Estrutura cristalográfica da enzima superóxido dismutase de Trypanosoma brucei e análise da especificidade do metal incorporado por acoplamento estatístico / Crystal structure of the superoxide dismutase enzyme from Trypanosoma brucei and incorporated metal specificity analysis by statistical coupling.

Bachega, José Fernando Ruggiero

25 July 2008

A doença do sono é causada pelo parasita Tripanosoma brucei. Considerada uma doença negligenciada, mata milhares de pessoas todos os anos na África subsaariana. O T.brucei não apresenta resposta imune pronunciada, o que dificulta o desenvolvimento de vacinas, e os medicamentos disponíveis são escassos. Os tripanossomatídeos são comprovadamente sensíveis ao stress oxidativo causado pelo radical superóxido. Assim, as enzimas superóxido dismutases (SODs) são a primeira linha de defesa contra esse radical. As SODs são metalo enzimas (EC 1.5.1.1) capazes de catalisar a dismutação do superóxido em oxigênio molecular e peróxido de hidrogênio. São classificadas de acordo com o metal incorporado na estrutura: cobre e zinco (CuZnSOD), ferro ou manganês (Fe/MnSOD) e níquel (NiSODs). Neste trabalho de mestrado, a enzima TbFeSODB2 de T.brucei foi, expressa, purificada, cristalizada e teve sua estrutura resolvida. A estrutura cristalográfica da enzima do parasita foi comparada com a enzima humana análoga contendo manganês (HuMnSOD), onde foram evidenciadas as principais diferenças entre as duas estruturas que podem ser exploradas para o desenho do novos inibidores seletivos. Foi realizada uma análise de acoplamento estatístico, onde com base em um alinhamento múltiplo dessas enzimas determinou-se resíduos que são capazes de interferir na seletividade do metal incorporado e estado oligomérico das SODs. / Sleeping sickness, caused by the parasite Tripanosoma brucei, is considered a neglected disease, killing thousands of people every year in subsaharian Africa. T. brucei does not generate a pronounced immune response, difficulting the development of vaccines. Furthermore, available medicines are scarce. Tripanosomatides are known to be sensitive to oxidative stress caused by the superoxide radical. Therefore, the superoxide dismutase enzymes (SODs) are a primary line of defence for the parasites against this radical. SODs are metalloenzymes (EC 1.5.1.1) capable of catalyzing superoxide dismutation into molecular oxygen and hydrogen peroxide. SODs are classified according to the incorporated metal: copper/zinc (CuZnSOD), iron/manganese (Fe or MnSOD) and nickel (NiSODs). In the work presented here, TbFeSODB2 from T. brucei was expressed, purified, crystallized and its 3D structure solved. The crystal structure of the parasite enzyme was compared to the homologous human enzyme containing manganese (HuMnSOD), revealing evidence for differences between both structures which could be exploited in the design of new selective inhibitors. In addition, a statistical coupling analysis was performed on the entire Fe/MnSOD superfamily, based on a multiple sequence alignment. It was shown that this technique was able to identify novel residue determinants of metal selectivity and oligomeric state.

P15 trypanosome microtubule associated protein : structure/function analysis and vaccine development for the prevention of African sleeping sickness.

Rasooly, Reuven.

January 2001

Trypanosomes are hemoflagellated protozoan parasites causing chagas disease in South America, Leishmaniasis throughout the world, and African sleeping sickness in humans and nagana in animals in Africa. About 55 million people and 25 million cattle have been estimated to be at risk of contracting African sleeping sickness or nagana respectively. Once injected into the blood stream via the bite of a tsetse fly, the parasite evades the host's immune response by repeatedly changing its surface antigens, thus making the development of a vaccine seem impossible. Furthermore, chemotherapy existing today can be toxic, suggesting that novel methods to prevent diseases caused by trypanosomes are essential. All parasites of the Trypanosomatidae family contain unique microtubular structures called the subpellicular microtubules. Microtubules are made of tubulin and of microtubule associated proteins (MAPs). Unlike other microtubules, the subpellicular microtubules are crosslinked to one another and to the plasma membrane. The unique structure of the subpellicular microtubules has been attributed to unique trypanosome subpellicular MAPs which stabilize the microtubule polymers and crosslink them to one another. Three unique types of subpellicular MAPs have been identified: MARP, which is a high molecular mass MAP that stabilizes microtubules, p52 that is a 52kDa MAP which crosslinks microtubules, and pI5, which is a I5kDa protein which bundles microtubules. Because trypanosome MAPs have been shown to be unique to these parasites, these molecules could serve as useful target sites for therapy. In this study pI5 was cloned and sequenced and shown to contain highly organized, nearly identical tandem repeats with a periodicity of 10 amino acids, rich in positively charged and in hydrophobic amino acids. It was shown that pI5 can also bind phospholipids, suggesting that it may not only bundle the microtubule polymer through its positively charged amino acids but may also crosslink the microtubules to the plasma membrane through its hydrophobic regions, thus contributing to the stable structure of the subpellicular microtubules. To test for the efficiency of pI5 as a vaccine candidate, the recombinant pI5 was cloned into an adenovirus, which was used as a vaccine delivery system for pI5. Mice were vaccinated with the native purified pI5, with the expressed recombinant pI5 and with the adenovirus containing the recombinant pI5 gene (Ad-pI5). The results indicated that pI5 protected 100% of the animals vaccinated with the recombinant molecule (8/8), and 87% of the animals vaccinated with the native protein (7/S), while none of the control animals were protected. Animals that were vaccinated with the Ad-pI5 were protected but so were the control animals vaccinated with an adenovirus containing the lacZ gene. We have shown that vaccination with the adenovirus is associated with an elevated CDS+ T cell response which is known to be trypanostatic (S6), suggesting that animals vaccinated with Ad-pIS may have been protected not only by the specific anti-plS response but also by non specific immunity that was induced by the adenovirus itself. The source of the native and recombinant pI5 was from a different strain of T. brucei that was used for challenge. Since the subpellicular microtubules are common to all members of the Trypanosomatidae family, pI5 may ultimately serve as a common target for therapy to all types of diseases caused by trypanosomes. / Thesis (Ph.D.)-University of Natal, Pietermaritzburg, 2001.

Parasitic vaccines.

Microtubules.

Trypanosoma brucei.

Trypanosomiasis--Control.

Trypanosomiasis--Africa.

Theses--Microbiology.

Molecular analysis of the congopain gene family.

Kalundi, Erastus Mulinge.

January 2008

Animal trypanosomosis is a major constraint in livestock production in Sub-Saharan Africa. With the emergence of resistance against trypanocidal drugs, the cost and environmental concerns raised by vector control, and the challenge of antigenic variation in vaccine development, alternative control measures are being sought. An anti-disease strategy, whereby the immune response or chemotherapy is aimed towards pathogenic factors rather than the parasite itself, constitutes such a novel approach. Congopain is the major cysteine protease in Trypanosoma congolense, and upon release in the bloodstream of infected cattle, acts as a pathogenic factor. It is therefore an attractive candidate for an anti-disease vaccine. It was hence deemed necessary to investigate the variability of congopain-like cysteine proteases before attempting to design drugs and vaccines based on the inhibition of congopain. Most congopain-like cysteine protease genes of T. congolense exist in a single locus of 12-14 copies organised as tandem repeats of 2 kb gene units. A gene unit library of 120 clones was constructed out of several cosmid clones selected in a previous study that contained various lengths of the congopain locus. Some 24 gene unit clones were sequenced, and it was found that congopain genes cluster in three sub-families, named CP1 (8 clones), CP2 (12 clones) and CP3 (4 clones). The latter most characteristically shows a substitution of the active site cysteine by a serine. Isoform specific primers were designed and used to verify the proportions of the three isoforms (one third CP1, half CP2 and a sixth CP3) in the remaining clones of the library. Since this first study was conducted in one isolate, IL 3000, the results were subsequently validated in a large array of isolates, of T. congolense, as well as T. vivax and T. brucei subspecies, by a PCR approach. Finally, to gain access to copies of congopain genes that are not present in the locus, but rather scattered in the genome, an attempt was made to construct a 2 kb size-restricted genomic library. Only 206 clones could be produced, of which a mere 8 coded for congopain-like proteases. The fact that 7 out of 8 of these clones belong to CP3 (thought to be inactive) suggested a cloning artefact, possibly related to the activity of the cloned proteases. Overall, all congopain genes appear very conserved in a given species, with 87-99% identity at protein level. The pre- and pro-region were the most conserved, while the catalytic domain was the most variable, especially around the active site cysteine, with frequent replacement by a serine residue, and in one instance by phenylalanine. The histidine residue of the catalytic triad was also substituted by either a serine or a tyrosine in some instances. The proenzyme cleavage site sequence was also variable, with APEA being the predominant N-terminal sequence. RT-PCR analyses indicated that CP1, CP2 and CP3 mRNA are all present in the bloodstream forms of T. congolense, showing that these variants are likely to be expressed. The conclusion of this study is that, given the high overall conservation of congopain genes in the genome, for the purpose of anti-disease vaccine, it is likely that a single immunogen will suffice to raise antibody able to inhibit all circulating congopain-like cysteine proteases. For chemotherapy however, a more in-depth enzymatic characterisation of the mutants, involving functional recombinant expression, will have to be undertaken. / Thesis (M.Sc.)-University of KwaZulu-Natal, Pietermaritzburg, 2008.

Cysteine proteinases.

Trypanosomiasis in animals--Vaccination.

Molecular structure.

Genes.

Theses--Biochemistry.

Recombinant expression and evaluation of a- and b- tubulin from Trypanosoma congolense as vaccine candidates for African trypanosomiasis.

Bartlett, Cara-Lesley.

January 2010

African trypanosomiasis is caused by protozoan parasites known as trypanosomes, which are transmitted by the tsetse fly, affecting both humans and animals. Trypanosoma congolense is one of the main trypanosome species affecting cattle and causes the disease known as nagana. Control of animal African trypanosomiasis currently relies on chemotherapy and vector control methods, neither of which has proven satisfactory. An effective vaccine against trypanosomiasis would be the most cost effective solution to control the disease; however, due to the phenomenon of antigenic variation, intrinsic to the parasite’s outer coat of variable surface glycoprotein, this has not yet been achieved. Recent vaccine efforts have been centred on identification of invariant parasite antigens for use as vaccine candidates. Trypanosome cytoskeleton components have in recent years been shown to be capable of providing a protective immune response against trypanosome infection. These include tubulin proteins, which form the main components of the cytoskeleton, as well as microtubule associated proteins (MAPs) and paraflagellar rod proteins. In the present study α- and β-tubulin from T. congolense were recombinantly expressed and their immuno-protective potential in mice assessed. Amplification of both α- and β-tubulin ORFs from T. congolense genomic DNA was followed by cloning of the amplicons into the T-vector pTZ57R/T, and thereafter sub-cloning into the bacterial expression vector, pET238a and the yeast expression vector pPICZαA28. Only the α-tubulin amplicon was successfully sub-cloned into pICZAαA28; however, no protein expression was achieved upon transfection of the methylotrophic yeast, Pichia pastoris, with this construct. Subcloning of both α- and β-tubulin inserts into pET28a was successful. Expression of recombinant α- and β-tubulin as fusion proteins with a histidine tag, both at a size of 55 kDa, was achieved in Escherichia coli host BL21 (DE3). Recombinant proteins were successfully purified using nickel chelate chromatography under denaturing conditions. Refolding was first attempted by dilution of purified denatured proteins in a refolding buffer followed by reconcentration, but was largely unsuccessful. A second, more successful refolding method was performed wherein denatured proteins were refolded by application of a decreasing gradient of urea, while bound to a nickel chelate column. Native tubulin from cultured T.congolense procyclics was successfully purified and renatured using a polymerisation/depolymerisation method for use as a control for immunisation. Mice were immunised separately with refolded recombinant α- and β-tubulin, native tubulin or an irrelevant protein VP4AA expressed in the same way as the tubulins. ELISA analysis confirmed the production of antibodies against each protein. Parasitaemia developed in all mice following challenge with T. congolense. Only the group immunised with β-tubulin recorded no deaths during the monitoring period despite the presence of parasitaemia, with 60% of mice immunised with α-tubulin or VP4AA and the no antigen control and no mice from the native tubulin immunised group surviving. The results showed that partial protection against trypanosomiasis caused by T. congolense infection was achieved in the group immunised with β-tubulin and suggest that β-tubulin may have vaccine potential. / Thesis (M.Sc.)-University of KwaZulu-Natal, Pietermaritzburg, 2010.

Livestock--Trypanotolerance.

Tubulins.

Trypanosoma.

Trypanosomiasis in animals--Vaccination.

Theses--Biochemistry.

Vivapain : a cysteine peptidase from Trypanosoma vivax.

Vather, Perina.

January 2010

African animal trypanosomosis is a devastating disease affecting livestock mainly found in sub-Saharan Africa. This disease is known as nagana and is transmitted by the trypanosome parasite from the tsetse fly vector to a mammalian host. There are three African trypanosomes namely Trypanosoma vivax, T. congolense and T. brucei brucei that are the causative agents responsible for this disease in African cattle. This disease is serious since it not only affects livestock but also has a negative impact on the sub-Saharan African economy. There is, therefore, a great demand for better control methods of the disease and suitable diagnostic methods. Current control measures such as the use of trypanocidal drugs, tsetse fly eradication methods and trypanotolerant cattle have become inadequate. The defence mechanism of the trypanosome to continuously change its surface coat by a process of antigenic variation has made it impossible to produce a suitable vaccine. Therefore, chemotherapy is still one of the key approaches for control of this wasting disease. The long existence of the current trypanocidal drugs has allowed the development of drug resistance. The development of new chemotherapeutic drugs is focused on targeting the pathogenic factors such as parasite cysteine peptidases that contribute to the disease. Vivapain is the main cysteine peptidase of T. vivax and shares high sequence identity with congopain, the main cysteine peptidase of T. congolense, which was previously shown to be a pathogenic factor contributing to trypanosomosis. Vivapain, thus, has potential as a target for chemotherapeutic drug design. Hence, the first part of this study involved the recombinant expression and enzymatic characterisation of vivapain for future production of new synthetic inhibitors for the use in new trypanocidal drugs. The catalytic domain of vivapain (Vp) was recombinantly expressed in the Pichia pastoris yeast expression system and enzymatically characterised. The main finding from this study was that Vp was only able to hydrolyse a substrate if the P2 position was occupied by either a hydrophobic Phe or Leu residue. Vp was also found to be active close to physiological pH and was inhibited by the reversible cysteine peptidases, leupeptin, antipain and chymostatin and the irreversible cysteine peptidases L-trans-epoxysuccinyl-leucylamido (4-guanidino) butane (E-64), iodoacetic acid (IAA) and iodoacetamide (IAN). A further important aspect of controlling trypanosomosis is the diagnosis of the disease. Clinical, parasitological, molecular and serological techniques have been applied and used to diagnose trypanosomosis. One of the most promising serological techniques has proven to be the enzyme-linked immunosorbent assay (ELISA), more specifically the antibody and antigen detection ELISAs. The main requirement for this technique is a readily available and reproducible antigen such as that produced by recombinant expression. While there are recombinant antigens that are available to be used to detect T. congolense, T. brucei brucei and even T. evansi infections, there are none available to detect T. vivax infections. In the second part of this study, a mutant inactive full length form of vivapain (FLVp) was expressed in a bacterial expression system for the detection of T. vivax infections. Antibodies against this antigen were produced in both chickens and mice. Both the chicken IgY and mice sera were able to detect the recombinant FLVp in western blots. The mice sera were also able to detect native vivapain in a T. vivax lysate, which is very promising for future use of the FLVp antigen and the corresponding antibodies in diagnosis of T. vivax infections in sera of infected animals. / Thesis (M.Sc.)-University of KwaZulu-Natal, Pietermaritzburg, 2010.

Peptidase.

Trypanosoma.

Drug development.

Theses--Biochemistry.

Estrutura cristalográfica da enzima superóxido dismutase de Trypanosoma brucei e análise da especificidade do metal incorporado por acoplamento estatístico / Crystal structure of the superoxide dismutase enzyme from Trypanosoma brucei and incorporated metal specificity analysis by statistical coupling.

José Fernando Ruggiero Bachega

25 July 2008

A doença do sono é causada pelo parasita Tripanosoma brucei. Considerada uma doença negligenciada, mata milhares de pessoas todos os anos na África subsaariana. O T.brucei não apresenta resposta imune pronunciada, o que dificulta o desenvolvimento de vacinas, e os medicamentos disponíveis são escassos. Os tripanossomatídeos são comprovadamente sensíveis ao stress oxidativo causado pelo radical superóxido. Assim, as enzimas superóxido dismutases (SODs) são a primeira linha de defesa contra esse radical. As SODs são metalo enzimas (EC 1.5.1.1) capazes de catalisar a dismutação do superóxido em oxigênio molecular e peróxido de hidrogênio. São classificadas de acordo com o metal incorporado na estrutura: cobre e zinco (CuZnSOD), ferro ou manganês (Fe/MnSOD) e níquel (NiSODs). Neste trabalho de mestrado, a enzima TbFeSODB2 de T.brucei foi, expressa, purificada, cristalizada e teve sua estrutura resolvida. A estrutura cristalográfica da enzima do parasita foi comparada com a enzima humana análoga contendo manganês (HuMnSOD), onde foram evidenciadas as principais diferenças entre as duas estruturas que podem ser exploradas para o desenho do novos inibidores seletivos. Foi realizada uma análise de acoplamento estatístico, onde com base em um alinhamento múltiplo dessas enzimas determinou-se resíduos que são capazes de interferir na seletividade do metal incorporado e estado oligomérico das SODs. / Sleeping sickness, caused by the parasite Tripanosoma brucei, is considered a neglected disease, killing thousands of people every year in subsaharian Africa. T. brucei does not generate a pronounced immune response, difficulting the development of vaccines. Furthermore, available medicines are scarce. Tripanosomatides are known to be sensitive to oxidative stress caused by the superoxide radical. Therefore, the superoxide dismutase enzymes (SODs) are a primary line of defence for the parasites against this radical. SODs are metalloenzymes (EC 1.5.1.1) capable of catalyzing superoxide dismutation into molecular oxygen and hydrogen peroxide. SODs are classified according to the incorporated metal: copper/zinc (CuZnSOD), iron/manganese (Fe or MnSOD) and nickel (NiSODs). In the work presented here, TbFeSODB2 from T. brucei was expressed, purified, crystallized and its 3D structure solved. The crystal structure of the parasite enzyme was compared to the homologous human enzyme containing manganese (HuMnSOD), revealing evidence for differences between both structures which could be exploited in the design of new selective inhibitors. In addition, a statistical coupling analysis was performed on the entire Fe/MnSOD superfamily, based on a multiple sequence alignment. It was shown that this technique was able to identify novel residue determinants of metal selectivity and oligomeric state.

Functional expression of Trypanosoma congolense pyroglutamyl peptidase type 1 and development of reverse genetics tools.

Mucache, Hermogenes Neves.

06 November 2013

Trypanosoma congolense is a protozoan parasite transmitted by tsetse flies. It causes bovine trypanosomosis, the major disease for livestock in sub-Saharan Africa. Control methods include trypanocidal drugs and vector control, but none is fully satisfactory, due to resistance and environmental issues. A method that would have the greatest impact on controlling the disease is vaccination. However, development of a conventional vaccine has been hampered by the mechanism of antigenic variation, which allows the parasite to evade the host’s immune system. An alternative strategy in vaccine design is to target the bioactive compounds released by dead and dying trypanosomes. This approach is termed ‘‘anti-disease’’, and does not affect the survival of the parasite but targets the pathogenic factors released by the trypanosomes. The development of a successful anti-disease vaccine necessitates knowledge of all pathogenic factors involved in the disease process. Several macromolecules, primarily peptidases, have been implicated in the pathogenesis of trypanosomosis. Pyroglutamyl peptidase type I (PGP) was shown to be involved in abnormal degradation of thyrotropin- and gonadotropin-releasing hormones in rodents infected with T. brucei, but to date no data are available on the T. congolense PGP. Molecular cloning and expression in E. coli of the coding sequence of T. congolense PGP, as well as the enzymatic characterisation of the recombinant protein, are reported here, completed by the development of reverse genetics tools for studies of gene function. A 678 bp PCR fragment covering the complete open reading frame of PGP was cloned and sequenced. The deduced amino acid sequence showed 52% and 29% identity with the T. brucei and Leishmania major enzymes respectively. The catalytic residues Glu, Cys and His described in Bacilus amyloliquefaciens PGP are conserved in the T. congolense sequence. PGP was expressed in bacterial systems as a soluble active, 26 kDa enzyme. The recombinant enzyme showed activity specific for the fluorescent substrate pGlu-AMC, with a kcat/Km of 1.11 s-1μM. PGP showed activity in the pH 6.5-10 range, with maximal activity at pH 9.0. The enzyme was strongly inhibited by sulfhydryl-blocking reagents such as iodoacetic acid and iodoacetamide with a kass of 125 M-1 s-1 and 177 M-1 s-1 respectively. Antibodies raised in chickens against the recombinant enzyme allowed the detection of native PGP in both procyclic and bloodstream T. congolense developmental stages, and displayed complete inhibition of the enzyme in vitro at physiological concentrations. To get insight into the role of PGP in parasite biology and trypanosomosis progression, two types of vectors for reverse genetics studies were developed. For RNA interference, a 400 bp 3′ end segment of the PGP open reading frame was cloned into the plasmid p2T7Ti, that will allow PGP gene down-regulation upon integration into the genome of an engineered tetracycline-inducible strain such as TRUM:29-13. For gene knock-out, several rounds of molecular engineering were carried-out in order to create two plasmid vectors, pGL1184-based (blasticidin resistance) and pGL1217-based (neomycin resistance), each bearing 200 bp-long regions at the 5′ and 3′ ends of the PGP open reading frame. In subsequent studies, taking advantage of the recent advances in culture and transformation of T. congolense, these plasmids will allow the creation of single and double knock-out mutants of PGP. / Thesis (M.Sc.)-University of KwaZulu-Natal, Pietermaritzburg, 2012.

Trypanosomiasis in animals--Vaccination.

Livestock--Trypanotolerance.

Trypanosoma.

Theses--Biochemistry.

Identification and characterisation of novel pathogenic factors of Trypanosoma congolense.

Pillay, Davita.

January 2010

Trypanosoma congolense is a major causative agent of the bovine disease trypanosomosis which has a considerable economic impact on sub-Saharan Africa. Current control methods for trypanosomosis are unsatisfactory and vaccine development has been hampered by antigenic variation. An anti-disease vaccine is based on the idea that disease is caused by the pathogenic factors released by the parasite, rather than by the parasite itself. Therefore, if these pathogenic factors could be neutralised by antibodies produced by vaccination, the disease could be circumvented. The method used here for identification of novel pathogenic factors is based on the concept that trypanotolerant cattle are able to mitigate the disease by generating a specific immune response against a few key antigens (pathogenic factors). Two immuno-affinity columns were therefore prepared: one containing IgG from noninfected sera and a second column containing IgG from trypanotolerant N’Dama cattle serially infected with T. congolense. The differential binding of antigens to the two columns allowed identification of antigens specifically recognised by the immune system of a trypanotolerant animal, i.e. potential pathogenic factors. The most promising antigens identified included several variant cathepsin L-like cysteine peptidases (CPs) and the Family M1 Clan MA aminopeptidases (APs). For the CPs, a study of the genetic organisation was conducted in order to further understand the variability present in this gene family. To this end, two different mini-libraries of cathepsin L-like genes were prepared: one in which genes as different as possible from congopain (the major CP of T. congolense) were selected, and a second which contained all possible genes present in the congopain array. Analysis of the sequences obtained in these two mini-libraries showed that there was significant variability of the genes within the congopain array. Two variants of CPs, chosen for differences in their catalytic triads, were cloned for expression. The recombinantly expressed CP variants differed in substrate preferences from one another and from C2 (the recombinant truncated form of congopain), and surprisingly, all enzymes were active at physiological pH. The two APs were cloned and expressed as insoluble inclusion bodies in an E. coli system, and subsequently refolded. The refolded APs showed a substrate preference for H-Ala-AMC, an optimum pH of 8.0, localisation to the cytoplasm and inhibition by puromycin. The two APs were not developmentally regulated and present in procyclic, metacyclic and bloodstream form parasites. Down-regulation of both APs by RNAi resulted in a slightly reduced growth rate in procyclic parasites in vitro. Immunisation of BALB/c mice with the APs did not provide protection when challenged with T. congolense. For an anti-disease vaccine to be protective, it would possibly have to include all pathogenic factors, including the two APs and at least one CP described in the present study. / Thesis (Ph.D.)-University of KwaZulu-Natal, Pietermaritzburg, 2010.

Trypanosoma.

African trypanosomiasis--Pathogenesis.

Antigens.

Peptidase.

Cattle--Immunology.

Theses--Biochemistry.

Caractérisation des sialidases chez le parasite Trypanosoma vivax : rôle dans l’anémie / Characterization of sialidase in the parasite Trypanosoma vivax : role in anemia

Guegan, Fabien

09 December 2010

La trypanosomiase animale africaine (TAA) est une pathologie qui sévit en Afrique sub-saharienne et qui représente un obstacle majeur à l’élevage du bétail et à la production agricole. Cette pathologie est causée principalement par les parasites T. congolense et T. vivax. Elle affecte le bétail, les animaux domestiques et sauvages, sur un territoire de 10 millions de km2 où ces animaux cohabitent avec l’insecte vecteur, la mouche Tsé-Tsé. L’infection du bétail par ces parasites provoque une anémie sévère pouvant entraîner la mort de l’animal. Dans ce contexte, nous nous sommes intéressés à l’étude des mécanismes impliqués dans le développement de l’anémie lors de l’infection de l’animal par T. vivax. Pour cela, nous avons développé un modèle murin d’infection par T. vivax. Nous avons démontré que l’infection à T. vivax induit d’importantes modifications des acides sialiques présents à la surface des érythrocytes. De plus, nous avons établi un système expérimental « ex-vivo » qui nous a permis de montrer que l’anémie observée au cours de l’infection était dépendante du mécanisme d’érythrophagocytose. Les modifications en acides sialiques des érythrocytes constitueraient un signal de reconnaissance des érythrocytes par les cellules phagocytaires de l’hôte. Par ailleurs, nous avons mis au point des conditions de culture in vitro pour tous les stades parasitaires de T. vivax et T. congolense afin de développer des outils de génomique fonctionnelle. Ces avancées nous ont notamment permis d’identifier des enzymes de type sialidase et trans-sialidase et de détecter les activités enzymatiques correspondantes dans les formes infectieuses de ces parasites. Nous avons exprimé des trans-sialidases recombinantes et démontré qu’elles étaient capables de reproduire in vitro certaines des caractéristiques pathologiques définies in vivo : modifications en acides sialiques des érythrocytes et augmentation de l’érythrophagocytose. Par conséquent, ces travaux ont permis pour la première fois de mettre en évidence un lien entre l’expression des sialidases et trans-sialidases chez le parasite T. vivax et le développement de l’anémie au cours de la TAA. / African animal trypanosomiasis (AAT) is a parasitic disease occurring in sub-Saharan Africa. It impairs livestock development and agricultural production. This disease is mainly caused by T. congolense and T. vivax parasites and is present in livestock, domestic and wild animals, covering an area of over a 10 millions km2, that is known as the Tsé-Tsé fly belt. These infections cause severe anaemia leading to animal death in most cases. In this context, we were interested in unravelling the mechanisms responsible for anaemia caused by T. vivax infection. We developed a murine model for T. vivax infection and our data pointed out important sialic acid modifications of the mouse erythrocyte surface during infection. Additionally, an ex-vivo experimental model was established which proved that anaemia associated with infection depends on erythrophagocytosis. Consequently, we propose that sialic acid modifications associated with infection are involved in the erythrophagocytosis mechanism. Furthermore, in order to develop genetic tools we established in vitro culture conditions for all parasite forms of T. vivax and T. congolense. Parasite cultivation allowed the detection of sialidase and trans-sialidase activity and identifies the presence and function of these proteins in the mammalian form of the parasite. Moreover, trans-sialidase recombinant proteins reproduced some of the T. vivax infection characteristics such as sialic acid modification and increased erythrophagocytosis. Consequently, this work provides the first evidence that links the expression of sialidases and trans-sialidases in T. vivax with the development of anemia during AAT.

Trypanosomiase

Trypanosoma vivax

Sialidases

Anémie

Trypanosomiasis

Trypanosoma vivax

Sialidase

Anemia

African Sleeping Sickness in British Uganda and Belgian Congo, 1900-1910: Ecology, Colonialism, and Tropical Medicine

bivens, dana

01 January 2015

This thesis deconstructs the social, ecological, and colonial elements of the 1900-1910 Human African Trypanosomiasis (African Sleeping Sickness) epidemic which affected British Uganda and Belgian Congo. This paper investigates the epidemic’s medical history, and the subsequent social control policies which sought to govern the actions of the indigenous population. In addition, this paper argues that the failure to understand and respect the region’s ecological conditions and local knowledge led to disease outbreaks in epidemic proportions. Retroactive policies sought to inflict western medical practices on a non-western population, which resulted in conflict and unrest in the region. In the Belgian Congo, colonial authorities created a police state in which violence and stringent control measures were used to manage the local population. In Uganda, forced depopulation in infected regions destabilized local economies. This thesis compares and contrasts the methods used in these regions, and investigates the effects of Germ Theory on Sleeping Sickness policy and social perceptions during the colonial period in Africa.

African Sleeping Sickness

Trypanosomiasis

Tropical Medicine

Ecology

Arts and Humanities