Goran Söhl

Structural and functional diversity of connexin genes in the mouse and human genome.

Abstract Gap junctions are clustered channels between contacting cells through which direct intercellular communication via diffusion of ions and metabolites can occur. Two hemichannels, each built up of six connexin protein subunits in the plasma membrane of adjacent cells, can dock to each other to form conduits between cells. We have recently screened mouse and human genomic data bases and have found 19 connexin (Cx) genes in the mouse genome and 20 connexin genes in the human genome. One mouse connexin gene and two human connexin genes do not appear to have orthologs in the other genome. With three exceptions, the characterized connexin genes comprise two exons whereby the complete reading frame is located on the second exon. Targeted ablation of eleven mouse connexin genes revealed basic insights into the functional diversity of the connexin gene family. In addition, the phenotypes of human genetic disorders caused by mutated connexin genes further complement our understanding of connexin functions in the human organism. In this review we compare currently identified connexin genes in both the mouse and human genome and discuss the functions of gap junctions deduced from targeted mouse mutants and human genetic disorders.

Expression and functions of neuronal gap junctions

Gap junctions are channel-forming structures in contacting plasma membranes that allow direct metabolic and electrical communication between almost all cell types in the mammalian brain. At least 20 connexin genes and 3 pannexin genes probably code for gap junction proteins in mice and humans. Gap junctions between murine neurons (also known as electrical synapses) can be composed of connexin 36, connexin 45 or connexin 57 proteins, depending on the type of neuron. Furthermore, pannexin 1 and 2 are likely to form electrical synapses. Here, we discuss the roles of connexin and pannexin genes in the formation of neuronal gap junctions, and evaluate recent functional analyses of electrical synapses that became possible through the characterization of mouse mutants that show targeted defects in connexin genes.

An Update on Connexin Genes and their Nomenclature in Mouse and Man

Gap junctions, composed of connexin protein subunits, allow direct communication through conduits between neighboring cells. Twenty and twenty-one members of the connexin gene family are likely to be expressed in the mouse and human genome, respectively, 19 of which can be grouped into sequence-orthologous pairs. Their gene structure appears to be relatively simple. In most cases, an untranslated exon1 is separated by an intron of different lengh from exon2 that includes the uninterrupted coding region and the 3′-untranslated region. However, there are several exceptions to this scheme, since some mouse connexin genes contain different 5′-untranslated regions spliced either in an alternative and/or consecutive manner. Additionally, in at least 3 mouse and human connexin genes (mCx36, mCx39, mCx57 and hCx31.3, hCx36, as well as hCx40.1) the reading frame is spliced together from 2 different exons. So far, there are two nomenclatures to classify the known connexin genes: The “Gja/Gjb” nomenclature, as it is currently adopted by the NCBI data base, contains some inconsistencies compared to the “Cx” nomenclature. Here we suggest some minor corrections to co-ordinate the “Gja/Gjb” nomenclature with the “Cx” nomenclature. Furthermore, this short review contains an update on phenotypic correlations between connexin deficient mice and patients bearing mutations in their orthologous connexin genes.

The murine gap junction gene connexin36 is highly expressed in mouse retina and regulated during brain development.

A new gap junction gene isolated from rat brain cDNA, mouse retina cDNA and mouse genomic DNA is called connexin36, since it codes for a connexin protein of 321 amino acids corresponding to the theoretical molecular mass of 36 045 kDa (rat) and 36 084 kDa (mouse). Only one amino acid residue differs between rat and mouse connexin36. In the single murine connexin36 gene, an 1.14‐kb intron interrupts the coding region, similar as in the homologous skate connexin35 gene. Because of this unique feature, mouse connexin36 differs from the other 13 murine connexin genes and is suggested to form a new δ subclass of connexins. Connexin36 mRNA (2.9 kb) is highly expressed in adult retina and less abundant in brain where it gradually increased during fetal development until day 7 post partum, and decreased thereafter.

Increased apoptosis and inflammation after focal brain ischemia in mice lacking connexin43 in astrocytes

Astrocytes secrete cytokines and neurotrophic factors to neurons, consistent with a neurosupportive role for astrocytes. However, in ischemic or metabolic insults, the function of astrocytic gap junctions composed mainly from connexin43 (Cx43) remains controversial. We have previously shown that heterozygous Cx43 null mice subjected to middle cerebral artery occlusion exhibited significantly enhanced stroke volume and apoptosis compared to wild-type mice. In this study, we used mice in which the human GFAP promoter-driven cre transgene deletes the floxed Cx43 gene in astrocytes, excluding the effects from reduced Cx43 expression in many other cell types as well as astrocytes. We induced focal brain ischemia in mice lacking Cx43 in astrocytes [Cre(+)] and control littermates [Cre(-)]. Cre(+) mice showed a significantly increased stroke volume and enhanced apoptosis, detected by terminal dUTP nick-end labeling and caspase-3 immunostaining, compared to Cre(-) mice. Inflammatory response assessed by the microglial marker CD11b was amplified in the penumbra of Cre(+) mice compared to that of Cre(-) mice. Our results suggest that astrocytic gap junctions could be important for the regulation of neuronal apoptosis and the inflammatory response after stroke. These findings support the view that astrocytes play a critical role in neuroprotection during ischemic insults.

Emerging complexities in identity and function of glial connexins

Recent research results indicate that glial gap-junction communication is much more complex and widespread than originally thought, and has diverse roles in brain homeostasis and the response of the brain to injury. The situation is far from clear, however. Pharmacological agents that block gap junctions can abolish neuron-glia long-range signaling and can alleviate neuronal damage whereas, intriguingly, opposite effects are observed in mice lacking connexin43, a major gap-junction subunit protein in astrocytes. How can the apparently contradictory results be explained, and how is specificity achieved within the glial gap-junction system? Another key issue in understanding glial connexin function is that oligodendrocytes and astrocytes, each of which express distinct connexin isotypes, are thought to participate in brain homeostasis by forming a panglial syncytium. Molecular analysis has revealed a surprising diversity of connexin expression and function, and this has led to new hypotheses regarding their roles in the brain, which could be tested using new approaches.

Functional expression of connexin57 in horizontal cells of the mouse retina

Horizontal cells are interneurons of the vertebrate retina that exhibit strong electrical and tracer coupling but the identity of the channel‐forming connexins has remained elusive. Here we show that horizontal cells of the mouse retina express connexin57 (Cx57). We have generated Cx57‐deficient mice by replacing the Cx57 coding region with a lacZ reporter gene, expressed under control of the endogenous Cx57 promoter. These mice were fertile and showed no obvious anatomical or behavioural abnormalities. Cx57 mRNA was expressed in the retina of wild‐type littermates but was absent from the retina of Cx57‐deficient mice. Previously reported results that the Cx57 gene was very weakly expressed in several other mouse tissues turned out to be unspecific. Cx57 mRNA is abundantly expressed in the retina and weakly in the thymus of adult mice but absent in all other adult tissues tested, including brain. Furthermore, Cx57 is expressed in embryonic kidney at E16.5 to E18.5 days post‐conception, as indicated by the pattern of lacZ expression. Within the retina, lacZ signals were assigned exclusively to horizontal cells based on co‐localization with cell‐type‐specific marker proteins. Microinjection of Neurobiotin into horizontal cells of isolated retinae revealed less than 1% of tracer coupling in Cx57‐deficient retinae compared with wild‐type controls. Cx57 is the first connexin identified in mammalian horizontal cells and the first connexin whose expression is apparently restricted to only one type of neuron.

Reduction of high-frequency network oscillations (ripples) and pathological network discharges in hippocampal slices from connexin 36-deficient mice

Recent evidence suggests that electrotonic coupling is an important mechanism for neuronal synchronisation in the mammalian cortex and hippocampus. Various types of network oscillations have been shown to depend on, or be sharpened by, gap junctions between inhibitory interneurones or excitatory projection cells. Here we made use of a targeted disruption of the gene coding for Cx36, a recently discovered neuronal gap junction subunit, to analyse its role in hippocampal network behaviour. Mice lacking Cx36 are viable and lack obvious morphological or behavioural abnormalities. Stimulation of afferent and efferent fibre pathways in hippocampal slices revealed a largely normal function of the synaptic circuitry, including tetanically evoked network oscillations. Spontaneous sharp waves and ripple (∼200 Hz) oscillations, however, occurred less frequently in slices from Cx36 ‐/‐ mice, and ripples were slightly slower than in littermate controls. Moreover, epileptiform discharges elicited by 4‐aminopyridine were attenuated in slices from Cx36 ‐/‐ mice. Our findings indicate that Cx36 plays a role in the generation of certain forms of network synchronisation in the hippocampus, namely sharp wave‐ripple complexes and hypersynchronous epileptiform discharges.

Expression of connexin36 in cone pedicles and OFF-cone bipolar cells of the mouse retina

Transgenic technology, immunocytochemistry, electrophysiology, intracellular injection techniques, and reverse transcription PCR were combined to study the expression of neuronal connexin36 (Cx36) in the outer plexiform layer of the mouse retina. Transgenic animals expressed either a fusion protein of full-length Cx36 with enhanced green fluorescent protein (EGFP) attached at the C terminus or exon 2 of Cx36 was replaced byβ-galactosidase (β-gal). In the outer nuclear layer,β-gal-positive cell bodies, which were confined to the most distal region close to the outer limiting membrane, displayed immunoreactivity against S-cone opsin. Cx36–EGFP puncta colocalized with cone pedicles, which were visualized by intracellular injection. In reverse transcriptase PCR experiments, Cx36 mRNA was never detected in samples of rods harvested from the outer nuclear layer. These results strongly suggest expression of Cx36 in cones but not in rods. In vertical sections, Cx36 expression in the vitreal part of the outer plexiform layer was characterized by a patchy distribution. Immunocytochemistry with antibodies against the neurokinin-3 receptor and the potassium channel HCN4 (hyperpolarization-activated cyclic nucleotide-gated potassium channel) displayed clusters of the Cx36 label on the dendrites of OFF-cone bipolar cells. In horizontal sections, these clusters of Cx36 appeared as round or oval-shaped groups of individual puncta, and they were always aligned with the base of cone pedicles. Double-labeling experiments and single-cell reverse transcriptase PCR ruled out expression of Cx36 in horizontal cells and rod bipolar cells. At light microscopic resolution, we found close association of Cx36–EGFP with the AMPA-type glutamate receptor subunit GluR1 but not with GluR2–GluR4, the kainate receptor subunit GluR5, or the metabotropic glutamate receptor mGluR6.

Expression patterns of connexin genes in mouse retina

To analyze the molecular basis of gap junctional communication in mouse retina, we examined the expression pattern of the following 13 connexin (Cx) genes: Cx26, Cx30, Cx30.3, Cx31, Cx31.1, Cx32, Cx36, Cx37, Cx40, Cx43, Cx45, Cx46, and Cx50. By using reverse transcriptase‐polymerase chain reactions with primer oligonucleotides to murine connexin genes, we detected mRNAs of Cx26, Cx31, Cx32, Cx36, Cx37, Cx40, Cx43, Cx45, and Cx50. Retinae from heterozygous mice with targeted replacement of most of the Cx45 open reading frame by a lacZ reporter gene showed Cx45 promoter activity in somata of the ganglion cell layer and the inner nuclear layer. Immunoblot and immunofluorescence analyses with antibodies generated to murine connexin epitopes revealed the presence of Cx36, Cx37, Cx43, and Cx45 proteins: The outer and inner plexiform layer were immunopositive for Cx36 and Cx45. Cx37 immunoreactivity was found in blood vessels of the inner retina. Cx43 immunolabeling was detected in the ganglion cell layer and nerve fiber layer where it was largely colocalized with immunostaining of glial fibrillary acidic protein suggesting that Cx43‐positive cells could be of glial origin. No Cx26 protein was detected in retina by using Cx26 antibodies for immunoblot analyses or confocal microscopy. Furthermore, comparative immunofluorescence analyses of retinae from mice deficient for Cx31, Cx32, or Cx40 with retinae of wild‐type mice revealed no specific immunostaining. Our results demonstrate regional specificity in expression of connexin genes in mouse retina and, thus, provide a basis for future assignments of functional defects in connexin‐deficient mice to cells in different regions of the retina. J. Comp. Neurol. 425:193–201, 2000.