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Intercellular Channels (intercellular + channel)
Selected AbstractsConnexins, cell motility, and the cytoskeletonCYTOSKELETON, Issue 11 2009Stephan Olk Abstract Connexins (Cx) comprise a family of transmembrane proteins, which form intercellular channels between plasma membranes of two adjoining cells, commonly known as gap junctions. Recent reports revealed that Cx proteins interact with diverse cellular components to form a multiprotein complex, which has been termed "Nexus". Potential interaction partners include proteins such as cytoskeletal proteins, scaffolding proteins, protein kinases and phosphatases. These interactions allow correct subcellular localization of Cxs and functional regulation of gap junction-mediated intercellular communication. Evidence is accruing that Cxs might have channel-independent functions, which potentially include regulation of cell migration, cell polarization and growth control. In the current review, we summarize recent knowledge on Cx interactions with cytoskeletal proteins and highlight some aspects of their role in cellular motility. Cell Motil. Cytoskeleton 66: 1000,1016, 2009. © 2009 Wiley-Liss, Inc. [source] Modulation of astrocyte P2Y1 receptors by the carboxyl terminal domain of the gap junction protein Cx43GLIA, Issue 2 2008Eliana Scemes Abstract Gap junction proteins, connexins, provide intercellular channels that allow ions and small signaling molecules to be transmitted to adjacent coupled cells. Besides this function, it is becoming apparent that connexins also exert channel-independent effects, which are likely mediated by processes involving protein,protein interactions. Although a number of connexin interacting proteins have been identified, only little is known about the functional consequences of such interactions. We have previously shown that deletion of the astrocytic gap junction protein, connexin43 (Cx43) causes a right-ward shift in the dose-response curve to P2Y1R agonists and decreased P2Y1R expression levels. To evaluate whether these changes were due to reduced gap junctional communication or to protein,protein interactions, Cx43-null astrocytes were transfected with full-length Cx43 and Cx43 domains, and P2Y1R function and expression levels evaluated. Results indicate that restoration of P2Y1R function is independent of gap junctional communication and that the Cx43 carboxyl terminus spanning the SH3 binding domain (260,280) participates in the rescue of P2Y1R pharmacological behavior (shifting to the left the P2Y1R dose-response curve) without affecting its expression levels. These results suggest that the Cx43 carboxyl-terminus domain provides a binding site for an intracellular molecule, most likely a member of the c-Src tyrosine kinase family, which affects P2Y1R-induced calcium mobilization. It is here proposed that a nonchannel function of Cx43 is to serve as a decoy for such kinases. Such modulation of P2Y1R is expected to influence several neural cell functions, especially under inflammation and neurodegenerative disorders where expression levels of Cx43 are decreased. © 2007 Wiley-Liss, Inc. [source] THE CONNEXIN 32 NERVE-SPECIFIC PROMOTER IS DIRECTLY ACTIVATED BY Egr2/Krox20 IN HeLa CELLSJOURNAL OF THE PERIPHERAL NERVOUS SYSTEM, Issue 1 2002M. Musso Connexin 32 (Cx32) belongs to a protein family that forms intercellular channels mediating the exchange of ions and chemical messengers. In the peripheral nervous system (PNS) Cx32 is expressed in Schwann cells and contributes to the homeostasis and structural integrity of myelin. Mutations of this gene determine X-linked form of Charcot Marie-Tooth (CMTX) disease. Cx 32 is transcriptionally regulated in a tissue-specific manner by two different promoters termed P1 and P2. P2, active in Schwann cells, is located 5 kb downstream from the P1 promoter and at 500 bp from the exon 2 that contains the entire coding region. Previously, by Electrophoretical Mobility Shift Assay (EMSA) we have identified a sequence (-101/-93), within P2, specifically recognized by recombinant Egr2. In order to prove the direct involvement of Egr2 in the transcriptional control of the Cx32 gene, we have performed transfection experiments in HeLa cells with a luciferase driven by the P2 promoter in presence or not of a vector expressing Krox20, the mouse homologue of human Egr2. We have found that the construct in which the sequence -103/-93 is mutated is not activated as well as the wild type sequence. Moreover we have detected another upstream sequence (-236/-213) recognized by recombinant Egr2 and other transcription factors present in HeLa nuclear extract like SP1. The construct, lacking this sequence and carrying the mutated downstream Egr2 recognition sequence, is not activated at all by Krox20. Taken together these findings strongly suggest the role of Egr2 in the transcriptional control of Connexin 32 through both sequences. The laboratory is a member of the European CMT Consortium; partially granted by Ministero della Sanit, to PM, MURST and Ateneo to FA. [source] Expression of gap junction protein connexin 32 in chronic liver diseasesLIVER INTERNATIONAL, Issue 2 2000Kazuaki Yamaoka Abstract:Background: Gap junctions contain intercellular channels through which contacting cells communicate directly. The expression of connexin 32, a major gap junction protein in the liver, during the progression of chronic liver diseases has not yet been clarified. Methods: Immunohistochemical staining was performed using anti-connexin 32 antibody on 6 specimens of normal human liver, 7 of chronic viral hepatitis, and 7 of liver cirrhosis. Results: The number of gap junction plaques in chronic viral hepatitis and liver cirrhosis was significantly smaller than that in normal liver (10350±2180 and 7550±3040 vs 22560±3700 spots/mm2, p<0.01). The number of gap junction plaques tended to be lower in liver cirrhosis than in chronic viral hepatitis. Conclusion: These results suggest that in chronic liver diseases impaired intercellular communication between hepatocytes occurs. [source] Charges dispersed over the permeation pathway determine the charge selectivity and conductance of a Cx32 chimeric hemichannelTHE JOURNAL OF PHYSIOLOGY, Issue 10 2008Seunghoon Oh Previous studies have shown that charge substitutions in the amino terminus of a chimeric connexin, Cx32*43E1, which forms unapposed hemichannels in Xenopus oocytes, can result in a threefold difference in unitary conductance and alter the direction and amount of open channel current rectification. Here, we determine the charge selectivity of Cx32*43E1 unapposed hemichannels containing negative and/or positive charge substitutions at the 2nd, 5th and 8th positions in the N-terminus. Unlike Cx32 intercellular channels, which are weakly anion selective, the Cx32*43E1 unapposed hemichannel is moderately cation selective. Cation selectivity is maximal when the extracellular surface of the channel is exposed to low ionic strength solutions implicating a region of negative charge in the first extracellular loop of Cx43 (Cx43E1) in influencing charge selectivity analogous to that reported. Negative charge substitutions at the 2nd, 5th and 8th positions in the intracellular N-terminus substantially increase the unitary conductance and cation selectivity of the chimeric hemichannel. Positive charge substitutions at the 5th position decrease unitary conductance and produce a non-selective channel while the presence of a positive charge at the 5th position and negative charge at the 2nd results in a channel with conductance similar to the parental channel but with greater preference for cations. We demonstrate that a cysteine substitution of the 8th residue in the N-terminus can be modified by a methanthiosulphonate reagent (MTSEA-biotin-X) indicating that this residue lines the aqueous pore at the intracellular entrance of the channel. The results indicate that charge selectivity of the Cx32*43E1 hemichannel can be determined by the combined actions of charges dispersed over the permeation pathway rather than by a defined region that acts as a charge selectivity filter. [source] Role of villus microcirculation in intestinal absorption of glucose: coupling of epithelial with endothelial transportTHE JOURNAL OF PHYSIOLOGY, Issue 2 2003J. R. Pappenheimer Capillaries in jejunal villi can absorb nutrients at rates several hundred times greater (per gram tissue) than capillaries in other tissues, including contracting skeletal muscle and brain. We here present an integrative hypothesis to account for these exceptionally large trans-endothelial fluxes and their relation to epithelial transport. Equations are developed for estimating concentration gradients of glucose across villus capillary walls, along paracellular channels and across subjunctional lateral membranes of absorptive cells. High concentrations of glucose discharged across lateral membranes to subjunctional intercellular spaces are delivered to abluminal surfaces of villus capillaries by convection-diffusion in intercellular channels without significant loss of concentration. Post-junctional paracellular transport thus provides the series link between epithelial and endothelial transport and makes possible the large trans-endothelial concentration gradients required for absorption to blood. Our analysis demonstrates that increases of villus capillary blood flow and permeability-surface area product (PS) are essential components of absorptive mechanisms: epithelial transport of normal digestive loads could not be sustained without concomitant increases in capillary blood flow and PS. The low rates of intestinal absorption found in anaesthetised animals may be attributed to inhibition of normal villus microvascular responses to epithelial transport. [source] A description of the structural determination procedures of a gap junction channel at 3.5,Å resolutionACTA CRYSTALLOGRAPHICA SECTION D, Issue 8 2009Michihiro Suga Intercellular signalling is an essential characteristic of multicellular organisms. Gap junctions, which consist of arrays of intercellular channels, permit the exchange of ions and small molecules between adjacent cells. Here, the structural determination of a gap junction channel composed of connexin 26 (Cx26) at 3.5,Å resolution is described. During each step of the purification process, the protein was examined using electron microscopy and/or dynamic light scattering. Dehydration of the crystals improved the resolution limits. Phase refinement using multi-crystal averaging in conjunction with noncrystallographic symmetry averaging based on strictly determined noncrystallographic symmetry operators resulted in an electron-density map for model building. The amino-acid sequence of a protomer structure consisting of the amino-terminal helix, four transmembrane helices and two extracellular loops was assigned to the electron-density map. The amino-acid assignment was confirmed using six selenomethionine (SeMet) sites in the difference Fourier map of the SeMet derivative and three intramolecular disulfide bonds in the anomalous difference Fourier map of the native crystal. [source] | |||||||||||||