Cerebellum granule cell FHF (Dover et al. 2016)

 Download zip file   Auto-launch 
Help downloading and running models
Accession:206267
"Neurons in vertebrate central nervous systems initiate and conduct sodium action potentials in distinct subcellular compartments that differ architecturally and electrically. Here, we report several unanticipated passive and active properties of the cerebellar granule cell's unmyelinated axon. Whereas spike initiation at the axon initial segment relies on sodium channel (Nav)-associated fibroblast growth factor homologous factor (FHF) proteins to delay Nav inactivation, distal axonal Navs show little FHF association or FHF requirement for high-frequency transmission, velocity and waveforms of conducting action potentials. ...'
Reference:
1 . Dover K, Marra C, Solinas S, Popovic M, Subramaniyam S, Zecevic D, D'Angelo E, Goldfarb M (2016) FHF-independent conduction of action potentials along the leak-resistant cerebellar granule cell axon. Nat Commun 7:12895 [PubMed]
Model Information (Click on a link to find other models with that property)
Model Type: Axon; Dendrite;
Brain Region(s)/Organism: Cerebellum;
Cell Type(s): Cerebellum interneuron granule cell;
Channel(s): I A; I Calcium; I K; I K,Ca; I M; I Na,p; I Na,t; I Potassium; I Sodium; Kir;
Gap Junctions:
Receptor(s): AMPA; Gaba; NMDA;
Gene(s):
Transmitter(s):
Simulation Environment: NEURON;
Model Concept(s):
Implementer(s): Solinas, Sergio [solinas at unipv.it]; Subramaniyam, Sathyaa [sakthisathyaa at gmail.com]; D'Angelo, Egidio [dangelo at unipv.it]; Goldfarb, Mitchell goldfarb at genectr.hunter.cuny.edu];
Search NeuronDB for information about:  Cerebellum interneuron granule cell; AMPA; NMDA; Gaba; I Na,p; I Na,t; I A; I K; I M; I K,Ca; I Sodium; I Calcium; I Potassium; Kir;
/
GrC_FHF_ModelDB
images
README.html
AmpaCOD.mod
GRC_CA.mod *
GRC_CALC.mod *
GRC_GABA.mod *
GRC_KA.mod *
GRC_KCA.mod *
GRC_KIR.mod *
GRC_KM.mod
GRC_KV.mod *
GRC_LKG1.mod *
GRC_LKG2.mod *
GRC_LKG3.mod
GRC_NA.mod
Grc_sine.mod
NmdaS.mod
Pregen.mod *
CClamp_soma.ses
ComPanel.hoc
Fig5.ses
Grc_Cell.hoc
helper_procedures.hoc
Ina.ses
KOFHF.DAPF.slowalfabeta.REV5.30.2016.ses
modComPanel.hoc
mosinit.hoc
Parametri.hoc
Start.hoc
WTFHF.DAPF.slowalfabeta.REV5.30.2016.ses
                            
TITLE Cerebellum Granule Cell Model

COMMENT
        KA channel
   
	Author: E.D'Angelo, T.Nieus, A. Fontana
	Last revised: Egidio 3.12.2003
ENDCOMMENT

NEURON { 
	SUFFIX GRC_KA
	USEION k READ ek WRITE ik 
	RANGE gkbar, ik, g, alpha_a, beta_a, alpha_b, beta_b
	RANGE Aalpha_a, Kalpha_a, V0alpha_a
	RANGE Abeta_a, Kbeta_a, V0beta_a
	RANGE Aalpha_b, Kalpha_b, V0alpha_b
	RANGE Abeta_b, Kbeta_b, V0beta_b
	RANGE V0_ainf, K_ainf, V0_binf, K_binf
	RANGE a_inf, tau_a, b_inf, tau_b 
} 
 
UNITS { 
	(mA) = (milliamp) 
	(mV) = (millivolt) 
} 
 
PARAMETER { 
	Aalpha_a = 0.8147 (/ms) :4.88826
	Kalpha_a = -23.32708 (mV)
	V0alpha_a = -9.17203 (mV)
	Abeta_a = 0.1655 (/ms)   : 0.99285	
	Kbeta_a = 19.47175 (mV)
	V0beta_a = -18.27914 (mV)

	Aalpha_b = 0.0368 (/ms)  : 0.11042 
	Kalpha_b = 12.8433 (mV)
	V0alpha_b = -111.33209 (mV)   
	Abeta_b = 0.0345(/ms)   : 0.10353 
	Kbeta_b = -8.90123 (mV)
	V0beta_b = -49.9537 (mV)

	V0_ainf = -38(mV)
	K_ainf = -17(mV)

	V0_binf = -78.8 (mV)
	K_binf = 8.4 (mV)
	v (mV) 
	gkbar= 0.0032 (mho/cm2) :0.003 
	ek = -84.69 (mV) 
	celsius = 30 (degC) 
} 

STATE { 
	a
	b 
} 

ASSIGNED { 
	ik (mA/cm2) 
	a_inf 
	b_inf 
	tau_a (ms) 
	tau_b (ms) 
	g (mho/cm2) 
	alpha_a (/ms)
	beta_a (/ms)
	alpha_b (/ms)
	beta_b (/ms)
} 
 
INITIAL { 
	rate(v) 
	a = a_inf 
	b = b_inf 
} 
 
BREAKPOINT { 
	SOLVE states METHOD derivimplicit 
	g = gkbar*a*a*a*b 
	ik = g*(v - ek)
	alpha_a = alp_a(v)
	beta_a = bet_a(v) 
	alpha_b = alp_b(v)
	beta_b = bet_b(v) 
} 
 
DERIVATIVE states { 
	rate(v) 
	a' =(a_inf - a)/tau_a 
	b' =(b_inf - b)/tau_b 
} 
 
FUNCTION alp_a(v(mV))(/ms) { LOCAL Q10
	Q10 = 3^((celsius-25.5(degC))/10(degC))
:	alp_a = Q10*Aalpha_a*exp(Kalpha_a*(v-V0alpha_a)) 
:	alp_a = -0.04148(/mV-ms)*linoid(v+67.697(mV),-3.857(mV))
	alp_a = Q10*Aalpha_a*sigm(v-V0alpha_a,Kalpha_a)
} 
 
FUNCTION bet_a(v(mV))(/ms) { LOCAL Q10
	Q10 = 3^((celsius-25.5(degC))/10(degC))
:	bet_a = Q10*Abeta_a*exp(Kbeta_a*(v-V0beta_a)) 
:	bet_a = 0.0359(/mV-ms)*linoid(v+45.878(mV),23.654(mV))
	bet_a = Q10*Abeta_a/(exp((v-V0beta_a)/Kbeta_a))
} 
 
FUNCTION alp_b(v(mV))(/ms) { LOCAL Q10
	Q10 = 3^((celsius-25.5(degC))/10(degC))
:	alp_b = Q10*Aalpha_b*exp(Kalpha_b*(v-V0alpha_b)) 
:	alp_b = 0.356(/mV-ms)*linoid(v+231.03(mV),17.8(mV))
	alp_b = Q10*Aalpha_b*sigm(v-V0alpha_b,Kalpha_b)
} 
 
FUNCTION bet_b(v(mV))(/ms) { LOCAL Q10
	Q10 = 3^((celsius-25.5(degC))/10(degC))
:	bet_b = Q10*Abeta_b*exp(Kbeta_b*(v-V0beta_b)) 
:	bet_b = -0.00825(/mV-ms)*linoid(v+43.284(mV),-8.927(mV))
	bet_b = Q10*Abeta_b*sigm(v-V0beta_b,Kbeta_b)
} 
 
PROCEDURE rate(v (mV)) {LOCAL a_a, b_a, a_b, b_b 
	TABLE a_inf, tau_a, b_inf, tau_b 
	DEPEND Aalpha_a, Kalpha_a, V0alpha_a, 
	       Abeta_a, Kbeta_a, V0beta_a,
               Aalpha_b, Kalpha_b, V0alpha_b,
               Abeta_b, Kbeta_b, V0beta_b, celsius FROM -100 TO 30 WITH 13000 
	a_a = alp_a(v)  
	b_a = bet_a(v) 
	a_b = alp_b(v)  
	b_b = bet_b(v) 
	a_inf = 1/(1+exp((v-V0_ainf)/K_ainf)) 
	tau_a = 1/(a_a + b_a) 
	b_inf = 1/(1+exp((v-V0_binf)/K_binf))
	tau_b = 1/(a_b + b_b) 
: Bardoni Belluzzi data
:	a_inf = 1/(1+exp(-(v+46.7)/19.8))
:	tau_a = 0.41*exp(-(v+43.5)/42.8)+0.167
:	b_inf = 1/(1+exp((v+78.8)/8.4))
:	tau_b = 10.8 + 0.03*v + 1/(57.9*exp(0.127*v)+0.000134*exp(-0.059*v))
}

FUNCTION linoid(x (mV),y (mV)) (mV) {
        if (fabs(x/y) < 1e-6) {
                linoid = y*(1 - x/y/2)
        }else{
                linoid = x/(exp(x/y) - 1)
        }
} 

FUNCTION sigm(x (mV),y (mV)) {
                sigm = 1/(exp(x/y) + 1)
}

Loading data, please wait...