Abstract
The dorsolateral striatum is critically involved in the execution and learning of sensorimotor tasks. It is proposed that this striatal function is achieved by the integration of convergent somatosensory and motor corticostriatal (CS) inputs in striatal medium-spiny neurons (MSNs). However, the cellular mechanisms of integration and propagation of somatosensory information in the CS pathway remain unknown. Here, by means of in vivo intracellular recordings in the rat, we analysed how sensory events generated by multi-whisker deflection, which provide essential somaesthetic information in rodents, are processed in contralateral barrel cortex layer 5 neurons and in the related somatosensory striatal MSNs. Pyramidal layer 5 barrel cortex neurons, including neurons antidromically identified as CS, responded to whisker deflection by depolarizing postsynaptic potentials that could reliably generate action potential discharge. In contrast, only half of recorded somatosensory striatal MSNs displayed whisker-evoked synaptic depolarizations that were effective in eliciting action potentials in one-third of responding neurons. The remaining population of MSNs did not exhibit any detectable electrical events in response to whisker stimulation. The relative inconstancy of sensory-evoked responses in MSNs was due, at least in part, to a Cl−-dependent membrane conductance concomitant with the cortical inputs, which was probably caused by whisker-induced activation of striatal GABAergic interneurons. Our results suggest that the propagation of whisker-mediated sensory flow through the CS pathway results in a refinement of sensory information in the striatum, which might allow the selection of specific sets of MSNs that are functionally significant during a given somaesthetic-guided behaviour.
Non-technical summary
The striatum is a deep-brain region that controls sensory-guided behaviours. It is proposed that this striatal function is achieved by the integration of sensory information arising from the cerebral cortex. By means of in vivo electrophysiological tools, we examine in the rat how natural sensory events are integrated in cortical neurons and subsequently processed in their neuronal targets in the striatum. Although cortical neurons are reliably excited by the sensory stimulus, we found that neurons in the striatum display either no sensory response or a synaptic excitation that is able to produce a functional signal in only half of the neurons. These data show that the propagation of the sensory flow from the cortex to the striatum results in a refinement of external information that could allow the selection of more appropriate behaviours.
Introduction
The dorsolateral striatum integrates sensorimotor information that is encoded by patterned corticostriatal (CS) inputs arising from motor and somatosensory cortical areas (Flaherty & Graybiel, 1994, 1995; Deniau et al. 1996; Alloway et al. 2006), a process suggested to be involved in regulation, correct sequencing and learning of voluntary behaviour tasks (Graybiel et al. 1994; Barnes et al. 2005; Graybiel, 2008; Pennartz et al. 2009). In rodents, the whisker-related somatosensory system allows a tactile-mediated internal representation of the proximal environment, sensory information that guides exploratory behaviours in progress and participates in the planning of future action (Brecht, 2007; Petersen, 2007). The elucidation of integration processes of whisker-generated sensory responses in the related CS pathway is thus of crucial importance for establishing a cellular basis of striatum-related somaesthetic-guided behaviours.
Sensory events generated by whisker deflection access the dorsolateral striatum via a polysynaptic pathway sequentially composed of primary sensory neurons connecting, by glutamatergic synapses, trigeminal nuclei neurons. The latter convey sensory information to contralateral ventral posteromedial and medial posterior thalamic nuclei, where a second glutamatergic synapse excites thalamocortical neurons projecting to the primary somatosensory barrel cortex (Petersen, 2007). Thalamocortical axons originating from the ventral posteromedial nucleus form discrete clusters in layer 4 that provide the basis of the ‘barrel’ map. Barrel cortex neurons projecting bilaterally to the striatum are distributed uniformly across layer 5 and aligned with barrel or septal compartments (Wright et al. 2001; Alloway et al. 2006) with a significantly higher number of ipsilateral projections (Alloway et al. 2006). Corticostriatal projections from the whisker barrel cortex have a crude somatotopic organization and terminate in densely packed clusters with distributed bead varicosities that occupy curved lamellar-shaped regions along the dorsolateral edge of the neostriatum (Alloway et al. 1999).
Although it has been shown that neurons of the dorsolateral striatum could fire in response to cutaneous, visual and auditory stimuli (Wilson et al. 1983; Strecker et al. 1985; Carelli & West, 1991), little information is available about the cellular and synaptic integrative properties of the whisker-sensitive CS system. However, consistent with the CS projections from the barrel cortex, mechanical stimulation of vibrissae increases both glucose utilization (Brown et al. 1996, 2002) and the firing rate of extracellularly recorded single units (Carelli & West, 1991) in the contralateral dorsolateral striatum. Moreover, electrical stimulation of the whisker pad induces synaptic depolarizations in neurons located in the somatosensory striatum (Wright et al. 2001).
Here, we investigated, for the first time at the intracellular level, how sensory events generated by multiple-whisker deflection are processed in the CS pathway. Using in vivo intracellular recordings in the rat, we first examined the sensory-evoked responses in layer 5 barrel cortex pyramidal cells, including neurons antidromically identified as CS. Medium-sized spiny neurons (MSNs), known to integrate and convert cortical inputs into functionally relevant striatal outputs (Wilson, 1995a; Stern et al. 1997; Mahon et al. 2001, 2004), were then intracellularly recorded in the striatal sector receiving barrel cortex inputs and their sensory responses were analysed and compared to those recorded in CS cells. Whereas CS neurons showed a highly reliable synaptic activation following whisker deflection, the corresponding MSNs could be subcategorized as a function of their responsiveness to sensory inputs, including neurons without detectable response, neurons displaying subthreshold synaptic depolarizations, and cells that could be depolarized above spike threshold.
Methods
Ethical approval
All surgical and experimental procedures were in accordance with European Union (directive 86/609/EEC) and INSERM guidelines and complied with The Journal of Physiology's policies on animal experimentation (Drummond, 2009). Every precaution was taken to minimize stress and the number of animals used in each series of experiments.
Animal preparation
Experiments were performed in vivo using 77 adult male Sprague–Dawley rats (8–15 weeks old) (Charles River, L’Arbresle, France). Animals were initially anaesthetized with sodium pentobarbital (40 mg kg−1, i.p.; CEVA Santé Animale, Libourne, France) and ketamine (100 mg kg−1, i.m.; Imalgène, Merial, France). A cannula was inserted into the trachea and the animal was placed in a stereotaxic frame. Wounds and pressure points were repeatedly (every 2 h) infiltrated with lidocaine (lignocaine, 2%). Once the surgical procedures had been completed, additional doses of pentobarbital (10–15 mg kg−1, i.p.) were regularly administered and the depth of anaesthesia was assessed by continuous monitoring of heart rate and surface electro-corticographic (ECoG) activity. In a restricted number of experiments (n = 13 adult male Sprague–Dawley rats), analgesia was achieved, and rats maintained in a narcotized and sedated state, by injections of fentanyl (3 μg kg−1, i.p.; Janssen-Cilag, Issy-les-Moulinaux, France) repeated every 20–30 min (Mahon et al. 2001; Polack & Charpier, 2006). To obtain long-lasting stable intracellular recordings, rats were then immobilized with gallamine triethiodide (40 mg, i.m., every 2 h; Sigma, France) and artificially ventilated. Body temperature was maintained (36.5–37.5°C) with a homeothermic blanket. At the end of the experiments, animals received an overdose of sodium pentobarbital (200 mg kg−1, i.p.).
Electrophysiological recordings
Spontaneous ECoG activity and surface event-related potentials (ERPs) (Fig. 1A and B), evoked by contralateral stimulations of whiskers (see below), were recorded with a low impedance (∼60 kΩ) silver electrode placed on the dura above the primary somatosensory barrel cortex (6.8–7.3 mm anterior to the interaural line; 5 mm lateral to the midline) (Paxinos & Watson, 1986). The reference electrode was placed in a muscle on the opposite side of the head.
Intracellular recordings were performed using glass micropipettes filled with 2 m potassium acetate (KAc; 50–80 MΩ). In one experimental series (see Fig. 7A–C), MSNs were intracellularly recorded with KCl-filled microelectrodes (3 m, 30–40 MΩ). For intracellular labelling, 1% Neurobiotin (Vector Laboratories, Burlingame, CA, USA) was added to the micropipette solution. Single-unit extracellular recordings and juxtacellular labelling (see below) of striatal cells were made with glass electrodes (7–15 MΩ) filled with 0.5 m NaCl and 1.7% Neurobiotin.
The value of membrane potential was calculated as the mean of the distribution of spontaneous subthreshold activity (10 s duration). The membrane potential values were eventually corrected when a tip potential was recorded after termination of the intracellular recording. Measurements of apparent membrane input resistance and time constant were based on the linear electrical cable theory applied to an idealized isopotential neuron (Rall, 1969). Apparent membrane input resistance of cortical neurons was assessed from the linear portion of the voltage–current (V–I) relationship (square current pulses of 200 ms duration, applied every 1.25 s) (see Fig. 2Bb). Because MSNs display prominent inward membrane rectification during injection of large-amplitude negative current pulses (Nisenbaum & Wilson, 1995; Mahon et al. 2001, 2004) (Fig. 4Bb), their membrane input resistance was measured by the mean (n = 20) membrane potential change at the end of hyperpolarizing current pulses of −0.4 nA. The membrane time constant was given by the coefficient of the exponential decay fit of the current-induced hyperpolarization.
Layer 5 cortical cells, located within the barrel cortex, were recorded from the vicinity of the ECoG electrode at the following stereotaxic coordinates: 5.2–8.5 mm anterior to the interaural line, 3.8–5 mm lateral to the midline, and 944–3380 μm under the cortical surface. Some of these cells could be electrophysiologically identified as CS neurons by their antidromic activation (see Fig. 3A). To avoid any stimulation of fibres de passage, after 3-D reconstruction (not shown) of anterogradely labelled barrel cortex corticofugal axons (Fig. 1B, see below for detailed procedures), we identified a striatal sector in which the cortical projections arising from the barrel cortex did not project to other subcortical structures. Accordingly, electrical stimulations were applied rostrally to the level where CS axons enter the ipsilateral striatum, at the following stereotaxic coordinates: 7.3–7.5 mm anterior to the interaural line, 4.6–4.7 mm lateral to the midline, and 4 mm under the brain surface. The striatal stimulations used for antidromic activation (200 μs duration, 4–11 V) were applied with a bipolar concentric electrode (NE-100; Rhodes Medical Instruments, Woodland Hills, CA, USA). The criteria used for identification of antidromic action potentials were their constant latency in response to striatal stimulation and their collision with spontaneously occurring orthodromic action potentials (Fig. 3A).
Striatal MSNs and interneurons were recorded in the ipsilateral striatal projection field of the barrel cortex CS neurons (Fig. 1C). The corresponding stereotaxic coordinates were as follows: 7–8.5 mm anterior to the interaural line, 4.4–5 mm lateral to the midline, and 3.3–6 mm ventral to the brain surface.
Anatomical procedures and identification of the barrel cortex-related striatal sector
Extracellularly recorded neurons were labelled by juxtacellular injection of Neurobiotin (Pinault, 1996; Paz et al. 2007). Briefly, positive current pulses (1–8 nA; 200 ms) were applied at a frequency of 2.5 Hz through the bridge circuit of the amplifier. The current was slowly increased while the electrode was advanced toward the neuron in 1 μm steps until the cell discharge was driven by the injected current. Current pulses were applied for a 10–30 min period to obtain a reliable labelling of neuronal processes. For intracellular recordings, depolarizing current pulses (0.2–1 nA; 200 ms) were applied at a frequency of 0.9 Hz at the end of the recording period. The histochemical methods used to reveal the morphology of intra- and juxtacellularly filled neurons have been described in detail previously (Polack & Charpier, 2006). The position of labelled neurons within the cortex or the striatum was then confirmed using the atlas of Paxinos & Watson (1986).
Extracellular deposits of Phaseolus vulgaris Leucoagglutinin (PHA-L) were made into the barrel cortex to determine the site and the pattern of striatal innervations by barrel cortex CS neurons (n = 2 experiments). The correct location of the tip of the injection electrode into the barrel cortex (7.3 mm anterior to the interaural line, 5 mm lateral to the midline, and 1.8 mm ventral to the brain surface) (Fig. 1B) was confirmed by the recording, at the surface of the injected cortical region, of large-amplitude ERPs evoked by application of air-puffs to the contralateral whiskers (Fig. 1A). PHA-L (2.5% in phosphate-buffered saline; Vector Laboratories) was iontophoretically ejected via glass micropipettes (internal tip diameter 8–10 μm) by positive current pulses of 4.5 μA (7 s on/7 s off) for 35–40 cycles. The histological procedures applied to visualize the axons of anterogradely labelled CS neurons are described in detail elsewhere (Degos et al. 2008). Axonal terminations in the striatum ipsilateral to the injected barrel cortex (Fig. 1D) were observed on a light microscope under brightfield illumination and reconstructed at high-power magnification using the Neurolucida system. The striatal location of CS projections (Fig. 1C), as well as their clustered pattern of axonal terminals (Fig. 1D), were identical to those described in a detailed previous anatomical study (Alloway et al. 1999).
Whisker stimulation
Sensory stimulations, consisting of puffs of compressed air delivered by a picospritzer unit (Picospritzer III, Intracel Ltd, Royston, Herts, UK), were applied through a 1 mm diameter glass pipette placed 15–25 mm rostrolateral from the whiskers. Air puffs (50 ms duration) were given 50 times for each tested intensity (ranging between 8 and 55 p.s.i.) with a low frequency (0.24 Hz) to prevent adaptation of whisker-evoked responses (Chung et al. 2002). The intensity of the optimal sensory stimulus, i.e. the minimal air-puff pressure that generated a contralateral ERP of maximal amplitude (100–200 μV), was determined at the beginning of each experiment. Under these conditions, the air-puff stimuli deflected 4–8 whiskers by ∼10 deg.
Data acquisition and analysis
Intracellular recordings were obtained under current-clamp conditions using the active bridge mode of an Axoclamp-2B amplifier (Axon Instruments, Union City, CA, USA). Data were digitized and stored on-line with a sampling rate of 25 kHz (intracellular signals), or 3 kHz (ECoG, ERP). Cross-correlograms between subthreshold intracellular activity (1–2 s of continuous recording down-sampled at 3 kHz) and ECoG signal, with the cortical wave as the temporal reference, were calculated using Spike 2 (CED Software; Cambridge Electronic Design, Cambridge, UK).
The amplitude of action potentials was calculated, after averaging 5–10 waveforms, as the potential difference between their voltage threshold, measured as the membrane potential at which the dV/dt exceeded 10 V s−1 (Mahon et al. 2003), and the peak of the spike waveform. Their total duration was measured as the time between their voltage threshold and the return to the same membrane potential value. The spontaneous firing rate of neurons was calculated from a continuous recording period >10 s.
The latency of intracellular sensory-evoked responses was calculated as the time between the onset of the air-puff stimulus and the foot of the evoked potential. Neuronal events having a shape (rising and decay phases) and/or latency that did not match those of the mean synaptic response obtained after averaging 30–50 trials were not considered as induced by the whisker stimulation and discarded. The amplitude of individual sensory-evoked subthreshold potentials was measured as the voltage difference between the membrane potential at the foot and the peak of the response. The firing probability of neurons in response to whisker deflections was calculated as the ratio between the number of suprathreshold synaptic responses and the total number of sensory-evoked responses.
Numerical values are given as means ± standard error of the mean (s.e.m.). Statistical significances were assessed using, appropriately, Student's t tests, the Mann–Whitney rank sum test, the Kruskal–Wallis one-way analysis of variance on ranks or the Levene median test. Statistical analyses were performed with SigmaStat 3.1 (SPSS Inc., Chicago, IL, USA) and curve fitting with Origin 7.0 (OriginLab Corp., Northampton, MA, USA).
Results
Sensory integration in barrel cortex layer 5 CS neurons
We first examined the sensory responses evoked in pyramidal neurons (n = 65) located in layer 5 of the barrel cortex, which contains the corticofugal neurons projecting to the dorsolateral striatum (Wright et al. 2001; Alloway et al. 2006). The depth of intracellular recordings, between 944 and 3380 μm from the cortical surface (1534 ± 48 μm; n = 65 cells), suggested that the recorded neurons were exclusively located in layer 5 (Hall & Lindholm, 1974). This was subsequently confirmed by histological analysis of labelled neurons (n = 3; Fig. 2A), which exhibited the typical morphological features of large-size layer 5 pyramidal neurons of the barrel cortex (Feldman, 1984; Manns et al. 2004; Wilent & Contreras, 2004), including a triangular or ovoid cell body, a prominent apical dendrite extending vertically toward the pial surface and basal dendrites radiating out from the base of the soma.
The electrical membrane properties of recorded cortical neurons included a membrane potential of −64 ± 0.4 mV (range, −70.5 to −57 mV; n = 65 cells) (Fig. 2Ba and Cb), an apparent input resistance (Fig. 2Ba and Bb) of 22 ± 0.9 MΩ (range, 10.4–40.8 MΩ; n = 65 cells) and a membrane time constant (Fig. 2Ba) ranging between 3.6 and 18 ms (8 ± 0.3 ms; n = 65 cells). Action potential amplitude had a mean value of 65.4 ± 0.8 mV (n = 65 cells), with a total duration of 1.4 ± 0.1 ms (n = 65 cells), and a voltage threshold of −51.6 ± 0.4 mV (range, −57.5 to −41.6 mV; n = 65 cells). In about half of the recorded cells, large-amplitude hyperpolarizing current pulses could induce a depolarizing ‘sag’ of membrane potential (Fig. 2Ba), probably caused by a hyperpolarization-activated inward cationic current (Ih, Breton & Stuart, 2009). The negative current pulse was followed immediately by a post-inhibitory rebound of depolarization (Fig. 2Ba, crossed arrows), possibly caused by the slow kinetics of Ih and/or by a low voltage-activated calcium potential. In response to depolarizing current injection, barrel cortex layer 5 neurons responded preferentially with either regular (n = 30; Fig. 2Ba top) or intrinsic bursting pattern (n = 35; Fig. 2Ba bottom, arrow). The V–I relationship, measured from the early part of the voltage deflection (Fig. 2Ba, circles), was linear (Fig. 2Bb) and the corresponding firing frequency–current curve followed a sigmoid function (Fig. 2Bb), with a maximal firing rate of 48.4 ± 2 Hz (n = 60 cells). The membrane potential in all cells showed ongoing oscillatory-like depolarizations, which were correlated with the related ECoG activity and provoked spontaneous firing ranging from 0.05 and 23.5 Hz (Fig. 3B). Altogether, these morpho-functional properties are consistent with those already described for rat layer 5 barrel cortex neurons in vitro and in vivo (Ito, 1992; Gottlieb & Keller, 1997; Zhu & Connors, 1999; Schubert et al. 2001, 2006; Manns et al. 2004; Breton & Stuart, 2009).
Air puffs applied to the contralateral whiskers evoked depolarizing postsynaptic potentials (dPSPs) in all recorded layer 5 neurons having a latency ranging between 13 and 29 ms (18.1 ± 0.4 ms, n = 65 neurons) (Fig. 2Ca–c) and a mean amplitude, calculated from subthreshold responses, of 6.5 ± 0.3 mV (range, 2.5–13 mV). These synaptic properties are similar to those previously measured from layer 5 barrel cortex neurons in response to principal or multiple whiskers stimulation (Moore & Nelson, 1998; Manns et al. 2004; Wilent & Contreras, 2004). As exemplified in Fig. 2Ca, a progressive increase in air-puff intensity, which enhanced the number of activated whiskers and their deflection magnitude, gradually enhanced the amplitude of subthreshold dPSPs. As previously shown in the same cell type (Manns et al. 2004), these multi-whisker synaptic responses could eventually reach action potential threshold with a firing probability that could further increase in parallel with the intensity of the sensory inputs (Fig. 2Ca).
In response to iterative optimal whisker stimulation, i.e. with the minimal intensity required to produce the largest ERP in our experimental conditions (see Methods), most of the tested neurons (58 out of 65) could display suprathreshold dPSPs with a probability of evoking an action potential ranging from 0.02 to 1 (0.46 ± 0.04, n = 58 neurons) (Fig. 2Ca and b). In these neurons activated by whisker deflection, the latency of evoked action potentials was 22.3 ± 0.6 ms (range, 15–34 ms, n = 58 neurons). In the remaining layer 5 neurons (7 out of 65), sensory stimuli, whatever their intensity, produced dPSPs (maximal amplitude, 5.4 ± 0.3 mV; from 4.2 to 6.3 mV, n = 7 neurons) that remained subthreshold for action potential generation (Fig. 2Cc). In this limited subset of neurons, the lack of sensory-evoked firing was not due to a defect in their intrinsic excitability since their input resistance (25 ± 2 MΩ, n = 7 neurons) and membrane time constant (7.9 ± 0.9 ms, n = 7 neurons) were not statistically different to those measured from neurons that could be fired by the sensory stimulus (P > 0.1 for each parameter). However, the mean membrane potential of cells that could exhibit suprathreshold responses (−63.5 ± 0.4 mV; n = 58 neurons) was slightly, but significantly (P = 0.03), more depolarized than that of neurons only displaying subthreshold dPSPs (−66.8 ± 1.4 mV; n = 7 neurons), suggesting, as observed in somatosensory cortex neurons (Sachdev et al. 2004) and other cortical cells (Azouz & Gray, 1999; Chance et al. 2002), that the responsiveness of barrel cortex layer 5 neurons to sensory inputs depends upon the concomitant spontaneous membrane potential fluctuations. Three layer 5 cells displayed ON–OFF responses with a mean firing probability at the OFF potential of 0.2 ± 0.07 (range, 0.05–0.28; n = 3 cells). We did not find any substantial differences between sensory-evoked responses recorded from intrinsic bursting and regular spiking neurons.
Some of the recorded layer 5 cortical neurons (n = 7) were unequivocally identified as barrel cortex CS cells by their antidromic activation (Fig. 3A) from the ipsilateral striatal region receiving axonal projections from the barrel cortex (see Methods and Fig. 1C). The average antidromic latency was 0.54 ± 0.10 ms (n = 7 cells) (Fig. 3A, top traces), corresponding to a conduction velocity of 7.8 ± 1.4 m s−1, a value that is in the upper range of those previously calculated from CS neurons projecting to other striatal sectors (Cowan & Wilson, 1994; Mahon et al. 2001). In response to depolarizing current pulses, CS neurons displayed either a regular spiking (n = 3) or an intrinsic bursting (n = 4) (Fig. 3A, inset) pattern. As observed in the whole population of layer 5 neurons, identified CS cells exhibited spontaneous rhythmic membrane depolarizations that were temporally correlated with the barrel cortex ECoG signal (Fig. 3B). The mean membrane potential of CS neurons (−65.5 ± 1.7 mV, n = 7 neurons), as well as their mean spontaneous firing rate (4.5 ± 2.2 Hz, n = 7 neurons), were concordant (P > 0.15 for both parameters) with those measured from layer 5 barrel cortex neurons that were not formally identified as CS (membrane potential, −63.6 ± 0.4 mV; firing rate, 5.8 ± 0.8 Hz; n = 58 neurons). All CS neurons responded to whisker deflection by dPSPs that could generate action potentials (Fig. 3C and D middle traces) with a probability of 0.54 ± 0.16 (range, 0.03–0.98, n = 7 neurons) and a latency of 25.6 ± 1.7 ms (range, 18.3–33.7 ms, n = 7 neurons). These values did not statistically differ (P > 0.05 for both values) from those calculated from unidentified layer 5 cells (firing probability, 0.45 ± 0.05, range, 0.02–1; firing latency, 21.8 ± 0.6 ms, range, 15.1–33.8 ms, n = 51 neurons) and were similarly distributed. These findings indicate that CS neurons do not provide a distinct functional subset among the barrel cortex layer 5 neurons and suggest that the sensory responsiveness in the overall cortical neuron population recorded in this study is statistically representative of the sensory integration process in CS cells. This assumption is also supported by the single experiment illustrated in Fig. 3D in which an identified CS cell (middle traces) and a layer 5 cortical cell not identified as CS (bottom traces) displayed similar sensory responses (top inset) and intrinsic firing patterns (bottom inset).
Morphological and electrophysiological features of barrel cortex-related striatal MSNs
We analysed the morphological and electrophysiological properties of MSNs (n = 49) located in the striatal projection field of the barrel cortex. Medium spiny neurons account for the majority of neurons in the striatum (Chang et al. 1982) and integrate on their dendritic spines thousands of glutamatergic inputs arising from a large number of converging CS cells (Wilson, 1995a; Kincaid et al. 1998). Labelled cells (see Methods) (Figs 4A and 7A), which confirmed the location of recorded neurons within the striatal region receiving inputs from the barrel cortex, displayed the distinctive morphological features of MSNs (Chang et al. 1982; Kawaguchi et al. 1990). Briefly, they possessed somata of diameter between 10 and 20 μm, with 4–6 ramified primary dendrites densely covered with spines apart from their most proximal regions (Figs 4A and 7A).
Consistent with their morphological features, intracellularly recorded striatal neurons had the characteristic electrophysiological properties of MSNs as described in vitro and in vivo (Kawaguchi et al. 1989; Nisenbaum et al. 1994; Nisenbaum & Wilson, 1995; Mahon et al. 2001, 2003, 2004; Slaght et al. 2004). They had a highly polarized membrane potential (−76.1 ± 0.7 mV, from −86.3 to −66.7 mV; n = 49), an apparent membrane input resistance of 26.7 ± 1.2 MΩ (range, 12.4–54.5 MΩ; n = 47) and a membrane time constant ranging between 5.1 and 18.7 ms (9 ± 0.4 ms; n = 47 cells) (Fig. 4Ba). The membrane V–I relationship consistently displayed a marked inward rectification in response to current pulses of increasing negative intensity (Fig. 4Bb, dashed line). Threshold positive current pulses evoked a slow ramp-like membrane depolarization (Fig. 4Ba, dashed line) that led to a delay in the first action potential discharge. An increase in the intensity of positive current resulted in a reduction of the first latency and repetitive firing (Fig. 4Ba, grey trace). Action potentials of MSNs had an amplitude and duration of 61.8 ± 1 mV and 1.2 ± 0.03 ms (n = 49 cells), respectively, and a voltage threshold of −49.4 ± 0.3 mV (n = 49 cells). In accordance with their monosynaptic excitatory inputs arising from the barrel cortex, MSNs displayed spontaneous membrane potential fluctuations tightly correlated with the ECoG signal (Fig. 4C), which generated a weak and erratic discharge of action potentials (0.6 ± 0.3 Hz; range, 0.01–5.7 Hz; n = 17 cells). As expected from their prominent membrane inward rectification (Fig. 4Bb), due to a powerful voltage-activated K+ conductance (Nisenbaum et al. 1994; Mahon et al. 2004), DC hyperpolarization of MSNs resulted in an attenuation of amplitude of spontaneous synaptic depolarizations (Fig. 4C, lowest trace).
Multi-whisker-evoked responses in striatal MSNs
We analysed the sensory responses evoked in MSNs (n = 49) by deflection of contralateral whiskers. Striatal cells could be subcategorized as a function of their responsiveness to an optimal sensory stimulus, which was adjusted in each experiment to provoke the largest cortical response (see Methods).
In 27 MSNs (∼55% of tested neurons), air-puffs applied to contralateral whiskers could generate stimulus-dependent responses. These ‘responding neurons’ exhibited sub- or suprathreshold sensory-evoked dPSPs with a mean latency of 21.0 ± 0.7 ms (range, 14.6–32.6 ms; n = 27 neurons). In all responding cells, as observed in layer 5 barrel cortex neurons (see Fig. 2Ca), the amplitude of sensory responses increased in parallel with the stimulus intensity (Fig. 5A). However, when the air pressure on whiskers was above that of the optimal stimulus, we observed a reduction of the synaptic depolarization (Fig. 5A) and a subsequent diminution of the evoked firing (data not shown).
Among the responding MSNs, 19 (39% of tested cells) exhibited, in response to multi-whisker deflection, subthreshold dPSPs with a latency of 21.5 ± 1.0 ms (range, 14.6–32.6 ms; n = 19 neurons) (Fig. 5B). Their mean amplitude and time-to-peak were of 8.5 ± 0.8 mV (range, 3.3–15.9 mV; n = 19 cells) and 8.9 ± 1.2 ms (range, 3.9–22 ms; n = 19 cells), respectively. Although amplitude and shape of individual sensory-induced dPSPs showed a high trial-to-trial variability (Fig. 5B, upper records), probably due to their polysynaptic origin, the average response (Fig. 5B, lower trace) revealed a consistent waveform characterized by a steep initial slope depolarization of 1.1 ± 0.1 V s−1 (n = 19 cells) and a subsequent slow decaying repolarization lasting between 18 and 108 ms. This synaptic response was followed by an electrical silence (37.4–128 ms of duration) that could be associated with a slight membrane hyperpolarization (1–7 mV), which often preceded a rebound depolarization (Fig. 5B, lowest trace).
Whisker stimulation was effective in generating suprathreshold synaptic responses in eight MSNs (16% of recorded cells) (Figs 5C and 6Bb). In these cells fired by the sensory stimulus, the latency of evoked dPSPs was 19.9 ± 0.7 ms (range, 17.7–22 ms; n = 8 neurons), a value similar (P = 0.3) to that calculated for MSNs only responding by subthreshold depolarizations. The probability of discharge on depolarizing potentials was relatively low and highly variable among cells (0.17 ± 0.1, range, 0.03–0.35; n = 8 neurons) with a latency of action potential ranging from 19.1 to 30.6 ms (mean, 24.3 ± 1.6 ms; n = 8 neurons) (Figs 5C and 6Bb). In these cells that could be fired by whisker deflection, the episodic subthreshold sensory-evoked dPSPs (Figs 5C and 6Bb, lowest traces) had an amplitude of 8.1 ± 1.2 mV and a time-to-peak of 6.8 ± 0.5 ms (n = 8 cells) that did not differ (P > 0.9 for each parameter) from those measured in cells showing exclusively subthreshold responses. The current-induced firing in neurons that responded to whisker stimulation by either sub- or suprathreshold potentials was similar, suggesting that the lack of sensory-evoked firing was not caused by an endogenous inability to generate action potentials (Fig. 5Da vs. Db). Moreover, the complex waveform of evoked synaptic potentials and subsequent voltage fluctuations recorded in MSNs with subthreshold responses was similar to that observed in neurons that could be activated by sensory inputs (Fig. 5C vs. B).
In the remaining 22 MSNs (45% of tested neurons), even though some synaptic depolarizations could occur within the appropriate temporal window after the sensory stimulus (Fig. 6Aa, oblique arrows), the averaging of 50 successive trials did not reveal any sensory-evoked response (Fig. 6Aa and Ba lower traces). It is very unlikely that this absence of whisker-induced response was due to an inability of sensory stimulations to activate CS barrel cortex neurons since the corresponding surface ERP had large amplitude and a standard shape (Fig. 6Aa, top record). This assumption is also supported by the single experiment illustrated in Fig. 6B in which the same sensory stimulus was unable to generate a response in one MSN (Ba) whereas it was effective in inducing suprathreshold potentials in a neighbouring MSN (Bb). As shown in Fig. 6Ab, the voltage changes and firing patterns induced by current injections in unresponsive neurons were analogous to those recorded in sensory responding MSNs (see Fig. 5D for comparison).
The heterogeneous sensory-induced responses recorded in striatal MSNs could, in theory, result from differences in their membrane excitability. To test for this hypothesis, we compared the values of membrane potential, input resistance, membrane time constant, action potential voltage threshold and spontaneous firing rate calculated from MSNs exhibiting suprathreshold responses (n = 8) or subthreshold responses (n = 19) and those without identified responses (n = 22). As shown in the summary histograms in Fig. 6C, none of these parameters was found to be significantly different between the three groups of MSNs (P > 0.05 for each parameter).
Contribution of chloride-dependent inhibition in sensory integration in MSNs
The lack of sensory response in some of the recorded MSNs, as well as the inability of some of the responding neurons to generate an action potential, is not due to a defect in their intrinsic excitability (see above). Instead, it could result from an insufficient excitatory synaptic drive and/or from a shunting inhibition concomitant with the sensory-evoked synaptic excitation. To test for a possible inhibitory role of a Cl−-dependent synaptic conductance in the sensory integration in MSNs, we performed intracellular recordings of MSNs with KCl-filled electrodes (n = 13 neurons). In such recording conditions, it is expected that the activation of GABA type-A receptors in the membrane MSNs (Wilson, 2007) will cause a dramatic outflow of Cl− resulting in additional synaptic depolarizations and an increased firing rate (Slaght et al. 2004).
Chloride-loaded MSNs were intracellularly filled with Neurobiotin and their morphological features were found to be similar to those of MSNs recorded with KAc-filled electrodes (Fig. 7Avs.Fig. 4A), demonstrating the identity of striatal cells recorded in both conditions. Whereas the membrane potential of MSNs filled with Cl− was more depolarized (−66.8 ± 1.5 mV, from −74.5 to −55.5 mV; n = 13 neurons; P < 0.001), their input resistance (29.3 ± 2.2 MΩ; n = 13 neurons) and spike threshold (−48.4 ± 0.7 mV; n = 13 neurons) remained unchanged (P > 0.15 for both parameters) compared to those recorded with KAc electrodes. The presence of depolarizing Cl−-dependent synaptic potentials in the background activity was attested by an uncommonly large amplitude and prolonged spontaneous depolarizations (Fig. 7B inset), which were responsible for an elevated firing rate (1.6 ± 0.6 Hz, from 0.03 to 7.1 Hz, n = 13 neurons; P = 0.01) (Fig. 7B).
A remarkable finding was the dramatic increase in the proportion of MSNs responding to sensory stimulation when recorded with KCl-filled electrodes (Fig. 7D). In 11 neurons (85% of Cl−-loaded MSNs), whisker deflection provoked dPSPs that occurred with a latency of 24.0 ± 1.2 ms (n = 11 neurons). These sensory-evoked responses could evoke action potentials (Fig. 7Ca) with a probability of 0.15 (range, 0.05–0.25; n = 8 cells) and a latency of 29.7 ± 2.7 ms (range, 22.9–41.6 ms; n = 8 cells), or remained subthreshold (n = 3 cells) (Fig. 7Cb). Interestingly, the time-to-peak of sensory-induced synaptic depolarizations in Cl−-filled MSNs (11.1 ± 1.6 ms; n = 11 cells) was slightly but not significantly (P > 0.05) longer than that measured from sensory responding MSNs recorded with KAc electrodes (8.3 ± 4.6 ms; n = 27 neurons), suggesting the existence of a Cl−-dependent synaptic conductance in the initial part of the sensory-evoked response in MSNs.
Our results suggested that contralateral whisker deflection generated a short-latency Cl−-dependent conductance in MSNs that could produce a shunting effect on CS synaptic inputs, a process that could account, at least in part, for the defect of sensory responsiveness in some of the MSNs (see Discussion). Because most MSNs were silent following sensory stimulus, GABAergic interactions between MSNs would participate only moderately in the increase in Cl− conductance (Wilson, 2007). It might instead originate from a feed-forward activation of intrastriatal GABAergic interneurons, which can be synaptically activated by CS inputs (Ramanathan et al. 2002; Mallet et al. 2005) and are known to produce a robust Cl−-dependent inhibition able to block the generation of action potentials in MSNs (Wilson, 2007). We tested this hypothesis by performing extracellular recordings of striatal interneurons (n = 20) from the same striatal sector where MSNs were recorded. Extracellularly recorded neurons were considered as fast-spiking GABAergic interneurons (Kawaguchi, 1993; Mallet et al. 2005; Kreitzer, 2009) on the basis of their short-duration action potentials (0.66 ± 0.04 ms; range, 0.4–0.9 ms; n = 20 neurons) (Fig. 7Ea, inset) and their morphological properties, revealed after juxtacellular injection of Neurobiotin (see Methods), including oval somata of ∼15 μm diameter and 3–5 smooth primary dendrites giving rise to restricted or extended dendritic arborization (Fig. 7Ea) (Kawaguchi, 1993). Six striatal interneurons (30% of recorded cells) responded with high reliability to whisker deflection by 1–3 action potentials (Fig. 7Eb). The latency of the first sensory-evoked spike was 20.6 ± 1.9 ms (n = 6 cells) (Fig. 7Eb).
Differential sensory integration in CS neurons and MSNs
Our in vivo intracellular recordings revealed that barrel cortex layer 5 neurons, including identified CS cells, responded with high reliability to contralateral multi-whisker deflection, most cortical neurons (89% of recorded cells) exhibiting sensory-evoked dPSPs that could elicit spike discharge with a mean probability of 0.46 (Fig. 8A and B). In contrast, the sensory integration in the corresponding postsynaptic striatal MSNs was less secure with about 45% of neurons not showing any response to whisker deflection and 55% of cells exhibiting evoked dPSPs, which could generate action potentials in only ∼30% of the responding neurons (Fig. 8A). When MSNs could be activated by whisker stimulations their firing was delayed by ∼2 ms compared to the sensory-evoked discharge in cortical cells, a value that is compatible with the monosynaptic connectivity between the two cell populations (see Discussion). However, the firing probability of responding MSNs was significantly lower than that of layer 5 cortical cells (P < 0.05) (Fig. 8B) while the corresponding temporal dispersion of firing latencies in both neuronal sets was similar (P > 0.1) (Fig. 8B).
Altogether, this statistical comparison between all neurons recorded in the layer 5 barrel cortex and in the corresponding somatosensory striatum suggested that the propagation of sensory responses from cortex to striatum resulted in a decrease in the number of responding neurons and a reduction in the firing probability of neurons that could be activated. This was directly confirmed by further analysing individual experiments in which both layer 5 barrel cortex cells and MSNs were recorded and submitted to the same sensory stimulus (n = 17 experiments) (Fig. 8Ca and Cb). As illustrated by the single experiment shown in Fig. 8Ca, identical sensory stimuli could reliably evoke suprathreshold responses in a barrel cortex layer 5 cell (firing probability = 0.7) whereas they generated subthreshold dPSPs in a MSN and were inefficient at inducing any response in another MSN. The pooled representation of sensory responses recorded from the same experiments in barrel cortex layer 5 neurons and striatal MSNs (Fig. 8Cb) demonstrated that, for a given multi-whisker deflection, the quasi-totality of cortical cells were activated (29 out of 32; 91%) whereas most MSNs displayed subthreshold responses (12 out of 33; 36%) or were unaffected (15 out of 33; 45%) by the sensory stimulus. In this set of experiments, in which the relative timing of cortical and striatal sensory responses could be directly compared, the mean latencies of whisker-mediated cortical spikes and synaptic depolarizations in MSNs were 20.9 ± 0.8 ms (n = 21 layer 5 neurons) and 21.6 ± 1.0 ms (n = 18 MSNs), respectively, corresponding to a fast CS transmission in accordance with the propagation time of CS action potentials (∼0.6 ms, see above) in addition to an excitatory monosynaptic delay (∼0.3 ms; Eccles, 1964).
To confirm that the results presented above are not conditional upon a specific anaesthetic procedure, we performed an additional set of experiments in rats (n = 13) anaesthetized with fentanyl (see Methods), which induces a relatively desynchronized background ECoG (Mahon et al. 2001; Polack & Charpier, 2006). Barrel cortex layer 5 neurons (n = 12) and related MSNs (n = 15), recorded under fentanyl, had similar electrical membrane properties and current-induced firing patterns to those recorded from pentobarbital-anaesthetized rats (Supplemental Fig. 1Ca and Cb, available online only). Among cortical cells, contralateral multi-whisker deflection induced dPSPs having a mean latency of 14.8 ± 0.6 ms; n = 12 neurons), which were efficient at generating action potentials in 92% of recorded cells (mean firing probability = 0.38 ± 0.09; n = 11 neurons) (Supplemental Fig. 1A top and D). As observed under pentobarbital, only a limited proportion of MSNs (n = 8; 53% of recorded neurons) could exhibit whisker-mediated dPSPs (Supplemental Fig. 1B and D), which had a mean latency of 22.7 ± 1.6 ms (n = 8 neurons) and were able to produce suprathreshold responses in only 20% of recorded MSNs (n = 3) (Supplemental Fig. 1B and D) with a low firing probability (from 0.02 to 0.2). In the remaining MSNs (n = 7; 47% of recorded neurons), no sensory response could be detected (Supplemental Fig. 1A bottom and D). These results, similar to those obtained under pentobarbital anaesthesia (Fig. 8Avs. Supplemental Fig. 1D), demonstrate that the differential sensory integration in CS neurons and MSNs does not depend upon specific experimental conditions and occurs during various profiles of cortical activities.
Discussion
The main findings of the present study, which provides the first description of the intracellular sensory events generated in the corticostriatal pathway by contralateral whisker deflection, are as follows: (1) layer 5 barrel cortex neurons, including identified CS cells projecting to the dorsolateral striatum, responded to sensory stimuli by dPSPs that mostly caused cell firing; (2) about 55% of recorded striatal MSNs displayed sensory-evoked depolarizations that could generate action potentials in a third of these neurons; (3) the remaining MSNs did not exhibit any detectable electrical events in response to whisker stimulation; (4) the proportion of sensory-responding MSNs was dramatically increased by intracellular injection of Cl−, suggesting that an inhibitory GABA type-A synaptic conductance is responsible, at least in part, for the relative unreliability of sensory-evoked responses in MSNs; and (5) putative striatal GABAergic interneurons could be activated by whisker stimulation, a process that may account for the Cl−-dependent synaptic conductance observed in MSNs. These results suggest that the propagation of sensory flow through the CS pathway following whisker deflection results in a partial loss or a refinement of sensory information in the striatum.
Sensory activation of barrel cortex CS neurons
Our in vivo intracellular recordings in the barrel cortex were exclusively made from layer 5 where the somata of corticofugal neurons projecting to the dorsolateral striatum are located (Wright et al. 1999, 2001; Alloway et al. 2006). Although only a limited number of cells (11% of recorded neurons) were antidromically identified as CS cells, we did not find any significant difference between the electrophysiological features of identified and unidentified CS cells, including their membrane properties and sensory-evoked responses, which are also similar to those previously described from barrel cortex layer 5 pyramidal neurons in vivo (Zhu & Connors 1999; Schubert et al. 2001, 2006; Manns et al. 2004; Wilent & Contreras, 2004).
Consistent with the local optimal surface ERPs, all recorded cortical neurons showed a highly reliable sensory-evoked synaptic activation, which could originate from various thalamocortical and intracortical networks activated by whisker deflection (Brecht, 2007). Superficial layer 5 pyramids receive excitatory thalamic input from the medial posterior nucleus (Lu & Lin, 1993), they are interconnected (Schubert et al. 2006) and innervated by axonal arbors from layer 4 excitatory spiny stellate cells (Brecht & Sakmann, 2002; Schubert et al. 2006). In contrast, the large pyramidal cells in the deeper part of layer 5 integrate excitatory inputs from ventral posteromedial thalamic projections (Lu & Lin, 1993), axonal ramifications of layer 2–3 neurons (Lübke et al. 2003) and are also reciprocally connected (Markram et al. 1997). These glutamatergic, thalamic and intracortical inputs probably account for the early part of evoked dPSPs. It is also probable that this fast sensory-induced excitation is partially overlapped by a fast inhibitory synaptic conductance (Wilent & Contreras, 2004), possibly resulting from the activation of intracortical GABAergic interneurons by thalamocortical projections (Swadlow, 2003). It is likely that this surrounding inhibition, which would be amplified by multiple whisker activation (Mirabella et al. 2001; Ego-Stengel et al. 2005), partly governs the probabilistic firing of CS cells following sensory stimulation and is responsible for sublinear summation of responses when increasing the number of coincident inputs (Mirabella et al. 2001) (see Fig. 2Ca).
Origin and heterogeneity of whisker-mediated responses in striatal MSNs
A striking result is the heterogeneous and insecure whisker-mediated sensory responsiveness of MSNs recorded within the striatal projection field of the barrel cortex, which contrasts with the high reliability of sensory integration in CS neurons. Notably, the lack of correlated synaptic depolarization between CS neurons and related MSNs (∼45% of recorded MSNs) as well as between neighbouring MSNs was not previously reported (Stern et al. 1998; Charpier et al. 1999; Mahon et al. 2001). Whereas 89% of layer 5 cortical cells, including all of the identified CS neurons, displayed suprathreshold dPSPs in response to whisker stimulation, only 55% of MSNs exhibited whisker-mediated dPSPs that could cause, in only ∼30% of these responding neurons, action potential discharge. Such an imbalance between the firing rates of CS cells and MSNs is consistent with what was previously described in vivo during anaesthetic-dependent rhythmic spontaneous activities (Stern et al. 1997; Mahon et al. 2001, 2004).
It is likely that the whisker-evoked depolarizations in MSNs are mainly due to the activation of their barrel cortex CS afferents. First, glutamatergic CS projections provide the major source of synaptic contacts onto the dendrites of MSNs (Kincaid et al. 1998), including those located in the barrel cortex-related striatal sector (Wright et al. 1999, 2001; Alloway et al. 1999, 2006), and are known to sculpt their spontaneous membrane depolarizations (Wilson, 1995a; Wilson & Kawaguchi, 1996; Stern et al. 1997; Charpier et al. 1999; Mahon et al. 2001, 2004). Second, the mean delay between whisker-mediated cortical action potentials and synaptic depolarizations in MSNs, measured from the different couples (n = 33 from 17 experiments) of cortical and striatal cells recorded in the same experiment and in response to identical multi-whisker deflection, was 1.6 ± 1.1 ms, a value consistent with monosynaptic transmission and in accordance with the fast propagation of the CS action potentials we measured. Third, there is no identified direct projection from whisker-related thalamic nuclei to the dorsolateral striatum (Smith et al. 2004). Finally, the temporal sequence of whisker-mediated synaptic events in MSNs resembles the one induced by electrical stimulation of ipsilateral CS neurons (Charpier et al. 1999; Mahon et al. 2003). However, the possibility is not excluded that the primary motor and secondary somatosensory cortical areas, which converge on the somatosensory striatum (Alloway et al. 2006) and could be activated by whisker stimulation (Chakrabarti & Alloway, 2006; Ferezou et al. 2007), participate in the sensory-evoked responses in MSNs.
The heterogeneous sensory events in MSNs could originate from different, and possibly synergistic, cellular, synaptic and network mechanisms. It is very unlikely that all non-responding MSNs were located in a striatal sector that did not receive whisker-induced CS inputs since it was possible to record, in the same animal and following identical stimuli, neighbouring MSNs exhibiting subthreshold dPSPs, suprathreshold potentials or no response (see Fig. 8Ca and Cb). However, given the partial somatotopic representation of the barrel cortex in the striatum (Alloway et al. 1999), we cannot exclude the possibility that some unresponsive MSNs were situated between the clustered axonal terminals of stimulated CS neurons. More probably, the absence of a whisker-mediated striatal response could result from two types of shunting inhibition. First, the relatively low input resistance and short time constant of MSNs membrane (Nisenbaum & Wilson, 1995; Wilson, 1995a,b; Mahon et al. 2004; this study), which is caused by a powerful voltage-gated K+-dependent membrane conductance (Nisenbaum & Wilson, 1995), would filter out small dendritic synaptic events, making them undetectable at the somatic level. Second, as demonstrated by the dramatic increase in the number of responsive MSNs after intracellular injection of Cl−, together with the sensory-evoked firing of putative striatal GABAergic interneurons, it is likely that whisker deflection produces a cortex-mediated activation of intrastriatal GABAergic interneurons (Mallet et al. 2005) that, in turn, produce a Cl−-dependent shunting inhibition of excitatory synaptic potentials in MSNs (Slaght et al. 2004). This would demonstrate a functional role of feed-forward inhibition during striatal sensory integration.
About half the MSNs were synaptically excited by the multi-whisker deflection. These neurons were probably located in the striatal spot receiving convergent inputs from the CS neurons activated by the sensory stimulation. However, most of these cells responded with synaptic depolarizations that could not reach spike threshold. This could be due to the large voltage drop required to fire MSNs from their resting potential and the activation of inhibitory voltage-gated K+-dependent conductances acting close to action potential threshold (Nisenbaum et al. 1994; Nisenbaum & Wilson, 1995). It is also probable that the activation of striatal GABAergic interneurons produces a shunting inhibition that limits synaptic depolarization positive to the equilibrium potential of Cl− and, consequently, prevents firing in most MSNs.
Functional implication
It is proposed that the dorsolateral striatum is crucially involved in the control of sensorimotor tasks via the integration, and complex processing, of convergent inputs from functionally related and interconnected somatosensory and motor cortical areas (Flaherty & Graybiel, 1994, 1995; Alloway et al. 2006). Taken together, our findings indicate that striatal MSNs located within the projection field of barrel cortex respond differentially to multiple whisker deflection. This process, probably governed by subtle interplay between cortical synaptic inputs, intrastriatal inhibitory networks and the membrane properties of MSNs (see above), might allow a selection or a refinement of ‘contextual-dependent’ barrel cortex information in the striatum by rejecting combinations of whisker movement that are functionally irrelevant during a given sensorimotor task. The whisker-sensitive MSNs also integrate additional somatosensory and motor information arising from convergent secondary somatosensory and primary motor cortices (Alloway et al. 2006). Accordingly, the firing of whisker-related MSNs will be further selected and facilitated when cortical areas are co-activated, either synchronously or in close temporal sequence, thereby encoding specific sets of CS networks that are functionally significant during somaesthetic-guided behaviours.
Acknowledgments
This work was supported by the Ministère Français de la Recherche, the Institut National de la Santé et de la Recherche Médicale and by grants from the Agence Nationale de la Recherche (ANR R06274DS, 2006) and the Programme Interdisciplinaire-CNRS Neuro IC 2010. We thank Anne-Marie Godeheu and Verena Aliane for histological processing.
Glossary
Abbreviations
- CS
corticostriatal
- dPSPs
depolarizing postsynaptic potentials
- ECoG
electro-corticographic
- ERPs
event-related potentials
- KAc
potassium acetate
- MSNs
medium-sized spiny neurons
- PHA-L
Phaseolus vulgaris leucoagglutinin
- V–I
voltage–current
Author contributions
S.C., M.P. and S.M. conceived the conceptual framework of the study and designed the experiments. M.P. and S.M. performed the experiments. M.P. performed the analysis and M.P., J.-M.D., S.M. and S.C. participated in the interpretation of the data. S.C. wrote the manuscript and M.P., J.-M.D. and S.M. revised and improved it. All the authors have approved the final version of the manuscript.
Supporting information
References
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