Team:Paris Bettencourt/Project/TMAU

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<div id="topheader"><a class=playlist id=link href="https://www.youtube.com/watch?v=fmrlEKFcXPY" target="_blank"><img src="https://static.igem.org/mediawiki/2014/0/05/Playlistpb.png">&nbsp;&nbsp;Something Fishy</a>
<img src="https://static.igem.org/mediawiki/2014/b/b9/Somethingfishy.png" class=nameimg>
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<td><b>BACKGROUND</b></br><br>
<td><b>BACKGROUND</b></br><br>
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<p class=text1>Trimethylaminuria (TMAU) commonly called Fish Odor Syndrom, is a rare genetic disease; trimethylamine (TMA) is naturally produces in the gut by the intestinal flora but it supposed to be degraded in the liver by the FMO3 enzyme coded by a gene with the same name. The suffering patients have a mutated FMO3 gene, and TMA is excreted in sweat, saliva and urine, causing a strong fish odor. </p></td>
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<p class=text1>Trimethylaminuria (TMAU), or Fish Odor Syndrome, is a rare genetic disease caused by inactivating mutations in the <i>FMO3</i> gene. Consequently, trimethylamine (TMA) accumulates in sweat, saliva, and urine, causing a strong fish odor. Patients suffer no other serious symptoms, except a difficult social condition.</p></td>
<td><b>AIMS</b></br><br>
<td><b>AIMS</b></br><br>
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<p class=text1><i>tmm</i> (trimethylamine monooxygenase) gene is a bacterial gene found in the bacteria <i>Ruegeria pomeroyi</i> and is similar to the human <i>FMO3</i> gene. The aim of this project is to clone <i>tmm</i> into <i>Corynebacterium striatum</i>, a bacteria of the skin, and to incorporate the new strain in a probiotic cosmetic in order to cure fish odor.</p></td>
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<p class=text1> TMA is also processed by the trimethylamine monooxygenase (TMM) of <i>Ruegeria pomeroyi</i>, an enzyme similar to human <i>FMO3</i>. Expressing this enzyme in human skin bacteria should remove trimethylamine from sweat and reduce its unpleasant odor. TMM-expressing bacteria in a cream or spray could be a cheap and stable way to deliver the therapeutic enzyme to TMAU patients.</p></td>
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<td><b>RESULTS</b></br><br>
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<td><b>ACHIEVEMENTS</b></br><br>
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<p class=text1><ul id=alignliste>
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<td><b>BIOBRICKS</b></br><br>
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<li>Cloned <i>TMM</i> into <i>E.coli</i> using pSB1C3 and pSEVA315 vectors, creating a new Biobrick: BBa_K1403015.</li>
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<li>Characterized and quantified the activity of TMM by a colorimetric assay.</li>
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<li>Confirmed the degradation of trimethylamine by GC/MS.
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<td><a href="#intro">Introduction</a></td>
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<td><a href="#aims">Aims</a></td>
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<td><a href="#part1">Introduction</a></td>
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<td><a href="#">Part3</a></td>
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<td><a href="#part2">Results</a></td>
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<td><a href="#results">Part4</a></td>
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<td><a href="#part3">Methods</a></td>
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<td><a href="#motivation">Part5</a></td>
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<p class=text2><img src='https://static.igem.org/mediawiki/2014/5/58/Figure1-TMMPB_.png' width='400px'></br><b>Figure 1. Trimethylamine production and degradation in the human body.</b></br>
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(A) In humans, choline is converted into trimethylamine and acetaldehyde by the gut bacteria <i>Desulfovibrio desulfuricans</i>.</br>
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(B) Trimethylamine is degraded in the liver into trimethylamine-N-oxyde by FMO3 (flavin-containing mono oxygenase 3).</br>
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(C) Mutations in the <i>FMO3</i> gene can cause the loss of the function of the enzyme. In these patients, trimethylamine is excreted into sweat, urine and breath, causing a strong fish odor.</p>
<h6>Introduction</h6><br>
<h6>Introduction</h6><br>
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<p>Trimethylamine (TMA) is produced in the intestine by <i>Desulfovibrio desulfuricans</i> thanks to the fermentation of choline. In healthy patients, the FMO3 gene allows the degradation of TMA in the liver into a non-volatile compound, TMA oxide. But a mutation in the FMO3 sequence is most of the time the cause of TMAU: TMA is not degraded and is then excreted in sweat, saliva and urine leading to a strong fish odor. The patients are otherwise healthy but the disease affect their social relationships and can lead to depression. There is no cure for this metabolic disorder but some treatments, often based on avoiding some sorts of food, tend to lower the symptoms.</p>
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<p class=text1>Trimethylamine (TMA) is a volatile compound smelling strongly of spoiled fish. It is produced during human digestion when choline, a B-complex vitamin, is fermented by gut bacteria (<a href="https://2014.igem.org/Team:Paris_Bettencourt/Bibliograpy">Craciun, S. <i>et al.</i>, 2012</a>) (Fig. 1A). Normally it proceeds to the liver where it is oxidized by FMO3, a flavin-containing monooxygenase (Fig. 1B). The product of FMO3 is trimethylamine oxide (TMAO), which is odorless.</br></br>
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<img src='https://static.igem.org/mediawiki/2014/b/b3/Sch%C3%A9ma_fish_odor_syndrom.jpg'>
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Trimethylaminuria (TMAU), or fish odor syndrome, is a rare genetic disorder in which patients are not able to fully oxidize TMA. TMAO is an autosomal recessive disorder, requiring two nonfunctional alleles of the FMO3 gene. More than 30 known mutations can inactivate FMO3, and inactive alleles have an estimated 0.1-1% global frequency (<a href="https://2014.igem.org/Team:Paris_Bettencourt/Bibliograpy">Mitchell, S.C <i>et al.</i>, 2001</a>). TMAU currently has no cure.</br></br>
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We propose that TMAU could be treated with a genetically modified skin bacteria. The trimethylamine monooxygenase (TMM) of <i>Ruegeria pomeroyi</i> also oxdizes TMA to TMAO (<a href="https://2014.igem.org/Team:Paris_Bettencourt/Bibliograpy">Chen, Y. <i>et al.</i>, 2011</a>). Applying this enzyme to the skin should eliminate TMA in sweat and, therefore, unpleasant odor. Expression in a bacterium of the skin microbiome could be a cheap and stable way to deliver the therapeutic enzyme. Here we present the expression and characterization of TMM in <i>E. coli</i> and <i>Corynebacterium striatum</i>, a skin-native bacterium.</p>
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<h6>Aims</h6><br>
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<p>The strain <i>Ruegeria pomeroyi</i>, a genus of the Rhodobacteraceae, produces an enzyme called trimethylamine monooxygenase thanks to the <i>tmm</i> gene. As FMO3, this enzyme degrades trimethylamine into trimethylamine-N-oxide but is adapted to a bacterial expression. The project aims at cloning <i>tmm</i> into <i>E.coli</i> and then into <i>Corynebacterium striatum</i>, one of the most common bacteria of the skin. The new strain would be integrated to the skin microbiome and would suppress the fish odor.</p>
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<p class=text2><img src='https://static.igem.org/mediawiki/2014/a/a3/Can_you_smell_fish_odor.png'>
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<b>Figure 2. The human nose can detect fish odor from a solution with a concentration of 1mM.</b> </br>
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10 participants were asked to smell trimethylamine samples at different concentrations and asked whether they could detect any difference with a control (water). An odor threshold was found at 1 mM and trimethylamine at concentrations of 0.1 mM or below was not detected.</br></br></br></br></br></br>
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<img src='https://static.igem.org/mediawiki/2014/e/ee/Figure2_TMMPB.png'></br>
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</br>
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<b>Figure 3. Characterisation of TMM using indigo production.</b></br>
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(A) TMM allows the degradation of trimethylamine into trimethylamine-N-oxide.</br>
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(B) TMM activity can be detected by the presence of indigo, a blue dye. Indole is naturally produced from tryptophan by tryptophanase in <i>E. coli</i> and can be converted into indigo by TMM.</br>
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(C) Indigo can be detected in TMM-expressing <i>E.coli</i> (left) but not in the control (right) after 14h of culture in LB medium supplemented with 2g/l of tryptophan.</br>
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</br>
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<img src='https://static.igem.org/mediawiki/2014/f/f0/Spectrum_indigoPB.png' width='800px'></br>
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<b>Figure 4. Average absorbances of DMSO extractions from bacterial lysates shows TMM activity.</b></br> This graph shows the absorbance spectra of DMSO extractions from  TMM-expressing <i>E. coli</i> (+TMM) or control (-TMM) in LB medium (-trp) or in LB supplemented with tryptophan (+trp). The grey area shows the expected absorbance peak of indigo.</br>
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</br>
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<img src='https://static.igem.org/mediawiki/2014/8/88/TMMGC_PB.png' width='800px'></br>
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<b>Figure 5. GC/MS analysis of cultures of <i>E. coli</i> expressing TMM or an empty vector (control).</b></br>
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(A) GC/MS spectra of triplicates of cultures of <i>E. coli</i> expressing TMM or an empty vector (control). The peaks were analysed and compared to a database, showing the confidence rate for TMA.</br>RT = Retention time</br>MA = Measured Area</br>
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(B) Average area of the peaks corresponding to TMA in TMM-expressing <i>E.coli</i> and control (p-value=0.0199).
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<img src='https://static.igem.org/mediawiki/2014/6/63/TmafinalPB.gif' width='800px'></br>
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<b>Figure 6. Diffusion model of trimethylamine through air.</b></br> This animation shows the concentration of trimethylamine  diffusing through air from a patient over a time period of 0 to 1000 hours. From the graph on the left of the animation, you can see that the odor threshold is reached very early in the model, given that the concentration of trimethylamine  at the skin surface is kept at a constant concentration of 500-600 ppm.
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<h6>Results</h6><br>
<h6>Results</h6><br>
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<b>Odor panel of trimethylamine</b></br>
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We first wanted to determine which concentration of trimethylamine we had to use for our experiments. Ten volonteers were asked to smell trimethylamine samples at different concentrations and to say whether they could detect any difference with a control (water). An odor threshold was found at 1 mM and trimethylamine at concentrations of 0.1 mM or below was not detected (Fig. 2). </br>
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<h6>Motivation</h6><br>
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<b>Cloning</b></br>
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We synthesized TMM from <i>R. pomeroyi</i> and expressed it in <i>E. coli</i>. The construct (BBa_K1403015) included a constitutive promoter and was cloned in the standard high-copy BioBrick vector pSB1C3. Following 24 hours of incubation at 37 C, a dark pigment was visible in the transformed colonies.</br>
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</br>
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<b>Characterisation of TMM activity in <i>E.coli</i></b></br>
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The TMM enzyme is not specific to TMA as a substrate. It is also known to oxidize indole to indoxyl, which dimerizes into the well known blue pigment indigo (Fig 3B). Indole is a natural product of tryptophan metabolism in <i>E. coli</i>.</br>
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We took advangage of this indole production activity to characterize the TMM enzyme. <i>E. coli</i> that were cultured in LB supplemented with tryptophan (2 g/L) produced a deep blue pigment (Fig. 3C) with absorbance properties matching indigo (Fig. 4). Without TMM expression or without tryptophan, indigo production was minimal or absent.</br>
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</br>
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<b>GC/MS </b></br>
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GC/MS confirmed the activity of TMM by proving the degradation of trimethylamine (Fig. 5). It was performed on extractions from cultures of TMM-expressing <i>E. coli</i> (TMM) and control expressing an empty vector in a LB medium supplemented with trimethylamine (1 mM).  The results show a significant decrease (p-value = 0,0199) of the concentration of TMA in <i>TMM</i>-expressing <i>E.coli</i> (Fig. 5B). This confirms the efficiency of degradation of the fish odor by TMM. </br>
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</br>
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<b>Modeling of TMA diffusion</b></br>
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A simple model was created for the diffusion of trimethylamine into the air using COMSOL Multiphysics (a physics-based interface to solve partial differential equations). The model is shown in Fig.6. From literature, it was found that the odor threshold of trimethylamine in air is approximately 3.2E-5 ppm air (<a href="https://2014.igem.org/Team:Paris_Bettencourt/Bibliograpy"> Nagata, 1993</a>), using the triangle odor bag method. This odor threshold was reached approximately 10 hours in the model, at a distance of 5 cm from the skin surface.</p></br>
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</br></br>
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</br><h6>Methods</h6><br>
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<p class=text1>
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<b>Cloning</b></br>
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The TMM gene was produced by gene synthesis (IDT). The final construct was codon-optimized for <i>E. coli</i> expression and included a strong constitutive promoter and ribosome binding site.</br>
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For <i>E. coli</i> expression, we cloned the TMM construct into the standard high-copy BioBrick vector pSB1C3. For expression in <i>C. striatum</i> we used the vector pSEVA351, a universal vector with a high-copy replication origin (<a href="https://2014.igem.org/Team:Paris_Bettencourt/Bibliograpy">Standard European Vector Architecture</a>).
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<b>Indigo absorbance</b></br>
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TMM does not only degrade trimethylamine into trimethylamine-N-oxide, but also converts indole into indigo. Measurement of TMM activity was performed on TMM-expressing <i>E.coli</i> using the <a href="https://2014.igem.org/Team:Paris_Bettencourt/Protocols#prot10"  >isolation of indigo protocol</a> inspired of <a href="https://2014.igem.org/Team:Paris_Bettencourt/Bibliograpy" >Choi H.S., Kim J.K <i>et al.</i> (2003)</a>. The control is <i>E. coli</i> expressing pSB1C3.
 +
</br>
 +
</br>
 +
<b>GC/MS analysis</b></br>
 +
For the GC/MS analysis, 1µl of the sample was injected into the instrument in split mode. We used a Rtx5MS- 30m column with 0.25-mm ID and 0.25µm df. Data analysis was performed with X Caliber software. Component peaks were quantified by peak area normalized to an internal standard.<br>
 +
 
 +
</br>
 +
</br>
 +
<b>Modeling</b></br>
 +
The model is based on a 2D axisymmetric geometry, with the air modeled as the space 5 cm around the skin surface. Here, the skin surface is kept at a constant concentration, C<sub>0</sub> = 1.39 <sup>+</sup>/<sub>-</sub> 0.483 uM. This value refers to the approximate amount of trimethylamine in sweat (Bain, 2005). The diffusivity of trimethylamine through the air was calculated using the Chapman-Enskog theory of gas diffusivity given by the following equation:</br></br>
 +
D = (1.858E-3 * T<sup>(3/2)</sup> * (1/M<sub>1</sub> + 1/M<sub>2</sub>)<sup>(1/2)</sup>) / (p * s<sub>12</sub><sup>2</sup> * w)</br></br>
 +
where D is the diffusivity of the trimethylamine</br>
 +
T is the room temperature, 298 K</br>
 +
p is the air pressure, 1 atm</br>
 +
M<sub>1</sub> is the mass of the trimethylamine, 59.11 g/mol</br>
 +
M<sub>2</sub> is the mass of the air, 29 g/mol</br>
 +
s<sub>12</sub> is the average collision diameter, which is around 340 Angstroms for gas molecules in air, and w is the dimensionless temperature-dependent collision integral, usually on the order of 1.</br>
 +
</br>
 +
Thus, the diffusion coefficient of trimethylamine was tabulated to be 1.9*10<sup>-9</sup> m<sup>2</sup>/s.</br><br><br><br>
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Latest revision as of 03:40, 18 October 2014

BACKGROUND

Trimethylaminuria (TMAU), or Fish Odor Syndrome, is a rare genetic disease caused by inactivating mutations in the FMO3 gene. Consequently, trimethylamine (TMA) accumulates in sweat, saliva, and urine, causing a strong fish odor. Patients suffer no other serious symptoms, except a difficult social condition.

AIMS

TMA is also processed by the trimethylamine monooxygenase (TMM) of Ruegeria pomeroyi, an enzyme similar to human FMO3. Expressing this enzyme in human skin bacteria should remove trimethylamine from sweat and reduce its unpleasant odor. TMM-expressing bacteria in a cream or spray could be a cheap and stable way to deliver the therapeutic enzyme to TMAU patients.

ACHIEVEMENTS

  • Cloned TMM into E.coli using pSB1C3 and pSEVA315 vectors, creating a new Biobrick: BBa_K1403015.
  • Characterized and quantified the activity of TMM by a colorimetric assay.
  • Confirmed the degradation of trimethylamine by GC/MS.
Introduction Results Methods


Figure 1. Trimethylamine production and degradation in the human body.
(A) In humans, choline is converted into trimethylamine and acetaldehyde by the gut bacteria Desulfovibrio desulfuricans.
(B) Trimethylamine is degraded in the liver into trimethylamine-N-oxyde by FMO3 (flavin-containing mono oxygenase 3).
(C) Mutations in the FMO3 gene can cause the loss of the function of the enzyme. In these patients, trimethylamine is excreted into sweat, urine and breath, causing a strong fish odor.

Introduction

Trimethylamine (TMA) is a volatile compound smelling strongly of spoiled fish. It is produced during human digestion when choline, a B-complex vitamin, is fermented by gut bacteria (Craciun, S. et al., 2012) (Fig. 1A). Normally it proceeds to the liver where it is oxidized by FMO3, a flavin-containing monooxygenase (Fig. 1B). The product of FMO3 is trimethylamine oxide (TMAO), which is odorless.

Trimethylaminuria (TMAU), or fish odor syndrome, is a rare genetic disorder in which patients are not able to fully oxidize TMA. TMAO is an autosomal recessive disorder, requiring two nonfunctional alleles of the FMO3 gene. More than 30 known mutations can inactivate FMO3, and inactive alleles have an estimated 0.1-1% global frequency (Mitchell, S.C et al., 2001). TMAU currently has no cure.

We propose that TMAU could be treated with a genetically modified skin bacteria. The trimethylamine monooxygenase (TMM) of Ruegeria pomeroyi also oxdizes TMA to TMAO (Chen, Y. et al., 2011). Applying this enzyme to the skin should eliminate TMA in sweat and, therefore, unpleasant odor. Expression in a bacterium of the skin microbiome could be a cheap and stable way to deliver the therapeutic enzyme. Here we present the expression and characterization of TMM in E. coli and Corynebacterium striatum, a skin-native bacterium.

Figure 2. The human nose can detect fish odor from a solution with a concentration of 1mM.
10 participants were asked to smell trimethylamine samples at different concentrations and asked whether they could detect any difference with a control (water). An odor threshold was found at 1 mM and trimethylamine at concentrations of 0.1 mM or below was not detected.







Figure 3. Characterisation of TMM using indigo production.
(A) TMM allows the degradation of trimethylamine into trimethylamine-N-oxide.
(B) TMM activity can be detected by the presence of indigo, a blue dye. Indole is naturally produced from tryptophan by tryptophanase in E. coli and can be converted into indigo by TMM.
(C) Indigo can be detected in TMM-expressing E.coli (left) but not in the control (right) after 14h of culture in LB medium supplemented with 2g/l of tryptophan.


Figure 4. Average absorbances of DMSO extractions from bacterial lysates shows TMM activity.
This graph shows the absorbance spectra of DMSO extractions from TMM-expressing E. coli (+TMM) or control (-TMM) in LB medium (-trp) or in LB supplemented with tryptophan (+trp). The grey area shows the expected absorbance peak of indigo.


Figure 5. GC/MS analysis of cultures of E. coli expressing TMM or an empty vector (control).
(A) GC/MS spectra of triplicates of cultures of E. coli expressing TMM or an empty vector (control). The peaks were analysed and compared to a database, showing the confidence rate for TMA.
RT = Retention time
MA = Measured Area
(B) Average area of the peaks corresponding to TMA in TMM-expressing E.coli and control (p-value=0.0199).


Figure 6. Diffusion model of trimethylamine through air.
This animation shows the concentration of trimethylamine diffusing through air from a patient over a time period of 0 to 1000 hours. From the graph on the left of the animation, you can see that the odor threshold is reached very early in the model, given that the concentration of trimethylamine at the skin surface is kept at a constant concentration of 500-600 ppm.

Results

Odor panel of trimethylamine
We first wanted to determine which concentration of trimethylamine we had to use for our experiments. Ten volonteers were asked to smell trimethylamine samples at different concentrations and to say whether they could detect any difference with a control (water). An odor threshold was found at 1 mM and trimethylamine at concentrations of 0.1 mM or below was not detected (Fig. 2).

Cloning
We synthesized TMM from R. pomeroyi and expressed it in E. coli. The construct (BBa_K1403015) included a constitutive promoter and was cloned in the standard high-copy BioBrick vector pSB1C3. Following 24 hours of incubation at 37 C, a dark pigment was visible in the transformed colonies.

Characterisation of TMM activity in E.coli
The TMM enzyme is not specific to TMA as a substrate. It is also known to oxidize indole to indoxyl, which dimerizes into the well known blue pigment indigo (Fig 3B). Indole is a natural product of tryptophan metabolism in E. coli.
We took advangage of this indole production activity to characterize the TMM enzyme. E. coli that were cultured in LB supplemented with tryptophan (2 g/L) produced a deep blue pigment (Fig. 3C) with absorbance properties matching indigo (Fig. 4). Without TMM expression or without tryptophan, indigo production was minimal or absent.

GC/MS
GC/MS confirmed the activity of TMM by proving the degradation of trimethylamine (Fig. 5). It was performed on extractions from cultures of TMM-expressing E. coli (TMM) and control expressing an empty vector in a LB medium supplemented with trimethylamine (1 mM). The results show a significant decrease (p-value = 0,0199) of the concentration of TMA in TMM-expressing E.coli (Fig. 5B). This confirms the efficiency of degradation of the fish odor by TMM.

Modeling of TMA diffusion
A simple model was created for the diffusion of trimethylamine into the air using COMSOL Multiphysics (a physics-based interface to solve partial differential equations). The model is shown in Fig.6. From literature, it was found that the odor threshold of trimethylamine in air is approximately 3.2E-5 ppm air ( Nagata, 1993), using the triangle odor bag method. This odor threshold was reached approximately 10 hours in the model, at a distance of 5 cm from the skin surface.





Methods

Cloning
The TMM gene was produced by gene synthesis (IDT). The final construct was codon-optimized for E. coli expression and included a strong constitutive promoter and ribosome binding site.
For E. coli expression, we cloned the TMM construct into the standard high-copy BioBrick vector pSB1C3. For expression in C. striatum we used the vector pSEVA351, a universal vector with a high-copy replication origin (Standard European Vector Architecture).

Indigo absorbance
TMM does not only degrade trimethylamine into trimethylamine-N-oxide, but also converts indole into indigo. Measurement of TMM activity was performed on TMM-expressing E.coli using the isolation of indigo protocol inspired of Choi H.S., Kim J.K et al. (2003). The control is E. coli expressing pSB1C3.

GC/MS analysis
For the GC/MS analysis, 1µl of the sample was injected into the instrument in split mode. We used a Rtx5MS- 30m column with 0.25-mm ID and 0.25µm df. Data analysis was performed with X Caliber software. Component peaks were quantified by peak area normalized to an internal standard.


Modeling
The model is based on a 2D axisymmetric geometry, with the air modeled as the space 5 cm around the skin surface. Here, the skin surface is kept at a constant concentration, C0 = 1.39 +/- 0.483 uM. This value refers to the approximate amount of trimethylamine in sweat (Bain, 2005). The diffusivity of trimethylamine through the air was calculated using the Chapman-Enskog theory of gas diffusivity given by the following equation:

D = (1.858E-3 * T(3/2) * (1/M1 + 1/M2)(1/2)) / (p * s122 * w)

where D is the diffusivity of the trimethylamine
T is the room temperature, 298 K
p is the air pressure, 1 atm
M1 is the mass of the trimethylamine, 59.11 g/mol
M2 is the mass of the air, 29 g/mol
s12 is the average collision diameter, which is around 340 Angstroms for gas molecules in air, and w is the dimensionless temperature-dependent collision integral, usually on the order of 1.

Thus, the diffusion coefficient of trimethylamine was tabulated to be 1.9*10-9 m2/s.



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