Lu Gao

Discovery of imidazopyridine derivatives as highly potent respiratory syncytial virus fusion inhibitors.

A series of imidazolepyridine derivatives were designed and synthesized according to the established docking studies. The imidazopyridine derivatives were found to have good potency and physical-chemical properties. Several highly potent compounds such as 8ji, 8jl, and 8jm were identified with single nanomolar activities. The most potent compound 8jm showed an IC50 of 3 nM, lower microsome clearance and no CYP inhibition. The profile of 8jm appeared to be superior to BMS433771, and supported further optimization.

HBVcircle: A novel tool to investigate hepatitis B virus covalently closed circular DNA

BACKGROUND & AIMSnHepatitis B virus (HBV) covalently closed circular DNA (cccDNA) persists as a stable episome in infected hepatocytes and serves as a template for the transcription of all viral genes. Due to the narrow host range of HBV, the development of a robust mouse model that supports cccDNA-dependent viral replication is a key hurdle in the development of novel HBV therapeutics. This study aimed to develop a novel tool to investigate HBV cccDNA.nnnMETHODSnThrough minicircle technology, HBVcircle, a recombinant cccDNA, was easily generated and extracted from a genetically engineered E. coli strain. We characterized the performance of HBVcircle in cell culture by transfection and in immunocompetent mice by hydrodynamic injection (HDI).nnnRESULTSnWe demonstrated that HBVcircle formed authentic cccDNA-like molecules in vitro in transiently transfected hepatic cells and in vivo in mouse liver after HDI. HBVcircle supported high levels and persistent HBV replication. In addition, we investigated different factors affecting HBV in vivo replication and persistence, including the host genetic background, vector design and dosage, viral genes and genotypes, and immune activation status. Furthermore, different classes of anti-HBV drugs were also assessed with the HBVcircle system.nnnCONCLUSIONnCompared with previous reported HBV mouse models which employ other viral vectors to introduce overlength HBV genomes, viral gene expression and associated phenotypes are entirely driven by cccDNA-like viral genomes in the HBVcircle mouse model. Therefore, the HBVcircle is a close mimic of cccDNA, and it represents a novel tool for addressing HBV cccDNA related biological questions and for anti-HBV drug discovery.nnnLAY SUMMARYnTo establish a mouse model that supports cccDNA-dependent transcription, a novel tool named HBVcircle, was developed with minicircle technology. HBVcircle formed authentic cccDNA-like molecules in hepatocytes, and supported high levels and persistent HBV replication in vivo. The HBVcircle is a close mimic of cccDNA, and it represents a novel tool for addressing HBV cccDNA related biological questions and for anti-HBV drug discovery.

Discovery of Piperazinylquinoline Derivatives as Novel Respiratory Syncytial Virus Fusion Inhibitors.

A novel series of piperazinylquinoline derivatives were discovered as respiratory syncytial virus (RSV) fusion inhibitors by the ligand-based screening approach. Among 3,000 hits, 1-amino-3-[[2-(4-phenyl-1-piperidyl)-4-quinolyl]amino]propan-2-ol (7) was proven to be active against the RSV long (A) strain. The anti-RSV activity was improved by converting piperidine to benzylcarbonyl substituted piperazine. The basic side chain was also found to be crucial for anti-RSV activity. The selected analogues, 45 and 50, demonstrated anti-RSV activities up to EC50 = 0.028 μM and 0.033 μM, respectively. A direct anti-RSV effect was confirmed by a plaque reduction assay and a fusion inhibition assay. Both 45 and 50 showed promising DMPK properties with good oral bioavailability, and could potentially lead to novel therapeutic agents targeting the RSV fusion process.

Discovery and Pre-Clinical Characterization of Third-Generation 4-H Heteroaryldihydropyrimidine (HAP) Analogues as Hepatitis B Virus (HBV) Capsid Inhibitors

Described herein are the discovery and structure-activity relationship (SAR) studies of the third-generation 4-H heteroaryldihydropyrimidines (4-H HAPs) featuring the introduction of a C6 carboxyl group as novel HBV capsid inhibitors. This new series of 4-H HAPs showed improved anti-HBV activity and better drug-like properties compared to the first- and second-generation 4-H HAPs. X-ray crystallographic study of analogue 12 (HAP_R01) with Cp149 Y132A mutant hexamer clearly elucidated the role of C6 carboxyl group played for the increased binding affinity, which formed strong hydrogen bonding interactions with capsid protein and coordinated waters. The representative analogue 10 (HAP_R10) was extensively characterized in vitro (ADMET) and in vivo (mouse PK and PD) and subsequently selected for further development as oral anti-HBV infection agent.

Hepatitis B Virus Sensitivity to Interferon-α in Hepatocytes is More Associated with Cellular Interferon Response than with Viral Genotype

Interferon‐α (IFN‐α) is used to treat chronic hepatitis B virus (HBV) infection, but only 20%‐40% of patients respond well. Clinical observations have suggested that HBV genotype is associated with the response to IFN therapy; however, its role in viral responsiveness to IFN in HBV‐infected hepatocytes remains unclear. Here, we produced infectious virions of HBV genotypes A to D to infect three well‐recognized cell–culture–based HBV infection systems, including primary human hepatocytes (PHH), differentiated HepaRG (dHepaRG), and HepG2‐NTCP cells to quantitatively compare the antiviral effect of IFN‐α on HBV across genotypes and cell models. The efficacy of IFN‐α against HBV in hepatocytes was generally similar across genotypes A2, B5, C2, and D3; however, it was significantly different among the infection models given that the half maximal inhibitory concentration value of IFN‐α for inhibition of viral DNA replication in PHH (<20 U/mL) and dHepaRG cells were much lower than that in HepG2‐NTCP cells (>500 U/mL). Notably, even in PHH, IFN‐α did not reduce HBV covalently closed circular DNA at the concentrations for which viral antigens and DNA replication intermediates were strongly reduced. The three cell‐culture models exhibited differential cellular response to IFN‐α. The genes reported to be associated with responsiveness to IFN‐α in patients were robustly induced in PHH while weakly induced in HepG2‐NTCP cells upon IFN‐α treatment. Reduction or promotion of IFN response in PHH or HepG2‐NTCP cells significantly attenuated or improved the inhibitory capacity of IFN‐α on HBV replication, respectively. Conclusion: In the cell–culture–based HBV infection models, the sensitivity of HBV to IFN‐α in hepatocytes is determined more by the cell‐intrinsic IFN response than by viral genotype, and improvement of the IFN response in HepG2‐NTCP cells promotes the efficacy of IFN‐α against HBV. (Hepatology 2018;67:1237‐1252).

Discovery of Benzoazepinequinoline (BAQ) Derivatives as Novel, Potent, Orally Bioavailable Respiratory Syncytial Virus Fusion Inhibitors

A novel benzoazepinequnoline (BAQ) series was discovered as RSV fusion inhibitors. BAQ series originated from compound 2, a hit from similarity-based virtual screening. In SAR exploration, benzoazepine allowed modifications in the head moiety. Benzylic sulfonyl on benzoazepine and 6-Me on quinoline were crucial for good anti-RSV activity. Although the basic amine in the head portion was crucial for anti-RSV activity, the attenuated basicity was required to reduce Vss. Introducing oxetane to the head portion led to discovery of compound 1, which demonstrated single-digit nM anti-RSV activity against different RSV strains, reasonable oral exposure in plasma, and 78-fold higher exposure in lung. Compound 1 also displayed 1 log viral reduction in a female BALB/c mice RSV model by b.i.d. oral dosing at 12.5 mg/kg. A single resistant mutant at L138F in fusion protein proved compound 1 to be a RSV fusion inhibitor.

Discovery of Small Molecule Therapeutics for Treatment of Chronic HBV Infection

The chronic infection of hepatitis B virus (HBV) inflicts 250 million people worldwide representing a major public health threat. A significant subpopulation of patients eventually develop cirrhosis and hepatocellular carcinoma (HCC). Unfortunately, none of the current standard therapies for chronic hepatitis B (CHB) result in a satisfactory clinical cure rate. Driven by a highly unmet medical need, multiple pharmaceutical companies and research institutions have been engaged in drug discovery and development to improve the CHB functional cure rate, defined by sustainable viral suppression and HBsAg clearance after a finite treatment. This Review summarizes the recent advances in the discovery and development of novel anti-HBV small molecules. It is believed that an improved CHB functional cure rate may be accomplished via the combination of molecules with distinct MoAs. Thus, certain molecules may evolve into key components of a suitable combination therapy leading to superior outcome of clinical efficacy in the future.