Functionally refined encoding of threat memory by distinct populations of basal forebrain cholinergic projection neurons.

Neurons of the basal forebrain nucleus basalis and posterior substantia innominata (NBM/SIp) comprise the major source of cholinergic input to the basolateral amygdala (BLA). Using a genetically encoded acetylcholine (ACh) sensor in mice, we demonstrate that BLA-projecting cholinergic neurons can 'learn' the association between a naive tone and a foot shock (training) and release ACh in the BLA in response to the conditioned tone 24 hr later (recall). In the NBM/SIp cholinergic neurons express the immediate early gene, Fos following both training and memory recall. Cholinergic neurons that express Fos following memory recall display increased intrinsic excitability. Chemogenetic silencing of these learning-activated cholinergic neurons prevents expression of the defensive behavior to the tone. In contrast, we show that NBM/SIp cholinergic neurons are not activated by an innately threatening stimulus (predator odor). Instead, VP/SIa cholinergic neurons are activated and contribute to defensive behaviors in response to predator odor, an innately threatening stimulus. Taken together, we find that distinct populations of cholinergic neurons are recruited to signal distinct aversive stimuli, demonstrating functionally refined organization of specific types of memory within the cholinergic basal forebrain of mice.

Functionally refined encoding of threat memory by distinct populations of basal forebrain cholinergic projection neurons.

Neurons of the basal forebrain nucleus basalis and posterior substantia innominata (NBM/SIp) comprise the major source of cholinergic input to the basolateral amygdala (BLA). Using a genetically-encoded acetylcholine (ACh) sensor in mice, we demonstrate that BLA-projecting cholinergic neurons can "learn" the association between a naïve tone and a foot shock (training) and release ACh in the BLA in response to the conditioned tone 24h later (recall). In the NBM/SIp cholinergic neurons express the immediate early gene, Fos following both training and memory recall. Cholinergic neurons that express Fos following memory recall display increased intrinsic excitability. Chemogenetic silencing of these learning-activated cholinergic neurons prevents expression of the defensive behavior to the tone. In contrast, we show that NBM/SIp cholinergic neurons are not activated by an innately threatening stimulus (predator odor). Instead, VP/SIa cholinergic neurons are activated and contribute to defensive behaviors in response to predator odor, an innately threatening stimulus. Taken together, we find that distinct populations of cholinergic neurons are recruited to signal distinct aversive stimuli, demonstrating functionally refined organization of specific types of memory within the cholinergic basal forebrain of mice.

Enhancing Culturally Sensitive Curriculum in an Osteopathic Medical School.

Considering changing demographics in the United States, future physicians need exposure to specialized training ensuring effective communication with non-native English-speaking patients, particularly Spanish-speaking patients. We examine the impact of a medical Spanish terminology module on the linguistic competence of second-year osteopathic medical students participating in Kansas City University's Score 1 for Health program. Our goal is to enhance Spanish communication in clinical settings and to improving the quality and value of care delivered to patients.

Electrophysiological properties of basal forebrain cholinergic neurons identified by genetic and optogenetic tagging.

Recent developments in the generation of neuronal population-specific, genetically modified mouse lines have allowed precise identification and selective stimulation of cholinergic neurons in vivo. Although considerably less laborious than studies conducted with post hoc identification of cholinergic neurons by immunostaining, it is not known whether the genetically based labeling procedures that permit in vivo identification are electrophysiologically benign. In this study, we use mice carrying a bacterial artificial chromosome transgene that drives expression of a tau-green fluorescent fusion protein specifically in cholinergic neurons. This allowed us to visualize basal forebrain cholinergic neurons in acute slice preparations. Using whole cell, patch clamp electrophysiological recording in acute brain slices, here we present original data about the basic electrical properties of these genetically tagged cholinergic neurons including firing rate, resting membrane potential, rheobase, and various characteristics of their action potentials and after-hyperpolarization potentials. The basic electrical properties are compared (i) with non-cholinergic neurons in the same brain regions; (ii) in cholinergic neurons between immature animals and young adults; and (iii) with cholinergic neurons that are expressing light-sensitive channels. Our conclusions based on these data are (i) cholinergic neurons are less excitable then their non-cholinergic neighbors, (ii) the basic properties of cholinergic neurons do not significantly change between adolescence and young adulthood and (iii) these properties are not significantly affected by chronic expression of the excitatory opsin, oChIEF. This is an article for the special issue XVth International Symposium on Cholinergic Mechanisms.

Cholinergic Signaling Controls Conditioned Fear Behaviors and Enhances Plasticity of Cortical-Amygdala Circuits.

We examined the contribution of endogenous cholinergic signaling to the acquisition and extinction of fear- related memory by optogenetic regulation of cholinergic input to the basal lateral amygdala (BLA). Stimulation of cholinergic terminal fields within the BLA in awake-behaving mice during training in a cued fear-conditioning paradigm slowed the extinction of learned fear as assayed by multi-day retention of extinction learning. Inhibition of cholinergic activity during training reduced the acquisition of learned fear behaviors. Circuit mechanisms underlying the behavioral effects of cholinergic signaling in the BLA were assessed by in vivo and ex vivo electrophysiological recording. Photostimulation of endogenous cholinergic input (1) enhances firing of putative BLA principal neurons through activation of acetylcholine receptors (AChRs), (2) enhances glutamatergic synaptic transmission in the BLA, and (3) induces LTP of cortical-amygdala circuits. These studies support an essential role of cholinergic modulation of BLA circuits in the inscription and retention of fear memories.

Optogenetic studies of nicotinic contributions to cholinergic signaling in the central nervous system.

Molecular manipulations and targeted pharmacological studies provide a compelling picture of which nicotinic receptor subtypes are where in the central nervous system (CNS) and what happens if one activates or deletes them. However, understanding the physiological contribution of nicotinic receptors to endogenous acetylcholine (ACh) signaling in the CNS has proven a more difficult problem to solve. In this review, we provide a synopsis of the literature on the use of optogenetic approaches to control the excitability of cholinergic neurons and to examine the role of CNS nicotinic ACh receptors (nAChRs). As is often the case, this relatively new technology has answered some questions and raised others. Overall, we believe that optogenetic manipulation of cholinergic excitability in combination with some rigorous pharmacology will ultimately advance our understanding of the many functions of nAChRs in the brain.

Positive modulation of alpha7 nAChR responses in rat hippocampal interneurons to full agonists and the alpha7-selective partial agonists, 4OH-GTS-21 and S 24795.

One approach for the identification of therapeutic agents for Alzheimer's disease has focused on the research of alpha7 nAChR-selective agonists such as the partial agonists 3-(4-hydroxy,2-methoxybenzylidene)anabaseine (4OH-GTS-21) and, more recently, 2-[2-(4-bromophenyl)-2-oxoethyl]-1-methyl pyridinium (S 24795). An alternative approach for targeting alpha7 nAChR has been the development of positive modulators for this receptor. In this study we examined the interactions between full or partial agonists and positive modulators of alpha7 nAChRs in situ in brain tissue. Three positive modulators were used, 5-hydroxyindole (5-HI), 1-(5-chloro-2,4-dimethoxy-phenyl)-3-(5-methyl-isoxanol-3-yl)-urea (PNU-120596), and genistein. Whole-cell recordings were performed in stratum radiatum interneurons from rat brain slices. Hippocampal interneurons were stimulated by ACh, choline, S 24795, or 4OH-GTS-21, before and after bath perfusion with the positive modulators. 5-HI was not effective at potentiating 200 microM 4OH-GTS-21-evoked responses, however 5-HI induced a sustained potentiation of responses evoked by 30 microM 4OH-GTS-21. When 1 mM ACh and 200 microM 4OH-GTS-21 were applied alternately alpha7-mediated responses to both agonists were reduced, suggesting that high concentration of 4OH-GTS-21 produces residual inhibition or desensitization and that 5-HI is not effective at overcoming receptor desensitization. Similar results were obtained with alpha7 receptors expressed in Xenopus oocytes. Interestingly, responses evoked by S 24795 were potentiated by 5-HI but not by genistein. Additionally, PNU-120596 was able to potentiate alpha7-mediated responses, regardless of the nature of the agonist. We demonstrated that the potentiation of alpha7 nAChR response would depend on the nature and the effective concentration of the agonist involved and its particular interaction with the positive modulator.

Selective inhibition of acetylcholine-evoked responses of alpha7 neuronal nicotinic acetylcholine receptors by novel tris- and tetrakis-azaaromatic quaternary ammonium antagonists.

A family of 20 tris-azaaromatic quaternary ammonium (AQA) compounds were tested for their inhibition of alpha7 nicotinic acetylcholine receptors (nAChRs) expressed in Xenopus laevis oocytes. The potency of inhibitory activity was related to the hydrophobic character of the tris head groups. Two tris-AQA compounds were studied in detail: the highly effective inhibitor 1,3,5-tri-[5-(1-quinolinum)-pent-1-yn-1-yl]-benzene tribromide (tPyQB) and the less potent antagonist 1,3,5,-tri-{5-[1-(2-picolinium)]-pent-1-yn-1-yl}benzene tribromide (tPy2PiB). In addition, we evaluated 1,2,4,5-tetra-{5-[1-(3-benzyl)pyridinium]pent-1-yl}benzene tetrabromide (tkP3BzPB), a tetrakis-AQA with very hydrophobic headgroups. We compared the activity of the AQA compounds to the frequently used alpha7-antagonist methyllycaconitine (MLA). Both tPyQB and tkP3BzPB were selective antagonists of alpha7. However, although inhibition by tPyQB was reversible within 5 min, the recovery time constant for tkP3BzPB inhibition was 26.6 +/- 0.8 min, so that the equilibrium inhibition in the prolonged presence of nanomolar concentrations of tkP3BzPB was nearly 100%. The potency, selectivity, and slow reversibility of tkP3BzPB were comparable with or greater than that of MLA. The inhibitory actions of tPyQB, tPy2PiB, and tkP3BzPB were evaluated on the acetylcholine (ACh)-evoked responses of native nAChRs in rat brain slices. The alpha7-mediated responses of hippocampal interneurons were effectively reduced by 1 microM tPyQB and tkP3BzPB but not tPy2PiB. In rat medial septum, tkP3BzPB produced a greater inhibition of ACh-evoked responses of cells with fast inward currents (type I) than of cells with predominantly slow kinetics (type II), suggesting that tkP3BzPB can block alpha7 yet preserve the responsiveness of non-alpha7 receptors. These agents might be helpful in elucidating complex receptor responses in brain regions with mixed populations of nAChRs.

Activation and desensitization of nicotinic alpha7-type acetylcholine receptors by benzylidene anabaseines and nicotine.

Nicotinic receptor activation is inextricably linked to desensitization. This duality affects our ability to develop useful therapeutics targeting nicotinic acetylcholine receptor (nAChR). Nicotine and some alpha7-selective experimental partial agonists produce a transient activation of alpha7 receptors followed by a period of prolonged residual inhibition or desensitization (RID). The object of the present study was to determine whether RID was primarily due to prolonged desensitization or due to channel block. To make this determination, we used agents that varied significantly in their production of RID and two alpha7-selective positive allosteric modulators (PAMs): 5-hydroxyindole (5HI), a type 1 PAM that does not prevent desensitization; and 1-(5-chloro-2,4-dimethoxy-phenyl)-3-(5-methyl-isoxanol-3-yl)-urea (PNU-120596), a type 2 PAM that reactivates desensitized receptors. The RID-producing compounds nicotine and 3-(2,4-dimethoxybenzylidene)anabaseine (diMeOBA) could obscure the potentiating effects of 5HI. However, through the use of nicotine, diMeOBA, and the RID-negative compound 3-(2,4-dihydroxybenzylidene)anabaseine (diOHBA) in combination with PNU-120596, we confirmed that diMeOBA produces short-lived channel block of alpha7 but that RID is because of the induction of a desensitized state that is stable in the absence of PNU-120596 and activated in the presence of PNU-120596. In contrast, diOHBA produced channel block but only readily reversible desensitization, whereas nicotine produced desensitization that could be converted into activation by PNU-120596 but no demonstrable channel block. Steady-state currents through receptors that would otherwise be desensitized could also be produced by the application of PNU-120596 in the presence of a physiologically relevant concentration of choline (60 microM), which may be significant for the therapeutic development of type 2 PAMs.

Contribution of position alpha4S336 on functional expression and up-regulation of alpha4beta2 neuronal nicotinic receptors.

Phosphorylation of the nicotinic acetylcholine receptor (nAChR) is believed to play a critical role in its nicotine-induced desensitization and up-regulation. We examined the contribution of a consensus PKC site in the alpha4 M3/M4 intracellular loop (alpha4S336) on the desensitization and up-regulation of alpha4beta2 nAChRs expressed in oocytes. Position alpha4S336 was replaced with either alanine to abolish potential phosphorylation at this site or with aspartic acid to mimic phosphorylation at this same site. Mutations alpha4S336A and alpha4S336D displayed a threefold increase in the ACh-induced response and an increase in ACh EC(50). Epibatidine binding revealed a three and sevenfold increase in surface expression for the alpha4S336A and alpha4S336D mutations, respectively, relative to wild-type, therefore, both mutations enhanced expression of the alpha4beta2 nAChR. Interestingly, the EC(50)'s and peak currents for nicotine activation remained unaffected in both mutants. Both mutations abolished the nicotine-induced up-regulation that is normally observed in the wild-type. The present data suggest that adding or removing a negative charge at this phosphorylation site cannot be explained by a simple straightforward on-and-off mechanism; rather a more complex mechanism(s) may govern the functional expression of the alpha4beta2 nAChR. Along the same line, our data support the idea that phosphorylation at multiple consensus sites in the alpha4 subunit could play a remarkable role on the regulation of the functional expression of the alpha4beta2 nAChR.

Modulation of spontaneous hippocampal synaptic events with 5-hydroxyindole, 4OH-GTS-21, and rAAV-mediated alpha7 nicotinic receptor gene transfer.

One approach to treatment of negative cognitive effects associated with Alzheimer's disease and schizophrenia may involve activation of neuronal alpha7 nicotinic acetylcholine receptors (nAChRs). We used the alpha7-selective partial agonist 3-(4-hydroxy, 2-methoxy-benzylidene)anabaseine (4OH-GTS-21), the alpha7 modulator 5-hydroxyindole (5-HI), and recombinant adeno-associated virus (rAAV)-mediated alpha7 gene transfer in order to test the hypothesis whether combining these strategies would significantly increase indirect measures of alpha7 nAChR function, including measures of spontaneous synaptic events in CA1 pyramidal cells. 5-HI (1 mM), and 5-HI (1 mM)+4OH-GTS-21 (5 microM) increased the frequency of APV- and NBQX-sensitive currents, while 5-HI+4OH-GTS-21 increased the frequency and amplitude of bicuculline-sensitive currents. Effects on EPSCs were blocked with tetrodotoxin (TTX) (1 microM), but not by methyllycaconitine (MLA) (50 nM). Neither TTX nor MLA reduced the potentiation of IPSC frequencies. However, TTX blocked, and in some cases MLA reduced, the potentiation of IPSC amplitudes. These data suggest that effects of 5-HI+4OH-GTS-21 on EPSC frequency were associated with action potential-dependent transmitter release produced by 5HI, and that potentiation of IPSC amplitudes resulted at least in part, from activation of alpha7 nAChRs. Finally, rAAV-mediated alpha7 gene transfer did not alter the magnitude of effects produced by 5-HI or 5-HI+4OH-GTS-21. Thus, although we previously showed that direct measures of alpha7 nAChR function were enhanced by alpha7 gene transfer, indirect measures of alpha7 nAChRs function were not significantly enhanced by combining alpha7 gene transfer with either agonist activation or positive allosteric modulation of alpha7 nAChRs.

Neuronal nicotinic receptors as brain targets for pharmacotherapy of drug addiction.

Nicotine addiction and other forms of drug addiction continue to be significant public health problems in the United States and the rest of the world. Accumulated evidence indicates that brain nicotinic acetylcholine receptors (nAChRs) are a heterogenous family of ion channels expressed in the various parts of the brain. A growing body of preclinical studies suggests that brain nAChRs are critical targets for the development of pharmacotherapies for nicotine and other drug addictions. In this review, we will discuss the nAChR subtypes, their function in response to endogenous brain transmitters, and how their functions are regulated in the presence of nicotine. Furthermore, we will discuss the role of nAChRs in mediating nicotine-induced addictive behavior in animal models. Additionally, we will provide an overview of the effects of nicotine and nicotinic compounds on the mesolimbic dopamine system, part of the reinforcement/reward circuitry of the brain, as an example of the neurochemical basis of nicotine addiction and other drug addictions. An appreciation of the complexity of nicotinic receptors and their regulation will be necessary for the development of nicotinic receptor modulators as potential pharmacotherapy for drug addiction.

Partial agonist and neuromodulatory activity of S 24795 for alpha7 nAChR responses of hippocampal interneurons.

S 24795 evoked methyllycaconitine-sensitive inward currents in voltage-clamped hippocampal interneurons with maximum amplitude about 14% that of ACh-evoked responses. Experiments with rat alpha7 receptors expressed in Xenopus oocytes confirmed that S 24795 is a partial agonist of alpha7 nAChR with an EC(50) of 34+/-11 microM and I(max) of approximately 10% relative to ACh. When 60 microM ACh was co-applied to alpha7-expressing oocytes along with increasing concentrations of S 24795, there was a progressive decrease in response compared to the responses to 60 microM ACh alone (IC(50) 45+/-9 microM). The positive allosteric modulator 5-hydroxyindole potentiated ACh- and S 24795-evoked responses of alpha7 receptors in both oocytes and hippocampal interneurons. In hippocampal slice experiments, depending on the ACh concentrations in the application pipette and the ratio of ACh to S 24795, co-application of S 24795 with ACh variously increased, decreased, or had no effect on responses, compared to ACh alone. In order to estimate the effective dilution factor for the pressure application experiments, we tested alpha7 receptors in oocytes with ACh alone and in co-application with S 24795 at the same ratios as in the slice experiments, but at varying dilution factors. The pattern of interaction seen in the slice experiments was most closely matched under the conditions of a 3:100 dilution, suggesting that the pipette solution was diluted approximately 30-fold at the site of action. This dilution factor was consistent with the potency of ACh and S 24795 in the oocyte expression system (EC(50)s approximately 30 microM).

Nicotine-induced up-regulation and desensitization of alpha4beta2 neuronal nicotinic receptors depend on subunit ratio.

Desensitization induced by chronic nicotine exposure has been hypothesized to trigger the up-regulation of the alpha4beta2 neuronal nicotinic acetylcholine receptor (nAChR) in the central nervous system. We studied the effect of acute and chronic nicotine exposure on the desensitization and up-regulation of different alpha4beta2 subunit ratios (1alpha:4beta, 2alpha:3beta, and 4alpha:1beta) expressed in Xenopus oocytes. The presence of alpha4 subunit in the oocyte plasmatic membrane increased linearly with the amount of alpha4 mRNA injected. nAChR function and expression were assessed during acute and after chronic nicotine exposure using a two-electrode voltage clamp and whole-mount immunofluorescence assay along with confocal imaging for the detection of the alpha4 subunit. The 2alpha4:3beta2 subunit ratio displayed the highest ACh sensitivity. Nicotine dose-response curves for the 1alpha4:4beta2 and 2alpha4:3beta2 subunit ratios displayed a biphasic behavior at concentrations ranging from 0.1 to 300 microm. A biphasic curve for 4alpha4:1beta2 was obtained at nicotine concentrations higher than 300 microm. The 1alpha4:4beta2 subunit ratio exhibited the lowest ACh- and nicotine-induced macroscopic current, whereas 4alpha4:1beta2 presented the largest currents at all agonist concentrations tested. Desensitization by acute nicotine exposure was more evident as the ratio of beta2:alpha4 subunits increased. All three alpha4beta2 subunit ratios displayed a reduced state of activation after chronic nicotine exposure. Chronic nicotine-induced up-regulation was obvious only for the 2alpha4: 3beta2 subunit ratio. Our data suggest that the subunit ratio of alpha4beta2 determines the functional state of activation, desensitization, and up-regulation of this neuronal nAChR. We propose that independent structural sites regulate alpha4beta2 receptor activation and desensitization.