Anticoagulant heparan sulfate proteoglycans expression in the rat ovary peaks in preovulatory granulosa cells

Ovarian granulosa cells synthesize anticoagulant heparan sulfate proteoglycans (aHSPGs), which bind and activate antithrombin III. To determine if aHSPGs could contribute to the control of proteolytic activities involved in follicular development and ovulation, we studied the pattern of expression of these proteoglycans during the ovarian cycle. aHSPGs were localized on cells and tissues by (125)I-labeled antithrombin III binding followed by microscopic autoradiography. Localization of aHSPGs has shown that cultured granulosa cells, hormonally stimulated by gonadotropins to differentiate in vitro, up-regulate their synthesis and release of aHSPGS: In vivo, during gonadotropin-stimulated cycle, aHSPGs are present on granulosa cells of antral follicles and are strongly labeled in preovulatory follicles. These data demonstrate that aHSPG expression in the ovarian follicle is hormonally induced to culminate in preovulatory follicles. Moreover, we have shown that five heparan sulfate core proteins mRNA (perlecan; syndecan-1, -2, and -4; and glypican-1) are synthesized by granulosa cells, providing attachment for anticoagulant heparan sulfate chains on the cell surface and in the extracellular matrix. These core proteins are constantly expressed during the cycle, indicating that modulations of aHSPG levels observed in the ovary are likely controlled at the level of the biosynthesis of anticoagulant heparan sulfate glycosaminoglycan chains. This expression pattern enables aHSPGs to focus serine protease inhibitors in the developing follicle to control proteolysis and fibrin formation at ovulation.     

Metabolic pathways of heparan sulfate proteoglycans in a rat parathyroid cell line.

The distribution of heparan sulfate (HS) proteoglycans in clonal rat parathyroid cells is regulated by the extracellular Ca2+ concentration, which is a principal factor for parathyroid cell function (Takeuchi, Y., Sakaguchi, K., Yanagishita, M., Aurbach, G. D., and Hascall, V. C. (1990) J. Biol. Chem. 265, 13661-13668). Increasing the concentration of extracellular Ca2+ in the physiological range redistributes HS proteoglycans from the cell surface to an intracellular compartment. We have now examined effects of the extracellular Ca2+ concentration on the metabolism of the HS proteoglycans in detail using [35S]sulfate metabolic labeling-chase experiments. Two distinct metabolic pathways were demonstrated: (i) the intracellular generation of HS chains from HS proteoglycans in prelysosomal compartments followed by their release into the medium (pathway 1), and (ii) intracellular generation of HS oligosaccharides from HS chains in prelysosomal compartments, which are eventually degraded into free sulfate in lysosomes (pathway 2). The HS oligosaccharides were exclusively present within the cells, whereas HS chains were found primarily in the medium. The cells do not internalize either HS proteoglycans or HS chains from the medium. These observations indicate that these two degradation pathways are independent. In addition to these pathways, approximately 15% of the HS proteoglycans were released into the medium as a proteoglycan form. Treatment of cells with chloroquine, a lysosomotropic agent, did not affect generation of HS chains but inhibited conversion of HS chains to HS oligosaccharides or to free sulfate and resulted in the release of HS chains from the cells. The drug did not affect metabolic pathway 1. The extracellular Ca2+ concentration did not alter these intracellular degradation pathways for HS proteoglycans in the parathyroid cells. Thus, extracellular Ca2+ appears to regulate only the distribution of HS proteoglycans between the cell surface and intracellular compartments, and the process of cycling between these compartments when extracellular Ca2+ is low.     

Internalization and stepwise degradation of heparan sulfate proteoglycans in rat hepatocytes.

Intracellular transport and degradation of membrane anchored heparan sulfate proteoglycans (HSPGs) were studied in cultured rat hepatocytes labeled with [35S]sulfate and [3H]glucosamine. Pulse chase experiments showed that membrane anchored HSPGs were constitutively transported to the cell surface after completion of polymerization and modification of the glycosaminoglycan chains in the Golgi apparatus. The intact HSPGs had a relatively short residence time at the cell surface and in non-degrading compartments (T(1/2) approximately 2-3 h), while [35S]sulfate labeled degradation products were found in lysosomes, and to a lesser extent in late endosomes. These degradation products which were free heparan sulfate chains with little or no protein covalently attached, were approximately half the size of the original glycosaminoglycan chains and were the only degradation intermediate found in the course of HSPG catabolism in these cells. In cells incubated in the presence of the microtubule perturbant vinblastine, or in the presence of the vacuolar ATPase inhibitor bafilomycin A1, and in cells incubated at 19 degrees C, the endocytosed HSPGs were retained in endosomes and no degradation products were detected. Disruption of lysosomes with glycyl-phenylalanine 2-naphthylamide (GPN) revealed a GPN resistant degradative compartment with both intact and partially degraded HSPGs. This compartment probably corresponds to late endosomes. Treatment of hepatocytes with the thiol protease inhibitor leupeptin inhibited the final degradation of the protein moiety of the HSPGs. The protein portion seems to be degraded completely before the glycosaminoglycan chains are cleaved. The degradation of the glycosaminoglycan chains is rapid and complete with one observable intermediate.     

Recycling of transferrin receptors and heparan sulfate proteoglycans in a rat parathyroid cell line.

We examined recycling of heparan sulfate (HS) proteoglycans and transferrin receptor (Tf-R) in a rat parathyroid cell line. While extracellular Ca2+ concentration ([Ca2+]e) regulates the recycling of HS proteoglycans in parathyroid cells, such that HS proteoglycans only recycle when [Ca2+]e is lowered below physiological levels, recycling of Tf-R occurs equally well both in 0.05 mM (low) and 2 mM (high) [Ca2+]e. Inhibiting endocytosis chemically with phenylarsine oxide or at low temperature (4 degrees C) did not abolish the effects of changing [Ca2+]e on HS proteoglycans in the recycling compartment even though transport of HS proteoglycans from the Golgi complex to the cell surface was inhibited in low [Ca2+]e. Microtubules are not involved in the recycling of HS proteoglycans or of Tf-R since nocodazole did not affect these processes. Inhibiting the increase of intracellular Ca2+ by an intracellular Ca2+ chelator sustained recycling of HS proteoglycans even in the presence of high [Ca2+]e. These observations show that the exocytosis pathway of HS proteoglycans in the recycling compartment is specifically regulated by [Ca2+]e, whereas that for constitutive secretion is not. Therefore, the recycling of HS proteoglycans may be directly related to some functions of parathyroid cells regulated by [Ca2+]e. Although the mechanism by which [Ca2+]e regulates the exocytosis and recycling of HS proteoglycans is uncertain, it is suggested that an increase of intracellular Ca2+ is necessary, but not necessarily sufficient, for inhibiting their exocytosis.     

Differential partition of anticoagulant heparan sulfate proteoglycans synthesized by endothelial and fibroblastic cell lines

The heparan sulfate proteoglycans that bind and activate antithrombin III (aHSPGs) are synthesized by endothelial cells as well as other nonvascular cells. We determined the amounts of cell surface–associated and soluble aHSPGs generated by the rat fat pad endothelial (RFP) cell line and the fibroblast (LTA) cell line. The RFP cells exhibit higher levels of cell surface–associated aHSPGs as compared to LTA cells, whereas LTA cells release larger amounts of soluble aHSPGs as compared to RFP cells. After confluence RFP cells show an increase in both cell surface–associated and soluble aHSPGs. In contrast, postconfluent LTA cells maintain a constant level of cell surface–associated and soluble aHSPGs. These observations indicate that different cells types can preferentially accumulate aHSPGs as cell surface–associated or soluble forms which could reflect alternate biological functions.     

Effect of chlorate on the sulfation of lipoprotein lipase and heparan sulfate proteoglycans. Sulfation of heparan sulfate proteoglycans affects lipoprotein lipase degradation

In avian-cultured adipocytes 76% of the newly synthesized lipoprotein lipase is degraded before release into the medium (Cupp, M., Bensadoun, A., and Melford, K. (1987) J. Biol. Chem. 262, 6383-6388). The same group (Cisar, L. A., Hoogewerf, A. J., Cupp, M., Rapport, C. A., and Bensadoun, A. (1989) J. Biol. Chem. 264, 1767-1774) has proposed that the interaction of lipoprotein lipase with a class of cell surface heparan sulfate proteoglycans is necessary for degradation to occur. To test further this hypothesis, the binding capacity of the plasma membrane for the lipase was decreased by inhibiting the sulfation of glycosaminoglycans with sodium chlorate, an inhibitor of sulfate adenyltransferase. Chlorate decreased sulfate incorporation into trypsin-releasable heparan sulfate proteoglycans to 20% of control levels. The amount of uronic acid in the trypsin-releasable heparan sulfate proteoglycans remained constant. Therefore, chlorate decreased sulfation density on heparan sulfate chains by approximately 5-fold. In the same fractions, chlorate increased the median heparan sulfate Mr measured on Sephacryl S-300. Chlorate decreased the maximum binding of 125I-lipoprotein lipase to adipocytes by 4-fold, but no significant effects on the affinity constants were observed. Chlorate increased lipoprotein lipase secretion in a dose-dependent relationship up to 30 mM. Utilizing a pulse-chase protocol, it was shown that lipase synthesis in control and chlorate-treated cells was not significantly different and that the increased secretion could be accounted for by a decreased lipoprotein lipase degradation rate. In control cells 77 +/- 11% of the synthesized enzyme was degraded whereas in chlorate-treated cells degradation was reduced to 42 +/- 9% of the synthesized amount. The present study shows that decreased sulfation of heparan sulfate proteoglycans decreases the maximum binding of the lipase for the adipocyte cell surface. Consistent with the model that binding of lipoprotein lipase to cell surface heparan sulfate is required for lipase degradation, degradation is reduced in chlorate-treated cultures. In this report it is also shown that chlorate inhibits lipoprotein lipase sulfation and that desulfation of the enzyme has no effect on its catalytic efficiency or on its binding to cultured adipocytes.     

Metabolic labeling of glycosylphosphatidylinositol-anchor of heparan sulfate proteoglycans in rat ovarian granulosa cells.

The glycosylphosphatidylinositol (GPI)-anchor of the plasma membrane-associated heparan sulfate (HS) proteoglycan was metabolically radiolabeled with [3H]myristic acid, [3H]palmitic acid, [3H]inositol, [3H]ethanolamine, or [32P]phosphate in rat ovarian granulosa cell culture. Cell cultures labeled with [3H]myristic acid or [3H]palmitic acid were extracted with 4 M guanidine HCl buffer containing 2% Triton X-100 and the proteoglycans were purified by ion exchange chromatography after extensive delipidation. Specific incorporation of 3H into GPI-anchor was demonstrated by removing the label with a phosphatidylinositol-specific phospholipase C (PI-PLC). Incorporation of 3H activity into glycosaminoglycans and core glycoproteins was also demonstrated. However, the specific activity of 3H in these structures was approximately 2 orders of magnitude lower than that in the GPI-anchor, suggesting that 3H label was the result of the metabolic utilization of catabolic products of the 3H-labeled fatty acids. PI-PLC treatment of cell cultures metabolically labeled with [3H]inositol, [3H]ethanolamine, or [32P]phosphate specifically released radiolabeled cell surface-associated HS proteoglycans indicating the presence of GPI-anchor in these proteoglycans. GPI-anchored HS proteoglycans accounted for 20-30% of the total cell surface-associated HS proteoglycans and virtually all of them were removed by PI-PLC. These results further substantiate the presence of GPI-anchored heparan sulfate proteoglycan in ovarian granulosa cells and its cell surface localization.     

Differential expression of heparan sulfate domains in rat spleen.

The microarchitecture of the spleen is composed of a meshwork of reticulum cells and their matrix. Heparan sulfates (HS) are important components of this meshwork and are involved in processes such as cell adhesion, cell migration, and cytokine/growth factor binding. The expression of HS epitopes was analyzed using anti-HS antibodies. Four different staining patterns were observed, as exemplified by antibodies RB4EA12, HS4E4, AO4B08, and HS4C3. These antibodies recognize different chemical modifications in HS. In adult spleen, RB4EA12 stained only the reticular meshwork and blood vessels in the red pulp and marginal zone. HS4E4 stained blood vessel-associated basal lamina. AO4B08 and HS4C3 stained the reticular meshwork and blood vessels throughout the spleen, but only AO4B08 strongly stained smooth muscle cells and ring fibers. Interleukin-2 localized in the red pulp and marginal zone and was bound to HS. AO4B08, HS4C3, and RB4EA12 but not HS4E4 co-localized with interleukin-2. In 10-day-old spleen, HS4E4 recognized reticular fibers, which were not stained in the adult stage. Immunoelectron microscopy revealed that HS was restricted to basal laminae and reticular fibers. Taken together, data show that HS epitopes are differentially expressed in the spleen and that this may create specific extracellular environments for immunological processes.     

Isolation and characterization of heparan sulfate proteoglycans produced by cloned rat microvascular endothelial cells.

We have isolated heparan sulfate proteoglycans (HSPGs) from cloned rat microvascular endothelial cells using a combination of ion-exchange chromatography, affinity fractionation with antithrombin III (AT III), and gel filtration in denaturing solvents. The anticoagulantly active heparan sulfate proteoglycans (HSPGact) which bind tightly to AT III bear mainly anticoagulantly active heparan sulfate (HSact) whereas the anticoagulantly inactive heparan sulfate proteoglycans (HSPGinact) possess mainly anticoagulantly inactive heparan sulfate (HSinact). HSact and HSinact were also isolated by a combination of ion-exchange chromatography, treatment with protease and chondroitin ABC lyase, and affinity fractionation with AT III. HSact and HSinact have molecular sizes of about 25-30 kDa with the same overall composition of monosaccharides except that HSact exhibits about nine glucuronsyl 3-O-sulfated glucosamines/chain whereas HSinact possesses about three glucuronsyl 3-O-sulfated glucosamines/chain. Direct isolation of the AT III-binding site of HSact by exposing carbohydrate chains to Flavobacterium heparitinase in the presence of protease inhibitor revealed only a single interaction site which contained two to three glucuronsyl 3-O-sulfated glucosamine residues. The core proteins of HSPGact and HSPGinact were isolated by treatment with Flavobacterium heparitinase and purification by ion-exchange chromatography. The molecular sizes of the core proteins were established by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and their primary structures were examined by cleavage with trypsin or endopeptidase Glu-C as well as separation of peptides by reverse-phase high performance liquid chromatography. The results showed that both sets of core proteins exhibited three major components with molecular sizes of 50, 30, and 25 kDa, respectively. The 25-kDa species appears to be a proteolytic degradation product of the 30-kDa species. The peptide mapping revealed that HSPGact and HSPGinact possess extremely similar core proteins.     

Role of heparan sulfate proteoglycans in cell-cell signaling in Drosophila.

Heparan sulfate proteoglycans (HSPGs) are abundant molecules associated with the cell surface and extracellular matrix, and consist of a protein core to which heparan sulfate (HS) glycosaminoglycan (GAG) chains are attached. Although these molecules have been the focus of intense biochemical studies in vitro, their biological functions in vivo were unclear until recently. We have undertaken an in vivo functional study of HSPGs in Drosophila. Our studies, as well as others, demonstrate the critical roles of HSPGs in several major signaling pathways, including ibroblast growth factor (FGF), Wnt, Hedgehog (Hh) and TGF-beta. Our results also suggest that specific HS GAG chain modifications, as well as specific HSPG protein cores, are involved in specific signaling pathways.     

Highly potent and selective peptide-based inhibitors of the hepatitis C virus serine protease: towards smaller inhibitors

Structure-activity studies on a hexapeptide N-terminal cleavage product of a dodecamer substrate led to the identification of very potent and highly specific inhibitors of the HCV NS3 protease/NS4A cofactor peptide complex. The largest increase in potency was accomplished by the introduction of a (4R)-naphthalen-1-yl-4-methoxy substituent to the P2 proline. N-Terminal truncation resulted in tetrapeptides containing a C-terminal carboxylic acid, which exhibited low micromolar activity against the HCV serine protease.     

Extracellular calcium regulates distribution and transport of heparan sulfate proteoglycans in a rat parathyroid cell line

The regulation of the cellular distribution of proteoglycans in a clonal rat parathyroid cell line by extracellular Ca2+ concentrations ([Ca2+]e) was studied. Proteoglycans synthesized by the cells metabolically labeled with [35S]sulfate have been shown to be almost exclusively heparan sulfate (HS) proteoglycans (Yanagishita, M., Brandi, M.L., and Sakaguchi, K. (1989) J. Biol. Chem. 264, 15714-15720), which are generally associated with the plasma membrane. The proportion of HS proteoglycans on the cell surface was approximately 20% in 2.1 mM (high) [Ca2+]e, whereas it increased to 50-60% in 0.05 mM (low) [Ca2+]e. Cell-associated HS proteoglycans redistribute in response to changing [Ca2+]e with a t 1/2 less than 4 min; HS proteoglycans appear on the cell surface as [Ca2+]e decreases and disappear from the cell surface as [Ca2+]e increases. Further, HS proteoglycans on the cell surface recycle to and from an intracellular compartment approximately 10 times before their degradation in low [Ca2+]e but do not recycle in high [Ca2+]e. The distribution of newly synthesized HS proteoglycans is regulated by [Ca2+]e but is independent of [Ca2+]e during biosynthesis. In low [Ca2+]e, at least 50% of the HS proteoglycans pulse-labeled for 10 min are transported from the Golgi complex to the cell surface or to the recycling compartment with a t 1/2 of approximately 20 min. Another approximately 10% appear on the cell surface in either low or high [Ca2+]e in a compartment with a long half-life. Addition of Mg2+ or Ba2+ to the low [Ca2+]e cultures had little effect on the distribution of HS proteoglycans. These observations suggest that [Ca2+]e specifically regulates the distribution and recycling of cell-associated HS proteoglycans in the parathyroid cells.     

Characterization of heparan sulfate proteoglycans synthesized by rat ovarian granulosa cells in culture

Rat ovarian granulosa cells were isolated from immature female rats after stimulation with pregnant mare's serum gonadotropin and maintained in culture. Proteoglycans were labeled using [35S]sulfate, [3H]serine, [3H]glucosamine, or [3H]mannose as precursors. A species of heparan sulfate proteoglycan was purified using DEAE-Sephacel chromatography under dissociative conditions in the presence of detergent. The heparan sulfate proteoglycan, which constituted approximately 15% of the 35S-labeled proteoglycans in the culture medium has a similar hydrodynamic size (Kd = 0.62 on Sepharose CL-2B) and buoyant density distribution in CsCl density gradients as the low buoyant density dermatan sulfate proteoglycan synthesized by the same granulosa cells and described in the accompanying report (Yanagishita, M., and Hascall, V. C. (1983) J. Biol. Chem. 258, 12847-12856). The heparan sulfate chains (average Mr = 28,000) have an average of 0.8-0.9 sulfate groups/repeating disaccharide, of which 50% are N-sulfate, 30% are alkaline-labile O-sulfate (presumably on the 6-position of glucosamine residues), and 20% are alkaline-resistant O-sulfate groups. Alkaline borohydride treatment released both N-linked oligosaccharide-peptides containing mannose, glucosamine, and sialic acid, and O-linked oligosaccharides. Trypsin digestion of the proteoglycan generated fragments which contain (a) glycosaminoglycan-peptides with an average of 2 heparan sulfate chains/peptide; (b) clusters of O-linked oligosaccharides on peptides; and (c) N-linked oligosaccharide-peptides, which are as small as single N-linked oligosaccharides. The compositions of the O-linked and N-linked oligosaccharides and the trypsin fragments of this heparan sulfate proteoglycan were very similar to those of the low buoyant density dermatan sulfate proteoglycan synthesized by the same cells.     

Effects of MgCl2 on the release and recycling of heparan sulfate proteoglycans in a rat parathyroid cell line.

Divalent cations, such as Mg2+, Ba2+, and Co2+, are known to mimic the effects of Ca2+ in parathyroid cells, but it is not clear whether the mechanism of their action is the same as that of Ca2+. We have shown that extracellular Ca2+ concentration ([Ca2+]e) regulates the distribution and recycling of cell-surface heparan sulfate (HS) proteoglycans in a rat parathyroid cell line; at normal to high [Ca2+]e (e.g., 2 mM) HS proteoglycans are primarily localized intracellularly, while at low [Ca2+]e (0.05 mM) they are translocated to the cell surface and rapidly recycle (Takeuchi, Y., Sakaguchi, K., Yanagishita, M., Aurbach, G. D., and Hascall, V. C., 1990, J. Biol. Chem. 265, 13661-13668). We now show that a high concentration of Mg2+ (8 mM) reduces the amount of recycling HS proteoglycans in low [Ca2+]e. However, the primary effects of high Ca2+ and high Mg2+ on the recycling HS proteoglycans are different. High [Ca2+]e causes translocation of HS proteoglycans to intracellular compartments, while high Mg2+ stimulates cleavage of their core proteins and subsequent shedding of HS proteoglycans into the medium, thereby depleting the recycling molecules. However, high Mg2+ does not induce shedding of HS proteoglycans in high [Ca2+]e. The effects of Ba2+ and Co2+ were similar to those of Mg2+, but Sr2+ showed no significant effects on HS proteoglycan translocation. Otherwise, 8 mM Mg2+ did not alter biosynthesis or intracellular catabolism of HS proteoglycans. These observations suggest that the recycling of HS proteoglycans in parathyroid cells is sensitive only to [Ca2+]e, whereas several other divalent cations can deplete the recycling HS proteoglycans by a distinctly different mechanism. Thus, the mechanism by which Ca2+ regulates the amounts of the recycling HS proteoglycans may be more physiological and play a functional role in parathyroid cells.     

Isolation of the heparan sulfate proteoglycans from the extracellular matrix of rat skeletal muscle

We have previously shown that asymmetric collagen-tailed acetylcholinesterase (AChE) is anchored to the extracellular matrix (ECM) by heparan sulfate proteoglycans (HSPGs). Here we present our studies on the characterization of such PGs from the ECM of rat skeletal muscles. After radiolabeling with 35SO4 for 24h, PGs were extracted from the muscle ECM with 4.0 M guanidine-HCl containing protease inhibitors. PGs were subsequently isolated using sequential DEAE-Sephacel chromatography, digestion with chondroitinase ABC, and Sepharose CL-4B. Two different hydrodynamic size species of HSPGs were found. One type had a Mr of 4-6 X 10(5) (Kav = 0.25) as estimated by gel chromatography in the presence of 1% SDS and accounted for 75% of the total HSPGs. The other HSPG had a Mr 1.5-2.5 X 10(5) (Kav = 0.41). The glycosaminoglycan (GAG) side chains (Mr 20,000 and 12,000) were found composed only of heparan sulfate as determined by nitrous acid oxidation and heparitinase treatment. The large-sized HSPG, which is concentrated in synaptic regions, contains only GAG chains of Mr 20,000, suggesting that each HSPG contains only one kind of heparan sulfate chain in its structure. Our results definitively establish by biochemical criteria that the basement membrane of mammalian skeletal muscle contains HSPGs, the likely matrix receptor for the immobilization of the asymmetric collagen-tailed AChE at the neuromuscular junction.     

Partial characterization of heparan and dermatan sulfate proteoglycans synthesized by normal rat glomeruli

Rat glomerular heparan sulfate (HS) and dermatan sulfate (DS) proteoglycan synthesis was studied in vitro and in vivo. Incorporation of [35S]sulfate into macromolecules was linear over 16 h in vitro, and DS was the predominant glycosaminoglycan (GAG), while HS dominated in vivo incubations. Proteoglycans were found in the bottom 2/5 (high density) CsCl gradient fractions and eluted as two overlapping peaks from DEAE-Sephacel columns. The proportion of low density 35S-glycoproteins and 35S-proteoglycans increased with time. Two high buoyant density HS proteoglycans were extracted from glomeruli and eluted in DEAE peak I. The first, HS-tIA, had an Mr of 130 X 10(3) with Mr 12.5 X 10(3) GAG chains. This proteoglycan was released from the tissue by trypsin and was partially displaced by heparin treatment. In addition, it was rapidly released into the medium of label-chase experiments after which it migrated slightly more rapidly than HS-tIA in gels, with HS chains similar in length to its tissue counterpart. The second, HS-tIB, had an Mr of 8.6 X 10(3) with little or no attached protein. This proteoglycan was characterized as intracellular as it resisted release by trypsin treatment or heparin extraction in medium and was not detected in the medium of label-chase experiments. Two tissue DS proteoglycans were characterized. The first, DS-tIA, co-purified with HS-tIA and was the predominant proteoglycan synthesized during 4-h in vitro incubations. Like HS-tIA, it was rapidly released into medium and displaced from cell surfaces or tissue "receptors" by heparin or trypsin treatments. A second, Sepharose CL-6B-excluded DS proteoglycan from DEAE peak II, DS-tII, accumulated in tissue over 16 h in vitro. This proteoglycan was self-associating and contained clusters of iduronic acid residues along its Mr 26 X 10(3) DS chains. It resisted extraction from the tissue with heparin, trypsin, and detergent. No DS-tII was detected in the incubation medium. Instead, medium proteoglycans eluted as single Sepharose CL-6B-included peaks. DS chains from medium proteoglycans were shorter (Mr 18 X 10(3)) and had more regularly spaced iduronic acid residues than GAGs from DS-tII. The length and sulfation patterns of DS-mII GAG were similar to GAG from DS-tIA. Thus, glomeruli rapidly synthesized and released Sepharose CL-6B-included heparin-displaceable DS and HS proteoglycans while retaining a Sepharose CL-6B-excluded self-associating DS proteoglycan and an intracellular HS.     

In vivo turnover of the basement membrane and other heparan sulfate proteoglycans of rat glomerulus

The metabolic turnover of rat glomerular proteoglycans in vivo was investigated. Newly synthesized proteoglycans were labeled during a 7-h period after injecting sodium [35S]sulfate intraperitoneally. At the end of the labeling period a chase dose of sodium sulfate was given. Subsequently at defined times (0-163 h) the kidneys were perfused in situ with 0.01% cetylpyridinium chloride in phosphate-buffered saline to maximize the recovery of 35S-proteoglycans. Glomeruli were isolated from the renal cortex and analyzed for 35S-proteoglycans by autoradiographic, biochemical, and immunochemical methods. Grain counting of autoradiographs revealed a complex turnover pattern of 35S-labeled macromolecules, commencing with a rapid phase followed by a slower phase. Biochemical analysis confirmed the biphasic pattern and showed that the total population of [35S]heparan sulfate proteoglycans had a metabolic half-life (t1/2) of 20 and 60 h in the early and late phases, respectively. Heparan sulfate proteoglycans accounted for 80% of total 35S-proteoglycans, the remainder being chondroitin/dermatan sulfate proteoglycans. Whole glomeruli were extracted with 4% 3-[(cholamidopropyl)dimethy-lammonio]-1-propanesulfonate-4 M guanidine hydrochloride, a procedure which solubilized greater than 95% of the 35S-labeled macromolecules. Of these 11-13% was immunoprecipitated by an antiserum against heparan sulfate proteoglycan which, in immunolocalization experiments, showed specificity for staining the basement membrane of rat glomeruli. Autoradiographic analysis showed that 18% of total radioactivity present at the end of the labeling period was associated with the glomerular basement membrane. The glomerular basement membrane [35S]heparan sulfate proteoglycans, identified by immunoprecipitation, have a very rapid turnover with an initial phase, t1/2 = 5 h, and a later phase t1/2 = 20 h.     

Differential expression of cell surface heparan sulfate proteoglycans in human mammary epithelial cells and lung fibroblasts.

Treating the liposome-intercalatable heparan sulfate proteoglycans from human lung fibroblasts and mammary epithelial cells with heparitinase and chondroitinase ABC revealed different core protein patterns in the two cell types. Lung fibroblasts expressed heparan sulfate proteoglycans with core proteins of approximately 35, 48/90 (fibroglycan), 64 (glypican), and 125 kDa and traces of a hybrid proteoglycan which carried both heparan sulfate and chondroitin sulfate chains. The mammary epithelial cells, in contrast, expressed large amounts of a hybrid proteoglycan and heparan sulfate proteoglycans with core proteins of approximately 35 and 64 kDa, but the fibroglycan and 125-kDa cores were not detectable in these cells. Phosphatidylinositol-specific phospholipase C and monoclonal antibody (mAb) S1 identified the 64-kDa core proteins as glypican, whereas mAb 2E9, which also reacted with proteoglycan from mouse mammary epithelial cells, tentatively identified the hybrid proteoglycans as syndecan. The expression of syndecan in lung fibroblasts was confirmed by amplifying syndecan cDNA sequences from fibroblastic mRNA extracts and demonstrating the cross-reactivity of the encoded recombinant core protein with mAb 2E9. Northern blots failed to detect a message for fibroglycan in the mammary epithelial cells and in several other epithelial cell lines tested, while confirming the expression of both glypican and syndecan in these cells. Confluent fibroblasts expressed higher levels of syndecan mRNA than exponentially growing fibroblasts, but these levels remained lower than observed in epithelial cells. These data formally identify one of the cell surface proteoglycans of human lung fibroblasts as syndecan and indicate that the expression of the cell surface proteoglycans varies in different cell types and under different culture conditions.     

Differential association of rat liver heparan sulfate proteoglycans in membranes of the Golgi apparatus and the plasma membrane

Heparan sulfate proteoglycans (HSPG) of rat liver are associated with the plasma membrane in a hydrophobic intrinsic and a hydrophilic extrinsic form. We were interested in determining whether or not these two forms could be detected in the Golgi apparatus, the subcellular site of addition of oligosaccharides and sulfate to HSPG. In vivo and in vitro radiolabeled HSPG from rat liver Golgi apparatus membranes could only be solubilized with detergents that disrupt the membrane lipid bilayer, suggesting that they are solely associated via hydrophobic interactions. Both forms of HSPG were detected in plasma membranes of rat liver and isolated rat hepatocytes. The detergent-solubilized HSPG bound to octyl-Sepharose columns, whereas the hydrophilic form did not; this latter form, however, was released from the membrane by heparin. The hydrophobic anchor of HSPG in the Golgi and plasma membranes was insensitive to treatment with phosphatidylinositol-specific phospholipase C under conditions in which alkaline phosphatase was sensitive; this suggests that the hydrophobic anchor of HSPG is the core protein itself. Preliminary experiments suggest that the subcellular site of processing of the hydrophobic to the hydrophilic form of HSPG is the plasma membrane. A specific processing activity, probably a protease of the plasma membrane not present in serum or the endoplasmic reticulum membrane, converted hydrophobic HSPG of the Golgi membrane to the hydrophilic form. In addition, pulse-chase experiments with [35S]Na2SO4 in rats demonstrated that at short times, the bulk of the radiolabeled cellular HSPG was in the Golgi apparatus; later on, the bulk of the radioactivity was found in the plasma membrane, the only subcellular site where the hydrophilic form of HSPG was detected.