Parasitic Trypanosoma Brucei Research Articles

Antigenic variation in Trypanosoma brucei infections: an holistic view.

Trypanosoma brucei parasites undergo clonal phenotypic (antigenic) variation to promote their transmission between mammals and tsetse-fly vectors. This process is classically considered to be a mechanism for evading humoral immune responses, but such an explanation cannot account for the high rate of switching between variable antigens or for their hierarchical (i.e. non-random) expression. I suggest that these anomalies can be explained by a new model: that antigenic variation has evolved as a bifunctional, rather than as a unifunctional, strategy that not only evades humoral immune responses but also enables competition between parasite strains in concomitantly infected hosts. This competition causes a depression of cellular responses. My proposal gives rise to a number of testable predictions. First, low numbers of trypanosomes should express some variable antigen types (VATs) in infections several weeks before these VATs are detectable. Second, as an infection progresses, the number of VATs expressed simultaneously in the population should decrease. Third, immunisation to generate a T helper 1 response against those VATs that are expressed most frequently should lower parasitaemias and reduce virulence.

The involvement of gRNA-binding protein gBP21 in RNA editing-an in vitro and in vivo analysis.

RNA editing in the parasitic organism Trypanosoma brucei is characterised by the insertion and deletion of uridylate residues into otherwise incomplete primary transcripts. The processing reaction is a required pathway for the expression of most mitochondrial genes and proceeds by a cascade of enzyme-catalysed steps. RNA editing involves one or more macromolecular ribonucleoprotein complexes which are likely to interact with additional components as the reaction proceeds. Here we examined the involvement of the gRNA-binding polypeptide gBP21, a protein which has been demonstrated to be associated with active RNA editing complexes. We show that in vitro RNA editing can be suppressed by the addition of a gBP21-specific antibody or by immunodepletion of the protein. By creating a gBP21 knockout mutant we analysed the requirement for the protein in vivo. gBP21(-) trypanosomes are viable as bloodstream stage cells and contain edited mRNAs. However, the knockout mutant is not capable of differentiating from the bloodstream to the insect life cycle stage in vitro. Moreover, mutant cells are characterised by a low mitochondrial transcript abundance. Together, these data establish that gBP21 contributes a non-essential function to the RNA editing reaction and further suggest that the protein is involved in additional mitochondrial processes which impact a larger pool of mitochondrial transcripts.

Rapid uptake and phosphorylation of D-mannose, and limited D-mannose 6-phosphate isomerization in the glycolytic pathway of bloodstream forms of Trypanosoma brucei gambiense.

Bloodstream forms of the parasitic protozoa Trypanosoma brucei gambiense derive all of needed energy through an unusual glycolysis. In an earlier study, we showed that D-mannose specifically inhibited the growth of bloodstream forms of T. b. gambiense. We investigated D-mannose transport into the T. b. gambiense bloodstream forms and its metabolism in the initial phase of the glycolytic pathway. D-Mannose was transported rapidly into the bloodstream forms of T. b. gambiense (K(m) = 378 microM), and D-glucose competitively inhibited D-mannose uptake. D-Mannose and D-glucose are transported into bloodstream trypanosomes by the same carrier. Hexokinase from the bloodstream trypanosomes could convert D-mannose to D-mannose 6-phosphate (K(m) = 155.8 microM; Vmax = 0.93 mumol/min/mg protein); with kinetic properties very similar to D-glucose phosphorylation (K(m) = 199.4 microM; Vmax = 1.15 mumol/min/mg protein). D-Mannose 6-phosphate could be further metabolized in the glycolytic pathway. However, the metabolic rate was extremely slow, and D-mannose 6-phosphate accumulated in the glycosomes. D-Mannose may cause growth inhibition of bloodstream trypanosomes through an extremely high concentration of D-mannose 6-phosphate in the glycosomes.

Inhibition of growth of Trypanosoma brucei parasites in chronic infections.

The growth of Trypanosoma brucei parasites in chronic infections was investigated by superimposing upon chronic infections, secondary infections in which all parasites expressed the same variable antigen type (VAT). The fate of trypanosomes in secondary infections could then be monitored using the VAT as a marker to discriminate cells in primary and secondary infections and thus enable growth to be observed separately from its interactions with antigenic variation on the part of the parasite and specific immune responses of the host. Our results show that as an infection proceeds, the growth rate is progressively inhibited in mice and sheep, suggesting that inhibition is a general feature of chronic infections. Inhibition was not specific to either the stock or the VAT of the trypanosome, but the degree of inhibition did vary between stocks. Inhibition appeared to be mediated by a lowering of the rate of replication of 'slender'-form parasites rather than by an increase in either the rate of differentiation from dividing slender to non-dividing 'stumpy' forms or the mortality caused by non-specific immune mechanisms. Evidence indicated that the development of specific immune responses to non-variant parasite antigens was also unlikely. These data constitute, we believe, the first evidence for negative regulation of growth in vivo, which may be an important determinant of the virulence of trypanosome infections.

Trypanosomes cause dysregulation of c-fos expression in the rat suprachiasmatic nucleus.

Rats infected with the parasite Trypanosoma brucei brucei showed selective changes of c-fos expression in the suprachiasmatic nucleus of the hypothalamus (SCN) during spontaneous sleep (S) and wakefulness (W) under a basal 12 h/12 h light-dark (L-D) cycle. In the vast majority of W (D phase) control animals the SCN was devoid of cells displaying Fos-related immunopositivity, while Fos-like-immunoreactive (ir) neurones were detected in most S (L phase) control rats. In most infected animals, on the other hand, Fos-ir neurones were detected in the SCN during W, but not during the S period, with a significant difference between control and infected S rats. Thus, these data indicate that the basal c-fos expression in the SCN during the L-D and S-W cycles is considerably altered in experimental trypanosomiasis. This is the first observation of a selective change in the SCN in trypanosome-infected rat brains. Since the SCN plays an important role as a pace-maker for biological rhythms, this finding may provide a basis for understanding the pathogenesis behind endogenous rhythm dyregulation and changes in sleeping pattern in human trypanosomiasis (African sleeping sickness).

Mechanisms for the elimination of potentially lytic complement-fixing variable surface glycoprotein antibody-complexes in Trypanosoma brucei.

Live antibody-coated Trypanosoma brucei parasites remove variable surface glycoprotein (VSG)-antibody complexes from their surface upon warming to 37 degrees C and evade antibody-activated complement lysis by both protein synthesis-dependent and protein synthesis-independent mechanisms. The protein synthesis-dependent process follows antibody-mediated trypanosome agglutination, whereas the protein synthesis-independent mechanism can occur in the absence of trypanosome agglutination. The latter process leads to a more rapid elimination of complement-fixing VSG-antibody complexes.

Comparison of the effects of immune killing mechanisms on Trypanosoma brucei parasites of slender and stumpy morphology

Trypanosoma brucei slender forms predominate over stumpy forms as the parasite population grows but at the peak of a parasitaemic wave and during remission of infection stumpy forms predominate. To determine whether this change in predominance might be caused by selective killing of slender forms, the fates of slender and stumpy form trypanosomes in two in vitro assays of immune-mediated killing were compared. Parasite populations in which > 90% of cells were of slender morphology were observed to be killed by antibody-dependent complement-mediated lysis approximately five times faster than populations in which < 15% of cells were slender and most were of intermediate or stumpy morphology. Quantification of the relationship between the proportion of slender forms in the population and the rate of lysis indicated that slender forms were killed approximately 7.3 times faster than other forms. In an opsonization assay, no differences were observed between slender and stumpy forms in the extent to which they attached to macrophages in an antibody-dependent manner. These results suggest that the change in proportions of slender and stumpy forms at the peak of a parasitaemic wave results from slender forms being more susceptible to complement-mediated killing as the antibody response develops.

Restricted rotation analogs of S-adenosylmethionine: synthesis, evaluation as inhibitors of S-adenosylmethionine decarboxylase, and potential use as selective antitrypanosomal agents

A series of restricted rotation analogs of S-adenosylmethionine were synthesized and evaluated as inhibitors of S-adenosylmethionine decarboxylase from Escherichia coli. These analogs were also evaluated for inhibitory activity against cultured mammalian cells, and against the parasite Trypanosoma brucei brucei. All analogs tested appeared to selectively inhibit trypanosomal growth. In particular, compound 5 (AdoMac) inhibits the growth of Trypanosoma brucei brucei with an IC 50 of 5.2μM.

A novel microtubule-binding motif identified in a high molecular weight microtubule-associated protein from Trypanosoma brucei.

The major component of the cytoskeleton of the parasitic hemoflagellate Trypanosoma brucei is a membrane skeleton which consists of a single layer of tightly spaced microtubules. This array encloses the entire cell body, and it is apposed to, and connected with, the overlying cell membrane. The microtubules of this array contain numerous microtubule-associated proteins. Prominent among those is a family of high molecular weight, repetitive proteins which consist to a large extent of tandemly arranged 38-amino acid repeat units. The binding of one of these proteins, MARP-1, to microtubules has now been characterized in vitro and in vivo. MARP-1 binds to microtubules via tubulin domains other than the COOH-termini used by microtubule-associated proteins from mammalian brain, e.g., MAP2 or Tau. In vitro binding assays using recombinant protein, as well as transfection of mammalian cell lines, have established that the repetitive 38-amino acid repeat units represent a novel microtubule-binding motif. This motif is very similar in length to those of the mammalian microtubule-associated proteins Tau, MAP2, and MAP-U, but both its sequence and charge are different. The observation that the microtubule-binding motifs both of the neural and the trypanosomal proteins are of similar length may reflect the fact that both mediate binding to the same repetitive surface, the microtubule, while their sequence and charge differences are in agreement with the observation that they interact with different domains of the tubulins.

Characterization of a cDNA encoding a cysteine-rich cell surface protein located in the flagellar pocket of the protozoan Trypanosoma brucei.

We have characterized a cDNA encoding a cysteine-rich, acidic integral membrane protein (CRAM) of the parasitic protozoa Trypanosoma brucei and Trypanosoma equiperdum. Unlike other membrane proteins of T. brucei, which are distributed throughout the cell surface, CRAM is concentrated in the flagellar pocket, an invagination of the cell surface of the trypanosome where endocytosis has been documented. Accordingly, CRAM also locates to vesicles located underneath the pocket, providing evidence of its internalization. CRAM has a predicted molecular mass of 130 kilodaltons and has a signal peptide, a transmembrane domain, and a 41-amino-acid cytoplasmic extension. A characteristic feature of CRAM is a large extracellular domain with a roughly 66-fold acidic, cysteine-rich 12-amino-acid repeat. CRAM is conserved among different protozoan species, including Trypanosoma cruzi, and CRAM has structural similarities with eucaryotic cell surface receptors. The most striking homology of CRAM is to the human low-density-lipoprotein receptor. We propose that CRAM functions as a cell surface receptor of different trypanosome species.

Characterization of a cDNA Encoding a Cysteine-Rich Cell Surface Protein Located in the Flagellar Pocket of the Protozoan Trypanosoma brucei

We have characterized a cDNA encoding a cysteine-rich, acidic integral membrane protein (CRAM) of the parasitic protozoa Trypanosoma brucei and Trypanosoma equiperdum. Unlike other membrane proteins of T. brucei, which are distributed throughout the cell surface, CRAM is concentrated in the flagellar pocket, an invagination of the cell surface of the trypanosome where endocytosis has been documented. Accordingly, CRAM also locates to vesicles located underneath the pocket, providing evidence of its internalization. CRAM has a predicted molecular mass of 130 kilodaltons and has a signal peptide, a transmembrane domain, and a 41-amino-acid cytoplasmic extension. A characteristic feature of CRAM is a large extracellular domain with a roughly 66-fold acidic, cysteine-rich 12-amino-acid repeat. CRAM is conserved among different protozoan species, including Trypanosoma cruzi, and CRAM has structural similarities with eucaryotic cell surface receptors. The most striking homology of CRAM is to the human low-density-lipoprotein receptor. We propose that CRAM functions as a cell surface receptor of different trypanosome species.

Survival and infectivity of Trypanosoma brucei in refrigerated pig blood

Trypanosoma brucei parasites survived for 72 h or longer in refrigerated pig blood. The survival period was directly proportional to the initial parasite concentration of the sample. Infectivity of the parasites declined faster than survival, being less than 1 per 10 5 motile organisms at 72 h. The stage of infection in the pig (early vs. late) did not appear to influence subsequent survival periods or infectivity of the parasites in vitro.

The major component of the paraflagellar rod of Trypanosoma brucei is a helical protein that is encoded by two identical, tandemly linked genes.

The flagellum of the parasitic hemoflagellate Trypanosoma brucei contains two major structures: (a) the microtubule axoneme, and (b) a highly ordered, filamentous array, the paraflagellar rod (PFR). This is a complex, three-dimensional structure, of yet unknown function, that extends along most of the axoneme and is closely linked to it. Its major structural component is a single protein of 600 amino acids. This PFR protein can assume two different conformations, resulting in two distinct bands of apparent molecular masses of 73 and 69 kD in SDS-gel electrophoresis. Secondary structure predictions indicate a very high helix content. Despite its biochemical similarity to the intermediate filament proteins (solubility properties, amino acid composition, and high degree of helicity), the PFR protein does not belong in this class of cytoskeletal proteins. The PFR protein is coded for by two tandemly linked genes of identical nucleotide sequence. Both genes are transcribed into stable mRNAs of very similar length that carry the mini-exon sequence at their 5' termini.

Coated Vesicles from the Protozoan Parasite Trypanosoma brucei: Purification and Characterization

A procedure was developed to purify a coated vesicle fraction from the protozoan parasite Trypanosoma brucei. Electron microscopy revealed a difference between T. brucei coated vesicles and clathrin-coated vesicles from other eukaryotes: trypanosome vesicles were larger (100 to 150 nm in diameter) and contained an inner coat of electron-dense material in addition to the external coat. Evidence suggests that the internal coat is the parasite's variant surface glycoprotein (VSG) coat. The SDS-PAGE analysis shows the major protein of T. brucei coated vesicles has a molecular mass of 61 kD, similar to VSG; this protein was recognized in an immunoblot by anti-VSG serum. Trypanosome coated vesicles also contain a protein which comigrates with the major protein (clathrin) of coated vesicles purified from rat brains. However, this protein is a minor component and it is not serologically cross-reactive with mammalian clathrin. Immunoblot analysis demonstrated that the parasite vesicles contained host IgG, IgM, and serum albumin.

Isolation of a subpellicular microtubule protein from Trypanosoma brucei that mediates crosslinking of microtubules.

The cell body of Trypanosomatidae is enclosed in densely packed, crosslinked, subpellicular microtubules closely underlying the plasma membrane. We isolated the subpellicular microtubules from bloodstream Trypanosoma brucei parasites by use of a zwitterion detergent. These cold stable structures were solubilized by a high ionic strength salt solution, and the soluble proteins that contained tubulin along with several other proteins were further fractionated by Mono S cation exchange column chromatography. Two distinct peaks were eluted containing one protein each, which had an apparent molecular weight of 52 kDa and 53 kDa. (Mr was determined by SDS-gel electrophoresis). Only the 52 kDa protein showed specific tubulin binding properties, which were demonstrated by exposure of nitrocellulose-bound trypanosome proteins to brain tubulin. When this protein was added to brain tubulin in the presence of taxol and GTP, microtubule bundles were formed with regular crosslinks between the parallel closely packed microtubules. The crosslinks were about 7.2 nm apart (center to center). Under the same conditions, but with the 53 kDA protein or without trypanosome derived proteins, brain tubulin polymerized to single microtubules. It is thus suggested that the unique structural organization of the subpellicular microtubules is dictated by specific parasite proteins and is not an inherent property of the polymerizing tubulin. The in vitro reconstituted microtubule bundles are strikingly similar to the subpellicular microtubule network of the parasite.

Large microtubule-associated protein of T. brucei has tandemly repeated, near-identical sequences.

The parasitic protozoon Trypanosoma brucei contains a highly organized membrane skeleton, consisting of a dense array of parallel, singlet microtubules that are laterally interconnected and that are also in tight contact with the overlying cell membrane. A high molecular weight, heat-stable protein from this membrane skeleton was isolated that is localized along the microtubules. Protease digestion experiments and sequencing of a cloned gene segment showed that most of the protein is built up by more than 50 nearly identical tandem repeats with a periodicity of 38 amino acids.

Spectrin-like proteins in the paraflagellar rod structure of Trypanosoma brucei.

A polyclonal, monospecific rabbit antibody to human erythrocyte spectrins cross-reacted with two sets of proteins (a doublet of 180/200K and a triplet of 67-66-65K; K = 10(3) Mr) in the parasitic protozoon Trypanosoma brucei brucei. Except for the 66K protein, the cross-reacting proteins are localized in the flagellum, on the basis of evidence from cell fractionation and immunofluorescence microscopy. Immunogold labelling and electron micrographs further revealed that the spectrin-like proteins are confined to the paraflagellar rod structure. The spectrin-like proteins with apparent molecular weights of 180 and 200 share homology with spectrin band 1, since V8-protease from Staphylococcus aureus generated similarly sized, antigenic peptides from these proteins. The results indicate homology between the cross-reacting proteins and human red cell spectrin.

A microtubule-binding protein of Trypanosoma brucei which contains covalently bound fatty acid.

Covalently linked fatty acids are increasingly recognized as an important type of post-translational protein modification. Many of such acylated proteins are found associated with cellular membranes. The membrane skeleton of the parasitic hemoflagellate Trypanosoma brucei consists of a regular array of microtubules which are tightly bound to the overlying cell membrane. A microtubule-binding protein (p41) has been identified within this structure which carries covalently bound fatty acid. The fatty acid linkage is sensitive to hydroxylamine treatment. After chemical transesterification, the released radioactivity co-migrates with fatty acid methyl esters in thin-layer chromatograms, establishing that the fatty acid was covalently bound to p41 via an ester (thioester) linkage. Upon detergent extraction of trypanosomes, p41 remains tightly bound to the cytoskeleton as long as Ca2+ ions are present. It can selectively be released from this structure by the addition of excess EGTA. Conversely, p41 binds to isolated cytoskeletons and to purified microtubules in vitro, the reaction again being entirely Ca2+-dependent.

A 60-kDa cytoskeletal protein from Trypanosoma brucei brucei can interact with membranes and with microtubules.

The cytoskeleton of eukaryotic cells is a major determinant of cellular architecture and of many cellular functions. In addition to or in place of the transcellular cytoskeleton, many eukaryotic cells also contain membrane-associated cytoskeletal structures (membrane skeletons), which are important for cellular structure and function. The membrane skeleton of the parasitic hemoflagellate Trypanosoma brucei consists of a dense array of singlet microtubules (subpellicular microtubules), which are tightly associated to the overlying cell membrane. This study reports the identification of a microtubule-associated protein from Trypanosoma brucei that constitutes a component of the link between this microtubular array and the cell membrane. The protein can bind in vitro both to microtubules and to membrane vesicles or liposomes. Furthermore, it can crosslink microtubules and membrane vesicles, suggesting that it exerts a similar function in the membrane skeleton.

Subpellicular and flagellar microtubules of Trypanosoma brucei brucei contain the same alpha-tubulin isoforms.

The cytoskeleton of the parasitic hemoflagellate Trypanosoma brucei brucei essentially consists of two microtubule-based structures: a subpellicular layer of singlet microtubules, which are in close contact with the cell membrane, and the flagellar axoneme. In addition, the cells contain a small pool of soluble tubulin. Two-dimensional gel electrophoretic analysis of the tubulins present in these subcellular compartments revealed two distinct electrophoretic isoforms of alpha-tubulin, termed alpha 1 and alpha 3. alpha 1-Tubulin most likely represents the primary translation product, while alpha 3-tubulin is a posttranslationally acetylated derivative of alpha 1-tubulin. In the pool of soluble cytoplasmic tubulin, alpha 1 is the predominant species, while the very stable flagellar microtubules contain almost exclusively the alpha 3-tubulin isoform. The subpellicular microtubules contain both isoforms. Neither of the two alpha-tubulin isoforms is organelle specific, but the alpha 3 isoform is predominantly located in stable microtubules.