Glucose-induced sequential processing of a glycosyl-phosphatidylinositol-anchored ectoprotein in Saccharomyces cerevisiae.

Transfer of spheroplasts from the yeast Saccharomyces cerevisiae to glucose leads to the activation of an endogenous (glycosyl)-phosphatidylinositol-specific phospholipase C ([G]PI-PLC), which cleaves the anchor of at least one glycosyl-phosphatidylinositol (GPI)-anchored protein, the cyclic AMP (cAMP)-binding ectoprotein Gce1p (G. Müller and W. Bandlow, J. Cell Biol. 122:325-336, 1993). Analyses of the turnover of two constituents of the anchor, myo-inositol and ethanolamine, relative to the protein label as well as separation of the two differently processed versions of Gce1p by isoelectric focusing in spheroplasts demonstrate the glucose-induced conversion of amphiphilic Gce1p first into a lipolytically cleaved hydrophilic intermediate, which is then processed into another hydrophilic version lacking both myo-inositol and ethanolamine. When incubated with unlabeled spheroplasts, the lipolytically cleaved intermediate prepared in vitro is converted into the version lacking all anchor constituents, whereby the anchor glycan is apparently removed as a whole. The secondary cleavage ensues independently of the carbon source, attributing the key role in glucose-induced anchor processing to the endogenous (G)PI-PLC. The secondary processing of the lipolytically cleaved intermediate of Gce1p at the plasma membrane is correlated with the emergence of a covalently linked high-molecular-weight form of a cAMP-binding protein at the cell wall. This protein lacks anchor components, and its protein moiety appears to be identical with double-processed Gce1p detectable at the plasma membrane in spheroplasts. The data suggest that glucose-induced double processing of GPI anchors represents part of a mechanism of regulated cell wall expression of proteins in yeast cells.     

The cAMP-binding ectoprotein from Saccharomyces cerevisiae is membrane-anchored by glycosyl-phosphatidylinositol.

Saccharomyces cerevisiae contains an amphiphilic cAMP-binding glycoprotein at the outer face of the plasma membrane (M(r) = 54,000). It is converted to a hydrophilic form by treatment with glycosyl-phosphatidylinositol-specific phospholipases C and D (GPI-PLC/D), suggesting membrane anchorage by a covalently bound glycolipid. Determination of the constituents of the purified anchor by gas-liquid chromatography and amino acid analysis reveals the presence of glycerol, myo-inositol, glucosamine, galactose, mannose, ethanolamine, and asparagine (as the carboxyl-terminal amino acid of the Pronase-digested protein to which the anchor is attached). Complementary results are obtained by metabolic labeling, indicating that fatty acids and phosphorus are additional anchor constituents. The phosphorus is resistant to alkaline phosphatase, whereas approximately half is lost from the protein after treatment with GPI-PLD or nitrous acid, and all is removed by aqueous HF indicating the presence of two phosphodiester bonds. Inhibition of N-glycosylation by tunicamycin or removal of protein-bound glycan chains by N-glycanase or Pronase does not abolish radiolabeling of the anchor structure by any of the above compounds. Analysis of the products obtained after sequential enzymic and chemical degradation of the anchor agrees with the arrangement of constituents in GPIs from higher eucaryotes. Evidence for anchorage of the yeast cAMP-binding protein by a GPI anchor is strengthened additionally by the reactivity of the GPI-PLC-cleaved anchor with antibodies directed against the cross-reacting determinant of trypanosomal variant surface glycoproteins.     

A cAMP-binding ectoprotein in the yeast Saccharomyces cerevisiae.

Purified plasma membranes from the yeast Saccharomyces cerevisiae bind about 1.2 pmol of cAMP/mg of protein with high affinity (Kd = 6 nM). By using photoaffinity labeling with 8-N3-[32P]cAMP, we have identified in plasma membrane vesicles a cAMP-binding protein (Mr = 54,000) that is present also in bcy1 disruption mutants, lacking the cytoplasmic R subunit of protein kinase A (PKA). This argues that it is genetically unrelated to PKA. Neither high salt, nor alkaline carbonate, nor cAMP extract the protein from the membrane, suggesting that it is not peripherally bound. The observation that (glycosyl)phosphatidylinositol-specific phospholipases (or nitrous acid) release the amphiphilic protein from the membrane, thereby converting it to a hydrophilic form, indicates anchorage by a glycolipidic membrane anchor. Treatment with N-glycanase reduces the Mr to 44,000-46,000 indicative of a modification by N-linked carbohydrate side chain(s). In addition to the action of a phospholipase, the efficient release from the membrane requires the removal of the carbohydrate side chain(s) or the presence of high salt or methyl alpha-mannopyranoside, suggesting complex interactions with the membrane involving not only the glycolipidic anchor but also the glycan side chain(s). Topological studies show that the protein is exposed to the periplasmic space, raising intriguing questions for the function of this protein.     

Stimulation of a glycosyl-phosphatidylinositol-specific phospholipase by insulin and the sulfonylurea, glimepiride, in rat adipocytes depends on increased glucose transport

Lipoprotein lipase (LPL) and glycolipid-anchored cAMP-binding ectoprotein (Gce1) are modified by glycosyl-phosphatidylinositol (GPI) in rat adipocytes, however, the linkage is potentially unstable. Incubation of the cells with either insulin (0.1-30 nM) or the sulfonylurea, glimepiride (0.5-20 microM), in the presence of glucose led to conversion of up to 35 and 20%, respectively, of the total amphiphilic LPL and Gce1 to their hydrophilic versions. Inositol- phosphate was retained in the residual protein-linked anchor structure. This suggests cleavage of the GPI anchors by an endogenous GPI-specific insulin- and glimepiride-inducible phospholipase (GPI-PL). Despite cleavage, hydrophilic LPL and Gce1 remained membrane associated and were released only if a competitor, e.g., inositol- (cyclic)monophosphate, had been added. Other constituents of the GPI anchor (glucosamine and mannose) were less efficient. This suggests peripheral interaction of lipolytically cleaved LPL and Gce1 with the adipocyte cell surface involving the terminal inositol- (cyclic)monophosphate epitope and presumably a receptor of the adipocyte plasma membrane. In rat adipocytes which were resistant toward glucose transport stimulation by insulin, the sensitivity and responsiveness of GPI-PL to stimulation by insulin was drastically reduced. In contrast, activation of both GPI-PL and glucose transport by the sulfonylurea, glimepiride, was not affected significantly. Inhibition of glucose transport or incubation of rat adipocytes in glucose-free medium completely abolished stimulation of GPI-PL by either insulin or glimepiride. The activation was partially restored by the addition of glucose or nonmetabolizable 2-deoxyglucose. These data suggest that increased glucose transport stimulates a GPI-PL in rat adipocytes.     

Insulin-like signaling in yeast: modulation of protein phosphatase 2A, protein kinase A, cAMP-specific phosphodiesterase, and glycosyl-phosphatidylinositol-specific phospholipase C activities

Previously, we have described significant effects of human insulin on glucose metabolism in the yeast Saccharomyces cerevisiae under conditions of growth limitation. These regulations apparently rely on a transmembrane receptor capable of binding human insulin and responding by tyrosine/serine phosphorylation of a specific set of polypeptides [Müller, G., Rouveyre, N., Crecelius, A., and Bandlow, W. (1998) Biochemistry 37, 8683-8695; Müller, G., Rouveyre, N., Upshon, C., Gross, E., and Bandlow, W. (1998) Biochemistry 37, 8696-8704; Müller, G., Rouveyre, N., Upshon, C., and Bandlow, W. (1998) Biochemistry 37, 8705-8713]. To characterize the molecular link between the initial steps in insulin-like signaling in yeast and the changes in the activities of glycogen synthase and glycogen phosphorylase, we examined here the effects of human insulin on a set of key regulatory enzymes of glycogen metabolism, protein phosphatase 2A (PP2A), cAMP-specific phosphodiesterase (cAMP-PDE), and protein kinase A (PKA). PP2A was activated about 2-fold by insulin in spheroplasts and in intact cells, whereas the fraction of active PKA was significantly reduced in a cAMP-independent manner as well as through a subsequent up to 3-fold increase in particulate cAMP-PDE activity accompanied by a 50% decrease in cytosolic cAMP levels. In addition, glycosyl-phosphatidylinositol-specific phospholipase C (GPI-PLC), which in isolated rat adipocytes is activated by insulin, was stimulated to up to 5-fold by glucose and 10-fold by glucose plus insulin in both yeast spheroplasts and intact cells leading to a concentration-dependent leftward shift of the glucose-response curve for activation of the GPI-PLC. GPI-PLC was most pronouncedly stimulated by authentic human insulin compared to various insulin analogues and insulin-like growth factor I. In addition to lipolytic cleavage by GPI-PLC, the GPI anchor of the cAMP-binding ectoprotein, Gce1p, was secondarily processed by a rapid proteolytic event. As the GPI-PLC reaction is rate limiting, the efficiency of the two-step anchor cleavage was significantly increased when insulin was present together with glucose as compared to glucose alone. The insulin concentrations effective in modulating PP2A, PKA, cAMP-PDE, and GPI-PLC activities correlate well with those required for half-saturation of the specific binding sites as well as for stimulation of protein phosphorylation and glycogen accumulation. The data suggest that mammalian insulin-sensitive cells and yeast share (part of) the key regulatory mechanism (consisting of PP2A, PKA, cAMP-PDE, and GPI-PLC) involved in the transduction of the insulin signal from the respective receptor systems to glycogen synthase and phosphorylase.     

A transferrin-binding protein of Trypanosoma brucei is encoded by one of the genes in the variant surface glycoprotein gene expression site.

A transferrin-binding protein (TFBP) with an apparent molecular weight of 42 kd was purified from detergent-soluble membrane proteins of bloodstream forms of Trypanosoma brucei. The protein is not expressed in the insect-borne stage of the parasite's life-cycle. Purified TFBP can be converted from an amphiphilic to a hydrophilic form by cleavage with T.brucei glycosylphosphatidylinositol (GPI)-specific phospholipase C, demonstrating that the C-terminus is modified by a GPI-membrane anchor. The TFBP is encoded by an expression-site-associated gene [ESAG 6 in the nomenclature of Pays et al. (1989) Cell, 57, 835-845] which is under the control of the promoter transcribing the expressed variant surface glycoprotein gene. The possible function of TFBP as a receptor for the uptake of transferrin in bloodstream forms is discussed.     

Dolichol phosphate mannose synthase is required in vivo for glycosyl phosphatidylinositol membrane anchoring, O mannosylation, and N glycosylation of protein in Saccharomyces cerevisiae.

Glycosyl phosphatidylinositol (GPI) anchoring, N glycosylation, and O mannosylation of protein occur in the rough endoplasmic reticulum and involve transfer of precursor structures that contain mannose. Direct genetic evidence is presented that dolichol phosphate mannose (Dol-P-Man) synthase, which transfers mannose from GDPMan to the polyisoprenoid dolichol phosphate, is required in vivo for all three biosynthetic pathways leading to these covalent modifications of protein in yeast cells. Temperature-sensitive yeast mutants were isolated after in vitro mutagenesis of the yeast DPM1 gene. At the nonpermissive temperature of 37 degrees C, the dpm1 mutants were blocked in [2-3H]myo-inositol incorporation into protein and accumulated a lipid that could be radiolabeled with both [2-3H]myo-inositol and [2-3H]glucosamine and met existing criteria for an intermediate in GPI anchor biosynthesis. The likeliest explanation for these results is that Dol-P-Man donates the mannose residues needed for completion of the GPI anchor precursor lipid before it can be transferred to protein. Dol-P-Man synthase is also required in vivo for N glycosylation of protein, because (i) dpm1 cells were unable to make the full-length precursor Dol-PP-GlcNAc2Man9Glc3 and instead accumulated the intermediate Dol-PP-GlcNAc2Man5 in their pool of lipid-linked precursor oligosaccharides and (ii) truncated, endoglycosidase H-resistant oligosaccharides were transferred to the N-glycosylated protein invertase after a shift to 37 degrees C. Dol-P-Man synthase is also required in vivo for O mannosylation of protein, because chitinase, normally a 150-kDa O-mannosylated protein, showed a molecular size of 60 kDa, the size predicted for the unglycosylated protein, after shift of the dpm1 mutant to the nonpermissive temperature.     

Two lipid-anchored cAMP-binding proteins in the yeast Saccharomyces cerevisiae are unrelated to the R subunit of cytoplasmic protein kinase A.

We show that the yeast, Saccharomyces cerevisiae, contains two cAMP-binding proteins in addition to the well-characterized regulatory (R) subunit of cytoplasmic cAMP-dependent protein kinase (PKA). We provide evidence that they comprise a new type of cAMP receptor, membrane-anchored by covalently attached lipid structures. They are genetically not related to the cytoplasmic R subunit. The respective proteins can be detected in sral mutants, in which the gene for the R subunit of PKA has been disrupted and a monoclonal antibody raised against the cytoplasmic R subunit does not cross-react with the two membrane-bound cAMP-binding proteins. In addition, they differ from the cytoplasmic species also with respect to their location and the peptide maps of the photoaffinity-labeled proteins. Although they differ from one another in molecular mass and subcellular location, peptide maps of the cAMP-binding domains resemble each other and both proteins are membrane-anchored by lipid structures, one to the outer surface of the plasma membrane, the other to the outer surface of the inner mitochondrial membrane. Both anchors can be metabolically labeled by Etn, myo-Ins and fatty acids. In addition, the anchor structure of the cAMP receptor from plasma membranes can be radiolabeled by GlcN and Man. After cleavage of the anchor with glycosylphosphatidylinositol-specific phospholipase C from trypanosomes, the solubilized cAMP-binding protein from plasma membranes reacts with antibodies which specifically recognize the cross-reacting determinant from soluble trypanosomal coat protein, suggesting similarity of the anchors. Degradation studies also point to the glycosylphosphatidylinositol nature of the anchor from the plasma membrane, whereas the mitochondrial counterpart is less complex in that it lacks carbohydrates. The plasma membrane cAMP receptor is, in addition, modified by an N-glycosidically linked carbohydrate side chain, responsible mainly for its higher molecular mass.     

Inositol acylation of a potential glycosyl phosphoinositol anchor precursor from yeast requires acyl coenzyme A.

Glycosyl phosphoinositol (GPI) anchors on proteins can be modified by palmitoylation of their inositol residue, which makes such anchors resistant to cleavage by phosphatidylinositol-specific phospholipase C (PI-PLC) (Roberts, W. L., Myher, J. J., Kuksis, A., Low, M. G., and Rosenberry, T.L. (1988) J. Biol. Chem. 263, 18766-18775). Mannosylated GPI lipids made in trypanosomal and mammalian cells can also be inositol-acylated, indicating that inositol acylation may be a normal step in GPI anchor synthesis. We find that Saccharomyces cerevisiae mutants blocked in dolichyl phosphate mannose synthesis accumulate a lipid that can be radiolabeled in vivo with [3H]myo-inositol, [3H]GlcN, and [3H]palmitic acid. This lipid is resistant to PI-PLC, yet sensitive to mild alkaline hydrolysis, and has been characterized as GlcN-phosphatidylinositol (PI), fatty acylated on its inositol residue. When yeast membranes are incubated with UDP-[14C] GlcNAc, 14C-labeled GlcNAc-PI and GlcN-PI are made. Addition of ATP and CoA, or of palmitoyl-CoA to incubations results in the synthesis of [14C]GlcN-(acyl-inositol)PI. This lipid is also made when membranes are incubated with [1-14C]palmitoyl-CoA and UDP-GlcNAc. We propose that acyl CoA is the donor in inositol acylation of GlcN-PI, and that GlcN-(acyl-inositol)PI is an obligatory intermediate in GPI synthesis.     

Association of (c)AMP-degrading glycosylphosphatidylinositol-anchored proteins with lipid droplets is induced by palmitate, H2O2 and the sulfonylurea drug, glimepiride, in rat adipocytes

Inhibition of lipolysis in rat adipocytes by palmitate, H2O2 and the antidiabetic sulfonylurea drug, glimepiride, has been demonstrated to rely on the upregulated conversion of cAMP to adenosine by enzymes associated with lipid droplets (LD) rather than on cAMP degradation by the insulin-stimulated microsomal phosphodiesterase 3B (Müller, G., Wied, S., Over, S., and Frick, W. (2008) Biochemistry 47, 1259-1273). Here these two enzymes were identified as the glycosylphosphatidylinositol (GPI)-anchored phosphodiesterase, Gce1, and the 5'-nucleotidase, CD73, on basis of the following findings: (i) Photoaffinity labeling with 8-N3-[32P]cAMP and [14C]5'-FSBA of LD from palmitate-, glucose oxidase- and glimepiride-treated, but not insulin-treated and basal, adipocytes led to the identification of 54-kDA cAMP- and 62-kDa AMP-binding proteins. (ii) The amphiphilic proteins were converted into hydrophilic versions and released from the LD by chemical or enzymic treatments specifically cleaving GPI anchors, but resistant toward carbonate extraction. (iii) The cAMP-to-adenosine conversion activity was depleted from the LD by adsorption to (c)AMP-Sepharose. (iv) cAMP-binding to LD was increased upon challenge of the adipocytes with palmitate, glimepiride or glucose oxidase and abrogated by phospholipase C digestion. (v) The 62-kDa AMP-binding protein was labeled with typical GPI anchor constituents and reacted with anti-CD73 antibodies. (vi) Inhibition of the bacterial phosphatidylinitosol-specific phospholipase C or GPI anchor biosynthesis blocked both agent-dependent upregulation and subsequent loss of cAMP-to-adenosine conversion associated with LD and inhibition of lipolysis. (vii) Gce1 and CD73 can be reconstituted into and exchanged between LD in vitro. These data suggest a novel insulin-independent antilipolytic mechanism engaged by palmitate, glimepiride and H2O2 in adipocytes which involves the upregulated expression of a GPI-anchored PDE and 5'-nucleotidase at LD. Their concerted action may ensure degradation of cAMP and inactivation of hormone-sensitive lipase in the vicinity of LD.     

Isolation and characterization of a phosphatidylinositol-glycan-anchor-specific phospholipase D from bovine brain

In recent years an increasing number of proteins has been shown to be membrane-anchored by a covalently attached PtdIns-glycan residue. In mammalian cells little is known about PtdIns-glycan-specific phospholipases which might play a role in the metabolism of PtdIns-glycan-anchored proteins. In order to identify PtdIns-glycan-specific phospholipases, a rapid and sensitive assay for such enzymes was developed using the PtdIns-glycan-anchored amphiphilic membrane form of acetylcholinesterase as substrate. The rate of product formation was monitored by the increase in soluble hydrophilic acetylcholinesterase in the aqueous phase after separation in Triton X-114. With this assay we established the presence of a PtdIns-glycan-specific phospholipase in bovine brain. This enzyme was soluble and could be partially purified by a heat step followed by chromatography on DEAE-cellulose and by gel filtration on Sepharose CL-6B. PtdIns-glycan-specific phospholipase had a high affinity for the PtdIns-glycan anchor of the substrate (Km = 52 nM) and did not degrade either PtdCho or PtdIns. Hydrophobic labeling of the anchor of the substrate with 3-trifluoromethyl-3-(m-[125I]iodophenyl)diazirine [( 125I]TID) caused a marked decrease in the cleavage rate and methylation of the amino group of the glucosamine residue of the anchor decreased the cleavage rate to zero. Using [125I]TID-labeled substrate, diradylglycerol phosphate was identified as the second product showing that the cleavage specificity of PtdIns-glycan-specific phospholipase was that of a phospholipase D. PtdIns-glycan-specific phospholipase D was inhibited by mercurials, omicron-phenanthroline and EGTA. It was stimulated by Ca2+ in micromolar concentrations indicating that PtdIns-glycan-phospholipase D is a Ca2(+)-regulated enzyme.     

Thematic review series: lipid posttranslational modifications. GPI anchoring of protein in yeast and mammalian cells, or: how we learned to stop worrying and love glycophospholipids

Glycosylphosphatidylinositol (GPI) anchoring of cell surface proteins is the most complex and metabolically expensive of the lipid posttranslational modifications described to date. The GPI anchor is synthesized via a membrane-bound multistep pathway in the endoplasmic reticulum (ER) requiring >20 gene products. The pathway is initiated on the cytoplasmic side of the ER and completed in the ER lumen, necessitating flipping of a glycolipid intermediate across the membrane. The completed GPI anchor is attached to proteins that have been translocated across the ER membrane and that display a GPI signal anchor sequence at the C terminus. GPI proteins transit the secretory pathway to the cell surface; in yeast, many become covalently attached to the cell wall. Genes encoding proteins involved in all but one of the predicted steps in the assembly of the GPI precursor glycolipid and its transfer to protein in mammals and yeast have now been identified. Most of these genes encode polytopic membrane proteins, some of which are organized in complexes. The steps in GPI assembly, and the enzymes that carry them out, are highly conserved. GPI biosynthesis is essential for viability in yeast and for embryonic development in mammals. In this review, we describe the biosynthesis of mammalian and yeast GPIs, their transfer to protein, and their subsequent processing.     

烟曲霉蛋白质分泌载体的构建及酸性磷酸酯酶的细胞定位

[目的]在酵母细胞中蛋白质的糖基磷酸肌醇化(GPI)修饰是将GPI定位于细胞膜或细胞壁的信号.目前已对酵母GPI蛋白的细胞定位信号有一定了解,但对丝状真菌GPI蛋白的定位则了解甚少.AfPhoA是丝状真菌烟曲霉(Aspergillus fumigatus)的酸性磷酸酯酶,是GPI修饰的蛋白.该蛋白首先分离自细胞膜,随后又发现该蛋白与细胞壁结合.分析其C-端序列也未发现已知的定位信号,因此目前还不能确定其细胞定位.[方法]我们以绿色荧光蛋白(GFP)作为报告分子,将AfPhoA的C-端序列与GFP的C-端融合后检测融合GFP的细胞定位.[结果]我们用烟曲霉几丁质酶AfChiB1的启动子和N-端信号肽构建了可在烟曲霉中分泌表达GFP的表达载体pchiGFP.在此基础上将AfPhoA的C-端与GFP融合,融合质粒与pCDA14共转化烟曲霉后筛选到一株转化子.该转化子可表达融合GFP,在诱导和非诱导条件下,融合GFP均主要分布在细胞膜上,随培养时间的延长,融合GFP在细胞壁上也有少量分布;在培养上清液中只能检出约30KD的GFP融合蛋白,而没有完整的GFP融合蛋白,推测为从GPI锚上水解释放的.[结论]我们的研究结果表明,AfPhoA蛋白GPI修饰的作用是使该蛋白定位于细胞膜.本研究不仅初步确定了AfPhoA蛋白GPI修饰的细胞膜定位功能,而且为烟曲霉基因与蛋白质功能的研究建立了一个有效表达系统.     

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.     

The endoplasmic reticulum (ER) translocon can differentiate between hydrophobic sequences allowing signals for glycosylphosphatidylinositol anchor addition to be fully translocated into the ER lumen

The signal sequence within polypeptide chains that designates whether a protein is to be anchored to the membrane by a glycosylphosphatidylinositol (GPI) anchor is characterized by a carboxyl-terminal hydrophobic domain preceded by a short hydrophilic spacer linked to the GPI anchor attachment (omega) site. The hydrophobic domain within the GPI anchor signal sequence is very similar to a transmembrane domain within a stop transfer sequence. To investigate whether the GPI anchor signal sequence is translocated across or integrated into the endoplasmic reticulum membrane we studied the translocation, GPI anchor addition, and glycosylation of different variants of a model GPI-anchored protein. Our results unequivocally demonstrated that the hydrophobic domain within a GPI signal cannot act as a transmembrane domain and is fully translocated even when followed by an authentic charged cytosolic tail sequence. However, a single amino acid change within the hydrophobic domain of the GPI-signal converts it into a transmembrane domain that is fully integrated into the endoplasmic reticulum membrane. These results demonstrated that the translocation machinery can recognize and differentiate subtle changes in hydrophobic sequence allowing either full translocation or membrane integration.     

An amphitropic cAMP-binding protein in yeast mitochondria. 1. Synergistic control of the intramitochondrial location by calcium and phospholipid

A cAMP-binding protein is found to be integrated into the inner mitochondrial membrane of the yeast Saccharomyces cerevisiae under normal conditions. It resists solubilization by high salt and chaotropic agents. The protein is, however, converted to a soluble form which then resides in the intermembrane space, when isolated mitochondria are incubated with low concentrations of calcium. Phospholipids or diacylglycerol (or analogues) dramatically increases the efficiency of receptor release from the inner membrane, whereas these compounds alone are ineffective. Also, cAMP does not effect or enhance liberation from the membrane of the cAMP-binding protein. Photoaffinity labeling with 8-N3-[32P]cAMP followed by mitochondrial subfractionation and sodium dodecyl sulfate-polyacrylamide gel electrophoresis does not reveal differences in the apparent molecular weight between the membrane-bound and the soluble form of the cAMP receptor. The two forms differ, however, in their partitioning behavior in Triton X-114 as well as in their protease resistance, indicating that the release from the membrane is accompanied by a change in lipophilicity and conformation of the receptor protein. Evidence is presented that a change of the intramitochondrial location of the yeast cAMP-binding protein also occurs in vivo and leads to the activation of a mitochondrial cAMP-dependent protein kinase. The cAMP-binding protein is the first example of a mitochondrial protein with amphitropic character; i.e., it has the property to occur in two different locations, as a membrane-embedded and a soluble form.     

Proteomic scale high-sensitivity analyses of GPI membrane anchors

Glycosylphosphatidylinositol (GPI) anchored proteins are ubiquitous in eukaryotic cells. Earlier analysis methods required large amounts of purified protein to elucidate the structure of the GPI. This paper describes methods for analyzing GPIs on a ‘proteomic’ scale. Partially purified proteins may be run on sodium dodecyl sulphate polyacrylamide gel electrophoresis and then blotted onto a polyvinylidene difluoride (PVDF) membrane. Following identification of the protein the piece of PVDF may be subjected to various chemical treatments, which are specific for GPI structures. The first method uses gas chromatography–mass spectrometry and it enables the presence of a GPI anchor to be confirmed. The second method depends on the cleavage of phosphate bonds and permits the carbohydrate structure to be elucidated by electrospray or matrix assisted laser desorption ionization-time of flight mass spectrometry. The final method described uses deamination of the glucosamine residue to release the lipid moiety for analysis by mass spectrometry.     

Fusion of sequence elements from non-anchored proteins to generate a fully functional signal for glycophosphatidylinositol membrane anchor attachment

Glycophosphatidylinositol (GPI) membrane anchor attachment is directed by a cleavable signal at the COOH terminus of the protein. The complete lack of homology among different GPI-anchored proteins suggests that this signal is of a general nature. Previous analysis of the GPI signal of decay accelerating factor (DAF) suggests that the minimal requirements for GPI attachment are (a) a hydrophobic domain and (b) a cleavage/attachment site consisting of a pair of small residues positioned 10-12 residues NH2-terminal to a hydrophobic domain. As an ultimate test of these rules we constructed four synthetic GPI signals, meeting these requirements but assembled entirely from sequence elements not normally involved in GPI attachment. We show that these synthetic signals are able to direct human growth hormone (hGH), a secreted protein, to the plasma membrane via a GPI anchor. Our results indicate that different hydrophobic sequences, derived from either the prolactin or hGH NH2-terminal signal peptide, can be linked to different cleavage sites via different hydrophilic spacers to produce a functional GPI signal. These data confirm that the only requirements for GPI-anchoring are a pair of small residues positioned 10-12 residues NH2 terminal to a hydrophobic domain, no other structural motifs being necessary.     

The cell cycle modulated glycoprotein GP115 is one of the major yeast proteins containing glycosylphosphatidylinositol

The cell cycle modulated protein gp115 (115 kDa, isoelectric point about 4.8-5) of Saccharomyces cerevisiae undergoes various post-translational modifications. It is N-glycosylated during its maturation along the secretory pathway where an intermediary precursor of 100 kDa (p100), dynamically related to the mature gp115 protein, is detected at the level of endoplasmic reticulum. Moreover, we have shown by the use of metabolic labeling with [35S]methionine, [3H]palmitic acid and myo-[3H]inositol combined with high resolution two-dimensional gel electrophoresis and immunoprecipitation with a specific antiserum, that gp115 is one of the major palmitate- and inositol-containing proteins in yeast. These results, and the susceptibility of gp115 to phosphatidylinositol-specific phospholipase C treatment strongly indicate that gp115 contains the glycosylphosphatidylinositol (GPI) structure as membrane anchor domain. The two-dimensional analysis of the palmitate- and inositol-labeled proteins has also allowed the characterization of other polypeptides which possibly contain a GPI structure.     

Substrate specificity of soluble and membrane-associated ADP-ribosyltransferase ART2.1

ADP-ribosyltransferases (ARTs) are a family of enzymes that catalyze the covalent transfer of an ADP-ribose moiety, derived from NAD, to an amino acid of an acceptor protein, thereby altering its function. To date, little information is available on the protein target specificity of different ART family members. ART2 is a T-cell-specific transferase, attached to the cell surface by a glycosylphosphatidylinositol (GPI) anchor, and also found in serum. Here we investigated the role of ART2 localization in serum or on the cell surface, or solubilized with detergents or enzymes, on its target protein specificity. We found that detergent solubilization of cell membranes, or release of ART2 by phosphoinositide-specific phospholipase C treatment, altered the ability of ART2 to ADP-ribosylate high or low molecular weight histone proteins. Similarly, soluble recombinant ART2 (lacking the GPI anchor) showed a different histone specificity than did cell-bound ART2. When soluble ART2 was incubated with serum proteins in the presence of [32P]-labeled NAD, several serum proteins were ADP-ribosylated in a thiol-specific manner. Mass spectrometry of labeled proteins identified albumin and transferrin as ADP-ribosylated proteins in serum. Collectively, these studies reveal that the membrane or solution environment of ART2 plays a pivotal role in determining its substrate specificity.