Deficits in cognitive function and hippocampal plasticity in GM2/GD2 synthase knockout mice

In this study, we used GM2/GD2 synthase knockout (GM2/GD2^?/?) mice to examine the influence of deficiency in ganglioside “a‐pathway” and “b‐pathway” on cognitive performances and hippocampal synaptic plasticity. Eight‐week‐old GM2/GD2^?/? male mice showed a longer escape‐latency in Morris water maze test and a shorter latency in step‐down inhibitory avoidance task than wild‐type (WT) mice. Schaffer collateral‐CA1 synapses in the hippocampal slices from GM2/GD2^?/? mice showed an increase in the slope of EPSPs with reduced paired‐pulse facilitation, indicating an enhancement of their presynaptic glutamate release. In GM2/GD2^?/? mice, NMDA receptor (NMDAr)‐dependent LTP could not be induced by high‐frequency (100–200 Hz) tetanus or θ‐burst conditioning stimulation (CS), whereas NMDAr‐independent LTP was induced by medium‐frequency CS (20–50 Hz). The application of mono‐sialoganglioside GM1 in the slice from GM2/GD2^?/? mice, to specifically recover the a‐pathway, prevented the increased presynaptic glutamate release and 20 Hz‐LTP induction, whereas it could not rescue the impaired NMDAr‐dependent LTP. These findings suggest that b‐pathway deficiency impairs cognitive function probably through suppression of NMDAr‐dependent LTP, while a‐pathway deficiency may facilitate NMDAr‐independent LTP through enhancing presynaptic glutamate release. As both of the NMDAr‐independent LTP and increased presynaptic glutamate release were sensitive to the blockade of L‐type voltage‐gated Ca²⁺ channels (L‐VGCC), a‐pathway deficiency may affect presynaptic L‐VGCC. © 2013 Wiley Periodicals, Inc.     

Diabetes mellitus concomitantly facilitates the induction of long-term depression and inhibits that of long-term potentiation in hippocampus

Memory impairments, which occur regularly across species as a result of ageing, disease (such as diabetes mellitus) and psychological insults, constitute a useful area for investigating the neurobiological basis of learning and memory. Previous studies in rats found that induction of diabetes (with streptozotocin, STZ) impairs long‐term potentiation (LTP) but enhances long‐term depression (LTD) induced by high‐ (HFS) and low‐frequency stimulations (LFS), respectively. Using a pairing protocol under whole‐cell recording conditions to induce synaptic plasticity at Schaffer collateral synapses in hippocampal CA1 slices, we show that LTD and LTP have similar magnitudes in diabetic and age‐matched control rats. But, in diabetic animals, LTD is induced at more polarized and LTP more depolarized membrane potentials (V_ms) compared with controls: diabetes produces a 10 mV leftward shift in the threshold for LTD induction and 10 mV rightward shift in the LTD–LTP crossover point of the voltage–response curve for synaptic plasticity. Prior repeated short‐term potentiations or LTP are known to similarly, though reversibly, lower the threshold for LTD induction and raise that for LTP induction. Thus, diabetes‐ and activity‐dependent modulation of synaptic plasticity (referred to as metaplasticity) display similar phenomenologies. In addition, compared with naïve synapses, prior induction of LTP produces a 10 mV leftward shift in V_ms for inducing subsequent LTD in control but not in diabetic rats. This could indicate that diabetes acts on synaptic plasticity through mechanisms involved in metaplasticity. Persistent facilitation of LTD and inhibition of LTP may contribute to learning and memory impairments associated with diabetes mellitus.     

A putative lysophosphatidylinositol receptor GPR55 modulates hippocampal synaptic plasticity

GPR55, an orphan G‐protein coupled receptor, is activated by lysophosphatidylinositol (LPI) and the endocannabinoid anandamide, as well as by other compounds including THC. LPI is a potent endogenous ligand of GPR55 and neither GPR55 nor LPIs' functions in the brain are well understood. While endocannabinoids are well known to modulate brain synaptic plasticity, the potential role LPI could have on brain plasticity has never been demonstrated. Therefore, we examined not only GPR55 expression, but also the role its endogenous ligand could play in long‐term potentiation, a common form of synaptic plasticity. Using quantitative RT‐PCR, electrophysiology, and behavioral assays, we examined hippocampal GPR55 expression and function. qRT‐PCR results indicate that GPR55 is expressed in hippocampi of both rats and mice. Immunohistochemistry and single cell PCR demonstrates GPR55 protein in pyramidal cells of CA1 and CA3 layers in the hippocampus. Application of the GPR55 endogenous agonist LPI to hippocampal slices of GPR55^+/+ mice significantly enhanced CA1 LTP. This effect was absent in GPR55^?/? mice, and blocked by the GPR55 antagonist CID 16020046. We also examined paired‐pulse ratios of GPR55^?/? and GPR55^+/+ mice with or without LPI and noted significant enhancement in paired‐pulse ratios by LPI in GPR55^+/+ mice. Behaviorally, GPR55^?/? and GPR55^+/+ mice did not differ in memory tasks including novel object recognition, radial arm maze, or Morris water maze. However, performance on radial arm maze and elevated plus maze task suggests GPR55^?/? mice have a higher frequency of immobile behavior. This is the first demonstration of LPI involvement in hippocampal synaptic plasticity.     

Group I metabotropic glutamate receptors regulate the frequency-response function of hippocampal CA1 synapses for the induction of LTP and LTD

Synaptically released glutamate binds to ionotropic or metabotropic glutamate receptors. Metabotropic glutamate receptors (mGluRs) are G‐protein‐coupled receptors and can be divided into three subclasses (Group I–III) depending on their pharmacology and coupling to signal transduction cascades. Group I mGluRs are coupled to phospholipase C and are implicated in several important physiological processes, including activity‐dependent synaptic plasticity, but their exact role in synaptic plasticity remains unclear. Synaptic plasticity can manifest itself as an increase or decrease of synaptic efficacy, referred to as long‐term potentiation (LTP) and long‐term depression (LTD). The likelihood, degree and direction of the change in synaptic efficacy depends on the history of the synapse and is referred to as ‘metaplasticity’. We provide direct experimental evidence for an involvement of group I mGluRs in metaplasticity in CA1 hippocampal synapses. Bath application of a low concentration of the specific group I agonist 3,5‐dihydroxyphenylglycine (DHPG), which does not affect basal synaptic transmission, resulted in a leftward shift of the frequency–response function for the induction of LTD and LTP in naïve synapses. DHPG resulted in the induction of LTP at frequencies which induced LTD in control slices. These alterations in the induction of LTD and LTP resemble the metaplastic changes observed in previously depressed synapses. In addition, in the presence of DHPG additional potentiation could be induced after LTP had apparently been saturated. These findings provide strong evidence for an involvement of group I mGluRs in the regulation of metaplasticity in the CA1 field of the hippocampus.     

Aberrant NMDA‐dependent LTD after perinatal ethanol exposure in young adult rat hippocampus

Irreversible cognitive deficits induced by ethanol exposure during fetal life have been ascribed to a lower NMDA‐dependent synaptic long‐term potentiation (LTP) in the hippocampus. Whether NMDA‐dependent long‐term depression (LTD) may also play a critical role in those deficits remains unknown. Here, we show that in vitro LTD induced with paired‐pulse low frequency stimulation is enhanced in CA1 hippocampus field of young adult rats exposed to ethanol during brain development. Furthermore, single pulse low frequency stimulation, ineffective at this age (LFS600), induced LTD after ethanol exposure accompanied with a stronger response than controls during LFS600, thus revealing an aberrant form of activity‐dependent plasticity at this age. Blocking NMDA receptor or GluN2B containing NMDA receptor prevented both the stronger response during LFS600 and LTD whereas Zinc, an antagonist of GluN2A containing NMDA receptor, was ineffective on both responses. In addition, LFS600‐induced LTD was revealed in controls only with a reduced‐Mg²⁺ medium. In whole dissected hippocampus CA1 field, perinatal ethanol exposure increased GluN2B subunit expression in the synaptic compartment whereas GluN2A was unaltered. Using pharmacological tools, we suggest that LFS600 LTD was of synaptic origin. Altogether, we describe a new mechanism by which ethanol exposure during fetal life induces a long‐term alteration of synaptic plasticity involving NMDA receptors, leading to an aberrant LTD. We suggest this effect of ethanol may reflect a delayed maturation of the synapse and that aberrant LTD may also participates to long‐lasting cognitive deficits in fetal alcohol spectrum disorder. © 2015 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.     

The requirement of BDNF for hippocampal synaptic plasticity is experience‐dependent

Brain‐derived neurotrophic factor (BDNF) supports neuronal survival, growth, and differentiation and has been implicated in forms of hippocampus‐dependent learning. In vitro, a specific role in hippocampal synaptic plasticity has been described, although not all experience‐dependent forms of synaptic plasticity critically depend on BDNF. Synaptic plasticity is likely to enable long‐term synaptic information storage and memory, and the induction of persistent (>24 h) forms, such as long‐term potentiation (LTP) and long‐term depression (LTD) is tightly associated with learning specific aspects of a spatial representation. Whether BDNF is required for persistent (>24 h) forms of LTP and LTD, and how it contributes to synaptic plasticity in the freely behaving rodent has never been explored. We examined LTP, LTD, and related forms of learning in the CA1 region of freely dependent mice that have a partial knockdown of BDNF (BDNF^+/?). We show that whereas early‐LTD (<90min) requires BDNF, short‐term depression (<45 min) does not. Furthermore, BDNF is required for LTP that is induced by mild, but not strong short afferent stimulation protocols. Object‐place learning triggers LTD in the CA1 region of mice. We observed that object‐place memory was impaired and the object‐place exploration failed to induce LTD in BDNF^+/? mice. Furthermore, spatial reference memory, that is believed to be enabled by LTP, was also impaired. Taken together, these data indicate that BDNF is required for specific, but not all, forms of hippocampal‐dependent information storage and memory. Thus, very robust forms of synaptic plasticity may circumvent the need for BDNF, rather it may play a specific role in the optimization of weaker forms of plasticity. The finding that both learning‐facilitated LTD and spatial reference memory are both impaired in BDNF^+/? mice, suggests moreover, that it is critically required for the physiological encoding of hippocampus‐dependent memory. © 2015 The Authors Hippocampus Published by Wiley Periodicals, Inc.     

Interaction of DHPG‐LTD and synaptic‐LTD at senescent CA3‐CA1 hippocampal synapses

The susceptibility, but not the magnitude, of long‐term depression (LTD) induced by hippocampal CA3‐CA1 synaptic activity (synaptic‐LTD) increases with advanced age. In contrast, the magnitude of LTD induced by pharmacological activation of CA3‐CA1 group I metabotropic glutamate receptors (mGluRs) increases during aging. This study examined the signaling pathways involved in induction of LTD and the interaction between paired‐pulse low frequency stimulation‐induced synaptic‐LTD and group I mGluR selective agonist, (RS)‐3,5‐dihydroxyphenylglycine (DHPG, 100 µM)‐induced DHPG‐LTD in hippocampal slices obtained from aged (22–24 months) male Fischer 344 rats. Prior induction of synaptic‐LTD did not affect induction of DHPG‐LTD; however, prior induction of the DHPG‐LTD occluded synaptic‐LTD suggesting that expression of DHPG‐LTD may incorporate synaptic‐LTD mechanisms. Application of individual antagonist for the group I mGluR (AIDA), the N‐methyl‐d ‐aspartate receptor (NMDAR) (AP‐5), or L‐type voltage‐dependent Ca²⁺ channel (VDCC) (nifedipine) failed to block synaptic‐LTD and any two antagonists severely impaired synaptic‐LTD induction, indicating that activation of any two mechanisms is sufficient to induce synaptic‐LTD in aged animals. For DHPG‐LTD, AIDA blocked DHPG‐LTD and individually applied NMDAR or VDCC attenuated but did not block DHPG‐LTD, indicating that the magnitude of DHPG‐LTD depends on all three mechanisms. © 2014 Wiley Periodicals, Inc.     

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.     

BDNF contributes to the facilitation of hippocampal synaptic plasticity and learning enabled by environmental enrichment

Sensory, motor, and cognitive stimuli, resulting from interactions with the environment, play a key role in optimizing and modifying the neuronal circuitry required for normal brain function. An experimental animal model for this phenomenon comprises environmental enrichment (EE) in rodents. EE causes profound changes in neuronal and signaling levels of excitation and plasticity throughout the entire central nervous system and the hippocampus is particularly affected. The mechanisms underlying these changes are not yet fully understood. As brain‐derived neurotrophic factor (BDNF) supports hippocampal long‐term potentiation (LTP), we explored whether it participates in the facilitation of synaptic plasticity and hippocampus‐dependent learning that occurs following EE. In the absence of EE, LTP elicited by high‐frequency stimulation was equivalent in wildtype mice and heterozygous BDNF^+/? siblings. LTP elicited by theta‐burst stimulation in BDNF^+/? mice was less than in wildtypes. Long‐term depression (LTD) was also impaired. EE for three weeks, beginning after weaning, improved hippocampal LTP in both wildtype and transgenic animals, with LTP in transgenics achieving levels seen in wildtypes in the absence of EE. Object recognition memory was evident in wildtypes 24 h and 7 days after initial object exposure. EE improved memory performance in wildtypes 24 h but not 7 days after initial exposure. BDNF^+/? mice in the absence of EE showed impaired memory 7 days after initial object exposure that was restored by EE. Western blotting revealed increased levels of BDNF, but not proBDNF, among both EE cohorts. These data support that BDNF plays an intrinsic role in improvements of synaptic plasticity and cognition that occur in EE. © 2014 The Authors. Hippocampus Published by Wiley Periodicals, Inc.     

Possible relationship between the stress‐induced synaptic response and metaplasticity in the hippocampal CA1 field of freely moving rats

Hippocampal long‐term potentiation (LTP) is suppressed not only by stress paradigms but also by low frequency stimulation (LFS) prior to LTP‐inducing high frequency stimulation (HFS; tetanus), termed metaplasticity. These synaptic responses are dependent on N‐methyl‐D ‐aspartate receptors, leading to speculations about the possible relationship between metaplasticity and stress‐induced LTP impairment. However, the functional significance of metaplasticity has been unclear. The present study elucidated the electrophysiological and neurochemical profiles of metaplasticity in the hippocampal CA1 field, with a focus on the synaptic response induced by the emotional stress, contextual fear conditioning (CFC). The population spike amplitude in the CA1 field was decreased during exposure to CFC, and LTP induction was suppressed after CFC in conscious rats. The synaptic response induced by CFC was mimicked by LFS, i.e., LFS impaired the synaptic transmission and subsequent LTP. Plasma corticosterone levels were increased by both CFC and LFS. Extracellular levels of γ‐aminobutyric acid (GABA), but not glutamate, in the hippocampus increased during exposure to CFC or LFS. Furthermore, electrical stimulation of the medial prefrontal cortex (mPFC), which caused decreases in freezing behavior during exposure to CFC, counteracted the LTP impairment induced by LFS. These findings suggest that metaplasticity in the rat hippocampal CA1 field is related to the neural basis of stress experience‐dependent fear memory, and that hippocampal synaptic response associated stress‐related processes is under mPFC regulation. Synapse 63:549‐556, 2009. © 2009 Wiley‐Liss, Inc.     

Modulatory metaplasticity induced by pregnenolone sulfate in the rat hippocampus: A leftward shift in LTP/LTD‐frequency curve

We recently have found that an acute application of the neurosteroid pregnenolone sulfate (PREGS) at 50 μM to rat hippocampal slices induces a long‐lasting potentiation (LLP_PREGS) via a sustained ERK2/CREB activation at perforant‐path/granule‐cell synapses in the dentate gyrus. This study is a follow up to investigate whether the expression of LLP_PREGS influences subsequent frequency‐dependent synaptic plasticity. Conditioning electric stimuli (CS) at 0.1–200 Hz were given to the perforant‐path of rat hippocampal slices expressing LLP_PREGS to induce long‐term potentiation (LTP) and long‐term depression (LTD). The largest LTP was induced at about 20 Hz‐CS, which is normally a subthreshold frequency, and the largest LTD at 0.5 Hz‐CS, resulting in a leftward‐shift of the LTP/LTD‐frequency curve. Furthermore, the level of LTP at 100 Hz‐CS was significantly attenuated to give band‐pass filter characteristics of LTP induction with a center frequency of about 20 Hz. The LTP induced by 20 Hz‐CS (termed 20 Hz‐LTP) was found to be postsynaptic origin and dependent on L‐type voltage‐gated calcium channel (L‐VGCC) but not on N‐methyl‐D ‐aspartate receptor (NMDAr). Moreover, the induction of 20 Hz‐LTP required a sustained activation of ERK2 that had been triggered by PREGS. In conclusion, the transient elevation of PREGS is suggested to induce a modulatory metaplasticity through a sustained activation of ERK2 in an L‐VGCC dependent manner. © 2009 Wiley‐Liss, Inc.     

Forebrain NR2B overexpression enhancing fear acquisition and long‐term potentiation in the lateral amygdala

N‐methyl‐d ‐aspartic acid (NMDA) receptor‐dependent long‐term potentiation (LTP) at the thalamus–lateral amygdala (T‐LA) synapses is the basis for acquisition of auditory fear memory. However, the role of the NMDA receptor NR2B subunit in synaptic plasticity at T‐LA synapses remains speculative. In the present study, using transgenic mice with forebrain‐specific overexpression of the NR2B subunit, we have observed that forebrain NR2B overexpression results in enhanced LTP but does not alter long‐term depression (LTD) at the T‐LA synapses in transgenic mice. To elucidate the cellular mechanisms underlying enhanced LTP at T‐LA synapses in these transgenic mice, AMPA and NMDA receptor‐mediated postsynaptic currents have been measured. The data show a marked increasing in the amplitude and decay time of NMDA receptor‐mediated currents in these transgenic mice. Consistent with enhanced LTP at T‐LA synapses, NR2B‐transgenic mice exhibit better performance in the acquisition of auditory fear memory than wild‐type littermates. Our results demonstrate that up‐regulation of NR2B expression facilitates acquisition of auditory cued fear memory and enhances LTP at T‐LA synapses.     

Mice lacking the adenosine A1 receptor have normal spatial learning and plasticity in the CA1 region of the hippocampus, but they habituate more slowly

Using mice with a targeted disruption of the adenosine A1 receptor (A1R), we examined the role of A1Rs in hippocampal long-term potentiation (LTP), long-term depression (LTD), and memory formation. Recordings from the Shaffer collateral-CA1 pathway of hippocampal slices from adult mice showed no differences between theta burst and tetanic stimulation-induced LTP in adenosine A1 receptor knockout (A1R-/-), heterozygote (A1R+/-), and wildtype (A1R+/+) mice. However, paired pulse facilitation was impaired significantly in A1R-/- slices as compared to A1R+/+ slices. LTD in the CA1 region was unaffected by the genetic manipulation. The three genotypes showed similar memory acquisition patterns when assessed for spatial reference and working memory in the Morris water maze tasks at 9 months of age. However, 10 months later A1R-/- mice showed some deficits in the 6-arm radial tunnel maze test. The latter appeared, however, not due to memory deficits but to decreased habituation to the test environment. Taken together, we observe normal spatial learning and memory and hippocampal CA1 synaptic plasticity in adult adenosine A1R knockout mice, but find modifications in arousal-related processes, including habituation, in this knockout model.     

Asymmetries in long‐term and short‐term plasticity at thalamic and cortical inputs to the amygdala in vivo

Converging lines of evidence suggest that synaptic plasticity at auditory inputs to the lateral amygdala (LA) is critical for the formation and storage of auditory fear memories. Auditory information reaches the LA from both thalamic and cortical areas, raising the question of whether they make distinct contributions to fear memory storage. Here we address this by comparing the induction of long‐term potentation (LTP) at the two inputs in vivo in anesthetized rats. We first show, using field potential measurements, that different patterns and frequencies of high‐frequency stimulation (HFS) consistently elicit stronger LTP at cortical inputs than at thalamic inputs. Field potential responses elicited during HFS of thalamic inputs were also smaller than responses during HFS of cortical inputs, suggesting less effective postsynaptic depolarization. Pronounced differences in the short‐term plasticity profiles of the two inputs were also observed: whereas cortical inputs displayed paired‐pulse facilitation, thalamic inputs displayed paired‐pulse depression. These differences in short‐ and long‐term plasticity were not due to stronger inhibition at thalamic inputs: although removal of inhibition enhanced responses to HFS, it did not enhance thalamic LTP and left paired‐pulse depression unaffected. These results highlight the divergent nature of short‐ and long‐term plasticity at thalamic and cortical sensory inputs to the LA, pointing to their different roles in the fear learning system.     

Enhancement of intestinal inflammation in mice lacking interleukin 10 by deletion of the serotonin reuptake transporter

Abstract Background Enterochromaffin cells and enteric neurons synthesize and release serotonin (5‐HT). Reuptake, mediated by a plasmalemmal transporter (SERT) terminates the action of released 5‐HT. Serotonin secretion and serotonin reuptake transporter (SERT) expression have been reported to be decreased in TNBS‐induced experimental colitis and in patients with ulcerative colitis. The present study was designed to utilize the transgenic deletion of SERT as a gain‐of‐function model to test the hypothesis that 5‐HT is a pro‐inflammatory mediator in experimental colitis. Methods Colitis was compared in animals with IL10^+/+SERT^+/+ (wild‐type), IL10^?/?SERT^+/+, IL10^?/?SERT^+/?, and IL10^?/?/SERT^?/? (double knockout) genotypes. Macroscopic and histological damage scores were evaluated after a time period of up to 15 weeks. Key Results Serotonin reuptake transporter expression was significantly increased in the inflamed colons of IL‐10^?/? mice, which displayed intestinal damage and a minor decrement in general health. General health was significantly worse and intestinal inflammation was more severe in IL‐10^?/?SERT^+/?, and IL‐10^?/?SERT^?/? mice than in IL‐10^?/?SERT^+/+ or wild‐type animals. Regardless of the associated SERT genotype, the number of 5‐HT‐immunoreactive cells was decreased by ～55–65% in all mice lacking IL‐10. Conclusions & Inferences Our observations indicate that colitis associated with IL‐10 deficient mice is enhanced when the IL‐10 deficiency is combined with a SERT deficiency. The data support the concept that 5‐HT is a pro‐inflammatory mediator in the gut.     

Inactivation of ATRX in forebrain excitatory neurons affects hippocampal synaptic plasticity

α‐Thalassemia X‐linked intellectual disability (ATR‐X) syndrome is a neurodevelopmental disorder caused by mutations in the ATRX gene that encodes a SNF2‐type chromatin‐remodeling protein. The ATRX protein regulates chromatin structure and gene expression in the developing mouse brain and early inactivation leads to DNA replication stress, extensive cell death, and microcephaly. However, the outcome of Atrx loss of function postnatally in neurons is less well understood. We recently reported that conditional inactivation of Atrx in postnatal forebrain excitatory neurons (ATRX‐cKO) causes deficits in long‐term hippocampus‐dependent spatial memory. Thus, we hypothesized that ATRX‐cKO mice will display impaired hippocampal synaptic transmission and plasticity. In the present study, evoked field potentials and current source density analysis were recorded from a multichannel electrode in male, urethane‐anesthetized mice. Three major excitatory synapses, the Schaffer collaterals to basal dendrites and proximal apical dendrites, and the temporoammonic path to distal apical dendrites on hippocampal CA1 pyramidal cells were assessed by their baseline synaptic transmission, including paired‐pulse facilitation (PPF) at 50‐ms interpulse interval, and by their long‐term potentiation (LTP) induced by theta‐frequency burst stimulation. Baseline single‐pulse excitatory response at each synapse did not differ between ATRX‐cKO and control mice, but baseline PPF was reduced at the CA1 basal dendritic synapse in ATRX‐cKO mice. While basal dendritic LTP of the first‐pulse excitatory response was not affected in ATRX‐cKO mice, proximal and distal apical dendritic LTP were marginally and significantly reduced, respectively. These results suggest that ATRX is required in excitatory neurons of the forebrain to achieve normal hippocampal LTP and PPF at the CA1 apical and basal dendritic synapses, respectively. Such alterations in hippocampal synaptic transmission and plasticity could explain the long‐term spatial memory deficits in ATRX‐cKO mice and provide insight into the physiological mechanisms underlying intellectual disability in ATR‐X syndrome patients.     

Heterosynaptic long‐term depression mediated by ATP released from astrocytes

Heterosynaptic long‐term depression (hLTD) at untetanized synapses accompanying the induction of long‐term potentiation (LTP) spatially sharpens the activity‐induced synaptic potentiation; however, the underlying mechanism remains unclear. We found that hLTD in the hippocampal CA1 region is caused by stimulation‐induced ATP release from astrocytes that suppresses transmitter release from untetanized synaptic terminals via activation of P2Y receptors. Selective stimulation of astrocytes expressing channelrhodopsin‐2, a light‐gated cation channel permeable to Ca²⁺, resulted in LTD of synapses on neighboring neurons. This synaptic modification required Ca²⁺ elevation in astrocytes and activation of P2Y receptors, but not N‐methyl‐D ‐aspartate receptors. Furthermore, blocking P2Y receptors or buffering astrocyte intracellular Ca²⁺ at a low level prevented hLTD without affecting LTP induced by SC stimulation. Thus, astrocyte activation is both necessary and sufficient for mediating hLTD accompanying LTP induction, strongly supporting the notion that astrocytes actively participate in activity‐dependent synaptic plasticity of neural circuits. © 2012 Wiley Periodicals, Inc.     

A brief, but repeated, swimming protocol is sufficient to overcome amyloid beta-protein inhibition of hippocampal long-term potentiation

Alzheimer's disease starts as an almost imperceptible malady, first observed clinically as a mild memory problem. Accumulating genetic and biochemical data have suggested that amyloid β‐protein (Aβ) plays an important role in this memory loss, and Aβ has been shown to suppress long‐term potentiation (LTP), a cellular model for memory and learning. Here we show that a very brief (3 min) swimming, twice daily for 2 weeks, rescues LTP inhibition in the CA1 region of hippocampal slices caused by Aβ₄₂ or Aβ₄₀ carrying the Arctic mutation using a theta burst stimulation (TBS) protocol. Whereas the input–output curve was not affected, the paired‐pulse ratio was reduced in mice receiving our repeated swimming protocol, suggesting a possible involvement of presynaptic facilitation. Similar to swimming, Aβ's inhibition of LTP could be rescued with the adenylyl cyclase, forskolin. Interestingly, this swimming protocol produced conditions in which a weak‐TBS could invoke LTP not observed in naïve mice, which again was mimicked by forskolin. In contrast, the protein kinase A (PKA) inhibitor, H89, blocked both the forskolin and swimming potentiation of LTP; these data implicate cAMP/PKA signaling in the protective effect of swimming and mediating Aβ′ detrimental effects. Our data add a new simple behavior paradigm that shows the importance of an environmental factor in reversing the pathophysiological effects of Aβ, and suggest new therapeutic avenues.     

Cocaine‐ or stress‐induced metaplasticity of LTP in the dorsal and ventral hippocampus

Despite the well documented role of the hippocampus in various modes of drug reinstatement behavior, the persisting effects of in vivo cocaine exposure on hippocampal synaptic plasticity are not sufficiently understood. In this report we investigated the effects of cocaine conditioning on long‐term potentiation (LTP) in the CA1 region of hippocampus along its septotemporal axis. Male Sprague‐Dawley rats experienced a behavioral protocol, in which locomotor activity was monitored in response to various conditioning treatments. LTP was measured in ex vivo slice preparations taken 1–2 weeks after the last behavioral session from the ventral (vH) and dorsal (dH) sectors of hippocampus. Unexpectedly, experiencing the minor intermittent stimuli of the behavioral protocol caused stress‐induced metaplastic changes in both vH (increased LTP) and dH (decreased LTP) in the saline conditioned rats relative to behaviorally naïve controls. These stress effects in the vH and dH were blocked by conditioning with either mineralocorticoid (spironolactone) or glucocorticoid (mifepristone) antagonists, respectively. Stress‐induced metaplasticity in the vH was also prevented by prior administration of the kappa opioid antagonist nor‐binaltorphimine. Cocaine conditioning induced locomotor sensitization and significantly increased LTP in the vH without causing significant change in LTP in the dH. Cocaine‐induced metaplasticity in the vH was prevented by co‐administration of the dopamine D_2‐like antagonist eticlopride during cocaine conditioning, but not by co‐administration of the D_1/5 antagonist SCH 23390. Our results suggest that the functional connectivity of hippocampus is altered by metaplastic triggers such as exposure to drugs of abuse and/or stressors, thereby shifting the efferent output of hippocampus from dH (cortical) toward vH (limbic) influenced circuits. © 2014 Wiley Periodicals, Inc.