Insights from spectroscopic and in-silico techniques for the exploitation of biomolecular interactions between Human serum albumin and Paromomycin.

The study of molecular interactions of drug-protein are extremely important from the biological aspect in all living organisms, and therefore such type of investigation hold a tremendous significance in rational drug design and discovery. In the present study, the molecular interactions between paromomycin (PAR) and human serum albumin (HSA) have been studied by different biophysical techniques and validated by in-silico approaches. The results obtained from Ultraviolet-visible spectroscopy (UV) and Fourier transform infrared spectroscopy (FT-IR) demonstrated a remarkable change upon the complexation of PAR with HSA. Circular Dichroism (CD), Dynamic Light Scattering (DLS) and Resonance Rayleigh scattering (RRS) results revealed a significant secondary structure alteration and reduction of hydrodynamic radii upon the conjugation of PAR with HSA. The fluorescence spectroscopy results also apparently revealed the static quenching mechanism. The number of binding sites, binding constants, and Gibbs free energy values were calculated to illustrate the nature of intermolecular interactions. Similarly, the in-silico docking and molecular dynamics simulation clearly explain the theoretical basis of the binding mechanism of PAR with HSA. The experimental and docking approaches suggested that PAR binds to the hydrophobic cavity site I of HSA. The finding of present investigation will provide binding insight of PAR and associated alterations in the stability and conformation of HSA.

Bio-fabrication of catalytic platinum nanoparticles and their in vitro efficacy against lungs cancer cells line (A549).

Platinum based drugs are considered as effective agents against various types of carcinoma; however, the severe toxicity associated with the chemically prepared platinum complexes limit their practical applications. Similarly, water pollution caused by various organic moieties is another serious health problem worldwide. Hence, an intense need exists to develop new, effective and biocompatible materials with catalytic and biomedical applications. In the present contribution, we prepared platinum nanoparticles (PtNPs) by a green route using phytochemicals as a source of reducing and stabilizing agents. Well dispersed and crystalline PtNPs of spherical shapes were prepared and characterized. The bio-fabricated PtNPs were used as catalyst and anticancer agents. Catalytic performance of the PtNPs showed that 84% of the methylene blue can be reduced in 32min under visible light irradiation (K=0.078min-1). Similarly the catalytic conversion of 4-nitrophenol to 4-aminophenol was achieved in <20min (K=0.124min-1). The in vitro anticancer study revealed that biogenic PtNPs are the efficient nano-agents possessing strong anticancer activity against the lungs cancer cells line (A549). Interestingly, the as prepared PtNPs were well tolerated by normal human cells, and therefore, could be effective and biocompatible agents in the treatment of different cancer cells.

Biophysical and molecular docking approaches for the investigation of biomolecular interactions between amphotericin B and bovine serum albumin.

Exogenous drug as an antidote to treat various infections get absorbed in the blood circulatory system of a human can directly contact with transporter proteins such as serum albumin. Therefore, for rational drug discovery, understanding the biomolecular interaction between drugs and protein is highly important. In this contribution, we describe the possible interactions between an antifungal drug Amphotericin B (AmB) and Bovine Serum Albumin (BSA) using multi-spectroscopic techniques and further confirmed through in-silico approaches. Binding effects of AmB on BSA conformation, surface morphology, topology, and stability were determined by Ultraviolet-visible spectroscopy (UV), Fourier transform infrared spectroscopy (FT-IR), Circular Dichroism (CD), Transmission Electron Microscopy (TEM), Dynamic Light Scattering (DLS), Fluorescence Spectroscopy and Molecular dynamic simulations. The Stern-Volmer equation was used to determine the binding site (0.4) and binding constant (8.16×105M-1). The intrinsic intensity of the native BSA was quenched by AmB through static quenching mechanism. The calculated Gibbs free energy value (-8.70kcal/mol) indicated the involvement of hydrogen bonding and hydrophobic contacts in BSA-AmB interaction. The hydrodynamic radii and surface contact area of BSA-AmB molecules are decreasing which can strongly support the stabilizing action of complex particles. Moreover, the finding of this work will provide information for the drug designers to further study the AmB binding mechanism and their pharmacodynamics and pharmacokinetics features in order to achieve better therapeutic efficacy.