Calcium/calmodulin-dependent protein kinase II clusters in adult rat hippocampal slices.

We have previously reported the formation of calcium/calmodulin-dependent protein kinase II (CaMKII) clusters approximately 110 nm in diameter in hippocampal neurons in culture and in the intact adult brain, under conditions that simulate ischemic stress and increase [Ca(2+)](i) [Dosemeci et al. (2000) J. Neurosci. 20, 3076-3084; Tao-Cheng et al. (2001) Neuroscience 106, 69-78]. These observations suggest that ischemia-like conditions that prevail during the dissection of brain tissue for the preparation of hippocampal slices could lead to the formation of CaMKII clusters. We now show by pre-embedding immuno-electron microscopy that, indeed, CaMKII clusters are present in the CA1 pyramidal neurons in hippocampal slices from adult rats fixed immediately after dissection, and that the number of CaMKII clusters increases with the delay time between decapitation and fixation. Moreover, CaMKII clusters are typically localized near the endoplasmic reticulum. When acute slices are allowed to recover in oxygenated medium for 2 h, CaMKII clusters mostly disappear, indicating that clustering is reversible. Also, the postsynaptic density, another site for CaMKII accumulation under excitatory conditions, becomes thinner upon recovery. Treatment of recovered slices with high potassium for 90 s causes the re-appearance of CaMKII clusters in nearly all CA1 pyramidal cells examined. On the other hand, when dissociated hippocampal neurons in primary culture are exposed to the same depolarizing conditions, only approximately 25% of neurons exhibit CaMKII clusters, indicating a difference in the susceptibility of the neurons in culture and in acute slices to excitatory stimuli. Altogether these observations indicate that the effect of CaMKII clustering should be considered when interpreting experimental results obtained with hippocampal slices.

BDNF enhances quantal neurotransmitter release and increases the number of docked vesicles at the active zones of hippocampal excitatory synapses.

Brain-derived neurotrophic factor (BDNF) is emerging as a key mediator of activity-dependent modifications of synaptic strength in the CNS. We investigated the hypothesis that BDNF enhances quantal neurotransmitter release by modulating the distribution of synaptic vesicles within presynaptic terminals using organotypic slice cultures of postnatal rat hippocampus. BDNF specifically increased the number of docked vesicles at the active zone of excitatory synapses on CA1 dendritic spines, with only a small increase in active zone size. In agreement with the hypothesis that an increased docked vesicle density enhances quantal neurotransmitter release, BDNF increased the frequency, but not the amplitude, of AMPA receptor-mediated miniature EPSCs (mEPSCs) recorded from CA1 pyramidal neurons in hippocampal slices. Synapse number, independently estimated from dendritic spine density and electron microscopy measurements, was also increased after BDNF treatment, indicating that the actions of BNDF on mEPSC frequency can be partially attributed to an increased synaptic density. Our results further suggest that all these actions were mediated via tyrosine kinase B (TrkB) receptor activation, established by inhibition of plasma membrane tyrosine kinases with K-252a. These results provide additional evidence of a fundamental role of the BDNF-TrkB signaling cascade in synaptic transmission, as well as in cellular models of hippocampus-dependent learning and memory.

Microheterogeneity of calcium signalling in dendrites.

Transient changes in the intracellular concentration of free Ca2+ ([Ca2+]i) originating from voltage- or ligand-gated influx and by ligand- or Ca2+-gated release from intracellular stores, trigger or modulate many fundamental neuronal processes, including neurotransmitter release and synaptic plasticity. Of the intracellular compartments involved in Ca2+ clearance, the endoplasmic reticulum (ER) has received the most attention because it expresses Ca2+ pumps and Ca2+ channels, thus endowing it with the potential to act as both an intracellular calcium sink and store. We review here our ongoing work on the role of calcium sequestration into, and release from, ER cisterns and the role that this plays in the generation and termination of free [Ca2+]i transients in dendrites of pyramidal neurons in hippocampal slices during and after synaptic activity. These studies have been approached by combining parallel microfluorometric measurements of free cytosolic [Ca2+]i transients with energy-dispersive X-ray microanalytical measurements of total Ca content within specific dendritic compartments at the electron microscopy level. Our observations support the emerging realization that specific subsets of dendritic ER cisterns provide spatial and temporal microheterogeneity of Ca2+ signalling, acting not only as a major intracellular Ca sink involved in active clearance mechanisms after voltage- and ligand-gated Ca2+ influx, but also as an intracellular Ca2+ source that can be mobilized by a signal cascade originating at activated synapses.

Calcium signals in long-term potentiation and long-term depression.

We describe postsynaptic Ca2+ signals that subserve induction of two forms of neuronal plasticity, long-term potentiation (LTP) and long-term depression (LTD), in rat hippocampal neurons. The common induction protocol for LTP, a 1-s, 50-Hz tetanus, generates Ca2+ increases of about 50-Hz in dendritic spines of CA1 neurons. These very large increases, measured using a low affinity indicator (Mg fura 5), were found only in the spines and tertiary dendrites, and were dependent upon influx through N-methyl-D-aspartate (NMDA) gated channels. High affinity Ca2+ indicators (e.g., fura 2) are unable to demonstrate these events. In acute slices, neighboring dendritic branches often showed very different responses to a tetanus, and in some instances, neighboring spines on the same dendrite responded differently. LTD in mature CA1 neurons was induced by a low frequency stimulus protocol (2 Hz, 900 pulses), in the presence of GABA- and NMDA-receptor blockers. This LTD protocol produced dendritic Ca2+ increases of <1 microM. Duration of the Ca2+ increase was approximately 30 s and was due to voltage-gated Ca2+ influx. Finally, the ability of synaptically addressed Ca2+ stores to release Ca2+ was studied in CA3 neurons and was found to require immediate preloading and high intensity presynaptic stimulation, conditions unlike normal LTP-LTD protocols.

Correlated measurements of free and total intracellular calcium concentration in central nervous system neurons.

Transient changes in the intracellular concentration of free calcium ([Ca2+])i) act as a trigger or modulator for a large number of important neuronal processes. Such transients can originate from voltage- or ligand-gated fluxes of Ca2+ into the cytoplasm from the extracellular space, or by ligand- or Ca2+(-)gated release from intracellular stores. Characterizing the sources and spatio-temporal patterns of [Ca2+]i transients is critical for understanding the role of different neuronal compartments in dendritic integration and synaptic plasticity. Optical imaging of fluorescent indicators sensitive to free Ca2+ is especially suited to studying such phenomena because this approach offers simultaneous monitoring of large regions of the dendritic tree in individual living central nervous system neurons. In contrast, energy-dispersive X-ray (EDX) microanalysis provides quantitative information on the amount and location of intracellular total, i.e., free plus bound, calcium (Ca) within specific subcellular dendritic compartments as a function of the activity state of the neuron. When optical measurements of [Ca2+]i transients and parallel EDX measurements of Ca content are used in tandem, and correlated simultaneously with electrophysiological measurements of neuronal activity, the combined information provides a relatively general picture of spatio-temporal neuronal total Ca fluctuations. To illustrate the kinds of information available with this approach, we review here results from our ongoing work aimed at evaluating the role of various Ca uptake, release, sequestration, and extrusion mechanisms in the generation and termination of [Ca2+]i transients in dendrites of pyramidal neurons in hippocampal slices during and after synaptic activity. Our observations support the long-standing speculation that the dendritic endoplasmic reticulum acts not only as an intracellular Ca2+ source that can be mobilized by a signal cascade originating at activated synapses, but also as a major intracellular Ca sink involved in active clearance mechanisms after voltage- and ligand-gated Ca2+ influx.

Impairments in high-frequency transmission, synaptic vesicle docking, and synaptic protein distribution in the hippocampus of BDNF knockout mice.

Brain-derived neurotrophic factor (BDNF) promotes long-term potentiation (LTP) at hippocampal CA1 synapses by a presynaptic enhancement of synaptic transmission during high-frequency stimulation (HFS). Here we have investigated the mechanisms of BDNF action using two lines of BDNF knockout mice. Among other presynaptic impairments, the mutant mice exhibited more pronounced synaptic fatigue at CA1 synapses during high-frequency stimulation, compared with wild-type animals. Quantitative analysis of CA1 synapses revealed a significant reduction in the number of vesicles docked at presynaptic active zones in the mutant mice. Synaptosomes prepared from the mutant hippocampus exhibited a marked decrease in the levels of synaptophysin as well as synaptobrevin [vesicle-associated membrane protein (VAMP-2)], a protein known to be involved in vesicle docking and fusion. Treatment of the mutant slices with BDNF reversed the electrophysiological and biochemical deficits in the hippocampal synapses. Taken together, these results suggest a novel role for BDNF in the mobilization and/or docking of synaptic vesicles to presynaptic active zones.

Estradiol increases spine density and NMDA-dependent Ca2+ transients in spines of CA1 pyramidal neurons from hippocampal slices.

To investigate the physiological consequences of the increase in spine density induced by estradiol in pyramidal neurons of the hippocampus, we performed simultaneous whole cell recordings and Ca2+ imaging in CA1 neuron spines and dendrites in hippocampal slices. Four- to eight-days in vitro slice cultures were exposed to 17beta-estradiol (EST) for an additional 4- to 8-day period, and spine density was assessed by confocal microscopy of DiI-labeled CA1 pyramidal neurons. Spine density was doubled in both apical and basal dendrites of the CA1 region in EST-treated slices; consistently, a reduction in cell input resistance was observed in EST-treated CA1 neurons. Double immunofluorescence staining of presynaptic (synaptophysin) and postsynaptic (alpha-subunit of CaMKII) proteins showed an increase in synaptic density after EST treatment. The slopes of the input/output curves of both alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) and N-methyl-D-aspartate (NMDA) postsynaptic currents were steeper in EST-treated CA1 neurons, consistent with the observed increase in synapse density. To characterize NMDA-dependent synaptic currents and dendritic Ca2+ transients during Schaffer collaterals stimulation, neurons were maintained at +40 mV in the presence of nimodipine, picrotoxin, and 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX). No differences in resting spine or dendritic Ca2+ levels were observed between control and EST-treated CA1 neurons. Intracellular Ca2+ transients during afferent stimulation exhibited a faster slope and reached higher levels in spines than in adjacent dendrites. Peak Ca2+ levels were larger in both spines and dendrites of EST-treated CA1 neurons. Ca2+ gradients between spine heads and dendrites during afferent stimulation were also larger in EST-treated neurons. Both spine and dendritic Ca2+ transients during afferent stimulation were reversibly blocked by D, L-2-amino-5-phosphonovaleric acid (D,L-APV). The increase in spine density and the enhanced NMDA-dependent Ca2+ signals in spines and dendrites induced by EST may underlie a threshold reduction for induction of NMDA-dependent synaptic plasticity in the hippocampus.

Presynaptic modulation of synaptic transmission and plasticity by brain-derived neurotrophic factor in the developing hippocampus.

In addition to the regulation of neuronal survival and differentiation, neurotrophins may play a role in synapse development and plasticity. Application of brain-derived neurotrophic factor (BDNF) promotes long-term potentiation (LTP) in CA1 synapses of neonatal hippocampus, which otherwise exhibit only short-term potentiation. This is attributable, at least in part, to an attenuation of the synaptic fatigue induced by high-frequency stimulation (HFS). However, the prevention of synaptic fatigue by BDNF could be mediated by an attenuation of synaptic vesicle depletion from presynaptic terminals and/or a reduction of the desensitization of postsynaptic receptors. Here we provide evidence supporting a presynaptic effect of BDNF. The effect of BDNF on synaptic fatigue depended on the stimulation frequency, not on the stimulus duration nor on the number of stimulation pulses. BDNF was only effective when the synapses were stimulated at frequencies >50 Hz. Treatment with BDNF also potentiated paired-pulse facilitation (PPF), a parameter reflecting changes in the properties of presynaptic terminals. This effect of BDNF was restricted only to PPF elicited with interpulse intervals

The first-order giant neurons of the giant fiber system in the squid: electrophysiological and ultrastructural observations.

The giant fiber system controlling mantle contraction used for jet propulsion in squid consists of two sets of three giant neurons organized in tandem. The somata of the 1st- and 2nd-order giant cells are located in the brain, while the perikarya of the 3rd-order giant cells are encountered in the stellate ganglia of the mantle. The somata and dendrites of one fused pair of 1st-order giant cells are thought to receive synaptic input from the eye, statocyst, skin proprioceptors, and supraesophageal lobes. To define the cellular properties for integration of such an extensive synaptic load, especially given its diversity, intracellular recordings and electron microscopic observations were performed on 1st-order giant cells in an isolated head preparation. Spontaneous bursts of action potentials and spikes evoked by extracellular stimulation of the brachial lobe were sensitive to the Na+ channel blocker TTX. Action potentials were also abolished by recording with microelectrodes containing the membrane impermeant, use dependent Na+ channel blocker QX-314. The small action potential amplitude and the abundant synaptic input imply that the spike initiation zone is remotely located from the recording site. The high spontaneous activity in the isolated head preparation, as well as the presence of synaptic junctions resembling inhibitory synapses, suggest; that afferent synapses on 1st-order giant neurons might represent the inhibitory control of the giant fiber system. The characterization of the electroresponsive properties of the 1st-order giant neurons will provide a description of the single cell integrative properties that trigger the rapid jet propulsion necessary for escape behavior in squid.

Activity-dependent calcium sequestration in dendrites of hippocampal neurons in brain slices.

Synaptic activity-dependent changes in the spatio-temporal distribution of calcium ions regulate important neuronal functions such as dendritic integration and synaptic plasticity, but the processes that terminate the free Ca2+ transients associated with these changes remain unclear. We have characterized at the electron microscopic level the intracellular compartments involved in buffering free Ca2+ transients in dendritic cytoplasm of CA3 neurons by measuring the larger changes in the concentrations of total Ca that persist for several minutes after neuronal activity. Quantitative energy-dispersive x-ray microanalysis of cryosections from hippocampal slice cultures rapidly frozen 3 min after afferent synaptic activity identified a subset of dendritic endoplasmic reticulum (ER) as a high-capacity Ca2+ buffer. Calcium sequestration by cisterns of this subset of ER was graded, reversible, and dependent on a thapsigargin-sensitive Ca2+-ATPase. Sequestration was so robust that after repetitive high-frequency stimulation the Ca content of responsive ER cisterns increased as much as 20-fold. These results demonstrate that a subpopulation of ER is the major dendritic Ca sequestration compartment in the minutes after neuronal activity.

Ca2+ release from intracellular stores induced by afferent stimulation of CA3 pyramidal neurons in hippocampal slices.

1. Ca2+ imaging and simultaneous intracellular recording were performed on CA3 pyramidal neurons in hippocampal slice cultures and standard acute slices. Both fura-2 and a dextran conjugate of fura-2 (MW = 10,000) were used in the Ca2+ measurements to control for compartmentalization artifacts. Experiments were performed under conditions giving minimal ligand- and voltagegated Ca2+ influx, with the use of competitive and noncompetitive antagonists of ionotropic glutamate receptors and steady-state depolarization, respectively. 2. Tetanic stimulation of stratum lucidum evoked dendritic Ca2+ transients with rapid onset that were blocked by the noncompetitive N-methyl-D-aspartate (NMDA) receptor antagonist, MK-801 (2-5 microM), but not by the competitive alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) receptor antagonist, 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX) (10-50 microM). Zn(2+)-containing mossy fiber terminals (assessed by Timm's staining) and postsynaptic structures (thorny excrescences) are preserved in s. lucidum of hippocampal slice cultures. 3. A Ca2+ store loading protocol, consisting of brief repolarizations followed by steady depolarization, primed most of the neurons so that a subsequent tetanus gave a Ca2+ increase in the presence of MK-801 that was reported by both fura-2 and the dextran conjugate. The onset of the Ca2+ increase was significantly delayed (by 2-3 s) with respect to the MK-801-sensitive increase, and often had a different spatial pattern within the neuron. Response characteristics were similar in slice cultures and acute slices. 4. The delayed Ca2+ increase showed a steep rundown with subsequent stimuli, but was restored by further priming by the Ca2+ store loading paradigm. Postsynaptic currents evoked by the tetani under these conditions were not correlated with the magnitude of the delayed Ca2+ transients. 5. Delayed Ca2+ increases were observed in 44% of the neurons dialyzed with normal intracellular solution at room temperature. The success rate of observing delayed Ca2+ transients was increased to 86% in neurons maintained at 30 degrees C, and dialyzed with an inhibitor of the inositol-triphosphate-3-kinase. 6. The delayed Ca2+ transients could not be initiated after inhibition of endosomal Ca(2+)-ATPase-mediated uptake by thapsigargin. 7. Both fura-2 and the dextran conjugate reported increases in resting Ca2+ levels after the loading protocols, that were absent after priming in thapsigargin, and decreases in resting Ca2+ levels after successive tetani in MK-801, suggesting that the Ca2+ changes were largely cytosolic. 8. The present results support the hypothesis that these synaptically mediated, delayed Ca2+ transients represent release from intracellular Ca2+ stores that can be loaded and depleted repeatedly, and are evoked by presynaptic release of endogenous neurotransmitter.

Regulation of synaptic responses to high-frequency stimulation and LTP by neurotrophins in the hippocampus.

Neurotrophins promote neuronal survival and differentiation, but the fact that their expression is modified by neuronal activity, suggests a role in regulating synapse development and plasticity. In developing hippocampus, the expression of brain derived neurotrophic factor (BDNF) and its receptor TrkB increases in parallel with the ability to undergo long-term potentiation (LTP). Here we report a mechanism by which BDNF modulates hippocampal LTP. Exogenous BDNF promoted the induction of LTP by tetanic stimulation in young (postnatal day 12-13) hippocampal slices, which in the absence of BDNF show only short-term potentiation (STP). This effect was due to an enhanced ability of hippocampal synapses to respond to tetanic stimulation, rather than to a direct modulation of the LTP-triggering mechanism. A TrkB-IgG fusion protein, which scavenges endogenous BDNF, reduced the synaptic responses to tetanus as well as the magnitude of LTP in adult hippocampus. Our results suggest that BDNF may regulate LTP in developing and adult hippocampus by enhancing synaptic responses to tetanic stimulation.

G protein-coupled receptors mediate a fast excitatory postsynaptic current in CA3 pyramidal neurons in hippocampal slices.

Synaptic activation in the presence of competitive (D,L-APV,CNQX) and noncompetitive (MK-801,GYKI-52466) ionotropic glutamate receptor antagonists induced fast (10-90% rise time of 15-30 msec) postsynaptic responses in CA3 pyramidal neurons from acute and cultured hippocampal slices. Postsynaptic currents were studied extensively in slice cultures, and displayed a linear current-voltage relationship, with a reversal potential between 0 mV and +10 mV, suggesting the activation of a nonselective cationic conductance. Inhibition of the GTPase cycle by intracellular perfusion with the nonhydrolyzable analog of GDP, GDP beta S, blocked the fast postsynaptic responses evoked in ionotropic antagonists, as well as baclofen-mediated outward K+ currents, known to be mediated by G protein-coupled GABAB receptors. Intracellular perfusion with GDP beta S did not affect the AMPA/kainate component of the synaptic currents. Irreversible activation of G proteins by intracellular perfusion with the nonhydrolyzable analog of GTP, GMP-PNP, occluded the baclofen responses, and evoked an inward current, consistent with the synaptically mediated conductance. Incubation of the slice cultures in pertussis toxin for 72 hr blocked baclofen-induced outward K+ currents, while the fast postsynaptic currents remained. The metabotropic glutamate receptor (mGluR) agonists 1S,3R-ACPD and 1S,3S-ACPD induced an inward current in the presence of the ionotropic antagonists, and occluded the fast EPSCs. The fast EPSCs were partially blocked by the mGluR antagonists L-AP3 and (+)MCPG, but there was differential antagonists sensitivity in two pathways stimulated (CA3 stratum radiatum vs CA3 stratum oriens). These data suggest that fast postsynaptic responses evoked in the presence of ionotropic glutamate receptor antagonists are mediated by G protein-coupled mGluRs linked to nonselective cationic channels.

Spontaneous and evoked glutamate signalling influences Fos-lacZ expression and pyramidal cell death in hippocampal slice cultures from transgenic rats.

Previously, we established that a spatially and temporally predictable pattern of spontaneous cell death occurs in pyramidal hippocampal neurons maintained in organotypic slice cultures. We have begun to examine the signalling events that may be relevant to this process by analyzing the expression of cellular immediate-early genes (cIEGs). In the present studies, organotypic hippocampal cultures were generated from transgenic rats that carry a fos-lacZ fusion gene. beta-Galactosidase activity in these rats accurately recapitulates Fos expression. An association was observed between cell death, as determined by propidium iodide (PI) staining, and Fos-lacZ expression. There was a consistent rise in beta-galactosidase activity in vulnerable regions 1-2 days before the peak of spontaneous neuronal death. Long-term treatment with TTX, CNQX, or D,L-APV inhibited the spontaneous neuronal death as well as Fos-lacZ expression. Furthermore, Fos-lacZ induction and cell death could be evoked by removal of these receptor antagonists or by application of the excitotoxin, kainic acid. The association between cIEG expression and cell death, shown here and by others, suggests that these genes contribute to regulatory events involved with cell death and/or protection.

Micromolar Ca2+ transients in dendritic spines of hippocampal pyramidal neurons in brain slice.

The magnitude and dynamics of [Ca2+] changes in spines and dendrites of hippocampal CA1 pyramidal neurons have been characterized using a low affinity fluorescent indicator, mag-Fura 5, that is sensitive to Ca2+ in the micromolar range. During tetanic stimulation (1 s), we observed progressive [Ca2+] increases in distal CA1 spines to as much as 20-40 microM, both in organotypic slice culture and acute slice. Similar accumulations were reached during continuous depolarization (+10 mV, 1 s) when K+ channels had been blocked, but not with spike trains driven by postsynaptic current injection. The large [Ca2+] increases due to tetanic stimulation were blocked by APV, indicating that NMDA receptor-dependent influx was critical for the large responses. These findings have significant implications for low affinity Ca(2+)-dependent biochemical processes and show a new upper limit for [Ca2+] changes measured in these neurons during stimulation.

Spontaneous pyramidal cell death in organotypic slice cultures from rat hippocampus is prevented by glutamate receptor antagonists.

A predictable pattern of selective neuronal cell death occurs in organotypic slice cultures of neonatal rat hippocampus during the second and third weeks in vitro. We serially examined organotypic cultures at three, four, seven, 14, 21 and 28 days in vitro, using uptake of the fluorescent dye propidium iodide to identify degenerating cells. After seven days in vitro, the cell degeneration that accompanies the slicing procedure appears to have ended. However, at 14 days in vitro, degenerating neurons could be identified in area CA3. When many degenerating cells were present in a slice, they were distributed in the dentate hilus (CA4) and proximal portions of CA1 as well. Neuronal degeneration involving mainly CA1 pyramidal cells was still apparent at 21 days in vitro, but was much less marked than at 14 days. Study of fixed cultures with light and electron microscopy methods confirmed the presence of degenerating neurons with a pyknotic or vacuolated appearance. Spontaneous neuronal degeneration at 14 and at 21 days in vitro was almost entirely prevented by the addition of 10.5 mM Mg2+ or 3 mM kynurenic acid (a glutamate receptor antagonist), beginning at seven days in vitro. Cell death was markedly decreased by treatment with 100 microM DL-2-amino-5-phosphonovaleric acid (a selective antagonist of N-methyl-D-aspartate glutamate receptors). Removal of the blocking agents by returning cultures to control media at 28 days in vitro induced widespread neuronal degeneration, involving all the regions of the hippocampal slice cultures. The inhibition of spontaneous neuronal cell death by glutamate receptor antagonists and by blockade of glutamate release at synapses suggests that the mechanism of cell death involves glutamate receptors. The time course of degeneration suggests that the vulnerability to glutamate excitotoxicity is an aspect of developmentally regulated components of glutamatergic synapses acquired in the hippocampal organotypic cultures after the first week in vitro.

Calcium signaling in dendritic spines of hippocampal neurons.

Intracellular Ca2+ dynamics have been measured using imaging techniques in dendrites and spines of CA3 hippocampal neurons in brain slice under both acute and tissue culture conditions. In response to presynaptic stimulation, micromolar levels of Ca2+ are rapidly reached in spines of distal dendrites. If stimulus parameters are chosen judiciously so as to minimize postsynaptic firing, then the dendrite shaft increases are far less. Spine Ca2+ increases are largely dependent upon activation of NMDA receptors. At the large mossy fiber synapses, presynaptic stimuli also produce large Ca2+ increases but the differences in shaft-spine Ca2+ levels are much less; often they are insignificant. Also at these locations, postsynaptic firing, without presynaptic stimulation is sufficient to produce large increases in spine Ca2+ levels.

Optical imaging of cytosolic calcium, electrophysiology, and ultrastructure in pyramidal neurons of organotypic slice cultures from rat hippocampus.

Organotypic slice cultures from rat hippocampal cortex grown in an interface between culture medium and a CO2-enriched atmosphere maintained much of the morphological connectivity characteristic of the hippocampus in situ and thinned out considerably, facilitating optical measurements of fluorescent dyes sensitive to Ca2+ in individual neurons. Pyramidal neurons of the CA3 region presented morphological features of differentiated cells, including complex dendritic arborization and large numbers of dendritic spines. The fine cytoskeletal substructure at the postsynaptic density, below the plasma membrane, and within the core of the head and neck of dendritic spines in rapidly frozen slice cultures presents the characteristic morphology previously described for Purkinje cell dendritic spines in acutely dissected cerebellar cortex slices after rapid freezing. CA3 neurons responded to intracellular current injection with a train of action potentials, spike frequency adaptation, and a slow afterhyperpolarization. These spike trains caused rapid increases in dendritic [Ca2+]i that decayed to resting levels after termination of the current pulse. Dendritic spines were clearly observed in proximal dendrites of CA3 neurons in live preparations. [Ca2+]i transients in these dendritic spines closely followed the changes observed in the main dendritic shaft. Orthodromic synaptic stimulation from the dentate hilus generated long-lasting synaptic potentials accompanied by large [Ca2+]i transient in CA3 pyramidal neurons. The [Ca2+]i response was first observed in the proximal dendrites, after which the soma exhibited a [Ca2+]i increase, returning to resting levels within 10 s after the synaptic stimulus. Slice cultures thus provide a favorable opportunity to investigate [Ca2+]i responses in individual neurons maintained in an organotypic synaptic environment, taking advantage of high-resolution optical techniques.

Cytoplasmic structure in organotypic cultures of rat hippocampus prepared by rapid freezing and freeze-substitution fixation.

We have compared rapid freezing followed by freeze-substitution fixation with conventional aldehyde fixation as preparative methods for the electron microscopic study of organotypic cultures of neonatal rat hippocampus. Rapid freezing by contact with a copper block chilled by liquid helium was accomplished without mechanical distortion of superficial structures, and preserved structure to a depth of at least 20 microns without visible ice crystals. Freeze-substitution fixation in acetone/osmium tetroxide, followed by en bloc staining with tannic acid and uranyl acetate, provided satisfactory staining of cytoplasm and organelles. While both preparative techniques yielded generally satisfactory results, rapid freezing provided much better preservation of astrocytic lysosomal inclusions, and afforded new views of intermediate filament substructure. Rapid freezing and freeze-substitution fixation seemed especially well suited to the preservation of short filamentous proteins, such as those forming the membrane cytoskeleton of dendritic spines or those associated with synaptic vesicles. The combination of rapid freezing methods and organotypic culture provides an opportunity to examine cytoplasmic structure in tissue from deep regions of the brain which had previously been inaccessible to rapid freezing techniques.

Postnatal development of the hypothalamic ventromedial nucleus: neurons and synapses.

1. In this report the postnatal differentiation of the hypothalamic ventromedial nucleus (VMN) was studied. The main maturational changes detected at the fine structural level occurred between 10 and 20 days of postnatal life. 2. In 5-day-old rats the majority of neurons was undifferentiated, with rudimentary cytoplasmic organelles. Dendritic profiles presented an empty appearance due to an electron-lucent matrix and scarce content of organelles. 3. At 10 days there was a significant proliferation of cytoplasmic organelles in the perikaryon, mainly of those involved in protein biosynthesis as the rough endoplasmic reticulum (RER) and the Golgi complex. 4. After 20 days of age the VMN neurons acquired the cytological appearance of adult neurons, with well-organized RER, Golgi complexes, and pleomorphic mitochondria. Concurrent with these changes, there was a marked development of other organelles in the neuropil, which was accompanied by an increase in synaptic density and differentiation of their subsynaptic structures.