Using an in vitro rat brain stem slice preparation, we examined the postnatal changes in glycinergic inhibitory postsynaptic currents (IPSCs) and passive membrane properties that underlie a developmental change in inhibitory postsynaptic potentials (IPSPs) recorded in hypoglossal motoneurons (HMs). Motoneurons were placed in three age groups: neonate (P0-3), intermediate (P5-8), and juvenile (P10-18). During the first two postnatal weeks, the decay time course of both unitary evoked IPSCs [mean decay time constant, taudecay = 17.0 +/- 1.6 (SE) ms in neonates and 5.5 +/- 0.4 ms in juveniles] and spontaneous miniature IPSCs (taudecay = 14.2 +/- 2.4 ms in neonates and 6.3 +/- 0.7 ms in juveniles) became faster. As glycine uptake does not influence IPSC time course at any postnatal age, this change most likely results from a developmental alteration in glycine receptor (GlyR) subunit composition. We found that expression of fetal (alpha2) GlyR subunit mRNA decreased, whereas expression of adult (alpha1) GlyR subunit mRNA increased postnatally. Single GlyR-channels recorded in outside-out patches excised from neonate motoneurons had longer mean burst durations than those from juveniles (18.3 vs. 11.1 ms). Concurrently, HM input resistance (RN) and membrane time constant (taum) decreased (RN from 153 +/- 12 MOmega to 63 +/- 7 MOmega and taum from 21.5 +/- 2.7 ms to 9.1 +/- 1.0 ms, neonates and juveniles, respectively), and the time course of unitary evoked IPSPs also became faster (taudecay = 22.4 +/- 1.8 and 7.7 +/- 0.9 ms, neonates vs. juveniles, respectively). Simulated synaptic currents were used to probe more closely the interaction between IPSC time course and taum, and these simulations demonstrated that IPSP duration was reduced as a consequence of postnatal changes in both the kinetics of the underlying GlyR channel and the membrane properties that transform the IPSC into a postsynaptic potential. Additionally, gramicidin perforated-patch recordings of glycine-evoked currents reveal a postnatal change in reversal potential, which is shifted from -37 to -73 mV during this same period. Glycinergic PSPs are therefore depolarizing and prolonged in neonate HMs and become faster and hyperpolarizing during the first two postnatal weeks.
Using whole cell patch-clamp recording in a rat brain stem slice preparation, we found that gamma-aminobutyric acid (GABA) and glycine act as cotransmitters to hypoglossal motoneurons (HMs). Focal application of GABA and glycine onto a single HM revealed that GABAA and glycine receptors are present on the same neuron. To demonstrate that HMs receive both GABAergic and glycinergic synaptic inputs, we simultaneously recorded GABAA- and glycine-receptor-mediated spontaneous miniature inhibitory postsynaptic currents (mIPSCs) in single HMs. GABAergic and glycinergic mIPSCs were differentiated based on their kinetics and modulation by pentobarbital. Specifically, GABAA-receptor-mediated events decayed more slowly than glycine-receptor-mediated events. GABAergic response decay kinetics were prolonged by pentobarbital, whereas glycinergic response decay kinetics remained unchanged. The distinct kinetics of the glycine- and GABAA-receptor-mediated synaptic events allowed us to record dual component mIPSCs, mIPSCs that are mediated by both receptor types. These data suggest that GABA and glycine are colocalized in the same presynaptic vesicle and are coreleased from presynaptic terminals opposed to motoneurons.
1. The role of multiple potassium conductances in action potential repolarization and repetitive firing behavior of hypoglossal motoneurons was investigated using intracellular recording techniques in a brain stem slice preparation of the neonatal rat (0-15 days old). 2. The action potential was followed by two distinct afterhyperpolarizations (AHPs). The early one was of short duration and is termed the fAHP; the later AHP was of longer duration and is termed the mAHP. The amplitudes of both AHPs were enhanced by membrane potential depolarization (further from EK). In addition, their amplitudes were reduced by high extracellular K+ concentration, suggesting that activation of potassium conductances underlies both phases of the AHP. 3. Prolongation of the action potential and blockade of the fAHP were observed after application of 1) tetraethylammonium (TEA) (1-10 mM) and 2) 4-aminopyridine (4-AP) (0.1-0.5 mM). Calcium channel blockers had little or no effect on the fAHP or action potential duration. 4. The size of the mAHP was diminished by 1) manganese, 2) lowering external Ca2+, 3) apamin, and 4) intracellular injection of ethylene glycol-bis(beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid (EGTA) suggesting that influx of calcium activates the potassium conductance that underlies the mAHP. 5. The mAHP was unaffected by nifedipine (20 microM), but was strongly reduced by focal application of omega-conotoxin GVIA, suggesting that N-type calcium channels represent the major calcium influx pathway for activation of the calcium-dependent K+ conductance underlying the mAHP. 6. Repetitive firing properties were investigated by injecting long-duration depolarizing current pulses. Steady-state firing rose linearly with injected current amplitude. The slope of the firing frequency-current (f-I) relationship averaged approximately 30 Hz/nA in control conditions. Blockade of the conductance underlying the mAHP caused a marked increase in the minimal repetitive firing frequency and in the slope of the f-I plot, indicating a prominent role for the conductance underlying the mAHP in controlling repetitive firing behavior. 7. We conclude that action potential repolarization and AHPs are due to activation of pharmacologically distinct potassium conductances. Whereas repolarization of the action potential and the fAHP involves primarily a voltage-dependent, calcium-independent potassium conductance that is TEA- and 4-AP-sensitive, the mAHP requires the influx of extracellular calcium and is apamin sensitive. Activation of the calcium-activated potassium conductance greatly influences the normal repetitive firing of neonatal hypoglossal motoneurons.
Glycine uptake governs glycine site occupancy at NMDA receptors of excitatory synapses. J. Neurophysiol. 80: 3336-3340, 1998. At central synapses occupation of glycine binding sites of N-methyl--aspartate receptors (NMDA-Rs) is a necessary prerequisite for the excitatory neurotransmitter glutamate to activate these receptors. There is conflicting evidence as to whether glycine binding sites normally are saturated. If they are not, then alterations in local glycine concentration could modulate excitatory synaptic transmission. By using an in vitro brain stem slice preparation we investigated whether the glycine site is saturated for synaptically activated NMDA-Rs in neonatal rat hypoglossal motoneurons. We found that the NMDA-R-mediated component of spontaneous miniature excitatory postsynaptic currents could be potentiated by exogenously applied glycine as well as by -serine. The effects of glycine were observed only at concentrations (100 microM or more) two orders of magnitude above the apparent dissociation constant of glycine from NMDA receptors. In contrast, -serine, a nontransported NMDA-R glycine site agonist, was effective in the low micromolar range, i.e., at concentrations similar to those found to be effective on isolated cells or on outside-out patches. We conclude that at these synapses the glycine concentration around synaptic NMDA-Rs is set below the concentration required to saturate their glycine site and is likely to be stabilized by a powerful glycine transport mechanism.
1. Whole cell recordings of glutamatergic excitatory postsynaptic currents (EPSCs) evoked by electrical stimulation in the reticular formation were made from visualized hypoglossal motoneurons (HMs) in rat brain stem slices. 2. Carbachol, muscarine, or physostigmine reduced EPSC amplitude to 50 +/- 3%, 37 +/- 3%, and 54 +/- 7% (mean +/- SE) of control, respectively; effects of carbachol and physostigmine were antagonized by atropine (1-2 microM). EPSC depression was most effectively antagonized by methoctramine, an M2 muscarinic acetylcholine receptor (mAChR) antagonist with a high affinity constant (pKB) of 8.07 for the receptor mediating this response, whereas pirenzepine, an M1 mAChR antagonist, had a pKB of < 7.0, showing that EPSC depression was mediated by the M2 mAChR. 3. Postsynaptic properties of HMs (holding current and input resistance), EPSCs (reversal potential, rise time, half-width, and decay time constant), and postsynaptic glutamate-gated currents (amplitude and waveform) were not altered by carbachol or muscarine. 4. Muscarine did not decrease presynaptic neuron excitability, because the frequency of spontaneous EPSCs in HMs in the absence of tetrodotoxin (TTX) was either unchanged or increased. Leak and action currents of reticular formation neurons were not significantly altered by muscarine. In contrast, with TTX present, the frequency of spontaneous miniature glutamatergic EPSCs in HMs was decreased by both carbachol (mean change = 203 +/- 46%) and muscarine (mean change = 185 +/- 26%), with no change in miniature EPSC amplitude distribution. 5. Muscarinic depression of excitatory transmission to HMs thus occurs at the presynaptic terminal, most probably affecting release mechanisms downstream from calcium entry, and is likely to be significant during rapid eye movement sleep, possibly underlying the loss of tongue tone and inspiratory activity during this state.
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