Ethanolaminephosphate side chain added to glycosylphosphatidylinositol (GPI) anchor by mcd4p is required for ceramide remodeling and forward transport of GPI proteins from endoplasmic reticulum to Golgi

Glycosylphosphatidylinositol (GPI) anchors of mammals as well as yeast contain ethanolaminephosphate side chains on the alpha1-4- and the alpha1-6-linked mannoses of the anchor core structure (protein-CO-NH-(CH(2))(2)-PO(4)-6Manalpha1-2Manalpha1-6Manalpha1-4GlcNH(2)-inositol-PO(4)-lipid). In yeast, the ethanolaminephosphate on the alpha1-4-linked mannose is added during the biosynthesis of the GPI lipid by Mcd4p. MCD4 is essential because Gpi10p, the mannosyltransferase adding the subsequent alpha1-2-linked mannose, requires substrates with an ethanolaminephosphate on the alpha1-4-linked mannose. The Gpi10p ortholog of Trypanosoma brucei has no such requirement. Here we show that the overexpression of this ortholog rescues mcd4Delta cells. Phenotypic analysis of the rescued mcd4Delta cells leads to the conclusion that the ethanolaminephosphate on the alpha1-4-linked mannose, beyond being an essential determinant for Gpi10p, is necessary for an efficient recognition of GPI lipids and GPI proteins by the GPI transamidase for the efficient transport of GPI-anchored proteins from the endoplasmic reticulum to Golgi and for the physiological incorporation of ceramides into GPI anchors by lipid remodeling. Furthermore, mcd4Delta cells have a marked defect in axial bud site selection, whereas this process is normal in gpi7Delta and gpi1. This also suggests that axial bud site selection specifically depends on the presence of the ethanolaminephosphate on the alpha1-4-linked mannose.     

In vivo characterization of the GPI assembly defect in yeast mcd4-174 mutants and bypass of the Mcd4p-dependent step in mcd4Delta cells

Yeast mcd4-174 mutants are blocked in glycosylphosphatidylinositol (GPI) anchoring of protein, but the stage at which GPI biosynthesis is interrupted in vivo has not been identified, and Mcd4p has also been implicated in phosphatidylserine and ATP transport. We report that the major GPI that accumulates in mcd4-174 in vivo is Man(2)-GlcN-(acyl-Ins)PI, consistent with proposals that Mcd4p adds phosphoethanolamine to the first mannose of yeast GPI precursors. Mcd4p-dependent modification of GPIs can partially be bypassed in the mcd4-174/gpi11 double mutant and in mcd4Delta; mutants by high-level expression of PIG-B and GPI10, which respectively encode the human and yeast mannosyltransferases that add the third mannose of the GPI precursor. Rescue of mcd4Delta; by GPI10 indicates that Mcd4p-dependent addition of EthN-P to the first mannose of GPIs is not obligatory for transfer of the third mannose by Gpi10p.     

Deletion of GPI7, a yeast gene required for addition of a side chain to the glycosylphosphatidylinositol (GPI) core structure, affects GPI protein transport, remodeling, and cell wall integrity.

Gpi7 was isolated by screening for mutants defective in the surface expression of glycosylphosphatidylinositol (GPI) proteins. Gpi7 mutants are deficient in YJL062w, herein named GPI7. GPI7 is not essential, but its deletion renders cells hypersensitive to Calcofluor White, indicating cell wall fragility. Several aspects of GPI biosynthesis are disturbed in Deltagpi7. The extent of anchor remodeling, i.e. replacement of the primary lipid moiety of GPI anchors by ceramide, is significantly reduced, and the transport of GPI proteins to the Golgi is delayed. Gpi7p is a highly glycosylated integral membrane protein with 9-11 predicted transmembrane domains in the C-terminal part and a large, hydrophilic N-terminal ectodomain. The bulk of Gpi7p is located at the plasma membrane, but a small amount is found in the endoplasmic reticulum. GPI7 has homologues in Saccharomyces cerevisiae, Caenorhabditis elegans, and man, but the precise biochemical function of this protein family is unknown. Based on the analysis of M4, an abnormal GPI lipid accumulating in gpi7, we propose that Gpi7p adds a side chain onto the GPI core structure. Indeed, when compared with complete GPI lipids, M4 lacks a previously unrecognized phosphodiester-linked side chain, possibly an ethanolamine phosphate. Gpi7p contains significant homology with phosphodiesterases suggesting that Gpi7p itself is the transferase adding a side chain to the alpha1,6-linked mannose of the GPI core structure.     

Phosphatidylethanolamine is the donor of the phosphorylethanolamine linked to the alpha1,4-linked mannose of yeast GPI structures

Glycosylphosphatidylinositol (GPI) anchors of all species contain the core structure protein-CO-NH-(CH(2))(2)-PO(4)-Manalpha1-2Manalpha1-6Manalpha1-4GlcNalpha1-6inositol-PO(4)-lipid. In recent studies in yeast it was found that gpi10-1 mutants accumulate M2, an abnormal intermediate having the structure Manalpha1-6[NH(2)-(CH(2))(2)-PO(4)-->]Manalpha1-4GlcNalpha1-6(acyl-->)inositol-PO(4)-lipid. It thus was realized that yeast GPI lipids, as their mammalian counterparts, contain an additional phosphorylethanolamine side chain on the alpha1,4-linked mannose. The biosynthetic origin of this phosphorylethanolamine group was investigated using gpi10-1 Deltaept1 Deltacpt1, a strain which is unable to synthesize phosphatidylethanolamine by transferring phosphorylethanolamine from CDP-ethanolamine onto diacylglycerol, but which still can make phosphatidylethanolamine by decarboxylation of phosphatidylserine. Gpi10-1 Deltaept1 Deltacpt1 triple mutants are unable to incorporate [(3)H]ethanolamine into M2 although metabolic labeling with [(3)H]inositol demonstrates that they make as much M2 as gpi10-1. In contrast, when labeled with [(3)H]serine, the triple mutant incorporates more label into M2 than gpi10-1. This result establishes that the phosphorylethanolamine group on the alpha1,4-linked mannose is derived from phosphatidylethanolamine and not from CDP-ethanolamine.     

Both mammalian PIG-M and PIG-X are required for growth of GPI14-disrupted yeast

GPI mannosyltransferase I (GPI-MT-I) transfers the first mannose to a GPI-anchor precursor, glucosamine-(acyl)phosphatidylinositol [GlcN-(acyl)PI]. Mammalian GPI-MT-I consists of two components, PIG-M and PIG-X, which are homologous to Gpi14p and Pbn1p in Saccharomyces cerevisiae, respectively. In the present study, we disrupted yeast GPI14 and analysed the phenotype of gpi14 yeast. The gpi14 haploid cells were inviable and accumulated GlcN-(acyl)PI. We cloned PIG-M homologues from human, Plasmodium falciparum (PfPIG-M) and Trypanosoma brucei (TbGPI14), and tested whether they could complement gpi14-disrupted yeast. None of them restored GPI-MT-I activity and cell growth in gpi14-disrupted yeast. However, gpi14-disrupted yeast cells with human PIG-M, but not with PfPIG-M or TbGPI14, grew slowly but significantly when they were supplemented with rat PIG-X. This suggests that the association of PIG-X and PIG-M for GPI-MT-I activity is not interchangeable between mammals and the other lower eukaryotes.     

Glycosylphosphatidylinositol biosynthesis defects in Gpi11p- and Gpi13p-deficient yeast suggest a branched pathway and implicate gpi13p in phosphoethanolamine transfer to the third mannose

Glycosylphosphatidylinositols (GPIs) are critical for membrane anchoring and intracellular transport of certain secretory proteins. GPIs have a conserved trimannosyl core bearing a phosphoethanolamine (EthN-P) moiety on the third mannose (Man-3) through which the glycolipid is linked to protein, but diverse GPI precursors with EthN-Ps on Man-1 and Man-2 have also been described. We report on two essential yeast genes whose products are required late in GPI assembly. GPI11 (YDR302w) encodes a homologue of human Pig-Fp, a protein implicated in the addition of EthN-P to Man-3. PIG-F complements the gpi11 deletion, but the rescued haploids are temperature sensitive. Abolition of Gpi11p or Pig-Fp function in GPI11 disruptants blocks GPI anchoring and formation of complete GPI precursors and leads to accumulation of two GPIs whose glycan head groups contain four mannoses but differ in the positioning and number of side chains, probably EthN-Ps. The less polar GPI bears EthN-P on Man-2, whereas the more polar lipid has EthN-P on Man-3. The latter finding indicates that Gpi11p is not required for adding EthN-P to Man-3. Gpi13p (YLL031cp), a member of a family of phosphoryltransferases, is a candidate for the enzyme responsible for adding EthN-P to Man-3. Depletion of Gpi13p in a Gpi11p-defective strain prevents formation of the GPI bearing EthN-P on Man-3, and Gpi13p-deficient strains accumulate a Man(4)-GPI isoform that bears EthN-P on Man-1. We further show that the lipid accumulation phenotype of Gpi11p-deficient cells resembles that of cells lacking Gpi7p, a sequence homologue of Gpi13p known to add EthN-P to Man-2 of a late-stage GPI precursor. This result suggests that in yeast a Gpi11p-deficiency can affect EthN-P addition to Man-2 by Gpi7p, in contrast to the Pig-Fp defect in mammalian cells, which prevents EthN-P addition to Man-3. Because Gpi11p and Pig-Fp affect EthN-P transfer to Man-2 and Man-3, respectively, these proteins may act in partnership with the GPI-EthN-P transferases, although their involvement in a given EthN-P transfer reaction varies between species. Possible roles for Gpi11p in the supply of the EthN-P donor are discussed. Because Gpi11p- and Gpi13p-deficient cells accumulate isoforms of Man(4)-GPIs with EthN-P on Man-2 and on Man-1, respectively, and because the GPIs that accumulate in Gpi11p-defective strains are likely to have been generated independently of one another, we propose that the yeast GPI assembly pathway is branched.     

GPI anchor biosynthesis in yeast: phosphoethanolamine is attached to the alpha1,4-linked mannose of the complete precursor glycophospholipid

Cells synthesize the GPI anchor carbohydrate core by successively adding N-acetylglucosamine, three mannoses, and phosphoethanolamine (EtN-P) onto phosphatidylinositol, thus forming the complete GPI precursor lipid which is then added to proteins. Previously, we isolated a GPI deficient yeast mutant accumulating a GPI intermediate containing only two mannoses, suggesting that it has difficulty in adding the third, alpha1,2-linked Man of GPI anchors. The mutant thus displays a similar phenotype as the mammalian mutant cell line S1A-b having a mutation in the PIG-B gene. The yeast mutant, herein named gpi10-1 , contains a mutation in YGL142C, a yeast homolog of the human PIG-B. YGL142C predicts a highly hydrophobic integral membrane protein which by sequence is related to ALG9, a yeast gene required for adding Man in alpha1,2 linkage to N-glycans. Whereas gpi10-1 cells grow at a normal rate and make normal amounts of GPI proteins, the microsomes of gpi10-1 are completely unable to add the third Man in an in vitro assay. Further analysis of the GPI intermediate accumulating in gpi10 shows it to have the structure Manalpha1-6(EtN-P-)Manalpha1-4GlcNalpha1- 6(acyl) Inositol-P-lipid. The presence of EtN-P on the alpha1,4-linked Man of GPI anchors is typical of mammalian and a few other organisms but had not been observed in yeast GPI proteins. This additional EtN-P is not only found in the abnormal GPI intermediate of gpi10-1 but is equally present on the complete GPI precursor lipid of wild type cells. Thus, GPI biosynthesis in yeast and mammals proceeds similarly and differs from the pathway described for Trypanosoma brucei in several aspects.      

YLL031c belongs to a novel family of membrane proteins involved in the transfer of ethanolaminephosphate onto the core structure of glycosylphosphatidylinositol anchors in yeast

MCD4 and GPI7 are important for the addition of glycosylphosphatidylinositol (GPI) anchors to proteins in the yeast Saccharomyces cerevisiae. Mutations in these genes lead to a reduction of GPI anchoring and cell wall fragility. Gpi7 mutants accumulate a GPI lipid intermediate of the structure Manalpha1-2[NH(2)-(CH(2))(2)-PO(4)-->]Manalpha1-2Manalpha 1-6[NH(2)-(C H(2))(2)-PO(4)-->]Manalpha1-4GlcNalpha1-6[acyl-->]inositol-P O(4)-lipi d, which, in comparison with the complete GPI precursor lipid CP2, lacks an HF-sensitive side chain on the alpha1-6-linked mannose. In contrast, mcd4-174 accumulates only minor amounts of abnormal GPI intermediates. Here we investigate whether YLL031c, an open reading frame predicting a further homologue of GPI7 and MCD4, plays any role in GPI anchoring. YLL031c is an essential gene. Its depletion results in a reduction of GPI anchor addition to GPI proteins as well as to cell wall fragility. YLL031c-depleted cells accumulate GPI intermediates with the structures Manalpha1-2Manalpha1-2Manalpha1-6[NH(2)-(CH(2))(2)-PO( 4)-->]Manalpha1 -4GlcNalpha1-6[acyl-->]inositol-PO(4)-lipid and Manalpha1-2Manalpha1-2Manalpha1-6Manalpha1-4G lcNalpha1-6[acyl-->]inos itol-PO(4)-lipid. Subcellular localization studies of a tagged version of YLL031c suggest that this protein is mainly in the ER, in contrast to Gpi7p, which is found at the cell surface. The data are compatible with the idea that YLL031c transfers the ethanolaminephosphate to the inner alpha1-2-linked mannose, i.e. the group that links the GPI lipid anchor to proteins, whereas Mcd4p and Gpi7p transfer ethanolaminephosphate onto the alpha1-4- and alpha1-6-linked mannoses of the GPI anchor, respectively.     

Pig-n, a mammalian homologue of yeast Mcd4p, is involved in transferring phosphoethanolamine to the first mannose of the glycosylphosphatidylinositol

Many cell surface proteins are anchored to the membrane via a glycosylphosphatidylinositol (GPI) moiety, which is attached to the C terminus of the proteins. The core of the GPI anchor is conserved in all eukaryotes but is modified by various side chains. We cloned a mouse phosphatidylinositol glycan-class N (Pig-n) gene that encodes a 931amino acid protein expressed in the endoplasmic reticulum, which is homologous to yeast Mcd4p. We disrupted the gene in F9 embryonal carcinoma cells. In the Pig-n knockout cells, the first mannose in the GPI precursors was not modified by phosphoethanolamine. Nevertheless, further biosynthetic steps continued with the addition of the third mannose and the terminal phosphoethanolamine. The surface expression of Thy-1 was only partially affected, indicating that modification of the first mannose by phosphoethanolamine is not essential for attachment of GPI anchors in mammalian cells. An inhibitor of GPI biosynthesis, YW3548/BE49385A, inhibited transfer of phosphoethanolamine to the first mannose in mammalian cells but only slightly affected the surface expression of GPI-anchored proteins. Biosynthesis of GPI in the Pig-n knockout cells was not affected by YW3548/BE49385A, and yeast overexpressing MCD4 was highly resistant to YW3548/BE49385A, suggesting that Pig-n and Mcd4p are targets of this drug.     

The glycosylphosphatidylinositol (GPI) signal sequence of human placental alkaline phosphatase is not recognized by human Gpi8p in the context of the yeast GPI anchoring machinery

Biosynthesis of glycosylphosphatidylinositol (GPI)-anchored proteins involves the action of a GPI trans-amidase, which replaces the C-terminal GPI signal sequence (GPI-SS) of the primary translation product with a preformed GPI lipid. The transamidation depends on a complex of four proteins, Gaa1p, Gpi8p, Gpi16p and Gpi17p. Although the GPI anchoring pathway is conserved throughout the eukaryotic kingdom, it has been reported recently that the GPI-SS of human placental alkaline phosphatase (hPLAP) is not recognized by the yeast transamidase, but is recognized in yeast that contain the human Gpi8p homologue. This finding suggests that Gpi8p is intimately involved in the recognition of GPI precursor proteins and may also be responsible for the subtle taxon-specific differences in transamidase specificity that sometimes prevent the efficient GPI anchoring of heterologously expressed GPI proteins. Here, we confirm that the GPI signal sequence of hPLAP is indeed not recognized by the yeast GPI-anchoring machinery. However, in our hands, GPI attachment cannot be restored by the co-expression of human Gpi8p in yeast cells under any circumstances.     

Elimination of GPI2 suppresses glycosylphosphatidylinositol GlcNAc transferase activity and alters GPI glycan modification in Trypanosoma brucei

Many eukaryotic cell-surface proteins are post-translationally modified by a glycosylphosphatidylinositol (GPI) moiety that anchors them to the cell membrane. The biosynthesis of GPI anchors is initiated in the endoplasmic reticulum by transfer of GlcNAc from UDP-GlcNAc to phosphatidylinositol. This reaction is catalyzed by GPI GlcNAc transferase, a multisubunit complex comprising the catalytic subunit Gpi3/PIG-A as well as at least five other subunits, including the hydrophobic protein Gpi2, which is essential for the activity of the complex in yeast and mammals, but the function of which is not known. To investigate the role of Gpi2, we exploited Trypanosoma brucei (Tb), an early diverging eukaryote and important model organism that initially provided the first insights into GPI structure and biosynthesis. We generated insect-stage (procyclic) trypanosomes that lack TbGPI2 and found that in TbGPI2-null parasites, (i) GPI GlcNAc transferase activity is reduced, but not lost, in contrast with yeast and human cells, (ii) the GPI GlcNAc transferase complex persists, but its architecture is affected, with loss of at least the TbGPI1 subunit, and (iii) the GPI anchors of procyclins, the major surface proteins, are underglycosylated when compared with their WT counterparts, indicating the importance of TbGPI2 for reactions that occur in the Golgi apparatus. Immunofluorescence microscopy localized TbGPI2 not only to the endoplasmic reticulum but also to the Golgi apparatus, suggesting that in addition to its expected function as a subunit of the GPI GlcNAc transferase complex, TbGPI2 may have an enigmatic noncanonical role in Golgi-localized GPI anchor modification in trypanosomes.     

GPI7 is the second partner of PIG-F and involved in modification of glycosylphosphatidylinositol

Many eukaryotic cell surface proteins are anchored to the membrane via glycosylphosphatidylinositol (GPI). GPI is synthesized from phosphatidylinositol by stepwise reactions and attached en bloc to nascent proteins. In mammalian cells, the major GPI species transferred to proteins is termed H7. By attachment of an additional ethanolamine phosphate (EtNP) to the second mannose, H7 can be converted to H8, which acts as a minor type of protein-linked GPI and also exists as a free GPI on the cell surface. Yeast GPI7 is involved in the transfer of EtNP to the second mannose, but the corresponding mammalian enzyme has not yet been clarified. Here, we report that the human homolog of Gpi7p (hGPI7) forms a protein complex with PIG-F and is involved in the H7-to-H8 conversion. We knocked down hGPI7 by RNA interference and found that H7 accumulated with little production of H8. Immunoprecipitation experiments revealed that hGPI7 was associated with and stabilized by PIG-F, which is known to bind to and stabilize PIG-O, a protein homologous to hGPI7. PIG-O is a transferase that adds EtNP to the third mannose, rendering GPI capable of attaching to proteins. We further found that the overexpression of hGPI7 decreased the level of PIG-O and, therefore, decreased the level of EtNP transferred to the third mannose. Finally, we propose a mechanism for the regulation of GPI biosynthesis through competition between the two independent enzymes, PIG-O and hGPI7, for the common stabilizer, PIG-F.     

Complementation of Essential Yeast GPI Mannosyltransferase Mutations Suggests a Novel Specificity for Certain Trypanosoma and Plasmodium PigB Proteins

The glycosylphosphatidylinositol (GPI) anchor is an essential glycolipid that tethers certain eukaryotic proteins to the cell surface. The core structure of the GPI anchor is remarkably well conserved across evolution and consists of NH₂-CH₂-CH₂-PO₄-6Manα1,2Manα1,6Manα1,4-GlcNα1,6-myo-inositol-PO₄-lipid. The glycan portion of this structure may be modified with various side-branching sugars or other compounds that are heterogeneous and differ from organism to organism. One such modification is an α(1,2)-linked fourth mannose (Man-IV) that is side-branched to the third mannose (Man-III) of the trimannosyl core. In fungi and mammals, addition of Man-III and Man-IV occurs by two distinct Family 22 α(1,2)-mannosyltransferases, Gpi10/PigB and Smp3/PigZ, respectively. However, in the five protozoan parasite genomes we examined, no genes encoding Smp3/PigZ proteins were observed, despite reports of tetramannosyl-GPI structures (Man₄-GPIs) being produced by some parasites. In this study, we tested the hypothesis that the Gpi10/PigB proteins produced by protozoan parasites have the ability to add both Man-III and Man-IV to GPI precursors. We used yeast genetics to test the in vivo specificity of Gpi10/PigB proteins from several Plasmodium and Trypanosoma species by examining their ability to restore viability to Saccharomyces cerevisiae strains harboring lethal defects in Man-III (gpi10Δ) or Man-IV (smp3Δ) addition to GPI precursor lipids. We demonstrate that genes encoding PigB enzymes from T. cruzi, T. congolense and P. falciparum are each capable of separately complementing essential gpi10Δ and smp3Δ mutations, while PIGB genes from T. vivax and T. brucei only complement gpi10Δ. Additionally, we show the ability of T. cruzi PIGB to robustly complement a gpi10Δ/smp3Δ double mutant. Our data suggest that certain Plasmodium and Trypanosoma PigB mannosyltransferases can transfer more than one mannose to GPI precursors in vivo, and suggest a novel biosynthetic mechanism by which Man₄-GPIs may be synthesized in these organisms.     

Yeast Gpi8p is essential for GPI anchor attachment onto proteins.

Glycosylphosphatidylinositol (GPI) anchors are added onto newly synthesized proteins in the ER. Thereby a putative transamidase removes a C-terminal peptide and attaches the truncated protein to the free amino group of the preformed GPI. The yeast mutant gpi8-1 is deficient in this addition of GPIs to proteins. GPI8 encodes for an essential 47 kDa type I membrane glycoprotein residing on the luminal side of the ER membrane. GPI8 shows significant homology to a novel family of vacuolar plant endopeptidases one of which is supposed to catalyse a transamidation step in the maturation of concanavalin A and acts as a transamidase in vitro. Humans have a gene which is highly homologous to GPI8 and can functionally replace it.     

The GPI transamidase complex of Saccharomyces cerevisiae contains Gaa1p, Gpi8p, and Gpi16p

Gpi8p and Gaa1p are essential components of the GPI transamidase that adds glycosylphosphatidylinositols (GPIs) to newly synthesized proteins. After solubilization in 1.5% digitonin and separation by blue native PAGE, Gpi8p is found in 430-650-kDa protein complexes. These complexes can be affinity purified and are shown to consist of Gaa1p, Gpi8p, and Gpi16p (YHR188c). Gpi16p is an essential N-glycosylated transmembrane glycoprotein. Its bulk resides on the lumenal side of the ER, and it has a single C-terminal transmembrane domain and a small C-terminal, cytosolic extension with an ER retrieval motif. Depletion of Gpi16p results in the accumulation of the complete GPI lipid CP2 and of unprocessed GPI precursor proteins. Gpi8p and Gpi16p are unstable if either of them is removed by depletion. Similarly, when Gpi8p is overexpressed, it largely remains outside the 430-650-kDa transamidase complex and is unstable. Overexpression of Gpi8p cannot compensate for the lack of Gpi16p. Homologues of Gpi16p are found in all eucaryotes. The transamidase complex is not associated with the Sec61p complex and oligosaccharyltransferase complex required for ER insertion and N-glycosylation of GPI proteins, respectively. When GPI precursor proteins or GPI lipids are depleted, the transamidase complex remains intact.     

Gpi19, the Saccharomyces cerevisiae homologue of mammalian PIG-P, is a subunit of the initial enzyme for glycosylphosphatidylinositol anchor biosynthesis

Glycosylphosphatidylinositols (GPIs) are attached to the C termini of some glycosylated secretory proteins, serving as membrane anchors for many of those on the cell surface. Biosynthesis of GPIs is initiated by the transfer of N-acetylglucosamine (GlcNAc) from UDP-GlcNAc to phosphatidylinositol. This reaction is carried out at the endoplasmic reticulum (ER) by an enzyme complex called GPI-N-acetylglucosaminyltransferase (GPI-GlcNAc transferase). The human enzyme has six known subunits, at least four of which, GPI1, PIG-A, PIG-C, and PIG-H, have functional homologs in the budding yeast Saccharomyces cerevisiae. The uncharacterized yeast gene YDR437w encodes a protein with some sequence similarity to human PIG-P, a fifth subunit of the GPI-GlcNAc transferase. Here we show that Ydr437w is a small but essential subunit of the yeast GPI-GlcNAc transferase, and we designate its gene GPI19. Similar to other mutants in the yeast enzyme, temperature-sensitive gpi19 mutants display cell wall defects and hyperactive Ras phenotypes. The Gpi19 protein associates with the yeast GPI-GlcNAc transferase in vivo, as judged by coimmuneprecipitation with the Gpi2 subunit. Moreover, conditional gpi19 mutants are defective for GPI-GlcNAc transferase activity in vitro. Finally, we present evidence for the topology of Gpi19 within the ER membrane.     

GPI7 involved in glycosylphosphatidylinositol biosynthesis is essential for yeast cell separation

GPI7 is involved in adding ethanolaminephosphate to the second mannose in the biosynthesis of glycosylphosphatidylinositol (GPI) in Saccharomyces cerevisiae. We isolated gpi7 mutants, which have defects in cell separation and a daughter cell-specific growth defect at the non-permissive temperature. WSC1, RHO2, ROM2, GFA1, and CDC5 genes were isolated as multicopy suppressors of gpi7-2 mutant. Multicopy suppressors could suppress the growth defect of gpi7 mutants but not the cell separation defect. Loss of function mutations of genes involved in the Cbk1p-Ace2p pathway, which activates the expression of daughter-specific genes for cell separation after cytokinesis, bypassed the temperature-sensitive growth defect of gpi7 mutants. Furthermore, deletion of EGT2, one of the genes controlled by Ace2p and encoding a GPI-anchored protein required for cell separation, ameliorated the temperature sensitivity of the gpi7 mutant. In this mutant, Egt2p was displaced from the septal region to the cell cortex, indicating that GPI7 plays an important role in cell separation via the GPI-based modification of daughter-specific proteins in S. cerevisiae.     

Active site determination of Gpi8p, a caspase-related enzyme required for glycosylphosphatidylinositol anchor addition to proteins

Glycosylphosphatidylinositol (GPI) anchors are attached to newly synthesized proteins in the ER by a transamidation reaction during which a C-terminal GPI attachment signal is replaced by a preformed GPI precursor lipid. This reaction depends on GAA1 and GPI8, the latter belonging to a novel cysteine protease family. Homologies between this family and other Cys proteinases, such as caspases, pointed to Cys199 and His157 as potential active site residues. Indeed, gpi8 alleles mutated at Cys199 or His157 are nonfunctional, i.e., they are unable to suppress the lethality of Deltagpi8 mutants. The overexpression of these nonfunctional alleles in wild-type cells leads to the accumulation of the free GPI precursor lipid CP2, delays the maturation of the GPI protein Gas1p, and arrests cell growth. The dominant negative effect of the Cys199 mutant cannot be overcome by the simultaneous overexpression of Gaa1p. Most GPI8 alleles mutated in other conserved regions of the protein can complement the growth defect of Deltagpi8, but nevertheless accumulate CP2. CP2 accumulation, a delay in Gas1p maturation and a slowing of cell growth can also be observed when Gpi8p is depleted to 50% of its normal level in wild-type cells. The dominant negative effect of nonfunctional and partially functional mutant alleles can best be explained by assuming that Gpi8p works as part of a homo- or heteropolymeric complex.     

Gaa1p and gpi8p are components of a glycosylphosphatidylinositol (GPI) transamidase that mediates attachment of GPI to proteins

Many eukaryotic cell surface proteins are anchored to the membrane via glycosylphosphatidylinositol (GPI). The GPI is attached to proteins that have a GPI attachment signal peptide at the carboxyl terminus. The GPI attachment signal peptide is replaced by a preassembled GPI in the endoplasmic reticulum by a transamidation reaction through the formation of a carbonyl intermediate. GPI transamidase is a key enzyme of this posttranslational modification. Here we report that Gaa1p and Gpi8p are components of a GPI transamidase. To determine a role of Gaa1p we disrupted a GAA1/GPAA1 gene in mouse F9 cells by homologous recombination. GAA1 knockout cells were defective in the formation of carbonyl intermediates between precursor proteins and transamidase as determined by an in vitro GPI-anchoring assay. We also show that cysteine and histidine residues of Gpi8p, which are conserved in members of a cysteine protease family, are essential for generation of a carbonyl intermediate. This result suggests that Gpi8p is a catalytic component that cleaves the GPI attachment signal peptide. Moreover, Gaa1p and Gpi8p are associated with each other. Therefore, Gaa1p and Gpi8p constitute a GPI transamidase and cooperate in generating a carbonyl intermediate, a prerequisite for GPI attachment.     

Glycosylphosphatidylinositol membrane anchors in Saccharomyces cerevisiae: absence of ceramides from complete precursor glycolipids.

Glycosylphosphatidylinositol (GPI) anchoring of membrane proteins occurs through two distinct steps, namely the assembly of a precursor glycolipid and its subsequent transfer onto newly synthesized proteins. To analyze the structure of the yeast precursor glycolipid we made use of the pmi40 mutant that incorporates very high amounts of [3H]mannose. Two very polar [3H]mannose-labeled glycolipids named CP1 and CP2 qualified as GPI precursor lipids since their carbohydrate head group, Man alpha 1,2(X-->PO4-->6)Man alpha 1,2Man alpha 1,6Man alpha-GlcN-inositol (with X most likely being ethanolamine) comprises the core structure which is common to all GPI anchors described so far. CP1 predominates in cells grown at 24 degrees C whereas CP2 is induced by stress conditions. The apparent structural identity of the head groups suggests that CP1 and CP2 contain different lipid moieties. The lipid moieties of both CP1 and CP2 can be removed by mild alkaline hydrolysis although the protein-bound GPI anchors made by the pmi40 cells under identical labeling conditions contain mild base resistant ceramides. These findings imply that the ceramide moiety found on the majority of yeast GPI anchored proteins is added through a lipid remodeling step that occurs after the addition of the GPI precursor glycolipids to proteins.