Exploration of α/β/γ-peptidomimetics design for BH3 helical domain.

Systematic incorportation of ring-constrained β- and γ-amino acid residues to α-helix mimetics engenders stable helical secondary structures. In this paper, functional α/β/γ-helical peptidomimetics were explored for the mimicry of BH3...

Chemical classification of MDM2 inhibitors

MDM2 inhibitors class of anti-neoplastic drugs has been evolve after the successful discovery of the nutlins and other potent inhibitors. MDM2 inhibitors can specifically target the tumour cells in the body, by selectively reactivating the inhibited p53 function in the tumour cells.None of the compound of this class has been entered into the market till date, all are under clinical trials. Hence, various researcher classifies them according to their p53 topology mimetic property and as per their peptide type or non-peptide type.Synthetic peptide type of inhibitors can mimic the conformation of p53 helix. Whereas, small organic molecule (non-peptide) type of MDM2 inhibitors have been further subdivided as Non α-helix mimetics (small molecule inhibitors) and α-helix mimetics. In a line with synthetic inhibitors, many potent MDM2 inhibitors are derived from the natural origin (marine, fungus). Therefore, keeping in a view of all these characteristics, here we have classified them as per best of our knowledge.

In Silico Exploration of Small-Molecule α-Helix Mimetics as Inhibitors of SARS-COV-2 Attachment to ACE2

The novel coronavirus, SARS-CoV-2, has infected more than 10 million people and caused more than 502,539 deaths worldwide as of June 2020. The explosive spread of the virus and the rapid increase in the number of cases require the immediate development of effective therapies and vaccines as well as accurate diagnosis tools. The pathogenesis of the disease is triggered by the entry of SARS-CoV-2 via its spike protein into ACE2-bearing host cells, particularly pneumocytes, resulting in overactivation of the immune system, which attacks the infected cells and damages the lung tissue. The interaction of the SARS-CoV-2 receptor binding domain (RBD) with host cells is primarily mediated by the N-terminal helix of the ACE2; thus, inhibition of the spike-ACE2 interaction may be a promising therapeutic strategy for blocking the entry of the virus into host cells. In this paper, we used an in-silico approach to explore small-molecule α-helix mimetics as inhibitors that may disrupt the attachment of SARS-CoV-2 to ACE2. First, the RBD-ACE2 interface in the 6M0J structure was studied by the MM-GBSA decomposition module of the HawkDock server, which led to the identification of two critical target regions in the RBD. Next, two virtual screening experiments of 7236 α-helix mimetics from ASINEX were conducted on the above regions using the iDock tool, which resulted in 10 candidates with favorable binding affinities. Finally, the stability of RBD complexes with the top-two ranked compounds was further validated by 40 ns MD simulations using Desmond package of Schrodinger.<br>

In Silico Exploration of Small-Molecule α-Helix Mimetics as Inhibitors of SARS-COV-2 Attachment to ACE2

The novel coronavirus, SARS-CoV-2, has infected more than 10 million people and caused more than 502,539 deaths worldwide as of June 2020. The explosive spread of the virus and the rapid increase in the number of cases require the immediate development of effective therapies and vaccines as well as accurate diagnosis tools. The pathogenesis of the disease is triggered by the entry of SARS-CoV-2 via its spike protein into ACE2-bearing host cells, particularly pneumocytes, resulting in overactivation of the immune system, which attacks the infected cells and damages the lung tissue. The interaction of the SARS-CoV-2 receptor binding domain (RBD) with host cells is primarily mediated by the N-terminal helix of the ACE2; thus, inhibition of the spike-ACE2 interaction may be a promising therapeutic strategy for blocking the entry of the virus into host cells. In this paper, we used an in-silico approach to explore small-molecule α-helix mimetics as inhibitors that may disrupt the attachment of SARS-CoV-2 to ACE2. First, the RBD-ACE2 interface in the 6M0J structure was studied by the MM-GBSA decomposition module of the HawkDock server, which led to the identification of two critical target regions in the RBD. Next, two virtual screening experiments of 7236 α-helix mimetics from ASINEX were conducted on the above regions using the iDock tool, which resulted in 10 candidates with favorable binding affinities. Finally, the stability of RBD complexes with the top-two ranked compounds was further validated by 40 ns MD simulations using Desmond package of Schrodinger.<br>

Cell Surface-Expressed GPI-Anchored Peptides from the CHR Domain of gp41 Are Potent Inhibitors of HIV-1 Fusion

Current antiretroviral therapy efficiently suppresses viral replication but cannot eliminate latent HIV reservoirs. Moreover, the associated high costs, side effects, and drug resistance have stimulated a need for the development of alternative methods of HIV-1/AIDS treatment, such as peptide inhibitors or gene editing. Recently, we have developed Surface Oligopeptide knock-in for Rapid Target Selection (SORTS), a method for the rapid selection of CRISPR/Cas9 gene-edited cells via knock-in of the Flag and HA epitope tags embedded into the shortest GPI-protein, CD52. By targeting the capsid region of the HIV-1 genome, we demonstrate that SORTS can be applied in provirus eradication. However, the cells with inactivated provirus will be susceptible to HIV re-infection. We hypothesized that knocking in one of the peptides from the CHR-domain of gp41, which are known potent inhibitors of HIV-1 fusion, instead of the epitope tag, will provide “post-curable” HIV-1 resistance. While these peptides were extensively studied as soluble substances, their inhibitory effects on HIV after expression on cell surfaces via GPI-anchor are largely unknown. In this study, we established HEK293T/CD4/R5 and Raji/CD4/R5 HIV-1 permissive cell lines that stably expressed one of the gp41 peptides C34, MT-C34, MT-C34-R, and MT34-15D, or alfa-helix mimetics HP23L, p52, and MT-WQ-IDL. For cell surface delivery, the indicated peptides were embedded into the CD52 molecule, and upstream GFP was used to select transformed cells. Using a single-cycle replication assay with the inLuc reporter vector and different Envs, we demonstrated that C34-based GPI-anchored peptides inhibited both cell-free and cell-to-cell HIV-1 infection by at least two orders of magnitude. With the exception of HP23L, the alfa-helix mimetics were less potent inhibitors. Thus, peptides from gp41 associated with lipid rafts and exerted a strong inhibitory activity which can far exceed that determined for soluble peptides, but this should be tested further.

Synthesis of a Bcl9 Alpha-Helix Mimetic for Inhibition of PPIs by a Combination of Electrooxidative Phenol Coupling and Pd-Catalyzed Cross Coupling

Teraryl-based alpha-helix mimetics have resulted in efficient inhibitors of protein-protein interactions (PPIs). Extending the concept to even longer oligoarene systems would allow for the mimicking of even larger interaction sites. We present a highly efficient synthetic modular access to quateraryl alpha-helix mimetics, in which, at first, two phenols undergo electrooxidative dehydrogenative cross-coupling. The resulting 4,4′-biphenol is then activated by conversion to nonaflates, which serve as leaving groups for iterative Pd-catalyzed Suzuki-cross-coupling reactions with suitably substituted pyridine boronic acids. This work, for the first time, demonstrates the synthetic efficiency of using both electroorganic as well as transition-metal catalyzed cross-coupling in the assembly of oligoarene structures.