INTRODUCTION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

IN ARTERIES AND VEINS from the rabbit, guinea pig, pig, and mouse, direct intercellular communication via gap junction channels may play a central role in the mediation of endothelium-dependent relaxations that do not involve nitric oxide (NO) or prostanoids and are widely attributed to an endothelium-derived hyperpolarizing factor (EDHF) (6, 9, 11, 14, 15, 19, 23, 31, 34). Gap junction channels are formed by the docking of two connexon hemichannels, each constructed from six connexin protein subunits that cross the cell membrane four times with two loops exposed extracellularly (28), and cell-cell coupling is thought to occur predominantly at sites where several hundred such channels cluster in plaquelike structures in the cell membrane (7, 27). Different connexin subtypes are conventionally classified according to their molecular weight (in kDa), with endothelial and smooth muscle cells expressing Cx37, Cx40, and Cx43, according to vessel type and species (32). In the rabbit mesenteric artery, Cx43 is the only connexin detectable in smooth muscle cells on Western blot analysis, and EDHF-type relaxations and hyperpolarizations evoked by ACh are attenuated by a synthetic undecapeptide homologous to the Gap 27 domain of the second extracellular loop of this connexin (9). This peptide may be denoted ^37,43Gap 27, inasmuch as the sequence is also conserved in Cx37 (Table 1). Substitution of three amino acids in the ^37,43Gap 27 sequence, so as to confer homology with the corresponding domain of Cx40 (denoted ⁴⁰Gap 27; Table 1), abolishes its ability to inhibit EDHF-type relaxations in rabbit arteries, thereby confirming a high degree of connexin specificity (10).

^37,43Gap 27 also inhibits EDHF-type hyperpolarizations in guinea pig and porcine arteries but is inactive in the rat hepatic artery, leading to the suggestion that gap junctions play a negligible role in EDHF-type relaxations in this vessel type but, rather, that K⁺ ions released from the endothelium promote smooth muscle hyperpolarization and relaxation by activating inwardly rectifying K⁺ channels and an Na⁺-K⁺-ATPase (13-15). It is possible, however, that restricted expression of Cx43 in the rat hepatic artery (22) accounts for this apparent insensitivity to ^37,43Gap 27. Indeed, expression of Cx43 in rat arteries is vessel specific, being present in the endothelium and media of elastic arteries, but confined to the endothelium or completely absent from the vessel wall in muscular arteries (22, 32, 35). Cx37 and Cx40 similarly exhibit wide regional variations in expression in the rat vasculature (24, 26, 30). To evaluate the possible contributions of these different connexins to EDHF-type responses in the rat hepatic artery, we have therefore exploited similarities and differences in their Gap 26 and Gap 27 domains to generate a series of connexin-specific peptides that were administered alone and in combination in isolated arterial rings. Mechanical studies were conducted in tandem with dye transfer experiments in A7r5 cells, a rat aortic smooth muscle line that expresses Cx40 and Cx43 (21). Specific antibodies were used to define the distribution of different connexin subtypes in the arterial wall and A7r5 monolayers. Collectively, the findings provide evidence that Cx37, Cx40, and Cx43 each contribute to EDHF-type relaxations in the rat hepatic artery.

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Isolated arterial rings. Rings of hepatic artery 1-1.5 mm wide, obtained from male Wistar rats (200-250 g) killed by cervical dislocation, were mounted in a Mulvany myograph (Danish Myo Technology) containing gassed (95% O₂-5% CO₂, pH 7.4, 37°C) Holman's solution of the following composition (in mM): 120 NaCl, 5 KCl, 2.5 CaCl₂, 1.3 NaH₂PO₄, 25 NaHCO₃, 11 glucose, and 10 sucrose. Tension was initially set at 0.25 g and readjusted as necessary during an equilibrium period of 1 h.

Immunohistochemistry. Freshly isolated rat hepatic arteries were cryopreserved in OCT compound (BDH) cooled by liquid nitrogen. Cryosections of transverse rings (8-10 µm thick) were prepared and mounted onto poly-L-lysine-coated slides (Surgipath), air-dried, and stored at 20°C. Immediately before the sections were immunostained, they were fixed in 20°C methanol for 10 min and then rehydrated in PBS (120 mM NaCl and 2.7 mM Na₂PO₄ · 2H₂O, pH 7.4) for 10 min. Permeabilization was performed in PBS containing 0.1% (vol/vol) Triton X-100 for 30 min, and the sections were blocked with PBS containing 0.5% (wt/vol) BSA for 30 min at room temperature. Sections were stained with the following primary antibodies: for Cx43, a monoclonal antibody generated against amino acids 252-279 on the COOH-terminal tail (Chemicon; 4 µg/ml) was used, and for Cx45, Cx40, and Cx37, rabbit polyclonal antipeptide antibodies, prepared against 14 (Cx45) and 19 (Cx37 and Cx40) amino acid sequences on the COOH-terminal tail of each connexin, were used (Alpha Diagnostics; 5 µg/ml). The endothelial cell layer was also stained with factor VIII-conjugated FITC (Serotec; 1:100 dilution). Primary antibodies were incubated for 2 h at 37°C and then washed for 30 min at room temperature in PBS. Secondary antibodies of goat anti-mouse conjugated Alexa 488 or goat anti-rabbit conjugated Alexa 546 (Molecular Probes; 1:500 dilution) were incubated for 45 min at 37°C and then extensively washed to remove unbound antibody. The sections were then mounted under Fluorsave (Calbiochem).

Confocal laser scanning microscopy. Rat hepatic artery sections and A7r5 cells were imaged with a Bio-Rad MRC 1024ES laser scanning system. For costained samples, images were taken using simultaneous dual-channel screening with emission filters set at 488 and 546 nm for Alexa 488 and Alexa 546, respectively. For the artery sections, images were collected at 0.5-µm steps and then processed using the Bio-Rad Lasersharp software to obtain a three-dimensional single-maximum optical projection view for each section.

Dye transfer. A7r5 cells were seeded at a density of 1 × 10⁶ cells per 60-mm² tissue culture dish and cultured as described above. Confluent cell monolayers were washed twice with PBS and then preincubated in Leibowitz L-15 medium for 90 min at 37°C. In some experiments, ⁴³Gap 26 or ⁴⁰Gap 27 peptide (600 µM) or a combination of these peptides at 300 or 500 µM each were present during this incubation period. At 15 min after microinjection of Lucifer yellow CH (charge 2, 457 Da), cells were fixed in 4% paraformaldehyde, and the percentage of injections resulting in dye transfer to 0, 1-4, 5-10, and >10 neighboring cells was evaluated as previously described (10, 11).

Drugs. All reagents were obtained from Sigma Chemical unless otherwise stated. The purity of the gap peptides was >95%.

Statistics. Values are means ± SE. Concentration-relaxation curves to ACh were evaluated by one-way ANOVA, with Bonferroni multiple comparisons test as a further method of analysis. Concentrations of ACh causing half-maximal relaxation (EC₅₀) and maximal relaxations (expressed as percent reversal of PE-induced constriction) were compared by a Student's t-test. P < 0.05 was considered significant.

	RESULTS

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Inhibition of EDHF-type relaxations by gap junction peptides and apamin + charybdotoxin. EDHF-type relaxations were maximal at 10 µM ACh, with a maximal response of ~80% of PE-induced tone (Fig. 1A, Table 2). Preincubation with ^37,40Gap 26, ⁴³Gap 26, ^37,43Gap 27, and ⁴⁰Gap 27 (all at 600 µM) did not significantly alter maximal relaxation to ACh or EC₅₀ compared with control (n = 5 for all; Figs. 1B and 2, Table 2). Preincubation with ^37,40Gap 26 + ⁴⁰Gap 27 or ^37,43Gap 27 + ⁴³Gap 26 (300 µM for each component) was similarly without effect (n = 5 and 4, respectively; Figs. 1C and 3, A and B, Table 2). However, after preincubation with ^37,40Gap 26 + ⁴³Gap 26 or ^37,43Gap 27 + ⁴⁰Gap 27 (300 µM for each peptide), maximal EDHF-type relaxations to ACh were significantly reduced (P < 0.05, n = 5 for both; Fig. 3, C and D, Table 2). Although EC₅₀ values were not altered after preincubation with ^37,40Gap 26 + ⁴³Gap 26, there was a significant rightward shift after incubation with ^37,43Gap 27 + ⁴⁰Gap 27 (P < 0.05; Table 2). Preincubation with ^37,40Gap 26 + ^37,43Gap 27 (300 µM each) inhibited maximal relaxations (P < 0.01, n = 5; Fig. 3E, Table 2) with a significant rightward shift in EC₅₀ values (P < 0.05; Table 2). Washout for 1 h restored ACh-evoked relaxation (Fig. 3E, Table 2). ⁴⁰Gap 27 + ⁴³Gap 26 (300 µM each) attenuated the maximal response to ACh (P < 0.001, n = 5; Figs. 1D and 3F, Table 2) with a significant shift in EC₅₀ values (Table 2; P < 0.01). After a 1-h washout, maximal relaxations and EC₅₀ values were partially restored (n = 4; Fig. 3F, Table 2). Increasing the concentrations of ⁴⁰Gap 27 and ⁴³Gap 26 to 500 µM each caused a further shift in the concentration-relaxation curve to ACh (P < 0.001, n = 5; Fig. 3F, Table 2). Preincubation with ^37,43Gap 27 + ⁴⁰Gap 27 + ⁴³Gap 26 (300 µM each) before or after constriction to PE (300 nM) effectively abolished EDHF-type relaxations (n = 4; Figs. 1E and 3F, Table 2). Apamin + charybdotoxin attenuated maximal relaxations to ACh from 88.5 ± 6.8 to 12.3 ± 3.6% of PE-induced constriction (P < 0.001, n = 4; Fig. 1F) with a significant rightward shift in EC₅₀ values from 0.18 ± 0.08 to 35.7 ± 2.1 µM (P < 0.001).

View larger version (13K): [in this window] [in a new window]   Fig. 1.   Representative traces showing ACh-evoked endothelium-derived hyperpolarizing factor (EDHF)-type relaxations (A) and effects of preincubation with 40Gap 27 (600 µM; B) and combinations of 37,40Gap 26 + 40Gap 27 or 40Gap 27 + 43Gap 26 (300 µM for each component; C and D). E and F: effects of 37,43Gap 27 + 40Gap 27 + 43Gap 26 (300 µM each) and apamin + charybdotoxin (500 and 100 nM, respectively) on phenylephrine (PE)-induced tone and subsequent ACh-evoked relaxation. W, washout.

View larger version (31K): [in this window] [in a new window]   Fig. 2.   Concentration-response curves showing effects of 600 µM 37,40Gap 26 (A), 40Gap 27 (B), 43Gap 26 (C), and 37,43Gap 27 (D) on EDHF-type relaxation to ACh. None of these peptides significantly altered maximal relaxation or EC50.

View larger version (32K): [in this window] [in a new window]   Fig. 3.   Concentration-response curves showing effects of preincubation with different peptide combinations on EDHF-type relaxation. Preincubation with 37,40Gap 26 + 40Gap 27 (300 µM each, n = 5; A) and 43Gap 26 + 37,43Gap 27 (300 µM each, n = 4; B) did not significantly alter responses to ACh, whereas 37,40Gap 26 + 43Gap 26 (300 µM each, P < 0.05, n = 5; C) and 40Gap 27 + 37,43Gap 27 (300 µM each, P < 0.05, n = 5; D) caused significant inhibition of maximal relaxations. More pronounced inhibition of ACh-evoked relaxations was demonstrated by 37,40Gap 26 + 37,43Gap 27 (300 µM each, P < 0.001, n = 5; E) and 40Gap 27 + 43Gap 26 (300 and 500 µM, P < 0.001, n = 5 for both; F). Effects of 37,40Gap 26 + 37,43Gap 27 were completely reversible, whereas 40Gap 27 + 43Gap 26 showed only partial reversibility after repeated washout. 37,43Gap 27 + 40Gap 27 + 43Gap 26 (300 µM for each, P < 0.001, n = 4) effectively abolished ACh-evoked relaxations, with only partial reversibility (not shown).

Effects of gap junction peptides and apamin + charybdotoxin on PE-induced tone. PE (300 nM) evoked constrictions of 1.6 ± 0.1 g (n = 42) that were not significantly affected by preincubation with gap peptides, alone or in paired combinations (Table 2). After constriction by 300 nM PE, ^37,43Gap 27 + ⁴⁰Gap 27 + ⁴³Gap 26 (300 µM each) did not significantly alter tone, whereas apamin + charybdotoxin caused a sustained increase from 1.6 ± 0.2 to 2.1 ± 0.1 g (P < 0.01, n = 4 in both cases; Fig. 1, E and F).

Connexin distribution in rat hepatic artery. Immunostaining of connexin proteins in the wall of the hepatic artery revealed the typical punctate distribution of gap junction plaques and demonstrated considerable heterogeneity in the expression of Cx37, Cx40, and Cx43 (Fig. 4, A-F). Cx37 was widely expressed in the endothelium and media, but whereas Cx43-containing plaques were similarly found in the endothelium, in the media they were restricted to the adventitial border. Studies at high magnification showed Cx37-containing gap junction plaques at the smooth muscle-endothelium interface (Fig. 4G). Expression of Cx40 appeared to be restricted to the endothelium as confirmed by costaining with factor VIII (Fig. 4, H and I).

View larger version (143K): [in this window] [in a new window]   Fig. 4.   Transverse sections of rat hepatic artery stained with antibodies to connexins Cx37, Cx40, and Cx43 and secondary goat anti-mouse Alexa 488 (green) or goat anti-rabbit Alexa 546 (red) as appropriate. A: Cx37 immunostaining (red) showing wide expression of Cx37 in endothelial and smooth muscle cell layers. B: Cx43 immunostaining (green) showing limited levels of Cx43 in endothelium and pockets of Cx43 expression at adventitial interface. C: merged image of A and B demonstrating areas of Cx43 and Cx37 colocalization (yellow) as identified by arrows. D: Cx40 immunostaining (red) showing restriction to endothelium. E: Cx43 immunostaining (green). F: merged image of D and E demonstrating colocalization of Cx40 and Cx43 in endothelium (yellow) as identified by arrows. G: high-magnification Cx37 immunostaining with arrows showing small plaques at myoendothelial interface. H: immunostaining with a factor VIII-conjugated FITC antibody, an endothelium-specific cell marker. I: double-immunofluorescent staining of factor VIII and Cx40 showing restriction of Cx40 to endothelium. Scale bar, 15 µm.

View larger version (41K): [in this window] [in a new window]   Fig. 5.   Colocalization analysis of Cx43 with Cx37 (A) and Cx43 with Cx40 (B). Areas of specific staining for Cx37, Cx43, and Cx40 represented in Fig. 4, A-C, and Fig. 4, D and E, are indicated. For each image, 5 different areas of nonspecific secondary antibody staining were selected as background to calculate the percentage of red and green pixels that were colocalized. Fluorograms illustrate high levels of expression of Cx37 compared with Cx43 (A) and demonstrate that the majority of Cx43 expressed in the endothelium colocalizes with Cx40 (B).

Characterization of connexin expression in A7r5 cells. Immunocytochemical analysis demonstrated that A7r5 cells express Cx43 and Cx40 in gap junction plaques at sites of cell-cell contact. Costaining with Cx43 and Cx40 antibodies showed almost complete coexpression of the two connexin subtypes (Fig. 6).

View larger version (142K): [in this window] [in a new window]   Fig. 6.   Connexin expression in confluent monolayers of A7r5 cells. A: cells stained with a primary Cx40 rabbit polyclonal antibody and secondary goat anti-rabbit conjugated Alexa 546 antibody (red). B: cells stained with a primary Cx43 mouse monoclonal antibody and a secondary goat anti-mouse Alexa 488 antibody (green). C: merged images of A and B showing colocalization of Cx40 and Cx43 (yellow). D: graphical representation of colocalization of Cx40 and Cx43. Arrows, coincident staining of Cx40 and Cx43 gap junction plaques.

Dye transfer in A7r5 cell monolayers. Under control conditions, 87 ± 5% of cells transferred dye to 10 neighboring cells and 6 ± 4% of cells transferred dye to 5-10 neighboring cells. After preincubation of the cells with 600 µM ⁴³Gap 26 or ⁴⁰Gap 27, no significant difference in the ability of cells to transfer dye to >10 cells was evident (79 ± 13 and 72 ± 16%, respectively). When cells were incubated with both peptides at 300 µM each, only 14 ± 5% of cells transferred dye to >10 cells in association with an increase in the number of cells transferring dye to <10 cells. At up to 500 µM each, only 8 ± 6% of cells transferred dye to >10 cells (Figs. 7 and 8).

View larger version (221K): [in this window] [in a new window]   Fig. 7.   Effects of 43Gap 26 and 40Gap 27 on dye transfer in confluent A7r5 cells treated with these peptides singly or in combination after microinjection of Lucifer yellow cells and fixation. A: control cells. B, C, and D: after treatment with 43Gap 26 + 40Gap 27 (300 µM each), 43Gap 26 (600 µM), and 40Gap 27 (600 µM) respectively. *Injected cell.

View larger version (31K): [in this window] [in a new window]   Fig. 8.   Histogram showing percent transfer of Lucifer yellow dye to 1-4, 5-10, and >10 neighboring cells after intracytoplasmic injection of a single A7r5 cell. Dye transfer was significantly reduced after coincubation with 43Gap 26 + 40Gap 27 (300 or 500 µM each, P < 0.001) but not 43Gap 26 (600 µM) or 40Gap 27 (600 µM) alone. Results are presented for 50 injections/plate in each experimental group.

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

In the present study, short connexin-mimetic peptides homologous to the extracellular loops of Cx37, Cx40, and Cx43 have been employed to investigate the contribution of gap junctional communication to NO- and prostanoid-independent relaxations of the rat hepatic artery. The findings provide evidence that direct cell-cell coupling underpins EDHF-type responses in this vessel type.

In the presence of N^G-nitro-L-arginine methyl ester and indomethacin, maximum EDHF-type relaxations evoked by ACh were on the order of 80% of PE-induced tone. At 600 µM, none of the peptides, ^37,40Gap 26, ⁴³Gap 26, ^37,43Gap 27, or ⁴⁰Gap 27, significantly affected the initial constrictor response to PE or maximal relaxation and EC₅₀ values for the concentration-relaxation curves constructed for ACh. Furthermore, in experiments with two peptides at individual concentrations of 300 µM each, combinations targeted principally to Cx40 (^37,40Gap 26 + ⁴⁰Gap 27) or to Cx43 (⁴³Gap 26 + ^37,43Gap 27) were also inactive. By contrast, paired peptide combinations targeted specifically to either of the Gap 26 and Gap 27 domains of Cx37, Cx40, and Cx43 (^37,40Gap 26 + ⁴³Gap 26 and ^37,43Gap 27 + ⁴⁰Gap 27) or a combination targeted to both of these domains (^37,40Gap 26 + ^37,43Gap 27) attenuated maximum relaxations to ACh by 30-40% and caused two- to fivefold rightward shifts in the EC₅₀ for relaxation. A peptide combination that should in theory exert no effect on gap junctions constructed from Cx37 (⁴³Gap 26 + ⁴⁰Gap 27) similarly attenuated maximum relaxations to ACh by ~50% when both components were administered at 300 or 500 µM each, although the higher-concentration combination caused larger (~25- vs. ~2-fold) increases in the EC₅₀ for relaxation. EDHF-type responses to ACh were effectively abolished by ^37,43Gap 27 + ⁴³Gap 26 + ⁴⁰Gap 27 when each component was administered at 300 µM. The observation that this triple combination suppressed the response to ACh at a total peptide concentration of 900 µM, whereas ⁴³Gap 26 + ⁴⁰Gap 27 resulted in only partial inhibition at a total concentration of 1,000 µM, suggests that a spectrum of gap junction channels constructed from Cx37, Cx40, and Cx43 contributes to EDHF-type relaxations in the rat hepatic artery.

To confirm that specific combinations of inhibitory peptide may be necessary to attenuate intercellular communication between cells coupled by more than one connexin subtype, dye transfer studies were performed in an A7r5 cell system that was shown to coexpress Cx40 and Cx43 in gap junction plaques. At individual concentrations of 600 µM, neither ⁴³Gap 26 nor ⁴⁰Gap 27 affected the spread of Lucifer yellow in confluent A7r5 monolayers, whereas combined peptide administration at 300 or 500 µM each decreased the number of cells transferring dye to 10 neighboring cells from ~80% to 10%. These findings contrast with the effects of connexin-mimetic peptides in COS-7 cells, a fibroblast line that expresses Cx43 as its only functional connexin protein. Predictably, in this system ^37,43Gap 27 attenuates intercellular diffusion of Lucifer yellow, whereas ⁴⁰Gap 27 is without effect, thus emphasizing the connexin selectivity of these peptides (10). Although the molecular mechanism through which such agents interrupt intercellular communication remains to be established (2), the inability of four different peptides to affect relaxation in the rat hepatic artery individually and their complete lack of effect on PE-induced tone in combinations that inhibited relaxations to ACh exclude nonspecific actions against other mechanisms involved in the EDHF phenomenon. The activation of Ca²⁺-activated K⁺ channels, for example, is an essential component of EDHF-type responses that are abolished by the peptidergic K⁺ channel blockers charybdotoxin and apamin when administered in combination (5, 12, 13, 36). Unlike connexin-mimetic peptides, however, coadministration of these agents induces pronounced vascular smooth muscle constriction, as confirmed in the present study in the rat hepatic artery.

Immunohistological staining revealed the typical punctate appearance of gap junction plaques in the rat hepatic artery and demonstrated that different connexin subtypes were distributed heterogeneously in the vascular wall. Cx37, Cx40, and Cx43 were each present in large interendothelial plaques, whereas in the smooth muscle cells of the media there was wide expression of Cx37 but limited expression of Cx43 in pockets of gap junction plaques near the adventitia and no detectable expression of Cx40. Inasmuch as Cx40 and Cx43 were absent from subintimal smooth muscle but predominant in the endothelium, the ability of ⁴³Gap 26 and ⁴⁰Gap 27 to attenuate EDHF-type relaxations when administered in combination implies an important role for both connexins in endothelial signaling via gap junctions in the rat hepatic artery. Indeed, previous studies with layered "sandwich" preparations of endothelium-intact and endothelium-denuded arterial strips have provided evidence that direct endothelium-smooth muscle communication is central to EDHF-type responses in rabbit arteries (9). Although analogous experiments remain to be performed with rat vessels, it seems unlikely that direct intercellular communication within the endothelial monolayer plays a major role in the initiation of EDHF-type relaxations via chemical signalling mechanisms, inasmuch as each cell will be exposed to an identical concentration of ACh in organ chamber experiments. While ^37,43Gap 27 inhibits the propagation of Ca²⁺ waves in coupled respiratory epithelial cells (4), we previously showed that this peptide does not inhibit ACh-evoked NO production by the endothelium, which, like the synthesis of the putative EDHF, is Ca²⁺ dependent (9, 18). Furthermore, uncoupling of endothelial cells with 18-glycyrrhetinic acid, a lipophilic aglycone that disrupts gap junction plaques (20), does not affect direct endothelial cell hyperpolarization induced by ACh, which is a major stimulus to Ca²⁺ influx in the electrically nonexcitable endothelial cell (33). It is nevertheless conceivable that the large ~150-fold increase in the electrical resistance of the endothelial monolayer that follows uncoupling of its component cells (33) impairs its ability to function as a low-resistance current source able to transmit hyperpolarizing current into the media via passive electrotonic mechanisms. It remains to be determined whether inhibition of homocellular smooth muscle communication via gap junctions, and thus in theory the relay of chemical and/or electrical signals from the endothelium through successive layers of smooth muscle cells in the media, contributes to the ability of connexin-mimetic peptides to attenuate EDHF-type relaxations, a possibility suggested by observations that ⁴³Gap 26 and ^37,43Gap 27 abolish rhythmic contractile activity in endothelium-denuded rings of rabbit superior mesenteric artery (8).

Specialized triple immunostaining techniques have previously documented colocalization of Cx37, Cx40, and Cx43 in the endothelium of the rat aorta and coronary artery (35), and in the present study, quantitative analysis with double-antibody staining demonstrated that the majority of Cx43 in the endothelium of the rat hepatic artery was associated with Cx40 or Cx37. Although the antibody combinations available did not permit direct analysis of the overlap between Cx37 and Cx40, cross-correlation of the observed staining patterns indicates that Cx40 and Cx37 may also colocalize in endothelial gap junction plaques in the rat hepatic artery. By contrast, Cx37 and Cx43, the only connexin subtypes present in the media, showed little overlap in smooth muscle gap junction plaques. Recent serial electron-microscopic studies have definitively demonstrated the existence of myoendothelial gap junction plaques in rat mesenteric arteries and have shown that these are more than five times smaller than plaques coupling endothelial cells (29). In the present study, small plaques could be identified at the endothelium-smooth muscle interface in the rat hepatic artery, although the fluorescent antibody technique possesses insufficient spatial resolution to classify these as myoendothelial with certainty. In theory, such plaques could contain homotypic (Cx37/Cx37), heterotypic (Cx40/Cx37, Cx43/Cx37), and heteromeric (each hemichannel containing a mixture of different connexin proteins) gap junctions (3, 16, 21) constructed from Cx37, Cx40, and/or Cx43 in the endothelium and Cx37 in smooth muscle. Further research is necessary to define the precise connexin composition of such channels, inasmuch as differences in their susceptibility to connexin-mimetic peptides could potentially explain why EDHF-type relaxations and hyperpolarizations in the rabbit mesenteric artery are sensitive to inhibition by ^37,43Gap 27 alone (9, 11), whereas peptide combinations are necessary in the rat hepatic artery. Further research is also necessary to determine the extent to which NO- and prostanoid-independent responses result from direct intercellular diffusion of chemical signals into the vessel wall and/or the spread of hyperpolarizing current from the endothelium. Although passive conduction is not thought to contribute to EDHF-type relaxations in thick-walled conduit arteries because of electrical mismatching between the large mass of the media and the endothelial monolayer (1), electrotonic mechanisms may nevertheless play a role in the response to ACh in microvessels where the mass of the two cell layers is comparable (17).

In summary, we have provided evidence that intercellular communication via myoendothelial gap junctions constructed from Cx37, Cx40, and Cx43 underpins EDHF-type relaxations of the rat hepatic artery. Apparent species and/or vessel heterogeneity in the contribution of gap junctions to agonist-induced responses may reflect variations in connexin expression in the endothelial and medial layers of the vascular wall, rather than fundamental differences in the mechanisms that ultimately mediate vasorelaxation.