Your search keyword '"Steven A, Prescott"' showing total 91 results

1. Similar excitability through different sodium channels and implications for the analgesic efficacy of selective drugs

Author

Yu-Feng Xie, Jane Yang, Stéphanie Ratté, and Steven A Prescott

Subjects

pain, degeneracy, sodium channel, Nav1.7, Nav1.8, excitability, Medicine, Science, Biology (General), QH301-705.5

Abstract

Nociceptive sensory neurons convey pain-related signals to the CNS using action potentials. Loss-of-function mutations in the voltage-gated sodium channel NaV1.7 cause insensitivity to pain (presumably by reducing nociceptor excitability) but clinical trials seeking to treat pain by inhibiting NaV1.7 pharmacologically have struggled. This may reflect the variable contribution of NaV1.7 to nociceptor excitability. Contrary to claims that NaV1.7 is necessary for nociceptors to initiate action potentials, we show that nociceptors can achieve similar excitability using different combinations of NaV1.3, NaV1.7, and NaV1.8. Selectively blocking one of those NaV subtypes reduces nociceptor excitability only if the other subtypes are weakly expressed. For example, excitability relies on NaV1.8 in acutely dissociated nociceptors but responsibility shifts to NaV1.7 and NaV1.3 by the fourth day in culture. A similar shift in NaV dependence occurs in vivo after inflammation, impacting ability of the NaV1.7-selective inhibitor PF-05089771 to reduce pain in behavioral tests. Flexible use of different NaV subtypes exemplifies degeneracy – achieving similar function using different components – and compromises reliable modulation of nociceptor excitability by subtype-selective inhibitors. Identifying the dominant NaV subtype to predict drug efficacy is not trivial. Degeneracy at the cellular level must be considered when choosing drug targets at the molecular level.

Published

2024

2. Homeostatic regulation of neuronal function: importance of degeneracy and pleiotropy

Author

Jane Yang and Steven A. Prescott

Subjects

degeneracy, pleiotropy, excitability, ion channels, homeostatic regulation, robustness, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Neurons maintain their average firing rate and other properties within narrow bounds despite changing conditions. This homeostatic regulation is achieved using negative feedback to adjust ion channel expression levels. To understand how homeostatic regulation of excitability normally works and how it goes awry, one must consider the various ion channels involved as well as the other regulated properties impacted by adjusting those channels when regulating excitability. This raises issues of degeneracy and pleiotropy. Degeneracy refers to disparate solutions conveying equivalent function (e.g., different channel combinations yielding equivalent excitability). This many-to-one mapping contrasts the one-to-many mapping described by pleiotropy (e.g., one channel affecting multiple properties). Degeneracy facilitates homeostatic regulation by enabling a disturbance to be offset by compensatory changes in any one of several different channels or combinations thereof. Pleiotropy complicates homeostatic regulation because compensatory changes intended to regulate one property may inadvertently disrupt other properties. Co-regulating multiple properties by adjusting pleiotropic channels requires greater degeneracy than regulating one property in isolation and, by extension, can fail for additional reasons such as solutions for each property being incompatible with one another. Problems also arise if a perturbation is too strong and/or negative feedback is too weak, or because the set point is disturbed. Delineating feedback loops and their interactions provides valuable insight into how homeostatic regulation might fail. Insofar as different failure modes require distinct interventions to restore homeostasis, deeper understanding of homeostatic regulation and its pathological disruption may reveal more effective treatments for chronic neurological disorders like neuropathic pain and epilepsy.

Published

2023

3. Synchrony-Division Neural Multiplexing: An Encoding Model

Author

Mohammad R. Rezaei, Reza Saadati Fard, Milos R. Popovic, Steven A. Prescott, and Milad Lankarany

Subjects

neural coding, information representation, multiplexed coding, synchronous and asynchronous spikes, general linear model, Science, Astrophysics, QB460-466, Physics, QC1-999

Abstract

Cortical neurons receive mixed information from the collective spiking activities of primary sensory neurons in response to a sensory stimulus. A recent study demonstrated an abrupt increase or decrease in stimulus intensity and the stimulus intensity itself can be respectively represented by the synchronous and asynchronous spikes of S1 neurons in rats. This evidence capitalized on the ability of an ensemble of homogeneous neurons to multiplex, a coding strategy that was referred to as synchrony-division multiplexing (SDM). Although neural multiplexing can be conceived by distinct functions of individual neurons in a heterogeneous neural ensemble, the extent to which nearly identical neurons in a homogeneous neural ensemble encode multiple features of a mixed stimulus remains unknown. Here, we present a computational framework to provide a system-level understanding on how an ensemble of homogeneous neurons enable SDM. First, we simulate SDM with an ensemble of homogeneous conductance-based model neurons receiving a mixed stimulus comprising slow and fast features. Using feature-estimation techniques, we show that both features of the stimulus can be inferred from the generated spikes. Second, we utilize linear nonlinear (LNL) cascade models and calculate temporal filters and static nonlinearities of differentially synchronized spikes. We demonstrate that these filters and nonlinearities are distinct for synchronous and asynchronous spikes. Finally, we develop an augmented LNL cascade model as an encoding model for the SDM by combining individual LNLs calculated for each type of spike. The augmented LNL model reveals that a homogeneous neural ensemble model can perform two different functions, namely, temporal- and rate-coding, simultaneously.

Published

2023

4. Minimal requirements for a neuron to coregulate many properties and the implications for ion channel correlations and robustness

Author

Jane Yang, Husain Shakil, Stéphanie Ratté, and Steven A Prescott

Subjects

regulation, homeostasis, degeneracy, excitability, noise, ion channel, Medicine, Science, Biology (General), QH301-705.5

Abstract

Neurons regulate their excitability by adjusting their ion channel levels. Degeneracy – achieving equivalent outcomes (excitability) using different solutions (channel combinations) – facilitates this regulation by enabling a disruptive change in one channel to be offset by compensatory changes in other channels. But neurons must coregulate many properties. Pleiotropy – the impact of one channel on more than one property – complicates regulation because a compensatory ion channel change that restores one property to its target value often disrupts other properties. How then does a neuron simultaneously regulate multiple properties? Here, we demonstrate that of the many channel combinations producing the target value for one property (the single-output solution set), few combinations produce the target value for other properties. Combinations producing the target value for two or more properties (the multioutput solution set) correspond to the intersection between single-output solution sets. Properties can be effectively coregulated only if the number of adjustable channels (nin) exceeds the number of regulated properties (nout). Ion channel correlations emerge during homeostatic regulation when the dimensionality of solution space (nin − nout) is low. Even if each property can be regulated to its target value when considered in isolation, regulation as a whole fails if single-output solution sets do not intersect. Our results also highlight that ion channels must be coadjusted with different ratios to regulate different properties, which suggests that each error signal drives modulatory changes independently, despite those changes ultimately affecting the same ion channels.

Published

2022

5. Precision Health Resource of Control iPSC Lines for Versatile Multilineage Differentiation

Author

Matthew R. Hildebrandt, Miriam S. Reuter, Wei Wei, Naeimeh Tayebi, Jiajie Liu, Sazia Sharmin, Jaap Mulder, L. Stephen Lesperance, Patrick M. Brauer, Rebecca S.F. Mok, Caroline Kinnear, Alina Piekna, Asli Romm, Jennifer Howe, Peter Pasceri, Guoliang Meng, Matthew Rozycki, Deivid C. Rodrigues, Elisa C. Martinez, Michael J. Szego, Juan C. Zúñiga-Pflücker, Michele K. Anderson, Steven A. Prescott, Norman D. Rosenblum, Binita M. Kamath, Seema Mital, Stephen W. Scherer, and James Ellis

Subjects

Medicine (General), R5-920, Biology (General), QH301-705.5

Abstract

Summary: Induced pluripotent stem cells (iPSC) derived from healthy individuals are important controls for disease-modeling studies. Here we apply precision health to create a high-quality resource of control iPSCs. Footprint-free lines were reprogrammed from four volunteers of the Personal Genome Project Canada (PGPC). Multilineage-directed differentiation efficiently produced functional cortical neurons, cardiomyocytes and hepatocytes. Pilot users demonstrated versatility by generating kidney organoids, T lymphocytes, and sensory neurons. A frameshift knockout was introduced into MYBPC3 and these cardiomyocytes exhibited the expected hypertrophic phenotype. Whole-genome sequencing-based annotation of PGPC lines revealed on average 20 coding variants. Importantly, nearly all annotated PGPC and HipSci lines harbored at least one pre-existing or acquired variant with cardiac, neurological, or other disease associations. Overall, PGPC lines were efficiently differentiated by multiple users into cells from six tissues for disease modeling, and variant-preferred healthy control lines were identified for specific disease settings. : Ellis, Scherer, and colleagues apply precision health to upgrade iPSC quality for disease modeling. The resource provides control lines from four healthy individuals, clinical annotation of whole-genome variants, and identification of variant-preferred lines for neurologic and cardiac disease. Resource users demonstrated versatile differentiation into functional cells from six tissues, and CRISPR-edited cells phenocopied a cardiomyopathy model. Keywords: Personal Genome Project Canada, control iPSCs, whole-genome sequencing, gene editing, cellular phenotyping, disease modeling

Published

2019

6. Excitatory neurons are more disinhibited than inhibitory neurons by chloride dysregulation in the spinal dorsal horn

Author

Kwan Yeop Lee, Stéphanie Ratté, and Steven A Prescott

Subjects

allodynia, neuropathic pain, disinhibition, spinal cord, KCC2, spatial summation, Medicine, Science, Biology (General), QH301-705.5

Abstract

Neuropathic pain is a debilitating condition caused by the abnormal processing of somatosensory input. Synaptic inhibition in the spinal dorsal horn plays a key role in that processing. Mechanical allodynia – the misperception of light touch as painful – occurs when inhibition is compromised. Disinhibition is due primarily to chloride dysregulation caused by hypofunction of the potassium-chloride co-transporter KCC2. Here we show, in rats, that excitatory neurons are disproportionately affected. This is not because chloride is differentially dysregulated in excitatory and inhibitory neurons, but, rather, because excitatory neurons rely more heavily on inhibition to counterbalance strong excitation. Receptive fields in both cell types have a center-surround organization but disinhibition unmasks more excitatory input to excitatory neurons. Differences in intrinsic excitability also affect how chloride dysregulation affects spiking. These results deepen understanding of how excitation and inhibition are normally balanced in the spinal dorsal horn, and how their imbalance disrupts somatosensory processing.

Published

2019

7. Chloride Dysregulation through Downregulation of KCC2 Mediates Neuropathic Pain in Both Sexes

Author

Josiane C.S. Mapplebeck, Louis-Etienne Lorenzo, Kwan Yeop Lee, Cédric Gauthier, Milind M. Muley, Yves De Koninck, Steven A. Prescott, and Michael W. Salter

Subjects

Biology (General), QH301-705.5

Abstract

Summary: The behavioral features of neuropathic pain are not sexually dimorphic despite sex differences in the underlying neuroimmune signaling. This raises questions about whether neural processing is comparably altered. Here, we test whether the K+-Cl− co-transporter KCC2, which regulates synaptic inhibition, plays an equally important role in development of neuropathic pain in male and female rodents. Past studies on KCC2 tested only males. We find that inhibiting KCC2 in uninjured animals reproduces behavioral and electrophysiological features of neuropathic pain in both sexes and, consistent with equivalent injury-induced downregulation of KCC2, that counteracting chloride dysregulation reverses injury-induced behavioral and electrophysiological changes in both sexes. These findings demonstrate that KCC2 downregulation contributes equally to pain hypersensitivity in males and females. Whereas diverse (and sexually dimorphic) mechanisms regulate KCC2, regulation of intracellular chloride relies almost exclusively on KCC2. Directly targeting KCC2 thus remains a promising strategy for treatment of neuropathic pain in both sexes. : Neuropathic pain arises in males and females through distinct neuroimmune signaling. Yet the behavioral (or clinical) features of neuropathic pain are not sexually dimorphic. Mapplebeck et al. demonstrate that KCC2—though regulated in multiple, sex-specific ways—is uniquely responsible for the synaptic disinhibition causing neuropathic pain in both sexes. Keywords: K+-Cl− co-transporter KCC2, sex differences, degeneracy, neuropathic pain, disinhibition, GABA, glycine, BDNF

Published

2019

8. Reproducible and fully automated testing of nocifensive behavior in mice

Author

Christopher Dedek, Mehdi A. Azadgoleh, and Steven A. Prescott

Abstract

Pain in rodents is often inferred from their withdrawal to noxious stimulation, using the threshold stimulus intensity or response latency to quantify pain sensitivity. This usually involves applying stimuli by hand and measuring responses by eye, which limits reproducibility and throughput to the detriment of preclinical pain research. Here, we describe a device that standardizes and automates pain testing by providing computer-controlled aiming, stimulation, and response measurement. Optogenetic and thermal stimuli are applied to the hind paw using blue and infrared light, respectively. Red light delivered through the same light path assists with aiming, and changes in its reflectance off the paw are used to measure paw withdrawal latency with millisecond precision at a fraction of the cost and data processing associated with high-speed video. Using standard video, aiming was automated by training a neural network to recognize the paws and move the stimulator using motorized linear actuators. Real-time data processing allows for closed-loop control of stimulus initiation and termination. We show that stimuli delivered with this device are significantly less variable than hand-delivered stimuli, and that reducing stimulus variability is crucial for resolving stimulus-dependent variations in withdrawal. Slower stimulus waveforms whose stable delivery is made possible with this device reveal details not evident with typical photostimulus pulses. Moreover, the substage video reveals a wealth of “spontaneous” behaviors occurring before and after stimulation that can considered alongside withdrawal metrics to better assess the pain experience. Automation allows comprehensive testing to be standardized and carried out efficiently.

Published

2023

9. Multiscale Computer Model of the Spinal Dorsal Horn Reveals Changes in Network Processing Associated with Chronic Pain

Author

Sekiguchi K, Medlock L, William W. Lytton, Steven A. Prescott, and Salvador Dura-Bernal

Subjects

Spinal Cord Dorsal Horn, General Neuroscience, Dynorphin, Biology, Stimulus (physiology), Inhibitory postsynaptic potential, Spinal cord, Posterior Horn Cells, medicine.anatomical_structure, Spinal Cord, Interneurons, Synapses, medicine, biology.protein, Excitatory postsynaptic potential, Humans, Computer Simulation, Neuron, Calretinin, Chronic Pain, Neuroscience, Parvalbumin, Research Articles

Abstract

Pain-related sensory input is processed in the spinal dorsal horn (SDH) before being relayed to the brain. That processing profoundly influences whether stimuli are correctly or incorrectly perceived as painful. Significant advances have been made in identifying the types of excitatory and inhibitory neurons that comprise the SDH, and there is some information about how neuron types are connected, but it remains unclear how the overall circuit processes sensory input or how that processing is disrupted under chronic pain conditions. To explore SDH function, we developed a computational model of the circuit that is tightly constrained by experimental data. Our model comprises conductance-based neuron models that reproduce the characteristic firing patterns of spinal neurons. Excitatory and inhibitory neuron populations, defined by their expression of genetic markers, spiking pattern, or morphology, were synaptically connected according to available qualitative data. Using a genetic algorithm, synaptic weights were tuned to reproduce projection neuron firing rates (model output) based on primary afferent firing rates (model input) across a range of mechanical stimulus intensities. Disparate synaptic weight combinations could produce equivalent circuit function, revealing degeneracy that may underlie heterogeneous responses of different circuits to perturbations or pathological insults. To validate our model, we verified that it responded to reduction of inhibition (i.e. disinhibition) and ablation of specific neuron types in a manner consistent with experiments. Thus validated, our model offers a valuable resource for interpreting experimental results and testing hypotheses in silico to plan experiments for examining normal and pathological SDH circuit function.Significance StatementWe developed a multiscale computer model of the posterior part of spinal cord gray matter (spinal dorsal horn), involved in perception of touch and pain. The model reproduces several experimental observations and makes predictions about how specific types of spinal neurons and synapses influence projection neurons that send information to the brain. Misfiring of these projection neurons can produce anomalous sensations associated with chronic pain. Our computer model will not only assist in planning future experiments, but will also be useful for developing new pharmacotherapy for chronic pain disorders, connecting the effect of drugs acting at the molecular scale with emergent properties of neurons and circuits that shape the pain experience.

Published

2022

10. Paresthesia during spinal cord stimulation depends on synchrony of dorsal column axon activation

Author

Boriss Sagalajev, Tianhe Zhang, Nooshin Abdollahi, Noosha Yousefpour, Laura Medlock, Dhekra Al-Basha, Alfredo Ribeiro-da-Silva, Rosana Esteller, Stéphanie Ratté, and Steven A. Prescott

Abstract

Spinal cord stimulation (SCS) reduces chronic pain. Conventional (40-60 Hz) SCS engages spinal inhibitory mechanisms by activating low-threshold mechanoreceptive afferents with axons in the dorsal columns (DCs). But activating DC axons typically causes a buzzing sensation (paresthesia) that can be uncomfortable. Kilohertz-frequency (1-10 kHz) SCS produces analgesia without paresthesia and is thought, therefore, not to activate DC axons, leaving its mechanism unclear. Here we show in rats that kilohertz-frequency SCS activates DC axons but causes them to spike less synchronously than conventional SCS. Spikes desynchronize because axons entrain irregularly when stimulated at intervals shorter than their refractory period, a phenomenon we call overdrive desynchronization. Effects of overdrive desynchronization on evoked compound action potentials were verified in simulations, rats, pigs, and a chronic pain patient. Whereas synchronous spiking in DC axons is necessary for paresthesia, asynchronous spiking is sufficient to produce analgesia. Asynchronous activation of DC axons thus produces paresthesia-free analgesia.

Published

2023

11. A combined strategy for dynamic probabilistic risk assessment of fission battery designs using EMRALD and DEPM

Author

Arjun Earthperson, Courtney M. Otani, Daniel Nevius, Steven R. Prescott, and Mihai A. Diaconeasa

Subjects

Nuclear Energy and Engineering, Energy Engineering and Power Technology, Safety, Risk, Reliability and Quality, Waste Management and Disposal

Published

2023

12. TRPC4 and GIRK channels underlie neuronal coding of firing patterns that reflect G

Author

Jin-Bin, Tian, Jane, Yang, William C, Joslin, Veit, Flockerzi, Steven A, Prescott, Lutz, Birnbaumer, and Michael X, Zhu

Subjects

Neurons, Mice, G Protein-Coupled Inwardly-Rectifying Potassium Channels, Action Potentials, Animals, Cell Communication, GTP-Binding Protein alpha Subunits, Gi-Go, Synaptic Transmission, GTP-Binding Protein alpha Subunits, TRPC Cation Channels

Abstract

Transient receptor potential canonical 4 (TRPC4) is a receptor-operated cation channel codependent on both the Gq/11–phospholipase C signaling pathway and Gi/o proteins for activation. This makes TRPC4 an excellent coincidence sensor of neurotransmission through Gq/11- and Gi/o-coupled receptors. In whole-cell slice recordings of lateral septal neurons, TRPC4 mediates a strong depolarizing plateau that shuts down action potential firing, which may or may not be followed by a hyperpolarization that extends the firing pause to varying durations depending on the strength of Gi/o stimulation. We show that the depolarizing plateau is codependent on Gq/11-coupled group I metabotropic glutamate receptors and on Gi/o-coupled γ-aminobutyric acid type B receptors. The hyperpolarization is mediated by Gi/o activation of G protein–activated inwardly rectifying K+ (GIRK) channels. Moreover, the firing patterns, elicited by either electrical stimulation or receptor agonists, encode information about the relative strengths of Gq/11 and Gi/o inputs in the following fashion. Pure Gq/11 input produces weak depolarization accompanied by firing acceleration, whereas pure Gi/o input causes hyperpolarization that pauses firing. Although coincident Gq/11–Gi/o inputs also pause firing, the pause is preceded by a burst, and both the pause duration and firing recovery patterns reflect the relative strengths of Gq/11 versus Gi/o inputs. Computer simulations demonstrate that different combinations of TRPC4 and GIRK conductances are sufficient to produce the range of firing patterns observed experimentally. Thus, concurrent neurotransmission through the Gq/11 and Gi/o pathways is converted to discernible electrical responses by the joint actions of TRPC4 and GIRK for communication to downstream neurons.

Published

2022

13. Combined Changes in Chloride Regulation and Neuronal Excitability Enable Primary Afferent Depolarization to Elicit Spiking without Compromising its Inhibitory Effects.

Author

Petri Takkala, Yi Zhu, and Steven A Prescott

Subjects

Biology (General), QH301-705.5

Abstract

The central terminals of primary afferent fibers experience depolarization upon activation of GABAA receptors (GABAAR) because their intracellular chloride concentration is maintained above electrochemical equilibrium. Primary afferent depolarization (PAD) normally mediates inhibition via sodium channel inactivation and shunting but can evoke spikes under certain conditions. Antidromic (centrifugal) conduction of these spikes may contribute to neurogenic inflammation while orthodromic (centripetal) conduction could contribute to pain in the case of nociceptive fibers. PAD-induced spiking is assumed to override presynaptic inhibition. Using computer simulations and dynamic clamp experiments, we sought to identify which biophysical changes are required to enable PAD-induced spiking and whether those changes necessarily compromise PAD-mediated inhibition. According to computational modeling, a depolarizing shift in GABA reversal potential (EGABA) and increased intrinsic excitability (manifest as altered spike initiation properties) were necessary for PAD-induced spiking, whereas increased GABAAR conductance density (ḡGABA) had mixed effects. We tested our predictions experimentally by using dynamic clamp to insert virtual GABAAR conductances with different EGABA and kinetics into acutely dissociated dorsal root ganglion (DRG) neuron somata. Comparable experiments in central axon terminals are prohibitively difficult but the biophysical requirements for PAD-induced spiking are arguably similar in soma and axon. Neurons from naïve (i.e. uninjured) rats were compared before and after pharmacological manipulation of intrinsic excitability, and against neurons from nerve-injured rats. Experimental data confirmed that, in most neurons, both predicted changes were necessary to yield PAD-induced spiking. Importantly, such changes did not prevent PAD from inhibiting other spiking or from blocking spike propagation. In fact, since the high value of ḡGABA required for PAD-induced spiking still mediates strong inhibition, we conclude that PAD-induced spiking does not represent failure of presynaptic inhibition. Instead, diminished PAD caused by reduction of ḡGABA poses a greater risk to presynaptic inhibition and the sensory processing that relies upon it.

Published

2016

14. Author response: Minimal requirements for a neuron to coregulate many properties and the implications for ion channel correlations and robustness

Author

Jane Yang, Husain Shakil, Stéphanie Ratté, and Steven A Prescott

Published

2022

15. Chloride Channels

Author

Steven A. Prescott

Published

2022

16. Precision Health Resource of Control iPSC Lines for Versatile Multilineage Differentiation

Author

Jaap Mulder, Stephen W. Scherer, Rebecca S.F. Mok, Naeimeh Tayebi, Deivid C. Rodrigues, Sazia Sharmin, Guoliang Meng, Michele K. Anderson, James Ellis, Seema Mital, Peter Pasceri, Juan Carlos Zúñiga-Pflücker, Jennifer L. Howe, Wei Wei, Norman D. Rosenblum, Caroline Kinnear, Jiajie Liu, Binita M. Kamath, Asli Romm, Matthew Rozycki, Michael J. Szego, Lee Stephen Lesperance, Miriam S. Reuter, Patrick M. Brauer, Matthew R. Hildebrandt, Alina Piekna, Elisa C. Martinez, and Steven A. Prescott

Subjects

Resource, 0301 basic medicine, cellular phenotyping, T-Lymphocytes, Induced Pluripotent Stem Cells, Cell Separation, Disease, Computational biology, Biology, Biochemistry, Frameshift mutation, 03 medical and health sciences, control iPSCs, 0302 clinical medicine, Genome editing, Ectoderm, disease modeling, Genetics, Humans, Cell Lineage, Myocytes, Cardiac, Cell Self Renewal, Induced pluripotent stem cell, lcsh:QH301-705.5, Gene Editing, Neurons, Whole genome sequencing, lcsh:R5-920, Whole Genome Sequencing, Cell Differentiation, Cell Biology, Health resource, Cortical neurons, Phenotype, 3. Good health, Organoids, 030104 developmental biology, lcsh:Biology (General), whole-genome sequencing, Personal Genome Project Canada, CRISPR-Cas Systems, lcsh:Medicine (General), 030217 neurology & neurosurgery, Developmental Biology

Abstract

Summary Induced pluripotent stem cells (iPSC) derived from healthy individuals are important controls for disease-modeling studies. Here we apply precision health to create a high-quality resource of control iPSCs. Footprint-free lines were reprogrammed from four volunteers of the Personal Genome Project Canada (PGPC). Multilineage-directed differentiation efficiently produced functional cortical neurons, cardiomyocytes and hepatocytes. Pilot users demonstrated versatility by generating kidney organoids, T lymphocytes, and sensory neurons. A frameshift knockout was introduced into MYBPC3 and these cardiomyocytes exhibited the expected hypertrophic phenotype. Whole-genome sequencing-based annotation of PGPC lines revealed on average 20 coding variants. Importantly, nearly all annotated PGPC and HipSci lines harbored at least one pre-existing or acquired variant with cardiac, neurological, or other disease associations. Overall, PGPC lines were efficiently differentiated by multiple users into cells from six tissues for disease modeling, and variant-preferred healthy control lines were identified for specific disease settings., Graphical Abstract, Highlights • Precision health resource of high-quality control iPSC lines for disease modeling • Versatile differentiation into six functional cell types shown by resource users • CRISPR gene editing reveals expected phenotype of cardiomyopathy model • Variant annotation identified preferred lines for neurologic and cardiac disease, Ellis, Scherer, and colleagues apply precision health to upgrade iPSC quality for disease modeling. The resource provides control lines from four healthy individuals, clinical annotation of whole-genome variants, and identification of variant-preferred lines for neurologic and cardiac disease. Resource users demonstrated versatile differentiation into functional cells from six tissues, and CRISPR-edited cells phenocopied a cardiomyopathy model.

Published

2019

17. Spike initiation properties in the axon support high-fidelity signal transmission

Author

Mohammad Amin Kamaleddin, Nooshin Abdollahi, Stéphanie Ratté, and Steven A Prescott

Subjects

nervous system

Abstract

The axon initial segment (AIS) converts graded depolarization into all-or-none spikes that are transmitted by the axon to downstream neurons. Analog-to-digital transduction and digital signal transmission call for distinct spike initiation properties (filters) and those filters should, therefore, differ between the AIS and distal axon. Here we show that unlike the AIS, which spikes repetitively during sustained depolarization, the axon spikes transiently and only if depolarization reaches threshold before KV1 channels activate. Rate of depolarization is critical. This was shown by optogenetically evoking spikes in the distal axon of CA1 pyramidal neurons using different photostimulus waveforms and pharmacological conditions while recording antidromically propagated spikes at the soma, thus circumventing the prohibitive difficulty of patching intact axons. Computational modeling shows that KV1 channels in the axon implement a high-pass filter that is matched to the axial current waveform associated with spike propagation, thus maximizing the signal-to-noise ratio to ensure high-fidelity transmission of spike-based signals.

Published

2021

18. Hippocampal bursts caused by changes in NMDA receptor-dependent excitation in a mouse model of variant CJD

Author

Stéphanie Ratté, Steven A. Prescott, John Collinge, and John G.R. Jefferys

Subjects

Prion, Variant CJD, Burst, Hippocampus, Electrophysiology, NMDA, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Prion diseases are heterogeneous in clinical presentation, suggesting that different prion diseases have distinct pathophysiological changes. To understand the pathophysiology specific to variant Creutzfeldt–Jakob Disease (vCJD), in vitro electrophysiological studies were performed in a mouse model in which human-derived vCJD prions were transmitted to transgenic mice expressing human instead of murine prion protein. Paired-pulse stimulation of the Schaffer collaterals evoked hypersynchronous bursting in the hippocampus of vCJD-inoculated mice; comparable bursts were never observed in control or Prnp knockout mice, or in mice inoculated with a strain of prion associated with classical CJD. Furthermore, NMDA receptor-mediated excitation was increased in vCJD-inoculated mice. Using pharmacological experiments and computer simulations, we demonstrate that the increase in NMDA receptor-mediated excitation is necessary and sufficient to explain the distinctive bursting pattern in vCJD. These pathophysiological changes appear to result from a prion strain-specific gain-of-function and may explain some of the distinguishing clinical features of vCJD.

Published

2008

19. Subthreshold membrane currents confer distinct tuning properties that enable neurons to encode the integral or derivative of their input

Author

Stephanie eRatté, Milad eLankarany, Young-Ah eRho, Adam ePatterson, and Steven A Prescott

Subjects

coincidence detector, Neural coding, Spike, action potential, integrator, Differentiator, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Neurons rely on action potentials, or spikes, to encode information. But spikes can encode different stimulus features in different neurons. We show here through simulations and experiments how neurons encode the integral or derivative of their input based on the distinct tuning properties conferred upon them by subthreshold currents. Slow-activating subthreshold inward (depolarizing) current mediates positive feedback control of subthreshold voltage, sustaining depolarization and allowing the neuron to spike on the basis of its integrated stimulus waveform. Slow-activating subthreshold outward (hyperpolarizing) current mediates negative feedback control of subthreshold voltage, truncating depolarization and forcing the neuron to spike on the basis of its differentiated stimulus waveform. Depending on its direction, slow-activating subthreshold current cooperates or competes with fast-activating inward current during spike initiation. This explanation predicts that sensitivity to the rate of change of stimulus intensity differs qualitatively between integrators and differentiators. This was confirmed experimentally in spinal sensory neurons that naturally behave as specialized integrators or differentiators. Predicted sensitivity to different stimulus features was confirmed by covariance analysis. Integration and differentiation, which are themselves inverse operations, are thus shown to be implemented by the slow feedback mediated by oppositely directed subthreshold currents expressed in different neurons.

Published

2015

20. Criticality and degeneracy in injury-induced changes in primary afferent excitability and the implications for neuropathic pain

Author

Stéphanie Ratté, Yi Zhu, Kwan Yeop Lee, and Steven A Prescott

Subjects

neuropathic pain, degeneracy, excitability, membrane potential oscillation, dynamic clamp, bursting, Medicine, Science, Biology (General), QH301-705.5

Abstract

Neuropathic pain remains notoriously difficult to treat despite numerous drug targets. Here, we offer a novel explanation for this intractability. Computer simulations predicted that qualitative changes in primary afferent excitability linked to neuropathic pain arise through a switch in spike initiation dynamics when molecular pathologies reach a tipping point (criticality), and that this tipping point can be reached via several different molecular pathologies (degeneracy). We experimentally tested these predictions by pharmacologically blocking native conductances and/or electrophysiologically inserting virtual conductances. Multiple different manipulations successfully reproduced or reversed neuropathic changes in primary afferents from naïve or nerve-injured rats, respectively, thus confirming the predicted criticality and its degenerate basis. Degeneracy means that several different molecular pathologies are individually sufficient to cause hyperexcitability, and because several such pathologies co-occur after nerve injury, that no single pathology is uniquely necessary. Consequently, single-target-drugs can be circumvented by maladaptive plasticity in any one of several ion channels.

Published

2014

21. Identification of molecular pathologies sufficient to cause neuropathic excitability in primary somatosensory afferents using dynamical systems theory.

Author

Young-Ah Rho and Steven A Prescott

Subjects

Biology (General), QH301-705.5

Abstract

Pain caused by nerve injury (i.e. neuropathic pain) is associated with development of neuronal hyperexcitability at several points along the pain pathway. Within primary afferents, numerous injury-induced changes have been identified but it remains unclear which molecular changes are necessary and sufficient to explain cellular hyperexcitability. To investigate this, we built computational models that reproduce the switch from a normal spiking pattern characterized by a single spike at the onset of depolarization to a neuropathic one characterized by repetitive spiking throughout depolarization. Parameter changes that were sufficient to switch the spiking pattern also enabled membrane potential oscillations and bursting, suggesting that all three pathological changes are mechanistically linked. Dynamical analysis confirmed this prediction by showing that excitability changes co-develop when the nonlinear mechanism responsible for spike initiation switches from a quasi-separatrix-crossing to a subcritical Hopf bifurcation. This switch stems from biophysical changes that bias competition between oppositely directed fast- and slow-activating conductances operating at subthreshold potentials. Competition between activation and inactivation of a single conductance can be similarly biased with equivalent consequences for excitability. "Bias" can arise from a multitude of molecular changes occurring alone or in combination; in the latter case, changes can add or offset one another. Thus, our results identify pathological change in the nonlinear interaction between processes affecting spike initiation as the critical determinant of how simple injury-induced changes at the molecular level manifest complex excitability changes at the cellular level. We demonstrate that multiple distinct molecular changes are sufficient to produce neuropathic changes in excitability; however, given that nerve injury elicits numerous molecular changes that may be individually sufficient to alter spike initiation, our results argue that no single molecular change is necessary to produce neuropathic excitability. This deeper understanding of degenerate causal relationships has important implications for how we understand and treat neuropathic pain.

Published

2012

22. Lionfish venom elicits pain predominantly through the activation of nonpeptidergic nociceptors

Author

Steven A. Prescott, Reza Sharif-Naeini, Stephanie Mouchbahani-Constance, Albena Davidova, Hugues Petitjean, L. Stephen Lesperance, and Amanda MacPherson

Subjects

0301 basic medicine, Time Factors, Poison control, Venom, Pharmacology, Mice, 0302 clinical medicine, Fish Venoms, Ganglia, Spinal, Medicine, Pain Measurement, Neurogenic inflammation, Microglia, Microfilament Proteins, medicine.anatomical_structure, Neurology, Hyperalgesia, Nociceptor, Neurogenic Inflammation, medicine.symptom, Sensory Receptor Cells, Green Fluorescent Proteins, Pain, TRPV Cation Channels, Mice, Transgenic, Inflammation, 03 medical and health sciences, Calcium imaging, Animals, Humans, Envenomation, Acrylamides, Analysis of Variance, Dose-Response Relationship, Drug, business.industry, Calcium-Binding Proteins, Bridged Bicyclo Compounds, Heterocyclic, Mice, Inbred C57BL, Disease Models, Animal, Luminescent Proteins, HEK293 Cells, Oncogene Proteins v-fos, 030104 developmental biology, Anesthesiology and Pain Medicine, Gene Expression Regulation, Touch, Exploratory Behavior, Calcium, Neurology (clinical), Capsaicin, business, 030217 neurology & neurosurgery

Abstract

The lionfish (Pterois volitans) is a venomous invasive species found in the Caribbean and Northwestern Atlantic. It poses a growing health problem because of the increase in frequency of painful stings, for which no treatment or antidote exists, and the long-term disability caused by the pain. Understanding the venom's algogenic properties can help identify better treatment for these envenomations. In this study, we provide the first characterization of the pain and inflammation caused by lionfish venom and examine the mechanisms through which it causes pain using a combination of in vivo and in vitro approaches including behavioral, physiological, calcium imaging, and electrophysiological testing. Intraplantar injections of the venom produce a significant increase in pain behavior, as well as a marked increase in mechanical sensitivity for up to 24 hours after injection. The algogenic substance(s) are heat-labile peptides that cause neurogenic inflammation at the site of injection and induction of Fos and microglia activation in the superficial layers of the dorsal horn. Finally, calcium imaging and electrophysiology experiments show that the venom acts predominantly on nonpeptidergic, TRPV1-negative, nociceptors, a subset of neurons implicated in sensing mechanical pain. These data provide the first characterization of the pain and inflammation caused by lionfish venom, as well as the first insight into its possible cellular mechanism of action.

Published

2018

23. Using dynamic clamp to quantify pathological changes in the excitability of primary somatosensory neurons

Author

Petri Takkala and Steven A. Prescott

Subjects

0301 basic medicine, Physiology, Chemistry, Conductance, Depolarization, Stimulation, Hyperpolarization (biology), Somatosensory system, 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, medicine.anatomical_structure, Clamp, Dorsal root ganglion, medicine, Neuroscience, 030217 neurology & neurosurgery, Ion channel

Abstract

KEY POINTS Primary somatosensory neurons normally respond to somatic depolarization with transient spiking but can switch to repetitive spiking under pathological conditions. This switch in spiking pattern reflects a qualitative change in spike initiation dynamics and contributes to the hyperexcitability associated with chronic pain. Neurons can be converted to repetitive spiking by adding a virtual conductance using dynamic clamp. By titrating the conductance to determine how much must be added to cause repetitive spiking, we found that small cells are more susceptible to switching (i.e. required less added conductance) than medium-large cells. By measuring how much less conductance is required to cause repetitive spiking when dynamic clamp was combined with other pathomimetic manipulations (e.g. application of inflammatory mediators), we measured how much each manipulation facilitated repetitive spiking. Our results suggest that many pathological factors facilitate repetitive spiking but that the switch to repetitive spiking requires the cumulative effect of many co-occurring factors. ABSTRACT Primary somatosensory neurons become hyperexcitable in many chronic pain conditions. Hyperexcitability can include a switch from transient to repetitive spiking during sustained somatic depolarization. This switch results from diverse pathological processes that impact ion channel expression or function. Because multiple pathological processes co-occur, isolating how much each contributes to switching the spiking pattern is difficult. Our approach to this challenge involves adding a virtual sodium conductance via dynamic clamp. The magnitude of that conductance was titrated to determine the minimum required to enable rheobasic stimulation to evoke repetitive spiking. The minimum required conductance, termed g¯ Na ∗, was re-measured before and during manipulations designed to model various pathological processes in vitro. The reduction in g¯ Na ∗ caused by each pathomimetic manipulation reflects how much the modelled process contributes to switching the spiking pattern. We found that elevating extracellular potassium or applying inflammatory mediators reduced g¯ Na ∗ whereas direct hyperpolarization had no effect. Inflammatory mediators reduced g¯ Na ∗ more in medium-large (>30 μm diameter) neurons than in small (⩽30 μm diameter) neurons, but had equivalent effects in cutaneous and muscle afferents. The repetitive spiking induced by dynamic clamp was also found to differ between small and medium-large neurons, thus revealing latent differences in adaptation. Our study demonstrates a novel way to determine to what extent individual pathological factors facilitate repetitive spiking. Our results suggest that most factors facilitate but do not cause repetitive spiking on their own, and, therefore, that a switch to repetitive spiking results from the cumulative effect of many co-occurring factors.

Published

2018

24. Sensory Afferents Use Different Coding Strategies for Heat and Cold

Author

Sylvain L. Côté, Erik Bélanger, Feng Wang, Yves De Koninck, Daniel Côté, Steven A. Prescott, and Patrick Desrosiers

Subjects

Male, 0301 basic medicine, Hot Temperature, Sensory Receptor Cells, Population, Biology, Somatosensory system, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, 0302 clinical medicine, Thermal stimulation, Dorsal root ganglion, Ganglia, Spinal, Afferent, medicine, Animals, Neurons, Afferent, education, education.field_of_study, Cold Temperature, Mice, Inbred C57BL, 030104 developmental biology, medicine.anatomical_structure, nervous system, Sensory afferents, Thermoception, Calcium, Female, Neuroscience, 030217 neurology & neurosurgery, Coding (social sciences)

Abstract

Primary afferents transduce environmental stimuli into electrical activity that is transmitted centrally to be decoded into corresponding sensations. However, it remains unknown how afferent populations encode different somatosensory inputs. To address this, we performed two-photon Ca2+ imaging from thousands of dorsal root ganglion (DRG) neurons in anesthetized mice while applying mechanical and thermal stimuli to hind paws. We found that approximately half of all neurons are polymodal and that heat and cold are encoded very differently. As temperature increases, more heating-sensitive neurons are activated, and most individual neurons respond more strongly, consistent with graded coding at population and single-neuron levels, respectively. In contrast, most cooling-sensitive neurons respond in an ungraded fashion, inconsistent with graded coding and suggesting combinatorial coding, based on which neurons are co-activated. Although individual neurons may respond to multiple stimuli, our results show that different stimuli activate distinct combinations of diversely tuned neurons, enabling rich population-level coding.

Published

2018

25. Artifactual hyperpolarization during extracellular electrical stimulation: Proposed mechanism of high-rate neuromodulation disproved

Author

Milad Lankarany, Rosana Esteller, Tianhe Zhang, Stéphanie Ratté, Steven A. Prescott, and L. Stephen Lesperance

Subjects

Patch-Clamp Techniques, 0206 medical engineering, Biophysics, Stimulation, 02 engineering and technology, Hippocampal formation, Hippocampus, lcsh:RC321-571, 03 medical and health sciences, 0302 clinical medicine, Current clamp, medicine, Animals, Patch clamp, lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, Cells, Cultured, Neurons, Excitability, Neuromodulation, Chemistry, General Neuroscience, Depolarization, Hyperpolarization (biology), Spinal cord, 020601 biomedical engineering, Electric Stimulation, Voltage-Sensitive Dye Imaging, Rats, Hyperpolarization, medicine.anatomical_structure, Rheobase, Spinal cord stimulation, Spinal Cord, Neurology (clinical), Artifacts, Neuroscience, 030217 neurology & neurosurgery

Abstract

Background Kilohertz-frequency electric field stimulation (kEFS) applied to the spinal cord can reduce chronic pain without causing the buzzing sensation (paresthesia) associated with activation of dorsal column fibers. This suggests that high-rate spinal cord stimulation (SCS) has a mode of action distinct from conventional, parasthesia-based SCS. A recent study reported that kEFS hyperpolarizes spinal neurons, yet this potentially transformative mode of action contradicts previous evidence that kEFS induces depolarization and was based on patch clamp recordings whose accuracy in the presence of kEFS has not been verified. Objectives We sought to elucidate the basis for kEFS-induced hyperpolarization and to validate the effects of kEFS observed in patch clamp recordings by comparing with independent optical methods. Methods Using patch clamp electrophysiology and voltage-sensitive dye (VSD) imaging, we measured the response to kEFS applied in vitro to hippocampal and spinal neurons. Results The kEFS-induced hyperpolarization observed with current clamp recordings was corroborated by VSD imaging and rheobase measurements in patched neurons. However, no hyperpolarization was observed when imaging unpatched neurons or when recording with a voltage-follower amplifier rather than with a patch clamp amplifier (PCA). We found that EFS induced an artifactual current in PCAs that was injected back into current clamped neurons. The artifactual current induced by single, charge-balanced EFS pulses caused modest hyperpolarization, but these unitary hyperpolarizations accumulated when EFS pulses were repeated at kilohertz frequencies. Conclusion Our results rule out hyperpolarization as the mechanism underlying kEFS-mediated analgesia and highlight the risk of recording artifacts caused by extracellular electrical stimulation.

Published

2018

26. Origin of heterogeneous spiking patterns from continuously distributed ion channel densities: a computational study in spinal dorsal horn neurons

Author

Arjun Balachandar and Steven A. Prescott

Subjects

0301 basic medicine, Dorsum, education.field_of_study, Quantitative Biology::Neurons and Cognition, Physiology, Chemistry, Population, Parameter space, Potassium channel, Tonic (physiology), 03 medical and health sciences, 030104 developmental biology, 0302 clinical medicine, medicine.anatomical_structure, medicine, Neuron, Biological system, education, 030217 neurology & neurosurgery, Bifurcation, Ion channel

Abstract

Key points Distinct spiking patterns may arise from qualitative differences in ion channel expression (i.e. when different neurons express distinct ion channels) and/or when quantitative differences in expression levels qualitatively alter the spike generation process. We hypothesized that spiking patterns in neurons of the superficial dorsal horn (SDH) of spinal cord reflect both mechanisms. We reproduced SDH neuron spiking patterns by varying densities of KV 1- and A-type potassium conductances. Plotting the spiking patterns that emerge from different density combinations revealed spiking-pattern regions separated by boundaries (bifurcations). This map suggests that certain spiking pattern combinations occur when the distribution of potassium channel densities straddle boundaries, whereas other spiking patterns reflect distinct patterns of ion channel expression. The former mechanism may explain why certain spiking patterns co-occur in genetically identified neuron types. We also present algorithms to predict spiking pattern proportions from ion channel density distributions, and vice versa. Abstract Neurons are often classified by spiking pattern. Yet, some neurons exhibit distinct patterns under subtly different test conditions, which suggests that they operate near an abrupt transition, or bifurcation. A set of such neurons may exhibit heterogeneous spiking patterns not because of qualitative differences in which ion channels they express, but rather because quantitative differences in expression levels cause neurons to operate on opposite sides of a bifurcation. Neurons in the spinal dorsal horn, for example, respond to somatic current injection with patterns that include tonic, single, gap, delayed and reluctant spiking. It is unclear whether these patterns reflect five cell populations (defined by distinct ion channel expression patterns), heterogeneity within a single population, or some combination thereof. We reproduced all five spiking patterns in a computational model by varying the densities of a low-threshold (KV 1-type) potassium conductance and an inactivating (A-type) potassium conductance and found that single, gap, delayed and reluctant spiking arise when the joint probability distribution of those channel densities spans two intersecting bifurcations that divide the parameter space into quadrants, each associated with a different spiking pattern. Tonic spiking likely arises from a separate distribution of potassium channel densities. These results argue in favour of two cell populations, one characterized by tonic spiking and the other by heterogeneous spiking patterns. We present algorithms to predict spiking pattern proportions based on ion channel density distributions and, conversely, to estimate ion channel density distributions based on spiking pattern proportions. The implications for classifying cells based on spiking pattern are discussed.

Published

2018

27. Efficacy of synaptic inhibition depends on multiple, dynamically interacting mechanisms implicated in chloride homeostasis.

Author

Nicolas Doyon, Steven A Prescott, Annie Castonguay, Antoine G Godin, Helmut Kröger, and Yves De Koninck

Subjects

Biology (General), QH301-705.5

Abstract

Chloride homeostasis is a critical determinant of the strength and robustness of inhibition mediated by GABA(A) receptors (GABA(A)Rs). The impact of changes in steady state Cl(-) gradient is relatively straightforward to understand, but how dynamic interplay between Cl(-) influx, diffusion, extrusion and interaction with other ion species affects synaptic signaling remains uncertain. Here we used electrodiffusion modeling to investigate the nonlinear interactions between these processes. Results demonstrate that diffusion is crucial for redistributing intracellular Cl(-) load on a fast time scale, whereas Cl(-)extrusion controls steady state levels. Interaction between diffusion and extrusion can result in a somato-dendritic Cl(-) gradient even when KCC2 is distributed uniformly across the cell. Reducing KCC2 activity led to decreased efficacy of GABA(A)R-mediated inhibition, but increasing GABA(A)R input failed to fully compensate for this form of disinhibition because of activity-dependent accumulation of Cl(-). Furthermore, if spiking persisted despite the presence of GABA(A)R input, Cl(-) accumulation became accelerated because of the large Cl(-) driving force that occurs during spikes. The resulting positive feedback loop caused catastrophic failure of inhibition. Simulations also revealed other feedback loops, such as competition between Cl(-) and pH regulation. Several model predictions were tested and confirmed by [Cl(-)](i) imaging experiments. Our study has thus uncovered how Cl(-) regulation depends on a multiplicity of dynamically interacting mechanisms. Furthermore, the model revealed that enhancing KCC2 activity beyond normal levels did not negatively impact firing frequency or cause overt extracellular K(-) accumulation, demonstrating that enhancing KCC2 activity is a valid strategy for therapeutic intervention.

Published

2011

28. Biophysical basis for three distinct dynamical mechanisms of action potential initiation.

Author

Steven A Prescott, Yves De Koninck, and Terrence J Sejnowski

Subjects

Biology (General), QH301-705.5

Abstract

Transduction of graded synaptic input into trains of all-or-none action potentials (spikes) is a crucial step in neural coding. Hodgkin identified three classes of neurons with qualitatively different analog-to-digital transduction properties. Despite widespread use of this classification scheme, a generalizable explanation of its biophysical basis has not been described. We recorded from spinal sensory neurons representing each class and reproduced their transduction properties in a minimal model. With phase plane and bifurcation analysis, each class of excitability was shown to derive from distinct spike initiating dynamics. Excitability could be converted between all three classes by varying single parameters; moreover, several parameters, when varied one at a time, had functionally equivalent effects on excitability. From this, we conclude that the spike-initiating dynamics associated with each of Hodgkin's classes represent different outcomes in a nonlinear competition between oppositely directed, kinetically mismatched currents. Class 1 excitability occurs through a saddle node on invariant circle bifurcation when net current at perithreshold potentials is inward (depolarizing) at steady state. Class 2 excitability occurs through a Hopf bifurcation when, despite net current being outward (hyperpolarizing) at steady state, spike initiation occurs because inward current activates faster than outward current. Class 3 excitability occurs through a quasi-separatrix crossing when fast-activating inward current overpowers slow-activating outward current during a stimulus transient, although slow-activating outward current dominates during constant stimulation. Experiments confirmed that different classes of spinal lamina I neurons express the subthreshold currents predicted by our simulations and, further, that those currents are necessary for the excitability in each cell class. Thus, our results demonstrate that all three classes of excitability arise from a continuum in the direction and magnitude of subthreshold currents. Through detailed analysis of the spike-initiating process, we have explained a fundamental link between biophysical properties and qualitative differences in how neurons encode sensory input.

Published

2008

29. Author response: Excitatory neurons are more disinhibited than inhibitory neurons by chloride dysregulation in the spinal dorsal horn

Author

Kwan Yeop Lee, Steven A. Prescott, and Stéphanie Ratté

Subjects

Dorsum, Chemistry, French horn, medicine, Excitatory postsynaptic potential, Inhibitory postsynaptic potential, Chloride, Neuroscience, medicine.drug

Published

2019

30. Excitatory neurons are more disinhibited than inhibitory neurons by chloride dysregulation in the spinal dorsal horn

Author

Steven A. Prescott, Stéphanie Ratté, and Kwan Yeop Lee

Subjects

0301 basic medicine, Male, KCC2, spatial summation, Somatosensory system, Chloride, Rats, Sprague-Dawley, 0302 clinical medicine, Nervous System Physiological Phenomena, Biology (General), Neurons, 0303 health sciences, Symporters, Chemistry, General Neuroscience, General Medicine, medicine.anatomical_structure, Allodynia, Hyperalgesia, Models, Animal, Neuropathic pain, Excitatory postsynaptic potential, Medicine, Female, medicine.symptom, Research Article, medicine.drug, Spinal Cord Dorsal Horn, Cell type, QH301-705.5, Science, disinhibition, Summation, Inhibitory postsynaptic potential, Models, Biological, General Biochemistry, Genetics and Molecular Biology, 03 medical and health sciences, Chlorides, medicine, Animals, allodynia, 030304 developmental biology, neuropathic pain, General Immunology and Microbiology, spinal cord, Spinal cord, Rats, 030104 developmental biology, Disinhibition, Receptive field, Rat, Neuralgia, Neuroscience, 030217 neurology & neurosurgery

Abstract

Neuropathic pain is a debilitating condition caused by the abnormal processing of somatosensory input. Synaptic inhibition in the spinal dorsal horn plays a key role in that processing. Mechanical allodynia – the misperception of light touch as painful – occurs when inhibition is compromised. Disinhibition is due primarily to chloride dysregulation caused by hypofunction of the potassium-chloride co-transporter KCC2. Here we show, in rats, that excitatory neurons are disproportionately affected. This is not because chloride is differentially dysregulated in excitatory and inhibitory neurons, but, rather, because excitatory neurons rely more heavily on inhibition to counterbalance strong excitation. Receptive fields in both cell types have a center-surround organization but disinhibition unmasks more excitatory input to excitatory neurons. Differences in intrinsic excitability also affect how chloride dysregulation affects spiking. These results deepen understanding of how excitation and inhibition are normally balanced in the spinal dorsal horn, and how their imbalance disrupts somatosensory processing.

Published

2019

31. Control iPSC lines with clinically annotated genetic variants for versatile multi-lineage differentiation

Author

Patrick M. Brauer, Jaap Mulder, Juan Carlos Zúñiga-Pflücker, Jennifer L. Howe, Rebecca S.F. Mok, Peter Pasceri, Matthew R. Hildebrandt, Caroline Kinnear, Naeimeh Tayebi, Stephen W. Scherer, Matthew Rozycki, Michael J. Szego, Deivid C. Rodrigues, Asli Romm, Michele K. Anderson, Lee Stephen Lesperance, Guoliang Meng, Alina Piekna, James Ellis, Steven A. Prescott, Jiajie Liu, Elisa C. Martinez, Binita M. Kamath, Seema Mital, Sazia Sharmin, Wei Wei, Miriam S. Reuter, and Norman D. Rosenblum

Subjects

Whole genome sequencing, 0303 health sciences, Cell type, Lineage differentiation, Disease, Computational biology, Biology, Phenotype, Frameshift mutation, 03 medical and health sciences, 0302 clinical medicine, Directed differentiation, Induced pluripotent stem cell, 030217 neurology & neurosurgery, 030304 developmental biology

Abstract

SummaryInduced Pluripotent Stem Cells (iPSC) derived from healthy individuals are important controls for disease modeling studies. To create a resource of genetically annotated iPSCs, we reprogrammed footprint-free lines from four volunteers in the Personal Genome Project Canada (PGPC). Multilineage directed differentiation efficiently produced functional cortical neurons, cardiomyocytes and hepatocytes. Pilot users further demonstrated line versatility by generating kidney organoids, T-lymphocytes and sensory neurons. A frameshift knockout was introduced into MYBPC3 and these cardiomyocytes exhibited the expected hypertrophic phenotype. Whole genome sequencing (WGS) based annotation of PGPC lines revealed on average 20 coding variants. Importantly, nearly all annotated PGPC and HipSci lines harboured at least one pre-existing or acquired variant with cardiac, neurological or other disease associations. Overall, PGPC lines were efficiently differentiated by multiple users into cell types found in six tissues for disease modeling, and clinical annotation highlighted variant-preferred lines for use as unaffected controls in specific disease settings.

Published

2019

32. Differentially synchronized spiking enables multiplexed neural coding

Author

Milad Lankarany, Steven A. Prescott, Stéphanie Ratté, and Dhekra Al-Basha

Subjects

Computer science, neural coding, Stimulus (physiology), ENCODE, Somatosensory system, Multiplexing, 03 medical and health sciences, Mice, 0302 clinical medicine, Animals, rate code, 030304 developmental biology, Neurons, 0303 health sciences, Multidisciplinary, Sensory stimulation therapy, multiplexing, temporal code, business.industry, synchrony, Pattern recognition, Somatosensory Cortex, Biological Sciences, Asynchronous communication, Artificial intelligence, business, Neural coding, 030217 neurology & neurosurgery, Decoding methods, Neuroscience

Abstract

Significance The nervous system processes phenomenal amounts of information. This processing must be conducted efficiently. In telecommunications systems, efficiency is increased by transmitting multiple signals through a single communication channel, or multiplexing. Neurons also multiplex. Here, we demonstrate a strategy for multiplexing different features of aperiodic stimuli: Cortical neurons use the rate of asynchronous spiking to encode stimulus intensity while using the timing of synchronous spikes to encode abrupt changes in stimulus intensity. This is possible because high-contrast features (e.g., edges) evoke spikes that transiently synchronize across neurons, whereas low-contrast features evoke sustained asynchronous spiking whose rate is proportional to stimulus intensity. Differentially synchronized spiking evoked in the same neurons by different stimulus features enables the formation of multiplexed representations., Multiplexing refers to the simultaneous encoding of two or more signals. Neurons have been shown to multiplex, but different stimuli require different multiplexing strategies. Whereas the frequency and amplitude of periodic stimuli can be encoded by the timing and rate of the same spikes, natural scenes, which comprise areas over which intensity varies gradually and sparse edges where intensity changes abruptly, require a different multiplexing strategy. Recording in vivo from neurons in primary somatosensory cortex during tactile stimulation, we found that stimulus onset and offset (edges) evoked highly synchronized spiking, whereas other spikes in the same neurons occurred asynchronously. Stimulus intensity modulated the rate of asynchronous spiking, but did not affect the timing of synchronous spikes. From this, we hypothesized that spikes driven by high- and low-contrast stimulus features can be distinguished on the basis of their synchronization, and that differentially synchronized spiking can thus be used to form multiplexed representations. Applying a Bayesian decoding method, we verified that information about high- and low-contrast features can be recovered from an ensemble of model neurons receiving common input. Equally good decoding was achieved by distinguishing synchronous from asynchronous spikes and applying reverse correlation methods separately to each spike type. This result, which we verified with patch clamp recordings in vitro, demonstrates that neurons receiving common input can use the rate of asynchronous spiking to encode the intensity of low-contrast features while using the timing of synchronous spikes to encode the occurrence of high-contrast features. We refer to this strategy as synchrony-division multiplexing.

Published

2019

33. Electrophysiology equipment for reliable study of kHz electrical stimulation

Author

Marom Bikson, Steven A. Prescott, Mohamad FallahRad, Niranjan Khadka, Rosana Esteller, Tianhe Zhang, Stéphanie Ratté, Bradley Lawrence Hershey, and Adantchede L. Zannou

Subjects

0301 basic medicine, High rate, Materials science, Physiology, Pulse (signal processing), Stimulation, Neurophysiology, Neuromodulation (medicine), Electric Stimulation, Electrophysiological Phenomena, 03 medical and health sciences, Microelectrode, Electrophysiology, 030104 developmental biology, 0302 clinical medicine, Brain stimulation, otorhinolaryngologic diseases, sense organs, Topical Review, Microelectrodes, 030217 neurology & neurosurgery, Biomedical engineering

Abstract

Characterizing the cellular targets of kHz (1–10 kHz) electrical stimulation remains a pressing topic in neuromodulation because expanding interest in clinical application of kHz stimulation has surpassed mechanistic understanding. The presumed cellular targets of brain stimulation do not respond to kHz frequencies according to conventional electrophysiology theory. Specifically, the low‐pass characteristics of cell membranes are predicted to render kHz stimulation inert, especially given the use of limited‐duty‐cycle biphasic pulses. Precisely because kHz frequencies are considered supra‐physiological, conventional instruments designed for neurophysiological studies such as stimulators, amplifiers and recording microelectrodes do not operate reliably at these high rates. Moreover, for pulsed waveforms, the signal frequency content is well above the pulse repetition rate. Thus, the very tools used to characterize the effects of kHz electrical stimulation may themselves be confounding factors. We illustrate custom equipment design that supports reliable electrophysiological recording during kHz‐rate stimulation. Given the increased importance of kHz stimulation in clinical domains and compelling possibilities that mechanisms of actions may reflect yet undiscovered neurophysiological phenomena, attention to suitable performance of electrophysiological equipment is pivotal. [Image: see text]

Published

2019

34. Chloride Regulation: A Dynamic Equilibrium Crucial for Synaptic Inhibition

Author

Steven A. Prescott, Laurent Vinay, Yves De Koninck, and Nicolas Doyon

Subjects

0301 basic medicine, chloride, Neuroscience(all), Presynaptic inhibition, Neural Inhibition, equilibrium potential, Models, Biological, K+ Cl− cotransporter 2, 03 medical and health sciences, 0302 clinical medicine, Chlorides, medicine, Animals, Homeostasis, Humans, Dynamic equilibrium, General Commentary, Chemistry, General Neuroscience, Cl− channel, synaptic inhibition, 030104 developmental biology, Nonlinear Dynamics, Disinhibition, Cl− concentration, Synapses, membrane potential, medicine.symptom, Neuroscience, 030217 neurology & neurosurgery, Intracellular, conductance

Abstract

Fast synaptic inhibition relies on tight regulation of intracellular Cl(-). Chloride dysregulation is implicated in several neurological and psychiatric disorders. Beyond mere disinhibition, the consequences of Cl(-) dysregulation are multifaceted and best understood in terms of a dynamical system involving complex interactions between multiple processes operating on many spatiotemporal scales. This dynamical perspective helps explain many unintuitive manifestations of Cl(-) dysregulation. Here we discuss how taking into account dynamical regulation of intracellular Cl(-) is important for understanding how synaptic inhibition fails, how to best detect that failure, why Cl(-) regulation is energetically so expensive, and the overall consequences for therapeutics.

Published

2016

35. Chloride dysregulation and inhibitory receptor blockade yield equivalent disinhibition of spinal neurons yet are differentially reversed by carbonic anhydrase blockade

Author

Kwan Yeop Lee and Steven A. Prescott

Subjects

Male, medicine.medical_specialty, Pharmacology, Inhibitory postsynaptic potential, Rats, Sprague-Dawley, Receptors, Glycine, Chlorides, Neurotrophic factors, Physical Stimulation, Internal medicine, medicine, Animals, Nervous System Physiological Phenomena, GABA-A Receptor Antagonists, Carbonic Anhydrase Inhibitors, Glycine receptor, Symporters, biology, GABAA receptor, Chemistry, Brain-Derived Neurotrophic Factor, Neural Inhibition, Rats, Blockade, Acetazolamide, Posterior Horn Cells, Anesthesiology and Pain Medicine, Endocrinology, Allodynia, Neurology, Hyperalgesia, Disinhibition, biology.protein, Neurology (clinical), medicine.symptom, Neurotrophin

Abstract

Synaptic inhibition plays a key role in processing somatosensory information. Blocking inhibition at the spinal level is sufficient to produce mechanical allodynia, and many neuropathic pain conditions are associated with reduced inhibition. Disinhibition of spinal neurons can arise through decreased GABAA/glycine receptor activation or through dysregulation of intracellular chloride. We hypothesized that these distinct disinhibitory mechanisms, despite all causing allodynia, are differentially susceptible to therapeutic intervention. Specifically, we predicted that reducing bicarbonate efflux by blocking carbonic anhydrase with acetazolamide (ACTZ) would counteract disinhibition caused by chloride dysregulation without affecting normal inhibition or disinhibition caused by GABAA/glycine receptor blockade. To test this, responses to innocuous tactile stimulation were recorded in vivo from rat superficial dorsal horn neurons before and after different forms of pharmacological disinhibition and again after application of ACTZ. Blocking GABAA or glycine receptors caused hyperresponsiveness equivalent to that caused by blocking the potassium chloride cotransporter KCC2, but, consistent with our predictions, only disinhibition caused by KCC2 blockade was counteracted by ACTZ. ACTZ did not alter responses of neurons with intact inhibition. As pathological downregulation of KCC2 is triggered by brain-derived neurotrophic factor, we also confirmed that ACTZ was effective against brain-derived neurotrophic factor-induced hyperresponsiveness. Our results argue that intrathecal ACTZ has antiallodynic effects only if allodynia arises through chloride dysregulation; therefore, behavioral evidence that ACTZ is antiallodynic in nerve-injured animals affirms the contribution of chloride dysregulation as a key pathological mechanism. Although different disinhibitory mechanisms are not mutually exclusive, these results demonstrate that their relative contribution dictates which specific therapies will be effective.

Published

2015

36. Microglial pannexin-1 channel activation is a spinal determinant of joint pain

Author

Allison Reid, Steven A. Prescott, Melissa S. O’Brien, John R. Matyas, Kwan Yeop Lee, Natalya Patrick, Patrick L. Stemkowski, Heather Leduc-Pessah, Jeff Biernaskie, Boriss Sagalajev, Nicole E. Burma, Paul T. Salo, Tuan Trang, Jo Anne Stratton, Jason J. McDougall, Gerald W. Zamponi, Michael Mousseau, and Charlie H.T. Kwok

Subjects

Male, 0301 basic medicine, Neurophysiology, Arthritis, Nerve Tissue Proteins, Stimulation, Hindlimb, Osteoarthritis, Pharmacology, Connexins, Spinal Cord Diseases, Rats, Sprague-Dawley, Mice, 03 medical and health sciences, 0302 clinical medicine, Animals, Medicine, Research Articles, Mice, Knockout, Multidisciplinary, Microglia, business.industry, SciAdv r-articles, Pannexin, medicine.disease, Arthralgia, Arthritis, Experimental, Rats, 3. Good health, 030104 developmental biology, Nociception, medicine.anatomical_structure, Hyperalgesia, Joint pain, medicine.symptom, business, 030217 neurology & neurosurgery, Research Article, Neuroscience

Abstract

A new therapeutic option for treating arthritis pain., Chronic joint pain such as mechanical allodynia is the most debilitating symptom of arthritis, yet effective therapies are lacking. We identify the pannexin-1 (Panx1) channel as a therapeutic target for alleviating mechanical allodynia, a cardinal sign of arthritis. In rats, joint pain caused by intra-articular injection of monosodium iodoacetate (MIA) was associated with spinal adenosine 5′-triphosphate (ATP) release and a microglia-specific up-regulation of P2X7 receptors (P2X7Rs). Blockade of P2X7R or ablation of spinal microglia prevented and reversed mechanical allodynia. P2X7Rs drive Panx1 channel activation, and in rats with mechanical allodynia, Panx1 function was increased in spinal microglia. Specifically, microglial Panx1-mediated release of the proinflammatory cytokine interleukin-1β (IL-1β) induced mechanical allodynia in the MIA-injected hindlimb. Intrathecal administration of the Panx1-blocking peptide 10panx suppressed the aberrant discharge of spinal laminae I-II neurons evoked by innocuous mechanical hindpaw stimulation in arthritic rats. Furthermore, mice with a microglia-specific genetic deletion of Panx1 were protected from developing mechanical allodynia. Treatment with probenecid, a clinically used broad-spectrum Panx1 blocker, resulted in a striking attenuation of MIA-induced mechanical allodynia and normalized responses in the dynamic weight-bearing test, without affecting acute nociception. Probenecid reversal of mechanical allodynia was also observed in rats 13 weeks after anterior cruciate ligament transection, a model of posttraumatic osteoarthritis. Thus, Panx1-targeted therapy is a new mechanistic approach for alleviating joint pain.

Published

2018

37. Chloride Dysregulation through Downregulation of KCC2 Mediates Neuropathic Pain in Both Sexes

Author

Milind M. Muley, Michael W. Salter, Kwan Yeop Lee, Steven A. Prescott, Cédric Gauthier, Louis-Etienne Lorenzo, Yves De Koninck, and Josiane C.S. Mapplebeck

Subjects

0301 basic medicine, Male, Presynaptic inhibition, Down-Regulation, General Biochemistry, Genetics and Molecular Biology, Rats, Sprague-Dawley, 03 medical and health sciences, Mice, 0302 clinical medicine, Downregulation and upregulation, Chlorides, medicine, Animals, Carbonic Anhydrase Inhibitors, lcsh:QH301-705.5, Sex Characteristics, Symporters, business.industry, Brain-Derived Neurotrophic Factor, Rats, Sexual dimorphism, Acetazolamide, Mice, Inbred C57BL, Posterior Horn Cells, Electrophysiology, Thiazoles, 030104 developmental biology, lcsh:Biology (General), Spinal Cord, Disinhibition, Hyperalgesia, Thioglycolates, Neuropathic pain, Neural processing, Neuralgia, Female, medicine.symptom, business, Neuroscience, 030217 neurology & neurosurgery, Intracellular

Abstract

Summary: The behavioral features of neuropathic pain are not sexually dimorphic despite sex differences in the underlying neuroimmune signaling. This raises questions about whether neural processing is comparably altered. Here, we test whether the K+-Cl− co-transporter KCC2, which regulates synaptic inhibition, plays an equally important role in development of neuropathic pain in male and female rodents. Past studies on KCC2 tested only males. We find that inhibiting KCC2 in uninjured animals reproduces behavioral and electrophysiological features of neuropathic pain in both sexes and, consistent with equivalent injury-induced downregulation of KCC2, that counteracting chloride dysregulation reverses injury-induced behavioral and electrophysiological changes in both sexes. These findings demonstrate that KCC2 downregulation contributes equally to pain hypersensitivity in males and females. Whereas diverse (and sexually dimorphic) mechanisms regulate KCC2, regulation of intracellular chloride relies almost exclusively on KCC2. Directly targeting KCC2 thus remains a promising strategy for treatment of neuropathic pain in both sexes. : Neuropathic pain arises in males and females through distinct neuroimmune signaling. Yet the behavioral (or clinical) features of neuropathic pain are not sexually dimorphic. Mapplebeck et al. demonstrate that KCC2—though regulated in multiple, sex-specific ways—is uniquely responsible for the synaptic disinhibition causing neuropathic pain in both sexes. Keywords: K+-Cl− co-transporter KCC2, sex differences, degeneracy, neuropathic pain, disinhibition, GABA, glycine, BDNF

Published

2018

38. A mutation-independent approach for muscular dystrophy via upregulation of a modifier gene

Author

Dwi U, Kemaladewi, Prabhpreet S, Bassi, Steven, Erwood, Dhekra, Al-Basha, Kinga I, Gawlik, Kyle, Lindsay, Elzbieta, Hyatt, Rebekah, Kember, Kara M, Place, Ryan M, Marks, Madeleine, Durbeej, Steven A, Prescott, Evgueni A, Ivakine, and Ronald D, Cohn

Subjects

Gene Editing, Male, Genes, Modifier, Genetic Therapy, Fibrosis, Muscular Dystrophies, Up-Regulation, Mice, CRISPR-Associated Protein 9, Mutation, Disease Progression, Animals, Female, Laminin, CRISPR-Cas Systems, Muscle, Skeletal

Abstract

Neuromuscular disorders are often caused by heterogeneous mutations in large, structurally complex genes. Targeting compensatory modifier genes could be beneficial to improve disease phenotypes. Here we report a mutation-independent strategy to upregulate the expression of a disease-modifying gene associated with congenital muscular dystrophy type 1A (MDC1A) using the CRISPR activation system in mice. MDC1A is caused by mutations in LAMA2 that lead to nonfunctional laminin-α2, which compromises the stability of muscle fibres and the myelination of peripheral nerves. Transgenic overexpression of Lama1, which encodes a structurally similar protein called laminin-α1, ameliorates muscle wasting and paralysis in mouse models of MDC1A, demonstrating its importance as a compensatory modifier of the disease

Published

2018

39. Physiological Dynamics in Demyelinating Diseases: Unraveling Complex Relationships through Computer Modeling

Author

Steven A. Prescott, Stefan Bittner, Sven G. Meuth, Klaus M. Stiefel, and Jay S. Coggan

Subjects

Pathology, medicine.medical_specialty, Economic shortage, Review, multiple sclerosis, Models, Biological, Catalysis, drug discovery, Inorganic Chemistry, lcsh:Chemistry, 03 medical and health sciences, 0302 clinical medicine, neurodegenerative disease, Medicine, Humans, Computer Simulation, Physical and Theoretical Chemistry, Molecular Biology, lcsh:QH301-705.5, Spectroscopy, Myelin Sheath, 030304 developmental biology, Simple (philosophy), Cognitive science, 0303 health sciences, Reductionism, business.industry, Mechanism (biology), Organic Chemistry, Neurodegenerative Diseases, General Medicine, Axons, 3. Good health, Computer Science Applications, myelin, computational model, lcsh:Biology (General), lcsh:QD1-999, Myelin sheath, DECIPHER, demyelination, business, 030217 neurology & neurosurgery, Demyelinating Diseases

Abstract

Despite intense research, few treatments are available for most neurological disorders. Demyelinating diseases are no exception. This is perhaps not surprising considering the multifactorial nature of these diseases, which involve complex interactions between immune system cells, glia and neurons. In the case of multiple sclerosis, for example, there is no unanimity among researchers about the cause or even which system or cell type could be ground zero. This situation precludes the development and strategic application of mechanism-based therapies. We will discuss how computational modeling applied to questions at different biological levels can help link together disparate observations and decipher complex mechanisms whose solutions are not amenable to simple reductionism. By making testable predictions and revealing critical gaps in existing knowledge, such models can help direct research and will provide a rigorous framework in which to integrate new data as they are collected. Nowadays, there is no shortage of data; the challenge is to make sense of it all. In that respect, computational modeling is an invaluable tool that could, ultimately, transform how we understand, diagnose, and treat demyelinating diseases.

Published

2015

40. Novel method to assess axonal excitability using channelrhodopsin-based photoactivation

Author

Bin Feng, Yi Zhu, Gerald F. Gebhart, Erica S. Schwartz, and Steven A. Prescott

Subjects

Male, Light, Physiology, Photic Stimulation, Neural Conduction, Action Potentials, Channelrhodopsin, Mice, Inbred Strains, Optogenetics, Somatosensory system, Mice, Channelrhodopsins, Cellular and Molecular Properties of Neurons, medicine, Animals, Axon, Cells, Cultured, biology, Chemistry, General Neuroscience, Axons, Mice, Inbred C57BL, medicine.anatomical_structure, nervous system, Rhodopsin, biology.protein, Neuroscience, Intracellular

Abstract

Measuring the excitability of individual axons is complicated by the prohibitive difficulty in obtaining intracellular recordings. Here, we present an innovative methodology that enables local excitability to be measured anywhere in a channelrhodopsin (ChR2)-expressing neuron. The approach hinges on activating ChR2 in a spatially and temporally precise manner while recording the resulting spike train from a remote site. We validated this approach in primary afferent neurons (PANs). Initial encoding of somatosensory stimuli relies on transduction of the physical stimulus into a receptor potential and transformation of the receptor potential into a spike train; the transformation process depends on the excitability of the most distal PAN endings but, as explained above, is extraordinarily difficult to study in situ using traditional methods. Using ChR2-based photoactivation, we show 1) that excitability differs between the distal endings and more proximal portions of PAN axons, 2) that the transformation process differs between PANs, and 3) that the transformation process is directly affected by inflammation. Beyond presenting an innovative method by which to study axonal excitability, this study has validated its utility in helping to decipher the earliest stages of somatosensory encoding.

Published

2015

41. Origin of heterogeneous spiking patterns from continuously distributed ion channel densities: a computational study in spinal dorsal horn neurons

Author

Arjun, Balachandar and Steven A, Prescott

Subjects

Posterior Horn Cells, Potassium Channels, Models, Neurological, Action Potentials, Animals, Computational Biology, Computer Simulation, Ion Channels, Perspectives

Abstract

Distinct spiking patterns may arise from qualitative differences in ion channel expression (i.e. when different neurons express distinct ion channels) and/or when quantitative differences in expression levels qualitatively alter the spike generation process. We hypothesized that spiking patterns in neurons of the superficial dorsal horn (SDH) of spinal cord reflect both mechanisms. We reproduced SDH neuron spiking patterns by varying densities of KNeurons are often classified by spiking pattern. Yet, some neurons exhibit distinct patterns under subtly different test conditions, which suggests that they operate near an abrupt transition, or bifurcation. A set of such neurons may exhibit heterogeneous spiking patterns not because of qualitative differences in which ion channels they express, but rather because quantitative differences in expression levels cause neurons to operate on opposite sides of a bifurcation. Neurons in the spinal dorsal horn, for example, respond to somatic current injection with patterns that include tonic, single, gap, delayed and reluctant spiking. It is unclear whether these patterns reflect five cell populations (defined by distinct ion channel expression patterns), heterogeneity within a single population, or some combination thereof. We reproduced all five spiking patterns in a computational model by varying the densities of a low-threshold (K

Published

2017

42. Nonlinear Relationship Between Spike-Dependent Calcium Influx and TRPC Channel Activation Enables Robust Persistent Spiking in Neurons of the Anterior Cingulate Cortex

Author

Steven A. Prescott, Stéphanie Ratté, and Sergei Karnup

Subjects

0301 basic medicine, Male, Patch-Clamp Techniques, Feedback, Psychological, chemistry.chemical_element, Calcium, Gyrus Cinguli, Calcium in biology, Rats, Sprague-Dawley, 03 medical and health sciences, Transient receptor potential channel, 0302 clinical medicine, Calcium imaging, Transient Receptor Potential Channels, Animals, Computer Simulation, Calcium Signaling, TRPC, Research Articles, Neurons, Voltage-dependent calcium channel, General Neuroscience, Pyramidal Cells, Hyperpolarization (biology), Electrophysiological Phenomena, Rats, Electrophysiology, 030104 developmental biology, chemistry, Nonlinear Dynamics, Calcium Channels, Neuroscience, 030217 neurology & neurosurgery, Algorithms

Abstract

Continuation of spiking after a stimulus ends (i.e. persistent spiking) is thought to support working memory. Muscarinic receptor activation enables persistent spiking among synaptically isolated pyramidal neurons in anterior cingulate cortex (ACC), but a detailed characterization of that spiking is lacking and the underlying mechanisms remain unclear. Here, we show that the rate of persistent spiking in ACC neurons is insensitive to the intensity and number of triggers, but can be modulated by injected current, and that persistent spiking can resume after several seconds of hyperpolarization-imposed quiescence. Using electrophysiology and calcium imaging in brain slices from male rats, we determined that canonical transient receptor potential (TRPC) channels are necessary for persistent spiking and that TRPC-activating calcium enters in a spike-dependent manner via voltage-gated calcium channels. Constrained by these biophysical details, we built a computational model that reproduced the observed pattern of persistent spiking. Nonlinear dynamical analysis of that model revealed that TRPC channels become fully activated by the small rise in intracellular calcium caused by evoked spikes. Calcium continues to rise during persistent spiking, but because TRPC channel activation saturates, firing rate stabilizes. By calcium rising higher than required for maximal TRPC channel activation, TRPC channels are able to remain active during periods of hyperpolarization-imposed quiescence (until calcium drops below saturating levels) such that persistent spiking can resume when hyperpolarization is discontinued. Our results thus reveal that the robust intrinsic bistability exhibited by ACC neurons emerges from the nonlinear positive feedback relationship between spike-dependent calcium influx and TRPC channel activation.SIGNIFICANCE STATEMENTNeurons use action potentials, or spikes, to encode information. Some neurons can store information for short periods (seconds to minutes) by continuing to spike after a stimulus ends, thus enabling working memory. This so-called “persistent” spiking occurs in many brain areas and has been linked to activation of canonical transient receptor potential (TRPC) channels. However, TRPC activation alone is insufficient to explain many aspects of persistent spiking such as resumption of spiking after periods of imposed quiescence. Using experiments and simulations, we show that calcium influx caused by spiking is necessary and sufficient to activate TRPC channels and that the ensuing positive feedback interaction between intracellular calcium and TRPC channel activation can account for many hitherto unexplained aspects of persistent spiking.

Published

2017

43. Somatosensation and Pain

Author

Stéphanie Ratté and Steven A. Prescott

Subjects

medicine.medical_specialty, Proprioception, Chronic pain, Sensory system, Somatosensory system, medicine.disease, Nociception, Physical medicine and rehabilitation, Allodynia, Neuropathic pain, Hyperalgesia, medicine, medicine.symptom, Psychology

Abstract

The somatosensory system is responsible for processing proprioceptive, thermal, touch, and pain information from the body surface and internal tissues. The skin is in fact the largest sensory organ in the body. Braille readers demonstrate a capacity to use discriminative touch in ways most of us will never develop, yet all of us can appreciate different textures. Somatosensation provides sensory feedback which, although mostly subconscious, is crucial for many motor activities. Among somatic modalities, pain is notable for attracting our immediate attention. Normal pain caused by intense (noxious) stimuli alerts us to danger and thus serves an important adaptive role, and the heightened sensitivity associated with inflammatory pain facilitates our recovery from injury. But abnormal processing of somatosensory information can result in chronic neuropathic pain, a disease in its own right. This chapter addresses normal somatosensation and how its disruption can result in chronic pain.

Published

2017

44. Normal and abnormal coding of somatosensory stimuli causing pain

Author

Qiufu Ma, Yves De Koninck, and Steven A. Prescott

Subjects

General Neuroscience, Perception, media_common.quotation_subject, Diffuse noxious inhibitory control, Noxious stimulus, Nociceptor, Stimulus (physiology), Neural coding, Psychology, Somatosensory system, Neuroscience, Coactivation, media_common

Abstract

Noxious stimuli usually cause pain and pain usually arises from noxious stimuli, but exceptions to these apparent truisms are the basis for clinically important problems and provide valuable insight into the neural code for pain. In this Review, we discuss how painful sensations arise. We argue that, although primary somatosensory afferents are tuned to specific stimulus features, natural stimuli often activate more than one type of afferent. Manipulating coactivation patterns can alter perception in ways that argue against each type of afferent acting independently (as expected for strictly labeled lines), suggesting instead that signals conveyed by different types of afferents interact. Deciphering the central circuits that mediate those interactions is critical for explaining the generation and modulation of neural signals that ultimately elicit pain. The advent of genetic and optical dissection techniques promise to dramatically accelerate progress toward this goal, which will facilitate the rational design of future pain therapeutics.

Published

2014

45. Abstract #159: Hardware suitable for electrophysiology and stimulation in kHz range

Author

Bradley Lawrence Hershey, Steven A. Prescott, Stéphanie Ratté, Niranjan Khadka, Mohamad FallahRad, Tianhe Zhang, Marom Bikson, Rosana Esteller, and Louis Zannou

Subjects

Range (music), Electrophysiology, Materials science, General Neuroscience, Biophysics, Neurology (clinical), lcsh:Neurosciences. Biological psychiatry. Neuropsychiatry, lcsh:RC321-571, Biomedical engineering

Published

2019

46. Multi-Hazard Advanced Seismic Probabilistic Risk Assessment Tools and Applications

Author

Justin Coleman, Carlo Parisi, Abhinav Gupta, Steven R. Prescott, Chandu Bolisetti, and Swetha Veeraraghavan

Subjects

Probabilistic risk assessment, Risk analysis (engineering), Computer science, Multi hazard

Published

2016

47. Demonstration of External Hazards Analysis

Author

Carlo Parisi, Justin Coleman, Ronaldo Szilard, Abinav Gupta, Robert Spears, and Steven R. Prescott

Subjects

Computer science

Published

2016

48. Pain processing by spinal microcircuits: afferent combinatorics

Author

Steven A. Prescott and Stéphanie Ratté

Subjects

Neurons, Dorsum, Afferent Pathways, genetic structures, Nerve net, General Neuroscience, Action Potentials, Pain, Stimulus (physiology), Spinal cord, Somatosensory system, Article, Pain processing, medicine.anatomical_structure, Spinal Cord, Afferent, medicine, Animals, Humans, Nerve Net, Psychology, Neuroscience

Abstract

Pain, itch, heat, cold, and touch represent different percepts arising from somatosensory input. How stimuli give rise to these percepts has been debated for over a century. Recent work supports the view that primary afferents are highly specialized to transduce and encode specific stimulus modalities. However, cross-modal interactions (e.g. inhibition or exacerbation of pain by touch) support convergence rather than specificity in central circuits. We outline how peripheral specialization together with central convergence could enable spinal microcircuits to combine inputs from distinctly specialized, co-activated afferents and to modulate the output signals thus formed through computations like normalization. These issues will be discussed alongside recent advances in our understanding of microcircuitry in the superficial dorsal horn.

Published

2012

49. Multiplexed coding through synchronous and asynchronous spiking

Author

Steven A. Prescott and Milad Lankarany

Subjects

0303 health sciences, Artificial neural network, Computer science, business.industry, General Neuroscience, sync, Pattern recognition, ENCODE, computer.software_genre, Multiplexing, Spike-triggered average, 03 medical and health sciences, Cellular and Molecular Neuroscience, 0302 clinical medicine, Asynchronous communication, Poster Presentation, Data mining, Artificial intelligence, business, Neural coding, computer, 030217 neurology & neurosurgery, 030304 developmental biology, Coding (social sciences)

Abstract

The prodigious capacity of our brain to process information relies on efficient neural coding strategies. In engineered systems, bandwidth is often increased through multiplexing multiple signals are simultaneously, yet independently, transmitted through a single communication channel. We have proposed previously that neural systems might implement the same sort of solution [1]. Here, we tested if/how multiplexed coding could be achieved through combined rate and temporal coding. We hypothesized that a set of neurons could independently encode two signals by using asynchronous spike rate to encode one signal and synchronous spike timing to encode the other. To test our hypothesis, we built a feed-forward neural network comprising Morris-Lecar (ML) model neurons. All neurons received a common input constructed from two distinct signals, slow and fast, plus uncorrelated fast noise. According to our hypothesis, slow and fast signals are independently encoded by different types of spikes; in other words, differentially correlated output spikes, namely, asynchronous (Async) and synchronous (Sync), enable encoding of slow and fast signals, respectively. To assess the feasibility of the multiplexed coding scheme, recorded spikes were classified into two independent classes based on the peristimulus time histogram (PSTH) calculated from the entire set of neurons. Spikes whose instantaneous rates exceeded a threshold were designated “Sync” and all others were designated “Async”. The spike triggered average (STA) was calculated for slow and fast signals using Sync and Async spikes, resulting in four different STAs. The Async-slow and Sync-fast STAs were clearly structured whereas the other two were not (Figure 1A). Using

Published

2015

50. ClC-2 Channels Regulate Neuronal Excitability, Not Intracellular Chloride Levels

Author

Stéphanie Ratté and Steven A. Prescott

Subjects

Intracellular Fluid, Patch-Clamp Techniques, Models, Neurological, Neurotransmission, Inhibitory postsynaptic potential, Synaptic Transmission, Chloride, Biophysical Phenomena, Membrane Potentials, Chlorides, Chloride Channels, medicine, Animals, Computer Simulation, Receptor, gamma-Aminobutyric Acid, Neurons, Symporters, urogenital system, Chemistry, GABAA receptor, General Neuroscience, Articles, Hyperpolarization (biology), Receptors, GABA-A, Electric Stimulation, Rats, Biochemistry, Biophysics, Chloride channel, Intracellular, medicine.drug

Abstract

Synaptic inhibition by GABAAreceptors requires a transmembrane chloride gradient. Hyperpolarization or shunting results from outward current produced by chloride flowing down this gradient, into the cell. Chloride influx necessarily depletes the chloride gradient. Therefore, mechanisms that replenish the gradient (by reducing intracellular chloride concentration, [Cl−]i) are crucial for maintaining the efficacy of GABAAreceptor-mediated inhibition. ClC-2 is an inward-rectifying chloride channel that is thought to help extrude chloride because inward rectification should, in principle, allow ClC-2 to act as a one-way chloride exit valve. But chloride efflux via ClC-2 nevertheless requires an appropriate driving force. Using computer modeling, we reproduced voltage-clamp experiments showing chloride efflux via ClC-2, but testing the same model under physiological conditions revealed that ClC-2 normally leaks chloride into the cell. The discrepancy is explained by the driving force conditions that exist under artificial versus physiological conditions, and by the fact that ClC-2 rectification is neither complete nor instantaneous. Thus, contrary to previous assertions that ClC-2 helps maintain synaptic inhibition by lowering [Cl−]i, our simulations show that ClC-2 mediates chloride influx, thus producing outward current and directly reducing excitability. To test how ClC-2 functions in real neurons, we used dynamic clamp to insert virtual ClC-2 channels into rat CA1 pyramidal cells with and without native ClC-2 channels blocked. Experiments confirmed that ClC-2 reduces spiking independently of inhibitory synaptic transmission. Our results highlight the importance of considering driving force when inferring how a channel functions under physiological conditions.

Published

2011