Team:TU Delft/Project/alkane-degradation/characterization

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(Difference between revisions)
(Alkane Degradation Characterization)
(Resting-cell assays)
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====Resting-cell assays====
====Resting-cell assays====
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As explained earlier the catalytic component of the alkane hydroxylase system is an integral membrane protein. Characterization must thus be done using an intact-membrane setup. An option which has been explored in literature [1] is the resting-cell assay a.k.a. biotransformation assay. The logic behind this is to stall the growth of a large volume of cells by using nitrogen-deficient medium to test their alkane conversion capabilities at near-zero growth.
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As explained earlier the catalytic component of the alkane hydroxylase system is an integral membrane protein. Characterization must thus be done using an intact-membrane setup. An option which has been explored in literature [1] is the resting-cell assay a.k.a. biotransformation assay. These assays will indicate the presence or absence of the desired enzymes, regardless of the alkane’s utilization for growth. The logic behind this is to stall the growth of a large volume of cells by using nitrogen-deficient medium to test their alkane conversion capabilities at near-zero growth.
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Extraction of the medium using an apolar solvent (such as ethyl acetate) after a certain amount of time and subsequent analysis by gas chromatography would indicate the presence of the corresponding alkanol and the decrease of alkane. For more on the experimental setup click [here], for the extraction method [here] and for the gas chromatography program [here].
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Extraction hydrocarbons from the medium using an apolar solvent (such as ethyl acetate) after the reaction and subsequent analysis by gas chromatography would indicate the presence of the corresponding alkanol and/or the decrease of alkane. For more on the experimental setup click [here], for the extraction method [here] and for the gas chromatography program [here].
===Characterization of the long-chain alkane monooxygenase===
===Characterization of the long-chain alkane monooxygenase===

Revision as of 14:20, 24 October 2010

CharacterizationResultsParts

Alkane Degradation Characterization

Introduction

In summary, the following strains were characterized:

  • E.coli K12 carrying [http://partsregistry.org/Part:BBa_K398014 BBa_K398014] in pSB1A2 (AH system)
  • E.coli K12 carrying [http://partsregistry.org/Part:BBa_K398017 BBa_K398017] in pSB1A2 (LadA)
  • E.coli TOP10 carrying [http://partsregistry.org/Part:BBa_K398027 BBa_K398027] in pSB1A2 (LadA)
  • E.coli K12 carrying [http://partsregistry.org/Part:BBa_K398018 BBa_K398018] in pSB1A2 (ADH)
  • E.coli K12 carrying [http://partsregistry.org/Part:BBa_K398029 BBa_K398029] in pSB1A2 (ALDH)

The characterization will generally be executed along with an 'empty' plasmid carrying strain:

  • E.coli K12 carrying [http://partsregistry.org/Part:BBa_J13002 BBa_J13002] in pSB1A2 ('empty' plasmid)

Characterization of the alkane hydroxylase system

Growth analysis

Of course, one of the first characterization experiments was to test growth of the E.coli strains carrying BBa_K398014 on alkanes. The alkanes octane and dodecane were tested as possible substrates in M9 minimal medium. The protocol can be found found [here]. The idea behind this is that E.coli might inherently contain an ADH and ALDH that, while it might be at an extremely low activity, can be able to degrade larger chain alkanes thus releasing energy for growth.

Resting-cell assays

As explained earlier the catalytic component of the alkane hydroxylase system is an integral membrane protein. Characterization must thus be done using an intact-membrane setup. An option which has been explored in literature [1] is the resting-cell assay a.k.a. biotransformation assay. These assays will indicate the presence or absence of the desired enzymes, regardless of the alkane’s utilization for growth. The logic behind this is to stall the growth of a large volume of cells by using nitrogen-deficient medium to test their alkane conversion capabilities at near-zero growth. Extraction hydrocarbons from the medium using an apolar solvent (such as ethyl acetate) after the reaction and subsequent analysis by gas chromatography would indicate the presence of the corresponding alkanol and/or the decrease of alkane. For more on the experimental setup click [here], for the extraction method [here] and for the gas chromatography program [here].

Characterization of the long-chain alkane monooxygenase

Enzyme activity assay based on GC-analysis

Enzyme activity assay based on NADH absorbance

Characterization of enzyme functionality

Parallel to this, resting-cell assays will be performed on growth-inhibited E.coli K12 strains containing the constructs described earlier. These assays will indicate the presence or absence of the desired enzymes, regardless of the alkane’s utilization for growth. The hydrocarbon compositions will be determined by gas chromatography analysis. For the intracellular enzymes, the cells were lysed and treated with the appropriate akanols and alkanals.

CharacterizationResultsParts