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Molecule Parameter List for PKC-DAG-AA* | 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 | mkp1_feedback_ effects | 4 | Network | Shared_Object_mkp1_feedback_effects, Sos, PKC, MAPK, PLA2, Ras, PDGFR | This is a network involving the MAPK-PKC feedback loop with input from the PDGFR in the synapse. The distinctive feature of this model is that it includes MKP-1 induction by MAPK, and the consequent inhibitory regulation of MAPK and the feedback loop. Lots of interesting dynamics arise from this. This link provides supplementary material for the paper Bhalla US et al. Science (2002) 297(5583):1018-23. In the form of several example simulations and demos for the figures in the paper. |
PKC-DAG-AA* acting as a Molecule in mkp1_feedback_effects Network
Name | Accession Name | Pathway Name | Initial Conc. (uM) | Volume (fL) | Buffered | PKC-DAG-AA* | mkp1_feedback_ effects Accession No. : 4 | PKC Pathway No. : 34 | 0 | 1000 | No | Membrane translocated form of PKC-DAG-AA complex. |
PKC-DAG-AA* acting as a Summed Molecule in mkp1_feedback_effects Network
Accession Name | Pathway Name | Target | Input | mkp1_feedback_ effects Accession No. : 4 | Shared_Object_ mkp1_feedback_ effects Pathway No. : 32 | PKC-active | PKC-DAG-AA* PKC-Ca-memb* PKC-Ca-AA* PKC-DAG-memb* PKC-basal* PKC-AA*
| This is the total active PKC. It is the sum of the respective activities of PKC-basal* PKC-Ca-memb* PKC-DAG-memb* PKC-Ca-AA* PKC-DAG-AA* PKC-AA* I treat PKC here in a two-state manner: Either it is in an active state (any one of the above list) or it is inactive. No matter what combination of stimuli activate the PKC, I treat it as having the same activity. The scaling comes in through the relative amounts of PKC which bind to the respecive stimuli. The justification for this is the mode of action of PKC, which like most Ser/Thr kinases has a kinase domain normally bound to and blocked by a regulatory domain. I assume that all the activators simply free up the kinase domain. A more general model would incorporate a different enzyme activity for each combination of activating inputs, as well as for each substrate. The current model seems to be a decent and much simpler approximation for the available data. One caveat of this way of representing PKC is that the summation procedure assumes that PKC does not saturate with its substrates. If this assumption fails, then the contributing PKC complexes would experience changes in availability which would affect their balance. Given the relatively low percentage of PKC usually activated, and its high throughput as an enzyme, this is a safe assumption under physiological conditions. |
PKC-DAG-AA* acting as a Product in a reaction in mkp1_feedback_effects 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 | PKC-act-by-DAG-A A | mkp1_feedback_ effects Accession No. : 4 | PKC Pathway No. : 34 | 2 (s^-1) | 0.2 (s^-1) | Keq = 0.1(uM) | 0.455sec | Substrate PKC-DAG-AA
Product PKC-DAG-AA*
| Membrane translocation step for PKC-DAG-AA complex. Rates from matching concentration-effect data in our two main references: Schaechter and Benowitz 1993 J Neurosci 13(10):4361 and Shinomura et al 1988 PNAS 88: 5149-5153 |
| Database compilation and code copyright (C) 2022, Upinder S. Bhalla and NCBS/TIFR This Copyright is applied to ensure that the contents of this database remain freely available. Please see FAQ for details. |
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