Lipopolysaccharide phase variation determines the complement-mediated serum susceptibility of Coxiella burnetii (original) (raw)

Abstract

Phase variation of Coxiella burnetii is due to variation of the lipopolysaccharide (LPS), a phenomenon analogous to smooth-to-rough LPS variation of gram-negative enteric bacteria. Virulent enterobacteria usually have a smooth LPS and resist serum killing, whereas avirulent rough LPS mutants are sensitive to complement-mediated serum killing. Like gram-negative enterobacteria, smooth LPS phase variants of C. burnetii are virulent, whereas the rough LPS variants are avirulent. We therefore studied the effects of human serum on the LPS variants of the Nine Mile strain of C. burnetii. Analogous to gram-negative enterobacteria, the smooth and intermediate LPS C. burnetii phase variants were resistant to complement-mediated serum killing, whereas the rough LPS variants were killed by serum complement. Although the smooth and intermediate LPS variants were serum resistant, they differed in their interactions with the complement system. The smooth LPS variant activated complement poorly and did not bind C3b; however, the intermediate LPS variant activated complement and bound C3b. The rough LPS variant activated complement via the alternative pathway, whereas the intermediate LPS variant activated the classical pathway. These results provide an explanation for the avirulent nature of the rough LPS variant of C. burnetii and suggest that differences in C. burnetii LPS structure influence the interactions of the LPS phase variants with the complement system.

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Selected References

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