Spelling suggestions: "subject:"trypanosoma.""
1 |
Modulation of the immune response in Trypanosoma lewisi infections.St-Charles, Marie-Hélène Carole January 1979 (has links)
No description available.
|
2 |
Modulation of the immune response in Trypanosoma lewisi infections.St-Charles, Marie-Hélène Carole January 1979 (has links)
No description available.
|
3 |
Evaluation of the pathogenicity in goats of Trypanosoma congolense from Matutuine, MozambiqueTchamo, Cesaltina da Conceicao Lopes Menete. January 2007 (has links)
Thesis (MSc ( Veterinary Tropical Diseases, Veterinary Science))--University of Pretoria, 2007. / Includes bibliographical references. Also available in print format.
|
4 |
Development of tools to improve the detection of Trypanoma evansi in Australia /Smuts, Celia Margaretha. January 2009 (has links)
Thesis (Ph.D.)--Murdoch University, 2009. / Thesis submitted to the Faculty of Health Sciences. Includes bibliographical references (leaves 183-209)
|
5 |
Pastoral livelihoods and the epidemiology of emergent trypanosomiasis on the Jos Plateau, NigeriaMajekodunmi, Ayodele January 2012 (has links)
African trypanosomiasis is a widespread disease of livestock which is a major constraint to livestock production, mixed farming and the rural economy. The Jos Plateau in Nigeria was historically free of tsetse flies and trypanosomiasis and this lack of disease attracted large numbers of cattle keeping pastoralists. The area now plays an important role in the national/regional cattle industry, holding 300,000 pastoralists and over a million cattle, ~ 7% of the national herd. However, over the past twenty years tsetse flies have (re)invaded the Jos plateau and trypanosomiasis is now a significant problem. Little is known about the distribution and overall prevalence of the disease across the Jos plateau or about the habits and customs that could affect the epidemiology of the disease in this area. This knowledge is essential if successful interventions to reduce its impact are to be put in place. To bridge this gap, a longitudinal two stage cluster survey was carried out in 2008 to determine the prevalence of bovine trypanosomiasis. The study showed that the prevalence of trypanosomiasis across the Jos plateau was 46.8% (39.0 – 54.5%) with no significant seasonal variation. T. b. brucei was present at a prevalence of 3.3% (1% – 5.5%); T. congolense savannah at a prevalence of 27.7% (21.8% - 33.6%); T. vivax at a prevalence of 26.7% (18.2% - 35.3%). Although there was no significant seasonal variation in prevalence across the Jos plateau, seasonal variations were observed at village level to create 3 distinct groups. Group 1 villages (50.0%) which followed the expected pattern of low prevalence in the dry season and high prevalence in the wet season; Group 2 villages (16.7%) where there was no seasonal variation; Group 3 villages (33.3%) where paradoxically the prevalence was higher in the dry season and lower in the wet season. This reversed epidemiological pattern is attributed to the harsh climatic conditions of the dry season which reduce resistance to infection in cattle and increase vector – host contact. Migration was shown to be a significant risk factor for trypanosomiasis infection and the dry season was shown to significantly increase the effect of all risk factors. Participatory rural assessment was also conducted to investigate socio – economic factors and knowledge, attitudes and practices concerning tsetse and trypanosomiasis. The results of the participatory rural assessment exercise show that trypanosomiasis is well recognised by farmers on the Jos plateau. They are aware of the animal health and production disadvantages associated with it and make considerable efforts to control it, along with other livestock diseases. However, they lack the adequate knowledge to effectively control these diseases themselves and there are gaps in veterinary service provision. Wealth ranking showed that the majority of pastoralists in the study were either in the ‘middle’ or ‘better – off’ groups. Only 6.1% were classed as poor. Anaemia as an indicator for trypanosomiasis was investigated and FAMACHA charts were evaluated as a potential penside test for anaemia. Results show that anaemia in cattle on the Jos Plateau is not strongly related to trypanosomiasis and that the FAMACHA chart is a poor test for anaemia in cattle.
|
6 |
Antigenic variation in Trypanosoma brucei, a relationship with poly ADP-ribose polymeraseMhlanga, Jama Donewell Mayixeke January 1994 (has links)
No description available.
|
7 |
[Trypanosoma equiperdum, Trypanosoma brucei and Trypanosoma hippicum infections in laboratory animals, chick embryos and chickensHood, Mary Noka, January 1900 (has links)
Based on thesis - University of Michigan. / "Reprinted from the American journal of tropical medicine, vol. 29, no. 3, May, 1949."
|
8 |
A field evaluation of three trypanosomosis control strategies in Kwazulu-Natal, South AfricaEmslie, Forbes Richard. January 2004 (has links)
Thesis (MSc (Veterinary Science))--University of Pretoria, 2004. / Includes bibliographical references.
|
9 |
The identification and characterization of two unique membrane-associated molecules of African trypanosomesStebeck, Caroline Elizabeth 19 July 2018 (has links)
The primary structure of a 38 kDa protein isolated from membrane preparations of
African trypanosomes (Trypanosoma brucei rhodesiense) was determined by protein and
DNA sequencing. Searching of the protein database with the trypanosome translated
amino acid sequence identified glycerol 3-phosphate dehydrogenase (EC 1.1.1.8) from
various prokaryotic and eukaryotic organisms as the optimal scoring protein.
Surprisingly, the eukaryotic trypanosome enzyme showed the highest degree of sequence
identity with the corresponding enzyme from the prokaryote Escherichia coli. Using
recombinant DNA techniques, the trypanosome molecule was expressed in Escherichia
coli and found to be enzymatically active, thus confirming the identity of the molecule as
an NAD+-dependent glycerol 3-phosphate dehydrogenase. A monoclonal antibody
specific for the 38 kDa protein was used to localize the enzyme to glycosomes. The
enzyme has a pi of 9.0, a net charge of +9 at physiological pH and contains the
peroxisome-like targeting tripeptide SKM at its C-terminus, all characteristic of
glycosomal enzymes. Amino acids predicted to be involved in the NAD+-dependent
glycerol 3-phosphate dehydrogenase active site have diverged from those of the
mammalian enzyme. Kinetic analyses of the trypanosome GPD and GPD from rabbit
muscle showed that the Km values of the two enzymes are different The data suggests
that the trypanosome protein may be a candidate target for rational drug design. Northern
and Southern blot analyses showed that the trypanosome NAD+-dependent glycerol 3-
phosphate dehydrogenase was translated from a single transcript and that only two gene
copies exist thus making this molecule an attractive target for knockout mutagenesis.
A second molecule, an abundant 11 kDa membrane protein, was also purified from
African trypanosomes. This protein cross-reacted with monoclonal antibodies originally
generated against the lipophosphoglycan-associated protein of Leishmania donovani.
Immunoblot analysis showed that the 11 kDa molecule was present in a variety of species
of kinetoplastids. It was found in several species and subspecies of African
trypanosomes and was present in low amounts in bloodstream forms and in larger
amounts in procyclic, epimastigote and metacyclic life cycle stages. The molecule was
present in procyclic trypanosome membranes at approximately [special characters omitted] molecules
per cell. Its wide distribution in kinetoplastids and its membrane disposition suggested a
name for this class of molecules (kinetoplastid membrane protein-11) and for the molecule
characterized in this thesis (trypanosome kinetoplastid membrane protein-11).
The kinetoplastid membrane protein-11 molecule was purified from Trypanosoma
brucei rhodesiense by organic solvent extraction and octyl-Sepharose chromatography
and a 14 amino acid internal peptide sequence was obtained by gas phase
microsequencing. This sequence matched a translated Leishmania donovani kinetoplastid
membrane protein-11 sequence, thus suggesting the use of the Leishmania sequence as a
probe to select for the Trypanosoma gene. Screening of a trypanosome cosmid library
with the Leishmania probe, in combination with a series of polymerase chain reaction
amplifications from both genomic DNA and cDNA, allowed the determination of the
entire DNA sequence and corresponding translated amino acid sequence of the
trypanosome kinetoplastid membrane protein-11. The 92 amino acid sequence showed
18 percent sequence divergence from the corresponding molecule of the related
kinetoplastid Leishmania donovani donovani^ including one key amino acid at position 45
which may be of functional relevance. The secondary structure of the trypanosome
molecule was predicted to form two amphipathic helices connected by a random-coil
segment, and suggests that it would interact with lipid bilayers in the parasite cell
membrane. Northern and Southern blot analyses using the T.b. rhodesiense ViTat 1.1
clone showed that the trypanosome molecule was translated from a single transcript and
that there was only a single gene copy, thus making this molecule an attractive target for
knockout mutagenesis. / Graduate
|
10 |
Pastoralist cattle productivity in a tsetse infested area of south west KenyaRoderick, Stephen January 1995 (has links)
No description available.
|
Page generated in 0.0339 seconds