Primary paranode demyelination modulates slowly developing axonal depolarization in a model of axonal injury

Neurological sequelae of mild traumatic brain injury are associated with the damage to white matter myelinated axons. In vitro models of axonal injury suggest that the progression to pathological ruin is initiated by the mechanical damage to tetrodotoxin-sensitive voltage-gated sodium channels that breaches the ion balance through alteration in kinetic properties of these channels. In myelinated axons, sodium channels are concentrated at nodes of Ranvier, making these sites vulnerable to mechanical injury. Nodal damage can also be inflicted by injury-induced partial demyelination of paranode/juxtaparanode compartments that flank the nodes and contain high density of voltage-gated potassium channels. Demyelination-induced potassium deregulation can further aggravate axonal damage; however, the role of paranode/juxtaparanode demyelination in immediate impairment of axonal function, and its contribution to the development of axonal depolarization remain elusive. A biophysically realistic computational model of myelinated axon that incorporates ion exchange mechanisms and nodal/paranodal/juxtaparanodal organization was developed and used to study the impact of injury-induced demyelination on axonal signal transmission. Injured axons showed alterations in signal propagation that were consistent with the experimental findings and with the notion of reduced axonal excitability immediately post trauma. Injury-induced demyelination strongly modulated the rate of axonal depolarization, suggesting that trauma-induced damage to paranode myelin can affect axonal transition to degradation. Results of these studies clarify the contribution of paranode demyelination to immediate post trauma alterations in axonal function and suggest that partial paranode demyelination should be considered as another “injury parameter” that is likely to determine the stability of axonal function.

[1]  S. Waxman,et al.  Immunolocalization of the Na+–Ca2+ exchanger in mammalian myelinated axons , 1997, Brain Research.

[2]  R. Neumar,et al.  Calpain Mediates Proteolysis of the Voltage-Gated Sodium Channel α-Subunit , 2009, The Journal of Neuroscience.

[3]  Riyi Shi,et al.  Conduction deficits and membrane disruption of spinal cord axons as a function of magnitude and rate of strain. , 2006, Journal of neurophysiology.

[4]  R. Kikinis,et al.  A review of magnetic resonance imaging and diffusion tensor imaging findings in mild traumatic brain injury , 2012, Brain Imaging and Behavior.

[5]  J. Wolf,et al.  Traumatic Axonal Injury Induces Calcium Influx Modulated by Tetrodotoxin-Sensitive Sodium Channels , 2001, The Journal of Neuroscience.

[6]  J. S. Coggan,et al.  Imbalance of ionic conductances contributes to diverse symptoms of demyelination , 2010, Proceedings of the National Academy of Sciences.

[7]  J. Vickers,et al.  Initial calcium release from intracellular stores followed by calcium dysregulation is linked to secondary axotomy following transient axonal stretch injury , 2010, Journal of neurochemistry.

[8]  Nicholas T. Carnevale,et al.  The NEURON Simulation Environment , 1997, Neural Computation.

[9]  R. Shi,et al.  Pathological changes of isolated spinal cord axons in response to mechanical stretch , 2002, Neuroscience.

[10]  Stephen W Marshall,et al.  Cumulative effects associated with recurrent concussion in collegiate football players: the NCAA Concussion Study. , 2003, JAMA.

[11]  J. Kamholz,et al.  CNS Myelin Paranodes Require Nkx6-2 Homeoprotein Transcriptional Activity for Normal Structure , 2004, The Journal of Neuroscience.

[12]  M. Bazhenov,et al.  Ionic Dynamics Mediate Spontaneous Termination of Seizures and Postictal Depression State , 2011, The Journal of Neuroscience.

[13]  C. McIntyre,et al.  Modeling the excitability of mammalian nerve fibers: influence of afterpotentials on the recovery cycle. , 2002, Journal of neurophysiology.

[14]  P. Jung,et al.  Simulation analysis of intermodal sodium channel function. , 2008, Physical review. E, Statistical, nonlinear, and soft matter physics.

[15]  P. Stys,et al.  Na+-Dependent Sources of Intra-Axonal Ca2+ Release in Rat Optic Nerve during In Vitro Chemical Ischemia , 2005, The Journal of Neuroscience.

[16]  P. Läuger,et al.  Electrogenic ion pumps , 1991 .

[17]  J W Moore,et al.  Simulations of conduction in uniform myelinated fibers. Relative sensitivity to changes in nodal and internodal parameters. , 1978, Biophysical journal.

[18]  A J McLean,et al.  Staining of amyloid precursor protein to study axonal damage in mild head injury. , 1994, Lancet.

[19]  G. Somjen,et al.  Simulated seizures and spreading depression in a neuron model incorporating interstitial space and ion concentrations. , 2000, Journal of neurophysiology.

[20]  W. Poon,et al.  The pathological spectrum of diffuse axonal injury in blunt head trauma: assessment with axon and myelin stains , 1994, Clinical Neurology and Neurosurgery.

[21]  D. I. Stephanova,et al.  Different effects of blocked potassium channels on action potentials, accommodation, adaptation and anode break excitation in human motor and sensory myelinated nerve fibres: computer simulations , 2000, Biological Cybernetics.

[22]  P. Stys,et al.  Na+‐Ca2+ Exchange in Anoxic/Ischemic Injury of CNS Myelinated Axons , 1996, Annals of the New York Academy of Sciences.

[23]  R. Nashmi,et al.  Mechanisms of axonal dysfunction after spinal cord injury: with an emphasis on the role of voltage-gated potassium channels , 2001, Brain Research Reviews.

[24]  O. Moran,et al.  Loosening of paranodal myelin by repetitive propagation of action potentials , 1983, Nature.

[25]  Elior Peles,et al.  The local differentiation of myelinated axons at nodes of Ranvier , 2003, Nature Reviews Neuroscience.

[26]  Pierre-Alexandre Boucher,et al.  Erratum to: Coupled left-shift of Nav channels: modeling the Na+-loading and dysfunctional excitability of damaged axons , 2012, Journal of Computational Neuroscience.

[27]  Agatha D. Lee,et al.  Acute and chronic changes in diffusivity measures after sports concussion. , 2011, Journal of neurotrauma.

[28]  Jason P. Mihalik,et al.  The Relationship Between Subconcussive Impacts and Concussion History on Clinical Measures of Neurologic Function in Collegiate Football Players , 2011, Annals of Biomedical Engineering.

[29]  Erin D Bigler,et al.  Neuropsychological results and neuropathological findings at autopsy in a case of mild traumatic brain injury , 2004, Journal of the International Neuropsychological Society.

[30]  Colin L. Stewart,et al.  Juxtaparanodal clustering of Shaker-like K+ channels in myelinated axons depends on Caspr2 and TAG-1 , 2003, The Journal of cell biology.

[31]  Hans Lassmann,et al.  Cortical demyelination and diffuse white matter injury in multiple sclerosis. , 2005, Brain : a journal of neurology.

[32]  D D Blatter,et al.  Nonspecific white matter degeneration following traumatic brain injury , 1995, Journal of the International Neuropsychological Society.

[33]  Pierre-Alexandre Boucher,et al.  Coupled left-shift of Nav channels: modeling the Na+-loading and dysfunctional excitability of damaged axons , 2012, Journal of Computational Neuroscience.

[34]  Vladislav Volman,et al.  Computer Modeling of Mild Axonal Injury: Implications for Axonal Signal Transmission , 2013, Neural Computation.

[35]  Wei Wu,et al.  Real-Time CARS Imaging Reveals a Calpain-Dependent Pathway for Paranodal Myelin Retraction during High-Frequency Stimulation , 2011, PloS one.

[36]  P. Stys,et al.  Anoxic and Ischemic Injury of Myelinated Axons in CNS White Matter: From Mechanistic Concepts to Therapeutics , 1998, Journal of cerebral blood flow and metabolism : official journal of the International Society of Cerebral Blood Flow and Metabolism.

[37]  D. Stephanova,et al.  Differences in potentials and excitability properties in simulated cases of demyelinating neuropathies. Part III. Paranodal internodal demyelination , 2005, Clinical Neurophysiology.

[38]  W. Maxwell Histopathological changes at central nodes of Ranvier after stretch‐injury , 1996, Microscopy research and technique.

[39]  Terrence J. Sejnowski,et al.  Computational models of neuron-astrocyte interaction in epilepsy , 2012, Front. Comput. Neurosci..

[40]  J. Trimmer,et al.  Developmental clustering of ion channels at and near the node of Ranvier. , 2001, Developmental biology.

[41]  Alexander Gow,et al.  A model of tight junction function in central nervous system myelinated axons. , 2008, Neuron glia biology.

[42]  P. Shrager,et al.  Ion channel redistribution and function during development of the myelinated axon. , 1998, Journal of neurobiology.

[43]  J. S. Coggan,et al.  Computational modeling of three-dimensional electrodiffusion in biological systems: application to the node of Ranvier. , 2008, Biophysical journal.

[44]  Hugo J. Bellen,et al.  Axon-Glia Interactions and the Domain Organization of Myelinated Axons Requires Neurexin IV/Caspr/Paranodin , 2001, Neuron.

[45]  M. H. Brill,et al.  Conduction velocity and spike configuration in myelinated fibres: computed dependence on internode distance. , 1977, Journal of neurology, neurosurgery, and psychiatry.

[46]  David F Meaney,et al.  Traumatic Axonal Injury Induces Proteolytic Cleavage of the Voltage-Gated Sodium Channels Modulated by Tetrodotoxin and Protease Inhibitors , 2004, The Journal of Neuroscience.

[47]  Heinrich H. Bülthoff,et al.  Learned Non-Rigid Object Motion is a View-Invariant Cue to Recognizing Novel Objects , 2012, Front. Comput. Neurosci..

[48]  Sonia Gasparini,et al.  Reduction of K+ Uptake in Glia Prevents Long-Term Depression Maintenance and Causes Epileptiform Activity , 1997, The Journal of Neuroscience.

[49]  M. Bhat Molecular organization of axo-glial junctions , 2003, Current Opinion in Neurobiology.

[50]  E. Nauman,et al.  Compression induces acute demyelination and potassium channel exposure in spinal cord. , 2010, Journal of neurotrauma.

[51]  D. Stephanova,et al.  Membrane property abnormalities in simulated cases of mild systematic and severe focal demyelinating neuropathies , 2008, European Biophysics Journal.

[52]  A. Buki,et al.  All roads lead to disconnection? – Traumatic axonal injury revisited , 2006, Acta Neurochirurgica.

[53]  T. M. Reeves,et al.  Proteolysis of Submembrane Cytoskeletal Proteins Ankyrin‐G and αII‐Spectrin Following Diffuse Brain Injury: A Role in White Matter Vulnerability at Nodes of Ranvier , 2010, Brain pathology.

[54]  R. Shi,et al.  Novel potassium channel blocker, 4-AP-3-MeOH, inhibits fast potassium channels and restores axonal conduction in injured guinea pig spinal cord white matter. , 2010, Journal of neurophysiology.

[55]  Steven A Prescott,et al.  Explaining pathological changes in axonal excitability through dynamical analysis of conductance-based models , 2011, Journal of neural engineering.

[56]  A. J. McLean,et al.  Stalning af amyloid percursor protein to study axonal damage in mild head Injury , 1994, The Lancet.

[57]  H Bostock,et al.  The strength‐duration relationship for excitation of myelinated nerve: computed dependence on membrane parameters. , 1983, The Journal of physiology.

[58]  R. Raghupathi,et al.  Calpain as a therapeutic target in traumatic brain injury , 2011, Neurotherapeutics.

[59]  Peter K. Stys,et al.  General mechanisms of axonal damage and its prevention , 2005, Journal of the Neurological Sciences.

[60]  C. Morris,et al.  Membrane trauma and Na+ leak from Nav1.6 channels. , 2009, American journal of physiology. Cell physiology.

[61]  M. Bennett,et al.  Relative conduction velocities of small myelinated and non-myelinated fibres in the central nervous system. , 1972, Nature: New biology.

[62]  Helen M. Bramlett,et al.  Quantitative structural changes in white and gray matter 1 year following traumatic brain injury in rats , 2002, Acta Neuropathologica.

[63]  A. Hodgkin,et al.  A quantitative description of membrane current and its application to conduction and excitation in nerve , 1990 .

[64]  Nicholas T. Carnevale,et al.  Expanding NEURON's Repertoire of Mechanisms with NMODL , 2000, Neural Computation.

[65]  A. Blight,et al.  Compression injury of mammalian spinal cord in vitro and the dynamics of action potential conduction failure. , 1996, Journal of neurophysiology.

[66]  D. I. Stephanova,et al.  Action potentials and ionic currents through paranodally demyelinated human motor nerve fibres: computer simulations , 1997, Biological Cybernetics.

[67]  D. I. Stephanova,et al.  A distributed-parameter model of the myelinated human motor nerve fibre: temporal and spatial distributions of action potentials and ionic currents , 1995, Biological Cybernetics.

[68]  R. Shi,et al.  Paranodal myelin damage after acute stretch in Guinea pig spinal cord. , 2012, Journal of neurotrauma.

[69]  S. Waxman,et al.  Ion channel organization of the myelinated fiber , 1990, Trends in Neurosciences.

[70]  D. Stephanova,et al.  Differences in potentials and excitability properties in simulated cases of demyelinating neuropathies. Part II. Paranodal demyelination , 2005, Clinical Neurophysiology.

[71]  D. Stephanova,et al.  Differences in potentials and excitability properties in simulated cases of demyelinating neuropathies. Part I , 2005, Clinical Neurophysiology.

[72]  Russ S Kotwal,et al.  Residual effects of combat-related mild traumatic brain injury. , 2013, Journal of neurotrauma.