Optical Reversal of Halothane-Induced Immobility in C. elegans

Singaram, Vinod K.; Somerlot, Benjamin H.; Falk, Scott A.; Falk, Marni J.; Sedensky, Margaret M.; Morgan, Philip G.

doi:10.1016/j.cub.2011.10.042

Cited by 19 publications

(23 citation statements)

References 42 publications

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“…Concluding Remarks and Implications-Toward understanding the molecular mechanisms of general anesthesia, recent reports emphasized the need to investigate how halogenated inhaled anesthetics with very similar chemical properties can achieve functional specificity (34,41). This study offers insight into this problem by suggesting that allosteric interactions affecting activation gating of Kv channels can explain the novel positive allosteric modulation of an archetypical Kv channel by the inhaled anesthetic sevoflurane.…”

Section: Discussionmentioning

confidence: 91%

Novel Activation of Voltage-gated K+ Channels by Sevoflurane

Barber

Liang

Covarrubias

2012

Journal of Biological Chemistry

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Background: Halogenated inhaled anesthetics modulate voltage-gated ion channels by unknown mechanisms. Results: Biophysical analyses revealed novel activation of K v channels by the inhaled anesthetic sevoflurane. Conclusion: K v channel activation by sevoflurane results from the positive allosteric modulation of activation gating. Significance: The unique activation of K v channels by sevoflurane demonstrates novel anesthetic specificity and offers new insights into allosteric modulation of channel gating.

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Section: Discussionmentioning

confidence: 91%

Novel Activation of Voltage-gated K+ Channels by Sevoflurane

Barber

Liang

Covarrubias

2012

Journal of Biological Chemistry

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“…Interestingly, of the mutations that been shown to affect general anesthesia, those with the biggest impact in flies (our data) and mammals [42] cause impairment of ion channel function. Whether these effects are due to loss of drug binding sites in the proteins affected by these mutations, or whether the resulting changes in membrane potential alter anesthetic efficacy [43] remains to be determined. Pharmacokinetics do not appear to be a factor, however, since at the EC 50 for emergence in both flies and mammals, isoflurane concentrations are similar in controls and mutants that have altered neural inertia [7].…”

Section: Discussionmentioning

confidence: 99%

Genetic and Anatomical Basis of the Barrier Separating Wakefulness and Anesthetic-Induced Unresponsiveness

et al. 2013

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A robust, bistable switch regulates the fluctuations between wakefulness and natural sleep as well as those between wakefulness and anesthetic-induced unresponsiveness. We previously provided experimental evidence for the existence of a behavioral barrier to transitions between these states of arousal, which we call neural inertia. Here we show that neural inertia is controlled by processes that contribute to sleep homeostasis and requires four genes involved in electrical excitability: Sh, sss, na and unc79. Although loss of function mutations in these genes can increase or decrease sensitivity to anesthesia induction, surprisingly, they all collapse neural inertia. These effects are genetically selective: neural inertia is not perturbed by loss-of-function mutations in all genes required for the sleep/wake cycle. These effects are also anatomically selective: sss acts in different neurons to influence arousal-promoting and arousal-suppressing processes underlying neural inertia. Supporting the idea that anesthesia and sleep share some, but not all, genetic and anatomical arousal-regulating pathways, we demonstrate that increasing homeostatic sleep drive widens the neural inertial barrier. We propose that processes selectively contributing to sleep homeostasis and neural inertia may be impaired in pathophysiological conditions such as coma and persistent vegetative states.

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“…A reliable consequence of NALCN knockdown is a membrane hyperpolarization [4], [11], [37]. Invertebrates have increased sensitivity to volatile anesthetics [38], [39] and defects in exocytosis [[7]–[10], that could relate to NALCN's influence on membrane potential serving to regulate secretion in neurons that require fast or continuous vesicle turnover.…”

Section: Discussionmentioning

confidence: 99%

NALCN Ion Channels Have Alternative Selectivity Filters Resembling Calcium Channels or Sodium Channels

et al. 2013

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NALCN is a member of the family of ion channels with four homologous, repeat domains that include voltage-gated calcium and sodium channels. NALCN is a highly conserved gene from simple, extant multicellular organisms without nervous systems such as sponges and placozoans and mostly remains a single gene compared to the calcium and sodium channels which diversified into twenty genes in humans. The single NALCN gene has alternatively-spliced exons at exons 15 or exon 31 that splices in novel selectivity filter residues that resemble calcium channels (EEEE) or sodium channels (EKEE or EEKE). NALCN channels with alternative calcium, (EEEE) and sodium, (EKEE or EEKE) -selective pores are conserved in simple bilaterally symmetrical animals like flatworms to non-chordate deuterostomes. The single NALCN gene is limited as a sodium channel with a lysine (K)-containing pore in vertebrates, but originally NALCN was a calcium-like channel, and evolved to operate as both a calcium channel and sodium channel for different roles in many invertebrates. Expression patterns of NALCN-EKEE in pond snail, Lymnaea stagnalis suggest roles for NALCN in secretion, with an abundant expression in brain, and an up-regulation in secretory organs of sexually-mature adults such as albumen gland and prostate. NALCN-EEEE is equally abundant as NALCN-EKEE in snails, but is greater expressed in heart and other muscle tissue, and 50% less expressed in the brain than NALCN-EKEE. Transfected snail NALCN-EEEE and NALCN-EKEE channel isoforms express in HEK-293T cells. We were not able to distinguish potential NALCN currents from background, non-selective leak conductances in HEK293T cells. Native leak currents without expressing NALCN genes in HEK-293T cells are NMDG+ impermeant and blockable with 10 µM Gd3+ ions and are indistinguishable from the hallmark currents ascribed to mammalian NALCN currents expressed in vitro by Lu et al. in Cell. 2007 Apr 20;129(2):371-83.

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Optical Reversal of Halothane-Induced Immobility in C. elegans

Cited by 19 publications

References 42 publications

Novel Activation of Voltage-gated K+ Channels by Sevoflurane

Novel Activation of Voltage-gated K+ Channels by Sevoflurane

Genetic and Anatomical Basis of the Barrier Separating Wakefulness and Anesthetic-Induced Unresponsiveness

NALCN Ion Channels Have Alternative Selectivity Filters Resembling Calcium Channels or Sodium Channels

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