Conserved Single Residue in the BK Potassium Channel Required for Activation by Alcohol and Intoxication in C. elegans

We share the goal of authors of this manuscript of using C. elegans as a model system to understand the effects of alcohol on neural signalling and behaviour (Dillon et al 2013) however we have differing interpretations with respect to dose in the context of whole worm experiments. This is important when considering the actions of ethanol as it has a complex pharmacology with pleiotropic effects spanning intoxication through to anaesthesia. The authors make an explicit statement in their methods sub-section entitled egg laying response, stating "Previous studies have demonstrated that internal concentrations are 40-60 mM when exposed to 400-600 mM external concentrations (Davies et al., 2003; Kapfhamer et al., 2008; Alaimo et al., 2012)". This comment about the dose during whole worm assays has prompted our response. Our previous publications provide evidence that ethanol rapidly equilibrates across the cuticle of the worm (Mitchell et al., 2007). This interpretation stems from the dose dependence and kinetics of ethanol induced behavioural inhibition of C. elegans and in particular the worm's rapid recovery from the effects of ethanol. These observations suggest the worm's cuticle is freely permeable to ethanol. This is reinforced by observations that the concentration-dependence and time-course over which ethanol inhibits the pharyngeal system in intact and in dissected preparations is very similar. Thus, our interpretation is that immersing worms in 400mM ethanol will result in approximately 400mM inside the worm. As a result of our investigations we are also of the firm opinion, as described in Mitchell et al 2007, that it is not possible to get an accurate measure of ethanol concentration inside the worm using methodologies described in Alaimo et al (2012) and on which the authors' interpretation is reliant.

References

Alaimo JT, Davis SJ, Song SS, Burnette CR, Grotewiel M, Shelton KL, Pierce -Shimomura JT, Davies AG, Bettinger JC. (2012) Ethanol metabolism and osmolarity modify behavioral responses to ethanol in C. elegans. Alcohol Clin Exp Res. 36:1840-50.

Davies AG, Pierce-Shimomura JT, Kim H, VanHoven MK, Thiele TR, Bonci A, Bargmann CI, McIntire SL. (2003) A central role of the BK potassium channel in behavioral responses to ethanol in C. elegans. Cell 115:655-66.

Dillon J, Andrianakis I, Mould R, Ient B, Liu W, James C, O'Connor V, Holden-Dye L. (2013) Distinct molecular targets including SLO-1 and gap junctions are engaged across a continuum of ethanol concentrations in Caenorhabditis elegans. FASEB J. 27:4266-78.

Kapfhamer D1, Bettinger JC, Davies AG, Eastman CL, Smail EA, Heberlein U, McIntire SL. (2008) Loss of RAB-3/A in Caenorhabditis elegans and the mouse affects behavioral response to ethanol .Genes Brain Behav. 7:669-76.

Mitchell PH, Bull K, Glautier S, Hopper NA, Holden-Dye L, O'Connor V. (2007) The concentration-dependent effects of ethanol on Caenorhabditis elegans behaviour. Pharmacogenomics J. 7:411-7.

Conflict of Interest:

We have published a relevant paper that has not been cited by the authors.