posted on 2014-05-27, 00:00authored byBijan
K. Paul, Narayani Ghosh, Saptarshi Mukherjee
This
Article reports a detailed characterization of the binding
interaction of a potential chemotherapeutic antibacterial drug, norfloxacin
(NOF), with the mammalian milk protein β-lactoglobulin (βLG).
The thermodynamic parameters, ΔH, ΔS, and ΔG, for the binding phenomenon
as-evaluated on the basis of van’t Hoff relationship reveal
the predominance of electrostatic/ionic interactions underlying the
binding process. However, the drug-induced quenching of the intrinsic
tryptophanyl fluorescence of the protein exhibits intriguing characteristics
on Stern–Volmer analysis (displays an upward curvature instead
of conforming to a linear regression). Thus, an extensive time-resolved
fluorescence spectroscopic characterization of the quenching process
has been undertaken in conjugation with temperature-dependent fluorescence
quenching studies to unveil the actual quenching mechanism. The invariance
of the fluorescence decay behavior of βLG as a function of the
quencher (here NOF) concentration coupled with the commensurate dependence
of the drug–protein binding constant (K) on
temperature, the drug-induced fluorescence quenching of βLG
is argued to proceed through static mechanism. This postulate is aided
further support from absorption, fluorescence, and circular dichroism
(CD) spectral studies. The present study also throws light on the
important issue of drug-induced modification in the native protein
conformation on the lexicon of CD, excitation–emission matrix
spectroscopic techniques. Concurrently, the drug–protein interaction
kinetics and the energy of activation of the process are also explored
from stopped-flow fluorescence technique. The probable binding locus
of NOF in βLG is investigated from AutoDock-based blind docking
simulation.