Team:Missouri Miners/Project

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'''PROJECT''' - Microbial Fuel Cell:
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'''Current PROJECT''' - Microbial Fuel Cell:
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The goal of this research is to manipulate E.Coli; thus granting them the ability to release electrons in an aerobic environment. This project utilizes geobacter's cytocromes, which makes its extracellular electron transfer possible. OmcB,OmcE,OmcS, and MacA are our target genes, since their proteins are the major electron smugglers out of the cell. By isolating and placing these cytocromes into bricks, we hope to harness the ability to produce electricity in biological systems.
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Past Project- Methanol Sensor
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The purpose of this research is to use recombinant technology to culture yeast cells capable of determining the concentration of ethanol and using these cells to construct an ethanol sensor.  Metabolic pathways exist for the metabolism of methanol and ethanol within some species of the Pichia taxa to include the yeast of our interest, ''Pichia pastoris''.  Alcohol oxidase (AO) appears to be the first and major enzyme produced in the methanol metabolic pathway of ''P. pastoris''. However, if both ethanol and methanol are present, P. pastoris will utilize the ethanol before consuming the methanol.  Consequently, the AOXI gene will not be expressed to produce the AO enzyme until the ethanol has been consumed.
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Fusing the AOXI gene promoter with the DNA sequence encoding a fluorescent protein will allow the expression of the AOXI gene to be detected.  In supplying the yeast cells with ethanol and methanol simultaneously, the cells will produce the fluorescent protein once the ethanol is utilized.  The concentration of ethanol can then be determined by measuring the time before fluorescence is detected.
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The goal of this research is the manipulation of E.Coli; granting them the ability to release electrons in an aerobic enviroment. This project utilizes geobacter's cytocromes, which makes it's extracellular electron transfer possible. The cytocromes OmcB,OmcE,OmcS, and MacA are our priority since they are the major electron smugglers out of the cell. By isolating and placing these cytocromes, some of which are naturally occur in E.Coli,into bricks we hope to make the electical application possible in other bacterial species. 
 
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|[[Image:Echain.JPG|right|frame|Extracellular Electron Transport Chain]]
 
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<!--- The Mission, Experiments --->
<!--- The Mission, Experiments --->
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Optimization of electron shuffle to external surfaces such as anodes is a primary goal.  Geobacter sulfurreducens happens to be our model bacteria due to its ability in nature to efficiently export electrons extracelluarly.  E. coli can be the chassis for this experiment due to its genome already containing some key proteins in our preferred pathway.  The proteins, such as extracellular pilin, MacA, and many other cytochromes, which E. coli does not have will be isolated from Geobacter sulfurreducens and introduced into E. coli to formulate the most optimal pathway for generating electronmotive force in a microbial fuel cell apparatus.   
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The optimization of electron shuffle within bacteria to external surfaces such as anodes is one of the primary goals of our project.  Geobacter sulfurreducens is the bacteria of choice due to its ability to efficiently export electrons outside of the cell.  E. coli is our desired "skeleton" bacteria for our project due to the bacteria's genome already containing many key proteins in the desired pathway.  Extracellular pilin, MacA, and many other cytochromes that E. coli does not have will be isolated from Geobacter sulfurreducens and introduced into E. coli to create the most optimal pathway for generating electronmotive force in a microbial fuel cell apparatus.   
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Some problems will be faced concerning plasmid engineering and the simple fact that Geobacter is anaerobic and E. coli is aerobic. Also, the role of Geobacter's pili in extracellular electron transfer is not clearly understood and could create a significant problem since e. coli does not have such pili.  As a team, we will push in the right direction harder than an emf on the internal resistivity of a toroid.  Many diverse team members will work in concert utilizing Missouri S&T’s dominating Electrical, Chemical, and Biological Engineering undergraduates along with Biological Science masterminds.
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A handful of problems have surfaced already in our project this year. Two of the most evident are correct plasmid engineering and Geobacter's anaerobic respiration contrasted to E. coli's aerobic respiration. Also, the role of Geobacter's pili in extracellular electron transfer is not clearly understood and could create a significant problem due to E. coli not having such pili.  As a team, we will strive in the right direction harder than an emf on the internal resistivity of a toroid.  Our team consists of many students working together from many diverse areas including Missouri S&T’s Electrical, Chemical, and Biological Engineering department along with the Biological Sciences.
== Project Details==
== Project Details==
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|Procedure:
|Procedure:
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Some of the techniques that have been used thus far in pursuing this project have been:
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Laboratory techniques that have been utilized by team members working on the project:
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#PCR amplification of the MacA and other cytocromes using PCR primers that added standard prefix and suffix sequences
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#Cloning the cytocrome PCR products into a commercial cloning vector
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#PCR amplification of the MacA and other cytochromes using PCR primers that added standard prefix and suffix sequences
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#Digesting the cytocrome plasmids to obtain the promoter genes of interest
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#Cloning the cytochrome PCR products into a commercial cloning vector
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#Digesting the cytochrome plasmids to obtain the promoter genes of interest
#Separating and isolating the enzyme digest fragments through gel electrophoresis
#Separating and isolating the enzyme digest fragments through gel electrophoresis
#Ligating the individual cytochrome promoters together
#Ligating the individual cytochrome promoters together
#Transforming bacterial cells with the recombined cytochrome plasmids
#Transforming bacterial cells with the recombined cytochrome plasmids
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|[[Image:Echain.jpg|200px|thumb|right|frame|Extracellular Electron Transport Chain]]
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Possible  Applications:
Possible  Applications:
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The application of thie eletron trasfer is limited only by the imagination.  
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The applications of a interchangeable electron transfer gene part are limitless.  
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The cytochrom cocktail could be used as a type of signal in a bacteria. It would produce small currents and be utalized in a similar fasion to the applications of flourescent proteins.  
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The cytochrome cocktail could be used as a signal within bacteria. It would produce small currents which would be utilized in a similar fashion to fluorescent proteins as markers and indicators of cellular activity.  
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Small electronics could uses living power sources (with future technological advances).
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Micro and nano-electronics could be adapted to use electron transfer modified bacteria as a cheap and effective power source.
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Medical arenas could benefit by using modified bacteria in areas of the body such as stomach and intestines and developing the bacteria as a long term mobile monitor.
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Medical research could benefit by using modified bacteria in areas of the body such as the stomach and intestines. The bacteria could be developed to act as a long term mobile monitor inside the human body.

Latest revision as of 14:57, 5 August 2009

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MissouriSandT.jpg

Current PROJECT - Microbial Fuel Cell:

The goal of this research is to manipulate E.Coli; thus granting them the ability to release electrons in an aerobic environment. This project utilizes geobacter's cytocromes, which makes its extracellular electron transfer possible. OmcB,OmcE,OmcS, and MacA are our target genes, since their proteins are the major electron smugglers out of the cell. By isolating and placing these cytocromes into bricks, we hope to harness the ability to produce electricity in biological systems.


Past Project- Methanol Sensor

The purpose of this research is to use recombinant technology to culture yeast cells capable of determining the concentration of ethanol and using these cells to construct an ethanol sensor. Metabolic pathways exist for the metabolism of methanol and ethanol within some species of the Pichia taxa to include the yeast of our interest, Pichia pastoris. Alcohol oxidase (AO) appears to be the first and major enzyme produced in the methanol metabolic pathway of P. pastoris. However, if both ethanol and methanol are present, P. pastoris will utilize the ethanol before consuming the methanol. Consequently, the AOXI gene will not be expressed to produce the AO enzyme until the ethanol has been consumed.

Fusing the AOXI gene promoter with the DNA sequence encoding a fluorescent protein will allow the expression of the AOXI gene to be detected. In supplying the yeast cells with ethanol and methanol simultaneously, the cells will produce the fluorescent protein once the ethanol is utilized. The concentration of ethanol can then be determined by measuring the time before fluorescence is detected.



Overall project

The optimization of electron shuffle within bacteria to external surfaces such as anodes is one of the primary goals of our project. Geobacter sulfurreducens is the bacteria of choice due to its ability to efficiently export electrons outside of the cell. E. coli is our desired "skeleton" bacteria for our project due to the bacteria's genome already containing many key proteins in the desired pathway. Extracellular pilin, MacA, and many other cytochromes that E. coli does not have will be isolated from Geobacter sulfurreducens and introduced into E. coli to create the most optimal pathway for generating electronmotive force in a microbial fuel cell apparatus.

A handful of problems have surfaced already in our project this year. Two of the most evident are correct plasmid engineering and Geobacter's anaerobic respiration contrasted to E. coli's aerobic respiration. Also, the role of Geobacter's pili in extracellular electron transfer is not clearly understood and could create a significant problem due to E. coli not having such pili. As a team, we will strive in the right direction harder than an emf on the internal resistivity of a toroid. Our team consists of many students working together from many diverse areas including Missouri S&T’s Electrical, Chemical, and Biological Engineering department along with the Biological Sciences.

Project Details

Procedure:

Laboratory techniques that have been utilized by team members working on the project:

  1. PCR amplification of the MacA and other cytochromes using PCR primers that added standard prefix and suffix sequences
  2. Cloning the cytochrome PCR products into a commercial cloning vector
  3. Digesting the cytochrome plasmids to obtain the promoter genes of interest
  4. Separating and isolating the enzyme digest fragments through gel electrophoresis
  5. Ligating the individual cytochrome promoters together
  6. Transforming bacterial cells with the recombined cytochrome plasmids
Extracellular Electron Transport Chain


Possible Applications: The applications of a interchangeable electron transfer gene part are limitless. The cytochrome cocktail could be used as a signal within bacteria. It would produce small currents which would be utilized in a similar fashion to fluorescent proteins as markers and indicators of cellular activity. Micro and nano-electronics could be adapted to use electron transfer modified bacteria as a cheap and effective power source. Medical research could benefit by using modified bacteria in areas of the body such as the stomach and intestines. The bacteria could be developed to act as a long term mobile monitor inside the human body.