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Literature DB >> 16112650

Calcium-dependent binding of calmodulin to neuronal gap junction proteins.

Gary S Burr¹, Cheryl K Mitchell, Yenabi J Keflemariam, Ruth Heidelberger, John O'Brien.

Abstract

We examined the interactions of calmodulin with neuronal gap junction proteins connexin35 (Cx35) from perch, its mouse homologue Cx36, and the related perch Cx34.7 using surface plasmon resonance. Calmodulin bound to the C-terminal domains of all three connexins with rapid kinetics in a concentration- and Ca2+-dependent manner. Dissociation was also very rapid. K(d)'s for calmodulin binding at a high-affinity site ranged from 11 to 72 nM, and K(1/2)'s for Ca2+ were between 3 and 5 microM. No binding to the intracellular loops was observed. Binding competition experiments with synthetic peptides mapped the calmodulin binding site to a 10-30 amino acid segment at the beginning of the C-terminal domain of Cx36. The micromolar K(1/2)'s and rapid on and off rates suggest that this interaction may change dynamically in neurons, and may occur transiently when Ca2+ is elevated to a level that would occur in the near vicinity of an activated synapse.

Entities: Chemical Gene Species

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Year: 2005 PMID： 16112650 PMCID： PMC2222552 DOI： 10.1016/j.bbrc.2005.08.007

Source DB: PubMed Journal: Biochem Biophys Res Commun ISSN： 0006-291X Impact factor: 3.575

32 in total

1. Functional characteristics of skate connexin35, a member of the gamma subfamily of connexins expressed in the vertebrate retina.

Authors: T W White; M R Deans; J O'Brien; M R Al-Ubaidi; D A Goodenough; H Ripps; R Bruzzone
Journal: Eur J Neurosci Date: 1999-06 Impact factor: 3.386

2. Functional expression of the murine connexin 36 gene coding for a neuron-specific gap junctional protein.

Authors: B Teubner; J Degen; G Söhl; M Güldenagel; F F Bukauskas; E B Trexler; V K Verselis; C I De Zeeuw; C G Lee; C A Kozak; E Petrasch-Parwez; R Dermietzel; K Willecke
Journal: J Membr Biol Date: 2000-08-01 Impact factor: 1.843

Review 3. Connexin domains relevant to the chemical gating of gap junction channels.

Authors: C Peracchia; X C Wang
Journal: Braz J Med Biol Res Date: 1997-05 Impact factor: 2.590

4. Calmodulin directly gates gap junction channels.

Authors: C Peracchia; A Sotkis; X G Wang; L L Peracchia; A Persechini
Journal: J Biol Chem Date: 2000-08-25 Impact factor: 5.157

Review 5. Calmodulin: a prototypical calcium sensor.

Authors: D Chin; A R Means
Journal: Trends Cell Biol Date: 2000-08 Impact factor: 20.808

6. Protein kinase A mediates regulation of gap junctions containing connexin35 through a complex pathway.

Authors: Xiaosen Ouyang; Virginia M Winbow; Leena S Patel; Gary S Burr; Cheryl K Mitchell; John O'Brien
Journal: Brain Res Mol Brain Res Date: 2005-04-27

7. Short-range functional interaction between connexin35 and neighboring chemical synapses.

Authors: A Pereda; J O'Brien; J I Nagy; M Smith; F Bukauskas; K G V Davidson; N Kamasawa; T Yasumura; J E Rash
Journal: Cell Commun Adhes Date: 2003 Jul-Dec

8. Dopamine D2 receptor-mediated modulation of rod-cone coupling in the Xenopus retina.

Authors: D Krizaj; R Gábriel; W G Owen; P Witkovsky
Journal: J Comp Neurol Date: 1998-09-07 Impact factor: 3.215

9. Connexin35 mediates electrical transmission at mixed synapses on Mauthner cells.

Authors: A Pereda; J O'Brien; J I Nagy; F Bukauskas; K G V Davidson; N Kamasawa; T Yasumura; J E Rash
Journal: J Neurosci Date: 2003-08-20 Impact factor: 6.167

10. Calmodulin colocalizes with connexins and plays a direct role in gap junction channel gating.

Authors: A Sotkis; X G Wang; T Yasumura; L L Peracchia; A Persechini; J E Rash; C Peracchia
Journal: Cell Commun Adhes Date: 2001

25 in total

Review 1. The gap junction cellular internet: connexin hemichannels enter the signalling limelight.

Authors: W Howard Evans; Elke De Vuyst; Luc Leybaert
Journal: Biochem J Date: 2006-07-01 Impact factor: 3.857

2. The neuronal connexin36 interacts with and is phosphorylated by CaMKII in a way similar to CaMKII interaction with glutamate receptors.

Authors: Cantas Alev; Stephanie Urschel; Stephan Sonntag; Georg Zoidl; Alfredo G Fort; Thorsten Höher; Mamoru Matsubara; Klaus Willecke; David C Spray; Rolf Dermietzel
Journal: Proc Natl Acad Sci U S A Date: 2008-12-18 Impact factor: 11.205

Review 3. Gap junctions.

Authors: Morten Schak Nielsen; Lene Nygaard Axelsen; Paul L Sorgen; Vandana Verma; Mario Delmar; Niels-Henrik Holstein-Rathlou
Journal: Compr Physiol Date: 2012-07 Impact factor: 9.090

4. A calcium-dependent pathway underlies activity-dependent plasticity of electrical synapses in the thalamic reticular nucleus.

Authors: Jessica Sevetson; Sarah Fittro; Emily Heckman; Julie S Haas
Journal: J Physiol Date: 2017-05-26 Impact factor: 5.182

5. Molecular and functional asymmetry at a vertebrate electrical synapse.

Authors: John E Rash; Sebastian Curti; Kimberly G Vanderpool; Naomi Kamasawa; Srikant Nannapaneni; Nicolas Palacios-Prado; Carmen E Flores; Thomas Yasumura; John O'Brien; Bruce D Lynn; Feliksas F Bukauskas; James I Nagy; Alberto E Pereda
Journal: Neuron Date: 2013-09-04 Impact factor: 17.173

Review 6. Gap junction regulation by calmodulin.

Authors: Juan Zou; Mani Salarian; Yanyi Chen; Richard Veenstra; Charles F Louis; Jenny J Yang
Journal: FEBS Lett Date: 2014-01-16 Impact factor: 4.124

7. Regulation of neuronal connexin-36 channels by pH.

Authors: Daniel González-Nieto; Juan M Gómez-Hernández; Belén Larrosa; Cristina Gutiérrez; María D Muñoz; Ilaria Fasciani; John O'Brien; Agata Zappalà; Federico Cicirata; Luis C Barrio
Journal: Proc Natl Acad Sci U S A Date: 2008-10-28 Impact factor: 11.205