Mycobacterium tuberculosis (Mtb) is a bacterium that causes tuberculosis (TB), the single leading cause of death in the world from infectious disease today. The macrophage is the host cell most commonly infected by Mtb and ultimately responsible for determining whether the outcome of exposure to Mtb is no infection, latent infection or active disease. We are testing two ways to improve the host's control of TB, both of which involve inhibiting targets in the macrophage, rather than in the bacterium, with the expectation that such host-directed therapies (HDT) can be combined with conventional anti-mycobacterial therapy (AMT) to shorten the course of curative treatment. We will test the following hypotheses. (1) Host control of Mtb will be favored by blocking Mtb-induced death of macrophages. Our preliminary evidence supports the specific hypothesis that Mtb- induced death of macrophages is exacerbated by the autocrine action of type I interferon. (2) Host control of Mtb will also be favored by enhancing macrophage activation over the level achieved with interferon-? (IFN?) alone. Our preliminary evidence supports the specific hypothesis that such enhancement is favored by a novel, drug-like chemical compound we have identified whose action leads to inhibition of mechanistic target of rapamycin (mTOR), resulting in the activation of certain transcription factors, including TFEB, that promote lysosomal biogenesis and autophagy. (3) The combination of enhanced survival of macrophages and their enhanced activation will be additive or synergistic in improving the control of Mtb and will not exacerbate immunopathology if the resulting reduction in bacterial burden and antigenic load is great enough. Accordingly, we will test the two HDTs alone and together in Mtb-infected mice, with and without AMT. Finally, we hypothesize that host-directed therapy (HDT) combined with anti-mycobacterial therapy (AMT) will allow treatment-shortening for relapse-free cure of Mtb-infected mice. The focus of Aim 1 is to prolong the survival of Mtb-infected macrophages in a healthy state and to define the mechanisms by which blockade of type I IFN signaling does so. The focus of Aim 2 is to enhance the activation of surviving macrophages and to define the role of mTOR and TFEB family transcription factors in doing so. The role of Aim 3 is to test these two interventions in combination with each other and with AMT.
Mycobacterium tuberculosis (Mtb) is a bacterium that causes tuberculosis (TB), the single leading cause of death in the world from infectious disease today, and the macrophage is the host cell most commonly infected by Mtb and ultimately responsible for determining whether the outcome of exposure to Mtb is no infection, latent infection or active disease. We are testing two ways to improve the host's control of TB, both of which involve inhibiting targets in the macrophage, rather than in the bacterium, with the expectation that such host- directed therapies (HDT) can be combined with conventional anti-mycobacterial drugs to shorten the course of curative treatment. We will test the effects and explore the mechanisms of each of these HDTs, then test them in combination with each other and with anti-mycobacterial drugs.
