4d4y Citations

Allosteric regulation of focal adhesion kinase by PIP₂ and ATP.

Zhou J, Bronowska A, Le Coq J, Lietha D, Gräter F
Biophys J 108 698-705 (2015)
Related entries: 4d4r, 4d4s, 4d4v, 4d55, 4d58, 4d5h, 4d5k

Cited: 20 times
EuropePMC logo PMID: 25650936

Abstract

Focal adhesion kinase (FAK) is a nonreceptor tyrosine kinase that regulates cell signaling, proliferation, migration, and development. A major mechanism of regulation of FAK activity is an intramolecular autoinhibitory interaction between two of its domains--the catalytic and FERM domains. Upon cell adhesion to the extracellular matrix, FAK is being translocated toward focal adhesion sites and activated. Interactions of FAK with phosphoinositide phosphatidylinsositol-4,5-bis-phosphate (PIP₂) are required to activate FAK. However, the molecular mechanism of the activation remains poorly understood. Recent fluorescence resonance energy transfer experiments revealed a closure of the FERM-kinase interface upon ATP binding, which is reversed upon additional binding of PIP₂. Here, we addressed the allosteric regulation of FAK by performing all-atom molecular-dynamics simulations of a FAK fragment containing the catalytic and FERM domains, and comparing the dynamics in the absence or presence of ATP and PIP₂. As a major conformational change, we observe a closing and opening motion upon ATP and additional PIP₂ binding, respectively, in good agreement with the fluorescence resonance energy transfer experiments. To reveal how the binding of the regulatory PIP₂ to the FERM F2 lobe is transduced to the very distant F1/N-lobe interface, we employed force distribution analysis. We identified a network of mainly charged residue-residue interactions spanning from the PIP₂ binding site to the distant interface between the kinase and FERM domains, comprising candidate residues for mutagenesis to validate the predicted mechanism of FAK activation.

Reviews citing this publication (6)

  1. Revisiting Netrin-1: One Who Guides (Axons). Boyer NP, Gupton SL. Front Cell Neurosci 12 221 (2018)
  2. Characterization of Lipid-Protein Interactions and Lipid-Mediated Modulation of Membrane Protein Function through Molecular Simulation. Muller MP, Jiang T, Sun C, Lihan M, Pant S, Mahinthichaichan P, Trifan A, Tajkhorshid E. Chem Rev 119 6086-6161 (2019)
  3. Review of PIP2 in Cellular Signaling, Functions and Diseases. Mandal K. Int J Mol Sci 21 E8342 (2020)
  4. Interplay between mechanics and signalling in regulating cell fate. De Belly H, Paluch EK, Chalut KJ. Nat Rev Mol Cell Biol 23 465-480 (2022)
  5. FAK inhibitors as promising anticancer targets: present and future directions. Mustafa M, Abd El-Hafeez AA, Abdelhafeez DA, Abdelhamid D, Mostafa YA, Ghosh P, Hayallah AM, A Abuo-Rahma GE. Future Med Chem 13 1559-1590 (2021)
  6. A regulatory role of membrane by direct modulation of the catalytic kinase domain. Prakash P. Small GTPases 12 246-256 (2021)

Articles citing this publication (14)

  1. Phosphatidylinositol 4,5-Bisphosphate Modulates the Affinity of Talin-1 for Phospholipid Bilayers and Activates Its Autoinhibited Form. Ye X, McLean MA, Sligar SG. Biochemistry 55 5038-5048 (2016)
  2. MARCKS Is Necessary for Netrin-DCC Signaling and Corpus Callosum Formation. Brudvig JJ, Cain JT, Schmidt-Grimminger GG, Stumpo DJ, Roux KJ, Blackshear PJ, Weimer JM. Mol Neurobiol 55 8388-8402 (2018)
  3. T cells transduce T-cell receptor signal strength by generating different phosphatidylinositols. Hawse WF, Cattley RT. J Biol Chem 294 4793-4805 (2019)
  4. Dynamic Allostery of the Catabolite Activator Protein Revealed by Interatomic Forces. Louet M, Seifert C, Hensen U, Gräter F. PLoS Comput Biol 11 e1004358 (2015)
  5. Novel Phosphotidylinositol 4,5-Bisphosphate Binding Sites on Focal Adhesion Kinase. Feng J, Mertz B. PLoS One 10 e0132833 (2015)
  6. Oncogenic Mutations Differentially Affect Bax Monomer, Dimer, and Oligomeric Pore Formation in the Membrane. Zhang M, Zheng J, Nussinov R, Ma B. Sci Rep 6 33340 (2016)
  7. Transforming growth factor β (TGF-β) receptor signaling regulates kinase networks and phosphatidylinositol metabolism during T-cell activation. Cattley RT, Lee M, Boggess WC, Hawse WF. J Biol Chem 295 8236-8251 (2020)
  8. ZINC40099027 activates human focal adhesion kinase by accelerating the enzymatic activity of the FAK kinase domain. Rashmi, More SK, Wang Q, Vomhof-DeKrey EE, Porter JE, Basson MD. Pharmacol Res Perspect 9 e00737 (2021)
  9. Niban apoptosis regulator 1 promotes gemcitabine resistance by activating the focal adhesion kinase signaling pathway in bladder cancer. Tong S, Yin H, Fu J, Li Y. J Cancer 13 1103-1118 (2022)
  10. Molecular Docking, Molecular Dynamics Simulations, and Free Energy Calculation Insights into the Binding Mechanism between VS-4718 and Focal Adhesion Kinase. Shi M, Chen T, Wei S, Zhao C, Zhang X, Li X, Tang X, Liu Y, Yang Z, Chen L. ACS Omega 7 32442-32456 (2022)
  11. Phospholipid binding to the FAK catalytic domain impacts function. Hall JE, Schaller MD. PLoS One 12 e0172136 (2017)
  12. Polarized focal adhesion kinase activity within a focal adhesion during cell migration. Li X, Combs JD, Salaita K, Shu X. Nat Chem Biol 19 1458-1468 (2023)
  13. Singular value decomposition for the correlation of atomic fluctuations with arbitrary angle. Yu M, Ma X, Cao H, Chong B, Lai L, Liu Z. Proteins 86 1075-1087 (2018)
  14. Three-Dimensional-QSAR and Relative Binding Affinity Estimation of Focal Adhesion Kinase Inhibitors. Ghosh S, Cho SJ. Molecules 28 1464 (2023)


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