Basement membrane-like matrix of teratocarcinoma-derived endodermal cells: presence of laminin and heparan sulfate in the matrix at points of attachment to cells

Teratocarcinoma-derived endodermal PYS-2 cells are known to synthesize an extracellular matrix containing the basement membrane molecules laminin, type IV collagen, and heparan sulfate proteoglycan as major constituents (I. Leivo, K. Alitalo, L. Risteli, A. Vaheri, R. Timpl, J. Wartiovaara, Exp Cell Res 137:15-23, 1982). Immunoferritin techniques with specific antibodies were used in the present study to define the ultrastructural localization of the above constituents in the fibrillar network. Laminin was detected in matrix network adjacent to the basal cell membrane and in protruding matrix fibrils that connect the matrix to the cell membrane. Ruthenium red-stainable heparinase-sensitive 10- to 20-nm particles were often present at the junction of the attachment fibrils and the matrix network, or along the attachment fibrils. A corresponding distribution of ferritin label was observed for basement membrane heparan sulfate proteoglycan. Type IV collagen was found in the matrix network but not in the attachment fibrils. The results suggest that the PYS-2 cells are connected to their pericellular matrix by fibrils containing laminin associated with heparan sulfate-containing particles. These results may also have relevance for the attachment of epithelial cells to basement membranes.     

Basement membrane matrix in vitro: focal binding of exogenous fibronectin to the matrix of teratocarcinoma-derived endodermal cells

Interaction of exogenous fibronectin with the basement membrane-like PYS-2 cell matrix, lacking fibronectin and hyaluronic acid but containing heparan sulfate proteoglycan, was studied in vitro. Both human plasma fibronectin and fibronectin in fetal calf serum bound to PYS-2 matrix; also, fragments of fibronectin containing heparin-binding domains but lacking the collagen-binding domain bound to the matrix. In immunoelectron microscopy the bound fibronectin was found as 20-40 nm globules or patches. Distribution of fibronectin differed from that of laminin and correlated best with that of heparan sulfate proteoglycan. The results suggest that the binding of fibronectin to basement membrane matrices is not due to random adherence but involves specific interactions with other components.     

Heterogeneity of heparan sulfate proteoglycans synthesized by PYS-2 cells

Antibodies to the basement membrane proteoglycan produced by the EHS tumor were used to immunoprecipitate [35S]sulfate-labeled protoglycans produced by PYS-2 cells. The immunoprecipitated proteoglycans were subsequently fractionated by CsCl density gradient centrifugation and Sepharose CL-4B chromatography. The culture medium contained a low-density proteoglycan eluting from Sepharose CL-4B at Kav = 0.18, containing heparan sulfate side chains of Mr = 35-40,000. The medium also contained a high-density proteoglycan eluting from Sepharose CL-4B at Kav = 0.23, containing heparan sulfate side chains of Mr = 30,000. The corresponding proteoglycans of the cell layer were all smaller than those in the medium. Since the antibodies used to precipitate those proteoglycans were directed against the protein core, this suggests that these proteoglycans share common antigenic features, and may be derived from a common precursor which undergoes modification by the removal of protein segments and a portion of each heparan sulfate chain.     

Localization of proteoheparan sulfate in rat aorta

This study describes the distribution of heparan sulfate proteoglycan ( HSPG ) within the rat aorta using immunocytochemical (biotin-avidin-peroxidase) and immuno-electron microscopy (125I-autoradiography). Heparan sulfate proteoglycan was isolated from a basement membrane producing mouse EHS sarcoma ( Hassell et al. 1980) and used to generate antisera in rabbits. Light microscopic observations revealed intense immunostaining of the intima and media of normal aorta, adventitial vasa vasorum, and aortic intimal fibromuscular thickenings induced by experimental injury (balloon de-endothelialization). Immunoelectron microscopy using 125I labeled antibodies to HSPG revealed that proteoheparan sulfate was localized to the amorphous layer of basement membrane below aortic and capillary endothelium. In addition, labeled anti- HSPG could be localized to the external lamina surrounding the smooth muscle cells in the hyperplastic intima. These studies reveal that antibodies prepared against a proteoheparan sulfate isolated from a basement membrane producing EHS sarcoma cross react with basement membrane structures within the aortic wall. Furthermore, these results demonstrate that the basement membranes beneath aortic and capillary endothelium and the external lamina surrounding aortic smooth muscle cells contain a heparan sulfate proteoglycan that is antigenically similar.     

Biosynthesis of sulphated macromolecules by rabbit lens epithelium. I. Identification of the major macromolecules synthesized by lens epithelial cells in vitro

Rabbit lens epithelial cells synthesize and secrete a variety of [35S]sulphate-labeled glycoconjugates in vitro. Associated with the cell layer, and with the medium, was a high molecular weight glycoconjugate(s) that contained heparan sulphate which was apparently covalently linked to sulphated glycoprotein. This component(s) was eluted in the void volume of a Sepharose CL-2B column and could not be fractionated by detergent treatment or extraction with lipid solvents. The cell layer also contained glycosaminoglycans (72% heparan sulphate, 28% chondroitin sulphate), as well as a small proportion of a low molecular weight sulphated glycoprotein. The major 35S-labeled species secreted into the medium were sulphated glycoproteins with approximate molecular weights of 120,000 and 35,000 together with a heparan sulphate proteoglycan. This proteoglycan could be precipitated from the culture medium with 30% saturated (NH4)2SO4 and eluted from Sepharose CL-4B columns at approximately the same position (Kav = 0.15) as heparan sulphate proteoglycans described in the basement membrane of the EHS "sarcoma" (Hassell, J. R., P. G. Robey, H. J. Barrach, J. Wilczek, S. I. Rennard, and G. R. Martin, 1980, Proc. Natl. Acad. Sci. USA, 77:4494-4498) and of the mouse mammary epithelium (David, G., and M. Bernfield, 1981, J. Cell Biol., 91:281-286). Its presence in the culture medium was unanticipated but may be explained by the inability of these cultures to deposit a basement membrane when grown on a plastic surface. The relationship of this heparan sulphate proteoglycan to the lens epithelial basement membrane is the subject of the following paper.     

Localization of proteoheparan sulfate in rat aorta

Summary This study describes the distribution of heparan sulfate proteoglycan (HSPG) within the rat aorta using immunocytochemical (biotin-avidin-peroxidase) and immunoelectron microscopy (¹²⁵I-autoradiography). Heparan sulfate proteoglycan was isolated from a basement membrane producing mouse EHS sarcoma (Hassell et al. 1980) and used to generate antisera in rabbits. Light microscopic observations revealed intense immunostaining of the intima and media of normal aorta, adventitial vasa vasorum, and aortic intimal fibromuscular thickenings induced by experimental injury (balloon de-endothelialization). Immunoelectron microscopy using ¹²⁵I labeled antibodies to HSPG revealed that proteoheparan sulfate was localized to the amorphous layer of basement membrane below aortic and capillary endothelium. In addition, labeled anti-HSPG could be localized to the external lamina surrounding the smooth muscle cells in the hyperplastic intima. These studies reveal that antibodies prepared against a proteoheparan sulfate isolated from a basement membrane producting EHS sarcoma cross react with basement membrane structures within the aortic wall. Furthermore, these results demonstrate that the basement membranes beneath aortic and capillary endothelium and the external lamina surrounding aortic smooth muscle cells contain a heparan sulfate proteoglycan that is antigenically similar.     

Multiple heparan sulfate proteoglycans synthesized by a basement membrane producing murine embryonal carcinoma cell line

The murine embryonal carcinoma derived cell line M1536-B3 secretes the basement membrane components laminin and entactin and, when grown in bacteriological dishes, produces and adheres to sacs of basement membrane components. Heparan sulfate proteoglycans have been isolated from these sacs, the cells, and the medium. At least three different heparan sulfate proteoglycans are produced by these cells as determined by proteoglycan size, glycosaminoglycan chain length, and charge density. The positions of the N- and O-sulfate groups in the glycosaminoglycan chains from each proteoglycan appear to be essentially the same despite differences in the size and culture compartment locations of the heparan sulfate proteoglycan. Additionally, small quantities of chondroitin sulfate proteoglycans are found in each fraction and copurify with each heparan sulfate proteoglycan. Because this cell line appears to synthesize at least three different heparan sulfate proteoglycans which are targeted to different final locations (basement membrane, cell surface, and medium), this will be a useful system in which to study the factors which determine final heparan sulfate proteoglycan structures and culture compartment targeting and the possible effects of the protein core(s) on heparan sulfate carbohydrate chain synthesis and secretion.     

Mouse mammary epithelial cells produce basement membrane and cell surface heparan sulfate proteoglycans containing distinct core proteins

Cultured mouse mammary (NMuMG) cells produce heparan sulfate-rich proteoglycans that are found at the cell surface, in the culture medium, and beneath the monolayer. The cell surface proteoglycan consists of a lipophilic membrane-associated domain and an extracellular domain, or ectodomain, that contains both heparan and chondroitin sulfate chains. During culture, the cells release into the medium a soluble proteoglycan that is indistinguishable from the ectodomain released from the cells by trypsin treatment. This medium ectodomain was isolated, purified, and used as an antigen to prepare an affinity-purified serum antibody from rabbits. The antibody recognizes polypeptide determinants on the core protein of the ectodomain of the cell surface proteoglycan. The reactivity of this antibody was compared with that of a serum antibody (BM-1) directed against the low density basement membrane proteoglycan of the Englebarth-Holm-Swarm tumor (Hassell, J. R., W. C. Leyshon, S. R. Ledbetter, B. Tyree, S. Suzuki, M. Kato, K. Kimata, and H. Kleinman. 1985. J. Biol. Chem. 250:8098-8105). The BM-1 antibody recognized a large, low density heparan sulfate-rich proteoglycan in the cells and in the basal extracellular materials beneath the monolayer where it accumulated in patchy deposits. The affinity-purified anti-ectodomain antibody recognized the cell surface proteoglycan on the cells, where it is seen on apical cell surfaces in subconfluent cultures and in fine filamentous arrays at the basal cell surface in confluent cultures, but detected no proteoglycan in the basal extracellular materials beneath the monolayer. The amino acid composition of the purified medium ectodomain was substantially different from that reported for the basement membrane proteoglycan. Thus, NMuMG cells produce at least two heparan sulfate-rich proteoglycans that contain distinct core proteins, a cell surface proteoglycan, and a basement membrane proteoglycan. In newborn mouse skin, these proteoglycans localize to distinct sites; the basement membrane proteoglycan is seen solely at the dermal-epidermal boundary and the cell surface proteoglycan is seen solely at the surfaces of keratinocytes in the basal, spinous, and granular cell layers. These results suggest that although heparan sulfate-rich proteoglycans may have similar glycosaminoglycan chains, they are sorted by the epithelial cells to different sites on the basis of differences in their core proteins.     

Isolation and partial characterization of a rat hepatoma heparan sulfate proteoglycan

A proteoglycan was isolated from a Morris rat hepatoma by sequential precipitations with ammonium sulfate and cetyl pyridinium chloride followed by chromatography on Sepharose CL-4B and DEAE-cellulose. The proteoglycan has a molecular weight of about 1.5 × 10⁵ with 40,000 molecular weight glycosaminoglycan side chains, identified as heparan sulfate based on resistance to chondroitinase and susceptibility to nitrous acid treatment. Immunological studies showed that the protein core of this proteoglycan is immunologically distinct from a rat yolk sac tumor chondroitin sulfate proteoglycan (Å. Oldberg, E. G. Hayman, and E. Ruoslahti, 1981,J. Biol. Chem.256, 10847–10852), but resembles a heparan sulfate proteoglycan isolated from a basement membrane-producing mouse tumor (J. R. Hassell, P.M. Robey, H.-J. Barrach, J. Wilczek, S. R. Rennard, and G. R. Martin, 1980, Proc. Nat. Acad. Sci. USA77, 4494–4498).     

Kinetics of proteoheparan sulfate synthesis, secretion, endocytosis, and catabolism by a hepatocyte cell line

The metabolism of heparan sulfate proteoglycan was studied in monolayer cultures of a rat hepatocyte cell line. Late log cells were labeled with 35SO4(2-) or [3H] glucosamine, and labeled heparan sulfate, measured as nitrous acid-susceptible product, was assayed in the culture medium, the pericellular matrix, and the intracellular pools. Heparan sulfate in the culture medium and the intracellular pools increased linearly with time, while that in the matrix reached a steady-state level after a 10-h labeling period. When pulse-labeled cells were incubated in unlabeled medium, a small fraction of the intracellular pool was released rapidly into the culture medium while the matrix heparan sulfate was taken up by the cells, and the resulting intracellular pool was rapidly catabolized. The structures of the heparan sulfate chains in the three pools were very similar. Both the culture medium pool and the cell-associated fraction of heparan sulfate contained proteoheparan sulfate plus a polydisperse mixture of heparan chains which were attached to little, if any, protein. Pulse-chase data suggested that the free heparan sulfate chains were formed as a result of catabolism of the proteoglycan. When NH4Cl, added to inhibit lysosomal function, was present during either a labeling period or a chase period, the total catabolism of the heparan sulfate chains to monosaccharides plus free SO2-4 was blocked, but the conversion of the proteoglycan to free heparan sulfate chains continued at a reduced rate.     

Lack of heparan sulfate proteoglycan in a discontinuous and irregular placental basement membrane

A discontinuous basement membrane of variable width that surrounds spongiotrophoblast cells of rat placenta was examined for the presence of type IV collagen, laminin, a heparan sulfate proteoglycan, entactin, and fibronectin using monospecific antibodies or antisera and the indirect peroxidase technique. At the level of the light microscope, the basement membrane was immunostained for type IV collagen, laminin, entactin, and fibronectin. Heparan sulfate proteoglycan immunostaining, however, was virtually absent even after pretreatment of sections with 0.1 N acetic acid, pepsin (0.1 microgram/ml) or 0.13 M sodium borohydride. Examination in the electron microscope confirmed the lack of immunostaining for heparan sulfate proteoglycan, whereas the other substances were mainly localized to the lamina densa part of the basement membrane. The absence of heparan sulfate proteoglycan in this discontinuous and irregular basement membrane even though type IV collagen, laminin, entactin, and fibronectin are present, suggests that heparan sulfate proteoglycan may have a structural role in the formation of basement membrane.     

Proteoheparan sulfate from human skin fibroblasts. Evidence for self-interaction via the heparan sulfate side chains

We have studied the affinity between fibroblast proteoheparan sulfate (medium- and cell surface-derived species) and heparan sulfate-agaroses by affinity chromatography. The evidence for an interaction between the heparan sulfate side chains of the proteoglycans and the immobilized heparan sulfate are as follows: (a) the individual side chains released from the proteoglycan by papain bind to the affinity matrix, (b) the bound proteoglycans are desorbed by a solution of cognate heparan sulfate chains, and (c) the core protein obtained by heparan sulfate-lyase digestion of the proteoglycan does not bind to the affinity matrix. The proteoglycans interact only with one subtype of heparan sulfate. The binding of free heparan sulfate chains to the affinity matrix is completely abolished by heparan sulfate oligosaccharides provided they are composed of both iduronate- and glucuronate-containing disaccharide sequences.     

Human basement membrane heparan sulfate proteoglycan core protein: a 467-kD protein containing multiple domains resembling elements of the low density lipoprotein receptor, laminin, neural cell adhesion molecules, and epidermal growth factor

The primary structure of the large human basement membrane heparan sulfate proteoglycan (HSPG) core protein was determined from cDNA clones. The cDNA sequence codes for a 467-kD protein with a 21-residue signal peptide. Analysis of the amino acid sequence showed that the protein consists of five domains. The amino-terminal domain I contains three putative heparan sulfate attachment sites; domain II has four LDL receptor-like repeats; domain III contains repeats similar to those in the short arms of laminin; domain IV has lg-like repeats resembling those in neural cell adhesion molecules; and domain V contains sequences resembling repeats in the G domain of the laminin A chain and repeats in the EGF. The domain structure of the human basement membrane HSPG core protein suggests that this mosaic protein has evolved through shuffling of at least four different functional elements previously identified in other proteins and through duplication of these elements to form the functional domains. Comparison of the human amino acid sequence with a partial amino acid sequence from the corresponding mouse protein (Noonan, D. M., E. A. Horigan, S. R. Ledbetter, G. Vogeli, M. Sasaki, Y. Yamada, and J. R. Hassell. 1988. J. Biol. Chem. 263:16379-16387) shows a major difference between the species in domain IV, which contains the Ig repeats: seven additional repeats are found in the human protein inserted in the middle of the second repeat in the mouse sequence. This suggests either alternative splicing or a very recent duplication event in evolution. The multidomain structure of the basement membrane HSPG implies a versatile role for this protein. The heparan sulfate chains presumably participate in the selective permeability of basement membranes and, additionally, the core protein may be involved in a number of biological functions such as cell binding, LDL-metabolism, basement membrane assembly, calcium binding, and growth- and neurite-promoting activities.     

Heterogeneous distribution of a basement membrane heparan sulfate proteoglycan in rat tissues

A heparan sulfate proteoglycan (HSPG) synthesized by murine parietal yolk sac (PYS-2) cells has been characterized and purified from culture supernatants. A monospecific polyclonal antiserum was raised against it which showed activity against the HSPG core protein and basement membrane specificity in immunohistochemical studies on frozen tissue sections from many rat organs. However, there was no reactivity with some basement membranes, notably those of several smooth muscle types and cardiac muscle. In addition, it was found that pancreatic acinar basement membranes also lacked the HSPG type recognized by this antiserum. Those basement membranes that lacked the HSPG strongly stained with antisera against laminin and type IV collagen. The striking distribution pattern is possibly indicative of multiple species of basement membrane HSPGs of which one type is recognized by this antiserum. Further evidence for multiple HSPGs was derived from the finding that skeletal neuromuscular junction and liver epithelia also did not contain this type of HSPG, though previous reports have indicated the presence of HSPGs at these sites. The PYS-2 HSPG was shown to be antigenically related to the large, low buoyant density HSPG from the murine Engelbreth-Holm swarm tumor. It was, however, confirmed that only a single population of antibodies was present in the serum. Despite the presence of similar epitopes on these two proteoglycans of different hydrodynamic properties, it was apparent that the PYS-2 HSPG represents a basement membrane proteoglycan of distinct properties reflected in its restricted distribution in vivo.     

Codistribution of heparan sulfate proteoglycan, laminin, and fibronectin in the extracellular matrix of normal rat kidney cells and their coordinate absence in transformed cells

We used antibodies raised against both a heparan sulfate proteoglycan purified from a mouse sarcoma and a chondroitin sulfate proteoglycan purified from a rat yolk sac carcinoma to study the appearance and distribution of proteoglycans in cultured cells. Normal rat kidney cells displayed a fibrillar network of immunoreactive material at the cell surface when stained with antibodies to heparan sulfate proteoglycan, while virally transformed rat kidney cells lacked such a surface network. Antibodies to chondroitin sulfate proteoglycan revealed a punctate pattern on the surface of both cell types. The distribution of these two proteoglycans was compared to that of fibronectin by double-labeling immunofluorescent staining. The heparan sulfate proteoglycan was found to codistribute with fibronectin, and fibronectin and laminin gave coincidental stainings. The distribution of chondroitin sulfate proteoglycan was not coincidental with that of fibronectin. Distinct fibers containing fibronectin but lacking chondroitin sulfate proteoglycan were observed. When the transformed cells were cultured in the presence of sodium butyrate, their morphology changed, and fibronectin, laminin, and heparan sulfate proteoglycan appeared at the cell surface in a pattern resembling that of normal cells. These results suggest that fibronectin, laminin, and heparan sulfate proteoglycan may be complexed at the cell surface. The proteoglycan may play a central role in assembly of such complexes since heparan sulfate has been shown to interact with both fibronectin and laminin.     

Interactions of basement membrane components

The binding of laminin, type IV collagen, and heparan sulfate proteoglycan to each other was assessed. Laminin binds preferentially to native type IV (basement membrane) collagen over other collagens. A fragment of laminin (Mr 600 000) containing the three short chains (Mr 200 000) but lacking the long chain (Mr 400 000) showed the same affinity for type IV collagen as the intact protein. The heparan sulfate proteoglycan binds well to laminin and to type IV collagen. These studies show that laminin, type IV collagen and heparan sulfate proteoglycan interact with each other. Such interactions in situ may determine the structure of basement membranes.     

Immunocytochemistry of extracellular matrix in the lamina propria of the rat testis: electron microscopic localization

The distribution of laminin, type IV collagen, heparan sulfate proteoglycan, and fibronectin was investigated in the rat testicular lamina propria by electron microscopic immunocytochemistry. Distinct patterns were observed for each antigen within the extracellular matrix (ECM) layers of the lamina propria. Laminin, type IV collagen, and heparan sulfate proteoglycan all localized to the seminiferous tubule basement membrane. Type IV collagen and heparan sulfate proteoglycan, but not laminin, localized to the seminiferous tubule side of the peritubular myoid cells. All four of the antigens were localized between the peritubular and lymphatic endothelial cells. Failure to localize fibronectin in the ECM layer between the Sertoli and peritubular myoid cells tends to support the concept that adult Sertoli cells do not produce this protein in vivo. Intracellular immunostaining was insufficient to allow unambiguous identification of the cellular source of any of the ECM molecules.     

Chondroitin sulfate proteoglycan is a constituent of the basement membrane in the rat embryo parietal yolk sac

Summary In addition to containing Type IV collagen, laminin and entactin, basement membranes contain small amounts of proteoglycans substituted primarily with heparan sulfate chains. We have previously shown, however, that parietal yolk sacs in organ culture synthesize predominantly chondroitin sulfate proteoglycan. In the present study, we have used histochemical and immunohistochemical techniques coupled with chondroitinase ABC digestion to provide evidence for the presence of chondroitin sulfate proteoglycan in the basement membrane (Reichert's membrane) of the 14.5-day rat embryo parietal yolk sac. The results revealed numerous cuprolinic blue-positive filaments and granules, 20–30 nm in greater length or diameter, dispersed throughout the thickness of the basement membrane. Both structures were removed by preincubating freshly isolated parietal yolk sacs with chondroitinase ABC. A similar labeling pattern was also obtained with immunoelectron microscopy using gold-labeled monoclonal anti-bodies directed against the three major isomers of protein-bound chondroitin sulfate. In contrast, coarser cuprolinic blue granules, 40–100 nm in diameter, were neither sensitive to chondroitinase ABC digestion nor labeled by the monoclonal antibodies. These results thus indicate that Reichert's membrane contains chondroitin sulfate proteoglycan in addition to heparan sulfate proteoglycan.     

Glomerular basement membrane proteoglycans are derived from a large precursor

The basement membrane heparan sulfate proteoglycan produced by the Englebreth-Holm-Swarm (EHS) tumor and by glomeruli were compared by immunological methods. Antibodies to the EHS proteoglycan immunoprecipitated a single precursor protein (Mr = 400,000) from [35S]methionine-pulsed glomeruli, the same size produced by EHS cells. These antibodies detected both heparan sulfate proteoglycans and glycoproteins in extracts of unlabeled glomeruli and glomerular basement membrane. The proteoglycans contained core proteins of varying size (Mr = 150,000 to 400,000) with a Mr = 250,000 species being predominant. The glycoproteins are fragments of the core protein which lack heparan sulfate side chains. Antibodies to glomerular basement membrane proteoglycan immunoprecipitated the precursor protein (Mr = 400,000) synthesized by EHS cells and also reacted with most of the proteolytic fragments of the EHS proteoglycan. This antibody did not, however, react with the P44 fragment, a peptide situated at one end of the EHS proteoglycan core protein. These data suggest that the glomerular basement membrane proteoglycan is synthesized from a large precursor protein which undergoes specific proteolytic processing.     

Bovine arterial smooth muscle cells synthesize two functionally different proteoheparan sulfate species

Cultured arterial smooth muscle cells synthesize two proteoheparan sulfate species. One is found associated with the cells, whereas the other is excreted into the medium. The two proteoheparan sulfates have similar hydrodynamic sizes but differ in the Mr of their core proteins. The cell-associated proteoheparan sulfate has a Mr of 92,000 while that of soluble proteoheparan sulfate is 38,000. The cell-associated and the soluble proteoheparan sulfate species differ in their ability to suppress the proliferation of smooth muscle cells. When added to the culture medium 2-5 micrograms/ml of the cell-associated and 20-25 micrograms/ml of the soluble proteoheparan sulfate species inhibit the growth of smooth muscle cells half maximally. The antiproliferative potency of both species resides in the heparan sulfate chains. Commercially available heparin has no antiproliferative effect and is not able to prevent the antiproliferative action of cellular heparan sulfate. In contrast to heparin, none of the heparan sulfate preparations has anticoagulant activity. Smooth muscle cells endocytose the soluble heparan sulfate at a rate three to four times higher than that of the cell-associated heparan sulfate. The data suggest that the cell-associated and the soluble proteoheparan sulfate species are separate and possibly genetically distinct molecules. Furthermore, the structural determinants for antiproliferative activity and the recognition sites for endocytotic uptake appear to be different.