Physical basis for the ofloxacin-induced acceleration of lysozyme aggregation and polymorphism in amyloid fibrils.

Aggregation of globular proteins is an intractable problem which generally originates from partially folded structures. The partially folded structures first collapse non-specifically and then reorganize into amyloid-like fibrils via one or more oligomeric intermediates. The fibrils and their on/off pathway intermediates may be toxic to cells and form toxic deposits in different human organs. To understand the basis of origins of the aggregation diseases, it is vital to study in details the conformational properties of the amyloidogenic partially folded structures of the protein. In this work, we examined the effects of ofloxacin, a synthetic fluoroquinolone compound on the fibrillar aggregation of hen egg-white lysozyme. Using two aggregation conditions (4M GuHCl at pH 7.0 and 37 °C; and pH 1.7 at 65 °C) and a number of biophysical techniques, we illustrate that ofloxacin accelerates fibril formation of lysozyme by binding to partially folded structures and modulating their secondary, tertiary structures and surface hydrophobicity. We also demonstrate that Ofloxacin-induced fibrils show polymorphism of morphology, tinctorial properties and hydrophobic surface exposure. This study will assist in understanding the determinant of fibril formation and it also indicates that caution should be exercised in the use of ofloxacin in patients susceptible to various aggregation diseases.

Effects of 2-amino-8-hydroxyquinoline interaction on the conformation of physiological isomers of human serum albumin.

The methods of synthetic chemistry create small molecules rapidly for screening, and ligand-protein interaction studies provide information on how a potential drug interacts with target or carrier proteins such as serum albumin. In this work, we investigate the interaction of amino derivative of 8-hydroxyquinoline, 2-amino-8-hydroxyquinoline (A8HQ), and the effects of its binding on the conformation of different isomers of human serum albumin (HSA) using multispectroscopic techniques and molecular modeling. We found that B isomer, which exists at pH 9, bound A8HQ (K a = 1.92 ± 0.07 × 10(5) M(-1) at 298 K) more strongly as compared with N isomer (K a = 1.19 ± 0.04 × 10(5) M(-1) at 298 K) of HSA, which is known to exist around pH 6. The binding constant at physiological pH (7.4) was also determined, and the value (K a = 1.38 ± 0.05 × 10(5) M(-1) at 298 K) was found to fall between those for N and B isomers, suggesting that both the N and B isomers exist in an equilibrium in plasma. We also determined the thermodynamic parameters such as changes in enthalpy, entropy , and free energy of binding by measuring the binding at four different temperatures. Based on molecular modeling and thermodynamic studies, we propound that the A8HQ-HSA binding involves mainly hydrophobic interactions and hydrogen bonding. Site-specific marker displacement experiments and molecular modeling showed that the molecule preferably binds in subdomain IIA close to Trp214. A8HQ binding to HSA isomers was found to cause both secondary and tertiary structural alterations in the protein.

Effects of hesperidin, a flavanone glycoside interaction on the conformation, stability, and aggregation of lysozyme: multispectroscopic and molecular dynamic simulation studies?

Hesperidin (HESP), a flavanone glycoside, shows high antioxidant properties and possess ability to go through the blood-brain barrier. Therefore, it could be a potential drug molecule against aggregation based diseases such as Alzheimer's, Parkinson's, and systemic amyloidoses. In this work, we investigated the potential of HESP to interact with hen egg-white lysozyme (HEWL) monomer and prevent its aggregation. The HESP-HEWL binding studies were performed using a fluorescence quenching technique, molecular docking and molecular dynamics simulations. We found a strong interaction of HESP with the lysozyme monomer (Ka, ~ 5 × 10(4) M(-1)) mainly through hydrogen bonding, water bridges, and hydrophobic interactions. We showed that HESP molecule spanned the highly aggregation prone region (amino acid residues 48-101) of HEWL and prevented its fibrillar aggregation. Further, we found that HESP binding completely inhibited amorphous aggregation of the protein induced by disulfide-reducing agent tries-(2-carboxyethyl) phosphine. Conformational and stability studies as followed by various tertiary and secondary structure probes revealed that HESP binding only marginally affected the lysozyme monomer conformation and increased both stability and reversibility of the protein against thermal denaturation. Future studies should investigate detail effects of HESP on solvent dynamics, structure, and toxicity of various aggregates. The answers to these questions will not only target the basic sciences, but also have application in biomedical and biotechnological sciences.