Lanthanide ion-doped silica nanohelix: a helical inorganic network acts as a chiral source for metal ions.

We demonstrate that lanthanide ions doped in nanometrical silica helices with a chirally arranged siloxane network without any organic mediates show induced chiroptical properties such as circular dichroism and circularly polarized luminescence.

Chirality induction on non-chiral dye-linked polysilsesquioxane in nanohelical structures.

We demonstrate the direct induction of chirally arranged organic dye-linked polysilsesquioxane through a sol-gel transcription using a chiral supramolecular template. The chiral arrangement was confirmed by using electronic and vibrational circular dichroism and circularly polarized luminescence spectroscopies.

Structural modulation study of inhibitory compounds for ribonuclease H activity of human immunodeficiency virus type 1 reverse transcriptase.

Reverse transcriptase of human immunodeficiency virus type 1 (HIV-1) has two enzymatic functions. One of the functions is ribonuclease (RNase) H activity concerning the digestion of only RNA of RNA/DNA hybrid. The RNase H activity is an attractive target for a new class of anti-HIV drugs because no approved inhibitor is available now. In our previous studies, an agent bearing 5-nitro-furan-2-carboxylic acid ester core was found from chemical screening and dozens of the derivatives were synthesized to improve compound potency. In this work, some parts of the chemical structure were modulated to deepen our understanding of the structure-activity relationship of the analogous compounds. Several derivatives having nitro-furan-phenyl-ester skeleton were shown to be potent RNase H inhibitors. Attaching methoxy-carbonyl and methoxy groups to the phenyl ring increased the inhibitory potency. No significant cytotoxicity was observed for these active derivatives. In contrast, the derivatives having nitro-furan-benzyl-ester skeleton showed modest inhibitory activities regardless of attaching diverse kinds of functional groups to the benzyl ring. Both the modulation of the 5-nitro-furan-2-carboxylic moiety and the conversion of the ester linkage resulted in a drastic decrease in inhibitory potency. These findings are informative for designing potent inhibitors of RNase H enzymatic activity of HIV-1.

Mechanism of drug resistance of hemagglutinin of influenza virus and potent scaffolds inhibiting its function.

Highly pathogenic influenza viruses have become a global threat to humans. It is important to select an effective therapeutic option suitable for the subtypes in an epidemic or pandemic. To increase the options, the development of novel antiviral agents acting on targets different from those of the currently approved drugs is required. In this study, we performed molecular dynamics simulations on a spike protein on the viral envelop, hemagglutinin, for the wild-type and three kinds of mutants using a model system consisting of a trimeric hemagglutinin complex, viral lipid membrane, solvation waters, and ions. A natural product, stachyflin, which shows a high level of antiviral activity specific to some subtypes of influenza viruses, was examined on binding to the wild-type hemagglutinin by docking simulation. The compound potency of stachyflin is, however, easily lost due to resistant mutations. From a comparison of simulation results between the wild-type and the resistant mutants, the reason for the drug resistance of hemagglutinin was clarified. Next, 8 compounds were selected from a chemical database by in silico screening, considering the findings from the simulations. Inhibitory activities to suppress the proliferation of influenza virus were measured by cell-based antiviral assays, and two chemical scaffolds were found to be potent for an inhibitor. More than 30 derivatives bearing either of these two chemical scaffolds were synthesized, and cell culture assays were carried out to evaluate the compound potency. Several derivatives displayed a high compound potency, and 50% effective concentrations of two synthesized compounds were below 1 µM.

Structural and biochemical study on the inhibitory activity of derivatives of 5-nitro-furan-2-carboxylic acid for RNase H function of HIV-1 reverse transcriptase.

Rapid emergence of drug-resistant variants is one of the most serious problems in chemotherapy for HIV-1 infectious diseases. Inhibitors acting on a target not addressed by approved drugs are of great importance to suppress drug-resistant viruses. HIV-1 reverse transcriptase has two enzymatic functions, DNA polymerase and RNase H activities. The RNase H activity is an attractive target for a new class of antiviral drugs. On the basis of the hit chemicals found in our previous screening with 20,000 small molecular-weight compounds, we synthesized derivatives of 5-nitro-furan-2-carboxylic acid. Inhibition of RNase H enzymatic activity was measured in a biochemical assay with real-time monitoring of florescence emission from the digested RNA substrate. Several derivatives showed higher inhibitory activities that those of the hit chemicals. Modulation of the 5-nitro-furan-2-carboxylic moiety resulted in a drastic decrease in inhibitory potency. In contrast, many derivatives with modulation of other parts retained inhibitory activities to varying degrees. These findings suggest the binding mode of active derivatives, in which three oxygen atoms aligned in a straight form at the nitro-furan moiety are coordinated to two divalent metal ions located at RNase H reaction site. Hence, the nitro-furan-carboxylic moiety is one of the critical scaffolds for RNase H inhibition. Of note, the RNase H inhibitory potency of a derivative was improved by 18-fold compared with that of the original hit compound, and no significant cytotoxicity was observed for most of the derivatives showing inhibitory activity. Since there is still much room for modification of the compounds at the part opposite the nitro-furan moiety, further chemical conversion will lead to improvement of compound potency and specificity.