: $Id: gabab.mod,v 1.9 2004/06/17 16:04:05 billl Exp $ COMMENT ----------------------------------------------------------------------------- Kinetic model of GABA-B receptors ================================= MODEL OF SECOND-ORDER G-PROTEIN TRANSDUCTION AND FAST K+ OPENING WITH COOPERATIVITY OF G-PROTEIN BINDING TO K+ CHANNEL PULSE OF TRANSMITTER SIMPLE KINETICS WITH NO DESENSITIZATION Features: - peak at 100 ms; time course fit to Tom Otis' PSC - SUMMATION (psc is much stronger with bursts) Approximations: - single binding site on receptor - model of alpha G-protein activation (direct) of K+ channel - G-protein dynamics is second-order; simplified as follows: - saturating receptor - no desensitization - Michaelis-Menten of receptor for G-protein production - "resting" G-protein is in excess - Quasi-stat of intermediate enzymatic forms - binding on K+ channel is fast Kinetic Equations: dR/dt = K1 * T * (1-R-D) - K2 * R dG/dt = K3 * R - K4 * G R : activated receptor T : transmitter G : activated G-protein K1,K2,K3,K4 = kinetic rate cst n activated G-protein bind to a K+ channel: n G + C <-> O (Alpha,Beta) If the binding is fast, the fraction of open channels is given by: O = G^n / ( G^n + KD ) where KD = Beta / Alpha is the dissociation constant ----------------------------------------------------------------------------- Parameters estimated from patch clamp recordings of GABAB PSP's in rat hippocampal slices (Otis et al, J. Physiol. 463: 391-407, 1993). ----------------------------------------------------------------------------- PULSE MECHANISM Kinetic synapse with release mechanism as a pulse. Warning: for this mechanism to be equivalent to the model with diffusion of transmitter, small pulses must be used... For a detailed model of GABAB: Destexhe, A. and Sejnowski, T.J. G-protein activation kinetics and spill-over of GABA may account for differences between inhibitory responses in the hippocampus and thalamus. Proc. Natl. Acad. Sci. USA 92: 9515-9519, 1995. For a review of models of synaptic currents: Destexhe, A., Mainen, Z.F. and Sejnowski, T.J. Kinetic models of synaptic transmission. In: Methods in Neuronal Modeling (2nd edition; edited by Koch, C. and Segev, I.), MIT press, Cambridge, 1996. This simplified model was introduced in: Destexhe, A., Bal, T., McCormick, D.A. and Sejnowski, T.J. Ionic mechanisms underlying synchronized oscillations and propagating waves in a model of ferret thalamic slices. Journal of Neurophysiology 76: 2049-2070, 1996. See also http://www.cnl.salk.edu/~alain Alain Destexhe, Salk Institute and Laval University, 1995 ----------------------------------------------------------------------------- ENDCOMMENT INDEPENDENT {t FROM 0 TO 1 WITH 1 (ms)} NEURON { POINT_PROCESS GABAB RANGE R, G, g, gmax NONSPECIFIC_CURRENT i GLOBAL Cmax, Cdur GLOBAL K1, K2, K3, K4, KD, Erev } UNITS { (nA) = (nanoamp) (mV) = (millivolt) (umho) = (micromho) (mM) = (milli/liter) } PARAMETER { gmax = 0.0001 (uS) Cmax = 0.5 (mM) : max transmitter concentration Cdur = 0.3 (ms) : transmitter duration (rising phase) : : From Kfit with long pulse (5ms 0.5mM) : K1 = 0.52 (/ms mM) : forward binding rate to receptor K2 = 0.0013 (/ms) : backward (unbinding) rate of receptor K3 = 0.098 (/ms) : rate of G-protein production K4 = 0.033 (/ms) : rate of G-protein decay KD = 100 : dissociation constant of K+ channel n = 4 : nb of binding sites of G-protein on K+ Erev = -95 (mV) : reversal potential (E_K) } ASSIGNED { v (mV) : postsynaptic voltage i (nA) : current = g*(v - Erev) g (umho) : conductance Gn R : fraction of activated receptor edc synon Rinf Rtau (ms) Beta (/ms) } STATE { Ron Roff G : fraction of activated G-protein } INITIAL { R = 0 G = 0 synon = 0 Rinf = K1*Cmax/(K1*Cmax + K2) Rtau = 1/(K1*Cmax + K2) Beta = K2 } BREAKPOINT { SOLVE bindkin METHOD cnexp Gn = G*G*G*G : ^n = 4 g = gmax * Gn / (Gn+KD) i = g*(v - Erev) } DERIVATIVE bindkin { Ron' = synon*K1*Cmax - (K1*Cmax + K2)*Ron Roff' = -K2*Roff R = Ron + Roff G' = K3 * R - K4 * G } : following supports both saturation from single input and : summation from multiple inputs : Note: automatic initialization of all reference args to 0 : except first NET_RECEIVE(weight, r0, t0 (ms)) { if (flag == 1) { : at end of Cdur pulse so turn off r0 = weight*(Rinf + (r0 - Rinf)*exp(-(t - t0)/Rtau)) t0 = t synon = synon - weight state_discontinuity(Ron, Ron - r0) state_discontinuity(Roff, Roff + r0) }else{ : at beginning of Cdur pulse so turn on r0 = weight*r0*exp(-Beta*(t - t0)) t0 = t synon = synon + weight state_discontinuity(Ron, Ron + r0) state_discontinuity(Roff, Roff - r0) :come again in Cdur net_send(Cdur, 1) } }