CaMKII Phosphorylation of the Voltage-Gated Sodium Channel Nav1.6 Regulates Channel Function and Neuronal Excitability

Zybura, Agnes Sara

01 1900

Indiana University-Purdue University Indianapolis (IUPUI) / Voltage-gated sodium channels (Navs) undergo remarkably complex modes of modulation to fine tune membrane excitability and neuronal firing properties. 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. Thus, Nav1.6 modulation and dysfunction may profoundly impact the input-output properties of neurons in normal and pathological conditions. Phosphorylation is a powerful and reversible mechanism that exquisitely modulates ion channels. To this end, the multifunctional calcium/calmodulin-dependent protein kinase II (CaMKII) can transduce neuronal activity through phosphorylation of diverse substrates to serve as a master regulator of neuronal function. Because Nav1.6 and CaMKII are independently linked to excitability disorders, I sought to investigate modulation of Nav1.6 function by CaMKII signaling to reveal an important mechanism underlying neuronal excitability. Multiple biochemical approaches show Nav1.6 is a novel substrate for CaMKII and reveal multi-site phosphorylation within the L1 domain; a hotspot for post-translational regulation in other Nav isoforms. Consistent with these findings, pharmacological inhibition of CaMKII reduces transient and persistent sodium currents in Purkinje neurons. Because Nav1.6 is the predominant sodium current observed in Purkinje neurons, these data suggest that Nav1.6 may be modulated through CaMKII signaling. In support of this, my studies demonstrate that CaMKII inhibition significantly attenuates Nav1.6 transient and persistent sodium currents and shifts the voltage-dependence of activation to more depolarizing potentials in heterologous cells. Interestingly, I show that these functional effects are likely mediated by CaMKII phosphorylation of Nav1.6 at S561 and T642, and that each phosphorylation site regulates distinct biophysical characteristics of the channel. These findings are further extended to investigate CaMKII modulation of disease-linked mutant Nav1.6 channels. I show that different Nav1.6 mutants display distinct responses to CaMKII modulation and reveal that acute CaMKII inhibition attenuates gain-of-function effects produced by mutant channels. Importantly, computational simulations modeling the effects of CaMKII inhibition on WT and mutant Nav1.6 channels demonstrate dramatic reductions in neuronal excitability in Purkinje and cortical pyramidal cell models. Together, these findings suggest that CaMKII modulation of Nav1.6 may be a powerful mechanism to regulate physiological and pathological neuronal excitability. / 2022-02-02

CaMKII

Electrophysiology

Nav1.6

Phosphorylation

Post-translational modification

Sodium channel

Voltage-Gated Sodium Channel Nav1.6 S-Palmitoylation Regulates Channel Functions and Neuronal Excitability

Pan, Yanling

04 1900

Indiana University-Purdue University Indianapolis (IUPUI) / The voltage-gated sodium channels (VGSCs) are critical determinants of neuronal excitability. They set the threshold for action potential generation. The VGSC isoform Nav1.6 participates in various physiological processes and contributes to distinct pathological conditions, but how Nav1.6 function is differentially regulated in different cell types and subcellular locations is not clearly understood. Some VGSC isoforms are subject to S-palmitoylation and exhibit altered functional properties in different S-palmitoylation states. This dissertation investigates the role of S-palmitoylation in Nav1.6 regulation and explores the consequences of S-palmitoylation in modulating neuronal excitability in physiological and pathological conditions. The aims of this dissertation were to 1) provide biochemical and electrophysiological evidence of Nav1.6 regulation by S-palmitoylation and identify specific S-palmitoylation sites in Nav1.6 that are important for excitability modulation, 2) determine the biophysical consequences of epilepsy-associated mutations in Nav1.6 and employ computational models for excitability prediction and 3) test the modulating effects of S-palmitoylation on aberrant Nav1.6 activity incurred by epilepsy mutations. To address these aims, an acyl-biotin exchange assay was used for Spalmitoylation detection and whole-cell electrophysiology was used for channel characterization and excitability examination. The results demonstrate that 1) Nav1.6 is biochemically modified and functionally regulated by S-palmitoylation in an isoform- and site-specific manner and altered S-palmitoylation status of the channel results in substantial changes of neuronal excitability, 2) epilepsy associated Nav1.6 mutations affect different aspects of channel function, but may all converge to gain-of-function alterations with enhanced resurgent currents and increased neuronal excitability and 3) S-palmitoylation can target specific Nav1.6 properties and could possibly be used to rescue abnormal channel function in diseased conditions. Overall, this dissertation reveals S-palmitoylation as a new mechanism for Nav1.6 regulation. This knowledge is critical for understanding the potential role of S-palmitoylation in isoform-specific regulation for VGSCs and providing potential targets for the modulation of excitability disorders. / 2022-05-06

computational model

epilepsy

Nav1.6

S-palmitoylation

SCN8A

voltage-gated sodium channel

Stress driven changes in the kinetics of bilayer embedded proteins: a membrane spandex and a voltage-gated sodium channel

Boucher, Pierre-Alexandre

27 May 2011

Bilayer embedded proteins are affected by stress. This general affirmation is, in this thesis, embodied by two types of proteins: membrane spandex and voltage-gated sodium channels. In this work, we essentially explore, using methods from physics, the theoretical consequences of ideas drawn from experimental biology. Membrane spandex was postulated to exist and we study the theoretical implications and possible benefits for a cell to have such proteins embedded in its bilayer. There are no specific membrane spandex proteins, rather any protein with a transition involving a large enough area change between two non-conducting states could act as spandex. Bacterial cells have osmovalve channels which open at near-lytic tensions to protect themselves against rupture. Spandex expanding at tensions just below the osmovalves’ opening tension could relieve tension enough as to avoid costly accidental osmovalve opening due to transient bilayer tension excursions. Another possible role for spandex is a tension-damper: spandex could be used to maintain bilayer tension at a fixed level. This would be useful as many bilayer embedded channels are known to be modulated by tension. The Stress/shear experienced in traumatic brain injury cause an immediate (< 2 min) and irreversible TTX-sensitive rise in axonal calcium. In situ, this underlies an untreatable condition, diffuse axonal injury. TTX sensitivity indicates that leaky voltage-gated sodium (Nav) channels mediate the calcium increase. Wang et al. showed that the mammalian adult CNS Nav isoform, Nav1.6, expressed in Xenopus oocytes becomes “leaky” when subjected to bleb-inducing pipette aspiration. This “leaky” condition is caused by a hyperpolarized-shift (left-shift or towards lower potentials, typically 20 mV) of the kinetically coupled processes of activation and inactivation thus effectively degrading a well-confined window conductance into a TTX-sensitive Na leak. We propose experimental protocols to determine whether this left-shift is the result of an all-or-none or graded process and whether persistent Na currents are also left-shifted by trauma. We also use modeling to assess whether left-shifted Nav channel kinetics could lead to Na+ (and hence Ca2+ ) loading of axons and to study saltatory propagation after traumatizing a single node of Ranvier.

membrane

spandex

tension

membrane proteins

tension relief

voltage-gated sodium channel

trauma

Nav1.6

subthreshold oscillations

activation

inactivation

Nav channel

osmovalve

membrane trauma

nodes of Ranvier

left-shift

Stress driven changes in the kinetics of bilayer embedded proteins: a membrane spandex and a voltage-gated sodium channel

Boucher, Pierre-Alexandre

27 May 2011

Bilayer embedded proteins are affected by stress. This general affirmation is, in this thesis, embodied by two types of proteins: membrane spandex and voltage-gated sodium channels. In this work, we essentially explore, using methods from physics, the theoretical consequences of ideas drawn from experimental biology. Membrane spandex was postulated to exist and we study the theoretical implications and possible benefits for a cell to have such proteins embedded in its bilayer. There are no specific membrane spandex proteins, rather any protein with a transition involving a large enough area change between two non-conducting states could act as spandex. Bacterial cells have osmovalve channels which open at near-lytic tensions to protect themselves against rupture. Spandex expanding at tensions just below the osmovalves’ opening tension could relieve tension enough as to avoid costly accidental osmovalve opening due to transient bilayer tension excursions. Another possible role for spandex is a tension-damper: spandex could be used to maintain bilayer tension at a fixed level. This would be useful as many bilayer embedded channels are known to be modulated by tension. The Stress/shear experienced in traumatic brain injury cause an immediate (< 2 min) and irreversible TTX-sensitive rise in axonal calcium. In situ, this underlies an untreatable condition, diffuse axonal injury. TTX sensitivity indicates that leaky voltage-gated sodium (Nav) channels mediate the calcium increase. Wang et al. showed that the mammalian adult CNS Nav isoform, Nav1.6, expressed in Xenopus oocytes becomes “leaky” when subjected to bleb-inducing pipette aspiration. This “leaky” condition is caused by a hyperpolarized-shift (left-shift or towards lower potentials, typically 20 mV) of the kinetically coupled processes of activation and inactivation thus effectively degrading a well-confined window conductance into a TTX-sensitive Na leak. We propose experimental protocols to determine whether this left-shift is the result of an all-or-none or graded process and whether persistent Na currents are also left-shifted by trauma. We also use modeling to assess whether left-shifted Nav channel kinetics could lead to Na+ (and hence Ca2+ ) loading of axons and to study saltatory propagation after traumatizing a single node of Ranvier.

membrane

spandex

tension

membrane proteins

tension relief

voltage-gated sodium channel

trauma

Nav1.6

subthreshold oscillations

activation

inactivation

Nav channel

osmovalve

membrane trauma

nodes of Ranvier

left-shift

Stress driven changes in the kinetics of bilayer embedded proteins: a membrane spandex and a voltage-gated sodium channel

Boucher, Pierre-Alexandre

27 May 2011

Bilayer embedded proteins are affected by stress. This general affirmation is, in this thesis, embodied by two types of proteins: membrane spandex and voltage-gated sodium channels. In this work, we essentially explore, using methods from physics, the theoretical consequences of ideas drawn from experimental biology. Membrane spandex was postulated to exist and we study the theoretical implications and possible benefits for a cell to have such proteins embedded in its bilayer. There are no specific membrane spandex proteins, rather any protein with a transition involving a large enough area change between two non-conducting states could act as spandex. Bacterial cells have osmovalve channels which open at near-lytic tensions to protect themselves against rupture. Spandex expanding at tensions just below the osmovalves’ opening tension could relieve tension enough as to avoid costly accidental osmovalve opening due to transient bilayer tension excursions. Another possible role for spandex is a tension-damper: spandex could be used to maintain bilayer tension at a fixed level. This would be useful as many bilayer embedded channels are known to be modulated by tension. The Stress/shear experienced in traumatic brain injury cause an immediate (< 2 min) and irreversible TTX-sensitive rise in axonal calcium. In situ, this underlies an untreatable condition, diffuse axonal injury. TTX sensitivity indicates that leaky voltage-gated sodium (Nav) channels mediate the calcium increase. Wang et al. showed that the mammalian adult CNS Nav isoform, Nav1.6, expressed in Xenopus oocytes becomes “leaky” when subjected to bleb-inducing pipette aspiration. This “leaky” condition is caused by a hyperpolarized-shift (left-shift or towards lower potentials, typically 20 mV) of the kinetically coupled processes of activation and inactivation thus effectively degrading a well-confined window conductance into a TTX-sensitive Na leak. We propose experimental protocols to determine whether this left-shift is the result of an all-or-none or graded process and whether persistent Na currents are also left-shifted by trauma. We also use modeling to assess whether left-shifted Nav channel kinetics could lead to Na+ (and hence Ca2+ ) loading of axons and to study saltatory propagation after traumatizing a single node of Ranvier.

membrane

spandex

tension

membrane proteins

tension relief

voltage-gated sodium channel

trauma

Nav1.6

subthreshold oscillations

activation

inactivation

Nav channel

osmovalve

membrane trauma

nodes of Ranvier

left-shift

Déclenchement d'activité ectopique et infidélité de la transmission dans un axone endommagé : une modélisation fondée sur le décalage cinétique des canaux sodiques

Lachance, Mathieu

08 January 2014

Les neurones endommagés développent de l'activité ectopique, c'est-à-dire qu'ils déchargent en l'absence de stimulus, ce qui engendre ensuite des douleurs neuropathiques. Des mesures expérimentales ont lié cette activité ectopique à un décalage cinétique (coupled left-shift, CLS) des canaux sodiques tensiodépendants. Nous avons donc construit un modèle numérique d'axone où une portion endommagée subit un tel décalage. Deux résultats fondamentaux et nouveaux sont obtenus : 1) En présence d'activité ectopique, une stimulation à haute fréquence peut entraîner la zone ectopique de l'axone à décharger à la même fréquence que le stimulus. La propagation est alors presque normale. 2) Dans un axone faiblement endommagé, sans activité ectopique au départ, un stimulus temporaire peut déclencher une activité ectopique qui perdure. Ceci amplifie le stimulus et peut donc être lié aux symptômes de douleurs neuropathiques. En plus de ces travaux de recherche, cette thèse propose une imposante section pédagogique, adressé au physicien qui débute en neurosciences. Injured neurons exhibit ectopic activity (ie. they fire without being stimulated), leading to neuropathic pain. Experiments have linked this ectopic activity to a kinetic shift (coupled left-shift, CLS) of the voltage-gated sodium channels. Therefore, we have designed a computational model axon where a damaged zone is affected by such a left-shift. Two important novel results were obtained : 1) In an ectopic axon, high-frequency stimulation can force the ectopic zone to phase-lock to the stimulation frequency. Propagation is then almost normal. 2) In a weakly damaged axon, without initial ectopic activity, a short stimulus can trigger a long lasting ectopic activity. This amplifies the stimulus and can thus be linked to neuropathic pain-like symptoms. In addition to this research work, this thesis encompasses a large educational section, addressed to physicists just starting in neuroscience.

douleurs neuropathiques

coupled left-shift (CLS)

acquired channelopathies

comportement ectopique

Nav1.6

sick excitable cell

mild axonal injury

neuropathic pain

ectopic behaviour

Stress driven changes in the kinetics of bilayer embedded proteins: a membrane spandex and a voltage-gated sodium channel

Boucher, Pierre-Alexandre

January 2011

Bilayer embedded proteins are affected by stress. This general affirmation is, in this thesis, embodied by two types of proteins: membrane spandex and voltage-gated sodium channels. In this work, we essentially explore, using methods from physics, the theoretical consequences of ideas drawn from experimental biology. Membrane spandex was postulated to exist and we study the theoretical implications and possible benefits for a cell to have such proteins embedded in its bilayer. There are no specific membrane spandex proteins, rather any protein with a transition involving a large enough area change between two non-conducting states could act as spandex. Bacterial cells have osmovalve channels which open at near-lytic tensions to protect themselves against rupture. Spandex expanding at tensions just below the osmovalves’ opening tension could relieve tension enough as to avoid costly accidental osmovalve opening due to transient bilayer tension excursions. Another possible role for spandex is a tension-damper: spandex could be used to maintain bilayer tension at a fixed level. This would be useful as many bilayer embedded channels are known to be modulated by tension. The Stress/shear experienced in traumatic brain injury cause an immediate (< 2 min) and irreversible TTX-sensitive rise in axonal calcium. In situ, this underlies an untreatable condition, diffuse axonal injury. TTX sensitivity indicates that leaky voltage-gated sodium (Nav) channels mediate the calcium increase. Wang et al. showed that the mammalian adult CNS Nav isoform, Nav1.6, expressed in Xenopus oocytes becomes “leaky” when subjected to bleb-inducing pipette aspiration. This “leaky” condition is caused by a hyperpolarized-shift (left-shift or towards lower potentials, typically 20 mV) of the kinetically coupled processes of activation and inactivation thus effectively degrading a well-confined window conductance into a TTX-sensitive Na leak. We propose experimental protocols to determine whether this left-shift is the result of an all-or-none or graded process and whether persistent Na currents are also left-shifted by trauma. We also use modeling to assess whether left-shifted Nav channel kinetics could lead to Na+ (and hence Ca2+ ) loading of axons and to study saltatory propagation after traumatizing a single node of Ranvier.

membrane

spandex

tension

membrane proteins

tension relief

voltage-gated sodium channel

trauma

Nav1.6

subthreshold oscillations

activation

inactivation

Nav channel

osmovalve

membrane trauma

nodes of Ranvier

left-shift

Déclenchement d'activité ectopique et infidélité de la transmission dans un axone endommagé : une modélisation fondée sur le décalage cinétique des canaux sodiques

Lachance, Mathieu

January 2014

Les neurones endommagés développent de l'activité ectopique, c'est-à-dire qu'ils déchargent en l'absence de stimulus, ce qui engendre ensuite des douleurs neuropathiques. Des mesures expérimentales ont lié cette activité ectopique à un décalage cinétique (coupled left-shift, CLS) des canaux sodiques tensiodépendants. Nous avons donc construit un modèle numérique d'axone où une portion endommagée subit un tel décalage. Deux résultats fondamentaux et nouveaux sont obtenus : 1) En présence d'activité ectopique, une stimulation à haute fréquence peut entraîner la zone ectopique de l'axone à décharger à la même fréquence que le stimulus. La propagation est alors presque normale. 2) Dans un axone faiblement endommagé, sans activité ectopique au départ, un stimulus temporaire peut déclencher une activité ectopique qui perdure. Ceci amplifie le stimulus et peut donc être lié aux symptômes de douleurs neuropathiques. En plus de ces travaux de recherche, cette thèse propose une imposante section pédagogique, adressé au physicien qui débute en neurosciences. Injured neurons exhibit ectopic activity (ie. they fire without being stimulated), leading to neuropathic pain. Experiments have linked this ectopic activity to a kinetic shift (coupled left-shift, CLS) of the voltage-gated sodium channels. Therefore, we have designed a computational model axon where a damaged zone is affected by such a left-shift. Two important novel results were obtained : 1) In an ectopic axon, high-frequency stimulation can force the ectopic zone to phase-lock to the stimulation frequency. Propagation is then almost normal. 2) In a weakly damaged axon, without initial ectopic activity, a short stimulus can trigger a long lasting ectopic activity. This amplifies the stimulus and can thus be linked to neuropathic pain-like symptoms. In addition to this research work, this thesis encompasses a large educational section, addressed to physicists just starting in neuroscience.

douleurs neuropathiques

coupled left-shift (CLS)

acquired channelopathies

comportement ectopique

Nav1.6

sick excitable cell

mild axonal injury

neuropathic pain

ectopic behaviour