Difference between revisions of "Team:UC San Diego/Description"

Latest revision as of 20:54, 20 November 2015

Uses of Luciferase

The Lux system’s bioluminescent reaction has been the subject of intense research. It is most often used as a reporter for gene expression and for tracking animal cells in vivo, and has more recently been utilized in synthetic biology for biosensor construction. As a result, it offers a powerful tool to researchers seeking to monitor a wide variety of biological and chemical processes.

About the Lux System

The luminescent output of the Lux system is jointly controlled by the activity of luciferase and a substrate-producing enzymatic complex. Firefly luminescence is the most well-known example of this type of reaction, but bioluminescent reactions also occur in beetles, marine bacteria, and other organisms. Between species, these reactions differ mechanistically and involve structurally distinct substrates and enzymes. We are studying the bacterial Lux system, in which an enzyme complex converts fatty acids into an aldehyde. Catalyzed by luciferase, these aldehydes then react with FMNH₂ and oxygen, emitting a photon and producing a fatty acid, FMN, and water. FMNH₂ is then regenerated by a flavin reductase, allowing for continuous light production with oxygen input.

Our Approach

Using existing approaches, mathematical models are limited in how they can predict and optimize metabolic pathways. We will be expressing several permutations of the bacterial Lux system to empirically determine its rate limiting steps by measuring the resulting light production. The identification of rate-limiting steps will then allow us to optimize the pathway. With these findings, an improved and experimentally validated mathematical model of the pathway will be constructed. By strategically altering biosynthetic gene expression, we will gain both a generalizable method to rapidly optimize metabolic pathways and a means to tailor the reporter/sensor to better suit our needs (i.e. make it brighter).

@@ Line 1: / Line 1: @@
+{{UC_San_Diego/Navbar}}
 <html>
-    <head>
+<body>
-        <meta charset="utf-8">
+      <div id="heading-pages">
-        <meta http-equiv="X-UA-Compatible" content="IE=edge">
+          <div class="row">
-        <title>Project</title>
+          <div class="col-md-6 col-md-offset-3 col-xs-8 col-xs-offset-2">
-        <meta name="description" content="">
+<p>
-        <meta name="viewport" content="width=device-width, initial-scale=1">
+</div>
+</div>
+</div>
+      <div class="container">
+        <div class="row">
+          <div class="col-md-12">
-<style type="text/css">
+            <div class="main-post">
+              <div class="image-post">
+                <img src="https://static.igem.org/mediawiki/2015/c/c1/UCSD_title-projover.png" alt="post image">
+              </div>
-		/* WIKI SETTINGS*/
-		/* Hide first heading */
-			.firstHeading {
-				display: none;
-			}
-		/*-- Remove borders, float content left and remove padding/margin */
-			#globalWrapper, #content{
-				background-color: transparent;
-				border: 0px;
-				float: center;
-                                width: 101%;
-				margin-left: -3px;
-				margin-top: -8px;
-				padding: auto;
-				padding-top: auto;
-			}
-		/*left align Black Menu Bar */
+              <div class="post-content">
-			#top_menu_inside {
+                <div class="post-discription">
-				margin-left: 0px;
-			}
-</style>
+<h3>Uses of Luciferase</h3>
+<p>The Lux system’s bioluminescent reaction has been the subject of intense research. It is most often used as a reporter for gene expression and for tracking animal cells <i>in vivo</i>, and has more recently been utilized in synthetic biology for biosensor construction. As a result, it offers a powerful tool to researchers seeking to monitor a wide variety of biological and chemical processes.</p>
-        <link rel="stylesheet" href="https://2015.igem.org/Team:UC_San_Diego/bootstrap.min.css?action=raw&amp;ctype=text/css">
+<h3>About the Lux System</h3>
-	<link href="http://maxcdn.bootstrapcdn.com/font-awesome/4.2.0/css/font-awesome.min.css" rel="stylesheet"> <!-- Font Awesome -->
+<p>The luminescent output of the Lux system is jointly controlled by the activity of luciferase and a substrate-producing enzymatic complex. Firefly luminescence is the most well-known example of this type of reaction, but bioluminescent reactions also occur in beetles, marine bacteria, and other organisms. Between species, these reactions differ mechanistically and involve structurally distinct substrates and enzymes. We are studying the bacterial Lux system, in which an enzyme complex converts fatty acids into an aldehyde. Catalyzed by luciferase, these aldehydes then react with FMNH<sub>2</sub> and oxygen, emitting a photon and producing a fatty acid, FMN, and water. FMNH<sub>2</sub> is then regenerated by a flavin reductase, allowing for continuous light production with oxygen input.</p>
-        <link rel="stylesheet" href="https://2015.igem.org/Team:UC_San_Diego/style.css?action=raw&amp;ctype=text/css">
-        <script src="https://2015.igem.org/Team:UC_San_Diego/modernizr-2.6.2.js?action=raw&amp;ctype=text/js"></script>
-  <link rel="stylesheet" href="//code.jquery.com/ui/1.11.4/themes/smoothness/jquery-ui.css">
+<h3>Our Approach</h3>
-  <script src="//code.jquery.com/jquery-1.10.2.js"></script>
+<p>Using existing approaches, mathematical models are limited in how they can predict and optimize metabolic pathways. We will be expressing several permutations of the bacterial Lux system to empirically determine its rate limiting steps by measuring the resulting light production. The identification of rate-limiting steps will then allow us to optimize the pathway. With these findings, an improved and experimentally validated mathematical model of the pathway will be constructed. By strategically altering biosynthetic gene expression, we will gain both a generalizable method to rapidly optimize metabolic pathways and a means to tailor the reporter/sensor to better suit our needs (i.e. make it brighter).</p>
-  <script src="//code.jquery.com/ui/1.11.4/jquery-ui.js"></script>
-  <style>
-  /* IE has layout issues when sorting (see #5413) */
-  .group { zoom: 1 }
-  </style>
-    </head>
+</div>
-    <body>
+</div>
-        <!--[if lt IE 7]>
+</div>
-            <p class="browsehappy">You are using an <strong>outdated</strong> browser. Please <a href="http://browsehappy.com/">upgrade your browser</a> to improve your experience.</p>
-        <![endif]-->
-    <div class="header" id="top">
-        <nav class="navbar navbar-inverse" role="navigation">
-          <div class="container">
-              <div class="navbar-header">
-                  <button type="button" id="nav-toggle" class="navbar-toggle" data-toggle="collapse" data-target="#main-nav">
-                    <span class="sr-only">Toggle navigation</span>
-                    <span class="icon-bar"></span>
-                    <span class="icon-bar"></span>
-                    <span class="icon-bar"></span>
-                  </button>
-                  <a href="index.html" class="navbar-brand">UCSD iGEM</a>
-              </div>
-<!-----------ALTERED
-              <div class="navbar-header">
-                  <button type="button" id="nav-toggle" class="navbar-toggle" data-toggle="collapse" data-target="#main-nav">
-                    <span class="sr-only">Toggle navigation</span>
-                    <span class="icon-bar"></span>
-                    <span class="icon-bar"></span>
-                    <span class="icon-bar"></span>
-                  </button>
-                  <a href="index.html" onClick="MyWindow=window.open('index.html','MyWindow'); return false;" class="navbar-brand scroll-top"><img src="images/logo.png" alt=“logo”>UCSD iGEM</a>
-              </div>
-&#9660;
----------------->
-              <!--/.navbar-header-->
-              <div id="main-nav" class="collapse navbar-collapse">
-                <ul class="nav navbar-nav navbar-right">
-                  <li><a href="#"><span>Project <i class="fa fa-caret-down"></i></span></a>
-                    <ul class="sub-menu">
-                      <li><a href="https://2015.igem.org/Team:UC_San_Diego/Module">Module</a></li>
-                      <li><a href="https://2015.igem.org/Team:UC_San_Diego/Parts">Parts</a></li>
-                      <li><a href="https://2015.igem.org/Team:UC_San_Diego/Results">Results</a></li>
-                      <li><a href="https://2015.igem.org/Team:UC_San_Diego/Applications">Applications</a></li>
-                      <li><a href="https://2015.igem.org/Team:UC_San_Diego/Safety">Safety</a></li>
-                    </ul>
-                  <li><a href="https://2015.igem.org/Team:UC_San_Diego/Wetlab">Wet Lab <i class="fa fa-caret-down"></i></a>
-                    <ul class="sub-menu">
-                      <li><a href="https://2015.igem.org/Team:UC_San_Diego/Wetlab#protocols">Protocols</a></li>
-                      <li><a href="https://2015.igem.org/Team:UC_San_Diego/Wetlab#data">Data</a></li>
-                    </ul>
-                  <li><a href="https://2015.igem.org/Team:UC_San_Diego/Modeling">Modeling <i class="fa fa-caret-down"></i></a>
-                    <ul class="sub-menu">
-                      <li><a href="https://2015.igem.org/Team:UC_San_Diego/Modeling#deterministic">Deterministic</a></li>
-                      <li><a href="https://2015.igem.org/Team:UC_San_Diego/Modeling#metacon">Metabolic Control</a></li>
-                    </ul>
-                  <li><a href="https://2015.igem.org/Team:UC_San_Diego/Team">Team <i class="fa fa-caret-down"></i></a>
-                    <ul class="sub-menu">
-                      <li><a href="https://2015.igem.org/Team:UC_San_Diego/Attributions">Attributions</a></li>
-                    </ul>
-                  <li><a href="https://2015.igem.org/Team:UC_San_Diego/Measurement">Interlab</a></li>
-                  <li><a href="https://2015.igem.org/Team:UC_San_Diego/Practices">Human Practices <i class="fa fa-caret-down"></i></a>
-                    <ul class="sub-menu">
-                      <li><a href="https://2015.igem.org/Team:UC_San_Diego/Practices#synbio">synbio.UCSD</a></li>
-                      <li><a href="https://2015.igem.org/Team:UC_San_Diego/Practices#hs">High School</a></li>
-                    </ul>
-                  <li><a href="https://2015.igem.org/Team:UC_San_Diego/Collaboration">Collaboration</a></li>
-                  <li><a href="https://2015.igem.org/Team:UC_San_Diego/Notebook">Notebook</a></li>
-                </ul>
-              </div>
-              </div>
-              <!--/.navbar-collapse-->
-      		</div>
-      		<!--/.container-->
-      </nav>
-          <!--/.navbar-->
-    </div>
-    <!--/.header-->
-      <div id="heading-pages">
-          <div>
-              <img src="https://static.igem.org/mediawiki/2015/f/f2/UCSD_header.jpg" alt="post header">
-          </div>
-          <div class="row">
-          <div class="col-md-6 col-md-offset-3 col-xs-8 col-xs-offset-2">
-            <h2>Project Description</h2>
-<h4>Uses of Luciferase</h4>
-<p>The lux system’s bioluminescent reaction has been the subject of intense research. It is most often used as a reporter for gene expression and for tracking animal cells in vivo, and has more recently been utilized in synthetic biology for biosensor construction. As a result, it offers a powerful tool to researchers seeking to monitor a wide variety of biological and chemical processes.</p>
-<h4>About the Lux System</h4>
-<p>The luminescent output of the lux system is jointly controlled by the activity of luciferase and a substrate-producing enzymatic complex. Firefly luminescence is the most well-known example of this type of reaction, but bioluminescent reactions also occur in beetles, marine bacteria, and other organisms. Between species, these reactions differ mechanistically and involve structurally distinct substrates and enzymes. We are studying the bacterial lux system, in which an enzyme complex converts fatty acids into an aldehyde. Catalyzed by luciferase, these aldehydes then react with FMNH2 and oxygen, emitting a photon and producing a fatty acid, FMN, and water. FMNH2 is then regenerated by a flavin reductase, allowing for continuous light production with oxygen input.</p>
-<h4>Our Approach</h4>
-<p>Using existing approaches, mathematical models are limited in how they can predict and optimize metabolic pathways. We will be expressing several permutations of the bacterial lux system to empirically determine its rate limiting steps by measuring the resulting light production. The identification of rate-limiting steps will then allow us to optimize the pathway. With these findings, an improved and experimentally validated mathematical model of the pathway will be constructed. By strategically altering biosynthetic gene expression, we will gain both a generalizable method to rapidly optimize metabolic pathways and a means to tailor the reporter/sensor to better suit our needs (i.e. make it brighter).</p>
            </div>
@@ Line 147: / Line 43: @@
        </div>
-      <footer>
-        <div class="container">
-          <div class="row">
-            <div class="copyright-text">
-              <p><font color=#728fce>Contact Us: ucsd.igem.2015@gmail.com</font></p>
-            </div>
-          </div>
-          <div class="col-md-12">
-            <div class="third-arrow">
-              <a href="#" class="scroll-link btn btn-dark" data-id="top"><i class="fa fa-angle-up"></i></a>
-            </div>
-          </div>
-        </div>
-      </footer>
-     <script src="https://2015.igem.org/Team:UC_San_Diego/jquery-1.11.1.min.js?action=raw&amp;ctype=text/js"></script>
-    <script src="https://2015.igem.org/Team:UC_San_Diego/bootstrap.min.js?action=raw&amp;ctype=text/js"></script>
-    <script src="https://2015.igem.org/Team:UC_San_Diego/main.js?action=raw&amp;ctype=text/js"></script>
    </body>
 </html>
+{{UC_San_Diego/Footer}}