2g5m Citations

Structural basis for spinophilin-neurabin receptor interaction.

Kelker MS, Dancheck B, Ju T, Kessler RP, Hudak J, Nairn AC, Peti W
Biochemistry 46 2333-44 (2007)
Cited: 22 times
EuropePMC logo PMID: 17279777

Abstract

Neurabin and spinophilin are neuronal scaffolding proteins that play important roles in the regulation of synaptic transmission through their ability to target protein phosphatase 1 (PP1) to dendritic spines where PP1 dephosphorylates and inactivates glutamate receptors. However, thus far, it is still unknown how neurabin and spinophilin themselves are targeted to these membrane receptors. Spinophilin and neurabin contain a single PDZ domain, a common protein-protein interaction recognition motif, which are 86% identical in sequence. We report the structures of both the neurabin and spinophilin PDZ domains determined using biomolecular NMR spectroscopy. These proteins form the canonical PDZ domain fold. However, despite their high degree of sequence identity, there are distinct and significant structural differences between them, especially between the peptide binding pockets. Using two-dimensional 1H-15N HSQC NMR analysis, we demonstrate that C-terminal peptide ligands derived from glutamatergic AMPA and NMDA receptors and cytosolic proteins directly and differentially bind spinophilin and neurabin PDZ domains. This peptide binding data also allowed us to classify the neurabin and spinophilin PDZ domains as the first identified neuronal hybrid class V PDZ domains, which are capable of binding both class I and II peptides. Finally, the ability to bind to glutamate receptor subunits suggests that the PDZ domains of neurabin and spinophilin are important for targeting PP1 to C-terminal phosphorylation sites in AMPA and NMDA receptor subunits.

Reviews citing this publication (5)

  1. The extended PP1 toolkit: designed to create specificity. Bollen M, Peti W, Ragusa MJ, Beullens M. Trends Biochem Sci 35 450-458 (2010)
  2. Protein Serine/Threonine Phosphatases: Keys to Unlocking Regulators and Substrates. Brautigan DL, Shenolikar S. Annu Rev Biochem 87 921-964 (2018)
  3. PDZ Protein Regulation of G Protein-Coupled Receptor Trafficking and Signaling Pathways. Dunn HA, Ferguson SS. Mol Pharmacol 88 624-639 (2015)
  4. A survey of the year 2007 literature on applications of isothermal titration calorimetry. Bjelić S, Jelesarov I. J Mol Recognit 21 289-312 (2008)
  5. Modulation of dendritic spines by protein phosphatase-1. Platholi J, Hemmings HC. Adv Pharmacol 90 117-144 (2021)

Articles citing this publication (17)

  1. Mu-opioid receptors transiently activate the Akt-nNOS pathway to produce sustained potentiation of PKC-mediated NMDAR-CaMKII signaling. Sánchez-Blázquez P, Rodríguez-Muñoz M, Garzón J. PLoS One 5 e11278 (2010)
  2. Molecular investigations of the structure and function of the protein phosphatase 1-spinophilin-inhibitor 2 heterotrimeric complex. Dancheck B, Ragusa MJ, Allaire M, Nairn AC, Page R, Peti W. Biochemistry 50 1238-1246 (2011)
  3. The histidine triad nucleotide-binding protein 1 supports mu-opioid receptor-glutamate NMDA receptor cross-regulation. Rodríguez-Muñoz M, Sánchez-Blázquez P, Vicente-Sánchez A, Bailón C, Martín-Aznar B, Garzón J. Cell Mol Life Sci 68 2933-2949 (2011)
  4. Actin and Actin-Binding Proteins: Masters of Dendritic Spine Formation, Morphology, and Function. Lin WH, Webb DJ. Open Neurosci J 3 54-66 (2009)
  5. Differential association of postsynaptic signaling protein complexes in striatum and hippocampus. Baucum AJ, Brown AM, Colbran RJ. J Neurochem 124 490-501 (2013)
  6. There is Diversity in Disorder-"In all Chaos there is a Cosmos, in all Disorder a Secret Order". Nielsen JT, Mulder FA. Front Mol Biosci 3 4 (2016)
  7. Flexibility in the PP1:spinophilin holoenzyme. Ragusa MJ, Allaire M, Nairn AC, Page R, Peti W. FEBS Lett 585 36-40 (2011)
  8. Conformational change upon ligand binding and dynamics of the PDZ domain from leukemia-associated Rho guanine nucleotide exchange factor. Liu J, Zhang J, Yang Y, Huang H, Shen W, Hu Q, Wang X, Wu J, Shi Y. Protein Sci 17 1003-1014 (2008)
  9. The guanine nucleotide exchange factor (GEF) Asef2 promotes dendritic spine formation via Rac activation and spinophilin-dependent targeting. Evans JC, Robinson CM, Shi M, Webb DJ. J Biol Chem 290 10295-10308 (2015)
  10. A single question to screen for major depression in the general population. Le Strat Y, Dubertret C. Compr Psychiatry 54 831-834 (2013)
  11. Analysis of synaptic gene expression in the neocortex of primates reveals evolutionary changes in glutamatergic neurotransmission. Muntané G, Horvath JE, Hof PR, Ely JJ, Hopkins WD, Raghanti MA, Lewandowski AH, Wray GA, Sherwood CC. Cereb Cortex 25 1596-1607 (2015)
  12. Role of the multidomain protein spinophilin in blood pressure and cardiac function regulation. da Costa-Goncalves AC, Tank J, Plehm R, Diedrich A, Todiras M, Gollasch M, Heuser A, Wellner M, Bader M, Jordan J, Luft FC, Gross V. Hypertension 52 702-707 (2008)
  13. Functional and structural recovery of the injured spinal cord in rats treated with gonadotropin-releasing hormone. Calderón-Vallejo D, Quintanar-Stephano A, Hernández-Jasso I, Jiménez-Hernández V, Ruiz-Ornelas J, Jiménez I, Quintanar JL. Neurochem Res 40 455-462 (2015)
  14. Structure-function analysis of the filamentous actin binding domain of the neuronal scaffolding protein spinophilin. Schüler H, Peti W. FEBS J 275 59-68 (2008)
  15. Structural characterization of the neurabin sterile alpha motif domain. Ju T, Ragusa MJ, Hudak J, Nairn AC, Peti W. Proteins 69 192-198 (2007)
  16. Spinophilin and the immune synapse. Seed B, Xavier R. J Cell Biol 181 181-183 (2008)
  17. Backbone and sidechain (1)H, (15)N and (13)C assignments of the human G-actin binding protein profilin IIa. Ju T, Peti W. Biomol NMR Assign 1 205-207 (2007)


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