Rudolf Werner

MIR-206 regulates connexin43 expression during skeletal muscle development

Skeletal myoblast fusion in vitro requires the expression of connexin43 (Cx43) gap junction channels. However, gap junctions are rapidly downregulated after the initiation of myoblast fusion in vitro and in vivo. In this study we show that this downregulation is accomplished by two related microRNAs, miR-206 and miR-1, that inhibit the expression of Cx43 protein during myoblast differentiation without altering Cx43 mRNA levels. Cx43 mRNA contains two binding sites for miR-206/miR-1 in its 3′-untranslated region, both of which are required for efficient downregulation. While it has been demonstrated before that miR-1 is involved in myogenesis, in this work we show that miR-206 is also upregulated during perinatal skeletal muscle development in mice in vivo and that both miR-1 and miR-206 downregulate Cx43 expression during myoblast fusion in vitro. Proper development of singly innervated muscle fibers requires muscle contraction and NMJ terminal selection and it is hypothesized that prolonged electrical coupling via gap junctions may be detrimental to this process. This work details the mechanism by which initial downregulation of Cx43 occurs during myogenesis and highlights the tight control mechanisms that are utilized for the regulation of gap junctions during differentiation and development.

Mutational analysis of gap junction formation

The paired oocyte cell-cell channel assay was used to investigate the mechanisms involved in the process of formation of gap junction channels. Single oocytes, injected with connexin-specific mRNAs, accumulate a pool of precursors from which cell-cell channels can form rapidly upon pairing. Several lines of evidence, including immunohistochemistry and surface labeling, indicate that part of this precursor pool is located in the cell membrane, probably in the form of closed hemichannels. The homophilic binding of hemichannels to each other can be mimicked by synthetic peptides representing the extracellular loop sequences of connexin32. The peptides specifically suppress channel formation. A crucial role is established for the six cysteines in the extracellular domains that are conserved in all vertebrate gap junction proteins. Change of any of these cysteines into serines results in absolute loss of function of the mutant connexin. The effects of thiol-specific reagents on channel formation suggest that docking and/or opening of channels involves disulfide exchange. Several of the variable amino acids in the extracellular loop sequences were found to determine specificity of connexin-connexin interactions.

Identification of a pore lining segment in gap junction hemichannels

The ability of certain connexins to form open hemichannels has been exploited to study the pore structure of gap junction (hemi)channels. Cysteine scanning mutagenesis was applied to cx46 and to a chimeric connexin, cx32E(1)43, which both form patent hemichannels when expressed in Xenopus oocytes. The thiol reagent maleimido-butyryl-biocytin was used to probe 12 cysteine replacement mutants in the first transmembrane segment and two in the amino-terminal segment. Maleimido-butyryl-biocytin was found to inhibit channel activity with cysteines in two equivalent positions in both connexins: I33C and M34C in cx32E(1)43 and I34C and L35C in cx46. These two positions in the first transmembrane segment are thus accessible from the extracellular space and consequently appear to contribute to the pore lining. The data also suggest that the pore structure is complex and may involve more than one transmembrane segment.

Analysis of a Charcot-Marie-Tooth Disease Mutation Reveals an Essential Internal Ribosome Entry Site Element in the Connexin-32 Gene

A mutation located in the 5′-untranslated region (5′-UTR) of the nerve-specific connexin-32 mRNA, previously found in a family with Charcot-Marie-Tooth disease (CMTX), was analyzed for its effect on the expression of a reporter gene (luciferase) in transgenic mice and in transfected cells. Whereas both mutant and wild-type genes appeared to be transcribed and spliced efficiently, no luciferase was detected from the mutant in either system, suggesting that the mutation affects translation of the mRNA. When the 5′-UTR of nerve-specific connexin-32 mRNA was inserted between the two genes of a bicistronic vector and transfected into various cell lines, expression of the second gene was significantly increased. Because the mutant did not facilitate translation of the second gene in the bicistronic mRNA system, this result suggested that the CMTX mutation abolished function of an internal ribosome entry site (IRES) in the 5′-UTR of the wild-type connexin-32 mRNA. The CMTX phenotype of the mutant 5′-UTR further suggested that the wild-type IRES was essential for the translation of the connexin-32 mRNA in nerve cells. In addition, other sequence elements of the connexin-32 IRES were characterized by mutation analysis. A mutation in either of the first two elements investigated showed loss of IRES function, whereas mutation of a third element showed gain of function.

Structure of a gap junction gene: Rat connexin-32

A genomic clone for the rat liver gap junction protein (connexin-32) was isolated and characterized by restriction enzyme mapping and sequence analysis. While the complete coding sequence is contained within one uninterrupted block, the 5′-untranslated region of the transcript contains a 6.1 kb intron. Both S1 nuclease protection and primer extension assays indicate multiple transcription start sites. Sequences homologous to cAMP response elements are found near the transcription start sites and within the 3′-end of the intron.

ATTEMPTS TO DEFINE FUNCTIONAL DOMAINS OF GAP JUNCTION PROTEINS WITH SYNTHETIC PEPTIDES

To map the binding sites involved in channel formation, synthetic peptides representing sequences of connexin 32 were tested for their ability to inhibit cell-cell channel formation. Both large peptides representing most of the two presumed extracellular loops of connexin32 and shorter peptides representing subsets of these larger peptides were found to inhibit cell-cell channel formation. The properties of the peptide inhibition suggested that the binding site is complex, involving several segments of both extracellular loops. One of the peptides (a 12-mer) did not inhibit but instead was found to form channels in membranes. Both in oocyte membranes and in bilayers, the channels formed by the peptide were asymmetrically voltage dependent. Their unit conductances ranged from 20 to 160 pS. These data are discussed in the form of a model in which the connexin sequence represented by the peptide is part of a beta structure providing the lining of the channel pore.

Connexin43 mRNA contains a functional internal ribosome entry site

A reporter gene construct was used to study the regulation of connexin43 (Cx43) expression, the major gap junction protein found in heart and uterus, in transfected cell lines. The construct had the firefly luciferase gene under the control of the Cx43 promoter. Inclusion of the 5′‐untranslated region (UTR) of the mRNA in the construct increased luciferase expression by 70%. A bicistronic vector assay demonstrated that the Cx43 5′‐UTR contains a strong internal ribosome entry site (IRES). Deletion analysis localized the IRES element to the upstream portion of the 5′‐UTR.

A connexin‐32 mutation associated with Charcot‐Marie‐Tooth disease does not affect channel formation in oocytes

Members of the connexin family differ most in their carboxy‐termini, both with respect to sequence and length. In order to assess the contribution of this region to channel function, a series of carboxy‐terminal deletion mutants were tested in the paired‐oocyte expression system. Connexin‐32 can be truncated by 64 amino acids without detectable loss of its known channel properties. Removal of additional amino acids results in a progressive loss of function over a stretch of 4 amino acids. In addition to this effect of length the charge of the carboxy‐terminus appears to be another determinant of channel function. One of the fully functional deletion mutants, carrying a stop codon after amino acid‐219, had been reported to be associated with Charcot‐Marie‐Tooth disease. The implications of this finding are discussed.

Gating Properties of Connexin32 Cell--Cell Channels and their Mutants Expressed in Xenopus Oocytes

Carboxyl-terminal deletion mutants of the gap junction protein connexin32 were tested in the oocyte cell—cell channel assay. Oocytes expressing a mutant lacking 58 carboxyl terminal amino acids were found to exhibit junctional conductances of the same magnitude as oocytes expressing wild-type connexin32. The gating properties of the channels formed by this mutant ofconnexin32 with respect to transjunctional voltage and cytoplasmic acidification are indistinguishable from those found with wild-type connexin32 channels. This includes a novel pH-dependent voltage gate. In another mutant, two carboxyl terminal serine residues, Ser233 and Ser240, were replaced by Asn residues. This double mutant has properties indistinguishable from wild-type connexin32, suggesting that phosphorylation of either of these serines is not required for channel opening.

A chimeric connexin forming gap junction hemichannels

Abstract Connexins are the subunits of gap junction channels which connect neighboring cells. With the exception of lens connexins, they usually do not form open hemichannels in the cell membrane of single cells. Here we describe a chimeric connexin consisting of cx32 where the first extracellular loop sequence is replaced by the corresponding cx43 sequence. This chimera, cx32E143, forms conventional gap junction channels in the paired oocyte assay. In addition cx32E143 induces a membrane conductance in single oocytes. This membrane conductance is voltage dependent and is similarly sensitive to CO2 as are gap junction channels formed by the chimera or by wild-type cx32. These data suggest that cx32E143 forms patent hemichannels in the plasma membrane of single oocytes. This conclusion is further supported by the observation that oocytes expressing cx32E143 take up from the bath medium tracer molecules known to pass through gap junction channels.