Team:Copenhagen/Project/Fungus

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<strong>Cytochrome p450 CYP 79 - the source of CyperMans fungus destroying power</strong>
 
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<b>Background information:</b>
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<b><center>The source of CyperMans <br><br>fungus destroying power</center></b></font>
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It has been proposed in the article Dynamic Metabolons [5] that the assembly and disassembly of enzymes complexes, so-called metabolons, may differentiate plant defense responses to insect attack and fungal infection.
 
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The two CYP79 and CYP71 subfamilies are part of a metabolon complex that shifts between assembly and disassembly, according to interactions with proteins or from specific metabolic demands. The CYP79 subfamily can by itself produce a substance called 4-hydroxyphenyl-acetaldeyde oxime. This substance is generally toxic to fungi and frequently used as chemical fungicides. They function by inhibiting mitochondrial oxidases and thereby promote lipid peroxidation and the production of toxic reactive oxygen species[5].
 
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The CYP79A1 uses L-Tyrosine as a substrate, which it hydroxylates twice on the amino-group in the presence of NADPH and O2. The products of these reactions are quite unstable and dehydration and decarboxylation will then produce 4-hydroxyphenyl-acetaldeyde oxime. [6] The CYP79B1 isoform is specific for tryptophan and therefore it produces indole 3-acetaldoxime instead, while A2 uses phenylalanine and produces phenylacetaldoxime.
 
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<b><center>Cytochrome p450 CYP 79</center></b></font>
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<b>The Project</b><br>
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The main goal is to standardize different plant CYP79s (A1, A2 and B1) and deliver them as BioBricks to iGEM.
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<b>Indtroduction </b><br>
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The plant cytochrome p450 79 are the crucial starting point in the conversion of aminoacids into cyanogenic glycosides important for defense mechanisms in plants.
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In this biosynthetic pathway the CYP79s and the CYP71 subfamilies are part of a enzyme complex – a so-called metabolon. It has been proposed in the article Dynamic Metabolons [5] that the assembly and disassembly of the metabolons, may differentiate plant defense responses to insect attack and fungal infection (Figure).
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<table class="https://static.igem.org/mediawiki/2011/7/7a/Model_metabolon.JPG" align="right">
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When isolated, the CYP79 subfamily will produce an intermediate in the biosynthetic pathway, a substance called an oxime. This substance is generally toxic to fungi and is frequently used as chemical fungicides. They function by inhibiting mitochondrial oxidases and thereby promote lipid peroxidation and the production of toxic reactive oxygen species[5].
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We will investigate following CYP79s: A1, A2 and B1.The CYP79A1 uses L-Tyrosine as a substrate, which it hydroxylates twice on the amino-group in the presence of NADPH and O2. The products of these reactions are quite unstable and dehydration and decarboxylation will then produce 4-hydroxyphenyl-acetaldehyde oxime. [6] The CYP79B1 isoform is specific for tryptophan and therefore it produces indole 3-acetaldoxime instead, while A2 uses phenylalanine and produces phenylacetaldoxime.
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<b>Experimental design</b><br>
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We will utilize our self-made standardized CYP79s in a biological system consisting of an IPTG inducible promoter, a RBS and a double terminator in a vector, all BioBricks characterized in the partsregistry.org. This system will enable us to control the expression of the given CYP, only being synthesized when IPTG is added.
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The objective is now to express the different plant CYP79s in E.coli, to determine whether they actually can be expressed as working proteins in them. This expression will be documented on a Western blot. If/When the CYPs are expressed; we will make membrane preparations in which the CYP should be embedded. This enables us to utilize the enzymatic activity of the CYP79s to convert aminoacids to oximes by hydroxylation, showed as a band on a TLC plate. 
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The production of oximes is a key step in our project. If we produce the oximes, we would verify that the disassembly of the plant’s metabolons consisting of CYP79s could lead to production of oximes, which wouldn’t be further converted to cyanogenic glycosides. This would be a proof of the concept, that disassembly of CYP metabolons in plants, functions as a switch from the defense against insects to the defense against fungal infection.
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<b>Ecological and economical prospects</b><br>
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The future perspective with our project is to study the use of this oxime producing agent.
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<u>CyperMan protecting wood:</u>
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<b>The Project: </b><br>
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One important feature is to determine whether it would be a viable solution to use an oxime producing agent as a type of fungicide. Here one of our ideas is to use of our CyperMan in wood protection. Oximes are already used in wood preservatives and paints to protect the wood from fungus and algae. The oximes in use are butanaldoximes, but the oximes produced by CyperMan should have the same effects. The idea is to paint the wood with our CyperMan. By having the CYP under an inducible promoter, induced by a cheap and accessible compound such as salt water, we could provide a cheap and easy way to protect wood without having to use chemical paint.  
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Our goal is to express different CYP79’s (more specifically from the subfamilies A1, A2 and B1) in E. Coli, to determine whether they can actually be expressed as working proteins in them. Then our idea is introduce a promoter to the system, which reacts to a specific chemical signal that is sent out by fungi.
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<u>Ecological and economical prospects:</u>
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Another use of our CyperMan could be in the industrial synthesis of oximes, thus using the modified bacteria as a factory to synthesize oximes for use in e.g paint and wood. One idea could be to spray the purifed oximes on the wood, where it would kill fungus and algae. This would be very favorable solution since the hydroxylation reactions carried out by the P450 are difficult to perform using conventional organic synthesis. 
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Our future aim with our project is to determine whether it would be a viable solution to use an oxime producing agent as a type of fungicide. The best scenario would be if the plants themselves was able to produce the oximes and thus protect themselves and eliminating the need for fungicides.   
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<u>CyperMan protecting plants:</u>
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Another use of CyperMan could be in wood protection. Oximes are already used in wood preservatives and paints to protect the wood from fungus and algae. The oximes in use are butanaldoximes, but the oximes produced by CyperMan should have the same effects. By having the cyp under a inducible promoter, induced by a cheap and accesseble compound such as salt water, we could provide a cheap and easy way to protect wood without having to use chemical paint.
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CyperMan could be the solution to the problem with pests destroying our farmlands. The idea is to express the CYP79 in plants, but only when harmful fungi are present. A thought is to introduce a promoter to the system, which reacts to a specific chemical signal sent out by fungi. This will enable the plants themselves to produce the oximes and thus protect themselves, subsequently eliminating the need for fungicides. Another dimension to this idea could be to make the expression of the CYP tissuespecific, thus limiting the release of oximes to beneficial fungi. One example is to target fungi attacking plant leaves by only expressing CYP79 in this area.
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You could use the bacteria for oxime production and spray it on the wood, where it would kill fungus and algae.
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Latest revision as of 13:12, 24 August 2011



The source of CyperMans

fungus destroying power



Cytochrome p450 CYP 79
The Project

The main goal is to standardize different plant CYP79s (A1, A2 and B1) and deliver them as BioBricks to iGEM.

Indtroduction

The plant cytochrome p450 79 are the crucial starting point in the conversion of aminoacids into cyanogenic glycosides important for defense mechanisms in plants. In this biosynthetic pathway the CYP79s and the CYP71 subfamilies are part of a enzyme complex – a so-called metabolon. It has been proposed in the article Dynamic Metabolons [5] that the assembly and disassembly of the metabolons, may differentiate plant defense responses to insect attack and fungal infection (Figure).

When isolated, the CYP79 subfamily will produce an intermediate in the biosynthetic pathway, a substance called an oxime. This substance is generally toxic to fungi and is frequently used as chemical fungicides. They function by inhibiting mitochondrial oxidases and thereby promote lipid peroxidation and the production of toxic reactive oxygen species[5].

We will investigate following CYP79s: A1, A2 and B1.The CYP79A1 uses L-Tyrosine as a substrate, which it hydroxylates twice on the amino-group in the presence of NADPH and O2. The products of these reactions are quite unstable and dehydration and decarboxylation will then produce 4-hydroxyphenyl-acetaldehyde oxime. [6] The CYP79B1 isoform is specific for tryptophan and therefore it produces indole 3-acetaldoxime instead, while A2 uses phenylalanine and produces phenylacetaldoxime.

Experimental design

We will utilize our self-made standardized CYP79s in a biological system consisting of an IPTG inducible promoter, a RBS and a double terminator in a vector, all BioBricks characterized in the partsregistry.org. This system will enable us to control the expression of the given CYP, only being synthesized when IPTG is added.

The objective is now to express the different plant CYP79s in E.coli, to determine whether they actually can be expressed as working proteins in them. This expression will be documented on a Western blot. If/When the CYPs are expressed; we will make membrane preparations in which the CYP should be embedded. This enables us to utilize the enzymatic activity of the CYP79s to convert aminoacids to oximes by hydroxylation, showed as a band on a TLC plate.

The production of oximes is a key step in our project. If we produce the oximes, we would verify that the disassembly of the plant’s metabolons consisting of CYP79s could lead to production of oximes, which wouldn’t be further converted to cyanogenic glycosides. This would be a proof of the concept, that disassembly of CYP metabolons in plants, functions as a switch from the defense against insects to the defense against fungal infection.

Ecological and economical prospects

The future perspective with our project is to study the use of this oxime producing agent.

CyperMan protecting wood:

One important feature is to determine whether it would be a viable solution to use an oxime producing agent as a type of fungicide. Here one of our ideas is to use of our CyperMan in wood protection. Oximes are already used in wood preservatives and paints to protect the wood from fungus and algae. The oximes in use are butanaldoximes, but the oximes produced by CyperMan should have the same effects. The idea is to paint the wood with our CyperMan. By having the CYP under an inducible promoter, induced by a cheap and accessible compound such as salt water, we could provide a cheap and easy way to protect wood without having to use chemical paint.

Another use of our CyperMan could be in the industrial synthesis of oximes, thus using the modified bacteria as a factory to synthesize oximes for use in e.g paint and wood. One idea could be to spray the purifed oximes on the wood, where it would kill fungus and algae. This would be very favorable solution since the hydroxylation reactions carried out by the P450 are difficult to perform using conventional organic synthesis.

CyperMan protecting plants:

CyperMan could be the solution to the problem with pests destroying our farmlands. The idea is to express the CYP79 in plants, but only when harmful fungi are present. A thought is to introduce a promoter to the system, which reacts to a specific chemical signal sent out by fungi. This will enable the plants themselves to produce the oximes and thus protect themselves, subsequently eliminating the need for fungicides. Another dimension to this idea could be to make the expression of the CYP tissuespecific, thus limiting the release of oximes to beneficial fungi. One example is to target fungi attacking plant leaves by only expressing CYP79 in this area.

References
[5]Moller, B. L. (2010) Plant science. Dynamic metabolons, Science 330, 1328-1329.
[6]Koch, B. M., Sibbesen, O., Halkier, B. A., Svendsen, I., and Moller, B. L. (1995) The primary sequence of cytochrome P450tyr, the multifunctional N-hydroxylase catalyzing the conversion of L-tyrosine to p-hydroxyphenylacetaldehyde oxime in the biosynthesis of the cyanogenic glucoside dhurrin in Sorghum bicolor (L.) Moench, Arch Biochem Biophys 323, 177-186.

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