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Fever and sickness behaviour during simulated Mycoplasma infection in ratsSwanepoel, Tanya 05 March 2013 (has links)
Thesis (Ph.D.(Physiology))--University of the Witwatersrand, Faculty of Health Sciences, 2012. / The acute phase response is implemented by infected hosts in response to exposure to
pathogens, including bacteria and viruses. Acute phase responses comprise physiological
and behavioural changes, such as fever and a range of “sickness behaviours”, including
lethargy and anorexia as well as impairment in learning and memory. Similar to other
sickness behaviours, the effect of infection on learning and memory processes has been
attributed to the release of pro-inflammatory cytokines, including interleukin-1β (IL-1β) and
interleukin-6 (IL-6). However, the exact role of IL-1β and IL-6 in mediating infection-induced
cognitive impairment is not clear. Unlike fever, anorexia and lethargy, which may benefit an
infected host, the physiological benefit of cognitive impairment during illness is doubtful.
To initiate an acute phase response experimentally, moieties of typical bacteria (Gramnegative
and Gram-positive) and viruses frequently are employed. Moieties from the atypical
Mycoplasmas seldom have been used. Consequently, there is a dearth of information on the
physiological mechanisms that underlie acute phase responses following Mycoplasma
infection, despite the prevalence of the disease in the general population. Mycoplasma
pneumoniae frequently causes community-acquired pneumonia, which may have serious
extra-pulmonary complications, including cognitive deficits. Therefore, I investigated fever
and sickness behaviours as well as cytokine responses in simulated, atypical Mycoplasma
infection.
I implemented an animal model of simulated Mycoplasma infection and characterised fever
and sickness behaviours, including lethargy and anorexia as well as impairment in learning
and memory during acute and recurrent acute simulated infection. I also characterized the
response in the periphery and in the brain of individual pro-inflammatory cytokines, IL-1β
and IL-6, to administration of fibroblast-stimulating lipopeptide-1 (FSL-1), which simulates Mycoplasma infection. Using rats, I recorded fever and lethargy with biotelemetry and
assessed effects of simulated Mycoplasma infection on learning and memory using a Morris
Water Maze. In addition, I examined the histology of tissue from the hippocampus, a key
brain area involved in spatial learning and memory, to assess residual effects of simulated
Mycoplasma infection on learning and memory.
I showed that bolus administration of a pyrogenic moiety from Mycoplasma, fibroblaststimulating
lipopeptide-1 (FSL-1), dose-dependently induced fever, lethargy, anorexia and
body mass stunting in rats. However, FSL-1 administration did not induce concomitant
impairment in spatial learning and memory. Importantly, at the time of testing in the Maze, I
found the concentrations of IL-1β to be up-regulated in both the hypothalamus and the
hippocampus, while the concentrations of IL-6 were unaffected. I also showed that recurrent
acute injections of FSL-1, at 10 d intervals, induced recurrent fevers, lethargy and anorexia
without the development of pyrogenic tolerance to any of the sickness responses measured.
However, there was no residual body mass stunting in rats and also no growth retardation,
despite the recurrent simulated infection. Equally importantly, there were neither lasting
detrimental effects on spatial learning and memory nor any residual histological damage to
the hippocampus of rats.
My findings in simulated Mycoplasma infection are important, firstly because Mycoplasma
infection is prevalent in both developing and developed countries and frequently causes
outbreaks, and secondly because Mycoplasma infection affects children and adolescents of
school-going age. My findings also are encouraging: although lasting detrimental effects,
including impairment in learning and memory as well as body mass stunting may occur in
other infections, these appear not to be inevitable outcomes in Mycoplasma infection.
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Microbiological studies of male non-gonococcal urethritis especially T-strain mycoplasmas in Chiang Mai and antibiotic sensitivity of microorganisms isolated, 1975 /Khwanpong Thienhiran. January 1976 (has links) (PDF)
Thesis (M.Sc. in Microbiology) -- Mahidol University, 1976.
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Urethritis and cervicitis with special reference to Chlamydia trachomatis and Mycoplasma genitalium : diagnostic and epidemiological aspects /Falk, Lars, January 2004 (has links) (PDF)
Diss. (sammanfattning) Linköping : Univ., 2004. / Härtill 5 uppsatser.
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Identification and characterization of virulence factors of mycoplasmasLuo, Wenyi. January 2009 (has links) (PDF)
Thesis (Ph.D.)--University of Alabama at Birmingham, 2009. / Title from PDF title page (viewed on July 1, 2010). Includes bibliographical references.
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Autoantibodies to Centrosomes are Diagnostic for Human Scleroderma and Can Be Induced by Experimental Mycoplasma Infection in Mice: A DissertationGavanescu, Irina Catrinel 20 December 2002 (has links)
The overall objective of this thesis work was to develop new insights into the etiology of scleroderma, a human systemic autoimmune disease, by analyzing the autoantibodies to centrosome antigens that develop during the disease. Centrosomes are perinuclear organelles that form microtubule arrays, including mitotic spindles that ensure the faithful segregation of chromosomes during mitosis.
These studies used a novel methodology to determine the prevalence of anti-centrosome autoantibodies in patients with scleroderma. Recombinant centrosome antigens were used to determine the antigenic specificity of anti-centrosome antibody subsets by immunoblotting. Centrosome marker antibodies were used in indirect immunofluorescence assays to distinguish centrosomes within the polymorphic staining pattern frequently given by scleroderma sera. We found that 43% of patients are autoreactive to centrosomes, a prevalence higher than has been reported for any other scleroderma autoantigen. Half of the centrosome-positive patients also had autoantibodies against other antigens used in scleroderma diagnosis. However, in the remaining half of these patients, anti-centrosome antibodies represented the sole class of autoantibodies that was detectable. Anti-centrosome antibodies were detected in only a small percentage of normal individuals and patients with other connective tissue diseases. These data suggest that anti-centrosome autoantibodies may represent a new diagnostic tool in scleroderma. Upon examination of anti-centrosome autoantibody development in an animal model, it appeared that this autoantibody specificity may develop in mice as a consequence of an infection.
An infectious agent was isolated by plaque-formation from carrier mice. Further characterization of the infectious agent was undertaken to obtain information on its physical, morphological and cytopathological properties. The infectious agent was identified by sequence and unique antigenic properties to be homologous to the pig pathogen Mycoplasma hyorhinis. When reintroduced into naive mice, the murine mycoplasma triggered anti-centrosome autoantibody development. While anti-centrosome autoantibodies of IgM isotype are part of the repertoire of naive unimmunized mice, mycoplasma infection specifically triggered the development of anti-centrosome IgG. Moreover, centrosome autoreactivity was prevented by antibiotic treatment. The autoantibody response evolved to recruit additional specificities, having IgM isotypes, reactive to endoplasmic reticulum-associated autoantigens.
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