Discovery of allostery in PKA signaling #MMPMID26097522
Zhang P; Kornev AP; Wu J; Taylor SS
Biophys Rev 2015[Jun]; 7 (2): 227-38 PMID26097522show ga
Cyclic AMP (cAMP)-dependent protein kinase (PKA) was the second protein kinase to be identified, and the PKA catalytic (C)-subunit serves as a prototype for the large protein kinase superfamily that contains over 500 gene products. The protein kinases regulate many biological functions in eukaryotic cells and are now also a major therapeutic target. The discovery of PKA nearly 50 years ago was quickly followed by the identification of the regulatory subunits that bind cAMP and release the catalytic activity from the holoenzyme. Thus in PKA we see the convergence of two major signaling mechanisms?protein phosphorylation and second messenger signaling through cAMP. Crystallography provides a foundation for understanding function, and detailed knowledge of the structure of the isolated regulatory (R)- and catalytic (C)-subunits has been extremely informative. Yet it is the R2C2 holoenzyme that predominates in cells, and the allosteric features of PKA signaling can only be fully appreciated by seeing the full-length protein. The symmetry and the quaternary constraints that one R:C heterodimer exerts on the other in the holoenzyme simply are not present in the isolated subunits or even in the R:C heterodimer.