Certain properties of isoniazid inhibition of mycolic acid synthesis in cell-free systems of M. aurum and M. avium.

In Mycobacterium tuberculosis isoniazid (INH)-susceptibility and the presence of a thermolabile catalase-peroxidase (T-catalase) are nearly always associated. It is shown in this study that an INH-susceptible strain of M. aurum had a T-catalase activity while its resistant mutants did not, but an in vitro susceptible strain of M. avium had a strong catalase activity without any detectable peroxidase properties. Synthesis of mycolic acids is a genus-specific target for INH and there is an excellent parallelism between INH-susceptibility of intact cells and that of a cell-free system synthesizing mycolic acids. We investigated whether the INH-inhibition of mycolic acid cell-free synthesis was dependent on a T-catalase activity in M. aurum and M. avium: no catalase activity was detectable in any of the cell-free systems tested, and addition of T-catalase from susceptible M. aurum strain to an INH-resistant system did not render it sensitive. So INH can inhibit mycolic acid synthesis independently of the presence of a T-catalase. An INH-susceptible cell-free system prepared from INH-treated (at the MIC) cells was progressively and irreversibly inhibited, while incubation of the same susceptible system in the presence of INH did not result in a significant irreversible inhibition. The possible participation of T-catalase in the irreversible effect of INH is discussed.

Mycobacteria glycolipids as potential pathogenicity effectors: alteration of model and natural membranes.

Four mycobacterial wall glycolipids were tested for their effects on phospholipidic liposome organization and passive permeability and on oxidative phosphorylation of isolated mitochondria. From fluorescence polarization of diphenylhexatriene performed on liposomes it was concluded that the two trehalose derivatives (dimycoloyltrehalose and polyphthienoyltrehalose) rigidified the fluid state of liposomes, the triglycosyl phenolphthiocerol slightly fluidized the gel state, while the peptidoglycolipid ("apolar" mycoside C) just shifted the phase transition temperature upward. Dimycoloyltrehalose was without effect on liposome passive permeability, as estimated from dicarboxyfluorescein leak rates, and polyphthienoyltrehalose and triglycosyl phenolphthiocerol slightly decreased leaks, while mycoside C dramatically increased leaks. Activity of these lipids on mitochondrial oxidative phosphorylation was examined. The two trehalose derivatives have been tested previously: both had the same type of inhibitory activity, dimycoloyltrehalose being the most active. Triglycosyl phenolphthiocerol was inactive. Mycoside C was very active, with effects resembling those of classical uncouplers: this suggested that its activity on mitochondria was related to its effect on permeability. All these membrane alterations were called nonspecific because it is likely that they result from nonspecific lipid-lipid interactions, and not from recognition between specific molecular structures. Such nonspecific interactions could be at the origin of some of the effects of mycobacteria glycolipids on cells of the immune system observed in the last few years.