//Created by libAntimony v2.4 model novak_1993__environment(time_) // Variable initializations: time_ = ; end model novak_1993__rate_constants(k1AA, k3, kinh, kcak, kbPPase, kfPPase, khPPase, kd_antiIE, ka, kc, ke, kg, V2_, V2__, V25_, V25__, Vwee_, Vwee__, K_a, K_b, K_c, K_d, K_e, K_f, K_g, K_h, Cdc25_T, Cdc25_P, Wee1_P, Wee1_T, UbE_T, UbE, k25, kwee, k2) // Assignment Rules: k25 := V25_ * (Cdc25_T - Cdc25_P) + V25__ * Cdc25_P; kwee := Vwee_ * Wee1_P + Vwee__ * (Wee1_T - Wee1_P); k2 := V2_ * (UbE_T - UbE) + V2__ * UbE; // Variable initializations: k1AA = 0; k3 = 0.01; kinh = 0.025; kcak = 0.25; kbPPase = 0.125; kfPPase = 0.1; khPPase = 0.087; kd_antiIE = 0.095; ka = 0.01; kc = 0.1; ke = 0.0133; kg = 0.0065; V2_ = 0; V2__ = 0; V25_ = 0.1; V25__ = 2; Vwee_ = 0.1; Vwee__ = 1; K_a = 0.1; K_b = 0.1; K_c = 0.01; K_d = 0.01; K_e = 0.3; K_f = 0.3; K_g = 0.01; K_h = 0.01; Cdc25_T = ; Cdc25_P = ; Wee1_P = ; Wee1_T = ; UbE_T = ; UbE = ; end model novak_1993__concentration_variables(Cdc2_T, Cdc25_T, Wee1_T, IE_T, UbE_T) // Variable initializations: Cdc2_T = 100; Cdc25_T = 1; Wee1_T = 1; IE_T = 1; UbE_T = 1; end model novak_1993__cyclin(cyclin, k1AA, k2, k3, Cdc2, time_) // Rate Rules: cyclin' = (k1AA - k2 * cyclin) - k3 * cyclin * Cdc2; // Variable initializations: cyclin = 1; k1AA = ; k2 = ; k3 = ; Cdc2 = ; time_ = ; end model novak_1993__cyclin_Cdc2(cyclin_Cdc2, kinh, kwee, kcak, k25, k3, k2, MPF_active, Tyr15P_dimer, cyclin, Cdc2, time_) // Rate Rules: cyclin_Cdc2' = (kinh * MPF_active - (kwee + kcak + k2) * cyclin_Cdc2) + k25 * Tyr15P_dimer + k3 * cyclin * Cdc2; // Variable initializations: cyclin_Cdc2 = 0; kinh = ; kwee = ; kcak = ; k25 = ; k3 = ; k2 = ; MPF_active = ; Tyr15P_dimer = ; cyclin = ; Cdc2 = ; time_ = ; end model novak_1993__Tyr15P_dimer(Tyr15P_dimer, kwee, k25, kcak, k2, kinh, cyclin_Cdc2, MPF_pre, time_) // Rate Rules: Tyr15P_dimer' = (kwee * cyclin_Cdc2 - (k25 + kcak + k2) * Tyr15P_dimer) + kinh * MPF_pre; // Variable initializations: Tyr15P_dimer = 0; kwee = ; k25 = ; kcak = ; k2 = ; kinh = ; cyclin_Cdc2 = ; MPF_pre = ; time_ = ; end model novak_1993__MPF_pre(MPF_pre, kwee, kinh, k2, k25, kcak, MPF_active, Tyr15P_dimer, time_) // Rate Rules: MPF_pre' = (kwee * MPF_active - (kinh + k25 + k2) * MPF_pre) + kcak * Tyr15P_dimer; // Variable initializations: MPF_pre = 0; kwee = ; kinh = ; k2 = ; k25 = ; kcak = ; MPF_active = ; Tyr15P_dimer = ; time_ = ; end model novak_1993__MPF_active(MPF_active, kcak, kinh, kwee, k2, k25, cyclin_Cdc2, MPF_pre, time_) // Rate Rules: MPF_active' = (kcak * cyclin_Cdc2 - (kinh + kwee + k2) * MPF_active) + k25 * MPF_pre; // Variable initializations: MPF_active = 0; kcak = ; kinh = ; kwee = ; k2 = ; k25 = ; cyclin_Cdc2 = ; MPF_pre = ; time_ = ; end model novak_1993__Cdc2(Cdc2, Tyr15P_dimer, cyclin_Cdc2, MPF_active, MPF_pre, Cdc2_T) // Assignment Rules: Cdc2 := Cdc2_T - (cyclin_Cdc2 + MPF_active + MPF_pre + Tyr15P_dimer); // Variable initializations: Tyr15P_dimer = ; cyclin_Cdc2 = ; MPF_active = ; MPF_pre = ; Cdc2_T = ; end model novak_1993__cyclin_T(cyclin_T, cyclin, Tyr15P_dimer, cyclin_Cdc2, MPF_active, MPF_pre) // Assignment Rules: cyclin_T := cyclin + cyclin_Cdc2 + MPF_active + MPF_pre + Tyr15P_dimer; // Variable initializations: cyclin = ; Tyr15P_dimer = ; cyclin_Cdc2 = ; MPF_active = ; MPF_pre = ; end model novak_1993__Cdc25_P(Cdc25_P, ka, kbPPase, K_b, K_a, MPF_active, Cdc25_T, time_) // Rate Rules: Cdc25_P' = (ka * MPF_active * (Cdc25_T - Cdc25_P)) / ((K_a + Cdc25_T) - Cdc25_P) - (kbPPase * Cdc25_P) / (K_b + Cdc25_P); // Variable initializations: Cdc25_P = 0; ka = ; kbPPase = ; K_b = ; K_a = ; MPF_active = ; Cdc25_T = ; time_ = ; end model novak_1993__Wee1_P(Wee1_P, ke, kfPPase, K_e, K_f, MPF_active, Wee1_T, time_) // Rate Rules: Wee1_P' = (ke * MPF_active * (Wee1_T - Wee1_P)) / ((K_e + Wee1_T) - Wee1_P) - (kfPPase * Wee1_P) / (K_f + Wee1_P); // Variable initializations: Wee1_P = 0; ke = ; kfPPase = ; K_e = ; K_f = ; MPF_active = ; Wee1_T = ; time_ = ; end model novak_1993__IE_P(IE_P, kg, khPPase, K_g, K_h, MPF_active, IE_T, time_) // Rate Rules: IE_P' = (kg * MPF_active * (IE_T - IE_P)) / ((K_g + IE_T) - IE_P) - (khPPase * IE_P) / (K_h + IE_P); // Variable initializations: IE_P = 0; kg = ; khPPase = ; K_g = ; K_h = ; MPF_active = ; IE_T = ; time_ = ; end model novak_1993__UbE(UbE, kc, kd_antiIE, K_c, K_d, IE_P, UbE_T, time_) // Rate Rules: UbE' = (kc * IE_P * (UbE_T - UbE)) / ((K_c + UbE_T) - UbE) - (kd_antiIE * UbE) / (K_d + UbE); // Variable initializations: UbE = 0; kc = ; kd_antiIE = ; K_c = ; K_d = ; IE_P = ; UbE_T = ; time_ = ; end model *novak_1993____main() // Sub-modules, and any changes to those submodules: environment: novak_1993__environment(time_); rate_constants: novak_1993__rate_constants(k1AA, k3, kinh, kcak, kbPPase, kfPPase, khPPase, kd_antiIE, ka, kc, ke, kg, V2_, V2__, V25_, V25__, Vwee_, Vwee__, K_a, K_b, K_c, K_d, K_e, K_f, K_g, K_h, Cdc25_T, Cdc25_P0, Wee1_P0, Wee1_T, UbE_T, UbE0, k25, kwee, k2); concentration_variables: novak_1993__concentration_variables(Cdc2_T, Cdc25_T, Wee1_T, IE_T, UbE_T); cyclin: novak_1993__cyclin(cyclin0, k1AA, k2, k3, Cdc20, time_); cyclin_Cdc2: novak_1993__cyclin_Cdc2(cyclin_Cdc20, kinh, kwee, kcak, k25, k3, k2, MPF_active0, Tyr15P_dimer0, cyclin0, Cdc20, time_); Tyr15P_dimer: novak_1993__Tyr15P_dimer(Tyr15P_dimer0, kwee, k25, kcak, k2, kinh, cyclin_Cdc20, MPF_pre0, time_); MPF_pre: novak_1993__MPF_pre(MPF_pre0, kwee, kinh, k2, k25, kcak, MPF_active0, Tyr15P_dimer0, time_); MPF_active: novak_1993__MPF_active(MPF_active0, kcak, kinh, kwee, k2, k25, cyclin_Cdc20, MPF_pre0, time_); Cdc2: novak_1993__Cdc2(Cdc20, Tyr15P_dimer0, cyclin_Cdc20, MPF_active0, MPF_pre0, Cdc2_T); cyclin_T: novak_1993__cyclin_T(cyclin_T0, cyclin0, Tyr15P_dimer0, cyclin_Cdc20, MPF_active0, MPF_pre0); Cdc25_P: novak_1993__Cdc25_P(Cdc25_P0, ka, kbPPase, K_b, K_a, MPF_active0, Cdc25_T, time_); Wee1_P: novak_1993__Wee1_P(Wee1_P0, ke, kfPPase, K_e, K_f, MPF_active0, Wee1_T, time_); IE_P: novak_1993__IE_P(IE_P0, kg, khPPase, K_g, K_h, MPF_active0, IE_T, time_); UbE: novak_1993__UbE(UbE0, kc, kd_antiIE, K_c, K_d, IE_P0, UbE_T, time_); end