Restricted distribution of connexin40, a gap junctional protein, in mammalian heart.

Gros, Daniël; Jarry-Guichard, T.; Velde, I. Ten; Mazière, Ann De; Kempen, Marjan J. A. van; Davoust, Jean; Briand, Jean‐Paul; Moorman, A. F. M.; Jongsma, Habo J.

doi:10.1161/01.res.74.5.839

Cited by 190 publications

(117 citation statements)

References 56 publications

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“…In adult mouse and rat hearts CX40 was shown to be expressed in the His bundle and the bundle branches (Gros et al, 1994. The present study demonstrates that CX40 is already expressed at 14 dpc in the early differentiating bundle branches on both sides of the growing interventricular septum.…”

Section: Distribution Of Cx40 In the Conduction Systemsupporting

confidence: 58%

“…In addition, in the adult rat and mouse, CX43 is also absent from the ventricular conduction tissue, i.e., the His bundle and the proximal part of the bundle branches (Van Kempen et al, 1991;Gourdie et al, 1992). Interestingly, CX40 distribution studies (Gourdie et al, 1993;Gros et al, 1994Gros et al, , 1995Van Kempen et al, 1995) showed that CX40 has a more restricted distribution than CX43 in adult mammalian hearts. These authors demonstrated that (2x40 is expressed not only in atria (depending on the species) but also in ventricular conduction system myocytes.…”

mentioning

confidence: 99%

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Developmental regulation of connexin 40 gene expression in mouse heart correlates with the differentiation of the conduction system

Delorme

Dahl

Jarry-Guichard

et al. 1995

Developmental Dynamics

154

108

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In adult mouse heart, CX40 is expressed in the atria and the proximal part of the ventricular conduction system (the His bundle and the upper parts of the bundle branches). This cardiac tissue is specialized in the conduction of the electrical impulse. CX40 is the only mouse connexin known to be expressed in these parts of the adult conductive tissue and is thus considered as a marker of the conduction system. In the present report, we investigated CX40 expression and distribution during mouse heart development. We first demonstrate that CX40 mRNA is regulated throughout development, as are other heart connexin transcripts, i.e., CX37, CX43, and (2x45, with a decreasing abundance as development proceeds. We also show that the CX40 transcript and protein are similarly regulated, CX40 being expressed as two different phosphorylated and un-phosphorylated forms of 41 and 40 kDa, respectively. Surprisingly, distribution studies demonstrated that CX40 is widely expressed in 11 days post-coitum (dpc) embryonic heart, where it is detected in both the atria and ventricle primordia. As development proceeds, the CX40 distribution pattern in the atria is maintained, whereas a more dynamic pattern is observed in the ventricles. From 14 dpc onwards, as the adult ventricular conduction system differentiates, CX40 decreases in the trabecular network and it is preferentially distributed in the ventricular conduction system. CX40 is thus the marker of the early differentiating conduction system. It is hypothesized that the conduction system is present in unorganized "embryonic" form at 11 dpc and trans-differentiates by 14 dpc into the adult conduction system. 0 1995 Wiley-Liss, Inc.

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Section: Distribution Of Cx40 In the Conduction Systemsupporting

confidence: 58%

mentioning

confidence: 99%

Developmental regulation of connexin 40 gene expression in mouse heart correlates with the differentiation of the conduction system

Delorme

Dahl

Jarry-Guichard

et al. 1995

Developmental Dynamics

154

108

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“…The difference in yi(main state) between Cx4O and Cx4O*43El,2 channels was surprising, since both connexins presumably possessed the same four transmembrane domains Ml-M4. In the case of heterotypic (Bruzzone et al, 1993) and human HeLa cells (Elfgang et al, 1995 surrounding working myocardium expresses Cx43 (Bastide et al, 1993;Gros et al, 1994 (Elfgang et al, 1995 Figure 3C). Previously, it had been shown that each immunofluorescent signal on contacting membranes of primary hepatocytes coincided with a gap junctional plaque (Dermietzel et al, 1987).…”

Section: Docking and Formation Of Heterotypic Gap Junctionsmentioning

confidence: 99%

“…This functional incompatibility is likely to contribute to the preferential propagation of action potentials along the bundles of murine conductive myocardiocytes (expressing Cx4O) which are surrounded by the working myocardium (expressing Cx43; Bastide et al, 1993;Gros et al, 1994). As yet, the molecular determinants causing the incompatibility between Cx4O and Cx43 hemichannels were not known.…”

Section: Introductionmentioning

confidence: 99%

Incompatibility of connexin 40 and 43 Hemichannels in gap junctions between mammalian cells is determined by intracellular domains.

Haubrich

Schwarz

Bukauskas

et al. 1996

MBoC

104

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Murine connexin 40 (Cx4O) and connexin 43 (Cx43) do not form functional heterotypic gap junction channels. This property may contribute to the preferential propagation of action potentials in murine conductive myocardium (expressing Cx4O) which is surrounded by working myocardium, expressing Cx43. When mouse Cx4O and Cx43 were individually expressed in cocultured human HeLa cells, no punctate immunofluorescent signals were detected on apposed plasma membranes between different transfectants, using antibodies specific for each connexin, suggesting that Cx40 and Cx43 hemichannels do not dock to each other. We wanted to identify domains in these connexin proteins which are responsible for the incompatibility. Thus, we expressed in HeLa cells several chimeric gene constructs in which different extracellular and intracellular domains of Cx43 had been spliced into the corresponding regions of Cx4O. We found that exchange of both extracellular loops (El and E2) in this system (Cx40*43E1,2) was required for formation of homotypic and heterotypic conductive channels, although the electrical properties differed from those of Cx4O or Cx43 channels. Thus, the extracellular domains of Cx43 can be directed to form functional homo-and heterotypic channels. Another chimeric construct in which both extracellular domains and the central cytoplasmic loop (El, E2, and C2) of Cx43 were spliced into Cx4O (Cx4O*43E1,2,C2) led to heterotypic coupling only with Cx43 and not with Cx4O transfectants. Thus, the central cytoplasmic loop of Cx43 contributed to selectivity. A third construct, in which only the C-terminal domain (C3) of Cx43 was spliced into Cx4O, i.e., Cx4O*43C3, showed neither homotypic nor heterotypic coupling with Cx4O and Cx43 transfectants, suggesting that the Cterminal region of Cx43 determined incompatibility.

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“…Cx40, Cx43 and Cx45 are the most abundant connexin isoforms of the working mammalian myocardial cells and the conduction system. Cx40 is mainly expressed in the atrium and in the conduction system [44][45][46][47][48][49], while Cx43 can be found both in atrial and ventricular cells but not in sinoatrial and atrioventricular nodes [46,[48][49][50][51][52][53][54][55]. Cx45 is preferentially expressed in sinoatrial and atrioventricular nodes, His-bundle and bundle branches [56][57][58].…”

Section: The Distribution Of Gap Junctionsmentioning

confidence: 99%

Chemistry, Physiology, and Pharmacology of β.-Adrenergic Mechanisms in the Heart. Why are .β-Blocker Antiarrhythmics Superior?

Szentmiklósi¹,

Szentandrássy²,

Hegyi³

et al. 2014

CPD

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The short-term beat-to-beat variability of cardiac action potential duration (SBVR) occurs as a random alteration of the ventricular repolarization duration. SBVR has been suggested to be more predictive of the development of lethal arrhythmias than the action potential prolongation or QT prolongation of ECG alone. The mechanism underlying SBVR is not completely understood but it is known that SBVR depends on stochastic ion channel gating, intracellular calcium handling and intercellular coupling.Coupling of single cardiomyocytes significantly decreases the beat-to-beat changes in action potential duration (APD) due to the electrotonic current flow between neighboring cells. The magnitude of this electrotonic current depends on the intercellular gap junction resistance. Reduced gap junction resistance causes greater electrotonic current flow between cells, and reduces SBVR.Myocardial ischaemia (MI) is known to affect gap junction channel protein expression and function. MI increases gap junction resistance that leads to slow conduction, APD and refractory period dispersion, and an increase in SBVR. Ultimately, development of reentry arrhythmias and fibrillation are associated post-MI. Antiarrhythmic drugs have proarrhythmic side effects requiring alternative approaches. A novel idea is to target gap junction channels. Specifically, the use of gap junction channel enhancers and inhibitors may help to reveal the precise role of gap junctions in the development of arrhythmias. Since cell-to-cell coupling is represented in SBVR, this parameter can be used to monitor the degree of coupling of myocardium.

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Restricted distribution of connexin40, a gap junctional protein, in mammalian heart.

Cited by 190 publications

References 56 publications

Developmental regulation of connexin 40 gene expression in mouse heart correlates with the differentiation of the conduction system

Developmental regulation of connexin 40 gene expression in mouse heart correlates with the differentiation of the conduction system

Incompatibility of connexin 40 and 43 Hemichannels in gap junctions between mammalian cells is determined by intracellular domains.

Chemistry, Physiology, and Pharmacology of β.-Adrenergic Mechanisms in the Heart. Why are .β-Blocker Antiarrhythmics Superior?

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Restricted distribution of connexin40, a gap junctional protein, in mammalian heart.

Cited by 190 publications

References 56 publications

Developmental regulation of connexin 40 gene expression in mouse heart correlates with the differentiation of the conduction system

Developmental regulation of connexin 40 gene expression in mouse heart correlates with the differentiation of the conduction system

Incompatibility of connexin 40 and 43 Hemichannels in gap junctions between mammalian cells is determined by intracellular domains.

Chemistry, Physiology, and Pharmacology of &#946;.-Adrenergic Mechanisms in the Heart. Why are .&#946;-Blocker Antiarrhythmics Superior?

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Chemistry, Physiology, and Pharmacology of β.-Adrenergic Mechanisms in the Heart. Why are .β-Blocker Antiarrhythmics Superior?