Homer1a regulates the activity-induced remodeling of synaptic structures in cultured hippocampal neurons

Activity-dependent re-organizations of central synapses are thought to play important roles in learning and memory. Although the precise mechanisms of how neuronal activities modify synaptic connections remain to be elucidated, the activity-induced neuronal proteins such as Homer1a may contribute to the onset of synaptic remodeling. To further understand the physiological roles of Homer1a, we first examined prolonged effects of neuronal stimulation capable of inducing Homer1a on the distribution of a postsynaptic protein Homer1c by live imaging and immunostaining. We found that glutamate stimulation induced a biphasic change in the distribution of Homer1c, in which the postsynaptic clusters of Homer1c defused initially after 30 min to 1 h, and then reassembled more than the original level after 4–8 h. When other synaptic proteins (postsynaptic density-95 (PSD95), Filamentous actin (F-actin), glutamate receptors, synaptotagmin, synaptophysin and synapsin) were analyzed by immunocytochemical methods, the distribution of these proteins also showed a similar biphasic pattern, suggesting that glutamate stimulation induces a global alteration in synaptic structures. To further dissect the functions of Homer1a in the activity-induced synaptic remodeling, the short hairpin RNA (shRNA) vectors that specifically block the expression of endogenous Homer1a were constructed. When the shRNA of Homer1a was introduced to the cells, the activity-induced changes were almost completely suppressed. The expression of surface glutamate receptor 2 was also inhibited, suggesting that Homer1a may modulate the efficacy of synaptic transmission.

Furthermore, we found that Homer1a contributes to the presynaptic remodeling in a retrograde manner. Our data indicate that Homer1a regulates the activity-induced biphasic changes of post- and pre-synaptic sites.     

Agonist-dependent postsynaptic effects of opioids on miniature excitatory postsynaptic currents in cultured hippocampal neurons

Although chronic treatment with morphine is known to alter the function and morphology of excitatory synapses, the effects of other opioids on these synapses are not clear. Here we report distinct effects of several opioids (morphine, [d-ala(2),me-phe(4),gly(5)-ol]enkephalin (DAMGO), and etorphine) on miniature excitatory postsynaptic currents (mEPSCs) in cultured hippocampal neurons: 1) chronic treatment with morphine for >3 days decreased the amplitude, frequency, rise time and decay time of mEPSCs. In contrast, "internalizing" opioids such as etorphine and DAMGO increased the frequency of mEPSCs and had no significant effect on the amplitude and kinetics of mEPSCs. These results demonstrate that different opioids can have distinct effects on the function of excitatory synapses. 2) mu opioid receptor fused with green fluorescence protein (MOR-GFP) is clustered in dendritic spines in most hippocampal neurons but is concentrated in axon-like processes in striatal and corticostriatal nonspiny neurons. It suggests that MORs might mediate pre- or postsynaptic effects depending on cell types. 3) Neurons were cultured from MOR knock-out mice and were exogenously transfected with MOR-GFP. Chronic treatment with morphine suppressed mEPSCs only in neurons that contained postsynaptic MOR-GFP, indicating that opioids can modulate excitatory synaptic transmission postsynaptically. 4) Morphine acutely decreased mEPSC amplitude in neurons expressing exogenous MOR-GFP but had no effect on neurons expressing GFP. It indicates that the low level of endogenous MORs could only allow slow opioid-induced plasticity of excitatory synapses under normal conditions. 5) A theoretical model suggests that morphine might affect the function of spines by decreasing the electrotonic distance from synaptic inputs to the soma.     

Serotonin attenuates a slow inhibitory postsynaptic potential in rat hippocampal neurons

Activity of hippocampal neurons was recorded in an in vitro slice preparation. Topical application of serotonin produced hyperpolarization, blockade of a slow afterhyperpolarization which follows a burst discharge and blockade of a slow inhibitory postsynaptic potential. The slow inhibitory postsynaptic potential evoked by stimulation of the apical dendritic region of the hippocampus is more sensitive to serotonin than the membrane potential or conductance. The effects of serotonin on the inhibitory postsynaptic potentials are blocked by the 5-HT1a antagonist spiperone, and not by mianserin, a 5-HT2 antagonist. The attenuation of the inhibitory postsynaptic potentials is not accompanied by a change in postsynaptic reactivity to GABA or baclofen. Serotonin blocks repetitive large inhibitory postsynaptic potentials evoked in hippocampal neurons by topical application of 4-aminopyridine. Putative interneurons are more sensitive to topical application of serotonin than pyramidal neurons. Fenfluramine, a serotonin releaser mimics the effects of topical application of serotonin indicating that synaptically released serotonin can produce the changes in membrane potential and reactivity to afferent stimulation. It is suggested that serotonin attenuates slow inhibitory postsynaptic potentials by inhibiting feed forward inhibitory interneurons which impinge upon the recorded pyramidal neurons.     

Transient focal cerebral ischemia differentially decreases Homer1a and 1b/c contents in the postsynaptic density

Homer is a scaffold protein in the postsynaptic density (PSD) and binds to the intracellular tail of group I metabotropic glutamate receptors (mGluRs). Although Homer contributes to the regulation of physiological function in synapses, the role of Homer proteins under pathophysiological conditions, such as cerebral ischemia, is still not fully clear. In the present study, we sought to determine whether transient focal cerebral ischemia would affect the level of Homer1 in the isolated-PSD fraction from rats. We showed that Homer1a (short form) and Homer1b/c (long form) as well as group I mGluR were localized in the cortical PSD. Cerebral ischemia decreased the content of Homer1a, which is a dominant-negative inhibitor of the long form of Homer proteins, in the PSD at 4 h of reperfusion without changing the level of Homer1a in cortical homogenates. On the other hand, the levels of Homer1b/c in the both PSD and homogenates were decreased at 24 h of reperfusion. These results suggest that these decreases in the level of Homer1 proteins after cerebral ischemia may contribute to the disturbance of synaptic function and subsequent development of cerebral ischemia.     

VEGF upregulates Homer 1a gene expression via the mitogen-activated protein kinase cascade in cultured cortex neurons

During stroke the blood-brain barrier (BBB) is damaged which can result in vasogenic brain edema and inflammation. The reduced blood supply leads to decreased delivery of oxygen and glucose to affected areas of the brain. Oxygen and glucose deprivation (OGD) can cause upregulation of glucose uptake of brain endothelial cells. In this letter, we investigated the influence of MK801, a non-competitive inhibitor of the NMDA-receptor, on the regulation of the glucose uptake and of the main glucose transporters glut1 and sglt1 in murine BBB cell line cerebEND during OGD. mRNA expression of glut1 was upregulated 68.7-fold after 6 h OGD, which was significantly reduced by 10 μM MK801 to 28.9-fold. Sglt1 mRNA expression decreased during OGD which was further reduced by MK801. Glucose uptake was significantly increased up to 907% after 6 h OGD and was still higher (210%) after the 20 h reoxygenation phase compared to normoxia. Ten micromolar MK801 during OGD was able to reduce upregulated glucose uptake after OGD and reoxygenation significantly. Presence of several NMDAR subunits was proven on the mRNA level in cerebEND cells. Furthermore, it was shown that NMDAR subunit NR1 was upregulated during OGD and that this was inhibitable by MK801. In conclusion, the addition of MK801 during the OGD phase reduced significantly the glucose uptake after the subsequent reoxygenation phase in brain endothelial cells.     

Excision-activated chloride channels in cultured postnatal rat hippocampal neurons

Chloride permeable intermediate conductance single channel events activated on patch excision were found in outside-out patches from cultured postnatal hippocampal neurons. A majority of the channels had a conductance of 83 ± 2.1 pS when recorded in a symmetrical TEAC1 solution. Two other populations of channels with conductance values of 62 ± 2.1 pS and 145 ± 1.9 pS were also observed. The reversal potentials for these intermediate conductance Cl⁻ channels coincided with that of the GABA activated channels. The channels characteristically appeared 5–15 min after patch excision, suggesting that these channels may be blocked by some diffusible factors under physiological conditions. Based on the measurements of channel burst durations while the channel was partially blocked, and the channel open times after complete relief from the block, the mechanism of blockade does not appear to be a simple open channel blockade. The high prevalence and its potential regulation by cytosolic factors suggest an important physiological role for these Cl⁻ channels coupling neuronal excitability with cellular metabolism.     

Single voltage-dependent potassium channels in cultured rat hippocampal neurons

Single-channel recordings using the gigohm seal patch-clamp technique were carried out on the somatic membranes of dissociated embryonic rat hippocampal neurons grown in cell culture. The recording medium contained tetrodotoxin to block the voltage-dependent Na+ conductance and Cd2+ to block Ca2+ and Ca2+-activated conductances. In the cell-attached configuration, depolarizing voltage steps activated outward directed single-channel currents with conductance 15-20 pS. The channel openings exhibited a moderate degree of flickering. The mean burst lifetimes ranged from 5 to 13 ms with a tendency to increase slightly at more depolarized potentials (T = 21-25 degrees C). Reversal potential measurements using excised membrane patches indicated that the channels behaved as expected of a K+-selective membrane pore. Channel opening occurred in Ca2+-free EGTA-containing solutions but was never observed in the presence of tetraethylammonium (TEA; 20 mM). The frequency of channel opening increased as the membrane was depolarized by up to 50 mV from resting potential; the fraction of time spent in the open state during the first 300 ms following a step depolarization increased e-fold for a 8-25 mV change in potential. First-latency histograms and simulations of the macroscopic current based on channel data obtained during repeated depolarizing voltage steps indicated that the probability of the channel being in the open state increases gradually with time after a step depolarization. During repeated depolarizing steps the channels appeared to randomly enter and exit a long-lived inactive state. It is concluded that these channels may underly the slowly activating, very slowly inactivating, TEA-sensitive voltage-dependent K+ current (IK) in cultured hippocampal neurons.     

Desensitization of GABA-induced currents in cultured rat hippocampal neurons.

The basic characteristics of desensitization of the GABAA receptor were investigated in cultured rat hippocampal neurons (three days to four weeks in vitro) using whole cell patch clamp techniques. GABA at 10-500 microM was perfused on to neurons for 30 or 60 s, with 60 s intervals of wash with control bath solution between perfusions. Desensitization, evaluated by peak-to-plateau ratio and time constants of current decay (tau), was dose-dependent and culture age-dependent. Desensitization was observed as early as three days in culture, the earliest time tested. At all ages, higher concentrations of GABA induced both larger and faster desensitization. Desensitization was markedly voltage-dependent and decreased with depolarization; peak-to-plateau ratio went from 6.3 to 1.4 and tau went from 4.6 to 26.8 s when holding potentials were changed from -80 mV to +30 mV. Low concentrations of GABA (1-2 microM) perfused for 2-60 s, which did not induce any current, had no effect on the maximal response nor desensitization produced by a subsequent application of 100 microM GABA. This finding suggests that GABA receptors were not desensitized without first being activated.     

Molecular correlates of the M-current in cultured rat hippocampal neurons

M-type K⁺ currents ( I _K(M)) play a key role in regulating neuronal excitability. In sympathetic neurons, M-channels are thought to be composed of a heteromeric assembly of KCNQ2 and KCNQ3 K⁺ channel subunits. Here, we have tried to identify the KCNQ subunits that are involved in the generation of I _K(M) in hippocampal pyramidal neurons cultured from 5- to 7-day-old rats. RT-PCR of either CA1 or CA3 regions revealed the presence of KCNQ2, KCNQ3, KCNQ4 and KCNQ5 subunits. Single-cell PCR of dissociated hippocampal pyramidal neurons gave detectable signals for only KCNQ2, KCNQ3 and KCNQ5; where tested, most also expressed mRNA for the vesicular glutamate transporter VGLUT1. Staining for KCNQ2 and KCNQ5 protein showed punctate fluorescence on both the somata and dendrites of hippocampal neurons. Staining for KCNQ3 was diffusely distributed whereas KCNQ4 was undetectable. In perforated patch recordings, linopirdine, a specific M-channel blocker, fully inhibited I _K(M) with an IC₅₀ of 3.6 ± 1.5 μM. In 70 % of these cells, TEA fully suppressed I _K(M) with an IC₅₀ of 0.7 ± 0.1 m m . In the remaining cells, TEA maximally reduced I _K(M) by only 59.7 ± 5.2 % with an IC₅₀ of 1.4 ± 0.3 m m ; residual I _K(M) was abolished by linopirdine. Our data suggest that KCNQ2, KCNQ3 and KCNQ5 subunits contribute to I _K(M) in these neurons and that the variations in TEA sensitivity may reflect differential expression of KCNQ2, KCNQ3 and KCNQ5 subunits.     

Synaptic transmission between cultured rat hippocampal neurons is enhanced by activation of protein kinase-C

Synaptic connections between rat hippocampal neurons were studied in dissociated cell culture. Activation of a cultured neuron by pulse application of glutamate could produce postsynaptic currents (PSCs) in other neurons in the culture dish. Activation of protein kinase C (PKC) by a phorbol ester caused an enhancement of the magnitude of the PSCs without affecting much the delay and decay time constant of the recorded PSCs. The increased reactivity to synaptic activation was not accompanied by a postsynaptic change in sensitivity to topical application of an excitatory amino acid, glutamate. A PKC inhibitor polymyxin B reduced the effects of the phorbol ester. It is suggested that PKC activation plays an important role in the regulation of release of neurotransmitters from cultured central neurons.     

Ghrelin promotes reorganization of dendritic spines in cultured rat hippocampal slices

Recent evidence suggests ghrelin may up-regulate the number of spine synapses. However, it is not completely understood whether an increased number of synapses are expressed on existing spines or accommodated in newly generated spines. We examined if ghrelin might have promoted the generation of new dendritic spines. Localization of polymerized actin (F-actin), highly expressed in dendritic spines, was assayed using phalloidin, a mushroom toxin that has a high affinity to F-actin. Alexa 488-conjugated phalloidin was visualized and relative changes in fluorescing puncta were quantified using a confocal microscope. Ghrelin was applied to cultured hippocampal slices for either 60 min or 23 h. Ghrelin increased the phalloidin fluorescent signals. The antagonist of the ghrelin receptor, D-Lys3-GHSR-6, blocked the ghrelin's effect of increasing the phalloidin signal, suggesting that the ghrelin's effect was mediated by the ghrelin receptor (GHSR1a). The ghrelin-mediated increase in phalloidin signals remained elevated while ghrelin was present in the culture media for 23 h. However, removal of ghrelin from culture media restored the phalloidin signal to control level. Our results suggest ghrelin may have a stimulating effect on the generation or remodeling of dendritic spines, and the spine change persists in the presence of ghrelin. The serum ghrelin level is high when the stomach is empty, and the ghrelin level remains high until metabolic demands are fulfilled. Thus, ghrelin may be involved in food-related and appetite-related learning in the hippocampus.     

Activation of mGlu receptors induces LTD without affecting postsynaptic sensitivity of CA1 neurons in rat hippocampal slices

Two forms of long-term depression (LTD) of excitatory synaptic transmission have been identified in the mammalian CNS, which are induced by the synaptic activation of N -methyl- d -aspartate (NMDA) and metabotropic glutamate (mGlu) receptors, respectively. The mGlu receptor-dependent form of LTD can be activated by application of 3,5-dihydroxyphenylglycine (DHPG), a group I selective mGlu receptor agonist. DHPG-induced LTD is increasingly being used to investigate the mechanisms of mGlu receptor-dependent LTD. However, recent experiments have argued for both a pre- and postsynaptic locus of expression of DHPG-induced LTD. In the present study we report that DHPG-induced LTD is not associated with changes in the sensitivity of CA1 neurons to bath applied AMPA. Furthermore, in contrast to homosynaptic LTD, DHPG-induced LTD is also not associated with changes in sensitivity to focally uncaged l -glutamate. These data do not support the notion that DHPG-induced LTD requires a modification of AMPA receptors, such as their internalisation, but are compatible with a presynaptic mechanism of expression.     

Two types of kainate response in cultured rat hippocampal neurons.

1. Two different types of kainate response were recorded in cultured rat hippocampal neurons with the use of the whole-cell and outside-out configurations of the patch-clamp technique. 2. There was an outward rectification in the current-voltage (I-V) plot of the kainate-induced current (type I response) in relatively large neurons bearing a morphological resemblance to young pyramidal cells. In smaller neurons with elliptical somata and fine neurites, the kainate response was characterized by a remarkable inward rectification in the I-V plot of the kainate-induced current and a significant permeability to Ca2+ (type II response). 3. Both type I and type II responses were negligible below 2 microM and almost saturated at 500 microM kainate. The concentrations producing half-maximal responses and the Hill coefficients were 68 microM and 1.76 and 56 microM and 1.21 for type I and type II responses, respectively. Both responses were suppressed similarly by the non-N-methyl-D-aspartate (NMDA) receptor antagonist 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX). 4. The mean single-channel conductance (gamma) of the type II kainate response was estimated, from the relation between the whole-cell mean currents and current variances, to be 8.7 pS. The power spectrum for the current noise was fitted with the sum of two Lorentzians with cutoff frequencies (fc) of 61.1 +/- 1.4 and 327.8 +/- 10.5 Hz (n = 12).(ABSTRACT TRUNCATED AT 250 WORDS)     

A chloride channel in excised patches from cultured rat hippocampal neurons

A non-calcium-dependent chloride channel of conductance 62 pS, found in isolated inside-out patches of cultured fetal rat hippocampal neurons, is described. The channel does not require the presence of any neurotransmitter to be active and probably plays a part in maintaining the normal resting membrane potential.     

ATP reduces voltage-activated K+ current in cultured rat hippocampal neurons

Effects of extracellular ATP were investigated in cultured rat hippocampal neurons using whole-cell voltage-clamp techniques. When a depolarizing step to +10 mV was applied from a holding potential of -60 mV, an outward K⁺ current was activated. ATP (3 to 300 μM) reduced the K⁺ current. Among adenosine derivatives, ADP (100 μM) slightly inhibited the K⁺ current, and AMP or adenosine (100 μM) was ineffective. UTP was as potent as ATP and α,β-methylene ATP was less effective than ATP. The inhibition by ATP of the K⁺ current was abolished by inclusion of 2 mM GDPβS in the intracellular solution. The results indicate that ATP inhibits K⁺ channels in rat hippocampal neurons through UTP-responsive P₂-purinoceptors coupled with GTP-binding proteins.     

安氟醚对海马CA1区锥体神经元的自发性微小抑制性突触后电流的调控

为探讨吸入性麻醉剂安氟醚对海马CA1区锥体神经元的γ-氨基丁酸(GABA)能自发性微小抑制性突触后电流(mIP-SCs)的调控作用,本研究采用酶消化和机械分离的单细胞模型,应用制霉菌素穿孔膜片钳技术,记录安氟醚对海马CA1区锥体神经元的GABA能突触后电流的影响。结果显示:(1)安氟醚可使GABA的浓度-效应曲线平行左移,但不影响GABA引起的最大反应;(2)安氟醚能够可逆性地增大GABA能自发性mIPSCs的发放频率而不影响其幅度;(3)在无钙细胞外液条件下,仍能观察到安氟醚对GABA能自发性mIPSCs发放频率的增强作用;膜通透性胞内钙库Ca2+的螯合剂BAPTA-AM可抑制安氟醚的增强作用。以上结果提示在海马CA1区安氟醚可能通过释放胞内钙库内的Ca2+使神经终末内Ca2+浓度升高而增加GABA的释放,从而达到中枢抑制作用。     

Properties of depolarization-induced suppression of inhibitory transmission in cultured rat hippocampal neurons

 Properties of depolarization-induced suppression of inhibitory transmission (”DSI”) in cultured rat hippocampal neurons were examined, by recording inhibitory postsynaptic currents (IPSCs) evoked by single presynaptic neurons. In about 40% of the inhibitory synapses, transient suppression of IPSCs was induced by applying a depolarizing pulse (to 0 mV, > 2 s) to the postsynaptic neuron, which was identified to be γ-aminobutyric acid dependent (GABAergic) in some pairs, and to be glutamatergic in some other pairs. This depolarization-induced suppression of IPSCs, ”DSI”, was Ca²⁺ dependent, and was associated with an increase in the paired-pulse ratio. Phorbol esters had an occluding effect on DSI when applied to the bath solution, but not to the pipette solution used for the postsynaptic neuron. Application of the opioid receptor antagonist naloxone had no effect on DSI. The present study demonstrates that a pair of cultured hippocampal neurons can exhibit DSI similar to that previously reported to occur in hippocampal slices; this suggests that a dissociated cell culture system can provide a useful model system for the study of DSI. Furthermore, it was found that inhibitory neurons, in addition to excitatory ones, can induce DSI, and that a process sensitive to phorbol esters, but not activation of opioid receptors, is involved in DSI. Received: 20 May 1997 / Accepted: 1 September 1997     

丹酚酸B对培养的新生大鼠海马神经元的影响

目的:本研究旨在观察丹酚酸B对体外培养新生大鼠海马神经元的影响,为丹酚酸B对中枢神经系统的作用提供实验依据。方法:体外培养新生大鼠海马神经元,神经元微管相关蛋白-2(MAP-2)免疫荧光染色对培养细胞进行鉴定,实验分为对照组和给药组(终浓度分别为5 mg/L和10 mg/L),荧光显微镜下观察细胞形态,MTT比色法检测丹酚酸B对海马神经细胞的活性,细胞核染色(DAPI)观察丹酚酸B对海马神经细胞增殖的影响。结果:免疫荧光染色显示细胞呈MAP-2阳性,丹酚酸B作用7 d后,能明显促进海马神经细胞的存活与增殖,且10 mg/L的丹酚酸B作用更明显。结论:丹酚酸B能明显促进海马神经细胞的存活与增殖,提示其具有改善脑功能的重要作用。