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Team:Sumbawagen/project/econey
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| - | < | + | <h3>ECONEY Project</h3> |
| - | + | <h2>Catabolite Repression Phenomenon</h2> | |
| + | <center><img src="https://static.igem.org/mediawiki/2014/0/07/Sumbawagen_catabolite_r.png"/><br></center> | ||
<p>There is a unique phenomenon of E.coli activity called “Catabolite Repression”. Catabolite repression is a type of positive control of transcription, since a regulatory protein affects an increase (upregulation) in the rate of transcription of an operon. The process was discovered in E. coli and was originally referred to as the glucose effect because it was found that glucose repressed the synthesis of certain inducible enzymes, even though the inducer of the pathway was present in the environment. </p> | <p>There is a unique phenomenon of E.coli activity called “Catabolite Repression”. Catabolite repression is a type of positive control of transcription, since a regulatory protein affects an increase (upregulation) in the rate of transcription of an operon. The process was discovered in E. coli and was originally referred to as the glucose effect because it was found that glucose repressed the synthesis of certain inducible enzymes, even though the inducer of the pathway was present in the environment. </p> | ||
| - | <p>Glucose is known to repress a large number of inducible enzymes in many | + | <p>Glucose is known to repress a large number of inducible enzymes in many differents bacteria. Glucose represses the induction of inducible operons by inhibiting the synthesis of cyclic AMP (cAMP), a nucleotide that is required for the initiation of transcription of a large number of inducible enzyme systems.</p> |
| - | <p>The role of cyclic a cAMP is complicated. cAMP is required to activate an allosteric protein called CAP (catabolite activator protein) which binds to the promoter CAP site and stimulates the binding of | + | <p>The role of cyclic a cAMP is complicated. cAMP is required to activate an allosteric protein called CAP (catabolite activator protein) which binds to the promoter CAP site and stimulates the binding of RNA polymerase to the promoter for the initiation of transcription. In the presence of glucose, cAMP levels are low, and transcription does not occur. In the absence of glucose, cAMP levels are high, CAP is activated by cAMP, and transcription occurs (in the presence of lactose).<br> |
| - | <h2> | + | <h2>Plasmid BBA_J04450</h2> |
| - | <p> We found plasmid BBa_J04450 in iGEM Parts Registry that works | + | <center><img src="https://static.igem.org/mediawiki/2014/4/41/Sumbawagen_econeyred_p.png"/><br></center> |
| - | <p> | + | <p> We found plasmid BBa_J04450 in iGEM Parts Registry that works based on catabolite repression theory. This plasmid consists of lactose promoter, ribosome binding site, mutant red fluorescent protein gene or mRFP gene and terminator. The LacI promoter works in the presence of lactose, resulting red color in bacteria from mRFP gene expression. Unfortunately, the expression of mRFP gene decreases in the prescence of glucose, resulting yellow color in the bacteria. We use this plasmid to measure glucose concentration.</p> |
| - | <p> We add 2 new circuits behind plasmid BBa_J04450. The first circuit consists of constitutive promoter, RBS, | + | |
| + | <h2>Constructing Econey</h2> | ||
| + | <p> We faced a problem that in high glucose concentration, the red color from mRFP gene expression goes dimer, while we want the device to express brighter red color in high glucose concentration. Thus, we modified the system by changing sensitivity of catabolite repression in order to make the system has ability to express red color in high glucose concentration. </p> | ||
| + | <p> We add 2 new circuits behind plasmid BBa_J04450. The first circuit consists of constitutive promoter, RBS, adenylate cyclase (AC) gene, and a terminator. The second circuit consists of constitutive promoter, RBS, IIA(Glc) gene, and a terminator.</p> | ||
<h2>ECONEY CIRCUITS</h2> | <h2>ECONEY CIRCUITS</h2> | ||
<p>Our ECONEY consists of 2 circuits.</p> | <p>Our ECONEY consists of 2 circuits.</p> | ||
<strong>Circuit #1</strong> | <strong>Circuit #1</strong> | ||
| - | <p>Circuit #1 consists of plasmid BBa_J04450 followed by a new circuit that consist of constitutive promoter, RBS, | + | <center><img src="https://static.igem.org/mediawiki/2014/2/29/Sbgen.sir1.png"/><br></center> |
| + | <p>Circuit #1 consists of plasmid BBa_J04450 followed by a new circuit that consist of constitutive promoter, RBS, CyaA gene, and a terminator. CyaA gene is controlled by constitutive promoter and located downstream of ECONEY Basic Circuit. Adenylate cyclase synthesize cAMP. Thus in high concentration of glucose, lac promoter may still active.</p><br> | ||
<strong>Circuit #2</strong> | <strong>Circuit #2</strong> | ||
| - | <p>Circuit #2 consists of plasmid BBa_J04450 followed by a new circuit that consist of constitutive promoter, RBS, | + | <center><img src="https://static.igem.org/mediawiki/2014/5/56/Sbgen.sir2.png"/><br></center> |
| + | <p>Circuit #2 consists of plasmid BBa_J04450 followed by a new circuit that consist of constitutive promoter, RBS, crr gene, and a terminator. Crr gene is also controlled by constitutive promoter and located downstream of ECONEY Basic Circuit. EIIA or IIAGlc in the PTS pathway helps glucose enter the cell. Thus in LOW concentration of glucose, lac promoter may already be repressed.</p> | ||
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<!-- Title --> | <!-- Title --> | ||
Latest revision as of 08:00, 19 February 2015
Team:Sumbawagen/Team
From 2014.igem.org
ECONEY Project
Catabolite Repression Phenomenon
There is a unique phenomenon of E.coli activity called “Catabolite Repression”. Catabolite repression is a type of positive control of transcription, since a regulatory protein affects an increase (upregulation) in the rate of transcription of an operon. The process was discovered in E. coli and was originally referred to as the glucose effect because it was found that glucose repressed the synthesis of certain inducible enzymes, even though the inducer of the pathway was present in the environment.
Glucose is known to repress a large number of inducible enzymes in many differents bacteria. Glucose represses the induction of inducible operons by inhibiting the synthesis of cyclic AMP (cAMP), a nucleotide that is required for the initiation of transcription of a large number of inducible enzyme systems.
The role of cyclic a cAMP is complicated. cAMP is required to activate an allosteric protein called CAP (catabolite activator protein) which binds to the promoter CAP site and stimulates the binding of RNA polymerase to the promoter for the initiation of transcription. In the presence of glucose, cAMP levels are low, and transcription does not occur. In the absence of glucose, cAMP levels are high, CAP is activated by cAMP, and transcription occurs (in the presence of lactose).
Plasmid BBA_J04450
We found plasmid BBa_J04450 in iGEM Parts Registry that works based on catabolite repression theory. This plasmid consists of lactose promoter, ribosome binding site, mutant red fluorescent protein gene or mRFP gene and terminator. The LacI promoter works in the presence of lactose, resulting red color in bacteria from mRFP gene expression. Unfortunately, the expression of mRFP gene decreases in the prescence of glucose, resulting yellow color in the bacteria. We use this plasmid to measure glucose concentration.
Constructing Econey
We faced a problem that in high glucose concentration, the red color from mRFP gene expression goes dimer, while we want the device to express brighter red color in high glucose concentration. Thus, we modified the system by changing sensitivity of catabolite repression in order to make the system has ability to express red color in high glucose concentration.
We add 2 new circuits behind plasmid BBa_J04450. The first circuit consists of constitutive promoter, RBS, adenylate cyclase (AC) gene, and a terminator. The second circuit consists of constitutive promoter, RBS, IIA(Glc) gene, and a terminator.
ECONEY CIRCUITS
Our ECONEY consists of 2 circuits.
Circuit #1
Circuit #1 consists of plasmid BBa_J04450 followed by a new circuit that consist of constitutive promoter, RBS, CyaA gene, and a terminator. CyaA gene is controlled by constitutive promoter and located downstream of ECONEY Basic Circuit. Adenylate cyclase synthesize cAMP. Thus in high concentration of glucose, lac promoter may still active.
Circuit #2
Circuit #2 consists of plasmid BBa_J04450 followed by a new circuit that consist of constitutive promoter, RBS, crr gene, and a terminator. Crr gene is also controlled by constitutive promoter and located downstream of ECONEY Basic Circuit. EIIA or IIAGlc in the PTS pathway helps glucose enter the cell. Thus in LOW concentration of glucose, lac promoter may already be repressed.
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