The metabolic activity of Mycobacterium tuberculosis, assessed by use of a novel inducible GFP expression system, correlates with its capacity to inhibit phagosomal maturation and acidification in human macrophages

M. tuberculosis generally reside in phagosomes within human macrophages that resist maturation and acidification, but exhibit significant heterogeneity. In this study we have constructed an IPTG inducible-GFP expression system in M. tuberculosis to assess the relationship between the metabolic status of M. tuberculosis and the degree of phagosomal maturation. Using these recombinant bacteria, we have found that, in human macrophages, M. tuberculosis that respond to IPTG with expression of GFP fluorescence, and hence are metabolically active, reside in non-acidified phagosomes that have not fused with Texas Red dextran prelabeled lysosomes. In contrast, M. tuberculosis that fail to express GFP in response to IPTG, and hence are metabolically inactive, reside within acidified phagosomes that have fused with Texas Red dextran labeled lysosomes. These studies demonstrate that metabolic activity of M. tuberculosis correlates strongly with phagosomal maturation and that the inducible GFP expression system is useful for assessing metabolic activity of intracellular M. tuberculosis

On the killing of mycobacteria by macrophages

Both pathogenic and non-pathogenic mycobacteria are internalized into macrophage phagosomes. Whereas the non-pathogenic types are invariably killed by all macrophages, the pathogens generally survive and grow. Here, we addressed the survival, production