Astrocyte calcium signals at Schaffer collateral to CA1 pyramidal cell synapses correlate with the number of activated synapses but not with synaptic strength

Glial cells respond to neuronal activity by transient increases in their intracellular calcium concentration. At hippocampal Schaffer collateral to CA1 pyramidal cell synapses, such activity-induced astrocyte calcium transients modulate neuronal excitability, synaptic activity, and LTP induction threshold by calcium-dependent release of gliotransmitters. Despite a significant role of astrocyte calcium signaling in plasticity of these synapses, little is known about activity-dependent changes of astrocyte calcium signaling itself. In this study, we analyzed calcium transients in identified astrocytes and NG2-cells located in the stratum radiatum in response to different intensities and patterns of Schaffer collateral stimulation. To this end, we employed multiphoton calcium imaging with the low-affinity indicator dye Fluo-5F in glial cells, combined with extracellular field potential recordings to monitor postsynaptic responses to the afferent stimulation. Our results confirm that somata and processes of astrocytes, but not of NG2-cells, exhibit intrinsic calcium signaling independent of evoked neuronal activity. Moderate stimulation of Schaffer collaterals (three pulses at 50 Hz) induced calcium transients in astrocytes and NG2-cells. Astrocyte calcium transients upon this three-pulse stimulation could be evoked repetitively, increased in amplitude with increasing stimulation intensity and were dependent on activation of metabotropic glutamate receptors. Activity-induced transients in NG2-cells, in contrast, showed a rapid run-down upon repeated three-pulse stimulation. Theta burst stimulation and stimulation for 5 min at 1 Hz induced synaptic potentiation and depression, respectively, as revealed by a lasting increase or decrease in population spike amplitudes upon three-pulse stimulation. Synaptic plasticity was, however, not accompanied by corresponding alterations in the amplitude of astrocyte calcium signals. Taken together, our results suggest that the amplitude of astrocyte calcium signals reflects the number of activated synapses but does not correlate with the degree of synaptic potentiation or depression at Schaffer collateral to CA1 pyramidal cell synapses.     

Enhanced astroglial Ca2+ signaling increases excitatory synaptic strength in the epileptic brain

The fine‐tuning of synaptic transmission by astrocyte signaling is crucial to CNS physiology. However, how exactly astroglial excitability and gliotransmission are affected in several neuropathologies, including epilepsy, remains unclear. Here, using a chronic model of temporal lobe epilepsy (TLE) in rats, we found that astrocytes from astrogliotic hippocampal slices displayed an augmented incidence of TTX‐insensitive spontaneous slow Ca²⁺ transients (STs), suggesting a hyperexcitable pattern of astroglial activity. As a consequence, elevated glutamate‐mediated gliotransmission, observed as increased slow inward current (SICs) frequency, up‐regulates the probability of neurotransmitter release in CA3‐CA1 synapses. Selective blockade of spontaneous astroglial Ca²⁺ elevations as well as the inhibition of purinergic P2Y1 or mGluR5 receptors relieves the abnormal enhancement of synaptic strength. Moreover, mGluR5 blockade eliminates any synaptic effects induced by P2Y1R inhibition alone, suggesting that the Pr modulation via mGluR occurs downstream of P2Y1R‐mediated Ca²⁺‐dependent glutamate release from astrocyte. Our findings show that elevated Ca²⁺‐dependent glutamate gliotransmission from hyperexcitable astrocytes up‐regulates excitatory neurotransmission in epileptic hippocampus, suggesting that gliotransmission should be considered as a novel functional key in a broad spectrum of neuropathological conditions. GLIA 2015;63:1507–1521     

Nicotine facilitates long‐term potentiation induction in oriens‐lacunosum moleculare cells via Ca2+ entry through non‐α7 nicotinic acetylcholine receptors

Hippocampal inhibitory interneurons have a central role in the control of network activity, and excitatory synapses that they receive express Hebbian and anti‐Hebbian long‐term potentiation (LTP). Because many interneurons in the hippocampus express nicotinic acetylcholine receptors (nAChRs), we explored whether exposure to nicotine promotes LTP induction in these interneurons. We focussed on a subset of interneurons in the stratum oriens/alveus that were continuously activated in the presence of nicotine due to the expression of non‐desensitizing non‐α7 nAChRs. We found that, in addition to α2 subunit mRNAs, these interneurons were consistently positive for somatostatin and neuropeptide Y mRNAs, and showed morphological characteristics of oriens‐lacunosum moleculare cells. Activation of non‐α7 nAChRs increased intracellular Ca²⁺ levels at least in part via Ca²⁺ entry through their channels. Presynaptic tetanic stimulation induced N‐methyl‐d ‐aspartate receptor‐independent LTP in voltage‐clamped interneurons at −70 mV when in the presence, but not absence, of nicotine. Intracellular application of a Ca²⁺ chelator blocked LTP induction, suggesting the requirement of Ca²⁺ signal for LTP induction. The induction of LTP was still observed in the presence of ryanodine, which inhibits Ca²⁺ ‐induced Ca²⁺ release from ryanodine‐sensitive intracellular stores, and the L‐type Ca²⁺ channel blocker nifedipine. These results suggest that Ca²⁺ entry through non‐α7 nAChR channels is critical for LTP induction. Thus, nicotine affects hippocampal network activity by promoting LTP induction in oriens‐lacunosum moleculare cells via continuous activation of non‐α7 nAChRs.     

Calcium Channel-Dependent Induction of Long-Term Synaptic Plasticity at Excitatory Golgi Cell Synapses of Cerebellum

Golgi cells, together with granule cells and mossy fibers, form a neuronal microcircuit regulating information transfer at the cerebellum input stage. Despite theoretical predictions, little was known about long-term synaptic plasticity at Golgi cell synapses. Here, we have used whole-cell patch-clamp recordings and calcium imaging to investigate long-term synaptic plasticity at excitatory synapses impinging on Golgi cells. In acute mouse cerebellar slices, mossy fiber theta-burst stimulation (TBS) could induce either long-term potentiation (LTP) or long-term depression (LTD) at mossy fiber-Golgi cell and granule cell-Golgi cell synapses. This synaptic plasticity showed a peculiar voltage dependence, with LTD or LTP being favored when TBS induction occurred at depolarized or hyperpolarized potentials, respectively. LTP required, in addition to NMDA channels, activation of T-type Ca²⁺ channels, while LTD required uniquely activation of L-type Ca²⁺ channels. Notably, the voltage dependence of plasticity at the mossy fiber-Golgi cell synapses was inverted with respect to pure NMDA receptor-dependent plasticity at the neighboring mossy fiber-granule cell synapse, implying that the mossy fiber presynaptic terminal can activate different induction mechanisms depending on the target cell. In aggregate, this result shows that Golgi cells show cell-specific forms of long-term plasticity at their excitatory synapses, that could play a crucial role in sculpting the response patterns of the cerebellar granular layer.SIGNIFICANCE STATEMENT This article shows for the first time a novel form of Ca²⁺ channel-dependent synaptic plasticity at the excitatory synapses impinging on cerebellar Golgi cells. This plasticity is bidirectional and inverted with respect to NMDA receptor-dependent paradigms, with long-term depression (LTD) and long-term potentiation (LTP) being favored at depolarized and hyperpolarized potentials, respectively. Furthermore, LTP and LTD induction requires differential involvement of T-type and L-type voltage-gated Ca²⁺ channels rather than the NMDA receptors alone. These results, along with recent computational predictions, support the idea that Golgi cell plasticity could play a crucial role in controlling information flow through the granular layer along with cerebellar learning and memory.     

Transient appearance of Ca2+‐permeable AMPA receptors is crucial for the production of repetitive LTP‐induced synaptic enhancement (RISE) in cultured hippocampal slices

We have previously shown that repetitive induction of long‐term potentiation (LTP) by glutamate (100 μM, 3 min, three times at 24‐hr intervals) provoked long‐lasting synaptic enhancement accompanied by synaptogenesis in rat hippocampal slice cultures, a phenomenon termed RISE (repetitive LTP‐induced synaptic enhancement). Here, we examined the role of Ca²⁺‐permeable (CP) AMPA receptors (AMPARs) in the establishment of RISE. We first found a component sensitive to the Joro‐spider toxin (JSTX), a blocker of CP‐AMPARs, in a field EPSP recorded from CA3‐CA1 synapses at 2–3 days after stimulation, but this component was not found for 9–10 days. We also observed that rectification of AMPAR‐mediated current appeared only 2–3 days after stimulation, using a whole‐cell patch clamp recording from CA1 pyramidal neurons. These findings indicate that CP‐AMPAR is transiently expressed in the developing phase of RISE. The blockade of CP‐AMPARs by JSTX for 24 hr at this developing phase inhibited RISE establishment, accompanied by the loss of small synapses at the ultrastructural level. These results suggest that transiently induced CP‐AMPARs play a critical role in synaptogenesis in the developing phase of long‐lasting hippocampal synaptic plasticity, RISE.     

Plasticity of synaptic glun receptors is required for the Src‐dependent induction of long‐term potentiation at CA3‐CA1 synapses

The induction of long‐term potentiation (LTP) of CA3‐CA1 synapses requires activation of postsynaptic N‐methyl‐D ‐aspartate receptors (GluNRs). At resting potential, the contribution of GluNRs is limited by their voltage‐dependent block by extracellular Mg²⁺. High‐frequency afferent stimulation is required to cause sufficient summation of excitatory synaptic potentials (EPSPs) to relieve this block and to permit an influx of Ca²⁺. It has been assumed that this relief of Mg²⁺ block is sufficient for induction. We postulated that the induction of LTP also requires a Src‐dependent plasticity of GluNRs. Using whole‐cell recordings, LTP (GluARs) of α‐amino‐3‐hydroxy‐5‐methyl‐4‐isoxazolepropionic acid receptors‐EPSCS was induced by pairing postsynaptic depolarization with presynaptic stimulation. This LTP was both GluNR and Src‐dependent, being sensitive to AP‐5, a GluNR selective antagonist, or to SU6656, a Src‐selective inhibitor. When CNQX was used to block all GluARs, we observed a long‐lasting potentiation of GluNR‐mediated EPSCs. This plasticity was prevented by transiently blocking GluNRs during the induction protocol or by chelating intracellular Ca²⁺. GluNRs plasticity was also prevented by bath applications of SU6656 or intracellular applications of the Src‐selective inhibitory peptide, Src(40–58). It was also blocked by preventing activation of protein kinase C, a kinase that is upstream of Src‐kinase‐dependent regulation of GluNRs. Both GluN2A and GluN2B receptors were found to contribute to the plasticity of GluNRs. The contribution of GluNRs and, in particular, their plasticity to the maintenance of LTP was explored using AP5 and SU6656, respectively. When applied >20 min after induction neither drug influenced the magnitude of LTP. However, when applied immediately after induction, treatment with either drug caused the initial magnitude of LTP to progressively decrease to a sustained phase of reduced amplitude. Collectively, our findings suggest that GluNR plasticity, although not strictly required for induction, is necessary for the maintenance of a nondecrementing component of LTP. © 2010 Wiley‐Liss, Inc.     

Glutamate released spontaneously from astrocytes sets the threshold for synaptic plasticity

Astrocytes exhibit spontaneous calcium oscillations that could induce the release of glutamate as gliotransmitter in rat hippocampal slices. However, it is unknown whether this spontaneous release of astrocytic glutamate may contribute to determining the basal neurotransmitter release probability in central synapses. Using whole‐cell recordings and Ca²⁺ imaging, we investigated the effects of the spontaneous astrocytic activity on neurotransmission and synaptic plasticity at CA3–CA1 hippocampal synapses. We show here that the metabolic gliotoxin fluorocitrate (FC) reduces the amplitude of evoked excitatory postsynaptic currents and increases the paired‐pulse facilitation, mainly due to the reduction of the neurotransmitter release probability and the synaptic potency. FC also decreased intracellular Ca²⁺ signalling and Ca²⁺‐dependent glutamate release from astrocytes. The addition of glutamine rescued the effects of FC over the synaptic potency; however, the probability of neurotransmitter release remained diminished. The blockage of group I metabotropic glutamate receptors mimicked the effects of FC on the frequency of miniature synaptic responses. In the presence of FC, the Ca²⁺ chelator 1,2‐bis(2‐aminophenoxy)ethane‐N,N,N ′,N ′‐tetra‐acetate or group I metabotropic glutamate receptor antagonists, the excitatory postsynaptic current potentiation induced by the spike‐timing‐dependent plasticity protocol was blocked, and it was rescued by delivering a stronger spike‐timing‐dependent plasticity protocol. Taken together, these results suggest that spontaneous glutamate release from astrocytes contributes to setting the basal probability of neurotransmitter release via metabotropic glutamate receptor activation, which could be operating as a gain control mechanism that regulates the threshold of long‐term potentiation. Therefore, endogenous astrocyte activity provides a novel non‐neuronal mechanism that could be critical for transferring information in the central nervous system.     

Long‐term depression of inhibitory synaptic transmission induced by spike‐timing dependent plasticity requires coactivation of endocannabinoid and muscarinic receptors

The precise timing of pre‐postsynaptic activity is vital for the induction of long‐term potentiation (LTP) or depression (LTD) at many central synapses. We show in synapses of rat CA1 pyramidal neurons in vitro that spike timing dependent plasticity (STDP) protocols that induce LTP at glutamatergic synapses can evoke LTD of inhibitory postsynaptic currents or STDP‐iLTD. The STDP‐iLTD requires a postsynaptic Ca²⁺ increase, a release of endocannabinoids (eCBs), the activation of type‐1 endocananabinoid receptors and presynaptic muscarinic receptors that mediate a decreased probability of GABA release. In contrast, the STDP‐iLTD is independent of the activation of nicotinic receptors, GABA_BRs and G protein‐coupled postsynaptic receptors at pyramidal neurons. We determine that the downregulation of presynaptic Cyclic adenosine monophosphate/protein Kinase A pathways is essential for the induction of STDP‐iLTD. These results suggest a novel mechanism by which the activation of cholinergic neurons and retrograde signaling by eCBs can modulate the efficacy of GABAergic synaptic transmission in ways that may contribute to information processing and storage in the hippocampus. © 2013 Wiley Periodicals, Inc.     

Zinc enhances long-term potentiation through P2X receptor modulation in the hippocampal CA1 region

Zn²⁺ is an essential ion that is stored in and co‐released from glutamatergic synapses and it modulates neurotransmitter receptors involved in long‐term potentiation (LTP). However, the mechanism(s) underlying Zn²⁺‐induced modulation of LTP remain(s) unclear. As the purinergic P2X receptors are relevant targets for Zn²⁺ action, we have studied their role in LTP modulation by Zn²⁺ in the CA1 region of rat hippocampal slices. Induction of LTP in the presence of Zn²⁺ revealed a biphasic effect – 5–50 μm enhanced LTP induction, whereas 100–300 μm Zn²⁺ inhibited LTP. The involvement of a purinergic mechanism is supported by the fact that application of the P2X receptor antagonists 2′,3′‐O‐(2,4,6‐trinitrophenyl) ATP (TNP‐ATP) and periodate‐oxidized ATP fully abolished the facilitatory effect of Zn²⁺. Notably, application of the P2X₇ receptor‐specific antagonist Brilliant Blue G did not modify the Zn²⁺‐dependent facilitation of LTP. Exogenous ATP also produced a biphasic effect – 0.1–1 μm ATP facilitated LTP, whereas 5–10 μm inhibited LTP. The facilitatory effect of ATP was abolished by the application of TNP‐ATP and was modified in the presence of 5 μm Zn²⁺, suggesting that P2X receptors are involved in LTP induction and that Zn²⁺ leads to an increase in the affinity of P2X receptors for ATP. The latter confirms our previous results from heterologous expression systems. Collectively, our results indicate that Zn²⁺ at low concentrations enhances LTP by modulating P2X receptors. Although it is not yet clear which purinergic receptor subtype(s) is responsible for these effects on LTP, the data presented here suggest that P2X₄ but not P2X₇ is involved.     

Relation Between Dendritic Ca2+ Levels and the Polarity of Synaptic Long-term Modifications in Rat Visual Cortex Neurons

Long-term changes of synaptic efficacy, in particular when they are use-dependent, are candidate mechanisms for the storage of information in the nervous system. In a variety of brain structures, including the neocortex and hippocampus, synapses are susceptible to long-term potentiation (LTP) and long-term depression (LTD). It has been hypothesized that the polarity of the synaptic gain change depends on the amplitude of the postsynaptic [Ca²⁺]_i rise, the threshold for the induction of LTD being lower than that for the induction of LTP. To test this assumption, we characterized Ca²⁺ signals in layer II/III pyramidal cells of rat visual cortex slices, using the fluorescent Ca²⁺ indicator fura-2, during application of stimulation protocols that had been adjusted to reliably induce either LTP or LTD in cells not loaded with fura-2. At dendritic sites activated by the stimulated afferents the intracellular [Ca²⁺] concentration ([Ca²⁺]_i) reached higher amplitudes and decayed more slowly with stimuli inducing LTP than with those inducing LTD. To directly analyse the functional significance of the observed difference in the Ca²⁺ signal amplitude, we examined whether a tetanization protocol suitable for the induction of LTP can be converted into a protocol inducing LTD by injecting the postsynaptic cells with Ca²⁺ chelators that reduce the concentration of effective free Ca²⁺. In the presence of fura-2 or BAPTA [bis(2-aminophenoxy) ethane-N,N,N′,N′-tetraacetate], the stimulation protocol that would normally produce LTP induced either LTD or failed to induce synaptic modifications altogether. These results support the hypothesis that the amplitude of the postsynaptic rise in [Ca²⁺]_i is a key factor in the determination of the polarity of synaptic gain change.     

Involvement of PKA and ERK pathways in ghrelin‐induced long‐lasting potentiation of excitatory synaptic transmission in the CA1 area of rat hippocampus

Acute effects of ghrelin on excitatory synaptic transmission were evaluated on hippocampal CA1 synapses. Ghrelin triggered an enduring enhancement of synaptic transmission independently of NMDA receptor activation and probably via postsynaptic modifications. This ghrelin‐mediated potentiation resulted from the activation of GHS‐R1a receptors as it was mimicked by the selective agonist JMV1843 and blocked by the selective antagonist JMV2959. This potentiation also required the activation of PKA and ERK pathways to occur as it was inhibited by KT5720 and U0126, respectively. Moreover it most probably involved Ca²⁺ influxes as both ghrelin and JMV1843 elicited intracellular Ca²⁺ increases, which were dependent on the presence of extracellular Ca²⁺ and mediated by L‐type Ca²⁺ channels opening. In addition, ghrelin potentiated AMPA receptor‐mediated [Ca²⁺]i increases while decreasing NMDA receptor‐mediated ones. Thus the potentiation of synaptic transmission by GHS‐R1a at hippocampal CA1 excitatory synapses probably results from postsynaptic mechanisms involving PKA and ERK activation, which are producing long‐lasting enhancement of AMPA receptor‐mediated responses.     

A silent eligibility trace enables dopamine‐dependent synaptic plasticity for reinforcement learning in the mouse striatum

Dopamine‐dependent synaptic plasticity is a candidate mechanism for reinforcement learning. A silent eligibility trace – initiated by synaptic activity and transformed into synaptic strengthening by later action of dopamine – has been hypothesized to explain the retroactive effect of dopamine in reinforcing past behaviour. We tested this hypothesis by measuring time‐dependent modulation of synaptic plasticity by dopamine in adult mouse striatum, using whole‐cell recordings. Presynaptic activity followed by postsynaptic action potentials (pre–post) caused spike‐timing‐dependent long‐term depression in D1‐expressing neurons, but not in D2 neurons, and not if postsynaptic activity followed presynaptic activity. Subsequent experiments focused on D1 neurons. Applying a dopamine D1 receptor agonist during induction of pre–post plasticity caused long‐term potentiation. This long‐term potentiation was hidden by long‐term depression occurring concurrently and was unmasked when long‐term depression blocked an L‐type calcium channel antagonist. Long‐term potentiation was blocked by a Ca²⁺‐permeable AMPA receptor antagonist but not by an NMDA antagonist or an L‐type calcium channel antagonist. Pre–post stimulation caused transient elevation of rectification – a marker for expression of Ca²⁺‐permeable AMPA receptors – for 2–4‐s after stimulation. To test for an eligibility trace, dopamine was uncaged at specific time points before and after pre‐ and postsynaptic conjunction of activity. Dopamine caused potentiation selectively at synapses that were active 2‐s before dopamine release, but not at earlier or later times. Our results provide direct evidence for a silent eligibility trace in the synapses of striatal neurons. This dopamine‐timing‐dependent plasticity may play a central role in reinforcement learning.     

The anticoagulant activated protein C (aPC) promotes metaplasticity in the hippocampus through an EPCR‐PAR1‐S1P1 receptors dependent mechanism

Thrombin and other clotting factors regulate long‐term potentiation (LTP) in the hippocampus through the activation of the protease activated receptor 1 (PAR1) and consequent potentiation of N‐methyl‐d ‐aspartate receptor (NMDAR) functions. We have recently shown that the activation of PAR1 either by thrombin or the anticoagulant factor activated protein C (aPC) has differential effects on LTP. While thrombin activation of PAR1 induces an NMDAR‐mediated slow onset LTP, which saturates the ability to induce further LTP in the exposed network, aPC stimulation of PAR1 enhances tetanus induced LTP through a voltage‐gated calcium channels mediated mechanism. In this study, we addressed the mechanisms by which aPC enhances LTP in hippocampal slices. Using extracellular recordings, we show that a short tetanic stimulation, which does not induce LTP, is able to enhance plasticity in the presence of aPC through a mechanism that requires the activation of sphingosine‐1 phosphate receptor 1 and intracellular Ca²⁺ stores. These data identify aPC as a “metaplastic molecule”, capable of shifting the threshold of LTP towards further potentiation. Our findings propose novel strategies to enhance plasticity in neurological diseases associated with the breakdown of the blood brain barrier and alterations in synaptic plasticity. © 2014 Wiley Periodicals, Inc.     

Involvement of intracellular Zn2+ signaling in LTP at perforant pathway–CA1 pyramidal cell synapse

Physiological significance of synaptic Zn²⁺ signaling was examined at perforant pathway–CA1 pyramidal cell synapses. In vivo long‐term potentiation (LTP) at perforant pathway–CA1 pyramidal cell synapses was induced using a recording electrode attached to a microdialysis probe and the recording region was locally perfused with artificial cerebrospinal fluid (ACSF) via the microdialysis probe. Perforant pathway LTP was not attenuated under perfusion with CaEDTA (10 mM), an extracellular Zn²⁺ chelator, but attenuated under perfusion with ZnAF‐2DA (50 μM), an intracellular Zn²⁺ chelator, suggesting that intracellular Zn²⁺ signaling is required for perforant pathway LTP. Even in rat brain slices bathed in CaEDTA in ACSF, intracellular Zn²⁺ level, which was measured with intracellular ZnAF‐2, was increased in the stratum lacunosum‐moleculare where perforant pathway–CA1 pyramidal cell synapses were contained after tetanic stimulation. These results suggest that intracellular Zn²⁺ signaling, which originates in internal stores/proteins, is involved in LTP at perforant pathway–CA1 pyramidal cell synapses. Because the influx of extracellular Zn²⁺, which originates in presynaptic Zn²⁺ release, is involved in LTP at Schaffer collateral‐CA1 pyramidal cell synapses, synapse‐dependent Zn²⁺ dynamics may be involved in plasticity of postsynaptic CA1 pyramidal cells.     

Astrocytic IP3Rs: Contribution to Ca2+ signalling and hippocampal LTP

Astrocytes regulate hippocampal synaptic plasticity by the Ca²⁺ dependent release of the N‐methyl d ‐aspartate receptor (NMDAR) co‐agonist d ‐serine. Previous evidence indicated that d ‐serine release would be regulated by the intracellular Ca²⁺ release channel IP₃ receptor (IP₃R), however, genetic deletion of IP₃R2, the putative astrocytic IP₃R subtype, had no impact on synaptic plasticity or transmission. Although IP₃R2 is widely believed to be the only functional IP₃R in astrocytes, three IP₃R subtypes (1, 2, and 3) have been identified in vertebrates. Therefore, to better understand gliotransmission, we investigated the functionality of IP₃R and the contribution of the three IP₃R subtypes to Ca²⁺ signalling. As a proxy for gliotransmission, we found that long‐term potentiation (LTP) was impaired by dialyzing astrocytes with the broad IP₃R blocker heparin, and rescued by exogenous d ‐serine, indicating that astrocytic IP₃Rs regulate d ‐serine release. To explore which IP₃R subtypes are functional in astrocytes, we used pharmacology and two‐photon Ca²⁺ imaging of hippocampal slices from transgenic mice (IP₃R2^?/? and IP₃R2^?/?;3^?/?). This approach revealed that underneath IP₃R2‐mediated global Ca²⁺ events are an overlooked class of IP₃R‐mediated local events, occurring in astroglial processes. Notably, multiple IP₃Rs were recruited by high frequency stimulation of the Schaffer collaterals, a classical LTP induction protocol. Together, these findings show the dependence of LTP and gliotransmission on Ca²⁺ release by astrocytic IP₃Rs. GLIA 2017;65:502–513     

Impairment of CaMKII activation and attenuation of neuropathic pain in mice lacking NR2B phosphorylated at Tyr1472

Ca²⁺/calmodulin‐dependent protein kinase II (CaMKII) is a key mediator of long‐term potentiation (LTP), which can be triggered by N‐methyl‐d ‐aspartate (NMDA) receptor‐mediated Ca²⁺ influx. We previously demonstrated that Fyn kinase‐mediated phosphorylation of NR2B subunits of NMDA receptors at Tyr1472 in the dorsal horn was involved in a neuropathic pain state even 1 week after nerve injury. Here we show that Y1472F‐KI mice with a knock‐in mutation of the Tyr1472 site to phenylalanine did not exhibit neuropathic pain induced by L5 spinal nerve transection, whereas they did retain normal nociceptive responses and induction of inflammatory pain. Phosphorylation of NR2B at Tyr1472 was only impaired in the spinal cord of Y1472F‐KI mice among the major phosphorylation sites. There was no difference in the Ca²⁺ response to glutamate and sensitivity to NMDA receptor antagonists between naive wild‐type and Y1472F‐KI mice, and the Ca²⁺ response to glutamate was attenuated in the Y1472F‐KI mice after nerve injury. Autophosphorylation of CaMKII at Thr286 was markedly impaired in Y1472F‐KI mice after nerve injury, but there was no difference in phosphorylation of CaMKII at Thr305 or protein kinase Cγ at Thr674, and activation of neuronal nitric oxide synthase and microglia in the superficial layer of spinal cord between wild‐type and Y1472F‐KI mice after the operation. These results demonstrate that the attenuation of neuropathic pain is caused by the impaired NMDA receptor‐mediated CaMKII signaling in Y1472F‐KI mice, and suggest that autophosphorylation of CaMKII at Thr286 plays a central part not only in LTP, but also in persistent neuropathic pain.     

The 5‐hydroxytryptamine4 receptor enables differentiation of informational content and encoding in the hippocampus

Long‐term synaptic plasticity, represented by long‐term depression (LTD) and long‐term potentiation (LTP) comprise cellular processes that enable memory. Neuromodulators such as serotonin regulate hippocampal function, and the 5‐HT₄‐receptor contributes to processes underlying cognition. It was previously shown that in the CA1‐region, 5‐HT₄‐receptors regulate the frequency‐response relationship of synaptic plasticity: patterned afferent stimulation that has no effect on synaptic strength (i.e., a θm‐frequency), will result in LTP or LTD, when given in the presence of a 5‐HT₄‐agonist, or antagonist, respectively. Here, we show that in the dentate gyrus (DG) and CA3 regions of freely behaving rats, pharmacological manipulations of 5‐HT₄‐receptors do not influence responses generated at θm‐frequencies, but activation of 5‐HT₄‐receptors prevents persistent LTD in mossy fiber (mf)‐CA3, or perforant path‐DG synapses. Furthermore, the regulation by 5‐HT₄‐receptors of LTP is subfield‐specific: 5‐HT₄‐receptor‐activation prevents mf‐CA3‐LTP, but does not strongly affect DG‐potentiation. These data suggest that 5‐HT₄‐receptor activation prioritises information encoding by means of LTP in the DG and CA1 regions, and suppresses persistent information storage in mf‐CA3 synapses. Thus, 5‐HT₄‐receptors serve to shape information storage across the hippocampal circuitry and specify the nature of experience‐dependent encoding. © 2016 The Authors Hippocampus Published by Wiley Periodicals, Inc.     

Intrinsic cellular and molecular properties of in vivo hippocampal synaptic plasticity are altered in the absence of key synaptic matrix molecules

Hippocampal synaptic plasticity comprises a key cellular mechanism for information storage. In the hippocampus, both long‐term potentiation (LTP) and long‐term depression (LTD) are triggered by synaptic Ca²⁺‐elevations that are typically mediated by the opening of voltage‐gated cation channels, such as N‐methyl‐d ‐aspartate receptors (NMDAR), in the postsynaptic density. The integrity of the post‐synaptic density is ensured by the extracellular matrix (ECM). Here, we explored whether synaptic plasticity is affected in adult behaving mice that lack the ECM proteins brevican, neurocan, tenascin‐C, and tenascin‐R (KO). We observed that the profiles of synaptic potentiation and depression in the dentate gyrus (DG) were profoundly altered compared to plasticity profiles in wild‐type littermates (WT). Specifically, synaptic depression was amplified in a frequency‐dependent manner and although late‐LTP (>24 hr) was expressed following strong afferent tetanization, the early component of LTP (<75 min post‐tetanization) was absent. LTP (>4 hr) elicited by weaker tetanization was equivalent in WT and KO animals. Furthermore, this latter form of LTP was NMDAR‐dependent in WT but not KO mice. Scrutiny of DG receptor expression revealed significantly lower levels of both the GluN2A and GluN2B subunits of the N‐methyl‐d ‐aspartate receptor, of the metabotropic glutamate receptor, mGlu5 and of the L‐type calcium channel, Ca_v1.3 in KO compared to WT animals. Homer 1a and of the P/Q‐type calcium channel, Ca_v1.2 were unchanged in KO mice. Taken together, findings suggest that in mice that lack multiple ECM proteins, synaptic plasticity is intact, but is fundamentally different.     

Activation of ryanodine receptors is required for PKA‐mediated downregulation of A‐type K+ channels in rat hippocampal neurons

A‐type K⁺ channels (I_A channels) contribute to learning and memory mechanisms by regulating neuronal excitabilities in the CNS, and their expression level is targeted by Ca²⁺ influx via synaptic NMDA receptors (NMDARs) during long‐term potentiation (LTP). However, it is not clear how local synaptic Ca²⁺ changes induce I_A downregulation throughout the neuron, extending from the active synapse to the soma. In this study, we tested if two major receptors of endoplasmic reticulum (ER), ryanodine (RyRs), and IP₃ (IP₃R) receptors, are involved in Ca²⁺‐mediated I_A downregulation in cultured hippocampal neurons of rats. The downregulation of I_A channels was induced by doubling the Ca²⁺ concentration in culture media (3.6 mM for 24 hrs) or treating with glycine (200 μM for 3 min) to induce chemical LTP (cLTP), and the changes in I_A peaks were measured electrophysiologically by a whole‐cell patch. We confirmed that Ca²⁺ or glycine treatment significantly reduced I_A peaks and that their effects were abolished by blocking NMDARs or voltage‐dependent Ca²⁺ channels (VDCCs). In this cellular processing, blocking RyRs (by ryanodine, 10 μM) but not IP₃Rs (by 2APB, 100 μM) completely abolished I_A downregulation, and the LTP observed in hippocampal slices was more diminished by ryanodine rather than 2APB. Furthermore, blocking RyRs also reduced Ca²⁺‐mediated PKA activation, indicating that sequential signaling cascades, including the ER and PKA, are involved in regulating I_A downregulation. These results strongly suggest a possibility that RyR contribution and mediated I_A downregulation are required to regulate membrane excitability as well as synaptic plasticity in CA3‐CA1 connections of the hippocampus. © 2017 Wiley Periodicals, Inc.     

Dendritic mechanisms controlling the threshold and timing requirement of synaptic plasticity

Active conductances located and operating on neuronal dendrites are expected to regulate synaptic integration and plasticity. We investigate how Kv4.2‐mediated A‐type K⁺ channels and Ca²⁺‐activated K⁺ channels are involved in the induction process of Hebbian‐type plasticity that requires correlated pre‐ and postsynaptic activities. In CA1 pyramidal neurons, robust long‐term potentiation (LTP) induced by a theta burst pairing protocol usually occurred within a narrow window during which incoming synaptic potentials coincided with postsynaptic depolarization. Elimination of dendritic A‐type K⁺ currents in Kv4.2^?/? mice, however, resulted in an expanded time window, making the induction of synaptic potentiation less dependent on the temporal relation of pre‐ and postsynaptic activity. For the other type of synaptic plasticity, long‐term depression, the threshold was significantly increased in Kv4.2^?/? mice. This shift in depression threshold was restored to normal when the appropriate amount of internal free calcium was chelated during induction. In concert with A‐type channels, Ca²⁺‐activated K⁺ channels also exerted a sliding effect on synaptic plasticity. Blocking these channels in Kv4.2^?/? mice resulted in an even larger potentiation while by contrast, the depression threshold was shifted further. In conclusion, dendritic A‐type and Ca²⁺‐activated K⁺ channels dually regulate the timing‐dependence and thresholds of synaptic plasticity in an additive way. © 2010 Wiley‐Liss, Inc.