TY - JOUR
T1 - Amplitude histogram-based method of analysis of patch clamp recordings that involve extreme changes in channel activity levels
AU - Yakubovich, Daniel
AU - Rishal, Ida
AU - Dessauer, Carmen W.
AU - Dascal, Nathan
N1 - Funding Information:
Acknowledgments This work was supported by grants from NIH [GM68493 (N.D.) and GM60419 (C.W.D.)] and US–Israel Binational Science Foundation (01-122, N.D. and C.W.D). The authors report no conflicts of interest.
PY - 2009/3
Y1 - 2009/3
N2 - Many ion channels show low basal activity, which is increased hundreds-fold by the relevant gating factor. A classical example is the activation G-protein-activated K+ channels (GIRK) by Gβγ subunit dimer. The extent of activation (relative to basal current), R a, is an important physiological parameter, usually readily estimated from whole cell recordings. However, calculation of R a often becomes non-trivial in multi-channel patches because of extreme changes in activity upon activation, from a seemingly single-channel pattern to a macroscopic one. In such cases, calculation of the net current flowing through the channels in the patch, Ī, before and after activation may require different methods of analysis. To address this problem, we utilized neuronal GIRK channels activated by purified Gβγ in excised patches of Xenopus oocytes. Channels were expressed at varying densities, from a few to several hundreds per patch. We present a simple and fast method of calculating Ī using amplitude histogram analysis and establish its accuracy by comparing with Ī calculated from event lists. This method allows the analysis of extreme changes in Ī in multichannel patches, which would be impossible using the standard methods of idealization and event list generation.
AB - Many ion channels show low basal activity, which is increased hundreds-fold by the relevant gating factor. A classical example is the activation G-protein-activated K+ channels (GIRK) by Gβγ subunit dimer. The extent of activation (relative to basal current), R a, is an important physiological parameter, usually readily estimated from whole cell recordings. However, calculation of R a often becomes non-trivial in multi-channel patches because of extreme changes in activity upon activation, from a seemingly single-channel pattern to a macroscopic one. In such cases, calculation of the net current flowing through the channels in the patch, Ī, before and after activation may require different methods of analysis. To address this problem, we utilized neuronal GIRK channels activated by purified Gβγ in excised patches of Xenopus oocytes. Channels were expressed at varying densities, from a few to several hundreds per patch. We present a simple and fast method of calculating Ī using amplitude histogram analysis and establish its accuracy by comparing with Ī calculated from event lists. This method allows the analysis of extreme changes in Ī in multichannel patches, which would be impossible using the standard methods of idealization and event list generation.
KW - Amplitude histogram
KW - G protein
KW - Ion channel
KW - Kir3
KW - Patch clamp
UR - http://www.scopus.com/inward/record.url?scp=62149096510&partnerID=8YFLogxK
U2 - 10.1007/s12031-008-9117-z
DO - 10.1007/s12031-008-9117-z
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C2 - 18622586
AN - SCOPUS:62149096510
SN - 0895-8696
VL - 37
SP - 201
EP - 211
JO - Journal of Molecular Neuroscience
JF - Journal of Molecular Neuroscience
IS - 3
ER -