Jane Jourdan

Connexin 43 connexon to gap junction transition is regulated by zonula occludens-1

Cx43 gap junctions (GJs) are integral to the function of the mammalian heart. It is shown that ZO-1 dynamically regulates the transition between Cx43 connexons and GJ intercellular channels, determining the balance of connexon-mediated cell permeability to GJ communication. Importantly, a novel domain proximal to GJs is identified—the perinexus.

Fusion of GFP to the carboxyl terminus of connexin43 increases gap junction size in HeLa cells.

The pattern of gap junctional coupling between cells is thought to be important for the proper function of many types of tissues. At present, little is known about the molecular mechanisms that control the size and distribution of gap junctions. We addressed this issue by expressing connexin43 (Cx43) constructs in HeLa cells, a connexin-deficient cell line. HeLa cells expressing exogenously introduced wild-type Cx43 formed small, punctate gap junctions. By contrast, cells expressing Cx43-GFP formed large, sheet-like gap junctions. These results suggest that the GFP tag, which is fused to the carboxyl terminus of Cx43, alters gap junction size by masking the carboxyl terminal amino acids of Cx43 that comprise a zonula occludins-1 (ZO-1) binding site. We are currently testing this hypothesis using deletion and dominant-negative constructs that directly target the interaction between Cx43 and ZO-1.

Cx43 Associates with Na v 1.5 in the Cardiomyocyte Perinexus

Gap junctions (GJs) are aggregates of channels that provide for direct cytoplasmic connection between cells. Importantly, this connection is thought responsible for cell-to-cell transfer of the cardiac action potential. The GJ channels of ventricular myocytes are composed of connexin43 (Cx43). Interaction of Cx43 with zonula occludens-1 (ZO-1) is localized not only at the GJ plaque, but also to the region surrounding the GJ, the perinexus. Cx43 in the perinexus is not detectable by immunofluorescence, yet localization of Cx43/ZO-1 interaction to this region indicated the presence of Cx43. Therefore, we hypothesized that Cx43 occurs in the perinexus at a lower concentration per unit membrane than in the GJ itself, making it difficult to visualize. To overcome this, the Duolink protein–protein interaction assay was used to detect Cx43. Duolink labeling of cardiomyocytes localized Cx43 to the perinexus. Quantification demonstrated that signal in the perinexus was lower than in the GJ but significantly higher than in nonjunctional regions. Additionally, Duolink of Triton X-100-extracted cultures suggested that perinexal Cx43 is nonjunctional. Importantly, the voltage gated sodium channel Nav1.5, which is responsible for initiation of the action potential, was found to interact with perinexal Cx43 but not with ZO-1. This work provides a detailed characterization of the structure of the perinexus at the GJ edge and indicates that one of its potential functions in the heart may be in facilitating conduction of action potential.

The Unstoppable Connexin43 Carboxyl-Terminus New Roles in Gap Junction Organization and Wound Healing

Abstract:  Intercellular connectivity mediated by gap junctions (GJs) composed of connexin43 (C×43) is critical to the function of excitable tissues such as the heart and brain. Disruptions to C×43 GJ organization are thought to be a factor in cardiac arrhythmias and are also implicated in epilepsy. This article is based on a presentation to the 4th Larry and Horti Fairberg Workshop on Interactive and Integrative Cardiology and summarizes the work of Gourdie and his lab on C×43 GJs in the heart. Background and perspective of recently published studies on the function of C×43‐interacting protein zonula occludens‐(ZO)‐1 in determining the organization of GJ plaques are provided. In addition how a peptide containing a PDZ‐binding sequence of C×43, developed as part of the work on cardiac GJ organization is also described, which has led to evidence for novel and unexpected roles for C×43 in modulating healing following tissue injury.

Quantitative Analysis of ZO-1 Colocalization with Cx43 Gap Junction Plaques in Cultures of Rat Neonatal Cardiomyocytes

The gap junction (GJ) is an aggregate of intercellular channels that facilitates cytoplasmic interchange of ions, second messengers, and other molecules of less than 1000 Da between cells. In excitable organs such as heart and brain, GJs configure extended intercellular pathways for stable and long-term propagation of action potential. In a previous study in adult rat heart, we have shown that the Drosophila disks-large related protein ZO-1 shows low to moderate colocalization at myocyte borders with the GJ protein Cx43. In the present study, we detail a protocol for characterizing the pattern and level of colocalization of ZO-1 with Cx43 in cultures of neonatal myocytes at the level of individual GJ plaques. The data indicate that ZO-1 shows on average a partial 26.6% overlap (SD = 11.3%) with Cx43 GJ plaques. There is a strong positive correlation between GJ plaque size and area of ZO-1 colocalization, indicating that the level of associated ZO-1 scales with the area of the GJ plaque. Qualitatively, the most prominent colocalization occurs at the plaque perimeter. These studies may provide insight into the presently unknown biological function of ZO-1 interaction with Cx43.

ZO-1 determines adherens and gap junction localization at intercalated disks

The disruption of the spatial order of electromechanical junctions at myocyte-intercalated disks (ICDs) is a poorly understood characteristic of many cardiac disease states. Here, in vitro and in vivo evidence is provided that zonula occludens-1 (ZO-1) regulates the organization of gap junctions (GJs) and adherens junctions (AJs) at ICDs. We investigated the contribution of ZO-1 to cell-cell junction localization by expressing a dominant-negative ZO-1 construct (DN-ZO-1) in rat ventricular myocytes (VMs). The expression of DN-ZO-1 in cultured neonatal VMs for 72 h reduced the interaction of ZO-1 and N-cadherin, as assayed by colocalization and coimmunoprecipitation, prompting cytoplasmic internalization of AJ and GJ proteins. DN-ZO-1 expression in adult VMs in vivo also reduced N-cadherin colocalization with ZO-1, a phenomenon not observed when the connexin-43 (Cx43)-ZO-1 interaction was disrupted using a mimetic of the ZO-1-binding ligand from Cx43. DN-ZO-1-infected VMs demonstrated large GJs at the ICD periphery and showed a loss of focal ZO-1 concentrations along plaque edges facing the disk interior. Additionally, there was breakdown of the characteristic ICD pattern of small interior and large peripheral GJs. Continuous DN-ZO-1 expression in VMs over postnatal development reduced ICD-associated Cx43 GJs and increased lateralized and cytoplasmic Cx43. We conclude that ZO-1 regulation of GJ localization is via an association with the N-cadherin multiprotein complex and that this is a key determinant of stable localization of both AJs and GJs at the ICD.

Wnt11 and Wnt7a are up‐regulated in association with differentiation of cardiac conduction cells in vitro and in vivo

The heart beat is coordinated by a precisely timed sequence of action potentials propagated through cells of the conduction system. Previously, we have shown that conduction cells in the chick embryo are derived from multipotent, cardiomyogenic progenitors present in the looped, tubular heart. Moreover, analyses of heterogeneity within myocyte clones and cell birth dating have indicated that elaboration of the conduction system occurs by ongoing, localized recruitment from within this multipotent pool. In this study, we have focused on a potential role for Wnt signaling in development of the cardiac conduction system. Treatment of embryonic myocytes from chick with endothelin‐1 (ET‐1) has been shown to promote expression of markers of Purkinje fiber cells. By using this in vitro model, we find that Wnt11 are Wnt7a are up‐regulated in association with ET‐1 treatment. Moreover, in situ hybridization reveals expression, although not temporal coincidence of, Wnt11 and Wnt7a in specialized tissues in the developing heart in vivo. Specifically, whereas Wnt11 shows transient and prominent expression in central elements of the developing conduction system (e.g., the His bundle), relative increases in Wnt7a expression emerge at sites consistent with the location of peripheral conduction cells (e.g., subendocardial Purkinje fibers). The patterns of Wnt11 and Wnt7a expression observed in vitro and in the embryonic chick heart appear to be consistent with roles for these two Wnts in differentiation of cardiac conduction tissues. Development Dynamics 227:536–543, 2003.

Cardiac Expression Patterns of Endothelin- Converting Enzyme (ECE): Implications for Conduction System Development

The spatiotemporal distribution of the endothelin‐converting enzyme (ECE) protein in the embryonic chick heart and the association of this polypeptide with the developing cardiac conduction system is described here for the first time. Further, we show how cardiac hemodynamic load directly affects ECE level and distribution. Endothelin (ET) is a cytokine involved in the inductive recruitment of Purkinje fibers. ET is produced by proteolytic cleavage of Big‐ET by ECE. We generated an antibody against chick ECE recognizing a single band at ∼70 kD to correlate the cardiac expression of this protein with that reported previously for its mRNA. ECE protein expression was more widespread compared to its mRNA, being present in endothelial cells, mesenchymal cells, and myocytes, and particularly enriched in the trabeculae and nascent ventricular conduction system. The myocardial expression was significantly modified under experimentally altered hemodynamic loading. In vivo, ET receptor blockade with bosentan delayed activation sequence maturation. These data support a role for ECE in avian cardiac conduction system differentiation and maturation. Developmental Dynamics 237:1746–1753, 2008.

STORM Localizations - Part 1/3

Zip file containing single molecule localization data from STORM. The zip file is divided into 3 volumes. Volume 1/3