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schliemann1

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schliemann1

The SBML for this model was obtained from the BioModels database (BioModels ID: BIOMD0000000407) Biomodels notes: The parameter scan for Caspase-3 and NF-kB with TNF ranging from 0.01ng/ml to 100ng/ml is shown in figure 3A of the reference published, and this has been reproduced here. The units in the model are in microMolar. So, the parameter scan was done with TNF ranging from 3.90625e-07microMolar (=0.01ng/ml) to 0.00390625microMolar (=100ng/ml). The plot shows the parameter scan done for 4 different values of TNF (0.0002, 0.00130234, 0.0026043 and 00390625).The model was integrated and simulated using Copasi v4.7 (Build 34). JWS Online curation: This model was curated by reproducing the figures as described in the BioModels Notes. No additional changes were made.

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Manuscript information

Heterogeneity reduces sensitivity of cell death for TNF-stimuli.

  • Monica Schliemann
  • Eric Bullinger
  • Steffen Borchers
  • Frank Allgöwer
  • Rolf Findeisen
  • Peter Scheurich
BMC Syst Biol 2011; 5 : 204
Abstract
BACKGROUND: Apoptosis is a form of programmed cell death essential for the maintenance of homeostasis and the removal of potentially damaged cells in multicellular organisms. By binding its cognate membrane receptor, TNF receptor type 1 (TNF-R1), the proinflammatory cytokine Tumor Necrosis Factor (TNF) activates pro-apoptotic signaling via caspase activation, but at the same time also stimulates nuclear factor κB (NF-κB)-mediated survival pathways. Differential dose-response relationships of these two major TNF signaling pathways have been described experimentally and using mathematical modeling. However, the quantitative analysis of the complex interplay between pro- and anti-apoptotic signaling pathways is an open question as it is challenging for several reasons: the overall signaling network is complex, various time scales are present, and cells respond quantitatively and qualitatively in a heterogeneous manner.
RESULTS: This study analyzes the complex interplay of the crosstalk of TNF-R1 induced pro- and anti-apoptotic signaling pathways based on an experimentally validated mathematical model. The mathematical model describes the temporal responses on both the single cell level as well as the level of a heterogeneous cell population, as observed in the respective quantitative experiments using TNF-R1 stimuli of different strengths and durations. Global sensitivity of the heterogeneous population was quantified by measuring the average gradient of time of death versus each population parameter. This global sensitivity analysis uncovers the concentrations of Caspase-8 and Caspase-3, and their respective inhibitors BAR and XIAP, as key elements for deciding the cell's fate. A simulated knockout of the NF-κB-mediated anti-apoptotic signaling reveals the importance of this pathway for delaying the time of death, reducing the death rate in the case of pulse stimulation and significantly increasing cell-to-cell variability.
CONCLUSIONS: Cell ensemble modeling of a heterogeneous cell population including a global sensitivity analysis presented here allowed us to illuminate the role of the different elements and parameters on apoptotic signaling. The receptors serve to transmit the external stimulus; procaspases and their inhibitors control the switching from life to death, while NF-κB enhances the heterogeneity of the cell population. The global sensitivity analysis of the cell population model further revealed an unexpected impact of heterogeneity, i.e. the reduction of parametric sensitivity.

Unit definitions 6

Unit definitions have no effect on the numerical analysis of the model. It remains the responsibility of the modeler to ensure the internal numerical consistency of the model. If units are provided, however, the consistency of the model units will be checked.

Name Definition
1e-18 mole
1.0 second^(-1.0)
1e-12 litre
1e-18 mole second^(-1.0)
1e+18 mole^(-1.0) second^(-1.0)
1e+36 mole^(-2.0) second^(-1.0)

Compartments 3

Id Name Spatial dimensions Size
cytoplasm 3.0 3.2 pl
extracellular 3.0 1344.0 pl
nucleus 3.0 1.056 pl

Species 47

Id Name Initial quantity Compartment Fixed
A20 A20 0.104434 a_mole cytoplasm
A20_mRNA A20_mRNA 5.56657e-05 a_mole nucleus
BAR BAR 0.28789 a_mole cytoplasm
BAR_Casp8 BAR:Casp8 0.0 a_mole cytoplasm
Casp3 Casp3 0.0 a_mole cytoplasm
Casp6 Casp6 0.0 a_mole cytoplasm
Casp8 Casp8 0.0 a_mole cytoplasm
FADD FADD 0.30944 a_mole cytoplasm
FLIP FLIP 0.0320472 a_mole cytoplasm
FLIP_mRNA FLIP_mRNA 0.000139056 a_mole nucleus
IKK IKK 0.64 a_mole cytoplasm
IKKa IKKa 0.0 a_mole cytoplasm
IkBa IkBa 0.00101518 a_mole cytoplasm
IkBa_N IkBa_N 0.0013839 a_mole nucleus
IkBa_NFkB IkBa:NFkB 0.0151032 a_mole cytoplasm
IkBa_NFkB_N IkBa:NFkB_N 9.00189e-05 a_mole nucleus
IkBa_mRNA IkBa_mRNA 5.31517e-05 a_mole nucleus
NFkB NFkB 0.000115365 a_mole cytoplasm
NFkB_N NFkB_N 0.000691431 a_mole nucleus
PARP PARP 1.66667 a_mole cytoplasm
PIkBa PIkBa 0.0 a_mole cytoplasm
RIP RIP 0.20256 a_mole cytoplasm
TNFR TNFR 0.00028 a_mole cytoplasm
TNFRC1 TNFRC1 0.0 a_mole cytoplasm
TNFRC2 TNFRC2 0.0 a_mole cytoplasm
TNFRC2_FLIP TNFRC2:FLIP 0.0 a_mole cytoplasm
TNFRC2_FLIP_FLIP TNFRC2:FLIP:FLIP 0.0 a_mole cytoplasm
TNFRC2_FLIP_pCasp8 TNFRC2:FLIP:pCasp8 0.0 a_mole cytoplasm
TNFRC2_FLIP_pCasp8_RIP_TRAF2 TNFRC2:FLIP:pCasp8:RIP:TRAF2 0.0 a_mole cytoplasm
TNFRC2_pCasp8 TNFRC2:pCasp8 0.0 a_mole cytoplasm
TNFRC2_pCasp8_pCasp8 TNFRC2:pCasp8:pCasp8 0.0 a_mole cytoplasm
TNFRCint1 TNFRCint1 0.0 a_mole cytoplasm
TNFRCint2 TNFRCint2 0.0 a_mole cytoplasm
TNFRCint3 TNFRCint3 0.0 a_mole cytoplasm
TNFR_E TNFR_E 0.005 a_mole extracellular
TNF_E TNF_E 0.2688 a_mole extracellular
TNF_TNFR_E TNF:TNFR_E 0.0 a_mole extracellular
TNF_TNFR_TRADD TNF:TNFR:TRADD 0.0 a_mole cytoplasm
TRADD TRADD 0.29344 a_mole cytoplasm
TRAF2 TRAF2 0.33056 a_mole cytoplasm
XIAP XIAP 7.83371 a_mole cytoplasm
XIAP_Casp3 XIAP:Casp3 0.0 a_mole cytoplasm
XIAP_mRNA XIAP_mRNA 0.000219646 a_mole nucleus
cPARP cPARP 0.0 a_mole cytoplasm
pCasp3 pCasp3 0.8 a_mole cytoplasm
pCasp6 pCasp6 0.064 a_mole cytoplasm
pCasp8 pCasp8 3.2 a_mole cytoplasm

Initial assignments 0

Initial assignments are expressions that are evaluated at time=0. It is not recommended to create initial assignments for all model entities. Restrict the use of initial assignments to cases where a value is expressed in terms of values or sizes of other model entities. Note that it is not permitted to have both an initial assignment and an assignment rule for a single model entity.

Definition
Reactions 88
Id Name Objective coefficient Reaction Equation and Kinetic Law Flux bounds
J1 TNFR transport into membrane TNFR > TNFR_E

ka_1 * TNFR
J10 TNFR Complex1 degradation TNFRC1 > ∅

ka_10 * TNFRC1
J11 TNFR Complex2 degradation TNFRC2 > ∅

ka_11 * TNFRC2
J12 TNFR Complex2~FLIP degradation TNFRC2_FLIP > ∅

ka_12 * TNFRC2_FLIP
J13 TNFR Complex2~FLIP~FLIP degradation TNFRC2_FLIP_FLIP > ∅

ka_13 * TNFRC2_FLIP_FLIP
J14 TNFR Complex2~Procaspase-8 degradation TNFRC2_pCasp8 > ∅

ka_14 * TNFRC2_pCasp8
J15 TNFR Complex2~Procaspase-8~Procaspase-8 degradation TNFRC2_pCasp8_pCasp8 > ∅

ka_15 * TNFRC2_pCasp8_pCasp8
J16 TNFR Complex2~FLIP~Procaspase-8 degradation TNFRC2_FLIP_pCasp8 > ∅

ka_16 * TNFRC2_FLIP_pCasp8
J17 TNFR Complex2~FLIP~Procaspase-8~RIP~TRAF2 degradation TNFRC2_FLIP_pCasp8_RIP_TRAF2 > ∅

ka_17 * TNFRC2_FLIP_pCasp8_RIP_TRAF2
J18 TNF~TNFR binding and release TNFR_E + TNF_E = TNF_TNFR_E

ka_18 * TNFR_E * TNF_E - kd_18 * TNF_TNFR_E
J19 TNF~TNFR~TRADD building TNF_TNFR_E + TRADD > TNF_TNFR_TRADD

ka_19 * TNF_TNFR_E * TRADD
J2 TNFR production ∅ > TNFR

ka_2
J20 TNFR Complex1 building RIP + TRAF2 + TNF_TNFR_TRADD > TNFRC1

ka_20 * RIP * TRAF2 * TNF_TNFR_TRADD
J21 Receptor internalisation step1 TNFRC1 > TNFRCint1

ka_21 * TNFRC1
J22 Receptor internalisation step2 TNFRCint1 > RIP + TRAF2 + TNFRCint2

ka_22 * TNFRCint1
J23 Receptor internalisation step3 {2.0}FADD + TNFRCint2 > TNFRCint3

ka_23 * pow(FADD, 2) * TNFRCint2
J24 Receptor internalisation step4 TNFRCint3 > TNFRC2

ka_24 * TNFRCint3
J25 FLIP recruitment to TNFR Complex2 TNFRC2 + FLIP > TNFRC2_FLIP

ka_25 * TNFRC2 * FLIP
J26 FLIP recruitment to TNFR Complex2~FLIP FLIP + TNFRC2_FLIP > TNFRC2_FLIP_FLIP

ka_26 * FLIP * TNFRC2_FLIP
J27 Procaspase-8 recruitment to TNFR Complex2 TNFRC2 + pCasp8 > TNFRC2_pCasp8

ka_27 * TNFRC2 * pCasp8
J28 Procaspase-8 recruitment to TNFR Complex2~Procaspase-8 TNFRC2_pCasp8 + pCasp8 > TNFRC2_pCasp8_pCasp8

ka_28 * TNFRC2_pCasp8 * pCasp8
J29 Caspase-8 activation by TNFR Complex2 TNFRC2_pCasp8_pCasp8 > TNFRC2 + Casp8

ka_29 * TNFRC2_pCasp8_pCasp8
J3 TNFR degradation TNFR_E > ∅

ka_3 * TNFR_E
J30 FLIP recruitment to TNFR Complex2~Procaspase-8 FLIP + TNFRC2_pCasp8 > TNFRC2_FLIP_pCasp8

ka_30 * FLIP * TNFRC2_pCasp8
J31 Procaspase-8 recruitment to TNFR Complex2~FLIP TNFRC2_FLIP + pCasp8 > TNFRC2_FLIP_pCasp8

ka_31 * TNFRC2_FLIP * pCasp8
J32 Caspase-8 activation by TNFR Complex2~FLIP~Procaspase-8 TNFRC2_FLIP_pCasp8 > TNFRC2 + Casp8

ka_32 * TNFRC2_FLIP_pCasp8
J33 RIP~TRAF2 recruitment at TNFR Complex2~FLIP~Procaspase-8 RIP + TRAF2 + TNFRC2_FLIP_pCasp8 > TNFRC2_FLIP_pCasp8_RIP_TRAF2

ka_33 * RIP * TRAF2 * TNFRC2_FLIP_pCasp8
J34 IKK activation by TNFR Complex2~FLIP~Procaspase-8~RIP~TRAF2 IKK > IKKa

ka_34 * TNFRC2_FLIP_pCasp8_RIP_TRAF2 * IKK
J35 IKK turnover ∅ = IKK

ka_35 - kd_35 * IKK
J36 NF-kappaB turnover ∅ = NFkB

ka_36 - kd_36 * NFkB
J37 FLIP turnover ∅ = FLIP

ka_37 - kd_37 * FLIP
J38 XIAP turnover ∅ = XIAP

ka_38 - kd_38 * XIAP
J39 A20 turnover ∅ = A20

ka_39 - kd_39 * A20
J4 RIP turnover ∅ = RIP

ka_4 - kd_4 * RIP
J40 IKK* degradation IKKa > ∅

ka_40 * IKKa
J41 IkappaBalpha~NF-kappaB complex degradation IkBa_NFkB > ∅

ka_41 * IkBa_NFkB
J42 nuclear NF-kappaB degradation NFkB_N > ∅

ka_42 * NFkB_N
J43 IkappaBalpha-mRNA degradation IkBa_mRNA > ∅

ka_43 * IkBa_mRNA
J44 IkappaBalpha degradation IkBa > ∅

ka_44 * IkBa
J45 free nuclear IkappaBalpha degradation IkBa_N > ∅

ka_45 * IkBa_N
J46 nuclear IkappaBalpha~NF-kappaB complex degradation IkBa_NFkB_N > ∅

ka_46 * IkBa_NFkB_N
J47 P-IkappaBa degradation PIkBa > ∅

ka_47 * PIkBa
J48 A20-mRNA degradation A20_mRNA > ∅

ka_48 * A20_mRNA
J49 XIAP-mRNA degradation XIAP_mRNA > ∅

ka_49 * XIAP_mRNA
J5 TRADD turnover ∅ = TRADD

ka_5 - kd_5 * TRADD
J50 FLIP-mRNA degradation FLIP_mRNA > ∅

ka_50 * FLIP_mRNA
J51 IKK activation by TNFR Complex1 IKK > IKKa

ka_51 * TNFRC1 * IKK
J52 IKK* inactivation IKKa > IKK

ka_52 * IKKa
J53 TNFR Complex1 inactivation by A20 TNFRC1 > TRAF2 + TNF_TNFR_TRADD

ka_53 * TNFRC1 * A20
J54 IkappaBalpha NF-kappaB association NFkB + IkBa > IkBa_NFkB

ka_54 * NFkB * IkBa
J55 release and degradation of bound IkappaBalpha IkBa_NFkB > NFkB + PIkBa

ka_55 * IKKa * IkBa_NFkB
J56 NF-kappaB nuclear translocation NFkB > NFkB_N

ka_56 * NFkB
J57 IkappaBalpha-mRNA transcription ∅ > IkBa_mRNA

ka_57 * NFkB_N
J58 IkappaBalpha translation ∅ > IkBa

ka_58 * IkBa_mRNA
J59 IkappaBalpha nuclear translocation IkBa = IkBa_N

ka_59 * IkBa - kd_59 * IkBa_N
J6 TRAF2 turnover ∅ = TRAF2

ka_6 - kd_6 * TRAF2
J60 IkappaBalpha binding NF-kappaB in nucleus NFkB_N + IkBa_N > IkBa_NFkB_N

ka_60 * NFkB_N * IkBa_N
J61 IkappaBalpha_NF-kappaB N-C export IkBa_NFkB_N > IkBa_NFkB

ka_61 * IkBa_NFkB_N
J62 A20-mRNA transcription ∅ > A20_mRNA

ka_62 * NFkB_N
J63 A20 translation ∅ > A20

ka_63 * A20_mRNA
J64 XIAP-mRNA transcription ∅ > XIAP_mRNA

ka_64 * NFkB_N
J65 XIAP translation ∅ > XIAP

ka_65 * XIAP_mRNA
J66 FLIP-mRNA transcription ∅ > FLIP_mRNA

ka_66 * NFkB_N
J67 FLIP translation ∅ > FLIP

ka_67 * FLIP_mRNA
J68 Procaspase-8 turnover ∅ = pCasp8

ka_68 - kd_68 * pCasp8
J69 Procaspase-3 turnover ∅ = pCasp3

ka_69 - kd_69 * pCasp3
J7 FADD turnover ∅ = FADD

ka_7 - kd_7 * FADD
J70 Procaspase-6 turnover ∅ = pCasp6

ka_70 - kd_70 * pCasp6
J71 Caspase-8 degradation Casp8 > ∅

ka_71 * Casp8
J72 Caspase-3 degradation Casp3 > ∅

ka_72 * Casp3
J73 Caspase-6 degradation Casp6 > ∅

ka_73 * Casp6
J74 XIAP~Caspase-3 complex degradation XIAP_Casp3 > ∅

ka_74 * XIAP_Casp3
J75 BAR turnover ∅ = BAR

ka_75 - kd_75 * BAR
J76 BAR~Caspase-8 complex degradation BAR_Casp8 > ∅

ka_76 * BAR_Casp8
J77 PARP turnover PARP = ∅

ka_77 * PARP - kd_77
J78 CPARP degradation cPARP > ∅

ka_78 * cPARP
J79 Caspase-3 activation pCasp3 > Casp3

ka_79 * pCasp3 * Casp8
J8 TNF~TNFR degradation TNF_TNFR_E > ∅

ka_8 * TNF_TNFR_E
J80 Caspase-6 activation pCasp6 > Casp6

ka_80 * pCasp6 * Casp3
J81 Caspase-8 activation pCasp8 > Casp8

ka_81 * pCasp8 * Casp6
J82 XIAP~Caspase-3 complex formation XIAP + Casp3 = XIAP_Casp3

ka_82 * XIAP * Casp3 - kd_82 * XIAP_Casp3
J83 XIAP degradation due to Caspase-3 XIAP > ∅

ka_83 * XIAP * Casp3
J84 XIAP~Caspase-3 complex breakup XIAP_Casp3 > XIAP

ka_84 * XIAP_Casp3
J85 negative feedback loop Caspase-3 on TNFR Complex1 RIP > ∅

ka_85 * RIP * Casp3
J86 FLIP degradation by Caspase-3 FLIP > ∅

ka_86 * FLIP * Casp3
J87 PARP cleavage as Casp3 substrate PARP > cPARP

ka_87 * Casp3 * PARP
J88 BAR~Caspase-8 complex formation BAR + Casp8 = BAR_Casp8

ka_88 * BAR * Casp8 - kd_88 * BAR_Casp8
J9 TNF:TNFR:TRADD degradation TNF_TNFR_TRADD > ∅

ka_9 * TNF_TNFR_TRADD

Parameters 106   0

Global parameters

Id Value

Local parameters

Id Value Reaction
ka_1 0.001 per_second J1 (TNFR transport into membrane)
ka_2 2.8e-07 a_mole_per_second J2 (TNFR production)
ka_3 5.6e-05 per_second J3 (TNFR degradation)
ka_4 2.0256e-05 a_mole_per_second J4 (RIP turnover)
kd_4 0.0001 per_second J4 (RIP turnover)
ka_5 2.9344e-05 a_mole_per_second J5 (TRADD turnover)
kd_5 0.0001 per_second J5 (TRADD turnover)
ka_6 3.3056e-05 a_mole_per_second J6 (TRAF2 turnover)
kd_6 0.0001 per_second J6 (TRAF2 turnover)
ka_7 3.0944e-05 a_mole_per_second J7 (FADD turnover)
kd_7 0.0001 per_second J7 (FADD turnover)
ka_8 5.6e-05 per_second J8 (TNF~TNFR degradation)
ka_9 0.02352 per_second J9 (TNF:TNFR:TRADD degradation)
ka_10 5.6e-05 per_second J10 (TNFR Complex1 degradation)
ka_11 5.6e-05 per_second J11 (TNFR Complex2 degradation)
ka_12 5.6e-05 per_second J12 (TNFR Complex2~FLIP degradation)
ka_13 5.6e-05 per_second J13 (TNFR Complex2~FLIP~FLIP degradation)
ka_14 5.6e-05 per_second J14 (TNFR Complex2~Procaspase-8 degradation)
ka_15 5.6e-05 per_second J15 (TNFR Complex2~Procaspase-8~Procaspase-8 degradation)
ka_16 5.6e-05 per_second J16 (TNFR Complex2~FLIP~Procaspase-8 degradation)
ka_17 5.6e-05 per_second J17 (TNFR Complex2~FLIP~Procaspase-8~RIP~TRAF2 degradation)
ka_18 0.00953471 per_a_mole_per_second J18 (TNF~TNFR binding and release)
kd_18 6.60377e-05 per_second J18 (TNF~TNFR binding and release)
ka_19 0.00427827 per_a_mole_per_second J19 (TNF~TNFR~TRADD building)
ka_20 0.0976562 per_a_mole_squared_per_second J20 (TNFR Complex1 building)
ka_21 0.001135 per_second J21 (Receptor internalisation step1)
ka_22 0.001135 per_second J22 (Receptor internalisation step2)
ka_23 0.0118534 per_a_mole_squared_per_second J23 (Receptor internalisation step3)
ka_24 0.1135 per_second J24 (Receptor internalisation step4)
ka_25 0.3125 per_a_mole_per_second J25 (FLIP recruitment to TNFR Complex2)
ka_26 0.3125 per_a_mole_per_second J26 (FLIP recruitment to TNFR Complex2~FLIP)
ka_27 0.03125 per_a_mole_per_second J27 (Procaspase-8 recruitment to TNFR Complex2)
ka_28 0.03125 per_a_mole_per_second J28 (Procaspase-8 recruitment to TNFR Complex2~Procaspase-8)
ka_29 0.45 per_second J29 (Caspase-8 activation by TNFR Complex2)
ka_30 0.3125 per_a_mole_per_second J30 (FLIP recruitment to TNFR Complex2~Procaspase-8)
ka_31 0.3125 per_a_mole_per_second J31 (Procaspase-8 recruitment to TNFR Complex2~FLIP)
ka_32 0.3 per_second J32 (Caspase-8 activation by TNFR Complex2~FLIP~Procaspase-8)
ka_33 0.00976562 per_a_mole_squared_per_second J33 (RIP~TRAF2 recruitment at TNFR Complex2~FLIP~Procaspase-8)
ka_34 0.03125 per_a_mole_per_second J34 (IKK activation by TNFR Complex2~FLIP~Procaspase-8~RIP~TRAF2)
ka_35 6.4e-05 a_mole_per_second J35 (IKK turnover)
kd_35 0.0001 per_second J35 (IKK turnover)
ka_36 1.6e-06 a_mole_per_second J36 (NF-kappaB turnover)
kd_36 0.0001 per_second J36 (NF-kappaB turnover)
ka_37 2.24902e-06 a_mole_per_second J37 (FLIP turnover)
kd_37 0.0001 per_second J37 (FLIP turnover)
ka_38 0.000772256 a_mole_per_second J38 (XIAP turnover)
kd_38 0.0001 per_second J38 (XIAP turnover)
ka_39 9.6e-06 a_mole_per_second J39 (A20 turnover)
kd_39 0.0001 per_second J39 (A20 turnover)
ka_40 0.0001 per_second J40 (IKK* degradation)
ka_41 0.0001 per_second J41 (IkappaBalpha~NF-kappaB complex degradation)
ka_42 0.0001 per_second J42 (nuclear NF-kappaB degradation)
ka_43 0.000394201 per_second J43 (IkappaBalpha-mRNA degradation)
ka_44 0.00154022 per_second J44 (IkappaBalpha degradation)
ka_45 0.0001 per_second J45 (free nuclear IkappaBalpha degradation)
ka_46 0.0001 per_second J46 (nuclear IkappaBalpha~NF-kappaB complex degradation)
ka_47 0.0115517 per_second J47 (P-IkappaBa degradation)
ka_48 0.000470498 per_second J48 (A20-mRNA degradation)
ka_49 0.000104931 per_second J49 (XIAP-mRNA degradation)
ka_50 0.000165744 per_second J50 (FLIP-mRNA degradation)
ka_51 93.75 per_a_mole_per_second J51 (IKK activation by TNFR Complex1)
ka_52 0.1 per_second J52 (IKK* inactivation)
ka_53 0.00625 per_a_mole_per_second J53 (TNFR Complex1 inactivation by A20)
ka_54 1.25 per_a_mole_per_second J54 (IkappaBalpha NF-kappaB association)
ka_55 0.104167 per_a_mole_per_second J55 (release and degradation of bound IkappaBalpha)
ka_56 0.0125 per_second J56 (NF-kappaB nuclear translocation)
ka_57 3.0303e-05 per_second J57 (IkappaBalpha-mRNA transcription)
ka_58 0.0606061 per_second J58 (IkappaBalpha translation)
ka_59 0.005 per_second J59 (IkappaBalpha nuclear translocation)
kd_59 0.00257576 per_second J59 (IkappaBalpha nuclear translocation)
ka_60 1.4348 per_a_mole_per_second J60 (IkappaBalpha binding NF-kappaB in nucleus)
ka_61 0.0151515 per_second J61 (IkappaBalpha_NF-kappaB N-C export)
ka_62 3.78788e-05 per_second J62 (A20-mRNA transcription)
ka_63 0.0151515 per_second J63 (A20 translation)
ka_64 3.33333e-05 per_second J64 (XIAP-mRNA transcription)
ka_65 0.0506061 per_second J65 (XIAP translation)
ka_66 3.33333e-05 per_second J66 (FLIP-mRNA transcription)
ka_67 0.00687273 per_second J67 (FLIP translation)
ka_68 0.000197531 a_mole_per_second J68 (Procaspase-8 turnover)
kd_68 6.17284e-05 per_second J68 (Procaspase-8 turnover)
ka_69 4.93827e-05 a_mole_per_second J69 (Procaspase-3 turnover)
kd_69 6.17284e-05 per_second J69 (Procaspase-3 turnover)
ka_70 3.95062e-06 a_mole_per_second J70 (Procaspase-6 turnover)
kd_70 6.17284e-05 per_second J70 (Procaspase-6 turnover)
ka_71 5.78704e-05 per_second J71 (Caspase-8 degradation)
ka_72 5.78704e-05 per_second J72 (Caspase-3 degradation)
ka_73 5.78704e-05 per_second J73 (Caspase-6 degradation)
ka_74 5.78704e-05 per_second J74 (XIAP~Caspase-3 complex degradation)
ka_75 1.66603e-06 a_mole_per_second J75 (BAR turnover)
kd_75 5.78704e-06 per_second J75 (BAR turnover)
ka_76 5.78704e-05 per_second J76 (BAR~Caspase-8 complex degradation)
ka_77 5.78704e-06 per_second J77 (PARP turnover)
kd_77 9.64506e-06 a_mole_per_second J77 (PARP turnover)
ka_78 5.78704e-06 per_second J78 (CPARP degradation)
ka_79 0.015625 per_a_mole_per_second J79 (Caspase-3 activation)
ka_80 0.009375 per_a_mole_per_second J80 (Caspase-6 activation)
ka_81 0.0015625 per_a_mole_per_second J81 (Caspase-8 activation)
ka_82 0.625 per_a_mole_per_second J82 (XIAP~Caspase-3 complex formation)
kd_82 0.001 per_second J82 (XIAP~Caspase-3 complex formation)
ka_83 1.875 per_a_mole_per_second J83 (XIAP degradation due to Caspase-3)
ka_84 5e-05 per_second J84 (XIAP~Caspase-3 complex breakup)
ka_85 0.15625 per_a_mole_per_second J85 (negative feedback loop Caspase-3 on TNFR Complex1)
ka_86 0.15625 per_a_mole_per_second J86 (FLIP degradation by Caspase-3)
ka_87 0.1875 per_a_mole_per_second J87 (PARP cleavage as Casp3 substrate)
ka_88 0.520833 per_a_mole_per_second J88 (BAR~Caspase-8 complex formation)
kd_88 0.001 per_second J88 (BAR~Caspase-8 complex formation)

Rules 0   0   0

Assignment rules

Definition

Rate rules

Definition

Algebraic rules

Definition

Events 0

Trigger Assignments