Abstract
Tonic conductance mediated by extrasynaptic GABAA receptors has been implicated in the modulation of network oscillatory activity. Using an in vitro brain slice to produce oscillatory activity and a kinetic model of GABAA receptor dynamics, we show that changes in tonic inhibitory input to fast spiking interneurons underlie benzodiazepine-site mediated modulation of neuronal network synchrony in rat primary motor cortex. We found that low concentrations (10 nM) of the benzodiazepine site agonist, zolpidem, reduced the power of pharmacologically-induced beta-frequency (15–30 Hz) oscillatory activity. By contrast, higher doses augmented beta power. Application of the antagonist, flumazenil, also increased beta power suggesting endogenous modulation of the benzodiazepine binding site. Voltage-clamp experiments revealed that pharmacologically-induced rhythmic inhibitory postsynaptic currents were reduced by 10 nM zolpidem, suggesting an action on inhibitory interneurons. Further voltage-clamp studies of fast spiking cells showed that 10 nM zolpidem augmented a tonic inhibitory GABAA receptor mediated current in fast spiking cells whilst higher concentrations of zolpidem reduced the tonic current. A kinetic model of zolpidem-sensitive GABAA receptors suggested that incubation with 10 nM zolpidem resulted in a high proportion of GABAA receptors locked in a kinetically slow desensitized state whilst 30 nM zolpidem favoured rapid transition into and out of desensitized states. This was confirmed experimentally using a challenge with saturating concentrations of GABA. Selective modulation of an interneuron-specific tonic current may underlie the reversal of cognitive and motor deficits afforded by low-dose zolpidem in neuropathological states.
Highlights
The primary motor cortex (M1) exhibits neuronal network oscillatory activity at beta frequency (15e30 Hz) (Murthy and Fetz, Abbreviations: AHP, after-hyperpolarization; aCSF, artificial cerebrospinal fluid; CCh, carbachol; FS, fast spiking; Itonic, tonic inhibitory current; M1, primary motor cortex; inter-event intervals (IEI), interevent interval; IPSCs, inhibitory postsynaptic currents; KA, kainic acid; KS, KolmogoroveSmirnov test; Local field potential (LFP), local field potential; ODEs, ordinary differential equations; sIPSCs, spontaneous IPSCs.1992; Baker et al, 1997)
Using an in vitro brain slice model of neuronal oscillatory activity and a kinetic model of GABAA receptor dynamics, we show that changes in tonic inhibitory input to FS interneurons produce bidirectional modulation of neuronal network synchrony in M1 mediated by benzodiazepine-site activation
Previous studies indicate that GABAA receptors containing a1 and g2 subunits are present on inhibitory interneurons, including
Summary
The primary motor cortex (M1) exhibits neuronal network oscillatory activity at beta frequency (15e30 Hz) (Murthy and Fetz, Abbreviations: AHP, after-hyperpolarization; aCSF, artificial cerebrospinal fluid; CCh, carbachol; FS, fast spiking; Itonic, tonic inhibitory current; M1, primary motor cortex; IEI, interevent interval; IPSCs, inhibitory postsynaptic currents; KA, kainic acid; KS, KolmogoroveSmirnov test; LFP, local field potential; ODEs, ordinary differential equations; sIPSCs, spontaneous IPSCs.1992; Baker et al, 1997). Recent evidence suggests that a sustained inhibitory membrane conductance (Itonic), arising from spillover of GABA, and mediated by high affinity extrasynaptic GABAA receptors (Farrant and Nusser, 2005; Bright et al, 2007) plays a fundamental role in shaping network excitability (Semyanov et al, 2004; Mann and Mody, 2010). As Itonic is more active in fast-spiking (FS) interneurons compared to pyramidal cells (Semyanov et al, 2003), and FS cells have been reported to express high levels of a1 subunit containing GABAA receptors (Bacci et al., 2003; Thomson et al, 2000), an effect of benzodiazepines on Itonic in a single FS cell could have a profound effect on synchronous activity in neuronal networks
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