Demonstration by heterologous expression that the Leishmania SCA1 gene encodes an arabinopyranosyltransferase

In part of the life cycle within their sand fly vector, Leishmania major parasites first attach to the fly's midgut through their main surface adhesin lipophosphoglycan (LPG) and later resynthesize a structurally distinct LPG that results in detachment and eventual transmission. One of these structural modifications requires the addition of alpha1,2-D-arabinopyranose caps to beta1,3-galactose side chains in the phosphoglycan repeat unit domain of LPG. We had previously identified two side chain arabinose genes (SCA1/2) that were involved in the alpha1,2-D-Arap capping. SCA1/2 exhibit canonical glycosyltransferase motifs, and overexpression of either gene leads to elevated microsomal alpha1,2-D-ArapT activity, resulting in arabinopyranosylation of beta1,3-Gal side chains in LPG (hereafter called side chain D-arabinopyranosyltransferase [sc-D-ArapT]). Heterologous expression in a null arabinose background was used to determine whether the SCA1 gene encodes the actual sc-D-ArapT. SCA1 expression constructs introduced into both mammalian COS-7 cells and the baculovirus-sf9 cell system exhibited considerable expression of the protein. However, functional sc-D-ArapT activity was observed only in the latter. In in vitro assays incubated with guanidine 59-diphosphate (GDP)-D-[3H]Arap as the sugar donor and utilizing exogenous LPG as an acceptor, significant sc-D-ArapT activity was observed when microsomes from the baculovirus-sf9 cells were incubated in presence of the LPG acceptor. No activity was observed in the absence of LPG. These results demonstrate that SCA1 encodes a sc-D-ArapT and provide the first example of heterologous expression of a D-ArapT gene.     

Leishmania braziliensis: a novel mechanism in the lipophosphoglycan regulation during metacyclogenesis

During metacyclogenesis of Leishmania in its sand fly vector, the parasite differentiates from a noninfective, procyclic form to an infective, metacyclic form, a process characterised by morphological changes of the parasite and also biochemical transformations in its major surface lipophosphoglycan (LPG). This lipid-anchored polysaccharide is polymorphic among species with variations in sugars that branch off the conserved Gal(beta1,4)Man(alpha1)-PO4 backbone of repeat units and the oligosaccharide cap. Lipophosphoglycan has been implicated as an adhesion molecule that mediates the interaction with the midgut epithelium of the sand fly in the subgenus Leishmania. This paper describes the LPG structure for the first time in a species from the subgenus Viannia, Leishmania (Viannia) braziliensis. The LPG from the procyclic form of L. braziliensis was found to lack side chain sugar substitutions. In contrast to other species from the subgenus Leishmania, metacyclic forms of L. braziliensis makes less LPG and add 1-2 (beta1-3) glucose residues that branch off the disaccharide-phosphate repeat units of LPG. Thus, this represents a novel mechanism in the regulation of LPG structure during metacyclogenesis.     

Functional identification of galactosyltransferases (SCGs) required for species-specific modifications of the lipophosphoglycan adhesin controlling Leishmania major-sand fly interactions

Lipophosphoglycan (LPG) is an abundant surface molecule that plays key roles in the infectious cycle of Leishmania major. The dominant feature of LPG is a polymer of phosphoglycan (PG) (6Galbeta1,4Manalpha1-PO(4)) repeating units. In L. major these are extensively substituted with Gal(beta1,3) side chains, which are required for binding to midgut lectins and survival. We utilized evolutionary polymorphisms in LPG structure and cross-species transfections to recover genes encoding the LPG side chain beta1,3-galactosyltransferases (betaGalTs). A dispersed family of six SCG genes was recovered, whose predicted proteins exhibited characteristics of eukaryotic GalTs. At least four of these proteins showed significant LPG side chain betaGalT activity; SCG3 exhibited initiating GalT activity whereas SCG2 showed both initiating and elongating GalT activity. However, the activity of SCG2 was context-dependent, being largely silent in its normal genomic milieu, and different strains show considerable variation in the extent of LPG galactosylation. Thus the L. major genome encodes a family of SCGs with varying specificity and activity, and we propose that strain-specific LPG galactosylation patterns reflect differences in their expression.     

Characterization of the elongating alpha-D-mannosyl phosphate transferase from three species of Leishmania using synthetic acceptor substrate analogues

Leishmania express lipophosphoglycans and proteophosphoglycans that contain Galbeta1-4Manalpha1-P phosphosaccharide repeat structures assembled by the sequential addition of Manalpha1-P and betaGal. The synthetic acceptor substrate Galbeta1-4Manalpha1-P-decenyl and a series of analogues were used to probe Leishmania alpha-D-mannosyl phosphate transferase activity. We show that the activity detected with Galbeta1-4Manalpha1-P-decenyl is the elongating alpha-D-mannosyl phosphate transferase associated with lipophosphoglycan biosynthesis (eMPT(LPG)). Differences in the apparent K(m) values for the donor and acceptor substrates were found using L. major, L. mexicana, and L. donovani promastigote membranes, but total activity correlated with the number of lipophosphoglycan repeats. Further comparisons showed that lesion-derived L. mexicana amastigotes, that do not express lipophosphoglycan, lack eMPT(LPG) and that nondividing L. major metacyclic promastigotes contain 5-fold less eMPT(LPG) activity than dividing procyclic promastigotes. The fine specificity of promastigote eMPT(LPG) activity was determined using 24 synthetic analogues of Galbeta1-4Manalpha1-P-decenyl. The three species gave similar results: the negative charge of the phosphodiester and the C-6 hydroxyl of the alphaMan residue are essential for substrate recognition, the latter most likely acting as a hydrogen bond acceptor. The C-6' hydroxyl of the betaGal residue is required for substrate recognition as well as for catalysis. The rate of Manalpha1-P transfer declines with increasing acceptor substrate chain length. The presence of a monosaccharide substituent at the C-3 position of the terminal betaGal residue abrogates Man-P transfer, showing that chain elongation must precede side chain modification during lipophosphoglycan biosynthesis. In contrast, substitution of the penultimate phosphosaccharide repeat does not abrogate transfer but is slightly stimulatory in L. mexicana and inhibitory in L. major.     

Production of nitric oxide by murine macrophages induced by lipophosphoglycan of Leishmania major

Protozoan parasites of the genus Leishmania cause a number of important human diseases. One of the key determinants of parasite infectivity and survival is the surface glycoconjugate lipophosphoglycan (LPG). In addition, LPG is shown to be useful as a transmission blocking vaccine. Since culture supernatant of parasite promastigotes is a good source of LPG, we made attempts to characterize functions of the culture supernatant, and membrane LPG isolated from metacyclic promastigotes of Leishmania major. The purification scheme included anion-exchange chromatography, hydrophobic interaction chromatography and cold methanol precipitation. The purity of supernatant LPG (sLPG) and membrane LPG (mLPG) was determined by SDS-PAGE and thin layer chromatography. The effect of mLPG and sLPG on nitric oxide (NO) production by murine macrophages cell line (J774.1A) was studied. Both sLPG and mLPG induced NO production in a dose dependent manner but sLPG induced significantly higher amount of NO than mLPG. Our results show that sLPG is able to promote NO production by murine macrophages.     

A lipophosphoglycan-independent method for isolation of infective Leishmania metacyclic promastigotes by density gradient centrifugation.

At the end of their growth in the sand fly, Leishmania parasites differentiate into the infective metacyclic promastigote stage, which is transmitted to the mammalian host. Thus, in experimental studies of parasite infectivity toward animals or macrophages, the use of purified metacyclics is generally preferred. While metacyclics of several Leishmania species can be efficiently purified with the aid of lectins or monoclonal antibodies, which differentially exploit stage-specific differences in the structure of the abundant surface glycolipid lipophosphoglycan (LPG), such reagents are unavailable for most species and they are unsuitable for studies involving LPG-deficient mutants. Here we describe a simple density gradient centrifugation method, which allows the rapid purification of infective metacyclic parasites from both wild-type and LPG-deficient Leishmania major. The purified metacyclic promastigotes are authentic, as judged by criteria such as their morphology, expression of the metacyclic-specific gene SHERP, and ability to invade and replicate within macrophages in vitro. Preliminary studies suggest that this method is applicable to other Leishmania species including L. donovani.     

Comparison of the protein kinase and acid phosphatase activities of five species of Leishmania

Promastigotes from log phase and stationary phase cultures of Leishmania donovani, L. braziliensis panamensis, L. tropica, L. major, and L. mexicana amazonensis were analyzed for their content of protein kinase and acid phosphatase activities. Cell surface, histone-specific protein kinase activity was 1.3- to 2.8-fold higher in stationary phase cells of all species except for L. tropica in which the activities of stationary and log phase cells were equal; L. mexicana amazonensis had the highest histone-specific protein kinase activity and L. donovani the lowest. When viable, motile promastigotes of all five species were incubated for 10 min with [gamma-32P]ATP and Mg2+ (10 mM) in the absence of exogenous histone acceptor; about one dozen proteins were phosphorylated in each case. Both log phase and stationary phase promastigotes of all five species extensively phosphorylated a 50-kDa protein that had the mobility of tubulin. Incubation of pure calf brain tubulin with [gamma-32P]ATP and purified L. donovani protein kinase resulted in extensive phosphorylation of the former. Highly infective metacyclic forms (PNA-) of L. major, isolated from a stationary culture using the peanut agglutinin (PNA), contained eight times more histone-specific protein kinase activity than noninfective log phase cells (PNA+). The PNA- and PNA+ forms of L. major both phosphorylated a 50-kDa protein when incubated with [gamma-32P]ATP and magnesium or manganese ions (10 mM); the 50-kDa protein was precipitated by anti-tubulin rabbit antibodies. Extracts of all five species contained large amounts of acid phosphatase activity.(ABSTRACT TRUNCATED AT 250 WORDS)     

Metacyclogenesis of Leishmania spp: species-specific in vitro transformation, complement resistance, and cell surface carbohydrate and protein profiles

Metacyclic (stationary) and logarithmic (log) forms of promastigotes of Leishmania donovani and Leishmania major were characterized in several ways. The highly active metacyclic forms were larger with more protein and less carbohydrate. The flagellum increased in length 2.4 times in L. major as compared to 1.8 times in L. donovani. Resistance to complement-mediated lysis by normal human serum of in vitro grown Leishmania promastigotes was related to the species, the growth phase in culture, and also the temperature. Metacyclic forms of both species had a much increased resistance to killing by normal serum at different temperatures. Differences in membrane-exposed carbohydrates were detected by fluorescein-conjugated lectins. Peanut agglutinin and Ulex agglutinin I differentiated log and stationary phase promastigotes of L. major. Higher amounts of acid phosphatase were demonstrated in the metacyclic phase. Differences in polypeptides were detected by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Two polypeptides of approximately 51 and 114 kDa were found exclusively in metacyclic promastigotes of both species, whereas 38- and 23-kDa polypeptides were lost or reduced during transformation from log to metacyclic phase promastigotes of L. donovani. In addition, a 75-kDa polypeptide was expressed only in metacyclic promastigotes of L. major.     

Intra-species and stage-specific polymorphisms in lipophosphoglycan structure control Leishmania donovani-sand fly interactions.

The Leishmania lipophosphoglycan conveys the ability for the parasites to avoid destruction in diverse host environments. During its life cycle within the sand fly vector, the parasite differentiates from a dividing procyclic promastigote stage that avoids expulsion from the midgut by attaching to the gut wall, to a nondividing metacyclic promastigote stage that is unable to attach to the midgut and migrates to the mouth parts for reinfection of a mammalian host. Lipophosphoglycan plays an integral role during this transition. Structurally, lipophosphoglycan is a multidomain glycoconjugate whose polymorphisms among species lie in the backbone Gal(beta 1,4)Man(alpha 1)-PO(4) repeating units and the oligosaccharide cap. We have characterized the lipophosphoglycan from an Indian L. donovani isolate. Unlike East African isolates, which express unsubstituted repeats and a galactose- and mannose-terminating cap, procyclic lipophosphoglycan from the Indian isolate consists of beta1,3-linked glucose residues that branch off the backbone repeats (n approximately 17) and also terminate the cap. Of biological significance, metacyclic lipophosphoglycan lacks the glucose residues while doubling the number of repeats. The importance of these developmental modifications in lipophosphoglycan structure was determined using binding experiments to Phlebotomus argentipes midguts. Procyclic promastigotes and procyclic LPG were able to bind to sand fly midguts in vitro whereas metacyclic parasites and LPG lost this capacity. These results demonstrate that the Leishmania adapts the synthesis of terminally exposed sugars of its LPG to manipulate parasite-sand fly interactions.     

Two functionally divergent UDP-Gal nucleotide sugar transporters participate in phosphoglycan synthesis in Leishmania major

In the protozoan parasite Leishmania, abundant surface and secreted molecules, such as lipophosphoglycan (LPG) and proteophosphoglycans (PPGs), contain extensive galactose in the form of phosphoglycans (PGs) based on (Gal-Man-PO(4)) repeating units. PGs are synthesized in the parasite Golgi apparatus and require transport of cytoplasmic nucleotide sugar precursors to the Golgi lumen by nucleotide sugar transporters (NSTs). GDP-Man transport is mediated by the LPG2 gene product, and here we focused on transporters for UDP-Gal. Data base mining revealed 12 candidate NST genes in the L. major genome, including LPG2 as well as a candidate endoplasmic reticulum UDP-glucose transporter (HUT1L) and several pseudogenes. Gene knock-out studies established that two genes (LPG5A and LPG5B) encoded UDP-Gal NSTs. Although the single lpg5A(-) and lpg5B(-) mutants produced PGs, an lpg5A(-)/5B(-) double mutant was completely deficient. PG synthesis was restored in the lpg5A(-)/5B(-) mutant by heterologous expression of the human UDP-Gal transporter, and heterologous expression of LPG5A and LPG5B rescued the glycosylation defects of the mammalian Lec8 mutant, which is deficient in UDP-Gal uptake. Interestingly, the LPG5A and LPG5B functions overlap but are not equivalent, since the lpg5A(-) mutant showed a partial defect in LPG but not PPG phosphoglycosylation, whereas the lpg5B(-) mutant showed a partial defect in PPG but not LPG phosphoglycosylation. Identification of these key NSTs in Leishmania will facilitate the dissection of glycoconjugate synthesis and its role(s) in the parasite life cycle and further our understanding of NSTs generally.     

Characterisation of a new Leishmania META gene and genomic analysis of the META cluster

The META1 gene of Leishmania is upregulated in metacyclic promastigotes and encodes a 12 kDa virulence-related protein, conserved in all Leishmania species analysed. In this study, the genomic region adjacent to the Leishmania amazonensis META1 gene was characterised and compared to the Leishmania major META1 locus as well as to syntenic loci identified in Trypanosoma brucei and Trypanosoma cruzi. Three new genes expressed with increased abundance of steady state mRNA in L. amazonensis promastigotes were identified, two of which are upregulated in stationary phase promastigotes, sharing the pattern of expression previously described for the META1 mRNA. One of these new genes, named META2, encodes a polypeptide of 444 amino acid residues with a repetitive structure showing three repeats of the META domain (defined as a small domain family found in the Leishmania META1 protein and in bacterial proteins hypothetically secreted and/or implicated in motility) and a carboxyl-terminal region similar to several putative calpain-like proteins of Trypanosoma and Leishmania.     

Developmental modification of lipophosphoglycan during the differentiation of Leishmania major promastigotes to an infectious stage.

Protozoan parasites of the genus Leishmania produce the novel surface glycoconjugate, lipophosphoglycan (LPG), which is required for parasite infectivity. In this study we show that LPG structure is modified during the differentiation of L. major promastigotes from a less infectious form in logarithmic growth phase to a highly infectious 'metacyclic' form during stationary growth phase. In both stages, the LPGs comprise linear chains of phosphorylated oligosaccharide repeat units which are anchored to the membrane via a glycosyl-phosphatidylinositol glycolipid anchor. During metacyclogenesis there is (i) an approximate doubling in the average number of repeat units per molecule from 14 to 30, (ii) a pronounced decrease in the relative abundance of repeat units with side chains of beta Gal or Gal beta 1-3Gal beta 1-, and a corresponding increase in repeat units with either no side chains or with side chains of Arap alpha 1-2 Gal beta 1- and (iii) a decrease in the frequency with which the glycolipid anchor is substituted with a single glucose alpha 1-phosphate residue. While the majority of the LPG phosphoglycan chains are capped with the neutral disaccharide, Man alpha 1-2Man, a significant minority of the chains appeared to terminate in non-phosphorylated repeat units and may represent incompletely capped species. We suggest that the developmental modification of LPG may be important in modulating the binding of promastigotes to receptors in the sandfly midgut and on human macrophages and in increasing the resistance of metacyclic promastigotes to complement-mediated lysis.     

The comparative fine structure and surface glycoconjugate expression of three life stages of Leishmania major

The cellular ultrastructure and surface glycoconjugate expression of three life stages of Leishmania major were compared. Noninfective logarithmic phase promastigotes (LP) are immature cells bearing a thin cell coat, short flagellum, small and empty flagellar pocket, and a loose cytoplasm filled with profiles of ER and large Golgi complex. LP also contain subpopulations of maturing cells containing less ER and Golgi and synthesizing cytoplasmic granules of different size, number, and electron-density. Infective or metacyclic promastigotes (MP) are fully differentiated nondividing forms with a thickened, prominent cell coat, long flagellum, distended flagellar pocket filled with secretory material, and few cytoplasmic organelles other than abundant electron-dense granules. Tissue amastigotes also contain electron-dense cytoplasmic granules, their flagellar pockets are also enlarged and contain secretory material, but they lack a discernable cell coat. Immunogold labeling of GP63 on the cell surface was extensive only on amastigotes. Promastigote GP63 appeared to be masked by the presence of a densely packed lipophosphoglycan (LPG) coat which was extensively labeled on the entire surface of MP and LP. An elongated, developmentally modified form of LPG was abundantly labeled only on MP. LPG was poorly labeled on amastigotes, arguing that the promastigote cell coat is a stage-specific structure which is lost during intracellular transformation.     

The lipophosphoglycan of Leishmania and macrophage protein kinase C

Lipophosphoglycan (LPG), the major cellsurface glycoconjugate of Leishmania promastigotes, is on essential virulence determinant. One feature of LPG resides in its strong inhibitory effect on the activity of purified protein kinase C (PKC). In this article, Albert Descoteaux and Salvatore Turco briefly review the evidence that LPG effectively inhibits PKC activity in the macrophage, and discuss the implication of such inhibition on Leishmania intramacrophoge survival.     

The generation of infective stage Leishmania major promastigotes is associated with the cell-surface expression and release of a developmentally regulated glycolipid

A monoclonal antibody, 3F12, was generated which reacted specifically against infective or metacyclic stage Leishmania major promastigotes, but not with noninfective promastigotes obtained from log phase cultures. The antibody recognized a cell surface and released molecule that could be metabolically labeled with [14C]glucose, [3H]mannose, [3H]galactose, and [3H]palmitic acid, but not with [35S]methionine or [3H]leucine. The molecule was the major species surface-labeled by [3H]sodium borohydride after periodate treatment. The glycolipid appeared to be shed primarily as free carbohydrate because 70% of the released material partitioned in the aqueous fraction after phase separation in TX-114. The molecule could be distinguished from the L. major glycolipid which has already been extensively described because its migration on sodium dodecyl sulfate-polyacrylamide gel electrophoresis was of higher relative m.w. However, a close relationship between the two molecules was indicated by the finding that another monoclonal antibody, WIC-79.3, recognized both forms of the glycolipid; one produced and released only by log phase promastigotes, and one produced and released only by metacyclic promastigotes. The loss of agglutination with peanut agglutinin which has been shown to accompany metacyclogenesis was found to be caused by the loss of expression of the log form of the glycolipid which in most cases appeared to be the result of the developmental modification of this molecule. A survey of a number of virulent and avirulent. L. major strains and clones reinforced an absolute association between the ability of these promastigotes to initiate infection in BALB/c mice and their expression and release of the 3F12-binding, developmentally regulated form of the glycolipid. Not only does this glycolipid serve as the first well defined molecular marker for infective stage metacyclic promastigotes, but its unique structure is very likely to contribute to the adaptive changes that allow these parasites to survive within the vertebrate host.     

Metacyclogenesis: a basic process in the biology of Leishmania

Metacyclogenesis is a process whereby Leishmania transforms from poorly infective procyclic promastigotes into highly infective metacyclic promastigotes. In nature, metacyclogenesis occurs in the insect vector. This transformation is accompanied by an increased ability to infect and survive in the vertebrate host, where the parasite is attacked by the host's immune system. Metacyclogenesis has also been shown to occur in axenic cultures of promastigotes. Morphological changes in size and shape, and length of flagellum were first associated with differentiation in the insect gut and in different phases of growth in culture. Later, the expression of molecules such as LPG and the surface protease gp63 were associated with this process. These two molecules were observed to undergo qualitative and quantitative modifications as the promastigotes differentiated from procyclic to metacyclic forms. Using cDNA subtractive hybridization-based methods or differential amplification, previously unknown genes tightly linked to metacyclogenesis have been identified. Gene products exclusively expressed in metacyclic promastigotes included a gene B product and Mat-1--a gene associated with metacyclogenesis. Other proteins, Meta-1, SHERP and HASP, were up-regulated during the metacyclic stage. The function and stage-regulated expression of these molecules and their relationship with infectivity are now under investigation.     

Leishmania major survival in selective Phlebotomus papatasi sand fly vector requires a specific SCG-encoded lipophosphoglycan galactosylation pattern

Phlebotomine sand flies that transmit the protozoan parasite Leishmania differ greatly in their ability to support different parasite species or strains in the laboratory: while some show considerable selectivity, others are more permissive. In "selective" sand flies, Leishmania binding and survival in the fly midgut typically depends upon the abundant promastigote surface adhesin lipophosphoglycan (LPG), which exhibits species- and strain-specific modifications of the dominant phosphoglycan (PG) repeat units. For the "selective" fly Phlebotomus papatasi PpapJ, side chain galactosyl-modifications (scGal) of PG repeats play key roles in parasite binding. We probed the specificity and properties of this scGal-LPG PAMP (Pathogen Associated Molecular Pattern) through studies of natural isolates exhibiting a wide range of galactosylation patterns, and of a panel of isogenic L. major engineered to express similar scGal-LPG diversity by transfection of SCG-encoded β1,3-galactosyltransferases with different activities. Surprisingly, both 'poly-scGal' and 'null-scGal' lines survived poorly relative to PpapJ-sympatric L. major FV1 and other 'mono-scGal' lines. However, survival of all lines was equivalent in P. duboscqi, which naturally transmit L. major strains bearing 'null-scGal'-LPG PAMPs. We then asked whether scGal-LPG-mediated interactions were sufficient for PpapJ midgut survival by engineering Leishmania donovani, which normally express unsubstituted LPG, to express a 'PpapJ-optimal' scGal-LPG PAMP. Unexpectedly, these "L. major FV1-cloaked" L. donovani-SCG lines remained unable to survive within PpapJ flies. These studies establish that midgut survival of L. major in PpapJ flies is exquisitely sensitive to the scGal-LPG PAMP, requiring a specific 'mono-scGal' pattern. However, failure of 'mono-scGal' L. donovani-SCG lines to survive in selective PpapJ flies suggests a requirement for an additional, as yet unidentified L. major-specific parasite factor(s). The interplay of the LPG PAMP and additional factor(s) with sand fly midgut receptors may determine whether a given sand fly host is "selective" or "permissive", with important consequences to both disease transmission and the natural co-evolution of sand flies and Leishmania.     

Leishmania chagasi: homogenous metacyclic promastigotes isolated by buoyant density are highly virulent in a mouse model

Homogenous metacyclic promastigotes of Leishmania chagasi were isolated by buoyant density from in vitro heterogeneous cultures and used for biochemical characterization of isoforms of the major surface protease (MSP). Compared to stationary phase promastigotes, metacyclic cells had three times more MSP, produced 3-fold higher parasite loads in a mouse model in vivo, and were more resistant to complement-mediated lysis in vitro. These metacyclic L. chagasi expressed both the virulence-associated 59-kDa, and the constitutively expressed 63-kDa, isoforms of MSP.     

Effect of glycolipids of Leishmania parasites on human monocyte activity. Inhibition by lipophosphoglycan

Lipophosphoglycan (LPG) and glycosyl phosphatidylinositol Ag (GPI), are glycolipids present on the membrane of Leishmania parasites. Both glycolipids have been chemically characterized. LPG is a polysaccharide of repeating phosphorylated units linked to a phosphocarbohydrate core that is anchored to the membrane by lysoalkyl phosphatidylinositol (PI). The GPI are smaller glycolipids with a structure resembling the phosphocarbohydrate core of the LPG. They are anchored to the membrane by alkyl acyl PI. Their relative abundance, uniqueness of structure, and cellular location suggest a role in interactions of the parasites with host cells. In the present study we examined the effect of LPG and GPI on the activation of human peripheral blood monocytes. Three parameters were studied: the production of IL-1, chemotactic locomotion, and oxidative burst. We found that whereas neither GPI nor LPG directly affected monocyte activity, preincubation of the monocytes with LPG strongly inhibited further activation: The production of IL-1, after stimulation with LPS, was decreased in a dose-dependent manner. Previous incubation with LPG also inhibited chemotactic locomotion of monocytes and neutrophils in response to diacylglycerol, zymosan-activated serum, FMLP and LTB4. Luminol-dependent chemiluminiscence caused by stimulation of the monocytes with streptococci and histone was also inhibited. After fragmentation of the LPG into phosphoglycan and 1-O-alkylglycerol by phosphatidylinositol-phospholipase C, only the phosphoglycan retained inhibitory activity. No difference in inhibitory activity was found between LPG prepared from Leishmania major or Leishmania donovani promastigotes. These results show that the phosphoglycan of LPG inhibits the immunologic response of normal human monocytes and neutrophils, and suggest that LPG may influence the nature of the inflammatory response surrounding infected cells.     

Leishmania major: Reactive oxygen species and interferon gamma induction by soluble lipophosphoglycan of stationary phase promastigotes

Protozoan parasites of the genus Leishmania cause a number of important human diseases. One of the key determinants of parasite infectivity and survival is membrane glycoconjugate lipophosphoglycan (mLPG). In addition, it has been shown that mLPG could be used as a transmission blocking vaccine. Since culture supernatant of parasite promastigotes is a good source of LPG, we attempted to compare the immunological properties of culture supernatant and membrane LPG prepared from stationary phase promastigotes of Leishmania major. The purity of supernatant LPG (sLPG) and membrane LPG (mLPG) was determined by thin layer chromatography. The effect of sLPG and mLPG on the production of reactive oxygen species (ROS) was studied using PBMCs isolated from healthy individuals. In addition, induction of IL-12, IFN-gamma and IL-10 secretion in the presence of sLPG and mLPG was investigated. Reactive oxygen species in addition to IL-10 and IL-12 were induced by both sLPG and mLPG. However, IFN-gamma production was promoted only in response to sLPG suggesting its ability to promote Th1 response and implication in vaccine design.