Studying the interaction of scopolamine with calf-thymus DNA: An in-vitro and in-silico approach and genotoxicity.

Scopolamine is used to treat various CNS disorder like urinary incontinence, motion sickness, spasmic movements. Despite its pharmaceutical properties, its interaction with DNA is not yet reported. In this article, the interaction between scopolamine and ct-DNA is reported using a combination of biophysical techniques. UV-visible and steady-state fluorescence spectroscopy were used to study interaction and complex formation. Competitive displacement assays and potassium iodide quenching confirmed the mode of binding between scopolamine and DNA. Structural changes induced in the ct-DNA in the presence of scopolamine were evaluated by CD spectroscopy. The plasmid nicking and NBT assay confirmed the genotoxic effect of scopolamine. In-silico study by molecular docking and molecular dynamics simulation revealed the mode of interaction, major stabilizing forces as well as the nucleotide sequences to which the scopolamine binds.

Interaction of memantine with calf thymus DNA: an in-vitro and in-silico approach and cytotoxic effect on the cancerous cell lines.

Memantine belongs to the class of cognition enhancers that functions as NMDA receptor antagonist, used to treat Alzheimer's disease. The interaction of memantine with DNA was not investigated. In the present study, the interaction of memantine with ct-DNA, as well as its cytotoxicity on cancer cells, was evaluated. UV-visible spectroscopy, steady-state fluorescence spectroscopic studies revealed the interaction between memantine and ct-DNA. The quenching studies, chemical denaturation, (CD), and DNA melting studies showed the groove binding mode of memantine with ct-DNA. The thermodynamic parameters revealed that the interaction between memantine and ct-DNA is enthalpically driven, and the stabilizing forces involved were hydrogen bonding and van der Waals interaction. The groove-binding was also observed by molecular docking studies, which corroborated the findings of spectroscopic investigations. Density function theory calculations confirmed the existence of electron donor and recipient groups. The stability of memantine and DNA interaction, as well as the critical residues involved in the interaction, was identified by molecular dynamics simulations. Memantine showed cytotoxicity towards the cancer cells as compared to normal cells, as observed by MTT assay. Inverted compound microscopy analysis of memantine treated cancer cell lines further confirmed the results obtained by MTT assay.Communicated by Ramaswamy H. Sarma.

Investigating the mechanism of binding of nalidixic acid with deoxyribonucleic acid and serum albumin: a biophysical and molecular docking approaches.

Nalidixic acid is a bacterial DNA gyrase inhibitor and the first member of the synthetic quinolone antibiotics. It is used in the treatment of various infectious diseases like urinary tract infections, respiratory infections, sexually transmitted diseases, acute bronchitis, and sinusitis. Interactions studies are of great significance as it will be beneficial for designing new therapeutic molecules with preferable plasma solubility and its efficacy. In this paper, we have aim to ascertain the binding mode of nalidixic acid with calf thymus DNA (ct-DNA) and bovine serum albumin (BSA) through various biophysical and in silico method. UV-visible absorption and fluorescence spectroscopic experiments confirmed the formation of a complex between nalidixic acid with ct-DNA. The binding constant is in the range of 103 M-1, indicating the groove binding mode between ct-DNA and nalidixic acid. Groove binding mode was also validated by competitive displacement assay, potassium iodide quenching experiment, circular dichroism, DNA melting studies. In the case of BSA, UV-visible absorption and fluorescence spectroscopic experiments confirmed the formation of a complex between nalidixic acid with BSA. The value of a binding constant in the case of BSA was found to be 1.517 × 105 M-1. The site marker displacement experiment revealed the binding location of nalidixic acid to a site I in BSA. Secondary structural and microenvironmental changes also studied through circular dichroism and three-dimensional fluorescence. Furthermore, the synchronous fluorescence spectra of BSA with nalidixic acid showed that there were changes in the microenvironment around tryptophan residues. In silico molecular docking further confirmed the binding of nalidixic acid to site I in BSA and the minor groove of DNA.Communicated by Ramaswamy H. Sarma.

Biophysical insight into the binding mechanism of doxofylline to bovine serum albumin: An in vitro and in silico approach.

Insight into the mechanistic binding of bovine serum albumin (BSA) with doxofylline can layout pivotal enlightenment with relevance to pharmacokinetics and pharmacodynamics properties. Herein, many spectroscopic techniques and computational methods had been employed to interpret the structural and binding dynamics of BSA-doxofylline interaction. Doxofylline quenched the intrinsic fluorescence of BSA by static quenching. The stoichiometry and the binding constant of the BSA-doxofylline complex were 1:1 and in the order of 103 M-1. It was also concluded that the binding process was spontaneous and exothermic, primarily based on the thermodynamic study. Circular dichroism and three-dimensional excitation-emission matrix fluorescence results concluded pronounced conformational and microenvironmental changes in BSA structure on binding with doxofylline. The influence of metal ions and vitamins on the binding affinity of the BSA-doxofylline system were also explored. The in vitro findings were further supported by in silico analysis. With a score value of -6.25 kcal/mol, molecular docking showed strong interactions. Molecular dynamics simulation interpretation also suggested the stable binding with lower deviation in the values of RMSD and RMSF obtained by uninterrupted long simulation run. These studies will propose the optimum potency of distribution of the doxofylline into the bloodstream for asthma treatment.

Interaction of thiamethoxam with DNA: Hazardous effect on biochemical and biological parameters of the exposed organism.

In the present scenario, insecticides/pesticides are used intensively to control the various insect pests. Indiscriminate use of these insecticides/pesticides affects the structure and function of the ecosystem. In this context, a thorough toxicological study of each insecticide/pesticide is a must to understand the hazardous effect of these chemicals on the target and non-target organisms. The present study was aimed to understand the hazardous effect of thiamethoxam against the Spodoptera litura. Different concentrations (20-80 µg/mL) of thiamethoxam were prepared, and fourth instar larvae of S. litura were allowed to feed for 12-72 h. We first examined the interaction of thiamethoxam with DNA. Next, treated and non-treated larvae were assessed for different biological parameters such as mortality, emergence, fecundity, fertility, longevities, and biochemical parameters. Our result showed that thiamethoxam directly interacts with the DNA and significantly influenced the different biological and biochemical parameters of exposed the organisms. We observed a significant change in stress enzymes such as SOD, CAT, and GST. A similar observation was also made with the oxidative marker for lipid damage, MDA and DNA damage, 8-OHdG, respectively. In conclusion, our results suggest that improper use of synthetic chemical insecticides influenced both biological and biochemical parameters through oxidative stress and probably damage the genetic material.

Application of HDR-CRISPR/Cas9 and Erythrocyte Binding for Rapid Generation of Recombinant Turkey Herpesvirus-Vectored Avian Influenza Virus Vaccines.

Avian influenza viruses (AIVs) are highly contagious and have caused huge economical loss to the poultry industry. AIV vaccines remain one of the most effective methods of controlling this disease. Turkey herpesvirus (HVT) is a commonly used live attenuated vaccine against Marek's disease; it has also been used as a viral vector for recombinant AIV vaccine development. The clustered regularly interspaced palindromic repeats (CRISPR)/Cas9 system is a gene editing tool which, in vaccinology, has facilitated the development of recombinant DNA viral-vectored vaccines. Here, we utilize homology-directed repair (HDR) for the generation of a HVT-H7N9 HA bivalent vaccine; a H7N9 HA expression cassette was inserted into the intergenic region between UL45 and UL46 of HVT. To optimize the selection efficiency of our bivalent vaccine, we combined CRISPR/Cas9 with erythrocyte binding to rapidly generate recombinant HVT-H7HA candidate vaccines.