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Literature DB >> 26359298

Two-color fluorescent analysis of connexin 36 turnover: relationship to functional plasticity.

Helen Yanran Wang¹, Ya-Ping Lin², Cheryl K Mitchell², Sripad Ram³, John O'Brien¹.

Abstract

Gap junctions formed of connexin 36 (Cx36, also known as Gjd2) show tremendous functional plasticity on several time scales. Changes in connexin phosphorylation modify coupling in minutes through an order of magnitude, but recent studies also imply involvement of connexin turnover in regulating cell-cell communication. We utilized Cx36 with an internal HaloTag to study Cx36 turnover and trafficking in cultured cells. Irreversible, covalent pulse-chase labeling with fluorescent HaloTag ligands allowed clear discrimination of newly formed and pre-existing Cx36. Cx36 in junctional plaques turned over with a half-life of 3.1 h, and the turnover rate was unchanged by manipulations of protein kinase A (PKA) activity. In contrast, changes in PKA activity altered coupling within 20 min. New Cx36 in cargo vesicles was added directly to existing gap junctions and newly made Cx36 was not confined to points of addition, but diffused throughout existing gap junctions. Existing connexins also diffused into photobleached areas with a half-time of less than 2 s. In conclusion, studies of Cx36-HaloTag revealed novel features of connexin trafficking and demonstrated that phosphorylation-based changes in coupling occur on a different time scale than turnover.

Entities: Gene

Keywords: Confocal microscopy; Connexin; Gap junction; Membrane trafficking; Pulse-chase; Tracer coupling

Mesh：

Substances：

Year: 2015 PMID： 26359298 PMCID： PMC4647165 DOI： 10.1242/jcs.162586

Source DB: PubMed Journal: J Cell Sci ISSN： 0021-9533 Impact factor: 5.285

68 in total

1. Multicolor and electron microscopic imaging of connexin trafficking.

Authors: Guido Gaietta; Thomas J Deerinck; Stephen R Adams; James Bouwer; Oded Tour; Dale W Laird; Gina E Sosinsky; Roger Y Tsien; Mark H Ellisman
Journal: Science Date: 2002-04-19 Impact factor: 47.728

Review 2. Molecular biology and genetics of gap junction channels.

Authors: N M Kumar; N B Gilula
Journal: Semin Cell Biol Date: 1992-02

3. Cloning and expression of two related connexins from the perch retina define a distinct subgroup of the connexin family.

Authors: J O'Brien; R Bruzzone; T W White; M R Al-Ubaidi; H Ripps
Journal: J Neurosci Date: 1998-10-01 Impact factor: 6.167

4. The effector and scaffolding proteins AF6 and MUPP1 interact with connexin36 and localize at gap junctions that form electrical synapses in rodent brain.

Authors: X Li; B D Lynn; J I Nagy
Journal: Eur J Neurosci Date: 2011-12-29 Impact factor: 3.386

5. Junctions form between catfish horizontal cells in culture.

Authors: S Hidaka; R Shingai; J E Dowling; K Naka
Journal: Brain Res Date: 1989-09-25 Impact factor: 3.252

6. Loss of connexin36 channels alters beta-cell coupling, islet synchronization of glucose-induced Ca2+ and insulin oscillations, and basal insulin release.

Authors: Magalie A Ravier; Martin Güldenagel; Anne Charollais; Asllan Gjinovci; Dorothée Caille; Goran Söhl; Claes B Wollheim; Klaus Willecke; Jean-Claude Henquin; Paolo Meda
Journal: Diabetes Date: 2005-06 Impact factor: 9.461

7. Expression of multiple connexins in cultured neonatal rat ventricular myocytes.

Authors: B J Darrow; J G Laing; P D Lampe; J E Saffitz; E C Beyer
Journal: Circ Res Date: 1995-03 Impact factor: 17.367

8. Proteolysis of connexin43-containing gap junctions in normal and heat-stressed cardiac myocytes.

Authors: J G Laing; P N Tadros; K Green; J E Saffitz; E C Beyer
Journal: Cardiovasc Res Date: 1998-06 Impact factor: 10.787

9. Diurnal and circadian regulation of connexin 36 transcript and protein in the mammalian retina.

Authors: Christiana Katti; Rachel Butler; Sumathi Sekaran
Journal: Invest Ophthalmol Vis Sci Date: 2013-01-28 Impact factor: 4.799

10. Development of a dehalogenase-based protein fusion tag capable of rapid, selective and covalent attachment to customizable ligands.

Authors: Lance P Encell; Rachel Friedman Ohana; Kris Zimmerman; Paul Otto; Gediminas Vidugiris; Monika G Wood; Georgyi V Los; Mark G McDougall; Chad Zimprich; Natasha Karassina; Randall D Learish; Robin Hurst; James Hartnett; Sarah Wheeler; Pete Stecha; Jami English; Kate Zhao; Jacqui Mendez; Hélène A Benink; Nancy Murphy; Danette L Daniels; Michael R Slater; Marjeta Urh; Aldis Darzins; Dieter H Klaubert; Robert F Bulleit; Keith V Wood
Journal: Curr Chem Genomics Date: 2012-10-05

22 in total

1. Zebrafish connexin 79.8 (Gja8a): A lens connexin used as an electrical synapse in some neurons.

Authors: Shunichi Yoshikawa; Alejandro Vila; Jasmin Segelken; Ya-Ping Lin; Cheryl K Mitchell; Duc Nguyen; John O'Brien
Journal: Dev Neurobiol Date: 2016-07-26 Impact factor: 3.964

2. Retinal Waves Modulate an Intraretinal Circuit of Intrinsically Photosensitive Retinal Ganglion Cells.

Authors: David A Arroyo; Lowry A Kirkby; Marla B Feller
Journal: J Neurosci Date: 2016-06-29 Impact factor: 6.167

3. Exendin-4 overcomes cytokine-induced decreases in gap junction coupling via protein kinase A and Epac2 in mouse and human islets.

Authors: Nikki L Farnsworth; Rachelle Walter; Robert A Piscopio; Wolfgang E Schleicher; Richard K P Benninger
Journal: J Physiol Date: 2018-11-29 Impact factor: 5.182

Two-color fluorescent analysis of connexin 36 turnover: relationship to functional plasticity.

1. Multicolor and electron microscopic imaging of connexin trafficking.

Review 2. Molecular biology and genetics of gap junction channels.

3. Cloning and expression of two related connexins from the perch retina define a distinct subgroup of the connexin family.

4. The effector and scaffolding proteins AF6 and MUPP1 interact with connexin36 and localize at gap junctions that form electrical synapses in rodent brain.

5. Junctions form between catfish horizontal cells in culture.

6. Loss of connexin36 channels alters beta-cell coupling, islet synchronization of glucose-induced Ca2+ and insulin oscillations, and basal insulin release.

7. Expression of multiple connexins in cultured neonatal rat ventricular myocytes.

8. Proteolysis of connexin43-containing gap junctions in normal and heat-stressed cardiac myocytes.

9. Diurnal and circadian regulation of connexin 36 transcript and protein in the mammalian retina.

10. Development of a dehalogenase-based protein fusion tag capable of rapid, selective and covalent attachment to customizable ligands.

1. Zebrafish connexin 79.8 (Gja8a): A lens connexin used as an electrical synapse in some neurons.

2. Retinal Waves Modulate an Intraretinal Circuit of Intrinsically Photosensitive Retinal Ganglion Cells.

3. Exendin-4 overcomes cytokine-induced decreases in gap junction coupling via protein kinase A and Epac2 in mouse and human islets.

4. A robust and economical pulse-chase protocol to measure the turnover of HaloTag fusion proteins.

Review 5. The electrical synapse: Molecular complexities at the gap and beyond.

Review 6. Design principles of electrical synaptic plasticity.

Review 7. Molecular mechanisms regulating formation, trafficking and processing of annular gap junctions.

8. Cysteine residues in the cytoplasmic carboxy terminus of connexins dictate gap junction plaque stability.

9. Nicotine protects rat hypoglossal motoneurons from excitotoxic death via downregulation of connexin 36.

10. The SNARE regulator Complexin3 is a target of the cone circadian clock.