GABAB-Receptor-Mediated Inhibition in Developing Mouse Ventral Posterior Thalamic Nucleus
Richard A. Warren1,
Peyman Golshani2, and
Edward G. Jones2
1 Centre de Recherche Fernand-Seguin, Montreal, Quebec H1N 3V2, Canada; and 2 Department of Anatomy and Neurobiology, University of California, Irvine, California 92697
 |
ABSTRACT |
Warren, Richard A., Peyman Golshani, and Edward G. Jones. GABAB-receptor-mediated inhibition in developing mouse ventral posterior thalamic nucleus. J. Neurophysiol. 78: 549-553, 1997. Inhibitory postsynaptic potentials (IPSPs) generated by activation of the thalamic reticular nucleus (RTN) were recorded in neurons of the ventral posterior nucleus (VP) in vitro in slices from mice aged postnatal day (P)1-P17. An early IPSP peaking 41 ± 2.5 (SE) ms after electrical stimulation of the internal capsule or RTN was found in 96% of VP neurons. This early IPSP was blocked by bicuculline, showing its dependence on
-aminobutyric acid-A (GABAA) receptors. A late IPSP peaking 357 ± 27 ms after the stimulus was observed in 22% of VP neurons in control medium but was uncovered in 38% of neurons when bicuculline was added. The late IPSP was blocked by addition of a GABAB antagonist, 2-hydroxysaclofen, to the medium (n = 7); it had a reversal potential of
98 ± 1.3 mV, 14 mV negative to the early component. In contrast to the early IPSP, whose reversal potential became more negative during postnatal development, the reversal potential of the late IPSP remained constant throughout the postnatal period studied. The most significant change in the late IPSP was shortening in duration, with reduction in latency-to-peak by >400 ms, between P1 and P10. No changes of comparable magnitude were observed in the duration of the earlier GABAA response. These results show that both GABAA and GABAB IPSPs are present very early in the postnatal thalamus and that their characteristics evolve along independent paths during postnatal development.
 |
INTRODUCTION |
Low-frequency oscillations in the interconnected network of thalamic and cortical neurons are accompaniments of changes in conscious state (Steriade et al. 1993
). Similar oscillations, characterized by 3-Hz spike and wave discharges in the cortical electroencephalogram (EEG), are accompaniments of petit mal epilepsy (Aicardi 1994
). Spindlelike oscillations and spike and wave discharges have their basis in oscillations of interconnected thalamic relay neurons and GABAergic neurons of the reticular nucleus (Steriade et al. 1993
). These depend in turn on generation of low-threshold calcium spikes that lead to recurrent bursts of action potentials as relay cells recover from
-aminobutyric acid (GABA)-imposed inhibition (Bal et al. 1995a
,b
; Huguenard and Prince 1994a
; Warren et al. 1994
). Drugs such as ethosuximide, which are effective in reducing the incidence of absence seizures, interfere with the cycle of recurrent inhibition and rebound oscillation (Coulter et al. 1989
; Huguenard and Prince 1994a
).
Slow-wave sleep is typically absent in rodents and notably reduced in other mammalian species during the early postnatal period (Jouvet-Mounier et al. 1970
) and absence seizures or seizurelike activity do not occur in human infants (Aicardi 1994
) or in infant animal models (Marescaux et al. 1992b
). This may be related to immaturity of the membrane and synaptic properties of thalamic relay and reticular neurons during early postnatal life; in mice these only reach the adult state and permit full development of thalamic oscillations toward the end of the second postnatal week (Warren and Jones 1997
).
Generation of rebound bursts in relay neurons is largely dependent on inhibition by the reticular nucleus through fast-acting, ionotropic GABAA receptors (Bal et al. 1995a
; Huguenard and Prince 1994a
; Warren et al. 1994
). The role of GABAB receptors may be more limited normally because GABAB antagonists reportedly do not affect intrathalamic oscillations in vitro (Bal et al. 1995a
; Warren et al. 1994
).
Nevertheless, GABAB receptor binding can be demonstrated in mouse thalamus in early postnatal life (e.g., Lin et al. 1993
), and typical, GABAB-mediated slow inhibitory postsynaptic potentials (IPSPs) and presynaptic GABAB effects occur in thalamic neurons of rats
8 days old (Huguenard and Prince 1994a
; Ulrich and Huguenard 1996
) and under certain conditions in carnivores (Bal et al. 1995a
; von Krosigk et al. 1993
). It was not possible to demonstrate GABAB-mediated IPSPs in earlier studies in mice (Warren and Jones 1997
; Warren et al. 1994
). In the present study we report their presence in ventral posterior nucleus (VP) neurons from birth.
 |
METHODS |
The methods have been previously described (Warren and Jones 1997
; Warren et al. 1994
). Thalamocortical slices 400 µm thick were prepared from ICR mice [postnatal day (P)1-P17] and continuously perfused at room temperature (22-25°C) with artificial cerebrospinal fluid (ACSF) containing (in mM) 126 NaCl, 3 KCl, 1.25 NaH2PO4, 1.3 MgSO4, 2.5 CaCl2, 26 NaHCO3, and 10 dextrose, pH 7.4 when bubbled with 95% O2-5% CO2. In 2 of 22 experiments, the ACSF contained 5 or 10 µM bicuculline methiodine (BMI) or bicuculline methchloride (BMC) throughout the experiment. Whole cell recordings were obtained with pipettes filled with (in mM) 140 potassium gluconate, 2 MgCl2, 0.1 CaCl2, 1.1 ethylene glycol-bis(
-aminoethyl ether)-N,N,N
,N
-tetraacetic acid-KOH, 10 N-2-hydroxyethylpiperazine-N
-2-ethanesulfonic acid, and 2 K2-ATP, pH adjusted to 7.3 ± 0.05 (SE) with KOH. Synaptic responses were evoked by cathodal stimulation consisting of 0.1-ms voltage pulses delivered at 0.05-0.1 Hz to the internal capsule or the thalamic reticular nucleus (RTN) through a monopolar tungsten electrode. A 10-mV junction potential was subtracted from all membrane potential measurements (Huguenard and Prince 1994a
; Spigelman et al. 1992
). Results are presented as means ± SE.
 |
RESULTS |
IPSPs evoked by electrical stimulation were recorded in 58 VP neurons from P1 to P17. All had resting membrane potentials negative to
50 mV and overshooting action potentials.

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| FIG. 1.
A: inhibitory postsynaptic potentials (IPSPs) recorded in 2 postnatal day (P)1 ventral posterior nucleus (VP) neurons. A1: response of a P1 neuron as a function of membrane potential. A2: effects of bicuculline methiodine (BMI) and 2-hydroxysaclofen (2-OHS) on response. Vertical dotted line: onset of -aminobutyric acid-B (GABAB) IPSP. A3: response of another P1 neuron in control artificial cerebrospinal fluid (ACSF). B: response of a P6 neuron to a train stimulus (8 pulses at 100 Hz) in control ACSF, in ACSF containing 10 µM BMI, and ACSF containing 10 µM BMI and 100 µM 2-OHS. C: IPSPs recorded in a P11 VP neuron. Vertical dotted lines in C1: locations at which responses were measured and plotted in C2. D: response of a P14 VP neuron to a single shock at internal capsule/thalamic reticular nucleus (RTN) border. D1: oscillatory response recorded in a P14 VP neuron in control ACSF. A single electrical shock initially evoked a large IPSP followed by a rebound burst and a series of recurring IPSPs continuing for >3 s. D2: bath administration of GABAergic and glutamatergic antagonists revealed the presence of a glutamatergic excitatory postsynaptic potential and of a GABAB IPSP. Concentrations of antagonists were: BMI, 10 µM; 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX), 20 µM; D-2-amino-5-phosphonovaleric acid (APV), 100 µM; 2-OHS, 100 µM. D3: superimposition of control and BMI + CNQX + APV traces, comparing time course of GABAA and GABAB IPSPs. Horizontal dotted lines: resting level ( 72 mV). Vertical dotted lines: peak of IPSPs (D3). Traces in D1 and D2, CONTROL and BMI are truncated. Voltages inA-D: resting membrane potential.
|
|
An early IPSP peaking 41 ± 2.5 ms (SE; range 18-93 ms, n = 49) after the stimulus was observed in 52 of 54 (96%) neurons recorded in slices perfused with normal ACSF. This early IPSP was reversibly blocked by the addition of 5-10 µM BMI or BMC in 37 neurons and was absent in 4 neurons recorded in slices perfused with ACSF containing BMI or BMC. The reversal potential of the early GABAA IPSP, measured in 46 neurons, became more negative with age (r2 = 0.333, P < 0.0001), as previously described (Warren and Jones 1997
).
A late IPSP with a peak at 357 ± 27 ms (range 200-697 ms, n = 24) after the stimulus was observed in 25 of 53 (47%) neurons. This late IPSP was observed in only 11 of 49 (22%) neurons recorded in control ACSF, but was uncovered in 10 of 26 (38%) neurons when BMI or BMC was added to the ACSF and was obtained in all 4 (100%) neurons recorded in slices perfused with ACSF containing BMI or BMC. This late IPSP was found in neurons from P1 to P17 and was abolished by addition of 100-200 µM 2-hydroxysaclofen (2-OHS, n = 7), indicating its dependence on GABAB receptors. The reversal potential of the late IPSP was measured only in neurons in which the peak of the response could be isolated, thus avoiding contamination by the GABAA IPSP. The reversal potential was
98 ± 1.3 mV (range
106 to
89 mV), on average 14 mV negative to the early component. As measured in 13 neurons, it showed no apparent relationship with postnatal age (r2 = 0.155, P = 0.183).
At all ages, both GABAA and GABAB IPSPs were hyperpolarizing at resting membrane potential. In some neurons, the inhibitory response appeared monophasic in control ACSF (Fig. 1A1) and a late IPSP could only be detected when BMI was added to the bathing medium, revealing a long-duration late IPSP that peaked almost 700 ms after the stimulus and 650 ms after the peak of the early component (Fig. 1A2). The GABAB nature of the late IPSP was confirmed by its abolition in the presence of 2-OHS. In Fig. 1A2, the late IPSP became apparent only during the recovery phase of the early IPSP (Fig. 1A2, vertical dotted line). Putative GABAB IPSPs were also observed at P1 in control ACSF. In some neurons, in control ACSF, the earlierGABAA response was lacking (Fig. 1A3), showing thatGABAB receptor can be activated under normal conditions. In other neurons, in control ACSF, the two IPSPs were seen and there was a clear distinction between the early and late IPSPs which could be recognized by the presence of a hump occurring between them. In these cases, each component could be individually reduced with the use of specific pharmacological agents (Fig. 1B) and the early IPSP visibly reversed before the late IPSP as the membrane was hyperpolarized (Fig. 1C).
The late IPSP could not be detected in the response as a function of membrane potential curve of certain VP neurons; in others, including at older ages, a late IPSP could only be uncovered by blocking the GABAA response. Figure 1D shows a P14 neuron that displayed recurrent IPSPs in response to single-shock stimulation of the internal capsule (Fig. 1D1). There was a large early IPSP but no obvious late component (Fig. 1D2, CONTROL). The late IPSP may have been obscured by activation of the low-threshold calcium spike. Addition of BMI uncovered a large excitatory postsynaptic potential that was blocked by 20 µM 6-cyano-7-nitroquinoxaline-2,3-dione and 50 µM D-2-amino-5-phosphonovaleric acid and revealed a small, late IPSP that was blocked by the addition of 2-OHS. Onset of the late GABAB IPSP coincided with the peak of the earlier GABAA IPSP and its peak occurred during the late recovery phase of the GABAA IPSP, during which the low-threshold calcium spike was apparently activated (Fig. 1D3, vertical dotted lines).
The reversal potential of the GABAB IPSP did not change during postnatal development, in contrast to the GABAA IPSP. The most striking change was a shortening of the latency between stimulus and peak of the GABAB response (Fig. 2A). A change of several hundred milliseconds was not paralleled by a change of comparable magnitude in the GABAA response (Fig. 2B). The latency-to-peak of theGABAB response was strongly correlated with postnatal age, explaining almost 75% of its variation. Less than 10% of the variation in the latency-to-peak of the GABAA response could be explained by postnatal age.

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| FIG. 2.
A: pharmacologically isolated GABAB IPSPs as a function of postnatal age. All 4 traces have the same horizontal scale and are aligned on stimulus artifact. B: plot of time between stimulus and peak of GABAA and GABAB IPSPs as a function of postnatal age. GABAA IPSPs values were best fitted by a linear regression and GABAB IPSPs values by a quadratic polynomial regression. Horizontal and vertical dotted lines as in Fig. 1.
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 |
DISCUSSION |
GABAB and GABAA IPSPs are present in mouse VP neurons from P1, showing that functional postsynaptic receptors of both types are present in the thalamus from birth. In other brain regions GABAB postsynaptic responses were not found before the end of the first postnatal week (Gaiarsa et al. 1995
; Luhmann and Prince 1991
). GABAB IPSPs were not previously detected (Warren and Jones 1997
; Warren et al. 1994
), probably because of masking by the large GABAA IPSPs or because of washing out of its second-messenger system constituents. We observed an increased probability of evoking a GABAB IPSP when GABAA-mediated inhibition was blocked by adding bicuculline to the perfusing medium. The blockade of GABAA receptors produces much larger bursts in RTN neurons through disinhibition (e.g., Bal et al. 1995b
; Huguenard and Prince 1994b
; Warren and Jones 1997
). This would result in the release of a larger amount of GABA, which may be necessary to evoke a GABAB IPSP (Destexhe and Sejnowski 1995
).
GABAA and GABAB receptor functions are differentially regulated during postnatal development. The most significant change in the GABAA IPSP was hyperpolarization of its reversal potential; this could be attributed to changes in Cl
gradients occurring during the first postnatal weeks (Zhang et al. 1991
). There was no change in the reversal potential of the GABAB IPSP, but there was a large change in the kinetics of the response. This cannot be attributed to alterations in axonal conductivity or neurotransmitter release because these should have affected GABAA IPSPs as well. Postsynaptic changes in membrane input resistance and time constant should also have affected GABAA and GABAB IPSPs equally. The changes in kinetics are, therefore, likely to be attributable to changes in transduction of synaptic signals through guanosine 5
-triphosphate-binding proteins and may reflect speeding up of the steps between binding of GABA to the receptor and gating of the K+ channel. This could be achieved through an increase in GABA concentration at the GABAB receptor site due to developmental changes in uptake mechanisms or to an increased density of terminals, reducing the delay needed for the buildup of active G protein to reach a level sufficient to activate the K+ channel (Destexhe and Sejnowski 1995
).
In the preparation used, intrathalamic oscillations are readily generated through synaptic interactions between RTN and VP neurons (Warren at al. 1994). In this and similar preparations from other species (Bal et al. 1995a
), GABAB antagonists produce no change in oscillations, suggesting that GABAB-mediated-inhibition has a limited role in normal spindle formation. Recent findings, however, suggest an active role in slower thalamic oscillations similar to those observed in absence seizures (Bal et al. 1995a
,b
; Marescaux et al. 1992a
), which generally do not occur in infants. The present study shows that functional GABAB receptors are present from birth and therefore could participate in genesis of absence attacks.
The presence of GABAB IPSPs in the thalamus during the early postnatal period, when normal development of the thalamocortical system is activity dependent, suggests that it may play an important role in synapse formation or stabilization (Katz and Shatz 1996
; Shatz 1996
). The extremely long duration of the GABAB IPSP makes it particularly suitable for filtering noncoincident peripheral (or cortical) excitatory inputs. In older rodents, blockade of thalamic GABAB receptors leads to decreased EEG synchronization (Juhasz et al. 1994
), indicating the importance of these receptors in promoting coherent firing of large ensembles of thalamocortical relay neurons. The presence of GABAB receptors at an early age is a step in the maturation of relay cell properties that eventually permit the burst firing on which thalamic oscillations depend (Warren and Jones 1997
).
 |
ACKNOWLEDGEMENTS |
This work was supported by National Institute of Neurological Disorders and Stroke Grant NS-30109. R. A. Warren was supported by the Fonds de la Recherche en Santé du Québec, Canada.
 |
FOOTNOTES |
Address for reprint requests: R. A. Warren, Centre de recherche Fernand-Seguin, 7331 rue Hochelaga, Montreal, Quebec H1N 3V2, Canada.
Received 14 January 1997; accepted in final form 3 April 1997.
 |
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