Comparative analysis of the unbinding pathways of antiviral drug Indinavir from HIV and HTLV1 proteases by Supervised Molecular Dynamics simulation

Determining the unbinding pathways of potential small molecule compounds from their target proteins is of great significance for designing efficacious treatment solutions. One of these potential compounds is the approved HIV-1 protease inhibitor, indinavir, which has a weak effect on the HTLV-1 protease. In this work, by employing SuMD method, we reconstructed the unbinding pathways of indinavir from HIV and HTLV-1 proteases in order to compare and to understand the mechanism of the unbinding, and also to discover the reasons for the lack of inhibitory activity of indinavir against the HTLV-1 protease. We achieved multiple unbinding events from both HIV and HTLV-1 proteases in which the RMSD values of indinavir reached over 4 nm. Also, we found that the mobility and the fluctuations of the flap region is higher in the HTLV-1 protease which makes the drug less stable. We realized that critically positioned aromatic residues such as Trp98/Trp98' and Phe67/Phe67' in the HTLV-1 protease can make strong pi-Stacking interactions with indinavir in the unbinding pathway which are unfavorable for the stability of indinavir in the active site. The details found in this study can make a good explanation for the lack of inhibitory activity of this drug against HTLV-1 protease. We believe the details discovered in this work can be a great assist for designing more effective and more selective inhibitors for the HTLV-1 protease.

Arginine Methylation Regulates Ribosome CAR Function

The ribosome CAR interaction surface is hypothesized to provide a layer of translation regulation through hydrogen-bonding to the +1 mRNA codon that is next to enter the ribosome A site during translocation. The CAR surface consists of three residues, 16S/18S rRNA C1054, A1196 (E. coli 16S numbering), and R146 of yeast ribosomal protein Rps3. R146 can be methylated by the Sfm1 methyltransferase which is downregulated in stressed cells. Through molecular dynamics analysis, we show here that methylation of R146 compromises the integrity of CAR by reducing the cation-pi stacking of the R146 guanidinium group with A1196, leading to reduced CAR hydrogen-bonding with the +1 codon. We propose that ribosomes assembled under stressed conditions have unmethylated R146, resulting in elevated CAR/+1 codon interactions, which tunes translation levels in response to the altered cellular context.

Targeted disruption of pi–pi stacking in Malaysian banana lectin reduces mitogenicity while preserving antiviral activity

Lectins, carbohydrate-binding proteins, have been regarded as potential antiviral agents, as some can bind glycans on viral surface glycoproteins and inactivate their functions. However, clinical development of lectins has been stalled by the mitogenicity of many of these proteins, which is the ability to stimulate deleterious proliferation, especially of immune cells. We previously demonstrated that the mitogenic and antiviral activities of a lectin (banana lectin, BanLec) can be separated via a single amino acid mutation, histidine to threonine at position 84 (H84T), within the third Greek key. The resulting lectin, H84T BanLec, is virtually non-mitogenic but retains antiviral activity. Decreased mitogenicity was associated with disruption of pi–pi stacking between two aromatic amino acids. To examine whether we could provide further proof-of-principle of the ability to separate these two distinct lectin functions, we identified another lectin, Malaysian banana lectin (Malay BanLec), with similar structural features as BanLec, including pi–pi stacking, but with only 63% amino acid identity, and showed that it is both mitogenic and potently antiviral. We then engineered an F84T mutation expected to disrupt pi–pi stacking, analogous to H84T. As predicted, F84T Malay BanLec (F84T) was less mitogenic than wild type. However, F84T maintained strong antiviral activity and inhibited replication of HIV, Ebola, and other viruses. The F84T mutation disrupted pi–pi stacking without disrupting the overall lectin structure. These findings show that pi–pi stacking in the third Greek key is a conserved mitogenic motif in these two jacalin-related lectins BanLec and Malay BanLec, and further highlight the potential to rationally engineer antiviral lectins for therapeutic purposes.

Arginine Methylation Regulates Ribosome CAR Function

The ribosome CAR interaction surface is hypothesized to provide a layer of translation regulation through hydrogen-bonding to the +1 mRNA codon that is next to enter the ribosome A site during translocation. The CAR surface consists of three residues, 16S/18S rRNA C1054, A1196 (E. coli 16S numbering), and R146 of yeast ribosomal protein Rps3. R146 can be methylated by the Sfm1 methyltransferase which is downregulated in stressed cells. Through molecular dynamics analysis, we show here that methylation of R146 compromises the integrity of CAR by reducing the pi stacking of the R146 guanidinium group with A1196, leading to reduced CAR hydrogen-bonding with the +1 codon. We propose that ribosomes assembled under stressed conditions have unmethylated R146, resulting in elevated CAR/+1 codon interactions, which tunes translation levels in response to the altered cellular context.

Strong Electronic Coupling of Graphene Nanoribbons onto Basal Plane of Glassy Carbon Electrode

The electrochemical behavior of graphene nanoribbons deposited onto glassy carbon electrode using pi-stacking interactions was investigated. We illustrate here that strong electronic communication could be achieved with basal plane of glassy carbon using simple electrochemical treatment.

Strong Electronic Coupling of Graphene Nanoribbons onto Basal Plane of Glassy Carbon Electrode

The electrochemical behavior of graphene nanoribbons deposited onto glassy carbon electrode using pi-stacking interactions was investigated. We illustrate here that strong electronic communication could be achieved with basal plane of glassy carbon using simple electrochemical treatment.

Pi-stacking interaction perphenazine modified zinc(II) phthalocyanine nanoparticles for photothermal and photodynamic therapy

Photodynamic therapy and photothermal therapy as non-invasive treatment methods have been receiving more and more attention. The report shows that zinc(II) phthalocyanine (Pc2) modified by perphenazine forms nanoparticles with a particle size of 110 nm by [Formula: see text]–[Formula: see text] stacking in water. It has good photothermal effect when illuminated by 680 nm laser in aqueous solution. In addition, its ability to produce active oxygen is 2.3-fold that of methylene blue, so Pc2 also has a good photodynamic effect. In vivo fluorescence shows that Pc2 has a good targeting effect on tumors. Under the synergistic effect of photodynamic therapy and photothermal therapy, Pc2 has good tumor inhibition efficiency.