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Molecule Parameter List for GDP-Ras | 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 | Accession and Pathway Details | |
Accession Name | Accession No. | Accession Type | Pathway Link | Ajay_Bhalla_ 2007_ReacDiff2 | 83 | Network | Shared_Object_Ajay_Bhalla_2007_ReacDiff, PKC, MAPK, Ras, CaM, PKM, chain, kinetics, PKC, MAPK, Ras, CaM, PKM, kinetics[1], PKC, MAPK, Ras, kinetics[3], CaM, PKM, kinetics[2], PKC, MAPK, Ras, CaM, PKM, PKC, MAPK, Ras, CaM, PKM, kinetics[4], PKC, MAPK, Ras, CaM, PKM, kinetics[5], PKC, MAPK, Ras, CaM, PKM, kinetics[6], 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, kinetics[24], PKC, MAPK, Ras, CaM, PKM, kinetics[25], PKC, MAPK, Ras, CaM, PKM, kinetics[26], PKC, MAPK, Ras, CaM, PKM, kinetics[27], PKC, MAPK, Ras, CaM, PKM, kinetics[28], PKC, MAPK, Ras, CaM, PKM, kinetics[29], PKC, MAPK, Ras, CaM, PKM, kinetics[30], PKC, MAPK, Ras, CaM, PKM, kinetics[31], PKC, MAPK, Ras, CaM, PKM, kinetics[32], PKC, MAPK, Ras, CaM, PKM, kinetics[33], PKC, MAPK, Ras, CaM, PKM, kinetics[34], PKC, MAPK, Ras, CaM, PKM, kinetics[35], PKC, MAPK, Ras, CaM, PKM, kinetics[36], PKC, MAPK, Ras, CaM, PKM, kinetics[37], PKC, MAPK, Ras, CaM, PKM, kinetics[38], PKC, MAPK, Ras, CaM, PKM | This is a 40-compartment reaction-diffusion-transport version of the Ajay_Bhalla_2007_PKM model. The original single-compartment model is repeated 40 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 In addition, we have a forward (dendrite to soma) transport term of 1 microns/sec. This converts to a rate of 0.1/sec, but applies only to the kf. So the total kf of the diffusion 'reaction' is 0.11 for D = 1 micron^2/sec, and kb is 0.01. If D=0.1 micron^2/sec then kf = 0.101 and kb = 0.001. In addition this model has all molecules buffered in the first and last compartments. This boundary conditions says that the molecules are not drained out of the first compartment, nor do they all pile up in the last one.
The stimulus file pkm_mapk22_transp_endbuf_D1e-13_Fig4CD which was used for the model to replicate Figure 4C and 4D from the paper.
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GDP-Ras acting as a Molecule in Ajay_Bhalla_2007_ReacDiff2 Network
Name | Accession Name | Pathway Name | Initial Conc. (uM) | Volume (fL) | Buffered | GDP-Ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 687 | 0.4842 | 1.5 | No | GDP bound form. See Rosen et al Neuron 12 1207-1221 June 1994. the activation loop is based on Boguski and McCormick Nature 366 643-654 93 Assume Ras is present at about the same level as craf-1, 0.2 uM. Hallberg et al JBC 269:6 3913-3916 1994 estimate upto 5-10% of cellular Raf is assoc with Ras. Given that only 5-10% of Ras is GTP-bound, we need similar amounts of Ras as Raf. | GDP-Ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 693 | 0.4842 | 1.5 | No | GDP bound form. See Rosen et al Neuron 12 1207-1221 June 1994. the activation loop is based on Boguski and McCormick Nature 366 643-654 93 Assume Ras is present at about the same level as craf-1, 0.2 uM. Hallberg et al JBC 269:6 3913-3916 1994 estimate upto 5-10% of cellular Raf is assoc with Ras. Given that only 5-10% of Ras is GTP-bound, we need similar amounts of Ras as Raf. | GDP-Ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 700 | 0.4842 | 1.5 | No | GDP bound form. See Rosen et al Neuron 12 1207-1221 June 1994. the activation loop is based on Boguski and McCormick Nature 366 643-654 93 Assume Ras is present at about the same level as craf-1, 0.2 uM. Hallberg et al JBC 269:6 3913-3916 1994 estimate upto 5-10% of cellular Raf is assoc with Ras. Given that only 5-10% of Ras is GTP-bound, we need similar amounts of Ras as Raf. | GDP-Ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 705 | 0.4842 | 1.5 | No | GDP bound form. See Rosen et al Neuron 12 1207-1221 June 1994. the activation loop is based on Boguski and McCormick Nature 366 643-654 93 Assume Ras is present at about the same level as craf-1, 0.2 uM. Hallberg et al JBC 269:6 3913-3916 1994 estimate upto 5-10% of cellular Raf is assoc with Ras. Given that only 5-10% of Ras is GTP-bound, we need similar amounts of Ras as Raf. | GDP-Ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 711 | 0.4842 | 1.5 | No | GDP bound form. See Rosen et al Neuron 12 1207-1221 June 1994. the activation loop is based on Boguski and McCormick Nature 366 643-654 93 Assume Ras is present at about the same level as craf-1, 0.2 uM. Hallberg et al JBC 269:6 3913-3916 1994 estimate upto 5-10% of cellular Raf is assoc with Ras. Given that only 5-10% of Ras is GTP-bound, we need similar amounts of Ras as Raf. | GDP-Ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 717 | 0.4842 | 1.5 | No | GDP bound form. See Rosen et al Neuron 12 1207-1221 June 1994. the activation loop is based on Boguski and McCormick Nature 366 643-654 93 Assume Ras is present at about the same level as craf-1, 0.2 uM. Hallberg et al JBC 269:6 3913-3916 1994 estimate upto 5-10% of cellular Raf is assoc with Ras. Given that only 5-10% of Ras is GTP-bound, we need similar amounts of Ras as Raf. | GDP-Ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 723 | 0.4842 | 1.5 | No | GDP bound form. See Rosen et al Neuron 12 1207-1221 June 1994. the activation loop is based on Boguski and McCormick Nature 366 643-654 93 Assume Ras is present at about the same level as craf-1, 0.2 uM. Hallberg et al JBC 269:6 3913-3916 1994 estimate upto 5-10% of cellular Raf is assoc with Ras. Given that only 5-10% of Ras is GTP-bound, we need similar amounts of Ras as Raf. | GDP-Ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 729 | 0.4842 | 1.5 | No | GDP bound form. See Rosen et al Neuron 12 1207-1221 June 1994. the activation loop is based on Boguski and McCormick Nature 366 643-654 93 Assume Ras is present at about the same level as craf-1, 0.2 uM. Hallberg et al JBC 269:6 3913-3916 1994 estimate upto 5-10% of cellular Raf is assoc with Ras. Given that only 5-10% of Ras is GTP-bound, we need similar amounts of Ras as Raf. | GDP-Ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 735 | 0.4842 | 1.5 | No | GDP bound form. See Rosen et al Neuron 12 1207-1221 June 1994. the activation loop is based on Boguski and McCormick Nature 366 643-654 93 Assume Ras is present at about the same level as craf-1, 0.2 uM. Hallberg et al JBC 269:6 3913-3916 1994 estimate upto 5-10% of cellular Raf is assoc with Ras. Given that only 5-10% of Ras is GTP-bound, we need similar amounts of Ras as Raf. | GDP-Ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 741 | 0.4842 | 1.5 | No | GDP bound form. See Rosen et al Neuron 12 1207-1221 June 1994. the activation loop is based on Boguski and McCormick Nature 366 643-654 93 Assume Ras is present at about the same level as craf-1, 0.2 uM. Hallberg et al JBC 269:6 3913-3916 1994 estimate upto 5-10% of cellular Raf is assoc with Ras. Given that only 5-10% of Ras is GTP-bound, we need similar amounts of Ras as Raf. | GDP-Ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 747 | 0.4842 | 1.5 | No | GDP bound form. See Rosen et al Neuron 12 1207-1221 June 1994. the activation loop is based on Boguski and McCormick Nature 366 643-654 93 Assume Ras is present at about the same level as craf-1, 0.2 uM. Hallberg et al JBC 269:6 3913-3916 1994 estimate upto 5-10% of cellular Raf is assoc with Ras. Given that only 5-10% of Ras is GTP-bound, we need similar amounts of Ras as Raf. | GDP-Ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 753 | 0.4842 | 1.5 | No | GDP bound form. See Rosen et al Neuron 12 1207-1221 June 1994. the activation loop is based on Boguski and McCormick Nature 366 643-654 93 Assume Ras is present at about the same level as craf-1, 0.2 uM. Hallberg et al JBC 269:6 3913-3916 1994 estimate upto 5-10% of cellular Raf is assoc with Ras. Given that only 5-10% of Ras is GTP-bound, we need similar amounts of Ras as Raf. | GDP-Ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 759 | 0.4842 | 1.5 | No | GDP bound form. See Rosen et al Neuron 12 1207-1221 June 1994. the activation loop is based on Boguski and McCormick Nature 366 643-654 93 Assume Ras is present at about the same level as craf-1, 0.2 uM. Hallberg et al JBC 269:6 3913-3916 1994 estimate upto 5-10% of cellular Raf is assoc with Ras. Given that only 5-10% of Ras is GTP-bound, we need similar amounts of Ras as Raf. | GDP-Ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 765 | 0.4842 | 1.5 | No | GDP bound form. See Rosen et al Neuron 12 1207-1221 June 1994. the activation loop is based on Boguski and McCormick Nature 366 643-654 93 Assume Ras is present at about the same level as craf-1, 0.2 uM. Hallberg et al JBC 269:6 3913-3916 1994 estimate upto 5-10% of cellular Raf is assoc with Ras. Given that only 5-10% of Ras is GTP-bound, we need similar amounts of Ras as Raf. | GDP-Ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 771 | 0.4842 | 1.5 | No | GDP bound form. See Rosen et al Neuron 12 1207-1221 June 1994. the activation loop is based on Boguski and McCormick Nature 366 643-654 93 Assume Ras is present at about the same level as craf-1, 0.2 uM. Hallberg et al JBC 269:6 3913-3916 1994 estimate upto 5-10% of cellular Raf is assoc with Ras. Given that only 5-10% of Ras is GTP-bound, we need similar amounts of Ras as Raf. | GDP-Ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 777 | 0.4842 | 1.5 | No | GDP bound form. See Rosen et al Neuron 12 1207-1221 June 1994. the activation loop is based on Boguski and McCormick Nature 366 643-654 93 Assume Ras is present at about the same level as craf-1, 0.2 uM. Hallberg et al JBC 269:6 3913-3916 1994 estimate upto 5-10% of cellular Raf is assoc with Ras. Given that only 5-10% of Ras is GTP-bound, we need similar amounts of Ras as Raf. | GDP-Ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 783 | 0.4842 | 1.5 | No | GDP bound form. See Rosen et al Neuron 12 1207-1221 June 1994. the activation loop is based on Boguski and McCormick Nature 366 643-654 93 Assume Ras is present at about the same level as craf-1, 0.2 uM. Hallberg et al JBC 269:6 3913-3916 1994 estimate upto 5-10% of cellular Raf is assoc with Ras. Given that only 5-10% of Ras is GTP-bound, we need similar amounts of Ras as Raf. | GDP-Ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 789 | 0.4842 | 1.5 | No | GDP bound form. See Rosen et al Neuron 12 1207-1221 June 1994. the activation loop is based on Boguski and McCormick Nature 366 643-654 93 Assume Ras is present at about the same level as craf-1, 0.2 uM. Hallberg et al JBC 269:6 3913-3916 1994 estimate upto 5-10% of cellular Raf is assoc with Ras. Given that only 5-10% of Ras is GTP-bound, we need similar amounts of Ras as Raf. | GDP-Ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 795 | 0.4842 | 1.5 | No | GDP bound form. See Rosen et al Neuron 12 1207-1221 June 1994. the activation loop is based on Boguski and McCormick Nature 366 643-654 93 Assume Ras is present at about the same level as craf-1, 0.2 uM. Hallberg et al JBC 269:6 3913-3916 1994 estimate upto 5-10% of cellular Raf is assoc with Ras. Given that only 5-10% of Ras is GTP-bound, we need similar amounts of Ras as Raf. | GDP-Ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 801 | 0.4842 | 1.5 | No | GDP bound form. See Rosen et al Neuron 12 1207-1221 June 1994. the activation loop is based on Boguski and McCormick Nature 366 643-654 93 Assume Ras is present at about the same level as craf-1, 0.2 uM. Hallberg et al JBC 269:6 3913-3916 1994 estimate upto 5-10% of cellular Raf is assoc with Ras. Given that only 5-10% of Ras is GTP-bound, we need similar amounts of Ras as Raf. | GDP-Ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 807 | 0.4842 | 1.5 | No | GDP bound form. See Rosen et al Neuron 12 1207-1221 June 1994. the activation loop is based on Boguski and McCormick Nature 366 643-654 93 Assume Ras is present at about the same level as craf-1, 0.2 uM. Hallberg et al JBC 269:6 3913-3916 1994 estimate upto 5-10% of cellular Raf is assoc with Ras. Given that only 5-10% of Ras is GTP-bound, we need similar amounts of Ras as Raf. | GDP-Ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 813 | 0.4842 | 1.5 | No | GDP bound form. See Rosen et al Neuron 12 1207-1221 June 1994. the activation loop is based on Boguski and McCormick Nature 366 643-654 93 Assume Ras is present at about the same level as craf-1, 0.2 uM. Hallberg et al JBC 269:6 3913-3916 1994 estimate upto 5-10% of cellular Raf is assoc with Ras. Given that only 5-10% of Ras is GTP-bound, we need similar amounts of Ras as Raf. | GDP-Ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 819 | 0.4842 | 1.5 | No | GDP bound form. See Rosen et al Neuron 12 1207-1221 June 1994. the activation loop is based on Boguski and McCormick Nature 366 643-654 93 Assume Ras is present at about the same level as craf-1, 0.2 uM. Hallberg et al JBC 269:6 3913-3916 1994 estimate upto 5-10% of cellular Raf is assoc with Ras. Given that only 5-10% of Ras is GTP-bound, we need similar amounts of Ras as Raf. | GDP-Ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 825 | 0.4842 | 1.5 | No | GDP bound form. See Rosen et al Neuron 12 1207-1221 June 1994. the activation loop is based on Boguski and McCormick Nature 366 643-654 93 Assume Ras is present at about the same level as craf-1, 0.2 uM. Hallberg et al JBC 269:6 3913-3916 1994 estimate upto 5-10% of cellular Raf is assoc with Ras. Given that only 5-10% of Ras is GTP-bound, we need similar amounts of Ras as Raf. | GDP-Ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 831 | 0.4842 | 1.5 | No | GDP bound form. See Rosen et al Neuron 12 1207-1221 June 1994. the activation loop is based on Boguski and McCormick Nature 366 643-654 93 Assume Ras is present at about the same level as craf-1, 0.2 uM. Hallberg et al JBC 269:6 3913-3916 1994 estimate upto 5-10% of cellular Raf is assoc with Ras. Given that only 5-10% of Ras is GTP-bound, we need similar amounts of Ras as Raf. | GDP-Ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 837 | 0.4842 | 1.5 | No | GDP bound form. See Rosen et al Neuron 12 1207-1221 June 1994. the activation loop is based on Boguski and McCormick Nature 366 643-654 93 Assume Ras is present at about the same level as craf-1, 0.2 uM. Hallberg et al JBC 269:6 3913-3916 1994 estimate upto 5-10% of cellular Raf is assoc with Ras. Given that only 5-10% of Ras is GTP-bound, we need similar amounts of Ras as Raf. | GDP-Ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 843 | 0.4842 | 1.5 | No | GDP bound form. See Rosen et al Neuron 12 1207-1221 June 1994. the activation loop is based on Boguski and McCormick Nature 366 643-654 93 Assume Ras is present at about the same level as craf-1, 0.2 uM. Hallberg et al JBC 269:6 3913-3916 1994 estimate upto 5-10% of cellular Raf is assoc with Ras. Given that only 5-10% of Ras is GTP-bound, we need similar amounts of Ras as Raf. | GDP-Ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 849 | 0.4842 | 1.5 | No | GDP bound form. See Rosen et al Neuron 12 1207-1221 June 1994. the activation loop is based on Boguski and McCormick Nature 366 643-654 93 Assume Ras is present at about the same level as craf-1, 0.2 uM. Hallberg et al JBC 269:6 3913-3916 1994 estimate upto 5-10% of cellular Raf is assoc with Ras. Given that only 5-10% of Ras is GTP-bound, we need similar amounts of Ras as Raf. | GDP-Ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 855 | 0.4842 | 1.5 | No | GDP bound form. See Rosen et al Neuron 12 1207-1221 June 1994. the activation loop is based on Boguski and McCormick Nature 366 643-654 93 Assume Ras is present at about the same level as craf-1, 0.2 uM. Hallberg et al JBC 269:6 3913-3916 1994 estimate upto 5-10% of cellular Raf is assoc with Ras. Given that only 5-10% of Ras is GTP-bound, we need similar amounts of Ras as Raf. | GDP-Ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 861 | 0.4842 | 1.5 | No | GDP bound form. See Rosen et al Neuron 12 1207-1221 June 1994. the activation loop is based on Boguski and McCormick Nature 366 643-654 93 Assume Ras is present at about the same level as craf-1, 0.2 uM. Hallberg et al JBC 269:6 3913-3916 1994 estimate upto 5-10% of cellular Raf is assoc with Ras. Given that only 5-10% of Ras is GTP-bound, we need similar amounts of Ras as Raf. | GDP-Ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 867 | 0.4842 | 1.5 | No | GDP bound form. See Rosen et al Neuron 12 1207-1221 June 1994. the activation loop is based on Boguski and McCormick Nature 366 643-654 93 Assume Ras is present at about the same level as craf-1, 0.2 uM. Hallberg et al JBC 269:6 3913-3916 1994 estimate upto 5-10% of cellular Raf is assoc with Ras. Given that only 5-10% of Ras is GTP-bound, we need similar amounts of Ras as Raf. | GDP-Ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 873 | 0.4842 | 1.5 | No | GDP bound form. See Rosen et al Neuron 12 1207-1221 June 1994. the activation loop is based on Boguski and McCormick Nature 366 643-654 93 Assume Ras is present at about the same level as craf-1, 0.2 uM. Hallberg et al JBC 269:6 3913-3916 1994 estimate upto 5-10% of cellular Raf is assoc with Ras. Given that only 5-10% of Ras is GTP-bound, we need similar amounts of Ras as Raf. | GDP-Ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 879 | 0.4842 | 1.5 | No | GDP bound form. See Rosen et al Neuron 12 1207-1221 June 1994. the activation loop is based on Boguski and McCormick Nature 366 643-654 93 Assume Ras is present at about the same level as craf-1, 0.2 uM. Hallberg et al JBC 269:6 3913-3916 1994 estimate upto 5-10% of cellular Raf is assoc with Ras. Given that only 5-10% of Ras is GTP-bound, we need similar amounts of Ras as Raf. | GDP-Ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 885 | 0.4842 | 1.5 | No | GDP bound form. See Rosen et al Neuron 12 1207-1221 June 1994. the activation loop is based on Boguski and McCormick Nature 366 643-654 93 Assume Ras is present at about the same level as craf-1, 0.2 uM. Hallberg et al JBC 269:6 3913-3916 1994 estimate upto 5-10% of cellular Raf is assoc with Ras. Given that only 5-10% of Ras is GTP-bound, we need similar amounts of Ras as Raf. | GDP-Ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 891 | 0.4842 | 1.5 | No | GDP bound form. See Rosen et al Neuron 12 1207-1221 June 1994. the activation loop is based on Boguski and McCormick Nature 366 643-654 93 Assume Ras is present at about the same level as craf-1, 0.2 uM. Hallberg et al JBC 269:6 3913-3916 1994 estimate upto 5-10% of cellular Raf is assoc with Ras. Given that only 5-10% of Ras is GTP-bound, we need similar amounts of Ras as Raf. | GDP-Ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 897 | 0.4842 | 1.5 | No | GDP bound form. See Rosen et al Neuron 12 1207-1221 June 1994. the activation loop is based on Boguski and McCormick Nature 366 643-654 93 Assume Ras is present at about the same level as craf-1, 0.2 uM. Hallberg et al JBC 269:6 3913-3916 1994 estimate upto 5-10% of cellular Raf is assoc with Ras. Given that only 5-10% of Ras is GTP-bound, we need similar amounts of Ras as Raf. | GDP-Ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 903 | 0.4842 | 1.5 | No | GDP bound form. See Rosen et al Neuron 12 1207-1221 June 1994. the activation loop is based on Boguski and McCormick Nature 366 643-654 93 Assume Ras is present at about the same level as craf-1, 0.2 uM. Hallberg et al JBC 269:6 3913-3916 1994 estimate upto 5-10% of cellular Raf is assoc with Ras. Given that only 5-10% of Ras is GTP-bound, we need similar amounts of Ras as Raf. | GDP-Ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 909 | 0.4842 | 1.5 | No | GDP bound form. See Rosen et al Neuron 12 1207-1221 June 1994. the activation loop is based on Boguski and McCormick Nature 366 643-654 93 Assume Ras is present at about the same level as craf-1, 0.2 uM. Hallberg et al JBC 269:6 3913-3916 1994 estimate upto 5-10% of cellular Raf is assoc with Ras. Given that only 5-10% of Ras is GTP-bound, we need similar amounts of Ras as Raf. | GDP-Ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 680 | 0.4842 | 1.5 | Yes | GDP bound form. See Rosen et al Neuron 12 1207-1221 June 1994. the activation loop is based on Boguski and McCormick Nature 366 643-654 93 Assume Ras is present at about the same level as craf-1, 0.2 uM. Hallberg et al JBC 269:6 3913-3916 1994 estimate upto 5-10% of cellular Raf is assoc with Ras. Given that only 5-10% of Ras is GTP-bound, we need similar amounts of Ras as Raf. | GDP-Ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 915 | 0.4842 | 1.5 | Yes | GDP bound form. See Rosen et al Neuron 12 1207-1221 June 1994. the activation loop is based on Boguski and McCormick Nature 366 643-654 93 Assume Ras is present at about the same level as craf-1, 0.2 uM. Hallberg et al JBC 269:6 3913-3916 1994 estimate upto 5-10% of cellular Raf is assoc with Ras. Given that only 5-10% of Ras is GTP-bound, we need similar amounts of Ras as Raf. |
GDP-Ras acting as a Substrate for an Enzyme in Ajay_Bhalla_2007_ReacDiff2 Network
| Enzyme Molecule / Enzyme Activity | Accession Name | Pathway Name | Km (uM) | kcat (s^-1) | Ratio | Enzyme Type | Reagents | 1 | inact-GEF / basal_GEF_ activity
| Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 680 | 10.1015 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | | 2 | GEF* / GEF*-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 680 | 0.505057 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg-act-ras | 3 | CaM-GEF / CaM-GEF-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 680 | 0.505057 | 0.2 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg_act-ras, but as of March 17, 2006, the kcat is scaled from 0.02 to 0.2 to have a stronger Ca response for the direct MAPK input. | 4 | inact-GEF / basal_GEF_ activity
| Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 687 | 10.1015 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | | 5 | GEF* / GEF*-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 687 | 0.505057 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg-act-ras | 6 | CaM-GEF / CaM-GEF-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 687 | 0.505057 | 0.2 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg_act-ras, but as of March 17, 2006, the kcat is scaled from 0.02 to 0.2 to have a stronger Ca response for the direct MAPK input. | 7 | inact-GEF / basal_GEF_ activity
| Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 693 | 10.1015 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | | 8 | GEF* / GEF*-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 693 | 0.505057 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg-act-ras | 9 | CaM-GEF / CaM-GEF-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 693 | 0.505057 | 0.2 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg_act-ras, but as of March 17, 2006, the kcat is scaled from 0.02 to 0.2 to have a stronger Ca response for the direct MAPK input. | 10 | inact-GEF / basal_GEF_ activity
| Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 700 | 10.1015 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | | 11 | GEF* / GEF*-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 700 | 0.505057 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg-act-ras | 12 | CaM-GEF / CaM-GEF-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 700 | 0.505057 | 0.2 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg_act-ras, but as of March 17, 2006, the kcat is scaled from 0.02 to 0.2 to have a stronger Ca response for the direct MAPK input. | 13 | inact-GEF / basal_GEF_ activity
| Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 705 | 10.1015 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | | 14 | GEF* / GEF*-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 705 | 0.505057 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg-act-ras | 15 | CaM-GEF / CaM-GEF-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 705 | 0.505057 | 0.2 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg_act-ras, but as of March 17, 2006, the kcat is scaled from 0.02 to 0.2 to have a stronger Ca response for the direct MAPK input. | 16 | inact-GEF / basal_GEF_ activity
| Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 711 | 10.1015 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | | 17 | GEF* / GEF*-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 711 | 0.505057 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg-act-ras | 18 | CaM-GEF / CaM-GEF-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 711 | 0.505057 | 0.2 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg_act-ras, but as of March 17, 2006, the kcat is scaled from 0.02 to 0.2 to have a stronger Ca response for the direct MAPK input. | 19 | inact-GEF / basal_GEF_ activity
| Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 717 | 10.1015 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | | 20 | GEF* / GEF*-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 717 | 0.505057 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg-act-ras | 21 | CaM-GEF / CaM-GEF-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 717 | 0.505057 | 0.2 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg_act-ras, but as of March 17, 2006, the kcat is scaled from 0.02 to 0.2 to have a stronger Ca response for the direct MAPK input. | 22 | inact-GEF / basal_GEF_ activity
| Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 723 | 10.1015 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | | 23 | GEF* / GEF*-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 723 | 0.505057 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg-act-ras | 24 | CaM-GEF / CaM-GEF-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 723 | 0.505057 | 0.2 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg_act-ras, but as of March 17, 2006, the kcat is scaled from 0.02 to 0.2 to have a stronger Ca response for the direct MAPK input. | 25 | inact-GEF / basal_GEF_ activity
| Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 729 | 10.1015 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | | 26 | GEF* / GEF*-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 729 | 0.505057 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg-act-ras | 27 | CaM-GEF / CaM-GEF-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 729 | 0.505057 | 0.2 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg_act-ras, but as of March 17, 2006, the kcat is scaled from 0.02 to 0.2 to have a stronger Ca response for the direct MAPK input. | 28 | inact-GEF / basal_GEF_ activity
| Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 735 | 10.1015 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | | 29 | GEF* / GEF*-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 735 | 0.505057 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg-act-ras | 30 | CaM-GEF / CaM-GEF-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 735 | 0.505057 | 0.2 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg_act-ras, but as of March 17, 2006, the kcat is scaled from 0.02 to 0.2 to have a stronger Ca response for the direct MAPK input. | 31 | inact-GEF / basal_GEF_ activity
| Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 741 | 10.1015 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | | 32 | GEF* / GEF*-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 741 | 0.505057 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg-act-ras | 33 | CaM-GEF / CaM-GEF-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 741 | 0.505057 | 0.2 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg_act-ras, but as of March 17, 2006, the kcat is scaled from 0.02 to 0.2 to have a stronger Ca response for the direct MAPK input. | 34 | inact-GEF / basal_GEF_ activity
| Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 747 | 10.1015 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | | 35 | GEF* / GEF*-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 747 | 0.505057 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg-act-ras | 36 | CaM-GEF / CaM-GEF-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 747 | 0.505057 | 0.2 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg_act-ras, but as of March 17, 2006, the kcat is scaled from 0.02 to 0.2 to have a stronger Ca response for the direct MAPK input. | 37 | inact-GEF / basal_GEF_ activity
| Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 753 | 10.1015 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | | 38 | GEF* / GEF*-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 753 | 0.505057 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg-act-ras | 39 | CaM-GEF / CaM-GEF-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 753 | 0.505057 | 0.2 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg_act-ras, but as of March 17, 2006, the kcat is scaled from 0.02 to 0.2 to have a stronger Ca response for the direct MAPK input. | 40 | inact-GEF / basal_GEF_ activity
| Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 759 | 10.1015 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | | 41 | GEF* / GEF*-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 759 | 0.505057 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg-act-ras | 42 | CaM-GEF / CaM-GEF-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 759 | 0.505057 | 0.2 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg_act-ras, but as of March 17, 2006, the kcat is scaled from 0.02 to 0.2 to have a stronger Ca response for the direct MAPK input. | 43 | inact-GEF / basal_GEF_ activity
| Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 765 | 10.1015 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | | 44 | GEF* / GEF*-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 765 | 0.505057 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg-act-ras | 45 | CaM-GEF / CaM-GEF-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 765 | 0.505057 | 0.2 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg_act-ras, but as of March 17, 2006, the kcat is scaled from 0.02 to 0.2 to have a stronger Ca response for the direct MAPK input. | 46 | inact-GEF / basal_GEF_ activity
| Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 771 | 10.1015 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | | 47 | GEF* / GEF*-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 771 | 0.505057 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg-act-ras | 48 | CaM-GEF / CaM-GEF-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 771 | 0.505057 | 0.2 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg_act-ras, but as of March 17, 2006, the kcat is scaled from 0.02 to 0.2 to have a stronger Ca response for the direct MAPK input. | 49 | inact-GEF / basal_GEF_ activity
| Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 777 | 10.1015 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | | 50 | GEF* / GEF*-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 777 | 0.505057 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg-act-ras | 51 | CaM-GEF / CaM-GEF-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 777 | 0.505057 | 0.2 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg_act-ras, but as of March 17, 2006, the kcat is scaled from 0.02 to 0.2 to have a stronger Ca response for the direct MAPK input. | 52 | inact-GEF / basal_GEF_ activity
| Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 783 | 10.1015 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | | 53 | GEF* / GEF*-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 783 | 0.505057 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg-act-ras | 54 | CaM-GEF / CaM-GEF-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 783 | 0.505057 | 0.2 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg_act-ras, but as of March 17, 2006, the kcat is scaled from 0.02 to 0.2 to have a stronger Ca response for the direct MAPK input. | 55 | inact-GEF / basal_GEF_ activity
| Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 789 | 10.1015 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | | 56 | GEF* / GEF*-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 789 | 0.505057 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg-act-ras | 57 | CaM-GEF / CaM-GEF-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 789 | 0.505057 | 0.2 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg_act-ras, but as of March 17, 2006, the kcat is scaled from 0.02 to 0.2 to have a stronger Ca response for the direct MAPK input. | 58 | inact-GEF / basal_GEF_ activity
| Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 795 | 10.1015 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | | 59 | GEF* / GEF*-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 795 | 0.505057 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg-act-ras | 60 | CaM-GEF / CaM-GEF-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 795 | 0.505057 | 0.2 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg_act-ras, but as of March 17, 2006, the kcat is scaled from 0.02 to 0.2 to have a stronger Ca response for the direct MAPK input. | 61 | inact-GEF / basal_GEF_ activity
| Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 801 | 10.1015 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | | 62 | GEF* / GEF*-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 801 | 0.505057 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg-act-ras | 63 | CaM-GEF / CaM-GEF-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 801 | 0.505057 | 0.2 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg_act-ras, but as of March 17, 2006, the kcat is scaled from 0.02 to 0.2 to have a stronger Ca response for the direct MAPK input. | 64 | inact-GEF / basal_GEF_ activity
| Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 807 | 10.1015 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | | 65 | GEF* / GEF*-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 807 | 0.505057 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg-act-ras | 66 | CaM-GEF / CaM-GEF-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 807 | 0.505057 | 0.2 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg_act-ras, but as of March 17, 2006, the kcat is scaled from 0.02 to 0.2 to have a stronger Ca response for the direct MAPK input. | 67 | inact-GEF / basal_GEF_ activity
| Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 813 | 10.1015 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | | 68 | GEF* / GEF*-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 813 | 0.505057 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg-act-ras | 69 | CaM-GEF / CaM-GEF-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 813 | 0.505057 | 0.2 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg_act-ras, but as of March 17, 2006, the kcat is scaled from 0.02 to 0.2 to have a stronger Ca response for the direct MAPK input. | 70 | inact-GEF / basal_GEF_ activity
| Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 819 | 10.1015 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | | 71 | GEF* / GEF*-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 819 | 0.505057 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg-act-ras | 72 | CaM-GEF / CaM-GEF-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 819 | 0.505057 | 0.2 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg_act-ras, but as of March 17, 2006, the kcat is scaled from 0.02 to 0.2 to have a stronger Ca response for the direct MAPK input. | 73 | inact-GEF / basal_GEF_ activity
| Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 825 | 10.1015 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | | 74 | GEF* / GEF*-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 825 | 0.505057 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg-act-ras | 75 | CaM-GEF / CaM-GEF-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 825 | 0.505057 | 0.2 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg_act-ras, but as of March 17, 2006, the kcat is scaled from 0.02 to 0.2 to have a stronger Ca response for the direct MAPK input. | 76 | inact-GEF / basal_GEF_ activity
| Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 831 | 10.1015 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | | 77 | GEF* / GEF*-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 831 | 0.505057 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg-act-ras | 78 | CaM-GEF / CaM-GEF-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 831 | 0.505057 | 0.2 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg_act-ras, but as of March 17, 2006, the kcat is scaled from 0.02 to 0.2 to have a stronger Ca response for the direct MAPK input. | 79 | inact-GEF / basal_GEF_ activity
| Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 837 | 10.1015 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | | 80 | GEF* / GEF*-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 837 | 0.505057 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg-act-ras | 81 | CaM-GEF / CaM-GEF-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 837 | 0.505057 | 0.2 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg_act-ras, but as of March 17, 2006, the kcat is scaled from 0.02 to 0.2 to have a stronger Ca response for the direct MAPK input. | 82 | inact-GEF / basal_GEF_ activity
| Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 843 | 10.1015 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | | 83 | GEF* / GEF*-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 843 | 0.505057 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg-act-ras | 84 | CaM-GEF / CaM-GEF-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 843 | 0.505057 | 0.2 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg_act-ras, but as of March 17, 2006, the kcat is scaled from 0.02 to 0.2 to have a stronger Ca response for the direct MAPK input. | 85 | inact-GEF / basal_GEF_ activity
| Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 849 | 10.1015 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | | 86 | GEF* / GEF*-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 849 | 0.505057 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg-act-ras | 87 | CaM-GEF / CaM-GEF-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 849 | 0.505057 | 0.2 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg_act-ras, but as of March 17, 2006, the kcat is scaled from 0.02 to 0.2 to have a stronger Ca response for the direct MAPK input. | 88 | inact-GEF / basal_GEF_ activity
| Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 855 | 10.1015 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | | 89 | GEF* / GEF*-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 855 | 0.505057 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg-act-ras | 90 | CaM-GEF / CaM-GEF-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 855 | 0.505057 | 0.2 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg_act-ras, but as of March 17, 2006, the kcat is scaled from 0.02 to 0.2 to have a stronger Ca response for the direct MAPK input. | 91 | inact-GEF / basal_GEF_ activity
| Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 861 | 10.1015 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | | 92 | GEF* / GEF*-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 861 | 0.505057 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg-act-ras | 93 | CaM-GEF / CaM-GEF-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 861 | 0.505057 | 0.2 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg_act-ras, but as of March 17, 2006, the kcat is scaled from 0.02 to 0.2 to have a stronger Ca response for the direct MAPK input. | 94 | inact-GEF / basal_GEF_ activity
| Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 867 | 10.1015 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | | 95 | GEF* / GEF*-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 867 | 0.505057 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg-act-ras | 96 | CaM-GEF / CaM-GEF-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 867 | 0.505057 | 0.2 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg_act-ras, but as of March 17, 2006, the kcat is scaled from 0.02 to 0.2 to have a stronger Ca response for the direct MAPK input. | 97 | inact-GEF / basal_GEF_ activity
| Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 873 | 10.1015 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | | 98 | GEF* / GEF*-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 873 | 0.505057 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg-act-ras | 99 | CaM-GEF / CaM-GEF-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 873 | 0.505057 | 0.2 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg_act-ras, but as of March 17, 2006, the kcat is scaled from 0.02 to 0.2 to have a stronger Ca response for the direct MAPK input. | 100 | inact-GEF / basal_GEF_ activity
| Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 879 | 10.1015 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | | 101 | GEF* / GEF*-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 879 | 0.505057 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg-act-ras | 102 | CaM-GEF / CaM-GEF-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 879 | 0.505057 | 0.2 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg_act-ras, but as of March 17, 2006, the kcat is scaled from 0.02 to 0.2 to have a stronger Ca response for the direct MAPK input. | 103 | inact-GEF / basal_GEF_ activity
| Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 885 | 10.1015 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | | 104 | GEF* / GEF*-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 885 | 0.505057 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg-act-ras | 105 | CaM-GEF / CaM-GEF-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 885 | 0.505057 | 0.2 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg_act-ras, but as of March 17, 2006, the kcat is scaled from 0.02 to 0.2 to have a stronger Ca response for the direct MAPK input. | 106 | inact-GEF / basal_GEF_ activity
| Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 891 | 10.1015 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | | 107 | GEF* / GEF*-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 891 | 0.505057 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg-act-ras | 108 | CaM-GEF / CaM-GEF-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 891 | 0.505057 | 0.2 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg_act-ras, but as of March 17, 2006, the kcat is scaled from 0.02 to 0.2 to have a stronger Ca response for the direct MAPK input. | 109 | inact-GEF / basal_GEF_ activity
| Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 897 | 10.1015 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | | 110 | GEF* / GEF*-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 897 | 0.505057 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg-act-ras | 111 | CaM-GEF / CaM-GEF-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 897 | 0.505057 | 0.2 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg_act-ras, but as of March 17, 2006, the kcat is scaled from 0.02 to 0.2 to have a stronger Ca response for the direct MAPK input. | 112 | inact-GEF / basal_GEF_ activity
| Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 903 | 10.1015 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | | 113 | GEF* / GEF*-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 903 | 0.505057 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg-act-ras | 114 | CaM-GEF / CaM-GEF-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 903 | 0.505057 | 0.2 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg_act-ras, but as of March 17, 2006, the kcat is scaled from 0.02 to 0.2 to have a stronger Ca response for the direct MAPK input. | 115 | inact-GEF / basal_GEF_ activity
| Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 909 | 10.1015 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | | 116 | GEF* / GEF*-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 909 | 0.505057 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg-act-ras | 117 | CaM-GEF / CaM-GEF-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 909 | 0.505057 | 0.2 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg_act-ras, but as of March 17, 2006, the kcat is scaled from 0.02 to 0.2 to have a stronger Ca response for the direct MAPK input. | 118 | inact-GEF / basal_GEF_ activity
| Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 915 | 10.1015 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | | 119 | GEF* / GEF*-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 915 | 0.505057 | 0.02 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg-act-ras | 120 | CaM-GEF / CaM-GEF-act-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 915 | 0.505057 | 0.2 | 4 | explicit E-S complex | Substrate GDP-Ras
Product GTP-Ras
| | Kinetics same as GEF-bg_act-ras, but as of March 17, 2006, the kcat is scaled from 0.02 to 0.2 to have a stronger Ca response for the direct MAPK input. |
GDP-Ras acting as a Product of an Enzyme in Ajay_Bhalla_2007_ReacDiff2 Network
| Enzyme Molecule / Enzyme Activity | Accession Name | Pathway Name | Km (uM) | kcat (s^-1) | Ratio | Enzyme Type | Reagents | 1 | GAP / GAP-inact-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 680 | 1.0104 | 10 | 4 | explicit E-S complex | Substrate GTP-Ras
Product GDP-Ras
| | From Eccleston et al JBC 268(36)pp27012-19 get Kd < 2uM, kcat - 10/sec From Martin et al Cell 63 843-849 1990 get Kd ~ 250 nM, kcat = 20/min I will go with the Eccleston figures as there are good error bars (10%). In general the values are reasonably close. k1 = 1.666e-3/sec, k2 = 1000/sec, k3 = 10/sec (note k3 is rate-limiting) 5 Nov 2002: Changed ratio term to 4 from 100. Now we have k1=8.25e-5; k2=40, k3=10. k3 is still rate-limiting. | 2 | GAP / GAP-inact-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 687 | 1.0104 | 10 | 4 | explicit E-S complex | Substrate GTP-Ras
Product GDP-Ras
| | From Eccleston et al JBC 268(36)pp27012-19 get Kd < 2uM, kcat - 10/sec From Martin et al Cell 63 843-849 1990 get Kd ~ 250 nM, kcat = 20/min I will go with the Eccleston figures as there are good error bars (10%). In general the values are reasonably close. k1 = 1.666e-3/sec, k2 = 1000/sec, k3 = 10/sec (note k3 is rate-limiting) 5 Nov 2002: Changed ratio term to 4 from 100. Now we have k1=8.25e-5; k2=40, k3=10. k3 is still rate-limiting. | 3 | GAP / GAP-inact-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 693 | 1.0104 | 10 | 4 | explicit E-S complex | Substrate GTP-Ras
Product GDP-Ras
| | From Eccleston et al JBC 268(36)pp27012-19 get Kd < 2uM, kcat - 10/sec From Martin et al Cell 63 843-849 1990 get Kd ~ 250 nM, kcat = 20/min I will go with the Eccleston figures as there are good error bars (10%). In general the values are reasonably close. k1 = 1.666e-3/sec, k2 = 1000/sec, k3 = 10/sec (note k3 is rate-limiting) 5 Nov 2002: Changed ratio term to 4 from 100. Now we have k1=8.25e-5; k2=40, k3=10. k3 is still rate-limiting. | 4 | GAP / GAP-inact-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 700 | 1.0104 | 10 | 4 | explicit E-S complex | Substrate GTP-Ras
Product GDP-Ras
| | From Eccleston et al JBC 268(36)pp27012-19 get Kd < 2uM, kcat - 10/sec From Martin et al Cell 63 843-849 1990 get Kd ~ 250 nM, kcat = 20/min I will go with the Eccleston figures as there are good error bars (10%). In general the values are reasonably close. k1 = 1.666e-3/sec, k2 = 1000/sec, k3 = 10/sec (note k3 is rate-limiting) 5 Nov 2002: Changed ratio term to 4 from 100. Now we have k1=8.25e-5; k2=40, k3=10. k3 is still rate-limiting. | 5 | GAP / GAP-inact-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 705 | 1.0104 | 10 | 4 | explicit E-S complex | Substrate GTP-Ras
Product GDP-Ras
| | From Eccleston et al JBC 268(36)pp27012-19 get Kd < 2uM, kcat - 10/sec From Martin et al Cell 63 843-849 1990 get Kd ~ 250 nM, kcat = 20/min I will go with the Eccleston figures as there are good error bars (10%). In general the values are reasonably close. k1 = 1.666e-3/sec, k2 = 1000/sec, k3 = 10/sec (note k3 is rate-limiting) 5 Nov 2002: Changed ratio term to 4 from 100. Now we have k1=8.25e-5; k2=40, k3=10. k3 is still rate-limiting. | 6 | GAP / GAP-inact-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 711 | 1.0104 | 10 | 4 | explicit E-S complex | Substrate GTP-Ras
Product GDP-Ras
| | From Eccleston et al JBC 268(36)pp27012-19 get Kd < 2uM, kcat - 10/sec From Martin et al Cell 63 843-849 1990 get Kd ~ 250 nM, kcat = 20/min I will go with the Eccleston figures as there are good error bars (10%). In general the values are reasonably close. k1 = 1.666e-3/sec, k2 = 1000/sec, k3 = 10/sec (note k3 is rate-limiting) 5 Nov 2002: Changed ratio term to 4 from 100. Now we have k1=8.25e-5; k2=40, k3=10. k3 is still rate-limiting. | 7 | GAP / GAP-inact-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 717 | 1.0104 | 10 | 4 | explicit E-S complex | Substrate GTP-Ras
Product GDP-Ras
| | From Eccleston et al JBC 268(36)pp27012-19 get Kd < 2uM, kcat - 10/sec From Martin et al Cell 63 843-849 1990 get Kd ~ 250 nM, kcat = 20/min I will go with the Eccleston figures as there are good error bars (10%). In general the values are reasonably close. k1 = 1.666e-3/sec, k2 = 1000/sec, k3 = 10/sec (note k3 is rate-limiting) 5 Nov 2002: Changed ratio term to 4 from 100. Now we have k1=8.25e-5; k2=40, k3=10. k3 is still rate-limiting. | 8 | GAP / GAP-inact-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 723 | 1.0104 | 10 | 4 | explicit E-S complex | Substrate GTP-Ras
Product GDP-Ras
| | From Eccleston et al JBC 268(36)pp27012-19 get Kd < 2uM, kcat - 10/sec From Martin et al Cell 63 843-849 1990 get Kd ~ 250 nM, kcat = 20/min I will go with the Eccleston figures as there are good error bars (10%). In general the values are reasonably close. k1 = 1.666e-3/sec, k2 = 1000/sec, k3 = 10/sec (note k3 is rate-limiting) 5 Nov 2002: Changed ratio term to 4 from 100. Now we have k1=8.25e-5; k2=40, k3=10. k3 is still rate-limiting. | 9 | GAP / GAP-inact-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 729 | 1.0104 | 10 | 4 | explicit E-S complex | Substrate GTP-Ras
Product GDP-Ras
| | From Eccleston et al JBC 268(36)pp27012-19 get Kd < 2uM, kcat - 10/sec From Martin et al Cell 63 843-849 1990 get Kd ~ 250 nM, kcat = 20/min I will go with the Eccleston figures as there are good error bars (10%). In general the values are reasonably close. k1 = 1.666e-3/sec, k2 = 1000/sec, k3 = 10/sec (note k3 is rate-limiting) 5 Nov 2002: Changed ratio term to 4 from 100. Now we have k1=8.25e-5; k2=40, k3=10. k3 is still rate-limiting. | 10 | GAP / GAP-inact-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 735 | 1.0104 | 10 | 4 | explicit E-S complex | Substrate GTP-Ras
Product GDP-Ras
| | From Eccleston et al JBC 268(36)pp27012-19 get Kd < 2uM, kcat - 10/sec From Martin et al Cell 63 843-849 1990 get Kd ~ 250 nM, kcat = 20/min I will go with the Eccleston figures as there are good error bars (10%). In general the values are reasonably close. k1 = 1.666e-3/sec, k2 = 1000/sec, k3 = 10/sec (note k3 is rate-limiting) 5 Nov 2002: Changed ratio term to 4 from 100. Now we have k1=8.25e-5; k2=40, k3=10. k3 is still rate-limiting. | 11 | GAP / GAP-inact-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 741 | 1.0104 | 10 | 4 | explicit E-S complex | Substrate GTP-Ras
Product GDP-Ras
| | From Eccleston et al JBC 268(36)pp27012-19 get Kd < 2uM, kcat - 10/sec From Martin et al Cell 63 843-849 1990 get Kd ~ 250 nM, kcat = 20/min I will go with the Eccleston figures as there are good error bars (10%). In general the values are reasonably close. k1 = 1.666e-3/sec, k2 = 1000/sec, k3 = 10/sec (note k3 is rate-limiting) 5 Nov 2002: Changed ratio term to 4 from 100. Now we have k1=8.25e-5; k2=40, k3=10. k3 is still rate-limiting. | 12 | GAP / GAP-inact-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 747 | 1.0104 | 10 | 4 | explicit E-S complex | Substrate GTP-Ras
Product GDP-Ras
| | From Eccleston et al JBC 268(36)pp27012-19 get Kd < 2uM, kcat - 10/sec From Martin et al Cell 63 843-849 1990 get Kd ~ 250 nM, kcat = 20/min I will go with the Eccleston figures as there are good error bars (10%). In general the values are reasonably close. k1 = 1.666e-3/sec, k2 = 1000/sec, k3 = 10/sec (note k3 is rate-limiting) 5 Nov 2002: Changed ratio term to 4 from 100. Now we have k1=8.25e-5; k2=40, k3=10. k3 is still rate-limiting. | 13 | GAP / GAP-inact-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 753 | 1.0104 | 10 | 4 | explicit E-S complex | Substrate GTP-Ras
Product GDP-Ras
| | From Eccleston et al JBC 268(36)pp27012-19 get Kd < 2uM, kcat - 10/sec From Martin et al Cell 63 843-849 1990 get Kd ~ 250 nM, kcat = 20/min I will go with the Eccleston figures as there are good error bars (10%). In general the values are reasonably close. k1 = 1.666e-3/sec, k2 = 1000/sec, k3 = 10/sec (note k3 is rate-limiting) 5 Nov 2002: Changed ratio term to 4 from 100. Now we have k1=8.25e-5; k2=40, k3=10. k3 is still rate-limiting. | 14 | GAP / GAP-inact-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 759 | 1.0104 | 10 | 4 | explicit E-S complex | Substrate GTP-Ras
Product GDP-Ras
| | From Eccleston et al JBC 268(36)pp27012-19 get Kd < 2uM, kcat - 10/sec From Martin et al Cell 63 843-849 1990 get Kd ~ 250 nM, kcat = 20/min I will go with the Eccleston figures as there are good error bars (10%). In general the values are reasonably close. k1 = 1.666e-3/sec, k2 = 1000/sec, k3 = 10/sec (note k3 is rate-limiting) 5 Nov 2002: Changed ratio term to 4 from 100. Now we have k1=8.25e-5; k2=40, k3=10. k3 is still rate-limiting. | 15 | GAP / GAP-inact-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 765 | 1.0104 | 10 | 4 | explicit E-S complex | Substrate GTP-Ras
Product GDP-Ras
| | From Eccleston et al JBC 268(36)pp27012-19 get Kd < 2uM, kcat - 10/sec From Martin et al Cell 63 843-849 1990 get Kd ~ 250 nM, kcat = 20/min I will go with the Eccleston figures as there are good error bars (10%). In general the values are reasonably close. k1 = 1.666e-3/sec, k2 = 1000/sec, k3 = 10/sec (note k3 is rate-limiting) 5 Nov 2002: Changed ratio term to 4 from 100. Now we have k1=8.25e-5; k2=40, k3=10. k3 is still rate-limiting. | 16 | GAP / GAP-inact-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 771 | 1.0104 | 10 | 4 | explicit E-S complex | Substrate GTP-Ras
Product GDP-Ras
| | From Eccleston et al JBC 268(36)pp27012-19 get Kd < 2uM, kcat - 10/sec From Martin et al Cell 63 843-849 1990 get Kd ~ 250 nM, kcat = 20/min I will go with the Eccleston figures as there are good error bars (10%). In general the values are reasonably close. k1 = 1.666e-3/sec, k2 = 1000/sec, k3 = 10/sec (note k3 is rate-limiting) 5 Nov 2002: Changed ratio term to 4 from 100. Now we have k1=8.25e-5; k2=40, k3=10. k3 is still rate-limiting. | 17 | GAP / GAP-inact-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 777 | 1.0104 | 10 | 4 | explicit E-S complex | Substrate GTP-Ras
Product GDP-Ras
| | From Eccleston et al JBC 268(36)pp27012-19 get Kd < 2uM, kcat - 10/sec From Martin et al Cell 63 843-849 1990 get Kd ~ 250 nM, kcat = 20/min I will go with the Eccleston figures as there are good error bars (10%). In general the values are reasonably close. k1 = 1.666e-3/sec, k2 = 1000/sec, k3 = 10/sec (note k3 is rate-limiting) 5 Nov 2002: Changed ratio term to 4 from 100. Now we have k1=8.25e-5; k2=40, k3=10. k3 is still rate-limiting. | 18 | GAP / GAP-inact-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 783 | 1.0104 | 10 | 4 | explicit E-S complex | Substrate GTP-Ras
Product GDP-Ras
| | From Eccleston et al JBC 268(36)pp27012-19 get Kd < 2uM, kcat - 10/sec From Martin et al Cell 63 843-849 1990 get Kd ~ 250 nM, kcat = 20/min I will go with the Eccleston figures as there are good error bars (10%). In general the values are reasonably close. k1 = 1.666e-3/sec, k2 = 1000/sec, k3 = 10/sec (note k3 is rate-limiting) 5 Nov 2002: Changed ratio term to 4 from 100. Now we have k1=8.25e-5; k2=40, k3=10. k3 is still rate-limiting. | 19 | GAP / GAP-inact-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 789 | 1.0104 | 10 | 4 | explicit E-S complex | Substrate GTP-Ras
Product GDP-Ras
| | From Eccleston et al JBC 268(36)pp27012-19 get Kd < 2uM, kcat - 10/sec From Martin et al Cell 63 843-849 1990 get Kd ~ 250 nM, kcat = 20/min I will go with the Eccleston figures as there are good error bars (10%). In general the values are reasonably close. k1 = 1.666e-3/sec, k2 = 1000/sec, k3 = 10/sec (note k3 is rate-limiting) 5 Nov 2002: Changed ratio term to 4 from 100. Now we have k1=8.25e-5; k2=40, k3=10. k3 is still rate-limiting. | 20 | GAP / GAP-inact-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 795 | 1.0104 | 10 | 4 | explicit E-S complex | Substrate GTP-Ras
Product GDP-Ras
| | From Eccleston et al JBC 268(36)pp27012-19 get Kd < 2uM, kcat - 10/sec From Martin et al Cell 63 843-849 1990 get Kd ~ 250 nM, kcat = 20/min I will go with the Eccleston figures as there are good error bars (10%). In general the values are reasonably close. k1 = 1.666e-3/sec, k2 = 1000/sec, k3 = 10/sec (note k3 is rate-limiting) 5 Nov 2002: Changed ratio term to 4 from 100. Now we have k1=8.25e-5; k2=40, k3=10. k3 is still rate-limiting. | 21 | GAP / GAP-inact-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 801 | 1.0104 | 10 | 4 | explicit E-S complex | Substrate GTP-Ras
Product GDP-Ras
| | From Eccleston et al JBC 268(36)pp27012-19 get Kd < 2uM, kcat - 10/sec From Martin et al Cell 63 843-849 1990 get Kd ~ 250 nM, kcat = 20/min I will go with the Eccleston figures as there are good error bars (10%). In general the values are reasonably close. k1 = 1.666e-3/sec, k2 = 1000/sec, k3 = 10/sec (note k3 is rate-limiting) 5 Nov 2002: Changed ratio term to 4 from 100. Now we have k1=8.25e-5; k2=40, k3=10. k3 is still rate-limiting. | 22 | GAP / GAP-inact-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 807 | 1.0104 | 10 | 4 | explicit E-S complex | Substrate GTP-Ras
Product GDP-Ras
| | From Eccleston et al JBC 268(36)pp27012-19 get Kd < 2uM, kcat - 10/sec From Martin et al Cell 63 843-849 1990 get Kd ~ 250 nM, kcat = 20/min I will go with the Eccleston figures as there are good error bars (10%). In general the values are reasonably close. k1 = 1.666e-3/sec, k2 = 1000/sec, k3 = 10/sec (note k3 is rate-limiting) 5 Nov 2002: Changed ratio term to 4 from 100. Now we have k1=8.25e-5; k2=40, k3=10. k3 is still rate-limiting. | 23 | GAP / GAP-inact-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 813 | 1.0104 | 10 | 4 | explicit E-S complex | Substrate GTP-Ras
Product GDP-Ras
| | From Eccleston et al JBC 268(36)pp27012-19 get Kd < 2uM, kcat - 10/sec From Martin et al Cell 63 843-849 1990 get Kd ~ 250 nM, kcat = 20/min I will go with the Eccleston figures as there are good error bars (10%). In general the values are reasonably close. k1 = 1.666e-3/sec, k2 = 1000/sec, k3 = 10/sec (note k3 is rate-limiting) 5 Nov 2002: Changed ratio term to 4 from 100. Now we have k1=8.25e-5; k2=40, k3=10. k3 is still rate-limiting. | 24 | GAP / GAP-inact-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 819 | 1.0104 | 10 | 4 | explicit E-S complex | Substrate GTP-Ras
Product GDP-Ras
| | From Eccleston et al JBC 268(36)pp27012-19 get Kd < 2uM, kcat - 10/sec From Martin et al Cell 63 843-849 1990 get Kd ~ 250 nM, kcat = 20/min I will go with the Eccleston figures as there are good error bars (10%). In general the values are reasonably close. k1 = 1.666e-3/sec, k2 = 1000/sec, k3 = 10/sec (note k3 is rate-limiting) 5 Nov 2002: Changed ratio term to 4 from 100. Now we have k1=8.25e-5; k2=40, k3=10. k3 is still rate-limiting. | 25 | GAP / GAP-inact-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 825 | 1.0104 | 10 | 4 | explicit E-S complex | Substrate GTP-Ras
Product GDP-Ras
| | From Eccleston et al JBC 268(36)pp27012-19 get Kd < 2uM, kcat - 10/sec From Martin et al Cell 63 843-849 1990 get Kd ~ 250 nM, kcat = 20/min I will go with the Eccleston figures as there are good error bars (10%). In general the values are reasonably close. k1 = 1.666e-3/sec, k2 = 1000/sec, k3 = 10/sec (note k3 is rate-limiting) 5 Nov 2002: Changed ratio term to 4 from 100. Now we have k1=8.25e-5; k2=40, k3=10. k3 is still rate-limiting. | 26 | GAP / GAP-inact-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 831 | 1.0104 | 10 | 4 | explicit E-S complex | Substrate GTP-Ras
Product GDP-Ras
| | From Eccleston et al JBC 268(36)pp27012-19 get Kd < 2uM, kcat - 10/sec From Martin et al Cell 63 843-849 1990 get Kd ~ 250 nM, kcat = 20/min I will go with the Eccleston figures as there are good error bars (10%). In general the values are reasonably close. k1 = 1.666e-3/sec, k2 = 1000/sec, k3 = 10/sec (note k3 is rate-limiting) 5 Nov 2002: Changed ratio term to 4 from 100. Now we have k1=8.25e-5; k2=40, k3=10. k3 is still rate-limiting. | 27 | GAP / GAP-inact-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 837 | 1.0104 | 10 | 4 | explicit E-S complex | Substrate GTP-Ras
Product GDP-Ras
| | From Eccleston et al JBC 268(36)pp27012-19 get Kd < 2uM, kcat - 10/sec From Martin et al Cell 63 843-849 1990 get Kd ~ 250 nM, kcat = 20/min I will go with the Eccleston figures as there are good error bars (10%). In general the values are reasonably close. k1 = 1.666e-3/sec, k2 = 1000/sec, k3 = 10/sec (note k3 is rate-limiting) 5 Nov 2002: Changed ratio term to 4 from 100. Now we have k1=8.25e-5; k2=40, k3=10. k3 is still rate-limiting. | 28 | GAP / GAP-inact-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 843 | 1.0104 | 10 | 4 | explicit E-S complex | Substrate GTP-Ras
Product GDP-Ras
| | From Eccleston et al JBC 268(36)pp27012-19 get Kd < 2uM, kcat - 10/sec From Martin et al Cell 63 843-849 1990 get Kd ~ 250 nM, kcat = 20/min I will go with the Eccleston figures as there are good error bars (10%). In general the values are reasonably close. k1 = 1.666e-3/sec, k2 = 1000/sec, k3 = 10/sec (note k3 is rate-limiting) 5 Nov 2002: Changed ratio term to 4 from 100. Now we have k1=8.25e-5; k2=40, k3=10. k3 is still rate-limiting. | 29 | GAP / GAP-inact-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 849 | 1.0104 | 10 | 4 | explicit E-S complex | Substrate GTP-Ras
Product GDP-Ras
| | From Eccleston et al JBC 268(36)pp27012-19 get Kd < 2uM, kcat - 10/sec From Martin et al Cell 63 843-849 1990 get Kd ~ 250 nM, kcat = 20/min I will go with the Eccleston figures as there are good error bars (10%). In general the values are reasonably close. k1 = 1.666e-3/sec, k2 = 1000/sec, k3 = 10/sec (note k3 is rate-limiting) 5 Nov 2002: Changed ratio term to 4 from 100. Now we have k1=8.25e-5; k2=40, k3=10. k3 is still rate-limiting. | 30 | GAP / GAP-inact-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 855 | 1.0104 | 10 | 4 | explicit E-S complex | Substrate GTP-Ras
Product GDP-Ras
| | From Eccleston et al JBC 268(36)pp27012-19 get Kd < 2uM, kcat - 10/sec From Martin et al Cell 63 843-849 1990 get Kd ~ 250 nM, kcat = 20/min I will go with the Eccleston figures as there are good error bars (10%). In general the values are reasonably close. k1 = 1.666e-3/sec, k2 = 1000/sec, k3 = 10/sec (note k3 is rate-limiting) 5 Nov 2002: Changed ratio term to 4 from 100. Now we have k1=8.25e-5; k2=40, k3=10. k3 is still rate-limiting. | 31 | GAP / GAP-inact-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 861 | 1.0104 | 10 | 4 | explicit E-S complex | Substrate GTP-Ras
Product GDP-Ras
| | From Eccleston et al JBC 268(36)pp27012-19 get Kd < 2uM, kcat - 10/sec From Martin et al Cell 63 843-849 1990 get Kd ~ 250 nM, kcat = 20/min I will go with the Eccleston figures as there are good error bars (10%). In general the values are reasonably close. k1 = 1.666e-3/sec, k2 = 1000/sec, k3 = 10/sec (note k3 is rate-limiting) 5 Nov 2002: Changed ratio term to 4 from 100. Now we have k1=8.25e-5; k2=40, k3=10. k3 is still rate-limiting. | 32 | GAP / GAP-inact-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 867 | 1.0104 | 10 | 4 | explicit E-S complex | Substrate GTP-Ras
Product GDP-Ras
| | From Eccleston et al JBC 268(36)pp27012-19 get Kd < 2uM, kcat - 10/sec From Martin et al Cell 63 843-849 1990 get Kd ~ 250 nM, kcat = 20/min I will go with the Eccleston figures as there are good error bars (10%). In general the values are reasonably close. k1 = 1.666e-3/sec, k2 = 1000/sec, k3 = 10/sec (note k3 is rate-limiting) 5 Nov 2002: Changed ratio term to 4 from 100. Now we have k1=8.25e-5; k2=40, k3=10. k3 is still rate-limiting. | 33 | GAP / GAP-inact-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 873 | 1.0104 | 10 | 4 | explicit E-S complex | Substrate GTP-Ras
Product GDP-Ras
| | From Eccleston et al JBC 268(36)pp27012-19 get Kd < 2uM, kcat - 10/sec From Martin et al Cell 63 843-849 1990 get Kd ~ 250 nM, kcat = 20/min I will go with the Eccleston figures as there are good error bars (10%). In general the values are reasonably close. k1 = 1.666e-3/sec, k2 = 1000/sec, k3 = 10/sec (note k3 is rate-limiting) 5 Nov 2002: Changed ratio term to 4 from 100. Now we have k1=8.25e-5; k2=40, k3=10. k3 is still rate-limiting. | 34 | GAP / GAP-inact-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 879 | 1.0104 | 10 | 4 | explicit E-S complex | Substrate GTP-Ras
Product GDP-Ras
| | From Eccleston et al JBC 268(36)pp27012-19 get Kd < 2uM, kcat - 10/sec From Martin et al Cell 63 843-849 1990 get Kd ~ 250 nM, kcat = 20/min I will go with the Eccleston figures as there are good error bars (10%). In general the values are reasonably close. k1 = 1.666e-3/sec, k2 = 1000/sec, k3 = 10/sec (note k3 is rate-limiting) 5 Nov 2002: Changed ratio term to 4 from 100. Now we have k1=8.25e-5; k2=40, k3=10. k3 is still rate-limiting. | 35 | GAP / GAP-inact-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 885 | 1.0104 | 10 | 4 | explicit E-S complex | Substrate GTP-Ras
Product GDP-Ras
| | From Eccleston et al JBC 268(36)pp27012-19 get Kd < 2uM, kcat - 10/sec From Martin et al Cell 63 843-849 1990 get Kd ~ 250 nM, kcat = 20/min I will go with the Eccleston figures as there are good error bars (10%). In general the values are reasonably close. k1 = 1.666e-3/sec, k2 = 1000/sec, k3 = 10/sec (note k3 is rate-limiting) 5 Nov 2002: Changed ratio term to 4 from 100. Now we have k1=8.25e-5; k2=40, k3=10. k3 is still rate-limiting. | 36 | GAP / GAP-inact-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 891 | 1.0104 | 10 | 4 | explicit E-S complex | Substrate GTP-Ras
Product GDP-Ras
| | From Eccleston et al JBC 268(36)pp27012-19 get Kd < 2uM, kcat - 10/sec From Martin et al Cell 63 843-849 1990 get Kd ~ 250 nM, kcat = 20/min I will go with the Eccleston figures as there are good error bars (10%). In general the values are reasonably close. k1 = 1.666e-3/sec, k2 = 1000/sec, k3 = 10/sec (note k3 is rate-limiting) 5 Nov 2002: Changed ratio term to 4 from 100. Now we have k1=8.25e-5; k2=40, k3=10. k3 is still rate-limiting. | 37 | GAP / GAP-inact-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 897 | 1.0104 | 10 | 4 | explicit E-S complex | Substrate GTP-Ras
Product GDP-Ras
| | From Eccleston et al JBC 268(36)pp27012-19 get Kd < 2uM, kcat - 10/sec From Martin et al Cell 63 843-849 1990 get Kd ~ 250 nM, kcat = 20/min I will go with the Eccleston figures as there are good error bars (10%). In general the values are reasonably close. k1 = 1.666e-3/sec, k2 = 1000/sec, k3 = 10/sec (note k3 is rate-limiting) 5 Nov 2002: Changed ratio term to 4 from 100. Now we have k1=8.25e-5; k2=40, k3=10. k3 is still rate-limiting. | 38 | GAP / GAP-inact-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 903 | 1.0104 | 10 | 4 | explicit E-S complex | Substrate GTP-Ras
Product GDP-Ras
| | From Eccleston et al JBC 268(36)pp27012-19 get Kd < 2uM, kcat - 10/sec From Martin et al Cell 63 843-849 1990 get Kd ~ 250 nM, kcat = 20/min I will go with the Eccleston figures as there are good error bars (10%). In general the values are reasonably close. k1 = 1.666e-3/sec, k2 = 1000/sec, k3 = 10/sec (note k3 is rate-limiting) 5 Nov 2002: Changed ratio term to 4 from 100. Now we have k1=8.25e-5; k2=40, k3=10. k3 is still rate-limiting. | 39 | GAP / GAP-inact-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 909 | 1.0104 | 10 | 4 | explicit E-S complex | Substrate GTP-Ras
Product GDP-Ras
| | From Eccleston et al JBC 268(36)pp27012-19 get Kd < 2uM, kcat - 10/sec From Martin et al Cell 63 843-849 1990 get Kd ~ 250 nM, kcat = 20/min I will go with the Eccleston figures as there are good error bars (10%). In general the values are reasonably close. k1 = 1.666e-3/sec, k2 = 1000/sec, k3 = 10/sec (note k3 is rate-limiting) 5 Nov 2002: Changed ratio term to 4 from 100. Now we have k1=8.25e-5; k2=40, k3=10. k3 is still rate-limiting. | 40 | GAP / GAP-inact-ras | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 915 | 1.0104 | 10 | 4 | explicit E-S complex | Substrate GTP-Ras
Product GDP-Ras
| | From Eccleston et al JBC 268(36)pp27012-19 get Kd < 2uM, kcat - 10/sec From Martin et al Cell 63 843-849 1990 get Kd ~ 250 nM, kcat = 20/min I will go with the Eccleston figures as there are good error bars (10%). In general the values are reasonably close. k1 = 1.666e-3/sec, k2 = 1000/sec, k3 = 10/sec (note k3 is rate-limiting) 5 Nov 2002: Changed ratio term to 4 from 100. Now we have k1=8.25e-5; k2=40, k3=10. k3 is still rate-limiting. |
GDP-Ras acting as a Substrate in a reaction in Ajay_Bhalla_2007_ReacDiff2 Network
Kd is calculated only for second order reactions, like nA+nB <->nC or nA<->nC+nD, where n is number and A,B,C,D are molecules, where as for first order reactions Keq is calculated.
Kd for higher order reaction are not consider. |
GDP-Ras acting as a Product in a reaction in Ajay_Bhalla_2007_ReacDiff2 Network
Kd is calculated only for second order reactions, like nA+nB <->nC or nA<->nC+nD, where n is number and A,B,C,D are molecules, where as for first order reactions Keq is calculated.
Kd for higher order reaction are not consider. |
| Name | Accession Name | Pathway Name | Kf | Kb | Kd | tau | Reagents | 1 | diff | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Shared_Object_ Ajay_Bhalla_ 2007_ReacDiff Pathway No. : 677 | 0.101 (s^-1) | 0.001 (s^-1) | Keq = 0.0099(uM) | 9.804sec | Substrate GDP-Ras
Product GDP-Ras
| 2 | Ras-intrinsic-GT Pase | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 680 | 0.0001 (s^-1) | 0 (s^-1) | - | - | Substrate GTP-Ras
Product GDP-Ras
| | This is extremely slow (1e-4), but it is significant as so little GAP actually gets complexed with it that the total GTP turnover rises only by 2-3 X (see Gibbs et al, JBC 265(33) 20437-20422) and Eccleston et al JBC 268(36) 27012-27019 kf = 1e-4 | 3 | diff | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Shared_Object_ Ajay_Bhalla_ 2007_ReacDiff Pathway No. : 677 | 0.101 (s^-1) | 0.001 (s^-1) | Keq = 0.0099(uM) | 9.804sec | Substrate GDP-Ras
Product GDP-Ras
| 4 | Ras-intrinsic-GT Pase | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 687 | 0.0001 (s^-1) | 0 (s^-1) | - | - | Substrate GTP-Ras
Product GDP-Ras
| | This is extremely slow (1e-4), but it is significant as so little GAP actually gets complexed with it that the total GTP turnover rises only by 2-3 X (see Gibbs et al, JBC 265(33) 20437-20422) and Eccleston et al JBC 268(36) 27012-27019 kf = 1e-4 | 5 | diff | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Shared_Object_ Ajay_Bhalla_ 2007_ReacDiff Pathway No. : 677 | 0.101 (s^-1) | 0.001 (s^-1) | Keq = 0.0099(uM) | 9.804sec | Substrate GDP-Ras
Product GDP-Ras
| 6 | Ras-intrinsic-GT Pase | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 693 | 0.0001 (s^-1) | 0 (s^-1) | - | - | Substrate GTP-Ras
Product GDP-Ras
| | This is extremely slow (1e-4), but it is significant as so little GAP actually gets complexed with it that the total GTP turnover rises only by 2-3 X (see Gibbs et al, JBC 265(33) 20437-20422) and Eccleston et al JBC 268(36) 27012-27019 kf = 1e-4 | 7 | diff | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Shared_Object_ Ajay_Bhalla_ 2007_ReacDiff Pathway No. : 677 | 0.101 (s^-1) | 0.001 (s^-1) | Keq = 0.0099(uM) | 9.804sec | Substrate GDP-Ras
Product GDP-Ras
| 8 | Ras-intrinsic-GT Pase | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 700 | 0.0001 (s^-1) | 0 (s^-1) | - | - | Substrate GTP-Ras
Product GDP-Ras
| | This is extremely slow (1e-4), but it is significant as so little GAP actually gets complexed with it that the total GTP turnover rises only by 2-3 X (see Gibbs et al, JBC 265(33) 20437-20422) and Eccleston et al JBC 268(36) 27012-27019 kf = 1e-4 | 9 | diff | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Shared_Object_ Ajay_Bhalla_ 2007_ReacDiff Pathway No. : 677 | 0.101 (s^-1) | 0.001 (s^-1) | Keq = 0.0099(uM) | 9.804sec | Substrate GDP-Ras
Product GDP-Ras
| 10 | Ras-intrinsic-GT Pase | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 705 | 0.0001 (s^-1) | 0 (s^-1) | - | - | Substrate GTP-Ras
Product GDP-Ras
| | This is extremely slow (1e-4), but it is significant as so little GAP actually gets complexed with it that the total GTP turnover rises only by 2-3 X (see Gibbs et al, JBC 265(33) 20437-20422) and Eccleston et al JBC 268(36) 27012-27019 kf = 1e-4 | 11 | diff | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Shared_Object_ Ajay_Bhalla_ 2007_ReacDiff Pathway No. : 677 | 0.101 (s^-1) | 0.001 (s^-1) | Keq = 0.0099(uM) | 9.804sec | Substrate GDP-Ras
Product GDP-Ras
| 12 | Ras-intrinsic-GT Pase | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 711 | 0.0001 (s^-1) | 0 (s^-1) | - | - | Substrate GTP-Ras
Product GDP-Ras
| | This is extremely slow (1e-4), but it is significant as so little GAP actually gets complexed with it that the total GTP turnover rises only by 2-3 X (see Gibbs et al, JBC 265(33) 20437-20422) and Eccleston et al JBC 268(36) 27012-27019 kf = 1e-4 | 13 | diff | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Shared_Object_ Ajay_Bhalla_ 2007_ReacDiff Pathway No. : 677 | 0.101 (s^-1) | 0.001 (s^-1) | Keq = 0.0099(uM) | 9.804sec | Substrate GDP-Ras
Product GDP-Ras
| 14 | Ras-intrinsic-GT Pase | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 717 | 0.0001 (s^-1) | 0 (s^-1) | - | - | Substrate GTP-Ras
Product GDP-Ras
| | This is extremely slow (1e-4), but it is significant as so little GAP actually gets complexed with it that the total GTP turnover rises only by 2-3 X (see Gibbs et al, JBC 265(33) 20437-20422) and Eccleston et al JBC 268(36) 27012-27019 kf = 1e-4 | 15 | diff | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Shared_Object_ Ajay_Bhalla_ 2007_ReacDiff Pathway No. : 677 | 0.101 (s^-1) | 0.001 (s^-1) | Keq = 0.0099(uM) | 9.804sec | Substrate GDP-Ras
Product GDP-Ras
| 16 | Ras-intrinsic-GT Pase | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 723 | 0.0001 (s^-1) | 0 (s^-1) | - | - | Substrate GTP-Ras
Product GDP-Ras
| | This is extremely slow (1e-4), but it is significant as so little GAP actually gets complexed with it that the total GTP turnover rises only by 2-3 X (see Gibbs et al, JBC 265(33) 20437-20422) and Eccleston et al JBC 268(36) 27012-27019 kf = 1e-4 | 17 | diff | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Shared_Object_ Ajay_Bhalla_ 2007_ReacDiff Pathway No. : 677 | 0.101 (s^-1) | 0.001 (s^-1) | Keq = 0.0099(uM) | 9.804sec | Substrate GDP-Ras
Product GDP-Ras
| 18 | Ras-intrinsic-GT Pase | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 729 | 0.0001 (s^-1) | 0 (s^-1) | - | - | Substrate GTP-Ras
Product GDP-Ras
| | This is extremely slow (1e-4), but it is significant as so little GAP actually gets complexed with it that the total GTP turnover rises only by 2-3 X (see Gibbs et al, JBC 265(33) 20437-20422) and Eccleston et al JBC 268(36) 27012-27019 kf = 1e-4 | 19 | diff | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Shared_Object_ Ajay_Bhalla_ 2007_ReacDiff Pathway No. : 677 | 0.101 (s^-1) | 0.001 (s^-1) | Keq = 0.0099(uM) | 9.804sec | Substrate GDP-Ras
Product GDP-Ras
| 20 | Ras-intrinsic-GT Pase | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 735 | 0.0001 (s^-1) | 0 (s^-1) | - | - | Substrate GTP-Ras
Product GDP-Ras
| | This is extremely slow (1e-4), but it is significant as so little GAP actually gets complexed with it that the total GTP turnover rises only by 2-3 X (see Gibbs et al, JBC 265(33) 20437-20422) and Eccleston et al JBC 268(36) 27012-27019 kf = 1e-4 | 21 | diff | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Shared_Object_ Ajay_Bhalla_ 2007_ReacDiff Pathway No. : 677 | 0.101 (s^-1) | 0.001 (s^-1) | Keq = 0.0099(uM) | 9.804sec | Substrate GDP-Ras
Product GDP-Ras
| 22 | Ras-intrinsic-GT Pase | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 741 | 0.0001 (s^-1) | 0 (s^-1) | - | - | Substrate GTP-Ras
Product GDP-Ras
| | This is extremely slow (1e-4), but it is significant as so little GAP actually gets complexed with it that the total GTP turnover rises only by 2-3 X (see Gibbs et al, JBC 265(33) 20437-20422) and Eccleston et al JBC 268(36) 27012-27019 kf = 1e-4 | 23 | diff | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Shared_Object_ Ajay_Bhalla_ 2007_ReacDiff Pathway No. : 677 | 0.101 (s^-1) | 0.001 (s^-1) | Keq = 0.0099(uM) | 9.804sec | Substrate GDP-Ras
Product GDP-Ras
| 24 | Ras-intrinsic-GT Pase | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 747 | 0.0001 (s^-1) | 0 (s^-1) | - | - | Substrate GTP-Ras
Product GDP-Ras
| | This is extremely slow (1e-4), but it is significant as so little GAP actually gets complexed with it that the total GTP turnover rises only by 2-3 X (see Gibbs et al, JBC 265(33) 20437-20422) and Eccleston et al JBC 268(36) 27012-27019 kf = 1e-4 | 25 | diff | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Shared_Object_ Ajay_Bhalla_ 2007_ReacDiff Pathway No. : 677 | 0.101 (s^-1) | 0.001 (s^-1) | Keq = 0.0099(uM) | 9.804sec | Substrate GDP-Ras
Product GDP-Ras
| 26 | Ras-intrinsic-GT Pase | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 753 | 0.0001 (s^-1) | 0 (s^-1) | - | - | Substrate GTP-Ras
Product GDP-Ras
| | This is extremely slow (1e-4), but it is significant as so little GAP actually gets complexed with it that the total GTP turnover rises only by 2-3 X (see Gibbs et al, JBC 265(33) 20437-20422) and Eccleston et al JBC 268(36) 27012-27019 kf = 1e-4 | 27 | diff | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Shared_Object_ Ajay_Bhalla_ 2007_ReacDiff Pathway No. : 677 | 0.101 (s^-1) | 0.001 (s^-1) | Keq = 0.0099(uM) | 9.804sec | Substrate GDP-Ras
Product GDP-Ras
| 28 | Ras-intrinsic-GT Pase | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 759 | 0.0001 (s^-1) | 0 (s^-1) | - | - | Substrate GTP-Ras
Product GDP-Ras
| | This is extremely slow (1e-4), but it is significant as so little GAP actually gets complexed with it that the total GTP turnover rises only by 2-3 X (see Gibbs et al, JBC 265(33) 20437-20422) and Eccleston et al JBC 268(36) 27012-27019 kf = 1e-4 | 29 | diff | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Shared_Object_ Ajay_Bhalla_ 2007_ReacDiff Pathway No. : 677 | 0.101 (s^-1) | 0.001 (s^-1) | Keq = 0.0099(uM) | 9.804sec | Substrate GDP-Ras
Product GDP-Ras
| 30 | Ras-intrinsic-GT Pase | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 765 | 0.0001 (s^-1) | 0 (s^-1) | - | - | Substrate GTP-Ras
Product GDP-Ras
| | This is extremely slow (1e-4), but it is significant as so little GAP actually gets complexed with it that the total GTP turnover rises only by 2-3 X (see Gibbs et al, JBC 265(33) 20437-20422) and Eccleston et al JBC 268(36) 27012-27019 kf = 1e-4 | 31 | diff | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Shared_Object_ Ajay_Bhalla_ 2007_ReacDiff Pathway No. : 677 | 0.101 (s^-1) | 0.001 (s^-1) | Keq = 0.0099(uM) | 9.804sec | Substrate GDP-Ras
Product GDP-Ras
| 32 | Ras-intrinsic-GT Pase | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 771 | 0.0001 (s^-1) | 0 (s^-1) | - | - | Substrate GTP-Ras
Product GDP-Ras
| | This is extremely slow (1e-4), but it is significant as so little GAP actually gets complexed with it that the total GTP turnover rises only by 2-3 X (see Gibbs et al, JBC 265(33) 20437-20422) and Eccleston et al JBC 268(36) 27012-27019 kf = 1e-4 | 33 | diff | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Shared_Object_ Ajay_Bhalla_ 2007_ReacDiff Pathway No. : 677 | 0.101 (s^-1) | 0.001 (s^-1) | Keq = 0.0099(uM) | 9.804sec | Substrate GDP-Ras
Product GDP-Ras
| 34 | Ras-intrinsic-GT Pase | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 777 | 0.0001 (s^-1) | 0 (s^-1) | - | - | Substrate GTP-Ras
Product GDP-Ras
| | This is extremely slow (1e-4), but it is significant as so little GAP actually gets complexed with it that the total GTP turnover rises only by 2-3 X (see Gibbs et al, JBC 265(33) 20437-20422) and Eccleston et al JBC 268(36) 27012-27019 kf = 1e-4 | 35 | diff | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Shared_Object_ Ajay_Bhalla_ 2007_ReacDiff Pathway No. : 677 | 0.101 (s^-1) | 0.001 (s^-1) | Keq = 0.0099(uM) | 9.804sec | Substrate GDP-Ras
Product GDP-Ras
| 36 | Ras-intrinsic-GT Pase | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 783 | 0.0001 (s^-1) | 0 (s^-1) | - | - | Substrate GTP-Ras
Product GDP-Ras
| | This is extremely slow (1e-4), but it is significant as so little GAP actually gets complexed with it that the total GTP turnover rises only by 2-3 X (see Gibbs et al, JBC 265(33) 20437-20422) and Eccleston et al JBC 268(36) 27012-27019 kf = 1e-4 | 37 | diff | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Shared_Object_ Ajay_Bhalla_ 2007_ReacDiff Pathway No. : 677 | 0.101 (s^-1) | 0.001 (s^-1) | Keq = 0.0099(uM) | 9.804sec | Substrate GDP-Ras
Product GDP-Ras
| 38 | Ras-intrinsic-GT Pase | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 789 | 0.0001 (s^-1) | 0 (s^-1) | - | - | Substrate GTP-Ras
Product GDP-Ras
| | This is extremely slow (1e-4), but it is significant as so little GAP actually gets complexed with it that the total GTP turnover rises only by 2-3 X (see Gibbs et al, JBC 265(33) 20437-20422) and Eccleston et al JBC 268(36) 27012-27019 kf = 1e-4 | 39 | diff | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Shared_Object_ Ajay_Bhalla_ 2007_ReacDiff Pathway No. : 677 | 0.101 (s^-1) | 0.001 (s^-1) | Keq = 0.0099(uM) | 9.804sec | Substrate GDP-Ras
Product GDP-Ras
| 40 | Ras-intrinsic-GT Pase | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 795 | 0.0001 (s^-1) | 0 (s^-1) | - | - | Substrate GTP-Ras
Product GDP-Ras
| | This is extremely slow (1e-4), but it is significant as so little GAP actually gets complexed with it that the total GTP turnover rises only by 2-3 X (see Gibbs et al, JBC 265(33) 20437-20422) and Eccleston et al JBC 268(36) 27012-27019 kf = 1e-4 | 41 | diff | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Shared_Object_ Ajay_Bhalla_ 2007_ReacDiff Pathway No. : 677 | 0.101 (s^-1) | 0.001 (s^-1) | Keq = 0.0099(uM) | 9.804sec | Substrate GDP-Ras
Product GDP-Ras
| 42 | Ras-intrinsic-GT Pase | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 801 | 0.0001 (s^-1) | 0 (s^-1) | - | - | Substrate GTP-Ras
Product GDP-Ras
| | This is extremely slow (1e-4), but it is significant as so little GAP actually gets complexed with it that the total GTP turnover rises only by 2-3 X (see Gibbs et al, JBC 265(33) 20437-20422) and Eccleston et al JBC 268(36) 27012-27019 kf = 1e-4 | 43 | diff | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Shared_Object_ Ajay_Bhalla_ 2007_ReacDiff Pathway No. : 677 | 0.101 (s^-1) | 0.001 (s^-1) | Keq = 0.0099(uM) | 9.804sec | Substrate GDP-Ras
Product GDP-Ras
| 44 | Ras-intrinsic-GT Pase | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 807 | 0.0001 (s^-1) | 0 (s^-1) | - | - | Substrate GTP-Ras
Product GDP-Ras
| | This is extremely slow (1e-4), but it is significant as so little GAP actually gets complexed with it that the total GTP turnover rises only by 2-3 X (see Gibbs et al, JBC 265(33) 20437-20422) and Eccleston et al JBC 268(36) 27012-27019 kf = 1e-4 | 45 | diff | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Shared_Object_ Ajay_Bhalla_ 2007_ReacDiff Pathway No. : 677 | 0.101 (s^-1) | 0.001 (s^-1) | Keq = 0.0099(uM) | 9.804sec | Substrate GDP-Ras
Product GDP-Ras
| 46 | Ras-intrinsic-GT Pase | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 813 | 0.0001 (s^-1) | 0 (s^-1) | - | - | Substrate GTP-Ras
Product GDP-Ras
| | This is extremely slow (1e-4), but it is significant as so little GAP actually gets complexed with it that the total GTP turnover rises only by 2-3 X (see Gibbs et al, JBC 265(33) 20437-20422) and Eccleston et al JBC 268(36) 27012-27019 kf = 1e-4 | 47 | diff | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Shared_Object_ Ajay_Bhalla_ 2007_ReacDiff Pathway No. : 677 | 0.101 (s^-1) | 0.001 (s^-1) | Keq = 0.0099(uM) | 9.804sec | Substrate GDP-Ras
Product GDP-Ras
| 48 | Ras-intrinsic-GT Pase | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 819 | 0.0001 (s^-1) | 0 (s^-1) | - | - | Substrate GTP-Ras
Product GDP-Ras
| | This is extremely slow (1e-4), but it is significant as so little GAP actually gets complexed with it that the total GTP turnover rises only by 2-3 X (see Gibbs et al, JBC 265(33) 20437-20422) and Eccleston et al JBC 268(36) 27012-27019 kf = 1e-4 | 49 | diff | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Shared_Object_ Ajay_Bhalla_ 2007_ReacDiff Pathway No. : 677 | 0.101 (s^-1) | 0.001 (s^-1) | Keq = 0.0099(uM) | 9.804sec | Substrate GDP-Ras
Product GDP-Ras
| 50 | Ras-intrinsic-GT Pase | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 825 | 0.0001 (s^-1) | 0 (s^-1) | - | - | Substrate GTP-Ras
Product GDP-Ras
| | This is extremely slow (1e-4), but it is significant as so little GAP actually gets complexed with it that the total GTP turnover rises only by 2-3 X (see Gibbs et al, JBC 265(33) 20437-20422) and Eccleston et al JBC 268(36) 27012-27019 kf = 1e-4 | 51 | diff | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Shared_Object_ Ajay_Bhalla_ 2007_ReacDiff Pathway No. : 677 | 0.101 (s^-1) | 0.001 (s^-1) | Keq = 0.0099(uM) | 9.804sec | Substrate GDP-Ras
Product GDP-Ras
| 52 | Ras-intrinsic-GT Pase | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 831 | 0.0001 (s^-1) | 0 (s^-1) | - | - | Substrate GTP-Ras
Product GDP-Ras
| | This is extremely slow (1e-4), but it is significant as so little GAP actually gets complexed with it that the total GTP turnover rises only by 2-3 X (see Gibbs et al, JBC 265(33) 20437-20422) and Eccleston et al JBC 268(36) 27012-27019 kf = 1e-4 | 53 | diff | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Shared_Object_ Ajay_Bhalla_ 2007_ReacDiff Pathway No. : 677 | 0.101 (s^-1) | 0.001 (s^-1) | Keq = 0.0099(uM) | 9.804sec | Substrate GDP-Ras
Product GDP-Ras
| 54 | Ras-intrinsic-GT Pase | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 837 | 0.0001 (s^-1) | 0 (s^-1) | - | - | Substrate GTP-Ras
Product GDP-Ras
| | This is extremely slow (1e-4), but it is significant as so little GAP actually gets complexed with it that the total GTP turnover rises only by 2-3 X (see Gibbs et al, JBC 265(33) 20437-20422) and Eccleston et al JBC 268(36) 27012-27019 kf = 1e-4 | 55 | diff | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Shared_Object_ Ajay_Bhalla_ 2007_ReacDiff Pathway No. : 677 | 0.101 (s^-1) | 0.001 (s^-1) | Keq = 0.0099(uM) | 9.804sec | Substrate GDP-Ras
Product GDP-Ras
| 56 | Ras-intrinsic-GT Pase | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 843 | 0.0001 (s^-1) | 0 (s^-1) | - | - | Substrate GTP-Ras
Product GDP-Ras
| | This is extremely slow (1e-4), but it is significant as so little GAP actually gets complexed with it that the total GTP turnover rises only by 2-3 X (see Gibbs et al, JBC 265(33) 20437-20422) and Eccleston et al JBC 268(36) 27012-27019 kf = 1e-4 | 57 | diff | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Shared_Object_ Ajay_Bhalla_ 2007_ReacDiff Pathway No. : 677 | 0.101 (s^-1) | 0.001 (s^-1) | Keq = 0.0099(uM) | 9.804sec | Substrate GDP-Ras
Product GDP-Ras
| 58 | Ras-intrinsic-GT Pase | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 849 | 0.0001 (s^-1) | 0 (s^-1) | - | - | Substrate GTP-Ras
Product GDP-Ras
| | This is extremely slow (1e-4), but it is significant as so little GAP actually gets complexed with it that the total GTP turnover rises only by 2-3 X (see Gibbs et al, JBC 265(33) 20437-20422) and Eccleston et al JBC 268(36) 27012-27019 kf = 1e-4 | 59 | diff | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Shared_Object_ Ajay_Bhalla_ 2007_ReacDiff Pathway No. : 677 | 0.101 (s^-1) | 0.001 (s^-1) | Keq = 0.0099(uM) | 9.804sec | Substrate GDP-Ras
Product GDP-Ras
| 60 | Ras-intrinsic-GT Pase | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 855 | 0.0001 (s^-1) | 0 (s^-1) | - | - | Substrate GTP-Ras
Product GDP-Ras
| | This is extremely slow (1e-4), but it is significant as so little GAP actually gets complexed with it that the total GTP turnover rises only by 2-3 X (see Gibbs et al, JBC 265(33) 20437-20422) and Eccleston et al JBC 268(36) 27012-27019 kf = 1e-4 | 61 | diff | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Shared_Object_ Ajay_Bhalla_ 2007_ReacDiff Pathway No. : 677 | 0.101 (s^-1) | 0.001 (s^-1) | Keq = 0.0099(uM) | 9.804sec | Substrate GDP-Ras
Product GDP-Ras
| 62 | Ras-intrinsic-GT Pase | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 861 | 0.0001 (s^-1) | 0 (s^-1) | - | - | Substrate GTP-Ras
Product GDP-Ras
| | This is extremely slow (1e-4), but it is significant as so little GAP actually gets complexed with it that the total GTP turnover rises only by 2-3 X (see Gibbs et al, JBC 265(33) 20437-20422) and Eccleston et al JBC 268(36) 27012-27019 kf = 1e-4 | 63 | diff | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Shared_Object_ Ajay_Bhalla_ 2007_ReacDiff Pathway No. : 677 | 0.101 (s^-1) | 0.001 (s^-1) | Keq = 0.0099(uM) | 9.804sec | Substrate GDP-Ras
Product GDP-Ras
| 64 | Ras-intrinsic-GT Pase | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 867 | 0.0001 (s^-1) | 0 (s^-1) | - | - | Substrate GTP-Ras
Product GDP-Ras
| | This is extremely slow (1e-4), but it is significant as so little GAP actually gets complexed with it that the total GTP turnover rises only by 2-3 X (see Gibbs et al, JBC 265(33) 20437-20422) and Eccleston et al JBC 268(36) 27012-27019 kf = 1e-4 | 65 | diff | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Shared_Object_ Ajay_Bhalla_ 2007_ReacDiff Pathway No. : 677 | 0.101 (s^-1) | 0.001 (s^-1) | Keq = 0.0099(uM) | 9.804sec | Substrate GDP-Ras
Product GDP-Ras
| 66 | Ras-intrinsic-GT Pase | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 873 | 0.0001 (s^-1) | 0 (s^-1) | - | - | Substrate GTP-Ras
Product GDP-Ras
| | This is extremely slow (1e-4), but it is significant as so little GAP actually gets complexed with it that the total GTP turnover rises only by 2-3 X (see Gibbs et al, JBC 265(33) 20437-20422) and Eccleston et al JBC 268(36) 27012-27019 kf = 1e-4 | 67 | diff | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Shared_Object_ Ajay_Bhalla_ 2007_ReacDiff Pathway No. : 677 | 0.101 (s^-1) | 0.001 (s^-1) | Keq = 0.0099(uM) | 9.804sec | Substrate GDP-Ras
Product GDP-Ras
| 68 | Ras-intrinsic-GT Pase | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 879 | 0.0001 (s^-1) | 0 (s^-1) | - | - | Substrate GTP-Ras
Product GDP-Ras
| | This is extremely slow (1e-4), but it is significant as so little GAP actually gets complexed with it that the total GTP turnover rises only by 2-3 X (see Gibbs et al, JBC 265(33) 20437-20422) and Eccleston et al JBC 268(36) 27012-27019 kf = 1e-4 | 69 | diff | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Shared_Object_ Ajay_Bhalla_ 2007_ReacDiff Pathway No. : 677 | 0.101 (s^-1) | 0.001 (s^-1) | Keq = 0.0099(uM) | 9.804sec | Substrate GDP-Ras
Product GDP-Ras
| 70 | Ras-intrinsic-GT Pase | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 885 | 0.0001 (s^-1) | 0 (s^-1) | - | - | Substrate GTP-Ras
Product GDP-Ras
| | This is extremely slow (1e-4), but it is significant as so little GAP actually gets complexed with it that the total GTP turnover rises only by 2-3 X (see Gibbs et al, JBC 265(33) 20437-20422) and Eccleston et al JBC 268(36) 27012-27019 kf = 1e-4 | 71 | diff | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Shared_Object_ Ajay_Bhalla_ 2007_ReacDiff Pathway No. : 677 | 0.101 (s^-1) | 0.001 (s^-1) | Keq = 0.0099(uM) | 9.804sec | Substrate GDP-Ras
Product GDP-Ras
| 72 | Ras-intrinsic-GT Pase | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 891 | 0.0001 (s^-1) | 0 (s^-1) | - | - | Substrate GTP-Ras
Product GDP-Ras
| | This is extremely slow (1e-4), but it is significant as so little GAP actually gets complexed with it that the total GTP turnover rises only by 2-3 X (see Gibbs et al, JBC 265(33) 20437-20422) and Eccleston et al JBC 268(36) 27012-27019 kf = 1e-4 | 73 | diff | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Shared_Object_ Ajay_Bhalla_ 2007_ReacDiff Pathway No. : 677 | 0.101 (s^-1) | 0.001 (s^-1) | Keq = 0.0099(uM) | 9.804sec | Substrate GDP-Ras
Product GDP-Ras
| 74 | Ras-intrinsic-GT Pase | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 897 | 0.0001 (s^-1) | 0 (s^-1) | - | - | Substrate GTP-Ras
Product GDP-Ras
| | This is extremely slow (1e-4), but it is significant as so little GAP actually gets complexed with it that the total GTP turnover rises only by 2-3 X (see Gibbs et al, JBC 265(33) 20437-20422) and Eccleston et al JBC 268(36) 27012-27019 kf = 1e-4 | 75 | diff | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Shared_Object_ Ajay_Bhalla_ 2007_ReacDiff Pathway No. : 677 | 0.101 (s^-1) | 0.001 (s^-1) | Keq = 0.0099(uM) | 9.804sec | Substrate GDP-Ras
Product GDP-Ras
| 76 | Ras-intrinsic-GT Pase | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 903 | 0.0001 (s^-1) | 0 (s^-1) | - | - | Substrate GTP-Ras
Product GDP-Ras
| | This is extremely slow (1e-4), but it is significant as so little GAP actually gets complexed with it that the total GTP turnover rises only by 2-3 X (see Gibbs et al, JBC 265(33) 20437-20422) and Eccleston et al JBC 268(36) 27012-27019 kf = 1e-4 | 77 | diff | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Shared_Object_ Ajay_Bhalla_ 2007_ReacDiff Pathway No. : 677 | 0.101 (s^-1) | 0.001 (s^-1) | Keq = 0.0099(uM) | 9.804sec | Substrate GDP-Ras
Product GDP-Ras
| 78 | Ras-intrinsic-GT Pase | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 909 | 0.0001 (s^-1) | 0 (s^-1) | - | - | Substrate GTP-Ras
Product GDP-Ras
| | This is extremely slow (1e-4), but it is significant as so little GAP actually gets complexed with it that the total GTP turnover rises only by 2-3 X (see Gibbs et al, JBC 265(33) 20437-20422) and Eccleston et al JBC 268(36) 27012-27019 kf = 1e-4 | 79 | Ras-intrinsic-GT Pase | Ajay_Bhalla_ 2007_ReacDiff2 Accession No. : 83 | Ras Pathway No. : 915 | 0.0001 (s^-1) | 0 (s^-1) | - | - | Substrate GTP-Ras
Product GDP-Ras
| | This is extremely slow (1e-4), but it is significant as so little GAP actually gets complexed with it that the total GTP turnover rises only by 2-3 X (see Gibbs et al, JBC 265(33) 20437-20422) and Eccleston et al JBC 268(36) 27012-27019 kf = 1e-4 |
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