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.     

Paramecium GPI proteins: variability of expression and localization

In Paramecium primaurelia, the two major classes of cell surface proteins, the surface antigen (SAg) and the surface GPI proteins (SGPs), are linked to the plasma membrane through a glycosylphosphatidylinositol (GPI) anchor. In the present study, we have characterized the expression of the SGPs in several geographical strains of P. primaurelia and P. tetraurelia at different temperatures, 23 degrees C and 32 degrees C. The identification of the expressed SGPs was performed on purified cilia, by establishing the SGP SDS-PAGE profiles under four different conditions: with or without their anchoring lipid, cleaved with a Bacillus thuringiensis phosphatidylinositol-specific phospholipase C (PI-PLC), and either in a reduced or in an unreduced state. This screening revealed the existence of specific sets of ciliary SGPs, as a function of temperature and the geographical origin of the strains. The SGPs the most abundant at 23 degrees C and 32 degrees C displayed a rapid turnover. We also looked for the presence of PI-PLC releasable proteins in purified cortices. In addition to the SAg and SGPs, the cortical fraction was shown to contain other PI-PLC releasable proteins, not found in the ciliary fraction, thus localized exclusively in the interciliary region.     

Glycosylinositol-phosphoceramide in the free-living protozoan Paramecium primaurelia: modification of core glycans by mannosyl phosphate.

Glycolipids synthesized in a cell-free system prepared from the free-living protozoan Paramecium primaurelia and labelled with [3H]mannose and [3H]glucosamine using GDP-[3H]mannose and UDP-[3H]N-acetyl glucosamine, respectively, were identified and structurally characterized as glycosylinositol-phosphoceramides (GIP-ceramides). The ceramide-based lipid was also found in the GIP membrane anchor of the G surface antigen of P.primaurelia, strain 156. Using a combination of in vitro labelling with GDP-[3H]mannose and in vivo labelling with 33P, we found that the core glycans of the P.primaurelia GIP-ceramides were substituted with an acid-labile modification identified as mannosyl phosphate. The modification of the glycosylinositol-phospholipid core glycan by mannosyl phosphate has not been described to date in other organisms. The biosynthesis of GIP-ceramide intermediates in P.primaurelia was studied by a pulse-chase analysis. Their structural characterization is reported. We propose the following structure for the putative GIP-ceramide membrane anchor precursor of P.primaurelia surface proteins: ethanolamine phosphate-6Man-alpha 1-2Man-alpha 1-6Man-(mannosyl phosphate)-alpha 1-4glucosamine-inositol-phosphoceramide.     

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.     

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.     

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.     

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.     

Identification of a novel insulin-sensitive glycophospholipid from H35 hepatoma cells

This study identifies and partially characterizes an insulin-sensitive glycophospholipid in H35 hepatoma cells. The incorporation of [3H]glucosamine into cell lipids was investigated. A major labeled lipid was purified by sequential thin layer chromatography using first an acid followed by a basic solvent system. After hydrochloric acid hydrolysis and sugar analysis by thin layer chromatography, 80% of the radioactivity in the purified lipid was found to comigrate with glucosamine. H35 cells were prelabeled with [3H]glucosamine for either 4 or 24 h and treated with insulin causing a dose-dependent stimulation of turnover of the glycophospholipid which was detected within 1 min. The purified glycolipid was cleaved by nitrous acid deamination indicating that the glucosamine C-1 was linked to the lipid moiety through a glycosidic bond. [14C]Ethanolamine, [3H]inositol, and [3H]sorbitol were not incorporated into the purified glycolipid. The incorporation of various fatty acids into this glycolipid was also studied. [3H]Palmitate was found to be preferentially incorporated while myristic acid, stearic acid, oleic acid, linoleic acid, linolenic acid, and arachidonic acid were either not incorporated or incorporated less than 10% of palmitate. The purified glycolipid labeled with [3H]palmitate was cleaved by treatment with phospholipase A2 but was resistant to mild alkali hydrolysis suggesting the presence of a 1-hexadecyl,2-palmitoyl-glyceryl moiety in the purified lipid. Treatment of labeled glycophospholipid with phosphatidylinositol-specific phospholipase C from Staphylococcus aureus generated a compound migrating as 1-alkyl,2-acyl-glycerol and a polar head group with a size in the range from 800 to 3500. These findings coupled with the nitrous acid deamination demonstrate that glucosamine was covalently linked through a phosphodiester bond to the glyceryl moiety of the purified glycolipid. These findings suggest that insulin acts on this glycophospholipid by stimulating an insulin-sensitive phospholipase C. This unique glycophospholipid may play an important role in insulin action by serving as precursor of insulin-generated mediators.     

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.     

Decay accelerating factor of complement is anchored to cells by a C-terminal glycolipid

Membrane-associated decay accelerating factor (DAF) of human erythrocytes (Ehu) was analyzed for a C-terminal glycolipid anchoring structure. Automated amino acid analysis of DAF following reductive radiomethylation revealed ethanolamine and glucosamine residues in proportions identical with those present in the Ehu acetylcholinesterase (AChE) anchor. Cleavage of radiomethylated 70-kilodalton (kDa) DAF with papain released the labeled ethanolamine and glucosamine and generated 61- and 55-kDa DAF products that retained all labeled Lys and labeled N-terminal Asp. Incubation of intact Ehu with phosphatidylinositol-specific phospholipase C (PI-PLC), which cleaves the anchors in trypanosome membrane form variant surface glycoproteins (mfVSGs) and murine thymocyte Thy-1 antigen, released 15% of the cell-associated DAF antigen. The released 67-kDa PI-PLC DAF derivative retained its ability to decay the classical C3 convertase C4b2a but was unable to membrane-incorporate and displayed physicochemical properties similar to urine DAF, a hydrophilic DAF form that can be isolated from urine. Nitrous acid deamination cleavage of Ehu DAF at glucosamine following labeling with the lipophilic photoreagent 3-(trifluoromethyl)-3-(m-[125I]iodophenyl)diazirine ([125I]TID) released the [125I]TID label in a parallel fashion as from [125I]TID-labeled AChE. Biosynthetic labeling of HeLa cells with [3H]ethanolamine resulted in rapid 3H incorporation into both 48-kDa pro-DAF and 72-kDa mature epithelial cell DAF. Our findings indicate that DAF and AChE are anchored in Ehu by the same or a similar glycolipid structure and that, like VSGs, this structure is incorporated into DAF early in DAF biosynthesis prior to processing of pro-DAF in the Golgi.     

Characterization with monoclonal antibodies of a surface antigen of Plasmodium falciparum merozoites

The merozoite, the extracellular form of the erythrocyte stage of the malarial parasite, invades the erythrocyte and develops intracellularly. Cloned hybridoma cell lines secreting monoclonal antibodies directed against the merozoite surface were selected by indirect immunofluorescent assay by using intact isolated merozoites. Monoclonal antibodies to a 200,000 m.w. merozoite surface antigen were selected and were used to characterize this protein and its role in erythrocyte invasion. Immunoelectron microscopy demonstrated that the antigen was located exclusively on the merozoite surface coat, distributed evenly over the entire surface. The 200,000 m.w. protein incorporated [3H]glucosamine, suggesting that it is a glycoprotein and could be purified to homogeneity by using immuno-affinity chromatography. Freshly isolated, invasive merozoites retained the 200,000 m.w. antigen, but the protein was rapidly cleaved to proteins of 90,000 and 50,000 m.w. when the merozoite was extracellular. The 50,000 m.w. fragment was retained the epitope binding to monoclonal antibody 5B1 and were labeled with [3H]glucosamine. Monoclonal antibodies against the 200,000 m.w. antigen partially inhibited merozoite invasion into erythrocytes.     

A new class of Paramecium surface proteins anchored in the plasma membrane by a glycosylinositol phospholipid. Membrane anchor of Paramecium cross-reacting glycoproteins.

Treatment of paramecia with ethanol or Triton X-100 solubilizes a major membrane protein, namely the surface antigen (SAg), and a set of glycopeptides in the range 40-60 kDa, which cross-react with the SAg. We demonstrate that these glycopeptides, called 'cross-reacting glycoproteins' (CRGs), are distinct molecules from the SAg. First, after purification of CRGs from ethanolic extracts of Paramecium primaurelia expressing the 156G SAg, the amino acid composition of a given CRG was found to be different from, and incompatible with, that of the 156G SAg. Secondly, we showed that the CRGs, although not immunologically detectable, are present in fractions containing the myristoylated form of the 156G SAg. The treatment of these fractions by phosphatidylinositol-specific phospholipases C enables us to reveal the CRGs through the unmasking of two distinct epitopes. One is the 'cross-reacting determinant' (CRD), initially described for the variant surface glycoproteins (VSGs) of Trypanosoma; the other determinant, called 'det-2355', is specific to the SAg and to the CRGs. Our results suggest that (1) phosphatidylinositol is covalently linked to the CRGs and (2) the CRD and the det-2355 are localized in the same region of the CRGs. We propose that the CRGs are a new set of surface proteins anchored in the cell membrane of Paramecium via a glycosylinositol phospholipid, in the same way as the SAgs.     

Characterization of [3H]palmitate- and [3H]ethanolamine-labelled proteins in the multicellular parasitic trematode Schistosoma mansoni.

Biosynthetic labelling experiments with cercariae and schistosomula of the multicellular parasitic trematode Schistosoma mansoni were performed to determine whether [3H]palmitate or [3H]ethanolamine was incorporated into proteins. Parasites incorporated [3H]palmitate into numerous proteins, as judged by SDS/polyacrylamide-gel electrophoresis and fluorography. The radiolabel was resistant to extraction with chloroform, but sensitive to alkaline hydrolysis, indicating the presence of an ester bond. Further investigation of the major 22 kDa [3H]palmitate-labelled species showed that the label could be recovered in a Pronase fragment which bound detergent and had an apparent molecular mass of 1200 Da as determined by gel filtration on Sephadex LH-20. Schistosomula incubated with [3H]ethanolamine for up to 24 h incorporated this precursor into several proteins; labelled Pronase fragments recovered from the three most intensely labelled proteins were hydrophilic and had a molecular mass of approx. 200 Da. Furthermore, reductive methylation of such fragments showed that the [3H]ethanolamine bears a free amino group, indicating the lack of an amide linkage. We also evaluated the effect of phosphatidylinositol-specific phospholipase C from Staphylococcus aureus: [3H]palmitate-labelled proteins of schistosomula and surface-iodinated proteins were resistant to hydrolysis with this enzyme. In conclusion, [3H]palmitate and [3H]ethanolamine are incorporated into distinct proteins of cercariae and schistosomula which do not bear glycophospholipid anchors. The [3H]ethanolamine-labelled proteins represent a novel variety of protein modification.     

Paramecium GPI Proteins: Variability of Expression and Localization

In Paramecium primaurelia, the two major classes of cell surface proteins, the surface antigen (SAg) and the surface GPI proteins (SGPs), are linked to the plasma membrane through a glycosylphosphatidylinositol (GPI) anchor. In the present study, we have characterized the expression of the SGPs in several geographical strains of P. primaurelia and P. tetraurelia at different temperatures, 23 °C and 32 °C. The identification of the expressed SGPs was performed on purified cilia, by establishing the SGP SDS-PAGE profiles under four different conditions: with or without their anchoring lipid, cleaved with a Bacillus thuringiensis phosphatidylinositol-specific phospholipase C (PI-PLC), and either in a reduced or in an unreduced state. This screening revealed the existence of specific sets of ciliary SGPs, as a function of temperature and the geographical origin of the strains. The SGPs the most abundant at 23 °C and 32 °C displayed a rapid turnover. We also looked for the presence of PI-PLC releasable proteins in purified cortices. In addition to the SAg and SGPs, the cortical fraction was shown to contain other PI-PLC releasable proteins, not found in the ciliary fraction, thus localized exclusively in the interciliary region.     

Activation of phospholipase C by the alpha subunits of the Gq and G11 proteins in transfected Cos-7 cells.

High efficiency transient transfection was used to introduce cDNA corresponding to various G protein alpha subunits into Cos-7 cells. The proteins that were subsequently synthesized were detected with specific G protein alpha subunit antipeptide antiserum and were localized in the membrane fraction of the cell. Cells that were prelabeled with the [3H]inositol and transfected with G alpha q and G alpha 11 cDNA showed marked increases in formation of [3H]inositol phosphates after stimulation with aluminum fluoride. Co-transfection with cDNAs corresponding to phosphoinositide specific phospholipase C beta 1 (PI-PLC beta 1) and to G alpha q or G alpha 11 resulted in even higher levels of inositol phosphate formation. The introduction of mutations that convert residue glutamine 209 to leucine in G alpha q and G alpha 11 resulted in persistent activation of PI-PLC and high steady state levels of inositol phosphates. On the other hand, transfection with a variety of other G alpha subunit cDNAs, i.e. G alpha Z, G alpha OA, G alpha OB, transducin, and the glutamine 205 to leucine mutants of G alpha Z and of G alpha OA did not increase inositol phosphate formation. To further test the specificity of G protein activation of PI-PLC, a cell-free system was prepared by using washed membranes of transiently transfected cells and purified PI-PLC beta 1. Membranes derived from G alpha q and G alpha 11, but not G alpha OA transfected cells, showed guanosine 5-O-thiotriphosphate (GTP gamma S)-stimulated PIP2 hydrolysis. The activity seen in the system reconstituted with membranes derived from G alpha 11-transfected cells was blocked by preincubation with specific G alpha 11 antipeptide antibodies. All of these results are consistent with the conclusion that G alpha q and G alpha 11 cDNA encode proteins that in the presence of GTP gamma S specifically activate PI-PLC.     

The glycophospholipid anchor of Thy-1. Biosynthetic labeling experiments with wild-type and class E Thy-1 negative lymphomas

The Thy-1 antigen of the surface of lymphocytes and neurons is anchored to the plasma membrane via a glycophospholipid moiety. In contrast, the Thy-1 synthesized by the class E Thy-1 negative mutant lymphoma is secreted as a hydrophilic species. The present investigation uses the approach of biosynthetic labeling to investigate further the structure of the intracellular Thy-1 of wild-type cells and the secreted Thy-1 of these mutant cells. In the wild-type cells, Thy-1 can be labeled with [3H] mannose, [3H]galactose, [3H]fucose, [3H]ethanolamine, and [3H]palmitic acid. In the latter two cases the label is recovered almost exclusively in a detergent-binding Pronase fragment of the protein. The incorporated label is in the form of [3H]ethanolamine, or [3H]palmitate and stearate, respectively. Reductive methylation of biosynthetically labeled Thy-1 and a nonradioactive sample of Thy-1 shows that [3H]ethanolamine is incorporated equally into two residues of ethanolamine, only one of which has a free amino group. A single residue of glucosamine with a free amino group is also detected. Each of the sugar precursors is incorporated with extensive conservation of chemical identity. In the class E cells, each of the labeled sugars but neither [3H]ethanolamine nor [3H]palmitate is incorporated into Thy-1. The anchor moiety therefore appears to be entirely missing, although N-linked oligosaccharide processing is essentially normal. We postulate that the anchor deficiency in the mutant cells results from a biosynthetic lesion.     

Incorporation of [3H]glucosamine into keratin-related polypeptides in pig epidermis

Metabolic labelling studies have provided evidence for glycosylated keratins in cultured pig epidermis. [3H]Glucosamine was incorporated into five major particulate polypeptides of Mr 68 000, 61 000, 57 000, 53,000 and 48,000. Radioactivity was present in protein-bound carbohydrate. Non-enzymic glycation was excluded. Labelling was largely unaffected by tunicamycin indicating that radioactivity was incorporated mainly into O-linked oligosaccharides. These [3H]glucosamine-labelled components were closely related to keratins since they had a similar electrophoretic mobility to polypeptides of purified pig prekeratin, they were immunoprecipitated by anti-prekeratin serum and they were incorporated into reconstituted, intermediate-sized, keratin filaments.     

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.     

Evidence for the organization of the transmembrane segments of (Na,K)-ATPase based on labeling lipid-embedded and surface domains of the alpha-subunit

The purpose of this work has been to examine the organization of the intramembranous portion of the alpha-subunit of membrane-bound (Na,K)-ATPase. Covalent labeling of the alpha-subunit and its tryptic fragments from within the lipid bilayer with [125I]iodonaphthylazide was combined with covalent labeling with 32P from [gamma-33P]ATP at the cytoplasmic surface and with [3H]N-(ouabain)-N'-(2-nitro-4-azidophenyl)ethylenediamine from the extra cellular surface. In control experiments using extensive proteolysis and reduced glutathione, it is confirmed that iodonaphthylazide labels segments of the protein within the lipid bilayer. The labeled segments of the alpha-subunit, produced by extensive proteolysis, are selectively extracted by organic solvents. Both at a low and at a high concentration of iodonaphthylazide, about 50% of label added to the medium is covalently attached to protein and lipid. At the low iodonaphthylazide concentration, the NH2-terminal Mr = 46,000 (46K) fragment of the alpha-subunit is preferentially labeled, while at the higher concentration of the 46K fragment, the 78K fragment, and the COOH-terminal 58K fragment are labeled. 32P from [gamma-32P]ATP is incorporated into the 46K fragment while [3H]N-(ouabain)-N'-(2-nitro-4-azido-phenyl)ethylenediamine from the extracellular surface labels all the major fragments, 78K, 58K, and 46K. The data provide evidence for a model of the path of the polypeptide chain with multiple traverses of the alpha-subunit across the bilayer and the NH2-terminal and three trypsin-sensitive bonds exposed at the cytoplasma surface.     

Regulation of surface antigen expression in Paramecium primaurelia. II. Role of the surface antigen itself.

In the wild-type strains, 156 and 168, of Paramecium primaurelia, the alleles G156 and G168 expressed at medium temperature specify two immunologically distinguishable surface antigens 156G and 168G, whose phenotypic expression shows allelic exclusion, the majority of heterozygotes being phenotypically [156G] while a small minority is phenotypically [156G-168G]. At high temperature, the antigens coded by another locus, generally the D locus, are expressed. This system, displaying both intergenic and interallelic exclusion, provides favourable material to analyze the respective roles of the genome, of the antigens expressed and of the environmental conditions, in particular temperature, on the regulation of the expression of surface antigens. This analysis was carried out by studying the variations of the expression of surface antigens as a function of temperature, culture medium and previously expressed antigens in different genetic situations (a) in homozygotes: the wild-type strains 156 and 168, and the isogenized strains "G156 isogenic 168 carrying the G156 allele in a 168 genetic background; (b) in heterozygotes of the two phenotypic classes of heterozygotes, [156G] and [156G-168G]. The results show that (1) the thermal stability of the expression of a given surface antigen and its rate of re-appearance at the cell surface depend on its own specificity; (2) in heterozygotes [156G-168G], the stability of the expression of the antigen 156G is modified and "adjusted" to that of the less stable surface antigen 168G, and (3) the surface antigen itself exerts a positive control on the maintenance of its own expression. An interpretative model of "transmembranous control" is proposed to account for the regulation of the expression of surface antigens in Paramecium.