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A chimeric mechanism for polyvalent trans-phosphorylation of PKA by PDK1

  1. Robert A. Romano1,
  2. Natarajan Kannan2,
  3. Alexandr P. Kornev3,
  4. Craig J. Allison3,
  5. Susan S. Taylor1,3,4,*

Article first published online: 29 APR 2009

DOI: 10.1002/pro.146

Issue

Protein Science

Protein Science

Volume 18, Issue 7, pages 1486–1497, July 2009

Additional Information

How to Cite

Romano, R. A., Kannan, N., Kornev, A. P., Allison, C. J. and Taylor, S. S. (2009), A chimeric mechanism for polyvalent trans-phosphorylation of PKA by PDK1. Protein Science, 18: 1486–1497. doi: 10.1002/pro.146

Author Information

  1. 1

    Departments of Chemistry and Biochemistry, University of California San Diego, La Jolla, California 92093-0654

  2. 2

    Department of Biochemistry and Molecular Biology and Institute of Bioinformatics, University of Georgia, Athens, Georgia 30602

  3. 3

    Howard Hughes Medical Institute, University of California San Diego, La Jolla, California 92093-0654

  4. 4

    Department of Pharmacology, University of California San Diego, La Jolla, California 92093-0654

*9500 Gilman Drive, La Jolla, CA 92093-0654

Publication History

  1. Issue published online: 23 JUN 2009
  2. Article first published online: 29 APR 2009
  3. Accepted manuscript online: 29 APR 2009 12:00AM EST
  4. Manuscript Accepted: 9 APR 2009
  5. Manuscript Revised: 6 APR 2009
  6. Manuscript Received: 18 FEB 2009

Funded by

  • NIH grant. Grant Number: GM19301

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Keywords:

  • PKA;
  • PDK1;
  • AGC kinases;
  • C-tail;
  • phosphorylation;
  • Ade motif;
  • HF motif;
  • turn motif

Abstract

Phosphorylation on the activation loop of AGC kinases is typically mediated by PDK1. The precise mechanism for this in-trans phosphorylation is unknown; however, docking of a hydrophobic (HF) motif in the C-tail of the substrate kinase onto the N-lobe of PDK1 is likely an essential step. Using a peptide array of PKA to identify other PDK1-interacting sites, we discovered a second AGC-conserved motif in the C-tail that interacts with PDK1. Since this motif [FD(X)1-2Y/F] lies in the active site tether region and in PKA contributes to ATP binding, we call it the Adenosine binding (Ade) motif. The Ade motif is conserved as a PDK1-interacting site in Akt and PRK2, and we predict it will be a PDK1-interacting site for most AGC kinases. In PKA, the HF motif is only recognized when the turn motif Ser338 is phosphorylated, possibly serving as a phosphorylation “switch” that regulates how the Ade and HF motifs interact with PDK1. These results demonstrate that the extended AGC C-tail serves as a polyvalent element that trans-regulates PDK1 for catalysis. Modeling of the PKA C-tail onto PDK1 structure creates two chimeric sites; the ATP binding pocket, which is completed by the Ade motif, and the C-helix, which is positioned by the HF motif. Together, they demonstrate substrate-assisted catalysis involving two kinases that have co-evolved as symbiotic partners. The highly regulated turn motifs are the most variable part of the AGC C-tail. Elucidating the highly regulated cis and trans functions of the AGC tail is a significant future challenge.

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