Late endosomal Rab7 regulates lysosomal trafficking of endocytic but not biosynthetic cargo in Trypanosoma brucei

We present the first functional analysis of the small GTPase, TbRab7, in Trypanosoma brucei. TbRab7 defines discrete late endosomes closely juxtaposed to the terminal p67(+) lysosome. RNAi indicates that TbRab7 is essential in bloodstream trypanosomes. Initial rates of endocytosis were unaffected, but lysosomal delivery of cargo, including tomato lectin (TL) and trypanolytic factor (TLF) were blocked. These accumulate in a dispersed internal compartment of elevated pH, likely derived from the late endosome. Surface binding of TL but not TLF was reduced, suggesting that cellular distribution of flagellar pocket receptors is differentially regulated by TbRab7. TLF activity was reduced approximately threefold confirming that lysosomal delivery is critical for trypanotoxicity. Unexpectedly, delivery of endogenous proteins, p67 and TbCatL, were unaffected indicating that TbRab7 does not regulate biosynthetic lysosomal trafficking. Thus, unlike mammalian cells and yeast, lysosomal trafficking of endocytosed and endogenous proteins occur via different routes and/or are regulated differentially. TbRab7 silencing had no effect on a cryptic default pathway to the lysosome, suggesting that the default lysosomal reporters p67ΔTM, p67ΔCD and VSGΔGPI do not utilize the endocytic pathway as previously proposed. Surprisingly, conditional knockout indicates that TbRab7 may be non-essential in procyclic insect form trypanosomes.     

Multiple motifs regulate trafficking of the LAMP-like protein p67 in the ancient eukaryote Trypanosoma brucei

p67 is a lysosome-associated membrane protein-like lysosomal type I transmembrane glycoprotein in African trypanosomes. The p67 cytoplasmic domain (CD) is both necessary and sufficient for lysosomal targeting in procyclic insect-stage parasites. The p67CD contains two [DE]XXXL[LI]-type dileucine motifs, which function as lysosomal targeting signals in mammalian cells. Using a green fluorescent protein fusion to the p67 transmembrane and cytoplasmic domains as a reporter system, we investigated the role of these motifs in lysosomal targeting in procyclic trypanosomes. Pulse-chase turnover studies, steady-state immunolocalization and quantitative flow cytometry all gave consistent results. Mutagenesis of the membrane-distal dileucine motif impairs lysosomal trafficking leading to partial appearance of the reporter on the cell surface. Mutagenesis of the membrane-proximal motif has little effect on proper targeting. Simultaneous mutagenesis of both motifs results in quantitative delivery to the cell surface. Thus, the distal motif plays a dominant role, but both dileucine motifs are necessary for maximal lysosomal targeting. Additional studies suggest that the upstream acidic residues in each motif influence lysosomal targeting and may also affect forward trafficking in the early secretory pathway. These results strongly suggest an evolutionary conservation in lysosomal trafficking mechanisms in the ancient eukaryote Trypanosoma brucei.     

Evidence for a Trypanosoma brucei lipoprotein scavenger receptor

African trypanosomes are lipid auxotrophs that live in the bloodstream of their human and animal hosts. Trypanosomes require lipoproteins in addition to other serum components in order to multiply under axenic culture conditions. Delipidation of the lipoproteins abrogates their capacity to support trypanosome growth. Both major classes of serum lipoproteins, LDL and HDL, are primary sources of lipids, delivering cholesterol esters, cholesterol, and phospholipids to trypanosomes. We show evidence for the existence of a trypanosome lipoprotein scavenger receptor, which facilitates the endocytosis of both native and modified lipoproteins, including HDL and LDL. This lipoprotein scavenger receptor also exhibits selective lipid uptake, whereby the uptake of the lipid components of the lipoprotein exceeds that of the protein components. Trypanosome lytic factor (TLF1), an unusual HDL found in human serum that protects from infection by lysing Trypanosoma brucei brucei, is also bound and endocytosed by this lipoprotein scavenger receptor. HDL and LDL compete for the binding and uptake of TLF1 and thereby attenuate the trypanosome lysis mediated by TLF1. We also show that a mammalian scavenger receptor facilitates lipid uptake from TLF1 in a manner similar to the trypanosome scavenger receptor. Based on these results we propose that HDL, LDL, and TLF1 are all bound and taken up by a lipoprotein scavenger receptor, which may constitute the parasite's major pathway mediating the uptake of essential lipids.     

Dual Functions of α-Ketoglutarate Dehydrogenase E2 in the Krebs Cycle and Mitochondrial DNA Inheritance in Trypanosoma brucei

The dihydrolipoyl succinyltransferase (E2) of the multisubunit α-ketoglutarate dehydrogenase complex (α-KD) is an essential Krebs cycle enzyme commonly found in the matrices of mitochondria. African trypanosomes developmentally regulate mitochondrial carbohydrate metabolism and lack a functional Krebs cycle in the bloodstream of mammals. We found that despite the absence of a functional α-KD, bloodstream form (BF) trypanosomes express α-KDE2, which localized to the mitochondrial matrix and inner membrane. Furthermore, α-KDE2 fractionated with the mitochondrial genome, the kinetoplast DNA (kDNA), in a complex with the flagellum. A role for α-KDE2 in kDNA maintenance was revealed in α-KDE2 RNA interference (RNAi) knockdowns. Following RNAi induction, bloodstream trypanosomes showed pronounced growth reduction and often failed to equally distribute kDNA to daughter cells, resulting in accumulation of cells devoid of kDNA (dyskinetoplastic) or containing two kinetoplasts. Dyskinetoplastic trypanosomes lacked mitochondrial membrane potential and contained mitochondria of substantially reduced volume. These results indicate that α-KDE2 is bifunctional, both as a metabolic enzyme and as a mitochondrial inheritance factor necessary for the distribution of kDNA networks to daughter cells at cytokinesis.     

De novo sphingolipid synthesis is essential for viability, but not for transport of glycosylphosphatidylinositol-anchored proteins, in African trypanosomes

De novo sphingolipid synthesis is required for the exit of glycosylphosphatidylinositol (GPI)-anchored membrane proteins from the endoplasmic reticulum in yeast. Using a pharmacological approach, we test the generality of this phenomenon by analyzing the transport of GPI-anchored cargo in widely divergent eukaryotic systems represented by African trypanosomes and HeLa cells. Myriocin, which blocks the first step of sphingolipid synthesis (serine + palmitate --> 3-ketodihydrosphingosine), inhibited the growth of cultured bloodstream parasites, and growth was rescued with exogenous 3-ketodihydrosphingosine. Myriocin also blocked metabolic incorporation of [3H]serine into base-resistant sphingolipids. Biochemical analyses indicate that the radiolabeled lipids are not sphingomyelin or inositol phosphorylceramide, suggesting that bloodstream trypanosomes synthesize novel sphingolipids. Inhibition of de novo sphingolipid synthesis with myriocin had no adverse effect on either general secretory trafficking or GPI-dependent trafficking in trypanosomes, and similar results were obtained with HeLa cells. A mild effect on endocytosis was seen for bloodstream trypanosomes after prolonged incubation with myriocin. These results indicate that de novo synthesis of sphingolipids is not a general requirement for secretory trafficking in eukaryotic cells. However, in contrast to the closely related kinetoplastid Leishmania major, de novo sphingolipid synthesis is essential for the viability of bloodstream-stage African trypanosomes.     

Cytosolic Peroxidases Protect the Lysosome of Bloodstream African Trypanosomes from Iron-Mediated Membrane Damage

African trypanosomes express three virtually identical non-selenium glutathione peroxidase (Px)-type enzymes which preferably detoxify lipid-derived hydroperoxides. As shown previously, bloodstream Trypanosoma brucei lacking the mitochondrial Px III display only a weak and transient proliferation defect whereas parasites that lack the cytosolic Px I and Px II undergo extremely fast lipid peroxidation and cell lysis. The phenotype can completely be rescued by supplementing the medium with the α-tocopherol derivative Trolox. The mechanism underlying the rapid cell death remained however elusive. Here we show that the lysosome is the origin of the cellular injury. Feeding the px I–II knockout parasites with Alexa Fluor-conjugated dextran or LysoTracker in the presence of Trolox yielded a discrete lysosomal staining. Yet upon withdrawal of the antioxidant, the signal became progressively spread over the whole cell body and was completely lost, respectively. T. brucei acquire iron by endocytosis of host transferrin. Supplementing the medium with iron or transferrin induced, whereas the iron chelator deferoxamine and apo-transferrin attenuated lysis of the px I–II knockout cells. Immunofluorescence microscopy with MitoTracker and antibodies against the lysosomal marker protein p67 revealed that disintegration of the lysosome precedes mitochondrial damage. In vivo experiments confirmed the negligible role of the mitochondrial peroxidase: Mice infected with px III knockout cells displayed only a slightly delayed disease development compared to wild-type parasites. Our data demonstrate that in bloodstream African trypanosomes, the lysosome, not the mitochondrion, is the primary site of oxidative damage and cytosolic trypanothione/tryparedoxin-dependent peroxidases protect the lysosome from iron-induced membrane peroxidation. This process appears to be closely linked to the high endocytic rate and distinct iron acquisition mechanisms of the infective stage of T. brucei. The respective knockout of the cytosolic px I–II in the procyclic insect form resulted in cells that were fully viable in Trolox-free medium.     

Trypanosoma brucei brucei and T. b. gambiense: Stumpy Bloodstream Forms Express More CB1 Epitope in Endosomes and Lysosomes than Slender Forms

CB1-glycoprotein is a component of flagellar pocket, endosome, and lysosome membranes of long, slender bloodstream forms of the Trypanosoma brucei subgroup of African trypanosomes. We have used immunoblotting, immunofluorescence, and cryoimmunoelectron microscopy to study CB1-glycoprotein expression as long, slender bloodstream forms of pleomorphic T. b. brucei and T. b. gambiense transform through intermediate stages into short, stumpy forms. Intermediate and stumpy forms express more CB1-glycoprotein than long, slender forms. These results, coupled with previous work showing that procyclic forms do not express CB1-glycoprotein, show that the expression of lysosomal membrane glycoproteins is regulated coordinately with other aspects of lysosome and endosome function as these trypanosomes go through their life cycle.     

Role of AP-1 in Developmentally Regulated Lysosomal Trafficking in Trypanosoma brucei

African trypanosomes are the causative agents of human trypanosomiasis (sleeping sickness). The pathogenic stage of the parasite has unique adaptations to life in the bloodstream of the mammalian host, including upregulation of endocytic and lysosomal activities. We investigated stage-specific requirements for cytoplasmic adaptor/clathrin machinery in post-Golgi apparatus biosynthetic sorting to the lysosome using RNA interference silencing of the Tbμ1 subunit of adaptor complex 1 (AP-1), in conjunction with immunolocalization, kinetic analyses of reporter transport, and quantitative endocytosis assays. Tbμ1 silencing was lethal in both stages, indicating a critical function(s) for the AP-1 machinery. Transport of soluble and membrane-bound secretory cargoes was Tbμ1 independent in both stages. In procyclic parasites, trafficking of the lysosomal membrane protein, p67, was disrupted, leading to cell surface mislocalization. The lysosomal protease trypanopain was also secreted, suggesting a transmembrane-sorting receptor for this soluble hydrolase. In bloodstream trypanosomes, both p67 and trypanopain trafficking were unaffected by Tbμ1 silencing, suggesting that AP-1 is not necessary for biosynthetic lysosomal trafficking. Endocytosis in bloodstream cells was also unaffected, indicating that AP-1 does not function at the flagellar pocket. These results indicate that post-Golgi apparatus sorting to the lysosome is critically dependent on the AP-1/clathrin machinery in procyclic trypanosomes but that this machinery is not necessary in bloodstream parasites. We propose a simple model for stage-specific default secretory trafficking in trypanosomes that is consistent with the behavior of other soluble and glycosylphosphatidylinositol-anchored cargos and which is influenced by upregulation of endocytosis in bloodstream parasites as an adaptation to life in the mammalian bloodstream.African trypanosomes (Trypanosoma brucei subspecies), the agents of African sleeping sickness, are alone among the kinetoplastid parasites (including Trypanosoma cruzi and Leishmania spp.) in having a pathogenic bloodstream stage that exists and replicates extracellularly in the mammalian host. This places unique constraints on the parasite in terms of dealing with host immune responses and on acquisition of essential nutrients. The parasite has evolved many strategies to deal with these constraints, the best known of which is the process of antigenic variation (9). Another is the lysosome, which impacts the host-pathogen balance in multiple ways. Trypanosomes have a single terminal lysosome that is the final repository of endocytic cargo acquired from the host serum for nutritional purposes (30), as well as for potentially lytic immune complexes removed from the cell surface (4, 8). Both endocytosis and lysosomal hydrolytic activities are differentially regulated through the trypanosome life cycle (11, 30), and there are stage-specific differences in the biosynthetic trafficking of essential lysosomal components (discussed below). The release of lysosomal proteases is a factor in the signature event of human infection, penetration of the central nervous system (36). Finally, lysosomal physiology is critical to the activity of an innate human serum resistance trait, trypanolytic factor, which limits the host range of Trypanosoma species (38).Clearly, given its multiple roles in pathogenesis, biogenesis of the lysosome is critical to the success of trypanosomes as human parasites. As in all eukaryotes, lysosomal biogenesis is a balance between the proper sorting of newly synthesized membranes and proteins and recycling of established membranes and proteins internalized from the cell surface. In each case, protein sorting involves recognition of specific signals in cargo molecules by cellular machinery for inclusion in nascent transport vesicles destined for downstream delivery. Unique sets of cytoplasmic coat complexes at discrete intracellular locations serve the dual purpose of simultaneously mediating vesicle formation and selective cargo loading. The best characterized of these machineries is the clathrin/adaptin system for formation of coated vesicles at the Golgi apparatus and the plasma membrane (10, 41). Adaptor complexes (APs) are cytosolic heterotetramers that interact with specific signals in the cytoplasmic domains of membrane cargo proteins, such as dileucine motifs ([E/D]XXXL[L/I]) and tyrosine motifs (YXXØ, where Ø is a bulky hydrophobic residue). The prototypic AP complexes are AP-1 and AP-2, which function at the trans-Golgi network and plasma membrane, respectively. Both are composed of two large subunits (γ/β1 in AP-1; α/β2 in AP-2) and two smaller subunits (σ1/μ1 in AP-1; σ2/μ2 in AP-2). YXXØ motifs interact with μ adaptins, and dileucine motifs interact with combinations of adaptin subunits in both AP-1 and AP-2 (26, 40, 42). It is the large subunits, particularly β adaptin, that mediate clathrin recruitment (19, 44). Other APs, AP-3 and AP-4, with discrete subunit compositions, also exist. AP-3 functions in trafficking to lysosome-related organelles, such as melanosomes, and AP-4 may be involved in basolateral trafficking in polarized epithelial cells (10). The genome of the African trypanosome, T. brucei, encodes a complete complement of orthologous subunits for AP-1, AP-3, and AP-4 but has no genes for AP-2, the major adaptor complex mediating endocytosis in vertebrate cells (16). This is likely due to evolutionary loss, since the closely related T. cruzi has orthologues of all four APs.Two major lysosomal cargo proteins have been studied in T. brucei, the LAMP (lysosome-associated membrane protein)-like protein p67 and the cathepsin L orthologue trypanopain. p67 is a type I membrane protein with a large glycosylated lumenal domain and a short cytoplasmic domain (1, 27). In procyclic insect stage (PCF) trypanosomes, the cytoplasmic domain is both necessary and sufficient for lysosomal targeting of a heterologous reporter, and its deletion results in mistargeting of p67 to the cell surface (1). The cytoplasmic domain contains two canonical dileucine motifs, mutation of which also results in delivery to the cell surface (47). These findings strongly indicate the existence of cognate cytoplasmic machinery for lysosomal delivery of p67 in PCF trypanosomes. Strikingly, however, the cytoplasmic domain, and its motifs, are totally dispensable for lysosomal targeting in bloodstream stage (BSF) trypanosomes (1). Deletion of the cytoplasmic domain results in minor mislocalization to the cell surface, but p67 is still overwhelmingly delivered to the lysosome. Ongoing lysosomal targeting cannot easily be attributed to misfolding of the lumenal domain, as suggested by others (3), since the normal transport-associated patterns of p67 glycosylation and cleavage prevail in these deletion constructs.Less is known about targeting of soluble trypanopain. In mammalian cells, soluble hydrolases are targeted to the lysosome by the addition of mannose-6-phosphate (M6P) moieties in the Golgi apparatus, which serve as ligands for recognition and lysosomal targeting by downstream M6P receptors (28). Soluble hydrolases can also be sorted by receptors that recognize polypeptide motifs, such as sortilins in mammalian cells (12) and Vps10 in yeast (13, 32). These receptors have lumenal cargo recognition domains and cytoplasmic domains containing signals for late endosomal targeting and recycling. M6P-modified N-linked glycans are not found in trypanosomes, and genes encoding the necessary enzymatic activities are absent from the genome (16), ruling out this possibility for trypanopain sorting. However, the T. cruzi orthologue, cruzipain, has been shown to rely on peptide motifs in the N-terminal prodomain for targeting (24), raising the possibility of a sortilin/Vps10p-like sorting receptor. Although there are no obvious orthologues of these proteins in the T. brucei genome, overexpression of trypanopain in PCF trypanosomes leads to secretion, an observation that is consistent with saturation of a specific sorting receptor (S. S. Sutterwala and J. D. Bangs, unpublished observations).Having previously studied the innate signals involved in p67 targeting (1, 47), we now turned our attention to the cognate machinery for post-Golgi apparatus sorting. Specifically, we investigate the role of trypanosomal AP-1 in stage-specific biosynthetic trafficking to the lysosome using RNA interference (RNAi)-mediated silencing of the Tbμ1 (geneDB no. Tb927.7.3180 [www.genedb.org]) subunit as our primary strategy. Our results demonstrate that AP-1 and clathrin are critical for lysosomal targeting of p67 and trypanopain in PCF trypanosomes but that they are essentially dispensable in BSF parasites. These data, in conjunction with the behavior of p67-targeting mutants (1) and other trypanosomal secretory reporters, lead us to propose a simple model for stage-specific default trafficking in African trypanosomes. Although in some respects our results are similar to those of a recent publication using RNAi silencing of the Tbγ1 subunit of AP-1 (3), they differ in key aspects, leading us to significantly different conclusions.     

African trypanosomes: intracellular trafficking of host defense molecules

Trypanosoma brucei brucei is the causative agent of Nagana in cattle and can infect a wide range of mammals but is unable to infect humans because it is susceptible to the innate cytotoxic activity of normal human serum. A minor subfraction of human high-density lipoprotein (HDL), containing apolipoprotein A-I (APOA1), apolipoprotein L-I (APOL1) and haptoglobin-related protein (HPR) provides this innate protection against T. b. brucei infection. Both HPR and APOL1 are cytotoxic to T. b. brucei but their specific activities for killing increase several hundred-fold when assembled in the same HDL. This HDL is called trypanosome lytic factor (TLF) and kills T. b. brucei following receptor binding, endocytosis, and lysosomal localization. Trypanosome lytic factor is activated in the acidic lysosome and facilitates lysosomal membrane disruption. Lysosomal localization is necessary for T. b. brucei killing by TLF. Trypanosoma brucei rhodesiense, which is indistinguishable from T. b. brucei, is resistant to TLF killing and causes human African sleeping sickness. Human infectivity by T. b. rhodesiense correlates with the evolution of a human serum resistance associated protein (SRA) that is able to ablate TLF killing. When T. b. brucei is transfected with the SRA gene it becomes highly resistant to TLF and human serum. In the SRA transfected cells, intracellular trafficking of TLF is altered and TLF mainly localizes to a subset of SRA containing cytoplasmic vesicles but not to the lysosome. These findings indicate that the cellular distribution of TLF is influenced by SRA expression and may directly determine susceptibility.     

Novel african trypanocidal agents: membrane rigidifying peptides

The bloodstream developmental forms of pathogenic African trypanosomes are uniquely susceptible to killing by small hydrophobic peptides. Trypanocidal activity is conferred by peptide hydrophobicity and charge distribution and results from increased rigidity of the plasma membrane. Structural analysis of lipid-associated peptide suggests a mechanism of phospholipid clamping in which an internal hydrophobic bulge anchors the peptide in the membrane and positively charged moieties at the termini coordinate phosphates of the polar lipid headgroups. This mechanism reveals a necessary phenotype in bloodstream form African trypanosomes, high membrane fluidity, and we suggest that targeting the plasma membrane lipid bilayer as a whole may be a novel strategy for the development of new pharmaceutical agents. Additionally, the peptides we have described may be valuable tools for probing the biosynthetic machinery responsible for the unique composition and characteristics of African trypanosome plasma membranes.     

Characterization of the Late Endosomal ESCRT Machinery in Trypanosoma brucei

The multivesicular body (MVB) is a specialized Rab7+ late endosome (LE) containing multiple intralumenal vesicles that function in targeting ubiquitinylated cell surface proteins to the lysosome for degradation. African trypanosomes lack a morphologically well‐defined MVB, but contain orthologs of the ESCRT (Endosomal Sorting Complex Required for Transport) machinery that mediates MVB formation. We investigate the role of TbVps23, an early ESCRT component, and TbVps4, the terminal ESCRT ATPase, in lysosomal trafficking in bloodstream form trypanosomes. Both localize to the TbRab7+ LE and RNAi silencing of each rapidly blocks growth. TbVps4 silencing results in approximately threefold accumulation of TbVps23 at the LE, consistent with blocking terminal ESCRT disassembly. Trafficking of endocytic and biosynthetic cargo, but not default lysosomal reporters, is also negatively affected. Others reported that TbVps23 mediates ubiquitin‐dependent lysosomal degradation of invariant surface glycoproteins (ISG65) (Leung et al., Traffic 2008;9:1698–1716). In contrast, we find that TbVps23 ablation does not affect ISG65 turnover, while TbVps4 silencing markedly enhances lysosomal degradation. We propose several models to accommodate these results, including that the ESCRT machinery actually retrieves ISG65 from the LE to earlier endocytic compartments, and in its absence ISG65 traffics more efficiently to the lysosome. Overall, these results confirm that the ESCRT machinery is essential in Trypanosoma brucei and plays important and novel role(s) in LE function in trypanosomes .     

Cathepsin-L Can Resist Lysis by Human Serum in Trypanosoma brucei brucei

Closely related African trypanosomes cause lethal diseases but display distinct host ranges. Specifically, Trypanosoma brucei brucei causes nagana in livestock but fails to infect humans, while Trypanosoma brucei gambiense and Trypanosoma brucei rhodesiense cause sleeping sickness in humans. T. b. brucei fails to infect humans because it is sensitive to innate immune complexes found in normal human serum known as trypanolytic factor (TLF) 1 and 2; the lytic component is apolipoprotein-L1 in both TLFs. TLF resistance mechanisms of T. b. gambiense and T. b. rhodesiense are now known to arise through either gain or loss-of-function, but our understanding of factors that render T. b. brucei susceptible to lysis by human serum remains incomplete. We conducted a genome-scale RNA interference (RNAi) library screen for reduced sensitivity to human serum. Among only four high-confidence ‘hits’ were all three genes previously shown to sensitize T. b. brucei to human serum, the haptoglobin-haemoglobin receptor (HpHbR), inhibitor of cysteine peptidase (ICP) and the lysosomal protein, p67, thereby demonstrating the pivotal roles these factors play. The fourth gene identified encodes a predicted protein with eleven trans-membrane domains. Using chemical and genetic approaches, we show that ICP sensitizes T. b. brucei to human serum by modulating the essential cathepsin, CATL, a lysosomal cysteine peptidase. A second cathepsin, CATB, likely to be dispensable for growth in in vitro culture, has little or no impact on human-serum sensitivity. Our findings reveal major and novel determinants of human-serum sensitivity in T. b. brucei. They also shed light on the lysosomal protein-protein interactions that render T. b. brucei exquisitely sensitive to lytic factors in human serum, and indicate that CATL, an important potential drug target, has the capacity to resist these factors.     

Trypanosome Lytic Factor,an Antimicrobial High-Density Lipoprotein,Ameliorates Leishmania Infection

Innate immunity is the first line of defense against invading microorganisms. Trypanosome Lytic Factor (TLF) is a minor sub-fraction of human high-density lipoprotein that provides innate immunity by completely protecting humans from infection by most species of African trypanosomes, which belong to the Kinetoplastida order. Herein, we demonstrate the broader protective effects of human TLF, which inhibits intracellular infection by Leishmania, a kinetoplastid that replicates in phagolysosomes of macrophages. We show that TLF accumulates within the parasitophorous vacuole of macrophages in vitro and reduces the number of Leishmania metacyclic promastigotes, but not amastigotes. We do not detect any activation of the macrophages by TLF in the presence or absence of Leishmania, and therefore propose that TLF directly damages the parasite in the acidic parasitophorous vacuole. To investigate the physiological relevance of this observation, we have reconstituted lytic activity in vivo by generating mice that express the two main protein components of TLFs: human apolipoprotein L-I and haptoglobin-related protein. Both proteins are expressed in mice at levels equivalent to those found in humans and circulate within high-density lipoproteins. We find that TLF mice can ameliorate an infection with Leishmania by significantly reducing the pathogen burden. In contrast, TLF mice were not protected against infection by the kinetoplastid Trypanosoma cruzi, which infects many cell types and transiently passes through a phagolysosome. We conclude that TLF not only determines species specificity for African trypanosomes, but can also ameliorate an infection with Leishmania, while having no effect on T. cruzi. We propose that TLFs are a component of the innate immune system that can limit infections by their ability to selectively damage pathogens in phagolysosomes within the reticuloendothelial system.     

Membrane Permeabilization by Trypanosome Lytic Factor, a Cytolytic Human High Density Lipoprotein

Trypanosome lytic factor (TLF) is a subclass of human high density lipoprotein (HDL) that mediates an innate immune killing of certain mammalian trypanosomes, most notably Trypanosoma brucei brucei, the causative agent of a wasting disease in cattle. Mechanistically, killing is initiated in the lysosome of the target trypanosome where the acidic pH facilitates a membrane-disrupting activity by TLF. Here we utilize a model liposome system to characterize the membrane binding and permeabilizing activity of TLF and its protein constituents, haptoglobin-related protein (Hpr), apolipoprotein L-1 (apoL-1), and apolipoprotein A-1 (apoA-1). We show that TLF efficiently binds and permeabilizes unilamellar liposomes at lysosomal pH, whereas non-lytic human HDL exhibits inefficient permeabilizing activity. Purified, delipidated Hpr and apoL-1 both efficiently permeabilize lipid bilayers at low pH. Trypanosome lytic factor, apoL-1, and apoA-1 exhibit specificity for anionic membranes, whereas Hpr permeabilizes both anionic and zwitterionic membranes. Analysis of the relative particle sizes of susceptible liposomes reveals distinctly different membrane-active behavior for native TLF and the delipidated protein components. We propose that lysosomal membrane damage in TLF-susceptible trypanosomes is initiated by the stable association of the TLF particle with the lysosomal membrane and that this is a property unique to this subclass of human HDL.High density lipoproteins (HDL)² are complex yet ordered macromolecules consisting of characteristic proteins embedded in a phospholipid monolayer that surrounds a hydrophobic core of esterified cholesterol and triglycerides. A subclass of HDL is responsible for an innate immune killing of the African blood stream parasite Trypanosoma brucei brucei (1–3), and very recently, has been shown to be cytotoxic to intracellular Leishmania promastigotes (4). The trypanolytic HDL particle, termed trypanosome lytic factor (TLF), is characterized by the presence of two proteins, apolipoprotein L-1 (apoL-1) and haptoglobin-related protein (Hpr), as well as the HDL ubiquitous apolipoprotein A-1 (apoA-1) (1, 5–7). Killing of the susceptible parasite involves high affinity binding to a cell-surface receptor, endocytosis, and trafficking of the TLF particle to the lysosome (8–12). The acidic lysosomal environment facilitates a membrane-disrupting activity by the TLF particle and subsequent cell death (9, 13). It has been shown that purified, delipidated apoL-1 or Hpr are sufficient for trypanosome killing. When these proteins are incorporated into the same lipoprotein particle, a several hundredfold increase in killing activity is exhibited (5). In addition, Molina-Portela et al. (14) show that maximal protection against T. b. brucei in a transgenic mouse model requires the expression of human Hpr, apoL-1, and apoA-1, supporting a synergistic mode of action.Haptoglobin-related protein evolved during primate evolution and is restricted to apes, old world monkeys, and humans (15). Haptoglobin-related protein is highly similar (92%) to the acute phase serum protein haptoglobin (Hp) (16). All mammals use Hp as a scavenger of hemoglobin (Hb) released during hemolysis associated with infection or trauma. Haptoglobin binds cell-free Hb with high affinity and facilitates its removal from the circulation through a receptor-mediated process in the liver (17). Like Hp, Hpr binds free Hb, yet this Hpr·Hb complex is not recognized by the requisite receptors in mammals and is thus not removed from the circulation (18). TLF uptake by susceptible trypanosomes requires specific binding to an Hpr·Hb complex that facilitates trafficking of the TLF particle to the lysosome (10). It has been proposed that once inside the lysosomal compartment, Hpr·Hb contributes directly to membrane disruption through the generation of oxygen radicals with the bound Hb providing the iron necessary for Fenton chemistry (7, 10, 19).Apolipoprotein L-1 is a unique member of the apolipoprotein L protein family in that, unlike the remaining apoL proteins, it possesses an N-terminal signal sequence and is thus secreted from cells. As is the case for Hpr, apoL-1 appeared during primate evolution (20–22). Within the circulation of primates, apoL-1 is exclusively associated with HDL, and the majority of the protein is in the TLF subclass (5). The apoL family members are all predicted to adopt amphipathic α-helical conformations, suggesting that their physiological role involves membrane interaction (20). Apolipoprotein L-1 shares limited homology with channel-forming colicins and, consistent with this observation, has been shown to function as an ion channel when incorporated into lipid bilayers (23).The ultimate fate of TLF-targeted lysosomal membranes is not firmly established. Several studies employing both in vivo cellular analysis and artificial membrane systems address this point with conflicting results. Electron microscopy studies with gold-conjugated TLF revealed accumulation of TLF in intracellular vesicles and subsequent vesicle membrane breakdown and appearance of gold particles in the cytoplasm (9). Widener et al. (10) observed efflux of lysosomally localized large molecular mass dextrans (500 kDa) in TLF-treated T. b. brucei. These data suggest that the lysosomal membrane experiences large scale disruption. In contrast, Perez-Morga et al. (23) and Vanhollebeke et al. (24) report uncontrollable lysosomal swelling in susceptible trypanosomes treated with normal human serum, suggesting stability of the lamellar structure of the lysosomal membrane after TLF attack. Swelling is attributed to apoL-1-mediated influx of Cl^– ions and concomitant osmotic flow of water into the lysosome. However, Molina-Portela et al. (25) observed the formation of cation-selective pores in TLF-treated planar lipid bilayers composed of trypanosome lipids. The diversity of activities reported for TLF and normal human serum may reflect the packaging of multiple toxins within the same complex that can act synergistically to provide optimal killing activity (5, 14).Here we utilize model liposomes to monitor the membrane activity of TLF and its protein constituents. We describe the effects of TLF, delipidated Hpr, apoL-1, and apoA-1 on the permeability of unilamellar liposomes. Additionally, we show that TLF, apoL-1, and apoA-1 exhibit lipid specificity and that Hpr, apoL-1, and apoA-1 induce large scale changes in the geometry of liposomes. These results provide a molecular basis for the recognition of lysosomal membranes by this toxic HDL and support a multicomponent mechanism for trypanosome killing.     

Trypanosoma Manulis N. Sp. From the Russian Pallas Cat Felis Manul

ABSTRACT. The morphology of Trypanosoma manulis n. sp. is described from living and stained specimens obtained from the blood of a Pallas cat, Felis manul , from Kazakhstan. the cat was also infected with a Hepatozoon sp. and feline immunodeficiency virus. the morphology of the trypanosome most closely resembles that of Trypanosoma mpapuense Reichenow and Trypanosoma heybergi Rodhain found in bats. Trypanosoma manulis does not grow well in conventional media, but co-culture with African green monkey kidney cells in Eagle's Minimum Essential Medium supplemented with 10% fetal calf serum at approximately 27° C resulted in luxuriant growth of trypanosomes. Under these growth conditions, epimastigotes adhered to the surface of the culture flask and to African green monkey kidney cells, as well as forming large rosettes. At 37° C, although growth was poor, transformation of the epimastigotes into the bloodstream forms occurred. This represents the first report of a trypanosome of the subgenus Megatrypanum in a felid.     

The trypanolytic factor of human serum: many ways to enter the parasite,a single way to kill

Humans have developed a particular innate immunity system against African trypanosomes, and only two Trypanosoma brucei clones (T. b. gambiense, T. b. rhodesiense) can resist this defence and cause sleeping sickness. The main players of this immunity are the primate‐specific apolipoprotein L‐I (apoL1) and haptoglobin‐related protein (Hpr). These proteins are both associated with two serum complexes, a minor subfraction of HDLs and an IgM/apolipoprotein A‐I (apoA1) complex, respectively, termed trypanosome lytic factor (TLF) 1 and TLF2. Although the two complexes appear to lyse trypanosomes by the same mechanism, they enter the parasite through various modes of uptake. In case of TLF1 one uptake process was characterized. When released in the circulation, haemoglobin (Hb) binds to Hpr, hence to TLF1. In turn the TLF1–Hpr–Hb complex binds to the trypanosome haptoglobin (Hp)–Hb receptor, whose original function is to ensure haem uptake for optimal growth of the parasite. This binding triggers efficient uptake of TLF1 and subsequent trypanosome lysis. While Hpr is involved as TLF ligand, the lytic activity is due to apoL1, a Bcl‐2‐like pore‐forming protein. We discuss the in vivo relevance of this uptake pathway in the context of other potentially redundant delivery routes.     

Glycosylphosphatidylinositol-dependent protein trafficking in bloodstream stage Trypanosoma brucei

We have previously demonstrated that glycosylphosphatidylinositol (GPI) anchors strongly influence protein trafficking in the procyclic insect stage of Trypanosoma brucei (M. A. McDowell, D. A. Ransom, and J. D. Bangs, Biochem. J. 335:681-689, 1998), where GPI-minus variant surface glycoprotein (VSG) reporters have greatly reduced rates of endoplasmic reticulum (ER) exit but are ultimately secreted. We now demonstrate that GPI-dependent trafficking also occurs in pathogenic bloodstream trypanosomes. However, unlike in procyclic trypanosomes, truncated VSGs lacking C-terminal GPI-addition signals are not secreted but are mistargeted to the lysosome and degraded. Failure to export these reporters is not due to a deficiency in secretion of these cells since the N-terminal ATPase domain of the endogenous ER protein BiP is efficiently secreted from transgenic cell lines. Velocity sedimentation experiments indicate that GPI-minus VSG dimerizes similarly to wild-type VSG, suggesting that degradation is not due to ER quality control mechanisms. However, GPI-minus VSGs are fully protected from degradation by the cysteine protease inhibitor FMK024, a potent inhibitor of the major lysosomal protease trypanopain. Immunofluorescence of cells incubated with FMK024 demonstrates that GPI-minus VSG colocalizes with p67, a lysosomal marker. These data suggest that in the absence of a GPI anchor, VSG is mistargeted to the lysosome and subsequently degraded. Our findings indicate that GPI-dependent transport is a general feature of secretory trafficking in both stages of the life cycle. A working model is proposed in which GPI valence regulates progression in the secretory pathway of bloodstream stage trypanosomes.     

Rab4 is an essential regulator of lysosomal trafficking in trypanosomes

Rapid endocytosis and recycling of surface proteins are important processes common to most nucleated eukaryotic cells. The best characterized membrane recycling routes are mediated by the small GTPases Rab4 and Rab11, but the precise roles that these pathways play have not been fully elucidated. The protozoan Trypanosoma brucei has a highly developed endocytic system that is similar to that found in metazoans, albeit with an accelerated rate of membrane turnover. We have used this organism to investigate the function of the trypanosome orthologue of Rab4 (TbRAB4) by a combination of RNA interference, microscopy, and quantitative trafficking assays. RNA interference-mediated suppression of TbRAB4 expression inhibited the growth of trypanosomes without affecting receptor-mediated endocytosis or ligand recycling. Ultrastructural analysis indicated a major defect in membrane transport events. The accumulation of fluorescent dextran, a fluid-phase marker, was blocked in cells lacking TbRAB4 protein. Since most fluid-phase markers are transported to the lysosome in T. brucei, the effects of TbRAB4 RNA interference on lysosomal function were investigated. By immunofluorescence, the major lysosomal protein p67 became progressively dispersed in cells lacking the TbRAB4 protein. Pulse-chase analysis demonstrated that initial proteolytic cleavage and glycan processing of p67 were unaffected but that cells failed to accumulate the later p67 proteolyzed products associated with the lysosome. To confirm the role of TbRAB4 in lysosomal trafficking, a constitutively active mutant, TbRAB4QL, was expressed. TbRAB4QL was closely associated with an enlarged multivesicular body that contained p67. In addition, cells expressing TbRAB4QL showed increased fluid-phase uptake when compared with the parental line. Taken together, these data suggest that TbRAB4 is involved in regulation of fluid-phase traffic to the lysosome in T. brucei but not in receptor-mediated endocytosis or recycling. These data have implications for the role of Rab4 in other cell systems.     

The GPI biosynthetic pathway as a therapeutic target for African sleeping sickness

African sleeping sickness is a debilitating and often fatal disease caused by tsetse fly transmitted African trypanosomes. These extracellular protozoan parasites survive in the human bloodstream by virtue of a dense cell surface coat made of variant surface glycoprotein. The parasites have a repertoire of several hundred immunologically distinct variant surface glycoproteins and they evade the host immune response by antigenic variation. All variant surface glycoproteins are anchored to the plasma membrane via glycosylphosphatidylinositol membrane anchors and compounds that inhibit the assembly or transfer of these anchors could have trypanocidal potential. This article compares glycosylphosphatidylinositol biosynthesis in African trypanosomes and mammalian cells and identifies several steps that could be targets for the development of parasite-specific therapeutic agents.     

Prostaglandin D2 induces programmed cell death in Trypanosoma brucei bloodstream form

African trypanosomes produce some prostanoids, especially PGD2, PGE2 and PGF2alpha (Kubata et al. 2000, J. Exp. Med. 192: 1327-1338), probably to interfere with the host's physiological response. However, addition of prostaglandin D2 (but not PGE2 or PGF2alpha) to cultured bloodstream form trypanosomes led also to a significant inhibition of cell growth. Based on morphological alterations and specific staining methods using vital dyes, necrosis and autophagy were excluded. Here, we report that in bloodstream form trypanosomes PGD2 induces an apoptosis-like programmed cell death, which includes maintenance of plasma membrane integrity, phosphatidylserine exposure, loss of mitochondrial membrane potential, nuclear chromatin condensation and DNA degradation. The use of caspase inhibitors cannot prevent the cell death, indicating that the process is caspase-independent. Based on these results, we suggest that PGD2-induced programmed cell death is part of the population density regulation as observed in infected animals.