Regulation of Action-Potential Firing in Spiny Neurons of the Rat Neostriatum In Vivo

Wickens, Jeffery R.; Wilson, Charles J.

doi:10.1152/jn.1998.79.5.2358

Cited by 130 publications

(114 citation statements)

References 26 publications

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“…While in the former 'down' state, the cells are unlikely to fire, even when an excitatory input signal is received. While in the less polarized 'up' state, an input signal can elicit an action potential [86,125]. Activation of the D1 receptor enhances the evoked response of medium spiny striatal output neurons to excitatory signals when the striatal neuron is in a relatively depolarized state (ca.…”

Section: Da Neurons Respond To Salient Unexpected Eventsmentioning

confidence: 99%

Dopamine gating of glutamatergic sensorimotor and incentive motivational input signals to the striatum

Horvitz

2002

Behavioural Brain Research

187

148

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Section: Da Neurons Respond To Salient Unexpected Eventsmentioning

confidence: 99%

Dopamine gating of glutamatergic sensorimotor and incentive motivational input signals to the striatum

Horvitz

2002

Behavioural Brain Research

187

148

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“…This is achieved by computing the contribution of measured action potentials to the average membrane potential. From intracellular voltage recordings of spontaneously active striatal medium spiny neurons (figure 3F in Wickens and Wilson, 1998), we estimate for a single spike an area of 6 mV × 100 msec between the firing threshold and the membrane potential. Using this value, the membrane potential is computed with…”

Section: Modelmentioning

confidence: 99%

“…This decay rate is reproduced by setting the value of the decay rate δ of the dopamine membrane effects to 0.8. The firing threshold is set to the average value for medium spiny neurons (Table 1) (Wickens and Wilson, 1998). As for the in vivo simulation, the reverse potential is set to a value just below firing threshold (Table 1).…”

Section: Dopamine Membrane Effectsmentioning

confidence: 99%

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Modeling functions of striatal dopamine modulation in learning and planning

Suri¹,

Bargas

Arbib³

2001

Neuroscience

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The activity of midbrain dopamine neurons is strikingly similar to the reward prediction error of TD reinforcement learning models. Experimental evidence and simulation studies suggest that dopamine neuron activity serves as an effective reinforcement signal for learning of sensorimotor associations in striatal matrisomes.In the current study, we simulate dopamine neuron activity with the Extended TD model (Suri and Schultz, submitted) and examine the influence of this signal on medium spiny neurons in striatal matrisomes. This model includes transient membrane effects of dopamine, dopamine-dependent longterm adaptations of corticostriatal transmission, and rhythmic fluctuations of the membrane potential between an elevated "up-state" and a hyperpolarized "down-state." The most dominant activity in the striatal matrisomes elicits behaviors via projections from the basal ganglia to the thalamus and the cortex. This "standard model" performs successfully when tested for sensorimotor learning and goaldirected behavior (planning). To investigate the contributions of these model assumptions to learning and planning, we test the performance of several model variants that lack one of these mechanisms. These simulations show that the adaptation of the dopamine-like signal is necessary for planning and for sensorimotor learning. Lack of dopamine-like novelty responses decreases the number of exploratory acts, which deteriorates planning capabilities. Sensorimotor learning requires dopamine-dependent long-term adaptation of corticostriatal transmission. The model loses its planning capabilities if the dopamine-like signal is simulated with the original TD model. The capability for planning is improved by transient dopamine membrane effects, dopamine-dependent long-term effects on corticostriatal transmission, dopamine-and input-dependent influences on the durations of membrane potential fluctuations, and manipulations that prolong the reaction time of the model. These simulation results suggest that striatal dopamine is important for sensorimotor learning, exploration, and planning.

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“…It is nevertheless clear that dopamine receptor activation plays a central role in corticostriatal plasticity, whether structural plasticity (Ingham et al, 1989;Day et al, 2006;Gerfen, 2006) or synaptic plasticity induced using high-frequency afferent stimulation (HFS) (Calabresi et al, 1992b;Wickens et al, 1996;Reynolds and Wickens, 2000;Kerr and Wickens, 2001;Reynolds et al, 2001). Because action potential (AP) firing, which is generally necessary for synaptic plasticity induction, is sparse in both cortical (Margrie et al, 2002;Brecht et al, 2003;Manns et al, 2004;Kerr et al, 2005;Lee et al, 2006;de Kock et al, 2007) and striatal spiny projection neurons in vivo, with single spikes occurring often (Wilson and Groves, 1981;Calabresi et al, 1990;Wilson and Kawaguchi, 1996;Wickens and Wilson, 1998;Mahon et al, 2006), HFS-based protocols may not translate well to in vivo-like activity. In addition, in many cortical areas including those that project to the striatum, synaptic plasticity has been induced using protocols that rely on the exact timing of postsynaptic APs in relation to presynaptic excitatory inputs (Magee and Johnston, 1997;Markram et al, 1997).…”

Section: Introductionmentioning

confidence: 99%

Dopamine Receptor Activation Is Required for Corticostriatal Spike-Timing-Dependent Plasticity

2008

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Single action potentials (APs) backpropagate into the higher-order dendrites of striatal spiny projection neurons during cortically driven "up" states. The timing of these backpropagating APs relative to the arriving corticostriatal excitatory inputs determines changes in dendritic calcium concentration. The question arises to whether this spike-timing relative to cortical excitatory inputs can also induce synaptic plasticity at corticostriatal synapses. Here we show that timing of single postsynaptic APs relative to the cortically evoked EPSP determines both the direction and the strength of synaptic plasticity in spiny projection neurons. Single APs occurring 30 ms before the cortically evoked EPSP induced long-term depression (LTD), whereas APs occurring 10 ms after the EPSP induced long-term potentiation (LTP). The amount of plasticity decreased as the time between the APs and EPSPs was increased, with the resulting spike-timing window being broader for LTD than for LTP. In addition, we show that dopamine receptor activation is required for this spike-timing-dependent plasticity (STDP). Blocking dopamine D 1 /D 5 receptors prevented both LTD and LTP induction. In contrast, blocking dopamine D 2 receptors delayed, but did not prevent, LTD and sped induction of LTP. We conclude (1) that, in combination with cortical inputs, single APs evoked in spiny projection neurons can induce both LTP and LTD of the corticostriatal pathway; (2) that the strength and direction of these synaptic changes depend deterministically on the AP timing relative to the arriving cortical inputs; (3) that, whereas dopamine D 2 receptor activation modulates the initial phase of striatal STDP, dopamine D 1 /D 5 receptor activation is critically required for striatal STDP. Thus, the timing of APs relative to cortical inputs alone is not enough to induce corticostriatal plasticity, implying that ongoing activity does not affect synaptic strength unless dopamine receptors are activated.

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Regulation of Action-Potential Firing in Spiny Neurons of the Rat Neostriatum In Vivo

Cited by 130 publications

References 26 publications

Dopamine gating of glutamatergic sensorimotor and incentive motivational input signals to the striatum

Dopamine gating of glutamatergic sensorimotor and incentive motivational input signals to the striatum

Modeling functions of striatal dopamine modulation in learning and planning

Dopamine Receptor Activation Is Required for Corticostriatal Spike-Timing-Dependent Plasticity

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