Molecular connexin partner remodeling orchestrates connexin traffic: From physiology to pathophysiology

Connexins, through gap junctional intercellular communication, are known to regulate many physiological functions involved in developmental processes such as cell proliferation, differentiation, migration and apoptosis. Strikingly, alterations of connexin expression and trafficking are often, if not always, associated with human developmental diseases and carcinogenesis. In this respect, disrupted trafficking dynamics and aberrant intracytoplasmic localization of connexins are considered as typical features of functionality failure leading to the pathological state. Recent findings demonstrate that interactions of connexins with numerous protein partners, which take place throughout connexin trafficking, are essential for gap junction formation, membranous stabilization and degradation. In the present study, we give an overview of the physiological molecular machinery and of the specific interactions between connexins and their partners, which are involved in connexin trafficking, and we highlight their changes in pathological situations.     

Pathways and control of connexin oligomerization

Connexins form gap junction channels that link neighboring cells into an intercellular communication network. Many cells that express multiple connexins produce heteromeric channels containing at least two connexins, which provides a means to fine tune gap junctional communication. Formation of channels by multiple connexins is controlled at two levels: by inherent structural compatibilities that enable connexins to hetero-oligomerize and by cellular mechanisms that restrict the formation of heteromers by otherwise compatible connexins. Here, I discuss roles for secretory compartments beyond the endoplasmic reticulum in connexin oligomerization and evidence that suggests that membrane microdomains help regulate connexin trafficking and assembly.     

Connexin45 interacts with zonula occludens-1 and connexin43 in osteoblastic cells

The relative expression of connexin43 and connexin45 modulates gap junctional communication and production of bone matrix proteins in osteoblastic cells. It is likely that changes in gap junction permeability are determined by the interaction between these two proteins. Cx43 interacts with ZO-1, which may be involved in trafficking of Cx43 or facilitating interactions between Cx43 and other proteins. In this study we sought to identify proteins that associate with Cx45 by coprecipitation in non-denaturing conditions. Cx45 was isolated with a 220-kDa protein that we identified as ZO-1. Under the same conditions, Cx43 also was isolated with anti-Cx45 antiserum from Cx45-transfected ROS cells (ROS/Cx45 cells). Cx43 antiserum could also coprecipitate ZO-1 in the transfected and untransfected ROS cells. Double label immunofluorescence studies showed that ZO-1, Cx43, and Cx45 colocalized at appositional membranes in ROS/Cx45 cells suggesting that all three proteins are normally associated in the cells. Additionally, we found that in vitro translated ZO-1 binds to the carboxyl-terminal of Cx45 indicating that there is a direct interaction between the carboxyl-terminal of Cx45 and ZO-1. These studies demonstrate that ZO-1 interacts with Cx45 as well as with Cx43, and suggest that the interaction of connexins with ZO-1 may play a role in regulating the composition of the gap junction and may modulate connexin-connexin interactions.     

Analysis of connexin phosphorylation sites

Most connexins, the proteins that form gap junction channels, are phosphoproteins. Connexin phosphorylation has been thought to regulate gap junctional protein trafficking, gap junction assembly, channel gating, and turnover. Connexin phosphorylation has been investigated in a variety of ways. Some connexins show mobility shifts in sodium dodecyl sulfate-polyacrylamide gel electrophoresis on phosphorylation. Kinase modulators can change the level of connexin phosphorylation and affect gap junctional communication levels. Metabolic labeling of cultured cells has allowed both phosphoamino acid identification and generation of phosphotryptic peptide maps. However, identification of the location of phosphorylated residues within the connexin sequence has required either targeted peptide synthesis, in vitro phosphorylation of known sites, and two-dimensional comigration studies or liquid chromatographic separation and N-terminal sequencing of peptides. In addition to these conventional methods, we discuss new applications of mass spectrometry to the identification of phosphorylated peptides and the specific residues phosphorylated within the connexin-derived peptide.     

Doubly mutant mice, deficient in connexin32 and -43, show normal prenatal development of organs where the two gap junction proteins are expressed in the same cells

The connexins are a family of proteins that form the intercellular membrane channels of gap junctions. Genes encoding 13 different rodent connexins have been cloned and characterized to date. Connexins vary both in their distribution among adult cell types and in the properties of the channels that they form. In order to explore the functional significance of connexin diversity, several mouse connexin-encoding genes have been disrupted by homologous recombination in embryonic stem cells. Although those experiments have illuminated specific physiological roles for individual connexins, the results have also raised the possibility that connexins may functionally compensate for one another in cells where they are coexpressed. In the present study, we have tested this hypothesis by interbreeding mice carrying null mutations in the genes (Gjb1 and Gja1) encoding connexin32 (beta 1 connexin) and connexin43 (alpha 1 connexin), respectively. We found that fetuses lacking both connexins survive to term but, as expected, the pups die soon thereafter from the cardiac abnormality caused by the absence of connexin43. A survey of the major organ systems of the doubly mutant fetuses, including the thyroid gland, developing teeth, and limbs where these two connexins are coexpressed, failed to reveal any morphological abnormalities not already seen in connexin43 deficient fetuses. Furthermore, the production of thyroxine by doubly mutant thyroids was confirmed by immunocytochemistry. We conclude that, at least as far as the prenatal period is concerned, the normal development of those three organs in fetuses lacking connexin43 cannot simply be explained by the additional presence of connexin32 and vice-versa. Either gap junctional coupling is dispensable in embryonic and fetal cells in which these two connexins are coexpressed, or coupling is provided by yet another connexin when both are absent.     

Regulation of gap junction intercellular communication by the ubiquitin system

Intercellular communication via gap junctions plays a critical role in numerous cellular processes, including the control of cell growth and differentiation, maintenance of tissue homeostasis and embryonic development. Gap junctions are aggregates of intercellular channels that enable adjacent cells in solid tissues to directly exchange ions and small molecules. These channels are formed by a family of integral membrane proteins called connexins, of which the best studied is connexin43. Connexins have a high turnover rate in most tissue types, and degradation of connexins is considered to be a tightly regulated process. Post-translational modification of connexins by ubiquitin is emerging as an important event in the regulation of connexin degradation. Ubiquitination is involved in endoplasmic reticulum-associated degradation of connexins as well as in trafficking of connexins to lysosomes. At both the endoplasmic reticulum and the plasma membrane, ubiquitination of connexins is strongly affected by changes in the extracellular environment. There is increasing evidence that the regulation of connexin ubiquitination might be an important mechanism for rapidly modifying the level of functional gap junctions at the plasma membrane, under both normal and pathological conditions. This review discusses the current knowledge about the regulation of intercellular communication via gap junctions by ubiquitination of connexins.     

Investigation of the reciprocal relationship between the expression of two gap junction connexin proteins, connexin46 and connexin43

Connexins are the transmembrane proteins that form gap junctions between adjacent cells. The function of the diverse connexin molecules is related to their tissue-specific expression and highly dynamic turnover. Although multiple connexins have been previously reported to compensate for each other's functions, little is known about how connexins influence their own expression or intracellular regulation. Of the three vertebrate lens connexins, two connexins, connexin43 (Cx43) and connexin46 (Cx46), show reciprocal expression and subsequent function in the lens and in lens cell culture. In this study, we investigate the reciprocal relationship between the expression of Cx43 and Cx46. Forced depletion of Cx43, by tumor-promoting phorbol ester 12-O-tetradecanoylphorbol-13-acetate, is associated with an up-regulation of Cx46 at both the protein and message level in human lens epithelial cells. An siRNA-mediated down-regulation of Cx43 results in an increase in the level of Cx46 protein, suggesting endogenous Cx43 is involved in the regulation of endogenous Cx46 turnover. Overexpression of Cx46, in turn, induces the depletion of Cx43 in rabbit lens epithelial cells. Cx46-induced Cx43 degradation is likely mediated by the ubiquitin-proteasome pathway, as (i) treatment with proteasome inhibitors restores the Cx43 protein level and (ii) there is an increase in Cx43 ubiquitin conjugation in Cx46-overexpressing cells. We also present data that shows that the C-terminal intracellular tail domain of Cx46 is essential to induce degradation of Cx43. Therefore, our study shows that Cx43 and Cx46 have novel functions in regulating each other's expression and turnover in a reciprocal manner in addition to their conventional roles as gap junction proteins in lens cells.     

Developmental expression patterns of connexin26 and -30 in the rat cochlea

Connexin proteins form transmembranous gap junction channels that connect adjacent cells. Connexin26 and connexin30 have been previously shown to be strongly expressed in the inner ear of adult rats and to be mainly colocalized. Because intercellular connections by gap junction proteins are crucial for maturation of different tissues, we investigated the developmental expression of connexin26 and connexin30 in pre- and postnatal rats using immunocytochemistry. In the rat otocyst, staining for connexin26 as well as for connexin30 appeared at the 17th day of gestation. However, at this stage, expression of connexin30 was low and restricted to the neurosensory epithelium. Beginning from the 3rd postnatal day connexin26 and -30 were expressed with highest immunoreaction in the spiral limbus, the neurosensory epithelium, and between the stria vascularis and the spiral ligament. Beginning from postnatal day 12 the staining pattern resembled that of adult animals, with additional strong staining between all fibrocytes of the spiral ligament. Double labeling experiments demonstrated strongest colocalization of both connexins between the stria vascularis and the spiral ligament. These results demonstrate that development of the cochlear gap junction system precedes the functional maturation of the rat inner ear, which takes place between the 2nd and 3rd postnatal week. In the cochlea of a 22-week-old human embryo, connexin26 and connexin30 could be detected in the lateral wall, suggesting that both connexins also play a crucial role in function of the human inner ear.     

Modifications in connexin expression in liver development and cancer

The establishment of an elaborate gap junctional intercellular communication network, especially between hepatocytes, is important for normal liver development. In fact, the production of the gap junction building blocks, the connexins, undergoes several well-defined changes throughout the hepatic differentiation process. This ultimately results in the acquisition of an adult connexin expression pattern which is critical for maintaining the fully differentiated hepatocyte-specific phenotype. Abnormalities of connexin production are observed in a number of pathological conditions, such as during liver cancer. This article provides an overview of these processes with emphasis on the underlying molecular mechanisms.     

The effects of connexin phosphorylation on gap junctional communication

Gap junctions are specialized membrane domains composed of collections of channels that directly connect neighboring cells providing for the cell-to-cell diffusion of small molecules, including ions, amino acids, nucleotides, and second messengers. Vertebrate gap junctions are composed of proteins encoded by the "connexin" gene family. In most cases examined, connexins are modified post-translationally by phosphorylation. Phosphorylation has been implicated in the regulation of gap junctional communication at several stages of the connexin "lifecycle", such as the trafficking, assembly/disassembly, degradation, as well as, the gating of gap junction channels. Since connexin43 (Cx43) is widely expressed in tissues and cell lines, we understand the most about how it is regulated, and thus, connexin43 phosphorylation is a major focus of this review. Recent reports utilizing new methodologies combined with the latest genome information have shown that activation of several kinases including protein kinase A, protein kinase C, p34(cdc2)/cyclin B kinase, casein kinase 1, mitogen-activated protein (MAP) kinase and pp60(src) kinase can lead to phosphorylation at 12 of the 21 serine and two of the six tyrosine residues in the C-terminal region of connexin43. In several cases, use of site-directed mutants of these sites have shown that these specific phosphorylation events can be linked to changes in gap junctional communication.     

Developmental expression patterns of connexin26 and ‐30 in the rat cochlea

Connexin proteins form transmembranous gap junction channels that connect adjacent cells. Connexin26 and connexin30 have been previously shown to be strongly expressed in the inner ear of adult rats and to be mainly colocalized. Because intercellular connections by gap junction proteins are crucial for maturation of different tissues, we investigated the developmental expression of connexin26 and connexin30 in pre‐ and postnatal rats using immunocytochemistry. In the rat otocyst, staining for connexin26 as well as for connexin30 appeared at the 17th day of gestation. However, at this stage, expression of connexin30 was low and restricted to the neurosensory epithelium. Beginning from the 3rd postnatal day connexin26 and ‐30 were expressed with highest immunoreaction in the spiral limbus, the neurosensory epithelium, and between the stria vascularis and the spiral ligament. Beginning from postnatal day 12 the staining pattern resembled that of adult animals, with additional strong staining between all fibrocytes of the spiral ligament. Double labeling experiments demonstrated strongest colocalization of both connexins between the stria vascularis and the spiral ligament. These results demonstrate that development of the cochlear gap junction system precedes the functional maturation of the rat inner ear, which takes place between the 2nd and 3rd postnatal week. In the cochlea of a 22‐week‐old human embryo, connexin26 and connexin30 could be detected in the lateral wall, suggesting that both connexins also play a crucial role in function of the human inner ear. Dev. Genet. 25:306–311, 1999. © 1999 Wiley‐Liss, Inc.     

Astroglial connexin 43 sustains glutamatergic synaptic efficacy

Astrocytes dynamic interactions with neurons play an active role in neurotransmission. The gap junction (GJ) subunits connexins 43 and 30 are strongly expressed in astrocytes and have recently been shown to regulate synaptic activity and plasticity. However, the specific role of connexin 43 in the morphological and electrophysiological properties of astrocytes in situ as well as in synaptic transmission remains unknown. Here, we show that connexin 43, a major determinant of astroglial GJ coupling, regulates astrocyte cell volume, but has no impact on astroglial passive membrane properties. Furthermore, we demonstrate that connexin 43 modulates glutamatergic synaptic activity of hippocampal CA1 pyramidal cells. This regulation involves changes in synaptically released glutamate, with no alteration in neuronal excitability or postsynaptic function. These results reveal connexin 43 as a critical player in neuroglial interactions by supporting synaptic efficacy.     

Expression of different connexin genes in rat uterus during decidualization and at term.

The expression of different connexin genes (cx26, cx32, cx37, cx43) that code for the protein subunits of gap junctions, was investigated in various uterine tissues during the estrous cycle of nonpregnant rats, in pregnant rats at decidualization and at term. Connexin gene expression was studied at the mRNA level by Northern blot hybridization and at the protein level by immunocytochemistry. In gap junctions from uterine epithelium, stroma, or myometrium, connexin 26 and/or connexin 43 are much more abundant than connexins 32 and 37. The expression of connexin 26 and 43 appears to be modulated by maternal steroid hormones. High expression of these connexins is found in developing decidual cells by day 7 to 8 post coitum; furthermore, coexpression of connexins 26 and 43 in myometrium is observed just before delivery on day 21 post coitum. In both the decidua and the myometrium, the connexin 26 protein appears to be distributed in lower abundance than connexin 43. In uterine epithelium only connexin 26 is expressed throughout all of the reproductive phases investigated. The enhanced expression of this gene correlates with higher levels of maternal estrogen both in the proestrus/estrus phase and at term. The distinct spatial and temporal pattern of expression of connexins 26 and 43 in different uterine tissues suggests a physiological role for these proteins during embryo implantation and subsequent contraction of the uterus at birth.     

Biological role of connexin intercellular channels and hemichannels

Gap junctions (GJ) and hemichannels (HC) formed from the protein subunits called connexins are transmembrane conduits for the exchange of small molecules and ions. Connexins and another group of HC-forming proteins, pannexins comprise the two families of transmembrane proteins ubiquitously distributed in vertebrates. Most cell types express more than one connexin or pannexin. While connexin expression and channel activity may vary as a function of physiological and pathological states of the cell and tissue, only a few studies suggest the involvement of pannexin HC in acquired pathological conditions. Importantly, genetic mutations in connexin appear to interfere with GJ and HC function which results in several diseases. Thus connexins could serve as potential drug target for therapeutic intervention. Growing evidence suggests that diseases resulting from HC dysfunction might open a new direction for development of specific HC reagents. This review provides a comprehensive overview of the current studies of GJ and HC formed by connexins and pannexins in various tissue and organ systems including heart, central nervous system, kidney, mammary glands, ovary, testis, lens, retina, inner ear, bone, cartilage, lung and liver. In addition, present knowledge of the role of GJ and HC in cell cycle progression, carcinogenesis and stem cell development is also discussed.     

Gap junction channels formed by coexpressed connexin40 and connexin43

Many cardiovascular cells coexpress multiple connexins (Cx), leading to the potential formation of mixed (heteromeric) gap junction hemichannels whose biophysical properties may differ from homomeric channels containing only one connexin type. We examined the potential interaction of connexin Cx43 and Cx40 in HeLa cells sequentially stably transfected with these two connexins. Immunoblots verified the production of comparable amounts of both connexins, cross-linking showed that both connexins formed oligomers, and immunofluorescence showed extensive colocalization. Moreover, Cx40 copurified with (His)(6)-tagged Cx43 by affinity chromatography of detergent-solubilized connexons, demonstrating the presence of both connexins in some hemichannels. The dual whole cell patch-clamp method was used to compare the gating properties of gap junctions in HeLa Cx43/Cx40 cells with homotypic (Cx40-Cx40 and Cx43-Cx43) and heterotypic (Cx40-Cx43) gap junctions. Many of the observed single channel conductances resembled those of homotypic or heterotypic channels. The steady-state junctional conductance (g(j,ss)) in coexpressing cell pairs showed a reduced sensitivity to the voltage between cells (V(j)) compared with homotypic gap junctions and/or an asymmetrical V(j) dependence reminiscent of heterotypic gap junctions. These gating properties could be fit using a combination of homotypic and heterotypic channel properties. Thus, whereas our biochemical evidence suggests that Cx40 and Cx43 form heteromeric connexons, we conclude that they are functionally insignificant with regard to voltage-dependent gating.     

Coexpression of connexin 45 with connexin 43 decreases gap junction size

In the human heart, ventricular myocytes express connexin 43 (Cx43) and traces of Cx45. In congestive heart failure, Cx43 levels decrease, Cx45 levels increase and gap junction size decreases. To determine whether alterations of connexin coexpression ratio influence gap junction size, we engineered a rat liver epithelial cell line that endogenously expresses Cx43 to coexpress inducible levels of Cx45 under stimulation of the insect hormone, ponasterone A. In cells induced to express Cx45, gap junction sizes are significantly reduced (by 15% to 20%; p < 0.001), an effect that occurs despite increased levels of junctional connexons made from both connexins. In contrast, coexpression of Cx40 with Cx43 does not lead to any change in gap junction size. These results are consistent with the idea that increased Cx45 expression in the failing ventricle contributes to decreased gap junction size.     

Crucial motifs and residues in the extracellular loops influence the formation and specificity of connexin docking

Most of the early studies on gap junction (GJ) channel function and docking compatibility were on rodent connexins, while recent research on GJ channels gradually shifted from rodent to human connexins largely due to the fact that mutations in many human connexin genes are found to associate with inherited human diseases. The studies on human connexins have revealed some key differences from those found in rodents, calling for a comprehensive characterization of human GJ channels. Functional studies revealed that docking and formation of functional GJ channels between two hemichannels are possible only between docking-compatible connexins. Two groups of docking-compatible rodent connexins have been identified. Compatibility is believed to be due to their amino acid residue differences at the extracellular loop domains (E1 and E2). Sequence alignment of the E1 and E2 domains of all connexins known to make GJs revealed that they are highly conserved and show high sequence identity with human Cx26, which is the only connexin with near atomic resolution GJ structure. We hypothesize that different connexins have a similar structure as that of Cx26 at the E1 and E2 domains and use the corresponding residues in their E1 and E2 domains for docking. Based on the Cx26 GJ structure and sequence analysis of well-studied connexins, we propose that the E1-E1 docking interactions are staggered with each E1 interacting with two E1s on the docked connexon. The putative E1 docking residues are conserved in both docking-compatible and -incompatible connexins, indicating that E1 does not likely serve a role in docking compatibility. However, in the case of E2-E2 docking interactions, the putative docking residues are only conserved within the docking-compatible connexins, suggesting the E2 is likely to serve the function of docking compatibility. Docking compatibility studies on human connexins have attracted a lot of attention due to the fact that putative docking residues are mutational hotspots for several connexin-linked human diseases. This article is part of a Special Issue entitled: Gap Junction Proteins edited by Jean Claude Herve.     

Ilimaquinone inhibits gap junctional communication in a connexin isotype-specific manner

Ilimaquinone (IQ) and brefeldin A (BFA) disrupt the Golgi complex structure and block protein transport to the plasma membrane, and inhibit gap junctional communication. HeLa cells expressing rat connexin26, 32, or 43, or mouse connexin31, 36, 45, or 57, were used to study the response patterns of gap junctional communication (dye transfer) to ilimaquinone, brefeldin, and the potent protein kinase C (PKC) activator 12-O-tetradecanoylphorbol-13-acetate (TPA). 12-O-Tetradecanoylphorbol-13-acetate (followed for 2 h) caused dose- and time-dependent decreases in communication for five of seven connexins, the unresponsive being connexin45 and 57. Brefeldin (followed for 6 h) caused dose- and time-dependent decreases in communication for six of seven connexins, the exception being connexin26. These results are consistent with Golgi-mediated transport to the cell membrane for all connexins except connexin26. In contrast, ilimaquinone (followed for 6 h) caused a rapid (15-30 min) and nearly complete inhibition of dye transfer through connexin43 channels. For the other connexins, there was a slow and weak response for connexin26, 31, and 32, reaching 65-70% of control communication level, while connexin36, 45, and 57 were unresponsive. Thus, among the tested connexins, ilimaquinone has a strong specificity for connexin43, and the mechanism appears independent of the Golgi complex and of protein kinase C.