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- | <html xmlns="http://www.w3.org/1999/xhtml" xml:lang="en" dir="ltr" lang="en"><head>
| + | {{GoettingenHeader|deu=Team:Goettingen/Project_deu|eng=Team:Goettingen/Project}} |
- | <meta http-equiv="Content-Type" content="text/html; charset=UTF-8">
| + | |
- | <meta name="keywords" content="Team:Goettingen,Team:Goettingen,Team:Goettingen/Homing coli,Team:Goettingen/Human Practice/Flash coli,Team:Goettingen/Press,Team:Goettingen/Project/General information">
| + | |
- | <link rel="shortcut icon" href="https://2012.igem.org/favicon.ico">
| + | |
- | <link rel="search" type="application/opensearchdescription+xml" href="https://2012.igem.org/wiki/opensearch_desc.php" title="2012.igem.org (English)">
| + | |
- | <link title="Creative Commons" type="application/rdf+xml" href="https://2012.igem.org/wiki/index.php?title=Team:Goettingen&action=creativecommons" rel="meta">
| + | |
- | <link rel="alternate" type="application/rss+xml" title="2012.igem.org RSS Feed" href="https://2012.igem.org/wiki/index.php?title=Special:Recentchanges&feed=rss">
| + | |
- | <link rel="alternate" type="application/atom+xml" title="2012.igem.org Atom Feed" href="https://2012.igem.org/wiki/index.php?title=Special:Recentchanges&feed=atom">
| + | |
| | | |
- | | + | == Our Project == |
- | <body class="mediawiki ns-0 ltr page-Team_Goettingen">
| + | Our project was born from the idea to create a real champion: the fastest <i>E. coli</i> in the world. As funny as this may sound first, |
- | | + | soon we were at the development of an ambitious plan to create our "Homing Coli" and apply its speed for selective purposes. |
- | | + | The ultimate goal was a fast swimming <i>E. coli</i> strain which would be able to recognize specific molecules on a mutagenized |
- | | + | receptor and head towards gradients of these substances on swimming agar plates. If this approach worked, it might be put to use |
- | | + | for the recognition of various molecules such as pollutants, toxins or even cancer cell markers. As our planning moved on, we soon |
- | <!-- start content -->
| + | created three different focus groups which should work in parallel on the biggest and most crucial components of our project. <br> |
- | | + | |
- | | + | |
- | | + | |
- | <style>
| + | |
- | h1.firstHeading { display: none; }
| + | |
- | | + | |
- | p {text-align: justify;}
| + | |
- | | + | |
- | a:link { color: #004080; text-decoration: none}
| + | |
- | a:visited { color:##003090; text-decoration: none}
| + | |
- | a:hover { color:#f29400; text-decoration: none}
| + | |
- | a:active { color:#f29400; text-decoration: none}
| + | |
- | | + | |
- | #bodyContent { padding: 10px auto; width: 910px; margin: auto; clear: none; }
| + | |
- | | + | |
- | table#team_members { text-align: justify; border: 0; }
| + | |
- | table#team_members h2, table#team_members h3 { clear: both; }
| + | |
- | | + | |
- | | + | |
- | /*-----------------------------------------------------------------------------------------------*/
| + | |
- | div.MenuBar ul li ul.DropDownMenu {
| + | |
- | display: none; /* Hides all drop-down menus. */
| + | |
- | | + | |
- | }
| + | |
- | /*
| + | |
- | li:hover works in IE7 and FF2.
| + | |
- | a:hover works in IE6 and FF2.
| + | |
- | a:hover breaks li:hover in FF2.
| + | |
- | */
| + | |
- | div.MenuBar ul li:hover ul.DropDownMenu li ul.SideMenu,
| + | |
- | div.MenuBar ul li a:hover ul.DropDownMenu li a ul.SideMenu {
| + | |
- | display: none; /* Hides all side menus. */
| + | |
- | }
| + | |
- | /*------------------------------------------------------------------------------------- Menu Bar */
| + | |
- | div.MenuBar {
| + | |
- | font: Verdana;
| + | |
- | height: 30px;
| + | |
- | width: 910px;
| + | |
- | /*width: 100%*/
| + | |
- | margin: 0;
| + | |
- | border-top: 0;
| + | |
- | border-right: 0;
| + | |
- | border-left: 0;
| + | |
- | padding: 0;
| + | |
- | background: #00446b;
| + | |
- | | + | |
- | }
| + | |
- | div.MenuBar ul {
| + | |
- | font: Verdana;
| + | |
- | text-align: center;
| + | |
- | list-style-type: none;
| + | |
- | margin: 0 auto;
| + | |
- | border: 0;
| + | |
- | padding: 0;
| + | |
- | background: #00446b;
| + | |
- | }
| + | |
- | div.MenuBar ul li {
| + | |
- | font: Verdana;
| + | |
- | display: block;
| + | |
- | padding: 0;
| + | |
- | margin: 0;
| + | |
- | font-size: 1.3em;
| + | |
- | float: left;
| + | |
- | background: #00446b;
| + | |
- | text-align: center;
| + | |
- | width: 107px;
| + | |
- | position: relative; /* Sets the positioning context for each drop-down menu. */
| + | |
- | }
| + | |
- | | + | |
- | div.MenuBar ul li a {
| + | |
- | font: Verdana;
| + | |
- | display: block;
| + | |
- | background: #00446b;
| + | |
- | height: 22px; /* Keep height + padding-top + padding-bottom sync with the menu bar height. */
| + | |
- | color: white;
| + | |
- | padding-top: 4px;
| + | |
- | padding-bottom: 4px;
| + | |
- | padding-left: 1em; /* Sets the left space between top-level items. */
| + | |
- | padding-right: 1em; /* Sets the right space between top-level items. */
| + | |
- | text-decoration: none;
| + | |
- | }
| + | |
- | | + | |
- | /*------------------------------------------------------------------------------ Drop-Down Menus */
| + | |
- | div.MenuBar ul li:hover ul.DropDownMenu,
| + | |
- | div.MenuBar ul li a:hover ul.DropDownMenu {
| + | |
- | display: block;
| + | |
- | width: 10em; /* Drop-down menu width.
| + | |
- | Use MenuTailor.css to customize. */
| + | |
- | height: 1em;
| + | |
- | padding: 1px; /* Sets the drop-down menu "effective border" width. */
| + | |
- | position: absolute;
| + | |
- | top: 28px; /* Places the drop-down menu under the menu bar.
| + | |
- | Keep it sync with the menu bar height. */
| + | |
- | left: 0; /* Aligns the drop-down menu to its top-level item. */
| + | |
- | background-color: #A3C0E0; /* Selected item. */
| + | |
- | color: #FFFFFF;
| + | |
- | | + | |
- | }
| + | |
- | div.MenuBar ul li:hover ul.DropDownMenu li a,
| + | |
- | div.MenuBar ul li a:hover ul.DropDownMenu li a {
| + | |
- | width: 10em; /* Keep it sync with the drop-down menu width.
| + | |
- | Use MenuTailor.css to customize. */
| + | |
- | height: 1em;
| + | |
- | padding-left: 0;
| + | |
- | padding-right: 0;
| + | |
- | background-color: #A3C0E0; /* Selected item. */
| + | |
- | color: #FFFFFF;
| + | |
- | }
| + | |
- | ul.DropDownMenu li a span {
| + | |
- | display: block;
| + | |
- | padding-left: 0.75em; /* Sets the left space of each drop-down menu item. */
| + | |
- | padding-right: 0.25em; /* Sets the right space of each drop-down menu item. */
| + | |
- | text-align: right; /* Aligns the >> symbol to the right. */
| + | |
- | }
| + | |
- | ul.DropDownMenu li a span span {
| + | |
- | float: left; /* Aligns the text (back) to the left. */
| + | |
- | font: 12px Verdana; /* Required for IE55. */
| + | |
- | height: 20px;
| + | |
- | color: #FFFFFF;
| + | |
- | }
| + | |
- | /*----------------------------------------------------------------------------------- Side Menus */
| + | |
- | div.MenuBar ul li:hover ul.DropDownMenu li:hover ul.SideMenu,
| + | |
- | div.MenuBar ul li a:hover ul.DropDownMenu li a:hover ul.SideMenu {
| + | |
- | display: block;
| + | |
- | width: 11em; /* Side menu width.
| + | |
- | Use MenuTailor.css to customize. */
| + | |
- | padding: 1px; /* Sets the side menu "effective border" width. */
| + | |
- | position: absolute;
| + | |
- | top: -1px; /* Aligns the side menu to its drop-down menu item.
| + | |
- | Keep it sync with the side menu "effective border" width. */
| + | |
- | left: 13em; /* Places the side menu to the right of the drop-down menu.
| + | |
- | Keep it sync with the drop-down menu width.
| + | |
- | Use MenuTailor.css to customize. */
| + | |
- | }
| + | |
- | div.MenuBar ul li:hover ul.DropDownMenu li:hover ul.SideMenu li a,
| + | |
- | div.MenuBar ul li a:hover ul.DropDownMenu li a:hover ul.SideMenu li a {
| + | |
- | width: 11em; /* Keep it sync with the side menu width.
| + | |
- | Use MenuTailor.css to customize. */
| + | |
- | font: 12px Verdana; /* Required for IE55. */
| + | |
- | left: 13em; /* Places the side menu to the right of the drop-down menu.
| + | |
- | Keep it sync with the drop-down menu width.
| + | |
- | Use MenuTailor.css to customize. */
| + | |
- | }
| + | |
- | div.MenuBar ul li ul.DropDownMenu li ul.SideMenu li a span {
| + | |
- | padding-left: 1.5em; /* Sets the left space of each side menu item. */
| + | |
- | padding-right: 0.5em; /* Sets the right space of each side menu item. */
| + | |
- | text-align: left;
| + | |
- | font: 12px Verdana; /* Required for IE55. */
| + | |
- | left: 13em; /* Places the side menu to the right of the drop-down menu.
| + | |
- | Keep it sync with the drop-down menu width.
| + | |
- | Use MenuTailor.css to customize. */
| + | |
- | }
| + | |
- | /*----------------------------------------------------------------------------- Browser Specific */
| + | |
- | * html div.MenuBar ul li a {
| + | |
- | float: left; /* Required for IE55 and IE6.
| + | |
- | Breaks O9.
| + | |
- | Hidden (* html) from non-IE browsers. */
| + | |
- | }
| + | |
- | * html ul.DropDownMenu li a:hover {
| + | |
- | cursor: hand; /* Required for IE55.
| + | |
- | Hidden (* html) from non-IE browsers. */
| + | |
- | }
| + | |
- | ul.DropDownMenu li a:hover {
| + | |
- | cursor: pointer; /* Required for IE6 and IE7.
| + | |
- | Hidding it (* html) from non-IE browsers breaks IE7!
| + | |
- | }
| + | |
- | * html div.MenuBar a:hover {
| + | |
- | text-decoration: none; /* Required for IE55 and IE6.
| + | |
- | Hidden (* html) from non-IE browsers. */
| + | |
- | }
| + | |
- | * html div.MenuBar ul li table,
| + | |
- | * html div.MenuBar ul li table td {
| + | |
- | border: 0; /* Required for IE55 and IE6.
| + | |
- | Hidden (* html) from non-IE browsers. */
| + | |
- | }
| + | |
- | /*------------------------------------------------------------------------------- Default Colors */
| + | |
- | div.MenuBar {
| + | |
- | background-color: Menu;
| + | |
- | border-bottom: 1px solid ButtonShadow;
| + | |
- | }
| + | |
- | div.MenuBar a {
| + | |
- | background-color: Menu; /* Top-level unselected items. */
| + | |
- | color: MenuText;
| + | |
- | }
| + | |
- | div.MenuBar ul li:hover a,
| + | |
- | div.MenuBar ul li a:hover {
| + | |
- | color: #A3C0E0;
| + | |
- | background-color: Highlight; /* Top-level selected item. */
| + | |
- | color: HighlightText;
| + | |
- | }
| + | |
- | /*...............................................................................................*/
| + | |
- | div.MenuBar ul li:hover ul.DropDownMenu,
| + | |
- | div.MenuBar ul li a:hover ul.DropDownMenu {
| + | |
- | background-color: ButtonShadow; /* Sets the drop-down menu "effective border" color. */
| + | |
- | }
| + | |
- | div.MenuBar ul li:hover ul.DropDownMenu li a,
| + | |
- | div.MenuBar ul li a:hover ul.DropDownMenu li a {
| + | |
- | background-color: Menu; Drop-down menu unselected items.
| + | |
- | Sets the drop-down menu "effective background" color. */
| + | |
- | color: MenuText;
| + | |
- | }
| + | |
- | div.MenuBar ul li:hover ul.DropDownMenu li:hover a,
| + | |
- | div.MenuBar ul li a:hover ul.DropDownMenu li a:hover {
| + | |
- | background-color: Highlight; /* Drop-down menu selected item. */
| + | |
- | color: HighlightText;
| + | |
- | }
| + | |
- | /*...............................................................................................*/
| + | |
- | div.MenuBar ul li:hover ul.DropDownMenu li:hover ul.SideMenu,
| + | |
- | div.MenuBar ul li a:hover ul.DropDownMenu li a:hover ul.SideMenu {
| + | |
- | background-color: ButtonShadow; /* Sets the side menu "effective border" color. */
| + | |
- | }
| + | |
- | div.MenuBar ul li:hover ul.DropDownMenu li:hover ul.SideMenu li a,
| + | |
- | div.MenuBar ul li a:hover ul.DropDownMenu li a:hover ul.SideMenu li a {
| + | |
- | background-color: Menu; /* Side menu unselected items.
| + | |
- | Sets the side menu "effective background" color. */
| + | |
- | color: MenuText;
| + | |
- | }
| + | |
- | div.MenuBar ul li:hover ul.DropDownMenu li:hover ul.SideMenu li a:hover,
| + | |
- | div.MenuBar ul li a:hover ul.DropDownMenu li a:hover ul.SideMenu li a:hover {
| + | |
- | background-color: Highlight; /* Side menu selected item. */
| + | |
- | color: HighlightText;
| + | |
- | }
| + | |
- | /*-----------------------------------------------------------------------------------------------*/
| + | |
- | | + | |
- | /*-------------------------------------------------------------------------------------- General */
| + | |
- | body {
| + | |
- | background: white;
| + | |
- | color: black;
| + | |
- | margin: 0;
| + | |
- | border: 0;
| + | |
- | padding: 0;
| + | |
- | }
| + | |
- | | + | |
- | | + | |
- | div.MenuBar {
| + | |
- | font: 13px arial, helvetica, sans-serif;
| + | |
- | }
| + | |
- | div.MenuBar ul {
| + | |
- | font: 13px arial, helvetica, sans-serif; /* Required for IE55. */
| + | |
- | }
| + | |
- | /*--------------------------------------------------------------------------------------- Colors */
| + | |
- | div.MenuBar {
| + | |
- | background-color: #0064C8; /* Selected item. */
| + | |
- | color: #FFFFFF;
| + | |
- | border-bottom: 1px solid ButtonShadow;
| + | |
- | }
| + | |
- | div.MenuBar a,
| + | |
- | div.MenuBar ul li:hover ul.DropDownMenu li a,
| + | |
- | div.MenuBar ul li a:hover ul.DropDownMenu li a,
| + | |
- | div.MenuBar ul li:hover ul.DropDownMenu li:hover ul.SideMenu li a,
| + | |
- | div.MenuBar ul li a:hover ul.DropDownMenu li a:hover ul.SideMenu li a {
| + | |
- | background-color: #00446b; /* Selected item. */
| + | |
- | color: #FFFFFF;
| + | |
- | }
| + | |
- | div.MenuBar ul li:hover a,
| + | |
- | div.MenuBar ul li a:hover,
| + | |
- | div.MenuBar ul li:hover ul.DropDownMenu li:hover a,
| + | |
- | div.MenuBar ul li a:hover ul.DropDownMenu li a:hover,
| + | |
- | div.MenuBar ul li:hover ul.DropDownMenu li:hover ul.SideMenu li a:hover,
| + | |
- | div.MenuBar ul li a:hover ul.DropDownMenu li a:hover ul.SideMenu li a:hover {
| + | |
- | background-color: #A3C0E0; /* Selected item. */
| + | |
- | color: #FFFFFF;
| + | |
- | }
| + | |
- | div.MenuBar ul li:hover ul.DropDownMenu,
| + | |
- | div.MenuBar ul li a:hover ul.DropDownMenu,
| + | |
- | div.MenuBar ul li:hover ul.DropDownMenu li:hover ul.SideMenu,
| + | |
- | div.MenuBar ul li a:hover ul.DropDownMenu li a:hover ul.SideMenu {
| + | |
- | background-color: ButtonShadow; /* Sets the drop-down and side menus "effective border" color. */
| + | |
- | }
| + | |
- | /*--------------------------------------------------------------------------------------- Widths */
| + | |
- | /*
| + | |
- | | + | |
- | /*
| + | |
- | Menu Bar 1
| + | |
- | Drop-Down Menu #2
| + | |
- | */
| + | |
- | div.MenuBar#navi ul li:hover ul.DropDownMenu#MB1-DDM4,
| + | |
- | div.MenuBar#navi ul li a:hover ul.DropDownMenu#MB1-DDM4,
| + | |
- | div.MenuBar#navi ul li:hover ul.DropDownMenu#MB1-DDM4 li a,
| + | |
- | div.MenuBar#navi ul li a:hover ul.DropDownMenu#MB1-DDM4 li a {
| + | |
- | width: 15.5em; /* Drop-down menu width. */
| + | |
- | }
| + | |
- | div.MenuBar#navi ul li:hover ul.DropDownMenu#MB1-DDM5,
| + | |
- | div.MenuBar#navi ul li a:hover ul.DropDownMenu#MB1-DDM5,
| + | |
- | div.MenuBar#navi ul li:hover ul.DropDownMenu#MB1-DDM5 li a,
| + | |
- | div.MenuBar#navi ul li a:hover ul.DropDownMenu#MB1-DDM5 li a {
| + | |
- | width: 14em; /* Drop-down menu width. */
| + | |
- | }
| + | |
- | | + | |
- | /*...............................................................................................*/
| + | |
- | /*
| + | |
- | Menu Bar 1
| + | |
- | Drop-Down Menu #2
| + | |
- | Side Menu #1
| + | |
- | */
| + | |
- | div.MenuBar#navi ul li:hover ul.DropDownMenu li:hover ul.SideMenu#MB1-DDM2-SM1,
| + | |
- | div.MenuBar#navi ul li a:hover ul.DropDownMenu li a:hover ul.SideMenu#MB1-DDM2-SM1 {
| + | |
- | left: 15.5em !important; /* Places the side menu to the right of the drop-down menu.
| + | |
- | Keep it sync with the drop-down menu width. */
| + | |
- | }
| + | |
- | div.MenuBar#navi ul li:hover ul.DropDownMenu li:hover ul.SideMenu#MB1-DDM2-SM1,
| + | |
- | div.MenuBar#navi ul li a:hover ul.DropDownMenu li a:hover ul.SideMenu#MB1-DDM2-SM1,
| + | |
- | div.MenuBar#navi ul li:hover ul.DropDownMenu li:hover ul.SideMenu#MB1-DDM2-SM1 li a,
| + | |
- | div.MenuBar#navi ul li a:hover ul.DropDownMenu li a:hover ul.SideMenu#MB1-DDM2-SM1 li a {
| + | |
- | width: 15em; /* Side menu width. */
| + | |
- | }
| + | |
- | /*...............................................................................................*/
| + | |
- | /*
| + | |
- | Menu Bar 1
| + | |
- | Drop-Down Menu #2
| + | |
- | Side Menu #2
| + | |
- | */
| + | |
- | div.MenuBar#navi ul li:hover ul.DropDownMenu li:hover ul.SideMenu#MB1-DDM2-SM2,
| + | |
- | div.MenuBar#navi ul li a:hover ul.DropDownMenu li a:hover ul.SideMenu#MB1-DDM2-SM2 {
| + | |
- | left: 15.5em !important; /* Places the side menu to the right of the drop-down menu.
| + | |
- | Keep it sync with the drop-down menu width. */
| + | |
- | }
| + | |
- | div.MenuBar#navi ul li:hover ul.DropDownMenu li:hover ul.SideMenu#MB1-DDM2-SM2,
| + | |
- | div.MenuBar#navi ul li a:hover ul.DropDownMenu li a:hover ul.SideMenu#MB1-DDM2-SM2,
| + | |
- | div.MenuBar#navi ul li:hover ul.DropDownMenu li:hover ul.SideMenu#MB1-DDM2-SM2 li a,
| + | |
- | div.MenuBar#navi ul li a:hover ul.DropDownMenu li a:hover ul.SideMenu#MB1-DDM2-SM2 li a {
| + | |
- | width: 7em; /* Side menu width. */
| + | |
- | }
| + | |
- | /*...............................................................................................*/
| + | |
- | /*
| + | |
- | Menu Bar 1
| + | |
- | Drop-Down Menu #2
| + | |
- | Side Menu #3
| + | |
- | */
| + | |
- | div.MenuBar#navi ul li:hover ul.DropDownMenu li:hover ul.SideMenu#MB1-DDM2-SM3,
| + | |
- | div.MenuBar#navi ul li a:hover ul.DropDownMenu li a:hover ul.SideMenu#MB1-DDM2-SM3 {
| + | |
- | left: 15.5em !important; /* Places the side menu to the right of the drop-down menu.
| + | |
- | Keep it sync with the drop-down menu width. */
| + | |
- | }
| + | |
- | div.MenuBar#navi ul li:hover ul.DropDownMenu li:hover ul.SideMenu#MB1-DDM2-SM3,
| + | |
- | div.MenuBar#navi ul li a:hover ul.DropDownMenu li a:hover ul.SideMenu#MB1-DDM2-SM3,
| + | |
- | div.MenuBar#navi ul li:hover ul.DropDownMenu li:hover ul.SideMenu#MB1-DDM2-SM3 li a,
| + | |
- | div.MenuBar#navi ul li a:hover ul.DropDownMenu li a:hover ul.SideMenu#MB1-DDM2-SM3 li a {
| + | |
- | width: 17em; /* Side menu width. */
| + | |
- | }
| + | |
- | /*...............................................................................................*/
| + | |
- | | + | |
- | </style>
| + | |
- | | + | |
- | | + | |
- | | + | |
- | </p><html xmlns="http://www.w3.org/1999/xhtml" xml:lang="en" dir="ltr" lang="en"><head>
| + | |
- | <meta http-equiv="Content-Type" content="text/html; charset=UTF-8">
| + | |
- | <meta name="keywords" content="Team:Goettingen,Team:Goettingen,Team:Goettingen/Homing coli,Team:Goettingen/Human Practice/Flash coli,Team:Goettingen/Press,Team:Goettingen/Project/General information">
| + | |
- | <link rel="shortcut icon" href="https://2012.igem.org/favicon.ico">
| + | |
- | <link rel="search" type="application/opensearchdescription+xml" href="https://2012.igem.org/wiki/opensearch_desc.php" title="2012.igem.org (English)">
| + | |
- | <link title="Creative Commons" type="application/rdf+xml" href="https://2012.igem.org/wiki/index.php?title=Team:Goettingen&action=creativecommons" rel="meta">
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- | <a href="https://2012.igem.org/Team:Goettingen/Notebook" style="color: white;">Notebook<!--[if gt IE 6]><!--></a><!--<![endif]-->
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- | <a href="https://2012.igem.org/Team:Goettingen/iGEM" style="color: white;">iGEM<!--[if gt IE 6]><!--></a><!--<![endif]-->
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- | <li><a href="https://2012.igem.org/Team:Goettingen/iGEM"><span><span>What is iGEM?</span></span></a></li>
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- | <!--<li><a href="https://2012.igem.org/Team:Goettingen/BioBrick_System"><span><span>iGEM BioBrick System</span></span></a></li>
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- | <li><a href="https://2012.igem.org/Team:Goettingen/Part_Registry"><span><span>iGEM Part Registry</span></span></a></li> -->
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- | <li><a href="https://2012.igem.org/Team:Goettingen/Goettingen"><span><span>City</span></span></a></li>
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- | <li><a href="https://2012.igem.org/Team:Goettingen/Goettingen/University"><span><span>Georg-August-University</span></span></a></li>
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- | <li><a href="https://2012.igem.org/Team:Goettingen/Goettingen/MPI"><span><span>Max-Planck-Institute</span></span></a></li>
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- | <li><a href="https://2012.igem.org/Team:Goettingen/Goettingen/S1-Demo_Lab"><span><span>S1-Demo Lab</span></span></a></li>
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- | <li><a href="https://2012.igem.org/Team:Goettingen/Human_Practice"><span><span>Why Human Practice?</span></span></a></li>
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- | <li><a href="https://2012.igem.org/Team:Goettingen/Human_Practice/Public_and_Media"><span><span>Public and Media</span></span></a></li>
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- | <!--</li><li><a href="https://2012.igem.org/Team:Goettingen/Newspaper"><span><span><div style="text-indent:20px;">⋅ Newspaper</div></span></span></a></li>
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- | </li><li><a href="https://2012.igem.org/Team:Goettingen/Conference"><span><span><div style="text-indent:20px;">⋅ Conference</div></span></span></a></li>
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- | </li><li><a href="https://2012.igem.org/Team:Goettingen/Synthetic_Biology_Day"><span><span><div style="text-indent:20px;">⋅ Synthetic Biology Day</div></span></span></a></li> -->
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- | </ul>
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- | <!--[if lte IE 6]></td></tr></table></a><![endif]-->
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- | <a href="https://2012.igem.org/Team:Goettingen/Sponsoring" style="color: white;">Sponsoring</a>
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- | <li><a href="https://2012.igem.org/Team:Goettingen/Sponsoring"><span><span>Interested in...?</span></span></a></li>
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- | <!-- <li><a href="https://2012.igem.org/Team:Goettingen/Human_Practice/Sponsors"><span><span>Sponsors</span></span></a></li>
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- | </div>
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- | | + | |
- | | + | |
- | <table>
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- | <!-- Text body -->
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- | <tbody><tr valign="top" align="left">
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- | <font face="Verdana" size="-1">
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| <br> | | <br> |
- | Language: <img height="20", src="http://www.patrickreinke.de/igem/eng.jpg">English, <img height="20", src="http://www.patrickreinke.de/igem/deu.jpg"> <a href="https://2012.igem.org/Team:Goettingen/Project_deu">Deutsch</a> <br>
| + | The first group focuses on the creation of effective swimming motility assays. All kinds of different media and swimming agar |
| + | plates were to be tested, because fast <i>E. coli</i> can only show their potential under the right conditions. Furthermore, an |
| + | efficient selection system should be created in order to separate the fast <i>E. coli</i> from the slower ones and to test potential |
| + | attractants for our swimmers.<br> |
| <br> | | <br> |
- | | + | Creation of a fast strain represents the main task for the second group. The main question here is: which genes have the potential |
- | <table id="toc" class="toc"><tbody><tr><td><div id="toctitle"><h2>Contents</h2> <span class="toctoggle">[<a href="javascript:toggleToc()" class="internal" id="togglelink">hide</a>]</span></div>
| + | to make our <i>E. coli</i> faster and how do they need to be regulated to achieve this? Naturally, genes that code for parts of |
- | <ul> | + | the bacterial motor, the flagellum, were selected for testing as well as FlhDC, a master regulator for motility and chemotaxis. |
- | <li class="toclevel-1"><a href="#Our_Project"><span class="tocnumber">1</span> <span class="toctext">Our Project</span></a></li>
| + | The output is then measured as motility on the first group's swimming plates. <br> |
- | <li class="toclevel-1"> <a href="#Chemotaxis"><span class="tocnumber">2</span> <span class="tocnumber"></span> <span class="toctext">Chemotaxis</span></a></li>
| + | |
- | <li class="toclevel-1"><a href="#Poster"><span class="tocnumber">3</span> <span class="tocnumber"></span> <span class="toctext">Poster</span></a></li> | + | |
- | </ul>
| + | |
- | </td></tr></tbody></table>
| + | |
| <br> | | <br> |
- | | + | The last group focuses on the directed mutagenesis of the aspartate receptor Tar. Thereby, a library of numerous different and new Tar |
- | | + | receptors can be created. Some of these might exhibit the ability to recognize a specific substance of interest. <i>E. coli</i> |
- | | + | strains possessing such mutated receptors can then be screened for homing ability towards a selection of chemical compounds. <br> |
- | | + | |
- | | + | |
- | | + | |
- | | + | |
- | | + | |
- | <!-- Text body -->
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- | <tbody><tr valign="top" align="left">
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- | <td style="padding: 0pt 20px 0pt 0pt;" width="910px">
| + | |
- | <font face="Verdana" size="-1">
| + | |
- | <h2><b><a name="Our_Project"></a>Our Project</b></h2>
| + | |
- | <p align="justify" style="line-height:1.6em">
| + | |
- | Our project was born from the idea to create a real champion: the fastest <i>E. coli</i> in the world. As funny as this may sound at first, soon we were at the development of an ambitious plan to create our "Homing Coli" and apply its speed for selective purposes. The ultimate goal was a fast swimming <i>E. coli</i> strain which would be able to recognize specific molecules on a mutagenized receptor and head towards gradients of these substances on swimming agar plates. If this approach worked, it might be put to use for the recognition of various molecules such as pollutants, toxins or even cancer cell markers. As our planning moved on, we soon created three different focus groups which should work in parallel on the biggest and most crucial components of our project. <br>
| + | |
- | <br>
| + | |
- | The first group focuses on the creation of effective swimming motility assays. All kinds of different media and swimming agar plates were to be tested, because fast <i>E. coli</i> can only show their potential under the right conditions. Furthermore, an efficient selection system should be created in order to separate the fast <i>E. coli</i> from the slower ones and to test potential attractants for our swimmers. <br>
| + | |
- | <br>
| + | |
- | Creation of a fast strain represents the main task for the second group. The main question here is: which genes have the potential to make our <i>E. coli</i> faster and how do they need to be regulated to achieve this? Naturally, genes that code for parts of the bacterial motor, the flagellum, were selected for testing as well as <i>FlhDC</i>, a master regulator for motility and chemotaxis. The output is then measured as motility on the first group's swimming plates. <br>
| + | |
- | <br>
| + | |
- | The last group focuses on the directed mutagenesis of the aspartate receptor TAR. Thereby, a library of numerous different and new TAR receptors can be created. Some of these might exhibit the ability to recognize a specific substance of interest. <i>E. coli</i> strains possessing such mutated receptors can then be screened for homing ability towards a selection of chemical compounds. <br> | + | |
- | <br>
| + | |
- | These three groups would focus mostly on their separate projects during the early phases of lab-work and also plan their schedules independently to minimize frictional losses. But as time progresses and the first results are obtained the work of our focus groups overlaps more and more in order to achieve our ultimate goal: the creation of Homing Coli.
| + | |
- | </p>
| + | |
| <br> | | <br> |
| + | These three groups would focus mostly on their separate projects during the early phases of lab-work and also plan their schedules |
| + | independently to minimize frictional losses. But as time progresses and the first results are obtained the work of our focus groups |
| + | overlaps more and more in order to achieve our ultimate goal: the creation of Homing Coli.<br> |
| <br> | | <br> |
| | | |
- | <tbody><tr valign="top" align="left">
| + | == Chemotaxis == |
- | <tr valign="top" align="left">
| + | ===Sensing and the mechanism of chemotaxis=== |
- | <td style="padding: 0pt 20px 0pt 0pt;" width="910px">
| + | Chemotaxis is a phenomenon whereby cells or organisms direct their orientation or movement in relation to a gradient of |
- | <font face="Verdana" size="-1">
| + | chemical agents (Fig 1). These chemical agents are known as chemoattractants and chemorepellants, which are inorganic or |
- | <h2><b><a name="Chemotaxis"></a>Chemotaxis</b></h2>
| + | organic substances like amino acids and sugars. They are able to activate chemotaxis in motile cells. This chemotaxis behavior is |
- | <p align="justify" style="line-height:1.6em">
| + | triggered by binding of chemoattractants or chemorepellants to chemotaxis receptors such as the target of our iGEM project, the aspartate receptor Tar. |
| | | |
| + | [[File:Goe_chemo1.png|700px|thumb|center|<b>Figure 1: Chemotaxis of <i>E. coli</i>.</b> (a) When no attractant is present <i>E. coli</i> switches from direct swimming to tumbling randomly. (b) In the presence of an attractant <i>E. coli</i> moves through the gradient in the direction of the attractant. (Attractant gradient is shown in green.) ]] |
| | | |
| + | Chemotaxis is based on high-order intracellular signaling structures. |
| + | Clustered receptors in the cell wall of bacteria sense signals and mediate downstream signaling in the cell via associated |
| + | proteins in a highly cooperative manner [2]. These high-order intracellular signaling structures are also known as two-component systems. |
| | | |
- | <p align="justify" style="line-height:1.6em">
| + | [[File:Goe_chemo2neu.jpg|250px|thumb|<b>Figure 2: Schematic structure of a two-component system.</b> A histidine kinase (HK) serves as sensing structure for |
- | <table> | + | attractants or repellents and mediates downstream signaling to autokinase (red). The response regulator (RR) consists of a receiver |
- | <tr><td>
| + | (purple) and an output module (green) which if activated induces gene expression [2].]] |
- | <p align="justify" style="line-height:1.6em"><b>Sensing and the mechanism of chemotaxis</b><br>
| + | |
- | Chemotaxis is a phenomenon whereby cells or organisms direct their orientation or movement in relation to a gradient of chemical agents (Fig 1). These chemical agents are known as chemoattractants and chemorepellants, which are inorganic or organic substances like amino acids and sugars. They are able to activate chemotaxis in motile cells. This chemotaxis behavior is triggered by binding of chemoattractants or chemorepellants to chemotaxis receptors such as the target of our iGEM project, the aspartate receptor Tar.</p>
| + | |
- | </td></tr>
| + | |
| | | |
- | <tr><td> | + | A two-component system consists of a sensory histidine kinase and a phosphorylable |
- | <br> | + | response regulator [2] (Fig 1). Transfer of the phosphate group from a histidine residue of the kinase domain to an aspartate |
- | <img src="https://static.igem.org/mediawiki/2012/9/91/Goe_chemo1.png"><br> | + | residue of the response regulator activates the output domain. This normally results in activation of gene expression. <br><br> |
| + | Beside the aspect that the sensing in <i>E. coli</i> is coupled to flagella-based motion, the two-component system is more complex. |
| + | There are five histidine-kinase-associated chemotaxis receptors of <i>E. coli</i> known. The receptors are typically arranged as |
| + | a trimeric application of dimeric receptor subunits (trimers of dimers) that are spanning through the membrane. |
| + | The receptors are methyl-accepting chemotaxis proteins (MCPs) that are directly associated with CheA, a histidine autokinase |
| + | and CheW, an adaptor protein that couples CheA to the receptor protein. <br> |
| + | There are two conformational states of receptor kinases possible: the kinase-on and kinase-off state [3]. In kinase-off state the |
| + | counter-clockwise (CCW) rotation is active, which leads to forward swimming. In the kinase-on state CheA autophosphorylation is |
| + | activated due to repellent binding whereas in the kinase-off state autophosphorylation is inactive due to attractant binding (Fig 3). <br><br> |
| + | In the case of kinase-on state, the autophosphorylated CheA transfers a phosphate group to one of the two response regulators, |
| + | CheY and CheB.CheY is responsible for motor control by binding to the flagellar rotary motor. This results in clockwise (CW) rotation, |
| + | which is visible as random directional movement. CheZ, a phosphatase, dephosphorylates CheY to keep random movement low (Fig 3). <br><br> |
| + | The methylesterase CheB and methyltransferase CheR are counterplayers in sensory adaptation. Here, the MCPs play a crucial role. |
| + | Both MCP sites have glutamines in their structure. These are functional mimics of methyl glutamates. In the case of CheB |
| + | is bound to a phosphate group from CheA, it mediates deamidation of glutamines to methyl-accepting glutamates. Therefore the |
| + | receptor is in the off-state with a high attractant affinity and it is likely to be methylated but not demethylated [3]. Because |
| + | the kinetics of methylation and demethylation are relatively slow, adaptation can take tens to hundreds of seconds [2].<br><br> |
| + | All in all, <i>E. coli</i> switches from tumbling to swimming when it is surrounded by a gradient of attractants. Increased |
| + | attractant stimulation results in both, terminating tumbling and activation of swimming towards the attractants [2].<br> |
| | | |
- | <b>Figure 1 Chemotaxis of E. coli. (a) When no attractant is present E. coli switches from direct swimming to tumbling randomly. (b) In the presence of an attractant E. coli moves through the gradient in the direction of the attractant. (Attractant gradient is shown in green.) [1]<br><br></b> | + | [[File:Goe_chemo3.png|500px|thumb|center|<b>Figure 3: Molecular mechanism of tumbling and swimming.</b> Activated CheA transfers a phosphate group to CheY |
- | </td></tr>
| + | thus activating clockwise (CW) rotation which leads <i>E. coli</i> tumble. CheZ dephosphorylates CheY to activate counter-clockwise |
| + | (CCW) flagella rotation that results in swimming.]] |
| | | |
| + | [[File:Goe_chemo4.png|500px|thumb|center|<b>Figure 4: Structure of <i>E. coli</i> chemoreceptor Tar.</b> Left: Ribbon diagram and chematic show of the 3D structure of Tar [3]. |
| + | Right: Detail view of the 3D structure ligand binding domain of Tar (PDB file: 1WAT).]] |
| | | |
| + | ===Tar chemoreceptor of <i>E. coli</i>=== |
| + | The aspartate receptor Tar (taxis to aspartate and repellents) is one member of five classical methyl-accepting chemotaxis proteins |
| + | in <i>E. coli</i> (Aer, Tar, Tsr, Trg and Tap) that mediate chemotactic response. The whole chemoreceptor is build of three parts: |
| + | a transmembrane sensing domain, a signal conversion domain and a kinase control domain (Fig 4). The transmembrane sensing domain of |
| + | Tar is a four helix bundle where one bundle consists of two antiparallel helices [3]. <br><br> |
| + | Tar is able to sense aspartate in a high sensitive manner and a lower sensitivity for glutamate and other compounds is |
| + | known [3]. The ligand binding site involves some aminoacid residues of four helices. Binding of the ligand causes a |
| + | conformational change. The signal is then transmitted across the membrane through the signal conversion domain to the |
| + | kinase control domain (Koshland <i>et al.</i>, 2001) which leads to flagellar motion.<br><br> |
| | | |
- | <tr><td>
| + | === Sensory molecules === |
- | <p align="justify" style="line-height:1.6em">Chemotaxis is based on high-order intracellular signaling structures. Clustered receptors in the cell wall of bacteria sense signals and mediate downstream signaling in the cell via associated proteins in a highly cooperative manner [2]. These high-order intracellular signaling structures are also known as two-component systems. </p>
| + | Sensory molecules are organic or inorganic agents that can be divided into two groups: chemoattractants and chemorepellents. |
- | </td></tr>
| + | Chemoattractants are molecules like aminoacids, organic or inorganic acids, small peptides or chemokines. They induce the active |
- | </table>
| + | motion of the bacteria towards the highest concentration of the attractant (Fig 5). |
- | | + | |
- | | + | |
- | <table>
| + | |
- | <tr><td width="170">
| + | |
- | <br><img src="https://static.igem.org/mediawiki/2012/d/d8/Goe_chemo2.png">
| + | |
- | </td><td width="370">
| + | |
- | <b>Figure 2: Schematic structure of a two-component system. A histidine kinase (HK) serves as sensing structure for attractants or repellents and mediates downstream signaling to autokinase (red). The response regulator (RR) consists of a receiver (purple) and an output module (green) which if activated induces gene expression [2].</b>
| + | |
- | <br><br></td></tr>
| + | |
- | </table>
| + | |
- | | + | |
- | | + | |
- | | + | |
- | <table>
| + | |
- | <tr><td>
| + | |
- | <p align="justify" style="line-height:1.6em">A two-component system consists of a sensory histidine kinase and a phosphorylable response regulator [2] (Fig 1). Transfer of the phosphate group from a histidine residue of the kinase domain to an aspartate residue of the response regulator activates the output domain. This normally results in activation of gene expression. <br><br>
| + | |
- | Beside the aspect that the sensing in E. coli is coupled to flagella-based motion, the two-component system is more complex. There are five histidine-kinase-associated chemotaxis receptors of E. coli known. The receptors are typically arranged as a trimeric application of dimeric receptor subunits (trimers of dimers) that are spanning through the membrane. The receptors are methyl-accepting chemotaxis proteins (MCPs) that are directly associated with CheA, a histidine autokinase and CheW, an adaptor protein that couples CheA to the receptor protein. <br>
| + | |
- | There are two conformational states of receptor kinases possible: the kinase-on and kinase-off state [3]. In kinase-off state the counter-clockwise (CCW) rotation is active, which leads to forward swimming. In the kinase-on state CheA autophosphorylation is activated due to repellent binding whereas in the kinase-off state autophosphorylation is inactive due to attractant binding (Fig 3). <br><br>
| + | |
- | In the case of kinase-on state, the autophosphorylated CheA transfers a phosphate group to one of the two response regulators,CheY and CheB.CheY is responsible for motor control by binding to the flagellar rotary motor. This results in clockwise (CW) rotation, which is visible as random directional movement. CheZ, a phosphatase, dephosphorylates CheY to keep random movement low (Fig 3). <br><br>
| + | |
- | The methylesterase CheB and methyltransferase CheR are counterplayers in sensory adaptation. Here, the MCPs play a crucial role. Both MCP sites have glutamines in their structure. These are functional mimics of methyl glutamates. In the case of CheB is bound to a phosphate group from CheA, it mediates deamidation of glutamines to methyl-accepting glutamates. Therefore the receptor is in the off-state with a high attractant affinity and it is likely to be methylated but not demethylated [3]. Because the kinetics of methylation and demethylation are relatively slow, adaptation can take tens to hundreds of seconds [2].<br><br>
| + | |
- | All in all, E. coli switches from tumbling to swimming when it is surrounded by a gradient of attractants. Increased attractant stimulation results in both, terminating tumbling and activation of swimming towards the attractants [2].<br>
| + | |
- | </p>
| + | |
- | </td></tr>
| + | |
- | | + | |
- | <tr><td>
| + | |
- | <br><img width="800" src="https://static.igem.org/mediawiki/2012/2/29/Goe_chemo3.png"><br>
| + | |
- | <b>Figure 3: Molecular mechanism of tumbling and swimming. Activated CheA transfers a phosphate group to CheY thus activating clockwise (CW) rotation which leads E. coli tumble. CheZ dephosphorylates CheY to activate counter-clockwise (CCW) flagella rotation that results in swimming.</b><br>
| + | |
- | <br></td></tr>
| + | |
- | | + | |
- | <tr><td>
| + | |
- | <br><img width="800" src="https://static.igem.org/mediawiki/2012/b/b6/Goe_chemo4.png"><br>
| + | |
- | <b>Figure 4: Structure of E. coli chemoreceptor Tar. Left: Ribbon diagram and chematic show of the 3D structure of Tar [3]. Right: Detail view of the 3D structure ligand binding domain of Tar (PDB file: 1WAT).</b>
| + | |
- | <br></td></tr>
| + | |
- | | + | |
- | <tr><td>
| + | |
- | <b>Tar chemoreceptor of E. coli</b><br>
| + | |
- | The aspartate receptor Tar (taxis to aspartate and repellents) is one member of five classical methyl-accepting chemotaxis proteins in E. coli (Aer, Tar, Tsr, Trg and Tap) that mediate chemotactic response. The whole chemoreceptor is build of three parts: a transmembrane sensing domain, a signal conversion domain and a kinase control domain (Fig 4). The transmembrane sensing domain of Tar is a four helix bundle where one bundle consists of two antiparallel helices [3]. <br><br>
| + | |
- | Tar is able to sense aspartate in a high sensitive manner and a lower sensitivity for glutamate and other compounds is known [3]. The ligand binding site involves some aminoacid residues of four helices. Binding of the ligand causes a conformational change. The signal is then transmitted across the membrane through the signal conversion domain to the kinase control domain (Koshland et al. 2001) which leads to flagellar motion.<br><br>
| + | |
- | | + | |
- | <b>Sensory molecules</b><br>
| + | |
- | Sensory molecules are organic or inorganic agents that can be divided into two groups: chemoattractants and chemorepellents. Chemoattractants are molecules like aminoacids, organic or inorganic acids, small peptides or chemokines. They induce the active motion of the bacteria towards the highest concentration of the attractant (Fig 5). | + | |
| Chemorepellents have a danger signaling function. If bacteria recognize repellents, they swim away from the source of repellents (Fig 5). <br><br> | | Chemorepellents have a danger signaling function. If bacteria recognize repellents, they swim away from the source of repellents (Fig 5). <br><br> |
- | Sensory molecules can be recognized by various receptors. E. coli has five of these receptors: Aer for sensing oxygen, Tar for sensing aspartate and repellents, Tsr for sensing serine and repellents, Trg for sensing ribose and galactose and Tap for sensing dipeptides. Rreceptors are able to mediate taxis to other sensory molecules as well but with lower affinity. Therefore we try to find new recpetors by mutagenesis of the sensory molecule binding site of Tar. | + | Sensory molecules can be recognized by various receptors. <i>E. coli</i> has five of these receptors: Aer for sensing |
| + | oxygen, Tar for sensing aspartate and repellents, Tsr for sensing serine and repellents, Trg for sensing ribose and galactose |
| + | and Tap for sensing dipeptides. Receptors are able to mediate taxis to other sensory molecules as well but with lower affinity. |
| + | Therefore, we try to find new recpetors by mutagenesis of the sensory molecule binding site of Tar. |
| | | |
- | </td></tr> | + | [[File:Goe_chemo5.png|800px|thumb|center|<b>Figure 5: Reaction of <i>E. coli</i> to chemoattractants and chemorepellents.</b> <i>E. coli</i> swims |
| + | towards the highest concentration of the chemoattractant or away from the highest concentration of the chemorepellent.]] |
| | | |
- | | + | Sources:<br> |
- | <tr><td>
| + | [1] Madigan M. T., Martinko J. M., Stahl D. A., Clark D. P. (2012). Brock Microbiology. Vol. 13. Pearson, San Francisco, 78 – 80<br> |
- | <br><img width="800" src="https://static.igem.org/mediawiki/2012/3/30/Goe_chemo5.png"><br>
| + | [2] Sourjik V., Armitage J. P. (2010). Spatial organization in bacterial chemotaxis. EMBO J. 29:16, 2724 - 2733<br> |
- | <b>Figure 5: Reaction of E. coli to chemoattractants and chemorepellents. E. coli swims towards the highest concentration of the chemoattractant or away from the highest concentration of the chemorepellent.</b>
| + | [3] Hazelbauer G. L., Falke J. J., Parkinson J. S. (2008). Bacterial chemoreceptors: high-performance signaling in networked arrays. Trends Biochem Sci. 33:1, 9 - 19<br> |
- | <br></td></tr>
| + | |
- | | + | |
- | | + | |
- | <tr><td>
| + | |
- | [1] Madigan M. T., Martinko J. M., Stahl D. A., Clark D. P. (2012). Brock Microbiology. Vol. 13. Pearson, San Francisco, pp. 78 – 80.<br> | + | |
- | [2] Sourjik V., Armitage J. P. (2010). Spatial organization in bacterial chemotaxis. EMBO J.<br> | + | |
- | [3] Hazelbauer G. L., Falke J. J., Parkinson J. S. (2008). Bacterial chemoreceptors: high-performance signaling in networked arrays. Trends Biochem Sci. <br> | + | |
- | [4] Koshland<br>
| + | |
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Chemotaxis is a phenomenon whereby cells or organisms direct their orientation or movement in relation to a gradient of
chemical agents (Fig 1). These chemical agents are known as chemoattractants and chemorepellants, which are inorganic or
organic substances like amino acids and sugars. They are able to activate chemotaxis in motile cells. This chemotaxis behavior is
triggered by binding of chemoattractants or chemorepellants to chemotaxis receptors such as the target of our iGEM project, the aspartate receptor Tar.
Chemotaxis is based on high-order intracellular signaling structures.
Clustered receptors in the cell wall of bacteria sense signals and mediate downstream signaling in the cell via associated
proteins in a highly cooperative manner [2]. These high-order intracellular signaling structures are also known as two-component systems.
A two-component system consists of a sensory histidine kinase and a phosphorylable
response regulator [2] (Fig 1). Transfer of the phosphate group from a histidine residue of the kinase domain to an aspartate
residue of the response regulator activates the output domain. This normally results in activation of gene expression.
Beside the aspect that the sensing in E. coli is coupled to flagella-based motion, the two-component system is more complex.
There are five histidine-kinase-associated chemotaxis receptors of E. coli known. The receptors are typically arranged as
a trimeric application of dimeric receptor subunits (trimers of dimers) that are spanning through the membrane.
The receptors are methyl-accepting chemotaxis proteins (MCPs) that are directly associated with CheA, a histidine autokinase
and CheW, an adaptor protein that couples CheA to the receptor protein.
There are two conformational states of receptor kinases possible: the kinase-on and kinase-off state [3]. In kinase-off state the
counter-clockwise (CCW) rotation is active, which leads to forward swimming. In the kinase-on state CheA autophosphorylation is
activated due to repellent binding whereas in the kinase-off state autophosphorylation is inactive due to attractant binding (Fig 3).
In the case of kinase-on state, the autophosphorylated CheA transfers a phosphate group to one of the two response regulators,
CheY and CheB.CheY is responsible for motor control by binding to the flagellar rotary motor. This results in clockwise (CW) rotation,
which is visible as random directional movement. CheZ, a phosphatase, dephosphorylates CheY to keep random movement low (Fig 3).
The methylesterase CheB and methyltransferase CheR are counterplayers in sensory adaptation. Here, the MCPs play a crucial role.
Both MCP sites have glutamines in their structure. These are functional mimics of methyl glutamates. In the case of CheB
is bound to a phosphate group from CheA, it mediates deamidation of glutamines to methyl-accepting glutamates. Therefore the
receptor is in the off-state with a high attractant affinity and it is likely to be methylated but not demethylated [3]. Because
the kinetics of methylation and demethylation are relatively slow, adaptation can take tens to hundreds of seconds [2].
All in all, E. coli switches from tumbling to swimming when it is surrounded by a gradient of attractants. Increased
attractant stimulation results in both, terminating tumbling and activation of swimming towards the attractants [2].
The aspartate receptor Tar (taxis to aspartate and repellents) is one member of five classical methyl-accepting chemotaxis proteins
in E. coli (Aer, Tar, Tsr, Trg and Tap) that mediate chemotactic response. The whole chemoreceptor is build of three parts:
a transmembrane sensing domain, a signal conversion domain and a kinase control domain (Fig 4). The transmembrane sensing domain of
Tar is a four helix bundle where one bundle consists of two antiparallel helices [3].
Tar is able to sense aspartate in a high sensitive manner and a lower sensitivity for glutamate and other compounds is
known [3]. The ligand binding site involves some aminoacid residues of four helices. Binding of the ligand causes a
conformational change. The signal is then transmitted across the membrane through the signal conversion domain to the
kinase control domain (Koshland et al., 2001) which leads to flagellar motion.
Sensory molecules are organic or inorganic agents that can be divided into two groups: chemoattractants and chemorepellents.
Chemoattractants are molecules like aminoacids, organic or inorganic acids, small peptides or chemokines. They induce the active
motion of the bacteria towards the highest concentration of the attractant (Fig 5).
Chemorepellents have a danger signaling function. If bacteria recognize repellents, they swim away from the source of repellents (Fig 5).
Sensory molecules can be recognized by various receptors. E. coli has five of these receptors: Aer for sensing
oxygen, Tar for sensing aspartate and repellents, Tsr for sensing serine and repellents, Trg for sensing ribose and galactose
and Tap for sensing dipeptides. Receptors are able to mediate taxis to other sensory molecules as well but with lower affinity.
Therefore, we try to find new recpetors by mutagenesis of the sensory molecule binding site of Tar.