Glycoconjugate structures of parasitic protozoa

Glycoconjugates are abundant and ubiquitious on the surface of many protozoan parasites. Their tremendous diversity has implicated their critical importance in the life cycle of these organisms. This review highlights our current knowledge of the major glycoconjugates, with particular emphasis on their structures, of representative protozoan parasites, including Leishmania, Trypanosoma, Giardia, Plasmodia, and others.     

Synthetic neoglycoconjugates of cell-surface phosphoglycans of Leishmania as potential anti-parasite carbohydrate vaccines

Leishmania are a genus of sandfly-transmitted protozoan parasites that cause a spectrum of debilitating and often fatal diseases in humans throughout the tropics and subtropics. During the parasite life cycle, Leishmania survive and proliferate in highly hostile environments. Their survival strategies involve the formation of an elaborate and dense cell-surface glycocalyx composed of diverse stage-specific glycoconjugates that form a protective barrier. Phosphoglycans constitute the variable structural and functional domain of major cell-surface lipophosphoglycan and secreted proteophosphoglycans. In this paper, we discuss structural aspects of various phosphoglycans from Leishmania with the major emphasis on the chemical preparation of neoglycoconjugates (neoglycoproteins and neoglycolipids) based on Leishmania lipophosphoglycan structures as well as the immunological evaluation for some of them as potential anti-leishmaniasis vaccines.     

The leishmanial lipophosphoglycan: a multifunctional molecule

A striking characteristic of leishmanial parasites is their ability to avoid destruction in hostile environments throughout their life cycle. To survive, the parasites must have evolved specialized molecules. One such molecule that has received considerable attention is an unusual glycoconjugate called lipophosphoglycan. The macromolecule is the major cell surface glycoconjugate of all Leishmania promastigotes. This minireview summarizes current information on the structure and possible functions of this intriguing molecule.     

Metabolic changes in glucose transporter-deficient Leishmania mexicana and parasite virulence

Leishmania mexicana are parasitic protozoa that express a variety of glycoconjugates that play important roles in their biology as well as the storage carbohydrate beta-mannan, which is an essential virulence factor for survival of intracellular amastigote forms in the mammalian host. Glucose transporter null mutants, which are viable as insect form promastigotes but not as amastigotes, do not take up glucose and other hexoses but are still able to synthesize these glycoconjugates and beta-mannan, although at reduced levels. Synthesis of these carbohydrate-containing macromolecules could be accounted for by incorporation of non-carbohydrate precursors into carbohydrates by gluconeogenesis. However, the significantly reduced level of the virulence factor beta-mannan in the glucose transporter null mutants compared with wild-type parasites may contribute to the non-viability of these null mutants in the disease-causing amastigote stage of the life cycle.     

Characterisation of a developmentally regulated amino acid transporter gene from Leishmania amazonensis

The metabolism of protozoan parasites of the Leishmania genus is strongly based on amino acid consumption, but little is known about amino acid uptake in these organisms. In the present work, we identified a Leishmania amazonensis gene (La-PAT1) encoding a putative amino acid transporter that belongs to the amino acid/auxin permease family, a group of H(+)/amino acid symporters. This single copy gene is upregulated in amastigotes, the life cycle stage found in the mammalian host. La-PAT1 putative orthologous sequences were identified in Leishmania infantum, Leishmania donovani, Leishmania major and Trypanosoma.     

Deciphering the Leishmania exoproteome: what we know and what we can learn

Parasitic protozoa of the genus Leishmania are the causative agents of leishmaniasis. Survival and transmission of these parasites in their different hosts require membrane-bound or extracellular factors to interact with and modify their host environments. Over the last decade, several approaches have been applied to study all the extracellular proteins exported by an organism at a particular time or stage in its life cycle and under defined conditions, collectively termed the secretome or the exoproteome. In this review, we focus on emerging data shedding light on the secretion mechanisms involved in the production of the Leishmania exoproteome. We also describe other methodologies currently available that could be used to analyse the Leishmania exoproteome. Understanding the complexity of the Leishmania exoproteome is a key component to elucidating the mechanisms used by these parasites for exporting proteins to the extracellular space during its life cycle. Given the importance of extracellular factors, a detailed knowledge of the Leishmania exoproteome may provide novel targets for rational drug design and/or a source of antigens for vaccine development.     

A systematic analysis of the early transcribed membrane protein family throughout the life cycle of Plasmodium yoelii

The early transcribed membrane proteins (ETRAMPs) are a family of small, highly charged transmembrane proteins unique to malaria parasites. Some members of the ETRAMP family have been localized to the parasitophorous vacuole membrane that separates the intracellular parasite from the host cell and thus presumably have a role in host-parasite interactions. Although it was previously shown that two ETRAMPs are critical for rodent malaria parasite liver-stage development, the importance of most ETRAMPs during the parasite life cycle remains unknown. Here, we comprehensively identify nine new etramps in the genome of the rodent malaria parasite Plasmodium yoelii, and elucidate their conservation in other malaria parasites. etramp expression profiles are diverse throughout the parasite life cycle as measured by RT-PCR. Epitope tagging of two ETRAMPs demonstrates protein expression in blood and liver stages, and reveals differences in both their timing of expression and their subcellular localization. Gene targeting studies of each of the nine uncharacterized etramps show that two are refractory to deletion and thus likely essential for blood-stage replication. Seven etramps are not essential for any life cycle stage. Systematic characterization of the members of the ETRAMP family reveals the diversity in importance of each family member at the interface between host and parasite throughout the developmental cycle of the malaria parasite.     

Inhibition of the spontaneous apoptosis of neutrophil granulocytes by the intracellular parasite Leishmania major

Macrophages are the major target cell population of the obligate intracellular parasites LEISHMANIA: Although polymorphonuclear neutrophil granulocytes (PMN) are able to internalize Leishmania promastigotes, these cells have not been considered to date as host cells for the parasites, primarily due to their short life span. In vitro coincubation experiments were conducted to investigate whether Leishmania can modify the spontaneous apoptosis of human PMN. Coincubation of PMN with Leishmania major promastigotes resulted in a significant decrease in the ratio of apoptotic neutrophils as detected by morphological analysis of cell nuclei, TUNEL assay, gel electrophoresis of low m.w. DNA fragments, and annexin V staining. The observed antiapoptotic effect was found to be associated with a significant reduction of caspase-3 activity in PMN. The inhibition of PMN apoptosis depended on viable parasites because killed Leishmania or a lysate of the parasites did not have antiapoptotic effect. L. major did not block, but rather delayed the programmed cell death of neutrophils by approximately 24 h. The antiapoptotic effect of the parasites could not be transferred by the supernatants, despite secretion of IL-8 by PMN upon coculture with L. major. In vivo, intact parasites were found intracellularly in PMN collected from the skin of mice 3 days after s.c. infection. This finding strongly suggests that infection with Leishmania prolongs the survival time of neutrophils also in vivo. These data indicate that Leishmania induce an increased survival of neutrophil granulocytes both in vitro and in vivo.     

Topoisomerases of kinetoplastid parasites as potential chemotherapeutic targets

The protozoan parasites Trypanosoma, Leishmania and Crithidia, which belong to the order kinetoplastidae, emerge from the most ancient eukaryotic lineages. The diversity found in the life cycle of these organisms must be directed by genetic events, wherein topoisomerases play an important role in cellular processes affecting the topology and organization of intracellular DNA. Topoisomerases are valuable as potential drug targets because they have indispensable function in cell biology. This review summarizes what is known about topoisomerase genes and proteins of kinetoplastid parasites and the roles of these enzymes as targets for therapeutic agents.     

The amastigote forms of Leishmania are experts at exploiting host cell processes to establish infection and persist

Leishmania are dimorphic protozoan parasites that live as flagellated forms in the gut of their sandfly vector and as aflagellated forms in their mammalian hosts. Although both parasite forms can infect macrophages and dendritic cells, they elicit distinct responses from mammalian cells. Amastigotes are the parasites forms that persist in the infected host; they infect cells recruited to lesions and disseminate the infection to secondary sites. In this review I discuss studies that have investigated the mechanisms that Leishmania amastigotes employ to harness the host cell's response to infection. It should be acknowledged that our understanding of the mechanisms deployed by Leishmania amastigotes to modulate the host cell's response to infection is still rudimentary. Nonetheless, the results show that amastigote interactions with mammalian cells promote the production of anti-inflammatory cytokines such as IL-10 and TGF-beta while suppressing the production of IL-12, superoxide and nitric oxide. An underlying issue that is considered is how these parasites that reside in sequestered vacuolar compartments target host cell processes in the cytosol or the nucleus; does this occur through the release of parasite molecules from parasitophorous vacuoles or by engaging and sustaining signalling pathways throughout the course of infection?     

Transmission stages of Plasmodium: does the parasite use the one same signal, provided both by the host and the vector, for gametocytogenesis and sporozoite maturation?

Among the microorganisms that strictly depend upon other organisms (hosts or vectors) for achieving their life cycle, protozoan and metazoan parasites have been often primarily distinguished through the major pathogenic processes they could induce. A variety of different mechanisms linked to parasitism can indeed systemically (e.g. Plasmodium falciparum) or locally (e.g. Toxoplasma gondii) induce important alterations of tissue homeostasis. But more than obvious pathogenicity, it is the capacity to be transmitted that is essential for parasite survival and there is increasing evidence that certain parasites can achieve their life cycle to the point of transmission in the absence of clinically detectable processes. For this, constitutive microenvironments of the host or vector can be exploited. Moreover, parasites are sometimes able to highjack effectors of the host's immune response towards conditioning the microenvironments which are permissive to differentiation of transmissible developmental stages. Based on a few examples taken from studies on the transmission stages of Leishmania, Toxoplasma and Plasmodium, we have here attempted to formulate a few hypothesis on the biology of the transmission stages of P. falciparum, i.e. on gametocytogenesis and sporozoite maturation. As discussants, we may have been somewhat dwarfed by issues evoked by the organizers of this meeting in the title of the session, i.e. 'Vector-parasite-man interactions'!... In reaction, we may have taken refuge in somewhat over-selective comments, biased by the objects of our personal research....     

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.     

Leishmania–host interactions: what has imaging taught us?

Leishmania parasites are well adapted to initiate infection, resist the onslaught of innate immunity and achieve a state of long-lived persistence. In recent years, the tools available to study these interactions have developed enormously and have become much more widely available. Confocal microscopy, live cell imaging, whole animal imaging and intra-vital 2-photon now complement and extend the classical light and electron microscopical techniques. Coupled with approaches to generate transgenic parasites that express imaging friendly reporter proteins, these tools are making the full breadth of the life cycle accessible to imaging studies. New insights into the life history of these highly successful parasites are emerging with increasing frequency, and often with startling clarity and visual drama. In this short review, we focus on how this new generation of imaging-based research tools has augmented our understanding of the complex interplay that occurs between Leishmania and the cells that it infects in mammalian hosts.     

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.     

Phosphoglycan repeat-deficient Leishmania mexicana parasites remain infectious to macrophages and mice

The human pathogen Leishmania synthesizes phosphoglycans (PGs) formed by variably modified phosphodisaccharide [6-Galbeta1-4Manalpha1-PO(4)] repeats and mannooligosaccharide phosphate [(Manalpha1-2)(0-5)Manalpha1-PO(4)] caps that occur lipid-bound on lipophosphoglycan, protein-bound on proteophosphoglycans, and as an unlinked form. PG repeat synthesis has been described as essential for survival and development of Leishmania throughout their life cycle, including for virulence to the mammalian host. In this study, this proposal was investigated in Leishmania mexicana using a spontaneous mutant that was fortuitously isolated from an infected mouse, and by generating a lmexlpg2 gene deletion mutant (Deltalmexlpg2), that lacks a Golgi GDP-Man transporter. The spontaneous mutant lacks PG repeats but synthesizes normal levels of mannooligosaccharide phosphate caps, whereas the Deltalmexlpg2 mutant is deficient in PG repeat synthesis and down-regulates cap expression. In contrast to expectations, both L. mexicana mutants not only retain their ability to bind to macrophages, but are also indistinguishable from wild type parasites with respect to colonization of and multiplication within host cells. Moreover, in mouse infection studies, the spontaneous L. mexicana repeat-deficient mutant and the Deltalmexlpg2 mutant showed no significant difference to a wild type strain with respect to the severity of disease caused by these parasites. Therefore, at least in Leishmania mexicana, PG repeat synthesis is not an absolute requirement for virulence.     

Leishmania major: clathrin and adaptin complexes of an intra-cellular parasite

To investigate the role of clathrin-mediated trafficking during the Leishmania lifecycle, open reading frames encoding clathrin heavy chain and the beta-adaptins, major components of the adaptor complexes, have been analysed both in silico and experimentally. The Leishmania genome encodes three beta-adaptins, which arose at a time predating speciation of these divergent trypanosomatids. Unlike Trypanosoma brucei, both clathrin heavy chain and beta-adaptin1 are constitutively expressed throughout the Leishmania life cycle. Clathrin relocalises in amastigotes relative to promastigotes, consistent with developmental alterations to the morphology of the endo-membrane system.     

Leishmania major CorA-like magnesium transporters play a critical role in parasite development and virulence

Establishment of infection by Leishmania depends on the transformation of the invading metacyclic promastigotes into the obligatory intracellular amastigotes, and their subsequent survival in the macrophage phagolysosome, which is low in magnesium. We show that two Leishmania major proteins designated MGT1 and MGT2, which play a critical role in these processes, belong to the two-transmembrane domain (2-TM-GxN) cation transporter family and share homology with the major bacterial magnesium transporter CorA. Although both are present in the endoplasmic reticulum throughout the life cycle of the parasite, MGT1 is more highly expressed in the infectious metacyclic parasites, while MGT2 is enriched in the immature procyclic stages. The two proteins, although predicted to be structurally similar, have features that suggest different regulatory or gating mechanisms. The two proteins may also be functionally distinct, since only MGT1 complements an Escherichia coliΔCorA mutant. In addition, deletion of one mgt1 allele from L. major led to increased virulence, while deletion of one allele of mgt2 resulted in slower growth and total loss of virulence in vitro and in vivo. This loss of virulence may be due to an impaired transformation of the parasites into amastigotes. Deletion of both mgt1 alleles in the hemizygous MGT2 knockdown parasites reversed the growth defect and partially restored virulence. Our data indicate that the MGTs play a critical role in parasite growth, development and virulence.     

Leishmania parasites (Kinetoplastida: Trypanosomatidae) reversibly inhibit visceral muscle contractions in hemimetabolous and holometabolous insects

Female sand flies can acquire protozoan parasites in the genus Leishmania when feeding on an infected vertebrate host. The parasites complete a complex growth cycle in the sand fly gut until they are transmitted by bite to another host. Recently, a myoinhibitory peptide was isolated from Leishmania major promastigotes. This peptide caused significant gut distension and reversible, dose-dependent inhibition of spontaneous hindgut contractions in the enzootic sand fly vector, Phlebotomus papatasi. The current study further characterizes myoinhibitory activity in L. major and other kinetoplastid parasites, using the P. papatasi hindgut and other insect organ preparations. Myoinhibitory activity was greatest in cultured promastigotes and in culture medium in late log-phase and early stationary-phase, coinciding with development of infective Leishmania morphotypes in the sand fly midgut. L. major promastigote lysates inhibited spontaneous contractions of visceral muscle preparations from hemimetabolous (Blattaria and Hemiptera) and holometabolous (Diptera) insects. Inhibition of visceral muscle contractions in three insect orders indicates a conserved mode of action. Myoinhibitory activity was detected also in Leishmania braziliensis braziliensis, a Sudanese strain of Leishmania donovani, and the kinetoplastid parasite Leptomonas seymouri. Protozoan-induced myoinhibition mimics the effect of insect myotropins. Inhibiting host gut contractions protects Leishmania parasites from being excreted after blood meal and peritrophic matrix digestion, allowing development and transmission of infective forms.