Receptors for hyaluronate on the surface of parent and virus-transformed cell lines : Binding and aggregation studies

Two sets of parent and virus-transformed cell lines (3T3 vs SV-3T3; BHK vs PY-BHK) were compared with respect to the extent of divalentcation independent aggregation which previously has been shown to depend upon the interaction of endogenous hyaluronate with specific receptors on the cell surface. When measured under conditions of physiological ionic strength, a significant amount of hyaluronidase-inhibitable aggregation was found in the virus-transformed cell lines (SV-3T3 and PY-BHK) but not in their parent counterparts (3T3 and BHK). However, when the same experiment was performed in a high ionic strength solution (0.5 M NaCl), the hyaluronidase inhibitable aggregation was detected in all of the cell lines. The differences in the aggregation between the various cell lines was also reflected in the binding of [³H]hyaluronate. In physiological saline, the virus-transformed cells bound greater amounts of hyaluronate (higher B_max) with a greater affinity (lower k_d) than did their untransformed counterparts. Increasing the ionic strength to 0.5 M NaCl increased the binding of [³H]hyaluronate by each cell line; however, the relative differences between the cell lines remained. These results indicate that variations in the ability of the cells to bind hyaluronate can partially account for the differences between the parent and the virus-transformed cells with respect to their ability to aggregate.     

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.     

Sulfation of chondroitin sulfate secreted by baby hamster kidney cells and their polyoma virus-transformed counterparts

Sulfation of glycosaminoglycans (GAGs) secreted by baby hamster kidney (BHK) cells and the polyoma virus-transformants (PY-BHK) was investigated. It has been reported that chondroitin sulfate (CS) of cell membranes from PY-BHK cells is undersulfated compared to that from BHK cells (Cancer Res. 43, 2712-2717, 1983). In the first series of experiments of the present study, cells were incubated with [3H]glucosamine and [35S]sulfate, and GAGs isolated from the culture medium were examined. GAG composition was comparable between the BHK and PY-BHK cultures. Disaccharide analysis of the chondroitinase ACII digests of the hyaluronate lyase-resistant materials showed a high proportion (68% for BHK and 47% for PY-BHK) of delta Di-0S, with delta Di-4S (32% for BHK and 53% for PY-BHK) as the major sulfated disaccharide on the basis of 3H-radioactivities. The beta-D-xyloside treatment did not alter the degree of undersulfation of the CS of either culture. In the second series of experiments, disaccharide analysis of the chondroitinase ABC digests of unlabeled GAGs demonstrated similar disaccharide composition for the two cell types. The BHK and PY-BHK preparations showed 28 and 17% (mol percent) of delta Di-0S, 58 and 72% of delta Di-4S, and 14 and 11% of delta Di-6S, respectively. These results indicate a considerable degree of undersulfation of secretory CS from both cells, and a slightly higher degree, if any, of under-sulfation of secretory CS from BHK cells if compared between the two cell types, which is in contrast to the results reported for membrane CS.     

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.     

Heparin-induced aggregation of lymphoid cells

The effects of different carbohydrates on cell-to-cell adhesion were examined in an aggregation assay, which consisted of swirling a suspension of cells and monitoring the loss of single cells with a Coulter Counter. Of the carbohydrates tested, only heparin and dextran sulfate induced cell aggregation. This effect occurred in freshly isolated mouse splenocytes and in cultured cells of lymphoid origin (P388, YAA-CI) but not in cell lines of fibroblastic origins (3T3, SV-3T3, BHK, and PY-BHK). Using the YAA-CI cell line for further study, we found that aggregation could be induced by relatively small amounts of heparin (less than 10 micrograms/ml). Binding experiments with 3H-heparin showed that under normal physiological conditions each YAA-CI cell bound approximately 2 X 10(6) molecules of heparin at saturation with a Kd of 3.5 X 10(-7) M. This binding was blocked by both unlabelled heparin and dextran sulfate but not by other carbohydrates. When the pH of the medium was decreased, the heparin-induced aggregation was inhibited, and the Kd of the 3H-heparin binding was increased. In a similar fashion, when the ionic strength of the medium was increased, heparin-induced aggregation was inhibited and the Kd of the interaction was increased. These results suggest that the aggregation is inversely related to the Kd of the interaction and that the binding of heparin to the cell surface is primarily of an ionic nature.     

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.     

Loss of hyaluronate-dependent coat during myoblast fusion

Cultured myoblasts were found to exhibit extensive, Streptomyces hyaluronidase-sensitive pericellular coats as revealed by exclusion of particles (fixed red blood cells). These coats are not discernible subsequent to fusion of the myoblasts to form myotubes. The myoblasts contained 2.5 times more hyaluronate attached to their cell surface than myotubes when the data was expressed per unit of protein, but no change in hyaluronate was evident on a per DNA basis. Hyaluronidase activities in the cultures were equivalent when expressed per unit of protein. We conclude that, although the myotubes accumulate larger amounts of protein than myoblasts, there is no compensatory increase in hyaluronate.     

Rous sarcoma virus-transformed baby hamster kidney cells express higher levels of asparagine-linked tri- and tetraantennary glycopeptides containing [GlcNAc-beta (1,6)Man-alpha (1,6)Man] and poly-N-acetyllactosamine sequences than baby hamster kidney cells

The alterations in complex-type N-linked oligosaccharides that can occur when an animal cell line is transformed by two dissimilar viruses were examined by comparing the N-linked oligosaccharides of baby hamster kidney (BHK) cells, metabolically radiolabeled with [2-3H]mannose, to the same class of oligosaccharides from BHK cells separately transformed by Rous sarcoma virus (RS-BHK), an RNA retrovirus, and polyoma virus (PY-BHK), a DNA papovavirus. Based on experiments that utilized serial lectin affinity chromatography, glycosidase digestions, and methylation analyses, both RS-BHK and PY-BHK cells demonstrated a significant increase in the relative amounts of tri- and tetraantennary complex-type N-linked oligosaccharides containing the branching sequence, [GlcNAc-beta(1,6)Man-alpha(1,6)Man], compared to the nontransformed BHK cells. In addition, almost all of the poly-N-acetyllactosamine sequence, [GlcNAc-beta(1,3)-Gal-beta(1,4)], was expressed on the tri- and tetraantennary N-linked oligosaccharides from BHK and RS-BHK cells that contain the sequence, [GlcNAc-beta(1,6)Man-beta(1,6)Man]. The increase in the relative amounts of this latter sequence in the transformed cells, therefore, most likely results in an increase in the amount of poly-N-acetyllactosamine sequence on the N-linked glycopeptides of these cells. The analysis of the degree of sialylation of the complex-type N-linked oligosaccharides from BHK and RS-BHK cells by ion exchange chromatography revealed no apparent differences, and in both of these cell types approximately 3% of the glycopeptide fraction radiolabeled with mannose was recovered in a highly negatively charged fraction that was identified by keratanase digestion to be keratan sulfate.     

Comparison of protein sulfation in control and virus-transformed baby hamster kidney cells

Protein sulfation in baby hamster kidney cells (BHK) and their polyoma virus transformants (PY-BHK) was studied comparatively. On in vivo labeling, [35S]-sulfate was incorporated into the 50K protein and proteins in the 100-180K range, represented by the 155K protein. The incorporation into both the 50K and 155K protein was elevated 2-3 fold in PY-BHK cells compared to in BHK cells. Tyrosine-O-sulfate was the only identifiable sulfated amino acid in both proteins. On in vitro labeling with [35S]3'-phosphoadenosine 5'-phosphosulfate (PAPS), at least 6 radioactive protein bands were discernible on gel electrophoresis. Of these, sulfation of the 57K and 60K proteins was elevated in PY-BHK cells compared to in BHK cells, whereas sulfation of the 39K protein was depressed in PY-BHK cells. Tyrosine-O-sulfate was the only identifiable sulfated amino acid in these proteins.     

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.     

Binding of hyaluronate to the surface of cultured cells

The binding of hyaluronate to SV-3T3 cells was measured by incubating a suspension of cells (released from the substratum with EDTA) with 3H-labeled hyaluronate and then applying the suspension to glass fiber filters which retained the cells and the bound hyaluronate. The extent of binding was a function of both the concentration of labeled hyaluronate and the cell number. Most of the binding took place within the first 2 min of the incubation and was not influenced by the presence or absence of divalent cations. The binding of labeled hyaluronate to SV-3T3 cells could be prevented by the addition of an excess of unlabeled hyaluronate. High molecular weight preparations of hyaluronate were more effective in preventing binding than low molecular weight preparations. The binding of [3H]hyaluronate was inhibited by high concentrations of oligosaccharide fragments of hyaluronate consisting of six sugars or more, and by chondroitin. The sulfated glycosaminoglycans (chondroitin-4-sulfate, chondroitin-6-sulfate, dermatan sulfate, heparin, and heparan sulfate) had little or no effect on the binding. The labeled hyaluronate bound to the cells could be totally removed by incubating the cells with testicular hyaluronidase, streptomyces hyaluronidase, or trypsin, indicating that the hyaluronate-binding sites are located on the cell surface.     

Hyaluronate-binding protein of simian virus 40-transformed 3T3 cells: membrane distribution and reconstitution into lipid vesicles

Hyaluronate-binding protein (HABP) has been extracted in detergent from the membranes of simian virus 40-transformed 3T3 (SV-3T3) cells (Underhill et al, J Biol Chem 258:8086-8091, 1983). When SV-3T3 cells were treated with trypsin prior to isolation and dissolution of the membranes, no hyaluronate-binding activity could be detected. This indicates that all of the detectable HABP of SV-3T3 cells is located on the external surface of the plasma membrane rather than on internal membranes, which would be inaccessible to the trypsin. The detergent-extracted HABP from SV-3T3 membranes was reconstituted into the membrane of lipid vesicles, which were formed by addition of exogenous phosphatidylcholine and cholic acid to the extracts followed by removal of detergent by dialysis against 0.02 M Tris pH 8.0 in the presence of protease inhibitors. Reconstitution was assessed by sedimentation in a discontinuous sucrose gradient and by gel filtration on Sepharose 4B in the presence and absence of detergent. The characteristics of binding of hyaluronate to the reconstituted HABP were then compared with those studied previously for the original membrane-bound HABP and the detergent-extracted HABP (Underhill et al, J Biol Chem 258:8086-8091, 1983). It was observed previously that binding of hyaluronate to HABP in the cell membranes was of higher affinity and specificity than to HABP in the detergent extracts of these membranes. It was found here that reconstitution of the extracted HABP into the membranes of lipid vesicles led to restoration of affinity of binding to the level observed in the original cell membranes. However, whereas chondroitin sulfate does not compete significantly for binding of hyaluronate to cell membrane-bound HABP, partial competition was observed for the reconstituted HABP as well as for detergent-extracted HABP. Thus, it is concluded that the high affinity of binding of hyaluronate to the plasma membrane of SV-3T3 cells is in part dependent on insertion of the HABP in the membrane, but that other interactions, not duplicated in our reconstitution experiments, must be necessary for the specificity of the HABP.     

Hyaluronate binding proteins also bind to fibronectin, laminin and collagen

Small molecular weight proteins, isolated from the culture medium of embryonic chick heart fibroblasts and 3T3 cell lines by hyaluronate affinity chromatography, bind in order of apparent affinity, to hyaluronate, fibronectin, collagen and laminin. Such proteins isolated from the MSV-transformed 3T3 cell line bind in greater amounts to the nectins and hyaluronate than do similar proteins isolated from heart fibroblasts or 3T3 cells. These small hyaluronate binding proteins are immunologically distinct from other well characterized proteins such as laminin, fibronectin, bovine serum albumin and actin. Their relationship to other small, extracellular proteins and their possible role in structuring of extracellular matrix are discussed.     

In vitro tumoricidal activity of macrophages against virus-transformed lines with temperature-dependent transformed phenotypic characteristics.

The susceptibility of targets to destruction by tumoricidal rat and mouse macrophages was studied with virus-transformed cell lines in which various elements of the transformed phenotype are only expressed at specific temperatures. BHK cells transformed by the ts3 mutant of polyoma virus, rat embryo 3Y1 cells transformed by a temperature-sensitive A cistron mutant of simian virus 40 (SV40) and the ts-H6-15 temperature-sensitive line of SV40-transformed mouse 3T3 cells were killed in vitro by macrophages at both the permissive (33 °C) or nonpermissive (39 °C) temperatures for expression of the transformed phenotype. 3T3, 3Y1 and BHK cells transformed by wild-type SV40 or polyoma virus were also destroyed by tumoricidal macrophages at both 33 and 39 °C, but untransformed 3T3, 3Y1, and BHK cells were not. Thus, transformed cells are killed by macrophages regardless of whether or not they express cell surface LETS protein or Forssman antigen, display surface changes which permit agglutination by low doses of plant lectins, express SV40 T antigen, have a low saturation density, or exhibit density-dependent inhibition of DNA synthesis.     

Sulfated mucopolysaccharides from normal and virus transformed rodent fibroblasts.

The sulfated mucopolysaccharide composition of normal and virus transformed Balb 3T3 and BHK21 cell lines is reported. It is shown that normal 3T3 cells contain mainly chondroitin sulfate B and heparitin sulfate. Relatively higher amounts of chondroitin sulface AC were observed in polyoma virus transformed 3T3 cells, besides an absolute increase of all the three sulfated mucopolysaccharides in the polyoma and SV 40 transformed cells. It is shown also that the three sulfated mucopolysaccharides are at least in part at the cell surface. Similar differences in sulfated mucopolysaccharide composition of normal and virus transformed BHK cell lines were also observed.     

Changes in the pericellular matrix during differentiation of limb bud mesoderm

Mesodermal cells in the developing chick embryo limb bud appear morphologically homogeneous until stage 21. At stage 22 the prechondrogenic and premyogenic areas begin to condense, culminating in the appearance of cartilage and muscle by stage 25-26. We have examined changes in the hyaluronate-dependent pericellular matrices elaborated by mesodermal cells of the limb bud from different developmental stages and the corresponding changes in production of cell surface-associated and secreted glycosaminoglycans. When placed in culture, most early mesodermal cells (stage 17 lateral plate and stage 19 limb bud) exhibited pericellular coats as visualized by the exclusion of particles. These coats were removed by treatment of the cultures with Streptomyces hyaluronidase. Cells from stage 20-21 limb buds (precondensation) had smaller coats, whereas cells derived from stage 22, 24, and 26 limb buds (condensed chondrogenic and myogenic regions) lacked coats. However, coats were reformed during subsequent cytodifferentiation of chondrocytes; chondrocytes from stage 28 and 30 limb buds, and more mature chondrocytes from stage 38 tibiae, had pericellular coats. Thus, cytodifferentiation of cartilage is accompanied by extensive intercellular matrix accumulation in vivo and reacquisition of pericellular coats in vitro. Although their structure was still dependent on hyaluronate, chondrocyte coats were associated with increased proteoglycan content compared to the coats of early mesodermal cells. The amount of incorporation of [3H]acetate into cell surface hyaluronate remained relatively constant from stages 17 to 38, whereas in the medium compartment, incorporation into hyaluronate was more than 4-fold greater by stage 17 and 19 mesodermal cells than by cells from stages between 20 and 38. However, there was a progressive increase in incorporation into cell surface and medium chondroitin sulfate throughout these developmental stages. Thus, at the time of cellular condensation in the limb bud in vivo, we have observed a reduction in size of hyaluronate-dependent pericellular coats and a dramatic change in the relative proportion of hyaluronate and chondroitin sulfate produced by the mesodermal cells in vitro.     

Characterization of phosphatidylthreonine in polyoma virus transformed fibroblasts.

A threonine phospholipid in polyoma virus-transformed hamster embryo fibroblasts has been characterized as phosphatidylthreonine. The identification has been made by chemical and enzymatic hydrolysis. Acid hydrolysis of the phospholipid produces free threonine. Mild alcoholysis produces a water-soluble derivative having the properties of glycerophosphorylthreonine. Hydrolysis with phospholipase C produces phosphorylthreonine which on prolonged acid hydrolysis yields threonine. Phosphatidylthreonine in the cell is more accessible to reaction with fluorodinitrobenzene than is phosphatidylserine. Phosphatidylthreonine also has been found as a major aminophospholipid in two other polyoma-transformed hamster cell lines and in the BHK-21/C13 line including the PVT-3 and TS-3 lines. the latter derived from BHK cells. Only a trace amount of phosphatidylthreonine occurs in normal liver, kidney and spleen of the adult mouse, in normal liver and kidney of the adult hamster, in whole mouse and hamster embryos, and in mouse 3T3 cells and SV40-transformed 3T3 cells.     

Hyaluronate degradation in 3T3 and simian virus-transformed 3T3 cells

The cellular control of hyaluronate levels was examined in cultures of simian virus 40-transformed 3T3 (SV3T3) and 3T3 cells which are known to differ in their metabolism of hyaluronate. When [3H]hyaluronate was added to cultures of the two cell lines, four times more ligand was bound per mg of protein by the SV3T3 cells than by the 3T3 cells. Of the bound [3H] hyaluronate, 40% was degraded by the SV3T3 cells to oligosaccharides characteristic of the breakdown of hyaluronate, but only 2% was degraded by 3T3 cells. Hyaluronidase activity was found in the cell layer and medium of the SV3T3 cultures, but was not detectable in 3T3 cells. The SV3T3 enzyme was active only at acidic pH, but at neutral pH the secreted SV3T3 hyaluronidase was thermally more stable then the cell-associated enzyme. In contrast, both cell lines were found to contain similar amounts of beta-glucuronidase and beta-N-acetylglucosaminidase activity. We conclude that the elevated capacity of SV3T3 cells to degrade hyaluronate may be partially responsible for their lack of the hyaluronate-containing pericellular coat which is prominent around 3T3 cells.     

Inhibition of spontaneous aggregation by wheat germ agglutinin in suspensions of BALB/c-3T3 and BHK21 tissue culture fibroblasts

A quantitative method of measuring cytoaggregation based on the Coulter electronic cell counter has been applied to the agglutination of BALB/c-3T3 and BHK21 tissue culture fibroblasts by wheat germ agglutinin. When agglutinin is added to transformed or trypsinized cell suspensions high aggregation rates are seen, and the results obtained are in close agreement with the well-known sensitivity of transformed cells to agglutination by lectins.In the absence of agglutinin, a small but reproducible amount of spontaneous aggregation can also be detected. It is related in some way to growth, since it is absent in suspension prepared from confluent (density-inhibited) cultures and is induced by either transfer to low density, additional serum, or transformation by viruses. Under conditions favouring growth, both BALB/c-3T3 and BHK21 cells show aggregation indices close to 25, corresponding to 10% of the maximum aggregation rate seen.This spontaneous aggregation is susceptible to inhibition by agglutinin. Inhibition occurs at low concentration (about 10 μg/ml) and aggregation rates thus pass through a minimum as the concentration of agglutinin is increased. Among the four different cell lines studied, sensitivity to inhibition is inversely related to agglutination. Thus 3T3 cells, which are barely agglutinated by 1 mg/ml of agglutinin, show 90% inhibition; polyoma virus-transformed BHK cells, which are agglutinated by 10 μg of agglutinin, show no inhibition at all.It is suggested that the agglutination of transformed cells is a consequence of their failure to respond to an inhibitory effect exerted by lectins upon an intrinsic adhesive property of the cell surface.     

The hyaluronate receptor is preferentially expressed on proliferating epithelial cells

In the present study, we have examined the distribution of the hyaluronate receptor as well as hyaluronate itself in a variety of adult tissues. The hyaluronate receptor was localized with a monoclonal antibody, termed K-3, while hyaluronate was localized using proteolytic fragments of cartilage proteoglycan. Staining with the K-3 monoclonal antibody revealed that the hyaluronate receptor was present in a variety of epithelia including the skin, cheek, tongue, esophagus, vagina, intestines, oviduct, and bladder. However, it was notably absent from epithelial cells of the cornea and stomach as well as from endothelial cells of blood vessels. When present, the hyaluronate receptor was preferentially located in regions of active cell growth, such as in the basal layers of stratified epithelium and at the base of the crypts of Lieberkuhn in intestinal epithelium. A similar phenomenon was observed in cultured 3T3 cells. Cultures of 3T3 cells that were actively proliferating were found to have greater amounts of the receptor than their nonproliferating counterparts. When the various tissues were examined for hyaluronate, it was found to have a widespread distribution, being present in most of the basement membranes and between the cells in stratified epithelium. Indeed, in many cases, the distribution of hyaluronate closely paralleled that of the hyaluronate receptor. These results suggest that the interaction between hyaluronate and its receptor is involved in cell-to-substratum adhesion.