Gap junction communication channel: peptides and anti-peptide antibodies as structural probes

Lipidated connexin mimetic peptides potently inhibit gap junction-mediated Ca2+-wave propagation

Connexin (Cx) mimetic peptides (e.g., Gap27: SRPTEKTIFII; Peptide5: VDCFLSRPTEKT) reversibly inhibit hemichannel (HCh) and gap junction channel (GJCh) function in a concentration- and time-dependent manner (HCh: ~5 µM, <1 h; GJCh: ~100 µM, > 1 h). We hypothesized that addition of a hexadecyl tail to SRPTEKT (SRPTEKT- Hdc) would improve its ability to concentrate in the plasma membrane and consequently increase its inhibitory efficacy. We show that SRPTEKT- Hdc inhibited intercellular Ca²⁺-wave propagation in Cx43-expressing MDCK and rabbit tracheal epithelial cells in a time (61-75 min)- and concentration (IC₅₀: 66 pM)-dependent manner, a concentration efficacy five orders of magnitude lower than observed for the nonlipidated Gap27. HCh-mediated dye uptake was inhibited by SRPTEKT- Hdc with similar efficacy. Following peptide washout, HCh-mediated dye uptake was restored to control levels, whereas Ca²⁺-wave propagation was only partially restored. Scrambled and reverse sequence lipidated peptides had no detectable inhibitory effect on Ca²⁺-wave propagation or dye uptake. Cx43 expression was unchanged by SRPTEKT- Hdc incubation; however, Triton-insoluble Cx43 was reduced by SRPTEKT- Hdc exposure and reversed following washout. In summary, our results show that SRPTEKT- Hdc blocked HCh function and intercellular Ca²⁺ signaling at concentrations that minimally affected dye coupling. Selective inhibition of intercellular Ca²⁺ signaling, likely indicative of channel conformation-specific SRPTEKT- Hdc binding, could contribute significantly to the protective effects of these mimetic peptides in settings of injury. Our data also demonstrate that lipidation represents a paradigm for development of highly potent, efficacious, and selective mimetic peptide inhibitors of hemichannel and gap junction channel-mediated signaling.

Connexin mimetic peptides inhibit Cx43 hemichannel opening triggered by voltage and intracellular Ca2+ elevation

Connexin mimetic peptides (CxMPs), such as Gap26 and Gap27, are known as inhibitors of gap junction channels but evidence is accruing that these peptides also inhibit unapposed/non-junctional hemichannels (HCs) residing in the plasma membrane. We used voltage clamp studies to investigate the effect of Gap26/27 at the single channel level. Such an approach allows unequivocal identification of HC currents by their single channel conductance that is typically ~220 pS for Cx43. In HeLa cells stably transfected with Cx43 (HeLa-Cx43), Gap26/27 peptides inhibited Cx43 HC unitary currents over minutes and increased the voltage threshold for HC opening. By contrast, an elevation of intracellular calcium ([Ca(2+)](i)) to 200-500 nM potentiated the unitary HC current activity and lowered the voltage threshold for HC opening. Interestingly, Gap26/27 inhibited the Ca(2+)-potentiated HC currents and prevented lowering of the voltage threshold for HC opening. Experiments on isolated pig ventricular cardiomyocytes, which display strong endogenous Cx43 expression, demonstrated voltage-activated unitary currents with biophysical properties of Cx43 HCs that were inhibited by small interfering RNA targeting Cx43. As observed in HeLa-Cx43 cells, HC current activity in ventricular cardiomyocytes was potentiated by [Ca(2+)](i) elevation to 500 nM and was inhibited by Gap26/27. Our results indicate that under pathological conditions, when [Ca(2+)](i) is elevated, Cx43 HC opening is promoted in cardiomyocytes and CxMPs counteract this effect.

Trafficking pathways leading to the formation of gap junctions

This chapter reports the mechanisms resulting in the assembly of gap junction intercellular communication channels. The connexin channel protein subunits are required to oligomerize into hexameric hemichannels (connexons) that may be homoor heteromeric in composition. Pairing of connexons in contacting cells leads to the formation of a gap junction unit. Subcellular fractionation studies using guinea-pig liver showed that oligomerization of connexins was complete on entry into Golgi, and that connexons showed heteromeric properties. The low ratio of connexin26 (Cx26; beta 2) relative to Cx32 (beta 1) in endomembranes compared to the approximately equal ratios found in plasma membranes and gap junctions suggest that Cx26 takes a non-classical route to the plasma membrane. Cultured cells, expressing connexin-aequorin chimeras, also provided evidence that Cx26 takes a more rapid non-classical route to the plasma membrane, because brefeldin A, a drug that disrupts the Golgi, had minimal effects on trafficking of Cx26 to the plasma membrane in contrast to its disruption of Cx32 trafficking. Finally, a cell-free approach for studying synthesis of connexons provided further evidence that Cx26 showed membrane insertion properties compatible with a more direct intracellular route to gap junctions. The presence of dual gap junction assembly pathways can explain many of the differential properties exhibited by connexins in cells.

Expression of three functional domains of connexin 32 as thioredoxin fusion proteins in Escherichia coli and generation of antibodies

Gap junctions, intercellular channels that allow cells to communicate directly, are constructed from connexin protein subunits. Connexins traverse the membrane four times and have two extracellular loops and one intracellular loop; the amino and carboxyl tails are located at the intracellular aspect of the plasma membrane. The first extracellular domain (EL1; residues 42-75), the intracellular domain (IL; 94-130), the carboxyl-terminus (CT; 208-283), and the full-length rat connexin 32 (Cx32) gene were subcloned and expressed in Escherichia coli as fusion proteins to the thioredoxin protein (Trx). Under optimal conditions, the expression levels of the various Cx32 domains differed. The Trx-EL1 and Trx-IL fusions were expressed at high levels in G1768 cells and represented 40-60% of total soluble cellular protein 4 h after induction with tryptophan. The Trx-CT fusion protein was produced less efficiently (20% of total soluble cellular protein). However, Trx-Cx32 (full length) was not expressed in E. coli. Linkage of full-length Cx32 to thioredoxin caused a dramatic decrease in the growth of the cultures after induction. Expressed Trx-EL1, Trx-IL, and Trx-CT fusion products were affinity purified over a Thio-Bond resin and used as antigens for generation of polyclonal antibodies to rat connexin32 in rabbits. Antibodies generated to thioredoxin-CT fusion and an antibody produced against a short synthetic peptide (GAP9) corresponding in sequence to an intracellular carboxyl-terminal tail of Cx32 (residues 264-283) identified the same proteins on Western blots. The antibodies to the Trx-CT fusion protein were of higher titer than those generated previously to synthetic peptides. Immunofluorescent staining of rat liver sections with Trx-IL and Trx-CT antibodies demonstrated Cx32 immunoreactivity in punctate areas of the cell surface corresponding to the expected positions of gap junctions.

Connexin 32 of gap junctions contains two cytoplasmic calmodulin-binding domains

A fluorescent calmodulin derivative, 2-chloro-[4-(epsilon-amino-Lys75)]-[6-(4- diethylaminophenyl)-1,3,5-triazin-4-yl]-calmodulin (TA-calmodulin) [Török and Trentham (1994) Biochemistry 33, 12807-12820], and equilibrium fluorescence methods were used to identify calmodulin-binding domains of connexin subunits of gap junctions. Synthetic peptides corresponding to six extramembrane regions of connexin 32, a major component of rat liver gap junctions, and peptides derived from connexin 43 and 26, were tested. Two cytoplasmically oriented peptides that correspond to an N-terminal 21-amino-acid sequence and a 15-amino-acid sequence at the C-terminal tail of connexin 32 bound TA-calmodulin in a Ca2+-dependent manner. The dissociation constants (Kd) of TA-calmodulin binding to GAP 10 (MNWTGLYTLLSGVNRHSTAIG, residues 1-21) and GAP 8M (ACARRAQRRSNPPSR, residues 216-230) were 27 nM and 1.2 microM respectively at 150 mM ionic strength, 2 mM MgCl2, 100 microM CaCl2, pH 7.0 and 21 degrees C. Both halves of each peptide were required for calmodulin binding. Substitution of Trp3 present in all connexins by Tyr increased Kd for TA-calmodulin by 40-fold. Liver gap junctions (whose connexons contain mainly connexin 32) and recombinant connexons constructed of connexin 26 expressed by baculovirus-infected insect cells exhibited weaker binding of TA-calmodulin with variable Ca2+-dependence. These studies identify two calmodulin-binding amino-acid sequences in connexin 32, and provide independent evidence that calmodulin may function as an intracellular ligand, regulating Ca2+-dependent intercellular communication across gap junctions.

Peptides homologous to extracellular loop motifs of connexin 43 reversibly abolish rhythmic contractile activity in rabbit arteries

1. Phenylephrine (10 microM) evoked rises in tension in isolated rings of endothelium-denuded rabbit superior mesenteric artery. These increases consisted of a tonic component with superimposed rhythmic activity, the frequency of which generally remained constant over time but whose amplitude exhibited cycle-to-cycle variability. 2. The amplitude, but not the frequency, of the rhythmic activity was affected by a series of short peptides possessing sequence homology with extracellular loops 1 and 2 of connexin 43 (Cx43). Oscillatory behaviour was abolished at concentrations of 100-300 microM (IC50 of 20-30 microM), without change in average tone. No synergy was evident between peptides corresponding to the extracellular loops, and cytoplasmic loop peptides were biologically inactive. 3. The putative gap junction inhibitor heptanol mimicked the action of the extracellular loop peptides and abolished rhythmic activity at concentrations of 100-300 microM without effects on frequency. However, in marked contrast to the peptides, heptanol completely inhibited the contraction evoked by phenylephrine (IC50, 283 +/- 28 microM). 4. The presence of mRNA encoding Cx32, Cx40 and Cx43 was detected in the rabbit superior mesenteric artery by reverse transcriptase-polymerase chain reaction. Western blot analysis showed that Cx43 was the major connexin in the endothelium-denuded vessel wall. 5. We conclude that intercellular communication between vascular smooth muscle cells via gap junctions is essential for synchronized rhythmic activity in isolated arterial tissue, whereas tonic force development appears to be independent of cell-cell coupling. The molecular specificity of the peptide probes employed in the study suggests that the smooth muscle relaxant effects of heptanol may be non-specific and unrelated to inhibition of gap junctional communication.

Connections with connexins: the molecular basis of direct intercellular signaling

Adjacent cells share ions, second messengers and small metabolites through intercellular channels which are present in gap junctions. This type of intercellular communication permits coordinated cellular activity, a critical feature for organ homeostasis during development and adult life of multicellular organisms. Intercellular channels are structurally more complex than other ion channels, because a complete cell-to-cell channel spans two plasma membranes and results from the association of two half channels, or connexons, contributed separately by each of the two participating cells. Each connexon, in turn, is a multimeric assembly of protein subunits. The structural proteins comprising these channels, collectively called connexins, are members of a highly related multigene family consisting of at least 13 members. Since the cloning of the first connexin in 1986, considerable progress has been made in our understanding of the complex molecular switches that control the formation and permeability of intercellular channels. Analysis of the mechanisms of channel assembly has revealed the selectivity of inter-connexin interactions and uncovered novel characteristics of the channel permeability and gating behavior. Structure/function studies have begun to provide a molecular understanding of the significance of connexin diversity and demonstrated the unique regulation of connexins by tyrosine kinases and oncogenes. Finally, mutations in two connexin genes have been linked to human diseases. The development of more specific approaches (dominant negative mutants, knockouts, transgenes) to study the functional role of connexins in organ homeostasis is providing a new perception about the significance of connexin diversity and the regulation of intercellular communication.

Ca(2+)-mobilizing hormones induce sequentially ordered Ca2+ signals in multicellular systems of rat hepatocytes

The development of hormone-mediated Ca2+ signals was analysed in polarized doublets, triplets and quadruplets of rat hepatocytes by video imaging of fura2 fluorescence. These multicellular models showed dilated bile canaliculi, and gap junctions were observed by using an anti-connexin-32 antibody. They also showed highly organized Ca2+ signals in response to vasopressin or noradrenaline. Surprisingly, the primary rises in intracellular Ca2+ concentration ([Ca2+]i) did not start randomly from any cell of the multiplet. It originated invariably in the same hepatocyte (first-responding cell), and then was propagated in a sequential manner to the nearest connected cells (cell 2, then 3, in triplets; cell 2, 3, then 4 in quadruplets). The sequential activation of the cells appeared to be an intrinsic property of multiplets of rat hepatocytes. (1) In the continued presence of hormones, the same sequential order was observed up to six times, i.e. at each train of oscillations occurring between the cells. (2) The order of [Ca2+]i responses was modified neither by the repeated addition of hormones nor by the hormonal dose. (3) The mechanical disruption of an intermediate cell slowed down the speed of the propagation, suggesting a role of gap junctions in the rapidity of the sequential activation of cells. (4) The same multiplet could have a different first-responding cell for vasopressin or noradrenaline, suggesting a role of the hormonal receptors in the sequentiality of cell responses. It is postulated that a functional heterogeneity of hormonal receptors, and the presence of functional gap junctions, are involved in the existence of sequentially ordered hormone-mediated [Ca2+]i rises in the multiplets of rat hepatocytes.

Pathophysiology of gap junctions in heart disease

Electrical coupling between cardiac muscle cells is mediated by specialized sites of plasma membrane interaction termed gap junctions. These junctions consist of clusters of membrane channels that directly link the cytoplasmic compartments of neighboring cells. Each gap-junctional channel consists of two connexons, one from each of the interacting plasma membranes, extending across the narrow extracellular gap. Connexons are constructed from connexins, a multigene family of conserved proteins. Different connexins confer specific electrophysiologic characteristics on the assembled channel protein. The major connexin of the mammalian heart is connexin43, although other types of connexins are also expressed, notably connexin40 in myocytes of the atrioventricular conduction system. Confocal laser scanning microscopy of anti-connexin43 immunolabeled samples reveals two major abnormalities in myocardial gap junctions in ischemic heart disease: loss of the usual ordered distribution of gap junctions at border zones adjacent to infarct scars, and reduction in the quantity of connexin43 gap junctions in myocardium distant from the infarct. These and other changes reported in myocardial gap-junctional communication pathways following infarction may result in heterogeneous anisotropic conduction and reduced conduction velocity, thereby forming a proarrhythmic substrate. Current evidence suggests that reduction in connexin43 content is a general pathogenetic feature of cardiac disease, and that changes in the expression levels of other connexin types may contribute to altered electrophysiologic function in the diseased heart.