Dual role of the fringe connection gene in both heparan sulphate and fringe-dependent signalling events.

The precise regulation of growth factor signalling is crucial to the molecular control of development in Drosophila. Post-translational modification of signalling molecules is one of the mechanisms that modulate developmental signalling specificity. We describe a new gene, fringe connection (frc), that encodes a nucleotide-sugar transporter that transfers UDP-glucuronic acid, UDP-N-acetylglucosamine and possibly UDP-xylose from the cytoplasm into the lumen of the endoplasmic reticulum/Golgi. Embryos with the frc mutation display defects in Wingless, Hedgehog and fibroblast growth factor signalling. Clonal analysis shows that fringe-dependent Notch signalling is disrupted in frc mutant tissue.

Stage-specific binding of Leishmania donovani to the sand fly vector midgut is regulated by conformational changes in the abundant surface lipophosphoglycan.

The life cycle of Leishmania parasites within the sand fly vector includes the development of extracellular promastigotes from a noninfective, procyclic stage into an infective, metacyclic stage that is uniquely adapted for transmission by the fly and survival in the vertebrate host. These adaptations were explored in the context of the structure and function of the abundant surface lipophosphoglycan (LPG) on Leishmania donovani promastigotes. During metacyclogenesis, the salient structural feature of L. donovani LPG is conserved, involving expression of a phosphoglycan chain made up of unsubstituted disaccharide-phosphate repeats. Two important developmental modifications were also observed. First, the size of the molecule is substantially increased because of a twofold increase in the number of phosphorylated disaccharide repeat units expressed. Second, there is a concomitant decrease in the presentation of terminally exposed sugars. This later property was indicated by the reduced accessibility of terminal galactose residues to galactose oxidase and the loss of binding by the lectins, peanut agglutinin, and concanavalin A, to metacyclic LPG in vivo and in vitro. The loss of lectin binding was not due to downregulation of the capping oligosaccharides as the same beta-linked galactose or alpha-linked mannose-terminating oligosaccharides were present in both procyclic and metacyclic promastigotes. The capping sugars on procyclic LPG were found to mediate procyclic attachment to the sand fly midgut, whereas these same sugars on metacyclic LPG failed to mediate metacyclic binding. And whereas intact metacyclic LPG did not inhibit procyclic attachment, depolymerized LPG inhibited as well as procyclic LPG, demonstrating that the ligands are normally buried. The masking of the terminal sugars is attributed to folding and clustering of the extended phosphoglycan chains, which form densely distributed particulate structures visible on fracture-flip preparations of the metacyclic surface. The exposure and subsequent masking of the terminal capping sugars explains the stage specificity of promastigote attachment to and release from the vector midgut, which are key events in the development of transmissible infections in the fly.

A specialized pathway affecting virulence glycoconjugates of Leishmania.

For virulence and transmission, the protozoan parasite Leishmania must assemble a complex glycolipid on the cell surface, the lipophosphoglycan (LPG). Functional complementation identified the gene LPG2, which encodes an integral Golgi membrane protein implicated in intracellular compartmentalization of LPG biosynthesis. Ipg2- mutants lack only characteristic disaccharide-phosphate repeats, normally present on both LPG and other surface or secreted molecules considered critical for infectivity. In contrast, a related yeast gene, VAN2/VRG4, is essential and required for general Golgi function. These results suggest that LPG2 participates in a specialized virulence pathway, which may offer an attractive target for chemotherapy.

Regulation of differentiation to the infective stage of the protozoan parasite Leishmania major by tetrahydrobiopterin.

A critical step in the infectious cycle of Leishmania is the differentiation of parasites within the sand fly vector to the highly infective metacyclic promastigote stage. Here, we establish tetrahydrobiopterin (H4B) levels as an important factor controlling the extent of metacyclogenesis. H4B levels decline substantially during normal development, and genetic or nutritional manipulations showed that low H4B caused elevated metacyclogenesis. Mutants lacking pteridine reductase 1 (PTR1) had low levels of H4B, remained infectious to mice, and induced larger cutaneous lesions (hypervirulence). Thus, the control of pteridine metabolism has relevance to the mechanism of Leishmania differentiation and the limitation of virulence during evolution.

Stage-specific adhesion of Leishmania promastigotes to the sandfly midgut.

Although leishmaniasis is transmitted to humans almost exclusively by the bite of infected phlebotomine sandflies, little is known about the molecules controlling the survival and development of Leishmania parasites in their insect vectors. Adhesion of Leishmania promastigotes to the midgut epithelial cells of the sandfly was found to be an inherent property of noninfective-stage promastigotes, which was lost during their transformation to metacyclic forms, thus permitting the selective release of infective-stage parasites for subsequent transmission by bite. Midgut attachment and release was found to be controlled by specific developmental modifications in terminally exposed saccharides on lipophosphoglycan, the major surface molecule on Leishmania promastigotes.

Microbial glycoconjugates.

The surfaces of all microbes are 'sugar coated' with molecules such as lipopolysaccharides in Gram-negative bacteria, capsular polysaccharides in bacteria, lipoarabinomannans in mycobacteria and lipophosphoglycan in Leishmania. The basic structures of these glycoconjugates are known and, in the case of pathogens, they can function as virulence determinants. Recent publications have refined some of these structures and have elucidated interesting genes and proteins responsible for their biosynthesis.

Lipophosphoglycan (LPG) and the identification of virulence genes in the protozoan parasite Leishmania.

Leishmania exploits several strategies to survive within the phagolysosome of vertebrate macrophages and be transmitted by sand fly vectors. Recent advances in functional genetic analysis provide a new avenue for identifying genes implicated in the infectious cycle of the parasite, such as those necessary for the synthesis and expression of the key surface glycoconjugate, lipophosphoglycan (LPG).

Glycoconjugates in Leishmania infectivity.

Leishmaniasis is a major health problem to humans and is caused by one of the world's major pathogens, the Leishmania parasite. These protozoa have the remarkable ability to avoid destruction in hostile environments they encounter throughout their life cycle. That Leishmania parasites have adapted to not only survive, but to proliferate largely is due to the protection conferred by unique glycoconjugates that are either on the parasites' cell surface or secreted. Most of these specialized molecules are members of a family of phosphoglycans while others are a family of glycosylinositol phospholipids. Together they have been implicated in a surprisingly large number of functions for the parasites throughout their life cycle and, therefore, are key players in their pathogenesis. This review summarizes the biological roles of these glycoconjugates and how they are believed to contribute to Leishmania survival in destructive surroundings.

Fusion of Sendai virus and individual host cells and inhibition of fusion by lipophosphoglycan measured with image correlation spectroscopy.

Fusion between Sendai virus (SV) and individual host cells was investigated with confocal laser scanning microscopy (CLSM) and image correlation spectroscopy (ICS). SV was labeled with the fluorescent probe 7-octadecylamino-4-nitrobenz-2-oxa-1,3-diazole (NBD-NH-C18) and was allowed to bind to host cells (HEp-2, BALB-3T3) at 4 degrees C. The effect of lipophosphoglycan (LPG), isolated from Leishmania donovani, on virus fusion was investigated by incorporation of LPG (0, 5, 10 or 20 microM) into the host cell membrane (HEp-2) before addition of SV. LPG did not affect the number of SV bound per cell. After incubation at 37 degrees C for 15 min without LPG, CLSM revealed a redistribution of NBD-NH-C18 from the SV envelope to the host cell membrane and an increase in average fluorescence intensity, indicating dequenching. ICS analysis of images obtained after incubation at 37 degrees C showed an increased mean cluster density to 260% of the value at 4 degrees C, reflecting the disappearance of labeled SV from the cell surface and diffusion of NBD-NH-C18 into the host cell membrane. Preincubation of the cells with LPG inhibited the temperature-induced redistribution and dequenching of NBD-NH-C18 in a concentration-dependent manner, with a total inhibition of fusion at 20 microM LPG. Together, the results demonstrate that CLSM combined with ICS is a powerful tool for studies of fusion of enveloped viruses with individual host cells and that LPG inhibits the fusion process at or before the hemifusion (lipid mixing) stage of SV interaction with cells.

Leishmania donovani infection enhances macrophage viability in the absence of exogenous growth factor.

Bone marrow-derived macrophages rapidly die in the absence of macrophage growth factor (M-CSF). However, as demonstrated here, bone marrow-derived macrophages infected with Leishmania donovani exhibit increased viability in the absence of exogenous growth factor. Forty-eight hours after inoculation with promastigotes or amastigotes, infected cell cultures contained 180 and 95% more cells, respectively, than control cultures. This effect was specific to Leishmania infection, as uptake of latex beads or avirulent promastigotes by macrophages did not enhance cell viability. L. donovani-infected macrophages also displayed increased phagocytic capacity, as compared with control macrophages and macrophages grown continuously in M-CSF-containing medium. Supernatants collected from infected cells elaborated a factor(s) that enhanced macrophage viability but did not stimulate macrophage DNA synthesis. This activity of L. donovani-infected cell-conditioned medium could be abrogated by preincubation of macrophages with cycloheximide before inoculation with the parasite, implying that macrophage protein synthesis is required for the elaboration of this factor(s).

Is lipophosphoglycan a virulence factor? A surprising diversity between Leishmania species.

Lipophosphoglycan is a prominent member of the phosphoglycan-containing surface glycoconjugates of Leishmania. Genetic tests enable confirmation of its role in parasite virulence and permit discrimination between the roles of lipophosphoglycan and related glycoconjugates. When two different lipophosphoglycan biosynthetic genes from Leishmania major were knocked out, there was a clear loss of virulence in several steps of the infectious cycle but, with Leishmania mexicana, no effect on virulence was found. This points to an unexpected diversity in the reliance of Leishmania species on virulence factors, a finding underscored by recent studies showing great diversity in the host response to Leishmania species.

A ricin agglutinin-resistant clone of Leishmania donovani deficient in lipophosphoglycan.

A variant cell line of Leishmania donovani (named R2D2) has been selected for resistance to the cytotoxic lectin ricin agglutinin and shown to be defective in the synthesis of its major glycoconjugate lipophosphoglycan. Compared to the parental line, R2D2 cells showed a marked resistance to the toxic effects of ricin and an increased sensitivity toward concanavalin A. The synthesis of lipophosphoglycan by R2D2 cells was judged to be less than 1% relative to that of wildtype cells as determined by incorporation of radioactive mannose and galactose and by electrophoretic and chromatographic analyses. Although lacking lipophosphoglycan, R2D2 parasites were capable of infecting cultured U937 macrophages.

Expression of a stage-specific lipophosphoglycan in Leishmania major amastigotes.

Amastigotes of Leishmania major were isolated from infected mice and radiolabeled for 2 h with [3H]galactose. An acidic [3H]glycoconjugate was extracted from a dilipidated residue fraction with the solvent water/ethanol/diethylether/pyridine/NH4OH (15:15:5:1:0.017). The radioactivity labeled glycoconjugate was found to possess the following characteristics that were similar to the lipophosphoglycan extractable from promastigotes: (i) migrated as a broad band upon electrophoresis on SDS polyacrylamide gels; (ii) deaminated with nitrous acid; and (iii) hydrolyzed with phosphatidylinositol-specific phospholipase C. Furthermore, analysis of the aqueous soluble material released by the latter enzyme revealed a negatively-charged [3H]polysaccharide intermediate in size compared to the analogous portions of LPG isolated from non-infective and metacyclic promastigotes. Most importantly, the [3H]polysaccharide was found to contain phosphate and was susceptible to mild acid hydrolysis, establishing that the intact molecule is a lipophosphoglycan. A structural difference, however, was found in the major, mild acid-generated fragment of the amastigote phosphoglycan, which was larger in size and not as anionic as the analogous fragment from the promastigote phosphoglycans. These results indicate that the amastigotes do express a lipophosphoglycan, but that it is structurally distinct from its promastigote counterparts.

Cell surface lipophosphoglycan of Leishmania donovani.

Based on a galactose oxidase/NaB[3H]4 technique of radiolabeling macromolecules, the major glycoconjugate (lipophosphoglycan) of Leishmania donovani promastigotes was determined to be located on the cell surface. Incorporated radioactivity was analyzed by gel filtration on Sephadex G-100, chromatography on ricin agglutinin-coupled agarose, and lability to mild acid hydrolysis. Lipophosphoglycan was present throughout the various phases of growth of promastigotes, but was preferentially expressed during the latter part of logarithmic phase and in the stationary phase. In addition, metabolically labeled lipophosphoglycan was released into the culture medium. Expression of this unusual glycoconjugate on the cell surface of L. donovani suggests that it may play a major role in host cell-parasite interactions.

Developmental modification of the lipophosphoglycan from Leishmania major promastigotes during metacyclogenesis.

Lipophosphoglycan was isolated from the dividing, noninfective stage and from the nondividing metacyclic stage of Leishmania major promastigotes. The lipophosphoglycans were characterized by SDS-PAGE and by chromatographic and quantitative analysis of phosphatidylinositol-specific phospholipase C- and mild acid-generated fragments. The results revealed two stage-specific structural differences: (i) an increase in size of the metacyclic form of the glycoconjugate due to an approximate doubling in the number of its salient phosphorylated saccharide units; and concomitantly, (ii) a subtle compositional change in these units. Gas-liquid chromatographic analysis indicated that the phosphatidylinositol lipid anchor was developmentally conserved. These developmental modifications suggest important roles for the lipophosphoglycan which have not been previously considered, such as promoting complement resistance within the vertebrate host, and midgut attachment and release within the sand fly vector.

Leishmania donovani has distinct mannosylphosphoryltransferases for the initiation and elongation phases of lipophosphoglycan repeating unit biosynthesis.

Lipophosphoglycan (LPG) is the predominant surface glycoconjugate of Leishmania promastigotes and plays several roles in the infectious cycle of this protozoan parasite. The salient feature of LPG is the presence of 15-30 copies of a disaccharide-phosphate repeating unit Gal(beta1,4)Man(alpha1-PO4), which is also found on many other secreted molecules (secretory acid phosphatase, phosphoglycan, proteophosphoglycan). This structural diversity suggests that a multiplicity of enzymes mediating repeating unit addition may exist, especially for the mannosylphosphoryltransferases (MPTs), which initiate repeating unit synthesis. This work has taken a combined biochemical-genetic approach to resolve this issue. An lpg- mutant of Leishmania donovani, JEDI, was obtained by antibody selection against cells expressing a repeating unit epitope of LPG. Metabolic and surface labeling experiments revealed that JEDI cells accumulated a truncated form of LPG bearing only a single repeating unit: [Gal(beta 1,4)Man(alpha1-PO4)][Gal(alpha1,6)Gal(alpha1,3)Gal(f)(beta1,3)[Glc(alpha 1-PO4)]Man(alpha1,3)Man(alpha1,4)GlcN(alpha1,6)]-PI. Enzymatic assays of microsomal preparations showed that JEDI lacked MPT activity when tested with a repeating unit acceptor but retained wild-type levels of the MPT activity with an LPG glycan core acceptor. These data indicate that at least two distinct MPT activities are required for LPG repeating unit synthesis: one involved in the 'initiation' of repeating unit synthesis on the LPG core (iMPT), and a second (lacking in JEDI) participating in the 'elongation' phase of repeating unit addition (eMPT), leading to the mature full-length LPG.

The immunochemical structure and surface arrangement of Leishmania donovani lipophosphoglycan determined using monoclonal antibodies.

Using intact Leishmania donovani promastigotes or purified L. donovani lipophosphoglycan (LPG) as immunogens, we have derived four LPG-specific monoclonal antibodies (MAbs). Two of these MAbs recognize an epitope consisting of the repeating phosphorylated galactose beta-1,4-mannose disaccharide portion of the molecule and cross-reacted with LPG from Leishmania major. These MAbs bound to the surface of living promastigotes of both species. The two other MAbs bound to the phosphosaccharide core structure of LPG and did not bind to the surface of living parasites, presumably due to masking of the core region. Experiments using all four MAbs with an LPG-deficient promastigote mutant indicated that both the repeat epitope and phosphosaccharide core were present in these cells, suggesting that incomplete assembly was responsible for the absence of intact LPG.

Reversion to virulence in Leishmania major correlates with expression of surface lipophosphoglycan.

An attenuated clone of Leishmania major was produced by chemical mutagenesis with N-methyl-N'-nitro-N-nitrosoguanidine and was biochemically characterized to determine the reason(s) for its loss of virulence. We found that the degree of virulence of L. major did not correlate with either the level of expression of promastigote surface protease (PSP) or with the enzymatic activity of the molecule. In contrast, the levels of lipophosphoglycan (LPG) expressed by the attenuated clone were found to be at least 6-fold less than those of virulent L. major. When the attenuated L. major was injected into BALB/c mice and allowed to revert to virulence, the degree of reversion to virulence that the parasites underwent correlated directly with the amount and form (metacyclic) of LPG expressed by the parasites. Thus, these results further implicate LPG as an important Leishmania virulence factor.

Stable DNA transfection of a wide range of trypanosomatids.

We have shown that the Leishmania major transfection vector pR-NEO (or derivatives thereof) can be introduced and stably maintained in four species complexes of pathogenic Leishmania (L. tropica, L. mexicana, L. donovani, L. braziliensis), and the genera Endotrypanum and Crithidia; transfection of Trypanosoma cruzi or Trypanosoma brucei was not successful. Quantitative plating assays showed that the transfection efficiencies were high in L. major and Leishmania amazonensis (5x10(-5)/cell) and about 10-fold less for Leishmania panamaensis and Crithidia. Leishmania donovani transfected with pR-NEO retained the ability to infect hamsters, and amastigotes recovered after 2 months yielded G418-resistant promastigotes which retained high levels of extrachromosomal pR-NEO DNA. In promastigotes, the transfected DNA existed as extrachromosomal circles, and expressed the predicted 2.4-kb hybrid NEO/DHFR-TS mRNA bearing the trans-spliced miniexon. Large quantitative differences were observed only in Crithidia: relative to transfected Leishmania species, the copy number of pR-NEO was elevated 20-fold, while the levels of the NEO/DHRFR-TS mRNA or Escherichia coli beta-galactosidase (synthesized from the expression vector pX-beta GAL) were reduced 80 and more than 1000-fold, respectively. Thus, genetic signals derived from L. major DNA that mediate RNA expression or stability are recognized by the heterologous Leishmania species but less efficiently by Crithidia. These studies suggest that pR-NEO derived vectors may be applied to the study of genes expressed throughout the life cycle in a wide range of pathogenic trypanosomatids.

Use of the green fluorescent protein as a marker in transfected Leishmania.

We have tested the suitability of the green fluorescent protein (GFP) of Aequorea victoria as a marker for studies of gene expression and protein targeting in the trypanosomatid parasite Leishmania. Leishmania promastigotes expressing GFP from episomal pXG vectors showed a bright green fluorescence distributed throughout the cell, readily distinguishable from control parasites. Transfection of a modified GFP gene containing GC-rich synonymous codons and the S65T mutation (GFP+) yielded a much higher fluorescence. FACS analysis revealed a clear quantitative separation between GFP-transfected and control parasites, with pXG-GFP+ transfectants showing fluorescence signals more than 100-fold background. Episomal DNAs could be recovered from small numbers of fixed cells, showing that GFP could be used as a convenient screenable marker for FACS separations. GFP was fused to the C-terminus of the LPG1 protein, which retained its ability to restore LPG expression when expressed in the lpg- R2D2 mutant of L. donovani. The LPG1(GFP) fusion was localized to a region situated between the nucleus and kinetoplast; its pattern was similar to that of LPG2, which is known to be located in the Golgi apparatus. This is notable as LPG1 participates in the biosynthesis of the glycan core of the LPG GPI anchor, whereas protein GPI anchor biosynthesis occurs in the endoplasmic reticulum. These studies suggest that the GFP will be a broadly useful marker in Leishmania.