C-terminal of the molecules. The specific and limited proteolysis of vimentin and desmin results in the deletion of the nucleic acid binding and filament assembly site of these proteins, indicating that the Ca2+-activated proteinase plays a role in regulating the function(s) of these intermediate filament proteins, rather than their simple turnover during the cell cycle.

The organization of intermediate filaments in normal human colonic epithelium and colonic carcinoma cells

A comparative ultrastructural study of the organization of intermediate filaments (tonofilaments) within normal colonic epithelium and colonic carcinoma cells was carried out. The pattern of development of the specialized intermediate filament (IF) network, occurring during the differentiation of normal colonic epithelial cells, was examined to allow a more complete comparison with tumour cells of different degrees of differentiation. Essentially the IF system becomes more organized as the cells differentiate, resulting in the formation of a three-dimensional network loosely surrounding the nucleus, extending through the sub-terminal web and basal cytoplasm, and inserting into lateral desmosomes. Another system of IFs also runs directly between lateral desmosomes, lying parallel to the plasma-membrane and desmosomal plaque, without inserting directly into the junction. Alterations in the organization of the IF system were seen in tumour cells with the type and extent being dependent upon their location and degree of differentiation. Cells within areas of the tumour where some degree of glandular structure was retained exhibited major alterations in their microfilament-containing structures. However, their IF system was essentially intact and lateral desmosomes were still present in similar numbers to those seen in normal, partially differentiated mid-crypt cells. Apolar tumour cells within areas of the tumour where a gross loss of cryptal architecture had occurred exhibited a striking disorganization of their IF system. No parallel bundles of interdesmosomal tonofilaments were present beneath the cell surface and the majority of the three-dimensional network appeared to have collapsed around the nucleus, although some extensions to randomly distributed surface desmosomes still occurred. It appears that this disorganization of the IF system is associated with a loss of cell polarity and may involve alterations in putative IF-associated proteins important in the interaction of IFs with surface desmosomes or other cytoskeletal elements. A study of this phenomenon may shed light on both the means of IF organization and assembly and their role in normal cells as well as the possible role of alterations in cytoskeletal elements in the expression or maintenance of the malignant phenotype.

Expression of the major neurofilament subunit in chicken erythrocytes

The 70,000-dalton core polypeptide of neurofilaments, thought to exist only in neurons, has been detected in chicken erythrocytes, where it coexists with vimentin and synemin as a component of the intermediate filament network. It is present in the circulating erythroid cells of embryos and young chickens but is nearly absent from the erythroid cells of adults. These findings are inconsistent with current models of intermediate filament expression, but provide another example of unexpected similarities between the nervous and hemopoietic systems.

Antibodies to intermediate filament proteins in the immunohistochemical identification of human tumours: an overview

Intermediate-sized filament proteins (IFP) are tissue specific in that antibodies to keratin, vimentin, desmin, glial fibrillary acidic protein (GFAP) and the neurofilament proteins can distinguish between cells of epithelial and mesenchymal origin as well as of myogenic and neural origin respectively. Malignant cells retain their tissue-specific IFP, which makes it possible to use these antibodies in tumour diagnosis. Carcinomas are exclusively detected by antibodies to keratin. Monoclonal antibodies to keratin have allowed the differentiation between subgroups of epithelial tumours until now between adenocarcinomas and squamous cell carcinomas. Lymphomas, melanomas and several soft tissue tumours are distinctly recognized by antibodies to vimentin. On the other hand, rhabdomyosarcomas and leiomyosarcomas are positive for desmin, while astrocytomas give a strong reaction with GFAP antibodies. Thus, antibodies to IFP are useful tools for differential diagnosis in surgical pathology.