Leishmania and Trypanosoma surface glycoproteins have a common glycophospholipid membrane anchor

Plant glycosylphosphatidylinositol anchored proteins at the plasma membrane-cell wall nexus

Approximately 1% of plant proteins are predicted to be post-translationally modified with a glycosylphosphatidylinositol (GPI) anchor that tethers the polypeptide to the outer leaflet of the plasma membrane. Whereas the synthesis and structure of GPI anchors is largely conserved across eukaryotes, the repertoire of functional domains present in the GPI-anchored proteome has diverged substantially. In plants, this includes a large fraction of the GPI-anchored proteome being further modified with plant-specific arabinogalactan (AG) O-glycans. The importance of the GPI-anchored proteome to plant development is underscored by the fact that GPI biosynthetic null mutants exhibit embryo lethality. Mutations in genes encoding specific GPI-anchored proteins (GAPs) further supports their contribution to diverse biological processes, occurring at the interface of the plasma membrane and cell wall, including signaling, cell wall metabolism, cell wall polymer cross-linking, and plasmodesmatal transport. Here, we review the literature concerning plant GPI-anchored proteins, in the context of their potential to act as molecular hubs that mediate interactions between the plasma membrane and the cell wall, and their potential to transduce the signal into the protoplast and, thereby, activate signal transduction pathways.

The Green Gut: Chlorophyll Degradation in the Gut of Spodoptera littoralis

Chlorophylls, the most prominent natural pigments, are part of the daily diet of herbivorous insects. The spectrum of ingested and digested chlorophyll metabolites compares well to the pattern of early chlorophyll-degradation products in senescent plants. Intact chlorophyll is rapidly degraded by proteins in the front- and midgut. Unlike plants, insects convert both chlorophyll a and b into the corresponding catabolites. MALDI-TOF/MS imaging allowed monitoring the distribution of the chlorophyll catabolites along the gut of Spodoptera littoralis larvae. The chlorophyll degradation in the fore- and mid-gut is strongly pH dependent, and requires alkaline conditions. Using LC-MS/MS analysis we identified a lipocalin-type protein in the intestinal fluid of S. littoralis homolog to the chlorophyllide a binding protein from Bombyx mori. Widefield and high-resolution autofluorescence microscopy revealed that the brush border membranes are covered with the chlorophyllide binding protein tightly bound via its GPI-anchor to the gut membrane. A function in defense against gut microbes is discussed.

Impact of Leishmania metalloprotease GP63 on macrophage signaling

The intramacrophage protozoan parasites of Leishmania genus have developed sophisticated ways to subvert the innate immune response permitting their infection and propagation within the macrophages of the mammalian host. Several Leishmania virulence factors have been identified and found to be of importance for the development of leishmaniasis. However, recent findings are now further reinforcing the critical role played by the zinc-metalloprotease GP63 as a virulence factor that greatly influence host cell signaling mechanisms and related functions. GP63 has been found to be involved not only in the cleavage and degradation of various kinases and transcription factors, but also to be the major molecule modulating host negative regulatory mechanisms involving for instance protein tyrosine phosphatases (PTPs). Those latter being well recognized for their pivotal role in the regulation of a great number of signaling pathways. In this review article, we are providing a complete overview about the role of Leishmania GP63 in the mechanisms underlying the subversion of macrophage signaling and functions.

Secreted virulence factors and immune evasion in visceral leishmaniasis

Evasion or subversion of host immune responses is a well-established paradigm in infection with visceralizing leishmania. In this review, we summarize current findings supporting a model in which leishmania target host regulatory molecules and pathways, such as the PTP SHP-1 and the PI3K/Akt signaling cascade, to prevent effective macrophage activation. Furthermore, we describe how virulence factors, secreted by leishmania, interfere with macrophage intracellular signaling. Finally, we discuss mechanisms of secretion and provide evidence that leishmania use a remarkably adept, exosome-based secretion mechanism to export and deliver effector molecules to host cells. In addition to representing a novel mechanism for trafficking of virulence factors across membranes, recent findings indicate that leishmania exosomes may have potential as vaccine candidates.

The alpha2delta subunits of voltage-gated calcium channels form GPI-anchored proteins, a posttranslational modification essential for function

Voltage-gated calcium channels are thought to exist in the plasma membrane as heteromeric proteins, in which the alpha1 subunit is associated with two auxiliary subunits, the intracellular beta subunit and the alpha(2)delta subunit; both of these subunits influence the trafficking and properties of Ca(V)1 and Ca(V)2 channels. The alpha(2)delta subunits have been described as type I transmembrane proteins, because they have an N-terminal signal peptide and a C-terminal hydrophobic and potentially transmembrane region. However, because they have very short C-terminal cytoplasmic domains, we hypothesized that the alpha(2)delta proteins might be associated with the plasma membrane through a glycosylphosphatidylinositol (GPI) anchor attached to delta rather than a transmembrane domain. Here, we provide biochemical, immunocytochemical, and mutational evidence to show that all of the alpha(2)delta subunits studied, alpha(2)delta-1, alpha(2)delta-2, and alpha(2)delta-3, show all of the properties expected of GPI-anchored proteins, both when heterologously expressed and in native tissues. They are substrates for prokaryotic phosphatidylinositol-phospholipase C (PI-PLC) and trypanosomal GPI-PLC, which release the alpha(2)delta proteins from membranes and intact cells and expose a cross-reacting determinant epitope. PI-PLC does not affect control transmembrane or membrane-associated proteins. Furthermore, mutation of the predicted GPI-anchor sites markedly reduced plasma membrane and detergent-resistant membrane localization of alpha(2)delta subunits. We also show that GPI anchoring of alpha(2)delta subunits is necessary for their function to enhance calcium currents, and PI-PLC treatment only reduces calcium current density when alpha(2)delta subunits are coexpressed. In conclusion, this study redefines our understanding of alpha(2)delta subunits, both in terms of their role in calcium-channel function and other roles in synaptogenesis.

Major surface protease of trypanosomatids: one size fits all?

Major surface protease (MSP or GP63) is the most abundant glycoprotein localized to the plasma membrane of Leishmania promastigotes. MSP plays several important roles in the pathogenesis of leishmaniasis, including but not limited to (i) evasion of complement-mediated lysis, (ii) facilitation of macrophage (Mø) phagocytosis of promastigotes, (iii) interaction with the extracellular matrix, (iv) inhibition of natural killer cellular functions, (v) resistance to antimicrobial peptide killing, (vi) degradation of Mø and fibroblast cytosolic proteins, and (vii) promotion of survival of intracellular amastigotes. MSP homologues have been found in all other trypanosomatids studied to date including heteroxenous members of Trypanosoma cruzi, the extracellular Trypanosoma brucei, unusual intraerythrocytic Endotrypanum spp., phytoparasitic Phytomonas spp., and numerous monoxenous species. These proteins are likely to perform roles different from those described for Leishmania spp. Multiple MSPs in individual cells may play distinct roles at some time points in trypanosomatid life cycles and collaborative or redundant roles at others. The cellular locations and the extracellular release of MSPs are also discussed in connection with MSP functions in leishmanial promastigotes.

Characterizing stability properties of supported bilayer membranes on nanoglassified substrates using surface plasmon resonance

Supported bilayer membranes (SBMs) formed on solid substrates, in particular glass, provide an ideal cell mimicking model system that has been found to be highly useful for biosensing applications. Although the stability of the membrane structures is known to determine the applicability, the subject has not been extensively investigated, largely because of the lack of convenient methods to monitor changes of membrane properties on glass in real time. This work reports the evaluation of the stability properties of a series of SBMs against chemical and air damage by use of surface plasmon resonance spectroscopy and nanoglassified gold substrates. Seven SBMs composed of phosphatidylcholine and DOPC+, including single-component, mixed, protein-reinforced SBMs (rSBMs) and protein-tethered bilayer membranes (ptBLMs), are studied. The stability properties under various conditions, especially the effects of surfactants, organic solvents, and dehydration damage on the bilayers, are compared. PC membranes are found to be easily removed from the glassy surfaces using relatively low concentrations of the surfactants, while DOPC+ is markedly more stable toward nonionic surfactant. DOPC+ membranes also demonstrated remarkable air stability while PC films exhibited considerable damage from dehydration. Doping of cholesterol does not improve PC's stability against SDS and Triton but changes the lipid membrane packing enough to protect against dehydration damage. Although rSBMs and ptBLMs improve air stability to a certain degree, they are still quite susceptible to significant damage/removal from ionic and nonionic surfactants at lower concentrations. Overall, DOPC+ has noted higher stability on glass, likely due to the favorable electrostatic interaction between the silicate surface and the lipid headgroup, making it a good candidate for application. Nanoglassy SPR proves to be an attractive platform capable of rapidly screening film stability in real-time, providing critical information for future work using supported membranes for sensing applications.

Internal and surface-localized major surface proteases of Leishmania spp. and their differential release from promastigotes

Major surface protease (MSP), also called GP63, is a virulence factor of Leishmania spp. protozoa. There are three pools of MSP, located either internally within the parasite, anchored to the surface membrane, or released into the extracellular environment. The regulation and biological functions of these MSP pools are unknown. We investigated here the trafficking and extrusion of surface versus internal MSPs. Virulent Leishmania chagasi undergo a growth-associated lengthening in the t(1/2) of surface-localized MSP, but this did not occur in the attenuated L5 strain. The release of surface-localized MSP was enhanced in a dose-dependent manner by MbetaCD, which chelates membrane cholesterol-ergosterol. Furthermore, incubation of promastigotes at 37 degrees C with Matrigel matrix, a soluble basement membrane extract of Engelbreth-Holm-Swarm tumor cells, stimulated the release of internal MSP but not of surface-located MSP. Taken together, these data indicate that MSP subpopulations in distinct cellular locations are released from the parasite under different environmental conditions. We hypothesize that the internal MSP with its lengthy t(1/2) does not serve as a pool for promastigote surface MSP in the sand fly vector but that it instead functions as an MSP pool ready for quick release upon inoculation of metacyclic promastigotes into mammals. We present a model in which these different MSP pools are released under distinct life cycle-specific conditions.

The ubiquitous gp63-like metalloprotease from lower trypanosomatids: in the search for a function

Plant and insect trypanosomatids constitute the "lower trypanosomatids", which have been used routinely as laboratory models for biochemical and molecular studies because they are easily cultured under axenic conditions, and they contain homologues of virulence factors from the classic human trypanosomatid pathogens. Among the molecular factors that contribute to Leishmania spp. virulence and pathogenesis, the major surface protease, alternatively called MSP, PSP, leishmanolysin, EC 3.4.24.36 and gp63, is the most abundant surface protein of Leishmania promastigotes. A myriad of functions have been described for the gp63 from Leishmania spp. when the metacyclic promastigote is inside the mammalian host. However, less is known about the functions performed by this molecule in the invertebrate vector. Intriguingly, gp63 is predominantly expressed in the insect stage of Leishmania, and in all insect and plant trypanosomatids examined so far. The gp63 homologues found in lower trypanosomatids seem to play essential roles in the nutrition as well as in the interaction with the insect epithelial cells. Since excellent reviews were produced in the last decade regarding the roles played by proteases in the vertebrate hosts, we focused in the recent developments in our understanding of the biochemistry and cell biology of gp63-like proteins in lower trypanosomatids.

The major surface protease (MSP or GP63) of Leishmania sp. Biosynthesis, regulation of expression, and function

Leishmania sp. are digenetic protozoa that cause an estimated 1.5-2 million new cases of leishmaniasis per year worldwide. Among the molecular factors that contribute to Leishmania sp. virulence and pathogenesis is the major surface protease, alternately called MSP, GP63, leishmanolysin, EC3.4.24.36, and PSP, which is the most abundant surface protein of leishmania promastigotes. Recent studies using gene knockout, antisense RNA and overexpression mutants have demonstrated a role for MSP in resistance of promastigotes to complement-mediated lysis and either a direct or indirect role in receptor-mediated uptake of leishmania. The MSP gene clusters in different Leishmania sp. include multiple distinct MSPs that tend to fall into three classes, which can be distinguished by their sequences and by their differential expression in parasite life stages. Regulated expression of MSP class gene products during the parasite life cycle occurs at several levels involving both mRNA and protein metabolism. In this review we summarize advances in MSP research over the past decade, including organization of the gene families, crystal structure of the protein, regulation of mRNA and protein expression, biosynthesis and possible functions. The MSPs exquisitely demonstrate the multiple levels of post-transcriptional gene regulation that occur in Leishmania sp. and other trypanosomatid protozoa.

Extracellular release of the surface metalloprotease, gp63, from Leishmania and insect trypanosomatids

Protease activity was found in spent culture medium collected from Leishmania donovani, L. mexicana, L. major, as well as the insect trypanosomatids, Crithidia luciliae and Leptomonas seymouri. Released protease activity increased linearly over time and was correlated to promastigote density. In SDS-PAGE, zymogram gels showed that the protease's molecular weight ranged from 43-100 kDa. Spent culture medium proteases were blocked by the metallo-protease inhibitors, 1,10-phenanthroline and Z-Tyr-Leu-NHOH, but not by bestatin, leupeptin, ABESF, pepstatin A, E-64 or aprotinin. Monoclonal and/or polyclonal antibodies to the leishmanial gp63 reacted with the released Crithidia, Leptomonas, L. major and L. donovani proteases. Cell surface biotinylation and immune precipitation using gp63-specific antibodies showed that >34% of the released protease originated from the surface. Antibodies against the Trypanosoma brucei variable surface glycoprotein cross-reactive determinant (CRD) did not recognize this activity, suggesting that the gp63 is not cleaved from the cell surface by a parasite phospholipase, but is released by an alternative mechanism.

Regulation of GP63 mRNA stability in promastigotes of virulent and attenuated Leishmania chagasi

GP63 is a 63-kDa glycoprotein that is abundantly expressed on the surface of all Leishmania species and is involved in several steps of promastigote infection of host cells. Leishmania chagasi has at least 18 haploid msp (major surface protease) genes encoding GP63 that are divided into three classes, mspS, mspL or mspC, according to their unique 3' UTR sequences and differential expression. All three msp classes are constitutively transcribed during virulent promastigote growth in vitro, although mspL mRNA is most abundant during logarithmic phase and mspS mRNA predominates in stationary phase. Thus, the steady state levels of the mspL and mspS mRNAs are post-transcriptionally regulated. Using Actinomycin D to arrest transcription, we found that in virulent promastigotes the half-life (t(1/2)) of mspL mRNA is coordinately modulated with growth phase, decreasing from a mean of 84 min during early logarithmic growth to a mean of 17 min at a stage intermediate between logarithmic and stationary phase. However, in attenuated promastigotes, the t(1/2) of mspL RNA remains the same throughout parasite growth. In contrast to mspL RNA, the t(1/2) of mspS and mspC RNA is constant throughout all growth phases of both virulent and attenuated promastigote growth. The presence of the translation inhibitor cycloheximide increases the t(1/2) of mspL RNA 4-6-fold in both virulent and attenuated promastigotes at all growth phases. These results indicate that the t(1/2) of mspL RNA is maintained by at least two distinct mechanisms - one activated during growth to stationary phase and the other dependent on a labile negative regulatory protein factor(s).

Vaccination against Leishmania major in a CBA mouse model of infection: role of adjuvants and mechanism of protection

Gp63 is a major surface protein of Leishmania promastigotes. Its protective efficacy has been tested in several experimental models using different mouse strains, gp63 forms, adjuvants and routes of immunization, giving rise to conflicting results. This investigation was designed to determine whether these discrepancies could be ascribed to differing experimental procedures, and to compare gp63-induced protection with that achieved using live promastigotes. Preliminary experiments demonstrated that gp63 was an extremely potent immunogen compared to a standard antigen (ovalbumin). Protection against Leishmania major infection afforded by gp63 inoculation was studied in CBA mice. Injection of gp63 in saline, or of CFA, BCG, and C. parvum without antigen, induced significant protection. When gp63 and adjuvants were combined, results differed depending on the site of vaccination relative to that of the challenge infection. Vaccination with gp63 plus adjuvants in the tail (i.e. close to the site of infection) led to a stronger reduction of lesion size than the basal level of protection elicited by adjuvants alone, except in the case of CFA. Surprisingly however, when the antigen was injected at a distance from the site of infection (immunization in the hind foot pads, infection in the rump), the protective effect of gp63 was decreased by the adjuvants. Finally, vaccination at either site using live parasites (radioattenuated or virulent promastigotes) resulted in most instances in better protection than achieved by any protocol using gp63 and adjuvants. While anti-gp63 T cells proliferated in vitro in response to L. major-infected bone marrow-derived macrophages, they were unable to activate macrophages for parasite killing. This is in contrast with lymphocytes from mice immunized with live parasites, which both proliferated and stimulated significant killing of the microorganisms within 48 h.

Proteases of protozoan parasites

Proteolytic enzymes seem to play important roles in the life cycles of all medically important protozoan parasites, including the organisms that cause malaria, trypanosomiasis, leishmaniasis, amebiasis, toxoplasmosis, giardiasis, cryptosporidiosis and trichomoniasis. Proteases from all four major proteolytic classes are utilized by protozoans for diverse functions, including the invasion of host cells and tissues, the degradation of mediators of the immune response and the hydrolysis of host proteins for nutritional purposes. The biochemical and molecular characterization of protozoan proteases is providing tools to improve our understanding of the functions of these enzymes. In addition, studies in multiple systems suggest that inhibitors of protozoan proteases have potent antiparasitic effects. This review will discuss recent advances in the identification and characterization of protozoan proteases, in the determination of the function of these enzymes, and in the evaluation of protease inhibitors as potential antiprotozoan drugs.

Protein S-myristoylation in Leishmania revealed with a heterologous reporter

Reversible esterification of myristic acid to cysteine residue(s) (S-myristoylation) was documented recently in the protozoan Trypanosoma brucei. Unlike N-myristoylation, S-myristoylation appears to be rare (or non-existent) in animal cells and has not been documented in any other trypanosome. Reasoning that a lack of knowledge of appropriate substrates may have contributed to this state of affairs, we devised an assay to test for protein S-myristoylation in the ancient eukaryote Leishmania. A cDNA encoding a glycosylphosphatidylinositol-phospholipase C (GPI-PLC) from T. brucei was transfected into Leishmania and the expressed protein analyzed for covalent lipid modifications. Leishmania modified the reporter with myristate in a thio-ester linkage. From these observations, we infer that (i) GPI-PLC may be used as a reporter of this lipid modification in eukaryotes, and (ii) protein S-myristoylation might have ancient origins.

Differentially expressed Leishmania major gp63 genes encode cell surface leishmanolysin with distinct signals for glycosylphosphatidylinositol attachment

The Leishmania cell surface metalloproteinase, leishmanolysin or GP63, is expressed in all stages of Leishmania major. Initial studies reported that in L. major the gp63 genes were arranged as five homologous, tandemly repeated genes (gp63 genes 1-5) and a sixth, less conserved gp63 gene located 8 kb downstream of gp63 gene 5. This study compared the sequences of L. major gp63 gene 1 and gp63 gene 6 and identified a seventh L. major gp63 gene located downstream from gp63 gene 6. The L. major gp63 genes exhibited stage-specific differences in their expression: gp63 genes 1-5 were expressed in promastigotes only, gp63 gene 6 was expressed in promastigotes and amastigotes, while gp63 gene 7 was expressed predominantly in stationary phase promastigotes and in amastigotes. Analysis of the predicted protein sequence of gp63 gene 6 (GP63-6) and gp63 gene 1 (GP63-1) showed that these two proteins were homologous in terms of overall predicted domain structure. L. major GP63-1 has been reported to contain a glycosylphosphatidylinositol (GPI) membrane anchor while sequence analysis predicted that GP63-6 contained a different hydrophobic C-terminus that may act as a transmembrane region. Transfection studies using L. major gp63 gene 1 and gp63 gene 6 expressed in L. donovani promastigotes showed that GP63-6 was expressed at the cell surface and that the distinct GP63-6 C-terminus was capable of mediating GPI anchor attachment.

Biochemical characterisation of an epitope on the surface membrane antigen (Cs-gp200) of the pathogenic piscine haemoflagellate Cryptobia salmositica Katz 1951

A protective surface antigen (200 kDa) on C. salmositica was detected using a monoclonal antibody (mAb-001). Enzymatic studies on the epitope indicated that it was sensitive to nonspecific protease K and to site-specific trypsin and protease V8 but not to alpha-chymotrypsin. The reactivity of the epitope with mAb-001 was not affected when the antigen was denatured with 8 M urea; however, reduction of the antigen with dithiothreitol destroyed the epitope. The epitope was susceptible to sodium m-periodate oxidation and N-glycosidase F, but not to O-glycosidase or neuraminidase. It was also sensitive to mild potassium hydrochloride hydrolysis and to phospholipase C, which is specific for phosphatidylinositol. These results suggest that the epitope consists of a polypeptide, a carbohydrate, and probably a phospholipid. The asparagine-bound N-glycosidically linked hybrid-type carbohydrate chain has the minimum length of a chitobiose core unit. There is probably a phosphatidylinositol residue which anchors the polypeptide to the surface membrane. The antigen is extensively posttranslationally modified.

Functional expression of a myo-inositol/H+ symporter from Leishmania donovani

The vast majority of surface molecules in such kinetoplastid protozoa as members of the genus Leishmania contain inositol and are either glycosyl inositol phospholipids or glycoproteins that are tethered to the external surface of the plasma membrane by glycosylphosphatidylinositol anchors. We have shown that the biosynthetic precursor for these abundant glycolipids, myo-inositol, is translocated across the parasite plasma membrane by a specific transporter that is structurally related to mammalian facilitative glucose transporters. This myo-inositol transporter has been expressed and characterized in Xenopus laevis oocytes. Two-electrode voltage clamp experiments demonstrate that this protein is a sodium-independent electrogenic symporter that appears to utilize a proton gradient to concentrate myo-inositol within the cell. Immunolocalization experiments with a transporter-specific polyclonal antibody reveal the presence of this protein in the parasite plasma membrane.

Anchoring of an immunogenic Plasmodium falciparum circumsporozoite protein on the surface of Dictyostelium discoideum

The circumsporozoite protein (CSP), a major antigen of Plasmodium falciparum, was expressed in the slime mold Dictyostelium discoideum. Fusion of the parasite protein to a leader peptide derived from Dictyostelium contact site A was essential for expression. The natural parasite surface antigen, however, was not detected at the slime mold cell surface as expected but retained intracellularly. Removal of the last 23 amino acids resulted in secretion of CSP, suggesting that the C-terminal segment of the CSP, rather than an ectoplasmic domain, was responsible for retention. Cell surface expression was obtained when the CSP C-terminal segment was replaced by the D. discoideum contact site A glycosyl phosphatidylinositol anchor signal sequence. Mice were immunized with Dictyostelium cells harboring CSP at their surface. The raised antibodies recognized two different regions of the CSP. Anti-sporozoite titers of these sera were equivalent to anti-peptide titers detected by enzyme-linked immunosorbent assay. Thus, cell surface targeting of antigens can be obtained in Dictyostelium, generating sporozoite-like cells having potentials for vaccination, diagnostic tests, or basic studies involving parasite cell surface proteins.

Intergenic regions between tandem gp63 genes influence the differential expression of gp63 RNAs in Leishmania chagasi promastigotes

The major surface protease, gp63, of Leishmania chagasi is encoded by 18 or more tandem msp genes that can be grouped into three classes on the basis of their unique 3'-untranslated sequences (3'-UTRs) and their differential expression. RNAs from the mspLs occur predominantly during the logarithmic phase of promastigote growth in vitro, RNAs from the mspSs are present mainly in stationary phase, and RNAs from mspCs occur throughout growth in culture. All three classes of gp63 genes are constitutively transcribed during all growth phases, indicating that their expression is post-transcriptionally regulated. Chimeric plasmids containing the three different 3'-UTRs and downstream intergenic regions (IRs) fused downstream of the beta-galactosidase (beta-gal) coding region were transfected into L. chagasi, and their effects on beta-gal RNA processing and enzymatic activity were examined. The presence of the 3'-UTRs by themselves had no substantive effect on beta-gal expression. However, the 3'-UTR from a mspS plus its IR resulted in about 20-fold more beta-gal activity and RNA in stationary phase relative to logarithmic phase cells. In contrast, the 3'-UTRs plus IRs of mspL and mspC had either no or little effect, respectively, on beta-gal expression. Thus, differential expression of the mspLs and mspSs is post-transcriptionally controlled by different mechanisms.

Crystallization and preliminary X-ray diffraction studies of leishmanolysin, the major surface metalloproteinase from Leishmania major

The membrane-bound GPI-anchored zinc metalloproteinase leishmanolysin purified from Leishmania major promastigotes has been crystallized in its mature form. Two crystal forms of leishmanolysin have been grown by the vapor diffusion method using 2-methyl-2,4-pentanediol as the precipitant. Macroseeding techniques were employed to produce large single crystals. Protein microheterogeneity in molecular size and charge was incorporated into both crystal forms. The tetragonal crystal form belongs to the space group P4(1)2(1)2 or the enantiomorph P4(3)2(1)2, has unit cell parameters of a = b = 63.6 A, c = 251.4 A, and contains one molecule per asymmetric unit. The second crystal form is monoclinic, space group C2, with unit cell dimensions a = 107.2 A, b = 90.6 A, c = 70.6 A, beta = 110.6 degrees, and also contains one molecule per asymmetric unit. Both crystal forms diffract X-rays beyond 2.6 A resolution and are suitable for X-ray analysis. Native diffraction data sets have been collected and the structure determination of leishmanolysin using a combination of the isomorphous replacement and the molecular replacement methods is in progress.

Developmentally regulated expression of a novel 59-kDa product of the major surface protease (Msp or gp63) gene family of Leishmania chagasi

All species of Leishmania express a major surface protease (Msp or gp63) that facilitates the interactions of the parasite with its environment at several steps in its life cycle. The msp gene family in Leishmania chagasi contains three classes of genes whose mRNAs are differentially expressed during parasite growth. Logarithmic phase (low infectivity) promastigotes express only 63-kDa versions of Msp, whereas stationary phase (high infectivity) promastigotes express both 63- and 59-kDa Msps. The different migrations of the 59- and 63-kDa proteins on acrylamide gels are not due to differences in N-linked glycosylation or the membrane anchor. Plasmid transfections of Leishmania demonstrate that mspS2 of the stationary gene class encodes a 59-kDa protein. Expression of the 59-kDa protein in stationary phase promastigotes ceases after about 12 weeks of in vitro cultivation when the parasites become attenuated. Attenuated parasites can be stimulated to re-express the 59-kDa Msp by passage through mice followed by several in vitro passages of recovered promastigotes. Amastigotes express yet another subset of Msp proteins. Thus, the 59-kDa product of mspS2 is expressed only in stationary phase promastigotes and only after recent exposure to environmental changes encountered in the mammalian host cell.

Differential targeting of two glucose transporters from Leishmania enriettii is mediated by an NH2-terminal domain

Leishmania are parasitic protozoa with two major stages in their life cycle: flagellated promastigotes that live in the gut of the insect vector and nonflagellated amastigotes that live inside the lysosomes of the vertebrate host macrophages. The Pro-1 glucose transporter of L. enriettii exists as two isoforms, iso-1 and iso-2, which are both expressed primarily in the promastigote stage of the life cycle. These two isoforms constitute modular structures: they differ exclusively and extensively in their NH2-terminal hydrophilic domains, but the remainder of each isoform sequence is identical to that of the other. We have localized these glucose transporters within promastigotes by two approaches. In the first method, we have raised a polyclonal antibody against the COOH-terminal hydrophilic domain shared by both iso-1 and iso-2, and we have used this antibody to detect the transporters by confocal immunofluorescence microscopy and immunoelectron microscopy. The staining observed with this antibody occurs primarily on the plasma membrane and the membrane of the flagellar pocket, but there is also light staining on the flagellum. We have also localized each isoform separately by introducing an epitope tag into each protein sequence. These experiments demonstrate that iso-1, the minor isoform, resides primarily on the flagellar membrane, while iso-2, the major isoform, is located on the plasma membrane and the flagellar pocket. Hence, each isoform is differentially sorted, and the structural information for targeting each transporter isoform to its correct membrane address resides within the NH2-terminal hydrophilic domain.

Immunological and structural conservation of mammalian skeletal muscle glycosylphosphatidylinositol-linked ADP-ribosyltransferases

NAD:arginine ADP-ribosyltransferases catalyze the ADP-ribosylation of arginine residues in proteins. Coding region nucleic acid and deduced amino acid sequences of a human skeletal muscle ADP-ribosyltransferase cDNA were, respectively, 80.8% and 81.3% identical to those of the rabbit skeletal muscle transferase. A human transferase-specific cDNA probe detected major mRNA of 1.2 kb (mouse and rat), 3.0 kb (rabbit), 3.8 kb (monkey), and 5.7 kb (human) upon Northern analysis. Polyclonal anti-rabbit ADP-ribosyltransferase antibodies reacted with 36,000 M(r) proteins in partially purified transferase preparations from bovine, dog, and rabbit heart muscle and a 40,000 M(r) protein from human skeletal muscle. The human muscle ADP-ribosyltransferase cDNA, like the previously cloned rabbit muscle transferase, predicts predominantly hydrophobic amino- and carboxy-terminal amino acid sequences, which is characteristic of glycosylphosphatidylinositol (GPI)-anchored proteins. On immunoblots of partially purified rabbit and human skeletal muscle ADP-ribosyltransferases, anti-cross-reacting determinant antibodies detected at 36,000 and 40,000 M(r), respectively, phosphatidylinositol-specific, phospholipase C-sensitive, GPI-anchored proteins. These data are consistent with the conclusion that GPI-anchored skeletal and cardiac muscle ADP-ribosyltransferases are conserved across mammalian species.

A glycosylphosphatidylinositol (GPI)-negative phenotype produced in Leishmania major by GPI phospholipase C from Trypanosoma brucei: topography of two GPI pathways

The major surface macromolecules of the protozoan parasite Leishmania major, gp63 (a metalloprotease), and lipophosphoglycan (a polysaccharide), are glycosylphosphatidylinositol (GPI) anchored. We expressed a cytoplasmic glycosylphosphatidylinositol phospholipase C (GPI-PLC) in L. major in order to examine the topography of the protein-GPI and polysaccharide-GPI pathways. In L. major cells expressing GPI-PLC, cell-associated gp63 could not be detected in immunoblots. Pulse-chase analysis revealed that gp63 was secreted into the culture medium with a half-time of 5.5 h. Secreted gp63 lacked anti-cross reacting determinant epitopes, and was not metabolically labeled with [3H]ethanolamine, indicating that it never received a GPI anchor. Further, the quantity of putative protein-GPI intermediates decreased approximately 10-fold. In striking contrast, lipophosphoglycan levels were unaltered. However, GPI-PLC cleaved polysaccharide-GPI intermediates (glycoinositol phospholipids) in vitro. Thus, reactions specific to the polysaccharide-GPI pathway are compartmentalized in vivo within the endoplasmic reticulum, thereby sequestering polysaccharide-GPI intermediates from GPI-PLC cleavage. On the contrary, protein-GPI synthesis at least up to production of Man(1 alpha 6)Man(1 alpha 4)GlcN-(1 alpha 6)-myo-inositol-1-phospholipid is cytosolic. To our knowledge this represents the first use of a catabolic enzyme in vivo to elucidate the topography of biosynthetic pathways. GPI-PLC causes a protein-GPI-negative phenotype in L. major, even when genes for GPI biosynthesis are functional. This phenotype is remarkably similar to that of some GPI mutants of mammalian cells: implications for paroxysmal nocturnal hemoglobinuria and Thy-1-negative T-lymphoma are discussed.

Biochemical analysis of the membrane and soluble forms of the complement regulatory protein of Trypanosoma cruzi

A developmentally regulated, 160-kDa trypomastigote surface glycoprotein was previously shown to bind the third component of complement and to inhibit activation of the alternative complement pathway, thus providing the parasites a means of avoiding the lytic effects of complement. We now show that this complement regulatory protein (CRP) binds human C4b, a component of the classical pathway C3 convertase, and may therefore also act to restrict classical complement activation. Characterization of the extent of carbohydrate modification of the protein revealed extensive N-linked glycosylation and no apparent O-linked sugars. The CRP purified from parasites treated with an inhibitor of N-linked glycosylation exhibited a decreased binding affinity for C3b compared with that of the fully glycosylated protein. We have previously shown that the protein was anchored to the membrane via a glycosyl phosphatidylinositol linkage and was spontaneously shed from the parasite surface. The spontaneous release of CRP from the parasite surface may augment the protection of the parasites from complement-mediated lysis by the removal of complement-CRP complexes. The majority of the shed CRP had an apparent molecular mass of 160 kDa and lacked the glycolipid anchor, whereas the membrane form was recovered with the glycolipid anchor attached and had an apparent molecular mass of 185 kDa. Both the membrane form (185 kDa) and the soluble form (160 kDa) retained binding affinity for C3b. Evidence is presented to indicate that the conversion of the 185-kDa membrane form to the 160-kDa form is the result of cleavage by an endogenous phospholipase C.

Phase separation of biomolecules in polyoxyethylene glycol nonionic detergents

The advantage of aqueous two-phase systems based on polyoxyethylene detergents over other liquid-liquid two-phase systems lies in their capacity to fractionate membrane proteins simply by heating the solution over a biocompatible range of temperatures (20 to 37 degrees C). This permits the peripheral membrane proteins to be effectively separated from the integral membrane proteins, which remain in the detergent-rich phase due to the interaction of their hydrophobic domains with detergent micelles. Since the first reports of this special characteristic of polyoxyethylene glycol detergents in 1981, numerous reports have consolidated this procedure as a fundamental technique in membrane biochemistry and molecular biology. As examples of their use in these two fields, this review summarizes the studies carried out on the topology, diversity, and anomalous behavior of transmembrane proteins on the distribution of glycosyl-phosphatidylinositol-anchored membrane proteins, and on a mechanism to describe the pH-induced translocation of viruses, bacterial endotoxins, and soluble cytoplasmic proteins related to membrane fusion. In addition, the phase separation capacity of these polyoxyethylene glycol detergents has been used to develop quick fractionation methods with high recoveries, on both a micro- and macroscale, and to speed up or increase the efficiency of bioanalytical assays.

The lysosomal gp63-related protein in Leishmania mexicana amastigotes is a soluble metalloproteinase with an acidic pH optimum

Leishmania mexicana amastigotes express a lysosomal protein, which is antigenically related to the promastigote surface metalloproteinase (gp63). It is shown that the purified gp63-related protein from amastigote is also an active metalloproteinase. The pH-optimum of the enzyme is acidic, similar to lysosomal cysteine proteinases, but distinct from the neutral to basic pH-optimum of the promastigote surface proteinase. This study appears to be the first report on a metalloproteinase with a lysosomal localization.

Chitin: a cell-surface component of Phytomonas françai

The occurrence of chitin as a structural component of the surface of the phytopathogenic protozoan Phytomonas françai was demonstrated by paper and gas-liquid chromatographic analysis of the products of enzymatic and chemical hydrolysis of alkali-resistant polysaccharides, lectin binding, glycosidase digestion, and infrared spectra. Chitin was characterized by its insolubility in hot alkali and chromatographic immobility as well as by the release of glucosamine on hydrolysis with strong acid and of N-acetylglucosamine (GlcNAc) on hydrolysis with chitinase. The presence of chitin was also shown directly by binding of wheat-germ agglutinin (WGA), which recognizes GlcNAc units, to the parasite surface. Fluorescein-labeled WGA binding was completely abolished by treatment with chitinase. This effect was specific since it could be prevented by incubating the enzyme with chitin before treatment of the phytomonads. These findings indicate that chitin is an exposed cell-surface polysaccharide in Phytomonas françai. The data were confirmed by the infrared spectrum of an alkali-insoluble residue, which showed a pattern typical of chitin.

Membrane insertion and antibody recognition of a glycosylphosphatidylinositol-anchored protein: an optical study

The kinetics of binding of a glycolipid-anchored protein (the promastigote surface protease, PSP) to planar lecithin bilayers is studied by an integrated optics technique, in which the bilayer membrane is supported on an optical wave guide and the phase velocities of guided light modes in the wave guide are measured. From these velocities, the optical parameters of the membrane and PSP layers deposited on the waveguide are determined, yielding in particular the mass of PSP bound to the membrane, which is followed in real time. From a comparison of the binding rates of PSP and PSP from which the lipid moiety has been removed, it is shown that the lipid moiety plays a key role in anchoring the protein to the membrane. Specific and nonspecific binding of antibodies to membrane-anchored PSP is also investigated. As little as a fifth of a monolayer of PSP is sufficient to suppress the appreciable nonspecific binding of antibodies to the membrane.

Isolation and characterization of a novel glycosyl-phosphatidylinositol-anchored glycoconjugate expressed by developing neurons

In search of new markers for studying thymic and nervous system ontogeny, we raised rat monoclonal antibodies against glycosyl-phosphatidylinositol-anchored molecules among which larger groupings have been shown to be ectoenzymes and adhesion molecules. Two of these monoclonal antibodies (H193-4 and H194-563, IgG) were found to recognize glycosyl-phosphatidylinositol-anchored glycoconjugates of 28-33 kDa (P31) and 50-70 kDa in developing mouse brain and thymus respectively, when these tissues were analysed by immunoblot experiments. P31 antigen was found to be transiently expressed by neurons in neural primary cultures [Rougon, G., Alterman, L., Dennis, K., Guo, X. J. & Kinnon, K. (1991) Eur. J. Immunol. 21, 1397-1402]. We show in this report that, in developing mouse brain, a maximal expression occurred between embryonic day 17 and post-natal day 5, a period that corresponds to the formation of neuronal networks. P31 antigen was immunopurified and found to possess the following properties: (a) it was soluble in alkaline solvents; (b) it bound to DEAE-cellulose and was eluted by a salt gradient of 0-1 M NaCl; (c) it was sensitive to endoglycosidase F digestion; (d) it was insensitive to heparinase, hyaluronidase, chondroitinase ABC, endo-beta-galactosidase and sialidase treatment; (e) it was labile to mild acid hydrolysis without loss of immunoreactivity; (f) it contained phosphate; (g) it lost its immunoreactivity after treatment with phosphatidylinositol phospholipase C and treatment. These characteristics combine to suggest that P31 is an anionic glycoconjugate sharing similarities with Leishmania donovani lipophosphoglycan and with the heat-stable antigen recognized by J11d antibody on murine hematopoïetic cells. This last hypothesis was further confirmed by the observation that oligonucleotide probes derived from the heat-stable antigen-encoding cDNA detect, in developing brain, a 1.8-kb mRNA species similar in size to that reported for the heat-stable antigen mRNA and following the same developmental expression as P31 antigen.

Structural analysis of a glycosylphosphatidylinositol glycolipid of Leishmania donovani

A glycosylphosphatidylinositol (GPI) glycolipid antigen recognized by sera from patients with visceral leishmaniasis was isolated from Leishmania donovani promastigotes. The carbohydrate moiety was cleaved from the lipid part by digestion with specific phosphatidylinositol phospholipase C. After separation, structural analysis was carried out on the phosphorylated inositol oligosaccharide and the alkylacyl glycerol. The following major structures were found: [formula: see text] The presence of the conserved sequence Man alpha 1-2Man alpha 1-6Man alpha 1-4GlcN-PI of glycosyl phosphatidylinositol protein anchors in this antigen may be consistent with a precursor role of Leishmania glycosyl phosphatidylinositol anchored proteins for this glycolipid.

Characterization of a glycosyl-phosphatidylinositol-anchored membrane protein from Trypanosoma cruzi

Four monoclonal antibodies (MAbs) specific for Trypanosoma cruzi were obtained. Flow cytometry analysis showed that these four MAbs stained the membranes of the three main morphological forms of T. cruzi: amastigotes, trypomastigotes, and epimastigotes. The four MAbs seemed to recognize the same 50- to 55-kDa antigen that was revealed by immunoblotting. Competition experiments revealed that they defined at least two different epitopes on the molecule. The antigen was detected on the external surface of the membrane by immunoelectron microscopy. Several experiments indicated that the 50- to 55-kDa antigen recognized by these four MAbs was a glycosyl-phosphatidylinositol-anchored membrane protein. (i) The antigen could be removed from the cell surface by treatment with proteases, NaOH, HNO2, and phosphatidylinositol-specific phospholipase C (PI-PLC). (ii) The phase distribution of the antigen in Triton X-114 solutions changed drastically upon treatment with PI-PLC. The antigen was found mainly in the detergent phase in nontreated samples and in the aqueous phase in PI-PLC-digested samples. (iii) A cross-reacting determinant that was found in other glycosyl-phosphatidylinositol-anchored membrane proteins appeared after PI-PLC treatment.

Molecular cloning and characterization of the immunologically protective surface glycoprotein GP46/M-2 of Leishmania amazonensis

Immunization of mice with the GP46/M-2 membrane glycoprotein has been demonstrated to elicit protection against infection with the parasitic protozoan Leishmania amazonensis. As this molecule is important for future vaccine studies of leishmaniasis, the gene encoding the GP46/M-2 surface membrane glycoprotein of Leishmania amazonensis has been cloned and sequenced. The protein sequence derived from the DNA sequence data is consistent with the known biochemical and immunochemical properties of the protein and indicates a number of structural areas of interest. A repetitive sequence (24 amino acids repeated four times) occurs within the amino-terminal portion of the molecule and constitutes approximately 22% of the total mature protein. The protease-resistant immunodominant carboxyl-terminal domain of the protein comprises approximately half of the molecule and consists of proline-rich and cysteine-rich areas of sequence; the distribution of cysteine residues is suggestive of metal binding motifs. The sequence predicts a hydrophobic leader peptide, and a putative attachment site for a glycosyl-phosphatidylinositol anchor is indicated at the carboxyl terminus, consistent with the membrane location of the protein. Southern blot analyses also indicate the presence of a GP46/M-2 gene family.

Characterization of Leishmania major antigen-liposomes that protect BALB/c mice against cutaneous leishmaniasis

Leishmania major antigen-liposomes prepared as dehydration-rehydration vesicles (DRV) and composed of equimolar amounts of L-alpha-distearoyl phosphatidylcholine and cholesterol confer high-level host-protective immunity against virulent homologous challenge to susceptible BALB/c mice. Physical and antigenic characterization of these protective liposomes is described. Both empty and L. major antigen-DRV were multilamellate and heterogeneous in size, ranging from 0.10 to 2.00 microns. Although the liposomes were made by using a crude mixture of promastigote antigens, lipophosphoglycan covered the liposome surface; this was demonstrated by immunogold electron microscopy. Application of sodium dodecyl sulfate-polyacrylamide gel electrophoresis and Western blot (immunoblot) analysis revealed preferential entrapment of the 63-kilodalton promastigote protease (gp63) into the DRV. We suggest that our L. major antigen-DRV merit further study because of their preferential entrapment of these two host protective antigens together with their long in vivo half-life. In addition, this report illustrates that intravenous or subcutaneous immunization of BALB/c mice with the same limited subset of protective antigens, predominantly lipophosphoglycan and gp63, within DRV liposomes leads to either protection and low splenic interleukin-3 production or to nonprotection and high splenic interleukin-3 production, respectively. This was consistent with our hypothesis that differential antigen presentation after administration of the same immunogen by the intravenous or the subcutaneous route results in differential T-cell activation.

A galactosyl(alpha 1-3)mannose epitope on phospholipids of Leishmania mexicana and L. braziliensis is recognized by trypanosomatid-infected human sera

An immunoglobulin M antibody reactive with galactosyl(alpha 1-3)mannose [Gal(alpha 1-3)Man] residues present on phospholipids extracted from Leishmania mexicana and L. braziliensis was found to be present in high titer in the serum of every normal individual studied. Periodate oxidation, acid hydrolysis, or acetylation suppressed immunoreactivity, suggesting that an oligosaccharide chain was responsible for antibody binding. Interaction occurs only with alpha-Gal terminal residues, since treatment of purified glycophospholipids with alpha-galactosidase but not with beta-galactosidase abolished it. Antibody bound to galactosyl(alpha 1-3)galactose-linked synthetic antigens but did not bind to the same residues present in rabbit, rat, and guinea pig erythrocytes or in murine laminin. Antigen-antibody binding was strongly blocked with Gal(alpha 1-3)Man and Gal(beta 1-4)Man. These results plus inhibition studies with several oligosaccharides suggest that they are indeed different from antibodies against the galactosyl(alpha 1-3)galactose residue. Anti-Gal(alpha 1-3)Man antibody values were significantly elevated in 89% of patients with diffuse cutaneous leishmaniasis, 84% of patients with localized cutaneous leishmaniasis, 69% of patients with mucocutaneous leishmaniasis, and 44 and 62% of patients with Trypanosoma cruzi or T. rangeli infection, respectively, but not in patients with 15 other different infectious and inflammatory diseases. Anti-Gal(alpha 1-3)Man antibody readily absorbed to American Leishmania and Trypanosoma culture forms, suggesting a surface membrane localization of reactive epitope. Gal(alpha 1-3)Man-bearing glycophospholipid was easily extracted from American Leishmania promastigotes and T. cruzi trypomastigotes as well as from American Trypanosoma culture forms. The possibility that this antibody arises against parasitic glycophospholipid-linked Gal(alpha 1-3)Man terminal residues is proposed.

Evidence for glycosyl-phosphatidylinositol anchoring of Toxoplasma gondii major surface antigens

The four major surface antigens of Toxoplasma gondii tachyzoites (P43, P35, P30, and P22) were made water soluble by phosphatidylinositol-specific phospholipase C (PI-PLC). These antigens were biosynthetically labeled with 3H-fatty acids, [3H]ethanolamine, and [3H]carbohydrates. Treatment of 3H-fatty-acid-labeled parasite lysates with PI-PLC removed the radioactive label from these antigens. A cross-reacting determinant was exposed on these antigens after PI-PLC treatment.

Evidence of T-cell recognition in mice of a purified lipophosphoglycan from Leishmania major

We have previously reported that a Leishmania major lipophosphoglycan (LPG), given with killed Corynebacterium parvum as an adjuvant, can vaccinate mice against cutaneous leishmaniasis. In order to analyze whether T cells are able to recognize this important parasite antigen, we have studied both humoral and cellular immune responses to L. major LPG that had been isolated from promastigotes by sequential solvent extraction and hydrophobic chromatography. The data show that immunization of mice with highly purified LPG induced an increase in frequency of L. major-reactive T cells and the production of immunoglobulin G antibodies to LPG. Furthermore, genetically resistant mice infected with L. major were able to develop a specific delayed-type hypersensitivity response in the ear to L. major LPG. These findings strongly suggest that T cells can recognize and respond to glycolipid antigens, in this case a host-protective Leishmania LPG, even though such antigens appear not to be potent T-cell stimulators in mice.

Evidence for glycosyl-phosphatidylinositol anchoring of Toxoplasma gondii major surface antigens

The four major surface antigens of Toxoplasma gondii tachyzoites (P43, P35, P30, and P22) were made water soluble by phosphatidylinositol-specific phospholipase C (PI-PLC). These antigens were biosynthetically labeled with 3H-fatty acids, [3H]ethanolamine, and [3H]carbohydrates. Treatment of 3H-fatty-acid-labeled parasite lysates with PI-PLC removed the radioactive label from these antigens. A cross-reacting determinant was exposed on these antigens after PI-PLC treatment.