Kinetics of Protein-Protein Interactions of Connexins: Use of Enzyme Linked Sorbent Assays

Determination of the protein-protein interactions of connexins has become a rapidly expanding field of research. While there are multiple methods of determining the identity of binding partners, determination of the strengths of interactions is not as simple. Here we describe the use of the in vitro method Enzyme Linked Sorbent Assay (ELSA) to compare binding affinities of known protein partners for Connexin43. We used the binding of Cx43 Carboxyl Terminal domain to the PDZ-2 domain of Zonula Occludens-1 and to the SH3 domain of c-Src. In the ELSA assay we found that while the binding of the SH3 domain of c-Src is pH-dependent, the interaction of the PDZ domain of ZO-1 is not. These data confirm findings using Surface Plasmon Resonance (1) and indicate that ELSA can be a useful tool in determining the kinetics of protein-protein interactions.     

Kinetics of Protein-Protein Interactions of Connexins: Use of Enzyme Linked Sorbent Assays

Determination of the protein-protein interactions of connexins has become a rapidly expanding field of research. While there are multiple methods of determining the identity of binding partners, determination of the strengths of interactions is not as simple. Here we describe the use of the in vitromethod Enzyme Linked Sorbent Assay (ELSA) to compare binding affinities of known protein partners for Connexin43. We used the binding of Cx43 Carboxyl Terminal domain to the PDZ-2 domain of Zonula Occludens-1 and to the SH3 domain of c-Src. In the ELSA assay we found that while the binding of the SH3 domain of c-Src is pH-dependent, the interaction of the PDZ domain of ZO-1 is not. These data confirm findings using Surface Plasmon Resonance (1) and indicate that ELSA can be a useful tool in determining the kinetics of protein-protein interactions.     

Astrocyte and Oligodendrocyte Connexins of the Glial Syncytium in Relation to Astrocyte Anatomical Domains and Spatial Buffering

Astroctyes express a set of three connexins (Cx26, Cx30, and Cx43) that are contained in astrocyte-to-astrocyte (A/A) gap junctions; oligodendrocytes express a different set of three connexins (Cx29, Cx32, and Cx47) that are contained in the oligodendrocyte side of necessarily heterotypic astrocyte-to-oligodendrocyte (A/O) gap junctions, and there is little ultrastructural evidence for gap junction formation between individual oligodendrocytes. In addition, primarily Cx29 and Cx32 are contained deeper in myelin sheaths, where they form autologous gap junctions at sites of uncompacted myelin. The presence of six connexins in macroglial cell populations has revealed unprecedented complexity of potential connexin coupling partners, and with restricted deployment of gap junctional intercellular communication (GJIC) within the “pan-glial” syncytium. New implications for the organization and regulation of spatial buffering mediated by glial GJIC are derived from recent observations of the existence of separate astrocyte anatomical domains, with only narrow regions of overlap between astrocyte processes at domain borders. Thus, widespread spatial buffering in the CNS may occur not successively through a multitude of processes arising from different astrocytes, but rather in a more orderly fashion from one astrocyte domain to another via intercellular coupling that occurs only at restricted regions of overlap between astrocyte domains, augmented by autocellular coupling that occurs within each domain.     

Multiple Neuronal Connexins in the Mammalian Retina

Gap junctions are abundant in the mammalian retina and many neuronal types form neural networks. Several different neuronal connexins have now been identified in the mammalian retina. Cx36 supports coupling in the AII amacrine cell network and is essential for processing rod signals. Cx36 is probably also responsible for photoreceptor coupling. Horizontal cells appear to be extensively coupled by either Cx50 or Cx57. These results indicate that multiple neuronal connexins are expressed in the mammalian retina and that different cell types express different connexins.     

Gap Junctions Mediate Glucose Transport Between GLUT1-Positive and -Negative Cells in the Spiral Limbus of the Rat Cochlea

To elucidate the role of the spiral limbus in glucose transport in the cochlea, we analyzed the expression and localization of GLUT1, connexin26, connexin30, and occludin in the spiral limbus of the rat cochlea. GLUT1 and occludin were detected in blood vessels. GLUT1, connexin26, connexin30, and occludin were also expressed in fibrocytes just basal to the supralimbal lining cells. Connexin26 and connexin30 were present among not only these GLUT1-positive fibrocytes but also GLUT1-negative fibrocytes. In vivo glucose imaging using 6-[N-(7-nitrobenz-2-oxa-1,3-diazol-4-yl)amino]-6-deoxyglucose (6-NBDG, MW 342) together with Evans Blue Albumin (EBA, MW 68,000) showed that 6-NBDG was rapidly distributed throughout the spiral limbus, whereas EBA was localized only in the vessels. Moreover, the gap junctional uncoupler heptanol inhibited the distribution of 6-NBDG. These findings suggest that gap junctions play an important role in glucose transport in the spiral limbus, i.e., that gap junctions mediate glucose transport from GLUT1-positive fibrocytes to GLUT1-negative fibrocytes in the spiral limbus.     

Connexins and their channels in inflammation

Inflammation may be caused by a variety of factors and is a hallmark of a plethora of acute and chronic diseases. The purpose of inflammation is to eliminate the initial cell injury trigger, to clear out dead cells from damaged tissue and to initiate tissue regeneration. Despite the wealth of knowledge regarding the involvement of cellular communication in inflammation, studies on the role of connexin-based channels in this process have only begun to emerge in the last few years. In this paper, a state-of-the-art overview of the effects of inflammation on connexin signaling is provided. Vice versa, the involvement of connexins and their channels in inflammation will be discussed by relying on studies that use a variety of experimental tools, such as genetically modified animals, small interfering RNA and connexin-based channel blockers. A better understanding of the importance of connexin signaling in inflammation may open up towards clinical perspectives.     

Dual Functions for Connexins: Cx43 Regulates Growth Independently of Gap Junction Formation

Connexins, the family of proteins that form vertebrate gap junctions, have key roles during development and in the adult. Previously, the physiological actions of connexins have been ascribed solely to formation of gap junction channels and thought to be mediated by the transfer of small molecules between neighboring cells. In conflict with this hypothesis here we demonstrate that Cx43 can affect cell growth independently of gap junction formation. This conclusion is based on four findings: (1) There is a lack of correlation between the action of Cx43 mutants Cx43-S255A, Cx43-S279A, and Cx43-S282A on growth and cell coupling in 3T3 A31 fibroblasts. (2) Blockade of gap junction formation, by either heptan-1-ol treatment or culturing cells at low density, had no effect on the ability of the Cx43 mutants to control growth. (3) Wildtype Cx43 inhibited growth of Neuro2a cells under conditions where gap junctions were unable to form. (4) The CT domain of Cx43, which lacks intrinsic gap junction activity, is as effective as the wildtype molecule in suppressing the growth of Neuro2a cells. These observations demonstrate that Cx43 has dual functions: first, its well-accepted role in forming a gap junction channel and, second, a direct action of the connexin protein on growth that is mediated via the cytoplasmic carboxyl domain.     

Phosphorylation of connexin43 on serine368 by protein kinase C regulates gap junctional communication

Phorbol esters (e.g., TPA) activate protein kinase C (PKC), increase connexin43 (Cx43) phosphorylation, and decrease cell-cell communication via gap junctions in many cell types. We asked whether PKC directly phosphorylates and regulates Cx43. Rat epithelial T51B cells metabolically labeled with (32)P(i) yielded two-dimensional phosphotryptic maps of Cx43 with several phosphopeptides that increased in intensity upon TPA treatment. One of these peptides comigrated with the major phosphopeptide observed after PKC phosphorylation of immunoaffinity-purified Cx43. Purification of this comigrating peptide and subsequent sequencing indicated that the phosphorylated serine was residue 368. To pursue the functional importance of phosphorylation at this site, fibroblasts from Cx43(-/-) mice were transfected with either wild-type (Cx43wt) or mutant Cx43 (Cx43-S368A). Intercellular dye transfer studies revealed different responses to TPA and were followed by single channel analyses. TPA stimulation of T51B cells or Cx43wt-transfected fibroblasts caused a large increase in the relative frequency of approximately 50-pS channel events and a concomitant loss of approximately 100-pS channel events. This change to approximately 50-pS events was absent when cells transfected with Cx43-S368A were treated with TPA. These data strongly suggest that PKC directly phosphorylates Cx43 on S368 in vivo, which results in a change in single channel behavior that contributes to a decrease in intercellular communication.     

Functional and morphological correlates of connexin50 expressed in Xenopus laevis oocytes

Electrophysiological and morphological methods were used to study connexin50 (Cx50) expressed in Xenopus laevis oocytes. Oocytes expressing Cx50 exhibited a new population of intramembrane particles (9.0 nm in diameter) in the plasma membrane. The particles represented hemichannels (connexin hexamers) because (a) their cross-sectional area could accommodate 24 +/- 3 helices, (b) when their density reached 300-400/microm2, they formed complete channels (dodecamers) in single oocytes, and assembled into plaques, and (c) their appearance in the plasma membrane was associated with a whole-cell current, which was activated at low external Ca2+ concentration ([Ca2+]o), and was blocked by octanol and by intracellular acidification. The Cx50 hemichannel density was directly proportional to the magnitude of the Cx50 Ca2+-sensitive current. Measurements of hemichannel density and the Ca2+-sensitive current in the same oocytes suggested that at physiological [Ca2+]o (1-2 mM), hemichannels rarely open. In the cytoplasm, hemichannels were present in approximately 0.1-microm diameter "coated" and in larger 0.2-0.5-microm diameter vesicles. The smaller coated vesicles contained endogenous plasma membrane proteins of the oocyte intermingled with 5-40 Cx50 hemichannels, and were observed to fuse with the plasma membrane. The larger vesicles, which contained Cx50 hemichannels, gap junction channels, and endogenous membrane proteins, originated from invaginations of the plasma membrane, as their lumen was labeled with the extracellular marker peroxidase. The insertion rate of hemichannels into the plasma membrane (80, 000/s), suggested that an average of 4,000 small coated vesicles were inserted every second. However, insertion of hemichannels occurred at a constant plasma membrane area, indicating that insertion by vesicle exocytosis (60-500 microm2 membranes/s) was balanced by plasma membrane endocytosis. These exocytotic and endocytotic rates suggest that the entire plasma membrane of the oocyte is replaced in approximately 24 h.     

Degradation of Connexins from the Plasma Membrane Is Regulated by Inhibitors of Protein Synthesis

Little is known about the mechanism and regulation of connexin turnover from the plasma membrane. We have used a combination of cell surface biotinylation, immunofluorescence microscopy, and scrape-load dye transfer assays to investigate the effect of the protein synthesis inhibitor cycloheximide on connexin43 and connexin32 after their transport to the plasmalemma. The results obtained demonstrate that cycloheximide inhibits the turnover of connexins from the surface of both gap junction assembly-deficient and -efficient cells. Moreover, cell surface connexin saved from destruction by cycloheximide can assemble into long-lived, functional gap junctional plaques. These findings support the concept that downregulation of connexin degradation from the plasma membrane can serve as a mechanism to enhance gap junction-mediated intercellular communication.     

A novel role for FGF and extracellular signal-regulated kinase in gap junction-mediated intercellular communication in the lens.

Gap junction-mediated intercellular coupling is higher in the equatorial region of the lens than at either pole, a property believed to be essential for lens transparency. We show that fibroblast growth factor (FGF) upregulates gap junctional intercellular dye transfer in primary cultures of embryonic chick lens cells without detectably increasing either gap junction protein (connexin) synthesis or assembly. Insulin and insulin-like growth factor 1, as potent as FGF in inducing lens cell differentiation, had no effect on gap junctions. FGF induced sustained activation of extracellular signal-regulated kinase (ERK) in lens cells, an event necessary and sufficient to increase gap junctional coupling. We also identify vitreous humor as an in vivo source of an FGF-like intercellular communication-promoting activity and show that FGF-induced ERK activation in the intact lens is higher in the equatorial region than in polar and core fibers. These findings support a model in which regional differences in FGF signaling through the ERK pathway lead to the asymmetry in gap junctional coupling required for proper lens function. Our results also identify upregulation of intercellular communication as a new function for sustained ERK activation and change the current paradigm that ERKs only negatively regulate gap junction channel activity.     

Dislocation and degradation from the ER are regulated by cytosolic stress

Akey step in ER-associated degradation (ERAD) is dislocation of the substrate protein from the ER into the cytosol to gain access to the proteasome. Very little is known about how this process is regulated, especially in the case of polytopic proteins. Using pulse-chase analysis combined with subcellular fractionation, we show that connexins, the four transmembrane structural components of gap junctions, can be chased in an intact form from the ER membrane into the cytosol of proteasome inhibitor-treated cells. Dislocation of endogenously expressed connexin from the ER was reduced 50-80% when the cytosolic heat shock response was induced by mild oxidative or thermal stress, but not by treatments that instead upregulate the ER unfolded protein response. Cytosolic but not ER stresses slowed the normally rapid degradation of connexins, and led to a striking increase in gap junction formation and function in otherwise assembly-inefficient cell types. These treatments also inhibited the dislocation and turnover of a connexin-unrelated ERAD substrate, unassembled major histocompatibility complex class I heavy chain. Our findings demonstrate that dislocation is negatively regulated by physiologically relevant, nonlethal stress. They also reveal a previously unrecognized relationship between cytosolic stress and intercellular communication.     

Connexins 26, 32 and 43 are expressed in virgin, pregnant and lactating mammary glands

Gap junctions (GJ) are formed by a number of homologous proteins termed connexins. Here expression of connexins Cx26, Cx32 and Cx43, was evaluated by immunofluorescence (IF) in mammary glands from virgin, pregnant and lactating rats. Cx26, Cx32 and Cx43 labeling was detected in epithelial parenchymal cells at all functional stages. Cx26 and Cx32 labeling was very low in glands from virgin animals, somewhat greater in glands from pregnant animals and significantly higher (in number and size) in lactating animals. In the last ones, Cx26 and Cx32 punctate labeling was localized to the basal and lateral membranes of alveolar epithelial cells and collecting ductules. Cx43 punctate labeling was restricted to the periphery of alveoli towards the basal pole of epithelial cells at all functional stages, and it enlarged slightly during lactation. At this localization, Cx43 may form GJ between myoepithelial cells and/or between epithelial and myoepithelial cells. Cx43 was also found to be steadily expressed in the connective tissue which surrounds and invades each parenchymal lobe, at all functional stages. At this localization, Cx43 may couple fibroblasts and/or adipose cells. IF studies in sections from lactating mice showed the same distribution of connexins. Immunoblots confirmed specificity of labeling and the presence of Cx32 and Cx43 in the mammary gland. The increase in connexin expression detected during pregnancy and lactation may be important for epithelial cell differentiation and secretion in the mammary gland.     

Gap junctions and the propagation of cell survival and cell death signals

Gap junctions are a unique type of intercellular channels that connect the cytoplasm of adjoining cells. Each gap junction channel is comprised of two hemichannels or connexons and each connexon is formed by the aggregation of six protein subunits known as connexins. Gap junction channels allow the intercellular passage of small (< 1.5 kDa) molecules and regulate essential processes during development and differentiation. However, their role in cell survival and cell death is poorly understood. We review experimental data that support the hypothesis that gap junction channels may propagate cell death and survival modulating signals. In addition, we explore the hypothesis that hemichannels (or unapposed connexons) might be used as a paracrine conduit to spread factors that modulate the fate of the surrounding cells. Finally, direct signal transduction activity of connexins in cell death and survival pathways is addressed.These authors share senior authorship.This study was supported by Ghent University GOA grant no. 12050502.This revised version was published online in May 2005 with corrections to one authors email address.     

Connexin expression in Huntington's diseased human brain

In Huntington's diseased human brain, it is in the caudate nucleus (CN) and globus pallidus (GP) of the basal ganglia where nerve cell death is seen most dramatically. The distribution of five gap junction proteins (connexins 26, 32, 40, 43 and 50) has been examined in these areas in normal and Huntington's diseased human brain using immunohistochemical techniques. There was no Cx50 expression observed and Cx40 was localized in the endothelial cells of blood vessels, with the Huntington's diseased brains having more numerous and smaller blood vessels than normal tissue. Cx26 and Cx32 revealed a similar distribution pattern to each other in both normal and diseased brains with little labelling in the CN but clear labelling in the GP. Cx43, expressed by astrocytes, was the most abundant connexin type of those studied. In both normal and diseased brains Cx43 in the GP was homogeneously distributed in the neuropil. In the CN, however, Cx43 density was both increased with Huntington's disease and became located in patches. Glial fibrillary acidic protein(GFAP) staining of astrocytes was also highly increased in the CN compared with normal brains. These labelling patterns indicate a reactive astrocytosis around degenerating neurons with an increased expression of astrocytic gap junctions. The enhanced coupling state between astrocytes, assuming the junctions are functional, could provide an increased spatial buffering capacity by the astrocytes in an attempt to maintain a proper environment for the neurons, helping promote neuronal survival in this neurodegenerative disorder.