Bis-acridines as lead antiparasitic agents: structure-activity analysis of a discrete compound library in vitro.

Parasitic diseases are of enormous public health significance in developing countries-a situation compounded by the toxicity of and resistance to many current chemotherapeutics. We investigated a focused library of 18 structurally diverse bis-acridine compounds for in vitro bioactivity against seven protozoan and one helminth parasite species and compared the bioactivities and the cytotoxicities of these compounds toward various mammalian cell lines. Structure-activity relationships demonstrated the influence of both the bis-acridine linker structure and the terminal acridine heterocycle on potency and cytotoxicity. The bioactivity of polyamine-linked acridines required a minimum linker length of approximately 10 A. Increasing linker length resulted in bioactivity against most parasites but also cytotoxicity toward mammalian cells. N alkylation, but less so N acylation, of the polyamine linker ameliorated cytotoxicity while retaining bioactivity with 50% effective concentration (EC(50)) values similar to or better than those measured for standard drugs. Substitution of the polyamine for either an alkyl or a polyether linker maintained bioactivity and further alleviated cytotoxicity. Polyamine-linked compounds in which the terminal acridine heterocycle had been replaced with an aza-acridine also maintained acceptable therapeutic indices. The most potent compounds recorded low- to mid-nanomolar EC(50) values against Plasmodium falciparum and Trypanosoma brucei; otherwise, low-micromolar potencies were measured. Importantly, the bioactivity of the library was independent of P. falciparum resistance to chloroquine. Compound bioactivity was a function of neither the potential to bis-intercalate DNA nor the inhibition of trypanothione reductase, an important drug target in trypanosomatid parasites. Our approach illustrates the usefulness of screening focused compound libraries against multiple parasite targets. Some of the bis-acridines identified here may represent useful starting points for further lead optimization.

Time-dependent inhibitors of trypanothione reductase: analogues of the spermidine alkaloid lunarine and related natural products.

The macrocyclic spermidine alkaloid lunarine 1 from Lunaria biennis is a competitive, time-dependent inhibitor of the protozoan oxidoreductase trypanothione reductase (TryR), a promising target in drug design against tropical parasitic diseases. Various molecules related to 1 and the alkaloid itself have been synthesized in racemic form and evaluated against TryR in order to determine the key features of 1 that are associated with time-dependent inhibition. Kinetic data are consistent with an inactivation mechanism involving a conjugate addition of an active site cysteine residue onto the C-24-C-25 double bond of the tricyclic nucleus of 1. Comparison of data for synthetic (+/-)-1, the natural product, and other derivatives 7-10 from L. biennis confirms the importance of the unique structure of the tricyclic core as a motif for inhibitor design and reveals that the non-natural enantiomer may be a more suitable scaffold upon which thiophilic groups may be presented.

Two interacting binding sites for quinacrine derivatives in the active site of trypanothione reductase: a template for drug design.

Trypanothione reductase is a key enzyme in the trypanothione-based redox metabolism of pathogenic trypanosomes. Because this system is absent in humans, being replaced with glutathione and glutathione reductase, it offers a target for selective inhibition. The rational design of potent inhibitors requires accurate structures of enzyme-inhibitor complexes, but this is lacking for trypanothione reductase. We therefore used quinacrine mustard, an alkylating derivative of the competitive inhibitor quinacrine, to probe the active site of this dimeric flavoprotein. Quinacrine mustard irreversibly inactivates Trypanosoma cruzi trypanothione reductase, but not human glutathione reductase, in a time-dependent manner with a stoichiometry of two inhibitors bound per monomer. The rate of inactivation is dependent upon the oxidation state of trypanothione reductase, with the NADPH-reduced form being inactivated significantly faster than the oxidized form. Inactivation is slowed by clomipramine and a melarsen oxide-trypanothione adduct (both are competitive inhibitors) but accelerated by quinacrine. The structure of the trypanothione reductase-quinacrine mustard adduct was determined to 2.7 A, revealing two molecules of inhibitor bound in the trypanothione-binding site. The acridine moieties interact with each other through pi-stacking effects, and one acridine interacts in a similar fashion with a tryptophan residue. These interactions provide a molecular explanation for the differing effects of clomipramine and quinacrine on inactivation by quinacrine mustard. Synergism with quinacrine occurs as a result of these planar acridines being able to stack together in the active site cleft, thereby gaining an increased number of binding interactions, whereas antagonism occurs with nonplanar molecules, such as clomipramine, where stacking is not possible.

Benzofuranyl 3,5-bis-polyamine derivatives as time-dependent inhibitors of trypanothione reductase.

The synthesis and evaluation of 3,5-disubstituted benzofuran derivatives as time-dependent inhibitors of the protozoan oxidoreductase trypanothione reductase are reported. These molecules were designed as simplified mimetics of the naturally occurring spermidine-bridged macrocyclic alkaloid lunarine 1, a known time-dependent inhibitor of trypanothione reductase. In this series of compounds the bis-polyaminoacrylamide derivatives 2-4 were all shown to be competitive inhibitors, but only the bis-4-methyl-piperazin-1-yl-propylacrylamide derivative 4 displayed time-dependent activity. The kinetics of time dependent inactivation of trypanothione reductase by 1 and 4 have been determined and are compared and discussed herein.

Ellman's-reagent-mediated regeneration of trypanothione in situ: substrate-economical microplate and time-dependent inhibition assays for trypanothione reductase.

Trypanothione reductase (TryR) is a key enzyme involved in the oxidative stress management of the Trypanosoma and Leishmania parasites, which helps to maintain an intracellular reducing environment by reduction of the small-molecular-mass disulphide trypanothione (T[S](2)) to its di-thiol derivative dihydrotrypanothione (T[SH](2)). TryR inhibition studies are currently impaired by the prohibitive costs of the native enzyme substrate T[S](2). Such costs are particularly notable in time-dependent and high-throughput inhibition assays. In the present study we report a protocol that greatly decreases the substrate quantities needed for such assays. This is achieved by coupling the assay with the chemical oxidant 5,5'-dithiobis-(2-nitrobenzoic acid) (DTNB), which can rapidly re-oxidize the T[SH](2) product back into the disulphide substrate T[S](2), thereby maintaining constant substrate concentrations and avoiding deviations from rate linearity due to substrate depletion. This has enabled the development of a continuous microplate assay for both classical and time-dependent TryR inhibition in which linear reaction rates can be maintained for 60 min or more using minimal substrate concentrations (<1 microM, compared with a substrate K (m) value of 30 microM) that would normally be completely consumed within seconds. In this manner, substrate requirements are decreased by orders of magnitude. The characterization of a novel time-dependent inhibitor, cis -3-oxo-8,9b-bis-(N(1)-acrylamidospermidyl)-1,2,3,4,4a,9b-hexahydrobenzofuran (PK43), is also described using these procedures.