Danger and distress: Parabrachial-extended amygdala circuits.

Our understanding of the role of the parabrachial nucleus (PBN) has evolved as technology has advanced, in part due to cell-specific studies and complex behavioral assays. This is reflected in the heterogeneous neuronal populations within the PBN to the extended amygdala (EA) circuits which encompass the bed nucleus of the stria terminalis (BNST) and central amygdala (CeA) circuitry, as they differentially modulate aspects of behavior in response to diverse threat-like contexts necessary for survival. Here we review how the PBN→CeA and PBN→BNST pathways differentially modulate fear-like behavior, innate and conditioned, through unique changes in neurotransmission in response to stress-inducing contexts. Furthermore, we hypothesize how in specific instances the PBN→CeA and PBN→BNST circuits are redundant and in part intertwined with their respective reciprocal projections. By deconstructing the interoceptive and exteroceptive components of affect- and stress related behavioral paradigms, evidence suggests that the PBN→CeA circuit modulates innate response to physical stimuli and fear conditioning. Conversely, the PBN→BNST circuit modulates distress-like stress in unpredictable contexts. Thereby, the PBN provides a pathway for alarming interoceptive and exteroceptive stimuli to be processed and relayed to the EA to induce stress-relevant affect. Additionally, we provide a framework for future studies to detail the cell-type specific intricacies of PBN→EA circuits in mediating behavioral responses to threats, and the relevance of the PBN in drug-use as it relates to threat and negative reinforcement. This article is part of the special Issue on 'Neurocircuitry Modulating Drug and Alcohol Abuse'.

Cocaine Augments Dopamine Mediated Inhibition of Neuronal Activity in the Dorsal Bed Nucleus of the Stria Terminalis.

The dorsal region of the bed nucleus of the stria terminalis (dBNST) receives substantial dopaminergic input which overlaps with norepinephrine input implicated in stress responses. Using ex vivo fast scan cyclic voltammetry in male C57BL6 mouse brain slices, we demonstrate that electrically stimulated dBNST catecholamine signals are of substantially lower magnitude and have slower uptake rates compared to caudate signals. Dopamine terminal autoreceptor activation inhibited roughly half of the catecholamine transient, and noradrenergic autoreceptor activation produced an ∼30% inhibition. Dopamine transporter blockade with either cocaine or GBR12909 significantly augmented catecholamine signal duration. We optogenetically targeted dopamine terminals in the dBNST of transgenic (TH:Cre) mice of either sex and, using ex vivo whole-cell electrophysiology, we demonstrate that optically stimulated dopamine release induces slow outward membrane currents and an associated hyperpolarization response in a subset of dBNST neurons. These cellular responses had a similar temporal profile to dopamine release, were significantly reduced by the D2/D3 receptor antagonist raclopride, and were potentiated by cocaine. Using in vivo fiber photometry in male C57BL6 mice during training sessions for cocaine conditioned place preference, we show that acute cocaine administration results in a significant inhibition of calcium transient activity in dBNST neurons compared to saline administration. These data provide evidence for a mechanism of dopamine-mediated cellular inhibition in the dBNST and demonstrate that cocaine augments this inhibition while also decreasing net activity in the dBNST in a drug reinforcement paradigm.SIGNIFICANCE STATEMENTThe dorsal bed nucleus of the stria terminalis (dBNST) is a region highly implicated in mediating stress responses, however, the dBNST also receives dopaminergic inputs from classically defined drug reward pathways. Here we used various techniques to demonstrate that dopamine signaling within the dorsal BNST region has inhibitory effects on population activity. We show that cocaine, an abused psychostimulant, augments both catecholamine release and dopamine-mediated cellular inhibition in this region. We also demonstrate that cocaine administration reduces population activity in the dBNST, in vivo Together these data support a mechanism of dopamine-mediated inhibition within the dBNST, providing a means by which drug-induced elevations in dopamine signaling may inhibit dBNST activity to promote drug reward.

BNST transient activity associates with approach behavior in a stressful environment and is modulated by the parabrachial nucleus.

Studies demonstrate a role for the bed nucleus of the stria terminalis (BNST) in modulating affective behavior and stress-reward integration. To explore the dynamic nature of in vivo BNST activity associated with anxiety-like behavior in a stress-inducing context, we utilized fiber photometry and detected BNST calcium transients in mice during the novelty-suppressed feeding task (NSFT). Phasic BNST activity emerged time-locked to novel object or food pellet approach during NSFT. The parabrachial nucleus (PBN) has a large input to the BNST and is thought to function as a danger signal, in arousal responses and in feeding behavior. To explore a potential role for the PBN as a contributor to BNST activity in NSFT, we investigated whether chemogenetic regulation of PBN activity altered the dynamic BNST response synchronized to NSFT approach behavior. We found that activation of the hM3D(Gq) DREADD in the PBN enhanced the observed transient signal in the BNST synchronized to the consummatory food approach, and was associated at the behavioral level with increased latency to consume food. Because the PBN has multiple efferent pathways, we next used a transsynaptic anterograde AAV-based strategy to express hM3D(Gq) specifically in PBN-innervated BNST (BNSTPBN) neurons in male and female mice. Activation of hM3D(Gq) in these BNSTPBN neurons increased latency to consume food in female, but not male mice. To further explore the population of BNST neurons contributing to phasic BNST activity associated with NSFT, we turned to PKCδ neurons in BNST. BNST(PKCδ) neurons are implicated in stress and food-related behavior, and we previously found that the expression of this kinase is regulated in the BNST by stress in a sex-dependent manner. Here, we demonstrate close apposition of CGRP, a marker of PBN terminals, adjacent to BNST(PKCδ) cells. Finally, we find that PKCδ-expressing BNST cells exhibit a large transient signal synchronized to the consummatory food approach similar to that seen with bulk BNST activity measures. Taken together these data demonstrate phasic BNST activity at a global and cell-specific level that is driven in part by PBN activity at the time of NSFT consummatory approach behavior.

Preclinical voluntary drinking models for alcohol abstinence-induced affective disturbances in mice.

Negative reinforcement is widely thought to play an important role in chronic alcohol-use disorders (AUDs), and high comorbidity between AUDs and affective disorders highlights the importance of investigating this relationship. Prominent models posit that repeated cycles of alcohol (ethanol, EtOH) exposure and withdrawal produce circuit adaptations in the central nervous system that drive a transition from positive- to negative reinforcement-based alcohol seeking. Evidence supporting this theory has accumulated in large part using forced EtOH administration models, such as chronic intragastric gavage and chronic vapor inhalation. However, recent studies utilizing simple voluntary EtOH delivery systems show that forced abstinence from EtOH intake administered by the animal itself can produce evolving and significant affective disturbances, particularly in female C57BL/6J mice. Here, we highlight these recent studies to support the idea that voluntary EtOH administration in mouse models, as well as a protracted abstinence period and less commonly used behavioral tasks, could unveil affective disturbances during abstinence that have remained elusive using high dosage forced EtOH administration paradigms.

Knockdown of BNST GluN2B-containing NMDA receptors mimics the actions of ketamine on novelty-induced hypophagia.

Administration of a single low dose of the N-methyl-D-aspartate (NMDA) receptor antagonist ketamine has been demonstrated to elicit long-lasting antidepressant effects in humans with depression, as well as in rodent models of depression. Although pharmacological studies have implicated the GluN2B subunit of the NMDA receptor in these effects, drugs targeting this subunit have off-target actions, and systemic administration of these compounds does not allow for delineation of specific brain regions involved. In this study, we assessed the role of GluN2B in the bed nucleus of the stria terminalis (BNST) in novelty-induced hypophagia (NIH) in mice. First, we verified that ketamine, as well as the GluN2B antagonist Ro25-6981, decreased the latency to consume food in a novel environment in a version of the NIH test. We then hypothesized that GluN2B-containing receptors within the BNST may be a target of systemic ketamine and contribute to behavioral effects. Through the combination of a GluN2B-floxed mouse line and stereotaxic delivery of lentiviral Cre recombinase, we found that targeted knockdown of this subunit within the BNST mimicked the reduction in affective behavior observed with systemic ketamine or Ro25-6981 in the NIH test. These data suggest a role for GluN2B-containing NMDARs within the BNST in the affective effects of systemic ketamine.

Developmental changes in the acute ethanol sensitivity of glutamatergic and GABAergic transmission in the BNST.

Glutamatergic and GABAergic transmission undergo significant changes during adolescence. Receptors for both of these transmitters (NMDAR, and GABAA) are known to be key targets for the acute effects of ethanol in adults. The current study set out to investigate the acute effects of ethanol on both NMDAR-mediated excitatory transmission and GABAergic inhibitory transmission within the bed nucleus of the stria terminalis (BNST) across age. The BNST is an area of the brain implicated in the negative reinforcing properties associated with alcohol dependence, and the BNST plays a critical role in stress-induced relapse. Therefore, assessing the developmental regulation of ethanol sensitivity in this key brain region is important to understanding the progression of ethanol dependence. To do this, whole-cell recordings of isolated NMDAR-evoked excitatory postsynaptic currents (eEPSCs) or evoked GABAergic inhibitory postsynaptic currents (eIPSCs) were performed on BNST neurons in slices from 4- or 8-week-old male C57BL/6J mice. Ethanol (50 mm) produced greater inhibition of NMDAR-eEPSCs in adolescent mice than in adult mice. This enhanced sensitivity in adolescence was not a result of shifts in function of the GluN2B subunit of the NMDAR, measured by Ro25-6981 inhibition and decay kinetics measured across age. Adolescent mice also exhibited greater ethanol sensitivity of GABAergic transmission, as ethanol (50 mm) enhanced eIPSCs in the BNST of adolescent but not adult mice. Collectively, this work illustrates that a moderate dose of ethanol produces greater inhibition of transmission in the BNST (through greater excitatory inhibition and enhancement of inhibitory transmission) in adolescents compared to adults. Given the role of the BNST in alcohol dependence, these developmental changes in acute ethanol sensitivity could accelerate neuroadaptations that result from chronic ethanol use during the critical period of adolescence.

Absence of Ca2+-stimulated adenylyl cyclases leads to reduced synaptic plasticity and impaired experience-dependent fear memory.

Ca(2+)-stimulated adenylyl cyclase (AC) 1 and 8 are two genes that have been shown to play critical roles in fear memory. AC1 and AC8 couple neuronal activity and intracellular Ca(2+) increases to the production of cyclic adenosine monophosphate and are localized synaptically, suggesting that Ca(2+)-stimulated ACs may modulate synaptic plasticity. Here, we first established that Ca(2+)-stimulated ACs modulate protein markers of synaptic activity at baseline and after learning. Primary hippocampal cell cultures showed that AC1/AC8 double-knockout (DKO) mice have reduced SV2, a synaptic vesicle protein, abundance along their dendritic processes, and this reduction can be rescued through lentivirus delivery of AC8 to the DKO cells. Additionally, phospho-synapsin, a protein implicated in the regulation of neurotransmitter release at the synapse, is decreased in vivo 1 h after conditioned fear (CF) training in DKO mice. Importantly, additional experiments showed that long-term potentiation deficits present in DKO mice are rescued by acutely replacing AC8 in the forebrain, further supporting the idea that Ca(2+)-stimulated AC activity is a crucial modulator of synaptic plasticity. Previous studies have demonstrated that memory is continually modulated by gene-environment interactions. The last set of experiments evaluated the effects of knocking out AC1 and AC8 genes on experience-dependent changes in CF memory. We showed that the strength of CF memory in wild-type mice is determined by previous environment, minimal or enriched, whereas memory in DKO mice is unaffected. Thus, overall these results show that AC1 and AC8 modulate markers of synaptic activity and help integrate environmental information to modulate fear memory.

alpha2A-adrenergic receptors heterosynaptically regulate glutamatergic transmission in the bed nucleus of the stria terminalis.

Stress is a major driving force in reinstatement of drug-seeking behavior. The bed nucleus of the stria terminalis (BNST) has been identified as a key brain region in this behavior, and receives a dense input of the stress-neurotransmitter norepinephrine through the ventral noradrenergic bundle. Activation of alpha(2)-adrenergic receptors (alpha(2)-ARs) in the BNST blocks stress-induced reinstatement of drug-seeking, indicating a potentially important role for these receptors. Currently, it is unclear how alpha(2)-AR agonists elicit this behavioral action, or through which alpha(2)-AR subtype. Activation of alpha(2)-ARs decreases glutamatergic transmission in the BNST, an effect which is nearly absent in the alpha(2A)-AR knockout mouse. Here, we take advantage of a knock-in mouse in which a hemagglutinin-tagged alpha(2A)-AR was inserted into the endogenous locus, along with the alpha(2A)-AR selective agonist guanfacine, to further study the role of the alpha(2A)-AR subtype in modulation of neurotransmission in the BNST. Using immunohistochemistry, we find that alpha(2A)-ARs are highly expressed in the BNST, and that this expression is more similar in distribution to the vesicular glutamate transporters than to either norepinephrine transporter or tyrosine hydroxylase positive terminals. Using whole cell patch-clamp recordings, we show that guanfacine causes a depression of evoked excitatory and, to a more limited extent, inhibitory fast synaptic transmission. In total, these data support a prominent heterosynaptic role for alpha(2A)-ARs in modulating fast synaptic transmission in the BNST.

Plasticity and behavior: new genetic techniques to address multiple forms and functions.

As the best-studied form of vertebrate synaptic plasticity, NMDA-receptor dependent long-term potentiation (NMDAR-LTP) has long been considered a leading candidate for a cellular locus for some aspects of learning and memory. However, assigning a specific role for this form of plasticity in learning and memory has proven surprisingly difficult. Two issues have contributed to this difficulty. First, a large number of molecules have been shown to in some way mediate or modulate not only NMDAR-LTP but also many forms of plasticity. Indeed, it is increasingly clear that multiple induction and maintenance mechanisms for plasticity exist, often at the same synapse. Second, linking cellular events to behavioral function has been hindered by a lack of sufficiently precise tools. In this review, we will discuss some of the proposed mechanisms of induction and maintenance of changes in synaptic efficacy and their regulation in the context of an attempt to understand their roles in animal behavior. Further, we will discuss recently developed genetic techniques, specifically, inducible transgenic models, which now allow more precise manipulations in the study of the roles plasticity plays in learning and memory.

Inducible and reversible enhancement of learning, memory, and long-term potentiation by genetic inhibition of calcineurin.

The threshold for hippocampal-dependent synaptic plasticity and memory storage is thought to be determined by the balance between protein phosphorylation and dephosphorylation mediated by the kinase PKA and the phosphatase calcineurin. To establish whether endogenous calcineurin acts as an inhibitory constraint in this balance, we examined the effect of genetically inhibiting calcineurin on plasticity and memory. Using the doxycycline-dependent rtTA system to express a calcineurin inhibitor reversibly in the mouse brain, we find that the transient reduction of calcineurin activity facilitates LTP in vitro and in vivo. This facilitation is PKA dependent and persists over several days in vivo. It is accompanied by enhanced learning and strengthened short- and long-term memory in several hippocampal-dependent spatial and nonspatial tasks. The LTP and memory improvements are reversed fully by suppression of transgene expression. These results demonstrate that endogenous calcineurin constrains LTP and memory.

ERK plays a regulatory role in induction of LTP by theta frequency stimulation and its modulation by beta-adrenergic receptors.

MAP kinase (ERK) translates cell surface signals into alterations in transcription. We have found that ERK also regulates hippocampal neuronal excitability during 5 Hz stimulation and thereby regulates forms of long-term potentiation (LTP) that do not require macromolecular synthesis. Moreover, ERK-mediated changes in excitability are selectively required for some forms of LTP but not others. ERK is required for the early phase of LTP elicited by brief 5 Hz stimulation, as well as for LTP elicited by more prolonged 5 Hz stimulation when paired with beta1-adrenergic receptor activation. By contrast, ERK plays no role in LTP elicited by a single 1 s 100 Hz train. Consistent with these results, we find that ERK is activated by beta-adrenergic receptors in CA1 pyramidal cell somas and dendrites.

Rolipram, a type IV-specific phosphodiesterase inhibitor, facilitates the establishment of long-lasting long-term potentiation and improves memory.

In an attempt to improve behavioral memory, we devised a strategy to amplify the signal-to-noise ratio of the cAMP pathway, which plays a central role in hippocampal synaptic plasticity and behavioral memory. Multiple high-frequency trains of electrical stimulation induce long-lasting long-term potentiation, a form of synaptic strengthening in hippocampus that is greater in both magnitude and persistence than the short-lasting long-term potentiation generated by a single tetanic train. Studies using pharmacological inhibitors and genetic manipulations have shown that this difference in response depends on the activity of cAMP-dependent protein kinase A. Genetic studies have also indicated that protein kinase A and one of its target transcription factors, cAMP response element binding protein, are important in memory in vivo. These findings suggested that amplification of signals through the cAMP pathway might lower the threshold for generating long-lasting long-term potentiation and increase behavioral memory. We therefore examined the biochemical, physiological, and behavioral effects in mice of partial inhibition of a hippocampal cAMP phosphodiesterase. Concentrations of a type IV-specific phosphodiesterase inhibitor, rolipram, which had no significant effect on basal cAMP concentration, increased the cAMP response of hippocampal slices to stimulation with forskolin and induced persistent long-term potentiation in CA1 after a single tetanic train. In both young and aged mice, rolipram treatment before training increased long- but not short-term retention in freezing to context, a hippocampus-dependent memory task.

Inducible and reversible gene expression with the rtTA system for the study of memory.

To obtain rapidly inducible and reversible expression of transgenes in the forebrain of the mouse, we have combined the reverse tetracycline-controlled transactivator (rtTA) system with the CaMKIIalpha promoter. We show that doxycycline induces maximal gene expression in neurons of the forebrain within 6 days and that this expression can be reversed by removal of doxycycline. Using calcineurin as a test transgene, we show that doxycycline-induced expression impairs both an intermediate form of LTP (I-LTP) in the hippocampus and the storage of spatial memory. The reversibility of the rtTA system in turn allowed us to examine the effects of the transgene on memory retrieval after normal storage had occurred. This examination suggests that retrieval requires some of the same molecular components required for storage.

Genetic and pharmacological evidence for a novel, intermediate phase of long-term potentiation suppressed by calcineurin.

To investigate the role of phosphatases in synaptic plasticity using genetic approaches, we generated transgenic mice that overexpress a truncated form of calcineurin under the control of the CaMKIIalpha promoter. Mice expressing this transgene show increased calcium-dependent phosphatase activity in the hippocampus. Physiological studies of these mice and parallel pharmacological experiments in wild-type mice reveal a novel, intermediate phase of LTP (I-LTP) in the CA1 region of the hippocampus. This intermediate phase differs from E-LTP by requiring multiple trains for induction and in being dependent on PKA. It differs from L-LTP in not requiring new protein synthesis. These data suggest that calcineurin acts as an inhibitory constraint on I-LTP that is relieved by PKA. This inhibitory constraint acts as a gate to regulate the synaptic induction of L-LTP.

Differential involvement of group II and group III mGluRs as autoreceptors at lateral and medial perforant path synapses.

1. Previous reports have shown that group III metabotropic glutamate receptors (mGluRs) serve as autoreceptors at the lateral perforant path, but to date there has been no rigorous determination of the roles of other mGluRs as autoreceptors at this synapse. Furthermore, it is not known which of the mGluR subtypes serve as autoreceptors at the medial perforant path synapse. With the use of whole cell patch-clamp and field excitatory postsynaptic potential (fEPSP) recording techniques, we examined the groups of mGluRs that act as autoreceptors at lateral and medial perforant path synapses in adult rat hippocampal slices. 2. Consistent with previous reports, the group III mGluR agonist (D,L)-2-amino-4-phosphonobutyric acid reduced fEPSPs and excitatory postsynaptic currents (EPSCs) in the dentate gyrus. However, the group-II-selective agonist (2S,1'R,2'R,3'R)-2-(2,3-dicarboxycyclopropyl)glycine (DCG-IV) also reduced fEPSPs and EPSCs, suggesting that multiple mGluR subtypes may serve as autoreceptors at perforant path synapses. 3. Selective activation of either medial or lateral perforant pathways revealed that micromolar concentrations of (L)-2-amino-4-phosphonobutyric acid (L-AP4) reduce fEPSPs in lateral but not medial perforant path, suggesting group III involvement at the lateral perforant pathway. Conversely, DCG-IV and 2R, 4R-4-aminopyrrolidine-2,4-dicarboxylate, another group-II-selective mGluR agonist, potently reduced fEPSPs at the medial but not lateral perforant path, suggesting that a group II mGluR may act as an autoreceptor at the medial perforant path-dentate gyrus synapse. 4. Antagonist studies with group-selective antagonists such as (2S,3S,4S)-2-methyl-2-(carboxycyclpropyl)glycine (MCCG; group II) and alpha-methyl-L-AP4 (MAP4; group III) suggest differential involvement of each group at these synapses. The effect of L-AP4 at the lateral perforant path synapse was blocked by MAP-4, but not MCCG. In contrast, the effect of DCG-IV was blocked by application of MCCG, but not MAP4. 5. Previous studies suggest that the effect of L-AP4 at the lateral perforant path synapse is mediated by a presynaptic mechanism. In the present studies, we found that concentrations of DCG-IV that reduce transmission at the medial perforant path synapse reduce paired-pulse depression and do not reduce kainate-evoked currents recorded from dentate granule cells. This is consistent with the hypothesis that DCG-IV also acts by a presynaptic mechanism.

Roles of metabotropic glutamate receptors in glial function and glial-neuronal communication.

The amino acid glutamate plays a key role in brain function. One of the major roles of glutamate is to mediate fast excitatory neurotransmission via activation of ionotropic glutamate receptors (iGluRs). More recently, however, it has become clear that glutamate also serves a regulatory function through activation of receptors coupled to modulation of second messenger systems [metabotropic glutamate receptors (mGluRs)]. A body of evidence suggests that mGluRs regulate neuronal function through modulation of ion channels and enzymes to modulate cellular excitability and synaptic transmission. Interestingly, it has become clear that in addition to activation of neuronal receptors, glutamate can activate both iGluRs and mGluRs on glia. A growing body of evidence suggests that the mGluRs on glia play important roles in both glial function and mediation of intercellular signaling.

Novel glial-neuronal signalling by coactivation of metabotropic glutamate and beta-adrenergic receptors in rat hippocampus.

1. We have previously reported that activation of group II-like metabotropic glutamate receptors (mGluRs) in rat hippocampus results in a potentiation of the accumulation of cAMP elicited by activation of G-protein Gs-coupled receptors. This large increase in cAMP levels results in release of cAMP or a cAMP metabolite and depression of synaptic transmission at the Schaffer collateral-CA1 pyramidal cell synapse through activation of A1 adenosine receptors. 2. Consistent with these studies, we report that antagonists of group II mGluRs block both the potentiation of cAMP accumulation elicited by activation of mGluRs and the depression of synaptic transmission induced by coactivation of mGluRs and beta-adrenergic receptors. 3. In situ hybridization studies suggest that of the cloned group II mGluRs only mGluR-3 mRNA is present in area CA1. Interestingly, mGluR-3 appears to be present predominantly in glia in this region. Thus, we tested the hypothesis that mGluRs coupled to potentiation of cAMP accumulation were present on glia rather than neurons in area CA1. 4. The selective group II mGluR agonist 2S,1'R,2'R,3'R-2(2,3-dicarboxycyclo-propyl)glycine (DCG-IV) failed to enhance cAMP-mediated electrophysiological responses to the beta-adrenergic receptor agonist isoprenaline (Iso) in CA1 pyramidal cells, suggesting that mGluRs coupled to potentiation of cAMP accumulation may not be present in these cells. 5. Pre-incubation of hippocampal slices with either of the selective glial toxins L-alpha-aminoadipic acid (L-AA) or fluorocitrate (FC) blocked mGluR-mediated potentiation of cAMP accumulation. However, L-AA and FC had no discernible effects on viability of CA1 pyramidal cells, or cAMP-mediated electrophysiological effects in these neurons. 6. Pre-incubation of hippocampal slices with the neurotoxin kainate resulted in disruption of neuronal transmission and degeneration of neurons in area CA1, but had no effect on mGluR-mediated potentiation of cAMP accumulation. 7. Pre-incubation of hippocampal slices with the cAMP/cAMP metabolite transport blocker probenicid blocked the depression of synaptic transmission elicited by coapplication of Iso and DCG-IV, while having no significant effect on cAMP accumulation elicited by these agonists. 8. Taken together, these data suggest that mGluRs coupled to potentiation of cAMP accumulation are present on glia rather than neurons in area CA1 of hippocampus. This suggests that a novel form of glial-neuronal communication may exist, since activation of these mGluRs in concert with beta-adrenergic receptors results in depression of synaptic transmission.

Metabotropic glutamate receptor (mGluR)-mediated potentiation of cyclic AMP responses does not require phosphoinositide hydrolysis: mediation by a group II-like mGluR.

Metabotropic glutamate receptors (mGluRs) in the CNS are coupled to a variety of second messenger systems, the best characterized of which is activation of phosphoinositide hydrolysis. Recently, we found that activation of mGluRs in rat brain slices by the selective mGluR agonist 1-aminocyclopentane-1S,3R-dicarboxylic acid (1S,3R-ACPD) potentiates cyclic AMP (cAMP) responses elicited by activation of other receptors coupled to Gs. It has been suggested that mGluR-mediated potentiation of cAMP responses is secondary to activation of phosphoinositide hydrolysis. However, preliminary evidence suggests that this is not the case. Therefore, we designed a series of experiments to test more fully the hypothesis that mGluR-mediated potentiation of cAMP responses is secondary to phosphoinositide hydrolysis. Inhibitors of both protein kinase C and intracellular calcium mobilization failed to antagonize 1S,3R-ACPD-stimulated potentiation of cAMP responses. Further, coapplication of phorbol esters and 1S,3R-ACPD induced a cAMP response that was greater than additive. Finally, (RS)-3,5-dihydroxyphenylglycine, a selective agonist of mGluRs coupled to phosphoinositide hydrolysis, failed to potentiate cAMP responses, whereas (2S,1'R,2'R,3'R)-2-(2,3-dicarboxycyclopropyl)glycine, an mGluR agonist that does not activate mGluRs coupled to phosphoinositide hydrolysis, elicited a robust potentiation of cAMP responses. In total, these data strongly suggest that mGluR-mediated potentiation of cAMP responses is not secondary to activation of phosphoinositide hydrolysis and is likely mediated by a group II mGluR.

Pharmacological differentiation of the effects of co-activation of beta-adrenergic and metabotropic glutamate receptors in rat hippocampus.

Activation of metabotropic glutamate receptors (mGluRs) can potentiate the cAMP response elicited by activation of beta-adrenergic receptors (beta ARs) in the hippocampus. We have shown that co-activation of mGluRs and beta ARs induces both an acute depression of excitatory synaptic transmission and a long-lasting excitation of CA1 pyramidal cells. However, these studies were performed using a non-selective mGluR agonist. We have now used subtype selective mGluR agonists, and report that while the acute depression of transmission exhibits a pharmacology consistent with mediation by this mGluR subtype, the lasting excitation of CA1 pyramidal cells may be mediated by an interaction between beta ARs and mGluRs that are coupled to phosphoinositide hydrolysis.