Exploring the interaction of bisphenol-S with serum albumins: a better or worse alternative for bisphenol a?

The interaction of bisphenol-S (BPS) with serum albumins using steady-state, synchronous, time-resolved, and circular dichroism spectroscopies has been investigated. The binding interactions have also been investigated in the case of bisphenol A (BPA). The fluorescence quenching pathways are different for both of these endocrine disrupting compounds. Steady-state and time-resolved studies reveal static quenching at lower concentrations of BPS and dynamic quenching at higher concentrations. CD results also maintained the concentration dependent variation with a complete distortion of α-helices at 10(-5) M BPS. Besides this, addition of sodium dodecyl sulfate (SDS) results in the further unfolding of protein in the case of BPS, whereas time-resolved studies indicated refolding for BPA denatured human serum albumin (HSA). The entire study indicates an irreversible binding of BPS with HSA. Hence, these results reveal the possible involvement of BPS in the physiological pathway raising a health threat as already their presences in body fluids are known.

Subpicomolar sensing of hydrogen peroxide with ovalbumin-embedded chitosan/polystyrene sulfonate multilayer membrane.

The use of ovalbumin (OVA)-immobilized layer-by-layer-assembled chitosan/polystyrene sulfonate membranes for the detection of hydrogen peroxide (H2O2) at subpicomolar levels is reported. The detection of mercuric chloride (HgCl2) and potassium iodide (KI) was also investigated. While the detection limits of HgCl2 and KI remained in the micromolar concentration range, H2O2 could be sensed to a remarkably lower range (subpicomolar). Analysis of fluorescence quenching data of OVA by H2O2 using Stern-Volmer plots revealed a static quenching mechanism with high Stern-Volmer quenching constant (9.10×10(12) L mol(-1)) and k (5.82×10(21) L mol(-1) s(-1)). The possibility of the conformational transition of OVA in the immobilized state is discussed using steady-state and time-resolved spectroscopic techniques. The resulting increased accessibility of tryptophan residues together with the reversibility of the bilayer for the sensing of H2O2 is also illustrated.

Fabrication of switchable protein resistant and adhesive multilayer membranes.

Fabrication of protein adhesive and resistant surfaces based on chitosan/polystyrene sulfonate (CHI/PSS) multilayer membranes is presented. Adsorption behavior of bovine serum albumin (BSA) and lysozyme to CHI/PSS multilayer was studied by simple adsorption method and under pressure driven (ultrafiltration) conditions. The protein incorporated membranes were characterized by FT-IR, UV-vis, SEM and AFM. The loading of proteins to the multilayer was found to be dependent on the nature of protein, pH, number of bilayers, methods of adsorption and time of adsorption. Simple adsorption resulted in BSA adhesive layers with some conformational changes at higher number of bilayers. Ultrafiltration leads to protein repellence at higher number of bilayers which is attributed to the presence of irremovable water. Lysozyme adsorption/sorption varied with pH. Surface coverage dominates at pH close to pI and at pH 5 under ultraflitration condition where as simple adsorption resulted in protein repellence at pI. The secondary structure of adsorbed lysozyme is preserved for a wide pH range (5-11). Desorption study of lysozyme adsorbed membranes at pH 8.8 was carried out to understand the adsorption/sorption of protein. Diffusion of the sorbed lysozyme from the inner layers to the surface is found to take place at lower concentrations of NaCl.