Aggregation of macrophages and fibroblasts is inhibited by a monoclonal antibody to the hyaluronate receptor

To examine the role of the hyaluronate receptor in cell to cell adhesion, we have employed the K-3 monoclonal antibody (MAb) which specifically binds to the hyaluronate receptor and blocks its ability to interact with hyaluronate. In the first set of experiments, we investigated the spontaneous aggregation of SV-3T3 cells, which involves two distinct mechanisms, one of which is dependent upon the presence of divalent cation and the other is independent. The divalent cation-independent aggregation was found to be completely inhibited by both intact and Fab fragments of the K-3 MAb. In contrast, the K-3 MAb had no effect on the divalent cation-dependent aggregation of cells. In a second set of experiments, we examined alveolar macrophages. The presence of hyaluronate receptors on alveolar macrophages was demonstrated by the fact that detergent extracts of these cells could bind [3H]hyaluronate, and this binding was blocked by the K-3 MAb. Immunoblot analysis of alveolar macrophages showed that the hyaluronate receptor had a Mr of 99,500, which is considerably larger than the 85,000 Mr for that on BHK cells. When hyaluronate was added to suspensions of alveolar macrophages, the cells were induced to aggregate. This effect was inhibited by the K-3 MAb, suggesting that the hyaluronate-induced aggregation was mediated by the receptor.     

The hyaluronate receptor is identical to a glycoprotein of Mr 85,000 (gp85) as shown by a monoclonal antibody that interferes with binding activity

The cell surface receptor for hyaluronate is an integral membrane glycoprotein of Mr 85,000 (Underhill, C. B., Thurn, A. L., and Lacy, B. E. (1985) J. Biol. Chem. 260, 8128-8133), which appears to be associated with actin filaments. This protein is similar in many respects to another protein, termed gp85, which was originally identified by Tarone, G., Ferracini, R., Galeto, G., and Comoglio, P. (1984) J. Cell Biol. 99, 512-519), using a monoclonal antibody designated as K-3. The gp85 is also a membrane glycoprotein of Mr 85,000 which is associated with the cytoskeleton. Indeed, immunohistological staining has shown that it is distributed in patches along stress fibers of spread baby hamster kidney (BHK) cells. In the present study, we have used the K-3 monoclonal antibody to determine whether gp85 is identical to the hyaluronate receptor. Initial studies showed that the K-3 antibody reacted with material at Mr 85,000 on immunoblots of a purified preparation of the hyaluronate receptor. In addition, the K-3 antibody specifically blocked the binding of [3H]hyaluronate to detergent extracts of the receptor from both BHK and polyoma virus transformed baby hamster kidney (PY-BHK) cells, as well as to intact PY-BHK cells. These results indicate that the K-3 antibody is directed against the hyaluronate receptor, which therefore must be identical to gp85. The K-3 antibody was then used to determine the relative number of hyaluronate receptors associated with parent (BHK) and transformed (PY-BHK) cells. Using an enzyme-linked assay, we found that parent cells had a substantially greater number of receptors than their transformed counterparts. These results were consistent with those obtained when detergent extracts of cells were directly assayed for [3H]hyaluronate binding activity.     

The hyaluronate receptor is a member of the CD44 (H-CAM) family of cell surface glycoproteins [published erratum appears in J Cell Biol 1991 Feb;112(3):following 513]

The present study was undertaken to determine the relationship between the hyaluronate receptor and CD44 (H-CAM), cell-surface glycoproteins of similar molecular weights that have been implicated in cell adhesion. In initial experiments, a panel of monoclonal antibodies directed against CD44 were tested for their ability to cross react with the hyaluronate receptor. These antibodies immunoprecipitated [3H]hyaluronate binding activity from detergent extracts of both mouse and human cells, indicating that the hyaluronate receptor is identical to CD44. In addition, one of these antibodies (KM-201 to mouse CD44) directly blocked the binding of labeled hyaluronate to the receptor and inhibited hyaluronate dependent aggregation of SV-3T3 cells. CD44 has also been implicated in lymphocyte binding to high endothelial venules during lymphocyte homing. Interestingly, the monoclonal antibody Hermes- 3, which blocks lymphocyte binding to the high endothelial venules of mucosal lymphoid tissue, had no effect on the binding of labeled hyaluronate. Furthermore, the binding of lymphocytes to high endothelial cells of lymph nodes and mucosal lymphoid tissue was not significantly affected by treatment with agents that block the binding of hyaluronate (hyaluronidase, excess hyaluronate and specific antibodies). Thus, CD44 appears to have at least two distinct functional domains, one for binding hyaluronate and another involved in interactions with mucosal high endothelial venules.     

The role of fibroblast growth factors on the differentiation of vaginal epithelium of neonatal mice

The uterus and upper 3/5 of the vagina originate from the Müllerian duct; however, these organs show quite distinct characteristics in morphology and function. To investigate factors controlling vaginal epithelial cell differentiation from a single layer of pseudostratified epithelium to a multi-layered stratified epithelium with keratin, we focused on fibroblast growth factors (Fgfs). Transformation related protein 63 (Trp63) expression, a marker of stratified epithelium, increased in the Müllerian vaginal epithelial cells from days 0 to 5, and keratin 14 (Krt14) was expressed from day 5, suggesting that Trp63-negative vaginal epithelial cells can differentiate into Trp63-positive cells after birth. Fgf7 and Fgf10 were localized in the vaginal stroma but their receptor, Fgf receptor 2IIIb (Fgfr2IIIb), was localized in the vaginal epithelium. Both Fgf9 and its receptor, Fgfr2IIIc, were localized in the vaginal epithelium. Vaginae cultured with FGF10 or anti-FGF9 antibody showed stratified epithelium with an intense Krt14 expression; however, an inhibitor of phosphorylation of mitogen-activated protein kinase 1/3 (MAPK1/3) canceled the effect of FGF10 and anti-FGF9 antibody. Thus, Fgf10 stimulates the differentiation of pseudostratified epithelial cells into stratified cells via MAPK1/3 pathway, and Fgf9 inhibits this differentiation in the neonatal mouse vagina.     

Tissue distribution of keratin 7 as monitored by a monoclonal antibody

Monoclonal antibody (RCK 105) directed against keratin 7 was obtained after immunization of BALB/c mice with cytoskeletal preparations from T24 cells and characterized by one- (1D) and two-dimensional (2D) immunoblotting. In cultured epithelial cells, known from gel electrophoretic studies to contain keratin 7, this antibody gives a typical keratin intermediate filament staining pattern, comparable to that obtained with polyclonal rabbit antisera to skin keratins or with other monoclonal antibodies, recognizing for example keratins 5 and 8 or keratin 18. Using RCK 105, the distribution of keratin 7 throughout human epithelial tissues was examined and correlated with expression patterns of other keratins. Keratin 7 was found to occur in the columnar and glandular epithelium of the lung, cervix, breast, in bile ducts, collecting ducts in the kidney and in mesothelium, but to be absent from gastrointestinal epithelium, hepatocytes, proximal and distal tubules of the kidney and myoepithelium. Nor could it be detected in the stratified epithelia of the skin, tongue, esophagus, or cervix but strongly stained all cell layers of the urinary bladder transitional epithelium. When applied to carcinomas derived from these different tissue types it became obvious that an antibody to keratin 7 may allow an immunohistochemical distinction between certain types of adenocarcinomas.     

A developmentally regulated wound epithelial antigen of the newt limb regenerate is also present in a variety of secretory/transport cell types

The role of the wound epithelium in amphibian limb regeneration is not understood. We showed previously that monoclonal antibody (mAb) WE3 stains the wound epithelium but not skin epidermis, suggesting that the WE3 antigen may be a marker for, or be important in, the function of the wound epithelium. In the present study, we conducted an extensive immunohistochemical survey of adult newt tissues to define the distribution of the WE3 antigen. The results show that the antigen is most commonly found in tissues specialized in macromolecular secretion and/or ion transport. Since the enzyme, carbonic anhydrase, serves as a useful marker for a variety of specialized transporting cell types, we examined whether this enzyme was present in WE3-reactive cells. Of the tissues examined, a striking degree of colocalization of carbonic anhydrase and the WE3 antigen was observed, further strengthening the view that the WE3 antigen is an important constituent of specialized transporting cells. A preliminary biochemical characterization suggests that the antigen is probably a glycoprotein, which elutes during gel filtration as a species of over 660 kDa. Possible implications for the function of the wound epithelium are discussed.     

Analysis of differentiation antigens on normal and carcinogen-altered rat epithelial cells in vivo and in culture

Two murine monoclonal antibodies, 3BG8 and 9BG8, which were raised against a rat tracheal squamous-cell-carcinoma cell line, recognize cell-surface antigens on normal rat squamous epithelium (skin, esophagus, vagina, and cornea) as well as on carcinogen-exposed, immortalized, rat tracheal epithelial cells. Monoclonal antibody 3BG8 binds to a 115-kilodalton cell-surface protein on undifferentiated basal cells of the epithelium, while the binding of the other antibody, 9BG8, occurs in both differentiated and undifferentiated populations of normal squamous epithelium and squamous cell carcinomas. Undifferentiated tracheal carcinomas bound only the 3BG8 antibody. No binding of either antibody was detected on normal tracheal mucociliary epithelium. Only under conditions that induce squamous differentiation of rat tracheal epithelium was binding of 3BG8 and 9BG8 detected. For reasons which are not clear at present, 9BG8 dramatically inhibits the growth of normal tracheal and esophageal cells in primary culture, whereas only 3BG8 affects the growth of carcinogen-altered tracheal cell lines. Based on antigen characterization and distribution, it is concluded that the 3BG8 and 9BG8 epitopes are localized on differentiation antigens which differ from others that have been previously described.     

A new high molecular mass protein showing unique localization in desmosomal plaque

A high molecular mass protein of 680 kD was identified and purified from the isolated desmosomes in bovine muzzle epidermal cells. This protein, called "desmoyokin" (from the English, yoke) here, showed no binding ability with keratin filaments in vitro, and its molecule had a characteristic dumbell shape approximately 170 nm in length. We have succeeded in obtaining one monoclonal antibody specific to desmoyokin. By the use of this monoclonal antibody and antidesmoplakin monoclonal antibody, desmoyokin was shown to be colocalized with desmoplakin at the immunofluorescence microscopic level; desmoyokin occurred only in the stratified epithelium, not in the simple epithelium nor in the other tissues. At the electron microscopic level, these two proteins were clearly seen to be sorted out in the plaque of desmosomes with desmoyokin at the periphery and desmoplakin at the center of the disk- shaped desmosomal plaque, suggesting that these two plaque proteins play distinct roles in forming and maintaining the desmosomes in stratified epithelium.     

An immunocytochemical method for localization of estrogen receptors in rat tissues using a dinitrophenyl (DNP)-labeled rat monoclonal primary antibody.

We have developed an immunocytochemical method to demonstrate estrogen receptor in hormone-sensitive tissues of the rat using a dinitrophenyl (DNP) hapten-labeled rat antihuman estrogen receptor monoclonal antibody (MAb), H222. Mouse IgM anti-DNP was used secondarily, followed by a DNP/peroxidase conjugate, diaminobenzidine/hydrogen peroxide chromogen, and silver intensification. This method was applied to tissues from intact female rats and showed that estrogen receptor was localized in the nuclei of the stromal and glandular components of the uterine endometrium. Reduced receptor staining was observed in the luminal epithelium, with minimal myometrial staining. Anterior pituitary glands showed heterogeneous immunostaining and ovaries expressed the receptor predominantly in the interstitial cells; fallopian tubes demonstrated substantial epithelial staining. Uteri from chemically castrated rats showed reduced estrogen receptor immunostaining in both stromal and luminal cells, whereas staining was enhanced in the glandular elements. Classical estrogen-unresponsive tissues (heart, lung, and spleen) were unstained. Antibody controls involved pre-blocking antibody recognition sites on the receptor with unlabeled antibodies to estrogen receptor (H222, H226, and D547), as well as use of an inappropriate DNP-labeled antibody to metallothionein. These controls illustrated the specific nature of the DNP-H222 binding.     

Immunohistochemical localization of the transferrin receptor in the seminiferous epithelium of the rat

The transferrin receptor has been immunohistochemically localized in the seminiferous epithelium of the rat with a monoclonal antibody, MRC OX26, which recognizes the transferrin receptor glycoprotein. The receptor was detectable on mitotically and meiotically dividing germ cells and, less abundantly, on round spermatids. It was lost from germ cells during spermatid elongation and was undetectable on immature spermatozoa. The transferrin receptor was also present on Sertoli cells in the testes of immature animals and on Sertoli cells in the testes of aspermatogenic animals that had been irradiated in utero. It was not detectable on Sertoli cells in the testes of cryptorchid animals. These studies demonstrate that the transferrin receptor is abundant on dividing germ cells as well as dividing somatic cells.     

Monoclonal antibodies against a glycoprotein localized in coated pits and endocytic vesicles inhibit alpha 2-macroglobulin binding and uptake

Eight monoclonal antibodies, all IgG2a, which recognize a 180/90-kDa glycoprotein similar in properties to the receptor for alpha 2-macroglobulin of mouse embryo 3T3 cell plasma membranes, have been tested for their effect on the binding and uptake of alpha 2-macroglobulin by live cells. One antibody directly inhibited binding of 125I-alpha 2-macroglobulin under conditions in which 125I-transferrin binding to the transferrin receptor was unaffected. Another monoclonal antibody decreased alpha 2-macroglobulin binding when preincubated with cells at 37 degrees C. This antibody was also capable of specifically binding to ligand-receptor complexes formed by preincubating 125I-alpha 2-macroglobulin with detergent extracts of Swiss 3T3 cells. Immunoelectron microscopy showed that the 180/90-kDa glycoprotein was localized in coated pits of the cell surface and in intracellular endocytic vesicles (receptosomes/endosomes). The data suggest that the 180/90-kDa glycoprotein is a component of the receptor for alpha 2-macroglobulin.     

Laryngeal papillomas: local cellular immune response, keratinization and viral antigen

Various parameters of the local cellular response have been studied in 16 laryngeal papillomas from ten patients with recurrent papillomas as well as normal control laryngeal and tracheal tissue by indirect immunofluorescence on frozen sections using monoclonal antibodies specific for T-cell subsets, Langerhans cells (LC) and HLA-DR antigens. Keratinization was investigated with a monoclonal antibody KL1 recognizing an acidic 56.5 Kd keratin, which is a marker of suprabasal cells in stratified squamous epithelium and is absent from the basal layer. The presence of viral antigen was detected with a rabbit antiserum raised against SDS-dissociated purified virus. A mild inflammatory response was observed in most biopsies. Cytotoxic/suppressor T-cells were the predominant cells found in the lesions. Compared with normal epithelium, the number of LC was dramatically reduced in the papillomatous epithelium. High densities of HLA-DR-positive cells were found mainly in the corium. The keratinization process was disturbed in most specimens in that both basal and suprabasal compartments reacted positively with the KL1 monoclonal antibody. Viral antigen was present in the nucleus of very occasional epithelial cells in some samples.     

Distribution of phosphodiesterase I in normal human tissues

Phosphodiesterase I (PDE I) is an exonuclease capable of hydrolyzing a variety of phosphate ester and pyrophosphate bonds. Cell fractionation and histochemical studies in animal tissues have localized PDE I in the plasma membrane of various epithelia. This suggests a role for the enzyme in active transport. Distribution of PDE I in human tissues has not previously been studied. We have produced a polyclonal antiserum to bovine intestinal PDE I and have demonstrated crossreactivity with the human intestinal enzyme. This polyclonal antiserum was used in PAP immunocytochemistry to localize immunoreactive PDE I in a variety of human tissues. Localization was prominent in the gastrointestinal tract, including the cytoplasm of gastric mucosa parietal cells, cytoplasm of surface epithelium and isolated crypt cells in small intestine, and the colonic epithelial cytoplasm and brush border. Parotid gland acinar cells and scattered ductal cells showed positive cytoplasmic staining. Acinar and scattered pancreatic islet cells contained immunoreactive PDE I, as did Kupffer cells of the liver sinusoids. Immunoreactive PDE I was found in all vascular endothelia. The epithelium of the urinary tract showed extensive immunoreactivity. This included the distal convoluted and collecting tubules of the kidney, and ureteral and bladder urothelium. In previous histochemical studies of animal tissues, no evidence of PDE I activity was noted in male or female reproductive tract. In this study, immunoreactive PDE I was localized to human Sertoli cells and to basal epithelium of the epididymis and prostate acini. Fallopian tube epithelium of female reproductive tract also demonstrated immunoreactive PDI I, as did several cell types in term placenta. Our immunocytochemical results with human tissues differ significantly from previous histochemical studies in animal tissues, principally in the genitourinary system. This may be due in part to the different detection systems employed as well as the higher sensitivity of the immunoperoxidase technique. This underscores the importance of adjunct techniques in tissue surveys. The widespread epithelial distribution of immunoreactive PDE I detected by this polyclonal antibody implies an integral role in cell function, probably in active transport.     

大鼠体内视网膜神经节细胞诱向因子(RGNTF)及其受体的免疫组织化学定位

本文用ＲＧＮＴＦ单克隆抗体及抗独特型单克隆抗体的免疫组织化学反应,对ＲＧＮＴＦ及其受体在 大鼠体内的分布进行了研究．结果显示,大鼠的肾脏、肾上腺、下颌下腺、胃底腺,以及睾丸的生精细胞对 ＲＧＮＴＩＦ均呈现强阳性免疫反应,并对ＲＧＮＴＦ抗独特型单克隆抗体也呈现阳性免疫反应,表明 ＲＧＮＴＦ及其受体有较广泛的分布,这种情况与神经生长因子（ＮＧＦ）及睫状节神经诱向（营养）因子 （ＣＮＴＦ）相类似．但是,ＲＧＮＴＦ及其受体的分布特点和ＮＧＦ、ＣＮＴＦ的分布是不完全相同的,提示作者 分离的ＲＧＮＴＦ与ＮＧＦ和ＣＮＴＦ不是同源物。这样肾上腺皮质、下颌下腺的浆液腺泡及导管上皮细胞、 胃底腺上皮细胞和生精细胞不仅能够产生ＲＧＮＴＦ,也能合成ＲＧＮＴＦ受体。因此,它们对ＲＧＮＴＦ可能 有自分泌的功能,ＲＧＮＴＦ对这些细胞可能有自身调节的效应。     

Characterization of a murine monoclonal antibody specific for an allotypic determinant on T cell antigen receptor

Repeated immunization of normal C57L/J (H-2b) mice with peripheral T cells from BALB.B (H-2b) mice results in the production of antibodies which react with the T cell receptor. A monoclonal antibody-producing hybridoma, F23.1, was isolated from immunized C57L/J mice showing this property. This monoclonal antibody recognizes approximately 25% of peripheral T cells in BALB mice. It stains approximately the same fraction of T cells and precipitates the same heterodimer as the rat monoclonal antibody described previously that was made against isolated receptor material. The allotypic determinant recognized by this monoclonal antibody is present in most common laboratory strains (BALB, C57BL, CBA, A, DBA, C3H) and is absent in C57L, C57BR, and SJL mice. Sorting peripheral T cells from BALB.B or (SJL X BALB/c)F1 mice for the F23.1+ and F23.1- subsets revealed that both populations contain approximately the same CTL precursor frequency for alloantigen. Thus, the T cell receptor allotype defined by F23.1 is present on CTL. Furthermore, cytotoxicity mediated by an F23.1+ CTL line could be blocked specifically by the F23.1 monoclonal antibody. Under appropriate conditions, the monoclonal antibody F23.1 bound to Sepharose 4B beads can induce resting peripheral T lymphocytes of allotype-positive strains to proliferate.     

Fluorescent morphological probe for hyaluronate

Hyaluronate levels change dramatically during morphogenesis of various tissues and organs. Morphological detection of the exact temporal and spatial distribution patterns of hyaluronate may help to elucidate its role in morphogenesis. Since no specific direct method for visualizing hyaluronate with the light or electron microscope is currently available, we have developed a morphological probe by exploiting the high-affinity interaction of cartilage proteoglycan with hyaluronate. The core protein of this proteoglycan consists of a region that binds specifically to hyaluronate with a high association constant, and a region to which the majority of sulfated polysaccharide chains are covalently attached. The polysaccharide chains were removed by treatment with chondroitinase ABC, and the core protein, labeled with rhodamine, was used as the probe. This fluorescent probe binds reversibly and specifically to [3H]hyaluronate in a binding assay using ammonium sulfate precipitation of the core protein. The probe has been used to visualize the cell surface hyaluronate of rat fibrosarcoma cells, 3T3 cells, and SV-40 transformed 3T3 cells, three cell types with significantly different amounts of cell surface-associated hyaluronate.     

Immunological evidence that the nonhormone binding component of avian steroid receptors exists in a wide range of tissues and species

A monoclonal antibody to a fungal protein has been used to demonstrate the presence of the nonhormone binding component of molybdate-stabilized steroid receptors in a variety of vertebrate tissues. We recently identified a steroid receptor in the aquatic fungus Achlya ambisexualis where sexual morphogenesis of the male is directed by the steroid antheridiol. This receptor resembles receptors of higher organisms in exhibiting an 8S, molybdate-stabilized form. In the chick oviduct, a 90 000 molecular weight protein has previously been shown to be associated with the molybdate-stabilized complex of the progesterone receptor. We have isolated a similar protein of molecular weight about 88 000 from A. ambisexualis and have obtained a hybridomal-derived monoclonal antibody directed against it. This mouse anti-Achlya immunoglobulin G1 (IgG1) cross-reacts with the 90 000 molecular weight protein in chick oviduct cytosol and was used to detect analogous 90 000 molecular weight proteins in mammalian tissues. Tissue cytosols were incubated with antibody, and the complexes were isolated onto protein A-Sepharose. The resin-bound proteins were then analyzed by gel electrophoresis. This procedure revealed the presence of 90 000 molecular weight proteins in several mammalian tissues including rat liver, mouse liver and uterus, pig ovarian granulosa cells, human endometrium, and HeLa cells. These results demonstrate that the 90 000 molecular weight protein is not peculiar to the chick oviduct but is present in several different tissues from a variety of animals. This antibody should be a useful probe for further studies on the biological role of these proteins.     

Establishment of a monoclonal antibody for human LXRα: Detection of LXRα protein expression in human macrophages

Liver X activated receptor alpha (LXRalpha) forms a functional dimeric nuclear receptor with RXR that regulates the metabolism of several important lipids, including cholesterol and bile acids. As compared with RXR, the LXRalpha protein level in the cell is low and the LXRalpha protein itself is very hard to detect. We have previously reported that the mRNA for LXRalpha is highly expressed in human cultured macrophages. In order to confirm the presence of the LXRalpha protein in the human macrophage, we have established a monoclonal antibody against LXRalpha, K-8607. The binding of mAb K-8607 to the human LXRalpha protein was confirmed by a wide variety of different techniques, including immunoblotting, immunohistochemistry, and electrophoretic mobility shift assay (EMSA). By immunoblotting with this antibody, the presence of native LXR protein in primary cultured human macrophage was demonstrated, as was its absence in human monocytes. This monoclonal anti-LXRalpha antibody should prove to be a useful tool in the analysis of the human LXRalpha protein.     

Endogenous hyaluronate-cell surface interactions in 3T3 and simian virus-transformed 3T3 cells

3T3 cells have a large, pericellular coat which contains 30 times more hyaluronate than the amount of cell surface hyaluronate associated with simian virus 40-transformed 3T3 (SV-3T3) cells. On the other hand, SV-3T3 cells have high affinity binding sites for exogenously added hyaluronate, whereas 3T3 cells have much lower affinity sites. Removal of cell surface hyaluronate from SV-3T3 cells by treatment with hyaluronidase caused a reproducible increase in their maximum binding capacity for exogenous hyaluronate but no significant change in binding affinity or specificity. For 3T3 cells, however, the maximum amount of binding decreased and the affinity of binding increased after hyaluronidase treatment. When endogenous cell surface hyaluronate was labeled metabolically and then the cells incubated in the presence of exogenous unlabeled hyaluronate, the labeled cell surface hyaluronate was quantitatively displaced from the SV-3T3 cells but was not displaced from the 3T3 cells. Chondroitin sulfate and heparin did not displace cell surface hyaluronate from either cell type. Membranes isolated from SV-3T3 cells bound hyaluronate specifically and with high affinity, whereas membranes from 3T3 cells did not consistently bind a significant amount of hyaluronate. We conclude from these studies that the retention of endogenous hyaluronate on the surface of SV-3T3 cells is mediated by binding sites similar to those detected by the addition of exogenous hyaluronate, and the mechanism of retention of endogenous hyaluronate on the surface of 3T3 cells differs from SV-3T3 cells.