Abstract | BACKGROUND: The aim of this study was to investigate host peroxisomal properties after leishmania infection and provide clues to protect peroxisomes during the search for new chemotherapeutic strategies against leishmaniasis. MATERIAL/METHODS: RESULTS: Liver peroxisomes were found to be functionally defective when purified after infection. The activities of catalase, urate oxidase, DHAPAT and SOD were either deficient or could not be detected after parasite infection. H2O2 producing peroxisomal b-oxidation was significantly elevated after 90 days of infection, with concomitant induction of superoxide radical production. Proteolytic activity in infected liver peroxisome was found to be inhibited, pointing to possible uneven processing of peroxisomal proteins. Electron microscopic studies revealed that the morphology of peroxisomes after leishmania infection was impaired. CONCLUSIONS: The evidence obtained for leishmania-induced peroxisomal dysfunction may provide clues to develop new drugs against this parasite, capable of protecting normal function of this ubiquitous host organelle for successful treatment.
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Authors | Bikramjit Raychaudhury, Shouvik Banerjee, Salil C Datta |
Journal | Medical science monitor : international medical journal of experimental and clinical research
(Med Sci Monit)
Vol. 9
Issue 4
Pg. BR125-9
(Apr 2003)
ISSN: 1234-1010 [Print] United States |
PMID | 12709663
(Publication Type: Journal Article, Research Support, Non-U.S. Gov't)
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Chemical References |
- Catalase
- Superoxide Dismutase
- Urate Oxidase
- Acyltransferases
- glycerone-phosphate O-acyltransferase
- Endopeptidases
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Topics |
- Acyltransferases
(metabolism)
- Animals
- Catalase
(metabolism)
- Cricetinae
- Endopeptidases
(metabolism)
- Leishmania donovani
(isolation & purification)
- Leishmaniasis, Visceral
(metabolism, pathology)
- Peroxisomes
(enzymology, metabolism, ultrastructure)
- Superoxide Dismutase
(metabolism)
- Urate Oxidase
(metabolism)
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