Cx36, Cx43 and Cx45 in mouse and rat cerebellar cortex: species‐specific expression,compensation in Cx36 null mice and co‐localization in neurons vs. glia

Electrical synapses formed by connexin36 (Cx36)‐containing gap junctions between interneurons in the cerebellar cortex have been well characterized, including those formed between basket cells and between Golgi cells, and there is gene reporter‐based evidence for the expression of connexin45 (Cx45) in the cerebellar molecular layer. Here, we used immunofluorescence approaches to further investigate expression patterns of Cx36 and Cx45 in this layer and to examine localization relationships of these connexins with each other and with glial connexin43 (Cx43). In mice, strain differences were found, such that punctate labelling for Cx36 was differentially distributed in the molecular layer of C57BL/6 vs. CD1 mice. In mice with EGFP reporter representing Cx36 expression, Cx36‐puncta were localized to processes of stellate cells and other cerebellar interneurons. Punctate labelling of Cx45 was faint in the molecular layer of wild‐type mice and was increased in intensity in mice with Cx36 gene ablation. The vast majority of Cx36‐puncta co‐localized with Cx45‐puncta, which in turn was associated with the scaffolding protein zonula occludens‐1. In rats, Cx45‐puncta were also co‐localized with Cx36‐puncta and additionally occurred along Bergmann glial processes adjacent to Cx43‐puncta. The results indicate strain and species differences in Cx36 as well as Cx45 expression, possible compensatory processes after loss of Cx36 expression and localization of Cx45 to both neuronal and Bergmann glial gap junctions. Further, expression of both Cx43 and Cx45 in Bergmann glia of rat may contribute to the complex properties of junctional coupling between these cells and perhaps to their reported coupling with Purkinje cells.     

Cytology and immunocytochemistry of the nucleus of the lateral line lobe in the electric fish Gnathonemus petersii (Mormyridae): evidence suggesting that GABAergic synapses mediate an inhibitory corollary discharge

Knollenorgans, low-threshold electroreceptors found in mormyrid fish, are involved primarily, if not exclusively, in communication. The rhombencephalic nucleus of the lateral line lobe (nLLL) is the target nucleus of knollenorgan afferents. Cells in the nLLL receive a few medium size to large endings with round synaptic vesicles (classified as spoon; large club; small club-, and rodlet-shaped endings) with which they form nexus (gap junction) and asymmetrical chemical synapses associated with the round synaptic vesicles. In addition these endings emit thin collaterals which terminate as small boutons on nLLL neurons; these boutons also have round vesicles and make mixed (electrotonic and chemical) synapses. In addition, cells in the nLLL receive synaptic input from numerous small boutons containing pleomorphic vesicles and making symmetric synapses. We have not found any interneurons within nLLL. Our ultrastructural analysis suggests that boutons synapsing on nLLL neurons belong to only two afferent fiber systems and that the wiring diagram of nLLL is extremely simple. We have studied the immunolocalization in nLLL of glutamic acid decarboxylase (GAD), the enzyme essential for the synthesis of GABA that is also a useful marker for this widely distributed inhibitory neurotransmitter. GAD immunoreactivity was confined to the small boutons with pleomorphic vesicles. GAD was also found in a nucleus projecting to the nLLL, here named the sublemniscal nucleus (SL), which probably conveys corollary discharge signals to the nLLL. This GABAergic projection may be responsible for the potent inhibition associated with the electric organ discharge command that has been described in these cells.     

Electrical coupling between astrocytes and between oligodendrocytes studied in mammalian cell cultures

The characteristics of electrical coupling between astrocytes and between oligodendrocytes were analyzed in cell cultures derived from rodent central nervous system. Experiments were carried out by impaling one member of a glial pair with separate voltage recording and current passing electrodes (cell 1) and the other cell, a measured distance from the first, with a voltage-recording electrode (cell 2). Astrocyte pairs within 300 microns of one another were always coupled. The coupling ratio was determined for 23 astrocytic pairs various distances apart, and decreased with distance in a roughly exponential manner. The average coupling ratio of astrocytes within 100 microns of each other was 0.44 +/- 0.32. Oligodendrocytes were less strongly coupled to each other than astrocytes. Even cells immediately adjacent to one another were often uncoupled. Among coupled oligodendrocytes within 100 microns of each other, the average coupling ratio was 0.11 +/- 0.1. Current passage between pairs of astrocytes and pairs of oligodendrocytes was nonrectifying. Application of 0.5 mM BaCl2 or 44.6 mM CsCl (substituted for NaCl) depolarized and increased the input resistance of astrocytes and oligodendrocytes. These ions also increased the coupling ratio in astrocyte pairs and oligodendrocyte pairs; this effect was rapid in onset and completely reversible. Ba++ and Cs+ appear to block resting K+ conductance in glia and probably increase the coupling ratio by increasing the effective length constant of the glial membrane without any direct effect on junctional resistance. In three cases, oligodendrocyte pairs that appear uncoupled in normal solution exhibited coupling in the presence of BaCl2 or CsCl. This suggests that oligodendrocytes may be widely coupled by junctions that provide only weak electrical interaction; such junctions might be important for the exchange of small metabolically active molecules. The strong electrical coupling among astrocytes, in concert with their K+-selective membrane conductance, would provide for an electrical syncytium well designed to transport K+ away from areas of focal extracellular accumulation (i.e., the spatial buffer mechanism), and these cells, more than oligodendrocytes, may provide this function.     

Expression and function of the neuronal gap junction protein connexin 36 in developing mammalian retina

With the advent of transgenic mice, much has been learned about the expression and function of gap junctions. Previously, we reported that retinal ganglion cells in mice lacking the neuronal gap junction protein connexin 36 (Cx36) have nearly normal firing patterns at postnatal day 4 (P4) but many more asynchronous action potentials than wild-type mice at P10 (Torborg et al. [2005] Nat. Neurosci. 8:72-78). With the goal of understanding the origin of this increased activity in Cx36-/- mice, we used a transgenic mouse (Deans et al. [2001] Neuron 31:477-485) to characterize the developmental expression of a Cx36 reporter in the retina. We found that Cx36 was first detected weakly at P2 and gradually increased in expression until it reached an adult pattern at P14. Although the onset of expression varied by cell type, we identified Cx36 in the glycinergic AII amacrine cell, glutamatergic cone bipolar cell, and retinal ganglion cells (RGCs). In addition, we used calcium imaging and multielectrode array recording to characterize further the firing patterns in Cx36-/- mice. Both correlated and asynchronous action potentials in P10 Cx36-/- RGCs were significantly inhibited by bath application of an ionotropic glutamate receptor antagonist, indicating that the increase in activity was synaptically mediated. Hence, both the expression patterns and the physiology suggest an increasing role for Cx36-containing gap junctions in suppressing RGC firing between waves during postnatal retinal development.     

The connexin 36 blockers quinine, quinidine and mefloquine inhibit cortical spreading depression in a rat neocortical slice model in vitro

A protocol for inducing cortical spreading depression (SD) on rat neocortical slices in vitro, upon local application of calibrated approximately nl drops of KCl, 3M was used to elicit SD events, recorded at two different points on the slice. This in vitro model was validated by the inhibition of SD episodes by the NMDA antagonist MK-801 (20 microM), the reference SD blocker. Quinine, its stereoisomer quinidine, and mefloquine consistently inhibited the SD episodes. Quinine and quinidine, 100 and 200 microM reduced the duration, while mefloquine, 100 and 200 microM reduced the amplitude of SD events, all in a concentration-dependent manner. These compounds have been reported to block gap junctions, specifically the neuronal connexin (Cx) 36, but they also exert other cellular effects. While further investigation is warranted to settle whether SD inhibition in vitro by quinine, quinidine and mefloquine reflects an involvement of neuronal Cx36 channels in SD generation/propagation, these results bear potential drug-discovery relevance for the migraine with aura.     

Electron microscopic immunocytochemical study of the distribution of parvalbumin-containing neurons and axon terminals in the primate dentate Gyrus and Ammon's horn

Five green monkeys were examined with light and electron microscopic preparations to explore the regional differences in the distribution of parvalbumin (PV)-positive neurons and axon terminals in the primate hippocampus. PV-positive neurons were mainly found in the hilus of the dentate gyrus and the strata oriens and pyramidale of Ammon's horn. In electron microscopic preparations, the PV-positive cells displayed nuclear infoldings, intranuclear rods, a large rim of perikaryal cytoplasm with numerous organelles and both asymmetric and symmetric axosomatic synapses. One prominent PV-positive cell type in CA1 was a large multipolar neuron that resembled the large basket cells of the neocortex. Although most PV-positive dendrites were aspiny and postsynaptic to numerous axon terminals, some PV-positive dendrites in the molecular layer of the dentate gyrus displayed filipodia-like appendages with no synapses or spines that were postsynaptic to multiple axon terminals. The PV-positive dendrites in the hilus and stratum oriens were apposed at specialized junctions that resembled gap junctions. PV-positive axons were concentrated in the principal cell layers, and formed axosomatic, axodendritic, and axon initial segment synapses. In cases where these axons were observed to appose the surface of granule cells for a long length, only one axosomatic symmetric synapse per cell was found. In the hilus, PV-positive axon terminals formed synapses onto thorny excrescences of spiny cells. Both semithin sections and electron microscopic preparations indicated that more PV-positive axon terminals formed symmetric axosomatic synapses with pyramidal cells in CA2 than in CA1 and CA3. Also, CA2 displayed a unique plexus of PV-positive axon terminals in stratum lacunosum moleculare. These results indicate that the PV-positive hippocampal cells form a subset of GABAergic local circuit neurons, including the basket and chandelier cells. The ubiquitous finding of PV-positive dendrites linked by gap junctions throughout the dentate gyrus and Ammon's horn adds further data to indicate that this subset of GABAergic neurons is linked electrotonically. The synaptic organization of PV-positive neurons in the hippocampus suggests their participation in both feedback and feedforward inhibition. The PV-positive neurons in the hippocampus are only a proportion of the basket and chandelier cells, whereas virtually all of these cells in neocortex are PV-positive. © 1993 Wiley-Liss, Inc.     

Light and electron microscopical studies on the spherical neurons in the electrosensory lateral line lobe of the gymnotiform fish,Sternopygus

Spherical cells are a principal cell type of the electrosensory lateral line lobe (ELLL) and play a crucial role in the jamming avoidance response (JAR) behavior. Since Sternopygus, a low frequency gymnotiform genus, does not display a JAR we searched for spherical cells in its ELLL. While present in Sternopygus, spherical cells differed remarkedly from those in the high-frequency gymnotiforms, Eigenmannia and Apteronotus. This study reveals species-characteristic differences in the morphology and synaptology of the spherical cell, a projection neuron located in the deep neuropil layer (DNL) of the ELLL. In contrast to the adendritic spherical cell of other species, the spherical neuron in Sternopygus exhibits an extensive basilar dendrite that extends into the primary electroreceptive afferent zone, the deep fiber layer (DFL). In Sternopygus, these neurons are distributed evenly across the full length of each tuberous subdivision, with cell densities highest in the centrolateral subdivision. At the ultrastructural level, the contacts on the soma, proximal, and distal dendrite of the spherical neuron in Sternopygus are asymmetrical chemical synapses, quite distinct from the electrotonic gap junctions found on the spherical neurons of other species.     

Expression of connexin36 in the adult and developing rat brain

The distribution of connexin36 (Cx36) in the adult rat brain and retina has been analysed at the protein (immunofluorescence) and mRNA (in situ hybridization) level. Cx36 immunoreactivity, consisting primarily of round or elongated puncta, is highly enriched in specific brain regions (inferior olive and the olfactory bulb), in the retina, in the anterior pituitary and in the pineal gland, in agreement with the high levels of Cx36 mRNA in the same regions. A lower density of immunoreactive puncta can be observed in several brain regions, where only scattered subpopulations of cells express Cx36 mRNA. By combining in situ hybridization for Cx36 mRNA with immunohistochemistry for a general neuronal marker (NeuN), we found that neuronal cells are responsible for the expression of Cx36 mRNA in inferior olive, cerebellum, striatum, hippocampus and cerebral cortex. Cx36 mRNA was also demonstrated in parvalbumin-containing GABAergic interneurons of cerebral cortex, striatum, hippocampus and cerebellar cortex. Analysis of developing brain further revealed that Cx36 reaches a peak of expression in the first two weeks of postnatal life, and decreases sharply during the third week. Moreover, in these early stages of postnatal development Cx36 is detectable in neuronal populations that are devoid of Cx36 mRNA at the adult stage. The developmental changes of Cx36 expression suggest a participation of this connexin in the extensive interneuronal coupling which takes place in several regions of the early postnatal brain.     

Evidence for a role of the N-terminal domain in subcellular localization of the neuronal connexin36 (Cx36)

The expression and functional properties of connexin36 (Cx36) have been investigated in two neuroblastoma cell lines (Neuro2A, RT4-AC) and primary hippocampal neurons transfected with a Cx36-enhanced green fluorescent protein (EGFP) expression vector. Transfected cells express Cx36-EGFP mRNA, and Cx36-EGFP protein is localized in the perinuclear area and cell membrane. Upon differentiation of cell lines, Cx36-EGFP protein was detectable in processes with both axonal and dendritic characteristics. Small gap junction plaques were found between adjacent cells, and electrophysiological recordings demonstrated that the electrical properties of these gap junctions were virtually indistinguishable from those reported for native Cx36. Mutagenesis of Cx36 led to the identification of a structural element that interferes with normal protein localization. In contrast, site directed mutagenesis of putative protein phosphorylation motifs did not alter subcellular localization. This excludes phosphorylation/dephosphorylation as a major regulatory step in Cx36 protein transport.     

缝隙连接蛋白36表达变化对帕金森病模型大鼠基底节环路功能的影响

目的 观察缝隙连接蛋白36(Cx36)在帕金森病模型大鼠纹状体和运动皮质区的表达变化,并探讨缝隙连接功能异常与帕金森病基底节环路功能紊乱间的关系。方法 采用6羟多巴胺注射法建立帕金森病动物模型,免疫组织化学染色及Westernblotting法检测纹状体及运动皮质区Cx36表达变化,免疫荧光双标染色进一步分析纹状体脑啡肽阳性传出神经元及Parvalbumin阳性中间神经元Cx36表达变化。结果 (1)免疫组织化学染色显示,帕金森病组大鼠右侧纹状体及运动皮质区Cx36表达水平高于正常对照组(均P<0.05)。(2)免疫荧光双标染色显示,纹状体脑啡肽阳性神经元数目和Cx36表达水平高于正常对照组(均P<0.05),而Parvalbumin阳性神经元数目和Cx36表达水平低于正常对照组(均P<0.05)。(3)Westernblotting法检测显示,帕金森病组大鼠右侧纹状体[(119.31±8.92)%]及运动皮质区[(138.20±17.88)%]Cx36表达水平高于正常对照组[(104.05±3.82)和(105.27±2.82)%,均P<0.05]。结论 帕金森病大鼠右侧纹状体及运动皮质区Cx36表达水平升高,纹状体脑啡肽阳性传出神经元Cx36表达上调,Parvalbumin阳性中间神经元Cx36表达下调。提示缝隙连接异常可能参与帕金森病皮质基底节皮质环路功能紊乱的发生机制。     

Neuronal coupling via connexin36 contributes to spontaneous synaptic currents of striatal medium-sized spiny neurons

Gap junctions provide a means for electrotonic coupling between neurons, allowing for the generation of synchronous activity, an important contributor to learning and memory. Connexin36 (Cx36) is largely neuron specific and provides a target for genetic manipulation to determine the physiological relevance of neuronal coupling. Within the striatum, Cx36 is more specifically localized to the interneuronal population, which provides the main inhibitory input to the principal projection medium-sized spiny neurons. In the present study, we examined the impact of genetic ablation of Cx36 on striatal spontaneous synaptic activity. Patch-clamp recordings were performed from medium-sized spiny neurons, the primary target of interneurons. In Cx36 knockout mice, the frequencies of both excitatory and inhibitory spontaneous postsynaptic currents were reduced. We also showed that activation of dopamine receptors differentially modulated the frequency of GABAergic currents in Cx36 knockout mice compared with their wild-type littermates, suggesting that dopamine plays a role in altering the coupling of interneurons. Taken together, the present findings demonstrate that electrical coupling of neuronal populations is important for the maintenance of normal chemical synaptic interactions within the striatum.     

Ultrastructural correlates of electrical-chemical synaptic transmission in goldfish cranial motor nuclei

The output connections of the cranial relay neurons, part of the Mauthner cell network, were examined in goldfish with light and electron microscopic techniques. Either lucifer yellow or horseradish peroxidase (HRP) was injected into cranial relay neuron axons to demonstrate that they diverge to several motor nuclei and to many motoneurons within one nucleus. Retrograde transport of the enzyme from injections of mandibular muscles was used to label the trigeminal motoneurons. In the electron microscope, cranial relay neuron processes were distinguished by the granular appearance of the electron-opaque polymer formed enzymatically by HRP, while the retrogradely labeled motoneurons had the polymer enclosed in lysosomes. The cranial relay neuron terminals contained many presynaptic vesicles which concentrated the HRP reaction product. Active zones and synaptic clefts were evident. At some synapses, both gap junctions and presynaptic vesicles were found. The mechanism of synaptic transmission was investigated by simultaneous recording with two intracellular microelectrodes from cranial relay neuron-motoneuron pairs. Composite postsynaptic potentials in a trigeminal motoneuron were evoked by intracellular stimulation of a cranial relay neuron axon. The earliest excitatory postsynaptic potential (EPSP) component had a latency of 0.25 msec and had a peak amplitude that was not depressed by repetitive stimulation. A second component had larger peak amplitudes which were reduced easily by repetitive stimulation. Antidromic action potentials were not transmitted from motoneurons to the cranial relay neuron axons. Thus, both electrical and chemical transmission probably occur at the cranial relay neuron-motoneuron synapses. Since the cranial relay neurons fire synchronously and receive excitatory chemical synapses, the function of the gap junctions and electrical transmission is unclear. Perhaps the importance of these gap junctions is more for transport of small molecules than for impulse transmission.     

Electrical interaction between neurons in the pigeon isthmo-optic nucleus

The present study used brain slices to investigate interneuronal communication in the isthmo-optic nucleus in pigeons. Electrical stimulation of the isthmo-optic tract generated a transmembrane potential in isthmo-optic cells that was obtained by subtracting the extracellular potential from the intracellular potential. This transmembrane potential resulted in enhancement of excitability and/or in production of spikes in 42 (63%) cells. In most cases, proximal axons marked in brain slices by Lucifer yellow were too short to reach the stimulation site, indicating that spikes were evoked by electrical field effect or ephaptic interaction produced by nearby cells whose axons were activated by stimulation. Eleven (16%) cells discharged a spikelet, or spike that was abolished by hyperpolarizing current injection leaving a spikelet. Markings of five of these cells all indicated the presence of dye-couplings, each of which consisted of a pair of cells. Fourteen (21%) cells only produced antidromic spikes with a short and constant latency. Four of these cells were marked and their axons passed through the stimulation site, implying that their nearby cells' axons might be cut too short to be electrically stimulated or they were in a sparse-cell area. The present results provide electrophysiological and neuroanatomical evidence that both electrical field effect and electrical coupling may play important roles in interneuronal communication within the pigeon isthmo-optic nucleus. These findings are supported by anatomical arrangement of densely packed cells and their oriented dendrites in this centrifugal nucleus.     

Cx36在癫持续状态大鼠海马神经元的表达

目的观察连接蛋白36（Cx36）在癫持续状态大鼠海马神经元的表达。方法建立36只氯化锂-匹罗卡品诱导的癫持续状态大鼠模型,随机分为生理盐水组、喹啉组、辛醇组（每组12只）,分别予以腹腔注射生理盐水、喹啉、辛醇,通过Racine评分判断大鼠给药前后癫发作情况,利用免疫荧光染色法、Western-blot法检测各组大鼠海马Cx36的表达。结果喹啉组和辛醇组给药前后大鼠行为学评分比较差异有统计学意义（P〈0.01）;而生理盐水组差异无统计学意义（P〉0.05）。喹啉组和辛醇组大鼠海马神经元Cx36的表达明显低于生理盐水组（P〈0.01）,但2组Cx36的表达量差异无统计学意义（P〉0.05）。结论 Cx36在癫发作中起着重要作用,可能成为潜在的治疗靶点。     

Gap junctions between human meningioma cells maintained in organ culture

Summary Intercellular junctions were commonly observed in a human syncitial meningioma maintained in organ culture for up to 44 days in vitro (DIV) using gelatin sponge foam matrices. The junctions were identified as one of three types: desmosomes; tight junctions; or gap junctions. Of the three types, gap junctions were frequently encountered and showed preservation of their characteristic ladder-like substructure. The results suggest that organ culture provides an environment that may facilitate correlation of the structure and function of gap junctions between coupled human meningioma cells.     

Activated microglia impairs neuroglial interaction by opening Cx43 hemichannels in hippocampal astrocytes

Glia plays an active role in neuronal functions and dysfunctions, some of which depend on the expression of astrocyte connexins, the gap junction channel and hemichannel proteins. Under neuroinflammation triggered by the endotoxin lipopolysacharide (LPS), microglia is primary stimulated and releases proinflammatory agents affecting astrocytes and neurons. Here, we investigate the effects of such microglial activation on astrocyte connexin‐based channel functions and their consequences on synaptic activity in an ex vivo model. We found that LPS induces astroglial hemichannel opening in acute hippocampal slices while no change is observed in gap junctional communication. Based on pharmacological and genetic approaches we found that the LPS‐induced hemichannel opening is mainly due to Cx43 hemichannel activity. This process primarily requires a microglial stimulation resulting in the release of at least two proinflammatory cytokines, IL‐1β and TNF‐α. Consequences of the hemichannel‐mediated increase in membrane permeability are a calcium rise in astrocytes and an enhanced glutamate release associated to a reduction in excitatory synaptic activity of pyramidal neurons in response to Schaffer's collateral stimulation. As a whole our findings point out astroglial hemichannels as key determinants of the impairment of synaptic transmission during neuroinflammation. GLIA 2015;63:795–811     

脑蛋白水解液对大鼠神经胶质细胞间缝隙连接通讯的研究

目的探讨脑蛋白水解液对大鼠神经胶质细胞间缝隙连接通讯功能的影响。方法由大鼠神经干细胞诱导培养神经胶质细胞至致密单层，分为脑蛋白水解液组、对照组及佛波酯阴性对照组继续培养，利用划痕标记染料示踪技术，以荧光黄染料在细胞间的扩散距离作为评价缝隙连接通讯的指标，测定脑蛋白水解液对大鼠胶质细胞间缝隙连接通讯的影响；采用逆转录-聚合酶链反应法检测脑蛋白水解液组和对照组细胞Cx43 mRNA表达的变化。结果脑蛋白水解液组荧光黄染料5min扩散距离为（189．80±6．56）μm，对照组扩散距离为（154．70±6．02）μm，组间差异有统计学意义（P〈0．01）；逆转录．聚合酶链反应检测显示脑蛋白水解液组细胞中Cx43mRNA相对表达量为0．89±0．13，高于对照组细胞的0．67±0．10，两组比较差异有统计学意义（P〈0．01）。结论脑蛋白水解液可通过上调胶质细胞Cx43基因的表达水平，增强大鼠胶质细胞间缝隙连接通讯，这可能是其在机体损伤修复过程中对胶质细胞起保护作用的重要机制。