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Solutions The extracellular saline contained (in mM): 125 NaCl, 2.5 KCl, 1.25 NaH2PO4, 26 NaHCO3, 2 CaCl2, 1 MgCl2, and 10 glucose and was bubbled with 5% CO2 and 95% O2. For PC recordings, pipettes contained (in mM): 150 CsCl or 150 KCl, 10 BAPTA or 10 EGTA, 4.6 MgCl2, 10 HEPES, 1 CaCl2, 4 Na-ATP, and 0.4 Na-GTP and 0.2% biocytin or 0.1% Lucifer yellow (dipotassium salt). For interneuron recordings, the composition of the intracellular solution was (in mM): 150 potassium gluconate or 150 KCl, 1 EGTA and 0.1 CaCl2 or 10 EGTA and 1 CaCl2, 4.6 MgCl2, 10 HEPES, 4 Na-ATP, and 0.4 Na-GTP and 0.2% biocytin or 0.2% neurobiotin. All chemicals were purchased from Sigma (St. Louis, MO) except neurobiotin (Vector Laboratories, Burlingame, CA). Presynaptic and postsynaptic recordings Borosilicate patch pipettes (Hilgenberg, Malsfeld, Germany) were pulled to a final tip resistance of 1.9-2.5 M
Volume 17, Number 23, Issue of December 1, 1997
Developmental Regulation of Basket/Stellate Cell
Purkinje Cell Synapses in the Cerebellum
Christophe Pouzat1 and Shaul Hestrin2 1 Arbeitsgruppe Zelluläre Neurobiologie, Max-Planck-Institut für Biophysikalische Chemie, D-37077 Göttingen, Germany, and 2 Department of Anatomy and Neurobiology, College of Medicine, University of Tennessee, Memphis, Tennessee 38163
ABSTRACT
We used paired recordings to study the development of synaptic transmission between inhibitory interneurons of the molecular layer and Purkinje cells in the cerebellar cortex of the rat. The electrophysiological data were combined with a morphological study of the recorded cells using biocytin or Lucifer yellow staining. Thirty-one interneuron-Purkinje cell pairs were obtained, and 11 of them were recovered morphologically. The age of the rats ranged from 11 to 31 d after birth. During this period synaptic maturation resulted in an 11-fold decrease in the average current evoked in a Purkinje cell by a spike in a presynaptic interneuron. Unitary IPSCs in younger animals exhibited paired-pulse depression, whereas paired-pulse facilitation was found in more mature animals. These data suggest that reduction in transmitter release probability contributed to the developmental decrease of unitary IPSCs. However, additional mechanisms at both presynaptic and postsynaptic loci should also be considered. The decrease of the average synaptic current evoked in a Purkinje cell by an action potential in a single interneuron suggests that as development proceeds interneuron activities must be coordinated to inhibit efficiently Purkinje cells.
Key words: inhibitory synapses; cerebellum; paired recordings; development; single-axon IPSCs; stellate cells; basket cells
INTRODUCTION
During development the number of synaptic contacts central neurons receive increases dramatically (Blue and Parnavelas, 1983
; Miller, 1986
The cerebellar cortex of the rat undergoes major changes during the first 4 postnatal weeks (Altman and Bayer, 1997
The inhibitory control of PCs is mediated by SCs and BCs (Eccles et al., 1966a
We studied the development of the interneuron
PC synapse using paired recordings from synaptically connected neurons, combined with morphological techniques. A dramatic reduction with age of the average IPSC evoked in a PC by the activity of a single interneuron was found. Furthermore, both presynaptic and postsynaptic factors were found to be involved.
These results have been presented in an abstract form (Pouzat et al., 1996
MATERIALS AND METHODS
Preparation of slices During deep anesthesia with Metofane (Jansen), Wistar rats (P11-P31) were decapitated, and the cerebellum was excised and placed in a cold (4°C) saline solution. Sagittal or parasagittal slices (150 µm thickness) were cut from the vermis with a Microslicer (Dosaka). The slices were allowed to recover for at least 1 hr in a saline solution maintained at ~34°C before being transferred to the recording chamber, where they were continuously perfused at a rate of 1-2 ml/min with the same saline solution at room temperature.for PC pipettes (with chloride solution) and 10-12 M
60 mV using two patch-clamp amplifiers (EPC 9, Heka; and Axopatch 200A, Axon Instruments). Series resistance compensation (50-80%) was routinely used for young PCs (Llano et al., 1991
In many experiments the presynaptic interneuron was recorded cell-attached, and the postsynaptic PC was recorded with the whole-cell configuration. In these cases continuous 1-min-long acquisition was used, with a sampling rate of 4 kHz and a Bessel filter set on 0.8 and 1 kHz for the EPC 9 and Axopatch, respectively. The series resistance of the postsynaptic PC was checked every one or two acquisition protocols. When a presynaptic whole-cell recording was used, the presynaptic interneuron was stimulated with short (2 msec) voltage pulse with an amplitude (typically 40-60 mV from rest) suitable to evoke an unclamped sodium action current. For the paired-pulse experiments, the onsets of the two pulses were separated by 30 msec, and the membrane was hyperpolarized by 10 mV between stimuli to remove voltage-dependent inactivation. This stimulation was repeated every 1-2 sec. Data were sampled at 20 kHz, and the Bessel filter was set to 4 and 2 kHz for the EPC 9 and Axopatch amplifiers, respectively. Analysis All the data were analyzed using Igor (Wavemetrics) together with in-house-developed routines.
No junction potential correction was applied for the experiments when a potassium gluconate solution was used to record from interneurons. Nevertheless, in several experiments several holding potentials (from
Cell-attached presynaptic. Pairs of cells with a presynaptic cell-attached configuration were analyzed using an off-line, spike-triggered averaging process. Briefly, the presynaptic spikes were detected, and a window was positioned in the postsynaptic trace, with the peak of the presynaptic spike at given position, producing a series of "spike-locked sweeps." These sweeps were then averaged, and positions were set for a peak measuring window (typically 2.5 msec long) and for a baseline measuring window (typically 2.0 msec long). The amplitudes of the individual events were then measured by subtracting the average currents within the two windows on each sweep. The noise was measured in a similar way (i.e., by using identical peak window length, baseline window length, and spacing between the windows) from the same sweeps, with the averaging windows positioned before the spike or from randomly generated points in the postsynaptic trace (this last method was preferred when the presynaptic firing rate was low). Care was taken to select a stationary presynaptic regimen to obtain a statistically meaningful estimate of the average evoked IPSC [or single-axon IPSC (sa-IPSC)]. Statistics The statistical significance of the difference of the mean of two samples was computed with a Mann-Whitney test. When three samples were compared [for the amplitude, coefficient of variation (CV), failure frequency, and variance over mean], an ANOVA was used first to show that the samples came from distributions with different means, and then a Mann-Whitney test was used on each pair of samples. The correlation between rise time and half-width and between amplitude and rise time of sa-IPSCs was estimated with Kendall's rank correlation coefficient. The variance used in the estimation of the CV and of the variance/mean ratio was computed by subtracting the noise variance from the evoked response variance. Because a reliable estimate of variance requires more data points than a reliable estimate of the mean, we obtained a reasonable estimate for only 21 of the 31 pairs. Averages are given together with the SE. Estimation of failure frequency In general the failure frequency (i.e., the estimate of the failure probability) could not be estimated by examining individual sweeps owing to the high background activity in the PCs and the small amplitude of the evoked events in more mature rats. Therefore, the cumulative distributions of both the sa-IPSCs and the noise were obtained by rank ordering, and the noise distribution was scaled to fit the sa-IPSC distribution in the negative current region. This scaling factor was taken as the failure frequency. For a few pairs with low background activity and large individual evoked IPSCs, an estimate of failure frequency could be obtained by classifying the individual sweeps as failure or success. In some pairs (5 of 31) insufficient data were collected to obtain a reliable estimate of failure probability. Morphology Our procedure was adapted from that of Horikawa and Armstrong (1988)
Whole-cell presynaptic. For paired-pulse experiments in young animals (P11-P15), in which the synaptic response to the first stimulus was large and in which the prestimulus baseline current was not reached within the interstimulus interval (30 msec), the response to the first stimulus was subtracted to correct the measurement of the second response. A scaled averaged response was used for this subtraction.
Two different embedding methods were used. The DAB-stained slices were dehydrated in an alcohol series and embedded in Canada balsam. A significant shrinkage (15-25%) occurred during the dehydration procedure. The DAB/Ni-stained slices were embedded directly in TB with 15-20% glycerol.
The Lucifer yellow-filled PCs were imaged with a CCD camera and a 63× water immersion objective. The DAB- and DAB/Ni-stained cells were photographed with a Zeiss microscope using a 100× (1.25 NA) oil immersion or a 40× (0.65 NA) objective, a 1.4 NA oil immersion condenser, differential interference contrast optics, and a green filter. The cells were drawn with a drawing tube attached to the microscope and the 100× objective. The photo montages were done with Adobe Photoshop.
RESULTS
This study is based on data from 31 basket cells (BC)- or stellate cells (SC)-PC pairs recorded from rat cerebellar slices, the ages of which ranged from P11 to P31. The whole-cell configuration of the patch-clamp technique (Hamill et al., 1981
Recordings from inhibitory interneurons (BCs and SCs) were obtained using a cell-attached and/or whole-cell configuration. In the first case "action currents" attributable to the spontaneous firing of these cells (Midtgaard, 1992a Developmental change of sa-IPSC amplitude
When paired recordings from young (P11-P15) and more mature (P26-P31) animals were compared, we observed a dramatic difference in sa-IPSC amplitude. This observation is illustrated in Figure 1, in which two BC-PC pairs are shown. The first cell pair (Fig. 1A) is from a P11 rat, and the second (Fig. 1B) is from a P28 rat. The recordings shown were obtained with a presynaptic whole-cell configuration. Figure 1, A3 and B4, illustrates individual postsynaptic responses to presynaptic stimuli (2 msec voltage pulses from
Fig. 1. Illustration of the developmental decrease of sa-IPSC amplitude. The PC layer has been oriented horizontally, the pial surface is toward the top, and the granular layer is toward the bottom. A, BC-PC pair from a P11 rat. A1, Photo montage of the pair with both cells filled with biocytin. The PC is on the left, and the BC is on the right. The BC axon can be followed until it enters the PC dendritic field and can be seen again as it continues its course past the PC. The PC axon is cut shortly after its origin. The external germinal layer can be seen above the limit of the Purkinje cell dendritic field (top left corner). A2, Drawing of the pair; the somatodendritic compartment of the basket cell is drawn in green, and its axon is in red. The PC is drawn in blue. The two arrows point to sites of putative synaptic contacts between the presynaptic axon and the postsynaptic cell. Note that the dendritic arborization of the BC is little developed at this stage, whereas its axon is already long and ramified but does not show any of the axosomatic specializations typical of BC-PC synapses. This pair was dehydrated and embedded in Canada balsam; during this procedure the slice shrunk with local inhomogeneities, which gave rise to the "wavy" appearance of the axon. The scale bar holds for both A1 and A2. A3, Examples of sa-IPSCs recorded in the PC after short voltage pulses in the presynaptic BC. B, BC-PC pair from a P28 rat. The BC was filled with biocytin, and the soma of the PC was filled with Lucifer yellow. B1, Detailed picture of the pair taken with fluorescence microscopy. The soma of the PC is the bright spot at the bottom (the dendritic tree of the PC was not filled). The soma of the BC is the black spot at the top. The BC axon originates on the right of the cell body (at "3 o'clock") and bends upward at the beginning of its course. Five out-of-focus dendritic branches of the BC are visible as well. A descending axon collateral of the BC comes in close apposition to the PC soma from the left. B2, Transmitted light picture of the same field as in B1. The soma of the PC is clearly recognizable (in focus) as well as the putative contact (on the left, at "9 o'clock"), the soma of the BC is slightly out of focus. The scale bar is common for B1 and B2. B3, General view of the BC (only two-thirds of the axon are shown). This slice was not dehydrated and was embedded in Tris buffer with 15% glycerol, leading to a better preservation of the neurite appearance than in A. B4, Examples of sa-IPSCs evoked in the PC on stimulation of the BC. Note the amplitude difference with the sa-IPSCs of A3. B5, Drawing of the pair. As in A, the somatodendritic compartment of the interneuron is green, the interneuron axon is red, and the postsynaptic PC is blue. The arrow points to the putative synaptic contact. The dendritic arborization of the BC is much more extensive than in A2. The axon sends two thick descending collaterals toward PC somata on the right. The scale bar holds for both B3 and B5.
[View Larger Version of this Image (97K GIF file)]
The developmental change in the mean unitary IPSCs obtained from 31 pairs is illustrated in Figure 2. We found that the average sa-IPSC decreased from 330 ± 100 pA in young animals (P11-P15) to 20 ± 7 pA in more mature animals (P26-P31). Thus, there is an order of magnitude difference between the amplitudes of sa-IPSCs observed in the two extreme ages. At the intermediate age (P16-P21) the mean sa-IPSC was 80 ± 18 pA. An ANOVA test showed that the three samples came from distributions with different means (p < 0.01). Moreover, the decrease in the average sa-IPSC amplitude with development is present independently of both cell type (circles, BCs; diamonds, SCs) and mode of presynaptic recording (filled symbols, whole-cell; open symbols, cell-attached). 
Fig. 2. Developmental changes of sa-IPSC amplitudes. Average sa-IPSCs from the 31 pairs studied. The data points for presynaptic BCs are marked by circles and for presynaptic SCs are marked by diamonds. Filled and open symbols represent presynaptic whole-cell and cell-attached recordings, respectively.
[View Larger Version of this Image (10K GIF file)]
Several nonexclusive factors can account for such a developmental decrease. First, one can argue that because Purkinje cell dendrites grow extensively during the period under investigation (Berry and Bradley, 1976 Morphology of the synaptic contacts
The morphology of 11 of the 31 pairs was retrieved (at least partially) after biocytin or Lucifer yellow staining (see Materials and Methods). The latter staining was used for PCs to make the interneuron axon easier to follow as it waves through the PC dendritic field. In young rats (P11-P15), pairs with either BCs or SCs as presynaptic elements were studied (Fig. 1A1,A2). In the intermediate period (P16-P21) one BC-PC pair and one SC-PC pair were visualized (data not shown), and in more mature rats (P26-P31) three BC-PC pairs were partially recovered (Fig. 1B3,B5).
In young rats the axonal diameter was uniform, exhibiting very few varicosities (putative synaptic sites; Breitenberg and Schüz, 1991
In the more mature rats, the BC axons were found to have a much more conventional morphology (Ramón y Cajal, 1911
The dendrites of Purkinje cells grow extensively during development. Therefore it is expected that attenuation of synaptic currents by dendritic filtering will increase with age. However, the morphological data suggest that at least some of the synaptic contacts in more mature animals are somatic or proximal, and thus, the attenuation of these contacts would be less than that expected at distal locations. Kinetics of the average sa-IPSCs
If the developmental decrease in the amplitude of the sa-IPSC was the result of passive filtering, a reduction in the amplitude and a slowing in the kinetics of the currents would be expected (Rall and Segev, 1985
The kinetics of the currents within and between age groups (young, P11-P15; and more mature, P26-P31) were compared as illustrated in Figure 3. For both age groups the largest (Fig. 3a,d), smallest (Fig. 3c,f) and an intermediate (Fig. 3b,e) sa-IPSCs are shown, all with the same time scale but with different amplitude scales (Fig. 3A1,A2,B1,B2). Figure 3B2 shows that slowly rising and decaying sa-IPSCs were recorded (Fig. 3f), as expected for an attenuated signal. But small average sa-IPSCs exhibiting a fast time course (the amplitude of Fig. 3e is 5 pA) were also recorded. A general comparison of the average sa-IPSC kinetics (Fig. 3C) showed a similarity of the two age groups, with rise times of 2.5 ± 0.4 msec at P11-P15 and 2.6 ± 0.5 msec at P26-P31 and half-widths of 15.3 ± 2.2 msec at P11-P15 and 16.7 ± 2.7 msec at P26-P31. Within both age groups a significant correlation was found between rise times and half-widths (p < 0.05) but not between rise times and amplitude (p > 0.05). The lack of correlation between the developmental reduction of synaptic current amplitude and slow kinetics together with the morphological data (showing that in more mature animals some of the PCs we recorded from receive somatic inputs from BCs) suggests that dendritic filtering cannot solely explain the 11-fold decrease in the sa-IPSC. 
Fig. 3. Kinetic properties of the sa-IPSCs. A, B, Averaged traces from P11-P15 (A) and P26-P31 (B) rats. For both ages the largest, the smallest, and an intermediate average are shown with the same time scale. A1, The largest (a, average of 80 sweeps) and an intermediate (b, dotted line, average of 71 sweeps) sa-IPSC from P11-P15 rats. A2, The smallest sa-IPSC from P11-P15 rats (c, average of 494 sweeps). B1, The largest sa-IPSC recorded from a P26-P31 rat (d, average of 50 sweeps). B2, An intermediate (e, dotted line, average of 969 sweeps) and the smallest sa-IPSCs (f, average of 2504 sweeps). These two currents have different time courses but similar peak amplitudes; f is filtered, and e is not. C, Plot of the half-width versus 10-90% rise time of the average sa-IPSCs in P11-P15 rats (open triangles) and P28-P31 rats (filled triangles). The two populations are kinetically similar, exhibiting the same correlation between rise time and half-width. The lower-case letters correspond to the currents shown in A and B. The filled triangle at the bottom left (the fastest current) corresponds to the BC-PC pair shown in Figure 1B; the slowest sa-IPSC from the younger rats (open triangle at top right) corresponds to the SC-PC pair of Figure 4A.
[View Larger Version of this Image (17K GIF file)]
Developmental change of paired-pulse responses
At the neuromuscular junction paired-pulse facilitation is inversely proportional to the mean quantal content, which is related to the release probability (Del Castillo and Katz, 1954
Two short pulses interspersed by 30 msec were used, and the paired-pulse ratio was measured. In Figure 4, an SC-PC pair from a P14 rat (Fig. 4A) is compared with a BC-PC pair from a P28 rat (Fig. 4B). In agreement with the dependence of the mean amplitude with age the mean amplitude of the first pulse response in Figure 4A was >600 pA, whereas it was only 75 pA in Figure 4B. The inflection at the end of the postsynaptic trace in Figure 4A is attributable to a spontaneous event. A strong depression of the second response was seen in the younger rat, whereas facilitation occurred in the more mature rat. In four experiments (with three SCs and one BC as presynaptic interneurons) at P11-P15 a paired-pulse depression was always seen, whereas in five of five cell pairs at P26-P31, paired-pulse facilitation was found (with three BCs and two SCs as presynaptic interneurons). The individual results are shown on Figure 4C. The average value of the paired-pulse ratio was 0.62 ± 0.16 at P11-P15 and 1.77 ± 0.23 at P26-P31; this difference was significant (p = 0.01). 
Fig. 4. Conversion of paired-pulse depression to paired-pulse facilitation. A, Paired-pulse stimulation at an SC-PC connection from a P14 rat. The top trace illustrates the presynaptic whole-cell current in response to the stimulating voltage pulse (the presynaptic interneuron was hyperpolarized from
[View Larger Version of this Image (10K GIF file)]
Developmental changes of variance and failure frequency of the sa-IPSCs
The previous result suggests that the release probability at individual sites decreases as development proceeds. For pairs in which a large number of evoked responses could be recorded, two additional parameters, related to presynaptic function, could be estimated independently: the CV of sa-IPSCs and the failure probability.
The squared inverse of the coefficient of variation, (1/CV)2, has been shown experimentally to increase by procedures increasing the release probability and to decrease when release probability is decreased (Clements 1990 
Fig. 5. Developmental changes of (1/CV)2, failure frequency, and variance over mean ratio. A, (1/CV)2 decreased with development; at P11-P15 it was 4.9 ± 1.6 (n = 8); at P16-P21 it decreased to 0.7 ± 0.2 (n = 7); and at P26-P31 it was 0.8 ± 0.2 (n = 6). B, Failure frequency increased from 0.12 ± 0.06 (n = 8) at P11-P15 to 0.33 ± 0.09 (n = 10) at P16-P21, and it was 0.33 ± 0.07 at P26-P31 (n = 8). C, Var/mean decreased from 87 ± 23 pA (n = 8) at P11-P15 and 80 ± 25 pA (n = 7) at P16-P21 to 18 ± 7 pA (n = 6) at P26-P31.
[View Larger Version of this Image (13K GIF file)]
The failure probability is another indicator of a presynaptic change that increases on a decrease of release probability or/and a decrease of number of release sites (Del Castillo and Katz, 1954
The three parameters previously studied suggest independently a presynaptic contribution to the overall developmental decrease in synaptic strength, but they do not rule out an additional postsynaptic change. To probe such a postsynaptic contribution, we evaluated the variance over mean ratio (var/mean) of individual sa-IPSCs. This parameter is expected to be dependent on the quantal size as predicted by the Poisson and the binomial models of synaptic transmission. In a Poisson model the quantal size, q is equal to var/mean, whereas in the binomial model q × (1
DISCUSSION
Our main finding is that the unitary IPSCs at both stellate cellDendritic filtering cannot account for the developmental reduction of sa-IPSC amplitudes
During development Purkinje cell dendrites increase extensively in length. Therefore, attenuation of synaptic signals by dendritic filtering is likely to be more pronounced in more mature animals. The extent of the attenuation depends on the location of the synaptic inputs, however, and proximal synapses are expected to be attenuated less than distal ones. At least some of the cell pairs we recorded from in more mature animals had proximal or somatic contacts, as indicated by the relatively fast rise time (Fig. 2B,C) and the putative location of release sites (Fig. 1B). Moreover, as a deterministic relationship is expected between the amplitude and the rise and decay times of filtered currents, they should have smaller amplitude and slower kinetics than the unfiltered ones (Rall and Segev, 1985Presynaptic contribution to the developmental reduction of sa-IPSC amplitude
We have found that during development there is a change in the response to paired-pulse stimulation that is generally interpreted as reflecting presynaptic properties. The results of Figure 4 demonstrate a switch from paired-pulse depression in P11-P15 rats to paired-pulse facilitation in P26-P31 animals and suggest a decrease of release probability with development. In addition, we found a sixfold decrease in (1/CV)2 and a threefold increase in the frequency of failures that are usually interpreted as reflecting a decrease in p or/and a decrease in number of release sites (N). A precise interpretation of the changes of these last two parameters is model-dependent, but we see a clear decrease of the mean quantal content (i.e., the product p × N, or the mean number of vesicles released per action potential). Overall it seems reasonable to postulate a decrease in release probability, leaving open the possibility of a change in the number of release sites. This result corresponds to what Bolshakov and Siegelbaum (1995)Postsynaptic contribution to the developmental decrease of sa-IPSC amplitude
We found a sixfold developmental reduction in the variance over mean ratio. This change could be interpreted, under specific assumptions, as suggesting a decrease of quantal size. However, further experiments that study receptor function directly are needed to understand the possible role of postsynaptic receptors in the overall developmental IPSC decrease. Interestingly, at another GABAergic synapse in the cerebellar cortex, a change in miniature IPSCs (mIPSCs) has been reported by Tia et al. (1996)Structure-function relation
As stated already, our morphological data do not allow us to evaluate the number of synaptic contacts between a given presynaptic interneuron and its postsynaptic PCs, and to our knowledge no quantitative morphological study of this synapse has been published. Nevertheless, our data can help address the nature of the difference between SCs and BCs. From the data in Figure 2, once dendritic filtering is taken into account, no major difference appears between IPSCs from BCs and SCs. Therefore, it seems reasonable to view SC and BC as a single cell type with different position of the cell bodies in the ML, as suggested by Ramón y Cajal (1911)
From another viewpoint it seems interesting to remark that the active zone of the BC Physiological consequences
Interneurons from the ML outnumber PCs by a factor of 10 in the adult rat (Korbo et al., 1993
FOOTNOTES
Received June 24, 1997; revised Aug. 15, 1997; accepted Sept. 12, 1997.
This work was supported by the Max-Planck-Society, grants from the European Community, Deutsche Forschungsgemeinshaft Grant SFB 406 (C.P.), and National Eye Institute Grant EYE09120 (S.H.). We thank Alain Marty and Isabel Llano for helpful discussions and support and Andrew Boxall, Dario Protti, Henrique von Gersdorff, Ralf Schneggenburger, Vinod Subramaniam, Céline Auger, and Boris Barbour for comments and discussion.
Correspondence should be addressed to Christophe Pouzat, Arbeitsgruppe Zelluläre Neurobiologie, Max-Planck-Institut für Biophysikalische Chemie, Am Fassberg, D-37077 Göttingen, Germany.
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