Heterogeneous distribution of a gap junction protein, connexin43, in the gastroduodenal junction of the guinea pig.

The gastroduodenal junction differs in morphology and function from the stomach and the duodenum. We studied the immunohistochemical distribution of the gap junction protein, connexin43, and the nerve terminal proteins, SNAP-25 and synaptotagmin, in the musculature of the guinea pig gastroduodenal junction. Connexin43-immunopositive structures were distributed throughout the circular layer of the gastroduodenal junction, most densely in the duodenal circular layer. The difference in the distribution patterns of these structures between the stomach and the duodenum was readily observed in the gastroduodenal junction. In the inner part of the circular muscle layer of the gastroduodenal junction, the connexin43-immunopositive structures were relatively few or non-existent, whereas the SNAP-25-containing nerve fibers and synaptotagmin-containing nerve terminals, clearly observed, were numerous. These findings show a heterogeneous distribution of the gap junctions and nerves in the gastroduodenal junction. The results suggest that the gastroduodenal junction has heterogeneous electrical connections among smooth muscle cells via gap junctions, and specific nerve innervation, which regulates gastroduodenal motility.     

Sexually dimorphic role of BNST vasopressin cells in sickness and social behavior in male and female mice

Circumstantial evidence supports the hypothesis that the sexually dimorphic vasopressin (AVP) innervation of the brain tempers sickness behavior in males. Here we test this hypothesis directly, by comparing sickness behavior in animals with or without ablations of BNST AVP cells, a major source of sexually dimorphic AVP in the brain. We treated male and female AVP-iCre+ and AVP-iCre− mice that had been injected with viral Cre-dependent caspase-3 executioner construct into the BNST with lipopolysaccharide (LPS) or sterile saline, followed by behavioral analysis. In all groups, LPS treatment reliably reduced motor behavior, increased anxiety-related behavior, and reduced sucrose preference and consumption. Male mice, whose BNST AVP cells had been ablated (AVP-iCre+), displayed only minor reductions in LPS-induced sickness behavior, whereas their female counterparts displayed, if anything, an increase in sickness behaviors. All saline-treated mice with BNST AVP cell ablations consumed more sucrose than did control mice, and males, but not females, with BNST AVP cell ablations showed reduced preference for novel conspecifics compared to control mice. These data confirm that BNST AVP cells control social behavior in a sexually dimorphic way, but do not play a critical role in altering sickness behavior.     

Fibroblast growth factors-5 and -9 distinctly regulate expression and function of the gap junction protein connexin43 in cultured astroglial cells from different brain regions

Astroglial cells contribute to neuronal maintenance and function in the normal and diseased brain. Gap junctions formed predominantly by connexin43 (cx43) provide important pathways to coordinate astroglial responses. We have previously shown that fibroblast growth factor (FGF)-2, which occurs ubiquitously in the CNS, downregulates gap junction communication in cortical and striatal, but not in mesencephalic astroglial cells in vitro (Reuss et al. Glia 22:19-30, 1998). Other members of the FGF family expressed in the CNS include FGF-5 and FGF-9. We show that both FGF-5 and FGF-9, like FGF-2, downregulate astroglial gap junctions and functional coupling. However, their effects are strikingly different from different brain regions, with regard to astroglial cells. FGF-5 specifically affects mesencephalic astroglial cells without changing coupling of cortical and striatal astroglia, while FGF-9 reduces gap junctional coupling in astroglia from all three brain regions. Both cx43 mRNA and protein levels as well as functional coupling assessed by dye spreading are affected. To clarify whether brain region-specific effects of FGFs on astroglial coupling are due to differential expression of FGF receptors (FGFR), we monitored expression of the four known FGFR mRNAs in astroglial cultures by RT-PCR. Irrespective of their regional origin, astroglial cells express mRNAs for FGFR-2 and FGFR-3. In summary, our results provide evidence for an important role of FGF-2, -5, and -9 in a distinct, CNS region-specific regulation mechanism of astroglial gap junction communication. The molecular basis underlying the regionally distinct responsiveness of astrocytes to different FGFs may be sought beyond distinct FGFR expression.     

Role of gap junction and connexin-43 in hypoxic-ischemic brain damage

INTRODUCTION Gap junction (GJ) is a special channel, which, at present, is thought to be the only one channel that can directly perform energy, sub- stance and information exchanges between two adjacent cells. GJ channel, widely existing in nervous system…     

Adolescence and the ontogeny of the hormonal stress response in male and female rats and mice

Adolescent development is marked by many changes in neuroendocrine function, resulting in both immediate and long-term influences on an individual’s physiology and behavior. Stress-induced hormonal responses are one such change, with adolescent animals often showing different patterns of hormonal reactivity following a stressor compared with adults. This review will describe the unique ways in which adolescent animals respond to a variety of stressors and how these adolescent-related changes in hormonal responsiveness can be further modified by the sex and previous experience of the individual. Potential central and peripheral mechanisms that contribute to these developmental shifts in stress reactivity are also discussed. Finally, the short- and long-term programming effects of chronic stress exposure during adolescence on later adult hormonal responsiveness are also examined. Though far from a clear understanding of the neurobehavioral consequences of these adolescent-related shifts in stress reactivity, continued study of developmental changes in stress-induced hormonal responses may shed light on the increased vulnerability to physical and psychological dysfunctions that often accompany a stressful adolescence.     

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.     

Sexually dimorphic changes in the exploratory and habituation profiles of heterozygous neuregulin-1 knockout mice

The neuregulin-1 gene is widely expressed in the central nervous system and is associated with increased risk for schizophrenia. Using an ethologically based approach, the phenotype of neuregulin-1 heterozygous knockout mice was examined by revealing the individual elements of behaviour in the murine repertoire over the prolonged course of interaction with the environment. During initial exploration, neuregulin-1 mutants displayed a phenotype characterized by increases in locomotion and rearing free, with sex-specific alterations in sifting and grooming. Over subsequent habituation, certain initial effects endured while new phenotypic effects emerged, some of which were again sex-specific. These studies elaborate a pleiotropic role of neuregulin-1 in development, plasticity and function, including sexual dimorphism, by defining the elemental, temporal and sex-specific characteristics of the neuregulin-1 mutant ethogram.     

Sexually dimorphic activation of the accessory, but not the main, olfactory bulb in mice by urinary volatiles

Previous research suggests that volatile body odourants detected by the main olfactory epithelium (MOE) are processed mainly by the main olfactory bulb (MOB) whereas nonvolatile body odourants detected by the vomeronasal organ (VNO) are processed via the accessory olfactory bulb (AOB). We asked whether urinary volatiles from males and females differentially activate the AOB in addition to the MOB in gonadectomized mice of either sex. Exposure to urinary volatiles from opposite-sex but not same-sex conspecifics augmented the number of Fos-immunoreactive mitral and granule cells in the AOB. Volatile urinary odours from male as well as female mice also stimulated Fos expression in distinct clusters of MOB glomeruli in both sexes. Intranasal administration of ZnSO(4), intended to disrupt MOE function, eliminated the ability of volatile urinary odours to stimulate Fos in both the MOB and AOB. In ovariectomized, ZnSO(4)-treated females a significant, though attenuated, AOB Fos response occurred after direct nasal exposure to male urine plus soiled bedding, suggesting that VNO signaling remained partially functional in these mice. Future studies will determine whether MOE or VNO signaling, or both types of input, drive the sexually dimorphic response of the AOB to volatile opposite-sex odours and whether this AOB response contributes to reproductive success.     

Excitatory effects of gap junction blockers on cerebral cortex seizure-like activity in rats and mice

Purpose:   The role of gap junctions in seizures is an area of intense research. Many groups have reported anticonvulsant effects of gap junction blockade, strengthening the case for a role for gap junctions in ictogenesis. The cerebral cortex is underrepresented in this body of research. We have investigated the effect of gap junction blockade on seizure-like activity in rat and mouse cerebral cortex slices.
Methods:   Seizure-like activity was induced by perfusing with low-magnesium artificial cerebrospinal fluid. The effect of three gap junction blockers was investigated in rat cortical slices; quinine (200 and 400 μ m ), quinidine (100 and 200 μ m ), and carbenoxolone (100 and 200 μ m ). In addition, the effect of mefloquine was investigated in wild-type mice and connexin36 knockout mice. The data were analyzed for the effect on frequency and amplitude of seizure-like events.
Results:   Paradoxical excitatory effects on seizure-like activity were observed for all three agents in rat cortical slices. Quinine (200 μ m ) and carbenoxolone (100 μ m ) increased both the frequency and amplitude of seizure-like events. Quinidine (100 μ m ) increased the frequency of events. Higher doses of quinine (400 μ m ) and carbenoxolone (200 μ m ) had biphasic excitatory–inhibitory effects. Similar excitatory effects were observed in adult wild-type mouse cortical slices perfused with mefloquine (5 μ m or 10 μ m ), but were absent in slices from connexin36-deficient mice.
Discussion:   In conclusion, we have shown a paradoxical proseizure effect of pharmacologic gap junction blockade in a cortical model of seizure-like activity. We suggest that this effect is probably due to a disruption of inhibitory interneuron coupling secondary to connexin36 blockade.     

Reduced expression of connexin-43 and functional gap junction coupling in human gliomas

Gap junctions are an important means for intercellular communication during development, processes of tissue differentiation, and in maintenance of adult tissue homeostasis. We investigated the expression levels and distribution of connexin-43 (Cx-43), the most abundant astrocytic gap junction protein, in acutely isolated astrocytes and glioma cells from biopsy tissue obtained from patients diagnosed with glioblastoma multiforme (GBM), low-grade astrocytomas (LGAs), or mesial temporal lobe epilepsy. Western blot and immunohistochemical analyses indicated an inverse correlation between the amount of Cx-43 protein and tumor malignancy grade, as assessed by calculating tissue mitotic indexes (MI) obtained using anti-Ki-67 nuclear antigen staining. Samples from epilepsy patients had a low MI and were intensely positive for Cx-43 staining, while LGA tissue samples exhibited moderate staining for Cx-43 and average MI, and GBM biopsies showed significantly lower levels of Cx-43 and high MI. Functional coupling was assayed using fluorescence recovery after photobleach (FRAP). We found that cells from glioma cell lines and primary cultures of human astrocytes from GBM tissues displayed significantly lower degrees of gap junction intercellular communication (GJIC) as indicated by longer and less complete recovery from photobleaching. Mean recovery values were GBM 23.8% +/- 11.4%, LGA 49.4% +/- 47%, and nontumor astrocytes 67.2% +/- 8.4%. Western blot analysis of several human glioma cell lines and tissue biopsies showed variable expression levels of Cx-43, which correlated negatively with the extent of recovery in the same samples. Taken together, our findings suggest that high-grade brain tumors show reduced intercellular communication and a decrease in connexin-43 protein levels.     

Sexually dimorphic behavioral and brain asymmetries in neonatal rats: effects of prenatal alcohol exposure

Behavioral and neuroanatomical asymmetries were assessed in 3-day-old male and female rat pups chosen from litters whose dams had received one of 3 prenatal treatments: 35% ethanol-derived calories, pair-fed control, or lab chow control. Behavioral laterality was assessed by observing the preferred tail bias on postnatal (PN) day 1. On PN day 3, brains were sectioned and morphometric analyses conducted for total brain volume, left and right neocortical volumes, and left and right hippocampal volumes. Prenatal alcohol exposure altered the population proportions of left, right and neutral tail biases in male pups on PN day 1. Female pups were affected by both prenatal alcohol exposure and maternal undernutrition/stress of pair-feeding. Prenatal alcohol exposure decreased body weight and total brain volume, but increased the brain volume/body weight ratio compared to both control groups. Prenatal alcohol exposure also reduced the volumes of the hippocampus and neocortex, with the greatest proportional reduction found in the volume of the anterior neocortex. A left-right anterior neocortical asymmetry was observed, with tail bias, prenatal treatment and sex all significant factors. Alcohol-exposed males showed a 'feminized' asymmetry. These results demonstrate that a sexually dimorphic cerebral asymmetry can be detected at birth in rats; this asymmetry appears to be related to a postural position bias. The reversal of normal interhemispheric relations by prenatal alcohol exposure in male offspring suggested that the in utero hormonal milieu modulates the development of cerebral lateralization.     

Sexually dimorphic responses of rats to fluoxetine in the forced swimming test are unrelated to the function of the serotonin transporter in the brain

Due to the prevalence of depression in women, female rats may be a better models for antidepressant research than males. In male rats, fluoxetine inhibited the serotonin (5-hydroxytryptamine, 5-HT) transporter (SERT) which is reducing the immobility time in the repeated forced swimming test (rFST). The performance of female rats in this test is unknown. In this study, responses of male and female rats in the rFST under chronic treatment with fluoxetine and the function of SERT in their brains were examined. Wistar rats received oral fluoxetine (females: 0, 1, 2.5, or 5 mg kg^-1 day^-1; males: 0 or 2.5 mg kg^-1 day^-1; in sucrose 10%, 1.5 ml/rat) 1 hr before the test daily for 12 days over the course of the rFST. rFST consisted of a 15 min pretest followed by 5 min sessions of swimming at 1 (test), 7 (retest 1), and 14 (retest 2) days later. SERT functioning was assessed by ex vivo assays of the frontal cortex and hippocampus of rats. Fluoxetine reduced immobility time of males in the rFST while it failed to do so in females. In vitro treatment with fluoxetine inhibited the uptake of 5-HT of both sexes similarly, while in vivo chronic administration of fluoxetine failed to do so. In summary, rats responded to the chronic treatment with fluoxetine in a sexually dimorphic fashion during the rFST despite the functioning of SERT in their brains remaining equally unchanged. Hence, our data suggest that sexually dimorphic responses to fluoxetine in rFST may be unrelated to the function of SERT in rat brains.     

A brain slice model for in vitro analyses of astrocytic gap junction and connexin43 regulation: actions of ischemia, glutamate and elevated potassium

Brain slices prepared from adult rats and maintained for up to 3 h in vitro were used to investigate the effects of pharmacological treatments on the phosphorylation state, immunolabelling characteristics and ultrastructural localization of astrocytic gap junctions and connexin43 (Cx43). Slices deprived of glucose/oxygen to mimic ischemia or those exposed to 1 mM glutamate for 1 h exhibited Cx43 dephosphorylation, epitope masking and gap junction internalization as revealed by Western blotting and Cx43 immunolocalization with various antibodies. Treatment with 15 mM K+ caused Cx43 dephosphorylation without junction internalization. The effects of glutamate and K+ were completely blocked by the N-methyl-D-aspartate (NMDA) glutamate receptor antagonist 2-amino-5-phosphonovalerate (APV), which acts largely on neuronal NMDA receptors, suggesting neuronal mediation of glial gap junction responses to these treatments. Astrocytes contained a dephosphorylated form of Cx43 with a typical migration profile at 41 kDa as well as novel, apparently dephosphorylated or partially phosphorylated, forms migrating at 43 kDa. These results indicate that slices prepared from adult brain can serve as a convenient model to investigate the molecular basis and receptor-mediated mechanisms underlying astrocytic Cx43 responses that have been observed in vivo following cerebral ischemia or neural activation. These processes can be related in part to neuronal regulation of astrocytic gap junctional coupling state, which is also amenable to analysis in brain slices.     

Pressure induces loss of gap junction communication and redistribution of connexin 43 in astrocytes

Astrocytes, the major glia in the nonmyelinated optic nerve head (ONH), connect via gap junctions built of connexin-43 (Cx43) to form a functional syncytium allowing communication and control of ionic and metabolic homeostasis of retinal ganglion cells (RGCs) axon. We examined gap junction intercellular communication (GJIC) by scrape loading assays in human ONH astrocytes exposed to hydrostatic (HP) or ambient pressure (CP) in vitro. Immunostaining, immunoprecipitation, and immunoblots were used to detect Cx43 distribution and phosphorylation in astrocytes exposed to HP with/without EGF receptor (EGFR) tyrosine kinase inhibitors AG1478 and AG82 and MAPK inhibitors U0126, PD98059, and SB203580. The data indicates that upon exposure to HP, astrocytes decrease GJIC and exhibit altered cellular localization and phosphorylation of Cx43. Inhibition of EGFR blocked the effects of HP on GJIC and HP-induced Cx43 tyrosine phosphorylation. Inhibitors of MAPK- ERK1/2 and -p38 caused partial closure of GJIC under CP and HP, which was maintained for 6 h. Inhibition of Big Mitogen-Activated Kinase 1/ERK5 (BMK1/ERK5) caused partial closure under CP and HP followed by full recovery after 6 h. Inhibition of MAPK did not affect the HP-induced increase in Cx43 serine 279/282 phosphorylation. We conclude that activation of the EGFR pathway in response to HP leads to decrease of GJIC via tyrosine phosphorylation of Cx43 in ONH astrocytes. In glaucoma under conditions of elevated intraocular pressure (IOP), astrocytes may lose GJIC altering the homeostasis of RGC axons, adopting the reactive phenotype, contributing to glaucomatous neuropathy.     

Modulation of astrocyte P2Y1 receptors by the carboxyl terminal domain of the gap junction protein Cx43

Gap junction proteins, connexins, provide intercellular channels that allow ions and small signaling molecules to be transmitted to adjacent coupled cells. Besides this function, it is becoming apparent that connexins also exert channel-independent effects, which are likely mediated by processes involving protein-protein interactions. Although a number of connexin interacting proteins have been identified, only little is known about the functional consequences of such interactions. We have previously shown that deletion of the astrocytic gap junction protein, connexin43 (Cx43) causes a right-ward shift in the dose-response curve to P2Y1R agonists and decreased P2Y1R expression levels. To evaluate whether these changes were due to reduced gap junctional communication or to protein-protein interactions, Cx43-null astrocytes were transfected with full-length Cx43 and Cx43 domains, and P2Y1R function and expression levels evaluated. Results indicate that restoration of P2Y1R function is independent of gap junctional communication and that the Cx43 carboxyl terminus spanning the SH3 binding domain (260-280) participates in the rescue of P2Y1R pharmacological behavior (shifting to the left the P2Y1R dose-response curve) without affecting its expression levels. These results suggest that the Cx43 carboxyl-terminus domain provides a binding site for an intracellular molecule, most likely a member of the c-Src tyrosine kinase family, which affects P2Y1R-induced calcium mobilization. It is here proposed that a nonchannel function of Cx43 is to serve as a decoy for such kinases. Such modulation of P2Y1R is expected to influence several neural cell functions, especially under inflammation and neurodegenerative disorders where expression levels of Cx43 are decreased.     

缝隙连接蛋白Cx32和Cx43在大鼠癫癎样放电后神经元的表达及生胃酮的干预作用

目的研究缝隙连接在癫癎发病机制中的作用.方法以体外培养大鼠海马神经元为研究对象,采用免疫细胞化学方法和实时定量逆转录-聚合酶链反应(RT-PCR)方法观察缝隙连接蛋白(connexin, Cx)32和Cx43的表达,并加用生胃酮干预.结果神经元经无镁液处理1 h后Cx32 mRNA迅速升高,至5 h升高了近10倍;蛋白表达在2 h后开始增多(21.80±1.74),8 h后(47.30±5.75)较对照组(9.30±1.25)增高了5倍.Cx43水平低于Cx32,无镁液作用5 h后mRNA表达显著增多,8 h后蛋白表达始明显增强.生胃酮显著抑制了其表达.结论 Cx32和Cx43在癫癎样放电后表达显著增多,生胃酮能够抑制其表达和神经元放电,提示缝隙连接在癫癎的发生发展过程中具有重要的作用.