Team:Bielefeld-Germany/Modell

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==Model of a fixed-bed reactor==
==Model of a fixed-bed reactor==
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In our project we plan to construct a fixed-bed reactor, where immobilized laccases degrade synthetic estrogen and other harmful substances. As a small selection we plan to caracterize our different laccases for three estrogens, three analgesics, four PAH´s, one insecticide and three possible redox mediators.
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In our project we plan to construct a fixed bed flocculation filtration tank, where immobilized laccases degrade synthetic estrogen and other harmful substances. As a small selection we plan to characterize our different laccases for three estrogens, three analgesics, four PAHs, one insecticide and three possible redox mediators.
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If we could model the degradation of one substrate by one Laccase, we could easily replace the specific K<sub>cat</sub> K<sub>M</sub><sup>-1</sup> quotient for another Laccase and the amounts of the other substrates.
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If we could model the degradation of one substrate by one laccase, we could easily replace the specific K<sub>cat</sub> K<sub>M</sub><sup>-1</sup> quotient of other laccases and the amounts of the other substrates.
   
   
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We ignore the possible cofactors ABTS, syringaldazine and viuloric acid, because on the one hand thy would cause increase the costs, and one the other hand they are harmful substances too. As shown by Team Substrate Analytic TVEL0 degrades ethinyl estradiol without reox mediator. So the reaction should follow the michaelis menten kinetics.
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We ignore the possible cofactors ABTS, syringaldazine and viuloric acid, because on the one hand using these cofactors would increase the costs, and on the other hand they are harmful substances. As shown by Team Substrate Analytic TVEL0 degrades ethinyl estradiol without a redox mediator. So the reaction should follow the Michaelis Menten kinetics.
==The reaction==
==The reaction==
[[File:Bielefeld2012_MMnew.png|right|300px]]
[[File:Bielefeld2012_MMnew.png|right|300px]]
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The normal michaelis menten cinetic (1) can be adaptet for low substrate concentrations. To do this formula (2) replaces [ES] in formula (3). The result is formula (4). The velocity of this reaction descibes the cange of the substrate concentration over time (5). Formula (6) and (7) steps to solve the integral. (8) is the resulting formula to determine the time dependent substrate concentration by given starconcentration A.
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The normal Michaelis Menten kinetics (1) can be adapted for low substrate concentrations. In order to do this formula (2) replaces [ES] in formula (3). The result is formula (4). The velocity of this reaction describes the change of the substrate concentration over time (5). Formula (6) and (7) solve the integral. Equation (8) is the resulting formula to determine the time dependent substrate concentration by a given start concentration A.
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This transformation of the Michaelis Menten kinetic can be found in "Stryer biochemie". The resulting formula is suitable for very low substrate concentrations. In this case we can estimate degradation of initial substrate [https://2012.igem.org/wiki/index.php?title=Team:Bielefeld-Germany/Project/Background/Concentrations concentrations] below  0.1 µg L<sup>-1</sup>.
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Because there isn't any information about the K<sub>cat</sub> K<sub>M</sub><sup>-1</sup> quotient for the degradation of [https://2012.igem.org/Team:Bielefeld-Germany/Project/Background#Estradiol: estradiol] in the enzyme database [http://www.brenda-enzymes.info Brenda] the K<sub>cat</sub> K<sub>M</sub><sup>-1</sup> quotients were used for modeling the oxidation of [http://www.sigmaaldrich.com/catalog/product/sigma/a1888?lang=de&region=DE ABTS], a redox mediator of the laccase. ABTS is used in this case only as placeholder, until suitable data for the substrates are available. In the following picture a few possible reactions of our laccase are shown.
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This transformation can be found in "Stryer biochemie". This formula is suitable for very low substrate concentrations. In this case we can estimate the substrate concentrations below [https://2012.igem.org/wiki/index.php?title=Team:Bielefeld-Germany/Project/Background/Concentrations 0.1 µg L<sup>-1</sup>].
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[[File:Bielefeld2012_model.jpg|center|800px|thumb|'''Figure 1: '''The model with different K<sub>cat</sub> K<sub>M</sub><sup>-1</sup> values. The span differs from 0.07 seconds to 1500 seconds to degrade all ABTS.]]
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[[File:Bielefeld2012_model.jpg|center|800px|thumb|Our Model with different K<sub>cat</sub> K<sub>M</sub><sup>-1</sup> values. The span differs from 0.1 seconds to 1500 seconds.]]
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We use K<sub>cat</sub> K<sub>M</sub><sup>-1</sup> values from 11 to 643500 that result in degradation time points from 0.07s to 1500s. Furthermore we try to integrate different temperatures to our model. In a span from 10°C to 30°C and a K<sub>cat</sub> K<sub>M</sub><sup>-1</sup> value of 1, the degradation differs from 40 s to 100s.
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==Extend the model with sewageplant data==
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==Extend the model with sewage plant data==
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[[File:Bielefeld2012_Schlossholte_Daten.jpg|600px|thumb|left|Sewageplant data from Schloss Holte. Temperature minimum: 8.1 °C, maximum: 20,8 °C and average temperature 14.4 °C; pH minimum: 6.6, maximum: 7.2 and average 6.9; flow minimum: 39.2 L s<sup>-1</sup>, maximum 232.8 L s<sup>-1</sup> and avarage 76.8 L s<sup>-1</sup>]]
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[[File:Bielefeld2012_Schlossholte_Daten.jpg|600px|thumb|left|'''Figure 2: '''Date taken from the sewage plant located in Schloss Holte. Temperature minimum: 8.1 °C, maximum: 20,8 °C and average temperature 14.4 °C; pH minimum: 6.6, maximum: 7.2 and average 6.9; flow minimum: 39.2 L s<sup>-1</sup>, maximum 232.8 L s<sup>-1</sup> and average 76.8 L s<sup>-1</sup>;]]
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We got discharge water data from Schlossholte about the water tempreture, pH value and flowrate. The temperature and pH value have a direct influence of enzymatic activity. Dependent on the enzymatic activity we want to calculate the time our fixed-bed reactor will need to degrdate 80 % of the substrates. This will be the dewll time. Combined with the actual flowrate we can determine the reactorsize. With a previously set enzyme concentration we could now calculate the reactor size. To estimate the feasibility we wart to know how much enzyme has to be produced for a wewage plant. A 3D model of the requirde enzme amount dependent of K<sub>cat</sub> K<sub>M</sub><sup>-1</sup> values and flowrate.
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The sewage plant in Schloss Holte provided information about the discharge water, particularly water temperature, pH value and flow rate. The temperature and pH value have a direct influence on the enzymatic activity. Dependent on the enzymatic activity we want to calculate the time our fixed-bed reactor will need to degrade 80 % of the substrates. This will be the dwell time. Combined with the actual flow rate we can determine the reactor size. To estimate the feasibility we want to know how much enzyme has to be produced for a sewage plant. A model of the required enzyme amount dependent of K<sub>cat</sub> K<sub>M</sub><sup>-1</sup> values and flow rate.
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[[File:Bielefeld2012_3d.jpg|600px|thumb|left|The required enzyme amount for a sewageplant is dependent on K<sub>cat</sub> K<sub>M</sub><sup>-1</sup> and the flow rate]]
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[[File:Bielefeld2012_3D.jpg|600px|thumb|left|'''Figure 3: '''The required enzyme amount (z axis) for a sewage plant is dependent on K<sub>cat</sub> K<sub>M</sub><sup>-1</sup> value (x axis) influenced by temperature and pH value and the flow rate (y axis). In the optimal case the needed enzyme amount is 29 g laccase to degrade 80 % of ABTS. In the worst case 350 g laccase will be needed.]]
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==Outlook==
==Outlook==
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"Team Substrate Analytic" will determine K<sub>cat</sub> K<sub>M</sub><sup>-1</sup>. Additionaly we have the opportunity to work with a lab sewageplant. So we´re going to test our model in defined conditions.
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The next step will be, to add more substrates and different laccases to our model. Hence we will need more data about laccases. K<sub>cat</sub> K<sub>M</sub><sup>-1</sup> values have to be determined as well as the specifity of the laccases. We have the opportunity to work with a [https://2012.igem.org/Team:Bielefeld-Germany/Sewage_treatment_plant#Conclusion lab-scale water treatment system]. So we plan to test our model in defined conditions.
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Latest revision as of 23:29, 18 November 2012

Modelling

Contents

Model of a fixed-bed reactor

In our project we plan to construct a fixed bed flocculation filtration tank, where immobilized laccases degrade synthetic estrogen and other harmful substances. As a small selection we plan to characterize our different laccases for three estrogens, three analgesics, four PAHs, one insecticide and three possible redox mediators. If we could model the degradation of one substrate by one laccase, we could easily replace the specific Kcat KM-1 quotient of other laccases and the amounts of the other substrates.

We ignore the possible cofactors ABTS, syringaldazine and viuloric acid, because on the one hand using these cofactors would increase the costs, and on the other hand they are harmful substances. As shown by Team Substrate Analytic TVEL0 degrades ethinyl estradiol without a redox mediator. So the reaction should follow the Michaelis Menten kinetics.

The reaction

Bielefeld2012 MMnew.png

The normal Michaelis Menten kinetics (1) can be adapted for low substrate concentrations. In order to do this formula (2) replaces [ES] in formula (3). The result is formula (4). The velocity of this reaction describes the change of the substrate concentration over time (5). Formula (6) and (7) solve the integral. Equation (8) is the resulting formula to determine the time dependent substrate concentration by a given start concentration A.

This transformation of the Michaelis Menten kinetic can be found in "Stryer biochemie". The resulting formula is suitable for very low substrate concentrations. In this case we can estimate degradation of initial substrate concentrations below 0.1 µg L-1.

Because there isn't any information about the Kcat KM-1 quotient for the degradation of estradiol in the enzyme database [http://www.brenda-enzymes.info Brenda] the Kcat KM-1 quotients were used for modeling the oxidation of [http://www.sigmaaldrich.com/catalog/product/sigma/a1888?lang=de&region=DE ABTS], a redox mediator of the laccase. ABTS is used in this case only as placeholder, until suitable data for the substrates are available. In the following picture a few possible reactions of our laccase are shown.





Figure 1: The model with different Kcat KM-1 values. The span differs from 0.07 seconds to 1500 seconds to degrade all ABTS.

We use Kcat KM-1 values from 11 to 643500 that result in degradation time points from 0.07s to 1500s. Furthermore we try to integrate different temperatures to our model. In a span from 10°C to 30°C and a Kcat KM-1 value of 1, the degradation differs from 40 s to 100s.

Extend the model with sewage plant data

Figure 2: Date taken from the sewage plant located in Schloss Holte. Temperature minimum: 8.1 °C, maximum: 20,8 °C and average temperature 14.4 °C; pH minimum: 6.6, maximum: 7.2 and average 6.9; flow minimum: 39.2 L s-1, maximum 232.8 L s-1 and average 76.8 L s-1;

The sewage plant in Schloss Holte provided information about the discharge water, particularly water temperature, pH value and flow rate. The temperature and pH value have a direct influence on the enzymatic activity. Dependent on the enzymatic activity we want to calculate the time our fixed-bed reactor will need to degrade 80 % of the substrates. This will be the dwell time. Combined with the actual flow rate we can determine the reactor size. To estimate the feasibility we want to know how much enzyme has to be produced for a sewage plant. A model of the required enzyme amount dependent of Kcat KM-1 values and flow rate.

Figure 3: The required enzyme amount (z axis) for a sewage plant is dependent on Kcat KM-1 value (x axis) influenced by temperature and pH value and the flow rate (y axis). In the optimal case the needed enzyme amount is 29 g laccase to degrade 80 % of ABTS. In the worst case 350 g laccase will be needed.



Outlook

The next step will be, to add more substrates and different laccases to our model. Hence we will need more data about laccases. Kcat KM-1 values have to be determined as well as the specifity of the laccases. We have the opportunity to work with a lab-scale water treatment system. So we plan to test our model in defined conditions.

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