Difference between revisions of "Team:Yale/notebook"

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     <div id="week6" data-reveal="" aria-labelledby="iGEM Modal" aria-hidden="true" role="dialog" class="reveal-modal grayModal">
 
     <div id="week6" data-reveal="" aria-labelledby="iGEM Modal" aria-hidden="true" role="dialog" class="reveal-modal grayModal">
 
       <h2 class="modal__title">Lessons from Week 5</h2>
 
       <h2 class="modal__title">Lessons from Week 5</h2>
       <p>Today, we're visiting a museum.</p>
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       <p>This week was centered on characterizing Rhizobia and cyanobacteria, PCR amplifying promoters and citrine, and transforming our plasmids of interest into cyanobacteria and E. coli.</p>
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      <p>For Rhizobia (Sinorhizobium meliloti 1021 strains 356, 370, 371 and Rhizobium tropici CIAT 899), we began antibiotic (rifampicin) and growth assays. The purpose of the rifampicin assays was to determine the antibiotic concentrations our Rhizobial strains were naturally resistant to; we would then be able to use an effective amount for strain selection (MAGE, transformations, etc). The growth assays were conducted to figure out the mid-log concentrations and doubling times of the Rhizobia strains. With this information, we could optimize our Rhizobia electroporation protocols—incubation periods and recovery times. Unfortunately, we encountered technical errors with our growth assays so these must be repeated next week.</p>
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      <p>For cyanobacteria, we worked on adjusting the pH of our growing media to standardize growth conditions (pH = 8.5). We were able to successfully grow Synechococcus PCC 7002 in ATCC 1047 media; it took around five days to reach a semi-confluent growing stage. We also continued to look into the efficiency of cyanobacterial growth under CO2 conditions, which according to literature, should be optimized in 3% CO2. According to our growth assays, cyanobacteria seems to be the most sensitive to OD 730, so this is the OD we will use for our future assays.</p>
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      <p>We were able to PCR amplify three rhizobium-specific inducible promoters: melA, bacA, and nodF. We also have the Anderson constitutive promoters from the iGEM registry, which we will use for both cyanobacteria and Rhizobia. For both organisms, we started amplifying our control genes of interest (GFP for Rhizobia, citrine for cyanobacteria) with overhangs to the promoters.</p>
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      <p>Much of our transformations this week were in preparation for Exonuclease and Ligation Independent Cloning (ELIC) or for amplification of broad host range plasmids into E. coli. We are considering using ELIC as a backup or more efficient alternative to Gibson assembly. For ELIC, we chose to work with the plasmid pZE21G as a control experiment; this plasmid along with the chromoprotein amilCP should be able to be successfully assembled. Additionally, we have been experimenting with natural transformation in cyanobacteria and are still waiting for the transformation cultures to grow up more before forming conclusions. Regarding electroporation in E. coli, we are still troubleshooting transformations with our two main plasmids pKT230 and k125000.</p>
 
       <p class="text-center"><img src="http://client.cameronyick.us/igem/assets/img/journal/pigeon.jpg"></p>
 
       <p class="text-center"><img src="http://client.cameronyick.us/igem/assets/img/journal/pigeon.jpg"></p>
      <p>Biofilm formation on surfaces is an issue in the medical field, naval industry, and other areas. We developed an anti-fouling peptide with two modular components: a mussel adhesion protein (MAP) anchor and LL-37, an antimicrobial peptide. MAPs can selectively attach to metal and organic surfaces via L-3,5-dihydroxyphenylalanine (L-DOPA), a nonstandard amino acid that was incorporated using a genetically recoded organism (GRO). Because this peptide is toxic to the GRO in which it is produced, we designed a better controlled inducible system that limits basal expression. This was achieved through a novel T7 riboregulation system that controls expression at both the transcriptional and translational levels.</p>
 
      <p>Biofilm formation on surfaces is an issue in the medical field, naval industry, and other areas. We developed an anti-fouling peptide with two modular components: a mussel adhesion protein (MAP) anchor and LL-37, an antimicrobial peptide. MAPs can selectively attach to metal and organic surfaces via L-3,5-dihydroxyphenylalanine (L-DOPA), a nonstandard amino acid that was incorporated using a genetically recoded organism (GRO). Because this peptide is toxic to the GRO in which it is produced, we designed a better controlled inducible system that limits basal expression. This was achieved through a novel T7 riboregulation system that controls expression at both the transcriptional and translational levels.</p>
 
 
       <p class="text-center"><a href="dropbox.com/#week6" class="file__link">Go to the Lab Notebook</a></p>
 
       <p class="text-center"><a href="dropbox.com/#week6" class="file__link">Go to the Lab Notebook</a></p>
 
       <h4 class="week_log">Entry for week<a href="#" data-reveal-id="week1">-1</a><a href="#" data-reveal-id="week2">1</a><a href="#" data-reveal-id="week3">2</a><a href="#" data-reveal-id="week4">3</a><a href="#" data-reveal-id="week5">4</a><a href="#" data-reveal-id="week6">5</a><a href="#" data-reveal-id="week7">6</a><a href="#" data-reveal-id="week8">7</a><a href="#" data-reveal-id="week9">8</a><a href="#" data-reveal-id="week10">9</a><a href="#" data-reveal-id="week11">10</a><a href="#" data-reveal-id="week12">10+</a>
 
       <h4 class="week_log">Entry for week<a href="#" data-reveal-id="week1">-1</a><a href="#" data-reveal-id="week2">1</a><a href="#" data-reveal-id="week3">2</a><a href="#" data-reveal-id="week4">3</a><a href="#" data-reveal-id="week5">4</a><a href="#" data-reveal-id="week6">5</a><a href="#" data-reveal-id="week7">6</a><a href="#" data-reveal-id="week8">7</a><a href="#" data-reveal-id="week9">8</a><a href="#" data-reveal-id="week10">9</a><a href="#" data-reveal-id="week11">10</a><a href="#" data-reveal-id="week12">10+</a>

Revision as of 12:43, 16 September 2015


<!DOCTYPE html> Yale iGem 2015: Notebook

Lab Notebook