Rapid Homeostatic Plasticity of Intrinsic Excitability in a Central Pattern Generator Network Stabilizes Functional Neural Network Output

Ransdell, Joseph L.; Nair, Satish S.; Schulz, David J.

doi:10.1523/jneurosci.1945-12.2012

Cited by 64 publications

(110 citation statements)

References 58 publications

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“…Only a single exception has been reported showing a negative correlation between mRNA levels of two A-type K + currents (Bergquist et al 2010). Another case of negative correlation was reported between two K + currents (Ransdell et al 2012), which show positive correlations, however, at the mRNA level, which suggests posttranscriptional regulation of these correlations.…”

Section: Invariance Of Activity and Current Correlationsmentioning

confidence: 95%

“…This is best exemplified in systems in which neurons are found with a single copy number. For example, in the stomatogastric and cardiac ganglia of the crab Cancer borealis identified neurons express highly variable conductance and mRNA levels of well-defined ionic currents (Liu et al 1998, Khorkova and Golowasch 2007, Schulz et al 2007, Ransdell et al 2012, Temporal et al 2012). However, what feature of activity each ionic current determines—or, inversely, which currents each activity trait in the system is determined by—is not clear for any system.…”

Section: Variabilitymentioning

confidence: 99%

“…Other interesting results from these computational studies indicate a prominent place for correlations of Ca ++ conductances with other conductances and indicate negative correlations between conductance pairs in specifying constant activity features. Surprisingly, to date, nearly all experimental studies have revealed the existence of linear and positive correlations between mRNA levels that code for different ion channels (Schulz et al 2006, 2007, Tobin et al 2009, Ransdell et al 2012, Temporal et al 2012) and between maximal conductances or maximal currents of a number of ionic currents in different cell types (MacLean et al 2003, 2005, Schulz et al 2006, Khorkova and Golowasch 2007, Ransdell et al 2012, Temporal et al 2012). Only a single exception has been reported showing a negative correlation between mRNA levels of two A-type K + currents (Bergquist et al 2010).…”

Section: Invariance Of Activity and Current Correlationsmentioning

confidence: 99%

“…However, the variability of ionic current or conductance levels between unambiguously identified neurons between individuals is being reported in a growing list of different preparations (Khorkova and Golowasch 2007, Olypher and Calabrese 2007, Schulz et al 2007, Leao et al 2012, Ransdell et al 2012, Temporal et al 2012, Unal et al 2012), including in genetically identical animals (Liss et al 2001, Swensen and Bean 2005, Etheredge et al 2007). This variability across individuals will here be referred to as population variability (box 1).…”

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confidence: 99%

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Ionic Current Variability and Functional Stability in the Nervous System

Golowasch¹

2014

BioScience

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Identified neurons in different animals express ionic currents at highly variable levels (population variability). If neuronal identity is associated with stereotypical function, as is the case in genetically identical neurons or in unambiguously identified individual neurons, this variability poses a conundrum: How is activity the same if the components that generate it—ionic current levels—are different? In some cases, ionic current variability across similar neurons generates an output gradient. However, many neurons produce very similar output activity, despite substantial variability in ionic conductances. It appears that, in many such cells, conductance levels of one ionic current vary in proportion to the conductance levels of another current. As a result, in a population of neurons, these conductances appear to be correlated. Here, I review theoretical and experimental work that suggests that neuronal ionic current correlation can reduce the global ionic current variability and can contribute to functional stability.

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Section: Invariance Of Activity and Current Correlationsmentioning

confidence: 95%

Section: Variabilitymentioning

confidence: 99%

Section: Invariance Of Activity and Current Correlationsmentioning

confidence: 99%

mentioning

confidence: 99%

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Ionic Current Variability and Functional Stability in the Nervous System

Golowasch¹

2014

BioScience

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“…Indeed, persistent sodium current is implicated in some forms of epilepsy and is a target of some antiepileptic drugs (Stafstrom 2007). Likewise, homeostatic upregulation of other subthreshold-activated potassium conductances (Ping and Tsunoda 2012;Ransdell et al 2012) could perhaps partially compensate for loss of Kv7 conductance. Changes in the covariation of the activity of the two neurons could also affect synaptic currents through spike timing-dependent plasticity or could trigger changes in intrinsic excitability (Cudmore et al 2010).…”

Section: Diseases and Homeostatic Plasticitymentioning

confidence: 99%

Kv7 channels regulate pairwise spiking covariability in health and disease

Ocker

Doiron

2014

Journal of Neurophysiology

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Ocker GK, Doiron B. Kv7 channels regulate pairwise spiking covariability in health and disease. J Neurophysiol 112: 340 -352, 2014. First published April 30, 2014 doi:10.1152/jn.00084.2014.-Low-threshold M currents are mediated by the Kv7 family of potassium channels. Kv7 channels are important regulators of spiking activity, having a direct influence on the firing rate, spike time variability, and filter properties of neurons. How Kv7 channels affect the joint spiking activity of populations of neurons is an important and open area of study. Using a combination of computational simulations and analytic calculations, we show that the activation of Kv7 conductances reduces the covariability between spike trains of pairs of neurons driven by common inputs. This reduction is beyond that explained by the lowering of firing rates and involves an active cancellation of common fluctuations in the membrane potentials of the cell pair. Our theory shows that the excess covariance reduction is due to a Kv7-induced shift from low-pass to band-pass filtering of the single neuron spike train response. Dysfunction of Kv7 conductances is related to a number of neurological diseases characterized by both elevated firing rates and increased network-wide correlations. We show how changes in the activation or strength of Kv7 conductances give rise to excess correlations that cannot be compensated for by synaptic scaling or homeostatic modulation of passive membrane properties. In contrast, modulation of Kv7 activation parameters consistent with pharmacological treatments for certain hyperactivity disorders can restore normal firing rates and spiking correlations. Our results provide key insights into how regulation of a ubiquitous potassium channel class can control the coordination of population spiking activity. . M currents have slow activation kinetics, lack inactivation dynamics, and decrease overall cellular excitability (Aiken et al. 1995;Gu et al. 2005;Higgs et al. 2007;Lawrence et al. 2006;Peters et al. 2005). M currents are due to heteromeric channels composed of Kv7.2/3 and Kv7.3/5 subunits that are encoded by the KCNQ gene family (Wang et al. 1998;Selyanko et al. 2001;Peters et al. 2005). Dysfunction of Kv7 channels is related to a number of disease: shifts in Kv7 activation have been associated with tinnitus (Li et al. 2013), mutations involved in peripheral nerve hyperexcitability decrease Kv7 surface expression (Wuttke et al. 2007), and changes in both voltage-sensing and surface expression have been related to neonatal epilepsy (Soldovieri et al. 2006). Kv7 mutations are also associated with the most common childhood epilepsy condition, rolandic epilepsy (Coppola et al. 2003;Neubauer et al. 2008). Despite the evidence of reduced Kv7 activation in tinnitus, chronic pain, and epilepsy, there lacks a coherent mechanistic theory for how Kv7 channels contribute to physiological signatures of such disease states.Two common neural correlates of tinnitus and epilepsy are elevated firing rates and excess spike train synchro...

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Motor inactivity in hibernating frogs: Linking plasticity that stabilizes neuronal function to behavior in the natural environment

Santin

2019

Developmental Neurobiology

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All animals must generate reliable neuronal activity to produce adaptive behaviors in an ever-changing environment. Neural systems are thought to achieve this goal, in part, through cellular and synaptic plasticity mechanisms that stabilize electrophysiological functions. Despite strong evidence for a role in regulating neuronal properties, these plasticity mechanisms have been difficult to link to natural behaviors in animals. In this review, I discuss how animals that inhabit extreme environments can address this challenge. As an example, I highlight recent work from frogs that stop breathing for several months during hibernation and, in response, use classic mechanisms of stabilizing plasticity to support respiratory motor output shortly after emergence. Furthermore, I describe problems for neuronal stability that may benefit from the study of hibernators: how circuits with variable modes of output control stabilizing mechanisms over long time scales and why some neural systems mount robust compensatory responses and others do not. By continuing to appreciate how diverse animal groups overcome challenges in the natural environment, we will broaden our view of the role that plasticity mechanisms play in stabilizing the nervous system. K E Y W O R D SAMPA receptor, control of breathing, hibernation, homeostatic plasticity, motor systems

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Rapid Homeostatic Plasticity of Intrinsic Excitability in a Central Pattern Generator Network Stabilizes Functional Neural Network Output

Cited by 64 publications

References 58 publications

Ionic Current Variability and Functional Stability in the Nervous System

Ionic Current Variability and Functional Stability in the Nervous System

Kv7 channels regulate pairwise spiking covariability in health and disease

Motor inactivity in hibernating frogs: Linking plasticity that stabilizes neuronal function to behavior in the natural environment

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