Evidence that free GPI glycolipids are essential for growth of Leishmania mexicana.

The cell surface of the parasitic protozoan Leishmania mexicana is coated by glycosylphosphatidylinositol (GPI)-anchored glycoproteins, a GPI-anchored lipophosphoglycan and a class of free GPI glycolipids. To investigate whether the anchor or free GPIs are required for parasite growth we cloned the L.mexicana gene for dolichol-phosphate-mannose synthase (DPMS) and attempted to create DPMS knockout mutants by targeted gene deletion. DPMS catalyzes the formation of dolichol-phosphate mannose, the sugar donor for all mannose additions in the biosynthesis of both the anchor and free GPIs, except for a alpha1-3-linked mannose residue that is added exclusively to the free GPIs and lipophosphoglycan anchor precursors. The requirement for dolichol-phosphate-mannose in other glycosylation pathways in L.mexicana is minimal. Deletion of both alleles of the DPMS gene (lmdpms) consistently resulted in amplification of the lmdpms chromosomal locus unless the promastigotes were first transfected with an episomal copy of lmdpms, indicating that lmdpms, and possibly GPI biosynthesis, is essential for parasite growth. As evidence presented in this and previous studies indicates that neither GPI-anchored glycoproteins nor lipophosphoglycan are required for growth of cultured parasites, it is possible that the abundant and functionally uncharacterized free GPIs are essential membrane components.

Delineation of three pathways of glycosylphosphatidylinositol biosynthesis in Leishmania mexicana. Precursors from different pathways are assembled on distinct pools of phosphatidylinositol and undergo fatty acid remodeling.

Glycosylphosphatidylinositol (GPI) glycolipids are major cell surface constituents in the Leishmania parasites. Distinct classes of GPI are present as membrane anchors for several surface glycoproteins and an abundant lipophosphoglycan as well as being the major glycolipids (GIPLs) in the plasma membrane. In this study we have identified putative precursors for the protein and lipophosphoglycan anchors and delineated the complete pathway for GIPL biosynthesis in Leishmania mexicana promastigotes. Based on the structural analyses of these GPI intermediates and their kinetics of labeling in vivo and in cell-free systems, we provide evidence that the GIPLs are the products of an independent biosynthetic pathway rather than being excess precursors of the anchor pathways. First, we show that the similar glycan head groups of the GIPL and protein/lipophosphoglycan anchor precursors are assembled on two distinct pools of PI corresponding to 1-O-(C18:0)alkyl-2-stearoyl-PI and 1-O-(C24:0/C26:0)-2-stearoyl-PI, respectively. These PI species account for 20 and 1% of the total PI pool, respectively, indicating a remarkable specificity in their selection. Second, analysis of the flux of intermediates through these pathways in vivo and in a cell-free system suggests that the GIPL and anchor pathways are independently regulated. We also show that GIPL biosynthesis requires fatty acid remodeling, in which the sn-2 stearoyl chains are replaced with myristoyl or lauroyl chains. Fatty acid remodeling is dependent on CoA and ATP and occurs on pre-existing but not on de novo synthesized GIPLs. We suggest that the compartmentalization of different GPI pathways may be important in regulating the species and stage-specific expression of different GPI structures in these parasites.

Developmentally regulated changes in the cell surface architecture of Leishmania parasites.

The cell surface of Leishmania parasites is coated by a highly unusual glycocalyx which varies markedly during the parasite life cycle. The predominant molecule on the extracellular promastigote (sandfly) stage is a complex lipophosphoglycan (LPG), which together with a number of GPI-anchored proteins and a family of low molecular weight glycoinositolphospholipids (GIPLs), forms a morphologically distinct protective coat over the plasma membrane. The structure of the LPG has been shown to vary in different species and during promastigote development in the sandfly. This polymorphism is thought to be important in allowing Leishmania parasites to colonize a range of insect hosts, and in facilitating the regulated migration of promastigotes along the sandfly alimentary canal. Stage-specific changes in LPG are also involved in preadapting promastigotes to life in the mammalian host. This complex glycocalyx coat is absent from the amastigote stage that proliferates in the phagolysosomes of mammalian macrophages, as the expression of both the LPG and GPI-anchored proteins is massively down-regulated. Instead, the plasma membrane of amastigotes is coated by a densely packed layer of parasite-derived GIPLs and host-derived glycosphingolipids. We propose that the down-regulation of the promastigote macromolecules and the acquisition of host glycolipids by amastigotes represents an important strategy to avoid detection by specific and non-specific components of the immune system.

The variant-specific surface protein of Giardia, VSP4A1, is a glycosylated and palmitoylated protein.

The variant-specific surface proteins (VSPs) of the ancient protist Giardia duodenalis (syn.: Giardia intestinalis, Giardia lamblia) are cysteine- and threonine-rich polypeptides that can vary considerably in sequence and size. In the present study, we have purified a VSP (VSP4A1, formerly called CR1SP-90) from a cloned Giardia isolate, derived from a sheep, by Triton X-114 phase partitioning and anion-exchange chromatography. Analysis of the purified VSP4A1 showed that this protein is posttranslationally modified with both glycans and lipid. The glycans of VSP4A1 were detected and partially characterized by (1) compositional analysis, which indicated the presence of GlcNAc and Glc (0.5 and 1.0 mol/mol of protein respectively), and (2) the specific labelling of VSP4A1 with galactosyltransferase/UDP-[3H]Gal. The glycans were released by beta-elimination, suggesting that they are O-linked to the protein. Bio-Gel P4 chromatography of the released galactosylated glycans and further compositional analysis suggested that the major glycan on the VSP is a trisaccharide with Glc at the reducing terminus. These and other results indicate the absence of any N-linked glycans on the VSP and suggest instead that it is elaborated with a novel type of short O-linked glycan. Compositional analysis and radiolabelling experiments also indicated that VSP4A1 is modified with covalently linked palmitate (1 mol/mol of protein). Hydroxylamine treatment at neutral pH of[3H]palmitate-labelled VSP4A1 indicated that the acyl chain may be attached by a thioester linkage. A likely location for the lipid modification appears to be in the region of the C-terminal domain where it may facilitate association of the protein with the plasma membrane.

Identification of two N-terminal non-alpha-helical domain motifs important in the assembly of glial fibrillary acidic protein.

The non-alpha-helical N-terminal domain of intermediate filament proteins plays a key role in filament assembly. Previous studies have identified a nonapeptide motif, SSYRRIFGG, in the non-alpha-helical N-terminal domain of vimentin that is required for assembly. This motif is also found in desmin, peripherin and the type IV intermediate filament proteins. GFAP is the only type III intermediate filament protein in which this motif is not readily identified. This study has identified two motifs in the non-alpha-helical N-terminal domain of mouse GFAP that play important roles in GFAP assembly. One motif is located at the very N terminus and has the consensus sequence, MERRRITS-ARRSY. It has some characteristics in common with the vimentin nonapeptide motif, SSYRRIFGG, including its location in the non-alpha-helical N-terminal domain and a concentration of arginine residues. Unlike the vimentin motif in which even conserved sequence changes affect filament assembly, the GFAP consensus sequence, MERRRITS-ARRSY, can be replaced by a completely unrelated sequence; namely, the heptapeptide, MVRANKR, derived from the lambda cII protein. When fused to GFAP sequences with sequential deletions of the N-terminal domain, the lambda cII heptapeptide was used to help identify a second motif, termed the RP-box, which is located just upstream of the GFAP alpha-helical rod domain. This RP-box affected the efficiency of filament assembly as well as protein-protein interactions in the filament, as shown by sedimentation assays and electron microscopy. These results are supported by previous data, which showed that the dramatic reorganization of GFAP within cells was due to phosphorylation-dephosphorylation of a site located in this RP-box. The results in this study suggest the RP-box motif to be a key modulator in the mechanism of GFAP assembly, and support a role for this motif in both the nucleation and elongation phases of filament assembly. The RP-box motif in GFAP has the consensus sequence, RLSL-RM-PP. Sequences similar to the GFAP RP-box motif are also to be found in vimentin, desmin and peripherin. Like GFAP, these include phosphorylation and proteolysis sites and are adjacent to the start of the central alpha-helical rod domain, suggesting that this motif of general importance to type III intermediate filament protein assembly.

Glycosyl-phosphatidylinositol molecules of the parasite and the host.

The glycosyl-phosphatidylinositol (GPI) protein-membrane anchors are ubiquitous among the eukaryotes. However, while mammalian cells typically express in the order of 100 thousand copies of GPI-anchor per cell, the parasitic protozoa, particularly the kinetoplastids, express up to 10-20 million copies of GPI-anchor and/or GPI-related glycolipids per cell. Thus GPI-family members dominate the cell surface molecular architecture of these organisms. In several cases, GPI-anchored proteins, such as the variant surface glycoprotein (VSG) of the African trypanosomes, or GPI-related glycolipids, such as the lipophosphoglycan (LPG) of the Leishmania, are known to be essential for parasite survival and infectivity. The highly elevated levels and specialised nature of GPI metabolism in the kinetoplastid parasites suggest that the GPI biosynthetic pathways might be good targets for the development of chemotherapeutic agents. This article introduces the range of GPI structures found in protozoan parasites, and their mammalian hosts, and discusses some aspects of GPI biosynthesis.

The mechanism of inhibition of glycosylphosphatidylinositol anchor biosynthesis in Trypanosoma brucei by mannosamine.

The inhibition of glycosylphosphatidylinositol anchor biosynthesis by mannosamine has been described previously in the procyclic forms of Trypanosoma brucei and in mammalian cells (Lisanti, M. P., Field, M. C., Caras, I. W. J., Menon, A. K., and Rodriguez-Boulan, E. (1991) EMBO J. 10, 1969-1977). A recent report has suggested that mannosamine exerts these effects by becoming incorporated into glycosylphosphatidylinositol anchor intermediates (Pan, Y-T., Kamitani, T., Bhuvaneswaran, C., Hallaq, Y., Warren, C. D., Yeh, E. T. H., and Elbein, A. D. (1992) J. Biol. Chem. 267, 21250-21255). In this paper we have analyzed the effects of mannosamine on glycosylphosphatidylinositol anchor and variant surface glycoprotein biosynthesis in the blood-stream form of T. brucei. Trypanosomes were biosynthetically labeled with [3H]mannosamine, and [3H]glucosamine in the presence of mannosamine, and the structures of the labeled glycolipids which accumulated were determined. The main glycolipid metabolite of mannosamine was shown to be ManN-Man-GlcN-PI. A trypanosome cell-free system preloaded with this compound was significantly impaired in its ability to synthesize glycosylphosphatidylinositol anchor intermediates beyond Man alpha 1-6Man alpha 1-4GlcN alpha 1-6PI. This compound is therefore proposed to be an inhibitor of the Dol-P-Man:Man alpha 1-6Man alpha 1-4GlcNa alpha 1-6PI alpha 1-2-mannosyltransferase of the GPI biosynthetic pathway. In living trypanosomes, 4 mM mannosamine had no effect on protein synthesis but reduced the rate of formation of mature glycosylphosphatidylinositol anchor precursors by 80%. This reduction in anchor precursor synthesis was insufficient to prevent the attachment of glycosylphosphatidylinositol anchors to newly synthesized variant surface glycoprotein molecules. These data suggest that the rate of anchor precursor synthesis in the bloodstream form of T. brucei, in contrast to mammalian cells and the procyclic form of T. brucei, is in large excess of the cellular requirements for protein anchorage.

Analysis of the neutral glycan fractions of glycosyl-phosphatidylinositols by thin-layer chromatography.

The radiolabeled neutral glycan fractions of both glycosyl-phosphatidylinositol (GPI) protein anchors and related glycolipids were analyzed by thin-layer chromatography on silica gel 60, using butanol:ethanol:water (4:3:3, v/v) or a combination of 1-propanol:acetone:water (9:6:5, v/v and 5:4:1, v/v) as solvents. Dextran acid hydrolysates were used as standards, and oligomers up to 11 glucose units could be resolved. A comparison of 18 GPI-glycan standards revealed that their migration was dependent mainly on the size of the oligosaccharide. Isomers were generally not resolved, with the exception of Man alpha 1-6Man alpha 1-4AHM and Man alpha 1-3Man alpha 1-4AHM. Structures containing galactofuranose or GalNAc were well resolved from structures containing only Galp and/or Manp. The utility of this method for the microsequencing of radiolabeled neutral glycans derived from two GPI glycolipids, using exoglycosidases and chemical treatments, is demonstrated. This method is a simple and useful complement to the existing chromatographic techniques.

Effect of glycosylation inhibitors on the structure and function of the murine transferrin receptor.

The murine transferrin receptor is a disulphide-linked dimer with three N-glycosylation sites. We have investigated the structural and functional properties of the transferrin receptor from murine plasmacytoma cells (NS-1 cells) treated with the glycosylation inhibitor, tunicamycin and the glycosylation-processing inhibitors, swainsonine and castanospermine. 1. Tunicamycin (1 microgram/ml) inhibited mannose incorporation in NS-1 cells by greater than 90%, but also inhibited methionine incorporation by up to 50%. Both swainsonine (1 microgram/ml) and castanospermine (50 micrograms/ml) resulted in mannose incorporation greater than 100% of untreated cells and neither drug affected methionine incorporation. 2. Incubation of NS-1 cells with tunicamycin resulted in a shift in the apparent molecular mass of the transferrin receptor from 96 kDa and 94 kDa to approximately 82 kDa. 3. Peptide N-glycosidase F digestion of the receptor from untreated cells resulted in the fully deglycosylated 82 kDa component as well as an 87 kDa component which represents partially deglycosylated receptor resistant to peptide N-glycosidase F digestion. 4. The receptor from swainsonine-treated cells was equally sensitive to peptide N-glycosidase F and endo-beta-N-acetylglucosaminidase H (endo H; resulting in both 87-kDa and 82-kDa components), whereas the receptor from castanospermine-treated cells was only partially sensitive to endo H. 5. Analysis of mannose- and fucose-labelled cellular glycopeptides by concanavalin-A--Sepharose chromatography showed that swainsonine (1 microgram/ml) treatment resulted in approximately 90% inhibition of the synthesis of complex N-glycans and an accumulation of fucosylated hybrid structures. In contrast, castanospermine (100 micrograms/ml) treatment resulted in only partial inhibition (60%) of the synthesis of complex N-glycans. 6. Analysis of the receptor from tunicamycin, swainsonine and castanospermine treated cells under nonreducing conditions showed a single component corresponding to the dimer, indicating that dimerisation of newly synthesised murine receptor is independent of carbohydrate. 7. The non-glycosylated receptor from tunicamycin-treated cells appears to bind transferrin as demonstrated by interaction with transferrin-Sepharose. 8. Surface expression of the receptor was not significantly altered in the presence of either swainsonine or castanospermine as judged by flow cytometry.