Release of GPI-anchored membrane proteins by a cell-associated GPI-specific phospholipase D.

Although many glycosylphosphatidylinositol (GPI)-anchored proteins have been observed as soluble forms, the mechanisms by which they are released from the cell surface have not been demonstrated. We show here that a cell-associated GPI-specific phospholipase D (GPI-PLD) releases the GPI-anchored, complement regulatory protein decay-accelerating factor (DAF) from HeLa cells, as well as the basic fibroblast growth factor-binding heparan sulfate proteoglycan from bone marrow stromal cells. DAF found in the HeLa cell culture supernatants contained both [3H]ethanolamine and [3H]inositol, but not [3H]palmitic acid, whereas the soluble heparan sulfate proteoglycan present in bone marrow stromal cell culture supernatants contained [3H]ethanolamine. 125I-labeled GPI-DAF incorporated into the plasma membranes of these two cell types was released in a soluble form lacking the fatty acid GPI-anchor component. GPI-PLD activity was detected in lysates of both HeLa and bone marrow stromal cells. Treatment of HeLa cells with 1,10-phenanthroline, an inhibitor of GPI-PLD, reduced the release of [3H]ethanolamine-DAF by 70%. The hydrolysis of these GPI-anchored molecules is likely to be mediated by an endogenous GPI-PLD because [3H]ethanolamine DAF is constitutively released from HeLa cells maintained in serum-free medium. Furthermore, using PCR, a GPI-PLD mRNA has been identified in cDNA libraries prepared from both cell types. These studies are the first demonstration of the physiologically relevant release of GPI-anchored proteins from cells by a GPI-PLD.     

Glycosylphosphatidylinositol-anchored and core protein-intercalated heparan sulfate proteoglycans in rat ovarian granulosa cells have distinct secretory, endocytotic, and intracellular degradative pathways.

Rat ovarian granulosa cells synthesize two distinct species of plasma membrane-intercalated heparan sulfate (HS) proteoglycans; glycosylphosphatidylinositol (GPI)-anchored and core protein-intercalated HS proteoglycans. Both species of HS proteoglycans are primarily localized on the plasma membrane. Cell surface localization of GPI-anchored and protein-intercalated HS proteoglycans can be determined by their accessibility to exogenously added phosphatidylinositol-specific phospholipase C (PI-PLC) and trypsin, respectively. Kinetic parameters for the processes involving their transfer from the Golgi to the cell surface, endocytosis and secretion, and the modes of intracellular degradation were determined by metabolic labeling experiments using [35S]sulfate and various chase protocols in combination with the use of PI-PLC and trypsin in rat ovarian granulosa cells. The experiments demonstrated that (i) both HS proteoglycan species are transferred from the Golgi to the cell surface with an average transit time of approximately 12 min. (ii) GPI-anchored HS proteoglycans are endocytosed with a t1/2 approximately 3 h, without being shed into the medium, and they are rapidly degraded, t1/2 approximately 25 min, without generating recognizable degradation intermediates. (iii) Protein-intercalated HS proteoglycans are partly (approximately 30%) shed from the cell surface into the medium and the remaining approximately 70% are endocytosed with a t1/2 approximately 4 h. After endocytosis, they undergo a slow (t1/2 approximately 4 h) stepwise degradation generating distinct HS oligosaccharides as degradation intermediates. These results indicate that the GPI-anchored and the protein-intercalated HS proteoglycans have distinct secretory, endocytotic, and intracellular degradation pathways probably due to the differences in their anchor structures.     

Structural comparisons between the soluble and the GPI-anchored forms of the Paramecium temperature-specific 156G surface antigen.

Biosynthetic labelling experiments performed on P primaurelia strain 156, expressing the temperature-specific G surface antigen, 156G SAg, demonstrated that the purified 156G SAg contained the components characteristic of a GPI-anchor. [3H]ethanolamine, [3H]myo-inositol, [32P]phosphoric acid and [3H]myristic acid could all be incorporated into the surface antigen. Myristic acid labelling was lost after treatment in vitro with Bacillus thuringiensis phosphatidylinositol-specific phospholipase C (PI-PLC). After complete digestion by pronase, a fragment containing the intact GPI-anchor of 156G surface antigen was isolated. This fragment was shown to be hydrophobic and glycosylated and to possess an epitope found specifically in the GPI component of GPI-anchored proteins. The role of the GPI-tail in anchoring the 156G surface antigen into the membrane was assessed by determining that purified 156G molecules with the GPI-anchor could be incorporated into lipid vesicles and red cell ghosts whereas the 156G molecules lacking the GPI-anchor, as result of treatment with B thuringiensis PI-PLC, could not. It has also been shown that the membrane-bound form and the soluble form, obtained after cleavage of the 156G SAg lipid moiety either by an endogenous PI-PLC or by a bacterial PI-PLC, displayed identical circular dichroic spectra.     

Glycolipid precursors for the membrane anchor of Trypanosoma brucei variant surface glycoproteins. II. Lipid structures of phosphatidylinositol-specific phospholipase C sensitive and resistant glycolipids

A common diagnostic feature of glycosylinositol phospholipid (GPI)-anchored proteins is their release from the membrane by a phosphatidylinositol-specific phospholipase C (PI-PLC). However, some GPI-anchored proteins are resistant to this enzyme. The best characterized example of this subclass is the human erythrocyte acetylcholinesterase, where the structural basis of PI-PLC resistance has been shown to be the acylation of an inositol hydroxyl group(s) (Roberts, W. L., Myher, J. J., Kuksis, A., Low, M. G., and Rosenberry, T. L. (1988) J. Biol. Chem. 263, 18766-18775). Both PI-PLC-sensitive and resistant GPI-anchor precursors (P2 and P3, respectively) have been found in Trypanosoma brucei, where the major surface glycoprotein is anchored by a PI-PLC-sensitive glycolipid anchor. The accompanying paper (Mayor, S., Menon, A. K., Cross, G. A. M., Ferguson, M. A. J., Dwek, R. A., and Rademacher, T. W. (1990) J. Biol. Chem. 265, 6164-6173) shows that P2 and P3 have identical glycans, indistinguishable from the common core glycan found on all the characterized GPI protein anchors. This paper shows that the single difference between P2 and P3, and the basis for the PI-PLC insusceptibility of P3, is a fatty acid, ester-linked to the inositol residue in P3. The inositol-linked fatty acid can be removed by treatment with mild base to restore PI-PLC sensitivity. Biosynthetic labeling experiments with [3H]palmitic acid and [3H]myristic acid show that [3H]palmitic acid specifically labels the inositol residue in P3 while [3H]myristic acid labels the diacylglycerol portion. Possible models to account for the simultaneous presence of PI-PLC-resistant and sensitive glycolipids are discussed in the context of available information on the biosynthesis of GPI-anchors.     

Two forms of plasma membrane-intercalated heparan sulfate proteoglycan in rat ovarian granulosa cells. Labeling of proteoglycans with a photoactivatable hydrophobic probe and effect of the membrane anchor-specific phospholipase C

The structures of cell-associated heparan sulfate (HS) proteoglycans and their interaction with the plasma membrane was studied using rat ovarian granulosa cell culture. HS proteoglycans were either metabolically labeled by incubating cell cultures with [3H] leucine and [35S]sulfate or labeled in plasma membrane preparations with a photoactivatable reagent, 3-(trifluoromethyl)-3-(m-[125I]iodophenyl)diazirine (TID), a compound which has been shown to selectively label the hydrophobic membrane-binding domains of several proteins. After purification of HS proteoglycans from the labeled cell cultures or from the labeled membrane preparations by repeated Q-Sepharose ion exchange chromatography in 8 M urea, they were analyzed by Superose 6 gel filtration and octyl-Sepharose chromatography both in 4 M guanidine HCl. The results indicated that the HS proteoglycans were labeled with 125I and therefore have an intramembranous domain. Phospholipase C (Bacillus thuringiensis), which specifically cleaves phosphatidylinositol membrane anchors, released approximately 25% of the 35S-labeled HS proteoglycans from the cell surface as well as 20-30% of the 125I-label from the 125I-TID-labeled HS proteoglycans. These data indicate that a subpopulation of HS proteoglycans are intercalated into the plasma membrane through a linkage structure involving phosphatidylinositol. Phospholipase C-resistant, 125I-labeled HS proteoglycans represent those species inserted into membrane through an intercalated peptide sequence. Core protein size of phosphatidylinositol-anchored species estimated by polyacrylamide gel electrophoresis after heparitinase digestion was approximately 80 kDa, and it was significantly larger than that of the directly intercalated species (approximately 70 kDa).     

The major surface antigen, P30, of Toxoplasma gondii is anchored by a glycolipid

P30, the major surface antigen of the parasitic protozoan Toxoplasma gondii, can be specifically labeled with [3H]palmitic acid and with myo-[2-3H]inositol. The fatty acid label can be released by treatment of P30 with phosphatidylinositol-specific phospholipase C (PI-PLC). Such treatment exposes an immunological "cross-reacting determinant" first described on Trypanosoma brucei variant surface glycoprotein. PI-PLC cleavage of intact parasites metabolically labeled with [35S]methionine results in the release of intact P30 polypeptide in a form which migrates faster in polyacrylamide gel electrophoresis. These results argue that P30 is anchored by a glycolipid. Results from thin layer chromatography analysis of purified [3H] palmitate-labeled P30 treated with PI-PLC, together with susceptibility to mild alkali hydrolysis and to cleavage with phospholipase A2, suggest that the glycolipid anchor of T. gondii P30 includes a 1,2-diacylglycerol moiety.     

Effects of monensin on the synthesis, transport, and intracellular degradation of proteoglycans in rat ovarian granulosa cells in culture

Rat ovarian granulosa cells, isolated from immature female rats 48 h after stimulation with 5 IU of pregnant mare's serum gonadotropin, were maintained in culture. The effects of monensin, a monovalent cationic ionophore, on various aspects of proteoglycan metabolism were studied by metabolically labeling cultures with [35S]sulfate, [3H]glucosamine, or [3H]glucose. Monensin inhibited post-translational modification of both heparan sulfate (HS) proteoglycans and dermatan sulfate (DS) proteoglycans, resulting in decreased synthesis of completed proteoglycans [( 35S]sulfate incorporation decreased to 10% of control by 30 microM monensin, with an ED50 approximately 1 microM). Proteoglycans synthesized in the presence of monensin showed undersulfation of both DS and HS glycosaminoglycans and altered N-linked and O-linked oligosaccharides, suggesting that the processing of all sugar moieties is closely associated. Monensin caused a decrease in the endogenous sugar supply to the UDP-N-acetylhexosamine pool as indicated by an increased 3H incorporation into DS chains [( 3H]glucosamine as precursor) in spite of the decrease in glycosaminoglycan synthesis. Monensin reduced and delayed transport of both secretory and membrane-associated proteoglycans from the Golgi complex to the cell surface. It took 2-4 min for newly labeled proteoglycans to reach the main transport process inhibited by monensin. Monensin at 30 microM did not prevent internalization of cell surface 35S-labeled proteoglycans but almost completely inhibited their intracellular degradation to free [35S]sulfate (ED50 approximately 1 microM), resulting in intracellular accumulation of both DS and HS proteoglycans. Pulse-chase experiments demonstrated that one of the intracellular degradation pathways involving proteolysis of both DS and HS proteoglycans and limited endoglycosidic cleavage of HS continued to operate in the presence of monensin. These results suggest that the intracellular degradation of proteoglycans involve both acidic and nonacidic compartments with monensin inhibiting those processes that normally occur in such acidic compartments as endosomes or lysosomes by raising their pH.     

Myristic acid, a rare fatty acid, is the lipid attached to the transforming protein of Rous sarcoma virus and its cellular homolog.

The lipid bound to p60src, the transforming protein of Rous sarcoma virus, has been identified by gas and thin-layer chromatography as the 14-carbon saturated fatty acid, myristic acid. The protein can be labeled biosynthetically with either [3H]myristic acid or [3H]palmitic acid. Incorporation of [3H]myristic acid was noticeably greater than incorporation of [3H]palmitic acid. All of the [3H]myristic acid-derived label in p60src was present as myristic acid. In contrast, none of the radioactivity derived from [3H]palmitic acid was recovered as palmitic acid. Instead, all 3H incorporated into p60src from [3H]palmitic acid arose by metabolism to myristic acid. The cellular tyrosine kinase, p60c-src also contains myristic acid. By comparison of the extent of myristylation of p60v-src with that of the Moloney murine leukemia virus structural protein precursor, Pr65gag, we estimate that greater than 80% of the molecules of p60v-src contain one molecule of this fatty acid. Myristylation is a rare form of protein modification. p60v-src contains 10 to 40% of the myristic acid bound to protein in cells transformed by Rous sarcoma virus and is easily identified in total cell lysates when [3H]myristic acid-labeled proteins are separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Comparison of the amount of [3H]myristic acid-labeled p60src in total cell lysates and in immunoprecipitates suggests that immunoprecipitation with rabbit anti-Rous sarcoma virus tumor sera detects ca. 25% of the p60src present in cells.     

Phosphatidylinositol anchor of HeLa cell alkaline phosphatase

Alkaline phosphatase from cancer cells, HeLa TCRC-1, was biosynthetically labeled with either 3H-fatty acids or [3H]ethanolamine as analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and fluorography of immunoprecipitated material. Phosphatidylinositol-specific phospholipase C (PI-PLC) released a substantial proportion of the 3H-fatty acid label from immunoaffinity-purified alkaline phosphatase but had no effect on the radioactivity of [3H]ethanolamine-labeled material. PI-PLC also liberated catalytically active alkaline phosphatase from viable cells, and this could be selectively blocked by monoclonal antibodies to alkaline phosphatase. However, the alkaline phosphatase released from 3H-fatty acid labeled cells by PI-PLC was not radioactive. By contrast, treatment with bromelain removed both the 3H-fatty acid and the [3H]ethanolamine label from the purified alkaline phosphatase. Subtilisin was also able to remove the [3H]ethanolamine-labeled from purified alkaline phosphatase. The 3H radioactivity in alkaline phosphatase purified from [3H]ethanolamine-labeled cells comigrated with authentic [3H]ethanolamine by anion-exchange chromatography after acid hydrolysis. The data suggest that the 3H-fatty acid and [3H]ethanolamine are covalently attached to the carboxyl-terminal segment since bromelain and subtilisin both release alkaline phosphatase from the membrane by cleavage at that end of the polypeptide chain. The data are consistent with findings for other proteins recently shown to be anchored in the membrane through a glycosylphosphatidylinositol structure and indicate that a similar structure contributes to the membrane anchoring of alkaline phosphatase.     

Incorporation of ethanolamine into insulin-sensitive glycosylated phosphatidylinositol of chick embryo fibroblasts

Insulin sensitive glycosylated phosphatidylinositol (GPI) from chick embryo fibroblasts was isolated and partially characterized. [(3)H]Ethanolamine was incorporated into lipids different from phosphatidylethanolamine, as shown by two sequential thin layer chromatographies (TLC) using an acidic solvent system followed by a basic solvent system. Other isotopes, myo-[(3)H]inositol, [(3)H]glucosamine, [(3)H]galactose, and [(3)H]palmitic acid were also incorporated into these lipids. These lipids were separated into two peaks on the second basic TLC, designated as peaks I and II from the origin. Insulin stimulation of cells caused a rapid breakdown of these two lipids. These two lipids were treated by nitrous acid and phosphatidylinositol-specific phospholipase C (PI-PLC). The radioactivity of peak I lipid was decreased by both treatments, and that of peak II lipid was also decreased by PI-PLC treatment but not significantly by nitrous acid treatment. Peak II lipid did not fulfill the criteria for GPI. Tritium released by the treatment of PI-PLC of peak I lipid was recovered in the aqueous phase. [(3)H]Ethanolamine-labeled peak I lipid was hydrolyzed by acid treatment and the hydrolysis products were analyzed by TLC and high performance liquid chromatography (HPLC). Tritium label was recovered as native label at the rate of 95%. [(3)H]Ethanolamine of peak I lipid was reductively methylated completely with formaldehyde and cyanoborohydride, as shown by HPLC analysis. The results indicate that peak I lipid contains primary ethanolamine as a glycan component and is insulin-sensitive free GPI.     

Fatty acylation of heparan sulfate proteoglycan from human colon carcinoma cells

A number of transmembrane proteins have been recently reported to be modified by the covalent addition of saturated fatty acids which may contribute to membrane targeting and specific protein-lipid interactions. Such modifications have not been reported in cell-associated heparan sulfate proteoglycans, although these macromolecules are known to be hydrophobic. Here, we report that a cell surface heparan sulfate proteoglycan is acylated with both myristate and palmitate, two long-chain saturated fatty acids. When colon carcinoma cells were labeled with [3H]myristic acid, a significant proportion of the label was shown to be specifically incorporated into the protein core of the proteoglycan. Characterization of fatty acyl moiety in the purified proteoglycan by reverse-phase high pressure liquid chromatography revealed that approximately 60% of the covalently bound fatty acids was myristate. We further show that this relatively rare 14-carbon fatty acid was bound to the protein core via a hydroxylamine- and alkali-resistant amide bond. The remaining 40% was the more common 16-carbon palmitate, which was bound via a hydroxylamine- and alkali-sensitive thioester bond. Palmitate appeared to be added post-translationally and derived in part from intracellular elongation of myristate, a process that occurred within the first two hours and was insensitive to inhibition of protein synthesis. Acylation of heparan sulfate proteoglycan represents a novel modification of this gene product and could play a role in a number of biological functions including specific interactions with membrane receptors and ligand stabilization.     

Differentiation of 3T3-L1 preadipocytes with 3-isobutyl-1-methylxanthine and dexamethasone stimulates cell-associated and soluble chondroitin 4-sulfate proteoglycans.

The proteoglycans (cell-associated and culture media) in 3T3-L1 preadipocytes in culture were analyzed before and during differentiation into adipocytes. Cells were metabolically labeled with [35S]sulfate and [3H] glucosamine for 24 h and then extracted and analyzed. There was a 1.68 +/- 0.07-fold increase in the 35S in medium proteoglycan during differentiation, whereas cell-associated proteoglycan radioactivity showed no increase. Analyses of radiolabeled molecules using ion-exchange chromatography, gel filtration, and high performance liquid chromatography after enzymatic or alkaline digestion indicated that all of the 35S label was recovered as two major species of chondroitin 4-sulfate proteoglycans (CSPG-I and CSPG-II) and 7% as heparan sulfate proteoglycan. CSPG-I has a mass of approximately 970 kDa with multiple chondroitin sulfate chains (average of 50 kDa each) and a core protein of approximately 370 kDa including oligosaccharides. CSPG-II has a mass of 140 kDa with one or two chondroitin sulfate chains (average of 68 kDa each) and a core protein of 41 kDa including oligosaccharides. CSPG-I appears to be similar to versican, whereas CSPG-II is similar to decorin and/or biglycan, found in other fibroblastic cells. Cell differentiation was associated with a specific increase in CSPG-I (4.0 +/- 0.2-fold in media and 3.2 +/- 0.5-fold in the cell-associated form). This system should facilitate study of the functional roles of proteoglycans during growth and differentiation.     

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.     

Developmental variation of glycosylphosphatidylinositol membrane anchors in Trypanosoma brucei. Identification of a candidate biosynthetic precursor of the glycosylphosphatidylinositol anchor of the major procyclic stage surface glycoprotein.

The major surface antigen of the mammalian bloodstream form of Trypanosoma brucei, the variant surface glycoprotein (VSG), is attached to the cell membrane by a glycosylphosphatidylinositol (GPI) anchor. The VSG anchor is susceptible to phosphatidylinositol-specific phospholipase C (PI-PLC). Candidate precursor glycolipids, P2 and P3, which are PI-PLC-sensitive and -resistant respectively, have been characterized in the bloodstream stage. In the insect midgut stage, the major surface glycoprotein, procyclic acidic repetitive glycoprotein, is also GPI-anchored but is resistant to PI-PLC. To determine how the structure of the GPI anchor is altered at different life stages, we characterized candidate GPI molecules in procyclic T. brucei. The structure of a major procyclic GPI, PP1, is ethanolamine-PO4-Man alpha 1-2Man alpha 1-6 Man alpha 1-GlcN-acylinositol, linked to lysophosphatidic acid. The inositol can be labeled with [3H]palmitic acid, and the glyceride with [3H]stearic acid. We have also found that all detectable ethanolamine-containing GPIs from procyclic cells contain acylinositol and are resistant to cleavage by PI-PLC. This suggests that the procyclic acidic repetitive glycoprotein GPI anchor structure differs from that of the VSG by virtue of the structures of the GPIs available for transfer.     

A surface antigen of Giardia lamblia with a glycosylphosphatidylinositol anchor.

Since Giardia lamblia trophozoites are exposed to high concentrations of fatty acids in their human small intestinal milieu, we determined the pattern of incorporation of [3H]palmitic acid and myristic acid into G. lamblia proteins. The pattern of fatty acylation was unusually simple since greater than 90% of the Giardia protein biosynthetically labeled with either [3H]palmitate or myristate migrated at approximately 49 kDa (GP49) in reducing sodium dodecyl sulfate-polyacrylamide gel electrophoresis during both growth and differentiation. GP49, which partitions into the Triton X-114 detergent phase, is localized on the cell surface since it is 125I-surface-labeled. GP49 was also biosynthetically labeled with [14C]ethanolamine and [3H]myoinositol, suggesting that it has a glycosylphosphatidylinositol (GPI) anchor. Moreover, phospholipase A2 (PLA2) or mild alkaline treatment released free fatty acids, indicating a diacylglycerol moiety with ester linkages. Finally, a 3H- and 14C-labeled species was released by nitrous acid deamination from [14C]palmitate- and [3H]myoinositol-labeled GP49. The GPI anchor of GP49 is unusual, however, because purified GP49 was cleaved by Bacillus cereus phosphatidylinositol (PI)-specific PLC, but not by Staphylococcus aureus PI-PLC, or plasma PLD, and did not react with antibody against the variant surface glycoprotein cross-reactive determinant. Moreover, the double-labeled deaminated GP49 anchor migrated faster than authentic PI in TLC and produced [3H]glycerophosphoinositol after deacylation. In contrast to the variable cysteine-rich G. lamblia surface antigens described previously, GP49 was identified in Western blots of every isolate tested, as well as in subclones of a single isolate which differ in expression of a major cysteine-rich 85/66-kDa surface antigen, which does not appear to be GPI-anchored. These observations suggest that GP49, the first common surface antigen to be described in G. lamblia, may play an important role in the interaction of this parasite with its environment.     

Glycosylphosphatidylinositol-anchored proteins found in the moss Marchantia polymorpha

A suspension culture of the moss Marchantia polymorpha was incubated with either [3H]ethanolamine or [3H]myristic acid, precursors of a glycosylphosphatidylinositol (GPI) anchor. By both of these a secretory protein of 47 kDa was consistently labelled. Amino acid composition analysis of the chromatographically purified 47-kDa protein exhibited the occurrence of ethanolamine and glucosamine at approximate molar ratios to protein of 1 and 4, respectively. Thus the secretory 47-kDa protein of M. polymorpha was concluded to be a GPI-anchored protein.     

Characterization of calcium accumulation in the brain of rats administered orally calcium: The significance of energy-dependent mechanism

Primary cultures of rat hepatocytes maintained on different matrix proteins such as collagen (Co IV) fibronectin (Fn), Laminin (Ln) or different tissue biomatrices were metabolically labelled with ³⁵[S]-SO₄ and the synthesis of sulphated proteoglycans was studied. The incorporation of the label into total glycosaminoglycan (GAG) was significantly higher in cells maintained on Co IV compared to those maintained on Fn or Ln. Similarly the incorporation of label was maximum in those cells maintained on the aortic biomatrix compared to liver or mammary gland biomatrix. About 80–95% of the GAG synthesised and secreted by cells maintained on individual matrix proteins and liver biomatrix was heparan sulphate (HS). But in the case of cells maintained on collagen IV aortic or mammary biomatrix in addition to HS, significant amount of chondroitin sulphate (CS) was also found. Nearly 50% of the total ³⁵[S]-GAG was associated with the cell layer after 24 h in culture in the case of cells maintained on individual matrix protein while those maintained on tissue biomatrix, retained about 70% of the ³⁵[S]-labelled proteoglycans (PG) with the cell layer. Analysis of the cell surface ³⁵[S]-labelled proteoglycans isolated from cells maintained on different biomatrix showed that it is a hybrid proteoglycan consisting of CS and HS. While the PG isolated from cells maintained on liver biomatrix consists of HS and CS in the ratio of 3:2 that from cells maintained on aorta or mammary gland matrix was about 2:3 indicating an alteration in the nature of the cell surface PGs produced by cells maintained on different tissue biomatrix. These results indicate that depending on the nature of the matrix substratum with which the cells are in contact, the nature and quantity of sulphated proteoglycans produced by hepatocytes vary.     

Acylation of Rat Brain Myelin Proteolipid Protein with Different Fatty Acids

The acylation of rat brain proteolipid protein (PLP) with tritiated palmitic, oleic, and myristic acids was studied in vivo and in vitro and compared with the acylation of lipids. Twenty-four hours after intracranial injection of [3H]myristic acid, only 16% of the PLP-bound label appeared as myristic acid, with 66% as palmitic, 9% as stearic, and 6% as oleic acid, whereas greater than 63% of the label in total or myelin phospholipid was in the form of myristic acid. In contrast, after labelling with [3H]palmitic or oleic acids, 75% and 86%, respectively, of the radioactivity in PLP remained in the original form. When brain tissue slices were incubated for short periods of time, the incorporation of palmitic and oleic acids into PLP exceeded that of myristic acid by a factor of 8. In both systems and with all precursors studied, the label associated with PLP was shown to be in ester linkage. The results suggest a preferential acylation of PLP with palmitic and oleic acids as compared with myristic acid. This is consistent with the fatty acid composition of the isolated PLP.     

Characterization of proteoglycans synthesized by rat thyroid cells in culture and their response to thyroid-stimulating hormone

A Fisher rat thyroid cell line was maintained in culture and the cells were labeled with [3H]glucosamine, [35S]sulfate, and [35S]cysteine to examine the synthesis of proteoglycans. 3H and 35S radioactivity from these precursors were incorporated into both chondroitin sulfate (CS) and heparan sulfate (HS) proteoglycans. CS proteoglycans were almost exclusively secreted into the medium while HS proteoglycans remained mainly associated with the cell layer. Single chain glycosaminoglycans released by papain digestion or alkaline borohydride treatment of either the CS or HS proteoglycans had average molecular weights of approximately 30,000 on Sepharose CL-6B chromatography. Both CS and HS proteoglycans were relatively small and contained only one or two glycosaminoglycans chains. 3H and 35S incorporation into both CS and HS proteoglycans were increased by thyroid-stimulating hormone (TSH) in a dose-dependent manner, which is in part explained by an adenylate cyclase-dependent mechanism as indicated by a similar effect in response to dibutyryl cAMP. TSH enhanced the incorporation of 35S into CS from [35S]cysteine about 1.5-fold and that from [35S]sulfate about 2-fold. This result demonstrated that the increased 35S incorporation from the [35S]sulfate precursor reflects an actual increase in sulfate incorporation and is not simply a result from an apparent increase in specific activity of the phosphoadenosine phosphosulfate donor. Analysis of disaccharides from chondroitinase digests revealed that the proportion of non-sulfated, 4-sulfated, and 6-sulfated disaccharides was not altered appreciably by TSH. These results, together with the disproportionate increase in 3H incorporation into CS from [3H]glucosamine, indicated that TSH increased the specific activity of the 3H label as well. Chase experiments revealed that CS proteoglycans were rapidly (t1/2 = 15 min) secreted into the medium and that the degradation of cell-associated proteoglycans was enhanced by TSH.     

Multiple forms of heparan sulfate proteoglycans in the Engelbreth-Holm-Swarm mouse tumor. The occurrence of high density forms bearing both heparan sulfate and chondroitin sulfate side chains

Heparan sulfate proteoglycan from the Engelbreth-Holm-Swarm mouse tumor was previously separated into two forms: a high density form (Form HD) and low density form (Form LD). In this study, the two forms were radiolabeled either metabolically with [35S]sulfate or [3H]serine or chemically with 125I. Pulse-chase experiments with [35S]sulfate showed no clear precursor-product relationship between the two forms. Analyses of the labeled proteoglycan samples with heparitinase and chondroitinase ABC indicated that Form LD is a large proteoglycan containing heparan sulfate chains attached to a single core molecule (Mr = 450,000), whereas Form HD is a mixture of small proteoglycans with four different size core molecules (Mr = 34,000, 29,000, 27,000, and 21,000), most, if not all, of which bear both heparan sulfate (Mr = 60,000) and chondroitin sulfate (Mr = 17,000) chains. Glycosaminoglycan-enriched fragments obtained from Form HD by V8 protease digestion were also shown to contain both heparitinase-susceptible chains and chondroitinase ABC-susceptible chains. Tryptic peptide maps of 125I-labeled Form HD and the glycosaminoglycan-enriched fragments derived therefrom were quite different from the corresponding maps for Form LD.