Immunogold evidence that neuronal gap junctions in adult rat brain and spinal cord contain connexin-36 but not connexin-32 or connexin-43

Rash, John E.; Staines, W.A.; Yasumura, Thomas; Patel, Daywin; Furman, Christophe; Stelmack, Gerald L.; Nagy, J.I.

doi:10.1073/pnas.97.13.7573

Cited by 272 publications

(258 citation statements)

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“…In light of ultrastructural evidence indicating extensive gap junctions between astrocytes and between astrocytes and oligodendrocytes, and the absence of intercellular gap junction formation between oligodendrocytes (Mugnaini, 1986;Rash et al, , 2000, it is clear that the astrocytic Cxs participate in the formation of A/A junctions, and contribute these Cxs to the astrocyte side of A/O gap junctions. Less clear and requiring detailed ultrastructural investigation, however, is the extent to which oligodendrocyte cell populations express each of Cx29, Cx32 and Cx47; the oligodendrocyte cellular compartments in which these Cxs are concentrated; and the nature of the gap junctional channels in which they engage.…”

Section: Discussionmentioning

confidence: 99%

“…In the CNS, astrocytes are extensively coupled by gap junctions (astrocyte-toastrocyte gap junctions [A/A junctions]) that, based on ultrastructural observations, were reported to contain Cx26, Cx30 and Cx43 (Yamamoto et al, 1990a,b;Nagy et al, 1999Nagy et al, , 2001. Also present are astrocyte-to-oligodendrocyte gap junctions (A/O junctions) that contain the former three Cxs on the astrocyte side, and Cx32 on the oligodendrocyte side Rash et al, 2000Rash et al, , 2001Nagy and Rash, 2000;Nagy et al, 2003a). Recently, it was reported that oligodendrocytes also express Cx47 (Odermatt et al, 2003) as well as Cx29, with conflicting results indicating either that mutually exclusive populations of these cells contain Cx29 and Cx32 (Altevogt et al, 2002), or that many of these cells contain both of these Cxs (Nagy et al, 2003a,b).…”

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Connexin47, connexin29 and connexin32 co-expression in oligodendrocytes and cx47 association with zonula occludens-1 (zo-1) in mouse brain

et al. 2004

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Gap junctions between glial cells in mammalian CNS are known to contain several connexins (Cx), including Cx26, Cx30 and Cx43 at astrocyte-to-astrocyte junctions, and Cx29 and Cx32 on the oligodendrocyte side of astrocyte-to-oligodendrocyte junctions. Recent reports indicating that oligodendrocytes also express Cx47 prompted the present studies of Cx47 localization and relationships to other glial connexins in mouse CNS. In view of the increasing number of connexins reported to interact directly with the scaffolding protein zonula occludens-1 (ZO-1), we investigated ZO-1 expression and Cx47/ZO-1 interaction capabilities in brain, spinal cord and Cx47-transfected HeLa cells. From counts of over 9000 oligodendrocytes labeled by immunofluorescence in various brain regions, virtually all of these cells were found to express Cx29, Cx32 and Cx47. Oligodendrocyte somata displayed robust Cx47-immunopositive puncta that were co-localized with punctate labeling for Cx32 and Cx43. By freeze-fracture replica immunogold labeling, Cx47 was abundant on the oligodendrocyte-side of oligodendrocyte/astrocyte gap junctions. By immunofluorescence, labeling for Cx47 along myelinated fibers was sparse in most brain regions, whereas Cx29 and Cx32 were previously found to be concentrated along these fibers. By immunogold labeling, Cx47 was found in numerous small gap junctions linking myelin to astrocytes, but not within deeper layers of myelin. Brain subcellular fractionation revealed a lack of Cx47 enrichment in myelin fractions, which nevertheless contained an enrichment of Cx32 and Cx29. Oligodendrocytes were immunopositive for ZO-1, and displayed almost total Cx47/ZO-1 colocalization. ZO-1 was found to co-immunoprecipitate with Cx47, and pull-down assays indicated binding of Cx47 to the second PDZ domain of ZO-1.Our results indicate widespread expression of Cx47 by oligodendrocytes, but with a distribution pattern in relative levels inverse to the abundance of Cx29 in myelin and paucity of Cx29 in oligodendrocyte somata. Further, our findings suggest a scaffolding and/or regulatory role of ZO-1 at the oligodendrocyte side of astrocyte-to-oligodendrocyte gap junctions. Keywords connexin47; connexin32; connexin43; gap junctions; PDZ domains; glia Gap junctions are localized at specialized cell-to-cell contacts of plasma membranes in which connexin (Cx) proteins form bidirectional intercellular channels that allow passage of ions and *Corresponding author. Tel: +1-204-789-3767; fax: +1-204-789-3934. E-mail address: nagyji@ms.umanitoba.ca (J. I. Nagy).. 1 Present address: Department of Pathology, Weifang Medical College, PR China. NIH Public Access Author ManuscriptNeuroscience. Author manuscript; available in PMC 2007 March 8. NIH-PA Author ManuscriptNIH-PA Author Manuscript NIH-PA Author Manuscriptsmall molecules between cells (Goodenough et al., 1996;Kumar and Gilula, 1996;Willecke et al., 2002). In the CNS, astrocytes are extensively coupled by gap junctions (astrocyte-toastrocyte gap junctions [A/A junctions]) that, base...

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Section: Discussionmentioning

confidence: 99%

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confidence: 99%

Connexin47, connexin29 and connexin32 co-expression in oligodendrocytes and cx47 association with zonula occludens-1 (zo-1) in mouse brain

et al. 2004

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“…Sternberger Monoclonals * For FRIL, all antibodies were used at 10 μg/ml. ** Previously characterized in Rash et al (2000) aa, amino acids…”

Section: Tbstrmentioning

confidence: 99%

“…749.11, 2002) for immunocytochemical precedent, Long and coworkers (Long et al, 2005) proposed Cx36 as the primary or sole connexin in neuronal gap junctions in SCN, and suggested that Cx36 deletion disrupted circadian rhythms. Among the 21 connexins known to be present in mammals (Condorelli et al, 1998;Söhl and Willecke, 2003;Willecke et al, 2002), both Cx36 and Cx45 have been demonstrated in ultrastructurally-defined neuronal gap junctions (Rash et al, 2000(Rash et al, , 2001Fukuda et al, 2006;Kamasawa et al, 2006), and there is immunocytochemical evidence for neuronal expression of Cx50 and Cx57 in retina (Massey et al, 2003;Hombach et al, 2004;O'Brien et al, 2006). In view of controversies surrounding the existence and connexin composition of neuronal gap junctions in SCN, we used confocal immunofluorescence microscopy and freeze-fracture replica immunogold labeling (FRIL) to document gap junctions in SCN neurons and to identify the constituent connexins in neurons vs. glia, and whole-cell recordings from hypothalamic slices to re-assess tracer and electrotonic coupling.…”

Section: Introductionmentioning

confidence: 99%

Connexin36 vs. connexin32, “miniature” neuronal gap junctions, and limited electrotonic coupling in rodent suprachiasmatic nucleus

et al. 2007

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Suprachiasmatic nucleus (SCN) neurons generate circadian rhythms, and these neurons normally exhibit loosely-synchronized action potentials. Although electrotonic coupling has long been proposed to mediate this neuronal synchrony, ultrastructural studies have failed to detect gap junctions between SCN neurons. Nevertheless, it has been proposed that neuronal gap junctions exist in the SCN; that they consist of connexin32 or, alternatively, connexin36; and that connexin36 knockout eliminates neuronal coupling between SCN neurons and disrupts circadian rhythms. We used confocal immunofluorescence microscopy and freeze-fracture replica immunogold labeling to examine the distributions of connexin30, connexin32, connexin36, and connexin43 in rat and mouse SCN and used whole-cell recordings to re-assess electrotonic and tracer coupling. Connexin32-immunofluorescent puncta were essentially absent in SCN but connexin36 was relatively abundant. Fifteen neuronal gap junctions were identified ultrastructurally, all of which contained connexin36 but not connexin32, whereas nearby oligodendrocyte gap junctions contained connexin32. In adult SCN, one neuronal gap junction was >600 connexons, whereas 75% were smaller than 50 connexons, which may be below the limit of detectability by fluorescence microscopy and thin-section electron microscopy. Whole-cell recordings in hypothalamic slices revealed tracer coupling with Neurobiotin in <5% of SCN neurons, and paired recordings (>40 pairs) did not reveal obvious electrotonic coupling or synchronized action potentials, consistent with few neurons possessing large gap junctions. However, most neurons had partial spikes or spikelets (often <1 mV), which remained after QX-314 had blocked sodium-mediated action potentials within the recorded neuron, consistent with spikelet transmission via small gap junctions. Thus, a few "miniature" gap junctions on most SCN neurons appear to mediate weak electrotonic coupling between limited numbers of neuron pairs, Publisher's Disclaimer: This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final citable form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. NIH Public Access Author ManuscriptNeuroscience. Author manuscript; available in PMC 2008 February 15. NIH-PA Author ManuscriptNIH-PA Author Manuscript NIH-PA Author Manuscript thus accounting for frequent detection of partial spikes and hypothetically providing the basis for "loose" electrical or metabolic synchronization of electrical activity commonly observed in SCN neuronal populations during circadian rhythms. Keywordsimmunocytochemistry; electrical synapse; freeze-fracture replica immunogold labeling; spikelet; metabolic coupling; syn...

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“…18 A expressão da conexina-36 é restrita aos neurônios, enquanto a conexina-32 e a conexina-43 são encontradas em oligodendrócitos e astrócitos, respectivamente. 18,24 Recentemente, o papel das JC na geração de crise tem sido estudado com mais detalhes em modelos de epilepsia in vivo, in vitro, em simulações computacionais e em humanos. Estudos eletrofisiológicos têm implicado as JC na geração de oscilações muito rápidas (OMR) precedendo as crises.…”

Section: Introductionunclassified

Papel das sinapses elétricas em crises epilépticas

Silva¹,

Bachiega-Salviano²,

Zanetti³

et al. 2010

J. epilepsy clin. neurophysiol.

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RESumoIntrodução: No sistema nervoso central a comunicação entre neurônios se realiza através de estruturas denominadas sinapses: elétricas ou químicas. As sinapses elétricas são formadas pela aproximação das membranas plasmáticas de dois neurônios formando estruturas chamadas junções comunicantes (gap junctions, do inglês). As junções comunicantes são compostas por seis subunidades da proteína conexina de cada membrana, formando poros que comunicam o citoplasma de células adjacentes e permitem a passagem de íons e pequenas moléculas. objetivos: A presente revisão pretende descrever e discutir os principais resultados que apontam para uma importante relação entre junções comunicantes e sincronia neuronal durante crises epilépticas. Resultados e Conclusão: Quando um neurônio é despolarizado, este tipo de comunicação permite a rápida transferência iônica entre as células, promovendo alta sincronia neuronal. Recentemente, o papel das junções comunicantes na geração e propagação de descargas epilépticas tem sido estudado através do uso de diferentes modelos experimentais in vivo, in vitro e in silico (modelos computacionais).unitermos: Junções comunicantes, sinapse elétrica, conexinas, crises epilépticas. AbStRACtThe role of eletrical synapses in epileptic seizures Introduction: In the central nervous system, neuronal communication is accomplished by structures called synapses: electrical or chemical. Electrical synapses are formed by the apposition of plasmatic membranes at gap junctions and the interaction of connexin subunits from two neurons. At this site, connexin complexes create intercellular pores that communicate the cytoplasm of adjacent neurons and allow free flow of ions and small molecules. objective: In this review, we will present and discuss recent results showing the possible involvement of electrical synapses in the neuronal hypersynchronization during epileptic seizures. Results and conclusion: When a neuron is depolarized, ions flow very rapidly from one cell to the other promoting high neuronal synchrony. More recently, the role of gap junctions in the generation and propagation of epileptic discharges has been investigated using combined approaches of in vivo, in vitro and in silico (computational) models. Keyword: Gap junctions, eletrical synapses, connexin and epileptic seizures IntRoduçãoAs investigações sobre junções comunicantes (JC) no sistema nervoso têm uma longa história, iniciando com um primeiro estudo reportando a comunicação direta e acoplamento elétrico entre células nervosas de invertebrados. 11 Este trabalho pioneiro abriu caminho para muitos outros que estabeleceram a comunicação elétrica entre neurônios, a chamada de sinapse elétrica, como distinta da neurotransmissão química. 4 Subsequentemente, vários estudos demonstraram que as sinapses elétricas não estavam restritas a invertebrados, mas também podiam ser encontradas em vertebrados, incluindo os mamíferos. 3 Hoje sabemos que há dois tipos de sinapses no sistema nervoso central (SNC): as sinapses elétricas e as sinapses quí...

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Immunogold evidence that neuronal gap junctions in adult rat brain and spinal cord contain connexin-36 but not connexin-32 or connexin-43

Cited by 272 publications

References 46 publications

Connexin47, connexin29 and connexin32 co-expression in oligodendrocytes and cx47 association with zonula occludens-1 (zo-1) in mouse brain

Connexin47, connexin29 and connexin32 co-expression in oligodendrocytes and cx47 association with zonula occludens-1 (zo-1) in mouse brain

Connexin36 vs. connexin32, “miniature” neuronal gap junctions, and limited electrotonic coupling in rodent suprachiasmatic nucleus

Papel das sinapses elétricas em crises epilépticas

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