Team:TU Delft/Project/sensing/parts

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(Catabolite repression control)
(Catabolite repression control)
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==Catabolite repression control==
==Catabolite repression control==
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[[Image:TUDelft_alkS.png|thumb|400px|right|'''Figure 1''' - AlkS Hydrocarbon Regulatory systems from ''Psuesomonas putida'' (F. Rojo, et al. 2009)]]
BioBrick: PalkS12-RBS-CFP-TT-PalkB-GFP-TT
BioBrick: PalkS12-RBS-CFP-TT-PalkB-GFP-TT
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[[Image:TUDelft_alkS.png|thumb|400px|right|'''Figure 1''' - AlkS Hydrocarbon Regulatory systems from ''Psuesomonas putida'' (F. Rojo, et al. 2009)]]
 
In ''Pseudomonas putida'', the AlkS transcriptional regulator activates the expression of its own gene, and that of alkT, from a promoter named PalkS2 in the presence of alkanes. This allows achieving AlkS levels that are high enough to activate the expression of the alkBFGHJKL operon from the PalkB promoter. AlkS recognizes C5–C10 n-alkanes as effectors, but does not respond to shorter or larger alkanes (Rojo et al. 2009) (fig.1)
In ''Pseudomonas putida'', the AlkS transcriptional regulator activates the expression of its own gene, and that of alkT, from a promoter named PalkS2 in the presence of alkanes. This allows achieving AlkS levels that are high enough to activate the expression of the alkBFGHJKL operon from the PalkB promoter. AlkS recognizes C5–C10 n-alkanes as effectors, but does not respond to shorter or larger alkanes (Rojo et al. 2009) (fig.1)

Revision as of 11:34, 12 September 2010

Making of BioBricks

Catabolite repression control

Figure 1 - AlkS Hydrocarbon Regulatory systems from Psuesomonas putida (F. Rojo, et al. 2009)

BioBrick: PalkS12-RBS-CFP-TT-PalkB-GFP-TT

In Pseudomonas putida, the AlkS transcriptional regulator activates the expression of its own gene, and that of alkT, from a promoter named PalkS2 in the presence of alkanes. This allows achieving AlkS levels that are high enough to activate the expression of the alkBFGHJKL operon from the PalkB promoter. AlkS recognizes C5–C10 n-alkanes as effectors, but does not respond to shorter or larger alkanes (Rojo et al. 2009) (fig.1)

In stead of using all the alkBFGHJKL genes, a GFP will be introduced into our system to check the functionality of the PalkB promoter in E.coli.

Therefore, the first construct is suitable for the analysis of transcriptional activity over the PalkS promoter. A plasmid containing the AlkS-PalkS-PalkB regulatory mechanism will be coupled to GFP and RFP generators in order to determine transcriptional activities of PalkS and PalkB at varying hydrocarbon concentrations by measuring fluorescence.

Control by Crp

BioBrick: P(Caif)-RBS-AlkS-TT-PalkB-GFP-TT

The expression of alkane degrading genes in our second E.coli regulatory system will be regulated by making the alkane-degrading genes sensitive to Crp. The global regulator protein Crp binds to regions of promoters known to activate genes involved in the degradation of non-glucose carbon sources, in this way activating the genes downstream of it.

For the induction of alkane-degradation genes in this construct the BioBrick consisted out of the P(CaiF) promoter, AlkS gene and PalkB gene.