Effect of metabolic alterations on the accumulation of technetium-99m-labeled d,l-HMPAO in slices of rat cerebral cortex

It is widely recognized that the distribution of technetium-99m-labeled d,l-hexamethylpropylene amine oxime (99mTc-HMPAO) in the brain is determined by the regional blood flow. However, other factors may affect this process including the metabolism of the brain tissue. To examine this possibility we studied the effects of metabolic alterations on 99mTc-HMPAO uptake in rat brain cortex slices, with concurrent measurement of oxygen consumption (QO2). 99mTc-HMPAO uptake was determined by incubating slices of rat cerebral cortex at 37 degrees C in Krebs-Ringer phosphate glucose medium containing 99mTc-HMPAO with and without test substances. Differential gradients for 99mTc activity between the tissue and the suspending medium (T/M ratio) were derived from the equation T/M[99mTc] = counts per gram of tissue/counts per milliliter of medium. The QO2 of the brain slices was measured using a biological oxygen monitor equipped with a polarographic oxygen probe. Inhibitors affecting oxidative phosphorylation caused parallel suppression of the T/M ratio and QO2. Agents that uncouple oxidation from phosphorylation increased the QO2 and decreased the T/M ratio. Incubation of slices at 22 degrees C depressed the T/M ratio and QO2. The presence of inhibitors of oxidative phosphorylation in the incubation medium increased the release of 99mTc activity from slices that had been prelabeled with 99mTc-HMPAO. These findings suggest that the altered metabolic status of the brain tissue modulates the kinetics and net accumulation of 99mTc-HMPAO at the cellular level by either depressing uptake, increasing back-diffusion, or both.

Adenosine inhibition of mesopontine cholinergic neurons: implications for EEG arousal

Increased discharge activity of mesopontine cholinergic neurons participates in the production of electroencephalographic (EEG) arousal; such arousal diminishes as a function of the duration of prior wakefulness or of brain hyperthermia. Whole-cell and extracellular recordings in a brainstem slice show that mesopontine cholinergic neurons are under the tonic inhibitory control of endogenous adenosine, a neuromodulator released during brain metabolism. This inhibitory tone is mediated postsynaptically by an inwardly rectifying potassium conductance and by an inhibition of the hyperpolarization-activated current. These data provide a coupling mechanism linking neuronal control of EEG arousal with the effects of prior wakefulness, brain hyperthermia, and the use of the adenosine receptor blockers caffeine and theophylline.

Nicotinic depolarizations of rat medial pontine reticular formation neurons studied in vitro

Either muscarinic or nicotinic cholinergic activation of the medial pontine reticular formation evokes a behavioral state, indistinguishable in most respects from that of natural rapid eye movement sleep. However, the presence of physiologically relevant nicotonic receptors has not been described. Intracellular current and single electrode voltage clamp recordings were used to analyse the electrophysiological responses of rat medial pontine reticular formation neurons to nicotinic activation in vitro. In response to the nicotonic agonist, 1,1-dimethyl-4-phenylpiperazinium iodine, depolarization in association with an inward current was observed in 70% of the medial pontine reticular formation neurons. This effect was insensitive to the muscarinic antagonist atropine and the nicotinic ganglionic antagonists mecamylamine and hexamethonium. However, the neuromuscular nicotinic antagonist D-tubocurare and dihydro-beta-erythroidine were effective. This is consistent with a cholinergic activation of medial pontine reticular formation neurons evoking a rapid eye movement sleep-like behavioral state, at least in part, by nicotinic receptors on these neurons.

Inhibitory action of muscarinic agonists on neurons in the rat laterodorsal tegmental nucleus in vitro

1. The effects of the mixed cholinergic agonist carbachol and the muscarinic agonist methacholine (MCh) on neurons of the laterodorsal tegmental nucleus (LDT) were studied with the use of intracellular and whole-cell patch-clamp recordings in a rat brain stem slice preparation. 2. Neurons were classified into one of two categories on the basis of their intrinsic membrane properties: those that displayed a prominent low-threshold calcium burst (LTB, 60%) and those that did not exhibit such a burst (non-LTB, 40%). 3. Neurons from which recordings were obtained were filled with biocytin, visualized with Texas-red avidin, and identified as cholinergic or noncholinergic with NADPH-diaphorase histochemistry. Eighty percent of the LTB neurons that were processed in this manner were cholinergic, and 60% of the non-LTB neurons were cholinergic. 4. Carbachol elicited a membrane hyperpolarization associated with a decrease in input resistance in 95% of the cells tested. Under voltage clamp this response was shown to be due to an outward current that reversed near the equilibrium potential for potassium and displayed marked inward rectification. The conductance/voltage relationship was fit to the Boltzmann equation with a mean V1/2 = -73 +/- 4 (SD) mV and a mean k value of 10 +/- 4. The carbachol-evoked current was fully blocked by extracellular barium. 5. There was no significant effect of carbachol on the transient currents IA or IT. 6. The carbachol-evoked current was mimicked by the specific muscarinic agonist methacholine and blocked by high concentrations of the muscarinic receptor antagonist pirenzepine (IC50 = 580 nM).(ABSTRACT TRUNCATED AT 250 WORDS)

Distribution of NADPH-diaphorase positive somata in the brainstem of the monitor lizard Varanus exanthematicus

The distribution and size of presumptive cholinergic somata in the brainstem of the Savanna monitor lizard Varanus exanthematicus were determined using the enzyme histochemical marker NADPH-diaphorase. Numerous neurons were labelled in the lizard brainstem with this technique. A three dimensional computer reconstruction of this population revealed that it shows marked similarity to the laterodorsal tegmental/pedunculopontine tegmental cholinergic cell column, an NADPH-diaphorase positive population in the mesopontine tegmentum of the mammalian brainstem.

Excitatory amino acid-mediated responses and synaptic potentials in medial pontine reticular formation neurons of the rat in vitro

Neurons of the medial pontine reticular formation (mPRF) are involved in the execution of numerous behaviors including initiation of locomotion, eye movements, startle responses, and rapid eye movement sleep phenomena. Approximately half of the afferent projections to mPRF neurons come from within the reticular formation (Shammah-Lagnado et al., 1987). In spite of the importance of reticulo-reticular connections, virtually nothing is known about transmitters mediating these synapses. In order to identify a candidate excitatory neurotransmitter, the actions of excitatory amino acids (EAAs) on the membrane properties of mPRF neurons recorded in rat brainstem slices in vitro were studied. Standard intracellular recording methods, including single-electrode voltage clamp, were used to examine the postsynaptic actions of EAAs. We also tested whether EAA antagonists block EPSPs evoked by stimulation of the contralateral reticular formation in the slices. mPRF neurons responded to both non-NMDA and NMDA agonists. NMDA-induced conductances were voltage dependent and depressed by physiological concentrations of magnesium. Stimulation of the contralateral reticular formation elicited EPSPs that were depressed by the general EAA antagonist kynurenate. Evoked EPSPs were partially depressed by 6,7-dinitroquinoxaline-2,3-dione. The evoked EPSP was further reduced by the NMDA antagonist (+/-)-2-amino-5-phosphonopentanoic acid in some cases. These results suggest that excitatory reticulo-reticular neurotransmission is mediated by an EAA. Both non-NMDA and NMDA receptors contribute to EAA neurotransmission in the mPRF formation and play an integral role in reticular formation function.

Adenosine-mediated synaptic inhibition: partial blockade by barium does not prevent anti-epileptiform activity

Adenosine-induced inhibition of evoked postsynaptic potentials (PSPs) and epileptiform burst firing in the CA1 subfield of rat hippocampal slices was studied with intracellular recordings in vitro. Adenosine (50 microM) caused a membrane hyperpolarization which was abolished during superfusion with 2 mM Ba2+. The adenosine-induced inhibition of the PSPs was still evident, although the magnitude of the effect was significantly reduced. Adenosine also reduced Ba(2+)-induced burst firing, but less effectively than it did bursts evoked by TEA (5 mM). The results suggest that adenosine inhibits synaptic transmission and epileptiform activity by at least 2 mechanisms: a postsynaptic barium-sensitive increase in gK and a presynaptic effect independent of this adenosine-evoked outward potassium conductance.

Serotonin1 and serotonin2 receptors hyperpolarize and depolarize separate populations of medial pontine reticular formation neurons in vitro

The action of serotonin on medial pontine reticular formation neurons was examined using intracellular electrophysiological methods in rat brainstem slices in vitro. A hyperpolarization associated with a decrease in input resistance was elicited by serotonin in 34% of the neurons, and a depolarization associated with an increase in input resistance was produced in 56% of the neurons. Both responses persisted in the presence of tetrodotoxin. The hyperpolarization resulted from a steady-state increase in outward current which varied with the external potassium concentration in a manner consistent with a conductance increase primarily to this ion. This response was mimicked by the serotonin1 agonist, 5-carboxamidotryptamine, as well as by the serotonin1a agonist, 8-hydroxy-dipropyl aminotetralin hydrobromide, and was blocked by spiperone, an antagonist of serotonin1 sites. The depolarization resulted from a steady-state decrease in outward current which varied with external potassium. The depolarization was mimicked by the serotonin2 agonist, alpha-methyl-5-hydroxytryptamine, and was blocked by the serotonin2 antagonist, ketanserin. Neither of these agents had any effect upon serotonin-induced hyperpolarizations. In conclusion, the excitability of medial pontine reticular formation neurons is influenced by serotonin acting to increase or decrease potassium conductance(s). These opposing effects reflect actions on distinct serotonin receptor subtypes that are segregated to distinct populations of medial pontine reticular formation neurons.

Sociometric status and academic, behavioral, and psychological adjustment: a five-year longitudinal study

Six hundred fourth-graders rated how much they liked to play with each of their classmates and then nominated their three best friends; 296 of the 600 children were assigned sociometric classifications of popular, neglected, average, controversial, or rejected status (the remaining 304 children failed to meet inclusion criteria). Five years later, 267 of the 296 classified children (90.2%) were evaluated on measures of academic performance, social behavior, and psychological adjustment. The number and type of contacts with the juvenile justice system were also determined. In general, children classified as rejected or controversial tended to fare more poorly on indices of long-term adjustment than did children classified as popular, neglected, or average. Results are discussed in terms of the predictive validity of sociometric rating and nomination procedures and their utility in identifying children at risk for later maladjustment.

Serotonin hyperpolarizes cholinergic low-threshold burst neurons in the rat laterodorsal tegmental nucleus in vitro

Serotonergic suppression of cholinergic neuronal activity implicated in the regulation of rapid eye movement sleep and its associated phenomenon, pontogeniculooccipital waves, has long been postulated, but no direct proof has been available. In this study, intracellular and whole-cell patch-clamp recording techniques were combined with enzyme histochemistry to examine the intrinsic electrophysiological properties and response to serotonin (5-HT) of identified cholinergic rat laterodorsal tegmental nucleus neurons in vitro. Sixty-five percent of the recorded neurons demonstrated a prominent low-threshold burst, and of these, 83% were cholinergic. In current-clamp recordings 64% of the bursting cholinergic neurons tested responded to the application of 5-HT with a membrane hyperpolarization and decrease in input resistance. This effect was mimicked by application of the selective 5-HT type 1 receptor agonist carboxamidotryptamine maleate. Whole-cell patch-clamp recordings revealed that the hyperpolarizing response was mediated by an inwardly rectifying K+ current. Application of 5-HT decreased excitability and markedly modulated the discharge pattern of cholinergic bursting neurons: during a 5-HT-induced hyperpolarization these neurons exhibited no rebound burst after hyperpolarizing current input and a burst in response to depolarizing current input. In the absence of 5-HT, the relatively depolarized cholinergic bursting neurons responded to an identical hyperpolarizing current input with a burst and did not produce a burst after depolarizing current input. These data provide a cellular and molecular basis for the hypothesis that 5-HT modulates rapid eye movement sleep phenomenology by altering the firing pattern of bursting cholinergic neurons.

Sociometric status and academic, behavioral, and psychological adjustment: A five-year longitudinal study

Six hundred fourth-graders rated how much they liked to play with each of their classmates and then nominated their three best friends; 296 of the 600 children were assigned sociometric classifications of popular, neglected, average, controversial, or rejected status (the remaining 304 children failed to meet inclusion criteria). Five years later, 267 of the 296 classified children (90.2%) were evaluated on measures of academic performance, social behavior, and psychological adjustment. The number and type of contacts with the juvenile justice system were also determined. In general, children classified as rejected or controversial tended to fare more poorly on indices of long-term adjustment than did children classified as popular, neglected, or average. Results are discussed in terms of the predictive validity of sociometric rating and nomination procedures and their utility in identifying children at risk for later maladjustment.

Muscarinic agonists activate an inwardly rectifying potassium conductance in medial pontine reticular formation neurons of the rat in vitro

Intracellular recordings were obtained from neurons in pontine reticular formation slices of the rat to characterize a cholinergic-gated increase in conductance. The conductance increase was associated with a hyperpolarization of the membrane potential and with an outward current under voltage-clamp conditions. Current-voltage relations and potassium substitution experiments indicated mediation by a change in permeability, primarily to potassium. This potassium conductance exhibited inward rectification at membrane potentials negative to resting potential, a novel finding for cholinergic actions in CNS neurons. Further characterization of this inwardly rectifying potassium conductance revealed marked sensitivity to low concentrations of barium. Cholinergically evoked currents were relatively unaffected by the presence of extracellular cesium. Cholinergic effects persisted in TTX. The outward currents elicited by carbachol or methacholine were blocked only by high concentrations of pirenzepine, a selective antagonist of the M1 muscarinic receptor. The interaction between these agents is quantitatively consistent with cholinergic action at postsynaptic muscarinic receptors of the non-M1 subtype.

Sociometric status: its stability and validity among neglected, rejected and popular children

Although important distinctions among sociometrically rejected, neglected, and popular children have been reported in the literature, concerns have been raised about use of negative peer nominations in identifying these children. A revised procedure developed by Asher and Dodge [Developmental Psychology, 22, 444-449 (1986)] eliminates the need to obtain negative peer nominations. In the present study, the construct validity of this revised procedure was explored and its long-term stability examined over 6, 12 and 18 months. Our findings establish significant differences on several indices among rejected, neglected and popular children. However, the differences between rejected and popular children were more robust than those between neglected and popular children, who failed to differ from one another on most of the measures. Moreover, fairly good long-term stability was found for popular and rejected status, whereas the long-term stability for neglected status was quite poor. These findings were addressed in the context of similar research employing negative nomination methods. Implications for the identification of at-risk children were also discussed.

The predictive validity of teacher nominations: a five-year followup of at-risk youth

The purpose of this study was to examine the predictive validity of a teacher nomination procedure for identifying at-risk children. Two hundred and twenty-five children were nominated by their teachers as well-adjusted (n = 75), socially withdrawn (n = 76), or socially aggressive (n = 74) during the fourth grade. Five years later, 198 of these children (88%) were located and their adjustment evaluated. Significant differences among the nominated children were found on a variety of measures, including academic grades, sociometric status, and social behavior. In addition, differences in school dropout and delinquent offenses were noted. Results are discussed in terms of the validity of teacher nomination procedures and their utility in identifying at-risk youth.

Two transient outward currents in histamine neurones of the rat hypothalamus in vitro

1. The transient outward current exhibited by the histamine neurones of the tuberomammillary nucleus was studied using the single-electrode voltage clamp technique in an in vitro rat hypothalamic slice preparation. 2. The transient outward current exhibited steady-state inactivation at the resting potential. Inactivation was removed by priming hyperpolarization with a V1/2 of -85 +/- 1.2 mV, while the V1/2 for activation was -60.3 +/- 2.1 mV. 3. The decay of the transient outward current was best fitted by two exponentials with time constants of 104 +/- 36 and 568 +/- 128 ms. These two components were provisionally termed IA,f and IA,s for the fast and slowly decaying currents, respectively. 4. Removal of inactivation was time dependent; inactivation was fully removed by hyperpolarizing pulses to -110 mV of 200 ms or greater duration. Removal of inactivation of IA,f was rapid, becoming complete with hyperpolarizing pre-pulses of 50 ms or greater, while removal of inactivation of IA,s was not complete until hyperpolarizing pre-pulses were 200 ms in duration. 5. The fast decaying current IA,f was selectively blocked by 1 mM-4-aminopyridine. Tetraethylammonium chloride (10 mM) had no effect on either IA,f or IA,s. 6. The inactivation curves for IA,s, determined both by using the values obtained from the amplitude of the computed slower exponential function as well as that of the current remaining in 1 mM 4-aminopyridine, were negative to those of IA,f. Similarly derived activation curves for IA,s were positive to those of IA,f. 7. Superfusion with a nominal 0 Ca2+ medium containing 10 mM-Mg2+ did not reduce the maximal transient outward current. 8. The reversal potential of IA,s with 2.5 mM-K+ in the medium was -95 +/- 3 mV; the reversal potential of IA,f was at least 15 mV negative to that of IA,s. 9. It is concluded that histaminergic tuberomammillary neurones possess at least two transient outward currents which can be distinguished on the basis of their rates of decay, 4-aminopyridine sensitivity, voltage dependence and reversal potentials.

Effects of histamine on dentate granule cells in vitro

Hippocampal slices from rat brain were exposed to histamine and related substances in a perfusion chamber. Granule cells of the dentate gyrus were studied with conventional extra- and intracellular recording and a single electrode voltage clamp. Histamine caused, through activation of H(2)-receptors, a small depolarization, an increase in the number of synaptic and action potentials, a block of the long lasting (but not the early) component of spike afterhyperpolarizations and a reduction of the accommodation of action potential firing. These effects were mimicked by forskolin (suggests activation of adenylate cyclase). In voltage clamp, histamine blocked a long lasting calcium-dependent outward tail current without any reduction of inward current. Thus histamine selectively blocks the late calcium-dependent potassium current in dentate granule cells which receive histaminergic input from the posterior hypothalamus. Histamine also reduces the field excitatory postsynaptic potential evoked by perforant path stimulation. These actions allow for a powerful modulation of excitatory signals and an effective regulation of hippocampal excitability.

Characterization of inhibition mediated by adenosine in the hippocampus of the rat in vitro

1. Intracellular recordings with single-electrode voltage clamp were employed to study the mechanism of adenosine-elicited inhibition of CA1 neurones of the rat in vitro. 2. Adenosine elicits a steady-state outward current in association with an increase in conductance. The driving force varied with external potassium concentration as predicted by the Nernst equation for a change primarily in potassium permeability. 3. Adenosine current was blocked by high concentrations of 4-aminopyridine or barium. In the majority of neurones this current was voltage insensitive. In the remainder, the current was inwardly rectifying. The rectification was blocked by tetraethylammonium. 4. When the adenosine-elicited potassium current was blocked, slow inward currents, normally carried by calcium, were unaffected by adenosine. We conclude that this adenosine inhibition is mediated by an increase in a voltage- and calcium-insensitive potassium conductance in CA1 neurones.

The brain histamine system in vitro

The electrophysiological properties of identified tuberomammillary histamine neurones were investigated in explant and slice preparations. The effects of histamine were studied on target neurones, mainly in the hippocampal slice. The results describe an important modulatory role of this diffusely projecting system.

Repetitive firing properties of medial pontine reticular formation neurones of the rat recorded in vitro

1. Intracellularly recorded neurones in nucleus reticularis pontis caudalis of the medial pontine reticular formation (mPRF) in the in vitro slice preparation were analysed for repetitive firing properties in response to intracellularly applied constant-current pulses. 2. Three neuronal classes were defined by this procedure: (1) non-burst neurones, which had only a non-burst firing pattern; (2) low-threshold burst neurones, which had either a low-threshold burst pattern or a non-burst pattern; (3) high-threshold burst neurones, which had either a high-threshold burst pattern or a non-burst pattern. 3. Histological characterization of electrophysiologically identified mPRF neurones with carboxyfluorescein showed no definite morphological difference between the first two classes. There was a trend for low-threshold burst neurones to have larger somata. 4. The low-threshold burst was generated by a slow calcium-dependent low-threshold spike, revealed in the presence of tetrodotoxin. The size of the low-threshold spike and thus the number of fast action potentials in the low-threshold burst was controlled by at least five factors including: activation; inactivation; amplitude of low-threshold conductance available to be activated; delayed outward conductance; and early transient outward conductance. 5. The non-burst pattern examined in both non-burst and low-threshold burst neurones appeared to be controlled primarily by one or more calcium-dependent potassium conductances sensitive to the removal of calcium and tetraethyl-ammonium. In the presence of tetrodotoxin (TTX), the addition of antagonists to calcium-dependent potassium current revealed a slow high-threshold calcium spike which was distinguished from the low-threshold spike by its threshold, lack of inactivation (at potentials negative to -40 mV) and insensitivity to Mg2+. A long-duration after-hyperpolarization (greater than 0.5 s) was not observed in any of these cells. 6. An early transient outward rectification sensitive to 4-aminopyridine and probably mediated by A-current was apparent in low-threshold burst and non-burst neurones and affected both the low-threshold burst and non-burst firing patterns. 7. Alteration of resting membrane potential, such as occurs in vivo during the depolarization associated with desynchronized sleep, may inactivate the low-threshold spike and the transient outward conductance responsible for the distinctive responses observed from more hyperpolarized membrane potentials and produce a more homogeneous non-burst response pattern. Membrane potential effects on intrinsic conductances thus may furnish an important mechanism for changes in mPRF neuronal responsivene

Cholinergic activation of medial pontine reticular formation neurons in vitro

Direct microinjection of cholinergic compounds into pontine reticular formation furnishes an excellent phenomenological model of the rapid eye movement phase of sleep (REM), but the mechanisms underlying this effect and whether they mimic the cellular events of natural REM remain unknown. Data presented here from intracellular recordings in vitro in the rat demonstrate that two-thirds of medial pontine reticular formation neurons respond to application of 0.5-1.0 microM carbachol with a depolarization characterized by a decreased conductance and a linear I/V curve. The resultant mimicry of REM cellular events by carbachol extends to membrane potential depolarization, increased cellular excitability, enhancement of PSPs from reticular stimulation, and the absence of a burst discharge pattern. The presence of these effects with tetrodotoxin and their blockade by atropine imply a direct, muscarinic cholinergic mediation. Other neurons tested responded with either a biphasic hyperpolarization-depolarization or a hyperpolarization. The hyperpolarization was associated with an increased conductance which exhibited pronounced inward rectification, an effect novel for cholinergic agonists in vertebrate CNS but described in heart cells.

Cholinergic activation of medial pontine reticular formation neurons in vitro

In vivo microinjections of cholinergic compounds into the medial pontine reticular formation have produced some or depending on the injection site, all of the phenomena of REM, thus providing the only adequate pharmacological model of this behavioral state. The necessary anatomical substrate, a cholinergic projection to the mPRF was recently demonstrated, however the direct effect of cholinergic agonists on mPRF neurons is unknown. We have examined the effects of carbachol on mPRF neurons recorded in vitro from brainstem slices of Sprague-Dawley rats (8-10 days old). Three kinds of response to the application of carbachol (0.5-1 microM) were observed (n = 15) as follows: a depolarizing response (67%), a hyperpolarizing response (20%) and a biphasic response consisting of a hyperpolarizing response followed by a depolarizing response (13%). Under voltage clamp control, the depolarizing response was observed as an inward current resulting from a decrease in conductance which was constant over the membrane potential range of -100 to -50 mV. Reversal potential was negative to -80 mV. An increase in the excitability of neurons (as measured by responses to identical intracellularly applied depolarizing current pulses) during the depolarizing responses was due to the increase in steady state inward current. When intracellular DC current of equal amplitude but opposite polarity was applied, no increase in excitability was observed. This response was always blocked by the addition of atropine (0.5-1 microM) to the perfusate. The hyperpolarizing response was observed as an increase in outward current due to an increase in conductance with marked voltage sensitivity (over the range of -100 to -50 mV) characteristic of the anomalous rectifier. Preliminary data indicated that the hyperpolarizing response was more sensitive to pirenzepine (complete blockade at 1.0 microM) than the depolarizing response (complete blockade at 2 microM) but neither response was affected by pirenzepine concentrations of 200 nM or less. Cholinergic effects on evoked depolarizing PSPs were examined on neurons with depolarizing (n = 3) and biphasic (n = 1) responses and in all cases, the PSPs were enhanced. This enhancement was blocked by atropine. In conclusion, it is suggested that activation of two different muscarinic receptors (neither of which is the M1 receptor) on mPRF neurons results in two different responses, a decrease in a voltage-insensitive potassium conductance and an increase in the anomalous rectifier.

Endogenous adenosine inhibits hippocampal CA1 neurones: further evidence from extra- and intracellular recording

Extracellular and intracellular recordings from CA1 pyramidal neurones of rats in vitro were used to study the effects of endogenous and exogenously applied adenosine. The adenosine receptor antagonist, caffeine, enhanced the intracellular recorded e.p.s.p.-i.p.s.p. sequence evoked by stimulation of the stratum radiatum which is antagonized by exogenous adenosine. The late, potassium dependent i.p.s.p. was not antagonized. The adenosine uptake inhibitor, nitrobenzylthioinosine (NBTI), mimicked the effects of exogenously applied adenosine. The effects of NBTI and of exogenously applied adenosine were antagonized by caffeine in the same manner. Exposure to adenosine deaminase enhanced the evoked field e.p.s.p. During this enhancement caffeines effects were significantly reduced. In low calcium high magnesium medium which abolishes synaptic activity, adenosine deaminase increased, NBTI decreased cell firing. We conclude that endogenous adenosine, release by a calcium independent mechanism, can exert an inhibitory tone on CA1 neurones in vitro. This is consistent with a role for adenosine as a mediator of negative feedback between the metabolic state and electrophysiological activity of nervous tissue.

Action and location of neuropeptide tyrosine (Y) on hippocampal neurons of the rat in slice preparations

The action of bath applied NPY (1-1,000 nM) was investigated on hippocampal slices of the rat with extra- and intracellular recording. Neuropeptide Y (NPY) at 10-1,000 nM caused a concentration-dependent, long-lasting reduction of excitatory postsynaptic potentials (EPSPs) in the hippocampal subfield CA1 and the area dentata, and an even stronger reduction of population spikes. Paired pulse experiments with low intensity, stimulation-evoked PSPs showed a marked increase in facilitation in the presence of NPY, indicating a presynaptic action. Spontaneous burst firing of CA1 pyramidal cells in low calcium, high magnesium medium was reduced, indicating a partially postsynaptic inhibitory action of NPY on their dendrites. Intracellular recording from CA1 somata during NPY administration revealed a reduction of the amplitudes of excitatory-inhibitory postsynaptic potential (EPSP-IPSP) sequences in the absence of changes in membrane potential and conductance. Accommodation of firing during long depolarizing pulses and afterhyperpolarizations were unchanged. The innervation pattern of NPY immunoreactive fibers in the same regions was studied in slices adjacent to the ones used for electrophysiology by using antisera against NPY and light and electron microscopy. There is a dense innervation of CA1 by NPY-immunoreactive axons and terminals, particularly in the stratum moleculare. NPY-immunoreactive neurons are present in the stratum oriens and pyramidale. The NPY labeled axons of the stratum moleculare participate in numerous synaptic contacts with the smaller dendritic elements in this layer, many of which belong to pyramidal neurons. These observations provide evidence for a dendritic NPY-immunoreactive innervation of CA1 neurons, which is in keeping with the electrophysiological effects of NPY on pyramidal neurons.(ABSTRACT TRUNCATED AT 250 WORDS)