Difference between revisions of "Team:Heidelberg/Cytochrome Engineering"
| Line 52: | Line 52: | ||
<h1>Experimental procedures</h1> | <h1>Experimental procedures</h1> | ||
<h2>Testing CYP1A2`s activity</h2> | <h2>Testing CYP1A2`s activity</h2> | ||
| − | Before we could start to evolve the CYP1A2 we first checked whether the enzyme can be expressed in its functional tertiary structure in our E.coli strain. CYP1A2 requires a heme group as cofactor which coordinates iron ions, a fast test using sodium dithionite can be conducted to proof whether the CYP1A2 is properly folded. Thereby sodium dithionite acts as a reducing agent and can be used to quantitatively detect iron ions in aqueous solutions. When sodium dithionite is added to the cell lysate of E.coli cells expressing CYP1A2 and the corresponding chaperone protein HDJ-1 a color change can be detected even by the eye. Further OD measurement at 550 nm will show a peak, indicating the reduction of iron ions by sodium dithionite <x-ref>kan2016directed</x-ref>. | + | Before we could start to evolve the CYP1A2 we first checked whether the enzyme can be expressed in its functional tertiary structure in our E.coli strain. CYP1A2 requires a heme group as cofactor which coordinates iron ions, a fast test using sodium dithionite can be conducted to proof whether the CYP1A2 is properly folded. Thereby sodium dithionite acts as a reducing agent and can be used to quantitatively detect iron ions in aqueous solutions. When sodium dithionite is added to the cell lysate of E.coli cells expressing CYP1A2 and the corresponding chaperone protein HDJ-1 a color change can be detected even by the eye. Further OD measurement at 550 nm will show a peak, indicating the reduction of iron ions by sodium dithionite <x-ref>kan2016directed</x-ref>. <br> }} |
{{Heidelberg/templateus/Imagebox|https://static.igem.org/mediawiki/2017/thumb/2/2d/T--Heidelberg--Team_Heidelberg_2017_CYP_dithinide_geschnitten_MK.png/139px-T--Heidelberg--Team_Heidelberg_2017_CYP_dithinide_geschnitten_MK.png| | {{Heidelberg/templateus/Imagebox|https://static.igem.org/mediawiki/2017/thumb/2/2d/T--Heidelberg--Team_Heidelberg_2017_CYP_dithinide_geschnitten_MK.png/139px-T--Heidelberg--Team_Heidelberg_2017_CYP_dithinide_geschnitten_MK.png| | ||
Figue 4: Test of CYP1A2 conformation by sodium dithionite| | Figue 4: Test of CYP1A2 conformation by sodium dithionite| | ||
After the addition of sodium dithionite to the E.coli cell lysate (expressing CYP1A2) a color change could be detected as the solution turned darker/brown. |pos = right | After the addition of sodium dithionite to the E.coli cell lysate (expressing CYP1A2) a color change could be detected as the solution turned darker/brown. |pos = right | ||
}} | }} | ||
| − | + | }} | |
{{Heidelberg/templateus/Contentsection| | {{Heidelberg/templateus/Contentsection| | ||
Revision as of 19:35, 1 November 2017
Cytochrome Engineering
Modulating CYP1A2 product specifity
Introduction
Enzymes, i.e. proteins mediating specific, catalytic functions, are amongst the most powerful molecular machines invented by nature. Since decades, humans utilize naturally occurring enzymes as bio detergents (e.g. in washing powderThe engineering of novel enzymes catalyzing reactions that do not or only inefficiently occur in nature holds great promise for biotechnological production of regenerative fuel, biomaterials and novel pharmaceuticals, e.g. based on Organosilicons. However, so far, enzyme engineering has typically been a time-consuming, elaborate, expensive and inefficient process, usually requiring laborious, iterative trial-and-error optimization of engineered candidates
To accelerate the development of novel enzymes, our team harnessed the engineering strategy nature uses: Evolution.
Figure 1: Selection process for improved CYP1A2 variants in directed evolution experiments
The evolutionary circle starts by M13 phages injecting their genome (SP) into bacterial cells, already containing two additional plasmids, AP and MP. The SP encodes CYP1A2 among genes (except geneIII) that are crucial for phage propagation. If through MP activation mutations in the CYP1A2 gene lead to improved CYP1A2 variants the intracellular level of theophylline increases. Theophylline molecules activate the theophylline riboswitch on the AP and thereby enhance geneIII expression. The assembled phages containing the improved CYP1A2 variant can leave the cell and propagate by infecting new cells.
Background
The human Cytochrome CYP1A2 is an example of a heme-dependent-thiolate monooxygenase, member of the P450 superfamily and plays an important role in the metabolism of many structurally unrelated substrates. Primarily the CYP1A2 is located in the endoplasmic reticulum of liver cells. It is of great interest as it is involved in the oxidative metabolism of many commonly used therapeutics and xenobiotics
Figue 2: Chemical structure of caffeine
Caffeine is a substrate of CYP1A2 perera2010caffeine .
Figue 3: Chemical structures of Paraxanthine, Theobromine and Theophylline
By N3 demethylation caffeine is metabolized into these three xanthine derivates by CYP1A2 perera2010caffeine .
Design of evolution circuit
Our evolution circuit for cytochrome engineering works as follows: Bacteriophages infect bacterial cells by introducing their genome. The genome encodes a Selection Plasmid (SP) that contains the human CYP1A2 variant and all necessary components for virus propagation except geneIII. The Accessory Plasmid (AP) codes for geneIII driven by a Psp-tet promoter and contains a riboswitch, located between the promoter and geneIII, which regulates the expression rate of geneIII. The riboswitch on the AP is only active if theophylline reaches a certain concentration within the bacterium. If CYP1A2 is active, caffeine is converted to theophylline and thereby increases the theophylline concentration. Additionally, the AP encodes for the chaperone HDJ-1, which is essential to receive the functional CYP1A2 enzyme (Fig.1).Experimental procedures
Testing CYP1A2`s activity
Before we could start to evolve the CYP1A2 we first checked whether the enzyme can be expressed in its functional tertiary structure in our E.coli strain. CYP1A2 requires a heme group as cofactor which coordinates iron ions, a fast test using sodium dithionite can be conducted to proof whether the CYP1A2 is properly folded. Thereby sodium dithionite acts as a reducing agent and can be used to quantitatively detect iron ions in aqueous solutions. When sodium dithionite is added to the cell lysate of E.coli cells expressing CYP1A2 and the corresponding chaperone protein HDJ-1 a color change can be detected even by the eye. Further OD measurement at 550 nm will show a peak, indicating the reduction of iron ions by sodium dithionite
Figue 4: Test of CYP1A2 conformation by sodium dithionite
After the addition of sodium dithionite to the E.coli cell lysate (expressing CYP1A2) a color change could be detected as the solution turned darker/brown.
Optimized PREDCEL Workflow
In general the PREDCEL protocol is followed as described in the PREDCEL Protocol. After the culture is grown to OD600 of 0.6 and the MP is activated by exchanging the initial medium containing glucose (repressing the MP) by medium containing arabinose, an 3 hour inoculation with phages takes place until the phage supernatant is transferred for the first time. After three rounds of passaging, the obtained phage supernatant is used to infect another E.coli strain, ensuring fast propagation of phages without selection pressure over night. Thereby phage wash out can be prevented and a sufficient phage titer can be generated for the inoculation of next PREDCEL culture. This is repeated after the next three rounds of selection are completed (Fig. 5).
Figue 1: title
gigure x with explanation of plaque assays
