Functional dissection of basal ganglia inhibitory input onto SNc dopaminergic neurons

Substania nigra (SNc) dopaminergic neurons show a pause-rebound firing pattern in response to aversive events. Because these neurons integrate information from predominately inhibitory brain areas, it is important to determine which inputs functionally inhibit the dopamine neurons and whether this pause-rebound firing pattern can be produced by a solely inhibitory input. Here, we functionally map genetically-defined inhibitory projections from the dorsal striatum (striosome and matrix) and globus pallidus (GPe; parvalbumin and Lhx6) onto SNc neurons. We find that GPe and striosomal inputs both pause firing in SNc neurons, but rebound firing only occurs after inhibition from striosomes. Indeed, we find that striosomes are synaptically optimized to produce rebound and preferentially inhibit a subpopulation of ventral, intrinsically rebound-ready SNc dopaminergic neurons on their reticulata dendrites. Therefore, we describe a self-contained dendrite-specific striatonigral circuit that can produce pause-rebound firing in the absence of excitatory input.

Neurophysiological alterations in the nucleus reuniens of a mouse model of Alzheimer’s disease

Transgenic mice that overproduce beta-amyloid (Aβ) peptides exhibit neurophysiological alterations at the cellular, synaptic and network levels. Recently, increased neuronal activity in nucleus reuniens (Re), has been linked to hyperexcitability within hippocampal-thalamo-cortical networks in the J20 mouse model of amyloidopathy. Here in vitro whole-cell patch clamp recordings were used to compare old pathology-bearing J20 mice and wild-type controls to examine whether alterations to the intrinsic electrophysiological properties of Re neurons could contribute to the amyloidopathy-associated Re hyperactivity. A greater proportion of Re neurons displayed a hyperpolarised membrane potential in J20 mice without changes to the incidence or frequency of spontaneous action potential (AP) generation. Passive membrane properties were independent of transgene expression. Re neurons recorded from J20 mice did not exhibit increased AP generation in response to depolarising current stimuli but did exhibit an increased propensity to rebound burst following hyperpolarising current stimuli. This increase in rebound firing does not appear to result from alterations to T-type calcium channels. Finally, in J20 mice there was an ∼8% reduction in spike width, similar to what we and others have reported in CA1 pyramidal neurons from multiple amyloidopathy mice. We conclude that alterations to the intrinsic properties of Re neurons may contribute to the hyperexcitability observed in hippocampal-thalmo-cortical circuits under pathological Aβ load.Key PointsAlterations in the neurophysiology of hippocampal and cortical neurons has been linked to network hyperexcitability in mouse models of amyloidopathy.The nucleus reuniens (Re) is part of a cognitive network involving the hippocampal formation and prefrontal cortex. Increased cellular activity in Re has been linked to the generation of hippocampal-thalamo-cortical seizure activity in J20 mice.Re neurons display hyperpolarised resting membrane potentials in J20 mice. Passive membrane properties are unaffected by transgene expression. Re neurons recorded from J20 mice did not exhibit increased excitability in response to depolarising current stimuli but did exhibit an increased propensity to rebound burst following hyperpolarising current stimuli. This increased rebound firing was not a result of changes in T-type Ca2+ conductances. Finally we observed a decrease in AP width.These results help us understand how altered Re cellular neurophysiology may contribute to hippocampal-thalamo-cortical hyperexcitability in J20 mice.

Calcium-based dendritic excitability and its regulation in the deep cerebellar nuclei

The deep cerebellar nuclei (DCN) convey the final output of the cerebellum and are a major site of activity-dependent plasticity. Here, using patch-clamp recording and two-photon calcium imaging in rat brain slices, we demonstrate that DCN dendrites exhibit three hallmarks of active amplification of electrical signals. First, they produce calcium transients with rise times of tens of milliseconds, comparable in amplitude and duration to calcium spikes in other neurons. Second, calcium signal amplitudes are undiminished along the length of dendrites to the farthest distances from the soma. Third, they can generate calcium signals even in the presence of tetrodotoxin, a sodium channel blocker that abolishes somatic action potential initiation. DCN calcium transients do require the action of T-type calcium channels, a common voltage-gated conductance in excitable dendrites. Dendritic calcium influx was evoked by release from hyperpolarization, peaked within tens of milliseconds, and was observed in both transient- and weak-rebound-firing neurons. In a survey across the DCN, transient-burst rebound firing, which was accompanied by the most rapid calcium flux, was more common in lateral nucleus than in interpositus nucleus and was not seen in medial nucleus. Rebound firing and calcium transients were not present in animals shipped 1–3 days before recording, a condition associated with elevated maternal and pup corticosterone and reduced pup body weight. Rebounds could be restored by the protein kinase C activator phorbol 12-myristate-13-acetate. Thus local calcium-based dendritic excitability supports a stage of presomatic amplification that is under regulation by stress and neuromodulatory influence.