Lesion-induced synaptogenesis in the dentate gyrus of aged rats: I. Loss and reacquisition of normal synaptic density.

Quantitative electron microscopy was used to examine the ability of aged (2-year-old) and young adult (90-day-old) rats to replace those synapses lost (85-90%) in the outer two-thirds of the molecular layer of the dentate gyrus after a complete unilateral lesion of the entorhinal cortex. In aged rats the synaptic density is significantly lower than that of young adults at 10 days postlesion. Synaptic replacement begins between 2 and 4 days postlesion in young adults, whereas there is a delay until after 10 days postlesion in aged rats. Once synapse replacement begins in aged rats, the rate of synapse reappearance is about equal that of young adults. Thus the initial 10 days postlesion appears critical to growth of responding afferents and reformation of synaptic contacts. Analysis of synapses in terms of noncomplex and complex synaptic types shows that the noncomplex type accounts for the significant synaptic density difference between the two age groups. Replacement of complex synapses is nearly indistinguishable between age groups and is complete by 60 days postlesion. In contrast the initial replacement rate of noncomplex synapses in aged rats is much slower than young adults, though the control synaptic density is achieved by the end of the time course.

Characterization of cholinergic and noradrenergic slow excitatory postsynaptic potentials from rat cerebral cortical neurons.

Intracellular recordings from layer V pyramidal neurons in rat somatosensory neocortical slices were used to investigate the effects of electrically stimulating slices known to contain cholinergic and noradrenergic fibers. Repetitive electrical stimulation ventral to the recording site elicited a series of fast excitatory postsynaptic potentials followed by an inhibitory postsynaptic potential. These potentials were followed by a slow excitatory postsynaptic potential that lasted up to tens of seconds. The slow excitatory postsynaptic potential was more prominent when neurons were depolarized to 5-10 mV below firing threshold and was associated with increased input resistance and generated action potentials. The slow excitatory postsynaptic potential increased the amplitude of membrane potential oscillations and blocked the slow afterhyperpolarization which followed trains of action potentials. The amplitude of the slow excitatory postsynaptic potential was sensitive to extracellular potassium concentration. Blockade of postsynaptic action potentials by QX-314 did not block slow excitatory postsynaptic potentials. Exposure of slices to tetrodotoxin did block slow excitatory postsynaptic potentials, indicating they were dependent on propagated action potentials. Application of antagonists of glutamate and fast GABA responses failed to block slow excitatory postsynaptic potentials. Exposure to atropine or either propranolol or atenolol partially antagonized slow excitatory postsynaptic potentials, but only when atropine was added in combination with one of the other agents was the slow excitatory postsynaptic potential completely blocked. Exposure of slices to eserine, imipramine, or cocaine enhanced slow excitatory postsynaptic potentials. It is concluded that the slow excitatory postsynaptic potential triggered in neocortical slices is a composite of a cholinergic and a noradrenergic slow excitatory postsynaptic potential, and these potentials are capable of altering the firing properties of neurons for tens of seconds.

N-methyl-D-aspartate transmission modulates GABAB-mediated inhibition of rat hippocampal pyramidal neurons in vitro.

Slow inhibition was investigated by stimulating inhibitory neurons at the border of stratum radiatum and lacunosum-moleculare with focal microapplications of glutamate, while recording resultant slow inhibitory postsynaptic potentials in CA1 pyramidal neurons in rat hippocampal slices. The slow inhibitory postsynaptic potentials evoked had an average peak amplitude of -2.2 mV, measured at -60 mV. Their peak conductance was 2.5 nS. These events were characterized as slow GABAB inhibitory postsynaptic potentials because they reversed at -90 mV, and were blocked by CGP 35348 (500 microM). Exposure to magnesium-free solutions augmented glutamate-evoked slow inhibitory postsynaptic potentials. Mean peak amplitude and conductance were -3.1 mV and 4.0 nS. Exposure to the N-methyl-D-aspartate antagonist MK-801 (20 microM) allowed separation of the glutamate-triggered slow inhibitory postsynaptic potential into components induced by non-N-methyl-D-aspartate and N-methyl-D-aspartate receptor activation. The N-methyl-D-aspartate component dominated, even under control conditions, and could account for up to 60% of the control slow inhibitory postsynaptic potential. Thus, the activation and recruitment of GABAB-mediated inhibition depend on both non-N-methyl-D-aspartate and N-methyl-D-aspartate-mediated excitation of inhibitory interneurons. Under physiological conditions slow inhibition may act as an important synaptic filtering mechanism, but when N-methyl-D-aspartate-mediated excitation increases, slow inhibition is further recruited, providing an important means to offset excessive excitation.

Properties of isolated GABAB-mediated inhibitory postsynaptic currents in hippocampal pyramidal cells.

Whole-cell recording techniques were used to record isolated slow inhibitory postsynaptic currents in CA1 pyramidal neurons from rat hippocampal slices. Application of 6-cyano-7-nitroquinoxaline-2,3-dione and 3-(2-carboxypiperazin-4-yl)propyl-1-phosphonic acid eliminated excitatory synaptic transmission, resulting in a 38% reduction in slow inhibitory postsynaptic current magnitude. Subsequent addition of the GABAA antagonist picrotoxin caused a further decrease in slow inhibitory postsynaptic current amplitude. The remaining, isolated slow inhibitory postsynaptic current was blocked by the GABAB antagonist 2-hydroxysaclofen and when cesium was substituted for intracellular potassium. The kinetics of isolated slow inhibitory postsynaptic currents were characterized by single exponential, fourth power activation, and double exponential inactivation. These slow inhibitory postsynaptic currents had a reversal potential of -85.7 +/- 1.6 mV, and a slope conductance of 935 +/- 277 pS. Single slow inhibitory postsynaptic currents carried a total charge flux of 13.4 +/- 7.6 pC. Repetitive stimulation up to 1 Hz progressively reduced steady-state slow inhibitory postsynaptic current amplitude. This attenuation was characterized by a decrease in slope conductance, but slow inhibitory postsynaptic current reversal potential remained unchanged, as did slow inhibitory postsynaptic current kinetics. These results indicate that, under physiological conditions, both ionotropic glutamate- and GABAA-mediated transmission contribute to slow inhibitory postsynaptic current recruitment. Given this finding, activity-dependent decreases in GABAA transmission could contribute to slow inhibitory postsynaptic current depression, though not exclusively, since isolated slow inhibitory postsynaptic currents also demonstrated this property. The use-dependent depression of isolated slow inhibitory postsynaptic currents may be a consequence of a reduction in transmitter release.

Cholinergic pharmacology of mammalian hippocampal pyramidal cells.

Responses of CAl pyramidal cells to cholinergic compounds were recorded with intracellular microelectrodes in guinea-pig hippocampal slices. Perfusion of slices with medium containing the muscarinic antagonists atropine or scopolamine (10(-7)-10(-6)M) blocked all actions of acetylcholine. Properties of control neurons and those from separate populations of neurons impaled in slices exposed to muscarinic blocking agents were compared. 1-2 h of perfusion with atropine-containing media significantly decreased membrane input resistance from 37.6 +/- 8.7 (S.D.) M omega (n = 74) to 21.9 +/- 7.7 (S.D.) M omega (n = 24) without producing significant changes in membrane potential. Muscarinic antagonists also reduced or eliminated the anomalous inward rectification normally seen in hippocampal pyramidal neurons. Exposure of slices to 10(-5)-10(-6)M eserine for about 1 h produced changes in neuronal membrane input resistance and potential and slow after hyperpolarizations similar to those elicited by application of acetylcholine. Bethanechol mimicked the actions of acetylcholine but was effective at lower concentrations and had longer lasting effects on afterhyperpolarizations. Nicotine produced an excitatory response in only one of 7 neurons. These experiments demonstrate that the actions of acetylcholine on hippocampal CAl neurons result from interaction with muscarinic receptors. Acetylcholine has modulatory effects on cell membrane properties which may be mediated through tonic release mechanisms.

Laminar properties of 4-aminopyridine-induced synchronous network activities in rat neocortex.

We examined the effects of 4-aminopyridine (4-AP) on isolated horizontal (superficial, middle and deep) rat neocortical slices in order to study laminar synchronous network behavior directly. Application of 4-AP induced spontaneous synchronized activity in all of these types of slices. In middle and deep layer slices the activities were similar to those of coronal slices, consisting of periodic short- and long-duration discharges. In superficial slices distinct spontaneous rhythmic multiphasic burst discharges were induced. Ionotropic glutamate receptor antagonists blocked the 4-AP-induced synchronous activities in middle and deep layer slices, but those in superficial slices persisted. The GABA(A) receptor antagonist picrotoxin suppressed this spontaneous synchronous activity resistant to 3-(2-carboxypiperazin-4-yl)propyl-1-phosphonic acid (a NMDA receptor antagonist) and 6-cyano-7-nitroquinoxaline-2,3-dione (a non-NMDA receptor antagonist), in superficial slices, leaving small, slow spontaneous events. In superficial slices with intact excitatory amino acid transmission, picrotoxin attenuated the 4-AP-induced spontaneous synchronous discharges, even in this highly convulsant environment. By contrast, conventional coronal slices showed robust spontaneous epileptiform discharges under these circumstances. In intact coronal slices focal 4-AP application in superficial layers induced spontaneous inhibitory GABAergic events, while delivery into deep layers led to epileptiform discharges. From these results we conclude that: (1) 4-AP-induced population discharges are driven by glutamatergic transmission in middle and deep layer horizontal slices, and by GABAergic transmission in superficial layers; (2) only superficial layers are capable of supporting synchronized GABAergic activity independent of excitatory amino acid transmission; (3) superficial layers do not sustain epileptiform activity in the absence of deep layer neurons; and (4) synchronized superficial networks can inhibit deep layer neuronal activity.

GABAA receptor-mediated mechanisms contribute to frequency-dependent depression of IPSPs in the hippocampus.

Intracellular recordings from in vitro guinea-pig hippocampal slices were obtained to investigate the mechanisms underlying activity-dependent depression of inhibitory postsynaptic potentials (IPSPs) in CA1 pyramidal neurons. IPSPs were studied following blockade of glutamatergic transmission. Attenuation of both fast and slow IPSP components was apparent at stimulus rates of > 0.2 Hz, but the late IPSP showed depression at even lower rates of stimulation. Overlap of these events made resolving response components during depression difficult. Fast IPSPs were isolated using CsCl-filled microelectrodes, blocking slow potassium-dependent IPSPs and reversing the chloride gradient. Under this condition repetitive stimulation did not induce IPSP depression. Other experiments showed slow IPSP depression at stimulus rates of < 0.5 Hz was relieved in the presence of picrotoxin which antagonizes GABAA events. These results suggest that activity-dependent depression of the fast IPSP results largely from chloride accumulation as a consequence of repetitive activation. Depression of the slow IPSP appears to arise from at least two components: (1) a masking of the slow hyperpolarization resulting from an apparent increase in the depolarizing GABA response due to chloride accumulation; and (2) a novel process involving GABAA receptors, perhaps mediated through presynaptic inhibition.

Recruitment of inhibition by enhanced activation of synaptic NMDA responses in the rat cerebral cortex.

Intracellular recordings of layer V neurons from rat neocortical slices were obtained to examine the effects of reducing extracellular magnesium on inhibition. Magnesium-free solutions induced interictal and ictal-like events in cortical neurons. Changes in synaptic events underlying epileptogenesis were studied when extracellular calcium was raised (from 2 to 3-7 mM) since this delayed seizure activity. With increasing time of exposure of cells to magnesium-free solutions, there was a significant increase in the size and duration of both the depolarizing and slow synaptic hyperpolarizing responses, but the fast synaptic hyperpolarization significantly declined in amplitude. When cells were recorded with cesium acetate-filled microelectrodes slow hyperpolarizing responses were blocked, but depolarization of cells to 0 mV allowed an isolated fast hyperpolarizing response to be recorded following synaptic stimulation. The amplitude of this response was unchanged after exposure to magnesium-free solutions. Synaptic responses of cells initially bathed in an N-methyl-D-aspartate (NMDA) antagonist (CPP) were unchanged by subsequent exposure to magnesium-free solutions. CPP exposure by itself caused a decrease in depolarization duration, increase in fast hyperpolarizing amplitude, and decrease in slow hyperpolarization amplitude and duration. When the fast hyperpolarization was viewed in isolation (cesium recording electrodes) at 0 mV, the amplitude of this event was unchanged by exposure to CPP. Given these results stimulus-response characteristics of neocortical neurons were reassessed under control conditions. With higher intensity stimuli larger depolarizing and slow hyperpolarizing responses were evoked, but the fast hyperpolarization showed a decremental response. These effects were reversed when CPP was added. When NMDA activity was enhanced by exposure to magnesium-free solutions or electrical stimulation, the amplitude of excitatory events and slow hyperpolarizations increased, but fast inhibitory responses showed limited capacity for incremental recruitment. This suggests fast inhibition is saturated (maximal) at submaximal levels of excitation, and can be overcome by increasing levels of excitation. Such a process is active under physiological conditions, altering the efficacy of inhibition.

Acetylcholine induced modulation of hippocampal pyramidal neurons.

Applications of acetylcholine to hippocampal slices maintained in vitro resulted in slow depolarizations and simultaneous increases in membrane resistance (RN)in hippocampal pyramidal neurons. Increases in RN had both voltage dependent and voltage independent components. These effects were associated with increases in cell discharge frequency, and development of spontaneous as well as synaptically and directly evoked burst discharges. The increase in RN and burst firing lasted for hours. Muscarinic antagonists blocked these actions and in addition, produced a decrease in membrane resistance, which appeared to be due to blockade of a tonic effect of acetylcholine on postsynaptic membrane properties. These findings suggest that ACh acts as a neuromodulator in the hippocampus.

Activity-dependent depression of monosynaptic fast IPSCs in hippocampus: contributions from reductions in chloride driving force and conductance.

Whole-cell recordings techniques were used to record pharmacologically isolated fast inhibitory postsynaptic currents (IPSCs) in CA1 pyramidal neurons from rat hippocampal slices. Repetitive extracellular stimulation up to 10 Hz progressively reduced steady-state fast IPSC amplitude. At low stimulation frequencies (up to 1 Hz), this attenuation was characterized by a positive shift of IPSC reversal potential with no change in IPSC conductance. Above 1 Hz stimulation, fast IPSC depression was associated with changes in both reversal potential and IPSC conductance. Use-dependent depression at low frequencies was prevented when cells were chloride-loaded using cesium chloride based intracellular solutions. These findings suggest that activity-dependent depression of fast IPSCs at low stimulus frequencies results entirely from a reduction in chloride driving force, stemming from intracellular chloride accumulation. Activity-dependent changes in fast IPSC conductance occur only at stimulation rates above 1 Hz.

Cholinergic excitation of mammalian hippocampal pyramidal cells.

Responses of CA1 pyramidal neurons to ACh were recorded with intracellular microelectrodes utilizing the in vitro guinea pig hippocampal slice preparation. ACh was delivered by drop or iontophoretic application to stratum oriens or stratum radiatum. Threshold dose for drop application was 1 mM. An initial hyperpolarization of 3.1 +/- 1.8 (S.D.) mV associated with a decrease in membrane input resistance (RN) of 21 +/- 9% (S.D.) occurred in about half the cells. This result is consistent with a presynaptic action of ACh mediated through excitation of inhibitory interneurons. This interpretation was supported by recordings of cholinergic excitatory responses from presumed interneurons, and repetitive spontaneous IPSPs from pyramidal neurons during the hyperpolarization. ACh evoked a slow depolarization (14.3 +/- 10.8 (S.D.) mV) accompanied by a peak increase in apparent input resistance (Ra) of about 60% in the majority of cells. Large increases in spike frequency were associated with these events but action potential shape was unchanged. Plots of Ra versus membrane potential following ACh application revealed that Ra increases were proportionately higher at depolarized membrane potential levels (less than or equal to -70 mV) in some neurons. In these cells Ra was increased significantly at -60 mV (28%), but only 6% at -75 mV. These results are consistent with the conclusion that ACh reduces a voltage-dependent gK, distinct from delayed rectification. ACh also induced a non-voltage-dependent increase in Ra in some cells. ACh-evoked changes in Ra were long-lasting and gave rise to alterations in firing mode, with development of burst generation. ACh also transiently blocked after hyperpolarizations which followed spike trains in pyramidal neurons and presumed interneurons, an action which may be related to effects on a Ca2+-activated gK.

Ionic mechanisms of cholinergic excitation in mammalian hippocampal pyramidal cells.

Intracellular recordings from CA1 hippocampal pyramidal neurons were obtained using the in vitro hippocampal slice preparation. Responses to ACh were monitored in the presence of blockers of voltage-dependent conductances including Mn2+, TTX and Ba2+. When Mn2+ was used to block voltage-dependent Ca conductance and possible indirect presynaptic cholinergic actions, ACh still induced a significant voltage-sensitive increase in apparent input resistance (Ra) (29%), but only an insignificant depolarization of membrane potential (Vm). When both voltage-dependent Ca and Na conductances were blocked by application of Mn2+ and TTX, respectively, ACh produced voltage-dependent increases in Ra (31%) without significant depolarization. In solutions containing TTX alone, ACh produced voltage-sensitive increases in Ra (32%) as well as a significant depolarization (6.2 +/- 3.1 mV (S.D.)). ACh transiently blocked the conductance increase which followed presumed Ca spikes, suggesting an action on the Ca-activated K-dependent conductance. The effects of Ba2+ application (100-200 microM) on Ra mimicked those of ACh. When ACh was applied to neurons in the presence of Ba2+, Ra remained unchanged, although Vm depolarization of 5-15 mV was still seen. The data indicate that ACh decreases both a voltage-dependent K conductance (distinct from that of the delayed rectifier) and a Ca-activated K conductance. Muscarinic cholinergic depolarization occurs as a result of blockade of K conductance, and is mediated by voltage-dependent Ca and Na conductances, and perhaps by presynaptic actions.

Decline in reactive fiber growth in the dentate gyrus of aged rats compared to young adult rats following entorhinal cortex removal.

The reaction of septal and commissural-associational afferents in the dentate gyrus was examined at various times following a unilateral entorhinal lesion in 2- and 3-month-old, 12- to 18-month-old and 25--30-month-old rats. The response of septo-hippocampal fibers was examined histochemically by staining for acetylcholinesterase (AChE) activity; and that of commissural-associational fibers by the Holmes' fiber stain. In 2- and 3-month-old rats, AChE staining fibers, which project to the outer three-fourths of the molecular layer of the dentate gyrus, increased their staining intensity within 5--6 days following lesion of the entorhinal cortex. The rate of the response and the eventual magnitude declined progressively with the age of the subject. In 2- and 3-month-old rats, the commissural-associational fiber plexus appeared to expand partially into the entorhinal zone within 6 days following the lesion. This response also decreased progressively in rate and magnitude with age. Animals in the oldest age group showed at 12 days after the lesion a greater variability in the expansion of the commissural-associational fiber plexus than all younger groups. Astrocytes in the dentate molecular layer appeared to become more abundant and more hypertrophied in unoperated animals with age. The appearance of astrocytes in 25- to 30-month-old rats was similar to that seen in 2- and 3-month-old animals following an entorhinal lesion. An entorhinal lesion in the aged animals did not appear to cause a marked change in the appearance of astrocytes.

Variations in electrophysiological properties of hippocampal neurons in different subfields.

Intracellular recordings were made from hippocampal pyramidal cells (HPCs) in subregions CA1a, b, c, CA2 and CA3a, b of the guinea pig hippocampal slice. There were significant differences in the mode of spike discharge at various sites. Most neurons in CA1b and CA3b fired single spikes spontaneously, or during intracellular depolarizing current pulses. HPCs in the CA1a and c, as well as CA2 and CA3a subregions usually had a burst mode of discharge under the same conditions. Basic differences in neuronal properties presumably underlie these varieties of behavior between or within various regions. Specification of the site or subregion of recording is important especially in those experiments where the mode of spike discharge or membrane events in HPCs are important variables.

Acetylcholine and norepinephrine mediate slow synaptic potentials in normal and epileptic neocortex.

Slow excitatory postsynaptic potentials (EPSPs) were identified in rat neocortical slices. Such potentials, resistant to blockade of glutamate and gamma-aminobutyric acid-A (GABAA) receptors, were partially antagonized by muscarinic or beta-adrenergic antagonists separately, and completely blocked when these agents were added in combination. Slow EPSPs were enhanced by a cholinesterase inhibitor or catecholamine reuptake blockers. Spontaneous epileptic discharges induced by picrotoxin also triggered slow EPSPs. Such potentials were pharmacologically identical to those induced by electrical stimulation under normal conditions. A non-conventional mechanism for synaptic transmission is postulated to account for triggering of slow EPSPs by epileptic discharges.

Removal of superficial inhibition releases hyperexcitability in middle and deep horizontal slices from rat somatosensory neocortex.

Synaptic physiology was studied in horizontal slices of rat somatosensory neocortex. Intrinsic properties of pyramidal neurons from horizontal slices resembled those recorded in cells from coronal slices, but cells in superficial horizontal slices displayed more prominent fast and slow inhibition, while cells from deeper slices showed disinhibition. This disinhibition in deeper horizontal slices resulted in epileptogenesis in 81% of middle and 35% of deep layer horizontal slices. Brief exposure to glutamate antagonists and dantrolene was ineffective in preventing epileptic activity, but limited pentobarbital exposure reduced the proportion of deep slices manifesting epileptiform activity by 75%. Thus, within cortex inhibition dominates superficially and excitation predominates in deeper layers. While the cortex is vulnerable to hyperexcitability when superficial cortex is compromised, enhancing fast inhibition can reset the excitation-inhibition balance, and prevent epileptogenesis.

Oscillatory behavior in inferior olive neurons: mechanism, modulation, cell aggregates.

Inferior olive neurons, in brain slices maintained in vitro, display spontaneous, continuous oscillations of their membrane potential which are consonant with olivary rhythmic activity seen in vivo. This oscillatory behavior was studied with intracellular electrophysiological techniques. The 3-10 Hz rhythmicity of these cells from guinea pigs is tetrodotoxin resistant and dependent on a somatic calcium conductance. The oscillatory behavior can exhibit intrinsic frequency modulation and can be altered by synaptic processes. Synaptic alteration of the oscillatory behavior by afferent sources and extensive electrotonic coupling between cells in local aggregates (shown by Lucifer yellow dye-coupling) provide the substrate for a potent central pattern generator with a well established efferent pathway for control of motor functions.

An in vitro model of persistent epileptiform activity in neocortex.

An in vitro model of persistent epileptiform activity was developed to study the mechanisms involved in epileptogenesis. Extracellular recordings were obtained from rat neocortical slices exposed to magnesium-free solution for 2 h. During exposure to magnesium-free solution spontaneous epileptiform activity consisting of interictal bursting and ictal-like discharges were observed. Interestingly, this activity persisted for hours after the slices were returned to magnesium-containing control solution. The N-methyl-D-aspartate (NMDA) receptor antagonist CPP prevented the development of the epileptiform activity, while the non-NMDA receptor antagonist CNQX abolished the epileptiform discharge that persisted after slices were returned to control solution. These findings suggest there are two distinct phases in the development of epileptic activity in this model, namely, induction (mediated by NMDA receptor activity) and maintenance (supported largely by non-NMDA receptor activity). The similarities and possible parallels between the mechanisms underlying this epileptogenesis and other forms of use-dependent modification of synaptic excitation, such as long-term potentiation, are discussed. This in vitro model of neocortical epileptogenesis may provide insights into the events underlying the development of clinical partial epilepsy.