Suppression of the transformed phenotype of breast cancer by tropomyosin-1

Gap junctional intercellular communication (GJIC) is thought to play a crucial role in cell differentiation. Small gap junction plaques are frequently associated with tight junction strands in hepatocytes, suggesting that gap junctions may be closely related to the role of tight junctions in the establishment of cell polarity. To examine the exact role of gap junctions in regulating tight junctions, we transfected connexin 32 (Cx32), Cx26, or Cx43 cDNAs into immortalized mouse hepatocytes derived from Cx32-deficient mice and examined the expression and function of the endogenous tight junction molecules. In transient wild-type Cx32 transfectants, immunocytochemistry revealed that endogenous occludin was in part localized at cell borders, where it was colocalized with Cx32, whereas neither was detected in parental cells. In Cx32 null hepatocytes transfected with Cx32 truncated at position 220 (R220stop), wild-type Cx26, or wild-type Cx43 cDNAs, occludin was not detected at cell borders. In stable wild-type Cx32 transfectants, occludin, claudin-1, and ZO-1 mRNAs and proteins were significantly increased compared to parental cells and all of the proteins were colocalized with Cx32 at cell borders. Treatment with a GJIC blocker, 18 beta-glycyrrhetinic acid, resulted in decreases of occludin and claudin-1 at cell borders in the stable transfectants. The induction of tight junction proteins in the stable transfectants was accompanied by an increase in both fence and barrier functions of tight junctions. Furthermore, in the stable transfectants, circumferencial actin filaments were also increased without a change of actin protein. These results indicate that Cx32 formation and/or Cx32-mediated intercellular communication may participate in the formation of functional tight junctions and actin organization.     

Downregulation of connexin32 protein and gap-junctional intercellular communication by cytokine-mediated acute-phase response in immortalized mouse hepatocytes

In the present study, we have analyzed the direct effects of cytokines, which mediate the acute-phase response in liver, on connexin expression and gap-junctional intercellular communication in immortalized MHSV12 mouse hepatocytes. When these cells were stimulated for 24 h with interleukin 1 and interleukin 6, the amount of connexin26 (Cx26) mRNA increased together with β?fibrinogen mRNA, as expected for this positive acute-phase gene. In contrast, connexin32 (Cx32) mRNA expression was not affected under these conditions. Indirect immunfluorescence revealed a drastic decrease in Cx32 signals, whereas slightly more Cx26 signals were found. Stronger stimulation with interleukin 1 and tumor necrosis factor α gave a dose-dependent increase in steady state levels of Cx26 and β-fibrinogen mRNA, but no further change in Cx32 mRNA level was seen. However, when Cx32 protein was analyzed on immunoblots, we found a 5-fold decrease in expression even at low cytokine doses that did not affect Cx32 mRNA expression. Under these conditions, cell to cell transfer of Lucifer yellow, microinjected into immortalized hepatocytes, was decreased by 70%, suggesting that intercellular communication through Cx32 channels was partially inhibited earlier than other genetic alterations characteristic of the acute-phase response. Thus, the major hepatic gap junction protein was largely downregulated at the beginning of the experimental inflammatory reaction, but about 30% of gap-junctional intercellular communication was maintained. This suggests that, during the acute-phase response, the second hepatic Cx26 protein may compensate in part for the downregulation of the Cx32 protein.     

Connexin 32 mutations from X-linked Charcot-Marie-Tooth disease patients: functional defects and dominant negative effects.

We have characterized the function of connexin (Cx) 32 gene mutations found in X-linked dominant Charcot-Marie-Tooth disease with respect to their ability to form functional gap junctions among themselves and to inactivate wild-type Cx32 by a dominant negative mechanism. We prepared four types of Cx32 mutant cDNAs and transfected them into HeLa cells, which do not show detectable levels of gap junctional intercellular communication (GJIC), nor expression of any connexins examined. Cells transfected with the wild-type Cx32 gene, but not those transfected with three different base substitution mutations (i.e. Cys 60 to Phe, Val 139 to Met, and Arg 215 to Trp), restored GJIC. Unexpectedly, in cells transfected with a nonsense mutant at codon 220, there was also restored GJIC. When we double-transfected these mutant constructs into the HeLa cells that had already been transfected with the wild-type Cx32 gene and thus were GJIC proficient, three base substitution mutants inhibited GJIC, suggesting that these three mutants can eliminate the function of wild-type Cx32 in a dominant negative manner. The nonsense mutation at codon 220 did not show such a dominant negative effect. Since both mutant and wild-type Cx32 mRNAs were detected, but only poor Cx32 protein expression at cell-cell contact areas was observed in the double transfectants, it is suggested that certain mutants form nonfunctional chimeric connexons with wild-type connexins, which are not properly inserted into the cytoplasmic membrane.     

Degradation of Connexins Through the Proteasomal, Endolysosomal and Phagolysosomal Pathways

Connexins comprise gap junction channels, which create a direct conduit between the cytoplasms of adjacent cells and provide for intercellular communication. Therefore, the level of total cellular connexin protein can have a direct influence on the level of intercellular communication. Control of connexin protein levels can occur through different mechanisms during the connexin life cycle, such as by regulation of connexin gene expression and turnover of existing protein. The degradation of connexins has been extensively studied, revealing proteasomal, endolysosomal and more recently autophagosomal degradation mechanisms that modulate connexin turnover and, subsequently, affect intercellular communication. Here, we review the current knowledge of connexin degradation pathways.     

Dynamic connexin43 expression and gap junctional communication during endoderm differentiation of F9 embryonal carcinoma cells

Gap junctional communication permits the direct intercellular exchange of small molecules and ions. In vertebrates, gap junctions are formed by the conjunction of two connexons, each consisting of a hexamer of connexin proteins, and are either established or degraded depending on the nature of the tissue formed. Gap junction function has been implicated in both directing developmental cell fate decisions and in tissue homeostasis/metabolite exchange. In mouse development, formation of the extra embryonal parietal endoderm from visceral endoderm is the first epithelial-mesenchyme transition to occur. This transition can be mimicked in vitro, by F9 embryonal carcinoma (EC) cells treated with retinoic acid, to form (epithelial) primitive or visceral endoderm, and then with parathyroid hormone-related peptide (PTHrP) to induce the transition to (mesenchymal) parietal endoderm. Here, we demonstrate that connexin43 mRNA and protein expression levels, protein phosphorylation and subcellular localization are dynamically regulated during F9 EC cell differentiation. Dye injection showed that this complex regulation of connexin43 is correlated with functional gap junctional communication. Similar patterns of connexin43 expression, localization and communication were found in visceral and parietal endoderm isolated ex vivo from mouse embryos at day 8.5 of gestation. However, in F9 cells this tightly regulated gap junctional communication does not appear to be required for the differentiation process as such.     

Effect of tumor-promoting and anti-promoting chemicals on the viability and junctional coupling of human hela cells transfected with DNAs coding for various murine connexin proteins

Gap-junctional intercellular communication is thought to be essential for maintaining cellular homeostasis and growth control. Its perturbation entails toxicological implications and it has been correlated with the in vivo tumor-promoting potential of chemicals. Little is known about the mechanism(s) responsible for the tumor promoters interference with the cellular coupling. Moreover, nongenotoxic carcinogens, as well as connexins (gap-junctional protein subunits), are known to be organ-/tissue-specific; this implies that the effect of different agents should be evaluated on their specific target, that is, connexin. To investigate the role of different connexins in regulating gap-junctional gating and to compare the properties of homotypic Junctional channels, we evaluated the effects of tissue-specific tumor promoters and anti-promoters on the viability and intercellular coupling (dye-transfer) of HeLa cells stably transfected with cDNAs coding for connexin(cx)43, cx40, cx26 and cx32. The results demonstrate that the transfectants possess individual Junctional permeabilities, differentially affected by the chemicals; they also show different sensitivities to the cytotoxic effect of the compounds. These findings confirm that connexin diversity may be responsible for the different gating properties of gap-junctional channels, being also suggestive for their separate functions and independent regulatory mechanisms.     

Intercellular communication and carcinogenesis

Two types of intercellular communication (humoral and cell contact-mediated) are involved in control of cellular function in multicellular organisms, both of them mediated by membrane-embedded proteins. Involvement of aberrant humoral communication in carcinogenesis has been well documented and genes coding for some growth factors and their receptors have been classified as oncogenes. More recently, cell contact-mediated communication has been found to have an important role in carcinogenesis, and some genes coding for proteins involved in this type of communication appear to form a family of tumor-suppressor genes. Both homologous (among normal or (pre-)cancerous cells) as well as heterologous (between normal and (pre)cancerous cells) communications appear to play important roles in cell growth control. Gap junctional intercellular communication (GJIC) is the only means by which multicellular organisms can exchange low molecular weight signals directly from within one cell to the interior of neighboring cells. GJIC is altered by many tumor-promoting agents and in many human and rodent tumors. We have recently shown that liver tumor-promoting agents inhibit GJIC in the rat liver in vivo. Molecular mechanisms which could lead to aberrant GJIC include: (1) mutation of connexin genes; (2) reduced and/or aberrant expression of connexin mRNA; (3) aberrant localization of connexin proteins, i.e., intracytoplasmic rather than in the cytoplasmic membrane; and (4) modulation of connexin functions by other proteins, such as those involved in extracellular matrix and cell adhesion. Whilst mutations of the cx 32 gene appear to be rare in tumors, cx 37 gene mutations have been reported in a mouse lung tumor cell line. Our results suggest that aberrant connexin localization is rather common in cancer cells and that possible molecular mechanisms include aberrant phosphorylation of connexin proteins and lack of cell adhesion molecules. Studies on transfection of connexin genes into tumor cells suggest that certain connexin genes (e.g., cx 26, cx 43 and cx 32) act as tumor-suppressor genes.     

性激素对生殖系统Cx43表达调控机制的研究进展

由连接蛋白43(connexin 43,Cx43)构成的细胞间间隙连接(gap junction,GJ)是介导细胞间直接的物质、能量交换及电、化学信号耦合的重要通路,其可保证细胞间功能活动的协调一致,在生殖系统细胞发育、分化及成熟等生理过程及功能活动中发挥非常重要的调控作用。性激素可在转录及翻译等层面调节生殖系统细胞Cx43的结构及表达,一方面通过核受体基因组机制调节Cx43基因的转录,另一方面通过非基因组快速信号传导通路机制调节Cx43的磷酸化水平,共同影响细胞间隙连接通讯(gap junction intracellular communication,GJIC),进一步干预生殖系统细胞的病理、生理过程及功能活动。近年来,性激素在心血管系统病生理状态下对连接蛋白调节的变化及机制研究较为成熟,而在子宫、卵巢等生殖器官中,对性激素通过调节连接蛋白及间隙连接进而影响细胞间信息流通的研究较少,其作用机制并不清晰。故本文结合近年来文献,综述性激素对生殖系统细胞Cx43表达及GJIC的调控机制的研究进展,旨在为今后深入地研究提供可行的思路。     

Overexpression of cardiac connexin45 increases susceptibility to ventricular tachyarrhythmias in vivo

Electrophysiological remodeling involving gap junctions has been demonstrated in failing hearts and may contribute to intercellular uncoupling, delayed conduction, enhanced arrhythmias, and vulnerability to sudden death in patients with heart failure. Recently, we showed that failing human hearts exhibit marked increases in connexin45 (Cx45) expression in addition to previously documented decreases in connexin43 (Cx43) expression. Each of these changes results in reduced gap junction coupling. The objective of the present study was to examine functional consequences of increased Cx45 in cardiac gap junctions. Transgenic mice with cardiac-selective overexpression of the developmentally downregulated cardiac connexin, connexin45 (Cx45OE mice) were subjected to in vivo electrophysiology studies in which an intracardiac catheter was used to induce ventricular arrhythmias in anesthetized mice, and in which ambulatory ECG monitoring was used to detect spontaneous arrhythmias in unanesthetized mice. Hearts were analyzed by TaqMan RT-PCR, immunostaining, immunoblotting, and echocardiography. Lucifer yellow and neurobiotin dye transfer was used to assess coupling in transgenic and control myocyte cultures. Cx45 mRNA was two orders of magnitude greater in Cx45OE mice. Cx45-immunoreactive signal at gap junctions increased twofold and total Cx45 protein by immunoblotting increased 25% in Cx45OE mice compared with nontransgenic littermate controls. Functionally, Cx45OE mice exhibited more inducible ventricular tachycardia than controls but did not exhibit any other functional or structural derangements as assessed by echocardiography. Ventricular myocytes isolated from Cx45OE mice exhibited diminished intercellular transfer of Lucifer yellow dye and increased transfer of neurobiotin, consistent with altered cell-to-cell communication. Thus increased myocardial expression of Cx45 results in remodeling of intercellular coupling and greater susceptibility to ventricular arrhythmias in vivo.     

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.     

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.