Natural flavonoid pectolinarin computationally targeted as a promising drug candidate against SARS-CoV-2.

Coronavirus disease-2019 (COVID-19) has become a global pandemic, necessitating the development of new medicines. In this investigation, we identified potential natural flavonoids and compared their inhibitory activity against spike glycoprotein, which is a target of SARS-CoV-2 and SARS-CoV. The target site for the interaction of new inhibitors for the treatment of SARS-CoV-2 has 82% sequence identity and the remaining 18% dissimilarities in RBD S1-subunit, S2-subunit, and 2.5% others. Molecular docking was employed to analyse the various binding processes used by each ligand in a library of 85 natural flavonoids that act as anti-viral medications and FDA authorised treatments for COVID-19. In the binding pocket of the target active site, remdesivir has less binding interaction than pectolinarin, according to the docking analysis. Pectolinarin is a natural flavonoid isolated from Cirsiumsetidensas that has anti-cancer, vasorelaxant, anti-inflammatory, hepatoprotective, anti-diabetic, anti-microbial, and anti-oxidant properties. The S-glycoprotein RBD region (330-583) is inhibited by kaempferol, rhoifolin, and herbacetin, but the S2 subunit (686-1270) is inhibited by pectolinarin, morin, and remdesivir. MD simulation analysis of S-glycoprotein of SARS-CoV-2 with pectolinarin complex at 100ns based on high dock-score. Finally, ADMET analysis was used to validate the proposed compounds with the highest binding energy.

Cashew nut shell oil as a potential feedstock for biodiesel production: An overview.

Biodiesel outperforms diesel in emissions and engine performance. They burn efficiently in diesel engines and are eco-friendly. Since cashew nut shell liquid (CNSO) is waste, commercial biodiesel production from it should be profitable. CNSO is cheap and can reduce cashew processing factory waste. From cashew kernels, CNSL is extracted using various mechanical, thermal, and solvent extraction techniques. This article examines current research into using cashew nutshell liquid biodiesel (CNSLBD) in diesel engines. The work also discusses Indian biodiesel demand, availability, export information, life cycle cost analysis, cost economics of per hectare yield, Indian government initiative of CNSO. This review also evaluates the viability of this fuel as an alternative energy source. CNSLBD is a prospective alternative fuel that has the potential to benefit both the cashew nut industry and the energy industry. In addition to this, the study examines the procedures for extracting CNSO. According to the findings of the study, CNSO is a prospective alternative fuel that has the potential to benefit both the cashew nut industry and the energy industry.

Moonlighting proteins: beacon of hope in era of drug resistance in bacteria.

Moonlighting proteins (MLPs) are ubiquitous and provide a unique advantage to bacteria performing multiple functions using the same genomic content. Targeting MLPs can be considered as a futuristic approach in fighting drug resistance problem. This review follows the MLP trail from its inception to the present-day state, describing a few bacterial MLPs, viz., glyceraldehyde 3'-phosphate dehydrogenase, phosphoglucose isomerase glutamate racemase (GR), and DNA gyrase. Here, we carve out that targeting MLPs are the beacon of hope in an era of increasing drug resistance in bacteria. Evolutionary stability, structure-functional relationships, protein diversity, possible drug targets, and identification of new drugs against bacterial MLP are given due consideration. Before the final curtain calls, we provide a comprehensive list of small molecules that inhibit the biochemical activity of MLPs, which can aid the development of novel molecules to target MLPs for therapeutic applications.

Interaction of HIV-1 integrase with polypyrimidine tract binding protein and associated splicing factor (PSF) and its impact on HIV-1 replication.

BACKGROUND: The different interactions between viral proteins and cellular host proteins are required for efficient replication of HIV-1. Various reports implicated host cellular proteins as a key factor that either interact directly with HIV-1 integrase (IN) or get involved in the integration process of virus resulting in the modulation of integration step. Polypyrimidine tract binding protein and associated splicing factor (PSF) has diverse functions inside the cell such as transcriptional regulation, DNA repair, acts as nucleic acids binding protein and regulate replication and infectivity of different viruses. RESULTS: The protein binding study identified the association of host protein PSF with HIV-1 integrase. The siRNA knockdown (KD) of PSF resulted in increased viral replication in TZM-bl cells, suggesting PSF has negative influence on viral replication. The quantitative PCR of virus infected PSF knockdown TZM-bl cells showed more integrated DNA and viral cDNA as compared to control cells. We did not observe any significant difference between the amount of early reverse transcription products as well as infectivity of virus in the PSF KD and control TZM-bl cells. Molecular docking study supported the argument that PSF hinders the binding of viral DNA with IN. CONCLUSION: In an attempt to study the host interacting protein of IN, we have identified a new interacting host protein PSF which is a splicing factor and elucidated its role in integration and viral replication. Experimental as well as in silico analysis inferred that the host protein causes not only change in the integration events but also targets the incoming viral DNA or the integrase-viral DNA complex. The role of PSF was also investigated at early reverse transcript production as well as late stages. The PSF is causing changes in integration events, but it does not over all make any changes in the virus infectivity. MD trajectory analyses provided a strong clue of destabilization of Integrase-viral DNA complex occurred due to PSF interaction with the conserved bases of viral DNA ends that are extremely crucial contact points with integrase and indispensable for integration. Thus our study emphasizes the negative influence of PSF on HIV-1 replication.

PPEF: A bisbenzimdazole potent antimicrobial agent interacts at acidic triad of catalytic domain of E. coli topoisomerase IA.

BACKGROUND: Topoisomerase is a well known target to develop effective antibacterial agents. In pursuance of searching novel antibacterial agents, we have established a novel bisbenzimidazole (PPEF) as potent E. coli topoisomerase IA poison inhibitor. METHODS: In order to gain insights into the mechanism of action of PPEF and understanding protein-ligand interactions, we have produced wild type EcTopo 67 N-terminal domain (catalytic domain) and its six mutant proteins at acidic triad (D111, D113, E115). The DDE motif is replaced by alanine (A) to create three single mutants: D111A, D113A, E115A and three double mutants: D111A-D113A, D113A-E115A and D111A-E115A. RESULTS: Calorimetric study of PPEF with single mutants showed 10 fold lower affinity than that of wild type EcTopo 67 (7.32 × 106 M-1for wild type, 0.89 × 106 M-1for D111A) and 100 fold lower binding with double mutant D113A-E115A (0.02 × 106 M-1) was observed. The mutated proteins showed different CD signature as compared to wild type protein. CD and fluorescence titrations were done to study the interaction between EcTopo 67 and ligands. Molecular docking study validated that PPEF has decreased binding affinity towards mutated enzymes as compared to wild type. CONCLUSION: The overall study reveals that PPEF binds to D113 and E115 of acidic triad of EcTopo 67. Point mutations decrease binding affinity of PPEF towards DDE motif of topoisomerase. GENERAL SIGNIFICANCE: This study concludes PPEF as poison inhibitor of E. coli Topoisomerase IA, which binds to acidic triad of topoisomerase IA, responsible for its function. PPEF can be considered as therapeutic agent against bacteria.

Benzimidazoles: Selective Inhibitors of Topoisomerase I with Differential Modes of Action.

DNA topoisomerases are unique enzymes that alter the topology of DNA by cleavage and religation mechanisms. Small molecules such as camptothecins and noncamptothecins are reported to inhibit different classes of topoisomerases. Benzimidazole, 2-(3,4-dimethoxyphenyl)-5-[5-(4-methylpiperazin-1-yl)-1 H-benzimidazol-2-yl]-1 H benzimidazole (DMA), a new analogue of Hoechst 33342, was observed as a selective and differential inhibitor of human and Escherichia coli DNA topoisomerase I. In this study, we have concluded that DMA and Hoechst 33342 have differential binding toward human and E. coli topoisomerase I. We also dissected the mechanism of differential binding, as DMA and Hoechst 33342 bind to human topoisomerase I with linear kinetics with reversible binding, whereas the same molecules bind to E. coli topoisomerase I in a nonlinear and irreversible manner, which contributes to higher affinity and comparatively good IC50 values toward E. coli topoisomerase I. Interestingly, DMA and Hoechst 33342 showed inhibition of mutant human topoisomerases I, i.e., A653P, N722S, and T729P, whereas these clinically relevant mutants are resistant to camptothecins.

Transition-Metal-Free Access to Pyridocarbazoles from 2-Alkynylindole-3-carbaldehydes via Azomethine Ylide.

An efficient approach for the synthesis of functionalized tetrahydro-pyrido/quinolinocarbazoles from 2-alkynylindole-3-carbaldehydes and l-proline utilizing a metal-free decarboxylative cyclization, ring expansion, and ring contraction strategy via the generation of azomethine ylide was developed. The reaction of 2-alkynylindole-3-carbaldehydes with l-thioproline leads to the formation of γ-carbolines. By virtue of this expedient method, a diverse range of biologically active heteroannulated carbazoles can be synthesized efficiently.

Utilization of chromic polydiacetylene assemblies as a platform to probe specific binding between drug and RNA.

Recognition of nucleic acids remains an important endeavor in biology. Nucleic acids adopt shapes ranging from A-form (RNA and GC rich DNA) to B-form (AT rich DNA). We show, in this contribution, shape-specific recognition of A-U rich RNA duplex by a neomycin (Neo)-polydiacetylene (PDA) complex. PDA assemblies are fabricated by using a well-known diacetylene (DA) monomer, 10,12-pentacosadiynoic acid (PCDA). The response of poly(PCDA) assemblies is generated by mixing with a modified neomycin-PCDA monomer (Neo-PCDA). The functionalization by neomycin moiety provides specific binding with homopolyribonucleotide poly (rA) - poly (rU) stimulus. Various types of alcohols are utilized as additives to enhance the sensitivity of poly(PCDA)/Neo-PCDA assemblies. A change of absorption spectra is clearly observed when a relatively low concentration of poly (rA)-poly (rU) is added into the system. Furthermore, poly(PCDA)/Neo-PCDA shows a clear specificity for poly (rA)-poly (rU) over the corresponding DNA duplex. The variation of linker between neomycin moiety and conjugated PDA backbone is found to significantly affect its sensitivity. We also investigate other parameters including the concentration of Neo-PCDA and the DA monomer structure. Our results provide here preliminary data for an alternative approach to improve the sensitivity of PDA utilized in biosensing and diagnostic applications.

Selective Inhibition of Escherichia coli RNA and DNA Topoisomerase I by Hoechst 33258 Derived Mono- and Bisbenzimidazoles.

A series of Hoechst 33258 based mono- and bisbenzimidazoles have been synthesized and their Escherichia coli DNA topoisomerase I inhibition, binding to B-DNA duplex, and antibacterial activity has been evaluated. Bisbenzimidazoles with alkynyl side chains display excellent E. coli DNA topoisomerase I inhibition properties with IC50 values <5.0 µM. Several bisbenzimidazoles (3, 6, 7, 8) also inhibit RNA topoisomerase activity of E. coli DNA topoisomerase I. Bisbenzimidazoles inhibit bacterial growth much better than monobenzimidazoles for Gram-positive strains. The minimum inhibitory concentration (MIC) was much lower for Gram positive bacteria (Enterococcus spp. and Staphylococcus spp., including two MRSA strains 0.3-8 µg/mL) than for the majority of Gram negative bacteria (Pseudomonas aeruginosa, 16-32 µg/mL, Klebsiella pneumoniae > 32 µg/mL). Bisbenzimidazoles showed varied stabilization of B-DNA duplex (1.2-23.4 °C), and cytotoxicity studies show similar variation dependent upon the side chain length. Modeling studies suggest critical interactions between the inhibitor side chain and amino acids of the active site of DNA topoisomerase I.

Naphthalenediimide-Linked Bisbenzimidazole Derivatives as Telomeric G-Quadruplex-Stabilizing Ligands with Improved Anticancer Activity.

Human telomeric G-quadruplex DNA stabilization has emerged as an exciting novel approach for anticancer drug development. In the present study, we have designed and synthesized three C2-symmetric bisubstituted bisbenzimidazole naphthalenediimide (NDI) ligands, ALI-C3 , BBZ-ARO, and BBZ-AROCH2 , which stabilize human telomeric G-quadruplex DNA with high affinity. Herein, we have studied the binding affinities and thermodynamic contributions of each of these molecules with G-quadruplex DNA and compared the same to those of the parent NDI analogue, BMSG-SH-3. Results of fluorescence resonance energy transfer and surface plasmon resonance demonstrate that these ligands have a higher affinity for G4-DNA over duplex DNA and induce the formation of a G-quadruplex. The binding equilibrium constants obtained from the microcalorimetry studies of BBZ-ARO, ALI-C3 , and BBZ-AROCH2 were 8.47, 6.35, and 3.41 µM, respectively, with h-telo 22-mer quadruplex. These showed 10 and 100 times lower binding affinity with h-telo 12-mer and duplex DNA quadruplexes, respectively. Analysis of the thermodynamic parameters obtained from the microcalorimetry study suggests that interactions were most favorable for BBZ-ARO among all of the synthesized compounds. The ΔGfree obtained from molecular mechanics Poisson-Boltzmann surface area calculations of molecular dynamics (MD) simulation studies suggest that BBZ-ARO interacted strongly with G4-DNA. MD simulation results showed the highest hydrogen bond occupancy and van der Waals interactions were between the side chains of BBZ-ARO and the DNA grooves. A significant inhibition of telomerase activity (IC50 = 4.56 µM) and induced apoptosis in cancer cell lines by BBZ-ARO suggest that this molecule has the potential to be developed as an anticancer agent.

Radioprotective Agents: Strategies and Translational Advances.

Radioprotectors are agents required to protect biological system exposed to radiation, either naturally or through radiation leakage, and they protect normal cells from radiation injury in cancer patients undergoing radiotherapy. It is imperative to study radioprotectors and their mechanism of action comprehensively, looking at their potential therapeutic applications. This review intimately chronicles the rich intellectual, pharmacological story of natural and synthetic radioprotectors. A continuous effort is going on by researchers to develop clinically promising radioprotective agents. In this article, for the first time we have discussed the impact of radioprotectors on different signaling pathways in cells, which will create a basis for scientific community working in this area to develop novel molecules with better therapeutic efficacy. The bright future of exceptionally noncytotoxic derivatives of bisbenzimidazoles is also described as radiomodulators. Amifostine, an effective radioprotectant, has been approved by the FDA for limited clinical use. However, due to its adverse side effects, it is not routinely used clinically. Recently, CBLB502 and several analog of a peptide are under clinical trial and showed high success against radiotherapy in cancer. This article reviews the different types of radioprotective agents with emphasis on the strategies for the development of novel radioprotectors for drug development. In addition, direction for future strategies relevant to the development of radioprotectors is also addressed.

Design, Synthesis, and Biological Evaluation of 1,2-Dihydroisoquinolines as HIV-1 Integrase Inhibitors.

6-Endo-dig-cyclization is an efficient method for the synthesis of 1,2-dihydroisoquinolines. We have synthesized few 1,2-dihydroisoquinolines having different functionality at the C-1, C-3, C-7, and N-2 positions for evaluation against HIV-1 integrase (HIV1-IN) inhibitory activity. A direct nitro-Mannich condensation of o-alkynylaldimines and dual activation of o-alkynyl aldehydes by inexpensive cobalt chloride yielded desired compounds. Out of 24 compounds, 4m and 6c came out as potent integrase inhibitors in in vitro strand transfer (ST) assay, with IC50 value of 0.7 and 0.8 µM, respectively. Molecular docking of these compounds in integrase revealed strong interaction between metal and ligands, which stabilizes the enzyme-inhibitor complex. The ten most active compounds were subjected to antiviral assay. Out of those, 6c reduced the level of p24 viral antigen by 91%, which is comparable to RAL in antiviral assay. Interestingly, these compounds showed similar ST inhibitory activity in G140S mutant, suggesting they can act against resistant strains.

Synthesis and biological evaluation of novel bisbenzimidazoles as Escherichia coli topoisomerase IA inhibitors and potential antibacterial agents.

Novel bisbenzimidazole inhibitors of bacterial type IA topoisomerase are of interest for the development of new antibacterial agents that are impacted by target-mediated cross resistance with fluoroquinolones. The present study demonstrates the successful synthesis and evaluation of bisbenzimidazole analogues as Escherichia coli topoisomerase IA inhibitors. 5-(4-Propylpiperazin-1-yl)-2-[2'-(4-ethoxyphenyl)-5'-benzimidazolyl]benzimidazole (12b) showed significant relaxation inhibition activity against EcTopo 1A (IC50 = 2 ± 0.005 µM) and a tendency to chelate metal ion. Interestingly, these compounds did not show significant inhibition of E. coli DNA gyrase and hTop 1 even up to 100 µM. Compound 12b has shown lowest MIC against E. coli strains among 24 compounds evaluated. The binding affinity constant and binding free energy of 12b with EcTopo 1A was observed 6.8 × 10(6) M(-1) and -10.84 kcal mol(-1) from isothermal titration calorimetry (ITC), respectively. In vivo mouse systemic infection and neutropenic thigh model experimental results confirmed the therapeutic efficacy of 12b, suggesting further development of this class of compounds as antibacterial agents.

Bi and tri-substituted phenyl rings containing bisbenzimidazoles bind differentially with DNA duplexes: a biophysical and molecular simulation study.

Recently synthesis of programmable DNA ligands which can regulate transcription factors have increased the interest of researchers on the functional ability of DNA interacting compounds. A series of DNA interacting compounds are being designed which can differentiate between GC and AT rich DNA. In this study, we have studied the specificity of a few novel bisbenzimidazoles having different bi/tri-substituted phenyl rings, with DNA duplexes using spectroscopic methods. This study entails an integrative approach where we combine biophysical methods and molecular dynamics simulation studies to establish suitable scaffolds to target A/T DNA. We have designed a few analogues of Hoechst 33342 viz.; dimethoxy (DMA), trimethoxy (TMA), dichloro (DCA) and difluoro (DFA) functionalities and performed molecular docking of newly designed analogues with biologically relevant AT and GC rich DNA sequences. The docking studies, along with molecular dynamics (MD) simulations of d(ATATATATATATATAT)2, d(GA4T4C)2, d(GT4A4C)2 and GC rich sequence: d(GCGCGCGCGCGCGCGC)2 complexed with DMA, TMA and DFA, showed that these molecules have higher binding affinity towards AT rich DNA. None of these compounds exhibited an affinity to GC rich DNA rather we observed that these compounds destabilize GC rich DNA. The binding was characterized by strong stabilization of the polynucleotides against thermal strand separation in thermal melting experiments. New insights into the molecules binding to DNA have emerged from these studies. All the DNA binding ligands stabilized d(GA4T4C)2 and d(GT4A4C)2 more out of the five oligomers used for the study, suggesting that these ligands bind 'A4T4' and 'T4A4' strongly as compared to 'ATAT' base pairs.

Influence of PNA containing 8-aza-7-deazaadenine on structure stability and binding affinity of PNA·DNA duplex: insights from thermodynamics, counter ion, hydration and molecular dynamics analysis.

This paper describes the synthesis of a novel 8-aza-7-deazapurin-2,6-diamine (DPP)-containing peptide nucleic acid (PNA) monomer and Boc protecting group-based oligomerization of PNA, replacing adenine (A) with DPP monomers in the PNA strand. The PNA oligomers were synthesized against the biologically relevant SV40 promoter region (2494-AATTTTTTTTATTTA-2508) of pEGFP-N3 plasmid. The DPP-PNA·DNA duplex showed enhanced stability as compared to normal duplex (A-PNA·DNA). The electronic distribution of DPP monomer suggested that DPP had better electron donor properties over 2,6-diamino purine. UV melting and thermodynamic analysis revealed that the PNA oligomer containing a diaminopyrazolo(3,4-d)pyrimidine moiety (DPP) stabilized the PNA·DNA hybrids compared to A-PNA·DNA. DPP-PNA·DNA duplex showed higher water activity (Δnw = 38.5) in comparison to A-PNA·DNA duplex (Δnw = 14.5). The 50 ns molecular dynamics simulations of PNA·DNA duplex containing DPP or unmodified nucleobase-A showed average H-bond distances in the DPP-dT base pair of 2.90 Å (OH-N bond) and 2.91 Å (NH-N bond), which were comparably shorter than in the A-dT base pair, in which the average distances were 3.18 Å (OH-N bond) and 2.97 Å (NH-N bond), and there was one additional H-bond in the DPP-dT base pair of around 2.98 Å (O2H-N2 bond), supporting the higher stability of DPP-PNA·DNA. The analysis of molecular dynamics simulation data showed that the system binding free energy increased at a rate of approximately -4.5 kcal mol(-1) per DPP base of the PNA·DNA duplex. In summary, increased thermal stability, stronger hydrogen bonding and more stable conformation in the DPP-PNA·DNA duplex make it a better candidate as antisense/antigene therapeutic agents.

Inhibition of HIV-1 Integrase gene expression by 10-23 DNAzyme.

HIV Integrase (IN) is an enzyme that is responsible for the integration of the proviral genome into the human genome, and this integration step is the first step of the virus hijacking the human cell machinery for its propagation and replication. 10-23 DNAzyme has the potential to suppress gene expressions through sequence-specific mRNA cleavage. We have designed three novel DNAzymes, DIN54, DIN116, and DIN152, against HIV-1 Integrase gene using Mfold software and evaluated them for target site cleavage activity on the in vitro transcribed mRNA. All DNAzymes were tested for its inhibition of expression of HIV Integrase protein in the transiently transfected cell lines. DIN116 and DIN152 inhibited IN-EGFP expression by 80 percent and 70 percent respectively.