Efficient Inhibition of Hepatitis B Virus (HBV) Replication and cccDNA Formation by HBV Ribonuclease H Inhibitors during Infection.

The hepatitis B virus (HBV) ribonuclease H (RNase H) is an attractive but unexploited drug target. Here, we addressed three limitations to the current state of RNase H inhibitor development: (a) Efficacy has been assessed only in transfected cell lines. (b) Cytotoxicity data are from transformed cell lines rather than primary cells. (c) It is unknown how the compounds work against nucleos(t)ide analog resistant HBV strains. Three RNase H inhibitors from different chemotypes, 110 (α-hydroxytropolone), 1133 (N-hydroxypyridinedione), and 1073 (N-hydroxynapthyridinone), were tested in HBV-infected HepG2-NTCP cells for inhibition of cccDNA accumulation and HBV product formation. 50% effective concentrations (EC50s) were 0.049-0.078 µM in the infection studies compared to 0.29-1.6 µM in transfected cells. All compounds suppressed cccDNA formation by >98% at 5 µM when added shortly after infection. HBV RNA, intracellular and extracellular DNA, and HBsAg secretion were all robustly suppressed. The greater efficacy of the inhibitors when added shortly after infection is presumably due to blocking amplification of the HBV cccDNA, which suppresses events downstream of cccDNA formation. The compounds had 50% cytotoxic concentrations (CC50s) of 16-100 µM in HepG2-derived cell lines but were nontoxic in primary human hepatocytes, possibly due to the quiescent state of the hepatocytes. The compounds had similar EC50s against replication of wild-type, lamivudine-resistant, and adefovir/lamivudine-resistant HBV, as expected because the RNase H inhibitors do not target the viral reverse transcriptase active site. These studies expand confidence in inhibiting the HBV RNase H as a drug strategy and support inclusion of RNase H inhibitors in novel curative drug combinations for HBV.

Design, synthesis, and biological evaluation of novel double-winged galloyl derivatives as HIV-1 RNase H inhibitors.

Human immunodeficiency virus (HIV) reverse transcriptase (RT)-associated ribonuclease H (RNase H) remains as the only enzyme encoded within the viral genome not clinically validated as an antiviral target. We have previously reported that the galloyl derivative II-25 had RNase H inhibitory activity in enzymatic assays but showed weak antiviral activity in phenotypic assays due its large polarity and poor membrane permeability. In this report, we report on a series of II-25 derivatives, obtained by addition of different hydrophobic moieties ("the wings") at the C-2 and C-3 positions of the piperazine ring that showed improved RNase H inhibitory activity. Six compounds showed strong inhibitory activity and were found to be more potent than ß-thujaplicinol in enzymatic assays. The most potent compound was IA-6 and exhibited the best inhibitory activity (IC50 = 0.067 ± 0.02 µM). IA-6 was around 11 and 30 times more potent than II-25 and ß-thujaplicinol, respectively. Molecular modeling studies predict a strong hydrophobic interaction between the furylmethylaminyl group of IA-6 and the side chain of His539, explaining the potent HIV-1 RNase H inhibition. Unfortunately, none of the derivatives showed significant antiviral activity in cell culture. It is worth emphasizing that most of the obtained compounds show low cytotoxicity (CC50 > 20 µM), which confirms the significance of identifying galloyl derivatives as valuable leads for further optimization.

Novel RNase H Inhibitors Blocking RNA-directed Strand Displacement DNA Synthesis by HIV-1 Reverse Transcriptase.

In retroviruses, strand displacement DNA-dependent DNA polymerization catalyzed by the viral reverse transcriptase (RT) is required to synthesize double-stranded proviral DNA. In addition, strand displacement during RNA-dependent DNA synthesis is critical to generate high-quality cDNA for use in molecular biology and biotechnology. In this work, we show that the loss of RNase H activity due to inactivating mutations in HIV-1 RT (e.g. D443N or E478Q) has no significant effect on strand displacement while copying DNA templates, but has a large impact on DNA polymerization in reactions carried out with RNA templates. Similar effects were observed with ß-thujaplicinol and other RNase H active site inhibitors, including compounds with dual activity (i.e., characterized also as inhibitors of HIV-1 integrase and/or the RT DNA polymerase). Among them, dual inhibitors of HIV-1 RT DNA polymerase/RNase H activities, containing a 7-hydroxy-6-nitro-2H-chromen-2-one pharmacophore were found to be very potent and effective strand displacement inhibitors in RNA-dependent DNA polymerization reactions. These findings might be helpful in the development of transcriptomics technologies to obtain more uniform read coverages when copying long RNAs and for the construction of more representative libraries avoiding biases towards 5' and 3' ends, while providing valuable information for the development of novel antiretroviral agents.

Small-molecule Inhibitors of HIV-1 Reverse Transcriptase-Associated Ribonuclease H Function: Challenges and Recent Developments.

Multiple combinations of antiretroviral drugs have remarkably improved the treatment of HIV-1 infection. However, life-long treatments and drug resistance are still an open issue that requires continuous efforts for the identification of novel antiviral drugs. BACKGROUND: The reverse transcriptase-associated ribonuclease H (RNase H) hydrolyzes the HIV genome to allow synthesizing viral DNA. Currently, no RNase H inhibitors (RHIs) have reached the clinical phase. Therefore, RNase H can be defined as an attractive target for drug design. OBJECTIVE: Despite the wealth of information available for RNase H domain, the development of RHIs with high specificity and low cellular toxicity has been disappointing. However, it is now becoming increasingly evident that reverse transcriptase is a highly versatile enzyme, undergoing major structural alterations to complete its catalysis, and that exists a close spatial and temporal interplay between reverse transcriptase polymerase and RNase H domains. This review sums up the present challenges in targeting RNase H encompassing the challenges in selectively inhibiting RNase H vs polymerase and/or HIV-1 integrase and the weak antiviral activity of active site inhibitors, probably for a substrate barrier that impedes small molecules to reach the targeted site. Moreover, the focus is given on the most recent progress in the field of medicinal chemistry that has led to the identification of several small molecules as RHIs in the last few years. CONCLUSION: RHIs could be a new class of drugs with a novel mechanism of action highly precious for the treatment of resistant HIV strains.

Design, synthesis, and biologic evaluation of novel galloyl derivatives as HIV-1 RNase H inhibitors.

Human immunodeficiency virus (HIV) reverse transcriptase (RT)-associated ribonuclease H (RNase H) remains as the only enzyme encoded within the viral genome not targeted by current antiviral drugs. In this work, we report the design, synthesis, and biologic evaluation of a novel series of galloyl derivatives with HIV-1 RNase H inhibitory activity. Most of them showed IC50 s at sub- to low-micromolar concentrations in enzymatic assays. The most potent compound was II-25 that showed an IC50 of 0.72 ± 0.07 µM in RNase H inhibition assays carried out with the HIV-1BH10 RT. II-25 was 2.8 times more potent than ß-thujaplicinol in these assays. Interestingly, II-25 and other galloyl derivatives were also found to inhibit the HIV IN strand transfer activity in vitro. Structure-activity relationships (SAR) studies and molecular modeling analysis predict key interactions with RT residues His539 and Arg557, while providing helpful insight for further optimization of selected compounds.

Update on Recent Developments in Small Molecular HIV-1 RNase H Inhibitors (2013-2016): Opportunities and Challenges.

Combinations of antiretroviral drugs are successfully used to treat HIV-infected patients. However, drug resistance is a major problem that makes discovery of new antiretroviral drugs an ongoing priority. The ribonuclease H (RNase H) activity of the HIV-1 reverse transcriptase catalyzes the selective hydrolysis of the RNA strand of RNA:DNA heteroduplex replication intermediates, and represents an attractive unexploited target for drug development. This review reports on recent progress in the characterization of HIV-1 RNase H inhibitors from 2013 to 2016, describing their chemical structures, structureactivity relationship and binding modes. Focus is given to emerging medicinal chemistry principles and insights into the discovery and development of RNase H inhibitors.

Antiretroviral activity of metal-chelating HIV-1 integrase inhibitors.

Data regarding the activity of metal complexes against HIV virus in cell are surprisingly scarce. In this study, we present the antiviral activity against HIV-infected cells of different types of chelating ligands and of their metal complexes. In particular, the carboxamide chelating scaffold and the corresponding coordination compounds demonstrated an interesting antiviral profile in the nanomolar range. These molecules inhibit not only HIV integrase catalytic activity, but they also interfere with the function of the RNase H component of the HIV reverse transcriptase. Here we also discuss the thermodynamic characterization in solution of the metal complexes of the most active ligands, affording to the best of our knowledge for the first time this type of data for complexes with anti-HIV activity.

Structure of a dihydroxycoumarin active-site inhibitor in complex with the RNase H domain of HIV-1 reverse transcriptase and structure-activity analysis of inhibitor analogs.

Human immunodeficiency virus (HIV) encodes four essential enzymes: protease, integrase, reverse transcriptase (RT)-associated DNA polymerase, and RT-associated ribonuclease H (RNase H). Current clinically approved anti-AIDS drugs target all HIV enzymatic activities except RNase H, which has proven to be a very difficult target for HIV drug discovery. Our high-throughput screening activities identified the dihydroxycoumarin compound F3284-8495 as a specific inhibitor of RT RNase H, with low micromolar potency in vitro. Optimization of inhibitory potency can be facilitated by structural information about inhibitor-target binding. Here, we report the crystal structure of F3284-8495 bound to the active site of an isolated RNase H domain of HIV-1 RT at a resolution limit of 1.71Å. From predictions based on this structure, compounds were obtained that showed improved inhibitory activity. Computational analysis suggested structural alterations that could provide additional interactions with RT and thus improve inhibitory potency. These studies established proof of concept that F3284-8495 could be used as a favorable chemical scaffold for development of HIV RNase H inhibitors.