Catalytic independent functions of a protein kinase as revealed by a kinase-dead mutant: study of the Lys72His mutant of cAMP-dependent kinase.

A highly conserved lysine in subdomain II is required for high catalytic activity among the protein kinases. This lysine interacts directly with ATP and mutation of this residue leads to a classical "kinase-dead" mutant. This study describes the biophysical and functional properties of a kinase-dead mutant of cAMP-dependent kinase where Lys72 was replaced with His. Although the mutant protein is less stable than the wild-type catalytic subunit, it is fully capable of binding ATP. The results highlight the effect of the mutation on stability and overall organization of the protein, especially the small lobe. Phosphorylation of the activation loop by a heterologous kinase, 3-phosphoinositide-dependent protein kinase-1 (PDK-1) also contributes dramatically to the global organization of the entire active site region. Deuterium-exchange mass spectrometry (DXMS) indicates a concerted stabilization of the entire active site following the addition of this single phosphate to the activation loop. Furthermore the mutant C-subunit is capable of binding both the type I and II regulatory subunits, but only after phosphorylation of the activation loop. This highlights the role of the large lobe as a scaffold for the regulatory subunits independent of catalytic competency and suggests that kinase dead members of the protein kinase superfamily may still have other important biological roles although they lack catalytic activity.

Allosteric network of cAMP-dependent protein kinase revealed by mutation of Tyr204 in the P+1 loop.

Previous studies on the catalytic subunit of cAMP-dependent protein kinase (PKA) identified a conserved interaction pair comprised of Tyr204 from the P+1 loop and Glu230 at the end of the alphaF-helix. Single-point mutations of Tyr204 to Ala (Y204A) and Glu230 to Gln (E230Q) both resulted in alterations in enzymatic kinetics. To understand further the molecular basis for the altered kinetics and the structural role of each residue, we analyzed the Y204A and the E230Q mutants using hydrogen/deuterium (H/D) exchange coupled with mass spectrometry and other biophysical techniques. The fact that the mutants exhibit distinct molecular properties, supports previous hypotheses that these two residues, although in the same interaction node, contribute to the same enzymatic functions through different molecular pathways. The Tyr204 mutation appears to affect the dynamic properties, while the Glu230 mutation affects the surface electrostatic profile of the enzyme. Furthermore, H/D exchange analysis defines the dynamic allosteric range of Tyr204 to include the catalytic loop and three additional distant surface regions, which exhibit increased deuterium exchange in the Y204A but not the E230Q mutant. Interestingly, these are the exact regions that previously showed decreased deuterium exchange upon binding of the RIalpha regulatory subunit of PKA. We propose that these sites, coupled with the P+1 loop through Tyr204, represent one of the major allosteric networks in the kinase. This coupling provides a coordinated response for substrate binding and enzyme catalysis. H/D exchange analysis also further defines the stable core of the catalytic subunit to include the alphaE, alphaF and alphaH-helix. All these observations lead to an interesting new way to view the structural architecture and allosteric conformational regulation of the protein kinase molecule.

Dissecting interdomain communication within cAPK regulatory subunit type IIbeta using enhanced amide hydrogen/deuterium exchange mass spectrometry (DXMS).

cAMP-dependent protein kinase (cAPK) is a heterotetramer containing a regulatory (R) subunit dimer bound to two catalytic (C) subunits and is involved in numerous cell signaling pathways. The C-subunit is activated allosterically when two cAMP molecules bind sequentially to the cAMP-binding domains, designated A and B (cAB-A and cAB-B, respectively). Each cAMP-binding domain contains a conserved Arg residue that is critical for high-affinity cAMP binding. Replacement of this Arg with Lys affects cAMP affinity, the structural integrity of the cAMP-binding domains, and cAPK activation. To better understand the local and long-range effects that the Arg-to-Lys mutation has on the dynamic properties of the R-subunit, the amide hydrogen/deuterium exchange in the RIIbeta subunit was probed by electrospray mass spectrometry. Mutant proteins containing the Arg-to-Lys substitution in either cAMP-binding domain were deuterated for various times and then, prior to mass spectrometry analysis, subjected to pepsin digestion to localize the deuterium incorporation. Mutation of this Arg in cAB-A (Arg230) causes an increase in amide hydrogen exchange throughout the mutated domain that is beyond the modest and localized effects of cAMP removal and is indicative of the importance of this Arg in domain organization. Mutation of Arg359 (cAB-B) leads to increased exchange in the adjacent cAB-A domain, particularly in the cAB-A domain C-helix that lies on top of the cAB-B domain and is believed to be functionally linked to the cAB-B domain. This interdomain communication appears to be a unidirectional pathway, as mutation of Arg230 in cAB-A does not effect dynamics of the cAB-B domain.