Leishmania gp63 molecule implicated in cellular adhesion lacks an Arg-Gly-Asp sequence

Multiple products of the Leishmania chagasi major surface protease (MSP or GP63) gene family

The major surface protease (MSP or GP63) of the Leishmania spp. protozoa facilitates parasite evasion of complement-mediated killing, phagocytosis by macrophages, and intracellular survival in macrophage phagolysosomes. Immunoblots of several Leishmania species have shown there are distinct MSP isoforms, but the biochemical bases for these differences are unknown. Northern blots show that transcripts of the three tandem gene classes encoding Leishmania chagasi MSP (MSPS, MSPL, MSPC) are differentially expressed during parasite growth in vitro. Cell-associated MSPs increase in abundance during growth, correlating directly with parasite virulence. We examined whether distinct products of these >18 MSP genes are either differentially expressed or differentially processed during parasite growth. Two-dimensional gel electrophoresis and immunoblots delineated more than 10 MSP isoforms in stationary phase L. chagasi, distributed between pIs of 5.2-6.1 and masses of 58-63 kDa. Post-translational modifications including N-glycosylation, GPI anchor addition and phosphorylation did not account for all differences among the isoforms. MALDI-TOF mass spectrometry demonstrated that at least some L. chagasi MSPs were the products of different MSP genes. One isoform was not available for surface biotinylation, suggesting it could be located internally. Parasites in logarithmic growth expressed only four MSP isoforms, and an attenuated strain of L. chagasi (L5) did not express one of the MSP classes (MSPS). These data demonstrate that the products of individual MSP genes are differentially expressed during Leishmania development. We hypothesize they may play different roles during parasite migration through its two hosts.

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.

Leishmania: fine mapping of the Leishmanolysin molecule's conserved core domains involved in binding and internalization

The Leishmanolysin molecule's role in the uptake of Leishmania parasites by the human U937 pro-myelocytic cell line was studied, using synthetic peptides representing the complete Leishmania (Viannia) guyanensis Leishmanolysin protein amino acid sequence. The particular peptides present in two protein's core domains efficiently impaired the internalization of promastigotes from four different Leishmania species and modified the kinetics of the binding of heterologous recombinant Leishmanolysin protein. The functional domains which exhibited this property represent a highly conserved portion of the sequence among different Leishmania species. The peptides' inhibitory activity correlated with their ability to bind molecules present on the surface of the human cell line. One of the two functional core domains identified involves the previously described adhesive sequence (SRYD) and the putative zinc-binding motif (HExxH). The second functional core domain includes a third histidine residue coordinated with zinc which determines the molecule's structural features. These findings indicate that the molecular interactions between Leishmanolysin's conserved domains and the macrophage surface molecules efficiently contribute to the parasite's internalization. Induction of neutralizing immune responses, which impair the early parasite-host interaction described here, may be an important alternative in designing synthetic subunit human leishmaniasis vaccines.

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.

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.

A unique, terminally glucosylated oligosaccharide is a common feature on Leishmania cell surfaces

The structures of N-linked oligosaccharides from various Leishmania life-cycle stages and species have been investigated in order to elucidate differences which may be correlated with virulence or tissue tropisms. The structure of gp63 glycans from L major log- and stationary-phase promastigotes were elucidated and compared with the total membrane associated oligosaccharides from five Leishmania spp. L. major gp63 glycans from promastigotes in either log or stationary phases of their growth cycle were shown to have two neutral oligosaccharides having Bio-Gel P4 hydrodynamic volumes of 10.5 and 9.6 glucose units (GU). Sequential exoglycosidase digestion, fragmentation by acetolysis and methylation analysis of hydrazine released glycans, revealed the structure of G9.6 to be a biantennary oligomannose type, having the composition Man6GlcNAc2. These data were confirmed by structural analysis of gp63 oligosaccharides released by digestion with endo-beta-N-acetylglucosaminidase H (Endo-H) and N-glycanase F. The larger glycan was found to be terminally glucosylated, having the composition GlcMan6GlcNAc2. These oligosaccharides were found to occupy only two of the three predicted N-linked glycosylation sites in the L. major gp63 molecule, at positions 300 and 407. On comparison with glycans from other Leishmania spp. and strains, these two oligosaccharides were consistently found to be the predominant promastigote structures. Following transformation to the amastigote stage, alterations in N-linked oligosaccharides appeared to be less consistent between species. L. m. mexicana amastigotes were found to display the same G10.5 and G9.6 glycans found on promastigotes while L. donovani LV9 amastigotes were found to be devoid of N-linked glycans.

Surface Zn-proteinase as a molecule for defense of Leishmania mexicana amazonensis promastigotes against cytolysis inside macrophage phagolysosomes

The role of the surface membrane Zn-proteinase in protecting the cellular integrity of the macrophage parasite Leishmania mexicana amazonensis from intraphagolysosomal cytolysis was studied. These cells lose their infectivity to host macrophages after prolonged cultivation in axenic growth medium. The virulent and attenuated variants of the parasite cells were cloned. Failure of these attenuated parasite cells to survive inside macrophage phagolysosomes is associated with 20- to 50-fold reduction in the expression of surface gp63 protein. In situ inhibition of gp63 proteinase activity inside Leishmania-infected macrophage phagolysosomes with targeted delivery of an inhibitor of gp63 proteinase activity, 1,10-phenanthroline, selectively eliminated intracellular Leishmania amastigotes, further suggesting the importance of this proteinase in phagolysosomal survival of the parasite. An upstream sequence (US) of the gp63 gene was cloned in front of the bacterial chloramphenicol acetyltransferase (CAT) gene in plasmid pCATbasic. Transfection of L. mexicana amazonensis cells with this recombinant plasmid showed that expression of the CAT gene from this US is 15- to 20-fold higher in virulent clones than in avirulent clones of the parasite. Band shift analysis with the cloned US also showed that binding of protein(s) was 15- to 20-fold higher in virulent cell extract than in avirulent cell extract. Coating of attenuated cells or liposomes with proteolytically active gp63 protects them from degradation inside macrophage phagolysosomes. These results suggest a novel mechanism of survival of this phagolysosomal parasite with the help of its surface Zn-proteinase.

Identification of a fibronectin-like molecule on the surface of Leishmania amastigotes

The major surface glycoprotein of Leishmania gp63, a fibronectin-like molecule, plays a key role in parasite-macrophage interaction. In this article, we describe a cross-reactivity between an anti-fibronectin monoclonal antibody and the amastigote gp63 by means of immunoelectron microscopy and immunoblot. Immunoreactivity was found on the amastigote membrane and in the flagellar pocket. We suggest that gp63 may play a role in the protection and/or nutrition process of the parasite in the phagolysosomes of the macrophage.

Leishmania mexicana amazonensis: differential display analysis and cloning of mRNAs from attenuated and infective forms

The virulence of Leishmania mexicana is determined by the concerted action of several parasite molecules. These cells lose their infectivity to host macrophages after prolonged cultivation in axenic growth media. Both virulent and attenuated variants of the parasite cells were cloned. The differential display reverse transcription-polymerase chain reaction technique was employed to understand whether this natural attenuation of the parasite cells is accompanied by differential expression of selected genes in those cells. Twelve different dinucleotide-anchored oligo(dT) antisense primers were used to make cDNAs from poly(A)+ mRNAs isolated from a clonal population of virulent and avirulent cells following a protocol optimized for Leishmania mRNAs. Those cDNAs were subjected to amplifications using each of the three different arbitrary decanucleotide primers and the corresponding anchored oligo(dT) primer. This procedure revealed four virulent-specific cDNA probes and one avirulent-specific cDNA probe. Differential expressions of these genes were confirmed by northern hybridization using the cloned cDNA probes. These results indicate that differential expression of genes may be the key in determining the molecular basis of leishmanial virulence.

Posttranslational regulation of a Leishmania HEXXH metalloprotease (gp63). The effects of site-specific mutagenesis of catalytic, zinc binding, N-glycosylation, and glycosyl phosphatidylinositol addition sites on N-terminal end cleavage, intracellular stability, and extracellular exit

Leishmanolysin (EC 3.4.24.36) (gp63) is a HEXXH metalloprotease, encoded by multicopied genes in Leishmania and implicated in the infectivity of these parasitic protozoa. We examined posttranslational regulation of gp63 expression by site-specific mutagenesis of the predicted catalytic/zinc-binding sites in the H264EXXH motif, the potential sites of N-glycosylation and glycosyl phosphatidylinositol addition. Mutant and wild-type genes were cloned into a Leishmania-specific vector for transfecting a deficient variant, which produced gp63 approximately 20-fold less than wild-type cells. The selective conditions chosen fully restored this deficiency in transfectants with the wild-type gene. Under these conditions, all transfectants were found comparable in both the plasmid copy number per cell and elevation of gp63 transcripts. Mutant and wild-type products in the transfectants were then compared quantitatively and qualitatively by specific immunologic and protease assays. The results indicate the following. 1) Glu-265 in the HEXXH motif is indispensable for the catalytic activity of gp63. The propeptide of the inactive mutant products was cleaved, suggestive of a non-intramolecular event. 2) Substitution of either His residue in HEXXH leads to apparent intracellular degradation of the mutant products, pointing to a role for zinc binding in in vivo stability of gp63. 3) The three potential sites of N-glycosylation at Asn-300, Asn-407, and Asn-534 are all utilized and contribute to intracellular stability of gp63. 4) Substitution of Asn-577 causes release of all mutant products, indicative of its specificity as a glycosyl phosphatidylinositol addition site for membrane anchoring of gp63. It is suggested that expression of gp63 as a functional protease is regulated by these posttranslational modification pathways.

Extensive polymorphism at the Gp63 locus in field isolates of Leishmania peruviana

Genetic diversity within and between tandemly arrayed copies of the Gp63 gene occurs in laboratory isolates of Leishmania spp., but the extent to which this represents natural genetic diversity has not been assessed. Here, the Gp63 locus is examined in 58 fresh isolates of L. peruviana, and clones derived from them, collected throughout the Peruvian Andes. Extensive polymorphism is observed, both in size of Gp63 containing chromosomes, and for restriction-fragment-length polymorphisms (RFLPs) at the Gp63 locus. All clones within an isolate are identical, including those with two distinct Gp63-hybridising chromosomal-sized pulsed-field gel electrophoresis (PFGE) bands, consistent with diploidy but with size differences in homologous chromosomes. For RFLP analysis, three enzymes were selected to cut within the coding region (PstI), in the intergenic region (SalI) and outside (EcoRI) the Gp63 gene cluster. PstI gave identical banding patterns across all isolates/clones. For EcoRI and SalI, all clones within an isolate were identical, but isolates were polymorphic for fragments at 13 (2-30 kb) and 8 (2.6-8.8 kb) different molecular mass locations generating 19 and 16 distinct RFLP patterns or genotypes for each enzyme, respectively. EcoRI restriction patterns, analysed by PFGE, were consistent with the presence of two clusters of Gp63 genes on each homologous chromosome, one contained within EcoRI fragments large enough to carry from 3 to 10 copies of the Gp63 gene, the second on fragments which could carry 1 or 2 copies of the gene. SalI patterns indicated variable restriction sites within clusters, but not within every intergenic region. A hierarchical analysis of variance of allele frequencies, expressed in terms of Wright's F-statistic, indicated significant barriers to gene flow at all levels, valleys within regions (north/south), villages within valleys, and individuals within villages. This extreme polymorphism at the Gp63 locus of L. peruviana demonstrates the great potential for generation of genetic diversity in parasite populations.

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.

Mutational and functional analysis of the Leishmania surface metalloproteinase GP63: similarities to matrix metalloproteinases

The major surface glycoprotein of Leishmania, referred to as GP63, is a zinc metalloproteinase of 63,000 M(r) present on promastigotes and amastigotes from diverse species of Leishmania. GP63 shares several characteristics with the members of the matrix metalloproteinase family including degradation of at least one component of the extracellular matrix, location at the cell surface, requirement for Zn2+ for proteinase activity and inhibition of the proteinase activity by chelating agents and alpha 2-macroglobulin. Site-directed mutagenesis of the cloned L. major GP63 genes was carried out to determine whether the proposed active site of Leishmania GP63 was homologous to those of other zinc metalloproteinases. The codon encoding the catalytic glutamic acid was modified to encode an aspartic acid and when expressed in COS-7 cells the resulting mutant GP63 had no demonstrable proteinase activity compared to wild type GP63. GP63 was predicted to be synthesized as a precursor protein containing a pro region at the NH2-terminus of GP63 implicated to be involved with the regulation of proteinase activity. As with many other proteinases, including matrix metalloproteinases, these enzymes are synthesized as latent proteinases that require activation for full proteinase activity. L. major recombinant GP63 (rGP63) has been produced in the baculovirus expression system where rGP63 was secreted as a latent proteinase. To study the activation of baculovirus rGP63, purified rGP63 was incubated with the mercurial compound, HgCl2, at concentrations previously shown to result in activation of other latent matrix degrading metalloproteinases and resulted in a significant enhancement of GP63 proteinase activity.(ABSTRACT TRUNCATED AT 250 WORDS)

Leishmania major HEXBP deletion mutants generated by double targeted gene replacement

The Leishmania major single-stranded DNA binding protein HEXBP contains nine 'CCHC' zinc finger motifs and binds to oligodeoxynucleotides derived from the antisense strand of the GP63 gene 5' flanking region in gel mobility shift assays and UV-crosslinking assays. In the present study a HEXBP-deficient clone of L. major was generated by double targeted gene replacement. The two HEXBP alleles were sequentially replaced with genes encoding resistance to the aminoglycoside antibiotics hygromycin B and G418 and drug-resistant clones were selected by plating on semi-solid drug-containing media. Successful deletion of both copies of the HEXBP gene implies that HEXBP is a not essential for growth of Leishmania promastigotes. Characterization HEXBP-deficient promastigotes revealed that HEXBP deficiency had no effect on the abundance of GP63 mRNA and protein in in vitro cultivated promastigotes and that HEXBP-deficient promastigotes were capable of lesion formation in BALB/c mice.

An investigation into the significance of the N-linked oligosaccharides of Leishmania gp63

Leishmania major promastigotes, when grown in the presence of tunicamycin (TM), produced a plasma membrane-bound, proteolytically active gp63 with a lower molecular weight than the native glycoprotein. However, this lower molecular weight form of gp63 continued to be recognized by concanavalin A (Con A), suggesting that inhibition of N-linked glycosylation was not complete. Metabolic labeling of gp63, using [35S]methionine, demonstrated that in the range of 5-10 micrograms ml-1 TM, only the lower molecular weight form was synthesized, suggesting that inhibition was complete and that lectin binding was likely due to the GPI anchored sugars. Removal of the oligosaccharides from L. major and L. mexicana amazonensis promastigotes using endoglycosidase F, caused the gp63 molecular weight to decrease to the same value observed in the presence of TM, once again without affecting the proteolytic activity. However, this deglycosylated enzyme continued to bind Con A until subsequently treated with periodate. The latter oxidation reaction resulted in complete loss of Con A binding without inhibiting the protease activity or the substrate specificity of gp63. Further investigations revealed that both glycosylated and deglycosylated gp63 were resistant to proteolytic digestion by either autolysis or cathepsin D. These findings indicate that the N-linked oligosaccharides of gp63 are not essential for folding, transport, maintenance of enzyme activity or resistance to proteolysis.

Sequence diversity and organization of the msp gene family encoding gp63 of Leishmania chagasi

During in vitro growth Leishmania chagasi promastigotes differentially express 3 classes of RNAs encoding the major surface protease (MSP) gp63 that can be distinguished by their unique 3' untranslated regions. Here we show that the three classes (logarithmic-specific, stationary-specific and constitutively expressed) are encoded by a family of at least 4 tandem stationary genes (mspS2, mspS1, mspS3 and mspS5) followed by twelve or more logarithmic genes (mspL genes), one constitutive gene (mspC) and a final stationary gene (mspS4). Some of the stationary genes can be distinguished from each other by groups of nucleotide differences within the coding regions that result in localized amino acid differences. Northern blots confirm that RNAs from the individual stationary genes are present in stationary, but not logarithmic, phase promastigotes. Western blots using sera directed against synthetic peptides indicate that correspondingly heterogeneous gp63 proteins are expressed in L. chagasi promastigotes. A 200-bp region upstream of all three gp63 gene classes is conserved except for a variable number of 6-bp repeats. Downstream of the gp63 coding regions are highly conserved, class-specific sequences that include the 3' untranslated regions and extend past the polyadenylation site for 65 bp (mspL), 345 bp (mspC) or 2.8 kb (mspS). These sequence features flanking the msp coding regions are likely important in the growth phase-specific expression of the three gp63 RNA classes.

Sequence heterogeneity and polymorphic gene arrangements of the Leishmania guyanensis gp63 genes

The Leishmania GP63 major surface protein gene family encodes multiple isoforms which differ predominantly in the carboxyterminal region. We have isolated 4 full-length gp63 cDNA clones derived from stationary-phase promastigote RNA of a cloned isolate of Leishmania guyanensis, a member of the braziliensis complex. These genes, along with the previously published L. guyanensis gp63 gene sequence [15], appeared to be mosaics of different combinations of 5' and 3' untranslated regions and sequences encoding the propeptide, internal, and C-terminal regions of GP63. The predicted L. guyanensis GP63 isoforms shared as little as 55% sequence identity, comparable to the inter-species diversity of GP63. The genomic organization of gp63 genes in L. guyanensis is highly complex: there are at least 4 distinct polymorphic forms of tandemly linked gene clusters, with intra-gene cluster variation in gene sequence and in the number of gene repeats. Southern blot analysis suggested that the arrangement of gp63 genes in this L. guyanensis isolate did not differ from that in the parental lines.

Mutational analysis of a signal sequence required for protein secretion in Leishmania major

In eukaryotes, amino-terminal extensions, signal sequences, mediate the translocation of lysosomal, membrane and secreted proteins into the lumen of the endoplasmic reticulum (ER). Structure/function studies indicate that eukaryotic signal sequences are composed of 3 distinct domains, a positively charged amino-terminal domain, a central hydrophobic domain, and a polar carboxy-terminal domain. In an attempt to better understand protein trafficking in Leishmania we have constructed strains of Leishmania major that secrete an exogenous protein, interferon-gamma (IFN-gamma), under the control of a mammalian signal sequence. In this report we present a mutational analysis of this signal sequence. Deletion of the entire signal sequence or the hydrophobic core region prevents secretion of IFN-gamma and results in cytoplasmic expression of the protein. Mutations in the amino-terminal domain indicate that a net positive charge is not required for efficient secretion of IFN-gamma. Mutations in the carboxy-terminal domain are more complex and display two phenotypes, either they prevent expression of IFN-gamma or they have no effect on protein secretion. These results indicate that the function of the signal sequence in targeting proteins to the ER in Leishmania is similar to that observed in yeasts and higher eukaryotes and suggests that the Leishmania protein secretory apparatus may also be similar.

Recombinant Leishmania surface glycoprotein GP63 is secreted in the baculovirus expression system as a latent metalloproteinase

A gene encoding the Leishmania surface metalloproteinase, GP63, was modified using the polymerase chain reaction to obtain effective secretion of recombinant GP63 (reGP63) in the baculovirus insect cell expression system. The coding region for the N-terminal signal peptide (SP) of GP63 was modified to resemble the SP for the GP67 envelope protein from the budded virus form of Autographa californica nuclear polyhedrosis virus. To prevent processing at the C-terminus with a glycosyl phosphatidylinositol anchor and the subsequent membrane anchoring of reGP63 in insect cells, the coding region for a putative SP at the C-terminus of GP63 was deleted. The reGP63 protein was glycosylated and secreted as a latent metalloproteinase in the baculovirus expression system. The reGP63 protein was purified from serum-free medium using concanavalin A lectin affinity chromatography, with a yield of 1 mg/l. The purified Leishmania reGP63 was secreted as a latent proteinase. Treatment of reGP63 with HgCl2 resulted in activation of full proteinase activity and a concomitant decrease in M(r). The mechanism of the activation of Leishmania reGP63 is consistent with that of other members of the family of matrix-degrading metalloproteinases.

Molecular variation in Leishmania

The surface coat of the protozoan parasite Leishmania affords remarkable protection in the harsh environments encountered within the insect vectors and vertebrate hosts. It also provides specificity for the interaction of these parasites with the cells in the sandfly gut and with the human macrophage. Surprisingly few molecules have been identified on the Leishmania surface. The major surface molecules of both promastigotes and amastigotes are the glycoconjugates lipophosphoglycan and a glycoprotein of approximately 63 kDa. These major surface molecules vary structurally between Leishmania species and throughout the life-cycle of the parasite. In addition to these major glycoconjugates, Leishmania produce a number of less abundant surface molecules, including a family of glycosyl-inositol phospholipids, the Promastigote Surface Antigen-2 complex of glycoproteins and a glycoprotein of M(r) 46,000. These molecules share the common feature of attachment to the plasma membrane via glycosylphosphatidylinositol lipid anchors. Leishmania also release molecules from their surface in a species specific manner. In this review we will examine the molecular variation of these molecules and their biological importance. We will also discuss the potential of these molecules as targets for chemotherapy and as candidate vaccines.

Structurally distinct genes for the surface protease of Leishmania mexicana are developmentally regulated

gp63 is a highly abundant glycosylphosphatidylinositol (GPI)-anchored membrane protein expressed in both the promastigote and the amastigote forms of Leishmania species. In Leishmania mexicana, gp63 exists as a heterogeneous family of proteins that are differentially processed and localized during the 2 developmental stages. In this study we determined the molecular organization of the L. mexicana gp63 gene family, demonstrating that the gp63 genes fall into 3 linked families of tandemly repeated, but structurally distinct, entities designated as C1, C2 and C3. The C1 and C2 gene clusters contain 4-5 copies each, while the C3 gene may be single copy. Whilst promastigotes contain transcripts from all 3 gene classes, the intracellular amastigote only expresses detectable transcript from the C1 gene class. Moreover, the sequence of the C1 genes predicts a unique carboxy terminus substantially different from the GPI anchor addition signal sequence found in other Leishmania spp. and which has characteristics incompatible with substitution with a GPI anchor. These findings have significance for both the diversity of gp63 and for the regulation of tightly clustered, tandem gene arrays.

Crithidia fasciculata contains a transcribed leishmanial surface proteinase (gp63) gene homologue

We have cloned and analysed a gene from the insect parasite, Crithidia fasciculata, with homology to the gp63 metalloendoproteinase gene of Leishmania. The Crithidia gene homologue is arranged as a multicopy family comprised of approximately 7 genes. The mature transcript is 4.0 kb. The predicted amino acid sequence has significant homology with Leishmania gp63s, contains a zinc-binding motif and a potential site for addition of a glycosylphosphatidylinositol anchor. Demonstration of a gp63 homologue in C. fasciculata, a monogenetic parasite, suggests that the molecule may play a role in parasite survival within the insect gut.

Leishmania major: differential regulation of the surface metalloprotease in amastigote and promastigote stages

During its life cycle, the protozoan parasite Leishmania major alternates from an intracellular amastigote form in the mammalian host to a flagellated promastigote form in the insect vector. The expression of the surface metalloprotease (PSP) during differentiation in vitro was investigated by Western and Northern blots, by immunoprecipitation of cells metabolically labeled with [35S]methionine or labeled at the surface with radioactive iodine, and by quantification of the proteolytic activity in substrate-containing polyacrylamide gels. We report that the surface metalloprotease is down-regulated at both the mRNA and the protein level in amastigotes, where it represents less than 1% of the equivalent proteolytic activity detected in promastigotes. A significant amount of mRNA is detected 4 hr after the onset of differentiation. The expression of the protease begins at that time and reaches steady state 8 hr later. The synthesis of PSP precedes the complete morphological differentiation to the promastigote stage and the appearance of the lipophosphoglycan, another major promastigote surface component. In contrast to PSP, a family of mercaptoethanol-activated proteases present in the amastigote exists only at a reduced level in the promastigote. The confinement of the surface metalloprotease to the insect stage of the parasite suggests that it has no physiological function in the parasitism maintenance of mammalian host macrophages.

Extrachromosomal genetic complementation of surface metalloproteinase (gp63)-deficient Leishmania increases their binding to macrophages

A major surface glycoprotein of 63 kDa (gp63) has been previously identified biochemically and genetically as a zinc proteinase conserved in pathogenic Leishmania spp. The functional significance of this proteinase was analyzed by genetic approaches. A 15-kilobase DNA with a tunicamycin-resistance gene from Leishmania amazonensis was ligated in two different orientations into pBluescript containing a gp63 gene from Leishmania major. These plasmid constructs were used to transfect a variant of L. amazonensis deficient in gp63 expression. Both constructs were found to confer tunicamycin resistance with equal efficiency and remained structurally unchanged in the transfectants. RNA and immunoblot analyses showed over-expression of gp63 in the transfectants with one of the two plasmids constructed. The over-produced products were enzymatically active and expressed on the cell surface. Significantly, the transfectants with over-expressed gp63 increased by 2-fold over controls in their binding to macrophages. Evidence presented thus indicates that the gp63 gene constructed in the plasmid as described and introduced exogenously expresses in the gp63-deficient variants and that the expressed products are functionally active.

Heterogeneity of the genes encoding the major surface glycoprotein of Leishmania donovani

The major surface glycoprotein of Leishmania (GP63) is present on all known species of Leishmania and likely plays an integral role during the infection of macrophages in the mammalian host. To identify regions of GP63 which may be of functional significance, the nucleotide sequence of a gene encoding GP63 of Leishmania donovani was determined and compared to the sequences reported for GP63 genes of Leishmania major and Leishmania chagasi. The GP63 nucleotide and predicted protein sequence was highly conserved among the 3 species despite their diverse geographical distribution. L. donovani GP63 is encoded by a multigene family and the gene locus contains at least 7 tandemly repeated genes and at least 3 genes which are dispersed from the tandem array. In addition, polymerase chain reaction and Southern blot analyses demonstrated that there was size heterogeneity within the pro-peptide coding regions of the multiple GP63 genes of L. donovani and that such genes were expressed concurrently in the promastigote life stage.

Molecular karyotype and chromosomal localization of genes encoding two major surface glycoproteins, gp63 and gp46/M2, hsp70, and beta-tubulin in cloned strains of several Leishmania species

The molecular karyotypes of several Leishmania isolates (Leishmania amazonensis, Leishmania braziliensis, Leishmania guyanensis, Leishmania panamensis, Leishmania donovani, Leishmania major, Leishmania aethiopica, Leishmania tropica, Leishmania enriettii) have been analyzed by clamped homogeneous electric field (CHEF) gel electrophoresis. The chromosomal localization of genes encoding 2 major surface glycoproteins, gp63 and gp46/M2, heat shock protein 70 (hsp70), and beta-tubulin was determined for cloned isolates of 8 of these Leishmania species. The chromosome size class assignment of hsp70 genes was most conserved in that all species contained a single hybridizing DNA band of approximately 1200 kb. The beta-tubulin gene probe hybridized predominantly to large (1600-1750 kb) chromosome-size DNA and to 1-5 additional bands, the number of which depended on the species. The number and size of DNA bands hybridizing to gp63 or gp46/M2 gene probes were not uniformly conserved among species. In contrast to previous reports of gp63 genes being located on a single chromosome, using various CHEF gel conditions we observed a Leishmania major gp63 gene probe hybridizing to at least 2 chromosomal DNA bands in the New World species and in L. tropica. Gp46/M2 genes were located on 1 band in L. donovani, L. major, and L. aethiopica or 2 bands in L. tropica and L. amazonensis, but surprisingly, do not hybridize to any chromosomal DNA of species in the L. braziliensis complex or in L. enriettii. Whenever both genes were present in a species, gp63 and gp46/M2 genes were located on different chromosomal DNA bands.

Substrate-dependent pH optima of gp63 purified from seven strains of Leishmania

The major surface glycoprotein of Leishmania, gp63, is a membrane-bound metalloprotease. Contradictory data supporting a neutral or acidic nature of this enzyme have been presented. Seven strains of Old and New World Leishmania, including Leishmania donovani complex (Leishmania infantum and L. donovani), Leishmania major, Leishmania tropica and Leishmania mexicana amazonensis were used for the purification and comparative study of gp63. The protein was extracted from promastigotes by phase separation in Triton X-114 and purified by anion exchange chromatography. In agreement with previous reports, all purified gp63 were found to be structurally and immunologically related. Both membrane-bound gp63, on the surface of promastigotes, and the purified proteases had optimal activity at neutral to alkaline pH on azocasein, whereas their activity was optimal at acidic to neutral pH against 125I-insulin B-chain. The IC50 concentrations of 1,10-phenathroline against the two substrates, at the optimal pH, were comparable, suggesting that both activities measured were associated with gp63 rather than another contaminating enzyme. This was further supported by the comparable enrichment values, estimated from the specific activity of the enzyme during purification, using both assays. These results explain the earlier apparent discrepancies and suggest that the optimum pH of gp63 is substrate-dependent and not related to species differences or to the different purification procedures applied.

Identification of a new operon involved in Listeria monocytogenes virulence: its first gene encodes a protein homologous to bacterial metalloproteases

The region flanking the transposon in a Tn1545-induced lecithinase-negative mutant of Listeria monocytogenes EGD was cloned and sequenced. The transposon had inserted in ORF D, the open reading frame previously identified downstream from hlyA, the gene encoding listeriolysin O. The complete sequence of ORF D from strain EGD has been determined as well as that of two other strains: LO28, a clinical isolate; and LM8, an epidemic strain. ORF D is 1,533 bp long and encodes a protein highly homologous to metalloproteases of bacilli, Serratia sp., Legionella pneumophila, and Pseudomonas aeruginosa. It was renamed prtA. Northern RNA blot analysis indicated that prtA is the first gene of a 6-kb operon, suggesting that the lecithinase-negative phenotype of the mutant might be due to a polar effect of the transposon insertion.

Immunoprotective Leishmania major synthetic T cell epitopes

Using the predictive algorithm of Rothbard and Taylor (1988. EMBO J. 7:93) and the primary structure of gp63 (Button, L., and M.R. McMaster. 1988. J. Exp. Med. 167:724; Miller, R.A., S.G. Reed, and M. Parsons. 1990. Mol. Biochem. Parasitol. 39:267) we have been able to delineate the structures of a number of gp63 T-cell epitopes which stimulate the proliferation of CD4+ cells. One of these synthetic antigens, inoculated subcutaneously with adjuvant, was shown to specifically induce proliferation of the Th1 subset and provided immunoprotection against two species of Leishmania parasites.