Team:Paris Bettencourt/Project/Odor Library

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Latest revision as of 15:56, 3 December 2014

@iGEM_Paris

Stop And Smell The Roses

BACKGROUND

Synthetic enzymes can produce odors that humans experience directly, without special instruments. The banana and wintergreeen smell BioBricks are iGEM icons, and a favorite way to introduce genetic engineering. An expanded library of easy-to-use odor enzymes would take synthetic biology to new audiences for creativity, beauty and fun!

AIMS

We standardized and simplified existing smell-producing BioBricks for banana, wintergreen, lemon and rain. Also, we created new BioBricks for the aromas of popcorn and jasmine. We made an odor wheel made out of genetic odors that follow a standard organization so that the general public can play with odor genes.

ACHIEVEMENTS

Created BioBricks coding for sequences for different enzymes to nullify the bad odor produced by E. coli.
We produced the smells that compose the main odor categories perceived by humans.
BioBricks submitted to be BioBrick registry: BBa_K1403003, BBa_K1403006, BBa_K1403009, BBa_K1403012, BBa_K1403017, BBa_K1403019

Introduction

Results

Methods

Figure 1. Odor palette composed of BioBricks containing coding sequences for different enzymes known to catalyze reactions that yield volatile compounds with distinctive smells. We included odors with different tonalities in order to explore the aromas resulting from different combinations of smelly units. The tonality of each smell is categorized as butter, balminess, citrus, non-citrus fruit and herbal. These cover half of the main odor categories perceivable to human beings.

Introduction

All living things can detect chemical signals from the environment. In humans, the direct chemical sense takes the form of olfaction. Although our sense of smell is less sensitive than that of other mammals, it is still capable of detecting many compounds at concentrations lower than 1 part per million. Odors can trigger emotional responses and memory associations, making them a very direct and visceral way to experience the environment.

Bacterial enzymes can produce volatile compounds, including many that are surprising and fun. A generation of iGEMers has had the chance to experience bacteria that smell like banana or mint. The goal of this project is to expand the range of odors that can be created with synthetic enzymes. An easy-to-use, standardized genetic odor library will empower a new generation to play with synthetic biological smells.

Figure 2. Basic structure of the odor cassettes: iGEM prefix, constitutive promoter, synthetic ribosome-binding site, coding sequence with his tag, and iGEM suffix

Results

We created BioBricks coding for sequences of different enzymes to explore each of the odors described in the palette. These sequences are codon-optmized for produced expression in E. coli and produce the smells that compose the main odor categories perceived by humans.

Methods

Odorless E. coli:
The tnaA deletion mutant E. coli was taken from location 63:E:9 in the Keio collection. Standard microbiology techniques were used to culture it in liquid and solid media. Subsequently, a single colony was taken to make a batch of Ca2Cl chemically competent cells using.

BioBricks:
The coding sequences for BMST1,ATF1, LIMS1 and GGS were extracted from the Registry. The ATF1 and LIMS1 generator BioBricks were taken from previous iGEM distribution kits and were cloned into the pSB1C3 vector downstream of BBa_J23108 constitutive promoter. The BMST1, JMT, and GDS sequences were codon optimized for expression in E. coli. A synthetic ribosome-binding site that includes XmaI and AgeI flanking restriction sites was designed using the RBS calculator from the Salis’ lab. All BioBricks were assembled using standard molecular biology cloning techniques and 3A iGEM assembly.

Characterization:
Transformed E. coli was grown in M9 minimal media with 2% glucose and complete amino acid mix overnight with the appropriate substrate.

System	Enzyme	Substrate	Concentration	Product
Jasmine	JMT	Jasmonic acid	1 mM	Methyl jasmonate
Mint	BMST1	Salicylic acid	2 mM	Methyl salicylate
Banana	ATF1	Isoamyl alcohol	5 mM	Isoamyl acetate
Limonene	LIMS1	Farnesyl diphosphate	Natural	(+)-Limonene
Rain	G/G D-synthase	Farnesyl diphosphate	Natural	Geosmin
Flowers	BMST1	Benzoic acid	5 mM	Methyl benzoate
Butter	AldB	Acetolactic acid	-	Acetoin
Sweat	agaA	3-M-2-hexenoic acid	-	3-HO-3-Methylhexanoic acid

Table 1. Substrate concentrations (mM).

Centre for Research and Interdisciplinarity (CRI)
Faculty of Medicine Cochin Port-Royal, South wing, 2nd floor
Paris Descartes University
24, rue du Faubourg Saint Jacques
75014 Paris, France

+33 1 44 41 25 22/25

paris-bettencourt-igem@googlegroups.com

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          <table id=headtable>
 		<tr>
-			<td><b>BACKGROUND</b></br><br>
+			<td><b><center>BACKGROUND</center></b></br><br>
 <p class=text1>Synthetic enzymes can produce odors that humans experience directly, without special instruments. The banana and wintergreeen smell BioBricks are iGEM icons, and a favorite way to introduce genetic engineering. An expanded library of easy-to-use odor enzymes would take synthetic biology to new audiences for creativity, beauty and fun!</p></td>
-			<td><b>AIMS</b></br><br>
+			<td><b><center>AIMS</center></b></br><br>
-<p class=text1><ul><li>Standardize and simplify existing smell-producing BioBricks for banana, wintergreen, lemon and rain.</li> <li>Create new BioBricks for the aromas of popcorn and jasmine.</li><li>Create an odor wheel made out of genetic odors that follow a standard organization so that the general public can play with odor genes.</li></ul></p></td>
+<p class=text1><left>We standardized and simplified existing smell-producing BioBricks for banana, wintergreen, lemon and rain. Also, we created new BioBricks for the aromas of popcorn and jasmine. We made an odor wheel made out of genetic odors that follow a standard organization so that the general public can play with odor genes.</left></li></ul></p></td>
-			<td><b>RESULTS</b></br><br>
+			<td><b><center>ACHIEVEMENTS</center></b></br><br>
-<p class=text1><ul><li> Created BioBricks coding for sequences for different enzymes to nullify the bad odor produced by <i>E. coli</i> and produce the smells that compose the main odor categories perceived by humans.</li> <li>BioBricks submitted to be BioBrick registry:BBa_K1403003, BBa_K1403006, BBa_K1403009,   BBa_K1403012, BBa_K1403017, BBa_K1403019</li> </p></td>
+<p class=text1><ul><li> Created BioBricks coding for sequences for different enzymes to nullify the bad odor produced by <i>E. coli.</i></li> <li>We produced the smells that compose the main odor categories perceived by humans.</li> <li>BioBricks submitted to be BioBrick registry: <a href="http://parts.igem.org/Part:BBa_K1403003">BBa_K1403003</a>, <a href="http://parts.igem.org/Part:BBa_K1403006">BBa_K1403006</a>, <a href="http://parts.igem.org/Part:BBa_K1403009">BBa_K1403009</a>, <a href="http://parts.igem.org/Part:BBa_K1403012">BBa_K1403012</a>, <a href="http://parts.igem.org/Part:BBa_K1403017">BBa_K1403017</a>, <a href="http://parts.igem.org/Part:BBa_K1403019">BBa_K1403019</a></li> </p></td>
 		</tr>
 	</table>
@@ Line 200: / Line 220: @@
 	<table id=tablelien>
 		<tr>
-			<td><a href="#part1">Aims and Achievement</a></td>
-			<td><a href="#part2">Introduction</a></td>
+			<td><a href="#part1">Introduction</a></td>
-			<td><a href="#part3">Results</a></td>
+			<td><a href="#part2">Results</a></td>
-			<td><a href="#part4">Methods</a></td>
+			<td><a href="#part3">Methods</a></td>
 		</tr>
 	</table>
 	<div id=part1 class=project>
-		<p class=text2><img id=image1 src="https://static.igem.org/mediawiki/2014/5/56/ODOR_WHEEL.png"></p>
-		<h6>Aims and Achievement</h6><br>
+<p class=text2>
-		<p class=text1>Here we present the design of an odor wheel. It is composed of BioBricks containing coding sequences for different enzymes known to catalyze reactions that yield volatile compounds with characteristic smells. We included smells with different tonalities in order to explore the aromas resulting from different combinations of smelly units. The tonality of each smell is categorized as butter, balminess, citrus, non-citrus fruit and herbal. These cover half of the main odor categories perceivable to human beings. </p>
+<img src="https://static.igem.org/mediawiki/2014/5/56/ODOR_WHEEL.png">
-	</div>
+<b>Figure 1. Odor palette composed of BioBricks containing coding sequences for different enzymes known to catalyze reactions that yield volatile compounds with distinctive smells. We included odors with different tonalities in order to explore the aromas resulting from different combinations of smelly units. The tonality of each smell is categorized as butter, balminess, citrus, non-citrus fruit and herbal. These cover half of the main odor categories perceivable to human beings.</b> </br>
-	<div id=part2 class=project>
+</br></br></br></br></br></br>
-		<p class=text2></p>
+</p>
-		<h6>Introduction</h6><br>
+		<h6>Introduction</h6>
-		<p class=text1>There are complex relations among the stereochemistry of volatile compounds, their ratio within a particular mix, the amount of active olfactory receptors expressed in the smeller, as well as the distribution, and interaction of the different olfactory receptor neurons (ORNs). Odors spark neurochemical signals that are processed in different areas of the brain; they trigger complex cognitive processes that affect emotional responses such as motivation and memory. Although the precise molecular mechanisms behind odor perception have not been fully understood, there has been significant advance in the biosynthesis of organic volatile compounds using bacterial and fungal systems.  </p>
+<br>
+		<p class=text1>All living things can detect chemical signals from the environment. In humans, the direct chemical sense takes the form of olfaction. Although our sense of smell is less sensitive than that of other mammals, it is still capable of detecting many compounds at concentrations lower than 1 part per million. Odors can trigger emotional responses and memory associations, making them a very direct and visceral way to experience the environment. <br>
+<br>
+Bacterial enzymes can produce volatile compounds, including many that are surprising and fun. A generation of iGEMers has had the chance to experience bacteria that smell like <a href="BBa_J45200">banana</a> or <a href="BBa_J45200">mint</a>. The goal of this project is to expand the range of odors that can be created with synthetic enzymes. An easy-to-use, standardized genetic odor library will empower a new generation to play with synthetic biological smells.
+</p></div>
+<div id=part2 class=project>
+<p class=text2>
+<img src="https://static.igem.org/mediawiki/2014/d/dd/Smellybricks.png"  | width='100px'>
+<b>Figure 2. Basic structure of the odor cassettes: iGEM prefix, <a href="http://parts.igem.org/Part:BBa_J23108">constitutive promoter</a>, synthetic ribosome-binding site, coding sequence with his tag, and iGEM suffix </b> </br>
+</p>
+		<h6>Results</h6>
+<br>
+		<p class=text1>
+We created BioBricks coding for sequences of different enzymes to explore each of the odors described in the palette. These sequences are codon-optmized for produced expression in <i>E. coli</i> and produce the smells that compose the main odor categories perceived by humans. </p>
 </div>
-	<div id=part3 class=project>
+<div id=part3 class=project>
-		<p class=text2></p>
+		<h6>Methods</h6>
-		<h6>Results</h6><br>
+<br>
-		<p class=text1>Proper BioBrick characterization is needed before tinkering with expression levels; the possibility to change ribosomal binding sites according to the desired expression is included in our design. We would also like to develop auto-inducible smelly systems, as well as broaden the available tones in our palette. </p>
+	<p class=text1>
-	</div>
+Odorless <i>E. coli</i>:
-<div id=part4 class=project>
+<br>
-		<p class=text2></p>
+The tnaA deletion mutant <i>E. coli</i> was taken from location 63:E:9 in the Keio collection. Standard microbiology techniques were used to culture it in liquid and solid media. Subsequently, a single colony was taken to make a batch of Ca2Cl chemically competent cells using.
-		<h6>Methods</h6><br>
+<br>
-		<p class=text1>Lorem ipsum dolor sit amet, consectetur adipiscing elit. Ut imperdiet diam eget quam imperdiet imperdiet. Mauris dapibus risus felis, sed ornare diam accumsan aliquet. Sed eu turpis porta, porttitor tortor et, condimentum augue. Curabitur a maximus nisi. Vivamus vitae magna ex. Donec congue auctor odio vitae tempus. In a gravida neque, et tristique tortor. Phasellus a odio sit amet enim ornare lobortis. Morbi sodales, diam non rutrum aliquam, ligula mauris consectetur urna, sed interdum quam risus sit amet enim. Aenean euismod enim magna, id pretium eros molestie non. Proin rutrum lobortis leo, sit amet congue erat. Nulla congue pellentesque augue porta dignissim. Pellentesque quis ex sollicitudin, condimentum risus varius, aliquet ipsum. Ut pulvinar aliquet maximus. Praesent imperdiet interdum commodo. </p>
+<br>
+	BioBricks:
+<br>
+The coding sequences for <a href="http://parts.igem.org/Part:BBa_J45119">BMST1</a>,<a href="http://parts.igem.org/Part:BBa_J45199">ATF1</a>, <a href="http://parts.igem.org/Part:BBa_I742111">LIMS1</a> and <a href="http://parts.igem.org/Part:BBa_K221000">GGS</a> were extracted from the Registry. The ATF1 and LIMS1 generator BioBricks were taken from previous iGEM distribution kits and were cloned into the pSB1C3 vector downstream of BBa_J23108 constitutive promoter. The BMST1, JMT, and GDS sequences were codon optimized for expression in <i>E. coli</i>. A synthetic ribosome-binding site that includes XmaI and AgeI flanking restriction sites was designed using the RBS calculator from the Salis’ lab. All BioBricks were assembled using standard molecular biology cloning techniques and 3A iGEM assembly.
+<br>
+<br>
+Characterization:
+<br>
+Transformed <i>E. coli</i> was grown in M9 minimal media with 2% glucose and complete amino acid mix overnight with the appropriate substrate.
+<table class="tableizer-table">
+<tr class="tableizer-firstrow"><th>System</th><th>Enzyme</th><th>Substrate</th><th>Concentration</th><th>Product</th></tr>
+ <tr><td>Jasmine</td><td>JMT</td><td>Jasmonic acid</td><td>1 mM</td><td>Methyl jasmonate</td></tr>
+ <tr><td>Mint</td><td>BMST1</td><td>Salicylic acid</td><td>2 mM</td><td>Methyl salicylate</td></tr>
+ <tr><td>Banana</td><td>ATF1</td><td>Isoamyl alcohol</td><td>5 mM</td><td>Isoamyl acetate</td></tr>
+ <tr><td>Limonene</td><td>LIMS1</td><td>Farnesyl diphosphate</td><td>Natural</td><td>(+)-Limonene</td></tr>
+ <tr><td>Rain</td><td>G/G D-synthase</td><td>Farnesyl diphosphate</td><td>Natural</td><td>Geosmin</td></tr>
+ <tr><td>Flowers</td><td>BMST1</td><td>Benzoic acid</td><td>5 mM</td><td>Methyl benzoate</td></tr>
+ <tr><td>Butter</td><td>AldB</td><td>Acetolactic acid</td><td>-</td><td>Acetoin</td></tr>
+ <tr><td>Sweat</td><td>agaA</td><td>3-M-2-hexenoic acid</td><td>-</td><td>3-HO-3-Methylhexanoic acid</td></tr>
+</table>
+<b>Table 1. Substrate concentrations (mM).</b> </br>
+ </p>
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