Lack of an endogenous GABAA receptor-mediated tonic current in hypoglossal motoneurons.

Tonic GABAA receptor-mediated current is an important modulator of neuronal excitability, but it is not known if it is present in mammalian motoneurons. To address this question studies were performed using whole-cell patch-clamp recordings from mouse hypoglossal motoneurons (HMs) in an in vitro slice preparation. In the presence of blockers of glutamatergic and glycinergic receptor-mediated transmission application of SR-95531 or bicuculline, while abolishing GABAA receptor-mediated phasic synaptic currents, did not reveal a tonic GABAA receptor-mediated current. Additionally, blockade of both GAT-1 and GAT-3 GABA transporters did not unmask this tonic current. In contrast, application of exogenous GABA (1 to 15 µm) resulted in a tonic GABAergic current that was observed when both GAT-1 and GAT-3 transporters were simultaneously blocked, and this current was greater than the sum of the current observed when each transporter was blocked individually. We also investigated which GABAA receptor subunits may be responsible for the current. Application of the δ subunit GABAA receptor agonist THIP resulted in a tonic GABAA receptor current. Application of the δ subunit modulator THDOC resulted in an enhanced tonic current. Application of the α5 subunit GABAA receptor inverse agonist L-655,708 did not modulate the current. In conclusion, these data show that HMs have tonic GABAA receptor-mediated current. The level of GABA in the vicinity of GABAA receptors responsible for this current is regulated by GABA transporters. In HMs a tonic current in response to exogenous GABA probably arises from activation of GABAA receptors containing δ subunits.

GAD67-GFP+ neurons in the Nucleus of Roller. II. Subthreshold and firing resonance properties.

In the companion paper we show that GAD67-GFP+ (GFP+) inhibitory neurons located in the Nucleus of Roller of the mouse brain stem can be classified into two main groups (tonic and phasic) based on their firing patterns in responses to injected depolarizing current steps. In this study we examined the responses of GFP+ cells to fluctuating sinusoidal ("chirp") current stimuli. Membrane impedance profiles in response to chirp stimulation showed that nearly all phasic cells exhibited subthreshold resonance, whereas the majority of tonic GFP+ cells were nonresonant. In general, subthreshold resonance was associated with a relatively fast passive membrane time constant and low input resistance. In response to suprathreshold chirp current stimulation at a holding potential just below spike threshold the majority of tonic GFP+ cells fired multiple action potentials per cycle at low input frequencies (<5 Hz) and either stopped firing or were not entrained by the chirp at higher input frequencies (= tonic low-pass cells). A smaller group of phasic GFP+ cells did not fire at low input frequency but were able to phase-lock 1:1 at intermediate chirp frequencies (= band-pass cells). Spike timing reliability was tested with repeated chirp stimuli and our results show that phasic cells were able to reliably fire when they phase-locked 1:1 over a relatively broad range of input frequencies. Most tonic low-pass cells showed low reliability and poor phase-locking ability. Computer modeling suggested that these different firing resonance properties among GFP+ cells are due to differences in passive and active membrane properties and spiking mechanisms. This heterogeneity of resonance properties might serve to selectively activate subgroups of interneurons.

GAD67-GFP+ neurons in the Nucleus of Roller: a possible source of inhibitory input to hypoglossal motoneurons. I. Morphology and firing properties.

In this study we examined the electrophysiological and morphological properties of inhibitory neurons located just ventrolateral to the hypoglossal motor (XII) nucleus in the Nucleus of Roller (NR). In vitro experiments were performed on medullary slices derived from postnatal day 5 (P5) to P15 GAD67-GFP knock-in mouse pups. on cell recordings from GFP+ cells in NR in rhythmic slices revealed that these neurons are spontaneously active, although their spiking activity does not exhibit inspiratory phase modulation. Morphologically, GFP+ cells were bi- or multipolar cells with small- to medium-sized cell bodies and small dendritic trees that were often oriented parallel to the border of the XII nucleus. GFP+ cells were classified as either tonic or phasic based on their firing responses to depolarizing step current stimulation in whole cell current clamp. Tonic GFP+ cells fired a regular train of action potentials (APs) throughout the duration of the pulse and often showed rebound spikes after a hyperpolarizing step. In contrast, phasic GFP+ neurons did not fire throughout the depolarizing current step but instead fired fewer than four APs at the onset of the pulse or fired multiple APs, but only after a marked delay. Phasic cells had a significantly smaller input resistance and shorter membrane time constant than tonic GFP+ cells. In addition, phasic GFP+ cells differed from tonic cells in the shape and time course of their spike afterpotentials, the minimum firing frequency at threshold current amplitude, and the slope of their current-frequency relationship. These results suggest that GABAergic neurons in the NR are morphologically and electrophysiologically heterogeneous cells that could provide tonic inhibitory synaptic input to HMs.

Retinal influences induce bidirectional changes in the kinetics of N-methyl-D-aspartate receptor-mediated responses in striate cortex cells during postnatal development.

Development of the visual callosal projection in rodents goes through an early critical period, from postnatal day (P) 4 to P6, during which retinal input specifies the blueprint for normal topographic connections, and a subsequent period of progressive pathway maturation that is largely complete by the time the eyes open, around P13. This study tests the hypothesis that these developmental stages correlate with age-related changes in the kinetics of synaptic responses mediated by the N-methyl-D-aspartate subclass of glutamate receptors (NMDARs). We used an in vitro slice preparation to perform whole-cell recordings from retrogradely-labeled visual callosal cells, as well from cortical cells with unknown projections. We analyzed age-related changes in the decay time constant of evoked as well as spontaneous excitatory postsynaptic currents mediated by N-methyl-D-aspartate subclass of glutamate receptors (NMDAR-EPSCs) in slices from normal pups and pups enucleated at different postnatal ages. In normal pups we found that the decay time constant of NMDAR-EPSCs increases starting at about P6 and decreases by about P13. In contrast, these changes were not observed in rats enucleated at birth. However, by delaying the age at which enucleation was performed we found that the presence of the eyes until P6, but not until P4, is sufficient for inducing slow NMDAR-EPSC kinetics during the second postnatal week, as observed in normal pups. These results provide evidence that the eyes exert a bidirectional effect on the kinetics of NMDARs: during a P4-P6 critical period, retinal influences induce processes that slow down the kinetics of NMDAR-EPSCs, while, near the age of eye opening, retinal input induces a sudden acceleration of NMDAR-EPSC kinetics. These findings suggest that the retinally-driven processes that specify normal callosal topography during the P4-P6 time window also induce an increase in the decay time constant of NMDAR-EPSCs. This increase in response kinetics may play an important role in the maturation of cortical topographic maps after P6. Using ifenprodil, a noncompetitive NR2B-selective blocker, we obtained evidence that although NR1/NR2B diheteromeric receptors contribute to evoked synaptic responses in both normal and enucleated animals, they are not primarily responsible for either the age-related changes in the kinetics of NMDAR-mediated responses, or the effects that bilateral enucleation has on the kinetics of NMDAR-EPSCs.

Effects of flunarizine on spontaneous synaptic currents in rat neocortex.

Flunarizine, a non-selective blocker of voltage-dependent Ca(2+) and Na(+) channels, is clinically effective against several neurological disorders, including epilepsy, migraine, and alternating hemiplegia of childhood. We examined the effects of flunarizine on spontaneous post-synaptic currents in acute brain slices maintained in vitro using patch-clamp electrophysiology. Flunarizine significantly attenuated the amplitude of spontaneous currents in pyramidal neurons from juvenile rat neocortex. Flunarizine had no effect on miniature spontaneous events recorded in the presence of tetrodotoxin, a blocker of voltage-dependent sodium channels. In high (9 mM) extracellular potassium, flunarizine reduced the amplitude and frequency of the spontaneous currents. Additionally, dimethyl sulfoxide, the solvent used in our experiments, reduced the amplitude of spontaneous currents, but only in high extracellular potassium. Our data suggest that the clinical activity of flunarizine may in part be a consequence of reducing spontaneous synaptic currents in the neocortex, especially under conditions of heightened neuronal activity.

Serotonergic modulation of supragranular neurons in rat sensorimotor cortex.

Numerous observations suggest diverse and modulatory roles for serotonin (5-HT) in cortex. Because of the diversity of cell types and multiple receptor subtypes and actions of 5-HT, it has proven difficult to determine the overall role of 5-HT in cortical function. To provide a broader perspective of cellular actions, we studied the effects of 5-HT on morphologically and physiologically identified pyramidal and nonpyramidal neurons from layers I-III of primary somatosensory and motor cortex. We found cell type-specific differences in response to 5-HT. Four cell types were observed in layer I: Cajal Retzius, pia surface, vertical axon, and horizontal axon cells. The physiology of these cells ranged from fast spiking (FS) to regular spiking (RS). In layers II-III, we observed interneurons with FS, RS, and late spiking physiology. Morphologically, these cells varied from bipolar to multipolar and included basket-like and chandelier cells. 5-HT depolarized or hyperpolarized pyramidal neurons and reduced the slow afterhyperpolarization and spike frequency. Consistent with a role in facilitating tonic inhibition, 5-HT2 receptor activation increased the frequency of spontaneous IPSCs in pyramidal neurons. In layers II-III, 70% of interneurons were depolarized by 5-HT. In layer I, 57% of cells with axonal projections to layers II-III (vertical axon) were depolarized by 5-HT, whereas 63% of cells whose axons remain in layer I (horizontal axon) were hyperpolarized by 5-HT. We propose a functional segregation of 5-HT effects on cortical information processing, based on the pattern of axonal arborization.