Tonic Nanomolar Dopamine Enables an Activity-Dependent Phase Recovery Mechanism That Persistently Alters the Maximal Conductance of the Hyperpolarization-Activated Current in a Rhythmically Active Neuron

Rodgers, Edmund W.; Fu, Jing Jing; Krenz, Wulf-Dieter C.; Baro, Deborah J.

doi:10.1523/jneurosci.3770-11.2011

Cited by 30 publications

(61 citation statements)

References 82 publications

(91 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…It appears that, once again, invertebrate models have begun to shed light on this complex issue. The concentration of dopamine in the hemolymph of spiny lobsters is at a low basal tone that changes slowly over time, whereas the concentration thought to be released within the STG is considerably higher and more transient (Rodgers et al, 2011). It remains to be determined whether the differential concentration of circulating steroids vs. neurosteroids can produce a similar basal tonic vs. elevated phasic modulation of neural circuits relevant to behavior (see Cornil, 2009; Cornil et al, 2012a for further discussion).…”

Section: Discussionmentioning

confidence: 99%

Frank Beach Award Winner: Steroids as neuromodulators of brain circuits and behavior

Remage‐Healey

2014

Hormones and Behavior

View full text Add to dashboard Cite

Neurons communicate primarily via action potentials that transmit information on the timescale of milliseconds. Neurons also integrate information via alterations in gene transcription and protein translation that are sustained for hours to days after initiation. Positioned between these two signaling timescales are the minute-by-minute actions of neuromodulators. Over the course of minutes, the classical neuromodulators (such as serotonin, dopamine, octopamine, and norepinephrine) can alter and/or stabilize neural circuit patterning as well as behavioral states. Neuromodulators allow many flexible outputs from neural circuits and can encode information content into the firing state of neural networks. The idea that steroid molecules can operate as genuine behavioral neuromodulators - synthesized by and acting within brain circuits on a minute-by-minute timescale - has gained traction in recent years. Evidence for brain steroid synthesis at synaptic terminals has converged with evidence for the rapid actions of brain-derived steroids on neural circuits and behavior. The general principle emerging from this work is that the production of steroid hormones within brain circuits can alter their functional connectivity and shift sensory representations by enhancing their information coding. Steroids produced in the brain can therefore change the information content of neuronal networks to rapidly modulate sensory experience and sensorimotor functions.

show abstract

Section: Discussionmentioning

confidence: 99%

Frank Beach Award Winner: Steroids as neuromodulators of brain circuits and behavior

Remage‐Healey

2014

Hormones and Behavior

View full text Add to dashboard Cite

show abstract

“…In a set of intriguing studies, the Baro lab [47*, 48*, 61, 62] has studied the effects of high and low concentrations of dopamine, mediated by different receptors and signal transduction pathways on channel expression and motor pattern generation in the STG. These studies highlight the importance of distinguishing between the modulatory tone that can arise from steady but low concentrations of a neuromodulator and the changes that can occur with short-term activation by higher concentrations [47*, 48*, 61, 62].…”

Section: Neuromodulation Can Reveal Variability or Diminish Its Impactmentioning

confidence: 99%

Robust circuit rhythms in small circuits arise from variable circuit components and mechanisms

Marder

Goeritz

Otopalik

2015

Current Opinion in Neurobiology

154

155

View full text Add to dashboard Cite

Small central pattern generating circuits found in invertebrates have significant advantages for the study of the circuit mechanisms that generate brain rhythms. Experimental and computational studies of small oscillatory circuits reveal that similar rhythms can arise from disparate mechanisms. Animal-to-animal variation in the properties of single neurons and synapses may underly robust circuit performance, and can be revealed by perturbations. Neuromodulation can produce altered circuit performance but also ensure reliable circuit function.

show abstract

“…However, dopamine also acts at high-affinity D1R receptors at far lower concentrations (~5 nM) to mediate a response that can regulate I H in an activity-dependent manner, precisely compensating for decreased I A via a concomitant calcineurin-dependent decrease in I H which restores LP phasing [32–34]. These findings demonstrate a mechanism by which modulation can provide flexibility and stability through a self-stabilizing feedback loop to maintain the I A :I H ratio, and that low levels of constitutive modulation can potentiate activity-dependent regulation of conductances [35]. Interestingly, these high-affinity D1 receptors also act on longer timescales to increase both of these ionic conductances through pathways that depend on transcription, translation, and RNA interference [36,37].…”

Section: Neuromodulator Dependent Plasticity Of Excitabilitymentioning

confidence: 99%

“…While neuromodulation can influence longer-term expression of channels in STG neurons (see above; [35–37,40]), only recently has there been evidence of direct activity-dependent feedback to the level of channel mRNAs. Temporal et al [46] recently performed such a study that decoupled the effects of loss of activity and neuromodulation as a result of decentralization of STG neurons (Figure 3D).…”

Section: Plasticity Of Channel Mrna Expressionmentioning

confidence: 99%

Homeostatic plasticity of excitability in crustacean central pattern generator networks

Schulz

Lane

2017

Current Opinion in Neurobiology

View full text Add to dashboard Cite

Plasticity of excitability can come in two general forms: changes in excitability that alter neuronal output (e.g. long-term potentiation of intrinsic excitability) or excitability changes that stabilize neuronal output (homeostatic plasticity). Here we discuss the latter form of plasticity in the context of the crustacean stomatogastric nervous system, and a second central pattern generator circuit, the cardiac ganglion. We discuss this plasticity at three levels: rapid homeostatic changes in membrane conductance, longer-term effects of neuromodulation on excitability, and the impacts of activity-dependent feedback on steady-state channel mRNA levels. We then conclude with thoughts on the implications of plasticity of excitability for variability of conductance levels across populations of motor neurons.

show abstract

Tonic Nanomolar Dopamine Enables an Activity-Dependent Phase Recovery Mechanism That Persistently Alters the Maximal Conductance of the Hyperpolarization-Activated Current in a Rhythmically Active Neuron

Cited by 30 publications

References 82 publications

Frank Beach Award Winner: Steroids as neuromodulators of brain circuits and behavior

Frank Beach Award Winner: Steroids as neuromodulators of brain circuits and behavior

Robust circuit rhythms in small circuits arise from variable circuit components and mechanisms

Homeostatic plasticity of excitability in crustacean central pattern generator networks

Contact Info

Product

Resources

About