Cell surface nanoanatomy of Leishmania major as revealed by fracture-flip. A surface meshwork of 44 nm fusiform filaments identifies infective developmental stage promastigotes

Fracture-flip (Anderson-Forsman and Pinto da Silva, J. Cell Sci. 90, 531-541; 1988) was used to reveal the nanoanatomy of the surface of Leishmania major promastigotes. Over the cell surface of infective metacyclic promastigotes we identify a meshwork of 44 nm long, fusiform filaments. These filaments are not seen in noninfective stages of the parasite. Replica-staining immunocytochemistry with monoclonal antibody against infective metacyclic lipophosphoglycan shows a uniform distribution of protein A-colloidal gold complexes over the cell surface. Thin sections show that acquisition of the high molecular weight lipophosphoglycan is reflected in a thicker glycocalyx. Conventional freeze-fracture shows that in infective metacyclic promastigotes there is a reversal of the partition of intramembrane particles--an additional morphological marker for the infective developmental stage. We hypothesize that the fusiform filaments represent metacyclic developmental lipophosphoglycan.     

Identification and purification of membrane and soluble forms of the major surface protein of Leishmania promastigotes

A major integral membrane glycoprotein of 63 kDa (p63), present at 500,000 copies/cell, was found on the surface of Leishmania major LEM 513 promastigotes. This protein was labeled either by surface iodination of the cells or by metabolic incorporation of [35S]methionine. Peptide maps of the proteins labeled by the two procedures were identical. Protein p63 was purified in three steps: extraction and phase separation in the nonionic detergent Triton X-114, chromatography on DEAE-cellulose, and finally chromatography on a Mono-Q column. The carbohydrate content as well as the concanavalin A receptor activity were characterized. A hydrophilic form of p63 was generated during the purification of the protein. This form was not derived by proteolysis from the amphiphilic protein found in the membrane, but may have been generated by the hydrolysis of a lipid containing myristyl residue(s) anchoring the protein in the membrane.     

Isolation of infective promastigotes of Leishmania major from long-term culture by cocultivation with macrophage cell line.

Research on Leishmania-macrophage interaction is mainly focused on the impact of the parasite on macrophages and several known virulent factors have been described. Furthermore, studies on macrophage revealed several defense mechanisms including various cytokines which are released by macrophages to defend against parasite. In the present study, a new aspect of this interaction was evaluated: parasite characteristics, which emerge when they were cocultivated with macrophage. Two promastigote characteristics, survival at high temperature (32 degrees C) and infectivity rate were the focus of this study. In this study, an in vitro coculture model for promastigotes with macrophage cell line, J774 A1, was introduced using a cell culture chamber system which separates both cell types by a microporous polycarbonate membrane. After 5-7 days of coculturing at 32 degrees C, a few promastigotes survived longer than control group. Once this population of parasite was cultured at optimal temperature (26 degrees C), the emerged new clone was much more infective for J774 A1 cell line in comparison with the original one. Having this system and using the new clone of promastigotes, parasite infectivity rate was raised from 1-2% of original clone to 35-45%. Using this new introduced technique, infective promastigotes were isolated from 9 month old frequently sub-cultured clone of Leishmania major. This coculturing system allows investigators to prepare infective promastigotes from the frequently cultured parasites. Molecular and biochemical mechanisms of this phenomenon need to be investigated.     

Cell surface carbohydrate of Leishmania mexicana amazonensis: differences between infective and non-infective forms

The cell surface carbohydrates of Leishmania mexicana amazonensis (amastigotes and promastigotes, both infective and non-infective forms) were comparatively analyzed by agglutination assay employing 28 highly purified lectins, and by binding assay using 125I-labeled lectins. Among the D-GalNAc binding lectins, Bandeiraea simplicifolia-I, Dolichos biflorus, Phaseolus vulgaris and Glycine max were highly specific for the amastigotes, while that from Maclura aurantiaca selectively agglutinated promastigotes. The lectins from Wistaria floribunda, Phaseolus lunatus (D-GalNAc), Arachis hypogaea (D-Gal) and Triticum vulgaris (D-GlcNAc) were selective for the infective forms (both amastigotes and promastigotes), not reacting with the non-infective ones. Conversely, no parasite agglutination occurred with the L-fucose binding lectins Lotus tetragonolobus and Ulex europaeus-I. Binding studies with 125I-labeled lectins from Wistaria floribunda, Triticum vulgaris and Arachis hypogaea were performed to find whether unagglutinated non-infective promastigotes might have receptors for these lectins, in which case absence of agglutination could be due to a peculiar arrangement of the receptors. These assays essentially confirmed the selectivity, demonstrated in the agglutination assays of these lectins for the infective promastigotes.     

The major surface protein of Leishmania promastigotes is a protease

The major surface protein of Leishmania promastigotes is evolutionarily conserved and is found in isolates of L. donovani, L. major, L. tropica, L. mexicana, and L. braziliensis. The data provided in this communication demonstrate that in L. major this integral membrane protein is a protease, which we now designate promastigote surface protease. The enzyme has an alkaline pH optimum and is active both in its detergent-solubilized form and at the surface of living or fixed promastigotes. A water-soluble form of promastigote surface protease is obtained following digestion with the phospholipase C responsible for the release of the variant surface glycoprotein of Trypanosoma brucei. Possible biological functions of promastigote surface protease during the life cycle of Leishmania parasites are discussed.     

Expression of the major surface glycoprotein of Leishmania donovani chagasi in virulent and attenuated promastigotes

Using both hamster and mouse models of infection, we documented that the virulence of Leishmania donovani chagasi promastigotes decreases over time, when parasites are maintained in long term culture after isolation from an infected animal. Concomitant with this loss of virulence is a marked decrease in amount of the major promastigote surface glycoprotein, gp63, present in promastigotes. The latter was shown by a decrease in binding of polyclonal anti-gp63 serum to attenuated (cultivated long term) as compared to virulent (recently isolated) promastigotes, using immunofluorescence and Western blot assays. Binding of Con A to promastigote glycoproteins, separated by SDS-PAGE, documented a similar decrease. An alteration in the mechanism of promastigote attachment to macrophages was also noted: purified gp63 inhibited attachment of virulent promastigotes to human monocyte-derived macrophages, but it did not affect the attachment of attenuated promastigotes. Northern blot analysis showed that, despite marked differences in the amount of gp63 protein, the quantity of gp63 RNA was comparable in attenuated and virulent promastigotes. However, virulent promastigotes contained two major gp63 RNA species of 3.0 and 2.7 kb, whereas attenuated promastigotes had one predominant gp63 RNA of 2.7 kb and only minor amounts of 3.0 kb RNA. Thus, the decrease in gp63 expression in attenuated, contrasted to virulent, promastigotes is associated with qualitative, but not quantitative, differences in the gp63 messenger RNA.     

Leishmania braziliensis: cell surface differences in promastigotes of pathogenic and nonpathogenic strains

A comparative study of cell surface characteristics of pathogenic and nonpathogenic promastigotes of Leishmania braziliensis, NR and LBY strains, respectively, was carried out by means of concanavalin A agglutination and labeling with concanavalin A-fluorescein isothiocyanate, concanavalin A-ferritin, and cationized ferritin. Cytochemical examination showed cell surface differences in lectin receptors and negative charge moieties in the two strains of L. braziliensis. The pathogenic NR strain agglutinated with low concentrations of concanavalin A and presented abundant lectin-binding and cationized ferritin-binding surface labeling. The nonpathogenic LBY strain neither agglutinated when incubated with concanavalin A, bound lectins, or cationized ferritin at the cell surface.     

Changing surface carbohydrate configurations during the growth of Leishmania major.

Surface carbohydrates of leishmanial promastigotes change during their growth cycle. These changes were monitored in a cloned line of Leishmania major in 2 media. A freshly isolated virulent strain was also examined. Infectivity, surface sugar moieties, and released glycoconjugates (EF) were examined and compared during the growth cycle. When promastigotes of the same clone were grown in different media, their lectin-mediated agglutination profiles were dissimilar, and both quantitative and qualitative variation was seen in the antigenic glycoconjugates released into the media. When labeled with fluorescent lectins, the virulent strain showed no loss of galactose, an increase of N-acetylglucosamine, and a midcycle decrease of N-acetylgalactosamine. Promastigotes of this strain were infective to hamsters throughout the growth cycle. The results presented indicate that culture medium components regulate carbohydrate surface configurations and, thereby, antigenic expression. Infectivity of the virulent strain was not dependent on the expression of a single surface carbohydrate.     

Phenotypic diversity of cloned lines of Leishmania major promastigotes

In vitro cultured promastigotes of virulent (V) and avirulent (A) cloned lines of Leishmania major, and the parental isolate LRC-L137, were examined with respect to morphology, cell size, growth rate, and apparent DNA content. Growth rates of all lines were comparable and both virulent (V121, LRC-L137) and avirulent parasites (A12, A52, A59) exhibited a progressive decrease in apparent DNA content with time in culture, as measured by incorporation of Hoechst Dye 33342. The four cloned lines and the parental isolate showed differences in the content of morphological variants and in the mean body length. Morphologically, there were similarities between A12 and A52 and between A59 and V121. Promastigote populations were also examined for the expression of the target antigen of a previously characterized monoclonal antibody, WIC-79.3. This antibody binds to a membrane antigen that is also present in culture supernatants of Leishmania of A1 serotype. Three different assays with culture supernatants all showed that V121, A59, and A12 were high producers with LRC-L137 and A52, low producers. Similar variation in expression of the 79.3 target antigen was detected in intact organisms of the various lines by immunofluorescence with flow cytometry. No simple correlation was found between the expression or release of the WIC-79.3 target antigen and virulence. The virulence or avirulence of all cloned lines for BALB/c mice remained stable. The data are discussed in terms of differentiation stages of L. major promastigotes and the continuing search for morphological and biochemical markers of virulence.     

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

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

Activity of an engineered synthetic killer peptide on Leishmania major and Leishmania infantum promastigotes

This study was undertaken to analyze the effect of an engineered, killer decapeptide (KP) on Leishmania major and Leishmania infantum promastigotes. The KP was synthesized on the basis of the sequence of a recombinant, single-chain anti-idiotypic antibody acting as a functional internal image of a yeast killer toxin. The evaluation of in vitro inhibitory activity of KP on L. major and L. infantum, release of intracellular green fluorescent protein (GFP) molecules by L. major, DNA fragmentation, and ultrastructural analysis (TEM) of L. infantum upon KP treatment were performed. KP presented antiproliferative and leishmanicidal activity with LC(50)/1 day of 58 and 72 microM for L. major and L. infantum, respectively. A dose-dependent decrease in proliferation and increase of killing of promastigotes was seen after KP treatment. No DNA fragmentation in L. infantum promastigotes or release of intracellular GFP molecules on peptide treatment of a GFP expressing L. major clone was demonstrated. Moreover the plasma-membrane was not disrupted, but, by TEM analysis, intracellular damage was observed.     

Population changes in Leishmania chagasi promastigote developmental stages due to serial passage

Leishmania chagasi causes visceral leishmaniasis, a potentially fatal disease of humans. Within the sand fly vector, L. chagasi replicates as promastigotes which undergo complex changes in morphology as they progress from early stage procyclic promastigotes, to intermediate stage leptomonad and nectomonad promastigotes, and ultimately to terminal stage metacyclic promastigotes that are highly infective to vertebrates. This developmental progression is largely recapitulated in vitro using axenic promastigote cultures that have been passaged only a few times. Within a single passage (which takes about a week), axenic cultures progress from logarithmic to stationary growth phases; parasites within those growth phases progress from stages that do not have metacyclic cell properties to ones that do. Interestingly, repeated serial passage of promastigote cultures will result in cell populations that exhibit perturbations in developmental progression, in expression levels of surface macromolecules (major surface protease, MSP, and promastigote surface antigen, PSA), and in virulence properties, including resistance to serum lysis. Experiments were performed to determine whether there exists a direct relationship between promastigote developmental form and perturbations associated with repeated serial passage. Passage 2 to passage 4 L. chagasi cultures at stationary growth phase were predominately (>85%) comprised of metacyclic promastigotes and exhibited high resistance to serum lysis and high levels of MSP and PSA. Serial passaging 8, or more, times resulted in a stationary phase population that was largely (>85%) comprised of nectomonad promastigotes, almost completely devoid (<2%) of metacyclic promastigotes, and that exhibited low resistance to serum lysis and low levels of MSP and PSA. The study suggests that the loss of particular cell properties seen in cells from serially passaged cultures is principally due to a dramatic reduction in the proportion of metacyclic promastigotes. Additionally, the study suggests that serially passaged cultures may be a highly enriched source of nectomonad-stage promastigotes, a stage that has largely been characterized only in mixtures containing other promastigote forms.     

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.     

CR1, the C3b receptor, mediates binding of infective Leishmania major metacyclic promastigotes to human macrophages

The role of complement receptors on monocyte derived human macrophages in phagocytosis of infective (MP) and noninfective (LP) developmental stages of Leishmania major promastigotes was studied. We compared binding of these specific developmental stages to MO after preincubation in fresh or heat-inactivated serum. Although LP do not require fresh serum for attachment, MP were dependent on serum C opsonization for entry. Inhibition of CR1 substantially abolished binding of the infective MP. In contrast, inhibition of iC3bR (CR3 and p150,95) had no effect on MP binding. Inhibition of both iC3bR, however, did block binding of nonopsonized LP. Attachment of LP to CR3 was blocked by fluid phase addition of mAb OKM1 and M1/70, which inhibit complement-independent binding to CR3, but not by mAb OKM10 which inhibits iC3b binding to this receptor. After fresh serum pretreatment of LP, however, only simultaneous inhibition of CR3 and CR1 effectively blocked their attachment. Addition of mannan did not inhibit attachment of either promastigote stage. Both opsonized and nonopsonized LP trigger a respiratory burst in MO, possibly via the C independent site in CR3, whereas the CR1-mediated uptake of MP does not generate a respiratory burst. The use of this receptor by MP may facilitate their subsequent intracellular survival.     

Preparation of highly infective Leishmania promastigotes by cultivation on SNB-9 biphasic medium

Protozoan hemoflagellates Leishmania are causative agents of leishmaniases and an important biological model for study of host-pathogen interaction. A wide range of methods of Leishmania cultivation on both biphasic and liquid media is available. Biphasic media are considered to be superior for initial isolation of the parasites and obtaining high promastigote infectivity; however, liquid media are more suitable for large-scale experiments. The aim of the present study was the adaptation and optimization of the cultivation of Leishmania promastigotes on a biphasic SNB-9 (saline-neopeptone-blood 9) medium that was originally developed for Trypanosoma cultivation and combines the advantages of biphasic and liquid media. SNB-9 medium is characterized with a large volume of the liquid phase, which facilitates the manipulation with the culture and provides parasite yields comparable to parasite yields on such liquid medium as Schneider's Insect Medium. We demonstrate that SNB-9 very considerably surpasses Schneider's Insect Medium in in vitro infectivity of the parasites. Additionally, we show that the ratio of apoptotic parasites, which are important for the infectivity of the inoculum, in Leishmania culture in SNB-9 is higher than in Leishmania culture in Schneider's Insect Medium. Thus, we demonstrate that the cultivation of Leishmania on SNB-9 reliably yields highly infective promastigotes suitable for experimental infection.     

Effect of hyper-osmotic stress on alanine content of Leishmania major promastigotes

Earlier studies showed that Leishmania major promastigotes are sensitive to osmotic conditions. A reduction in osmolality caused the cells to shorten and to rapidly release most of their large internal pool of alanine. In this study some effects of hyper-osmotic stress were examined. An increase in osmolality of the culture medium from 308 to 625 mOsm/kg caused only a small decrease in growth rate. When cells grown in the usual culture medium (308 mOsm/kg) were washed, resuspended in iso-osmotic buffer, and subjected to acute hyper-osmotic stress by addition of mannitol, the alanine content increased even in the absence of exogenous substrate. Promastigotes, depleted of alanine by a 5-min exposure to hypo-osmotic conditions, also synthesized alanine when resuspended in iso-osmotic buffer. Washed cells resuspended in iso-osmotic buffer consume their internal pool of alanine under aerobic conditions. Rates of consumption decreased on addition of mannitol, becoming zero at about 440 mOsm/kg. At higher osmolalities, alanine synthesis occurred. To estimate whether proteolysis could account for alanine synthesis in the absence of exogenous substrate, cells that had been grown with [1-14C]leucine were washed and resuspended under hypo-, iso-, and hyper-osmotic conditions and the amounts of 14CO2 and 14C-labelled peptides released in 1 h were measured. Little proteolysis occurred under these conditions, but the possibility that proteolysis was the source of the alanine increase, observed in response to hyper-osmotic stress, cannot be ruled out.     

Purification and biochemical characterization of two novel antigens from Leishmania major promastigotes

The identification and characterization of antigens that elicit human T cell responses is an important step toward understanding of Leishmania major infection and ultimately in the development of a vaccine. Micropreparative SDS-PAGE followed by electrotransfer to a PVDF membrane and elution of proteins from the PVDF, was used to separate 2 novel proteins from L. major promastigotes, which can induce antibodies of the IgG2a isotype in mice and also are recognized by antisera of recovered human cutaneous leishmaniasis subjects. Fractionation of the crude extract of L. major revealed that all detectable proteins of interest were present within the soluble Leishmania antigens (SLA). Quantitation of these proteins showed that their expression in promastigotes is relatively very low. Considering the molecular weight, immunoreactivity, chromatographic and electrophoretic behavior in reducing and non-reducing conditions, these proteins are probably 2 isoforms of a single protein. A digest of these proteins was resolved on Tricine-SDS-PAGE and immunoreactive fragments were identified by human sera. Two immunoreactive fragments (36.4 and 34.8 kDa) were only generated by endoproteinase Glu-C treatment. These immunoreactive fragments or their parent molecules may be ideal candidates for incorporation in a cocktail vaccine against cutaneous leishmaniasis.     

Identification of a surface membrane proton-translocating ATPase in promastigotes of the parasitic protozoan Leishmania donovani.

ATPase activities were measured in surface membranes and mitochondria isolated from promastigotes of the parasitic protozoan Leishmania donovani. The two enzymes were differentiated on the basis of pH optima, inhibitor sensitivity and by immunochemical methods. The surface-membrane (SM-) ATPase had an activity of 100 nmol/min per mg of protein, which was optimal at pH 6.5. The enzyme was Mg2+-dependent, partially inhibited by Ca2+, and unaffected by Na+ or K+. The SM-ATPase was inhibited by orthovanadate, NN'-dicyclohexylcarbodi-imide, and N-ethylmaleimide [IC50 (concentration causing half-maximal inhibition) 7.5, 25 and 520 microM respectively]; however, it was unaffected by ouabain, azide or oligomycin. The SM-ATPase demonstrated a Km of 1.05 mM and a Vmax. of 225 nmol/min per mg of protein. Moreover, fine-structure cytochemical results demonstrated that the SM-ATPase was localized to the cytoplasmic lamina of the parasite SM. A method was devised for the isolation of SM-derived vesicles. These were used to demonstrate the proton-pumping capacity of the SM-ATPase. Cumulatively, these results constitute the first demonstration of a surface-membrane proton-translocating ATPase in a parasitic protozoan.