DS86760016, a Leucyl-tRNA Synthetase Inhibitor with Activity against Pseudomonas aeruginosa.

DS86760016 is a new leucyl-tRNA-synthetase inhibitor at the preclinical development stage. DS86760016 showed potent activity against extended-spectrum multidrug-resistant Pseudomonas aeruginosa isolated from clinical samples and in vitro biofilms. In a murine catheter-associated urinary tract infection model, DS86760016 treatment resulted in significant eradication of P. aeruginosa from the kidney, bladder, and catheter without developing drug resistance. Our data suggest that DS86760016 has the potential to act as a new drug for the treatment of Pseudomonas infections.

Synthesis and evaluation of thiomannosides, potent and orally active FimH inhibitors.

FimH is a type I fimbrial lectin located at the tip of type-1 pili of Gram-negative uropathogenic Escherichia coli (UPEC) guiding its ability to adhere and infect urothelial cells. Accordingly, blocking FimH with small molecule inhibitor is considered as a promising new therapeutic alternative to treat urinary tract infections caused by UPEC. Herein, we report that compounds having the S-glycosidic bond (thiomannosides) had improved metabolic stability and plasma exposures when dosed orally. Especially compound 5h showed the potential to inhibit biofilm formation and also to disrupt the preformed biofilm. And compound 5h showed prophylactic effect in UTI model in mice.

Preclinical drug metabolism and pharmacokinetics of salinomycin, a potential candidate for targeting human cancer stem cells.

There has been a search for new anticancer agents to treat cancer resistance throughout the globe. Salinomycin (SAL), a broad spectrum antibiotic and a coccidiostat has been found to counter tumour resistance and kill cancer stem cells with better efficacy than the existing chemotherapeutic agents; paclitaxel and doxorubicin. This refocused its importance for treatment of human cancers. In this study, we studied the in vitro drug metabolism and pharmacokinetic parameters of SAL. SAL undergoes rapid metabolism in liver microsomes and has a high intrinsic clearance. SAL metabolism is mainly mediated by CYP enzymes; CYP3A4 the major enzyme metabolising SAL. The percent plasma protein binding of SAL in human was significantly lower as compared to mouse and rat plasma. CYP inhibition was carried out by chemical inhibition and recombinant enzyme studies. SAL was found to be a moderate inhibitor of CYP2D6 as well as CYP3A4. As CYP3A4 was the major enzyme responsible for metabolism of SAL, in vivo pharmacokinetic study in rats was done to check the effect of concomitant administration of Ketoconazole (KTC) on SAL pharmacokinetics. KTC, being a selective CYP3A4 inhibitor increased the systemic exposure of SAL significantly to 7-fold in AUC0-α and 3-fold increase in Cmax of SAL in rats with concomitant KTC administration.

Correlation of in vitro and in vivo plasma protein binding using ultracentrifugation and UPLC-tandem mass spectrometry.

The aim of the present study is to develop and demonstrate the correlation between in vitro and in vivo Plasma Protein Binding (PPB) using the ultracentrifugation method for its validation by using marketed compounds like atenolol, theophylline and phenytoin. In this study, in vitro PPB is carried out using ultracentrifugation, by spiking the selected marketed compounds at concentrations of 5 and 15 µM in plasma. In an in vivo study, rats (n = 3) were given a single oral dose (10 mg kg(-1)) and post-dose samples were subjected to ultracentrifugation to obtain the protein-free fraction. A rapid and highly sensitive method was developed and validated for determining the free fraction of marketed compounds in rat plasma using protein precipitation and analysis using an ultra performance liquid chromatography electrospray ionization (ESI) tandem mass spectrometer system (UPLC-MS/MS). The in vitro free fraction (fup) values were 0.93 ± 0.07 for atenolol, 0.31 ± 0.03 for theophylline and 0.09 ± 0.02 for phenytoin which correlated well with the corresponding in vivo values of 0.91 ± 0.03 for atenolol, 0.25 ± 0.02 for theophylline and 0.09 ± 0.01 for phenytoin with a coefficient of variation less than 11.06%, 11.45% and 13.67%, respectively. Therefore the validated high-throughput in vitro PPB study is expected to have a powerful impact on reducing the cost as well as time in the drug discovery process.

Synthesis, antimalarial activity, and preclinical pharmacology of a novel series of 4'-fluoro and 4'-chloro analogues of amodiaquine. Identification of a suitable "back-up" compound for N-tert-butyl isoquine.

On the basis of a mechanistic understanding of the toxicity of the 4-aminoquinoline amodiaquine (1b), three series of amodiaquine analogues have been prepared where the 4-aminophenol "metabolic alert" has been modified by replacement of the 4'-hydroxy group with a hydrogen, fluorine, or chlorine atom. Following antimalarial assessment and studies on mechanism of action, two candidates were selected for detailed ADME studies and in vitro and in vivo toxicological assessment. 4'-Fluoro-N-tert-butylamodiaquine (2k) was subsequently identified as a candidate for further development studies based on potent activity versus chloroquine-sensitive and resistant parasites, moderate to excellent oral bioavailability, low toxicity in in vitro studies, and an acceptable safety profile.

Candidate selection and preclinical evaluation of N-tert-butyl isoquine (GSK369796), an affordable and effective 4-aminoquinoline antimalarial for the 21st century.

N-tert-Butyl isoquine (4) (GSK369796) is a 4-aminoquinoline drug candidate selected and developed as part of a public-private partnership between academics at Liverpool, MMV, and GSK pharmaceuticals. This molecule was rationally designed based on chemical, toxicological, pharmacokinetic, and pharmacodynamic considerations and was selected based on excellent activity against Plasmodium falciparum in vitro and rodent malaria parasites in vivo. The optimized chemistry delivered this novel synthetic quinoline in a two-step procedure from cheap and readily available starting materials. The molecule has a full industry standard preclinical development program allowing first into humans to proceed. Employing chloroquine (1) and amodiaquine (2) as comparator molecules in the preclinical plan, the first preclinical dossier of pharmacokinetic, toxicity, and safety pharmacology has also been established for the 4-aminoquinoline antimalarial class. These studies have revealed preclinical liabilities that have never translated into the human experience. This has resulted in the availability of critical information to other drug development teams interested in developing antimalarials within this class.

Inhibitors of tripeptidyl peptidase II. 3. Derivation of butabindide by successive structure optimizations leading to a potential general approach to designing exopeptidase inhibitors.

The cholecystokinin-8 (CCK-8)-inactivating peptidase is a serine peptidase that has been shown to be a membrane-bound isoform of tripeptidyl peptidase II (EC 3.4.14.10). It cleaves the neurotransmitter CCK-8 sulfate at the Met-Gly bond to give Asp-Tyr(SO3H)-Met-OH + Gly-Trp-Met-Asp-Phe-NH2. Starting from Val-Pro-NHBu, a dipeptide of submicromolar affinity that had previously been generated to serve as a lead, successive optimization at P3, P1, and then P2 gave Abu-Pro-NHBu (18, Ki = 80 nM). Further transformation (by making a benzologue) gave the indoline analogue, butabindide (33) as a reversible inhibitor having nanomolar affinity (Ki = 7 nM). Retrospective analysis suggested the possibility of a general approach to designing exopeptidase inhibitors starting from the structure of the first hydrolysis product. Application of this approach to CCK-8 led to Abu-Phe-NHBu (37), but this only had Ki = 9.4 microM. Molecular modeling, to determine the minimum energy conformations and explain the 1000-fold better affinity of butabindide, indicated that 37 cannot access the likely active conformation of butabindide.