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Molecule Parameter List for Ca

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

Ca participated as	Molecule	Sum total of	Enzyme	Substrate of an enzyme	Product of an enzyme	Substrate in Reaction	Product in Reaction
No. of occurrences	25	0	0	0	0	149	49

Accession and Pathway Details

Accession Name	Accession No.	Accession Type	Pathway Link
Ajay_bhalla_ 2007_ReacDiff1_ 1e-12	81	Network	Shared_Object_Ajay_bhalla_2007_ReacDiff1_1e-12, PKC, MAPK, Ras, CaM, PKM, chain, kinetics, PKC, MAPK, Ras, CaM, PKM, kinetics[1], PKC, MAPK, Ras, CaM, PKM, kinetics[2], PKC, MAPK, Ras, CaM, PKM, kinetics[3], PKC, MAPK, MAPK, Ras, CaM, PKM, kinetics[4], PKC, MAPK, Ras, CaM, PKM, kinetics[5], PKC, MAPK, Ras, kinetics[6], CaM, PKM, PKC, MAPK, Ras, CaM, PKM, kinetics[7], PKC, Ras, CaM, PKM, kinetics[8], PKC, MAPK, Ras, CaM, PKM, kinetics[9], PKC, MAPK, Ras, CaM, PKM, kinetics[10], PKC, MAPK, Ras, CaM, PKM, kinetics[11], PKC, MAPK, Ras, CaM, PKM, kinetics[12], PKC, MAPK, Ras, CaM, PKM, kinetics[13], PKC, MAPK, Ras, CaM, PKM, kinetics[14], PKC, MAPK, Ras, CaM, PKM, kinetics[15], PKC, MAPK, Ras, CaM, PKM, kinetics[16], PKC, MAPK, Ras, CaM, PKM, kinetics[17], PKC, MAPK, Ras, CaM, PKM, kinetics[18], PKC, MAPK, Ras, CaM, PKM, kinetics[19], PKC, MAPK, Ras, CaM, PKM, kinetics[20], PKC, MAPK, Ras, CaM, PKM, kinetics[21], PKC, MAPK, Ras, CaM, PKM, kinetics[22], PKC, MAPK, Ras, CaM, PKM, kinetics[23], PKC, MAPK, Ras, CaM, PKM
This is a 25-compartment reaction-diffusion version of the Ajay_Bhalla_2007_PKM model. The original single-compartment model is repeated 25 times. In addition, a subset (27 out of 42) molecules can diffuse between compartments. Diffusion is implemented as a reaction between corresponding molecules in neighboring compartments. For D = 1e-12 m^2/sec (i.e., 1 micron^2/sec ) the kf and kb of this reaction for these 10 micron compartments are both 0.01/sec. For D = 1e-13 m^2/sec (i.e., 0.1 micron^2/sec ) the kf and kb are 0.001/sec. The stimulus file pkm_mapk22_diff_1e-12_Fig4A which was used for the model to replicate Figure 4A from the paper. This stimulus file pkm_mapk22_diff_1e-12_Fig4G which was used for the model to replicate Figure 4G from the paper

Ca acting as a Molecule in Ajay_bhalla_2007_ReacDiff1_1e-12 Network

Name	Accession Name	Pathway Name	Initial Conc. (uM)	Volume (fL)	Buffered
Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.08	1.5	No
Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics Pathway No. : 382	0.08	1.5	No
Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[1] Pathway No. : 388	0.08	1.5	No
Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[2] Pathway No. : 394	0.08	1.5	No
Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[3] Pathway No. : 400	0.08	1.5	No
Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[4] Pathway No. : 407	0.08	1.5	No
Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[5] Pathway No. : 413	0.08	1.5	No
Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[6] Pathway No. : 417	0.08	1.5	No
Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[7] Pathway No. : 425	0.08	1.5	No
Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[8] Pathway No. : 430	0.08	1.5	No
Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[9] Pathway No. : 436	0.08	1.5	No
Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[10] Pathway No. : 442	0.08	1.5	No
Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[11] Pathway No. : 448	0.08	1.5	No
Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[12] Pathway No. : 454	0.08	1.5	No
Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[13] Pathway No. : 460	0.08	1.5	No
Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[14] Pathway No. : 466	0.08	1.5	No
Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[15] Pathway No. : 472	0.08	1.5	No
Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[16] Pathway No. : 478	0.08	1.5	No
Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[17] Pathway No. : 484	0.08	1.5	No
Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[18] Pathway No. : 490	0.08	1.5	No
Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[19] Pathway No. : 496	0.08	1.5	No
Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[20] Pathway No. : 502	0.08	1.5	No
Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[21] Pathway No. : 508	0.08	1.5	No
Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[22] Pathway No. : 514	0.08	1.5	No
Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[23] Pathway No. : 520	0.08	1.5	No

Ca acting as a Substrate in a reaction in Ajay_bhalla_2007_ReacDiff1_1e-12 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	PKC-act-by-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	PKC Pathway No. : 376	0.6 (uM^-1 s^-1)	0.5 (s^-1)	Kd(bf) = 0.8333(uM)	-	Substrate Ca PKC-cytosolic Product PKC-Ca
	Need est of rate of assoc of Ca and PKC. Assume it is fast The original parameter-searched kf of 439.4 has been scaled by 1/6e8 to account for change of units to n. Kf now 8.16e-7, kb=.6085 Raised kf to 1e-6 to match Ca curve, kb to .5
2	CaM-Ca3-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 379	0.465 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 21.5051(uM)	-	Substrate Ca CaM-Ca3 Product CaM-Ca4
	Use K3 = 21.5 uM here from Stemmer and Klee table 3. kb/kf =21.5 6e5 so kf = 7.75e-7, kb = 10*
3	CaM-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 379	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM Product CaM-Ca
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
4	CaM-Ca2-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 379	3.6 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 2.7778(uM)	-	Substrate Ca CaM-Ca2 Product CaM-Ca3
	K3 = 21.5, K4 = 2.8. Assuming that the K4 step happens first, we get kb/kf = 2.8 uM = 1.68e6 so kf =6e-6 assuming kb = 10
5	CaM-Ca-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 379	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM-Ca Product CaM-Ca2
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
6	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
7	PKC-act-by-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	PKC Pathway No. : 383	0.6 (uM^-1 s^-1)	0.5 (s^-1)	Kd(bf) = 0.8333(uM)	-	Substrate Ca PKC-cytosolic Product PKC-Ca
	Need est of rate of assoc of Ca and PKC. Assume it is fast The original parameter-searched kf of 439.4 has been scaled by 1/6e8 to account for change of units to n. Kf now 8.16e-7, kb=.6085 Raised kf to 1e-6 to match Ca curve, kb to .5
8	CaM-Ca3-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 386	0.465 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 21.5051(uM)	-	Substrate Ca CaM-Ca3 Product CaM-Ca4
	Use K3 = 21.5 uM here from Stemmer and Klee table 3. kb/kf =21.5 6e5 so kf = 7.75e-7, kb = 10*
9	CaM-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 386	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM Product CaM-Ca
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
10	CaM-Ca2-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 386	3.6 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 2.7778(uM)	-	Substrate Ca CaM-Ca2 Product CaM-Ca3
	K3 = 21.5, K4 = 2.8. Assuming that the K4 step happens first, we get kb/kf = 2.8 uM = 1.68e6 so kf =6e-6 assuming kb = 10
11	CaM-Ca-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 386	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM-Ca Product CaM-Ca2
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
12	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
13	PKC-act-by-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	PKC Pathway No. : 401	0.6 (uM^-1 s^-1)	0.5 (s^-1)	Kd(bf) = 0.8333(uM)	-	Substrate Ca PKC-cytosolic Product PKC-Ca
	Need est of rate of assoc of Ca and PKC. Assume it is fast The original parameter-searched kf of 439.4 has been scaled by 1/6e8 to account for change of units to n. Kf now 8.16e-7, kb=.6085 Raised kf to 1e-6 to match Ca curve, kb to .5
14	PKC-act-by-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	PKC Pathway No. : 389	0.6 (uM^-1 s^-1)	0.5 (s^-1)	Kd(bf) = 0.8333(uM)	-	Substrate Ca PKC-cytosolic Product PKC-Ca
	Need est of rate of assoc of Ca and PKC. Assume it is fast The original parameter-searched kf of 439.4 has been scaled by 1/6e8 to account for change of units to n. Kf now 8.16e-7, kb=.6085 Raised kf to 1e-6 to match Ca curve, kb to .5
15	CaM-Ca3-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 392	0.465 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 21.5051(uM)	-	Substrate Ca CaM-Ca3 Product CaM-Ca4
	Use K3 = 21.5 uM here from Stemmer and Klee table 3. kb/kf =21.5 6e5 so kf = 7.75e-7, kb = 10*
16	CaM-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 392	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM Product CaM-Ca
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
17	CaM-Ca2-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 392	3.6 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 2.7778(uM)	-	Substrate Ca CaM-Ca2 Product CaM-Ca3
	K3 = 21.5, K4 = 2.8. Assuming that the K4 step happens first, we get kb/kf = 2.8 uM = 1.68e6 so kf =6e-6 assuming kb = 10
18	CaM-Ca-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 392	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM-Ca Product CaM-Ca2
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
19	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
20	PKC-act-by-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	PKC Pathway No. : 395	0.6 (uM^-1 s^-1)	0.5 (s^-1)	Kd(bf) = 0.8333(uM)	-	Substrate Ca PKC-cytosolic Product PKC-Ca
	Need est of rate of assoc of Ca and PKC. Assume it is fast The original parameter-searched kf of 439.4 has been scaled by 1/6e8 to account for change of units to n. Kf now 8.16e-7, kb=.6085 Raised kf to 1e-6 to match Ca curve, kb to .5
21	CaM-Ca3-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 398	0.465 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 21.5051(uM)	-	Substrate Ca CaM-Ca3 Product CaM-Ca4
	Use K3 = 21.5 uM here from Stemmer and Klee table 3. kb/kf =21.5 6e5 so kf = 7.75e-7, kb = 10*
22	CaM-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 398	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM Product CaM-Ca
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
23	CaM-Ca2-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 398	3.6 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 2.7778(uM)	-	Substrate Ca CaM-Ca2 Product CaM-Ca3
	K3 = 21.5, K4 = 2.8. Assuming that the K4 step happens first, we get kb/kf = 2.8 uM = 1.68e6 so kf =6e-6 assuming kb = 10
24	CaM-Ca-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 398	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM-Ca Product CaM-Ca2
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
25	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
26	PKC-act-by-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	PKC Pathway No. : 426	0.6 (uM^-1 s^-1)	0.5 (s^-1)	Kd(bf) = 0.8333(uM)	-	Substrate Ca PKC-cytosolic Product PKC-Ca
	Need est of rate of assoc of Ca and PKC. Assume it is fast The original parameter-searched kf of 439.4 has been scaled by 1/6e8 to account for change of units to n. Kf now 8.16e-7, kb=.6085 Raised kf to 1e-6 to match Ca curve, kb to .5
27	CaM-Ca3-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 405	0.465 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 21.5051(uM)	-	Substrate Ca CaM-Ca3 Product CaM-Ca4
	Use K3 = 21.5 uM here from Stemmer and Klee table 3. kb/kf =21.5 6e5 so kf = 7.75e-7, kb = 10*
28	CaM-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 405	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM Product CaM-Ca
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
29	CaM-Ca2-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 405	3.6 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 2.7778(uM)	-	Substrate Ca CaM-Ca2 Product CaM-Ca3
	K3 = 21.5, K4 = 2.8. Assuming that the K4 step happens first, we get kb/kf = 2.8 uM = 1.68e6 so kf =6e-6 assuming kb = 10
30	CaM-Ca-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 405	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM-Ca Product CaM-Ca2
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
31	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
32	PKC-act-by-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	PKC Pathway No. : 408	0.6 (uM^-1 s^-1)	0.5 (s^-1)	Kd(bf) = 0.8333(uM)	-	Substrate Ca PKC-cytosolic Product PKC-Ca
	Need est of rate of assoc of Ca and PKC. Assume it is fast The original parameter-searched kf of 439.4 has been scaled by 1/6e8 to account for change of units to n. Kf now 8.16e-7, kb=.6085 Raised kf to 1e-6 to match Ca curve, kb to .5
33	CaM-Ca3-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 411	0.465 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 21.5051(uM)	-	Substrate Ca CaM-Ca3 Product CaM-Ca4
	Use K3 = 21.5 uM here from Stemmer and Klee table 3. kb/kf =21.5 6e5 so kf = 7.75e-7, kb = 10*
34	CaM-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 411	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM Product CaM-Ca
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
35	CaM-Ca2-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 411	3.6 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 2.7778(uM)	-	Substrate Ca CaM-Ca2 Product CaM-Ca3
	K3 = 21.5, K4 = 2.8. Assuming that the K4 step happens first, we get kb/kf = 2.8 uM = 1.68e6 so kf =6e-6 assuming kb = 10
36	CaM-Ca-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 411	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM-Ca Product CaM-Ca2
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
37	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
38	PKC-act-by-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	PKC Pathway No. : 414	0.6 (uM^-1 s^-1)	0.5 (s^-1)	Kd(bf) = 0.8333(uM)	-	Substrate Ca PKC-cytosolic Product PKC-Ca
	Need est of rate of assoc of Ca and PKC. Assume it is fast The original parameter-searched kf of 439.4 has been scaled by 1/6e8 to account for change of units to n. Kf now 8.16e-7, kb=.6085 Raised kf to 1e-6 to match Ca curve, kb to .5
39	CaM-Ca3-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 418	0.465 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 21.5051(uM)	-	Substrate Ca CaM-Ca3 Product CaM-Ca4
	Use K3 = 21.5 uM here from Stemmer and Klee table 3. kb/kf =21.5 6e5 so kf = 7.75e-7, kb = 10*
40	CaM-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 418	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM Product CaM-Ca
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
41	CaM-Ca2-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 418	3.6 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 2.7778(uM)	-	Substrate Ca CaM-Ca2 Product CaM-Ca3
	K3 = 21.5, K4 = 2.8. Assuming that the K4 step happens first, we get kb/kf = 2.8 uM = 1.68e6 so kf =6e-6 assuming kb = 10
42	CaM-Ca-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 418	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM-Ca Product CaM-Ca2
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
43	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
44	PKC-act-by-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	PKC Pathway No. : 420	0.6 (uM^-1 s^-1)	0.5 (s^-1)	Kd(bf) = 0.8333(uM)	-	Substrate Ca PKC-cytosolic Product PKC-Ca
	Need est of rate of assoc of Ca and PKC. Assume it is fast The original parameter-searched kf of 439.4 has been scaled by 1/6e8 to account for change of units to n. Kf now 8.16e-7, kb=.6085 Raised kf to 1e-6 to match Ca curve, kb to .5
45	CaM-Ca3-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 423	0.465 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 21.5051(uM)	-	Substrate Ca CaM-Ca3 Product CaM-Ca4
	Use K3 = 21.5 uM here from Stemmer and Klee table 3. kb/kf =21.5 6e5 so kf = 7.75e-7, kb = 10*
46	CaM-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 423	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM Product CaM-Ca
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
47	CaM-Ca2-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 423	3.6 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 2.7778(uM)	-	Substrate Ca CaM-Ca2 Product CaM-Ca3
	K3 = 21.5, K4 = 2.8. Assuming that the K4 step happens first, we get kb/kf = 2.8 uM = 1.68e6 so kf =6e-6 assuming kb = 10
48	CaM-Ca-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 423	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM-Ca Product CaM-Ca2
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
49	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
50	PKC-act-by-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	PKC Pathway No. : 473	0.6 (uM^-1 s^-1)	0.5 (s^-1)	Kd(bf) = 0.8333(uM)	-	Substrate Ca PKC-cytosolic Product PKC-Ca
	Need est of rate of assoc of Ca and PKC. Assume it is fast The original parameter-searched kf of 439.4 has been scaled by 1/6e8 to account for change of units to n. Kf now 8.16e-7, kb=.6085 Raised kf to 1e-6 to match Ca curve, kb to .5
51	CaM-Ca3-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 428	0.465 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 21.5051(uM)	-	Substrate Ca CaM-Ca3 Product CaM-Ca4
	Use K3 = 21.5 uM here from Stemmer and Klee table 3. kb/kf =21.5 6e5 so kf = 7.75e-7, kb = 10*
52	CaM-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 428	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM Product CaM-Ca
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
53	CaM-Ca2-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 428	3.6 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 2.7778(uM)	-	Substrate Ca CaM-Ca2 Product CaM-Ca3
	K3 = 21.5, K4 = 2.8. Assuming that the K4 step happens first, we get kb/kf = 2.8 uM = 1.68e6 so kf =6e-6 assuming kb = 10
54	CaM-Ca-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 428	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM-Ca Product CaM-Ca2
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
55	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
56	PKC-act-by-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	PKC Pathway No. : 431	0.6 (uM^-1 s^-1)	0.5 (s^-1)	Kd(bf) = 0.8333(uM)	-	Substrate Ca PKC-cytosolic Product PKC-Ca
	Need est of rate of assoc of Ca and PKC. Assume it is fast The original parameter-searched kf of 439.4 has been scaled by 1/6e8 to account for change of units to n. Kf now 8.16e-7, kb=.6085 Raised kf to 1e-6 to match Ca curve, kb to .5
57	CaM-Ca3-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 434	0.465 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 21.5051(uM)	-	Substrate Ca CaM-Ca3 Product CaM-Ca4
	Use K3 = 21.5 uM here from Stemmer and Klee table 3. kb/kf =21.5 6e5 so kf = 7.75e-7, kb = 10*
58	CaM-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 434	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM Product CaM-Ca
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
59	CaM-Ca2-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 434	3.6 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 2.7778(uM)	-	Substrate Ca CaM-Ca2 Product CaM-Ca3
	K3 = 21.5, K4 = 2.8. Assuming that the K4 step happens first, we get kb/kf = 2.8 uM = 1.68e6 so kf =6e-6 assuming kb = 10
60	CaM-Ca-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 434	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM-Ca Product CaM-Ca2
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
61	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
62	PKC-act-by-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	PKC Pathway No. : 437	0.6 (uM^-1 s^-1)	0.5 (s^-1)	Kd(bf) = 0.8333(uM)	-	Substrate Ca PKC-cytosolic Product PKC-Ca
	Need est of rate of assoc of Ca and PKC. Assume it is fast The original parameter-searched kf of 439.4 has been scaled by 1/6e8 to account for change of units to n. Kf now 8.16e-7, kb=.6085 Raised kf to 1e-6 to match Ca curve, kb to .5
63	CaM-Ca3-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 440	0.465 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 21.5051(uM)	-	Substrate Ca CaM-Ca3 Product CaM-Ca4
	Use K3 = 21.5 uM here from Stemmer and Klee table 3. kb/kf =21.5 6e5 so kf = 7.75e-7, kb = 10*
64	CaM-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 440	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM Product CaM-Ca
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
65	CaM-Ca2-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 440	3.6 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 2.7778(uM)	-	Substrate Ca CaM-Ca2 Product CaM-Ca3
	K3 = 21.5, K4 = 2.8. Assuming that the K4 step happens first, we get kb/kf = 2.8 uM = 1.68e6 so kf =6e-6 assuming kb = 10
66	CaM-Ca-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 440	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM-Ca Product CaM-Ca2
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
67	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
68	PKC-act-by-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	PKC Pathway No. : 443	0.6 (uM^-1 s^-1)	0.5 (s^-1)	Kd(bf) = 0.8333(uM)	-	Substrate Ca PKC-cytosolic Product PKC-Ca
	Need est of rate of assoc of Ca and PKC. Assume it is fast The original parameter-searched kf of 439.4 has been scaled by 1/6e8 to account for change of units to n. Kf now 8.16e-7, kb=.6085 Raised kf to 1e-6 to match Ca curve, kb to .5
69	CaM-Ca3-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 446	0.465 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 21.5051(uM)	-	Substrate Ca CaM-Ca3 Product CaM-Ca4
	Use K3 = 21.5 uM here from Stemmer and Klee table 3. kb/kf =21.5 6e5 so kf = 7.75e-7, kb = 10*
70	CaM-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 446	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM Product CaM-Ca
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
71	CaM-Ca2-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 446	3.6 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 2.7778(uM)	-	Substrate Ca CaM-Ca2 Product CaM-Ca3
	K3 = 21.5, K4 = 2.8. Assuming that the K4 step happens first, we get kb/kf = 2.8 uM = 1.68e6 so kf =6e-6 assuming kb = 10
72	CaM-Ca-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 446	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM-Ca Product CaM-Ca2
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
73	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
74	PKC-act-by-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	PKC Pathway No. : 449	0.6 (uM^-1 s^-1)	0.5 (s^-1)	Kd(bf) = 0.8333(uM)	-	Substrate Ca PKC-cytosolic Product PKC-Ca
	Need est of rate of assoc of Ca and PKC. Assume it is fast The original parameter-searched kf of 439.4 has been scaled by 1/6e8 to account for change of units to n. Kf now 8.16e-7, kb=.6085 Raised kf to 1e-6 to match Ca curve, kb to .5
75	CaM-Ca3-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 452	0.465 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 21.5051(uM)	-	Substrate Ca CaM-Ca3 Product CaM-Ca4
	Use K3 = 21.5 uM here from Stemmer and Klee table 3. kb/kf =21.5 6e5 so kf = 7.75e-7, kb = 10*
76	CaM-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 452	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM Product CaM-Ca
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
77	CaM-Ca2-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 452	3.6 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 2.7778(uM)	-	Substrate Ca CaM-Ca2 Product CaM-Ca3
	K3 = 21.5, K4 = 2.8. Assuming that the K4 step happens first, we get kb/kf = 2.8 uM = 1.68e6 so kf =6e-6 assuming kb = 10
78	CaM-Ca-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 452	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM-Ca Product CaM-Ca2
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
79	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
80	PKC-act-by-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	PKC Pathway No. : 455	0.6 (uM^-1 s^-1)	0.5 (s^-1)	Kd(bf) = 0.8333(uM)	-	Substrate Ca PKC-cytosolic Product PKC-Ca
	Need est of rate of assoc of Ca and PKC. Assume it is fast The original parameter-searched kf of 439.4 has been scaled by 1/6e8 to account for change of units to n. Kf now 8.16e-7, kb=.6085 Raised kf to 1e-6 to match Ca curve, kb to .5
81	CaM-Ca3-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 458	0.465 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 21.5051(uM)	-	Substrate Ca CaM-Ca3 Product CaM-Ca4
	Use K3 = 21.5 uM here from Stemmer and Klee table 3. kb/kf =21.5 6e5 so kf = 7.75e-7, kb = 10*
82	CaM-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 458	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM Product CaM-Ca
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
83	CaM-Ca2-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 458	3.6 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 2.7778(uM)	-	Substrate Ca CaM-Ca2 Product CaM-Ca3
	K3 = 21.5, K4 = 2.8. Assuming that the K4 step happens first, we get kb/kf = 2.8 uM = 1.68e6 so kf =6e-6 assuming kb = 10
84	CaM-Ca-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 458	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM-Ca Product CaM-Ca2
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
85	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
86	PKC-act-by-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	PKC Pathway No. : 461	0.6 (uM^-1 s^-1)	0.5 (s^-1)	Kd(bf) = 0.8333(uM)	-	Substrate Ca PKC-cytosolic Product PKC-Ca
	Need est of rate of assoc of Ca and PKC. Assume it is fast The original parameter-searched kf of 439.4 has been scaled by 1/6e8 to account for change of units to n. Kf now 8.16e-7, kb=.6085 Raised kf to 1e-6 to match Ca curve, kb to .5
87	CaM-Ca3-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 464	0.465 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 21.5051(uM)	-	Substrate Ca CaM-Ca3 Product CaM-Ca4
	Use K3 = 21.5 uM here from Stemmer and Klee table 3. kb/kf =21.5 6e5 so kf = 7.75e-7, kb = 10*
88	CaM-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 464	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM Product CaM-Ca
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
89	CaM-Ca2-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 464	3.6 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 2.7778(uM)	-	Substrate Ca CaM-Ca2 Product CaM-Ca3
	K3 = 21.5, K4 = 2.8. Assuming that the K4 step happens first, we get kb/kf = 2.8 uM = 1.68e6 so kf =6e-6 assuming kb = 10
90	CaM-Ca-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 464	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM-Ca Product CaM-Ca2
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
91	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
92	PKC-act-by-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	PKC Pathway No. : 467	0.6 (uM^-1 s^-1)	0.5 (s^-1)	Kd(bf) = 0.8333(uM)	-	Substrate Ca PKC-cytosolic Product PKC-Ca
	Need est of rate of assoc of Ca and PKC. Assume it is fast The original parameter-searched kf of 439.4 has been scaled by 1/6e8 to account for change of units to n. Kf now 8.16e-7, kb=.6085 Raised kf to 1e-6 to match Ca curve, kb to .5
93	CaM-Ca3-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 470	0.465 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 21.5051(uM)	-	Substrate Ca CaM-Ca3 Product CaM-Ca4
	Use K3 = 21.5 uM here from Stemmer and Klee table 3. kb/kf =21.5 6e5 so kf = 7.75e-7, kb = 10*
94	CaM-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 470	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM Product CaM-Ca
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
95	CaM-Ca2-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 470	3.6 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 2.7778(uM)	-	Substrate Ca CaM-Ca2 Product CaM-Ca3
	K3 = 21.5, K4 = 2.8. Assuming that the K4 step happens first, we get kb/kf = 2.8 uM = 1.68e6 so kf =6e-6 assuming kb = 10
96	CaM-Ca-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 470	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM-Ca Product CaM-Ca2
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
97	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
98	CaM-Ca3-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 476	0.465 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 21.5051(uM)	-	Substrate Ca CaM-Ca3 Product CaM-Ca4
	Use K3 = 21.5 uM here from Stemmer and Klee table 3. kb/kf =21.5 6e5 so kf = 7.75e-7, kb = 10*
99	CaM-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 476	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM Product CaM-Ca
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
100	CaM-Ca2-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 476	3.6 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 2.7778(uM)	-	Substrate Ca CaM-Ca2 Product CaM-Ca3
	K3 = 21.5, K4 = 2.8. Assuming that the K4 step happens first, we get kb/kf = 2.8 uM = 1.68e6 so kf =6e-6 assuming kb = 10
101	CaM-Ca-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 476	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM-Ca Product CaM-Ca2
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
102	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
103	PKC-act-by-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	PKC Pathway No. : 479	0.6 (uM^-1 s^-1)	0.5 (s^-1)	Kd(bf) = 0.8333(uM)	-	Substrate Ca PKC-cytosolic Product PKC-Ca
	Need est of rate of assoc of Ca and PKC. Assume it is fast The original parameter-searched kf of 439.4 has been scaled by 1/6e8 to account for change of units to n. Kf now 8.16e-7, kb=.6085 Raised kf to 1e-6 to match Ca curve, kb to .5
104	CaM-Ca3-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 482	0.465 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 21.5051(uM)	-	Substrate Ca CaM-Ca3 Product CaM-Ca4
	Use K3 = 21.5 uM here from Stemmer and Klee table 3. kb/kf =21.5 6e5 so kf = 7.75e-7, kb = 10*
105	CaM-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 482	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM Product CaM-Ca
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
106	CaM-Ca2-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 482	3.6 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 2.7778(uM)	-	Substrate Ca CaM-Ca2 Product CaM-Ca3
	K3 = 21.5, K4 = 2.8. Assuming that the K4 step happens first, we get kb/kf = 2.8 uM = 1.68e6 so kf =6e-6 assuming kb = 10
107	CaM-Ca-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 482	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM-Ca Product CaM-Ca2
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
108	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
109	PKC-act-by-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	PKC Pathway No. : 485	0.6 (uM^-1 s^-1)	0.5 (s^-1)	Kd(bf) = 0.8333(uM)	-	Substrate Ca PKC-cytosolic Product PKC-Ca
	Need est of rate of assoc of Ca and PKC. Assume it is fast The original parameter-searched kf of 439.4 has been scaled by 1/6e8 to account for change of units to n. Kf now 8.16e-7, kb=.6085 Raised kf to 1e-6 to match Ca curve, kb to .5
110	CaM-Ca3-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 488	0.465 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 21.5051(uM)	-	Substrate Ca CaM-Ca3 Product CaM-Ca4
	Use K3 = 21.5 uM here from Stemmer and Klee table 3. kb/kf =21.5 6e5 so kf = 7.75e-7, kb = 10*
111	CaM-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 488	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM Product CaM-Ca
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
112	CaM-Ca2-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 488	3.6 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 2.7778(uM)	-	Substrate Ca CaM-Ca2 Product CaM-Ca3
	K3 = 21.5, K4 = 2.8. Assuming that the K4 step happens first, we get kb/kf = 2.8 uM = 1.68e6 so kf =6e-6 assuming kb = 10
113	CaM-Ca-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 488	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM-Ca Product CaM-Ca2
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
114	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
115	PKC-act-by-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	PKC Pathway No. : 491	0.6 (uM^-1 s^-1)	0.5 (s^-1)	Kd(bf) = 0.8333(uM)	-	Substrate Ca PKC-cytosolic Product PKC-Ca
	Need est of rate of assoc of Ca and PKC. Assume it is fast The original parameter-searched kf of 439.4 has been scaled by 1/6e8 to account for change of units to n. Kf now 8.16e-7, kb=.6085 Raised kf to 1e-6 to match Ca curve, kb to .5
116	CaM-Ca3-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 494	0.465 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 21.5051(uM)	-	Substrate Ca CaM-Ca3 Product CaM-Ca4
	Use K3 = 21.5 uM here from Stemmer and Klee table 3. kb/kf =21.5 6e5 so kf = 7.75e-7, kb = 10*
117	CaM-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 494	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM Product CaM-Ca
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
118	CaM-Ca2-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 494	3.6 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 2.7778(uM)	-	Substrate Ca CaM-Ca2 Product CaM-Ca3
	K3 = 21.5, K4 = 2.8. Assuming that the K4 step happens first, we get kb/kf = 2.8 uM = 1.68e6 so kf =6e-6 assuming kb = 10
119	CaM-Ca-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 494	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM-Ca Product CaM-Ca2
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
120	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
121	PKC-act-by-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	PKC Pathway No. : 497	0.6 (uM^-1 s^-1)	0.5 (s^-1)	Kd(bf) = 0.8333(uM)	-	Substrate Ca PKC-cytosolic Product PKC-Ca
	Need est of rate of assoc of Ca and PKC. Assume it is fast The original parameter-searched kf of 439.4 has been scaled by 1/6e8 to account for change of units to n. Kf now 8.16e-7, kb=.6085 Raised kf to 1e-6 to match Ca curve, kb to .5
122	CaM-Ca3-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 500	0.465 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 21.5051(uM)	-	Substrate Ca CaM-Ca3 Product CaM-Ca4
	Use K3 = 21.5 uM here from Stemmer and Klee table 3. kb/kf =21.5 6e5 so kf = 7.75e-7, kb = 10*
123	CaM-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 500	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM Product CaM-Ca
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
124	CaM-Ca2-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 500	3.6 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 2.7778(uM)	-	Substrate Ca CaM-Ca2 Product CaM-Ca3
	K3 = 21.5, K4 = 2.8. Assuming that the K4 step happens first, we get kb/kf = 2.8 uM = 1.68e6 so kf =6e-6 assuming kb = 10
125	CaM-Ca-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 500	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM-Ca Product CaM-Ca2
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
126	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
127	PKC-act-by-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	PKC Pathway No. : 503	0.6 (uM^-1 s^-1)	0.5 (s^-1)	Kd(bf) = 0.8333(uM)	-	Substrate Ca PKC-cytosolic Product PKC-Ca
	Need est of rate of assoc of Ca and PKC. Assume it is fast The original parameter-searched kf of 439.4 has been scaled by 1/6e8 to account for change of units to n. Kf now 8.16e-7, kb=.6085 Raised kf to 1e-6 to match Ca curve, kb to .5
128	CaM-Ca3-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 506	0.465 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 21.5051(uM)	-	Substrate Ca CaM-Ca3 Product CaM-Ca4
	Use K3 = 21.5 uM here from Stemmer and Klee table 3. kb/kf =21.5 6e5 so kf = 7.75e-7, kb = 10*
129	CaM-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 506	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM Product CaM-Ca
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
130	CaM-Ca2-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 506	3.6 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 2.7778(uM)	-	Substrate Ca CaM-Ca2 Product CaM-Ca3
	K3 = 21.5, K4 = 2.8. Assuming that the K4 step happens first, we get kb/kf = 2.8 uM = 1.68e6 so kf =6e-6 assuming kb = 10
131	CaM-Ca-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 506	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM-Ca Product CaM-Ca2
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
132	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
133	PKC-act-by-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	PKC Pathway No. : 509	0.6 (uM^-1 s^-1)	0.5 (s^-1)	Kd(bf) = 0.8333(uM)	-	Substrate Ca PKC-cytosolic Product PKC-Ca
	Need est of rate of assoc of Ca and PKC. Assume it is fast The original parameter-searched kf of 439.4 has been scaled by 1/6e8 to account for change of units to n. Kf now 8.16e-7, kb=.6085 Raised kf to 1e-6 to match Ca curve, kb to .5
134	CaM-Ca3-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 512	0.465 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 21.5051(uM)	-	Substrate Ca CaM-Ca3 Product CaM-Ca4
	Use K3 = 21.5 uM here from Stemmer and Klee table 3. kb/kf =21.5 6e5 so kf = 7.75e-7, kb = 10*
135	CaM-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 512	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM Product CaM-Ca
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
136	CaM-Ca2-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 512	3.6 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 2.7778(uM)	-	Substrate Ca CaM-Ca2 Product CaM-Ca3
	K3 = 21.5, K4 = 2.8. Assuming that the K4 step happens first, we get kb/kf = 2.8 uM = 1.68e6 so kf =6e-6 assuming kb = 10
137	CaM-Ca-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 512	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM-Ca Product CaM-Ca2
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
138	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
139	PKC-act-by-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	PKC Pathway No. : 515	0.6 (uM^-1 s^-1)	0.5 (s^-1)	Kd(bf) = 0.8333(uM)	-	Substrate Ca PKC-cytosolic Product PKC-Ca
	Need est of rate of assoc of Ca and PKC. Assume it is fast The original parameter-searched kf of 439.4 has been scaled by 1/6e8 to account for change of units to n. Kf now 8.16e-7, kb=.6085 Raised kf to 1e-6 to match Ca curve, kb to .5
140	CaM-Ca3-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 518	0.465 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 21.5051(uM)	-	Substrate Ca CaM-Ca3 Product CaM-Ca4
	Use K3 = 21.5 uM here from Stemmer and Klee table 3. kb/kf =21.5 6e5 so kf = 7.75e-7, kb = 10*
141	CaM-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 518	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM Product CaM-Ca
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
142	CaM-Ca2-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 518	3.6 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 2.7778(uM)	-	Substrate Ca CaM-Ca2 Product CaM-Ca3
	K3 = 21.5, K4 = 2.8. Assuming that the K4 step happens first, we get kb/kf = 2.8 uM = 1.68e6 so kf =6e-6 assuming kb = 10
143	CaM-Ca-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 518	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM-Ca Product CaM-Ca2
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
144	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
145	PKC-act-by-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	PKC Pathway No. : 521	0.6 (uM^-1 s^-1)	0.5 (s^-1)	Kd(bf) = 0.8333(uM)	-	Substrate Ca PKC-cytosolic Product PKC-Ca
	Need est of rate of assoc of Ca and PKC. Assume it is fast The original parameter-searched kf of 439.4 has been scaled by 1/6e8 to account for change of units to n. Kf now 8.16e-7, kb=.6085 Raised kf to 1e-6 to match Ca curve, kb to .5
146	CaM-Ca3-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 524	0.465 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 21.5051(uM)	-	Substrate Ca CaM-Ca3 Product CaM-Ca4
	Use K3 = 21.5 uM here from Stemmer and Klee table 3. kb/kf =21.5 6e5 so kf = 7.75e-7, kb = 10*
147	CaM-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 524	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM Product CaM-Ca
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853
148	CaM-Ca2-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 524	3.6 (uM^-1 s^-1)	10 (s^-1)	Kd(bf) = 2.7778(uM)	-	Substrate Ca CaM-Ca2 Product CaM-Ca3
	K3 = 21.5, K4 = 2.8. Assuming that the K4 step happens first, we get kb/kf = 2.8 uM = 1.68e6 so kf =6e-6 assuming kb = 10
149	CaM-Ca-bind-Ca	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	CaM Pathway No. : 524	8.4851 (uM^-1 s^-1)	8.4853 (s^-1)	Kd(bf) = 1(uM)	-	Substrate Ca CaM-Ca Product CaM-Ca2
	Lets use the fast rate consts here. Since the rates are so different, I am not sure whether the order is relevant. These correspond to the TR2C fragment. We use the Martin et al rates here, plus the Drabicowski binding consts. All are scaled by 3X to cell temp. kf = 2e-10 kb = 72 Stemmer & Klee: K1=.9, K2=1.1. Assume 1.0uM for both. kb/kf=3.6e11. If kb=72, kf = 2e-10 (Exactly the same !) 19 May 2006. Splitting the old CaM-TR2-bind-Ca reaction into two steps, each binding 1 Ca. This improves numerical stability and is conceptually better too. Overall rates are the same, so each kf and kb is the square root of the earlier ones. So kf = 1.125e-4, kb = 8.4853

Ca acting as a Product in a reaction in Ajay_bhalla_2007_ReacDiff1_1e-12 Network

	Name	Accession Name	Pathway Name	Kf	Kb	Kd	tau	Reagents
1	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
2	Ca_diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	5 (s^-1)	5 (s^-1)	Keq = 1(uM)	0.1sec	Substrate Ca_input Product Ca
3	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
4	Ca_diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics Pathway No. : 382	5 (s^-1)	5 (s^-1)	Keq = 1(uM)	0.1sec	Substrate Ca_input Product Ca
5	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
6	Ca_diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[1] Pathway No. : 388	5 (s^-1)	5 (s^-1)	Keq = 1(uM)	0.1sec	Substrate Ca_input Product Ca
7	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
8	Ca_diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[2] Pathway No. : 394	5 (s^-1)	5 (s^-1)	Keq = 1(uM)	0.1sec	Substrate Ca_input Product Ca
9	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
10	Ca_diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[3] Pathway No. : 400	5 (s^-1)	5 (s^-1)	Keq = 1(uM)	0.1sec	Substrate Ca_input Product Ca
11	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
12	Ca_diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[4] Pathway No. : 407	5 (s^-1)	5 (s^-1)	Keq = 1(uM)	0.1sec	Substrate Ca_input Product Ca
13	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
14	Ca_diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[5] Pathway No. : 413	5 (s^-1)	5 (s^-1)	Keq = 1(uM)	0.1sec	Substrate Ca_input Product Ca
15	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
16	Ca_diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[6] Pathway No. : 417	5 (s^-1)	5 (s^-1)	Keq = 1(uM)	0.1sec	Substrate Ca_input Product Ca
17	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
18	Ca_diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[7] Pathway No. : 425	5 (s^-1)	5 (s^-1)	Keq = 1(uM)	0.1sec	Substrate Ca_input Product Ca
19	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
20	Ca_diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[8] Pathway No. : 430	5 (s^-1)	5 (s^-1)	Keq = 1(uM)	0.1sec	Substrate Ca_input Product Ca
21	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
22	Ca_diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[9] Pathway No. : 436	5 (s^-1)	5 (s^-1)	Keq = 1(uM)	0.1sec	Substrate Ca_input Product Ca
23	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
24	Ca_diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[10] Pathway No. : 442	5 (s^-1)	5 (s^-1)	Keq = 1(uM)	0.1sec	Substrate Ca_input Product Ca
25	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
26	Ca_diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[11] Pathway No. : 448	5 (s^-1)	5 (s^-1)	Keq = 1(uM)	0.1sec	Substrate Ca_input Product Ca
27	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
28	Ca_diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[12] Pathway No. : 454	5 (s^-1)	5 (s^-1)	Keq = 1(uM)	0.1sec	Substrate Ca_input Product Ca
29	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
30	Ca_diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[13] Pathway No. : 460	5 (s^-1)	5 (s^-1)	Keq = 1(uM)	0.1sec	Substrate Ca_input Product Ca
31	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
32	Ca_diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[14] Pathway No. : 466	5 (s^-1)	5 (s^-1)	Keq = 1(uM)	0.1sec	Substrate Ca_input Product Ca
33	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
34	Ca_diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[15] Pathway No. : 472	5 (s^-1)	5 (s^-1)	Keq = 1(uM)	0.1sec	Substrate Ca_input Product Ca
35	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
36	Ca_diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[16] Pathway No. : 478	5 (s^-1)	5 (s^-1)	Keq = 1(uM)	0.1sec	Substrate Ca_input Product Ca
37	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
38	Ca_diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[17] Pathway No. : 484	5 (s^-1)	5 (s^-1)	Keq = 1(uM)	0.1sec	Substrate Ca_input Product Ca
39	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
40	Ca_diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[18] Pathway No. : 490	5 (s^-1)	5 (s^-1)	Keq = 1(uM)	0.1sec	Substrate Ca_input Product Ca
41	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
42	Ca_diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[19] Pathway No. : 496	5 (s^-1)	5 (s^-1)	Keq = 1(uM)	0.1sec	Substrate Ca_input Product Ca
43	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
44	Ca_diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[20] Pathway No. : 502	5 (s^-1)	5 (s^-1)	Keq = 1(uM)	0.1sec	Substrate Ca_input Product Ca
45	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
46	Ca_diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[21] Pathway No. : 508	5 (s^-1)	5 (s^-1)	Keq = 1(uM)	0.1sec	Substrate Ca_input Product Ca
47	diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	Shared_Object_ Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Pathway No. : 375	0.01 (s^-1)	0.01 (s^-1)	Keq = 1(uM)	50sec	Substrate Ca Product Ca
48	Ca_diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[22] Pathway No. : 514	5 (s^-1)	5 (s^-1)	Keq = 1(uM)	0.1sec	Substrate Ca_input Product Ca
49	Ca_diff	Ajay_bhalla_ 2007_ReacDiff1_ 1e-12 Accession No. : 81	kinetics[23] Pathway No. : 520	5 (s^-1)	5 (s^-1)	Keq = 1(uM)	0.1sec	Substrate Ca_input Product Ca

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