Difference between revisions of "Part:BBa K1172201"

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[[Image:IGEM_Bielefeld_NADHredoxreaction.jpg|450px|thumb|center|<p align="justify"> '''Figure 1: Redox reaction catalyzed by the glycerol dehydrogenase: NAD<sup>+</sup> is reduced to NADH by addition of two electrons (e<sup>-</sup>) and one proton (H<sup>+</sup>). '''</p>]]
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[[Image:iGEM_Bielefeld_NAD_oxidation_reduction.jpg|450px|thumb|center|<p align="justify"> '''Figure 1: Redox reaction catalyzed by the glycerol dehydrogenase: NAD<sup>+</sup> is reduced to NADH by addition of two electrons (e<sup>-</sup>) and one proton (H<sup>+</sup>). '''</p>]]
  
 
===Important parameters===
 
===Important parameters===

Revision as of 01:19, 5 October 2013

GldA - glycerol dehydrogenase from Escherichia coli

Usage and Biology

Mediators are essential for the use of Escherichia coli in Microbial Fuel Cells. The main goal when improving MFCs is to enhance the kinetics of the electron transfer between the bacterial cells and the fuel cell anode. Increasing the mediator concentration in the MFC is an efficient way to enhance electron transfer. In order to avoid the usage of expensive and toxic synthetic mediators, we engineered an E. coli KRX strain with an overexpressed glycerol dehydrogenase (GldA). GldA produces the endogenous mediator NADH from NAD+ and glycerol, which is the main carbon source in our medium. We were able to produce high amounts of NADH with the optimized E.coli, which resulted in a more efficient electron transfer. This demonstrates that genetically introducing an appropriate oxidoreductase into E. coli via gene manipulation can greatly improve the mediator production and power generation. We could show that the increased intracellular- and extracellular NADH concentration, leads to a 20 % enhanced current production in our Microbial Fuel Cell. The overexpression of the glycerol dehydrogenase in Escherichia coli is a great genetic optimization for electron shuttle-mediated extracellular electron transfer from bacteria to electrodes.

Figure 1: Redox reaction catalyzed by the glycerol dehydrogenase: NAD+ is reduced to NADH by addition of two electrons (e-) and one proton (H+).

Important parameters

The gldA gene from Escherichia coli was cloned and overexpressed in E. coli KRX under the control of different promoters (Table 1).

Table 1: Overview of GldA devices. Combination of GldA coding BioBrick (BBa_K1172201) with different promoters and RBS. The characterization of this BioBrick was performed by comparing Escherichia coli KRX wild type with Escherichia coli KRX carrying BBa_K1172203, BBa_K1172204 and BBa_K1172205.


Sequence and Features


Assembly Compatibility:
  • 10
    COMPATIBLE WITH RFC[10]
  • 12
    COMPATIBLE WITH RFC[12]
  • 21
    COMPATIBLE WITH RFC[21]
  • 23
    COMPATIBLE WITH RFC[23]
  • 25
    COMPATIBLE WITH RFC[25]
  • 1000
    COMPATIBLE WITH RFC[1000]


Results

Overview

  • Upon the expression of the glycerol dehydrogenase, the endogenous mediator production of Escherichia coli was measured. SDS-PAGE combined with MALDI-TOF MS/MS and different NADH-assays were performed to characterize the GldA BioBrick BBa_K1172201.


SDS-PAGE and MALDI-TOF

  • SDS-PAGE shows the protein glycerol dehydrogenase at the expected size of 40 kDa. In contrast to the Escherichia coli KRX wild type, the GldA protein under the control of the weak constitutive Anderson promoter (BBa_K1172205) can be seen by an only slightly stronger band. When the T7 (BBa_K1172203) and Lac (BBa_K1172204) promoter are used a strong band can be seen, which is equated with a strong expression and overproduction of GldA.


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Figure 4: SDS-PAGE with [http://www.thermoscientific.com/ecomm/servlet/productsdetail_11152___13576050_-1 Prestained Protein Ladder from Thermo Scientific] as marker. Comparison of protein expression between Escherichia coli KRX wild type and Escherichia coli KRX with BBa_K1172205, BBa_K1172204 and BBa_K1172203 after total cell disruption. The right-hand gel was loaded with a higher protein concentration. The SDS-PAGEs display the protein glycerol dehydrogenase at the expected size of 40 kDa and enhanced overproduction of the protein with increasing promoter strength.


  • Furthermore we were able to identify the overexpressed glycerol dehydrogenase (Figure. 4) with MALDI-TOF MS/MS.


NADH-Assays

  • An overproduction of the glycerol dehydrogenase results in an oversupply of products from the glycerol dehydrogenase. Glycerol dehydrogenase produces several mediators because of its broad substrate specificity. GldA is involved in several metabolic pathways, for example in the glycerol metabolism, which converts glycerol and NAD+ to glycerone, NADH and H+. NADH is a small, water-soluble redoxmolecule, which seems to be a great mediator for Microbial Fuel Cells. An overexpression of the glycerol dehydrogenase leads to an overproduction of NADH and therefore to an endogenous mediator production. Furthermore GldA seems to be very interesting in combination with our preferred MFC carbon source glycerol. Thus, it is essential to get reliable data on the NADH overproduction to see how many electron shuttles are available and how efficient the electron shuttle-mediated electron transfer (EET) will be.


  • We could observe an enhanced NADH production in comparison to the wild type for Escherichia coli KRX containing pSB1C3 with BBa_K1172203, BBa_K1172204 and BBa_K1172205 with increasing promoter strength. (Table 2 and Figure 5)


Table 2: Results of the NADH-assay. Comparison between Escherichia coli KRX wild type and Escherichia coli KRX with BBa_K1172205, BBa_K1172204 and BBa_K1172203. NADH concentration with standard deviation and concentration in comparison to the wild type is shown. Two biological and at least three technical replicates were analyzed.

Figure 5: Column chart with results of the NADH-assay. Comparison between Escherichia coli KRX wild typ and Escherichia coli KRX with BBa_K1172205, BBa_K1172204 and BBa_K1172203. NADH concentration with standard deviation and concentration in comparison to the wild type is shown. Two biological and at least three technical replicates were analyzed.


  • Compared to the Escherichia coli KRX wild type, Escherichia coli carrying GldA and T7 promoter (BBa_K1172203) shows 1.7 μM NADH overproduction and GldA with Lac promoter (BBa_K1172204) shows 0.2 μM NADH overproduction. The GldA expression by the Anderson promoter (BBa_K1172205) is too weak for a significant NADH overproduction.

  • For all following tests, E. coli with GldA and T7 promoter (BBa_K1172203) was used, because this strain by far shows the highest NADH production rate.


  • Former MFC tests showed, that glycerol is the best carbon source for growth of Escherichia coli under anaerobic respiration in our Microbial Fuel Cell. Therefore it is important to see, which effect an increased glycerol concentration has on the mediator production. To test these parameters, LB medium was supplemented with different amounts of glycerol (Table 3).


Table 3: Experimental design of the glycerol dependent NADH-assay. Supplementation of different amounts of glycerol to LB medium should show the effect of glycerol on NADH overproduction.


  • E.coli (BBa_K1172203) grown in glycerol-supplemented medium shows enhanced NADH production in contrast to the Escherichia coli KRX wild type and also in contrast to the Escherichia coli KRX with BBa_K1172203 and no further glycerol supplementation (Table 4 and Figure 6).


Table 4: Results of the NADH-assay. Comparison between Escherichia coli KRX wild type and Escherichia coli KRX with BBa_K1172203 supplemented with different amounts of glycerol to LB medium. NADH concentration with standard deviation and concentration in comparison to the wild type is shown. Two biological and at least three technical replicates were analyzed.

Figure 6: Column chart with results of the NADH-assay. Comparison between Escherichia coli KRX wild type and Escherichia coli KRX with BBa_K1172203 supplemented with different amounts of glycerol to LB medium. NADH concentration with standard deviation and concentration in comparison to the wild type is shown. Two biological and at least three technical replicates were analyzed.


  • The glycerol dependent NADH-assay shows the expected NADH overproduction for BBa_K1172203 when supplemented with glycerol. It was possible to increase the NADH production by 270 % in comparison to the Escherichia coli KRX wild type and up to 100 % in comparison to the E. coli KRX carrying BBa_K1172203, without glycerol supplementation. However, the supplemented glycerol concentration does not have a considerable impact on the NADH production. These characteristics in production improvement are initially only valid for LB medium with glycerol supplementation.


  • With previous NADH-assays we only observed the effects of GldA on the intracellular NADH concentration of E. coli. To additionally investigate the extracellular NADH concentrations, we tested the Escherichia coli KRX wild type strain and the E. coli KRX with pSB1C3 and BBa_K1172203 by cultivation with different glycerol concentrations in M9 medium. (Table 5)


Table 5: Experimental design of the glycerol dependent NADH-assay. Different concentrations of glycerol in M9 medium should show the effect of glycerol on NADH overproduction.


  • Cultivating Escherichia coli BBa_K1172203 with increasing glycerol concentration in M9 medium shows enhanced intracellular and also enhanced extracellular NADH concentrations in contrast to the Escherichia coli KRX wild type. (Table 6 and Figure 7)


Table 6: Results of the NADH-assay. Comparison between Escherichia coli KRX wild type and Escherichia coli KRX with BBa_K1172203 grown in M9 medium with different concentrations of glycerol. NADH concentration with standard deviation and concentration in comparison to the wild type is shown for cell disruption and supernatant fraction. Two biological and at least three technical replicates were analyzed.

Figure 7: Column chart with results of the NADH-assay. Comparison between Escherichia coli KRX wild type and Escherichia coli KRX with BBa_K1172203 grown in M9 medium with different concentrations of glycerol. NADH concentration with standard deviation and concentration in comparison to the wild type is shown for cell disruption (Intracellular) and supernatant (Extracellular) fraction. Two biological and at least three technical replicates were analyzed.


  • In addition to the previously observed increase in intracellular NADH concentration, we were able to show an enhanced extracellular NADH concentration. Heterologous expression of GldA BBa_K1172203 in E. coli seems to be an appropriate way for endogenous mediator production. Furthermore glycerol could be confirmed as a suitable substrate for the NADH production.

  • Intracellular NADH concentration increases up to 223 % in comparison to Escherichia coli KRX wild type with increasing promoter strength. It is also very interesting to see that the extracellular NADH concentration is 7 times higher than the intracellular concentration for all strains. Overexpression of GldA BBa_K1172203 in E. coli causes a 2.5 times higher extracellular NADH concentration compared with Escherichia coli KRX wild type.

  • However, it is surprising that the extracellular concentration of NADH is 7 times higher than the intracellular concentration. Therefore, we cannot be sure that the complete extracellular fluorescence is only due to the endogenous mediator NADH. There might be a substance that is directly or indirectly produced with the overexpression of GldA and secreted into the medium. Thus, we will analysis the extracellular fraction with LC ESI MS/MS, in order to identify potential compounds.

  • These data show that NADH is an adequate mediator for Microbial Fuel Cells. NADH can be transported across the cell membrane, which is indicated by much higher extracellular NADH concentration and thus allow NADH-mediated electron transfer (EET).


Microbial Fuel Cell Measurement

  • All NADH-assays showed great enhanced NADH overproduction for the GldA strain. Therefore higher electron transport efficiency should result in an improved bioelectricity output.

  • For testing the genetic engineered system in the Microbial Fuel Cell, we used Escherichia coli KRX with GldA and Lac promoter (BBa_K1172204) in contrast to Escherichia coli KRX wild type. Certainly NADH-assays determined Escherichia coli KRX with GldA and T7 promoter (BBa_K1172203) as the best endogenous mediator producing strain. Unfortunately we could not use this strain due to cultivation problems.

  • According to our assumptions, the extracellular electron transfer mediated by NADH is improved in the GldA strain resulting in an increased bioelectricity output. (Figure 8 and 9)


Figure 8: Microbial Fuel Cell results from cultivation of Escherichia coli KRX with GldA (BBa_K1172204) in contrast to Escherichia coli KRX wild type. Voltage curve from Escherichia coli KRX wild type and Escherichia coli KRX with GldA (BBa_K1172204) is shown over time over a resistance of 200 Ω. M9-medium was used with no supplementation of mediators.

Figure 9: Microbial Fuel Cell results from cultivation of Escherichia coli KRX with GldA (BBa_K1172204) in contrast to Escherichia coli KRX wild type. Electric charge curve from Escherichia coli KRX wild type and Escherichia coli KRX with GldA (BBa_K1172204) is shown over time over a resistance of 200 Ω. M9-medium was used with no supplementation of mediators.


  • Escherichia coli KRX with GldA (BBa_K1172204) shows a 27 % higher maximal voltage than the Escherichia coli KRX wild type. Over the whole cultivation, voltage was improved by about 20%. The calculation of the electric charge confirms the described results. Electric charge is equivalent to the number of transported electrons and 20 % enhanced for Escherichia coli KRX with GldA (BBa_K1172204). The maximal electric charge of 135 mC shows that the overexpression of the glycerol dehydrogenase enables endogenous mediator production and a more efficient electron shuttle-mediated electron transfer.

  • A further optimization by using Escherichia coli KRX with GldA and T7 promoter (BBa_K1172203) instead of Lac promoter (BBa_K1172203) would improve electricity output according to the NADH-assay results (Table 2 and Figure 5) of about 134 %. These results demonstrate that the redox mediator NADH from Escherichia coli facilitates the electron transfer between cell and electrode and shows a starting point for reducing costs of expensive and toxic exogenous mediators.


Conclusion

  • Mediators are essential for the use of Escherichia coli in Microbial Fuel Cells. The main goal of improving MFCs is to enhance kinetics of the electron transfer between the bacterial cells and the fuel cell anode. In order to decrease the usage of expensive and toxic synthetic mediators (exogenous mediators like methylene blue or neutral red), we produced the endogenous mediator NADH by overexpression of the glycerol dehydrogenase.

  • Looking at our project in its entirety, the overproduction of the glycerol dehydrogenase seems to be a great way for endogenous mediator production. The use of glycerol as our main carbon source for Escherichia coli in the MFC further enhances the efficiency of NADH production. We can show a 270 % higher intracellular NADH concentration (4 μM) for Escherichia coli KRX with GldA plasmid and a 170 % higher extracellular NADH concentration (24 μM) in contrast to the Escherichia coli KRX wild type.

  • The overexpression of GldA is a great genetic strategy to optimize mediator production as well as electricity generation in Microbial Fuel Cells. The most suitable and efficient GldA device for Escherichia coli is a combination with the rhamnose inducible T7 promoter (BBa_K1172203).


References

  • Kelley JJ, Dekker EE (1985) Identity of Escherichia coli D-1-amino-2-propanol: NAD+ oxidoreductase with E. coli glycerol dehydrogenase but not with Neisseria gonorrhoeae 1,2-propanediol:NAD+ oxidoreductase. [http://jb.asm.org/content/162/1/170.short| J. Bacteriol. 162: 170].

  • Mulichak AM (2005) Crystal structure of glycerol dehydrogenase. [http://www.rcsb.org/pdb/images/1ta9_bio_r_500.jpg| Research Collaboratory for Structural Bioinformatics (RCSB) Protein Data Band (PDB)].

  • Park DH, Kim SK, Shin IH, Jeong YJ (2000) Electricity production in biofuel cell using modified graphite electrode with Neutral Red. [http://link.springer.com/article/10.1023/A:1005674107841#page-1| Biotechnol. Lett 22: 1301].

  • Qiao Y, Li CM, Bao SJ, Lu ZS, Hong YH (2008) Electrocatalysis in microbial fuel cells - from electrode material to direct electrochemistry. [http://pubs.rsc.org/en/content/articlehtml/2010/ee/b923503e| Chem. Commun. 1290].

  • Ruzheinikov SN, Burke J, Sedelnikova S, Baker PJ, Taylor B, Bullough PA, Muir NM, Gore MG, Rice DW (2001) Glycerol Dehydrogenase: Structure, Specificity, and Mechanism of a Family III Polyol Dehydrogenase. [http://www.sciencedirect.com/science/article/pii/S0969212601006451|Structure 9: 789–802].

  • Seop CI, Moon H, Bretschger O, Jang JK, Park HI, Nealson KH, Kim BH (2006) Electrochemically Active Bacteria (EAB) and Mediator-Less Microbial Fuel Cells. [http://www.microbialfuelcell.org/Publications/EBL/1-10/8_2006_Chang%20I.%20S_%20Electrochemically%20active%20bacteria%20%28EAB%29%20and%20mediator-less%20microbial%20fuel%20cells.pdf|J. Microbiol. Biotechnol. 16 (2): 163–177].

  • Xiang K, Qiao Y, Ching CB, Li CM (2009) GldA overexpressing-engineered E. coli as superior electrocatalyst for microbial fuel cells. [http://www.sciencedirect.com/science/article/pii/S1388248109002835| Electrochemistry Communications 11: 1593–1595].

  • Zhang T, Cui C, Chen S, Ai X, Yang H, Shen P, Peng Z (2006) A novel mediatorless microbial fuel cell based on direct biocatalysis of Escherichia coli. [http://pubs.rsc.org/en/content/articlehtml/2006/cc/b600876c| Chem Commun 11: 2257–2259].