A quantitative description of excitatory amino acid neurotransmitter responses on cultured embryonic Xenopus spinal neurons

Predictive reward signal of dopamine neurons

The effects of lesions, receptor blocking, electrical self-stimulation, and drugs of abuse suggest that midbrain dopamine systems are involved in processing reward information and learning approach behavior. Most dopamine neurons show phasic activations after primary liquid and food rewards and conditioned, reward-predicting visual and auditory stimuli. They show biphasic, activation-depression responses after stimuli that resemble reward-predicting stimuli or are novel or particularly salient. However, only few phasic activations follow aversive stimuli. Thus dopamine neurons label environmental stimuli with appetitive value, predict and detect rewards and signal alerting and motivating events. By failing to discriminate between different rewards, dopamine neurons appear to emit an alerting message about the surprising presence or absence of rewards. All responses to rewards and reward-predicting stimuli depend on event predictability. Dopamine neurons are activated by rewarding events that are better than predicted, remain uninfluenced by events that are as good as predicted, and are depressed by events that are worse than predicted. By signaling rewards according to a prediction error, dopamine responses have the formal characteristics of a teaching signal postulated by reinforcement learning theories. Dopamine responses transfer during learning from primary rewards to reward-predicting stimuli. This may contribute to neuronal mechanisms underlying the retrograde action of rewards, one of the main puzzles in reinforcement learning. The impulse response releases a short pulse of dopamine onto many dendrites, thus broadcasting a rather global reinforcement signal to postsynaptic neurons. This signal may improve approach behavior by providing advance reward information before the behavior occurs, and may contribute to learning by modifying synaptic transmission. The dopamine reward signal is supplemented by activity in neurons in striatum, frontal cortex, and amygdala, which process specific reward information but do not emit a global reward prediction error signal. A cooperation between the different reward signals may assure the use of specific rewards for selectively reinforcing behaviors. Among the other projection systems, noradrenaline neurons predominantly serve attentional mechanisms and nucleus basalis neurons code rewards heterogeneously. Cerebellar climbing fibers signal errors in motor performance or errors in the prediction of aversive events to cerebellar Purkinje cells. Most deficits following dopamine-depleting lesions are not easily explained by a defective reward signal but may reflect the absence of a general enabling function of tonic levels of extracellular dopamine. Thus dopamine systems may have two functions, the phasic transmission of reward information and the tonic enabling of postsynaptic neurons.

AMPA and NMDA receptors expressed by differentiating Xenopus spinal neurons

N-methyl--aspartate (NMDA) receptors are often the first ionotropic glutamate receptors expressed at early stages of development and appear to influence neuronal differentiation by mediating Ca2+ influx. Although less well studied, alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) receptors also can generate Ca2+ elevations and may have developmental roles. We document the presence of AMPA and NMDA class receptors and the absence of kainate class receptors with whole cell voltage-clamp recordings from Xenopus embryonic spinal neurons differentiated in vitro. Reversal potential measurements indicate that AMPA receptors are permeable to Ca2+ both in differentiated neurons and at the time they first are expressed. The PCa/Pmonocation of 1.9 is close to that of cloned Ca2+-permeable AMPA receptors expressed in heterologous systems. Ca2+ imaging reveals that Ca2+ elevations are elicited by AMPA or NMDA in the absence of Mg2+. The amplitudes and durations of these agonist-induced Ca2+ elevations are similar to those of spontaneous Ca2+ transients known to act as differentiation signals in these cells. Two sources of Ca2+ amplify AMPA- and NMDA-induced Ca2+ elevations. Activation of voltage-gated Ca2+ channels by AMPA- or NMDA-mediated depolarization contributes approximately 15 or 30% of cytosolic Ca2+ elevations, respectively. Activation of either class of receptor produces elevations of Ca2+ that elicit further release of Ca2+ from thapsigargin-sensitive but ryanodine-insensitive stores, contributing an additional approximately 30% of Ca2+ elevations. Voltage-clamp recordings and Ca2+ imaging both show that these spinal neurons express functional AMPA receptors soon after neurite initiation and before expression of NMDA receptors. The Ca2+ permeability of AMPA receptors, their ability to generate significant elevations of [Ca2+]i, and their appearance before synapse formation position them to play roles in neural development. Spontaneous release of agonists from growth cones is detected with glutamate receptors in outside-out patches, suggesting that spinal neurons are early, nonsynaptic sources of glutamate that can influence neuronal differentiation in vivo.

Simulation and parameter estimation study of a simple neuronal model of rhythm generation: role of NMDA and non-NMDA receptors

Simple neural network models of the Xenopus embryo swimming CPG, based on the one originally developed by Roberts and Tunstall (1990), were used to investigate the role of the voltage-dependent N-methyl-D-aspartate (NMDA) receptor channels, in conjunction with faster non-NMDA components of synaptic excitation, in rhythm generation. The voltage-dependent NMDA current "follows" the membrane potential, leading to a postinhibitory rebound that is more efficient than one without voltage dependency and allows neurons to fire more than one action potential per cycle. Furthermore, the model demonstrated limited rhythmic activity in the absence of synaptic inhibition, supporting the hypothesis that the NMDA channels provide a basic mechanism for rhythmicity. However, the rhythmic properties induced by the NMDA current were observed only when there was moderate activation of the non-NMDA synaptic channels, suggesting a modulatory role for this component. The simulations also show that the voltage dependency of the NMDA conductance, as well as the fast non-NMDA current, stabilizes the alternation pattern versus synchrony. To verify that these effects and their implications on the mechanism of swimming and transition to other types of activity take place in the real preparation, constraints on parameter values have to be specified. A method to estimate synaptic parameters was tested with generated data. It is shown that a global analysis, based on multiple iterations of the optimization process (Foster et al., 1993), gives a better understanding of the parameter subspace describing network activity than a standard fit with a sensitivity analysis for an individual solution.

Modulation of dopamine neuronal activity by glutamate receptor subtypes

In vitro and in vivo electrophysiological studies have been used to assess the effects of glutamate, as well as specific agonists and antagonists for ionotropic, N-methyl-D-aspartate (NMDA), (R,S)-alpha-amino-3-hydroxy-5-methylisoxazole-4-propionic acid (AMPA) and kainate, and metabotropic subtypes of the glutamate receptor, on the neuronal firing activity of midbrain, substantia nigra zona compacta (A9) and ventral tegmental area (A10), dopamine neurons. In in vitro experiments, agonists for all glutamate receptor subtypes depolarize the membrane and increase firing rate. In in vivo experiments, iontophoretic application of these agonists increases the firing rate and induces burst-firing. Studies with subtype selective antagonists suggest that a tonic glutamate tone, acting via NMDA receptors, may modulate the firing activity of some dopamine neurons. Glutamatergic afferents from the subthalamus, pedunculopontine nucleus and frontal cortex can modulate the firing activity of dopamine neurons. The role(s) of the different glutamate receptor subtypes and pathways in mediating the physiological and pathological effects on dopamine systems is an area for further investigation.

Evidence for N-methyl-D-aspartate and AMPA subtypes of the glutamate receptor on substantia nigra dopamine neurons: possible preferential role for N-methyl-D-aspartate receptors

The present studies utilized extracellular single-unit recordings in chloral hydrate-anesthetized rats to evaluate the contribution of N-methyl-D-aspartate (NMDA) and (R,S)-alpha-amino-3-hydroxy-5-methylisoxazole-4-propionate (AMPA) subtypes of glutamate receptors to the excitatory effects of glutamate on substantia nigra dopamine neurons. Iontophoretic administration of NMDA, AMPA and glutamate increased the firing rate and amount of burst-firing of dopamine neurons. Iontophoretic application of the NMDA antagonist (+/-)-3-(2-carboxypiperazin-4-yl)-propyl-l-phosphonic acid (CPP) inhibited the excitatory effect of NMDA and glutamate, but not that of AMPA. Iontophoretic application of the AMPA antagonist 2,3-dihydroxy-6-nitro-7-sulfamoyl-benzo(f)-quinoxaline (NBQX), inhibited the excitatory effect of AMPA and glutamate, but not that of NMDA. CPP produced a greater antagonism of the glutamate excitation than did NBQX. In addition, CPP, but not NBQX, reduced the firing rate and burst-firing of a subpopulation of DA neurons. These data indicate that both NMDA and AMPA receptors are present on substantia nigra dopamine neurons and suggest that NMDA receptors may be more sensitive than AMPA receptors to endogenous glutamate and that a tonic glutamate tone, acting via NMDA receptor stimulation, may modulate the firing rate and burst-firing activity of some dopamine neurons.

Imaging of caffeine-inducible release of intracellular calcium in cultured embryonic mouse telencephalic neurons

To gain a better understanding of Ca(2+)-induced Ca2+ release in central neurons, we have studied the increase in intracellular Ca2+ concentration ([Ca2+]i) induced by application of caffeine to cells cultured from embryonic mouse telencephalon (hippocampus or cortex). The magnitudes and distributions of changes in [Ca2+]i in neuron somata were measured by quantitative video microscopy. We observed that application of caffeine to pyramidally shaped neurons typically initiated an increase in [Ca2+]i in the cytoplasmic region between the nucleus and the base of a major dendrite. [Ca2+] in this region increased over a period of 3 to 6 s and was followed by, with a slight delay, a surge of Ca2+ that moved across the soma and into or over the nucleus. Similar Ca2+ responses to caffeine were observed in Ca(2+)-containing and nominally Ca(2+)-free external solutions, suggesting that caffeine was inducing Ca2+ release from intracellular stores. Ca2+ responses to caffeine were potentiated by inducing a tonic Ca2+ influx through N-methyl-D-aspartate (NMDA)-type glutamate receptors activated by 0.3 microM glutamate and multiple responses to caffeine could be elicited by using this Ca2+ influx to refill the intracellular stores. Ryanodine inhibition of caffeine-induced Ca2+ release was use- and concentration-dependent; the median effective concentration EC50 for ryanodine declined from 22 microM for the first application of caffeine to 20 nM for the fourth. We conclude, based on these responses to caffeine, that ryanodine-sensitive mechanisms of intracellular Ca2+ release are active in hippocampal and cortical neurons and may be involved in generation of directed Ca2+ waves that engulf the nucleus.

The tonic/phasic model of dopamine system regulation: its relevance for understanding how stimulant abuse can alter basal ganglia function

The changes in dopamine system regulation occurring during stimulant administration are examined in relation to a new model of dopamine system function. This model is based on the presence of a tonic low level of extracellular dopamine that is released by the presynaptic action of corticostriatal afferents. In contrast, spike-dependent dopamine release results in a phasic, high concentration of dopamine in the synaptic cleft that is rapidly inactivated by reuptake. Tonic dopamine has the ability to down-modulate spike-dependent phasic dopamine release via stimulation of the very sensitive dopamine autoreceptors present on dopamine terminals. Stimulants are known to elicit locomotion and stimulate reward sites by releasing dopamine from terminals in the nucleus accumbens, which is followed by a rebound depression. It is proposed that the initial activating action of stimulants is caused by increasing the release of dopamine into the synaptic cleft to activate the phasic dopamine response. However, by interfering with dopamine uptake, stimulants also allow dopamine to escape the synaptic cleft, thereby depressing subsequent spike-dependent phasic dopamine release by increasing the tonic stimulation of the autoreceptor. In contrast, repeated stimulant administration is proposed to cause long-term sensitization by pharmacological disruption of a cascade of homeostatic compensatory processes. Upon drug withdrawal, the fast compensatory systems that were blocked by stimulants rapidly restore homeostasis to the system at a new steady-state level of interaction. As a consequence, the slowly changing but potentially more destabilizing compensatory responses are prevented from returning to their baseline conditions. This results in a permanent change in the responsivity of the system. Homeostatic systems are geared to compensate for unidimensional alterations in a system, and are capable of restoring function even after massive brain lesions or the continuous presence of stimulant drugs. However, the system did not evolve to deal effectively with repetitive introduction and withdrawal of drugs that disrupt dopamine system regulation. As a consequence, repeated insults to a biological system by application and withdrawal of drugs that interfere with its homeostatic regulation may be capable of inducing non-reversible changes in its response to exogenous and endogenous stimuli.

Induction of neuronal differentiation by planar signals in Xenopus embryos

The induction of the central nervous system in amphibian embryos is mediated both by early planar signals produced by mesoderm at the dorsal lip and later vertical signals emanating from the dorsal mesoderm after involution. We have examined the role and spatial extent of planar signals in the induction of neuronal differentiation. Planar explants that included only the deep layer of the dorsal marginal zone, comprising both the dorsal mesoderm and the contiguous dorsal ectoderm, were isolated at the beginning of gastrulation. After removal of the epithelial layer, explants were maintained in modified Danilchik's medium until mid-neurula stages, when they were transferred to modified Danilchik's medium + 0.1% bovine serum albumin and cultured on laminin. Neurite outgrowth occurred in 90% of these planar explants. In contrast, little or no neuronal differentiation occurred in either ventral planar explants or explants of ectoderm alone. Video analysis of cell movements shows that large-scale cell mixing does not occur between mesoderm cells and ectoderm cells in planar explants. Retrograde labelling of neuronal cell bodies indicates that cells throughout the ectoderm undergo neuronal differentiation; neurons also differentiate in cultures of distal ectoderm isolated at early neurula stages from planar explants prepared at the beginning of gastrulation. These observations indicate that planar signals act over an extended range to induce neuronal differentiation. The inductive capacity of vertical signals was examined by recombining animal caps from ultra-violet (UV) irradiated embryos with involuted mesoderm from normal midgastrula embryos. Differentiation of either neurons or anterior neural structures occurred in 73% of vertical recombinates. Our results demonstrate that planar signals from the dorsal lip of the blastopore are capable of inducing neuronal differentiation over a considerable distance in the absence of epithelial confinement, convergence and extension, and mixing between the mesoderm and ectoderm.

Cortical regulation of subcortical dopamine systems and its possible relevance to schizophrenia

A unique model of DA system regulation is presented, in which tonic steady-state DA levels in the ECF act to down-regulate the response of the system to pulsatile DA released by DA cell action potential generation. This type of regulation is similar in many respects to the phenomenon proposed to mediate the action of norepinephrine on target neurons; i.e., an increase in the "signal-to-noise" ratio as measured by postsynaptic cell firing (Freedman et al., 1977; Woodward et al., 1979). However, in this model the signal and the noise are neurochemical rather than electrophysiological. Furthermore, the "noise" (tonic DA in the ECF) actually down-regulates the "signal" (phasic DA release) directly, and thereby provides a "signal" of its own that affects the system over a longer time-course. Therefore, the difference between signal and noise may also depend on the time frame under which such determinations are made.

The depolarization block hypothesis of neuroleptic action: implications for the etiology and treatment of schizophrenia

Antipsychotic drugs are known to block dopamine receptors soon after their administration, resulting in an increase in dopamine neuron firing and dopamine turnover. Nonetheless, antipsychotic drugs must be administered repeatedly to schizophrenics before therapeutic benefits are produced. Recordings from dopamine neurons in rats have revealed that chronic antipsychotic drug treatment results in the time-dependent inactivation of dopamine neuron firing via over-excitation, or depolarization block. Furthermore, the clinical profile of the response to antipsychotic drugs appears to correspond to the dopamine system affected: antipsychotic drugs that exert therapeutic actions in schizophrenics inactivate dopamine neuron firing in the limbic-related ventral tegmental area, whereas drugs that precipitate extrapyramidal side effects cause depolarization block of the motor-related substantia nigra dopamine cells. One factor that remains unresolved with regard to the actions of antipsychotic drugs is the relationship between dopamine turnover and depolarization block--i.e., why does a significant level of dopamine release or turnover remain after antipsychotic drug treatment if dopamine cells are no longer firing? We addressed this question using an acute model of neuroleptic-induced depolarization block. In this model, dopamine cells recorded in rats one month after partial dopamine lesions could be driven into depolarization block by the acute administration of moderate doses of haloperidol. However, similar doses of haloperidol, which were effective at increasing dopamine levels in the striatum of intact rats, failed to change dopamine levels in lesioned rats. This is consistent with a model in which neuroleptic drugs exert their therapeutic effects in schizophrenics by causing depolarization block in DA cells, thereby preventing further activation of dopamine neuron firing in response to external stimuli. Thus, attenuating the responsivity of the dopamine system to stimuli may be more relevant to the therapeutic actions of antipsychotic drugs than receptor blockade or decreases in absolute levels of dopamine, which could presumably be circumvented by homeostatic adaptations in this highly plastic system.

Extracellular dopamine in striatum: Influence of nerve impulse activity in medial forebrain bundle and local glutamatergic input

Microdialysis probes were used to measure dopamine in, and to administer glutamate receptor antagonists and agonists to, the striatum of unanesthetized rats. Antagonists used were: kynurenate, 2-amino-5-phosphonovalerate and 6-cyano-7-nitroquinoxaline-2,3-dione. Agonists used were: N-methyl-D-aspartate and kainate. In some rats an additional dialysis probe was implanted in medial forebrain bundle for infusion of tetrodotoxin (10 microM) to block action potential propagation along dopaminergic axons in this pathway. The latter treatment reduced dopamine in striatal dialysate to below detectable levels (less than 0.5 pg). The quantity of dopamine in striatal dialysate was not reduced by the local application of glutamate receptor antagonists. At lower concentrations, the receptor antagonists failed to alter significantly the quantity of dopamine, whereas the highest concentration of each antagonist increased the amount of dopamine in the dialysate. At the highest concentration tested (0.75 mM or 1.0 mM), as well as at a lower concentration (0.1 mM), 2-amino-5-phosphonovalerate and 6-cyano-7-nitroquinoxaline-2,3-dione blocked the dopamine-releasing effects of exogenously applied N-methyl-D-aspartate (1.0 mM) or kainate (0.1 mM), respectively. Thus, concentrations of glutamate receptor antagonists that produced effective pharmacological blockade of the respective receptors had no effect on the basal amount of dopamine in striatal extracellular fluid. Finally, N-methyl-D-aspartate and kainate produced a significant elevation in extracellular dopamine during the infusion of tetrodotoxin into the medial forebrain bundle, indicating that impulse activity in this pathway is not necessary for dopamine release produced by glutamate receptor agonists.(ABSTRACT TRUNCATED AT 250 WORDS)

Voltage-gated calcium currents in cultured embryonic Xenopus spinal neurones

1. Voltage-gated Ca2+ currents were studied in cultured embryonic Xenopus spinal neurones using whole-cell gigaohm seal techniques. Cultures of neural plate cells were established from stage 15-17 embryos (see Methods), and were studied for up to 80 h in vitro. During this period neural precursor cells morphologically differentiate and commence expression of multiple types of voltage- and ligand-gated ion channels. 2. Embryonic Xenopus neurones studied during the first 20-40 h in culture display Ca2+ currents that correspond to the low-voltage-activated (T-type) and high-voltage-activated forms described in other neurones and excitable cells. These Ca2+ current types could be separated based on voltage dependencies and pharmacological sensitivities. 3. T-type Ca2+ current was activated at voltages positive to -50 mV, and was selectively blocked by 200 microM-Ni2+. Curves describing the voltage dependencies of activation and steady-state inactivation overlapped in a region centred on -40 mV. A small sustained Ca2+ current could be recorded within this voltage region. 4. High-voltage-activated (HVA) Ca2+ currents were observed at voltages positive to -10 mV, and could be separated into relaxing and sustained components (denoted as HVA-relaxing and HVA-sustained). HVA-relaxing current was selectively reduced by Met-enkephalin (17.5 microM). Both components of HVA current were sensitive to verapamil (100 microM), were almost completely blocked by omega-conotoxin (3 microM) and were insensitive to nifedipine (20 microM). 5. The data indicate that T-type Ca2+ current is present in the membrane during the initial period of channel and receptor expression, process outgrowth, and synaptogenesis, and is the dominant influence on voltage-gated Ca2+ influx during subthreshold voltage excursions. Further, at more positive voltages, T-type Ca2+ current contributes to inward Ca2+ current during the first 5-10 ms after depolarizing voltage steps, and thus to inward Ca2+ current during the rising phase of the long-lasting Ca(2+)-dependent embryonic action potential. HVA Ca2+ currents (particularly the relaxing component) influence the plateau phase.

Increases in intracellular calcium ion concentration during depolarization of cultured embryonic Xenopus spinal neurones

1. Changes in intracellular Ca2+ ion concentrations ([Ca2+]i) during potassium-induced depolarizations were studied in cultured embryonic Xenopus spinal neurones using the Ca(2+)-sensitive dye Fura-2 and quantitative fluorescence microscopy. 2. Membrane voltages attained during exposure to bath solutions containing 3, 10, 20, 30, 40 and 50 mM-K+ were determined under current clamp. In 3 mM-K(+)-containing solution (normal saline), the resting potential was -65 mV. The threshold voltage required to observe a measurable rise in [Ca2+]i was -40 mV (external potassium concentration [K+]o = 20 mM). The depolarization-induced [Ca2+]i signal had two components: a non-relaxing component, and, at voltages positive to -40 mV, an additional transient component on the rising phase that decayed over tens of seconds. There was substantial variability in the magnitudes of resting and voltage-induced changes in [Ca2+]i, but [Ca2+]i responses were qualitatively consistent between neurons of similar ages. 3. External potassium (K+o)-induced increases in [Ca2+]i were spatially non-homogeneous. The largest increases were seen in the nucleus, near the base of a major neurite, and in growth cones. Increases occurred more rapidly in neurites and growth cones than in somas. T-type and high-voltage-activated (HVA) channels appeared to be present in all cell regions. 4. Increases in [Ca2+]i evoked by 50 mM-K+ (depolarization to approximately -15 mV) were sensitive to treatments demonstrated to inhibit Ca2+ currents in these cells (T-type, HVA-relaxing and HVA-sustained), including Ni2+ (200 microM), Metenkephalin (17.5 microM), and omega-conotoxin (omega-CgTx; 5.5 microM). [Ca2+]i increases were reduced by caffeine (10 mM) and ryanodine (10-100 microM), agents that affect Ca2+ release from intracellular stores. 5. A sustained increase in [Ca2+]i observed at approximately -40 mV ([K+]o = 20 mM) was investigated in greater detail. Concentrations of Ni2+ sufficient to block T-type Ca2+ current slowed but did not block the rise in [Ca2+]i induced by 20 mM-K+. Met-enkephalin did not affect the [Ca2+]i response. omega-CgTx reduced the amplitude of the [Ca2+]i response, but did not eliminate the sustained component. Verapamil (100 microM), caffeine and ryanodine differentially reduced the sustained component as compared to the initial rising phase. These observations suggest that the rising phase was due to Ca2+ influx through T-type and other Ca2+ channels, and that the sustained phase was differentially sensitive to inhibition of internal Ca2+ release.(ABSTRACT TRUNCATED AT 400 WORDS)

Development of intracellular calcium responses to depolarization and to kainate and N-methyl-D-aspartate in cultured mouse hippocampal neurons

We have investigated the initial appearance of voltage-gated Ca channels and kainate- and NMDA-type glutamate receptors in cultured embryonic mouse hippocampal neurons. The Ca-dependent fluorescence change of the dye fura-2 was used as a sensitive assay for the presence of functional channels and receptors. Expression of functional NMDA receptors was observed on some hippocampal neurons as early as E14. By the equivalent of E15-16, 40-50% of cells responded to Ko-depolarization (50 mM), indicating the presence of functional voltage-gated Ca channels, approximately 20% of cells responded to kainate (50 microM), and just under 20% responded to NMDA (50 microM; in the presence of glycine and strychnine). By the equivalent of the end of the embryonic period 70-80% of cells responded to all 3 stimuli. As approximately 20% of cells in these cultures are glia, these data indicate that by the time of birth close to 100% of neurons express functioning kainate and NMDA receptors, and voltage-gated Ca channels. Increases in [Ca2+]i in embryonic neurons after application of NMDA were sensitive to APV and to external Mg, as are responses in mature neurons. The IC50 for block by external Mg of the [Ca2+]i increase induced by NMDA was 130 microM, and there was a slight positive correlation between the amplitude of the response to NMDA and sensitivity to external Mg.

Phasic versus tonic dopamine release and the modulation of dopamine system responsivity: a hypothesis for the etiology of schizophrenia

A novel mechanism for regulating dopamine activity in subcortical sites and its possible relevance to schizophrenia is proposed. This hypothesis is based on the regulation of dopamine release into subcortical regions occurring via two independent mechanisms: (1) transient or phasic dopamine release caused by dopamine neuron firing, and (2) sustained, "background" tonic dopamine release regulated by prefrontal cortical afferents. Behaviorally relevant stimuli are proposed to cause short-term activation of dopamine cell firing to trigger the phasic component of dopamine release. In contrast, tonic dopamine release is proposed to regulate the intensity of the phasic dopamine response through its effect on extracellular dopamine levels. In this way, tonic dopamine release would set the background level of dopamine receptor stimulation (both autoreceptor and postsynaptic) and, through homeostatic mechanisms, the responsivity of the system to dopamine in these sites. In schizophrenics, a prolonged decrease in prefrontal cortical activity is proposed to reduce tonic dopamine release. Over time, this would elicit homeostatic compensations that would increase overall dopamine responsivity and thereby cause subsequent phasic dopamine release to elicit abnormally large responses.

Endogenous neurotransmitter activates N-methyl-D-aspartate receptors on differentiating neurons in embryonic cortex

Before synapses form in embryonic turtle cerebral cortex, an endogenous neurotransmitter activates N-methyl-D-aspartate (NMDA) channels on neurons in the cortical plate. Throughout cortical development, these channels exhibit voltage-dependent Mg2+ blockade and are antagonized by D-2-amino-5-phosphonovaleric acid, a selective NMDA receptor antagonist. The activation in situ of these nonsynaptic NMDA channels demonstrates a potential physiological substrate for control of early neuronal differentiation.