Promastigote secretory gel from natural and unnatural sand fly vectors exacerbate Leishmania major and Leishmania tropica cutaneous leishmaniasis in mice.

Leishmania rely heavily on glycans to complete their digenetic life cycle in both mammalian and phlebotomine sand fly hosts. Leishmania promastigotes secrete a proteophosphoglycan-rich gel (Promastigote Secretory Gel, PSG) that is regurgitated during transmission and can exacerbate infection in the skin. Here we explored the role of PSG from natural Leishmania-sand fly vector combinations by obtaining PSG from Leishmania (L.) major-infected Phlebotomus (P.) papatasi and P. duboscqi and L. tropica-infected P. arabicus. We found that, in addition to the vector's saliva, the PSG from L. major and L. tropica potently exacerbated cutaneous infection in BALB/c mice, improved the probability of developing a patent cutaneous lesion, parasite growth and the evolution of the lesion. Of note, the presence of PSG in the inoculum more than halved the prepatent period of cutaneous L. tropica infection from an average of 32 weeks to 13 weeks. In addition, L. major and L. tropica PSG extracted from the permissive experimental vector, Lutzomyia (Lu.) longipalpis, also exacerbated infections in mice. These results reinforce and extend the hypothesis that PSG is an important and evolutionarily conserved component of Leishmania infection that can be used to facilitate experimental infection for drug and vaccine screening.

Leishmania tropica: intraspecific polymorphisms in lipophosphoglycan correlate with transmission by different Phlebotomus species.

Lipophosphoglycan (LPG) is a dominant surface molecule of Leishmania promastigotes which has been shown to be critical for parasite-sand fly vector interactions. To provide additional evidence for its importance in transmission, the LPGs from three Leishmania tropica strains that differ in their capability to infect sand flies, were biochemically characterized. One of these strains, ISER/IL/98/LRC-L747, was isolated from a Phlebotomus sergenti female collected in the Judean Desert close to Jerusalem. The other strains originated from a different focus in the Galilee region of northern Israel. One was isolated from a patient (MHOM/IL/02/Ofri-LRC-L863) and the other from a naturally infected Phlebotomus arabicus female (IARA/IL/00/Amnunfly1-LRC-L810). The LPG structures of the isolates from the Galilee (L863 and L810) were similar to each other, but differed in the LPG repeat units from the Judean Desert isolate (L747). The terminal sugar in the side chains of the repeat units of LPG purified from L863 and L810 was beta-galactose and was not capped with glucose, unlike L747 and a previously characterized L. tropica strain from Iraq (L36). Since L810 was isolated from P. arabicus and L747 from P. sergenti, variations in the structure of their LPGs may explain their capacity to infect different sand fly species.

gamma-Tubulin in Leishmania: cell cycle-dependent changes in subcellular localization and heterogeneity of its isoforms.

A panel of six anti-peptide antibodies recognizing epitopes in different regions of the gamma-tubulin molecule was used for the characterization and localization of gamma-tubulin during cell cycle in Leishmania promastigotes. Immunofluorescence microscopy revealed the presence of gamma-tubulin in the basal bodies, posterior pole of the cell, and in the flagellum. Furthermore, the antibodies showed punctuate staining in the subpellicular microtubule. This complex localization pattern was observed in both interphase and dividing cells, where staining of posterior poles and the subpellicular corset was more prominent. In posterior poles, gamma-tubulin co-distributed with the 210-kDa microtubule-interacting protein and the 57-kDa protein immunodetected with anti-vimentin antibody. Immunogold electron microscopy on thin sections of isolated flagella showed that gamma-tubulin was associated with the paraflagellar rod (PFR) that runs adjacent to the axonemal microtubules. Under different extraction conditions, gamma-tubulin in Leishmania was found only in insoluble cytoskeletal fractions, in contrast to tubulin dimers that were both in soluble and cytoskeletal pool. Two-dimensional electrophoresis revealed multiple charge variants of gamma-tubulin. Posttranslational modifications of Leishmania gamma-tubulin might therefore have an important role in the regulation of microtubule nucleation and interaction with other proteins. The complex pattern of gamma-tubulin localization and its properties indicate that gamma-tubulin in Leishmania might have other function(s) besides microtubule nucleation.

Cell cycle-dependent changes in localization of a 210-kDa microtubule-interacting protein in Leishmania.

Using the monoclonal antibody MA-01, a new 210-kDa microtubule-interacting protein was identified in Leishmania promastigotes by immunoblotting and by immunoprecipitation. The protein was thermostable and was located on microtubules prepared by taxol-driven polymerization in vitro. On fixed cells the antibody gave specific staining of flagellum, flagellar pocket, and mitotic spindle. Subpellicular microtubules were basically not decorated but posterior poles of the cells were labeled in a cell-cycle-dependent manner. In anterior and posterior poles of cells the 210-kDa protein codistributed with the 57-kDa protein, immunodetected with anti-vimentin antibody, that was located only on cell poles. Immunolocalization of the 57-kDa protein was most prominent in dividing cells. The presented data suggest that the 210-kDa protein is a newly identified microtubule-interacting protein of Leishmania that could be involved in anchoring the microtubules in posterior poles of these cells. The striking codistribution of the microtubule-interacting protein and the 57-kDa protein in protozoa is described for the first time.

Glycoinositol-phospholipid profiles of four serotypically distinct Old World Leishmania strains.

Glycoinositol-phospholipids (GIPLs) are the major glycolipid class and prominant surface antigens of leishmanial parasites. The GIPLs from four serologically distinct Old World strains of Leishmania were characterized to determine inter- and intra-specific differences in these glycolipids. These studies showed that: (1) the major GIPLs of Leishmania topica (LRC-L36) and Leishmania aethiopica (LRC-L495) belong to the alpha-mannose-terminating GIPL series (iM2, iM3 and iM4) that are structurally related to the glycosyl-phosphatidylinositol anchors of both the surface proteins and the abundant lipophosphoglycan (LPG). In contrast, the GIPLs from two Leishmania major strains (LRC-L456 and LRC-L580) belong to the alpha-galactose-terminating GIPL series (GIPL-1, -2 and -3) that are more structurally related to the LPG anchor; (2) the GIPL profiles of the L. major strains differed in that a significant proportion of the GIPL-2 and -3 species (approximately 40% and 80%, respectively) in LRC-L580 are substituted with a glucose-1-PO4 residue, while this type of substitution was not detected in LRC-L456; and (3) all the GIPLs contained either an alkylacyl- or a lysoalkyl-phosphatidylinositol lipid moiety. However, the alkyl chain compositions of different GIPLs within the same strain was variable. In L. major, the major GIPL species contained alkylacylglycerols with predominantly C18:0 and C24:0 alkyl chains, whereas the glucose-1-PO4-substituted GIPLs contained exclusively lysoalkylglycerols with C24:0 alkyl chains. In L. tropica, the major GIPL, iM2, contained predominantly C24:0 alkyl chains whereas the structurally related iM3 and iM4 GIPLs in this strain contained predominantly C18:0 alkyl chains. In L. aethiopica all the GIPLs (iM2, iM3, iM4) contained C18:0 alkyl chains. These data suggest that the synthesis of the GIPLs may occur in more than one subcellular compartment. The possibility that species-specific differences in the predominantly surface glycan structures may modulate the interaction of the parasite with the insect and mammalian hosts is discussed.

The structure of Leishmania major amastigote lipophosphoglycan.

Intracellular amastigotes of Leishmania major produce 6 x 10(4) copies/cell of a lipophosphoglycan (LPG) that is structurally distinct from the LPG produced by the extracellular promastigote form of L. major, Leishmania donovani, and Leishmania mexicana (reviewed by McConville, M. J. (1991) Cell Biol. Int. Rep. 15, 779-798). L. major amastigote LPG is composed of a lysoalkyl phosphatidylinositol lipid anchor that links via a diphosphorylated hexasaccharide core to a phosphoglycan (6-100 kDa). The structures of the anchor, the core, and the phosphoglycan were determined by monosaccharide and linkage analysis, fast atom bombardment-mass spectrometry, one-dimensional 1H NMR spectroscopy, and exoglycosidase microsequencing. The lipid anchor contains predominantly 1-O-alkylglycerols with 24:0 and 22:0 alkyl chains. The lipids are linked via a glycerol-myo-inositol-PO4 to a core glycan with the structure -PO4-6)Gal(alpha 1-)Gal(alpha 1-) Galf(beta 1-)[Glc(alpha 1-PO4-)]Man(alpha 1-)Man(alpha 1-)GlcN(alpha 1-). The chromatographic characteristics of the core glycan suggest that the saccharide components are linked similarly in amastigote and promastigote LPG. The phosphoglycan attached to the core consists of -PO4-6)Gal(beta 1-4)Man(alpha 1- repeats units which are either unsubstituted (70%) or substituted (30%) at the 3-position of the Gal residues with oligosaccharide side chains containing primarily Gal and some Glc. Thirteen different types of side chains were identified with the structures [Gal(beta 1-3)]x, where x = 1-11, or Glc(1-3)Glc(1-3), or Glc(1-3)Gal(beta 1-3), where glucose is probably in the beta-configuration. All monosaccharides in the phosphoglycan domain are in the pyranose configuration. The average number of repeat units per molecule is 36. The nonreducing terminus of the phosphoglycan chains probably terminates predominantly in the neutral disaccharide Gal(beta 1-4)Man(alpha 1-. Comparison of the structure of L. major amastigote LPG to L. major promastigote procyclic and metacyclic LPG forms (McConville, M. J., Turco, S. J., Furguson, M. A. J., and Sacks, D. L. (1992) Embo J. 11, 3593-3600) indicates that this molecule is developmentally modified throughout the different stages of the parasites' life cycle.

Leishmania major: characterisation and expression of a cytoplasmic stress-related protein.

The DNA sequence of a single-copy gene from Leishmania major has been determined and shown to share sequence identity with eukaryotic heat shock protein-70-related genes. Conserved features of the deduced open reading frame include amino acids implicated in ATP binding and a putative calmodulin-binding domain. Antibodies generated to the recombinant fusion protein recognise a 70-kDa molecule of pI 6.0. This molecule is constitutively expressed and localises to the cytoplasm in all stages of the parasite life cycle.

Real-time quantitative elemental analysis and mapping: microchemical imaging in cell physiology.

Recent advances in widely available microcomputers have made the acquisition and processing of digital quantitative X-ray maps of one to several cells readily feasible. Here we describe a system which uses a graphics-based microcomputer to acquire spectrally filtered X-ray elemental image maps that are fitted to standards, to display the image in real time, and to correct the post-acquisition image map with regard to specimen drift. Both high-resolution quantitative energy-dispersive X-ray images of freeze-dried cyrosections and low-dose quantitative bright-field images of frozen-hydrated sections can be acquired to obtain element and water content from the same intracellular regions. The software programs developed, together with the associated hardware, also allow static probe acquisition of data from selected cell regions with spectral processing and quantification performed on-line in real time. In addition, the unified design of the software program provides for off-line processing and analysing by several investigators at microcomputers remote from the microscope. The overall experimental strategy employs computer-aided imaging, combined with static probes, as an essential interactive tool of investigation for biological analysis. This type of microchemical microscopy facilitates studies in cell physiology and pathophysiology which focus on mechanisms of ionic (elemental) compartmentation, i.e. structure-function correlation at cellular and subcellular levels; it allows investigation of intracellular concentration gradients, of the heterogeneity of cell responses to stimuli, of certain fast physiological events in vivo at ultrastructural resolution, and of events occurring with low incidence or involving cell-to-cell interactions.

Structure and antigenicity of the lipophosphoglycan from Leishmania major amastigotes.

The lipophosphoglycan (LPG) of the intracellular amastigote form of the protozoan parasite Leishmania major is chemically distinct from the LPG on the surface of the extracellular promastigote form. Amastigote LPG is composed of the monosaccharides galactose, glucose, mannose, glucosamine and inositol in the molar ratio 51:30:24:1:1; arabinose is absent. The lipid anchor comprises four alkylglycerols, with alkyl chain lengths 24:0, 22:0, 20:0 and 26:0 in the molar ratio 68:18:8:6. Phosphate is present at 4% w/w of total carbohydrate. HPLC gel permeation reveals LPG to be a polydisperse family of molecules Mr 100-6 kDa. The results from immunological studies with LPG-directed antibodies are consistent with amastigote LPG having the expected tripartite structure of GPI-anchor, a core glycan and the phosphorylated disaccharide repeat backbone. Human sera from L. major patients bound amastigote LPG in enzyme-linked immunosorbent assays.

Transmission and scanning EM-immunogold labeling of Leishmania major lipophosphoglycan in the sandfly Phlebotomus papatasi.

Previous studies using immunostaining and light microscopy demonstrated expression of Leishmania major lipophosphoglycan (LPG) on parasites developing in the sandfly gut from 2 days post infection. By days 4 to 7 post infection, there appeared to be large amounts of parasite-free LPG deposited on/in the microvilli and epithelial cells lining the thoracic midgut, while forward migration of parasites and the morphological changes which accompany metacyclogenesis were associated with developmental modification of the LPG molecules. Studies presented here examine this process with much greater precision using electron microscopy and immunogold labeling techniques to study the different developmental forms (nectomonads, haptomonads, paramastigotes, and metacyclics) of promastigotes in the sandfly gut. Results obtained using LPG-specific monoclonal antibodies (WIC79.3, 45D3 and the metacyclic-specific 3F12) show (1) gold labeling over the cell surface, within the flagellar pocket, and extending along the entire length of the flagellum of electron-dense nectomonads observed in the abdominal and thoracic midgut regions on days 4 and 7 post infection, and of electron-lucid haptomonads in the foregut, (2) dense labeling around the flagellar tips, by which nectomonad forms bind to the midgut microvilli, but not on the microvilli themselves or within the epithelial cells lining the midgut, (3) significant metacyclic-specific (3F12) labeling on nectomonad forms in the lumen of the midgut and attached to the microvilli, and (4) dense labeling on the cell surface of electron-lucid paramastigotes in the esophagus and in the filamentous matrix surrounding paramastigote and metacyclic forms in the esophagus and pharynx. These results are discussed in the light of the proposed roles for LPG in parasite attachment to, and survival in, the sandfly gut.