Human connexin 43 gap junction channel gating: evidence for mode shifts and/or heterogeneity

Intracorporal injection of hSlo cDNA in rats produces physiologically relevant alterations in penile function

The Ca2+-sensitive K+ channel (maxi-K+) is an important modulator of corporal smooth muscle tone. The goal of these studies was twofold: 1) to determine the feasibility of transfecting corporal smooth muscle cells in vivo with the hSlo cDNA, which encodes for the human smooth muscle maxi-K+ channel, and 2) to determine whether transfection of the maxi-K+ channel would affect the physiological response to cavernous nerve stimulation in a rat model in vivo. Intracorporal microinjection of pCMVbeta/Lac Z DNA in 10-wk-old rats resulted in significant incorporation and expression of beta-galactosidase activity in 10 of 12 injected animals for up to 75 days postinjection. Moreover, electrical stimulation of the cavernous nerve revealed that, relative to the responses obtained in age-matched control animals (N = 12), intracavernous injection of naked pcDNA/hSlo DNA was associated with a statistically significant elevation in the mean amplitude of the intracavernous pressure response at all levels of current stimulation (range 0.5-10 mA) at both 1 mo (N = 5) and 2 mo (N = 8) postinjection. Furthermore, qualitatively similar observations were made at 3 mo (N = 2) and 4 mo (N = 2) postinjection. These data indicate that naked hSlo DNA is quite easily incorporated into corporal smooth muscle and, furthermore, that expression is sustained for at least 2 mo in corporal smooth muscle cells in vivo. Finally, after expression, hSlo is capable of measurably altering nerve-stimulated penile erection. Taken together, these data provide compelling evidence for the potential utility of gene therapy in the treatment of erectile dysfunction.

Evidence for heteromeric gap junction channels formed from rat connexin43 and human connexin37

Homomeric gap junction channels are composed solely of one connexin type, whereas heterotypic forms contain two homomeric hemichannels but the six identical connexins of each are different from each other. A heteromeric gap junction channel is one that contains different connexins within either or both hemichannels. The existence of heteromeric forms has been suggested, and many cell types are known to coexpress connexins. To determine if coexpressed connexins would form heteromers, we cotransfected rat connexin43 (rCx43) and human connexin37 (hCx37) into a cell line normally devoid of any connexin expression and used dual whole cell patch clamp to compare the observed gap junction channel activity with that seen in cells transfected only with rCx43 or hCx37. We also cocultured cells transfected with hCx37 or rCx43, in which one population was tagged with a fluorescent marker to monitor heterotypic channel activity. The cotransfected cells possessed channel types unlike the homotypic forms of rCx43 or hCx37 or the heterotypic forms. In addition, the noninstantaneous transjunctional conductance-transjunctional voltage (Gj/Vj) relationship for cotransfected cell pairs showed a large range of variability that was unlike that of the homotypic or heterotypic form. The heterotypic cell pairs displayed asymmetric voltage dependence. The results from the heteromeric cell pairs are inconsistent with summed behavior of two independent homotypic populations or mixed populations of homotypic and heterotypic channels types. The Gj/Vj data imply that the connexin-to-connexin interactions are significantly altered in cotransfected cell pairs relative to the homotypic and heterotypic forms. Heteromeric channels are a population of channels whose characteristics could well impact differently from their homotypic counterparts with regard to multicellular coordinated responses.

Voltage sensitivity of gap junction currents in rat osteoblast-like cells

The dependence of macroscopic gap junctional conductance (g(j)) upon transjunctional voltage (Vj) was examined in 39 paired osteoblast-like (OB) cells from primary cultures using the double whole cell patch clamp technique. OB cells were derived from calvarial explants of new-born rats. Instantaneous current-voltage (Ij-Vj) relationships of OB cell pairs (n = 6) were linear in the entire voltage range (-150 < Vj < 150 mV) examined. The steady-state Ij-Vj relationship was non-linear for V > or = +/-60 mV. The curve for the normalised steady-state junctional conductance-voltage relationship (Gss/G0-Vj) was bell-shaped, and was fitted with a two-state Boltzmann equation with a minimum conductance (Gmin) of 0.2-0.3, and a half deactivation voltage (Vo) of +/-83 mV. In two recordings unitary gap junction channel activity was observable. The linear I-V relationships revealed a single channel conductance of approximately 100 pS. Application of parathyroid hormone (10(-8) M) had no effect on the voltage dependence nor the magnitude of macroscopic currents (n = 7).

The "syncytial tissue triad": a model for understanding how gap junctions participate in the local control of penile erection

Recent findings from both clinical and experimental studies document the importance of syncytial relaxation and contraction of corporal smooth muscle to penile erection and detumescence, respectively. However, the mechanism(s) permitting coordinated response generation among the vast array of largely inexcitable corporal smooth muscle cells is unclear. In this report the compelling evidence for a major role of intercellular communication through gap junctions to erectile function is reviewed. Moreover, a novel concept is advanced to explain more fully the putative mechanistic basis for integrative erectile tissue biology. Specifically, the presence of gap junctions, in concert with the autonomic nervous system and myogenic intracellular signal transduction mechanisms, is postulated to form a "syncytial tissue triad" that is largely responsible for the local modulation of corporal smooth muscle tone. It is reasonable to assume that the existence of this "syncytial tissue triad" confers a plasticity, adaptability, and flexibility to erectile function that may well account for the observed diversity of mechanisms known to regulate penile erection as well as the multifaceted etiology of erectile dysfunction.

Gap junction channel gating and permselectivity: their roles in co-ordinated tissue function

1. The gating and permselective properties of gap junction channels are important parameters to determine in delineating their role in co-ordinated tissue function. This is of particular relevance in non-excitable tissues. 2. In the present study gating characteristics of rCx43 are demonstrated. The mean open times are of the order of 0.45-1.1 s. These values are extraordinarily large. 3. The permselectivity of a variety of gap junction channels is also illustrated to show the poor selectivity properties of gap junctions and, hence, their potential to allow the permeation of second messenger molecules. 4. Gating and permselectivity, along with diffusion modelling, produce a picture for gap junction channels that is consistent with physiologically relevant modulation or regulation of gap junction channel patency.

Gap junctions in vascular tissues. Evaluating the role of intercellular communication in the modulation of vasomotor tone

Integration and coordination of responses among vascular wall cells are critical to the local modulation of vasomotor tone and to the maintenance of circulatory homeostasis. This article reviews the vast literature concerning the principles that govern the initiation and propagation of vasoactive stimuli among vascular smooth muscle cells, which are nominally the final effectors of vasomotor tone. In light of the abundance of new information concerning the distribution and function of gap junctions between vascular wall cells throughout the vascular tree, particular attention is paid to this integral aspect of vascular physiology. Evidence is provided for the important contribution of intercellular communication to vascular function at all levels of the circulation, from the largest elastic artery to the terminal arterioles. The thesis of this review is that the presence of gap junctions, in concert with the autonomic nervous system, pacemaker cells, myogenic mechanisms, and/or electrotonic current spread (both hyperpolarizing and depolarizing waves through gap junctions), confers a plasticity, adaptability, and flexibility to vasculature that may well account for the observed diversity in regulation and function of vascular tissues throughout the vascular tree. It is hoped that the summary information provided here will serve as a launching pad for a new discourse on the mechanistic basis of the integrative regulation and function of vasculature, which painstakingly accounts for the undoubtedly complex and manifold role of gap junctions in vascular physiology/dysfunction.