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Studies on the stable antigens of African trypanosomes : Serodiagnosis of Trypanosoma congolense infection of rabbits by the latex fixation test /Mahmoud, Mahmoud Musa,1940- January 1970 (has links)
No description available.
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Autoimmunity and other immune mechanisms in rabbits with experimental Trypanosoma congolense infections /Mansfield, John Michael January 1972 (has links)
No description available.
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Studies on acid phosphatases of Trypanosoma congolense.Tosomba, Omalokoho Médard. 21 October 2013 (has links)
Bloodstream forms of African trypanosomes, which endocytose macromolecules exclusively
through their flagellar pockets, contain an acid phosphatase (AcP) activity in this organelle. In
the present thesis, AcP activity was demonstrated cytochemically in some intracellular vesicles
and on the surface of Trypanosoma congolense as well as in the flagellar pocket. Unlike other
trypanosomatids such as Leishmania spp. and Trichomonas spp., these trypanosomes, while
viable, did not release this enzyme into the surrounding medium.
In contrast to mammalian cells, the AcP in T. congolense was shown by cell fractionation to
be a non-lysosomal enzyme. The enzyme was mostly recovered in the microsomal and
cytosolic fractions which had 52.7% and 44.4% of the total activity, respectively. Further
separation of the microsomal fraction showed an association of AcP activity with vesicles
derived from the plasma membrane, Golgi apparatus and endoplasmic reticulum.
After ammonium sulfate precipitation and chromatography on a succession of columns
containing Sephacryl S-300, DEAE-cellulose and Sephadex G-75, two acid phosphatases
(AcPi and ACP2) were produced from the cytosolic fraction. A membrane-bound acid
phosphatase (ACP3) was isolated from the microsomal pellets extracted with Triton X-l 14 and
subjected to the above chromatographic procedures. The molecular mass of AcP 1 was higher
than 700 kDa. It had an isoelectric point of 4.7. AcP2 (pi 5.3) and AcP3 (pi 6.5) had
molecular masses of 33 and 320 kDa, respectively. AcPi and ACP3 were strongly inhibited by
vanadate while ACP2 was strongly inhibited by p-chloromercuribenzoate. None of the
enzymes was inhibited by tartrate but all were inhibited by NaF. The Km values for each of the
various substrates differed widely between the three AcPs indicating that the binding site of
each enzyme was distinct. The best of all the substrates tested was para-nitrophenyl
phosphate.
On non-denaturing gels the enzymes exhibited very high molecular masses but on denaturing
SDS-PAGE, two similar bands of activity, localised at 62 and 65 kDa, were observed in all
three AcP preparations. Thus the three isolated enzymes may be derived from the same base
62 and 65 kDa units. Differences between enzymes may be derived from differential
processing of the isoenzymes for different functions at different locations. / Thesis (Ph.D.)-University of Natal, Pietermaritzburg, 1997.
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Investigating the molecular basis of tsetse-trypanosome interactions / Investigating the molecular basis of tsetse-trypanosome interactionGoomeshi Nobary, Sarah 12 September 2014 (has links)
The parasitic pathogens of genus Trypanosoma cause significant morbidity and mortality worldwide. The most well studied Trypanosoma related diseases are African sleeping sickness (Trypanosoma brucei) and African Animal Trypanosomiasis (Trypanosoma congolense). Despite more than 100 years of research these diseases continue to have a devastating impact on the socioeconomic development of Africa. A major impediment to controlling outbreaks is the lack of an effective vaccine due, in part, to the parasite’s ability to continually alter its protein coat while in the host, which results in effectively evading the host immune system. Recent studies have identified Trypanosoma congolense proteins that are selectively expressed during transmission in the tsetse arthropod vector where the parasite’s protein coat is not constantly recycled. Of these proteins, Congolense Insect Stage Specific Antigen (TcCISSA) and Congolense Epimastigote Specific Protein (TcCESP) were selected for characterization based on cellular localization, expression levels and predicted roles in facilitating transmission by the tsetse fly.
The goal of the present study is to understand the crosstalk between T. congolense and its vector, the tsetse fly. Revealing the structure of proteins is a crucial step in determining their functions. In order to gain insight into the molecular basis of structure and function of TcCESP and TcCISSA we took various biophysical and biochemical approaches. TcCISSA was recombinantly produced in E. coli, crystallized and diffraction quality data collected to 2.5 Å resolution. Structure determination, however, has been problematic due to the absence of homologous models and the inability to take advantage of SelMet phasing due to the presence of only a single methionine in the sequence. Structure determination efforts are ongoing using multiple approaches including NMR. In contrast to TcCISSA, the size and complexity of TcCESP required insect cells for efficient recombinant production. While crystallization trials have yet to yield diffraction quality crystals, a combination of homology modeling validated by chemical crosslinking and mass spectrometry, and circular dichroism spectroscopy have yielded intriguing insight into the architecture of CESP. Characterizing the function of these proteins offers the potential for rare insight into the molecular crosstalk between the parasite and vector and may support the development of novel transmission blocking vaccines. / Graduate
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Phagocytosis of <i> Trypanosoma congolense </i> by macrophages : the role of IgM antibody to variant surface glycoprotein (VSG)Pan, Wanling 23 March 2005
<p><I> Trypanosoma congolense </i> is a single-cell blood parasite and an important pathogen causing African trypanosomiasis, also called ngana, in livestock. Ngana in cattle is a chronic disease associated with anemia, cachexia and increased susceptibility to secondary infections. Infection of mice can be used as an experimental model to study the host-parasite relationship. As determined by their survival time, BALB/c mice are highly susceptible to <i> T. congolense </i> infection, whereas C57BL/6 mice are relatively resistant. The surfaces of African trypanosomes are covered with a layer of a single species of glycoprotein, called variant surface glycoprotein (VSG). Production of antibodies to the VSG of African trypanosomes is one of the major immune responses leading to control of parasitemia. The reaction of antibodies with VSG of trypanosomes, for presently unknown reasons, predominantly activates the alternative complement pathway rather than the classical pathway of complement. IgM antibodies are the first and predominant class of anti-trypanosomal antibodies in infected animals. Antibody-mediated phagocytosis of <i> T. congolense </i> by macrophages is considered a major mechanism of control of parasitemia, besides antibody/complement-mediated lysis and cytotoxic effect by macrophage-derived nitric oxide (NO). The receptor(s) on macrophages that recognizes IgM antibody-coated trypanosomes and enables their phagocytosis is unknown. Interaction of antibodies with the VSG of trypanosomes not only causes phagocytosis of trypanosomes by macrophages, but also leads to the release of sVSG from the trypanosomes. sVSG has been found to modulate various functions of the host: induction of polyclonal B cell activation and modulation of macrophage functions, such as the induction of TNF-á synthesis and the inhibition of IFN-ã-induced nitric oxide production. The objectives of this thesis are:</p>
<p> 1) to test whether CR3 (Mac-1; CD11b/18) is involved in IgM anti-VSG-mediated phagocytosis of <i> T. congolense </i> by macrophages </p>
<p> 2) to test the effects of anti-VSG antibody and complement on the release of soluble VSG from <i> T. congolense </i> </p> <p>1) When the trypanosomes were incubated with IgM anti-VSG antibody and fresh mouse serum, fragments of complement component C3 were found to be deposited onto <i> Trypanosoma congolense </i>. Thus, it was assessed whether complement receptor CR3 (CD11b/CD18; receptor for iC3b) might be involved in IgM anti-VSG mediated phagocytosis of <i> T. congolense </i>. In the presence of fresh mouse serum, there was significantly and markedly less phagocytosis of IgM-opsonized <i> T. congolense </i> by CD11b-deficient macrophages compared to phagocytosis by normal macrophages (78% fewer <i> T. congolense </i> were ingested per macrophage). There also was significantly less TNF-á (38% less), but significantly more NO (63% more) secreted by CD11b-deficient macrophages that had engulfed trypanosomes than by equally treated normal macrophages. It was concluded that CR3 is the major, but not the only, receptor involved in IgM anti-VSG-mediated phagocytosis of <i> T. congolense </i> by macrophages. It was further concluded that signaling via CR3, associated with IgM anti-VSG-mediated phagocytosis of <i> T. congolense </i>, either directly or indirectly, enhances synthesis of disease-producing TNF-á and inhibits the synthesis of parasite-controlling NO.</p> <p> 2) This investigation revealed that there was more sVSG released from <i> T. congolense </i> by interaction with IgM anti-VSG than by interaction with equal amounts of IgG2a anti-VSG. The release of sVSG occurred in an antibody dose-dependent pattern. It was also found that IgM anti-VSG, after interacting with the surface of <i> T. congolense </i>, formed soluble immune complexes with released sVSG. The results also showed that antibody-induced release of sVSG can occur without complement, but is enhanced by complement. It was further tested whether fresh sera from either relatively resistant C57BL/6 mice or highly susceptible BALB/c mice, which differ in their complement cascade, had different effects on the release of sVSG from <i> T. congolense </i>. The results showed that antibody-induced shedding of sVSG was higher in the presence of fresh C57BL/6 serum than in the presence of fresh BALB/c serum. All these data suggest that the concentration of anti-VSG antibody, antibody class and source of complement can affect the release of sVSG from <i> T. congolense </i></p>.
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Phagocytosis of <i> Trypanosoma congolense </i> by macrophages : the role of IgM antibody to variant surface glycoprotein (VSG)Pan, Wanling 23 March 2005 (has links)
<p><I> Trypanosoma congolense </i> is a single-cell blood parasite and an important pathogen causing African trypanosomiasis, also called ngana, in livestock. Ngana in cattle is a chronic disease associated with anemia, cachexia and increased susceptibility to secondary infections. Infection of mice can be used as an experimental model to study the host-parasite relationship. As determined by their survival time, BALB/c mice are highly susceptible to <i> T. congolense </i> infection, whereas C57BL/6 mice are relatively resistant. The surfaces of African trypanosomes are covered with a layer of a single species of glycoprotein, called variant surface glycoprotein (VSG). Production of antibodies to the VSG of African trypanosomes is one of the major immune responses leading to control of parasitemia. The reaction of antibodies with VSG of trypanosomes, for presently unknown reasons, predominantly activates the alternative complement pathway rather than the classical pathway of complement. IgM antibodies are the first and predominant class of anti-trypanosomal antibodies in infected animals. Antibody-mediated phagocytosis of <i> T. congolense </i> by macrophages is considered a major mechanism of control of parasitemia, besides antibody/complement-mediated lysis and cytotoxic effect by macrophage-derived nitric oxide (NO). The receptor(s) on macrophages that recognizes IgM antibody-coated trypanosomes and enables their phagocytosis is unknown. Interaction of antibodies with the VSG of trypanosomes not only causes phagocytosis of trypanosomes by macrophages, but also leads to the release of sVSG from the trypanosomes. sVSG has been found to modulate various functions of the host: induction of polyclonal B cell activation and modulation of macrophage functions, such as the induction of TNF-á synthesis and the inhibition of IFN-ã-induced nitric oxide production. The objectives of this thesis are:</p>
<p> 1) to test whether CR3 (Mac-1; CD11b/18) is involved in IgM anti-VSG-mediated phagocytosis of <i> T. congolense </i> by macrophages </p>
<p> 2) to test the effects of anti-VSG antibody and complement on the release of soluble VSG from <i> T. congolense </i> </p> <p>1) When the trypanosomes were incubated with IgM anti-VSG antibody and fresh mouse serum, fragments of complement component C3 were found to be deposited onto <i> Trypanosoma congolense </i>. Thus, it was assessed whether complement receptor CR3 (CD11b/CD18; receptor for iC3b) might be involved in IgM anti-VSG mediated phagocytosis of <i> T. congolense </i>. In the presence of fresh mouse serum, there was significantly and markedly less phagocytosis of IgM-opsonized <i> T. congolense </i> by CD11b-deficient macrophages compared to phagocytosis by normal macrophages (78% fewer <i> T. congolense </i> were ingested per macrophage). There also was significantly less TNF-á (38% less), but significantly more NO (63% more) secreted by CD11b-deficient macrophages that had engulfed trypanosomes than by equally treated normal macrophages. It was concluded that CR3 is the major, but not the only, receptor involved in IgM anti-VSG-mediated phagocytosis of <i> T. congolense </i> by macrophages. It was further concluded that signaling via CR3, associated with IgM anti-VSG-mediated phagocytosis of <i> T. congolense </i>, either directly or indirectly, enhances synthesis of disease-producing TNF-á and inhibits the synthesis of parasite-controlling NO.</p> <p> 2) This investigation revealed that there was more sVSG released from <i> T. congolense </i> by interaction with IgM anti-VSG than by interaction with equal amounts of IgG2a anti-VSG. The release of sVSG occurred in an antibody dose-dependent pattern. It was also found that IgM anti-VSG, after interacting with the surface of <i> T. congolense </i>, formed soluble immune complexes with released sVSG. The results also showed that antibody-induced release of sVSG can occur without complement, but is enhanced by complement. It was further tested whether fresh sera from either relatively resistant C57BL/6 mice or highly susceptible BALB/c mice, which differ in their complement cascade, had different effects on the release of sVSG from <i> T. congolense </i>. The results showed that antibody-induced shedding of sVSG was higher in the presence of fresh C57BL/6 serum than in the presence of fresh BALB/c serum. All these data suggest that the concentration of anti-VSG antibody, antibody class and source of complement can affect the release of sVSG from <i> T. congolense </i></p>.
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Protein discovery in African Trypanosomes: studying differential protein expression throughout the parasite life cycle and identification of candidate biomarkers for diagnosing Trypanosome infectionsEyford, Brett Alexander 22 February 2013 (has links)
Research was undertaken to discover and study trypanosome proteins that may play important roles in host-parasite or vector-parasite interactions. The methods used mass spectrometry based proteomics ideally suited for analysis of low abundance molecules. First, isobaric tags were used to monitor changes in proteins expression throughout the life cycle of Trypanosoma congolense, an economically important livestock pathogen. This was the first large scale survey of protein expression in trypanosomes. In addition to generating protein expression data for approximately 2000 different parasite proteins, 6 previously undescribed T. congolense proteins were discovered. Several of the proteins with interesting expression trends were selected for molecular characterization and monoclonal antibody derivation. Second, immunoenrichment and mass spectrometry were used to identify the cognate antigen recognized by a T. congolense-specific monoclonal antibody. The antigen, a flagellar calcium binding protein, was expressed as a recombinant protein and used to test its utility as a potential serodiagnostic antigen for diagnosis of T. congolense infections. Third, a “deep-mining” protein discovery mass spectrometric method was used to identify trypanosome proteins present in the plasma of late-stage African sleeping sickness patients. A total of 254 trypanosome proteins were unequivocally identified by tandem mass spectrometry. These findings are unprecedented since never before have such a large number of pathogen proteins been discovered in human blood using a non-biased approach (i.e. without using a targeted assay). The proteins discovered provide insights into host-parasite interactions and are strong candidates as targets for new diagnostic assays. / Graduate
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Parasitological and molecular characterisation of isometamidium-sensitive and -resistant Trypanosoma congolense and T. brucei brucei isolates from cattle in East and West AfricaMebratu, Yohannes Afework January 1900 (has links)
Berlin : Freie Univ., Diss., 2005 / Dateiformat: zip, Dateien im PDF-Format. - Erscheinungsjahr an der Haupttitelstelle: 2005
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Cloning of the promoter regions of Trypanosoma brucei and Trypanosoma congolense cysteine protease genes.Dalasile, Thembile Lawrence. 23 December 2013 (has links)
Trypanosoma brucei and T. congolense are protozoan parasites that infect humans, domestic livestock and wildlife in Africa. These parasites undergo complex morphological
and biochemical changes, during the various stages of their life cycle. These changes
correlate with alterations in the levels of trypanosomal lysosomal cysteine proteases,
suggesting a role for transcriptional regulation of the cysteine protease in these parasites.
The mechanism of this regulation is not yet understood nor have the promoter regions of
the cloned trypanosome cysteine protease genes been investigated. This study involved an
attempt to clone the T. brucei and T. congolense DNA fragments containing the promoter
regions as the initial step in the investigation of the control elements of the cysteine protease gene.
Trypanosomes were isolated from infected rat blood employing a combination of the
methods of isopicnic isolation on Percoll gradients and DEAE-cellulose anion exchange
resin chromatography. Approximately 5 x 10⁹ viable trypanosome cells were isolated from
the infected rat blood and chromosomal DNA (approximately 500 μg) was extracted by
alkaline-lysis method. Trypanosome genomic libraries were initially constructed in
Eschericia coli HB101 employing the positive selection vector pEcoR251. The
Trypanosoma brucei pEcoR251 library contained 6 000 recombinants and the Trypanosoma
congolense library contained 15 000 recombinants. Plasmid DNA was then extracted from
pools of recombinants, employing the alkaline-lysis method, digested with EcoRl restriction
endonuclease and resolved by agarose gel electrophoresis. After Southern hybridisation,
the pEcoR251 libraries did not reveal any putative clones containing the fragment of interest
when probed with both an oligonucleotide probe and the PCR generated dsDNA probe.
Genomic libraries were then constructed in the phagemid pUC119. The T. brucei and T.
congolense genomic libraries contained 33 000 and 27 000 recombinants respectively.
Recombinants from the T. brucei and T. congolense libraries were pooled in lots of 400 and
300 respectively. Of the 80 T. brucei plasmid pools that were screened 30 pools contained
fragments that hybridised with the probe whilst 12 pools from the 90 T. congolense library
pools that were screened contained fragments that hybridised with the probe. Putative
clones identified appeared to contain inserts, ranging between two and seven kb in size. A
partial T. congolense library consisting of approximately 12 pools was screened by colony
hybridisation for identification of individual clones and 76 putative clones were identified.
After confirmation of these putative clones on a dot blot using a DIG-labelled dsDNA probe, a selection of 30 putative clones were subjected to Southern hybridisation using a
DIG-labelled DNA probe. Following Southern hybridisation 23 putative clones were
identified to contain DNA inserts of interest in the range of two to seven kb. Five clones,
designated pCPC1, pCPC2, pCPC3, pCPC4 and pCPC5 were then selected for further
restriction mapping. Clone pCPC4 contains a seven kb fragment of T. congolense genomic
DNA. A partial T. brucei library consisting of approximately 30 pools was screened by
colony hybridisation for the identification of individual putative clones. Although plasmid
pools containing putative clones were identified repeatedly by Southern blotting and
DNA/DNA hybridisation, it was not possible to identify individual putative clones following
transformation into E. coli MV1184 and colony hybridisation. / Thesis (M.Sc.)-University of Natal, Pietermaritzburg, 1997.
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The susceptibility of Trypanosoma congolense isolated in Zambézia Province (Mozambique) to isometamidium chloride, homidium chloride and diminazene aceturateJamal, Suzana Augusta José 02 March 2006 (has links)
Bovine trypanosomosis is a serious constraint to livestock development in large parts of Mozambique. In most areas where tsetse flies are present, the disease in livestock is controlled using curative and prophylactic trypanocidal drugs. Those drugs have been used for many years and new drugs are unlikely to become available in the near future. As a result, trypanosomes have developed resistance against the currently available trypanocidal compounds. Drug resistance has been detected in various African countries and is a serious impediment to the control of livestock trypanosomosis. A study was initiated to determine whether drug resistant trypanosome strains are present in Zambézia Province of Mozambique. The aim of this study was to determine the sensitivity of Trypanosoma congolense isolates from Chinde, Nicoadala and Maganja da Costa Districts to diminazene aceturate, isometamidium chloride and homidium chloride. To assess the effect of the farming system and the intensity of drug regimens on the development of drug resistance, trypanosome isolates were collected from cattle from subsistence, semisubsistence and commercial livestock production systems. Drug-use practices in each of the production systems were determined using a questionnaire. The methodology used to assess the level of drugs resistance in the trypanosome isolates was the standardized method described by Eisler et al. (2001). Seven isolates were selected for resistance testing. For each of the seven isolates, five different doses varying between 0.01-20 mg/kg body weight for isometamidium chloride, 0.01-10 mg/kg body weight for homidium chloride and 1-30 mg/kg body weight for diminazene aceturate were used. For each dose rate six mice were treated intraperitoneally with the appropriate quantity of the drug dissolved in 0.2 ml of sterile distilled water 24 hours after the inoculation of the blood containing the trypanosomes. The control mice (six mice per trypanocidal drug) received the same amount of water without the drug. In four of the seven isolates high levels of multiple drug resistance (diminazene aceturate and isometamidium chloride) were detected. One isolate had a low level of multiple (diminazene aceturate and isometamidium chloride) drug resistance. Two isolates were susceptible to both diminazene aceturate and isometamidium chloride. One of those was highly susceptible to isometamidium chloride even at the lowest dose rate. The observed levels of drug resistance could in most cases be correlated to the drug-use practices in the particular livestock production system. The results obtained from homidium chloride treatment are not conclusive, because most the mice cured after receiving 10 mg/kg body weight of the drug. Hence more research is required to establish the homidium threshold in mice. The results of this study should be useful to define the strategy of disease control in places where resistance of trypanocide were been reported. / Dissertation (MSc (Veterinary Science))--University of Pretoria, 2005. / Veterinary Tropical Diseases / unrestricted
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