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Molecule Parameter List for PKC-active

The statistics table lists the distribution of a molecule acting either as a substrate, product, enzyme or as a molecule within the network.
The text color of a molecule is highlighted by color.
Statistics
PKC-active participated asMoleculeSum total ofEnzymeSubstrate of an enzymeProduct of an enzymeSubstrate in ReactionProduct in Reaction
No. of occurrences2525750000

Accession and Pathway Details
Accession NameAccession No.Accession TypePathway Link
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13
  • 82NetworkShared_Object_Ajay_Bhalla_2007_ReacDiff1_1e-13 
    PKC MAPK Ras CaM PKM chain kinetics PKC MAPK Ras CaM PKM kinetics[1] 
    PKC MAPK Ras CaM PKM kinetics[2] PKC MAPK Ras CaM PKM kinetics[3] 
    PKC MAPK Ras CaM PKM kinetics[4] PKC MAPK Ras CaM PKM kinetics[5] 
    PKC MAPK Ras kinetics[6] CaM PKM PKC MAPK Ras CaM PKM kinetics[7] 
    PKC MAPK Ras CaM PKM kinetics[8] PKC MAPK Ras CaM PKM kinetics[9] 
    PKC MAPK Ras CaM PKM kinetics[10] PKC MAPK Ras CaM PKM kinetics[11] 
    PKC MAPK Ras CaM PKM kinetics[12] PKC MAPK Ras CaM PKM kinetics[13] 
    PKC MAPK Ras CaM PKM kinetics[14] PKC MAPK Ras CaM PKM kinetics[15] 
    PKC MAPK Ras CaM PKM kinetics[16] PKC MAPK Ras CaM PKM kinetics[17] 
    PKC MAPK Ras CaM PKM kinetics[18] PKC MAPK Ras CaM PKM kinetics[19] 
    PKC MAPK Ras CaM PKM kinetics[20] PKC MAPK Ras CaM PKM kinetics[21] 
    PKC MAPK Ras CaM PKM kinetics[22] PKC MAPK Ras CaM PKM kinetics[23] 
    PKC MAPK Ras CaM PKM 
    This is a 25-compartment reaction-diffusion version of the Ajay_Bhalla_2007_PKM model. The original single-compartment model is repeated 25 times. In addition, a subset (27 out of 42) molecules can diffuse between compartments. Diffusion is implemented as a reaction between corresponding molecules in neighboring compartments. For D = 1e-12 m^2/sec (i.e., 1 micron^2/sec ) the kf and kb of this reaction for these 10 micron compartments are both 0.01/sec. For D = 1e-13 m^2/sec (i.e., 0.1 micron^2/sec ) the kf and kb are 0.001/sec.
    The stimulus file pkm_mapk22_diff_1e-13_Fig4B which was used for the model to replicate Figure 4B from the paper.
    pkm_mapk22_diff_1e-13_Fig4H replicate Figure 4H.
    pkm_mapk22_diff_1e-13_Fig4I replicate Figure 4I.

    PKC-active acting as a Molecule in  
    Ajay_Bhalla_2007_ReacDiff1_1e-13 Network
    NameAccession NamePathway NameInitial Conc.
    (uM)
    Volume
    (fL)
    Buffered
    PKC-active
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • Shared_Object_
    Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Pathway No. : 526
  • 01.5No
    PKC-active
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics
    Pathway No. : 533
    01.5No
    PKC-active
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[1]
    Pathway No. : 539
    01.5No
    PKC-active
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[2]
    Pathway No. : 545
    01.5No
    PKC-active
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[3]
    Pathway No. : 551
    01.5No
    PKC-active
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[4]
    Pathway No. : 557
    01.5No
    PKC-active
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[5]
    Pathway No. : 563
    01.5No
    PKC-active
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[6]
    Pathway No. : 567
    01.5No
    PKC-active
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[7]
    Pathway No. : 575
    01.5No
    PKC-active
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[8]
    Pathway No. : 581
    01.5No
    PKC-active
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[9]
    Pathway No. : 587
    01.5No
    PKC-active
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[10]
    Pathway No. : 593
    01.5No
    PKC-active
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[11]
    Pathway No. : 599
    01.5No
    PKC-active
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[12]
    Pathway No. : 605
    01.5No
    PKC-active
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[13]
    Pathway No. : 611
    01.5No
    PKC-active
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[14]
    Pathway No. : 617
    01.5No
    PKC-active
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[15]
    Pathway No. : 623
    01.5No
    PKC-active
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[16]
    Pathway No. : 629
    01.5No
    PKC-active
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[17]
    Pathway No. : 635
    01.5No
    PKC-active
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[18]
    Pathway No. : 641
    01.5No
    PKC-active
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[19]
    Pathway No. : 647
    01.5No
    PKC-active
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[20]
    Pathway No. : 653
    01.5No
    PKC-active
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[21]
    Pathway No. : 659
    01.5No
    PKC-active
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[22]
    Pathway No. : 665
    01.5No
    PKC-active
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[23]
    Pathway No. : 671
    01.5No

    PKC-active acting as a Summed Molecule in  
    Ajay_Bhalla_2007_ReacDiff1_1e-13 Network
     Accession NanePathway NameTargetInput
    1
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • Shared_Object_
    Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Pathway No. : 526
  • PKC-activePKC-Ca-memb*
    PKC-DAG-memb*
    PKM-zeta
     
    2
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics
    Pathway No. : 533
    PKC-activePKC-Ca-memb*
    PKC-DAG-memb*
    PKM-zeta
     
    3
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[1]
    Pathway No. : 539
    PKC-activePKC-Ca-memb*
    PKC-DAG-memb*
    PKM-zeta
     
    4
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[2]
    Pathway No. : 545
    PKC-activePKC-Ca-memb*
    PKC-DAG-memb*
    PKM-zeta
     
    5
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[3]
    Pathway No. : 551
    PKC-activePKC-Ca-memb*
    PKC-DAG-memb*
    PKM-zeta
     
    6
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[4]
    Pathway No. : 557
    PKC-activePKC-Ca-memb*
    PKC-DAG-memb*
    PKM-zeta
     
    7
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[5]
    Pathway No. : 563
    PKC-activePKC-Ca-memb*
    PKC-DAG-memb*
    PKM-zeta
     
    8
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[6]
    Pathway No. : 567
    PKC-activePKC-Ca-memb*
    PKC-DAG-memb*
    PKM-zeta
     
    9
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[7]
    Pathway No. : 575
    PKC-activePKC-Ca-memb*
    PKC-DAG-memb*
    PKM-zeta
     
    10
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[8]
    Pathway No. : 581
    PKC-activePKC-Ca-memb*
    PKC-DAG-memb*
    PKM-zeta
     
    11
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[9]
    Pathway No. : 587
    PKC-activePKC-Ca-memb*
    PKC-DAG-memb*
    PKM-zeta
     
    12
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[10]
    Pathway No. : 593
    PKC-activePKC-Ca-memb*
    PKC-DAG-memb*
    PKM-zeta
     
    13
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[11]
    Pathway No. : 599
    PKC-activePKC-Ca-memb*
    PKC-DAG-memb*
    PKM-zeta
     
    14
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[12]
    Pathway No. : 605
    PKC-activePKC-Ca-memb*
    PKC-DAG-memb*
    PKM-zeta
     
    15
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[13]
    Pathway No. : 611
    PKC-activePKC-Ca-memb*
    PKC-DAG-memb*
    PKM-zeta
     
    16
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[14]
    Pathway No. : 617
    PKC-activePKC-Ca-memb*
    PKC-DAG-memb*
    PKM-zeta
     
    17
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[15]
    Pathway No. : 623
    PKC-activePKC-Ca-memb*
    PKC-DAG-memb*
    PKM-zeta
     
    18
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[16]
    Pathway No. : 629
    PKC-activePKC-Ca-memb*
    PKC-DAG-memb*
    PKM-zeta
     
    19
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[17]
    Pathway No. : 635
    PKC-activePKC-Ca-memb*
    PKC-DAG-memb*
    PKM-zeta
     
    20
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[18]
    Pathway No. : 641
    PKC-activePKC-Ca-memb*
    PKC-DAG-memb*
    PKM-zeta
     
    21
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[19]
    Pathway No. : 647
    PKC-activePKC-Ca-memb*
    PKC-DAG-memb*
    PKM-zeta
     
    22
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[20]
    Pathway No. : 653
    PKC-activePKC-Ca-memb*
    PKC-DAG-memb*
    PKM-zeta
     
    23
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[21]
    Pathway No. : 659
    PKC-activePKC-Ca-memb*
    PKC-DAG-memb*
    PKM-zeta
     
    24
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[22]
    Pathway No. : 665
    PKC-activePKC-Ca-memb*
    PKC-DAG-memb*
    PKM-zeta
     
    25
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[23]
    Pathway No. : 671
    PKC-activePKC-Ca-memb*
    PKC-DAG-memb*
    PKM-zeta
     

    PKC-active acting as an Enzyme in  
    Ajay_Bhalla_2007_ReacDiff1_1e-13 Network
     Enzyme Molecule /
    Enzyme Activity
    Accession NamePathway NameKm (uM)kcat (s^-1)RatioEnzyme TypeReagents
    1PKC-active /
    PKC-act-raf
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • Shared_Object_
    Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Pathway No. : 526
  • 20.000544explicit E-S complexSubstrate
    craf-1

    Product
    craf-1*
        Rate consts from Chen et al Biochem 32, 1032 (1993) k3 = k2 = 4 k1 = 9e-5 recalculated gives 1.666e-5, which is not very different. Looks like k3 is rate-limiting in this case: there is a huge amount of craf locked up in the enz complex. Let us assume a 10x higher Km, ie, lower affinity. k1 drops by 10x. Also changed k2 to 4x k3. Lowerd k1 to 1e-6 to balance 10X DAG sensitivity of PKC
    2PKC-active /
    PKC-inact-GAP
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • Shared_Object_
    Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Pathway No. : 526
  • 3.3333344explicit E-S complexSubstrate
    GAP

    Product
    GAP*
        Rate consts copied from PCK-act-raf This reaction inactivates GAP. The idea is from the Boguski and McCormick review.
    3PKC-active /
    PKC-act-GEF
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • Shared_Object_
    Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Pathway No. : 526
  • 3.3333344explicit E-S complexSubstrate
    inact-GEF

    Product
    GEF*
        Rate consts from PKC-act-raf. This reaction activates GEF. It can lead to at least 2X stim of ras, and a 2X stim of MAPK over and above that obtained via direct phosph of c-raf. Note that it is a push-pull reaction, and there is also a contribution through the phosphorylation and inactivation of GAPs. The original PKC-act-raf rate consts are too fast. We lower K1 by 10 X
    4PKC-active /
    PKC-act-raf
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics
    Pathway No. : 533
    20.000544explicit E-S complexSubstrate
    craf-1

    Product
    craf-1*
        Rate consts from Chen et al Biochem 32, 1032 (1993) k3 = k2 = 4 k1 = 9e-5 recalculated gives 1.666e-5, which is not very different. Looks like k3 is rate-limiting in this case: there is a huge amount of craf locked up in the enz complex. Let us assume a 10x higher Km, ie, lower affinity. k1 drops by 10x. Also changed k2 to 4x k3. Lowerd k1 to 1e-6 to balance 10X DAG sensitivity of PKC
    5PKC-active /
    PKC-inact-GAP
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics
    Pathway No. : 533
    3.3333344explicit E-S complexSubstrate
    GAP

    Product
    GAP*
        Rate consts copied from PCK-act-raf This reaction inactivates GAP. The idea is from the Boguski and McCormick review.
    6PKC-active /
    PKC-act-GEF
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics
    Pathway No. : 533
    3.3333344explicit E-S complexSubstrate
    inact-GEF

    Product
    GEF*
        Rate consts from PKC-act-raf. This reaction activates GEF. It can lead to at least 2X stim of ras, and a 2X stim of MAPK over and above that obtained via direct phosph of c-raf. Note that it is a push-pull reaction, and there is also a contribution through the phosphorylation and inactivation of GAPs. The original PKC-act-raf rate consts are too fast. We lower K1 by 10 X
    7PKC-active /
    PKC-act-raf
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[1]
    Pathway No. : 539
    20.000544explicit E-S complexSubstrate
    craf-1

    Product
    craf-1*
        Rate consts from Chen et al Biochem 32, 1032 (1993) k3 = k2 = 4 k1 = 9e-5 recalculated gives 1.666e-5, which is not very different. Looks like k3 is rate-limiting in this case: there is a huge amount of craf locked up in the enz complex. Let us assume a 10x higher Km, ie, lower affinity. k1 drops by 10x. Also changed k2 to 4x k3. Lowerd k1 to 1e-6 to balance 10X DAG sensitivity of PKC
    8PKC-active /
    PKC-inact-GAP
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[1]
    Pathway No. : 539
    3.3333344explicit E-S complexSubstrate
    GAP

    Product
    GAP*
        Rate consts copied from PCK-act-raf This reaction inactivates GAP. The idea is from the Boguski and McCormick review.
    9PKC-active /
    PKC-act-GEF
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[1]
    Pathway No. : 539
    3.3333344explicit E-S complexSubstrate
    inact-GEF

    Product
    GEF*
        Rate consts from PKC-act-raf. This reaction activates GEF. It can lead to at least 2X stim of ras, and a 2X stim of MAPK over and above that obtained via direct phosph of c-raf. Note that it is a push-pull reaction, and there is also a contribution through the phosphorylation and inactivation of GAPs. The original PKC-act-raf rate consts are too fast. We lower K1 by 10 X
    10PKC-active /
    PKC-act-raf
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[2]
    Pathway No. : 545
    20.000544explicit E-S complexSubstrate
    craf-1

    Product
    craf-1*
        Rate consts from Chen et al Biochem 32, 1032 (1993) k3 = k2 = 4 k1 = 9e-5 recalculated gives 1.666e-5, which is not very different. Looks like k3 is rate-limiting in this case: there is a huge amount of craf locked up in the enz complex. Let us assume a 10x higher Km, ie, lower affinity. k1 drops by 10x. Also changed k2 to 4x k3. Lowerd k1 to 1e-6 to balance 10X DAG sensitivity of PKC
    11PKC-active /
    PKC-inact-GAP
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[2]
    Pathway No. : 545
    3.3333344explicit E-S complexSubstrate
    GAP

    Product
    GAP*
        Rate consts copied from PCK-act-raf This reaction inactivates GAP. The idea is from the Boguski and McCormick review.
    12PKC-active /
    PKC-act-GEF
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[2]
    Pathway No. : 545
    3.3333344explicit E-S complexSubstrate
    inact-GEF

    Product
    GEF*
        Rate consts from PKC-act-raf. This reaction activates GEF. It can lead to at least 2X stim of ras, and a 2X stim of MAPK over and above that obtained via direct phosph of c-raf. Note that it is a push-pull reaction, and there is also a contribution through the phosphorylation and inactivation of GAPs. The original PKC-act-raf rate consts are too fast. We lower K1 by 10 X
    13PKC-active /
    PKC-act-raf
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[3]
    Pathway No. : 551
    20.000544explicit E-S complexSubstrate
    craf-1

    Product
    craf-1*
        Rate consts from Chen et al Biochem 32, 1032 (1993) k3 = k2 = 4 k1 = 9e-5 recalculated gives 1.666e-5, which is not very different. Looks like k3 is rate-limiting in this case: there is a huge amount of craf locked up in the enz complex. Let us assume a 10x higher Km, ie, lower affinity. k1 drops by 10x. Also changed k2 to 4x k3. Lowerd k1 to 1e-6 to balance 10X DAG sensitivity of PKC
    14PKC-active /
    PKC-inact-GAP
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[3]
    Pathway No. : 551
    3.3333344explicit E-S complexSubstrate
    GAP

    Product
    GAP*
        Rate consts copied from PCK-act-raf This reaction inactivates GAP. The idea is from the Boguski and McCormick review.
    15PKC-active /
    PKC-act-GEF
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[3]
    Pathway No. : 551
    3.3333344explicit E-S complexSubstrate
    inact-GEF

    Product
    GEF*
        Rate consts from PKC-act-raf. This reaction activates GEF. It can lead to at least 2X stim of ras, and a 2X stim of MAPK over and above that obtained via direct phosph of c-raf. Note that it is a push-pull reaction, and there is also a contribution through the phosphorylation and inactivation of GAPs. The original PKC-act-raf rate consts are too fast. We lower K1 by 10 X
    16PKC-active /
    PKC-act-raf
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[4]
    Pathway No. : 557
    20.000544explicit E-S complexSubstrate
    craf-1

    Product
    craf-1*
        Rate consts from Chen et al Biochem 32, 1032 (1993) k3 = k2 = 4 k1 = 9e-5 recalculated gives 1.666e-5, which is not very different. Looks like k3 is rate-limiting in this case: there is a huge amount of craf locked up in the enz complex. Let us assume a 10x higher Km, ie, lower affinity. k1 drops by 10x. Also changed k2 to 4x k3. Lowerd k1 to 1e-6 to balance 10X DAG sensitivity of PKC
    17PKC-active /
    PKC-inact-GAP
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[4]
    Pathway No. : 557
    3.3333344explicit E-S complexSubstrate
    GAP

    Product
    GAP*
        Rate consts copied from PCK-act-raf This reaction inactivates GAP. The idea is from the Boguski and McCormick review.
    18PKC-active /
    PKC-act-GEF
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[4]
    Pathway No. : 557
    3.3333344explicit E-S complexSubstrate
    inact-GEF

    Product
    GEF*
        Rate consts from PKC-act-raf. This reaction activates GEF. It can lead to at least 2X stim of ras, and a 2X stim of MAPK over and above that obtained via direct phosph of c-raf. Note that it is a push-pull reaction, and there is also a contribution through the phosphorylation and inactivation of GAPs. The original PKC-act-raf rate consts are too fast. We lower K1 by 10 X
    19PKC-active /
    PKC-act-raf
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[5]
    Pathway No. : 563
    20.000544explicit E-S complexSubstrate
    craf-1

    Product
    craf-1*
        Rate consts from Chen et al Biochem 32, 1032 (1993) k3 = k2 = 4 k1 = 9e-5 recalculated gives 1.666e-5, which is not very different. Looks like k3 is rate-limiting in this case: there is a huge amount of craf locked up in the enz complex. Let us assume a 10x higher Km, ie, lower affinity. k1 drops by 10x. Also changed k2 to 4x k3. Lowerd k1 to 1e-6 to balance 10X DAG sensitivity of PKC
    20PKC-active /
    PKC-inact-GAP
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[5]
    Pathway No. : 563
    3.3333344explicit E-S complexSubstrate
    GAP

    Product
    GAP*
        Rate consts copied from PCK-act-raf This reaction inactivates GAP. The idea is from the Boguski and McCormick review.
    21PKC-active /
    PKC-act-GEF
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[5]
    Pathway No. : 563
    3.3333344explicit E-S complexSubstrate
    inact-GEF

    Product
    GEF*
        Rate consts from PKC-act-raf. This reaction activates GEF. It can lead to at least 2X stim of ras, and a 2X stim of MAPK over and above that obtained via direct phosph of c-raf. Note that it is a push-pull reaction, and there is also a contribution through the phosphorylation and inactivation of GAPs. The original PKC-act-raf rate consts are too fast. We lower K1 by 10 X
    22PKC-active /
    PKC-act-raf
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[6]
    Pathway No. : 567
    20.000544explicit E-S complexSubstrate
    craf-1

    Product
    craf-1*
        Rate consts from Chen et al Biochem 32, 1032 (1993) k3 = k2 = 4 k1 = 9e-5 recalculated gives 1.666e-5, which is not very different. Looks like k3 is rate-limiting in this case: there is a huge amount of craf locked up in the enz complex. Let us assume a 10x higher Km, ie, lower affinity. k1 drops by 10x. Also changed k2 to 4x k3. Lowerd k1 to 1e-6 to balance 10X DAG sensitivity of PKC
    23PKC-active /
    PKC-inact-GAP
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[6]
    Pathway No. : 567
    3.3333344explicit E-S complexSubstrate
    GAP

    Product
    GAP*
        Rate consts copied from PCK-act-raf This reaction inactivates GAP. The idea is from the Boguski and McCormick review.
    24PKC-active /
    PKC-act-GEF
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[6]
    Pathway No. : 567
    3.3333344explicit E-S complexSubstrate
    inact-GEF

    Product
    GEF*
        Rate consts from PKC-act-raf. This reaction activates GEF. It can lead to at least 2X stim of ras, and a 2X stim of MAPK over and above that obtained via direct phosph of c-raf. Note that it is a push-pull reaction, and there is also a contribution through the phosphorylation and inactivation of GAPs. The original PKC-act-raf rate consts are too fast. We lower K1 by 10 X
    25PKC-active /
    PKC-act-raf
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[7]
    Pathway No. : 575
    20.000544explicit E-S complexSubstrate
    craf-1

    Product
    craf-1*
        Rate consts from Chen et al Biochem 32, 1032 (1993) k3 = k2 = 4 k1 = 9e-5 recalculated gives 1.666e-5, which is not very different. Looks like k3 is rate-limiting in this case: there is a huge amount of craf locked up in the enz complex. Let us assume a 10x higher Km, ie, lower affinity. k1 drops by 10x. Also changed k2 to 4x k3. Lowerd k1 to 1e-6 to balance 10X DAG sensitivity of PKC
    26PKC-active /
    PKC-inact-GAP
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[7]
    Pathway No. : 575
    3.3333344explicit E-S complexSubstrate
    GAP

    Product
    GAP*
        Rate consts copied from PCK-act-raf This reaction inactivates GAP. The idea is from the Boguski and McCormick review.
    27PKC-active /
    PKC-act-GEF
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[7]
    Pathway No. : 575
    3.3333344explicit E-S complexSubstrate
    inact-GEF

    Product
    GEF*
        Rate consts from PKC-act-raf. This reaction activates GEF. It can lead to at least 2X stim of ras, and a 2X stim of MAPK over and above that obtained via direct phosph of c-raf. Note that it is a push-pull reaction, and there is also a contribution through the phosphorylation and inactivation of GAPs. The original PKC-act-raf rate consts are too fast. We lower K1 by 10 X
    28PKC-active /
    PKC-act-raf
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[8]
    Pathway No. : 581
    20.000544explicit E-S complexSubstrate
    craf-1

    Product
    craf-1*
        Rate consts from Chen et al Biochem 32, 1032 (1993) k3 = k2 = 4 k1 = 9e-5 recalculated gives 1.666e-5, which is not very different. Looks like k3 is rate-limiting in this case: there is a huge amount of craf locked up in the enz complex. Let us assume a 10x higher Km, ie, lower affinity. k1 drops by 10x. Also changed k2 to 4x k3. Lowerd k1 to 1e-6 to balance 10X DAG sensitivity of PKC
    29PKC-active /
    PKC-inact-GAP
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[8]
    Pathway No. : 581
    3.3333344explicit E-S complexSubstrate
    GAP

    Product
    GAP*
        Rate consts copied from PCK-act-raf This reaction inactivates GAP. The idea is from the Boguski and McCormick review.
    30PKC-active /
    PKC-act-GEF
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[8]
    Pathway No. : 581
    3.3333344explicit E-S complexSubstrate
    inact-GEF

    Product
    GEF*
        Rate consts from PKC-act-raf. This reaction activates GEF. It can lead to at least 2X stim of ras, and a 2X stim of MAPK over and above that obtained via direct phosph of c-raf. Note that it is a push-pull reaction, and there is also a contribution through the phosphorylation and inactivation of GAPs. The original PKC-act-raf rate consts are too fast. We lower K1 by 10 X
    31PKC-active /
    PKC-act-raf
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[9]
    Pathway No. : 587
    20.000544explicit E-S complexSubstrate
    craf-1

    Product
    craf-1*
        Rate consts from Chen et al Biochem 32, 1032 (1993) k3 = k2 = 4 k1 = 9e-5 recalculated gives 1.666e-5, which is not very different. Looks like k3 is rate-limiting in this case: there is a huge amount of craf locked up in the enz complex. Let us assume a 10x higher Km, ie, lower affinity. k1 drops by 10x. Also changed k2 to 4x k3. Lowerd k1 to 1e-6 to balance 10X DAG sensitivity of PKC
    32PKC-active /
    PKC-inact-GAP
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[9]
    Pathway No. : 587
    3.3333344explicit E-S complexSubstrate
    GAP

    Product
    GAP*
        Rate consts copied from PCK-act-raf This reaction inactivates GAP. The idea is from the Boguski and McCormick review.
    33PKC-active /
    PKC-act-GEF
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[9]
    Pathway No. : 587
    3.3333344explicit E-S complexSubstrate
    inact-GEF

    Product
    GEF*
        Rate consts from PKC-act-raf. This reaction activates GEF. It can lead to at least 2X stim of ras, and a 2X stim of MAPK over and above that obtained via direct phosph of c-raf. Note that it is a push-pull reaction, and there is also a contribution through the phosphorylation and inactivation of GAPs. The original PKC-act-raf rate consts are too fast. We lower K1 by 10 X
    34PKC-active /
    PKC-act-raf
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[10]
    Pathway No. : 593
    20.000544explicit E-S complexSubstrate
    craf-1

    Product
    craf-1*
        Rate consts from Chen et al Biochem 32, 1032 (1993) k3 = k2 = 4 k1 = 9e-5 recalculated gives 1.666e-5, which is not very different. Looks like k3 is rate-limiting in this case: there is a huge amount of craf locked up in the enz complex. Let us assume a 10x higher Km, ie, lower affinity. k1 drops by 10x. Also changed k2 to 4x k3. Lowerd k1 to 1e-6 to balance 10X DAG sensitivity of PKC
    35PKC-active /
    PKC-inact-GAP
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[10]
    Pathway No. : 593
    3.3333344explicit E-S complexSubstrate
    GAP

    Product
    GAP*
        Rate consts copied from PCK-act-raf This reaction inactivates GAP. The idea is from the Boguski and McCormick review.
    36PKC-active /
    PKC-act-GEF
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[10]
    Pathway No. : 593
    3.3333344explicit E-S complexSubstrate
    inact-GEF

    Product
    GEF*
        Rate consts from PKC-act-raf. This reaction activates GEF. It can lead to at least 2X stim of ras, and a 2X stim of MAPK over and above that obtained via direct phosph of c-raf. Note that it is a push-pull reaction, and there is also a contribution through the phosphorylation and inactivation of GAPs. The original PKC-act-raf rate consts are too fast. We lower K1 by 10 X
    37PKC-active /
    PKC-act-raf
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[11]
    Pathway No. : 599
    20.000544explicit E-S complexSubstrate
    craf-1

    Product
    craf-1*
        Rate consts from Chen et al Biochem 32, 1032 (1993) k3 = k2 = 4 k1 = 9e-5 recalculated gives 1.666e-5, which is not very different. Looks like k3 is rate-limiting in this case: there is a huge amount of craf locked up in the enz complex. Let us assume a 10x higher Km, ie, lower affinity. k1 drops by 10x. Also changed k2 to 4x k3. Lowerd k1 to 1e-6 to balance 10X DAG sensitivity of PKC
    38PKC-active /
    PKC-inact-GAP
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[11]
    Pathway No. : 599
    3.3333344explicit E-S complexSubstrate
    GAP

    Product
    GAP*
        Rate consts copied from PCK-act-raf This reaction inactivates GAP. The idea is from the Boguski and McCormick review.
    39PKC-active /
    PKC-act-GEF
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[11]
    Pathway No. : 599
    3.3333344explicit E-S complexSubstrate
    inact-GEF

    Product
    GEF*
        Rate consts from PKC-act-raf. This reaction activates GEF. It can lead to at least 2X stim of ras, and a 2X stim of MAPK over and above that obtained via direct phosph of c-raf. Note that it is a push-pull reaction, and there is also a contribution through the phosphorylation and inactivation of GAPs. The original PKC-act-raf rate consts are too fast. We lower K1 by 10 X
    40PKC-active /
    PKC-act-raf
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[12]
    Pathway No. : 605
    20.000544explicit E-S complexSubstrate
    craf-1

    Product
    craf-1*
        Rate consts from Chen et al Biochem 32, 1032 (1993) k3 = k2 = 4 k1 = 9e-5 recalculated gives 1.666e-5, which is not very different. Looks like k3 is rate-limiting in this case: there is a huge amount of craf locked up in the enz complex. Let us assume a 10x higher Km, ie, lower affinity. k1 drops by 10x. Also changed k2 to 4x k3. Lowerd k1 to 1e-6 to balance 10X DAG sensitivity of PKC
    41PKC-active /
    PKC-inact-GAP
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[12]
    Pathway No. : 605
    3.3333344explicit E-S complexSubstrate
    GAP

    Product
    GAP*
        Rate consts copied from PCK-act-raf This reaction inactivates GAP. The idea is from the Boguski and McCormick review.
    42PKC-active /
    PKC-act-GEF
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[12]
    Pathway No. : 605
    3.3333344explicit E-S complexSubstrate
    inact-GEF

    Product
    GEF*
        Rate consts from PKC-act-raf. This reaction activates GEF. It can lead to at least 2X stim of ras, and a 2X stim of MAPK over and above that obtained via direct phosph of c-raf. Note that it is a push-pull reaction, and there is also a contribution through the phosphorylation and inactivation of GAPs. The original PKC-act-raf rate consts are too fast. We lower K1 by 10 X
    43PKC-active /
    PKC-act-raf
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[13]
    Pathway No. : 611
    20.000544explicit E-S complexSubstrate
    craf-1

    Product
    craf-1*
        Rate consts from Chen et al Biochem 32, 1032 (1993) k3 = k2 = 4 k1 = 9e-5 recalculated gives 1.666e-5, which is not very different. Looks like k3 is rate-limiting in this case: there is a huge amount of craf locked up in the enz complex. Let us assume a 10x higher Km, ie, lower affinity. k1 drops by 10x. Also changed k2 to 4x k3. Lowerd k1 to 1e-6 to balance 10X DAG sensitivity of PKC
    44PKC-active /
    PKC-inact-GAP
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[13]
    Pathway No. : 611
    3.3333344explicit E-S complexSubstrate
    GAP

    Product
    GAP*
        Rate consts copied from PCK-act-raf This reaction inactivates GAP. The idea is from the Boguski and McCormick review.
    45PKC-active /
    PKC-act-GEF
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[13]
    Pathway No. : 611
    3.3333344explicit E-S complexSubstrate
    inact-GEF

    Product
    GEF*
        Rate consts from PKC-act-raf. This reaction activates GEF. It can lead to at least 2X stim of ras, and a 2X stim of MAPK over and above that obtained via direct phosph of c-raf. Note that it is a push-pull reaction, and there is also a contribution through the phosphorylation and inactivation of GAPs. The original PKC-act-raf rate consts are too fast. We lower K1 by 10 X
    46PKC-active /
    PKC-act-raf
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[14]
    Pathway No. : 617
    20.000544explicit E-S complexSubstrate
    craf-1

    Product
    craf-1*
        Rate consts from Chen et al Biochem 32, 1032 (1993) k3 = k2 = 4 k1 = 9e-5 recalculated gives 1.666e-5, which is not very different. Looks like k3 is rate-limiting in this case: there is a huge amount of craf locked up in the enz complex. Let us assume a 10x higher Km, ie, lower affinity. k1 drops by 10x. Also changed k2 to 4x k3. Lowerd k1 to 1e-6 to balance 10X DAG sensitivity of PKC
    47PKC-active /
    PKC-inact-GAP
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[14]
    Pathway No. : 617
    3.3333344explicit E-S complexSubstrate
    GAP

    Product
    GAP*
        Rate consts copied from PCK-act-raf This reaction inactivates GAP. The idea is from the Boguski and McCormick review.
    48PKC-active /
    PKC-act-GEF
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[14]
    Pathway No. : 617
    3.3333344explicit E-S complexSubstrate
    inact-GEF

    Product
    GEF*
        Rate consts from PKC-act-raf. This reaction activates GEF. It can lead to at least 2X stim of ras, and a 2X stim of MAPK over and above that obtained via direct phosph of c-raf. Note that it is a push-pull reaction, and there is also a contribution through the phosphorylation and inactivation of GAPs. The original PKC-act-raf rate consts are too fast. We lower K1 by 10 X
    49PKC-active /
    PKC-act-raf
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[15]
    Pathway No. : 623
    20.000544explicit E-S complexSubstrate
    craf-1

    Product
    craf-1*
        Rate consts from Chen et al Biochem 32, 1032 (1993) k3 = k2 = 4 k1 = 9e-5 recalculated gives 1.666e-5, which is not very different. Looks like k3 is rate-limiting in this case: there is a huge amount of craf locked up in the enz complex. Let us assume a 10x higher Km, ie, lower affinity. k1 drops by 10x. Also changed k2 to 4x k3. Lowerd k1 to 1e-6 to balance 10X DAG sensitivity of PKC
    50PKC-active /
    PKC-inact-GAP
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[15]
    Pathway No. : 623
    3.3333344explicit E-S complexSubstrate
    GAP

    Product
    GAP*
        Rate consts copied from PCK-act-raf This reaction inactivates GAP. The idea is from the Boguski and McCormick review.
    51PKC-active /
    PKC-act-GEF
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[15]
    Pathway No. : 623
    3.3333344explicit E-S complexSubstrate
    inact-GEF

    Product
    GEF*
        Rate consts from PKC-act-raf. This reaction activates GEF. It can lead to at least 2X stim of ras, and a 2X stim of MAPK over and above that obtained via direct phosph of c-raf. Note that it is a push-pull reaction, and there is also a contribution through the phosphorylation and inactivation of GAPs. The original PKC-act-raf rate consts are too fast. We lower K1 by 10 X
    52PKC-active /
    PKC-act-raf
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[16]
    Pathway No. : 629
    20.000544explicit E-S complexSubstrate
    craf-1

    Product
    craf-1*
        Rate consts from Chen et al Biochem 32, 1032 (1993) k3 = k2 = 4 k1 = 9e-5 recalculated gives 1.666e-5, which is not very different. Looks like k3 is rate-limiting in this case: there is a huge amount of craf locked up in the enz complex. Let us assume a 10x higher Km, ie, lower affinity. k1 drops by 10x. Also changed k2 to 4x k3. Lowerd k1 to 1e-6 to balance 10X DAG sensitivity of PKC
    53PKC-active /
    PKC-inact-GAP
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[16]
    Pathway No. : 629
    3.3333344explicit E-S complexSubstrate
    GAP

    Product
    GAP*
        Rate consts copied from PCK-act-raf This reaction inactivates GAP. The idea is from the Boguski and McCormick review.
    54PKC-active /
    PKC-act-GEF
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[16]
    Pathway No. : 629
    3.3333344explicit E-S complexSubstrate
    inact-GEF

    Product
    GEF*
        Rate consts from PKC-act-raf. This reaction activates GEF. It can lead to at least 2X stim of ras, and a 2X stim of MAPK over and above that obtained via direct phosph of c-raf. Note that it is a push-pull reaction, and there is also a contribution through the phosphorylation and inactivation of GAPs. The original PKC-act-raf rate consts are too fast. We lower K1 by 10 X
    55PKC-active /
    PKC-act-raf
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[17]
    Pathway No. : 635
    20.000544explicit E-S complexSubstrate
    craf-1

    Product
    craf-1*
        Rate consts from Chen et al Biochem 32, 1032 (1993) k3 = k2 = 4 k1 = 9e-5 recalculated gives 1.666e-5, which is not very different. Looks like k3 is rate-limiting in this case: there is a huge amount of craf locked up in the enz complex. Let us assume a 10x higher Km, ie, lower affinity. k1 drops by 10x. Also changed k2 to 4x k3. Lowerd k1 to 1e-6 to balance 10X DAG sensitivity of PKC
    56PKC-active /
    PKC-inact-GAP
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[17]
    Pathway No. : 635
    3.3333344explicit E-S complexSubstrate
    GAP

    Product
    GAP*
        Rate consts copied from PCK-act-raf This reaction inactivates GAP. The idea is from the Boguski and McCormick review.
    57PKC-active /
    PKC-act-GEF
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[17]
    Pathway No. : 635
    3.3333344explicit E-S complexSubstrate
    inact-GEF

    Product
    GEF*
        Rate consts from PKC-act-raf. This reaction activates GEF. It can lead to at least 2X stim of ras, and a 2X stim of MAPK over and above that obtained via direct phosph of c-raf. Note that it is a push-pull reaction, and there is also a contribution through the phosphorylation and inactivation of GAPs. The original PKC-act-raf rate consts are too fast. We lower K1 by 10 X
    58PKC-active /
    PKC-act-raf
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[18]
    Pathway No. : 641
    20.000544explicit E-S complexSubstrate
    craf-1

    Product
    craf-1*
        Rate consts from Chen et al Biochem 32, 1032 (1993) k3 = k2 = 4 k1 = 9e-5 recalculated gives 1.666e-5, which is not very different. Looks like k3 is rate-limiting in this case: there is a huge amount of craf locked up in the enz complex. Let us assume a 10x higher Km, ie, lower affinity. k1 drops by 10x. Also changed k2 to 4x k3. Lowerd k1 to 1e-6 to balance 10X DAG sensitivity of PKC
    59PKC-active /
    PKC-inact-GAP
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[18]
    Pathway No. : 641
    3.3333344explicit E-S complexSubstrate
    GAP

    Product
    GAP*
        Rate consts copied from PCK-act-raf This reaction inactivates GAP. The idea is from the Boguski and McCormick review.
    60PKC-active /
    PKC-act-GEF
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[18]
    Pathway No. : 641
    3.3333344explicit E-S complexSubstrate
    inact-GEF

    Product
    GEF*
        Rate consts from PKC-act-raf. This reaction activates GEF. It can lead to at least 2X stim of ras, and a 2X stim of MAPK over and above that obtained via direct phosph of c-raf. Note that it is a push-pull reaction, and there is also a contribution through the phosphorylation and inactivation of GAPs. The original PKC-act-raf rate consts are too fast. We lower K1 by 10 X
    61PKC-active /
    PKC-act-raf
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[19]
    Pathway No. : 647
    20.000544explicit E-S complexSubstrate
    craf-1

    Product
    craf-1*
        Rate consts from Chen et al Biochem 32, 1032 (1993) k3 = k2 = 4 k1 = 9e-5 recalculated gives 1.666e-5, which is not very different. Looks like k3 is rate-limiting in this case: there is a huge amount of craf locked up in the enz complex. Let us assume a 10x higher Km, ie, lower affinity. k1 drops by 10x. Also changed k2 to 4x k3. Lowerd k1 to 1e-6 to balance 10X DAG sensitivity of PKC
    62PKC-active /
    PKC-inact-GAP
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[19]
    Pathway No. : 647
    3.3333344explicit E-S complexSubstrate
    GAP

    Product
    GAP*
        Rate consts copied from PCK-act-raf This reaction inactivates GAP. The idea is from the Boguski and McCormick review.
    63PKC-active /
    PKC-act-GEF
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[19]
    Pathway No. : 647
    3.3333344explicit E-S complexSubstrate
    inact-GEF

    Product
    GEF*
        Rate consts from PKC-act-raf. This reaction activates GEF. It can lead to at least 2X stim of ras, and a 2X stim of MAPK over and above that obtained via direct phosph of c-raf. Note that it is a push-pull reaction, and there is also a contribution through the phosphorylation and inactivation of GAPs. The original PKC-act-raf rate consts are too fast. We lower K1 by 10 X
    64PKC-active /
    PKC-act-raf
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[20]
    Pathway No. : 653
    20.000544explicit E-S complexSubstrate
    craf-1

    Product
    craf-1*
        Rate consts from Chen et al Biochem 32, 1032 (1993) k3 = k2 = 4 k1 = 9e-5 recalculated gives 1.666e-5, which is not very different. Looks like k3 is rate-limiting in this case: there is a huge amount of craf locked up in the enz complex. Let us assume a 10x higher Km, ie, lower affinity. k1 drops by 10x. Also changed k2 to 4x k3. Lowerd k1 to 1e-6 to balance 10X DAG sensitivity of PKC
    65PKC-active /
    PKC-inact-GAP
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[20]
    Pathway No. : 653
    3.3333344explicit E-S complexSubstrate
    GAP

    Product
    GAP*
        Rate consts copied from PCK-act-raf This reaction inactivates GAP. The idea is from the Boguski and McCormick review.
    66PKC-active /
    PKC-act-GEF
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[20]
    Pathway No. : 653
    3.3333344explicit E-S complexSubstrate
    inact-GEF

    Product
    GEF*
        Rate consts from PKC-act-raf. This reaction activates GEF. It can lead to at least 2X stim of ras, and a 2X stim of MAPK over and above that obtained via direct phosph of c-raf. Note that it is a push-pull reaction, and there is also a contribution through the phosphorylation and inactivation of GAPs. The original PKC-act-raf rate consts are too fast. We lower K1 by 10 X
    67PKC-active /
    PKC-act-raf
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[21]
    Pathway No. : 659
    20.000544explicit E-S complexSubstrate
    craf-1

    Product
    craf-1*
        Rate consts from Chen et al Biochem 32, 1032 (1993) k3 = k2 = 4 k1 = 9e-5 recalculated gives 1.666e-5, which is not very different. Looks like k3 is rate-limiting in this case: there is a huge amount of craf locked up in the enz complex. Let us assume a 10x higher Km, ie, lower affinity. k1 drops by 10x. Also changed k2 to 4x k3. Lowerd k1 to 1e-6 to balance 10X DAG sensitivity of PKC
    68PKC-active /
    PKC-inact-GAP
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[21]
    Pathway No. : 659
    3.3333344explicit E-S complexSubstrate
    GAP

    Product
    GAP*
        Rate consts copied from PCK-act-raf This reaction inactivates GAP. The idea is from the Boguski and McCormick review.
    69PKC-active /
    PKC-act-GEF
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[21]
    Pathway No. : 659
    3.3333344explicit E-S complexSubstrate
    inact-GEF

    Product
    GEF*
        Rate consts from PKC-act-raf. This reaction activates GEF. It can lead to at least 2X stim of ras, and a 2X stim of MAPK over and above that obtained via direct phosph of c-raf. Note that it is a push-pull reaction, and there is also a contribution through the phosphorylation and inactivation of GAPs. The original PKC-act-raf rate consts are too fast. We lower K1 by 10 X
    70PKC-active /
    PKC-act-raf
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[22]
    Pathway No. : 665
    20.000544explicit E-S complexSubstrate
    craf-1

    Product
    craf-1*
        Rate consts from Chen et al Biochem 32, 1032 (1993) k3 = k2 = 4 k1 = 9e-5 recalculated gives 1.666e-5, which is not very different. Looks like k3 is rate-limiting in this case: there is a huge amount of craf locked up in the enz complex. Let us assume a 10x higher Km, ie, lower affinity. k1 drops by 10x. Also changed k2 to 4x k3. Lowerd k1 to 1e-6 to balance 10X DAG sensitivity of PKC
    71PKC-active /
    PKC-inact-GAP
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[22]
    Pathway No. : 665
    3.3333344explicit E-S complexSubstrate
    GAP

    Product
    GAP*
        Rate consts copied from PCK-act-raf This reaction inactivates GAP. The idea is from the Boguski and McCormick review.
    72PKC-active /
    PKC-act-GEF
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[22]
    Pathway No. : 665
    3.3333344explicit E-S complexSubstrate
    inact-GEF

    Product
    GEF*
        Rate consts from PKC-act-raf. This reaction activates GEF. It can lead to at least 2X stim of ras, and a 2X stim of MAPK over and above that obtained via direct phosph of c-raf. Note that it is a push-pull reaction, and there is also a contribution through the phosphorylation and inactivation of GAPs. The original PKC-act-raf rate consts are too fast. We lower K1 by 10 X
    73PKC-active /
    PKC-act-raf
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[23]
    Pathway No. : 671
    20.000544explicit E-S complexSubstrate
    craf-1

    Product
    craf-1*
        Rate consts from Chen et al Biochem 32, 1032 (1993) k3 = k2 = 4 k1 = 9e-5 recalculated gives 1.666e-5, which is not very different. Looks like k3 is rate-limiting in this case: there is a huge amount of craf locked up in the enz complex. Let us assume a 10x higher Km, ie, lower affinity. k1 drops by 10x. Also changed k2 to 4x k3. Lowerd k1 to 1e-6 to balance 10X DAG sensitivity of PKC
    74PKC-active /
    PKC-inact-GAP
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[23]
    Pathway No. : 671
    3.3333344explicit E-S complexSubstrate
    GAP

    Product
    GAP*
        Rate consts copied from PCK-act-raf This reaction inactivates GAP. The idea is from the Boguski and McCormick review.
    75PKC-active /
    PKC-act-GEF
  • Ajay_Bhalla_
    2007_ReacDiff1_
    1e-13

    Accession No. : 82
  • kinetics[23]
    Pathway No. : 671
    3.3333344explicit E-S complexSubstrate
    inact-GEF

    Product
    GEF*
        Rate consts from PKC-act-raf. This reaction activates GEF. It can lead to at least 2X stim of ras, and a 2X stim of MAPK over and above that obtained via direct phosph of c-raf. Note that it is a push-pull reaction, and there is also a contribution through the phosphorylation and inactivation of GAPs. The original PKC-act-raf rate consts are too fast. We lower K1 by 10 X



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