ISSN:
1471-4159
Source:
Blackwell Publishing Journal Backfiles 1879-2005
Topics:
Medicine
Notes:
Abstract: Titrimetric determination of the dissociation constants for the binding of substrates to creatine kinase from monkey brain reveals 13-fold and 4-fold synergism in the forward and reverse directions, respectively. This synergism is expressed as a decrease in the KD for a given substrate in the ternary complex compared with the binary complex and may be a reflection of substrate-induced conformational change. Creatine kinase labeled with two molecules of 5′-iodoacetamidofluorescein displays a blue shift and a decrease in fluorescence intensity upon binding of MgADP, indicative of movement of the dye into a more hydrophobic environment and quenching of the extrinsic fluorescense. Rotational relaxation times determined from analysis of fluorescence polarization of dansylated brain creatine kinase decrease from 212 ± 7 ns to 189 ± 6 ns upon MgADP binding. Dansylated creatine kinase in 0.5% sodium dodecyl sulfate has a rotational relaxation time of 135 ± 6 ns. The rotational relaxation time of dansylated muscle-type isoenzyme is unaffected by MgADP and has the same value as the brain isoenzyme-MgADP complex. Polarization values at 25°C for muscle and brain enzyme labeled with 3 - (4 - maleimidylphenyl) - 7 - diethylamino - 4 - methylcoumarin compared with limiting polarization and polarization of the free dye suggest that the dye rotation is severely restricted in the muscle form, but possesses freedom of rotation in the brain form. These results support the conclusion that compared with the muscle isoenzyme, the brain isoenzyme is more open at the active site and more flexible overall. Binding of MgADP by brain creatine kinase produces a protein more compact across one or both of its rotational axes, thus resembling the conformation of the muscle isoenzyme. It is probable that creatine kinase in the brain, unlike that from muscle, is subject to kinetic regulation accompanied by conformational modification. This suggests that the neurobiochemical role of the brain isoenzyme is distinct from the metabolic function of the muscle isoenzyme.
Type of Medium:
Electronic Resource
URL:
http://dx.doi.org/10.1111/j.1471-4159.1983.tb04801.x
