Role of host lysosomal associated membrane protein (LAMP) in Trypanosoma cruzi invasion and intracellular development

Trypanosoma cruzi host cell entry depends on lysosomes for the formation of the parasitophorous vacuole. Lysosome internal surface is covered by two major proteins, highly sialilated, Lysosome Associated Membrane Proteins 1 and 2. T. cruzi, on the other hand, needs to acquire sialic acid from its host cell through the activity of trans-sialidase, an event that contributes to host cell invasion and later for parasite vacuole escape. Using LAMP1/2 knock out cells we were able to show that these two proteins are important for T. cruzi infection of host cells, both in entrance and intracellular development, conceivably by being the major source of sialic acid for T. cruzi.     

The autophagic pathway is a key component in the lysosomal dependent entry of Trypanosoma cruzi into the host cell

The etiologic agent of Chagas disease, Trypanosoma cruzi, infects mammalian cells activating a signal transduction cascade that leads to the formation of its parasitophorous vacuole. Previous works have demonstrated the crucial role of lysosomes in the establishment of T. cruzi infection. In this work we have studied the possible relationship between this parasite and the host cell autophagy. We show, for the first time, that the vacuole containing T. cruzi (TcPV) is decorated by the host cell autophagic protein LC3. Furthermore, live cell imaging experiments indicate that autolysosomes are recruited to parasite entry sites. Interestingly, starvation or pharmacological induction of autophagy before infection significantly increased the number of infected cells whereas inhibitors of this pathway reduced the invasion. In addition, the absence of Atg5 or the reduced expression of Beclin1, two proteins required at the initial steps of autophagosome formation, limited parasite entry and reduced the association between TcPV and the classical lysosomal marker Lamp-1. These results indicate that mammalian autophagy is a key process that favors the colonization of T. cruzi in the host cell.     

Trans-sialidase and mucins of Trypanosoma cruzi: an important interplay for the parasite

A dense glycocalix covers the surface of Trypanosoma cruzi, the agent of Chagas disease. Sialic acid in the surface of the parasite plays an important role in the infectious process, however, T. cruzi is unable to synthesize sialic acid or the usual donor CMP-sialic acid. Instead, T. cruzi expresses a unique enzyme, the trans-sialidase (TcTS) involved in the transfer of sialic acid from host glycoconjugates to mucins of the parasite. The mucins are the major glycoproteins in the insect stage epimastigotes and in the infective trypomastigotes. Both, the mucins and the TcTS are anchored to the plasma membrane by a glycosylphosphatidylinositol anchor. Thus, TcTS may be shed into the bloodstream of the mammal host by the action of a parasite phosphatidylinositol-phospholipase C, affecting the immune system. The composition and structure of the sugars in the parasite mucins is characteristic of each differentiation stage, also, interstrain variations were described for epimastigote mucins. This review focus on the characteristics of the interplay between the trans-sialidase and the mucins of T. cruzi and summarizes the known carbohydrate structures of the mucins.     

Trypanosoma cruzi: mechanisms for entry into host cells

Infective trypomastigote stages of the obligate intracellular protozoan parasite Trypanosoma cruzi are capable of entering virtually any mammalian cell in vitro. Entry is a complex process, involving initial parasite attachment to surface moieties of the target cell, internalization of the parasite via formation of a vacuole, and finally disruption of the vacuolar membrane to permit access of the parasite to the host cell cytoplasm. Attachment requires parasite metabolic energy. At sites of parasite entry recruitment of host cell lysosomes may occur, and lysosomal membrane components contribute prominently to formation of the parasitophorous vacuole. Parasite escape from the vacuole depends upon vacuolar acidification and is mediated by the coordinated action of a parasite-derived neuramindase/trans-sialidase that is capable of desialylating host-derived vacuolar membrane constituents, and a parasite-derived trans-membrane pore-forming protein. Dissection of the entry process at both the organellar and molecular level is providing fundamental and complementary insights into microbial pathogenesis and cell biology.     

A sialidase activity in the midgut of the insect Triatoma infestans is responsible for the low levels of sialic acid in Trypanosoma cruzi growing in the insect vector

Trypanosoma cruzi expresses a unique trans-sialidase that isresponsible for the transfer of sialic acid from host glycoproteinsand glycolipids to mucin-like glycoprotein acceptors on theparasite surface. The enzyme and the sialic acid acceptors arepresent in the mammalian forms of the parasite and in the parasiteforms that grow in axenic cultures, which correspond to thedevelopmental stages found in the insect vectors. Here we showthat parasite forms growing in the vector Triatoma infestansexpress trans-sialidase in the hind gut portions of the insectHowever, the sialic acid acceptors are poorly sialylated dueto the low concentration of sialic acid donors in the gut lumenof T.infestans, which feeds exclusively on blood that is richin sialic acid donors. These low levels of sialic acid donorsare due to a novel sialidase activity present mainly in theanterior midgut with high specificity for     

The secreted kinase ROP18 defends Toxoplasma's border

Toxoplasma gondii is a highly successful parasite capable of infecting virtually all warm-blooded animals by actively invading nucleated host cells and forming a modified compartment where it replicates within the cytosol. The parasite-containing vacuole provides a safe haven, even in professional phagocytes such as macrophages, which normally destroy foreign microbes. In an effort to eliminate the parasite, the host up-regulates a family of immunity-related p47 GTPases (IRGs), which are recruited to the parasite-containing vacuole, resulting in membrane rupture and digestion of the parasite. To avoid this fate, highly virulent strains of Toxoplasma coat the external surface of their vacuole with a secretory serine/threonine kinase, known as ROP18. At this host-pathogen interface, ROP18 phosphorylates and inactivates IRGs, thereby protecting the parasite from killing. These findings reveal a novel molecular mechanism by which the parasite disarms host innate immunity.     

Trans-sialidase genes expressed in mammalian forms of Trypanosoma cruzi evolved from ancestor genes expressed in insect forms of the parasite

The trans-sialidase of Trypanosoma cruzi mammalian forms transfers sialic acids from host's cell-surface glycoconjugates to acceptor molecules on parasite cell surface. To investigate the mechanism by which the mammalian stages of Trypanosoma cruzi have acquired their trans-sialidase, we compared the nucleotide and predicted amino acid sequences of trans-sialidase genes expressed in different developmental stages and strains of Trypanosoma cruzi with the sialidase gene of Trypanosoma rangeli and the sialidase genes of the prokaryotic genera Clostridium, Salmonella, and Actinomyces. The trans-sialidase gene products of Trypanosoma cruzi have a significant degree of structural and biochemical similarity to the sialidases found in bacteria and viruses, which would hint that horizontal gene transfer occurred in Trypanosome cruzi trans-sialidase evolutionary history. The comparison of inferred gene trees with species trees suggests that the genes encoding the T. cruzi trans-sialidase of mammalian forms might be derived from genes expressed in the insect forms of the genus Trypanosome. The branching order of trees inferred from T. cruzi trans-sialidase sequences, the sialidase from Trypanosoma rangeli, and bacterial sialidases parallels the expected branching order of the species and suggests that the divergence times of these sequences are remarkably long. Therefore, a vertical inheritance from a hypothetical eukaryotic trans-sialidase gene expressed in insect forms of trypanosomes is more likely to have occurred than the horizontal gene transfer from bacteria, and thus explains the presence of this enzyme in the mammalian infective forms of Trypanosoma cruzi.Correspondence to: M.R.S. Briones     

Host microtubule plus‐end binding protein CLASP1 influences sequential steps in the Trypanosoma cruzi infection process

Mammalian cell invasion by the protozoan parasite Trypanosoma cruzi involves host cell microtubule dynamics. Microtubules support kinesin‐dependent anterograde trafficking of host lysosomes to the cell periphery where targeted lysosome exocytosis elicits remodelling of the plasma membrane and parasite invasion. Here, a novel role for microtubule plus‐end tracking proteins (+TIPs) in the co‐ordination of T. cruzi trypomastigote internalization and post‐entry events is reported. Acute silencing of CLASP1, a +TIP that participates in microtubule stabilization at the cell periphery, impairs trypomastigote internalization without diminishing the capacity for calcium‐regulated lysosome exocytosis. Subsequent fusion of the T. cruzi vacuole with host lysosomes and its juxtanuclear positioning are also delayed in CLASP1‐depleted cells. These post‐entry phenotypes correlate with a generalized impairment of minus‐end directed transport of lysosomes in CLASP1 knock‐down cells and mimic the effects ofdynactin disruption. Consistent with GSK3β acting as a negative regulator of CLASP function, inhibition of GSK3β activity enhances T. cruzi entry in a CLASP1‐dependent manner and expression of constitutively active GSK3β dampens infection. This study provides novel molecular insights into the T. cruzi infection process, emphasizing functional links between parasite‐elicited signalling, host microtubule plus‐end tracking proteins and dynein‐based retrograde transport. Highlighted in this work is a previously unrecognized role for CLASPs in dynamic lysosome positioning, an important aspect of the nutrient sensing response in mammalian cells.     

Effects of shortened host life span on the evolution of parasite life history and virulence in a microbial host-parasite system

Background  

Ecological factors play an important role in the evolution of parasite exploitation strategies. A common prediction is that, as shorter host life span reduces future opportunities of transmission, parasites compensate with an evolutionary shift towards earlier transmission. They may grow more rapidly within the host, have a shorter latency time and, consequently, be more virulent. Thus, increased extrinsic (i.e., not caused by the parasite) host mortality leads to the evolution of more virulent parasites. To test these predictions, we performed a serial transfer experiment, using the protozoan Paramecium caudatum and its bacterial parasite Holospora undulata. We simulated variation in host life span by killing hosts after 11 (early killing) or 14 (late killing) days post inoculation; after killing, parasite transmission stages were collected and used for a new infection cycle.     

Only some members of a gene family in Trypanosoma cruzi encode proteins that express both trans-sialidase and neuraminidase activities.

Trypomastigotes, the blood stage form of the human parasite Trypanosoma cruzi, contain an enzyme on their surface, trans-sialidase, which catalyses the transfer of sialic acid from host glycoconjugates to acceptors on its own cell surface. At least a subset of the sialic acid-bearing acceptor molecules are involved in parasite invasion of host cells, an essential step in the life cycle of the parasite. Another trypomastigote surface enzyme that affects host cell invasion is neuraminidase and recent evidence suggests that both trans-sialidase and neuraminidase activities may be expressed by the same proteins on the parasite surface. We describe here the isolation and expression of several members of a trans-sialidase--neuraminidase gene family from T.cruzi. One of the isolated genes does indeed encode a protein with both trans-sialidase and neuraminidase activities, while other members of the gene family encode closely related proteins that express neither enzymatic activity. Chimeric protein constructs combining different portions of active and inactive genes identified a region of the gene necessary for enzymatic activity. Sequence analysis of this portion of the gene revealed a limited number of amino acid differences between the predicted active and inactive gene products.     

Trypanosoma cruzi utilizes the host low density lipoprotein receptor in invasion

Background

Trypanosoma cruzi, an intracellular protozoan parasite that infects humans and other mammalian hosts, is the etiologic agent in Chagas disease. This parasite can invade a wide variety of mammalian cells. The mechanism(s) by which T. cruzi invades its host cell is not completely understood. The activation of many signaling receptors during invasion has been reported; however, the exact mechanism by which parasites cross the host cell membrane barrier and trigger fusion of the parasitophorous vacuole with lysosomes is not understood.

Methodology/Principal Findings

In order to explore the role of the Low Density Lipoprotein receptor (LDLr) in T. cruzi invasion, we evaluated LDLr parasite interactions using immunoblot and immunofluorescence (IFA) techniques. These experiments demonstrated that T. cruzi infection increases LDLr levels in infected host cells, inhibition or disruption of LDLr reduces parasite load in infected cells, T. cruzi directly binds recombinant LDLr, and LDLr-dependent T. cruzi invasion requires PIP2/3. qPCR analysis demonstrated a massive increase in LDLr mRNA (8000 fold) in the heart of T. cruzi infected mice, which is observed as early as 15 days after infection. IFA shows a co-localization of both LDL and LDLr with parasites in infected heart.

Conclusions/Significance

These data highlight, for the first time, that LDLr is involved in host cell invasion by this parasite and the subsequent fusion of the parasitophorous vacuole with the host cell lysosomal compartment. The model suggested by this study unifies previous models of host cell invasion for this pathogenic protozoon. Overall, these data indicate that T. cruzi targets LDLr and its family members during invasion. Binding to LDL likely facilitates parasite entry into host cells. The observations in this report suggest that therapeutic strategies based on the interaction of T. cruzi and the LDLr pathway should be pursued as possible targets to modify the pathogenesis of disease following infection.     

Soluble N‐ethylmaleimide‐sensitive factor attachment protein receptors required during Trypanosoma cruzi parasitophorous vacuole development

Trypanosoma cruzi, the etiologic agent of Chagas disease, is an obligate intracellular parasite that exploits different host vesicular pathways to invade the target cells. Vesicular and target soluble N‐ethylmaleimide‐sensitive factor attachment protein receptors (SNAREs) are key proteins of the intracellular membrane fusion machinery. During the early times of T. cruzi infection, several vesicles are attracted to the parasite contact sites in the plasma membrane. Fusion of these vesicles promotes the formation of the parasitic vacuole and parasite entry. In this work, we study the requirement and the nature of SNAREs involved in the fusion events that take place during T. cruzi infection. Our results show that inhibition of N‐ethylmaleimide‐sensitive factor protein, a protein required for SNARE complex disassembly, impairs T. cruzi infection. Both TI‐VAMP/VAMP7 and cellubrevin/VAMP3, two v‐SNAREs of the endocytic and exocytic pathways, are specifically recruited to the parasitophorous vacuole membrane in a synchronized manner but, although VAMP3 is acquired earlier than VAMP7, impairment of VAMP3 by tetanus neurotoxin fails to reduce T. cruzi infection. In contrast, reduction of VAMP7 activity by expression of VAMP7's longin domain, depletion by small interfering RNA or knockout, significantly decreases T. cruzi infection susceptibility as a result of a minor acquisition of lysosomal components to the parasitic vacuole. In addition, overexpression of the VAMP7 partner Vti1b increases the infection, whereas expression of a KIF5 kinesin mutant reduces VAMP7 recruitment to vacuole and, concomitantly, T. cruzi infection. Altogether, these data support a key role of TI‐VAMP/VAMP7 in the fusion events that culminate in the T. cruzi parasitophorous vacuole development.     

Targeting host mitochondria: A role for the Trypanosoma cruzi amastigote flagellum

Trypanosoma cruzi is the kinetoplastid protozoan parasite that causes human Chagas disease, a chronic disease with complex outcomes including severe cardiomyopathy and sudden death. In mammalian hosts, T. cruzi colonises a wide range of tissues and cell types where it replicates within the host cell cytoplasm. Like all intracellular pathogens, T. cruzi amastigotes must interact with its immediate host cell environment in a manner that facilitates access to nutrients and promotes a suitable niche for replication and survival. Although potentially exploitable to devise strategies for pathogen control, fundamental knowledge of the host pathways co‐opted by T. cruzi during infection is currently lacking. Here, we report that intracellular T. cruzi amastigotes establish close contact with host mitochondria via their single flagellum. Given the key bioenergetic and homeostatic roles of mitochondria, this striking finding suggests a functional role for host mitochondria in the infection process and points to the T. cruzi amastigote flagellum as an active participant in pathogenesis. Our study establishes the basis for future investigation of the molecular and functional consequences of this intriguing host–parasite interaction.     

Characterization of host cell-derived membrane proteins of the vacuole surrounding different intracellular forms of Trypanosoma cruzi in J774 cells. Evidence for phagocyte receptor sorting during the early stages of parasite entry.

Trypanosoma cruzi, an obligate intracellular protozoan parasite, exhibits developmental regulation of virulence. Although both noninfective epimastigote and infective trypomastigote stages of T. cruzi enter phagocytic cells via the formation of a parasitophorous vacuole (PV), only the latter developmental stages survive ingestion and perpetuate the infection. To determine whether the membrane composition of PV surrounding these different stages might contribute to differences in the outcome of infection, we identified selected membrane constituents by immunofluorescence and intracellular radioiodination, and studied their incorporation into PV. Complement receptors (CR3) are incorporated preferentially into the PV membrane surrounding serum-opsonized epimastigotes but not culture-derived metacyclic trypomastigotes. FcR are not preferentially incorporated into PV membranes unless epimastigotes or culture-derived metacyclic trypomastigotes are opsonized with anti-T. cruzi antibody. PV surrounding either parasite stage contain beta 1 integrins and lysosomal membrane glycoproteins (lgp). These results indicate that the plasma membrane glycoproteins incorporated into the surrounding PV membrane differ depending upon the stage of parasite being internalized, and that these differences reflect, at least in part, selective ligation of cell surface receptors mediating uptake. Furthermore, they imply that although virulent trypomastigote stages may avoid host cell uptake by conventional phagocytic receptors, i.e., CR3 or FcR, they do not escape fusion with an lgp-containing vacuole where they could still be exposed to lysosomal antimicrobial mechanisms.     

Enzymatically inactive trans-sialidase from Trypanosoma cruzi binds sialyl and beta-galactopyranosyl residues in a sequential ordered mechanism

Host/parasite interaction mediated by carbohydrate/lectin recognition results in the attachment to and invasion of host cells and immunoregulation, enabling parasite replication and establishment of infection. Trypanosoma cruzi, the protozoan responsible for Chagas disease, expresses on its surface a family of enzymatically active and inactive trans-sialidases. The parasite uses the active trans-sialidase for glycoprotein sialylation in an unusual trans-glycosylation reaction. Inactive trans-sialidase is a sialic acid-binding lectin that costimulates host T cells through leucosialin (CD43) engagement. The co-mitogenic effect of trans-sialidase can be selectively abrogated by N-acetyllactosamine, suggesting the presence of an additional carbohydrate binding domain for galactosides, in addition to that for sialic acid. Here we investigated the interaction of inactive trans-sialidase in the presence of beta-galactosides. By using NMR spectroscopy, we demonstrate that inactive trans-sialidase has a beta-galactoside recognition site formed following a conformational switch induced by sialoside binding. Thus prior positioning of a sialyl residue is required for the beta-galactoside interaction. When an appropriate sialic acid-containing molecule is available, both sialoside and beta-galactoside are simultaneously accommodated in the inactive trans-sialidase binding pocket. This is the first report of a lectin recognizing two distinct ligands by a sequential ordered mechanism. This uncommon binding behavior may play an important role in several biological aspects of T. cruzi/host cell interaction and could shed more light into the catalytic mechanism of the sialic acid transfer reaction of enzymatically active trans-sialidase.     

Secreted protein with altered thrombospondin repeat (SPATR) is essential for asexual blood stages but not required for hepatocyte invasion by the malaria parasite Plasmodium berghei

Upon entering its mammalian host, the malaria parasite productively invades two distinct cell types, that is, hepatocytes and erythrocytes during which several adhesins/invasins are thought to be involved. Many surface-located proteins containing thrombospondin Type I repeat (TSR) which help establish host–parasite molecular crosstalk have been shown to be essential for mammalian infection. Previous reports indicated that antibodies produced against Plasmodium falciparum secreted protein with altered thrombospondin repeat (SPATR) block hepatocyte invasion by sporozoites but no genetic evidence of its contribution to invasion has been reported. After failing to generate Spatr knockout in Plasmodium berghei blood stages, a conditional mutagenesis system was employed. Here, we show that SPATR plays an essential role during parasite's blood stages. Mutant salivary gland sporozoites exhibit normal motility, hepatocyte invasion, liver stage development and rupture of the parasitophorous vacuole membrane resulting in merosome formation. But these mutant hepatic merozoites failed to establish a blood stage infection in vivo. We provide direct evidence that SPATR is not required for hepatocyte invasion but plays an essential role during the blood stages of P. berghei.     

Trypanosoma cruzi: Effect of the absence of 5-lipoxygenase (5-LO)-derived leukotrienes on levels of cytokines, nitric oxide and iNOS expression in cardiac tissue in the acute phase of infection in mice

Leukotrienes are important mediators of inflammatory responses. In this study, we investigated the effect of the absence of 5-lipoxygenase (5-LO)-derived leukotrienes on levels of cytokines, nitric oxide (NO) and iNOS expression in cardiac tissue of mice infected with Trypanosoma cruzi, the agent of Chagas’ disease. NO is a key mediator of parasite killing in mice experimentally infected with T. cruzi, and previous studies have suggested that leukotrienes, such as LTB₄, induces NO synthesis in T. cruzi-infected macrophages and plays a relevant role in the killing of parasite in a NO-dependent manner. We therefore investigated whether leukotrienes would have a similar role in vivo in controlling the parasite burden by regulating NO activity. We have made the striking observation that absence of 5-LO-derived leukotrienes results in increased NO and IL-6 production in the plasma with a concomitant decrease in the expression of iNOS in the cardiac tissue on day 12 after T. cruzi infection. These findings indicate that endogenous leukotrienes are important regulators of NO activity in the heart and therefore influence the cardiac parasite burden without exerting a direct action on IL-6 production in the acute phase of infection with T. cruzi.     

Recently differentiated epimastigotes from Trypanosoma cruzi are infective to the mammalian host

Trypanosoma cruzi, the etiologic agent of Chagas disease, has a complex life cycle in which four distinct developmental forms alternate between the insect vector and the mammalian host. It is assumed that replicating epimastigotes present in the insect gut are not infective to mammalian host, a paradigm corroborated by the widely acknowledged fact that only this stage is susceptible to the complement system. In the present work, we establish a T. cruzi in vitro and in vivo epimastigogenesis model to analyze the biological aspects of recently differentiated epimastigotes (rdEpi). We show that both trypomastigote stages of T. cruzi (cell‐derived and metacyclic) are able to transform into epimastigotes (processes termed primary and secondary epimastigogenesis, respectively) and that rdEpi have striking properties in comparison to long‐term cultured epimastigotes: resistance to complement‐mediated lysis and both in vitro (cell culture) and in vivo (mouse) infectivity. Proteomics analysis of all T. cruzi stages reveled a cluster of proteins that were up‐regulated only in rdEpi (including ABC transporters and ERO1), suggesting a role for them in rdEpi virulence. The present work introduces a new experimental model for the study of host‐parasite interactions, showing that rdEpi can be infective to the mammalian host.     

Protein kinase A catalytic subunit interacts and phosphorylates members of trans-sialidase super-family in Trypanosoma cruzi

Protein kinase A (PKA) has been suggested as a regulator of stage differentiation in Trypanosoma cruzi. Using a yeast two-hybrid system we have begun to characterize the downstream substrates of T. cruzi PKA. We identified several members of the trans-sialidase super family by this approach. Immunoprecitation demonstrated that a TcPKAc monoclonal antibody was able to pull-down proteins recognized by trans-sialidase antibodies as well as a SA85-1.1 antibody and vice versa. An in vitro phosphorylation assay demonstrated that PKA phosphorylated the recombinant protein of an active trans-sialidase. In addition, a phospho-(Ser/Thr) PKA substrate antibody detected bands on immunoblot analysis of trans-sialidase antibody precipitated proteins from parasite lysate and the media of L₆E₉ myoblasts infected with trypomastigotes as well as from a SA85-1.1 antibody precipitated proteins from parasite lysate. Immunofluorescence analysis suggested that some TcPKAc localizes to the plasma membrane surface of trypomastigotes. The identified trans-sialidases have PKA consensus phosphorylation sites located near the endoplasmic reticulum retention motif in the N-terminal. These data support that PKA phosphorylates trans-sialidase super family members in vivo.     

Virulence and competitive ability in an obligately killing parasite

Mixed infections are thought to have a major influence on the evolution of parasite virulence. During a mixed infection, higher within‐host parasite growth is favored under the assumption that it is critical to the competitive success of the parasite. As within‐host parasite growth may also increase damage to the host, a positive correlation is predicted between virulence and competitive success. However, when parasites must kill their hosts in order be transmitted, parasites may spend energy on directly attacking their host, even at the cost of their within‐host growth. In such systems, a negative correlation between virulence and competitive success may arise. We examined virulence and competitive ability in three sympatric species of obligately killing nematode parasites in the genus Steinernema. These nematodes exist in a mutualistic symbiosis with bacteria in the genus Xenorhabdus. Together the nematodes and their bacteria kill the insect host soon after infection, with reproduction of both species occurring mainly after host death. We found significant differences among the three nematode species in the speed of host killing. The nematode species with the lowest and highest levels of virulence were associated with the same species of Xenorhabdus, indicating that nematode traits, rather than the bacterial symbionts, may be responsible for the differences in virulence. In mixed infections, host mortality rate closely matched that associated with the more virulent species, and the more virulent species was found to be exclusively transmitted from the majority of coinfected hosts. Thus, despite the requirement of rapid host death, virulence appears to be positively correlated with competitive success in this system. These findings support a mechanistic link between parasite growth and both anti‐competitor and anti‐host factors.