Team:Uppsala University

From 2012.igem.org

(Difference between revisions)

Latest revision as of 02:25, 27 October 2012

Team Uppsala University – iGEM 2012

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... and that's how resistance is futile!

The Problem The first half of the 20th century saw a revolution in the treatment of one of the major curses of mankind: pathogenic microorganisms. After the invention of first sulfa and later penicillin, through the fourties, fifties and sixties a large number of antibiotic drugs were quickly found. The age when many bacterial infections meant life-threatening epidemics were soon forgotten, as illnesses could now be cured by a few days with antibiotics. During the sixties and seventies, bacterial infections was largely considered to be a solved problem in the western world, and drug researchers turned to other areas. However, evolution is a more powerful force than one can imagine, and soon the bacterias got the upper hand. In later years, it has become clear that bacterial resistance is spreading at a faster rate than anyone could imagine. Between the seventies and late nineties, no new classes of antibiotics were launched, while usage of antibiotics continued at an ever increasing rate. This created an ideal enviroment for antibiotic resistance to spread. Today, it is estimated that, in the EU alone, 25 000 patients die yearly of multidrug resistant infections, which also increase health care costs by over 1.5 billion euro per year. Antibiotic research has been given higher priority in academic institutions over the last decade, but it is clear that drug development is and has been stalled for a long time. But do we really have to give up classic antibiotic drugs? Team Uppsala University 2012 begs to differ. We believe that new knowledge about bacterial regulatory mechanisms can enable us to once again turn resistant bacteria sensitive to classic antibiotics. This summer, we decided to show it.		Achivements Working small RNAs! Constructed small RNAs that can downregulate antibiotic resistance. Read more Improved existing parts Improved standard plasmid backbones from the low copy pSB4X series. Read more Characterized promoters Characterized several promoters and their respective promoter strengths. Read more Helped other teams Our BioBricks have been requested by many iGEM teams. Read more New BioBricks Constructed several new BioBricks and characterized them. Read more Gained experience Had a great summer while working with our iGEM project. Read more


Silencing sRNA We have developed a modular screening system and protocol for finding silencing sRNAs against arbitrary genes. Using this, we have found strongly silencing sRNAs against a clinical antibiotic gene and lowered the minimal inhibatory concentration tenfold in resistant bacteria. Read more...	New backbones We have constructed a range of new standard low copy backbones, and variants with built-in lacIq repression for tight control of toxic genes, thermosensitivity and FRT sites for removing resistance cassettes. This work was done as it turned out that the common registry pSB4 backbones all have faulty copy number regulation, while we needed low copy backbones for out project. Read more...	Chromoproteins Proteins with a visible intrinsic color are the simplest possible reporters in molecular biology. Most iGEMers are familiar with the Red Flourescent Protein (RFP), but there are many other colors available among the organisms of the world. We have characterized and submitted new chromoproteins, allowing multiplexed colorful reporters. Read more...

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-<h2>Project description</h2>
+<h2>The Problem</h2>
 <div id="desc">
-<p>Team Uppsala University 2012 is dedicated to combating the rising antibiotic resistance in bacteria by means of synthetic biology. Old and well-known antibiotics are quickly becoming ineffective as resistance genes are spreading. Scientist around the world struggle with varying success to develop new antibacterial substances. But do we really have to abandon classic antibiotics? Team Uppsala University begs to differ, we believe new methods will allow us to combat the resistance itself, and make the bacteria once again sensitive to old drugs.</p>
+<p>The first half of the 20th century saw a revolution in the treatment of one of the major curses of mankind: pathogenic microorganisms. After the invention of first sulfa and later penicillin, through the fourties, fifties and sixties a large number of antibiotic drugs were quickly found. The age when many bacterial infections meant life-threatening epidemics were soon forgotten, as illnesses could now be cured by a few days with antibiotics. During the sixties and seventies, bacterial infections was largely considered to be a solved problem in the western world, and drug researchers turned to other areas. </p><p>
-<p>Working with real-world resistance genes isolated from ESBL outbreaks at Swedish hospitals, we are developing anti-resistance systems active at three different levels: DNA level, transcriptional level and translational level. Our systems will be delivered to the target bacteria using an engineered phage and/or a conjugative plasmid.</p>
-<p>At DNA level, we will develop a method for permanent removal of plasmids from bacteria. Using TAL Effector Nucleases, we will be able to target and cut individual resistance genes.</p>
+However, evolution is a more powerful force than one can imagine, and soon the bacterias got the upper hand. In later years, it has become clear that bacterial resistance is spreading at a faster rate than anyone could imagine. Between the seventies and late nineties, no new classes of antibiotics were launched, while usage of antibiotics continued at an ever increasing rate. This created an ideal enviroment for antibiotic resistance to spread. </p><p>
-<p>At transcriptional level, we will use synthetic super-repressors to repress transcription of resistance genes and native defense mechanisms in bacteria.</p>
-<p>At translational level, we will construct a modular large-scale screening system for sRNA:s and use it to find strongly silencing RNA sequences against three common resistance genes.</p>
+Today, it is estimated that, in the EU alone, 25 000 patients die yearly of multidrug resistant infections, which also increase health care costs by over 1.5 billion euro per year. Antibiotic research has been given higher priority in academic institutions over the last decade, but it is clear that drug development is and has been stalled for a long time.</p><p>
-<p>With this team on the project, there is no question about it: <b>Resistance is futile!</b></p>
+But do we really have to give up classic antibiotic drugs? Team Uppsala University 2012 begs to differ. We believe that new knowledge about bacterial regulatory mechanisms can enable us to once again turn resistant bacteria sensitive to classic antibiotics. This summer, we decided to show it.
+</p>
 </td>
 <td  valign="top">
 <h2>Achivements</h2>
 <div id="news">
-<b>Working smallRNA!</b><br>
-Constructed smallRNA downregulating antibiotic resistance.<br><b><a href="https://2012.igem.org/Team:Uppsala_University/Translational">Read more</a> </b>
+<b>Working small RNAs!</b><br>
+Constructed small RNAs that can downregulate antibiotic resistance.
+<a href="https://2012.igem.org/Team:Uppsala_University/Translational">Read more</a>
 <hr>
-<b>Improved existing part</b><br>
-Improved standard plasmid backbones from the 4 series. <br>
+<b>Improved existing parts</b><br>
+Improved standard plasmid backbones from the low copy pSB4X series.
 <a href="https://2012.igem.org/Team:Uppsala_University/Backbones">Read more</a>
 <hr>
-<b>Cool new biobricks</b><br>
-Made several biobricks and new applications for them, demonstrated how they worked and characterized them</a>.
+<b>Characterized promoters</b><br>
+Characterized several promoters and their respective promoter strengths.
+<a href="https://2012.igem.org/Team:Uppsala_University/Promoters">Read more</a>
 <hr>
-<b>Helped other teams.</b><br>
-By sending several of oour constructed biobrick parts to other teams. <br>
+<b>Helped other teams</b><br>
+Our BioBricks have been requested by many iGEM teams.
 <a href="https://2012.igem.org/Team:Uppsala_University/Collaborations">Read more</a>
 <hr>
-<b>Characterization of promotors</b><br>
-Measured several different promotors to gain better understand of promotor choice.
+<b>New BioBricks</b><br>
+Constructed several new BioBricks and characterized them.
+<a href="https://2012.igem.org/Team:Uppsala_University/Parts">Read more</a>
+<hr>
+<b>Gained experience</b><br>
+Had a great summer while working with our iGEM project.
+<a href="https://2012.igem.org/Team:Uppsala_University/Notebook">Read more</a>
 </div>
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-<img id="topimage" src="https://static.igem.org/mediawiki/2012/9/92/Srnahead.png" height="100">
+<img id="topimage" src="https://static.igem.org/mediawiki/2012/9/92/Srnalogo.png" height="100">
 </td>
 <td id="first">
-<img id="topimage" src="https://static.igem.org/mediawiki/2012/4/41/Backbones.png" height="100">
+<img id="topimage" src="https://static.igem.org/mediawiki/2012/0/05/PEL4X15_temp.png" height="100">
 </td>
 <td id="first">
@@ Line 191: / Line 205: @@
 <td style="vertical-align: top">
 <h2>Silencing sRNA</h2>
-<p id="second">We have developed a modular screening system and protocol for finding silencing sRNA:s against arbitrary genes. Using this, we have found a strongly silencing sRNA:s against a clinical antibiotic gene and lowered the minimary inhibatory concentration five-fold in resistant bacteria.
+<p id="second">We have developed a modular screening system and protocol for finding silencing sRNAs against arbitrary genes. Using this, we have found strongly silencing sRNAs against a clinical antibiotic gene and lowered the minimal inhibatory concentration tenfold in resistant bacteria.
 </p>
-<p id="more"><a href="/Team:Uppsala_University/Translational">Read more...</a>
+<p id="more"><a href="/Team:Uppsala_University/Project#sRNA">Read more...</a>
 </td>
 <td style="vertical-align: top">
-<h2>New Backbones</h2>
+<h2>New backbones</h2>
-<p id="second">We have constructed a range of new standard low copy backbones, and variants with built-in lacIq repression for tight control of toxic genes, thermosensitivity and FRT sites for removing resistance cassettes. This work was induced as it turned out that the common registry pSB4 backbones all have a faulty copy number regulation, while we needed low copy backbones for out project.</p>
+<p id="second">We have constructed a range of new standard low copy backbones, and variants with built-in lacIq repression for tight control of toxic genes, thermosensitivity and FRT sites for removing resistance cassettes. This work was done as it turned out that the common registry pSB4 backbones all have faulty copy number regulation, while we needed low copy backbones for out project.</p>
 <p id="more"><a href="/Team:Uppsala_University/Backbones">Read more...</a></p>
 </td>
 <td style="vertical-align: top">
 <h2>Chromoproteins</h2>
-<p id="second">Proteins with an visible intrinsic color are the simplest possible reporters i molecular biology. Most iGEM:ers are familiar with the Red Flourescent Protein (RFP), but there are many other colors aviable among all organism of the world. We have characterized and submitted new chromoproteins, allowing multiplexed colorful reporters. </p>
+<p id="second">Proteins with a visible intrinsic color are the simplest possible reporters in molecular biology. Most iGEMers are familiar with the Red Flourescent Protein (RFP), but there are many other colors available among the organisms of the world. We have characterized and submitted new chromoproteins, allowing multiplexed colorful reporters. </p>
 <p id="more"><a href="/Team:Uppsala_University/Chromoproteins">Read more...</a></div>
 </td>

Team:Uppsala University

From 2012.igem.org

Latest revision as of 02:25, 27 October 2012

The Problem

Achivements

Silencing sRNA

New backbones

Chromoproteins

Sponsors