Potassium channel blockers as an effective treatment to restore impulse conduction in injured axons

Shi, Riyi; Sun, Wenjing

doi:10.1007/s12264-011-1048-y

Cited by 25 publications

(39 citation statements)

References 73 publications

(136 reference statements)

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“…Additionally, a simulation with mutant-urotoxin (Lys25Ala) indicated that Lys25 does not have the same role in the binding of urotoxin to hK v 1.2 as in other a-KTx-6 toxins. Our results suggest that urotoxin may be useful as a pharmacologic tool to reveal the physiologic function of hK v 1.2 channels in in vitro and in vivo experiments, as a lead for peptidomimetics for the targeting of hK v 1.2 channels, and as an experimental therapeutic tool to restore axonal conduction in demyelinated axons, where inhibition of K 1 channels has beneficial effects (Beraud et al, 2006;Shi and Sun, 2011).…”

Section: Introductionmentioning

confidence: 90%

“…Knowledge of the interacting surfaces between the channels and toxins may allow the design of specific drugs to control pathologies associated with K 1 channels, such as demyelinating diseases (e.g., Guillain-Barré syndrome, multiple sclerosis) and Lambert-Eaton myasthenic syndrome (Judge and Bever, 2006;Shi and Sun, 2011).…”

Section: Characterization Of the Potassium Channel Blocker Urotoxinmentioning

confidence: 99%

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Structure, Molecular Modeling, and Function of the Novel Potassium Channel Blocker Urotoxin Isolated from the Venom of the Australian Scorpion Urodacus yaschenkoi

et al. 2014

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This communication reports the structural and functional characterization of urotoxin, the first K 1 channel toxin isolated from the venom of the Australian scorpion Urodacus yaschenkoi. It is a basic peptide consisting of 37 amino acids with an amidated C-terminal residue. Urotoxin contains eight cysteines forming four disulfide bridges with sequence similarities resembling the a-potassium channel toxin 6 (a-KTx-6) subfamily of peptides; it was assigned the systematic number of a-KTx-6.21. Urotoxin is a potent blocker of human voltage-gated potassium channel (K v )1.2 channels, with an IC 50 of 160 pM, whereas its affinity for other channels tested was in the nanomolar range (hK v 1

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Section: Introductionmentioning

confidence: 90%

Section: Characterization Of the Potassium Channel Blocker Urotoxinmentioning

confidence: 99%

Structure, Molecular Modeling, and Function of the Novel Potassium Channel Blocker Urotoxin Isolated from the Venom of the Australian Scorpion Urodacus yaschenkoi

et al. 2014

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“…Myelin enhances axonal conduction by both inhibiting ionic exchange across the membrane and increasing transverse resistance at the internodal region [12]. Accordingly, compromise of the structural integrity of myelin elicits significant conduction loss in spinal cord tissue partly due to the exposure and consequential activation of voltage-gated K + channels typically residing in the juxtaparanodal region [1, 10, 11, 13–15]. Ex vivo studies of spinal cord tissue have demonstrated that myelin damage and subsequent exposure of K + channels impaired signal propagation, indicated by a reduction of compound action potential (CAP) amplitude [10, 11, 14].…”

Section: Pathological Significance Of Myelin Damage In Cns Trauma Andmentioning

confidence: 99%

“…In the case of trauma, primary injury mediated by physical forces triggers subsequent pathological molecular mechanisms, deemed secondary injury [22, 23]. Separation of these two components was postulated decades ago and has been supported by many subsequent studies [13, 22, 23]. Recently, this phenomenon was demonstrated in an ex vivo acute spinal cord injury model where a mechanical stretch injury resulted in immediate myelin damage indicated by lengthening of the nodal region and retraction of myelin from the paranodal region following the physical insult [11].…”

Section: Mechanisms Of Myelin Damagementioning

confidence: 99%

Molecular mechanisms of acrolein-mediated myelin destruction in CNS trauma and disease

Shi

Joe

Tully

2015

Free Radical Research

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Myelin is a critical component of the nervous system facilitating efficient propagation of electrical signals and thus communication between the central and peripheral nervous systems and organ systems they innervate throughout the body. In instances of neurotrauma and neurodegenerative disease, injury to myelin is a prominent pathological feature responsible for conduction deficits and leaves axons vulnerable to damage from noxious compounds. Although the pathological mechanisms underlying myelin loss have yet to be fully characterized, oxidative stress appears to play a prominent role. Specifically, acrolein, a neurotoxic aldehyde that is both a product and instigator of oxidative stress, has been observed in studies to elicit demyelination through calcium-independent and -dependent mechanisms and also by affecting glutamate uptake and promoting excitotoxicity. Furthermore, pharmacological scavenging of acrolein has demonstrated a neuroprotective effect in animal disease models by conserving myelin structural integrity and alleviating functional deficits. This evidence is indicative that acrolein may be a key culprit of myelin damage while acrolein scavenging could potentially be a promising therapeutic approach for patients suffering from nervous system trauma and disease.

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“…These studies have raised a possibility that neuronal tracers may fail to fully illuminate those damaged (but structurally connected) axons, at least transiently and during the early phase of injury, potentially confounding the use of serial labeling approaches to argue for regeneration. Others have reported that surviving but compressed axons may also be physiologically abnormal for a certain period of time, probably due to altered myelin structure and potassium channel activity, leading to conduction failure and loss of function (Nashmi & Fehlings, 2001; Shi & Sun, 2011). …”

Section: Commonly Used Strategies Are Not Sufficientmentioning

confidence: 99%

Optic nerve regeneration in mammals: Regenerated or spared axons?

Fischer

Harvey

Pernet

et al. 2017

Experimental Neurology

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Intraorbital optic nerve crush in rodents is widely used as a model to study axon regeneration in the adult mammalian central nervous system. Recent studies using appropriate genetic manipulations have revealed remarkable abilities of mature retinal ganglion cell (RGC) axons to regenerate after optic nerve injury, with some studies demonstrating that axons can then go on to re-innervate a number of central visual targets with partial functional restoration. However, one confounding factor inherent to optic nerve crush injury is the potential incompleteness of the initial lesion, leaving spared axons that later on could erroneously be interpreted as regenerating distal to the injury site. Careful examination of axonal projection pattern and morphology may facilitate separating spared from regenerating RGC axons. Here we discuss morphological criteria and strategies that may be used to differentiate spared versus regenerated axons in the injured mammalian optic nerve.

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Potassium channel blockers as an effective treatment to restore impulse conduction in injured axons

Cited by 25 publications

References 73 publications

Structure, Molecular Modeling, and Function of the Novel Potassium Channel Blocker Urotoxin Isolated from the Venom of the Australian Scorpion Urodacus yaschenkoi

Structure, Molecular Modeling, and Function of the Novel Potassium Channel Blocker Urotoxin Isolated from the Venom of the Australian Scorpion Urodacus yaschenkoi

Molecular mechanisms of acrolein-mediated myelin destruction in CNS trauma and disease

Optic nerve regeneration in mammals: Regenerated or spared axons?

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