A multigene family encoding surface glycoproteins in Trypanosoma congolense

Trypanosoma congolense, the causative agent of the most important livestock disease in Africa, expresses specific surface proteins involved in its parasitic lifestyle. Unfortunately, the complete repertoire of such molecules is far from being deciphered. As these membrane components are exposed to the host environment, they could be used as therapeutic or diagnostic targets. By mining the T. congolense genome database, we identified a novel family of lectin-like glycoproteins (TcoClecs). These molecules are predicted to have a transmembrane domain, a tandem repeat amino acid motif, a signal peptide and a C-type lectin-like domain (CTLD). This paper depicts several experimental arguments in favor of a surface localization in bloodstream forms of T. congolense. A TcoClec gene was heterologously expressed in U-2 OS cells and the product could be partially found at the plasma membrane. TcoClecs were also localized at the surface of T. congolense bloodstream forms. The signal was suppressed when the cells were treated with a detergent to remove the plasma membrane or with trypsin to « shave » the parasites and remove their external proteins. This suggests that TcoClecs could be potential diagnostic or therapeutic antigens of African animal trypanosomiasis. The potential role of these proteins in T. congolense as well as in other trypanosomatids is discussed

Confining Trypanosoma brucei in emulsion droplets reveals population variabilities in division rates and improves in vitro cultivation

Trypanosome parasites are infecting mammals in Sub-Saharan Africa and are transmitted between hosts through bites of the tsetse fly. The transmission from the insect vector to the mammal host causes a number of metabolic and physiological changes. A fraction of the population continuously adapt to the immune system of the host, indicating heterogeneity at the population level. Yet, the cell to cell variability in populations is mostly unknown. We develop here an analytical method for quantitative measurements at the single cell level based on encapsulation and cultivation of single-cell Trypanosoma brucei in emulsion droplets. We first show that mammalian stage trypanosomes survive for several hours to days in droplets, with an influence of droplet size on both survival and growth. We unravel various growth patterns within a population and find that droplet cultivation of trypanosomes results in 10-fold higher cell densities of the highest dividing cell variants compared to standard cultivation techniques. Some variants reach final cell titers in droplets closer to what is observed in nature than standard culture, of practical interest for cell production. Droplet microfluidics is therefore a promising tool for trypanosome cultivation and analysis with further potential for high-throughput single cell trypanosome analysis

Procyclic trypanosomes recycle glucose catabolites and TCA cycle intermediates to stimulate growth in the presence of physiological amounts of proline

Trypanosoma brucei, a protist responsible for human African trypanosomiasis (sleeping sickness), is transmitted by the tsetse fly where the procyclic forms of the parasite develop in the proline-rich (1–2 mM) and glucose-depleted digestive tract. Proline is essential for the midgut colonization of the parasite in the insect vector, however other carbon sources could be available and used to feed its central metabolism. Here we show that procyclic trypanosomes can consume and metabolize metabolic intermediates, including those excreted from glucose catabolism (succinate, alanine and pyruvate), with the exception of acetate, which is the ultimate end-product excreted by the parasite. Among the tested metabolites, tricarboxylic acid (TCA) cycle intermediates (succinate, malate and α-ketoglutarate) stimulated growth of the parasite in the presence of 2 mM proline. The pathways used for their metabolism were mapped by proton-NMR metabolic profiling and phenotypic analyses of thirteen RNAi and/or null mutants affecting central carbon metabolism. We showed that (i) malate is converted to succinate by both the reducing and oxidative branches of the TCA cycle, which demonstrates that procyclic trypanosomes can use the full TCA cycle, (ii) the enormous rate of α-ketoglutarate consumption (15-times higher than glucose) is possible thanks to the balanced production and consumption of NADH at the substrate level and (iii) α-ketoglutarate is toxic for trypanosomes if not appropriately metabolized as observed for an α-ketoglutarate dehydrogenase null mutant. In addition, epimastigotes produced from procyclics upon overexpression of RBP6 showed a growth defect in the presence of 2 mM proline, which is rescued by α-ketoglutarate, suggesting that physiological amounts of proline are not sufficient per se for the development of trypanosomes in the fly. In conclusion, these data show that trypanosomes can metabolize multiple metabolites, in addition to proline, which allows them to confront challenging environments in the fly

A MAP6-Related Protein Is Present in Protozoa and Is Involved in Flagellum Motility

In vertebrates the microtubule-associated proteins MAP6 and MAP6d1 stabilize cold-resistant microtubules. Cilia and flagella have cold-stable microtubules but MAP6 proteins have not been identified in these organelles. Here, we describe TbSAXO as the first MAP6-related protein to be identified in a protozoan, Trypanosoma brucei. Using a heterologous expression system, we show that TbSAXO is a microtubule stabilizing protein. Furthermore we identify the domains of the protein responsible for microtubule binding and stabilizing and show that they share homologies with the microtubule-stabilizing Mn domains of the MAP6 proteins. We demonstrate, in the flagellated parasite, that TbSAXO is an axonemal protein that plays a role in flagellum motility. Lastly we provide evidence that TbSAXO belongs to a group of MAP6-related proteins (SAXO proteins) present only in ciliated or flagellated organisms ranging from protozoa to mammals. We discuss the potential roles of the SAXO proteins in cilia and flagella function

Microb Cell

, the causative agent of the most important livestock disease in Africa, expresses specific surface proteins involved in its parasitic lifestyle. Unfortunately, the complete repertoire of such molecules is far from being deciphered. As these membrane components are exposed to the host environment, they could be used as therapeutic or diagnostic targets. By mining the genome database, we identified a novel family of lectin-like glycoproteins (TcoClecs). These molecules are predicted to have a transmembrane domain, a tandem repeat amino acid motif, a signal peptide and a C-type lectin-like domain (CTLD). This paper depicts several experimental arguments in favor of a surface localization in bloodstream forms of . A TcoClec gene was heterologously expressed in U-2 OS cells and the product could be partially found at the plasma membrane. TcoClecs were also localized at the surface of bloodstream forms. The signal was suppressed when the cells were treated with a detergent to remove the plasma membrane or with trypsin to « shave » the parasites and remove their external proteins. This suggests that TcoClecs could be potential diagnostic or therapeutic antigens of African animal trypanosomiasis. The potential role of these proteins in as well as in other trypanosomatids is discussed

Diagnosis of African animal trypanosomiases: advantages, limitations and new improvement ways

Les trypanosomiases animales d’origine africaine représentent typiquement une maladie tropicale négligée. Elles sont causées par des parasites sanguicoles du genre Trypanosoma transmis par des insectes hématophages, de manière cyclique par les mouches tsé-tsé pour Trypanosoma congolense, T. vivax et T. brucei brucei, qui causent la nagana, de manière mécanique pour T. evansi, agent de la surra, et enfin par transmission sexuelle pour T. equiperdum, qui cause la dourine. La nagana est présente dans 38 pays d’Afrique subsaharienne où elle peut affecter de nombreuses espèces animales, sauvages et domestiques. Près de 55 millions de bovins vivent sous risque trypanosomien, sans compter les petits ruminants. Ces maladies détériorent la condition physique de l’animal, induisant une forte baisse de productivité. Dans les cas les plus sévères, et en l’absence de traitement, la mort survient en quelques semaines. L’impact socio-économique est estimé à 4,75 milliards de dollars de pertes annuelles, ce qui fait de ces maladies l’un des obstacles majeurs au développement de l’élevage en Afrique. Le contrôle de ces maladies se heurte à l’absence de vaccin, à des traitements dont les molécules sont peu nombreuses et contre lesquelles se développent de plus en plus de résistances de la part des parasites, et enfin à un diagnostic, moléculaire ou sérologique, dont la robustesse demande à être grandement améliorée. Les signes cliniques ne sont pas spécifiques, le diagnostic parasitologique est souvent peu sensible, et les méthodes moléculaires ne sont pas applicables sur le terrain. Les méthodes d’immunodiagnostic sous forme de tests de diagnostic rapide sont les seules adaptées au terrain, mais les rares tests existants sont très peu accessibles (disponibilité, prix), et manquent de spécificité et/ou de sensibilité. Ici, nous traiterons des limites et des avantages comparatifs des méthodes actuelles de diagnostic et proposerons de nouvelles pistes d’amélioration de ces dernières pour un meilleur contrôle de la maladie.The animal trypanosomiases of African origin are a rather typical example of a neglected tropical disease. They are caused by blood parasites of the Trypanosoma genus transmitted by haematophagous insects, cyclically by tsetse flies for Trypanosoma congolense, T. vivax and T. brucei brucei, which cause nagana, mechanically by T. evansi, the agent of surra, and finally by T. equiperdum, adapted to sexual transmission, which causes dourine. Nagana affects 38 African countries in the sub-Saharan region with 55 million cattle at risk, not counting small ruminants. These diseases deteriorate the animal’s physical condition, leading to a sharp drop in productivity; in the most severe cases, and in the absence of treatment, the animal dies within a few weeks. The socio-economic impact is estimated at US$ 4.75 billion in annual losses, making these diseases one of the major obstacles to livestock development in Africa. The control of these diseases is hampered by the lack of vaccines, a handful of molecules for treatment against which parasites are increasingly developing resistance, and finally, molecular or serological diagnostics whose robustness needs to be greatly improved. Clinical signs are not specific, parasitological diagnosis is often not very sensitive, and molecular methods are not applicable in the field. Immunodiagnostic methods in the form of rapid diagnostic tests are the only ones suitable for the field, but the few existing tests are poorly available and lack specificity and/or sensitivity. Here we address the advantages and limitations of current diagnostic methods and propose new ways of improving them for better disease control

Les méthodes de diagnostic des trypanosomiases animales africaines : avantages, limites et nouvelles pistes d’amélioration

International audienceThe animal trypanosomiases of African origin are a rather typical example of a neglected tropical disease. They are caused by blood parasites of the Trypanosoma genus transmitted by haematophagous insects, cyclically by tsetse flies for Trypanosoma congolense, T. vivax and T. brucei brucei, which cause nagana, mechanically by T. evansi, the agent of surra, and finally by T. equiperdum, adapted to sexual transmission, which causes dourine. Nagana affects 38 African countries in the sub-Saharan region with 55 million cattle at risk, not counting small ruminants. These diseases deteriorate the animal’s physical condition, leading to a sharp drop in productivity; in the most severe cases, and in the absence of treatment, the animal dies within a few weeks. The socio-economic impact is estimated at US$ 4.75 billion in annual losses, making these diseases one of the major obstacles to livestock development in Africa. The control of these diseases is hampered by the lack of vaccines, a handful of molecules for treatment against which parasites are increasingly developing resistance, and finally, molecular or serological diagnostics whose robustness needs to be greatly improved. Clinical signs are not specific, parasitological diagnosis is often not very sensitive, and molecular methods are not applicable in the field. Immunodiagnostic methods in the form of rapid diagnostic tests are the only ones suitable for the field, but the few existing tests are poorly available and lack specificity and/or sensitivity. Here we address the advantages and limitations of current diagnostic methods and propose new ways of improving them for better disease control.Les trypanosomiases animales d’origine africaine représentent typiquement une maladie tropicale négligée. Elles sont causées par des parasites sanguicoles du genre Trypanosoma transmis par des insectes hématophages, de manière cyclique par les mouches tsé-tsé pour Trypanosoma congolense, T. vivax et T. brucei brucei, qui causent la nagana, de manière mécanique pour T. evansi, agent de la surra, et enfin par transmission sexuelle pour T. equiperdum, qui cause la dourine. La nagana est présente dans 38 pays d’Afrique subsaharienne où elle peut affecter de nombreuses espèces animales, sauvages et domestiques. Près de 55 millions de bovins vivent sous risque trypanosomien, sans compter les petits ruminants. Ces maladies détériorent la condition physique de l’animal, induisant une forte baisse de productivité. Dans les cas les plus sévères, et en l’absence de traitement, la mort survient en quelques semaines. L’impact socio-économique est estimé à 4,75 milliards de dollars de pertes annuelles, ce qui fait de ces maladies l’un des obstacles majeurs au développement de l’élevage en Afrique. Le contrôle de ces maladies se heurte à l’absence de vaccin, à des traitements dont les molécules sont peu nombreuses et contre lesquelles se développent de plus en plus de résistances de la part des parasites, et enfin à un diagnostic, moléculaire ou sérologique, dont la robustesse demande à être grandement améliorée. Les signes cliniques ne sont pas spécifiques, le diagnostic parasitologique est souvent peu sensible, et les méthodes moléculaires ne sont pas applicables sur le terrain. Les méthodes d’immunodiagnostic sous forme de tests de diagnostic rapide sont les seules adaptées au terrain, mais les rares tests existants sont très peu accessibles (disponibilité, prix), et manquent de spécificité et/ou de sensibilité. Ici, nous traiterons des limites et des avantages comparatifs des méthodes actuelles de diagnostic et proposerons de nouvelles pistes d’amélioration de ces dernières pour un meilleur contrôle de la maladie

LdFlabarin, a new BAR domain membrane protein of Leishmania flagellum.

International audienceDuring the Leishmania life cycle, the flagellum undergoes successive assembly and disassembly of hundreds of proteins. Understanding these processes necessitates the study of individual components. Here, we investigated LdFlabarin, an uncharacterized L. donovani flagellar protein. The gene is conserved within the Leishmania genus and orthologous genes only exist in the Trypanosoma genus. LdFlabarin associates with the flagellar plasma membrane, extending from the base to the tip of the flagellum as a helicoidal structure. Site-directed mutagenesis, deletions and chimera constructs showed that LdFlabarin flagellar addressing necessitates three determinants: an N-terminal potential acylation site and a central BAR domain for membrane targeting and the C-terminal domain for flagellar specificity. In vitro, the protein spontaneously associates with liposomes, triggering tubule formation, which suggests a structural/morphogenetic function. LdFlabarin is the first characterized Leishmania BAR domain protein, and the first flagellum-specific BAR domain protein

<i>Tb</i>SAXO is an axoneme-associated protein in <i>T. brucei</i>.

<p><b>A</b>. Immuno-labeling and localization of <i>Tb</i>SAXO on PCF cytoskeletons. Left panel: <i>Tb</i>SAXO localization in the flagellum was identified by the mAb25 antibody (green). Labeling extends along the entire length of the flagellum from the flagellar transition zone (*, labeled with the FTZC antibody) to the distal tip. The PFR is labeled red and begins where the flagellum exits the cell (antibody L8C4). Right panel: a merge of IF and phase contrast. N: nucleus. K: kinetoplast. F: flagellum. Bar, 5 µm. <b>B</b>. Images of the proximal flagellar regions of PCF cytoskeletons from cells through mitosis and cytokinesis. In each row, the left panel shows the PFR and FTZC (*) (red), the center panel <i>Tb</i>SAXO (green), and the right panel shows merged images. The cell cycle stages are defined as 1K1N1F (1 Kinetoplast, 1 Nucleus, 1 Flagellum), 1K1N2F, 2K1N2F and 2K2N2F in rows a–d respectively. <i>Tb</i>SAXO labeling is present immediately distal to the FTZC and is clearly distinct from PFR staining. Bar, 1 µm. <b>C</b>. Immuno-gold electron microscopy reveals that <i>Tb</i>SAXO is localized in the axoneme. Mab25 immuno-gold particles can be seen mainly on the axoneme and not on the PFR of flagella of PCF WT cells. Bars, 100 nm.</p

<i>Tb</i>SAXO RNAi knockdowns exhibit impaired flagellar motility.

<p>Inducible RNAi<i>^TbSAXO</i> in PCF (<b>a, b, c, d</b>) and BSF (<b>e, f, g, h</b>) cells. Growth curves of PCF (<b>a</b>) and BSF (<b>e</b>) RNAi<i>^TbSAXO</i> cell lines. Corresponding WBs (PCF in <b>b</b>, BSF in <b>f</b>) of WT (parental), RNAi non-induced (-), and 24 h and 96 h induced cells probed with mAb25 and L8C4 (anti-PFR2). For PCF 5.10⁶ cells were used and 1.25×10⁵ cells for BSF. <b>c</b>. Sedimentation assay of PCF RNAi. WT (closed squares). RNAi non-induced (−TET) (closed triangles) and induced (+TET) (open circles). <b>d</b>. Mobility graph obtained from Movie S1. The positions of individual cells are plotted at 2.5 s intervals. Open circle: starting position of each cell. Arrowhead: ending position. Number in parentheses: time in seconds of a given cell was within the field of view. Bar, 10 µm. <b>g</b>. Graph of cell populations with orthodox and unorthodox kinetoplast number in BSF RNAi cultures (72 h of induction). K: kinetoplast. N: nucleus. Asterisks indicate statistical significance compared with the WT population, and −TET <i>versus</i> +TET condition (*<i>P<0.1</i>; ** <i>P<0.05</i>; ***<i>P<0.01</i>). <b>h</b> Electron-micrograph of a thin section of an aberrant BSF RNAi induced cell (72 h). (*) indicates a flagellum. Scale bar, 2 µm. Error bars in a, c, e, and g represent the standard error from 3 independent experiments.</p