Gap junctional connexins in the developing mouse cardiac conduction system.

Gap junctional channels which couple myocytes mediate conduction phenomena in the heart. These channels are dodecamers of transmembrane proteins belonging to the connexin family (Cx). Three Cxs, Cx43, -40 and -45, have been found to be expressed in cardiomyocytes. Each of them has a distinct spatiotemporal pattern of expression, which is regulated during development. In the adult mouse heart, Cx43 is expressed in all the working myocytes and most of the conductive myocytes; Cx45 is weakly expressed in all conductive myocytes, including those of the nodal tissues; Cx40 expression is restricted to the atria and ventricular conduction system. Analysis of mice with deletions of Cx genes has provided evidence that Cx43, -40 and -45, and consequently the gap junctional channels they form, are involved in both heart function and development. For example, Cx40 deficiency results in sinoatrial conduction impairments, a significant decrease of the conduction velocity in the atria, and a delay of the propagation of impulse in the His bundle. Transgenic mouse lines with modified Cx40 genes are now being used to draw up a detailed map of the conduction system in the adult and developing heart, and to identify the regulatory elements involved in the transcriptional regulation of the Cx40 gene. Some preliminary results of these studies are described.

Connexin expression and gap junctional intercellular communication in human first trimester trophoblast.

Connexin (Cx) expression and gap junctional intercellular communication (GJIC) are involved in development and differentiation processes, and recently mutation of connexin genes has been implicated in pathologies. In the human placenta, two distinct differentiation pathways of cytotrophoblastic cells coexist and lead to a fusion phenotype (villous trophoblast) and a proliferative/invasive phenotype (extravillous trophoblast). Here we characterized in situ and in vitro the expression of Cx transcripts and proteins in the villous and extravillous trophoblast of first trimester placenta. In addition, the GJIC functionality was investigated using the gap-fluorescence recovery after photobleaching (gap-FRAP) method. We demonstrated in the villous trophoblast the presence of Cx43 mRNA and of Cx43 protein localized between cytotrophoblastic cells and between cytotrophoblastic cells and syncytiotrophoblast. In vitro, a transient functional gap junctional intertrophoblastic communication was demonstrated during the trophoblast fusion leading to the multinucleated syncytiotrophoblast. During the proliferative process of the extravillous trophoblast, Cx40 is expressed in the proximal part of the cell columns. When cytotrophoblastic cells were cultured on Matrigel for 2 days, alpha5beta1 integrin expression was observed concomitant with the presence of Cx40 mRNA and of Cx40 protein between the cells. No evidence for a GJIC was detected in this induced extravillous phenotype. In addition, Cx32 was detected between some aggregated cells after 72 h of culture. Our data show that the presence of Cx43 allows an inter-trophoblastic GJIC and is associated with the fusion process leading to the villous syncytiotrophoblast and that the presence of Cx40 does not allow GJIC and is associated with the extravillous phenotype.