MECHANISM OF ACTIVATION OF PROTEIN KINASE-I FROM RABBIT SKELETAL-MUSCLE - MAPPING OF CAMP SITE BY SPIN-LABELED CYCLIC NUCLEOTIDES

Binding of adenosine 3′:5′‐monophosphate (cAMP) to protein kinase (type 1) from rabbit skeletal muscle has been investigated using spin‐labeled cAMP derivatives. Different compounds were synthesized with the spin label attached by spacer chains of different length at different positions on the adenine base. Immobilization of the spin label, determined by comparing the electron‐spin resonance spectra recorded in the presence of the kïnase with those of the free ligand in solutions of different viscosities, gave information about the geometry of the cAMP site. Strong immobilization of the N‐6 substituents up to a spacer length of seven atoms indicates a rather deep cleft of the cAMP site. The depth of this cleft differs, however, when the spin label is attached to the different positions at the adenine (N‐6, C‐2 and C‐8). Whereas the N‐6 derivatives indicate a rather deep site, the C‐2 derivatives reveal a significantly smaller depth and C‐8 substituents (syn conformation) obviously occupy a very shallow surface with almost no immobilization. In addition the binding affinities of the spin‐labeled cAMP derivatives have been determined, together with those of a series of (diamagnetic) C‐2 derivatives bearing hydrophobic alkyl chains of different length. The latter results helped to clarify the differences between the regions near to C‐2 and N‐6, respectively, of the cAMP site. N‐6 spin‐labeled derivatives have also been investigated in the presence of ATP and protein kinase. These results are interpreted as indicative of a conformational change at the cAMP site upon formation of the holoenzyme, due to binding of ATP, leaving cAMP less strongly immobilized. Copyright © 1978, Wiley Blackwell. All rights reserved