Stable Properties of Spontaneous EPSCs and Miniature Retinal EPSCs during the Development of ON/OFF Sublamination in the Ferret Lateral Geniculate Nucleus

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The Journal of Neuroscience, January 1, 1999, 19(1):236-247

Stable Properties of Spontaneous EPSCs and Miniature Retinal EPSCs during the Development of ON/OFF Sublamination in the Ferret Lateral Geniculate Nucleus
Carsten D. Hohnke and Mriganka Sur
Department of Brain and Cognitive Sciences, Massachusetts Institute of Technology, Cambridge, Massachusetts 02139

  ABSTRACT

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Retinal projections to the lateral geniculate nucleus (LGN) in ferrets progressively segregate into eye-specific laminae andsubsequently into sublaminae that receive inputs from either ON-centeror OFF-center afferents. To study the development of synapticefficacy during a period of activity-dependent growth and reorganizationin the CNS, we recorded spontaneous EPSCs (sEPSCs) from cellsof the LGN during ON/OFF sublamination. We also examined retinalinputs specifically by stimulating the optic tract in the presenceof strontium and recording evoked miniature EPSCs (emEPSCs). Therise times, areas, half-widths, and decay times of sEPSCs andemEPSCs and interevent intervals of sEPSCs recorded at the beginningof ON/OFF sublamination were not different from those recordedafter its completion. Typically EPSC areas were small (10-20 fC)but varied greatly both within and between neurons. The frequencyof sEPSCs was also quite variable, ranging from 0.2 to 5 Hz. sEPSCswere equivalent to miniature EPSCs recorded in the presence oftetrodotoxin, and both sEPSCs and emEPSCs were CNQX-sensitive.No difference was observed between sEPSCs recorded at room temperatureand those recorded at 34°C, and strontium could be substitutedfor calcium with no effect on sEPSC shape. These data argue fora remarkable stability in the components of at least AMPA-mediatedsynaptic transmission during a period of major synaptic rearrangementin theLGN.

Key words: activity-dependent; pattern formation; AMPA-synapse; retinal axons; LTP; visual system

  INTRODUCTION

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

The development of precise connectivity in the mammalian visual system depends on normal neural activity (for review, seeGoodman and Shatz, 1993; Cramer and Sur, 1995; Katz and Shatz,1996). For example, the segregation of left and right eye inputsin the visual cortex is disrupted after neonatal lid suture (Shermanand Spear, 1982) or intraocular injections of tetrodotoxin (TTX)(Stryker and Harris, 1986). Activity is also crucial to the developmentof the appropriate wiring in structures involved in earlier stagesof visual processing. In the ferret, retinogeniculate axons fromthe two eyes segregate during development to form eye-specificlayers (Linden et al., 1981). Subsequently, within each of theeye-specific layers, inputs from ON-center and OFF-center retinalganglion cells segregate to form sublaminae (Stryker and Zahs,1983; Hahm et al., 1991). Segregation of retinal inputs into eye-specificlaminae is modulated by activity (Shatz and Stryker, 1988; Cooket al., 1996; Penn et al., 1998), and the segregation into ON/OFFsublaminae is disrupted entirely by intraocular TTX injections(Cramer and Sur, 1997), inactivation of NMDA receptors (Hahm etal., 1991), or nitric oxide blockade (Cramer et al., 1996).

Not only is normal neural activity critical for appropriate retinogeniculate axon development, it is also involved in thedevelopment of its major postsynaptic target, the relay cellsof the lateral geniculate nucleus (LGN). When D-APV, an NMDA receptorantagonist, is infused into the thalamus during the third postnatalweek, LGN relay cells show an increase in dendritic branchingand the number of dendritic spines (Rocha and Sur, 1995). Likewise,intracranial infusions of TTX in fetal cats cause an increasein the density of dendritic spines (Dalva et al., 1994). Laterin development, after eye opening, the normal elimination of transientdendritic spines is delayed after early eye enucleation (Suttonand Brunso-Bechtold, 1993).

Activity-dependent development of connections in the visual system has components that seem to be shared with long-term potentiation(LTP) of synapses in the CA1 region of the hippocampus (Shatz,1990; Goodman and Shatz, 1993; Cramer and Sur, 1995). For example,both phenomena require electrical activity but may also requireNMDA receptor activation, nitric oxide production (Bliss and Collingridge,1993), and neurotrophin signaling (Cabelli et al., 1995; Kangand Schuman, 1995). Consequently, it has been suggested that LTPand its counterpart, long-term depression, underlie the stabilizationand withdrawal of synapses in developing sensory structures (Constantine-Patonet al., 1990; Kandel and O'Dell, 1992; Goodman and Shatz, 1993;Cramer and Sur, 1995; Katz and Shatz, 1996; Constantine-Patonand Cline, 1998). A similar mechanism may operate at the neuromuscularjunction where changes in connectivity are preceded by experience-drivenchanges in synaptic efficacy (Colman et al., 1997). Yet, exactlyhow changes in the wiring between two neurons are reflected bychanges in synaptic transmission between them is not wellunderstood.

There is, however, a growing body of evidence that suggests that NMDA receptor-mediated activity plays an important role ininitiating the stabilization of appropriate inputs during development(for review, see Hofer et al., 1994; Cramer and Sur, 1995; Constantine-Patonand Cline, 1998). NMDA receptors undergo developmental changesin their subunit composition in several regions of the nervoussystem (for review, see Scheetz and Constantine-Paton, 1994) thatcoincide with decreases in NMDA-mediated currents at the end ofperiods of axonal reorganization (Ramoa and Prusky, 1997; Shiet al., 1997). The longer duration of NMDA receptor-mediated responsesat immature synapses may facilitate the induction of a form ofLTP expressed as an increase in the effectiveness of AMPA responses(Constantine-Paton and Cline, 1998).

As a first step toward examining changes in AMPA-mediated synaptic transmission during a period of activity-dependent, axonalreorganization in the CNS, we have recorded spontaneous EPSCs(sEPSCs) and optic tract-evoked miniature EPSCs (emEPSCs) in brainslices from ferrets of varying ages during the period of ON/OFFsublamination in the LGN; at the retinogeniculate synapse sEPSCshave been shown to be quantal and equivalent to mEPSCs (Paulsenand Heggelund, 1994). In the LGN dramatic changes in connectivityare thought to be occurring during ON/OFF sublamination. Retinalaxons are refined in an activity-dependent manner during the thirdand fourth postnatal weeks (Cramer et al., 1996; Cramer and Sur,1997). Anatomical data from the cat suggest that the number ofretinal synapses on LGN cells increases by ~25% during the first8 weeks postnatally (Kalil and Scott, 1979; Mason 1982), whereasthe number of cortical inputs increases eightfold during the first10 weeks (Weber and Kalil, 1987). In addition to changes in NMDAreceptor-mediated current and a possible increase in the efficacyof AMPA synapses, it is possible that developmental changes inthe subunit composition of AMPA receptors occur during ON/OFFsublamination as they do in other regions of the nervous system(Durand and Zukin, 1993; Rossner et al., 1993; Jakowec et al.,1995). Thus, there are a number of reasons to expect changes insEPSCs and emEPSCs over thisperiod.

Surprisingly, we find no change in the properties of AMPA-mediated spontaneous and miniature retinal EPSCs over the periodof ON/OFF sublamination. These data have interesting implicationsfor activity-dependent development of retinogeniculatesynapses.

Preliminary reports have been published in abstract form (Hohnke and Sur, 1996, 1998).

  MATERIALS AND METHODS

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Whole-cell patch-clamp recordings (Blanton et al., 1989) were made during voltage clamp of LGN relay cells in thalamic slices(400 µm thick) from young [postnatal day 12 (P12) to P31] ferrets.The animals were deeply anesthetized with sodium pentobarbital(35 mg/kg, i.p.) and decapitated. A block of tissue includingthe thalamus was rapidly removed and placed in a cold solution(4°C) containing (in mM): NaCl (126), KCl (3), MgSO₄ (2), NaHCO₃(25), NaHPO₄ (1), CaCl₂ (2.5), and dextrose (10), saturated with95% O₂ and 5%CO₂, pH 7.4. In some experiments NaCl was replacedwith equiosmolar sucrose (252 mM; Aghajanian and Rasmussen, 1989),and kynurenic acid (0.5 mM) was added to minimize excitotoxicityduring slicing. The cortex was dissected away, and the remainingthalamus was sliced in the horizontal or coronal plane with aVibratome (Ted Pella model1000).

In most experiments, slices were maintained at room temperature and continuously superfused with the NaCl-based solution describedabove (control medium). In some experiments 50 µM bicucullinemethiodide (BMI; Sigma Chemical Co., St. Louis, MO), 1 µM tetrodotoxin(TTX, Sigma), and/or 10 µM 6-cyano-7-nitroquinoxaline-2,3-dione(CNQX disodium; Research Biochemicals, Natick, MA) was added tothe control medium. In a few experiments the calcium was replacedwith strontium (1-3 mM). Before "blind" recording, a slice wastransferred to an interface-type chamber and given 45 min to equilibrateto 34°C. In later experiments slices were transferred to a submersionchamber, and recordings were performed at room temperature undervisual control with differential interference contrast-enhancedoptics. In both cases, the boundaries of the LGN and the positionof the recording electrode were visible, and recordings were madein the A or A1lamina.

Retinal afferents were stimulated by delivering constant current through a bipolar stimulating electrode positioned in theoptic tract at the lateral edge of the slice. Electrical stimuli,averaging 5 mA for 0.02 msec, were delivered at 0.5 Hz, and emEPSCswere detected (as described below) during the 1 sec period afterthe synchronous response. Stimulus strength was set at a valueslightly greater than the value that produced the minimalresponse.

Patch pipettes were pulled from borosilicate glass (World Precision Instruments) on a horizontal pipette puller (Sutter Instruments)to tip resistances of 3-8 M $Omega$ . The pipettes were filled with (inmM): potassium gluconate (125), KCl (10), HEPES (10), sodium EGTA(1), CaCl₂ (0.1), MgCl₂ (2), Na-ATP (2), and Na-GTP (0.2) or cesiumgluconate (120), HEPES (10), sodium EGTA (1), CaCl₂ (0.1), MgCl₂(2), Na-ATP (2), and Na-GTP (0.1); the pH was adjusted to 7.3.Recordings were obtained with an Axopatch-200 amplifier (AxonInstruments), digitized using a Neurocorder encoding unit (Neurodata),and stored on video tape and computer disk for off-line analysis.Access resistance was monitored throughout the experiment butnot compensated for. Recordings that varied by >20% were not analyzed.Data were acquired off-line with the pClamp data acquisition software(Axon Instruments) and analyzed using Matlab (MathWorks). Cellswere voltage-clamped at $-$ 60 mV. Cells that showed overshootingaction potentials and that had resting membrane potentials morehyperpolarized than $-$ 40 mV were considered for analysis. Recordingsused for analysis had series resistances <33 M $Omega$ . sEPSCs and emEPSCswere automatically detected (using a threshold of 1.5-2.5 timesthe SD of the noise) below a moving average of the current andwere reviewed by visual inspection to eliminate noise-induceddetections. The events were fit using a least squares algorithmwith the sum of three (one rising and two decaying) exponentials(Soltesz and Mody, 1995). Area was calculated by integrating thefitted curve between the beginning and end of the event. Risetimes were calculated from 20 to 80%, widths at 50%, and decaytimes at e¹ of peak amplitude. Recordings from animals P29 and older (whenON/OFF sublamination is complete), termed the "older" group, werecompared with recordings from P12-P24 animals (when ON/OFF sublaminaeare actively segregating within eye-specific layers), termed the"younger"group.

Five types of nonparametric statistical analyses were performed, because none of the data appeared to be normally distributed,and, given the highly skewed nature of the distributions, medianvalues were used as the preferred measure of central tendency.Spearman's rank correlation was used to test for significant correlations.Median parameter values between groups were compared with theMann-Whitney U test, or, if the number of groups was more thantwo (e.g., when testing for interactions between intracellularsolution and age), with the Kruskal-Wallis nonparametric ANOVA.Parameter distributions from different conditions within the samerecording were compared with the Kolmogorov-Smirnov test. Finally,the Siegel-Tukey test was used to determine whether the varianceof median parameter values was different for the two groups. Valuesare presented as medians (mean ± SDs). In Figures 2B and 8B, valuesare expressed as SDs from the mean to allow the pooling of eventsacross cells (Hsia et al., 1998). To represent the younger andolder groups in the pool equally, 50 randomly selected eventswere chosen from an equal number of the youngest cells and oldestcells for which there were at least 50events.

  RESULTS

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

Spontaneous EPSCs

Spontaneous EPSCs were analyzed in 32 cells from animals between P12 and P31. sEPSCs were observed in ~66% of the cells andwere recorded from animals at all ages throughout the period ofsublamination. We observed no correlation between the age at whichrecordings were made and the observation of sEPSCs. We recorded2222 sEPSCs from younger animals and 739 sEPSCs from older animals.Typical distributions of areas and the averaged sEPSC for oneyounger and one older cell are shown in Figure 1. The histogramsshow skewed distributions that were observed at all ages for allsEPSC parameters measured and are similar to those seen in otherregions of the brain, including the hippocampus (McBain and Dingledine,1992, 1993; Jonas et al., 1993) and cerebral cortex (Hestrin 1992,1993; Stern et al., 1992). Pooled data from 10 of the youngestand 10 of the oldest cells show sEPSC area and interevent interval(IEI) histograms that are similar (Fig. 2A). Indeed, the shapesof the distributions were the same for the two groups (p > 0.05,Kolmogorov-Smirnov test; Fig. 2B), as were the distributions forrise, width, and decay times (p > 0.05).

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Figure 1. sEPSC areas in the LGN are stable during ON/OFF sublamination. Histograms of sEPSC areas and example current traces from a P19 (A) and a P30 (B) neuron are shown. Histograms for all properties measured were skewed toward larger values and showed considerable variability. The bottom traces for each neuron are averages of 50 consecutive sEPSCs.

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Figure 2. The shape of sEPSC area and IEI distributions is stable over ON/OFF sublamination. A, Histograms of pooled data from the youngest cells (n = 10) and the oldest cells (n = 10) are similar for both sEPSC area and IEIs. B, Cumulative histograms of the standardized areas and IEIs show that the shapes of the distributions did not change with age (p > 0.05, Kolmogorov-Smirnov test).

There was a significant correlation between access resistance and age (r_s = $-$ 0.41; p < 0.05), decreasing in the older animals[14 (13 ± 7) M $Omega$ ; n = 13 (from 10 animals)] compared with the youngeranimals [23 (23 ± 8) M $Omega$ ; n = 19 (from 13 animals)]. Consequently,sEPSC parameters that are sensitive to access resistances wouldshow artifactual developmental changes (Hohnke and Sur, 1996).However, the two parameters that we report on here are relativelyinsensitive to changes in access resistance. Neither the areasof the sEPSCs (r_s = 0.01; p > 0.05) nor their IEIs (r_s = $-$ 0.17;p > 0.05) were correlated with the access resistances. In contrast,peak amplitudes were significantly correlated with access resistance(r_s = $-$ 0.42; p < 0.05) and remained so when analysis was limitedto recordings with access resistances $<=$ 20 M $Omega$ (r_s = $-$ 0.71; p <0.05). Whole-cell capacitance was also significantly correlatedwith age (r_s = 0.48; p < 0.05), increasing from a median valueof 60 (61 ± 22) pF in the younger animals to 77 (76 ± 22) pF inthe older animals. The increase is likely attributable to thedevelopmental increase in soma size during this period (Suttonand Brunso-Bechtold, 1991; Rocha and Sur, 1995).

There was no correlation between age and resting potential (r_s = 0.09; p > 0.05; Fig. 3A). Median resting membrane potentialwas $-$ 50 mV ( $-$ 51 ± 8 mV; n = 19) in younger animals and $-$ 53 mV( $-$ 54 ± 12 mV; n = 13) in older animals. Input resistances, however,were significantly correlated with age (r_s = $-$ 0.53; p < 0.05).Input resistances were quite variable in the younger animals [217(384 ± 493) M $Omega$ ] and decreased by 33% in the older animals [147(166 ± 109) M $Omega$ ; Fig. 3B]. The variability in input resistanceshas been noted in other reports of adult and developing LGN cells(Bloomfield et al., 1987; White and Sur, 1992; Ramoa and McCormick,1994a) and is likely attributable to a large variability in thespecific membrane resistance of specific cell types (Bloomfieldet al., 1987). Part of the decrease in input resistance was attributableto the large input resistances of the two youngest neurons (P12);nonetheless, excluding these two neurons from the analysis didnot change the significance of the correlation (r_s = $-$ 0.43; p< 0.05).

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Figure 3. Development of electrophysiological and sEPSC properties of LGN cells during ON/OFF sublamination. Resting membrane potentials of cells were unchanged (A), whereas input resistances decreased significantly (B). The large input resistances recorded at P12 did not alter the significance of the developmental decrease (see Results for details). Neither sEPSC areas (C) nor IEIs (D) changed during this developmental period.

There was no significant change in the charge transfer of sEPSCs during the period of ON/OFF sublamination (Fig. 3C). Specifically,median area in the younger animals was 15 (21 ± 19) fC, and medianarea in the older animals was 15 (18 ± 9) fC (p > 0.05). Neitherwas the frequency of sEPSCs significantly changed after reorganizationof the retinal axons (Fig. 3D). The median IEI in the youngeranimals [529 (647 ± 439) msec] was slightly shorter than in theolder animals [705 (1059 ± 1096) msec; p > 0.05]. Limiting theanalysis to those recordings with $<=$ 20 M $Omega$ access resistance (n= 17) demonstrated that there was no correlation between accessresistance and rise times (r_s = 0.07; p > 0.05), half-widths (r_s= 0.12; p > 0.05), and decay times (r_s = 0.13; p > 0.05). In thissubpopulation of recordings no correlation was observed betweenage and rise times (r_s = 0.27; p > 0.05), half-widths (r_s = 0.45;p > 0.05), or decay times (r_s = 0.45; p > 0.05). Both areas andIEIs remained uncorrelated with access resistance and age. Thus,the younger and older groups had equivalent sEPSCs (Table 1).


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Table 1. Properties of sEPSCs in the LGN during and after ON/OFF sublamination

The sEPSCs we report on in this study were recorded in a number of different conditions that had little effect on their areasor IEIs. To fully characterize sEPSCs in the ferret LGN, we wereinterested in recording sEPSCs in the presence of an alternatedivalent cation. We tested whether replacing calcium with strontium,the most effective substitute for calcium with regard to transmitterrelease (Miledi 1966; Goda and Stevens, 1994; Abdul-Ghani et al.,1996; Oliet et al., 1996; Choi and Lovinger, 1997; Morishita andAlger, 1997), would affect the size or frequency of sEPSCs. Ourexperiments show that strontium is equivalent to calcium in supportingsEPSCs in the developing LGN; both the sEPSC areas and IEIs wereunchanged in the presence of strontium (Fig. 4). Recordings in0 mM calcium and 1-3 mM strontium revealed sEPSCs with areas [16(20 ± 12) fC] and IEIs [655 (825 ± 396) msec; n = 6] that werenot different from those recorded in normal calcium [15 (20 ±17) fC; p > 0.05; 607 (812 ± 859) msec; p > 0.05; n = 26]. Nodevelopmental change in the efficacy of strontium was observed.In strontium solutions, the areas [13.5 (13.5 ± 2.7) fC] and IEIs[583 (583 ± 126) msec] in the younger group (n = 2) were not significantlydifferent from the areas [18.1 (23.4 ± 13.4) fC; Q = 1.23; p >0.05, Kruskal-Wallis nonparametric ANOVA] and IEIs [932 (946 ±444) msec; Q = 0.86; p > 0.05] in the older group (n = 4; Table2).

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Figure 4. Strontium supports spontaneous synaptic transmission in the developing LGN. Sample histograms of sEPSC areas and IEIs for a P19 neuron recorded in calcium (A) are similar to those for a P15 neuron recorded in strontium (B). Traces are averages of 25 sEPSCs from each neuron. Strontium was as effective in mediating sEPSCs as calcium in both the younger and older groups.


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Table 2. Size and frequency of sEPSCs in the LGN under different recording conditions

The vast majority of sEPSCs that we recorded were CNQX-sensitive, quantal events: CNQX (10 µM) blocked all sEPSCs (n = 3;Fig. 5A), and sEPSCs under TTX blockade were similar to normalsEPSCs (Fig. 5B). The distributions of the IEIs in control [759(668 ± 249) msec] and TTX [483 (612 ± 358) msec] solutions werenot significantly different (in all cases p > 0.05, Kolmogorov-Smirnovtest; n = 4; Fig. 5C). Likewise, there was no significant changein sEPSC areas in TTX [13 (13 ± 5) fC] compared with control [13(13 ± 2) fC] solutions (in one case p = 0.02; in three cases p> 0.05, Kolmogorov-Smirnov test; Fig. 5D). By clamping the cellsat $-$ 60 mV, close to the chloride reversal potential, we expectedto not detect any spontaneous inhibitory postsynaptic currents.Indeed, no significant differences in areas or IEIs were observedbetween control (n = 7) and BMI solutions (n = 21) when recordingfrom animals of similar ages (Table 2).

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Figure 5. sEPSCs at resting membrane potential are AMPA-mediated, quantal events. A, CNQX blocked all sEPSCs. B, Five individual sEPSCs and their average traces are shown for control and TTX conditions. Cumulative amplitudes of sEPSC IEIs (C) and areas (D) show no difference between sEPSCs recorded in control and TTX solutions. The sEPSCs from four experiments are combined in each condition for illustrative purposes. Statistical analyses were performed for each experiment individually (see Materials and Methods for details).

Additionally, eight recordings with cesium gluconate in the recording electrode produced sEPSCs similar to those recordedwith potassium gluconate (n = 24). A slight but significant differencewas observed between sEPSC areas recorded from younger animalswith cesium gluconate and sEPSC areas recorded from older animalswith potassium gluconate (Q = 2.75; 0.02 < p < 0.05). However,no significant differences in areas or IEIs were observed betweenthe intracellular solutions when recording from animals of similarages. There were also no significant differences in areas or IEIsbetween sEPSCs recorded at room temperature and those recordedat 34°C (p > 0.05; Table 2).

Finally, we examined the coefficient of variation (CV) of the areas and IEIs of the sEPSCs to determine whether changes inthe variability of these parameters occurred during ON/OFF sublamination.There was no age-dependent change in the variability of sEPSCswithin a recording for any of the parameters measured. The medianCV (of the individual CVs) for area was 0.58 in the younger animalsand 0.57 in the older animals. The median CV for IEI was 1.1 inboth the younger and older animals. There was also no change inthe variability of sEPSCs between recordings. The variance ofthe median values in the younger group was not different fromthe variance in the older group for all the parameters measured(p > 0.5, Siegel-Tukeytest).

Evoked miniature EPSCs

To examine the retinal synapses specifically, we evoked asynchronous transmitter release by stimulating the optic tract afterreplacing extracellular calcium with strontium (Miledi, 1966;Goda and Stevens, 1994; Abdul-Ghani et al., 1996; Oliet et al.,1996; Choi and Lovinger, 1997; Morishita and Alger, 1997). Replacingextracellular calcium with strontium caused a marked decreasein the normal, synchronous release of transmitter and caused anafterdischarge of miniature EPSCs lasting up to 1 sec but occurringprimarily in the first 500 msec (Fig. 6).

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Figure 6. Replacing extracellular calcium with strontium allows for the analysis of unitary, retinal EPSCs. A, Stimulation of the optic tract in the presence of normal calcium results in a large EPSC. B, Replacing calcium with strontium causes a marked decrease in the synchronous response to stimulation and generates a discharge of asynchronous transmitter release. C, In the absence of stimulation, the frequency of sEPSCs is extremely low, suggesting that there is little contamination of the emEPSCs by sEPSCs of unknown origin. D, CNQX blocked all emEPSCs as well as what remains of the synchronous response in strontium. E, Responses to stimulation recovered after removal of CNQX from the bath.

Evoked miniature EPSCs were analyzed in 11 additional cells from animals between P15 and P31. We recorded 762 emEPSCs fromyounger animals and 529 emEPSCs from older animals. Typical distributionsof areas and the averaged emEPSC for one younger cell and oneolder cell are shown in Figure 7. As with sEPSCs, histograms ofemEPSC parameters showed skewed distributions at all ages. Morespecifically, pooled data from the youngest (n = 5) and the oldest(n = 5) cells show emEPSC area histograms with similar shapes(Fig. 8A). The cumulative histograms were the same for the twogroups (p > 0.05, Kolmogorov-Smirnov test; Fig. 8B), as were thedistributions for rise, width, and decay times (p > 0.05).

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Figure 7. emEPSC areas in the LGN are stable during ON/OFF sublamination. Histograms of emEPSC areas and example current traces from a P15 (A) and a P31 (B) neuron are shown. The bottom traces for each neuron are averages of 50 consecutive emEPSCs.

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Figure 8. The shape of emEPSC area distributions is stable over ON/OFF sublamination. A, Histograms of pooled data from the youngest cells (n = 5) and the oldest cells (n = 5) are similar for sEPSC area. B, Cumulative histograms of the standardized areas show that the shapes of the distributions did not change with age (p > 0.05, Kolmogorov-Smirnov test).

The access resistances of the recordings in this set of experiments were <20 M $Omega$ . The areas (r_s = 0.22; p > 0.05), rise times(r_s = 0.08; p > 0.05), and decay times (r_s = 0.05; p > 0.05) ofthe emEPSCs were not correlated with access resistance. The peakamplitudes of the emEPSCs, however, tended to correlate with theaccess resistance (r_s = $-$ 0.54; p = 0.06) as they did for the recordingsofsEPSCs.

The input resistances of the recordings in this set of experiments revealed the same developmental decrease that was observedduring the first set of experiments. Input resistance in the youngeranimals was 455 (424 ± 116) M $Omega$ , and input resistance in the olderanimals was 116 (191 ± 193) M $Omega$ (r_s = $-$ 0.58; p < 0.05).

The properties of emEPSCs recorded from younger animals [n = 5 (from three animals)] before ON/OFF sublamination were notdifferent from those made from older animals [n = 6 (from fouranimals)] after sublamination was complete. Median area in theyounger animals was 16 (14 ± 4) fC, and median area in the olderanimals was 22 (23 ± 11) fC (p > 0.05; Table 3). Rise times,widths, and decay times were also unchanged after the completionof sublamination (p > 0.05 for all comparisons; Table 3). Nocorrelation was observed between age and emEPSC rise times (r_s= 0.31; p > 0.05), areas (r_s = 0.29; p > 0.05), half-widths (r_s= 0.36; p > 0.05), or decay times (r_s = 0.41; p > 0.05).


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Table 3. Properties of evoked miniature retinal EPSCs in the LGN during and after ON/OFF sublamination

In general, emEPSCs and sEPSCs were quite similar. emEPSC areas in the younger animals [16 (14 ± 4) fC] were not differentfrom sEPSCs in the younger animals [15 (21 ± 19) fC; p > 0.05],nor were emEPSCs in the older animals [23 (23 ± 11) fC] differentfrom sEPSCs in the older animals [15 (18 ± 9) fC; p > 0.05]. Risetimes, widths, and decay times of emEPSCs were not different fromthose calculated for sEPSCs (compare Tables 1 and 3). More specifically,the areas and decay times of emEPSCs and sEPSCs from the samerecordings were not different from one another (n = 2; in bothcases p > 0.05, Kolmogorov-Smirnov test). In one cell, the risetimes of the emEPSCs [0.41 (0.44 ± 0.15) msec] were slightly shorterthan those of the sEPSCs [0.48 (0.54 ± 0.19) msec; p < 0.05, Kolmogorov-Smirnovtest] from the same recording. emEPSCs, like sEPSCs, were AMPA-mediatedat resting membrane potentials and could be blocked completelywith CNQX (10 µM; n = 6; Fig. 6). Last, the within-cell CV showedno age-dependent change for any of the parameters measured, norwas there a change in the variability of sEPSCs between recordings(p > 0.05, Siegel-Tukeytest).

  DISCUSSION

Top
Abstract
Introduction
Materials & Methods
Results
Discussion
References

We have demonstrated that sEPSCs are present in ferret LGN cells as early as P12 and occur throughout the period of ON/OFFsublamination. The results presented here suggest that the basicphysiological properties of these unitary inputs onto LGN cellsare present at the beginning of ON/OFF sublamination and do notchange significantly, although at least the retinal inputs areundergoing dramatic, activity-dependent anatomical reorganizationand development. Because the population of sEPSCs recorded froma neuron may be generated from a heterogeneous set of synapsetypes (e.g., retinal and cortical synapses), it is possible thatchanges occurring among one of those types are masked in our data.We examined retinal synapses specifically and show that unitary,AMPA-mediated, retinal EPSCs remain unchanged during ON/OFF sublaminationand are not different from the population of sEPSCs. Indeed, thesimilarity of sEPSCs and emEPSCs suggests that sEPSCs might derivelargely if not solely from retinalsynapses.

We analyzed these data for group differences (younger vs older group) as well as for correlation with age. Sublaminae canfirst be seen by P21 (Hahm et al., 1991) and are sharply segregatedby P26 (Cramer et al., 1996). There were very few cells in oursample between P21 and P24 (see Fig. 3); their properties werenot different from the younger group of cells, and they were includedin this group for analysis. Furthermore, the correlation analysesshowed no trend in any of the EPSC parameters withage.

Three caveats to our data should be noted. First, we recorded from a heterogeneous population of cells in the A layers ofthe LGN that include X-cells, Y-cells, and interneurons. It isunlikely that we recorded from many interneurons: recordings fromcells with small somas [which are characteristic of interneurons(Friedlander et al., 1981)] were avoided, and all cells includedin the analysis displayed easily evoked low-threshold calciumspikes, a characteristic of LGN relay cells (McCormick and Pape,1988). However, although we observed no systematic variationsin our data that might correlate with different LGN cell types,such a relationship cannot be excluded. Second, we recorded EPSCsonly at resting membrane potentials. Hence, changes at synapsesmediated by conductances not active at rest (NMDA receptors, forexample) cannot be excluded. Third, to the extent that changesin presynaptic transmitter release are not well assayed by thefrequency of sEPSCs (see below), they would not have been detectedby theseexperiments.

Another issue deserves comment. It is possible that immature inputs may have such low sEPSC amplitudes and/or frequenciesthat they cannot be reliably detected. However, our detectionthresholds allowed us to detect sEPSCs with extremely small amplitudesand areas (e.g., we detected events with amplitudes that wereless than two times the SD of the baseline noise). Additionally,we observed no increase in sEPSC frequency, which would be expectedif undetectably low, immature sEPSC frequencies matured to thefrequencies we observed during ON/OFFsublamination.

Comparison with other systems

The lack of developmental changes in sEPSCs that we observe in the LGN are similar to those reported for unitary EPSCs inthe rat neocortex (Burgard and Hablitz, 1993). That is, the characteristicsof sEPSCs are present early in development and do not change significantlyduring the third and fourth postnatal weeks. The development ofsEPSCs, miniature EPSCs (mEPSCs), and minimal evoked EPSPs (meEPSPs)have also been examined in other systems. The amplitude of sEPSCsand mEPSCs does not change in early development in the rat superiorcolliculus and visual cortex (Carmignoto and Vicini, 1992; Hestrin,1992; Shi et al., 1997). A developmental increase in meEPSP amplitudesbetween the third and fifth postnatal weeks has been reportedin the rat hippocampus to be attributable to an increase in quantalcontent as opposed to quantal size (Dumas and Foster, 1995). Infact, as in our study, mEPSCs do not increase in size during hippocampaldevelopment (Hsia et al., 1998). In the rat superior colliculus,NMDA-mediated mEPSC and sEPSC decay times decrease during thesecond and third postnatal weeks (Hestrin, 1992; Shi et al., 1997);NMDA-mediated decay times also decrease with age in visual cortex(Carmignoto and Vicini, 1992). The differences observed in thedevelopment of mEPSCs in various mammalian brain regions may beattributable to intrinsic differences in those regions or differencesin the recording conditions. For example, the experiments in visualcortex and superior colliculus were concerned with isolating theNMDA components of the mEPSCs and recorded events in the presenceof zero magnesium and/or at extremely depolarized potentials.In addition, Hestrin (1992) reported a qualitative, but not aquantitative, decline in mEPSC decay time in the superior colliculus.Shi et al. (1997) reported a decrease in sEPSC frequency afterretinocollicular map refinement in the rat that they suggest maybe attributable to the onset of GABA_A-mediated inhibition. GABA_A-and GABA_B-mediated inhibition first appear in the developing ferretLGN at P15 and between P21 and P30, respectively (Ramoa and McCormick,1994b), but we observed no significant decrease in the frequencyof sEPSCs at those times. In contrast, mEPSC frequency has beenreported to increase dramatically during hippocampal development(Hsia et al., 1998). In any case, a change in unitary EPSC frequencywould be difficult to interpret in developmental slice physiologystudies. Changes in frequency could be attributable to the slightlydifferent planes of section (Staley and Mody, 1991) and/or changesin the number of preserved contacts in a slice resulting fromthe growth and movement of a structure during development. Last,Blanton and Kriegstein (1991) reported increases in frequencyand rise and decay times of mEPSCs during embryonic developmentof the turtle cortex. These changes contrast with what is observedin the rat and ferret and may be attributable to species differencesor a difference in the developmental stage between an embryonicturtle cortex and postnatal cortical and subcortical structuresinmammals.

Retinogeniculate transmission during sublaminar segregation

We show that strontium can substitute for calcium in mediating sEPSCs at retinogeniculate synapses. No change in sEPSC sizeor frequency is observed when calcium is replaced with equal concentrationsof strontium. Strontium has been shown to be the most efficientsubstitute for calcium at the neuromuscular junction (Miledi,1966; Dodge et al., 1969; Meiri and Rahamimoff, 1971; Bain andQuastel, 1992). Fast synchronous release is inhibited when calciumis replaced with strontium, but the slower, asynchronous releaseis facilitated. Transmitter release is quantal in strontium, andspontaneous release continues. Similar findings have been reportedmore recently in the CNS (Goda and Stevens, 1994; Abdul-Ghaniet al., 1996; Oliet et al., 1996; Choi and Lovinger, 1997; Morishitaand Alger, 1997). In hippocampal slices, as in our study, thesize and frequency of sEPSCs are unchanged in the presence ofstrontium (Oliet et al., 1996). In addition to showing that strontiumcan be substituted for calcium, our findings show that the efficacyof that substitution is not altered during a period of activity-dependentplasticity in earlydevelopment.

We observe stable resting membrane potentials (RMPs) and a decrease in input resistances of LGN cells during sublamination.Two previous reports of the physiological development of ferretLGN cells, one using intracellular recordings (White and Sur,1992) and the other using whole-cell patch-clamp (Ramoa and McCormick,1994a), likewise reported a developmental decrease in input resistanceand stable RMPs during the third and fourth postnatal weeks. Adevelopmental decrease in input resistance has also been reportedin mouse thalamus (Warren and Jones, 1997), rat thalamus (PerezVelazquez and Carlen, 1996), rat superior olivary complex (Kandlerand Friauf, 1995), rat hippocampus (Spigelman et al., 1992), andrat neocortex (McCormick and Prince, 1987; Annis et al., 1993).In the LGN, it is possible that the observed developmental decreasein input resistance reflects a bias toward recording from Y-cellstoward the end of sublamination. Y-cells have larger somata andlower input resistances than X-cells in the adult cat (Crunelliet al., 1987) and response properties that develop later thanthose of X-cells (Daniels et al., 1978). It is also possible thatthe decrease in input resistance reflects the developmental increasein soma size of both X- and Y-cells (Rocha and Sur, 1995).

The developmental changes in receptor subunit composition and the putative role for LTP during development (see introductoryremarks) suggest a change in spontaneous and evoked miniatureEPSCs during ON/OFF sublamination of synapses mediated by NMDAand AMPA receptors on LGN cells. What might account for the stabilityof synaptic efficacy during a period of dramatic reorganizationof afferents and patternformation?

It is possible that homeostatic mechanisms maintain a constant synaptic efficacy during the period of ON/OFF sublamination.Such homeostasis may be of two types. First, it has been shownthat quantal amplitudes in cultured neocortical pyramidal neuronsare globally modulated by activity (Turrigiano et al., 1998),so that blockade of activity results in a scaling up of sEPSCamplitudes. Similarly, quantal amplitudes in cultured hippocampalneurons are negatively correlated with the number of synapticcontacts on these cells (Liu and Tsien, 1995). On this view, ifthe number of synaptic contacts (particularly retinal synapses)on LGN cells increases during sublamination, the amplitude (orareas) of sEPSCs and emEPSCs should decrease. The fact that sEPSCand emEPSC areas remain similar through the period of sublaminationmay be indicative of no major change in the overall number ofat least retinal synapses during this period. Indeed, the availabledata on postnatal cats (Kalil and Scott, 1979) is difficult torelate to postnatal ferrets and can be interpreted as reflectingonly a modest increase in retinogeniculate synapses over a periodsimilar to the P14-P28 period inferrets.

Second, synaptic rearrangement during ON/OFF sublamination implies that some synapses $---$ presumably incorrect ones $---$ are lost orretracted from cells, whereas new synapses are added. One interpretationof the data presented here is that the new synapses have propertiesvery similar to the ones they replace (Fig. 9). It is possiblethat the postsynaptic cell provides such stability, with synapsestargeted to specific dendritic sites regulated to have specificproperties. An alternative possibility is that retinogeniculatesynapses are correctly targeted in location and number by P14and sublamination consists of the separation of ON-center andOFF-center axon-cell pairs to the appropriate sublayer by P28(Fig. 9).

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Figure 9. Efficacy of AMPA-synapses on LGN cells appears to be normalized such that it remains stable throughout changes in neural activity and connectivity. A, Before ON/OFF sublamination retinal axons arborize in "inappropriate" areas of the LGN and may or may not make significant synaptic contacts outside of the areas that they will later be restricted to. B, After sublamination is complete, relay cells in the LGN receive inputs exclusively from either ON- or OFF-center retinal axons. C, Schematic of two possible explanations for the stability of synaptic efficacy during the activity-dependent reorganization of retinal axons in the LGN. If synaptic efficacy in the LGN is inversely proportional to the number of synaptic contacts as it is in the hippocampus (see Discussion for details), then either inappropriate inputs (open circles) have similar synaptic efficacies and are replaced by an equal number of appropriate inputs (closed circles), or only appropriate inputs are in place before sublamination, and their number does not increase.

These results add complexity to the hypothesis that developmental changes in connectivity are mirrored by changes in synapticefficacy (Constantine-Paton et al., 1990; Kandel and O'Dell, 1992;Goodman and Shatz, 1993; Cramer and Sur, 1995; Katz and Shatz,1996; Constantine-Paton and Cline, 1998). Although we did notfollow individual synapses over time, the population data do notindicate that a subset of synapses is strengthened whereas anotheris weakened and retracted over the period of sublamination. Rather,the results presented here suggest that total synaptic input toa neuron is "normalized" toward some acceptable level and thatif LTP is involved in the stabilization of appropriate synapsesduring development, a subsequent mechanism counteracts its effects.For example, an LTP-like mechanism by which changes in synapticefficacy decays over a period of hours (Cline, 1991), but whichinitially mediates synapse stabilization, may exist and wouldnot be detected by theseexperiments.

  FOOTNOTES

Received May 29, 1998; revised Oct. 16, 1998; accepted Oct. 16, 1998.

This work was supported by National Institutes of Health Grants EY 11512 and EY 07023. We thank Guosong Liu for valuable discussionand comments on this manuscript and Joseph Locascio for assistancewith statistical analyses. We also thank two anonymous refereesfor theircomments.
Correspondence should be addressed to Mriganka Sur, Massachusetts Institute of Technology, E25-235, 45 Carleton Street, Cambridge,MA02139.

  REFERENCES

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Abstract
Introduction
Materials & Methods
Results
Discussion
References

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