Abstract
Cryptococcus neoformans is an environmental fungus that causes an estimated 180,000 deaths annually and transitions from the external environment to the host environment to cause disease. CO(2) concentrations in the atmosphere (0.04%) are dramatically lower than in mammalian tissues (5%). Environmental C. neoformans strains that cannot tolerate 5% CO(2) are less virulent than CO(2)-tolerant strains. Microevolution at elevated CO(2) generates loss-of-function mutations in the nucleotide binding protein Avc1 that confer CO(2) tolerance to CO(2)-intolerant strains. Mechanistically, Avc1 positively regulates the expression of plasma membrane transporters, including PDR9, a phospholipid floppase that negatively modulates CO(2) fitness. Deletion of AVC1 in five CO(2)-intolerant environmental strains increases competitive fitness in host CO(2) and in a mouse infection model. Importantly, strains with similar AVC1 mutations emerge in patients with relapsed cryptococcosis. Therefore, this microevolutionary convergence strongly suggests that adaptation to host CO(2) is a significant driver of C. neoformans fitness during infection.