ABSTRACT
The binding properties between vitamin B12 (vitB12, cyanocobalamin) and fibrinogen (Fib) were investigated by UV-vis absorption and steady-state/three-dimentional (3D) fluorescence spectra techniques as well as molecular docking. The experimental results showed that the intrinsic fluorescence of Fib quenched by vitB12 with static mechanism to form a non-fluorescent complex. The positive signs of thermodynamic parameters, ΔH (92.18 kJ/mol) and ΔS (433.5 J/molK), indicated that the hydrophobic forces were dominant in the binding mode. The molecular docking data were found to be in agreement with these experimental results and were confirmed by three hydrophobic interactions between the Trp430, Try390 residues of Fib and the vitamin. 3D spectra showed that fibrinogen undergoes a conformation change when it interacts with vitB12. Based on non-radiative energy transfer theory, binding distance was calculated to be 3.94 nm between donor (tryptophan residues of Fib) and acceptor (vitB12). The limit of detection (LOD) of vitB12 was calculated as 2.08 µM in the presence of fibrinogen. The relative standard deviation (RSD) of method was 4.28% for determinations (n = 7) of a vitB12 solution with the concentration of 7.80 µM.
ABSTRACT
A novel carbazole compound, named 1-(9-ethyl-9H-carbazol-3-yl)-3-phenylurea (Cpu) was synthesized and its binding properties with protease enzymes (pepsin and trypsin) has been examined by steady-state fluorescence measurements, UV/vis absorption, infrared (FT-IR) and circular dicroism (CD) spectroscopies and also computational methods. The fluorescence experimental results indicated that the quenching mechanism of enzyme by Cpu is static process. The thermodynamic parameters (both negative ΔH/ΔS) and molecular docking results suggested that the binding of Cpu to pepsin/trypsin were driven by hydrogen bonds and van der Waals forces. Based on Förster's theory, the binding distance (r) between pepsin/trypsin and Cpu was calculated to be 3.072/2.784 nm, which implies that non-radiative energy transfer occurs from enzyme to Cpu. Furthermore, absorption, CD, and FT-IR spectral analysis provided an evidence that the presence of Cpu induced notable changes in the secondary structures and microenvironmental of both pepsin and trypsin, supporting its significant influence on these enzymes.
ABSTRACT
A new cationic indolium based styryl dye (Ci) as a fluorescent probe was synthesized and its anions selectivity/sensitivity properties/molecular interactions with protease enzymes (pepsin/trypsin) and ctDNA has been studied by spectroscopic and computational methods. The fluorescence measurements at different temperatures indicated that quenching mechanism of enzymes by Ci was static. ΔH and ΔS data pointed out electrostatic/hydrophobic interactions with pepsin, and also hydrogen bonds/van der Waals forces with trypsin of Ci. According to Förster's non-radiative energy transfer, binding distances (r) were calculated as 3.53/3.27 nm for pepsin/trypsin. It was also investigated that groove binding is effective in interaction with ctDNA. The results were supported with molecular docking analyzes which have same tendency. Ci has been demonstrated hypsochromic effect with a decrease in polarity of solvents and it showed highly selective colorimetric and fluorometric sensing behavior for cyanide in organic solvent and in aqueous solution. 1H NMR titration was performed to examine the interaction mechanism between Ci and cyanide. The LOD values of cyanide ion were reported as 4.87 × 10-9 M and 9.70 × 10-7 M in DMSO and DMSO/H2O binary mixture, respectively. In addition, sensitivity of Ci as a chemosensor to cyanide was investigated in bitter almond samples.