Abstract
Substantia nigra pars compacta (SNpc) dopaminergic neurons receive strong tonic inputs from GABAergic neurons in the substantia nigra pars reticulata (SNpr) and globus pallidus (GP), and glutamatergic neurons in the subthalamic nucleus. The presence of these tonic inputs raises the possibility that phasic disinhibition may trigger phasic bursts in dopaminergic neurons. We first applied constant NMDA and GABAA conductances onto a two-compartment single cell model of the dopaminergic neuron (Kuznetsov et al., 2006). The model exhibited disinhibition bursting upon stepwise removal of inhibition. A further bifurcation analysis suggests that disinhibition may be more robust than excitation alone in that for most levels of NMDA conductance, the cell remains capable of bursting even after a complete removal of inhibition, whereas too much excitatory input will drive the cell into depolarization block. To investigate the network dynamics of disinhibition, we used a modified version of an integrate-and-fire based model of the basal ganglia (Humphries et al., 2006). Synaptic activity generated in the network was delivered to the two-compartment single cell dopaminergic neuron. Phasic activation of the D1-expressing medium spiny neurons in the striatum (D1STR) produced disinhibition bursts in dopaminergic neurons through the direct pathway (D1STR to SNpr to SNpc). Anatomical studies have shown that D1STR neurons have collaterals that terminate in GP. Adding these collaterals to the model, we found that striatal activation increased the intra-burst firing frequency of the disinhibition burst as the weight of this connection was increased. Our studies suggest that striatal activation is a robust means by which disinhibition bursts can be generated by SNpc dopaminergic neurons, and that recruitment of the indirect pathway via collaterals may enhance disinhibition bursting.
Highlights
In behaving animals, midbrain dopaminergic neurons fire bursts of action potentials in response to salient stimuli (Redgrave et al, 1990; Horvitz et al, 1997; Schultz, 1998), when a greater than expected reward is received (Schultz et al, 1997), or during sequence learning (Jin and Costa, 2010)
Materials and Methods This study investigated conditions under which disinhibition in the basal ganglia network leads to bursting in midbrain dopaminergic neurons
We first investigated the range of synaptic parameters that can give rise to bursting in our single cell model of the midbrain dopaminergic neuron
Summary
Midbrain dopaminergic neurons fire bursts of action potentials in response to salient stimuli (Redgrave et al, 1990; Horvitz et al, 1997; Schultz, 1998), when a greater than expected reward is received (Schultz et al, 1997), or during sequence learning (Jin and Costa, 2010). One view of the dopaminergic neuron in vivo is that single-spiking is generated by an in vitro-like calcium – (Kita et al, 1986; Grace and Onn, 1989; Wilson and Callaway, 2000) or sodium-based (Guzman et al, 2009; Khaliq and Bean, 2010) pacemaking mechanism in which spikes can be advanced or delayed due to afferent input. Dopaminergic neurons in vivo are subject to strong tonic synaptic inputs, suggesting that an alternative but complementary mechanism by which dopaminergic neurons may fire bursts is through disinhibition
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