Abstract
Magnetic resonance and kinetic studies of the catalytic subunit of a Type II cAMP-dependent protein kinase from bovine heart have established the active complex to be an enzyme-ATP-metal bridge. The metal ion is β,γ coordinated with Δ chirality at the β-phosphorous atom. The binding of a second metal ion at the active site which bridges the enzyme to the three phosphoryl groups of ATP, partially inhibits the reaction. Binding of the metal-ATP substrate to the enzyme occurs in a diffusion-controlled reaction followed by a 40 ° change in the glycosidic torsional angle. This conformational change results from strong interaction of the nucleotide base with the enzyme. NMR studies of four ATP-utilizing enzymes show a correlation between such conformational changes and high nucleotide base specificity. Heptapeptide substrates and substrate analogs bind to the active site of the catalytic subunit at a rate significantly lower than collision frequency indicating conformational selection by the enzyme or a subsequent slow conformational change. NMR studies of the conformation of the enzyme-bound peptide substrates have ruled out α-helical and β-pleated sheet structures. The results of kinetic studies of peptide substrates in which the amino acid sequence was systematically varied were used to rule out the obligatory requirement for all possible β-turn conformations within the heptapeptide although an enzymatic preference for a β 2–5 or β 3–6 turn could not be excluded. Hence if protein kinase has an absolute requirement for a specific secondary structure, then this structure must be a coil. In the enzyme-substrate complex the distance along the reaction coordinate between the γ-P of ATP and the serine oxygen of the peptide substrate (5.3 ± 0.7 Å) allows room for a metaphosphate intermediate. This finding together with kinetic observations as well as the location of the inhibitory metal suggest a dissociative mechanism for protein kinase, although a mechanism with some associative character remains possible. Regulation of protein kinase is accomplished by competition between the regulatory subunit and peptide or protein substrates at the active site of the catalytic subunit. Thus, the regulatory subunit is found by NMR to block the binding of the peptide substrate to the active site of protein kinase but allows the binding of the nucleotide substrate and divalent cations. The dissociation constant of the regulatory subunit from the active site (10 −10 m) is increased ~10-fold by phosphorylation and ~10 4-fold by the binding of cAMP, to a value (10 −5 m) which exceeds the intracellular concentration of the R 2C 2 holoenzyme complex (10 −6 m). The resulting dissociation of the holoenzyme releases the catalytic subunit, permitting the active site binding of peptide or protein substrates.
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