| Name | Accession Name | Pathway Name | Kf | Kb | Kd | tau | Reagents |
1 | Complexing | Chemotaxis Accession No. : 57 | Chemotaxis Pathway No. : 228 | 0.1 (uM^-1 s^-1) | 1 (s^-1) | Kd(bf) = 10.0003(uM) | - | Substrate CheW Tar
Product TW
|
| Tar and CheW complex formation Kf = 1 * 10e5 /sec/M = 0.1 /sec/uM Kb = 1 /sec Bray et al 1993, Mol.Biol.Cell 4: 469-482 Table 3 pp.476 Reaction Scheme 3 |
2 | Complexing[1] | Chemotaxis Accession No. : 57 | Chemotaxis Pathway No. : 228 | 0.1 (uM^-1 s^-1) | 1 (s^-1) | Kd(bf) = 10.0003(uM) | - | Substrate CheW Tn
Product TnW
|
| Complex formation of Ni bound Tar and CheW Kf = 1 * 10e5 /sec/M = 0.1 /sec/uM Kb = 1 /sec Bray et al 1993, Mol.Biol.Cell 4: 469-482; Table 3 pp.476 Reaction Scheme 3 Footnote states that ligands do not have any effect on the formation of the Tar-Chew-CheA complex so same rates are used for Aspartate or Ni associated Tar complexes. |
3 | Complexing[2] | Chemotaxis Accession No. : 57 | Chemotaxis Pathway No. : 228 | 0.1 (uM^-1 s^-1) | 1 (s^-1) | Kd(bf) = 10.0003(uM) | - | Substrate CheW TA
Product TaW
|
| Complex formation of aspartate bound Tar and CheW Kf = 1 * 10e+05 /sec/M = 0.1 /sec/uM Kb = 1 /sec Bray et al 1993, Mol.Biol.Cell 4: 469-482; Table 3 pp.476 Reaction Scheme 3 Footnote states that ligands do not have any effect on the formation of complexes so same rates are used for Aspartate or Ni associated Tar complexes. |
4 | Complexing[7] | Chemotaxis Accession No. : 57 | Chemotaxis Pathway No. : 228 | 4 (uM^-1 s^-1) | 10 (s^-1) | Kd(bf) = 2.5(uM) | - | Substrate CheW TA
Product TWA
|
| TA and CheW complex formation Kf = 4*10e+05 /sec/M = 0.4 /sec/uM Kb = 1 /sec Table 3 pp.476 Reaction Scheme 7 Bray et al 1993, Mol.Biol.Cell 4: 469-482 Rates used here are 10 times that stated, to allow for faster time courses seen during the drop of bias on removal of stimulus. |
5 | Complexing[8] | Chemotaxis Accession No. : 57 | Chemotaxis Pathway No. : 228 | 4 (uM^-1 s^-1) | 10 (s^-1) | Kd(bf) = 2.5(uM) | - | Substrate CheW TnA
Product TnWA
|
| TnA and CheW complex formation Kf = 4*10e+05 /sec/M = 0.4 /sec/uM Kb = 1 /sec Bray et al 1993, Mol.Biol.Cell 4: 469-482 Table 3 pp.476 Reaction Scheme 7 Rates used here are 10 times that stated, to allow for faster time courses seen during the drop of bias on removal of stimulus. Footnote states that ligands do not have any effect on the formation of Tar-CheW-CheA complex so same rates are used for Aspartate or Ni associated Tar complexes. |
6 | Complexing[9] | Chemotaxis Accession No. : 57 | Chemotaxis Pathway No. : 228 | 4 (uM^-1 s^-1) | 10 (s^-1) | Kd(bf) = 2.5(uM) | - | Substrate CheW TaA
Product TaWA
|
| TaA and CheW complex formation Kf = 4*10e+05 /sec/M = 0.4 /sec/uM Kb = 1 /sec Bray et al 1993, Mol.Biol.Cell 4: 469-482 Table 3 pp.476 Reaction Scheme 7 Rates used here are 10 time that stated, to allow for faster time courses seen during the drop of bias on removal of stimulus. Footnote states that ligands do not have any effect on the formation of the Tar-CheW-CheA complex so same rates are used for Aspartate or Ni associated Tar complexes |
7 | Complexing[10] | Chemotaxis Accession No. : 57 | Chemotaxis Pathway No. : 228 | 0.05 (uM^-1 s^-1) | 1 (s^-1) | Kd(bf) = 19.9999(uM) | - | Substrate CheA CheW
Product WA
|
| CheA and CheW complex formation Kf = 5*10e+04 /sec/M = 0.05 /sec/uM As per Reaction 4 in 1REACT.BCT provided by Matthew Levin Kf = 0.01 /sec/uM Kb = 1 /sec Bray et al 1993, Mol.Biol.Cell 4: 469-482 Table 3 pp.476 Reaction Scheme 5 |