Team:Groningen/Project

From 2012.igem.org

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== Goal ==
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== Summary==
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Every year, ''1.300.000.000 tons'' of food are ''thrown away'' worldwide. This is one third of the global food production. One of the reasons for this is the fact that ''best before dates'' are imprecise. A reliable way of monitoring whether food is spoiled or not, could ''save upto 600 euro'' per household per year.
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To provide a method of monitoring the edibility of packaged meat and fish after the store-bought package has been opened.
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Our goal is to build a system to ''sense meat spoilage''. When a package of meat is saved after opening (1), a closed ''sticker'' containing'' Bacillus subtilis'' spores  is activated by breaking the middle compartment (2,similar to activating a glow-in-the-dark stick), whereby Alanine, and water are mixed with the spores to cause ‘’germination’’ (3). When the germinated microbes come in contact with ''volatiles from rotting meat'', a pathway is activated which results to the production of a ‘’pigment’’(4). When this happens, the consumer knows that he has to throw away the food (5). The different states of the volatile sensor are explained below.
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[[File:Groningen2012_RR_20120713_paintpicture.png|680px|center]]
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More detailed abstract to come once the theory has been proven experimentally. For now, the homepage provides a broad overview.
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== Construct ==
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The standard construct is a combination of biobricks.
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* BBa_K090403 (Backbone) - Single copy shuttle vector
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-
* BBa_K116632 (Positive feedback loop) - Uses the pRe promoter regulated by C11 and terminated by B0010.
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* BBa_K274100 (Reporter) - Modified carotenoid pathway to produce red pigment.
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-
[[File:Groningen2012_JP_20120618_pRe-CII-Lycopene_Construct_A.png|680px|center]]
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* Or, using BBa_K274002 (Reporter) - Violet pigment producer
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[[File:Groningen2012_JP_20120618_pRe-CII-Violacein_Construct_A.png|680px|center]]
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== States ==
== States ==
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=== Sporulation  ===
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=== Containment of ''Bacillus subtilis'' spores: the sticker===
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Magic
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The spores of ''Bacillus subtilis'' will be contained in a compartment which is impermeable for bacteria and liquids, but can still let through volatiles. Metabolites, water and Alanine should be separated from the spores by a breakable membrane. Mixing these compounds will cause germination.
=== Germination ===
=== Germination ===
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Magic involving tennis rackets, D-alanine, and water.
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Alanine and water can trigger germination of'' Bacillus subtilis''. The modeling team will provide information on the optimal concentrations for germination, and on the germination time.
 +
 
 +
===Activation Pathways===
 +
We follow two different strategies to build a pathway in ''Bacillus subtilis'' which can react to the presence of rotten meat volatiles. One is using the TnrA pathway, which is normally expressed in absence of ammonium (reference). For the other strategy, we use a transcriptomics approach searching for promoters present in ‘’Bacillus’’ reacting to rotten meat volatiles.
-
=== Pre-Activation ===
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====First strategy: TnrA pathway ====
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Pre-Activation
# The growth medium contains a low concentration of glutamine (gln), but no ammonia or ammonium (NH4).
# The growth medium contains a low concentration of glutamine (gln), but no ammonia or ammonium (NH4).
# Glutamine synthetase (GS) is activated due to the inadequate level of glutamine, however, it cannot synthesize more gln as it is lacking NH4.
# Glutamine synthetase (GS) is activated due to the inadequate level of glutamine, however, it cannot synthesize more gln as it is lacking NH4.
Line 31: Line 26:
# The TnrA represses the alsT promoter.
# The TnrA represses the alsT promoter.
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=== Activation ===
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Activation
# Rotting meat produces NH4.
# Rotting meat produces NH4.
# NH4 is enters the cell through the NrgAB ammonium transporter.
# NH4 is enters the cell through the NrgAB ammonium transporter.
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# No longer repressed, alsT activates along with its positive feedback loop containing the color reporter.
# No longer repressed, alsT activates along with its positive feedback loop containing the color reporter.
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=== Post-Activation ===
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====Second strategy: identification of “PBADmeat”====
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# The pRe promoter continually expresses the color and the loop promoter.
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TnrA is a repressor/activator which acts on a broad level. This makes it a tricky candidate for triggering a single reaction. Therefore, an alternative strategy is needed.
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# The rate of production is tuned to the spoiling time of the meat.
+
 
 +
To identify our rotten meat volatile reporter (short: PBADmeat), we performed an transcriptome analysis of ''Bacillus subtilis'' subjected to rotten meat (target) and to fresh meat (control) volatiles. Analysis of the differential expression between these two situations can lead to candidate promoters for our construct.
 +
 
 +
The technique: DNA Microarray
 +
MicroArrays are used to compare the expression of genes between two or more conditions.. At a certain growth fase, one isolates all mRNA (the transcriptome). Then the mRNA is copied into cDNA. The cDNA is tagged with a fluorescent dye, one condition red, the other green. Both conditions are then brought onto a MicroArray slide, where DNA of each gene of the organism of interest (in our case, Bacillus) is attached in separate wells (these are called “probes”). When the cDNA is brought onto the slide, it will hybridize with the probes. After fluorescence measurement, one will see a black dot when the gene is not transcribed in both conditions, an orange/yellow one when the gene is transcribed in both, and a green or red one when just one condition causes the transcription of the gene. The ratio of red/green will be a measure for differential expression.
 +
 
 +
===Color reporter===
 +
As a reporter, we choose to use a pigment. The big advantage of using a pigment over another type of reporter (for instance, GFP or an electrical signal) is that it can be detected without any equipment. A big drawback however, is the production speed of pigments.
 +
 
 +
To make ''Bacillus subtilis'' produce more pigment, we plan to build in a positive feedback loop. Different feedback loops are available in the Registry of Standard Biological Parts (for instance PLux/LuxR and pRE/CII). We plan to characterize and - if necessary - improve one for our construct.
 +
 
 +
We will start with using the e.chromi pigments from the iGEM team of Cambrige, 2008. These pigments (violacein and lycopene) are produced strongly in e.coli and are visible by eye at even low optical densities. To test if our construct principally works, however, we will use GFP.
=== Death  ===
=== Death  ===
 +
To make sure no live GMO will get into the environment, the death of ''Bacillus'' should be reached:
# The extracellular nutrients are depleted.
# The extracellular nutrients are depleted.
# Color reporter builds to toxic levels.
# Color reporter builds to toxic levels.
 +
 +
== Construct ==
 +
The standard construct is a combination of biobricks.
 +
*Backbone:Available in registry: BBa_K090403 (Backbone) - Single copy shuttle vector. Other option: build our own well-characterized backbone for our chassis.
 +
* BBa_K116632+BBa_K116602 (Positive feedback loop) - Uses the pRe promoter regulated by C11 and terminated by B0010.  Other options: BBa_J37019;BBa_K116639; BBaK116609.
 +
* BBa_K274100 (Reporter) - Modified carotenoid pathway to produce red pigment.
 +
[[File:Groningen2012_JP_20120618_pRe-CII-Lycopene_Construct_A.png|680px|center]]
 +
* Or, using BBa_K274002 (Reporter) - Violet pigment producer
 +
[[File:Groningen2012_JP_20120618_pRe-CII-Violacein_Construct_A.png|680px|center]]
== Modeling-Labwork Cooperation ==
== Modeling-Labwork Cooperation ==
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The modeling team of one will provide to the lab:
The modeling team of one will provide to the lab:
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# Creation, and critical analysis, of the reaction pathway from literature.
+
# Creation, and critical analysis, of the reaction pathways from literature.
* Identification
* Identification
# of the metabolites necessary to support growth. (Done: D-Glucose, Water, Glutamine, Potassium)
# of the metabolites necessary to support growth. (Done: D-Glucose, Water, Glutamine, Potassium)
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## Superimpose curves with different starting medium concentration.
## Superimpose curves with different starting medium concentration.
## Indicate the points at which sporulation occurs.
## Indicate the points at which sporulation occurs.
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The lab will provide to the modeling team:
The lab will provide to the modeling team:
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== Limitations due to time constraints ==
== Limitations due to time constraints ==
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* Concept is proven at room temperature, can be extended to less than 7oC using the psychotrophic bacteria bacillus cereus.
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* We chose to make our construct at room temperature/ 37 degrees. If this project leads to a proof of concept, a psychrotrophic bacterium like ''Bacillus cereus'' could be used as a chassis instead of ''Bacillus subtilis''. This bacterium is however a much harder to engineer and, unlike ''Bacillus subtilis'' harmful.
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* Adaptation of the eukaryotic receptor TAAR5 to bacillus subtilis to sense amines is possible, but not within 3 months.
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== Standard Operating Protocols ==
== Standard Operating Protocols ==

Revision as of 14:15, 13 July 2012





Contents

Summary

Every year, 1.300.000.000 tons of food are thrown away worldwide. This is one third of the global food production. One of the reasons for this is the fact that best before dates are imprecise. A reliable way of monitoring whether food is spoiled or not, could save upto 600 euro per household per year.

Our goal is to build a system to sense meat spoilage. When a package of meat is saved after opening (1), a closed sticker containing Bacillus subtilis spores is activated by breaking the middle compartment (2,similar to activating a glow-in-the-dark stick), whereby Alanine, and water are mixed with the spores to cause ‘’germination’’ (3). When the germinated microbes come in contact with volatiles from rotting meat, a pathway is activated which results to the production of a ‘’pigment’’(4). When this happens, the consumer knows that he has to throw away the food (5). The different states of the volatile sensor are explained below.

Groningen2012 RR 20120713 paintpicture.png

States

Containment of Bacillus subtilis spores: the sticker

The spores of Bacillus subtilis will be contained in a compartment which is impermeable for bacteria and liquids, but can still let through volatiles. Metabolites, water and Alanine should be separated from the spores by a breakable membrane. Mixing these compounds will cause germination.

Germination

Alanine and water can trigger germination of Bacillus subtilis. The modeling team will provide information on the optimal concentrations for germination, and on the germination time.

Activation Pathways

We follow two different strategies to build a pathway in Bacillus subtilis which can react to the presence of rotten meat volatiles. One is using the TnrA pathway, which is normally expressed in absence of ammonium (reference). For the other strategy, we use a transcriptomics approach searching for promoters present in ‘’Bacillus’’ reacting to rotten meat volatiles.

First strategy: TnrA pathway

Pre-Activation

  1. The growth medium contains a low concentration of glutamine (gln), but no ammonia or ammonium (NH4).
  2. Glutamine synthetase (GS) is activated due to the inadequate level of glutamine, however, it cannot synthesize more gln as it is lacking NH4.
  3. The low intracellular gln level shifts the ratio of GS to feedback-inhibited GS (FBI-GS) towards a higher level of GS.
  4. This higher level of GS allows a higher level of TnrA.
  5. The TnrA represses the alsT promoter.

Activation

  1. Rotting meat produces NH4.
  2. NH4 is enters the cell through the NrgAB ammonium transporter.
  3. GS converts NH4 into gln.
  4. Gln reaches the concentration required for steady cell growth.
  5. The ratio of GS to FBI-GS shifts towards a higher level of FBI-GS.
  6. The newly created FBI-GS binds to TnrA, creating an inactive complex.
  7. TnrA is unable to repress the alsT promoter.
  8. No longer repressed, alsT activates along with its positive feedback loop containing the color reporter.

Second strategy: identification of “PBADmeat”

TnrA is a repressor/activator which acts on a broad level. This makes it a tricky candidate for triggering a single reaction. Therefore, an alternative strategy is needed.

To identify our rotten meat volatile reporter (short: PBADmeat), we performed an transcriptome analysis of Bacillus subtilis subjected to rotten meat (target) and to fresh meat (control) volatiles. Analysis of the differential expression between these two situations can lead to candidate promoters for our construct.

The technique: DNA Microarray MicroArrays are used to compare the expression of genes between two or more conditions.. At a certain growth fase, one isolates all mRNA (the transcriptome). Then the mRNA is copied into cDNA. The cDNA is tagged with a fluorescent dye, one condition red, the other green. Both conditions are then brought onto a MicroArray slide, where DNA of each gene of the organism of interest (in our case, Bacillus) is attached in separate wells (these are called “probes”). When the cDNA is brought onto the slide, it will hybridize with the probes. After fluorescence measurement, one will see a black dot when the gene is not transcribed in both conditions, an orange/yellow one when the gene is transcribed in both, and a green or red one when just one condition causes the transcription of the gene. The ratio of red/green will be a measure for differential expression.

Color reporter

As a reporter, we choose to use a pigment. The big advantage of using a pigment over another type of reporter (for instance, GFP or an electrical signal) is that it can be detected without any equipment. A big drawback however, is the production speed of pigments.

To make Bacillus subtilis produce more pigment, we plan to build in a positive feedback loop. Different feedback loops are available in the Registry of Standard Biological Parts (for instance PLux/LuxR and pRE/CII). We plan to characterize and - if necessary - improve one for our construct.

We will start with using the e.chromi pigments from the iGEM team of Cambrige, 2008. These pigments (violacein and lycopene) are produced strongly in e.coli and are visible by eye at even low optical densities. To test if our construct principally works, however, we will use GFP.

Death

To make sure no live GMO will get into the environment, the death of Bacillus should be reached:

  1. The extracellular nutrients are depleted.
  2. Color reporter builds to toxic levels.

Construct

The standard construct is a combination of biobricks.

  • Backbone:Available in registry: BBa_K090403 (Backbone) - Single copy shuttle vector. Other option: build our own well-characterized backbone for our chassis.
  • BBa_K116632+BBa_K116602 (Positive feedback loop) - Uses the pRe promoter regulated by C11 and terminated by B0010. Other options: BBa_J37019;BBa_K116639; BBaK116609.
  • BBa_K274100 (Reporter) - Modified carotenoid pathway to produce red pigment.
Groningen2012 JP 20120618 pRe-CII-Lycopene Construct A.png
  • Or, using BBa_K274002 (Reporter) - Violet pigment producer
Groningen2012 JP 20120618 pRe-CII-Violacein Construct A.png

Modeling-Labwork Cooperation

Unlike previous years, there is a direct link between theory and practice.

The modeling team of one will provide to the lab:

  1. Creation, and critical analysis, of the reaction pathways from literature.
  • Identification
  1. of the metabolites necessary to support growth. (Done: D-Glucose, Water, Glutamine, Potassium)
  2. of the metabolites required for the reporter.
  3. of the metabolites required for germination.
  4. of the conditions for sporulation.
  • Quantification
  1. Rates of nutrient consumption versus temperature and biomass.
  2. Amount of O2 required, and the corresponding volume of air.
  3. Plot of growth rate vs. temperature.
  4. Plot of biomass amount vs. time
    1. Superimpose curves with different starting medium concentration.
    2. Indicate the points at which sporulation occurs.

The lab will provide to the modeling team:

  1. TnrA concentration as a function of extracellular glutamine concentration.
  2. Growth rate as a function of extracellular glutamine concentration.
  3. Rates of volatile production as a function of meat type and volume.

Limitations due to time constraints

  • We chose to make our construct at room temperature/ 37 degrees. If this project leads to a proof of concept, a psychrotrophic bacterium like Bacillus cereus could be used as a chassis instead of Bacillus subtilis. This bacterium is however a much harder to engineer and, unlike Bacillus subtilis harmful.

Standard Operating Protocols

In an effort to apply business concepts to the iGEM project we have agreed to conduct the project according to the following protocols. The specifics of these sections (such as the actual protocols or equipment listing) are contained within the SOP binder in the laboratory. This binder will be digitized for next year’s iGEM teams.

General

  1. How to set up an experiment.
    • Fully describe the experiment in a document before it is scheduled to be performed (document is described in point 2).
    • After the experiment is documented, it should be reviewed by at least one other iGEM member.
    • Upon completion of the experiment there should be a short discussion/interpretation of the results and a short outlook for subsequent experiments.
  2. Experiment Template
    • Insert outline of the template here
  3. Acronyms.
    • Each iGEM member is assigned an acronym: e.g. Marius Uebel will be MU.
  4. Data management.
    • Each filename should contain the original creator, date, and type of file. E.g. MU_20120412_igem12_sop_proposal.doc
  5. Ordering of material.
    • A single person should be responsible for ordering, this prevents multiple orders of an item and a more controlled inventory.

Lab Equipment and Materials

  1. Equipment.
    • Every piece of lab equipment should be accompanied by the manufacturer’s manual and a short how-to manual.
    • Overview and location of all our equipment should be written down in this part
  2. Protocols
    • All lab protocols should be consolidated into a central location in the lab in print form.

Methodology

  1. Culture
    • Contains general information and cultivation requirements of the chassis
  2. Assay
    • Short overview of any assay kits changes undertaken to suit the actual experiment.
    • All information on original assays