The Establishment of GABAergic and Glutamatergic Synapses on CA1 Pyramidal Neurons is Sequential and Correlates with the Development of the Apical Dendrite

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The Journal of Neuroscience, December 1, 1999, 19(23):10372-10382

The Establishment of GABAergic and Glutamatergic Synapses on CA1 Pyramidal Neurons is Sequential and Correlates with the Development of the Apical Dendrite
Roman Tyzio, Alfonso Represa, Isabel Jorquera, Yehezkel Ben-Ari, Henri Gozlan, and Laurent Aniksztejn
Institut de Neurobiologie de la Méditérranée, Institut National de la Santé, et de la Recherche Médicale, 13273 Marseille Cedex 09, France

  ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

We have performed a morphofunctional analysis of CA1 pyramidal neurons at birth to examine the sequence of formation of GABAergicand glutamatergic postsynaptic currents (PSCs) and to determinetheir relation to the dendritic arborization of pyramidal neurons.We report that at birth pyramidal neurons are heterogeneous. Threestages of development can be identified: (1) the majority of theneurons (80%) have small somata, an anlage of apical dendrite,and neither spontaneous nor evoked PSCs; (2) 10% of the neuronshave a small apical dendrite restricted to the stratum radiatumand PSCs mediated only by GABA_A receptors; and (3) 10% of theneurons have an apical dendrite that reaches the stratum lacunosummoleculare and PSCs mediated both by GABA_A and glutamate receptors.These three groups of pyramidal neurons can be differentiatedby their capacitance (C_m = 17.9 ± 0.8; 30.2 ± 1.6; 43.2 ± 3.0pF, respectively). At birth, the synaptic markers synapsin-1 andsynaptophysin labeling are present in dendritic layers but notin the stratum pyramidale, suggesting that GABAergic peridendriticsynapses are established before perisomatic ones. The presentobservations demonstrate that GABAergic and glutamatergic synapsesare established sequentially with GABAergic synapses being establishedfirst most likely on the apical dendrites of the principal neurons.We propose that different sets of conditions are required forthe establishment of functional GABA and glutamate synapses, thelatter necessitating more developed neurons that have apical dendritesthat reach the lacunosum moleculareregion.

Key words: CA1 pyramidal cells; development; GABA_A receptors; AMPA receptors; NMDA receptors; synaptic transmission

  INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Several studies suggest that the ionotropic GABA_A, NMDA, and AMPA receptors display a sequential participation in neuronalexcitation during development (Ben-Ari et al., 1989; Hosokawaet al., 1994; Durand et al., 1996; Liu et al., 1996; Garaschuket al., 1998). In the neonatal hippocampus as in other immaturebrain structures, GABA, the principal inhibitory transmitter ofthe adult CNS, provides most of the excitatory drive (Cherubiniet al., 1991; Ben-Ari et al., 1997). The shift from the depolarizingto the hyperpolarizing action of GABA is mediated by a changeof [Cl]_i (Owens et al., 1996; Rivera et al., 1999) and occurs in thehippocampus at the end of the first postnatal week (Ben-Ari etal., 1989).

The development of the glutamatergic synaptic transmission is characterized by an earlier participation of NMDA than AMPAreceptors. Thus, in the hippocampus, electrical stimuli evokein postnatal day 1 (P1)-P2 pyramidal cells a postsynaptic currentblocked only by NMDA receptor antagonists (Ben-Ari et al., 1989;Durand et al., 1996). Because of the voltage-dependent Mg²⁺ block of NMDA channels, these synapses are "silent" at restingmembrane potential. A recent study performed with immunogold electronmicroscopy provides direct evidence that around birth glutamatergicsynapses contain mostly NMDA receptors (NMDARs) (Petralia et al.,1999). The percentage of silent synapses decreases during developmentwith the progressive colocalization of AMPA with NMDA receptorsto the synaptic site (Durand et al., 1996; Hsia et al., 1998;Petralia et al., 1999) and could be mediated by neuronal activity(Malenka and Nicoll, 1997).

In spite of the importance of the CA1 hippocampal region in studies on developmental neurobiology and plasticity, the relationbetween the morphological and physiological properties of pyramidalcells has not been studied. This is important because the suggestedsequential maturation of GABA and glutamate synapses is not causedby a sequential arrival of afferent axons. Indeed, both GABAergic(Rozenberg et al., 1989; Dupuy and Houser, 1996) and glutamatergicfibers (Super and Soriano, 1994; Super et al., 1998) are presentin the hippocampus before birth. An alternative possibility isthat different sets of conditions are required for the establishmentof GABA and glutamate synapses and specifically that the degreeof maturation of the target cell is an important factor. In keepingwith this: (1) the $gamma$ 2 subunit of the GABA_A receptors that is requiredfor the synaptic targeting of GABA_A receptors (Essrich et al.,1998) is only expressed when cells have reached a certain degreeof maturation (Killisch et al., 1991); (2) glutamate receptorsreach the synaptic active zone only when the dendritic spine hasbeen formed (Rao et al., 1998); and (3) dendritic filopodia initiatephysical contacts with nearby axons and thus play an importantrole in synaptogenesis (Ziv and Smith, 1996). Here, we have performeda morphofunctional analysis of CA1 pyramidal cells at birth anddemonstrate that the establishment of GABAergic and glutamatergicsynapses is sequential and correlates with the degree of developmentof the CA1 pyramidal cell apicaldendrite.

  MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Experiments were performed on CA1 hippocampal slices obtained from male Wistar rats on the day ofbirth.

Slice preparation. After killing the rat by decapitation, the brain was rapidly removed and placed in oxygenated ice-cooledartificial CSF (ACSF) with the following composition (in mM):126 NaCl, 3.5 KCl, 2 CaCl₂, 1.3 MgCl₂, 25 NaHCO₃ 1.2 NaHPO₄, and10 glucose. Hippocampal transverse slices (350-400 µm) were cutusing Vibratome (VT 1000E; Leica, Nussloch, Germany) and keptin oxygenated (95% O₂ and 5% CO₂, pH 7.3) ACSF at room temperatureat least 1 hr before use. Individual slices were then transferredto the recording chamber where they were fully submerged and superfusedwith oxygenated ACSF at 30-32°C at a rate of 2-3 ml/min.

Electrophysiological recordings. CA1 pyramidal cells were recorded blindly or under visual control (with an axioscope; Zeiss)using patch-clamp technique in the whole cell-configuration (Hamillet al., 1981) with an Axopatch 200A (Axon Instruments, FosterCity, CA) or EPC9 amplifiers (Heka). Microelectrodes had a resistanceof 5-10 M $Omega$ and filled with a solution of the following composition(in mM): 130 CsGlu, 20 CsCl, 0.4 CaCl₂, 1.1 EGTA, 10 HEPES, 4Mg²⁺ATP, 0.3 Na⁺GTP, and biocytin (0.5-0.8%), pH 7.25, 270-280 mOsm. Slices werestimulated by a bipolar twisted nichrome electrode placed in thestratum radiatum of CA1 with an intensity that ranges between10 and 100 V amplitude, has a 30 µsec duration, and a frequencyof 0.05-0.033 Hz. In some experiments, trains of electrical stimulation(100 Hz, 1 sec) were also applied. In addition, to cover mostof the stratum radiatum (~400-600 µm diameter), the two branchesof the stimulating electrode (50 µm diameter each) were separatedat the tip so that one of the branches was placed in the stratumradiatum at the border of the stratum pyramidale and the otherclose to the stratum lacunosummoleculare.

Synaptic currents and agonist-evoked responses were acquired on a DAT tape recorder (Biological) and into a personal computerusing TL1 DMA Labmaster analog-to-digital converter. Data werethen analyzed using Acquis software (Gérard Sadoc, Paris, France).Measurement of the capacitance was performed by applying a 5 mVdepolarizing voltage step from $-$ 70 mV and the exponential fitof the capacitivecurrent.

Drugs used were: NMDA, AMPA, isoguvacine, 6-cyano-7-nitroquinoxaline-2,3 dione (CNQX), bicuculline, and D-2-amino-5-phosphonovalerate(D-APV), all purchased from Tocris Neuramin. Tetrodotoxin (TTX),biocytin, and picrotoxin were purchased from Sigma (St. Louis,MO). All these drugs have been dissolved in ACSF and applied tothebath.

Histological processing. To reveal biocytin-injected cells, slices were immerged in a fixative solution of paraformaldehyde(4%) and glutaraldehyde (0.2%) overnight at 4°C after electrophysiologicalrecording. To increase penetration of the reagents used for biocytindetection, slices were quickly frozen on dry ice and thawed inphosphate buffer. Slices were then rinsed in 0.05 M Tris-bufferedsaline (TBS), pH 7.4, containing 0.3% Triton X-100 for 30 minand incubated overnight at 4°C in an avidin $---$ biotin-peroxidasesolution prepared in TBS according to the manufacturers recommendation(Vectastain Elite ABC; Vector Laboratories, Burlingame, CA). Aftera 30 min wash in TBS and a 10 min rinse in Tris buffer (TB), pH7.6, slices were processed for 15 min in 0.06% 3-3-diaminobenzidinetetrahydrochloride and 0.01% hydrogen peroxide diluted in TB.The slices were then rinsed in TB for 30 min, mounted on gelatin-coatedslides, dehydrated, and coverslipped with permount. Stained cellswere reconstructed using a camera lucida. Size and branching patternwere analyzed using the Samba/2005, TITN software (Alcatel,France).

The distribution of synaptic proteins was analyzed using mouse anti-synaptophysin (1: 500) and rabbit anti-synapsin-1 (1:1000) (both are from Chemicon, Temecula, CA). This was performedon slices used for electrophysiology (see above) or from ratsanesthetized with pentobarbital and transcardially perfused with4% paraformaldehyde and 0.5% glutaraldehyde, because the numberof synapses could differ in both materials (Kirov and Harris,1999). Coronal or sagittal 40-µm-thick sections were incubatedovernight with primary antibodies and, after washing, immunoreactivitywas revealed using anti-mouse or anti-rabbit biotin-conjugatedantibodies and the avidin-biotinsystem.

Statistical analysis. Data are expressed as mean ± SEM. Statistical significance of difference between means was assessedwith ANOVA and t test, and the level of significance was set atp < 0.05.

  RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Three stages of CA1 pyramidal cell maturation in newborn rats

In a first group of experiments, 60 CA1 neurons were blindly recorded (in the medial part of CA1) from the pyramidal celllayer in the whole-cell configuration (Hamill et al., 1981) andoften injected with biocytin and reconstructed post hoc. Thesecells were identified as neurons (vs glia) because depolarizingsteps (20 mV, from $-$ 60 mV) evoked a fast TTX-sensitive inwardsodium current (Fig. 1B). They were identified as pyramidal neuronson the basis of the morphological reconstruction (see Fig. 6);by its location within the pyramidal cell layer, the presenceof an axon originated from the basilar part of the cell body andreached the alveus and the formation of a single apical dendriteperpendicularly oriented to the hippocampal fissure. Althoughnot analyzed in detail, bicuculline-sensitive network-driven spontaneousgiant depolarizing potentials (GDPs) were sometimes recorded (datanot shown) in keeping with earlier observations (Ben-Ari et al.,1989; Khazipov et al., 1997). Based on their synaptic spontaneousand evoked activities and their morphological features, theseneurons could be classified into three groups: (1) neurons withno spontaneous or evoked postsynaptic currents (PSCs) (silentneurons); (2) neurons with GABA_A but not glutamate PSCs (GABA-onlyneurons); and (3) neurons with GABA_A and glutamate (NMDA-onlyor NMDA plus AMPA) PSCs.

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Figure 1. Morphofunctional characteristics of a silent cell. A, This representative cell has just an anlage of apical dendrite and no basilar dendrite. In contrast, a long axon is observed in the stratum oriens (arrows). B, A 20 mV depolarizing step for 50 msec evoked a fast inward Na⁺ current that was blocked by bath application of TTX (1 µM) (the capacitive current has been truncated). C, Electrical stimulations (50-100 V, 30 µsec duration) of the stratum radiatum did not evoke synaptic currents at these three membrane potentials (mean of 10 traces evoked at 0.05 Hz). The truncated stimulation artifact is indicated by an arrow. D₁, Current-voltage (I-V) relationship of AMPA receptor-mediated response. The insert shows the current generated by bath application of AMPA (5 µM, 1.5 min) at $-$ 70 mV. D₂, I-V relationship of NMDA receptor-mediated response. The insert shows the current generated by bath application of NMDA (10 µM, 3 min) at $-$ 35 mV. D₃, I-V relationship of isoguvacine-mediated response. The current generated by bath application of isoguvacine (10 µM, 1 min) at $-$ 70 mV is shown in the insert. or, Stratum oriens; py, stratum pyramidale; ra, stratum radiatum.

Silent neurons
In 46 neurons, there was no spontaneous activity, even in conditions that favor transmitter release, such as elevating [K⁺]_o concentration (to 10 mM) to increase cell excitability or increasingosmolarity by the addition of sucrose (50 mM) to the bath (seeFig. 5A₂). Electrical stimulation (at least for 10 min) of thestrata lacunosum moleculare, radiatum, pyramidale, and oriensdid not evoke a synaptic response at a wide range of stimulusintensities and membrane potentials (Fig. 1C; see Fig. 5A₂). Furthermore,tetanic stimulation of the stratum radiatum (100 Hz, 1 sec) failedto generate PSCs (data not shown). These neurons express, however,ionotropic glutamate and GABA_A receptors because, in the presenceof TTX (1 µM), bath application of: (1) AMPA (5 µM, 1.5 min) generated,at $-$ 70 mV, an inward current of 22.4 ± 2. 8 pA (n = 29) that reversedpolarity at 4.1 ± 2.8 mV (n = 7), with a slope conductance of0.26 ± 0.07 nS (Fig. 1D₁). (2) NMDA (10 µM, 3 min) generated asmall inward current at $-$ 35 mV of 4 ± 1.1 pA (n = 16) that reversedpolarity at 0.6 ± 5.2 mV (n = 3). The current-voltage (I-V) relationshipshowed a region of negative slope conductance with a peak inwardcurrent in the $-$ 20 to $-$ 35 mV range and mean slope conductancein the linear part of the curve of 0.49 ± 0.09 nS (Fig. 1D₂).(3) The GABA_A receptor agonist isoguvacine (10 µM, 1 min), generated,at $-$ 70 mV, an inward current of 18.6 ± 2.1 pA (n = 26) that reversedpolarity at $-$ 32 ± 3.8 mV (n = 3). The I-V relationship of GABA_Acurrents was not totally linear and showed an outward rectificationfor values more positive than the reversal potential (Fig. 1D₃)(Blanton and Kriegstein, 1992; Serafini et al., 1998). Therefore,glutamate and GABA_A receptors are expressed before the presenceof spontaneous or evoked synaptic currents as in other structures(Blanton and Kriegstein, 1992; Walton et al., 1993; Chen et al.,1995; LoTurco et al., 1995; Serafini et al., 1998).
Silent neurons have a low capacitance 18.1 ± 0.7 pF (n = 46), and their morphological reconstruction (n = 18; Fig. 1A; seeFigs. 6, 8A) revealed a small round-shaped soma (143 ± 11 µm²) and an anlage of apical dendrite that was either entirely restrictedto the stratum pyramidale (15 of 18) or distributed exclusivelywithin the inner 50 µm part of the stratum radiatum (n = 3 of18). The apical dendrite was poorly arborized with few branchingpoints (1.1 ± 1) and no spines and, with one exception, no basilardendrites (Table 1). In contrast, axons were relatively welldeveloped, walked throughout the stratum oriens, and reached thealveus. Therefore, the majority of blindly recorded CA1 pyramidalneurons had no synaptic activity, no dendritic arborization, anda small capacitance. As depicted in Figure 6, silent cells didnot show a preferential location in the stratum pyramidale andwere observed either close to the stratum radiatum or close tothe stratum oriens.


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Table 1. Morphometric values from biocytin-stained CA1 pyramidal cells of newborn rats

Neurons that have GABA PSCs only
In eight neurons, both spontaneous and evoked PSCs by the stimulation of the stratum radiatum were recorded that were mediatedonly by GABA_A receptors because they were blocked by bicuculline(10 µM) or picrotoxin (100 µM) (Fig. 2B; see Fig. 5B₂) and reversedpolarity at a value close to the reversal potential of the currentgenerated by isoguvacine (data not shown). This population ofneurons was more mature than the previous group with: (1) a significantlyhigher capacitance 25.2 ± 3 pF (n = 8; p = 0.01); (2) a significantlylarger somatic size (221.7 ± 37.2 µm²; p = 0.017; n = 4 cells); (3) a more developed apical dendritethat arborized within the stratum radiatum and the presence ofbasilar dendrite or dendrites (Fig. 2A; see Figs. 6, 8A); and(4) significantly larger currents generated by bath applicationsof glutamate agonists. Thus, in the presence of bicuculline (10µM) and TTX (1 µM), bath application of AMPA (5 µM, 1.5 min) at $-$ 70 mV generated an inward current of 164 ± 22 pA (n = 6; p =10¹⁰ when compared with silent cells) with a mean slope conductanceof 1.9 ± 0.4 nS (p = 0.002; Fig. 2C). Similarly, bath applicationof NMDA (10 µM, 3 min) generated, at $-$ 35 mV, inward currents of16 ± 4 pA with a mean slope conductance measured in the linearpart of the curve of 1.1 ± 0.2 nS (n = 4; p = 0.04). Therefore,CA1 pyramidal neurons that have functional GABA_A, but not glutamate,PSCs are more mature than silent cells.

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Figure 2. Morphofunctional properties of a neuron with GABA_A receptor-mediated PSCs. A, The soma is bigger than that of silent neurons, and the apical dendrite arborizes in the stratum radiatum. B, Electrical stimulation of the stratum radiatum (37 V, 30 µsec duration) evoked in control a synaptic response that was inward at $-$ 70 mV and outward at 40 mV (each depicted synaptic response is the mean of five traces evoked at 0.05 Hz). Bicuculline (10 µM) abolished reversibly the synaptic current at both membrane potentials, even when the stimulus intensity was increased (traces in bicuculline represent PSCs evoked at 100 V, whereas the PSC shown after the washout of the antagonist is evoked as in control at 37 V). C, I-V relationship of AMPA (left graph) and NMDA (right graph) receptor-mediated currents (inserts depict the AMPA and NMDA currents at $-$ 70 and $-$ 35 mV, respectively).

Neurons with GABA and glutamate PSCs
In five recorded neurons, both spontaneous and evoked PSCs mediated by GABA_A and glutamate receptors were recorded (Fig. 3B;see Fig. 5C₂). Electrical stimulation of the stratum radiatumevoked a synaptic response that, at $-$ 70 mV, was partially reducedby bicuculline (10 µM) and completely eliminated by a subsequentapplication of CNQX (10 µM). Holding the membrane potential at40 mV revealed an outward synaptic current that was reduced bybicuculline and CNQX and completely blocked by further applicationof APV (50 µM), reflecting the participation of NMDA receptorsin the synaptic response. In one neuron, glutamatergic activitywas mediated by NMDA but not by AMPA receptors, i.e., the synapticresponse at $-$ 70 mV was eliminated by bicuculline, whereas at 40mV a CNQX-insensitive synaptic response was observed that wasfully blocked by APV (50 µM) (Fig. 4B,C). The converse, AMPA butnot NMDA receptor-mediated PSCs, was not observed.

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Figure 3. Morphofunctional properties of a neuron with GABA plus AMPA plus NMDA receptor-mediated PSCs. A, The apical dendrite reaches the stratum lacunosum moleculare (lm) and crosses the hippocampal fissure (represented by a line, F). B, The neuron has a synaptic response mediated by GABA_A, AMPA, and NMDA receptors. The stimulation of the stratum radiatum (60 V, 30 µsec duration) evoked both at $-$ 70 and 40 mV a synaptic response composed of a monosynaptic component and a polysynaptic GDP. Bicuculline (10 µM) decreased the monosynaptic component and eliminated the GDP. The remaining response is completely blocked by CNQX (10 µM) at $-$ 70 mV and by CNQX and APV (50 µM) at 40 mV. C, I-V relationship of AMPA receptor-mediated response (left curve) and NMDA receptor-mediated response (right curve). Inserts depict the AMPA and NMDA currents at $-$ 70 and $-$ 35 mV, respectively.

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Figure 4. Morphofunctional characteristic of a neuron with GABA plus NMDA receptor-mediated PSCs. A, Note that this cell has a similar shape to the one shown in Figure 3A. B, Plot of the amplitude of the PSCs versus time. In control, the stimulation intensity was 50 V. Application of bicuculline (10 µM) completely blocked the synaptic response evoked at $-$ 70 mV. Increasing the stimulus intensity to 100 V (indicated by the arrow) failed to restore any synaptic response. After holding the membrane potential at 40 mV, the same stimulus intensity evoked an outward synaptic response that is insensitive to CNQX but completely blocked by further application of APV (50 µM). C, PSCs corresponding to the graph depicted in B. Each trace is the average of five consecutive PSCs. The control PSC at $-$ 70 mV is evoked at 50 V, whereas others are evoked at 100 V.

Neurons with GABA and glutamate PSCs had a significantly higher capacitance than the GABA-active cells (46.2 ± 4.5 pF; p =0.006). They also had significantly larger currents generatedby AMPA and NMDA because in the presence of bicuculline and TTX,bath application of: (1) AMPA (5 µM, 1.5 min) generated, at $-$ 70mV, a mean inward current of 309 ± 48 pA (n = 5; p = 0.005) witha mean slope conductance of 4.3 ± 0.6 nS (p = 0.004) (Fig. 3C);(2) NMDA (10 µM, 3 min) generated a mean inward current at $-$ 35mV of 38 ± 6.3 pA (n = 5; p = 0.009) and with a mean slope conductancemeasured in the linear part of the curve of 3.3 ± 0.4 nS (p =0.004) (Fig. 3C). These cells have a higher level of morphologicalmaturation than GABA-active cells because their apical dendritereached the stratum lacunosum moleculare (Figs. 3A, 4A; see Figs.6, 8A), and they have also basilardendrites.
However, the quantitative comparison of the morphological differences between this group and the neurons with GABA PSCs onlyis precluded by the limited number of neurons. We therefore usedpatch recordings under visual control to increase the number ofneurons with synapticcurrents.

Visual patch recordings confirm the differences between the two populations of active neurons

Because blind patch studies suggest that active neurons have larger soma and a more extended apical dendrite, we recordedunder visual control pyramidal neurons with these features. All51 neurons recorded had PSCs, 24 had only GABA, and 27 had GABAand glutamate PSCs, including two neurons in which the synapticactivity was mediated by GABA and NMDA but not AMPA receptors.The nine additional neurons that were recorded under visual controlwith small soma and no apparent dendrite were, as expected, notactive (Figs. 5, 6). Pooling the data from blind and visual patchrecordings suggests that neurons with GABA and glutamate PSCsare more mature than neurons with GABA PSCs only (Table 1). Thisconclusion is supported by the following observations: (1) theapical dendrite of the neurons with GABA and glutamate PSCs reachedthe stratum lacunosum moleculare and arborized within this layer;in contrast the apical dendrite of neurons with GABA PSCs onlywere exclusively restricted to the stratum radiatum. (2) The basilardendrite of neurons with GABA and glutamate PSCs are more developed(length, number of branching points) than neurons with GABA PSCsonly, although the number of cells in which these dendrites areobserved was similar (n = 9 of 12 and 8 of 13, respectively).With one exception, the basilar dendrite did not reach the stratumoriens. (3) Although the number of spines at this stage was smallin the neurons with GABA PSCs only and GABA plus glutamate PSCs(one to three and one to nine spines, respectively), they weremore frequently observed in the latter (7 of 12 cells) than inthe former group (4 of 13 cells).

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Figure 5. Visual identification of silent and active neurons. A₁, Silent cell (C_m, 10 pF) with round shape soma and no apical dendrite. A₂, Bath application of sucrose (50 mM) or stimulation of the stratum radiatum (100 V, 30 µsec duration) failed to evoke any synaptic response both at $-$ 70 and 40 mV. B₁, GABA-active neuron (C_m, 27 pF) from the same slice has a bigger soma and an apical dendrite (arrows). B₂, The spontaneous activity is completely blocked by bicuculline (10 µM). In the presence of the antagonist, stimulation of the stratum radiatum (100 V, 30 µsec duration) failed to evoke a PSC at $-$ 70 and 40 mV (mean of 10 traces evoked at 0.05 Hz). C₁, GABA plus Glu-active cell from another slice (C_m, 40 pF). C₂, Note that AMPA receptor-mediated PSCs (asterisk) can easily be distinguished from GABA PSCs (filled circle) at $-$ 70 mV by the different decay time constant ( $tau$ = 1.33 msec, $tau$ = 19.76 msec, respectively).

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Figure 6. Camera lucida reconstruction of injected P0 pyramidal cells grouped accordingly to their synaptic properties. The neurons not represented here are shown in Figure 8A. Silent cells are shown in green, GABA-only in red, and neurons with GABA and NMDA or GABA plus NMDA plus AMPA receptor-mediated PSCs are in black and blue, respectively. Note that each group of cells has a relative homogenous degree of maturation. GABA-active and GABA plus glutamate-active neurons differ essentially by the presence of an apical dendrite in the stratum lacunosum moleculare. Note also that there are no morphological differences between GABA plus NMDA and GABA plus NMDA plus AMPA-active cells.

This comparison is based on the entire population of neurons with glutamate PSCs (i.e., NMDA-only and NMDA plus AMPA) becausethere were no morphological difference between glutamate-silentand glutamate-active neurons. As shown in Tables 1 and 2, thesewere similar in terms of capacitance, size of the soma, totaldendritic length, number of branching points, number of dendriticspines, and presence of basal dendrites.


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Table 2. Mean capacitance and statistical values of cells

Neuronal capacitance is a good predictor of the degree of maturation of the neurons. The capacitance of the three populationsof neurons were significantly different (Table 2) with a strongcorrelation between the mean capacitance and the mean dendriticlength (basilar plus apical or apical only) (r² = 0.99) (Fig. 7A). These observations suggest that the neuronalcapacitance enables one to predict the morphological propertiesof the cells. Because these analyses relied only on successfullyreconstructed neurons, we also compared the capacitance of thethree groups of cells that have not been reconstructed with thosefor which the morphology was available. As shown in Table 2 andFigure 7, B and C, there was no statistical difference betweenreconstructed and nonreconstructed neurons, suggesting that theyhave similar developmental profiles.

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Figure 7. The three different types of cells can be differentiated by their dendritic length and their capacitance. A, The apical or total (apical plus basilar) dendritic length of silent, GABA, and GABA plus Glu (NMDA-only and NMDA plus AMPA)-active cells are plotted according to their mean capacitance. B, The capacitance of all reconstructed cells is plotted according to their synaptic properties. The mean capacitance (indicated by a horizontal bar) of each cell type is significantly different from the other types (mean values and statistics are depicted in Table 2). C, The capacitance of all nonreconstructed cells are plotted according to their synaptic properties. As in B there is some overlap between the values, but here again the mean capacitance of each group is significantly different from the other populations.

Synaptic markers are not detected in the stratum pyramidale

Our data suggests that the first synapses established on pyramidal neurons are localized in the stratum radiatum. We havetested this hypothesis by analyzing the distribution of synaptophysinand synapsin-1, 2 synaptic markers on slices made from the brainof perfused rats. Immunoreactive boutons were present in the stratumradiatum (Fig. 8B,C) and also in the stratum oriens and lacunosummoleculare (data not shown) but not in the stratum pyramidale(n = 5 of 5). Because slices made from the brains of nonperfusedanimals differ in the number of synapses from those of perfusedrats (Kirov and Harris, 1999), we also performed immunohistochemicalstaining on slices used for electrophysiology. We found in thismaterial the same distribution of synaptophysin and synapsin-1as in slices from perfused rats (n = 4 of 4; data not shown) (wehave however not quantified the number of synaptic boutons inboth materials). Therefore, neurons with an anlage of apical dendriteare silent because they have no synapses and peridendritic GABAergicsynapses are established before perisomatic ones, in keeping withimmunocytochemical observations (Rozenberg et al., 1989; Dupuyand Houser, 1996).

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Figure 8. Synaptic boutons are present in the stratum radiatum but not in the stratum pyramidale. A, CA1 hippocampal section stained with cresyl violet. Three pyramidal cells not shown in Figure 6, the silent (green), GABA-only (red), and GABA plus NMDA plus AMPA-active neurons (black) are represented (camera lucida reconstruction) to show the distribution of the dendrites within all the layers. B, C, Other sections from the same hippocampus depict immunolabeling with synaptophysin (B) and Synapsin-1 (C) in the stratum radiatum but not in the stratum pyramidale.

  DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The present data show that at birth most CA1 pyramidal neurons are silent, with no synaptic currents, and provide direct evidencefor a sequential participation of GABAergic and glutamatergicreceptors in synaptic transmission. Our study provides to thebest of our knowledge the first evidence that this sequence iscorrelated with morphological changes: increase in length of dendrite,increase of somatic size, and whole-cell capacitance. It is infact possible to predict on the basis of these measurements whetherthe neuron is silent, has GABAergic-only, or GABAergic and glutamatergicfunctional synapses. The presence of a small apical dendrite inthe stratum radiatum is a necessary and sufficient morphologicalrequirement for the formation of functional GABA synapses, whereasglutamate synapses require a more developed dendrite that reachesthe stratum lacunosum moleculare (Fig. 9a). Therefore, dendriticgrowth may be modulated in a first stage (when the apical dendriteof the pyramidal neuron is restricted to the stratum radiatum)by GABAergic synaptic activity, whereas at a subsequent stage(once it has penetrated in the lacunosum moleculare), glutamatereceptor activity takes over the control of dendritic dynamics.A small percentage of neurons have glutamate silent synapses (PSCsmediated by NMDARs only). These neurons have a similar degreeof development as neurons with glutamate "active" synapses [PSCsmediated by NMDA and AMPA receptors (AMPARs)], suggesting thatin the hippocampus the activity-dependent acquisition of synapticAMPARs (Malenka and Nicoll, 1997) is a rapid process that doesnot require further maturation of the neurons (but see Wu et al.,1996; Rajan and Cline, 1998).

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Figure 9. Schematic diagram to depict the CA1 network in P0 hippocampal rats. a, Three different stages of maturation of pyramidal cell are observed at P0. To simplify this scheme, basilar dendrites and fibers in stratum oriens are not represented. Silent pyramidal cells have an anlage of apical dendrite restricted to the stratum pyramidale and are not contacted by synaptic inputs, although they have functional GABA_A and glutamate receptors (not shown). Pyramidal cells that have an apical dendrite in the stratum radiatum are contacted by GABAergic fibers. Functional Schaffer-commissural synapses are present only in cells that have apical dendrites in the stratum lacunosum moleculare. NMDARs are expressed at the synaptic site before AMPA receptors. B, Proposed model for the late participation of AMPA receptors to the synaptic transmission. The depolarization produced by GABA removes the voltage- dependent Mg²⁺ block from NMDA receptors (Leinekugel et al., 1997). The resulting increase in [Ca²⁺]_i promotes the synaptic expression of AMPA receptors that colocalize with NMDA receptors.

Heterogeneity of CA1 pyramidal cells at birth

Our morphofunctional data suggest that: (1) pyramidal neurons are heterogeneous at birth probably because of the durationof their neurogenesis from embryonic day 16 (E16) to E20 (Bayer,1980). The large majority of silent cells (80%) may representa population of neurons formed during the peak of neurogenesis(E18-E19) that have just reached the pyramidal layer after sojourning3 d in the intermediate zone (Altman and Bayer, 1990); synapticallyactive neurons are more developed and may have been generatedat an earlier stage. (2) As in developing neocortical pyramidalcells (Marin-Padilla, 1992), the axon develops before the dendritesbecause the neurons have extended axons in stratum oriens andalveus, including cells that have no dendrites; and (3) the apicaldendrite develops before the basilardendrite.

The sequential participation of GABA and glutamate in synaptic transmission

The earlier establishment of GABAergic synapses on the apical dendrites of pyramidal neurons is in keeping with the distributionof synapsin-synaptophysin and GAD-positive terminals that arepresent in the stratum radiatum but not in the stratum pyramidale(Rozenberg et al., 1989; Dupuy and Houser, 1996). These fibersmay originate either from GABAergic-positive neurons localizedin the stratum radiatum (Super et al., 1998) or in other layers(Gaiarsa et al., 1995). In fact, morphological reconstructionssuggest that at birth GABA-positive neurons are highly arborizedwith axonal arbors extending to dendritic layers (Gaiarsa et al.,1995). This is likely a consequence of their earlier generation(between E10 and E12) (Soriano et al., 1989; Super et al., 1998).The establishment of synapses only in neurons that have at leasta small apical dendrite suggest that GABAergic fibers that arepresent in the stratum radiatum before birth (Rozenberg et al.,1989; Dupuy and Houser, 1996) must await the development of pyramidalcells to establish synaptic contacts. Interestingly, the presenceof a single branch of the apical dendrite in the stratum radiatumis sufficient for the formation of functional GABAergic synapses,suggesting that the transport, clustering, and synaptic expressionof GABA_ARs occurs rapidly after the contact between the GABA terminalsand the apical dendrite has beenestablished.

As for GABAergic fibers, the glutamatergic inputs are present before the arrival of the dendrites in the molecular layers(Super and Soriano, 1994; Super et al., 1998). However, a differentsituation prevails for the formation of functional commissural-associationalsynapses. The crucial factor appears to be the presence of thedendrite in the lacunosum moleculare independently of the totaldendritic length in stratum radiatum (from 31 to 743 µm). Althoughthe molecular mechanisms have not been identified, the followingobservations deserve emphasis: (1) in cultures of developing hippocampalneurons, synaptic contacts are established before the synapticlocalization of glutamate receptors, which occurs once dendriticspines are formed (Rao et al., 1998). This raises the possibilitythat glutamatergic synapses are present in GABA-only neurons,but AMPARs are extrasynaptically located. However, in keepingwith a previous study (Durand et al., 1996), our results showthat dendritic spines are not required for the development offunctional glutamatergic synaptic transmission. Indeed, spineswere either absent or their density was extremely low in our neuronalpopulation, and there was no correlation between the presenceof spines and the type of synaptic responses evoked; (2) Sorianoand coworkers have recently suggested that glutamatergic synapsesare first established on GABAergic pioneer neurons (Super et al.,1998). They propose that synaptic contacts between glutamatergicaxons and pyramidal neurons occur only after the death of thesepioneer GABAergic neurons. Although this possibility cannot beexcluded, the abrupt formation of glutamatergic synapses on pyramidalneurons once their dendrite has penetrated the stratum lacunosummoleculare cannot be readily reconciled with this progressiveprogram cell death; (3) our observations suggest an inductiverole of the lacunosum moleculare in the maturation of glutamatergiccontacts. It is possible that factors are secreted in this layerand trigger the formation of functional glutamatergic synapseseither in the stratum radiatum and/or in the lacunosum moleculare.This signal could belong to the family of neurotrophins because:(1) BDNF mRNA is expressed in the entorhinal hippocampal systemat an early stage of development (Martinez et al., 1998), andit has been suggested that perforant path could release neurotrophins(Kossel et al., 1997); (2) TrkB and TrkC mRNAs are detected fromembryonic stages in the hippocampus (Martinez et al., 1998); (3)mice lacking TrkB and TrkC receptors have a reduced number ofperforant path and commissural-associational synaptic contactson pyramidal neurons (Martinez et al., 1998); (4) neurotrophinsaccelerate the formation of excitatory connections (Vicario-Abejonet al., 1998). However, an alternative possibility is that thelacunosum moleculare has no permissive effect per se, but thepresence of the apical dendrite in this layer only reflects moredeveloped pyramidal neurons. In this scenario, the signal requiredfor the formation of functional commissural-associational synapseson pyramidal neurons is determined by theirage.

Whatever the mechanisms, our observations suggest that formation of glutamatergic synapses requires a set of conditions thatdiffer from those required for the formation of GABAergicsynapses.

Glutamate-silent cells precede glutamate-active cells

Physiological and morphological studies suggest an earlier participation of NMDARs than AMPARs to synaptic transmission (Ben-Ariet al., 1989; Durand et al., 1996; Wu et al., 1996; Isaac et al.,1997; Hsia et al., 1998; Liao et al., 1999; Petralia et al., 1999;see also Rao et al., 1998). In keeping with these studies, wealso found a few neurons with PSCs mediated only by NMDARs evenin response to strong electrical stimuli and did not observe theconverse: PSCs mediated by AMPA but not NMDARs. There are thereforesilent neurons and not only silent synapses, as in these neuronsall glutamatergic synapses will not be active at resting membranepotential, provided that GABA_A receptors are blocked. Our observationthat the vast majority of glutamatergic PSCs are mediated by bothNMDA and AMPARs and very few (3 of 119 cells) by NMDARs contrastwith another study in which pure NMDA synapses predominate atan early stage of development in the CA1 region of the hippocampus(Durand et al., 1996). The simplest explanation is that theseauthors used minimal stimulations to determine the propertiesof few and possibly single synaptic PSCs. In contrast, in thepresent study, we have used maximal stimuli because our aims wereto determine the ensemble PSCs of developing neurons. Therefore,our results do not provide indications on the percentage of pureNMDA synapses or mixed NMDA plus AMPA synapses on individual neurons.In fact, determining the exact percentage may be a difficult taskin view of the apparent rapid conversion by neuronal dischargeof silent synapses to active ones

The synaptic expression of AMPARs is modulated by activity involving the activation of NMDARs and an increase in [Ca²⁺]_i (Malenka and Nicoll, 1997). Because GABA is depolarizing andremoves the voltage-dependent Mg²⁺ block from NMDA channels (Leinekugel et al., 1997) and GABA andNMDARs participate in PSCs before AMPARs (present data), we suggestthat the synergist activation of GABA and NMDARs strongly contributesto the maturation of glutamatergic synapses (Fig. 9b).

In conclusion, the coexistence of these different steps of maturation in P0 hippocampal slices provides a rare opportunityto study in vivo factors that may control the morphological developmentof pyramidal cells, synaptic expression of receptors, formationof functional synapses, and thus understand how the hippocampalcircuitdevelops.

  FOOTNOTES

Received June 24, 1999; revised Sept. 1, 1999; accepted Sept. 14, 1999.

Dr. Roman Tyzio is supported by Institut National de la Santé, et de la Recherche Médicale.
Correspondence should be addressed to Laurent Aniksztejn, Institut de Neurobiologie de la Méditérranée, Institut Nationalde la Santé, et de la Recherche Médicale, Unité 29, Parc Scientifiquede Luminy, B.P. 13, 13273 Marseille Cedex 09, France. E-mail:anik{at}inmed.univ-mrs.fr.

  REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

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