Identification of "dual-site"-binding diarylpyrimidines targeting both NNIBP and the NNRTI adjacent site of the HIV-1 reverse transcriptase.

Here, we reported a novel series of "dual-site" binding diarylpyrimidine (DAPY) derivatives targeting both the NNRTI adjacent site and NNRTIs binding pocket (NNIBP). The anti-HIV-1 activity results demonstrated that compound 9e (EC50 = 2.04-61.1 nM) displayed robust potencies against a panel of HIV-1 NNRTIs-resistant strains, being comparable to that of etravirine (ETR). Moreover, 9e displayed much lower cytotoxicity (CC50 = 59.2 µM) and higher SI values (4605) toward wild-type HIV-1 strain. The HIV-1 RT enzyme inhibitory activity clarified the binding target of 9e was HIV-1 RT (IC50 = 0.019 µM). Furthermore, the molecular modeling study was also investigated to give a reasonable explanation of the preliminary SARs. Further test indicated that 9e possessed significantly improved water solubility under pH 7.0 and 7.4 conditions. Additionally, the in silico prediction of physicochemical properties and CYP enzymatic inhibitory ability were investigated to evaluate their drug-like features. Consequently, compound 9e showed the highest activity and low cytotoxicity, which could be used as a lead for further modification to obtain potent HIV-1 NNRTIs.

Design, synthesis, and evaluation of "dual-site"-binding diarylpyrimidines targeting both NNIBP and the NNRTI adjacent site of the HIV-1 reverse transcriptase.

Inspired by our previous efforts to improve the drug-resistance profiles of HIV-1 non-nucleoside reverse transcriptase inhibitors (NNRTIs), a novel series of "dual-site" binding diarylpyrimidine (DAPY) derivatives targeting both the NNRTI adjacent site and NNRTIs binding pocket (NNIBP) were designed, synthesized, and evaluated for their anti-HIV potency in TZM-bl and MT-4 cells. Eight compounds exhibited moderate to excellent potencies in inhibiting wild-type (WT) HIV-1 replication with EC50 values ranging from 2.45 nM to 5.36 nM, and 14c (EC50 = 2.45 nM) proved to be the most promising inhibitor. Of note, 14c exhibited potent activity against the single mutant strain E138K (EC50 = 10.6 nM), being comparable with ETR (EC50 = 9.80 nM) and 3.5-fold more potent than that of compound 7 (EC50 = 37.3 nM). Moreover, 14c acted as a classical NNRTI with high affinity for WT HIV-1 RT (IC50 = 0.0589 µM). The detailed structure-activity relationships (SARs) of the representative compounds were also determined, and further supported by molecular dynamics simulation. Overall, we envision that the "dual-site"-binding NNRTIs have significant prospects and pave the way for the next round of rational design of potent anti-HIV-1 agents.

Contemporary medicinal-chemistry strategies for discovery of blood coagulation factor Xa inhibitors.

Introduction: Thrombosis is a common causal pathology for stroke, acute coronary syndrome and venous thromboembolism disorders, which are the leading cause of death worldwide. Anticoagulants have exhibited a crucial role in the prevention and treatment of thrombotic diseases. Factor Xa (FXa) is a serine protease with a central role in activating the complex blood coagulation cascade, and it is therefore regarded as an attractive target for antithrombotic agents. Areas covered: The authors review the current status of medicinal chemistry strategies for the discovery of novel FXa inhibitors and provide their expert perspectives on their future development. Expert opinion: Even if only a number of small-molecule FXa inhibitors have been reported to date, all currently available FXa inhibitors are associated with significant risk of bleeding, which may become life-threatening. There is, therefore, an urgent and unmet demand for potent novel FXa inhibitors that are potent treatments for thrombotic disorders, but which have a reduced risk of bleeding if their use is to be increasingly favored.

Discovery of potent HIV-1 non-nucleoside reverse transcriptase inhibitors by exploring the structure-activity relationship of solvent-exposed regions I.

Two novel series of human immunodeficiency virus-1 (HIV-1) non-nucleoside reverse transcriptase inhibitors (NNRTIs) bearing a thiophene[3,2-d]pyrimidine scaffold and sulfonamide linker in the right wing have been identified, which demonstrated activity against the wild-type (WT) HIV-1 strain in MT-4 cells with inhibitory concentrations ranging from micromolar to submicromolar. Especially, against the mutant strains K103N and E138K, most compounds exhibited more potent activity than against WT HIV-1. Compound 7 (EC50  = 0.014, 0.031 µM) achieved the most potent activity against the two mutants, being more effective than that of nevirapine (NVP, EC50  = 7.572, 0.190 µM) and comparable to that of etravirine (ETV, EC50  = 0.004, 0.014 µM). Molecular docking experiments on the novel analogs have also suggested that the extensive network of main chain hydrogen bonds are important in the binding mode, which may provide valuable insights for further optimization.

Design, synthesis, and antiviral evaluation of novel hydrazone-substituted thiophene[3,2-d]pyrimidine derivatives as potent human immunodeficiency virus-1 inhibitors.

In the previous studies of our laboratory, the thiophene[3,2-d]pyrimidine was identified as a promising scaffold for seeking highly potent HIV-1 non-nucleoside reverse transcriptase inhibitors (NNRTIs). In this study, we designed, synthesized, and biologically evaluated a series of thiophene[3,2-d]pyrimidine derivatives with changed linker between the thiophenepyrimidine core and the right wing. Some of the synthesized compounds exhibited excellent HIV-1 inhibitory potency with low (double-digit) nanomolar 50% effective concentration (EC50 ) values. Among them, compound 13a exhibited the most potent anti-HIV-1 activity (EC50  = 21.2 nM), which was 10-fold greater than that of NVP (EC50  = 281 nM). Moreover, 13a showed much lower cytotoxicity (CC50  = 183 µM) and higher selection index (SI = 8,632) than NVP, ETV, and AZT. Besides, some physicochemical properties and water solubility were calculated or measured. The preliminary structure-activity relationships and molecular simulation studies of these compounds were also discussed comprehensively to provide valuable direction for further design and optimization.

Discovery of Novel Diarylpyrimidine Derivatives as Potent HIV-1 NNRTIs Targeting the "NNRTI Adjacent" Binding Site.

A novel series of diarylpyrimidine derivatives, which could simultaneously occupy the classical NNRTIs binding pocket (NNIBP) and the newly reported "NNRTI Adjacent" binding site, were designed, synthesized, and evaluated for their antiviral activities in MT-4 cell cultures. The results demonstrated that six compounds (20, 27 and 31-34) showed excellent activities against wild-type (WT) HIV-1 strain (EC50 = 2.4-3.8 nM), which were more potent than that of ETV (EC50 = 4.0 nM). Furthermore, 20, 27, 33, and 34 showed more potent or equipotent activity against single mutant HIV-1 strains compared to that of ETV. Especially, 20 showed marked antiviral activity, which was 1.5-fold greater against WT and 1.5- to 3-fold greater against L100I, K103N, Y181C, Y188L, and E138K when compared with ETV. In addition, all compounds showed lower toxicity (CC50 = 5.1-149.2 µM) than ETV (CC50 = 2.2 µM). The HIV-1 RT inhibitory assay was further conducted to confirm their binding target. Preliminary structure-activity relationships (SARs), molecular modeling, and calculated physicochemical properties of selected compounds were also discussed comprehensively.

Further Exploring Solvent-Exposed Tolerant Regions of Allosteric Binding Pocket for Novel HIV-1 NNRTIs Discovery.

Based on the detailed analysis of the binding mode of diarylpyrimidines (DAPYs) with HIV-1 RT, we designed several subseries of novel NNRTIs, with the aim to probe biologically relevant chemical space of solvent-exposed tolerant regions in NNRTIs binding pocket (NNIBP). The most potent compound 21a exhibited significant activity against the whole viral panel, being about 1.5-2.6-fold (WT, EC50 = 2.44 nM; L100I, EC50 = 4.24 nM; Y181C, EC50 = 4.80 nM; F227L + V106A, EC50 = 17.8 nM) and 4-5-fold (K103N, EC50 = 1.03 nM; Y188L, EC50 = 7.16 nM; E138K, EC50 = 3.95 nM) more potent than the reference drug ETV. Furthermore, molecular simulation was conducted to understand the binding mode of interactions of these novel NNRTIs and to provide insights for the next optimization studies.

Current insights into anti-HIV drug discovery and development: a review of recent patent literature (2014-2017).

INTRODUCTION: To deal with the rapid emergence of drug resistance challenges, together with the difficulty to eradicate the virus, off-target effects and significant cumulative drug toxicities, it is still imperative to develop next-generation anti-HIV agents with novel chemical classes or new mechanisms of action. AREAS COVERED: We primarily focused on current strategies to discover novel anti-HIV agents. Moreover, examples of anti-HIV lead compounds were mainly selected from recently patented publications (reported between 2014 and 2017). In particular, 'privileged structure'-focused substituents decorating approach, scaffold hopping, natural-product diversification and prodrug are focused on. Furthermore, exploitation of new compounds with unexplored mechanisms of action and medicinal chemistry strategies to deplete the HIV reservoir were also described. Perspectives that could inspire future anti-HIV drug discovery are delineated. EXPERT OPINION: Even if a large number of patents have been disclosed recently, additional HIV inhibitors are still required, especially novel chemical skeletons displaying a unexploited mechanism of action. Current medicinal chemistry strategies are inadequate, and appropriate and new methodologies and technologies should be exploited to identify novel anti-HIV drug candidates in a time- and cost- effective manner.