A histologic, immunofluorescence, and electron microscopic study of the intracellular parasitism of Coxiella burnetii (the Q fever agent) in mouse lungs after intranasal challenge was undertaken. It was shown that this microorganism invades type I and, rarely, type II pneumocytes as well as pulmonary fibroblasts and histiocytes. The infectious process can be described as a focal intra-alveolar inflammation with the macrophages prevailing in the exudate. It is self-limited, with a complete resolution. The inflammation is associated with atelectases and with increased secretory activity by type II pneumocytes. Alveolar macrophages and granulocytes degrade C. burnetii. This degradation is followed by damage to and eventual disintegration of some macrophages and by damage to some bacterium-free pneumocytes and vascular endothelial cells in the vicinity of macrophages degrading organisms. The cell damage might be caused by lipopolysaccharide released from degraded organisms. The infectious process is also associated with the influx of T cells in the pneumonic foci, T-cell attachment to the macrophages degrading organisms, and fusion of some macrophages. These are considered a morphologic expression of cell-mediated immunity involved in the infectious process.
Lungs and spleens of white mice were examined after intranasal and intraperitoneal challenge with Coxiellae burnetii, respectively. As a rule, these organisms inhabit lung alveolar macrophages and spleen reticular cells’ vacuoles and are surrounded with a three-layered wall. The vacuoles seem to be formed from phagolysosomes. They are stable structures. When lodged within vacuoles for a long time, Coxiellae preserve viability. Due to the capacity of Coxiellae to parasitize in cellular phagolysosomes, one might consider Q-rickettsiosis as an ‘exoplasmic parasitosis’.
Two phase I strains of Coxiella burnetii of different virulence were injected into the yolk sacs of chicken embryos, and the yolk sacs and livers were examined at intervals by light, fluorescent, and electron microscopy. The high absorptive and digestive capacities of the yolk endoderm contributed to he entrance of the organisms into endodermal epithelial cells where C. burnetii multiplied. Organisms multiplied not only inside specific vacuoles originating from phagolysosomes but also in the cytoplasm itself. Lysis of the limiting membrane of some phagolysosomes, a normal function of endodermal cells, as well as rupture of vacuoles, provided the release of C. burnetii into the cytoplasm. The C. burnetii strain of greater virulence infected 100% of the endodermal cells, whereas the strain of lesser virulence infected only 60%. Budding of very small particles from the C. burnetii bodies was demonstrated. The particles were regarded as filterable forms of the organism. Despite the enormous multiplication of C. burnetii in the endodermal cells, organisms were only rarely detected in the vitelline blood vessels and liver sinusoids of the embryos. Peculiarities of the infectious process of C. burnetii in chicken embryos and possible mechanisms of limitation of spread of the infection are discussed.
Mouse omentum was studied after intraperitoneal challenge with tachyzoites of Toxoplasma gondii. Parasites inhabit omental histiocytes, fibroblasts, mesothelial cells, and free peritoneal macrophages. Recently infected cells showed enhanced metabolic and functional activity. Villous projections of the parasitophorous vacuole wall appeared, usually opposite the anterior pole of the parasite. In mesothelial cells, projections formed terminal swellings not observed in other infected cells. Activation of host cells was followed by reduction of the density of the cytoplasmic matrix, autophagosome formation, and intracellular edema, indicating the damage. The wall of the parasitophorous vacuole loses the supporting host cell endoplasmic reticulum that was attached to the vacuole just after entrance of the parasite into the cell. Then lysis of the parasitophorous vacuole and complete cell destruction occurs. The growth of parasites in undamaged cells does not coincide with the inflammatory response. Inflammation of the peritoneum develops only after the start of mass destruction of infected cells. Thus tachyzoites of Toxoplasma exert significant pathogenic effects by their ability to activate the host cell, causing lysis of the parasitophorous vacuole and subsequent destruction of the entire cell.
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