Trehalose dimycolate (TDM), also known as cord factor, is a major surface glycolipid of the cell wall of mycobacteria. Because of its potent biological functions in models of infection, adjuvancy, and immunotherapy, it is important to determine how its biosynthesis is regulated. Here we show that glucose, a host-derived product that is not readily available in the environment, causes Mycobacterium avium to down-regulate TDM expression while up-regulating production of another major glycolipid with immunological roles in T cell activation, glucose monomycolate (GMM). In vitro, the mechanism of reciprocal regulation of TDM and GMM involves competitive substrate selection by antigen 85A. The switch from TDM to GMM biosynthesis occurs near the physiological concentration of glucose present in mammalian hosts. We further demonstrate that GMM is produced in vivo by mycobacteria growing in mouse lung. These results establish an enzymatic pathway for GMM production. More generally, these observations provide a specific enzymatic mechanism for dynamic alterations of cell wall glycolipid remodeling in response to the transition from noncellular to cellular growth environments, including factors that are monitored by the host immune system.
Mycobacterium avium complex (MAC)2 includes a group of acid-fast bacteria that distribute widely in natural environments, including soil, water, aerosols, and dust (1). Although less virulent than Mycobacterium tuberculosis, these environmental mycobacteria occasionally infect humans, especially patients infected with human immunodeficiency virus type 1, where they represent a major cause of morbidity. The incidence of clinically overt MAC infection has increased significantly in recent years, and because of the multidrug resistance evolved by the microbes, MAC infection is difficult to clear with chemotherapeutic agents. Thus, M. tuberculosis and MAC are now the two major groups of mycobacteria species that require further efforts for prevention and treatment. Unlike M. tuberculosis, which transmits primarily from individuals with active disease, epidemiologic evidence suggests that such transmission pathways are unlikely for MAC. Rather, MAC infection appears to occur when susceptible individuals are exposed to environmental MAC. These observations predict that, upon infection, environmental MAC should undergo significant adaptive changes to allow its survival and replication within the host.Mycobacteria possess highly lipid-rich cell walls that are critical not simply for their acid-fast properties but also for their survival and replication. The cell wall contains mycolic acids, an ␣-alkyl--hydroxy fatty acid with extremely long carbon chains (ϳC 80 ), which are densely aligned in covalent association with the 6-position of arabinose termini of the underlying arabinogalactan sugar layer or exist as free molecules complexed to sugars, either glucose or trehalose. Arabinogalactan-linked mycolates are proposed to extend outward and interact noncovalently with carbon chains of the so-c...
