Dendrites: Bug Or Feature? Michael Ha¨ Usser Y and Bartlett Mel Z
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Dendritic Spikes and Their Influence on Extracellular Calcium Signaling
Dendritic Spikes and Their Influence on Extracellular Calcium Signaling MICHAEL C. WIEST,1 DAVID M. EAGLEMAN,2 RICHARD D. KING,1 AND P. READ MONTAGUE1 1Division of Neuroscience, Center for Theoretical Neuroscience, Baylor College of Medicine, Houston, Texas 77030; and 2Sloan Center for Theoretical Neurobiology, The Salk Institute, La Jolla, California 92037 Wiest, Michael C., David M. Eagleman, Richard D. King, and P. trical or neurotransmitter stimulation (Benninger et al. 1980; Read Montague. Dendritic spikes and their influence on extracellular Heinemann et al. 1990; Lucke et al. 1995; Nicholson et al. calcium signaling. J. Neurophysiol. 83: 1329–1337, 2000. Extracel- 1978; Pumain and Heinemann 1985; Stanton and Heine- lular calcium is critical for many neural functions, including neuro- mann 1986) (see Fig. 1). Given that many important com- transmission, cell adhesion, and neural plasticity. Experiments have putational processes function on millisecond time scales and shown that normal neural activity is associated with changes in extracellular calcium, which has motivated recent computational work submicron spatial scales, we were led to ask how electrical that employs such fluctuations in an information-bearing role. This events at these smaller scales affect the external calcium possibility suggests that a new style of computing is taking place in level. the mammalian brain in addition to current ‘circuit’ models that use In the mammalian brain, action potentials can propagate into only neurons and connections. Previous computational models of the dendrites of cortical and hippocampal neurons (Stuart and rapid external calcium changes used only rough approximations of Sakmann 1994). These spikes cause large influxes of calcium calcium channel dynamics to compute the expected calcium decre- from the extracellular space (Helmchen et al. -
Dendritic Sodium Spikes Endow Neurons with Inverse Firing
bioRxiv preprint doi: https://doi.org/10.1101/137984; this version posted November 7, 2018. The copyright holder for this preprint (which was not certified by peer review) is the author/funder, who has granted bioRxiv a license to display the preprint in perpetuity. It is made available under aCC-BY 4.0 International license. Noname manuscript No. (will be inserted by the editor) Dendritic sodium spikes endow neurons with inverse firing rate response to correlated synaptic activity Tomasz G´orski 1,2,* · Romain Veltz 3 · Mathieu Galtier 1 · H´elissande Fragnaud 1 · Jennifer S. Goldman 1,2 · Bartosz Tele´nczuk 1,2 · Alain Destexhe 1,2 Received: date / Accepted: date Abstract Many neurons possess dendrites enriched with integration is played by dendritic spikes: regenerative sodium channels and are capable of generating action currents through Na+, Ca2+ or NMDAr channels. The potentials. However, the role of dendritic sodium spikes first evidence of dendritic spikes came from field record- remain unclear. Here, we study computational mod- ings [1{5], corroborated by the intracellular recordings els of neurons to investigate the functional effects of [6{8]. The repertoire of techniques was further enlarged dendritic spikes. In agreement with previous studies, by patch clamp [9{13] and optical methods. Calcium we found that point neurons or neurons with passive imaging allowed for the direct observation of calcium dendrites increase their somatic firing rate in response spikes [14{18], and glutamate uncaging and voltage sen- to the correlation of synaptic bombardment for a wide sitive dyes led to the discovery of NMDA spikes [19,20]. -
The Decade of the Dendritic NMDA Spike
View metadata, citation and similar papers at core.ac.uk brought to you by CORE provided by OpenCommons at University of Connecticut University of Connecticut OpenCommons@UConn UCHC Articles - Research University of Connecticut Health Center Research 11-1-2010 The ecD ade of the Dendritic NMDA Spike Srdjan D. Antic University of Connecticut School of Medicine and Dentistry Wen-Liang Zho University of Connecticut School of Medicine and Dentistry Anna R. Moore University of Connecticut School of Medicine and Dentistry Shaina M. Shor University of Connecticut School of Medicine and Dentistry Katerina D. Ikonomu University of Connecticut School of Medicine and Dentistry Follow this and additional works at: https://opencommons.uconn.edu/uchcres_articles Part of the Life Sciences Commons, and the Medicine and Health Sciences Commons Recommended Citation Antic, Srdjan D.; Zho, Wen-Liang; Moore, Anna R.; Shor, Shaina M.; and Ikonomu, Katerina D., "The eD cade of the Dendritic NMDA Spike" (2010). UCHC Articles - Research. 309. https://opencommons.uconn.edu/uchcres_articles/309 HHS Public Access Author manuscript Author ManuscriptAuthor Manuscript Author J Neurosci Manuscript Author Res. Author Manuscript Author manuscript; available in PMC 2017 October 16. Published in final edited form as: J Neurosci Res. 2010 November 01; 88(14): 2991–3001. doi:10.1002/jnr.22444. The Decade of the Dendritic NMDA Spike Srdjan D. Antic, Wen-Liang Zhou, Anna R. Moore, Shaina M. Short, and Katerina D. Ikonomu Department of Neuroscience, Univ. Connecticut Health Center, Farmington, CT 06030, USA Abstract In the field of cortical cellular physiology, much effort has been invested in understanding thick apical dendrites of pyramidal neurons and the regenerative sodium and calcium spikes that take place in the apical trunk. -
Channel Density Distributions Explain Spiking Variability in the Globus Pallidus: a Combined Physiology and Computer Simulation Database Approach
7476 • The Journal of Neuroscience, July 23, 2008 • 28(30):7476–7491 Cellular/Molecular Channel Density Distributions Explain Spiking Variability in the Globus Pallidus: A Combined Physiology and Computer Simulation Database Approach Cengiz Gu¨nay,* Jeremy R. Edgerton,* and Dieter Jaeger Department of Biology, Emory University, Atlanta, Georgia 30322 Globus pallidus (GP) neurons recorded in brain slices show significant variability in intrinsic electrophysiological properties. To inves- tigate how this variability arises, we manipulated the biophysical properties of GP neurons using computer simulations. Specifically, we created a GP neuron model database with 100,602 models that had varying densities of nine membrane conductances centered on a hand-tuned model that replicated typical physiological data. To test the hypothesis that the experimentally observed variability can be attributed to variations in conductance densities, we compared our model database results to a physiology database of 146 slice record- ings.Theelectrophysiologicalpropertiesofgeneratedmodelsandrecordingswereassessedwithidenticalcurrentinjectionprotocolsand analyzed with a uniform set of measures, allowing a systematic analysis of the effects of varying voltage-gated and calcium-gated conductance densities on the measured properties and a detailed comparison between models and recordings. Our results indicated that most of the experimental variability could be matched by varying conductance densities, which we confirmed with additional partial block experiments. Further analysis resulted in two key observations: (1) each voltage-gated conductance had effects on multiple mea- sures such as action potential waveform and spontaneous or stimulated spike rates; and (2) the effect of each conductance was highly dependent on the background context of other conductances present. In some cases, such interactions could reverse the effect of the density of one conductance on important excitability measures. -
Dendritic Spikes Enhance Stimulus Selectivity in Cortical Neurons in Vivo
LETTER doi:10.1038/nature12600 Dendritic spikes enhance stimulus selectivity in cortical neurons in vivo Spencer L. Smith1,2, Ikuko T. Smith1,2, Tiago Branco1,3 & Michael Ha¨usser1 Neuronal dendrites are electrically excitable: they can generate orientation-tuned, high-frequency bursts of Na1 spikes riding on a regenerative events such as dendritic spikes in response to suffi- depolarization envelope, a finding that is consistent with the activation ciently strong synaptic input1–3. Although such events have been of voltage-gated Ca21 channels and synaptic NMDA receptor currents observed in many neuronal types4–9, it is not well understood how (Fig. 1d–g and Extended Data Fig. 1d). The properties of these spikes active dendrites contribute to the tuning of neuronal output in vivo. were in contrast to those of isolated spikes (single spikes separated Here we show that dendritic spikes increase the selectivity of neur- by at least 50 ms from other spikes), which are presumed to be back- onal responses to the orientation of a visual stimulus (orientation propagating action potentials (bAPs; Fig. 1d, e), although not all bAPs tuning). We performed direct patch-clamp recordings from the den- are isolated bAPs. The isolated bAPs exhibited a uniform amplitude drites of pyramidal neurons in the primary visual cortex of lightly and shape within a recording, and they decreased in amplitude and anaesthetized and awake mice, during sensory processing. Visual increased in width with increasing distance from the soma15 (Extended stimulation triggered regenerative local dendritic spikes that were Data Fig. 1e, f). In contrast to dendritic bursts, which can contain both distinct from back-propagating action potentials. -
Dendritic Spikes in Apical Dendrites of Neocortical Layer 2/3 Pyramidal Neurons
The Journal of Neuroscience, August 22, 2007 • 27(34):8999–9008 • 8999 Cellular/Molecular Dendritic Spikes in Apical Dendrites of Neocortical Layer 2/3 Pyramidal Neurons Matthew Evan Larkum, Jack Waters, Bert Sakmann, and Fritjof Helmchen Abteilung Zellphysiologie, Max-Planck-Institut fu¨r Medizinische Forschung, D-69120 Heidelberg, Germany Layer 2/3 (L2/3) pyramidal neurons are the most abundant cells of the neocortex. Despite their key position in the cortical microcircuit, synaptic integration in dendrites of L2/3 neurons is far less understood than in L5 pyramidal cell dendrites, mainly because of the difficulties in obtaining electrical recordings from thin dendrites. Here we directly measured passive and active properties of the apical dendrites of L2/3 neurons in rat brain slices using dual dendritic–somatic patch-clamp recordings and calcium imaging. Unlike L5 cells, L2/3dendritesdisplayedlittlesaginresponsetolongcurrentpulses,whichsuggestsalowdensityofIh inthedendritesandsoma.Thiswas also consistent with a slight increase in input resistance with distance from the soma. Brief current injections into the apical dendrite evoked relatively short (half-width 2–4 ms) dendritic spikes that were isolated from the soma for near-threshold currents at sites beyond the middle of the apical dendrite. Regenerative dendritic potentials and large concomitant calcium transients were also elicited by trains of somatic action potentials (APs) above a critical frequency (130 Hz), which was slightly higher than in L5 neurons. Initiation of dendritic spikes was facilitated by backpropagating somatic APs and could cause an additional AP at the soma. As in L5 neurons, we found that distal dendritic calcium transients are sensitive to a long-lasting block by GABAergic inhibition. -
Activity-Dependent Control of Neuronal Output by Local and Global Dendritic Spike Attenuation
Neuron Article Activity-Dependent Control of Neuronal Output by Local and Global Dendritic Spike Attenuation Stefan Remy,1,* Jozsef Csicsvari,2 and Heinz Beck1 1Laboratory for Cognition Research and Experimental Epileptology, Department of Epileptology, University of Bonn, Sigmund-Freud-Strasse 25, D-53105 Bonn, Germany 2MRC Anatomical Neuropharmacology Unit, Department of Pharmacology, University of Oxford, Mansfield Road, Oxford OX1 3TH, UK *Correspondence: [email protected] DOI 10.1016/j.neuron.2009.01.032 SUMMARY tion of NMDA receptors, voltage-gated Ca2+ channels and A-type K+ currents (Ariav et al., 2003; Losonczy and Magee, 2006; Neurons possess elaborate dendritic arbors which Schiller et al., 2000). If they are sufficiently large, dendritic spikes receive and integrate excitatory synaptic signals. Indi- can trigger a temporally precise action potential output (Ariav vidual dendritic subbranches exhibit local membrane et al., 2003). Individual dendritic branches differ in their propen- potential supralinearities, termed dendritic spikes, sity to generate prominent dendritic spikes and therefore vary which control transfer of local synaptic input to the in their capability to trigger axonal action potential output soma. Here, we show that dendritic spikes in CA1 (Losonczy et al., 2008). These differential properties appear to be a consequence of branch-specific local plasticity involving pyramidal cells are strongly regulated by specific voltage-gated ion channels (Losonczy et al., 2008). These find- types of prior input. While input in the linear range is ings highlight the role of dendritic branches as independent without effect, supralinear input inhibits subsequent processing units (Cai et al., 2004; Losonczy et al., 2008; Losonczy spikes, causing them to attenuate and ultimately fail and Magee, 2006) previously proposed in modeling studies + due to dendritic Na channel inactivation. -
Plasticity of Voltage-Gated Ion Channels in Pyramidal Cell Dendrites S Remy1,2, H Beck1 and Y Yaari3,4
Available online at www.sciencedirect.com Plasticity of voltage-gated ion channels in pyramidal cell dendrites S Remy1,2, H Beck1 and Y Yaari3,4 Dendrites of pyramidal neurons integrate multiple synaptic particularly interesting compartments where local inputs and transform them into axonal action potential output. changes in intrinsic excitability can occur. Indeed, in This fundamental process is controlled by a variety of dendritic some paradigms, intrinsic neuronal and synaptic plasticity channels. The properties of dendritic ion channels are not static can be induced simultaneously in the same compartment but can be modified by neuronal activity. Activity-dependent [3,4]. changes in the density, localization, or biophysical properties of dendritic voltage-gated channels can persistently alter the Pyramidal neurons integrate synaptic inputs that are integration of synaptic inputs. Furthermore, dendritic intrinsic widely distributed across the extent of the dendritic plasticity can induce neuronal output mode transitions (e.g. arborization. The magnitude of the local voltage deflec- from regular spiking to burst firing). Recent advances in the field tion at the dendrite, and how it propagates to the action reviewed here represent an important step toward uncovering potential initiation zone at the axon initial segment and the principles of neuronal input/output transformations in the first node of Ranvier [5,6], is strongly determined by response to various patterns of brain activity. both the passive properties of the dendritic tree and the Addresses active dendritic conductances [7]. The pattern of axonal 1 Department of Epileptology, University of Bonn Medical Center, output also depends on the properties of local axonal D-53105 Bonn, Germany conductances that transduce the dendritic signals into 2 German Center for Neurodegenerative Diseases (DZNE), D-53127, axonal spiking. -
Cooperative LTP Can Map Memory Sequences on Dendritic Branches
Update TRENDS in Neurosciences Vol.27 No.2 February 2004 69 27 Guidetti, P. et al. (2001) Early degenerative changes in transgenic mice 31 Kisselev, A.F. and Goldberg, A.L. (2001) Proteasome inhibitors: from expressing mutant huntingtin involve dendritic abnormalities but no research tools to drug candidates. Chem. Biol. 8, 739–758 impairment of mitochondrial energy production. Exp. Neurol. 169, 32 Lindsten, K. et al. (2002) Mutant ubiquitin found in neurodegenerative 340–350 disorders is a ubiquitin fusion degradation substrate that blocks 28 Hansson, O. et al. (1999) Transgenic mice expressing a Huntington’s proteasomal degradation. J. Cell Biol. 157, 417–427 disease mutation are resistant to quinolinic acid-induced striatal 33 Johnson, E.S. et al. (1995) A proteolytic pathway that excitotoxicity. Proc. Natl. Acad. Sci. U. S. A. 96, 8727–8732 recognizes ubiquitin as a degradation signal. J. Biol. Chem. 270, 29 Wong, P.C. et al. (2002) Genetically engineered mouse models of 17442–17456 neurodegenerative diseases. Nat. Neurosci. 5, 633–639 30 Rubinsztein, D.C. (2002) Lessons from animal models of Huntington’s 0166-2236/$ - see front matter q 2003 Elsevier Ltd. All rights reserved. disease. Trends Genet. 18, 202–209 doi:10.1016/j.tins.2003.12.002 Cooperative LTP can map memory sequences on dendritic branches Mayank R. Mehta Department of Neuroscience, Brown University, Providence, RI 02912, USA Hebbian synaptic learning requires co-activation of backpropagating action potential (BAP) simultaneously presynaptic and postsynaptic neurons. However, under propagates into the dendrites [4,5]. When the BAP some conditions, information regarding the postsyn- coincides with an EPSP, they summate non-linearly to aptic action potential, carried by backpropagating generate a large Ca2þ influx and hence LTP [6]. -
Mechanisms of Excitability in the Central and Peripheral Nervous Systems
Mechanisms of excitability in the central and peripheral nervous systems Implications for epilepsy and chronic pain JENNY TIGERHOLM Akademisk avhandling som med tillstånd av Kungliga Tekniska högskolan framlägges till offentlig granskning för avläggande av teknologie doktorsexamen i datalogi tisdag den 8 Maj 2012 klockan 10.00 i F3, Lindstedtsvägen 26, Kungliga Tekniska högskolan, Stockholm. ISRN KTH/CSC/A–12/01-SE TRITA-CSC-A 2012:02 ISSN-1653-5723 ISBN 978-91-7501-307-7 © Jenny Tigerholm, Maj 2012 iii Abstract The work in this thesis concerns mechanisms of excitability of neurons. Specif- ically, it deals with how neurons respond to input, and how their response is controlled by ion channels and other active components of the neuron. I have studied excitability in two systems of the nervous system, the hippocampus which is responsible for memory and spatial navigation, and the peripheral C–fiber which is responsible for sensing and conducting sensory information to the spinal cord. Within the work, I have studied the role of excitability mechanisms in normal function and in pathological conditions. For hippocampus the normal function includes changes in excitability linked to learning and memory. However, it also is intimately linked to pathological increases in excitability observed in epilepsy. In C–fibers, excitability controls sensitivity to responses to stimuli. When this response becomes enhanced, this can lead to pain. I have used computational modelling as a tool for studying hyperexcitability in neurons in the central nervous system in order to address mechanisms of epileptogenesis. Epilepsy is a brain disorder in which a subject has repeated seizures (convulsions) over time. -
Dendritic Spikes Mediate Negative Synaptic Gain Control in Cerebellar Purkinje Cells
Dendritic spikes mediate negative synaptic gain control in cerebellar Purkinje cells Ede A. Rancza,b,1 and Michael Häussera aWolfson Institute for Biomedical Research and Research Department of Neuroscience, Physiology and Pharmacology, University College London, London WC1E 6BT, United Kingdom; and bDivision of Neurophysiology, Medical Research Council National Institute for Medical Research, London NW7 1AA, United Kingdom Edited* by Rodolfo R. Llinás, New York University Medical Center, New York, NY, and approved November 8, 2010 (received for review June 28, 2010) Dendritic spikes appear to be a ubiquitous feature of dendritic dendritic spikes and axonal AP output in Purkinje cells by using excitability. In cortical pyramidal neurons, dendritic spikes increase simultaneous dendritic and somatic whole-cell recordings. Our the efficacy of distal synapses, providing additional inward current results show that a dendritic spike transiently increases synaptic to enhance axonal action potential (AP) output, thus increasing efficacy by promoting short bursts of somatic APs but dampen AP synaptic gain. In cerebellar Purkinje cells, dendritic spikes can trigger output over longer timescales. The interplay between these two synaptic plasticity, but their influence on axonal output is not well effects during sustained parallel fiber input results in a “clamping” understood. We have used simultaneous somatic and dendritic of Purkinje cells output over long timescales and, thus, a flattening patch-clamp recordings to directly assess the impact of dendritic of synaptic gain, in striking contrast to pyramidal cells (9). calcium spikes on axonal AP output of Purkinje cells. Dendritic spikes evoked by parallel fiber input triggered brief bursts of somatic APs, Results followed by pauses in spiking, which cancelled out the extra spikes in Single Dendritic Spikes Differentially Affect Axonal Output on the burst. -
Distinctive Properties and Powerful Neuromodulation of Nav1.6 Sodium Channels Regulates Neuronal Excitability
cells Review Distinctive Properties and Powerful Neuromodulation of Nav1.6 Sodium Channels Regulates Neuronal Excitability Agnes Zybura 1,2, Andy Hudmon 3 and Theodore R. Cummins 1,2,* 1 Program in Medical Neuroscience, Paul and Carole Stark Neurosciences Research Institute, Indiana University School of Medicine, Indianapolis, IN 46202, USA; [email protected] 2 Biology Department, School of Science, Indiana University-Purdue University Indianapolis, Indianapolis, IN 46202, USA 3 Department of Medicinal Chemistry and Molecular Pharmacology, College of Pharmacy, Purdue University, West Lafayette, IN 47907, USA; [email protected] * Correspondence: [email protected] Abstract: Voltage-gated sodium channels (Navs) are critical determinants of cellular excitability. These ion channels exist as large heteromultimeric structures and their activity is tightly controlled. In neurons, the isoform Nav1.6 is highly enriched at the axon initial segment and nodes, making it critical for the initiation and propagation of neuronal impulses. Changes in Nav1.6 expression and function profoundly impact the input-output properties of neurons in normal and pathological conditions. While mutations in Nav1.6 may cause channel dysfunction, aberrant changes may also be the result of complex modes of regulation, including various protein-protein interactions and post-translational modifications, which can alter membrane excitability and neuronal firing properties. Despite decades of research, the complexities of Nav1.6 modulation in health and disease are still being determined. While some modulatory mechanisms have similar effects on other Nav Citation: Zybura, A.; Hudmon, A.; isoforms, others are isoform-specific. Additionally, considerable progress has been made toward Cummins, T.R. Distinctive Properties and Powerful Neuromodulation of understanding how individual protein interactions and/or modifications affect Nav1.6 function.