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Presented by: Chris Raske. Cryptosporidium Parvum. A protozoan parasite which belongs to the class Coccidia. Undergoes a complex life cycle with alternating asexual and sexual reproductive cycles. It is one of the most common non-viral causes of diarrhea in many animals as well as humans.
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Cryptosporidium Parvum • A protozoan parasite which belongs to the class Coccidia. • Undergoes a complex life cycle with alternating asexual and sexual reproductive cycles. • It is one of the most common non-viral causes of diarrhea in many animals as well as humans. • The first reported human cases were in 1976, and continues to infect people worldwide. In 1993 there was an outbreak in Milwaukee which infected over 400,000 people.
Cryptosporidium Parvum • In immunocompetent individuals cryptosporidium causes transient diarrhea, however in immunosuppressed individuals, infection results in more persistent and severe diarrhea which can be fatal. (ex. AIDS) • Cryptosporidium generally infects the apical layer of endothelial cells of the intestine, and normally does not invade deeper layers of the gastrointestinal mucosa. • Upon infection, the epithelial cells release proinflamitory cytokines including neutrophil chemoattractants, which are at least partly responsible in attracting effector cells.
Cryptosporidium Parvum • Mice deficient in B cells are able to fully eliminate the parasite which suggests antibodies are not required for its elimination. • However, SCID mice and mice unable to make MHC class II molecules are susceptible to infection by C. parvum. • These results suggest that cell-mediated immunity is the most important factor in recovering from C. parvum infection.
Infection Leads to Cell Lysis • After excystation in the intestine, the parasite invades epithelial cells where it remains in a parasitophorous vacuole (PV) directly beneath the apical membrane of the cell. • It has been shown that cell lysis occurs at these parasitophorous vacuoles at the apical membrane. • However, the mechanism of cell death was previously unknown.
Researcher’s Objective • Are the cells undergoing cell death through apoptotic pathways or necrosis? • DNA condensation? • DNA fragmentation? • If it is an apoptotic pathway, what are the molecular mediators? Could a caspase inhibitor alter cryptosporidium’s pathology?
Apoptotic DNA Condensation and Fragmentation • During Apoptosis, the cell cycle arrests and DNA remains in a condensed form. • Apoptotic DNA fragmentation is a result of caspase dependent pathways. • Caspase-activated DNA fragmenting factor (CAD) is activated when it is cleaved by caspases and released from its inhibitor (ICAD). • Upon activation CAD enters the nucleus and degrades DNA
In a previous study researchers induced apoptosis in liver cells with Antibodies against Fas, then inhibited the apoptosis pathway with a caspase inhibitor. Caspase Inhibitors
Results Apoptotic nuclear condensation during infection: Both the number of cells infected and the number of apoptotic cells increased with higher concentrations of oocysts. Methods: Cytofluorimetry PI staining
Results Morphology of infected cells: DAPI staining to observe chromatin condensation (A) HCT-8 cells without C. parvum (B) HCT-8 cells with C. parvum
Results DNA Fragmentation: There is considerable DNA fragmentation when approximately 20% of cells are infected. However, in the presence of a caspase inhibitor (zVAD) the amount of fragmentation is decreased.
Results Z-VAD effect on nuclear condensation of infected cells: zVAD inhibited most of the DNA condensation, however it’s presence increased the % of infected cells.
Conclusions • C. parvum’s infection of epithelial cells does induce apoptosis. Both DNA condensation and fragmentation were observed shortly after infection. • DNA condensation and fragmentation were inhibited with a caspase inhibitor (z-VAD-fmk), which suggests a caspase dependent pathway. In addition the caspase inhibitor increased the percentage of infected cells.
Future Studies • A previous study showed C. parvum also caused apoptosis in an infected biliary epithelial cell line. Does C. parvum cause apoptosis in all epithelial cells and what is the exact mechanism? • Intrinsic or extrinsic pathway or both? • What are the consequences of inhibiting apoptosis in these epithelial cells in vivo? • Does it benefit the host or the pathogen? • During C. parvum infection the disruption of the intestinal barrier allows absorption of large molecules including lactulose and mannitol leading to more severe diarrhea. • Could apoptosis be contributing to this increased permeability?