Molecular cloning and functional expression of the mouse gap junction gene connexin-57 in human HeLa cells.

A new mouse connexin gene has been isolated that codes for a connexin protein of 505 amino acid residues. Based on the predicted molecular mass of 57.115 kDa, it has been designated connexin-57. Similar to most other mouse connexin genes, the coding region of connexin-57 is not interrupted by introns and exists in the mouse genome as a single-copy gene. Within the connexin family, this new gene shows highest sequence identity to porcine connexin-60 in the alpha group of connexins. The connexin-57 gene was mapped to a position on mouse chromosome 4, 30 centimorgans proximal to a cluster of previously mapped connexin genes. Low levels of connexin-57 mRNA were detected in skin, heart, kidney, testis, ovary, intestine, and in the mouse embryo after 8 days post coitum, but expression was not detected in brain, sciatic nerve or liver. In order to analyze gene function, the connexin-57 coding region was expressed by transfection in human HeLa cells, where it restored homotypic intercellular transfer of microinjected neurobiotin. Heterotypic transfer was observed between HeLa connexin-57 transfectants and HeLa cells, expressing murine connexin-43, -37, or -30.3. Double whole-cell voltage clamp analyses revealed that HeLa-connexin-57 transfectants expressed about 10 times more channels than parental HeLa cells. Voltage gating by transjunctional and transmembrane voltages as well as unitary conductance ( approximately 27 picosiemens) were different from intrinsic connexin channels in parental HeLa cells.     

Molecular cloning and developmental expression of two chick embryo gap junction proteins

The connexins are a family of related gap junction proteins which contain conserved transmembrane and extracellular domains but unique cytoplasmic regions. To identify connexins with potential roles in development, a chick embryo cDNA library was screened by hybridization at low stringency with a cDNA for rat connexin-43. cDNA clones for two previously undescribed connexins were isolated. Chick connexin-45 has a predicted molecular mass of 45,376 daltons; connexin-42 has a predicted molecular mass of 41,748 daltons. Both of these predicted connexin proteins share the homologous regions noted in other members of this family, and each has its own unique regions. Southern blots of chicken genomic DNA suggest that each connexin is encoded by a distinct single copy gene. RNA blots demonstrate that while chick connexin-43, -42, and -45 are each expressed in a number of chick organs, they each have a unique tissue distribution. Each connexin mRNA is present in heart. Blots of total RNA isolated from hearts of chick embryos of different ages demonstrate that the abundance of connexin-42 and -43 mRNAs varies no more than 2-fold between the embryo and the adult. However, connexin-45 mRNA shows a dramatic change, falling 10-fold from the 6-day embryonic heart to the adult. These multiple connexins are likely to have different physiological properties and may account for the multiple physiologically distinct gap junction channels which have been observed in cardiac myocytes. They may provide a mechanism for the formation of communication compartments in the developing myocardium.     

Conductance and permeability of the residual state of connexin43 gap junction channels

We used cell lines expressing wild-type connexin43 and connexin43 fused with the enhanced green fluorescent protein (Cx43-EGFP) to examine conductance and perm-selectivity of the residual state of Cx43 homotypic and Cx43/Cx43-EGFP heterotypic gap junction channels. Each hemichannel in Cx43 cell-cell channel possesses two gates: a fast gate that closes channels to the residual state and a slow gate that fully closes channels; the transjunctional voltage (V(j)) closes the fast gate in the hemichannel that is on the relatively negative side. Here, we demonstrate macroscopically and at the single-channel level that the I-V relationship of the residual state rectifies, exhibiting higher conductance at higher V(j)s that are negative on the side of gated hemichannel. The degree of rectification increases when Cl(-) is replaced by Asp(-) and decreases when K(+) is replaced by TEA(+). These data are consistent with an increased anionic selectivity of the residual state. The V(j)-gated channel is not permeable to monovalent positively and negatively charged dyes, which are readily permeable through the fully open channel. These data indicate that a narrowing of the channel pore accompanies gating to the residual state. We suggest that the fast gate operates through a conformational change that introduces positive charge at the cytoplasmic vestibule of the gated hemichannel, thereby producing current rectification, increased anionic selectivity, and a narrowing of channel pore that is largely responsible for reducing channel conductance and restricting dye transfer. Consequently, the fast V(j)-sensitive gating mechanism can serve as a selectivity filter, which allows electrical coupling but limits metabolic communication.     

Ionic blockade of the rat connexin40 gap junction channel by large tetraalkylammonium ions.

The rat connexin40 gap junction channel is permeable to monovalent cations including tetramethylammonium and tetraethylammonium ions. Larger tetraalkyammonium (TAA(+)) ions beginning with tetrabutylammonium (TBA(+)) reduced KCl junctional currents disproportionately. Ionic blockade by tetrapentylammonium (TPeA(+)) and tetrahexylammonium (THxA(+)) ions were concentration- and voltage-dependent and occurred only when TAA(+) ions were on the same side as net K(+) efflux across the junction, indicative of block of the ionic permeation pathway. The voltage-dependent dissociation constants (K(m)(V(j))) were lower for THxA(+) than TPeA(+), consistent with steric effects within the pore. The K(m)-V(j) relationships for TPeA(+) and THxA(+) were fit with different reaction rate models for a symmetrical (homotypic) connexin gap junction channel and were described by either a one- or two-site model that assumed each ion traversed the entire V(j) field. Bilateral addition of TPeA(+) ions confirmed a common site of interaction within the pore that possessed identical K(m)(V(j)) values for cis-trans concentrations of TPeA(+) ions as indicated by the modeled I-V relations and rapid channel block that precluded unitary current measurements. The TAA(+) block of K(+) currents and bilateral TPeA(+) interactions did not alter V(j)-gating of Cx40 gap junctions. N-octyl-tributylammonium and -triethylammonium also blocked rCx40 channels with higher affinity and faster kinetics than TBA(+) or TPeA(+), indicative of a hydrophobic site within the pore near the site of block.     

Editorial,Introduction and Acknowledgements

Gap junctions arc intercellular, water-filled channels composed of transmembrane proteins called connexins, six of which are arranged radially and dock with six homologous proteins in an adjacent cell to form an approximate 16 A pore. Through this pore cell-to-cell transfer of small water-soluble molecules up to about 1000 daltons occurs along concentration gradients. Connexins comprise a multigene family that share consensus sequences in the trans-membrane domains and the first and second extracellular loops. Comparison of the protein sequences of known human connexins with the draft nucleotide sequence of the human genome revealed two clones from chromosome 6 which showed strong similarity to highly conserved connexin sequences. Detailed analysis revealed the presence of a 672 nt open reading frame in these clones, encoding a 223 amino acid polypeptide with a predicted molecular weight of about 25 kD. This is smaller than other known human connexins. The ORF of the potential connexin25 was amplified by semi-nested PCR using human genomic DNA as a template. To confirm that this new gene encodes a connexin, Cx25 was transfected into a gap junction deficient subclone of the human HeLa cell line. After selection of transformants, cells were microinjected with the fluorescent dye Lucifer yellow. Transfectants but not controls successfully transferred dye, demonstrating that this new gene encodes a functional connexin.     

Cloning and functional expression of a novel human connexin-25 gene

Gap junctions are intercellular, water-filled channels composed of transmembrane proteins called connexins, six of which are arranged radially and dock with six homologous proteins in an adjacent cell to form an approximate 16 A pore. Through this pore cell-to-cell transfer of small water-soluble molecules up to about 1000 daltons occurs along concentration gradients. Connexins comprise a multigene family that share consensus sequences in the trans-membrane domains and the first and second extracellular loops. Comparison of the protein sequences of known human connexins with the draft nucleotide sequence of the human genome revealed two clones from chromosome 6 which showed strong similarity to highly conserved connexin sequences. Detailed analysis revealed the presence of a 672 nt open reading frame in these clones, encoding a 223 amino acid polypeptide with a predicted molecular weight of about 25 kD. This is smaller than other known human connexins. The ORF of the potential connexin25 was amplified by semi-nested PCR using human genomic DNA as a template. To confirm that this new gene encodes a connexin, Cx25 was transfected into a gap junction deficient subclone of the human HeLa cell line. After selection of transformants, cells were microinjected with the fluorescent dye Lucifer yellow. Transfectants but not controls successfully transferred dye, demonstrating that this new gene encodes a functional connexin.     

Size and selectivity of gap junction channels formed from different connexins

Gap junction channels have long been viewed as static structures containing a large-diameter, aqueous pore. This pore has a high permeability to hydrophilic molecules of 900 daltons in molecular weight and a weak ionic selectivity. The evidence leading to these conclusions is reviewed in the context of more recent observations primarily coming from unitary channel recordings from transfected connexin channels expressed in communication-deficient cell lines. What is emerging is a more diverse view of connexin-specific gap junction channel structure and function where electrical conductance, ionic selectivity, and dye permeability vary by one full order of magnitude or more. Furthermore, the often held contention that channel conductance and ionic or molecular selectivity are inversely proportional is refuted by recent evidence from five distinct connexin channels. The molecular basis for this diversity of channel function remains to be identified for the connexin family of gap junction proteins.     

Open Pore Block of Connexin26 and Connexin32 Hemichannels by Neutral,Acidic and Basic Glycoconjugates

The mechanisms of molecular discrimination by connexin channels are of acute biological and medical importance. The availability of affinity or open-pore blocking reagents for reliable and specific study of the connexin permeability pathway, would make possible the rigorous cellular and physiological studies required to inform, in molecular terms, the underlying role of intercellular communication pathways in development and disease. Previous work utilized a series of glucosaccharides labeled with an uncharged fluorescent aminopyridine (PA-) group to establish steric constraints to permeability through connexin hemichannels. In that work, the smallest probe permeable through homomeric Cx26 and heteromeric Cx26–Cx32 channels was the PA-disaccharide, and the smallest probe permeable through homomeric Cx32 channels was the PA-trisaccharide. The larger impermeable probes did not block permeation of the smaller probes. Building on this work, a new set of glucosaccharide probes was developed in which the label was one of a homologous series of novel anthranilic acid derivatives (ABG) that carry negative or positive formal charge or remain neutral at physiological pH. When the PA-label of the smallest impermeant PA-derivatized oligosaccharides was replaced by ABG label, the resulting probes acted as reversible, high-affinity inhibitors of large molecule permeation through connexin pores in a size and connexin-specific manner.     

Open Pore Block of Connexin26 and Connexin32 Hemichannels by Neutral, Acidic and Basic Glycoconjugates

The mechanisms of molecular discrimination by connexin channels are of acute biological and medical importance. The availability of affinity or open-pore blocking reagents for reliable and specific study of the connexin permeability pathway, would make possible the rigorous cellular and physiological studies required to inform, in molecular terms, the underlying role of intercellular communication pathways in development and disease. Previous work utilized a series of glucosaccharides labeled with an uncharged fluorescent aminopyridine (PA-) group to establish steric constraints to permeability through connexin hemichannels. In that work, the smallest probe permeable through homomeric Cx26 and heteromeric Cx26-Cx32 channels was the PA-disaccharide, and the smallest probe permeable through homomeric Cx32 channels was the PA-trisaccharide. The larger impermeable probes did not block permeation of the smaller probes. Building on this work, a new set of glucosaccharide probes was developed in which the label was one of a homologous series of novel anthranilic acid derivatives (ABG) that carry negative or positive formal charge or remain neutral at physiological pH. When the PA-label of the smallest impermeant PA-derivatized oligosaccharides was replaced by ABG label, the resulting probes acted as reversible, high-affinity inhibitors of large molecule permeation through connexin pores in a size and connexin-specific manner.     

Cloning and Functional Expression of a Novel Human Connexin-25 Gene

Gap junctions arc intercellular, water-filled channels composed of transmembrane proteins called connexins, six of which are arranged radially and dock with six homologous proteins in an adjacent cell to form an approximate 16 A pore. Through this pore cell-to-cell transfer of small water-soluble molecules up to about 1000 daltons occurs along concentration gradients. Connexins comprise a multigene family that share consensus sequences in the trans-membrane domains and the first and second extracellular loops. Comparison of the protein sequences of known human connexins with the draft nucleotide sequence of the human genome revealed two clones from chromosome 6 which showed strong similarity to highly conserved connexin sequences. Detailed analysis revealed the presence of a 672 nt open reading frame in these clones, encoding a 223 amino acid polypeptide with a predicted molecular weight of about 25 kD. This is smaller than other known human connexins. The ORF of the potential connexin25 was amplified by semi-nested PCR using human genomic DNA as a template. To confirm that this new gene encodes a connexin, Cx25 was transfected into a gap junction deficient subclone of the human HeLa cell line. After selection of transformants, cells were microinjected with the fluorescent dye Lucifer yellow. Transfectants but not controls successfully transferred dye, demonstrating that this new gene encodes a functional connexin.     

Open pore block of connexin26 and connexin32 hemichannels by neutral, acidic and basic glycoconjugates

The mechanisms of molecular discrimination by connexin channels are of acute biological and medical importance. The availability of affinity or open-pore blocking reagents for reliable and specific study of the connexin permeability pathway, would make possible the rigorous cellular and physiological studies required to inform, in molecular terms, the underlying role of intercellular communication pathways in development and disease. Previous work utilized a series of glucosaccharides labeled with an uncharged fluorescent aminopyridine (PA-) group to establish steric constraints to permeability through connexin hemichannels. In that work, the smallest probe permeable through homomeric Cx26 and heteromeric Cx26-Cx32 channels was the PA-disaccharide, and the smallest probe permeable through homomeric Cx32 channels was the PA-trisaccharide. The larger impermeable probes did not block permeation of the smaller probes. Building on this work, a new set of glucosaccharide probes was developed in which the label was one of a homologous series of novel anthranilic acid derivatives (ABG) that carry negative or positive formal charge or remain neutral at physiological pH. When the PA-label of the smallest impermeant PA-derivatized oligosaccharides was replaced by ABG label, the resulting probes acted as reversible, high-affinity inhibitors of large molecule permeation through connexin pores in a size and connexin-specific manner.     

Single administration of hepatotoxic chemicals transiently decreases the gap-junction-protein levels of connexin 32 in rat liver.

Effects of a single administration of hepatotoxic chemicals on the major gap-junction protein of liver (connexin 32) were studied in rats. The connexin-32 content was analyzed by immunoblotting and immunohistochemistry using an affinity-purified monoclonal antibody against connexin 32. The connexin-32 content decreased dramatically to less than 10% of the control value 24 h after injection of 25 mg/kg dimethylnitrosamine and returned to the normal level 240 h later. Injection of CCl4 at a dose of 1 ml/kg also caused a transient reduction of connexin-32 content in the liver, as seen after the dimethylnitrosamine injection. The decrease in hepatic connexin-32 content was inversely correlated to the increase in plasmic alanine-aminotransferase activity which has been used as an index of acute liver injury. The changes in connexin 32 were essentially similar to those observed in regenerating liver after partial hepatectomy. However, incorporation of [3H]thymidine into liver DNA after dimethylnitrosamine injection was significantly less than that obtained after partial hepatectomy. The 5'-nucleotidase activity of the plasma-membrane fraction of the liver was not significantly altered by the injection of dimethylnitrosamine. These results suggest that liver gap-junction protein is specifically reduced by acute liver injury and that this kind of decrease in connexin 32 is not simply related to cell proliferation, unlike the decrease after partial hepatectomy.     

Modulation of membrane channel currents by gap junction protein mimetic peptides: size matters

Connexin mimetic peptides are widely used to assess the contribution of nonjunctional connexin channels in several processes, including ATP release. These peptides are derived from various connexin sequences and have been shown to attenuate processes downstream of the putative channel activity. Yet so far, no documentation of effects of peptides on connexin channels has been presented. We tested several connexin and pannexin mimetic peptides and observed attenuation of channel currents that is not compatible with sequence specific actions of the peptides. Connexin mimetic peptides inhibited pannexin channel currents but not the currents of the channel formed by connexins from which the sequence was derived. Pannexin mimetic peptides did inhibit pannexin channel currents but also the channels formed by connexin 46. The same pattern of effects was observed for dye transfer, except that the inhibition levels were more pronounced than for the currents. The channel inhibition by peptides shares commonalities with channel effects of polyethylene glycol (PEG), suggesting a steric block as a mechanism. PEG accessibility is in the size range expected for the pore of innexin gap junction channels, consistent with a functional relatedness of innexin and pannexin channels. mimetic peptide; polyethylene glycol; calcium wave     

Multi-ion distributions in the cytoplasmic domain of inward rectifier potassium channels

Inward rectifier potassium (Kir) channels act as cellular diodes, allowing unrestricted flow of potassium (K⁺) into the cell while preventing currents of large magnitude in the outward direction. The rectification mechanism by which this occurs involves a coupling between K⁺ and intracellular blockers—magnesium (Mg²⁺) or polyamines—that simultaneously occupy the permeation pathway. In addition to the transmembrane pore, Kirs possess a large cytoplasmic domain (CD) that provides a favorable electronegative environment for cations. Electrophysiological experiments have shown that the CD is a key regulator of both conductance and rectification. In this study, we calculate and compare averaged equilibrium probability densities of K⁺ and Cl⁻ in open-pore models of the CDs of a weak (Kir1.1-ROMK) and a strong (Kir2.1-IRK) rectifier through explicit-solvent molecular-dynamics simulations in ∼1 M KCl. The CD of both channels concentrates K⁺ ions greater than threefold inside the cytoplasmic pore while IRK shows an additional K⁺ accumulation region near the cytoplasmic entrance. Simulations carried out with Mg²⁺ or spermine (SPM⁴⁺) show that these ions interact with pore-lining residues, shielding the surface charge and reducing K⁺ in both channels. The results also show that SPM⁴⁺ behaves differently inside these two channels. Although SPM⁴⁺ remains inside the CD of ROMK, it diffuses around the entire volume of the pore. In contrast, this polyatomic cation finds long-lived conformational states inside the IRK pore, interacting with residues E224, D259, and E299. The strong rectifier CD is also capable of sequestering an additional SPM⁴⁺ at the cytoplasmic entrance near a cluster of negative residues D249, D274, E275, and D276. Although understanding the actual mechanism of rectification blockade will require high-resolution structural information of the blocked state, these simulations provide insight into how sequence variation in the CD can affect the multi-ion distributions that underlie the mechanisms of conduction, rectification affinity, and kinetics.     

Pharmacological sensitivity of ATP release triggered by photoliberation of inositol-1,4,5-trisphosphate and zero extracellular calcium in brain endothelial cells

Recently, ATP has gained much interest as an extracellular messenger involved in the communication of calcium signals between cells. The mechanism of ATP release is, however, still a matter of debate. In the present study we investigated the possible contribution of connexin hemichannels or ion channels in the release of ATP in GP8, a rat brain endothelial cell line. Release of ATP was triggered by photoactivation of InsP(3) or by reducing the extracellular calcium concentration. Both trigger protocols induced ATP release significantly above baseline. InsP(3)-triggered ATP release was completely blocked by alpha-glycyrrhetinic acid (alpha-GA), the connexin mimetic peptides gap 26 and 27, and the trivalent ions gadolinium and lanthanum. ATP release triggered by zero calcium was, in addition to these substances, also blocked by flufenamic acid (FFA), niflumic acid, and NPPB. Gap 27 selectively blocked zero calcium-triggered ATP release in connexin-43 transfected HeLa cells, while having no effect in wild-type and connexin-32 transfected cells. Of all the agents used, only alpha-GA, FFA and NPPB significantly reduced gap junctional coupling. In conclusion, InsP(3) and zero calcium-triggered ATP release show major similarities but also some differences in their sensitivity to the agents applied. It is suggested that both stimuli trigger ATP release through the same mechanism, which is connexin-dependent, permeable in both directions, potently blocked by connexin mimetic peptides, and consistent with the opening of connexin hemichannels.     

Regulation of the inward rectifying properties of G-protein-activated inwardly rectifying K+ (GIRK) channels by Gbeta gamma subunits

Gbetagamma subunits are known to bind to and activate G-protein-activated inwardly rectifying K(+) channels (GIRK) by regulating their open probability and bursting behavior. Studying G-protein regulation of either native GIRK (I(KACh)) channels in feline atrial myocytes or heterologously expressed GIRK1/4 channels in Chinese hamster ovary cells and HEK 293 cells uncovered a novel Gbetagamma subunit mediated regulation of the inwardly rectifying properties of these channels. I(KACh) activated by submaximal concentrations of acetylcholine exhibited a approximately 2.5-fold stronger inward rectification than I(KACh) activated by saturating concentrations of acetylcholine. Similarly, the inward rectification of currents through GIRK1/4 channels expressed in HEK cells was substantially weakened upon maximal stimulation with co-expressed Gbetagamma subunits. Analysis of the outward current block underlying inward rectification demonstrated that the fraction of instantaneously blocked channels was reduced when Gbetagamma was over-expressed. The Gbetagamma induced weakening of inward rectification was associated with reduced potencies for Ba(2+) and Cs(+) to block channels from the extracellular side. Based on these results we propose that saturation of the channel with Gbetagamma leads to a conformational change within the pore of the channel that reduced the potency of extracellular cations to block the pore and increased the fraction of channels inert to a pore block in outward direction.     

The permeability of gap junction channels to probes of different size is dependent on connexin composition and permeant-pore affinities

Gap junctions have traditionally been characterized as nonspecific pores between cells passing molecules up to 1 kDa in molecular mass. Nonetheless, it has become increasingly evident that different members of the connexin (Cx) family mediate quite distinct physiological processes and are often not interchangeable. Consistent with this observation, differences in permeability to natural metabolites have been reported for different connexins, although the physical basis for selectivity has not been established. Comparative studies of different members of the connexin family have provided evidence for ionic charge selectivity, but surprisingly little is known about how connexin composition affects the size of the pore. We have employed a series of Alexa dyes, which share similar structural characteristics but range in size from molecular weight 350 to 760, to probe the permeabilities and size limits of different connexin channels expressed in Xenopus oocytes. Correlated dye transfer and electrical measurements on each cell pair, in conjunction with a three-dimensional mathematical model of dye diffusion in the oocyte system, allowed us to obtain single channel permeabilities for all three dyes in six homotypic and four heterotypic channels. Cx43 and Cx32 channels passed all three dyes with similar efficiency, whereas Cx26, Cx40, and Cx45 channels showed a significant drop-off in permeability with the largest dye. Cx37 channels only showed significant permeability for the smaller two dyes, but at two- to sixfold lower levels than other connexins tested. In the heterotypic cases studied (Cx26/Cx32 and Cx43/Cx37), permeability characteristics were found to resemble the more restrictive parental homotypic channel. The most surprising finding of the study was that the absolute permeabilities calculated for all gap junctional channels in this study are, with one exception, at least 2 orders of magnitude greater than predicted purely on the basis of hindered pore diffusion. Consequently, affinity between the probes and the pore creating an energetically favorable in-pore environment, which would elevate permeant concentration within the pore and hence the flux, is strongly implicated.     

Prediction of the translocation kinetics of a protein from its mechanical properties

Proteins are actively unfolded to pass through narrow channels in macromolecular complexes that catalyze protein translocation and degradation. Catalyzed unfolding shares many features that characterize the mechanical unfolding of proteins using the atomic force microscope (AFM). However, simulations of unfolding induced by the AFM and when a protein is translocated through a pore suggest that each process occurs by distinct pathways. The link, if any, between each type of unfolding, therefore, is not known. We show that the mechanical unfolding energy landscape of a protein, obtained using an atomistic molecular model, can be used to predict both the relative mechanical strength of proteins when unfolded using the AFM and when unfolded by translocation into a pore. We thus link the two processes and show that the import rate through a pore not only depends on the location of the initiation tag but also on the mechanical properties of the protein when averaged over all the possible geometries that are relevant for a given translocation initiation site.     

Cutting edge: Lack of evidence for connexin-43 expression in human epidermal Langerhans cells

A provocative study has shown that viral peptides may be transferred in vitro from epithelial cells to APC through connexin-43 gap junction channels. In support of this cross-presentation pathway, the study also reported that human dendritic cells, including Langerhans cells of skin, express connexin-43. In this report we show that if this was the case, the levels of connexin-43 are below those detectable by immunofluorescence, flow cytometry, quantitative PCR of purified CD1a+ cells, and electron microscopy, raising questions about the relevance of the connexin-43-dependent mechanism for Langerhans cells of noninflamed human skin.