Drug target validation of the trypanothione pathway enzymes through metabolic modelling.

A kinetic model of trypanothione [T(SH)(2)] metabolism in Trypanosoma cruzi was constructed based on enzyme kinetic parameters determined under near-physiological conditions (including glutathione synthetase), and the enzyme activities, metabolite concentrations and fluxes determined in the parasite under control and oxidizing conditions. The pathway structure is characterized by a T(SH)(2) synthetic module of low flux and low catalytic capacity, and another more catalytically efficient T(SH)(2) -dependent antioxidant/regenerating module. The model allowed quantification of the contribution of each enzyme to the control of T(SH)(2) synthesis and concentration (flux control and concentration control coefficients, respectively). The main control of flux was exerted by γ-glutamylcysteine synthetase (γECS) and trypanothione synthetase (TryS) (control coefficients of 0.58-0.7 and 0.49-0.58, respectively), followed by spermidine transport (0.24); negligible flux controls by trypantothione reductase (TryR) and the T(SH)(2)-dependent antioxidant machinery were determined. The concentration of reduced T(SH)(2) was controlled by TryR (0.98) and oxidative stress (-0.99); however, γECS and TryS also exerted control on the cellular level of T(SH(2)) when they were inhibited by more than 70%. The model predicted that in order to diminish the T(SH)(2) synthesis flux by 50%, it is necessary to inhibit γECS or TryS by 58 or 63%, respectively, or both by 50%, whereas more than 98% inhibition was required for TryR. Hence, simultaneous and moderate inhibition of γECS and TryS appears to be a promising multi-target therapeutic strategy. In contrast, use of highly potent and specific inhibitors for TryR and the antioxidant machinery is necessary to affect the antioxidant capabilities of the parasites.

Dissecting the essentiality of the bifunctional trypanothione synthetase-amidase in Trypanosoma brucei using chemical and genetic methods.

The bifunctional trypanothione synthetase-amidase (TRYS) comprises two structurally distinct catalytic domains for synthesis and hydrolysis of trypanothione (N(1),N(8)-bis(glutathionyl)spermidine). This unique dithiol plays a pivotal role in thiol-redox homeostasis and in defence against chemical and oxidative stress in trypanosomatids. A tetracycline-dependent conditional double knockout of TRYS (cDKO) was generated in bloodstream Trypanosoma brucei. Culture of cDKO parasites without tetracycline induction resulted in loss of trypanothione and accumulation of glutathione, followed by growth inhibition and cell lysis after 6 days. In the absence of inducer, cDKO cells were unable to infect mice, confirming that this enzyme is essential for virulence in vivo as well as in vitro. To establish whether both enzymatic functions were essential, an amidase-dead mutant cDKO line was generated. In the presence of inducer, this line showed decreased growth in vitro and decreased virulence in vivo, indicating that the amidase function is not absolutely required for viability. The druggability of TRYS was assessed using a potent small molecule inhibitor developed in our laboratory. Growth inhibition correlated in rank order cDKO, single KO, wild-type and overexpressing lines and produced the predicted biochemical phenotype. The synthetase function of TRYS is thus unequivocally validated as a drug target by both chemical and genetic methods.

A nuclear magnetic resonance-based functional assay for nicotinamide adenine dinucleotide synthetase.

Nicotinamide adenine dinucleotide synthetase (NadE) is an essential enzyme for bacterial pathogens and is thus a promising antibacterial target. It catalyzes the conversion of nicotinic acid adenine dinucleotide to nicotinamide adenine dinucleotide. Changes in chemical shifts that occur in the nicotinic acid ring as it is converted to nicotinamide can be used for monitoring the reaction. A robust nuclear magnetic resonance-based activity assay was developed using robotically controlled reaction initiation and quenching. The single-enzyme assay has less potential for false positives compared to a coupled activity assay and is especially well suited to the high concentration of compounds in fragment screens. The assay has been used to screen fragment libraries for NadE inhibitors.