RESUMO
Cryptosporidiosis is a diarrheal disease caused by infection with Cryptosporidium spp. parasites and is a leading cause of death in malnourished children worldwide. The only approved treatment, nitazoxanide, has limited efficacy in this at-risk patient population. Additional safe therapeutics are urgently required to tackle this unmet medical need. However, the development of anti-cryptosporidial drugs is hindered by a lack of understanding of the optimal compound properties required to treat this gastrointestinal infection. To address this knowledge gap, a diverse set of potent lysyl-tRNA synthetase inhibitors was profiled to identify optimal physicochemical and pharmacokinetic properties required for efficacy in a chronic mouse model of infection. The results from this comprehensive study illustrated the importance of balancing solubility and permeability to achieve efficacy in vivo. Our results establish in vitro criteria for solubility and permeability that are predictive of compound efficacy in vivo to guide the optimization of anti-cryptosporidial drugs. Two compounds from chemically distinct series (DDD489 and DDD508) were identified as demonstrating superior efficacy and prioritized for further evaluation. Both compounds achieved marked parasite reduction in immunocompromised mouse models and a disease-relevant calf model of infection. On the basis of these promising data, these compounds have been selected for progression to preclinical safety studies, expanding the portfolio of potential treatments for this neglected infectious disease.
Assuntos
Criptosporidiose , Lisina-tRNA Ligase , Permeabilidade , Solubilidade , Animais , Criptosporidiose/tratamento farmacológico , Camundongos , Lisina-tRNA Ligase/metabolismo , Lisina-tRNA Ligase/antagonistas & inibidores , Cryptosporidium/efeitos dos fármacos , Humanos , Inibidores Enzimáticos/farmacologia , Inibidores Enzimáticos/uso terapêutico , Inibidores Enzimáticos/química , Modelos Animais de DoençasRESUMO
The emergence of new synthetic cannabinoid receptor agonists (SCRAs) onto the illicit drugs market continues to cause harm, and the overall availability of physicochemical and pharmacokinetic data for new psychoactive substances is lacking. The lipophilicity of 23 SCRAs and the plasma protein binding (PPB) of 11 SCRAs was determined. Lipophilicity was determined using a validated chromatographic hydrophobicity index (CHI) log D method; tested SCRAs showed moderate to high lipophilicity, with experimental log D7.4 ranging from 2.48 (AB-FUBINACA) to 4.95 (4F-ABUTINACA). These results were also compared to in silico predictions generated using seven commercially available software packages and online tools (Canvas; ChemDraw; Gastroplus; MoKa; PreADMET; SwissADME; and XlogP). Licenced, dedicated software packages provided more accurate lipophilicity predictions than those which were free or had prediction as a secondary function; however, the latter still provided competitive estimates in most cases. PPB of tested SCRAs, as determined by equilibrium dialysis, was in the upper range of the lipophilicity scale, ranging from 90.8% (ADB-BUTINACA) to 99.9% (BZO-HEXOXIZID). The high PPB of these drugs may contribute to reduced rate of clearance and extended durations of pharmacological effects compared to lesser-bound SCRAs. The presented data improve understanding of the behaviour of these drugs in the body. Ultimately, similar data and predictions may be used in the prediction of the structure and properties of drugs yet to emerge on the illicit market.
RESUMO
Malaria and cryptosporidiosis, caused by apicomplexan parasites, remain major drivers of global child mortality. New drugs for the treatment of malaria and cryptosporidiosis, in particular, are of high priority; however, there are few chemically validated targets. The natural product cladosporin is active against blood- and liver-stage Plasmodium falciparum and Cryptosporidium parvum in cell-culture studies. Target deconvolution in P. falciparum has shown that cladosporin inhibits lysyl-tRNA synthetase (PfKRS1). Here, we report the identification of a series of selective inhibitors of apicomplexan KRSs. Following a biochemical screen, a small-molecule hit was identified and then optimized by using a structure-based approach, supported by structures of both PfKRS1 and C. parvum KRS (CpKRS). In vivo proof of concept was established in an SCID mouse model of malaria, after oral administration (ED90 = 1.5 mg/kg, once a day for 4 d). Furthermore, we successfully identified an opportunity for pathogen hopping based on the structural homology between PfKRS1 and CpKRS. This series of compounds inhibit CpKRS and C. parvum and Cryptosporidium hominis in culture, and our lead compound shows oral efficacy in two cryptosporidiosis mouse models. X-ray crystallography and molecular dynamics simulations have provided a model to rationalize the selectivity of our compounds for PfKRS1 and CpKRS vs. (human) HsKRS. Our work validates apicomplexan KRSs as promising targets for the development of drugs for malaria and cryptosporidiosis.
Assuntos
Criptosporidiose , Cryptosporidium parvum/enzimologia , Inibidores Enzimáticos/farmacologia , Lisina-tRNA Ligase/antagonistas & inibidores , Malária Falciparum , Plasmodium falciparum/enzimologia , Proteínas de Protozoários/antagonistas & inibidores , Animais , Criptosporidiose/tratamento farmacológico , Criptosporidiose/enzimologia , Modelos Animais de Doenças , Inibidores Enzimáticos/química , Humanos , Lisina-tRNA Ligase/metabolismo , Malária Falciparum/tratamento farmacológico , Malária Falciparum/enzimologia , Camundongos SCID , Proteínas de Protozoários/metabolismoRESUMO
ß-Lactams represent perhaps the most important class of antibiotics yet discovered. However, despite many years of active research, none of the currently approved drugs in this class combine oral activity with long duration of action. Recent developments suggest that new ß-lactam antibiotics with such a profile would have utility in the treatment of tuberculosis. Consequently, the historical ß-lactam pharmacokinetic data have been compiled and analyzed to identify possible directions and drug discovery strategies aimed toward new ß-lactam antibiotics with this profile.
Assuntos
Antibacterianos/farmacocinética , Antibacterianos/uso terapêutico , Descoberta de Drogas/métodos , Mycobacterium tuberculosis/efeitos dos fármacos , Tuberculose/tratamento farmacológico , beta-Lactamas/farmacocinética , beta-Lactamas/uso terapêutico , Administração Oral , Animais , Antibacterianos/administração & dosagem , Antibacterianos/classificação , Disponibilidade Biológica , Permeabilidade da Membrana Celular/efeitos dos fármacos , Meia-Vida , Haplorrinos , Humanos , Ligação Proteica , Estudos Retrospectivos , Solubilidade , Resultado do Tratamento , beta-Lactamas/administração & dosagem , beta-Lactamas/classificaçãoRESUMO
Production of drug metabolites is one area where enzymatic conversion has significant advantages over synthetic chemistry. These high value products are complex to synthesize, but are increasingly important in drug safety testing. The vast majority of drugs are metabolized by cytochromes P450 (P450s), with oxidative transformations usually being highly regio- and stereo-selective. The PPIs (proton pump inhibitors) are drugs that are extensively metabolized by human P450s, producing diverse metabolites dependent on the specific substrate. In the present paper we show that single mutations (A82F and F87V) in the biotechnologically important Bacillus megaterium P450 BM3 enzyme cause major alterations in its substrate selectivity such that a set of PPI molecules become good substrates in these point mutants and in the F87V/A82F double mutant. The substrate specificity switch is analysed by drug binding, enzyme kinetics and organic product analysis to confirm new activities, and X-ray crystallography provides a structural basis for the binding of esomeprazole to the F87V/A82F enzyme. These studies confirm that such 'gatekeeper' mutations in P450 BM3 produce major perturbations to its conformation and substrate selectivity, enabling novel P450 BM3 reactions typical of those performed by human P450s. Efficient transformation of several PPI drugs to human-like products by BM3 variants provides new routes to production of these metabolites.
Assuntos
Bacillus megaterium/genética , Proteínas de Bactérias/genética , Sistema Enzimático do Citocromo P-450/genética , NADPH-Ferri-Hemoproteína Redutase/genética , Inibidores da Bomba de Prótons/metabolismo , Bacillus megaterium/enzimologia , Proteínas de Bactérias/metabolismo , Cristalografia por Raios X , Sistema Enzimático do Citocromo P-450/metabolismo , Esomeprazol/metabolismo , Humanos , NADPH-Ferri-Hemoproteína Redutase/metabolismo , Ressonância Magnética Nuclear Biomolecular , Omeprazol/metabolismo , Oxirredução , Especificidade por SubstratoRESUMO
Cytochrome P450 monooxygenases (P450s) have enormous potential in the production of oxychemicals, due to their unparalleled regio- and stereoselectivity. The Bacillus megaterium P450 BM3 enzyme is a key model system, with several mutants (many distant from the active site) reported to alter substrate selectivity. It has the highest reported monooxygenase activity of the P450 enzymes, and this catalytic efficiency has inspired protein engineering to enable its exploitation for biotechnologically relevant oxidations with structurally diverse substrates. However, a structural rationale is lacking to explain how these mutations have such effects in the absence of direct change to the active site architecture. Here, we provide the first crystal structures of BM3 mutants in complex with a human drug substrate, the proton pump inhibitor omeprazole. Supported by solution data, these structures reveal how mutation alters the conformational landscape and decreases the free energy barrier for transition to the substrate-bound state. Our data point to the importance of such "gatekeeper" mutations in enabling major changes in substrate recognition. We further demonstrate that these mutants catalyze the same 5-hydroxylation reaction as performed by human CYP2C19, the major human omeprazole-metabolizing P450 enzyme.
Assuntos
Bacillus megaterium/enzimologia , Proteínas de Bactérias/química , Sistema Enzimático do Citocromo P-450/química , NADPH-Ferri-Hemoproteína Redutase/química , Omeprazol/química , Inibidores da Bomba de Prótons/química , Hidrocarboneto de Aril Hidroxilases/química , Hidrocarboneto de Aril Hidroxilases/genética , Hidrocarboneto de Aril Hidroxilases/metabolismo , Bacillus megaterium/genética , Proteínas de Bactérias/genética , Proteínas de Bactérias/metabolismo , Cristalografia por Raios X , Citocromo P-450 CYP2C19 , Sistema Enzimático do Citocromo P-450/genética , Sistema Enzimático do Citocromo P-450/metabolismo , Humanos , Hidroxilação/genética , Mutação , NADPH-Ferri-Hemoproteína Redutase/genética , NADPH-Ferri-Hemoproteína Redutase/metabolismo , Omeprazol/farmacocinética , Oxirredução , Estrutura Terciária de Proteína , Inibidores da Bomba de Prótons/farmacocinética , Relação Estrutura-AtividadeRESUMO
We describe the medicinal chemistry programme that led to the identification of the EP(1) receptor antagonist GSK269984A (8h). GSK269984A was designed to overcome development issues encountered with previous EP(1) antagonists such as GW848687X and was found to display excellent activity in preclinical models of inflammatory pain. However, upon cross species pharmacokinetic profiling, GSK269984A was predicted to have suboptimal human pharmacokinetic and was thus progressed to a human microdose study.