Susceptibility of beige mutant mice to candidiasis may be linked to a defect in granulocyte production by bone marrow stem cells.

The beige mutation in mice has a pervasive effect on mechanisms of host resistance to infectious agents. Best characterized are defects in granulocyte chemotaxis and phagocytosis, which are associated with increased susceptibility to bacteria, and a deficiency in the levels of natural killer (NK) cells, which has been linked to decreased resistance to both murine cytomegalovirus and the yeast Cryptococcus neoformans. The objective of the present experiments was to explore the cellular basis of the enhanced susceptibility of beige mice to systemic infection with the yeast Candida albicans. In contrast to murine cytomegalovirus and C. neoformans, infection with C. albicans did not induce any detectable NK cell activity in the spleen of bg/bg or bg/+ mice. Unfractionated bone marrow (BM) displayed some candidacidal activity, mediated by both phagocytic and nonphagocytic cells; however, there was no difference between homozygous and heterozygous mice in the effector function of normal BM cells or mononuclear cells derived from either short- or long-term BM cultures. On the other hand, peritoneal granulocytes from bg/bg mice were significantly more effective than those from bg/+ mice in killing Candida blastoconidia in vitro. A similar comparison of granulocytes from short-term BM cultures showed that the activities of cells from bg/bg and bg/+ mice were equivalent, indicating that the granulocytes derived from the peritoneal cavity of bg/bg mice had probably been exposed to some form of nonspecific stimulation in vivo. Somewhat surprisingly, long-term BM cultures did not support the continual growth of bg/bg granulocytes, and it is possible that the beige mutation may be associated with a lesion in the differentiation pathway that leads to the production of granulocytes. Taken together, the data indicate that, in beige mice, granulocytes rather than NK cells are a major determinant of natural resistance to C. albicans infections.