Kinetics of cytochrome b2 inactivation by acrylamide

A possible tertiary structure change induced by acrylamide in the DNA-binding domain of the Tn10-encoded Tet repressor. A fluorescence study

A thorough investigation of the acrylamide fluorescence quenching of F75TetR, a mutant of the Tn10-encoded TetR repressor containing a single Trp residue at position 43, was carried out. The Trp-43 residue is located in a helix alpha-turn-helix alpha (H-t-H) motif involved in the specific binding of F75TetR to the operator site in specific DNA. Distinct Ranges of acrylamide concentration have been assumed. At acrylamide concentrations below 0.15-0.2 M (a usual range of values in fluorescence quenching studies) the observed limited tertiary structure change induced by acrylamide is consistent with a noncooperative local unfolding of the DNA-binding domain. It is suggested that penetration of the neutral quencher could cause the deletion of a hydrophobic tertiary structure contact, partly involving TrP-43, responsible for the anchoring of the H-t-H motif inside the three-helix protein bundle, characterizing the N-terminal part. Correspondingly, the affinity of the mutant repressor for the operator was shown to decrease substantially (about five orders of magnitude), seemingly losing its specificity. A subsequent phase, up to 0.8 M acrylamide, was observed in which the involved intermediate protein structure is not further perturbed, nor is DNA binding.

Acrylamide quenching of the fluorescence of glyceraldehyde-3-phosphate dehydrogenase: reversible and irreversible effects

The acrylamide quenching of the tryptophan fluorescence of apo and holo glyceraldehyde-3-phosphate dehydrogenase (GAPDH) was studied. In the case of apo-GAPDH, the steady state fluorescence quenching cannot be described by the classical Stern-Volmer equation: strong cooperative quenching is observed. In the presence of Pi and/or cofactor NAD+, an inaccessible fraction appears. Cooperative quenching is partially suppressed in the presence of Pi and fully absent in the presence of NAD+. The measurements of the fluorescence lifetimes of the holo-enzyme by phasefluorometry allow the resolution of two lifetimes. The long-lived component is quenched by acrylamide, the short-lived component is not. Quenching induces a red shift of the steady state emission peak. The quenching parameters from the lifetime measurements allow the quantitative description of the steady state fluorescence quenching data. In agreement with the observations of Orstan and Gafni (Photochemistry and Photobiology, (1990) 31, 725-731), we find that acrylamide causes a slow, irreversible loss of activity and a reduction of titratable thiol groups when it acts on the apo-enzyme. This inactivation is strongly reduced in the presence of NAD+. We show that this inactivation is also slowed down by the presence of Pi, and that it is accompanied by a loss of the NAD+ binding site. Blocking the thiol groups with 5,5'-dithio-bis-(2-nitrobenzoic acid) does not lead to a protection against the irreversible inactivation by acrylamide, showing that reactions other than thiol modifications are involved in the irreversible effect. A fraction of the inactivation can be reversed by treatment with mercapto-ethanol.

Does the fluorescence quencher acrylamide bind to proteins?

We have studied the protein concentration dependence of the acrylamide quenching of the fluorescence of the proteins, human serum albumin and monellin, and we have found no such dependence for the concentration range of 0.5-20 mg/ml. These quenching studies were performed by fluorescence lifetime measurements using phase/modulation fluorometry. We have also performed equilibrium dialysis studies, which show no large degree of association of acrylamide with serum albumin, and we have found that acrylamide has only a small effect on the activity of selected enzymes. These various studies do not indicate the existence of strong acrylamide-protein interactions and are in discord with a recent report by Blatt et al. in this journal (Blatt, E., Husain, A. and Sawyer, W.H. (1986) Biochim. Biophys. Acta 871, 6-13).