Phosphate Binding in PNP Alters Transition-State Analogue Affinity and Subunit Cooperativity.

Purine nucleoside phosphorylases (PNPs) catalyze the phosphorolysis of 6-oxypurine nucleosides with an HPO42- dianion nucleophile. Nucleosides and phosphate occupy distinct pockets in the PNP active site. Evaluation of the HPO42- site by mutagenesis, cooperative binding studies, and thermodynamic and structural analysis demonstrate that alterations in the HPO42- binding site can render PNP inactive and significantly impact subunit cooperativity and binding to transition-state analogue inhibitors. Cooperative interactions between the cationic transition-state analogue and the anionic HPO42- nucleophile demonstrate the importance of reforming the transition-state ensemble for optimal inhibition with transition-state analogues. Altered phosphate binding in the catalytic site mutants helps to explain one of the known lethal PNP deficiency syndromes in humans.

Cell-Effective Transition-State Analogue of Phenylethanolamine N-Methyltransferase.

Phenylethanolamine N-methyltransferase (PNMT) catalyzes the S-adenosyl-l-methionine (SAM)-dependent methylation of norepinephrine to form epinephrine. Epinephrine is implicated in the regulation of blood pressure, respiration, Alzheimer's disease, and post-traumatic stress disorder (PTSD). Transition-state (TS) analogues bind their target enzymes orders of magnitude more tightly than their substrates. A synthetic strategy for first-generation TS analogues of human PNMT (hPNMT) permitted structural analysis of hPNMT and revealed potential for second-generation inhibitors [Mahmoodi, N.; J. Am. Chem. Soc. 2020, 142, 14222-14233]. A second-generation TS analogue inhibitor of PNMT was designed, synthesized, and characterized to yield a Ki value of 1.2 nM. PNMT isothermal titration calorimetry (ITC) measurements of inhibitor 4 indicated a negative cooperative binding mechanism driven by large favorable entropic contributions and smaller enthalpic contributions. Cell-based assays with HEK293T cells expressing PNMT revealed a cell permeable, intracellular PNMT inhibitor with an IC50 value of 81 nM. Structural analysis demonstrated inhibitor 4 filling catalytic site regions to recapitulate both norepinephrine and SAM interactions. Conformation of the second-generation inhibitor in the catalytic site of PNMT improves contacts relative to those from the first-generation inhibitors. Inhibitor 4 demonstrates up to 51,000-fold specificity for PNMT relative to DNA and protein methyltransferases. Inhibitor 4 also exhibits a 12,000-fold specificity for PNMT over the α2-adrenoceptor.

Kinetic Characterization and Inhibition of Trypanosoma cruzi Hypoxanthine-Guanine Phosphoribosyltransferases.

Chagas disease, caused by the parasitic protozoan Trypanosoma cruzi, affects over 8 million people worldwide. Current antiparasitic treatments for Chagas disease are ineffective in treating advanced, chronic stages of the disease, and are noted for their toxicity. Like most parasitic protozoa, T. cruzi is unable to synthesize purines de novo, and relies on the salvage of preformed purines from the host. Hypoxanthine-guanine phosphoribosyltransferases (HGPRTs) are enzymes that are critical for the salvage of preformed purines, catalyzing the formation of inosine monophosphate (IMP) and guanosine monophosphate (GMP) from the nucleobases hypoxanthine and guanine, respectively. Due to the central role of HGPRTs in purine salvage, these enzymes are promising targets for the development of new treatment methods for Chagas disease. In this study, we characterized two gene products in the T. cruzi CL Brener strain that encodes enzymes with functionally identical HGPRT activities in vitro: TcA (TcCLB.509693.70) and TcC (TcCLB.506457.30). The TcC isozyme was kinetically characterized to reveal mechanistic details on catalysis, including identification of the rate-limiting step(s) of catalysis. Furthermore, we identified and characterized inhibitors of T. cruzi HGPRTs originally developed as transition-state analogue inhibitors (TSAIs) of Plasmodium falciparum hypoxanthine-guanine-xanthine phosphoribosyltransferase (PfHGXPRT), where the most potent compound bound to T. cruzi HGPRT with low nanomolar affinity. Our results validated the repurposing of TSAIs to serve as selective inhibitors for orthologous molecular targets, where primary and secondary structures as well as putatively common chemical mechanisms are conserved.

A resistant mutant of Plasmodium falciparum purine nucleoside phosphorylase uses wild-type neighbors to maintain parasite survival.

Plasmodium falciparum purine nucleoside phosphorylase (PfPNP) catalyzes an essential step in purine salvage for parasite growth. 4'-Deaza-1'-Aza-2'-Deoxy-1'-(9-Methylene)-Immucillin-G (DADMe-ImmG) is a transition state analog inhibitor of this enzyme, and P. falciparum infections in an Aotus primate malaria model can be cleared by oral administration of DADMe-ImmG. P. falciparum cultured under increasing DADMe-ImmG drug pressure exhibited PfPNP gene amplification, increased protein expression, and point mutations involved in DADMe-ImmG binding. However, the weak catalytic properties of the M183L resistance mutation (∼17,000-fold decrease in catalytic efficiency) are inconsistent with the essential function of PfPNP. We hypothesized that M183L subunits may form mixed oligomers of native and mutant PfPNP monomers to give hybrid hexameric enzymes with properties conferring DADMe-ImmG resistance. To test this hypothesis, we designed PfPNP constructs that covalently linked native and the catalytically weak M183L mutant subunits. Engineered hybrid PfPNP yielded trimer-of-dimer hexameric protein with alternating native and catalytically weak M183L subunits. This hybrid PfPNP gave near-native Km values for substrate, but the affinity for DADMe-ImmG and catalytic efficiency were both reduced approximately ninefold relative to a similar construct of native subunits. Contact between the relatively inactive M183L and native subunits is responsible for altered properties of the hybrid protein. Thus, gene amplification of PfPNP provides adequate catalytic activity while resistance to DADMe-ImmG occurs in the hybrid oligomer to promote parasite survival. Coupled with the slow development of drug resistance, this resistance mechanism highlights the potential for DADMe-ImmG use in antimalarial combination therapies.

The design of protozoan phosphoribosyltransferase inhibitors containing non-charged phosphate mimic residues.

Phosphate groups play essential roles in biological processes, including retention inside biological membranes. Phosphodiesters link nucleic acids, and the reversible transfer of phosphate groups is essential in energy metabolism and cell-signalling processes. Phosphorylated metabolic intermediates are known targets for metabolic and disease-related disorders, and the enzymes involved in these pathways recognize phosphate groups in their catalytic sites. Therapeutics that target these enzymes can require charged (ionic) entities to capture the binding energy of ionic substrates. Such compounds are not cell-permeable and require pro-drug strategies for efficacy as therapeutics. Protozoan parasites such as Plasmodium and Trypanosoma spp. are unable to synthesise purines de novo and rely on the salvage of purines from the host cell to synthesise free purine bases. Purine phosphoribosyltransfereases (PPRTases) play a crucial role for purine salvage and are potential target for drug development. Here we present attempts to design inhibitors of PPRTases that are non-ionic and show affinity for the nucleotide 5'-phosphate binding site. Inhibitor design was based on known potent ionic inhibitors, reported phosphate mimics and computational modelling studies.

Mechanism of inhibition of botulinum neurotoxin type A light chain by two quinolinol compounds.

Quinolinol-based compounds are a promising starting point for discovery of effective inhibitors of the clostridial neurotoxin, botulinum neurotoxin type A light chain (BoNT/A LC). Insights into the mechanism of inhibition by quinolinol compounds facilitate interpretation of docking data and inhibitor optimization. In this study, a fluorogenic substrate of BoNT/A, SNAPtide, was used to study the mechanism by which two new quinolinol compounds, MSU58 and MSU84, with IC50 values of 3.3 µM and 5.8 µM, respectively, inhibit BoNT/A LC. Kinetic studies and model discrimination analysis showed both compounds to be competitive inhibitors of BoNT/A LC with inhibition constants (KI) 3.2 µM and 6.2 µM for MSU58 and MSU84, respectively. These data indicate that the inhibitors bind in the BoNT/A LC active site and that inhibitor binding is mutually exclusive with the binding of the substrate. This is the first study to report the competitive inhibition of BoNT/A LC by quinolinol compounds. These data help define the inhibitor binding pocket and, along with structure activity relationship studies, provide immediate direction for further compound synthesis.