Difference between revisions of "Team:Yale/notebook"

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       <p>This week, we focused on obtaining and using new plasmids, pKT230  and pZE21G, because our prior plasmid, BBa_K125000 was causing various problems, from being improperly annotated online to stubbornly refusing to be isolated using a maxi prep. However, very little actual lab work was done this week. In regards to non-lab work, we researched and described a way to knock out the mutS gene in both Cyanobacteria and Rhizobia and explored the possibility of also porting a CRISPR/Cas9 system into Cyanobacteria or Rhizobia.</p>
 
       <p>This week, we focused on obtaining and using new plasmids, pKT230  and pZE21G, because our prior plasmid, BBa_K125000 was causing various problems, from being improperly annotated online to stubbornly refusing to be isolated using a maxi prep. However, very little actual lab work was done this week. In regards to non-lab work, we researched and described a way to knock out the mutS gene in both Cyanobacteria and Rhizobia and explored the possibility of also porting a CRISPR/Cas9 system into Cyanobacteria or Rhizobia.</p>
 
       <p>For lab work: we successfully miniprepped pKT230 and pZE21G out of E. Coli once the OD was 0.611. The Jacobs-Wagner lab at Yale also graciously gave us S. Meliloti cultures to use: #1021, #WM249, and #MB501. S. meliloti WM249 and MB501 are derivatives of Rm1021 with transposon insertions permitting the efficient electroporation of E. coli plasmid DNA. WM249 contains a Tn5-233 element encoding gentamicin resistance, whereas MB501 (obtained from M. Barnett, Stanford University) contains the same Tn5-233 swapped for trimethoprim resistance. We were also able to isolate the isiAB promoter from Cyanobacteria Synechococcus PCC 6803 using the PCR procedure outlined in the procedural notes. However, the ends of the promoter were custom-made to be gibson-assembly-ed into the BBa_K125000 plasmid, so if we end up switching plasmids we’d need to re-isolate the promoter. </p>
 
       <p>For lab work: we successfully miniprepped pKT230 and pZE21G out of E. Coli once the OD was 0.611. The Jacobs-Wagner lab at Yale also graciously gave us S. Meliloti cultures to use: #1021, #WM249, and #MB501. S. meliloti WM249 and MB501 are derivatives of Rm1021 with transposon insertions permitting the efficient electroporation of E. coli plasmid DNA. WM249 contains a Tn5-233 element encoding gentamicin resistance, whereas MB501 (obtained from M. Barnett, Stanford University) contains the same Tn5-233 swapped for trimethoprim resistance. We were also able to isolate the isiAB promoter from Cyanobacteria Synechococcus PCC 6803 using the PCR procedure outlined in the procedural notes. However, the ends of the promoter were custom-made to be gibson-assembly-ed into the BBa_K125000 plasmid, so if we end up switching plasmids we’d need to re-isolate the promoter. </p>
       <p>Let me explain CRISPR. CRISPR (clustered regularly interspaced short palindromic repeats) is a recently discovered system from certain bacterial adaptive immunity systems  that uses guide RNA and the Cas9 proteins to create gene knockouts and gene replacements. Guide RNA locates a specific homologous sequence in the DNA following a PAM sequence. The Cas9 protein then causes a double stranded break in the DNA (see the graphic below put together by the Wuhan University iGEM team in China). Currently, we have found in literature that Synechococcus does not have a fully functional CRISPR-Cas system. This means that imported systems will work more effectively due to lack of cross talk. We also found that cyanobacteria are capable of non-homologous end joining (NHEJ). This means that cyanobacteria are prime targets for the porting of CRISPR- Cas systems. In order to test the ability of the imported CRISPR-Cas systems, we will target the UreC gene, a gene which confers sensitivity to solutions of urea and nickel sulfate. Already, we have designed the plasmids for the guide RNA and the Cas9 protein. Cas9 will be placed on a low copy number plasmid (Bba_125000) with an inducible promoter such as isiAB or nirA. gRNA will be placed on high copy number plasmid (KT230) with
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       <p>Let us explain CRISPR. CRISPR (clustered regularly interspaced short palindromic repeats) is a recently discovered mechanism from certain bacterial adaptive immunity systems  that uses guide RNA and the Cas9 proteins to create gene knockouts and gene replacements. Guide RNA locates a specific homologous sequence in the DNA following a PAM sequence. The Cas9 protein then causes a double stranded break in the DNA (see the graphic below put together by the Wuhan University iGEM team in China). Currently, we have found in literature that Synechococcus does not have a fully functional CRISPR-Cas system. This means that imported systems will work more effectively due to lack of cross talk. We also found that cyanobacteria are capable of non-homologous end joining (NHEJ). This means that cyanobacteria are prime targets for the porting of CRISPR- Cas systems. In order to test the ability of the imported CRISPR-Cas systems, we will target the UreC gene, a gene which confers sensitivity to solutions of urea and nickel sulfate. Already, we have designed the plasmids for the guide RNA and the Cas9 protein. Cas9 will be placed on a low copy number plasmid (Bba_125000) with an inducible promoter such as isiAB or nirA. gRNA will be placed on high copy number plasmid (KT230) with
 
a constitutive promoter such as psaA. If necessary, the cas9 protein can be placed next to a tetR promoter, a promoter found in E. Coli but not natively in cyanobacteria. In addition, recently it has been found that CRISPR works in Arabidopsis and several strains of rhizobium. However, no CRISPR has been found in the strains of Rhizobia we intend to use. It has also been shown that Rhizobia exhibits NHEJ. Whether or not pursuing CRISPR would be useful is an idea that needs to be discussed.</p>
 
a constitutive promoter such as psaA. If necessary, the cas9 protein can be placed next to a tetR promoter, a promoter found in E. Coli but not natively in cyanobacteria. In addition, recently it has been found that CRISPR works in Arabidopsis and several strains of rhizobium. However, no CRISPR has been found in the strains of Rhizobia we intend to use. It has also been shown that Rhizobia exhibits NHEJ. Whether or not pursuing CRISPR would be useful is an idea that needs to be discussed.</p>
 
       <p class="text-center"><img src="https://static.igem.org/mediawiki/2015/2/2e/WHU_Cas9_Schematic.png"></p>
 
       <p class="text-center"><img src="https://static.igem.org/mediawiki/2015/2/2e/WHU_Cas9_Schematic.png"></p>
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     <div id="week8" data-reveal="" aria-labelledby="iGEM Modal" aria-hidden="true" role="dialog" class="reveal-modal grayModal">
 
     <div id="week8" data-reveal="" aria-labelledby="iGEM Modal" aria-hidden="true" role="dialog" class="reveal-modal grayModal">
 
       <h2 class="modal__title">Lessons from Week 7</h2>
 
       <h2 class="modal__title">Lessons from Week 7</h2>
       <p>Today, we're visiting a museum.</p>
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       <p>This week consisted of more troubleshooting for everyone on the team. Experiments for determining growth, transformation, and selection parameters for PCC 7002, S. meliloti and R. tropici CIAT are well under way, but most of us ran into problems with the design and/or the results of these experiments.</p>
       <p class="text-center"><img src="http://client.cameronyick.us/igem/assets/img/journal/pigeon.jpg"></p>
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      <p>Erin obtained some unexpected results on her second exonuclease and ligation independent cloning (ELIC) experiment. The vector-only group, which is not supposed to confer resistance to antibiotic when transformed into E. coli, returned some growth. This may be due to faulty antibiotic, though it seems unlikely since the water-only control (row 4 in Fig. 1) returned the expected result of zero colonies.</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>
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       <p class="text-center"><img src="https://static.igem.org/mediawiki/2015/e/e4/Week7_1.jpeg"></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>
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       <p>Colin continued characterizing the growth and selection parameters for PCC7002 in the shaking incubator with ambient air (no supplemental CO2). He designed a growth assay which he ran on a 96-well plate to characterize the growth of the bacteria in the two candidate media (ATCC 1047 and A+) as well as to determine the minimum inhibitory concentrations (MICs) of six antibiotics of interest for PCC7002. Danny researched transformation methods for PCC7002 and designed experiments to test which method would me most efficient. He identified conjugation and natural competency as two possible methods for getting DNA into the cells, and began experimenting with these procedures. Erin focused less on PCC7002 issues this week to conduct her ELIC experiments for high-throughput DNA assembly (Fig. 1). This would be a fast alternative to Gibson assembly for putting together the large number of promoter-citrine and promoter-recombinase constructs we have designed. Members of the team focusing on PCC7002 studies (Colin, Danny, and Erin) took up much of Dan’s work since he left last week. This consists mainly of isolating several of the promoters he identified and assembling promoter-citrine constructs.</p>
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       <p>Colin and Danny also went to a hydroponics store to purchase a bright (20,000 lux) grow lamp to place on top of the PCC7002 shaking incubator.</p>
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      <p class="text-center"><img src="https://static.igem.org/mediawiki/2015/8/8d/Week7_2.jpeg"></p>
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      <p>The Rhizobium team also conducted selection assays to determine which antibiotics are most effective against Rhizobium tropici CIAT and Sinorhizobium meliloti 1021. Holly obtained inconclusive results in her selection assays (the assays report different resistances for what is supposedly the same organism), which may be an indication that the frozen stocks from which she was working are contaminated. Holly will conduct a colony PCR of the samples’ 16S region and send the products for sequencing. Since every prokaryotic species has a unique 16S sequence, this experiment should provide a definitive answer as to whether or not the frozen stocks are contaminated. Holly and Jessica continued working out transformation protocols for the strains, focusing mainly on conjugation. They conducted multiple conjugation experiments, along with an electroporation, and will analyze the results next week. They also conducted a centrifugation experiment in which they centrifuged CIAT 899 and Sm 356 at different centrifugation speeds; this was to determine which centrifugation speed to do their electroporations at (Fig. 2). Lionel spent much of his time in the Dellaporta lab working out LIC procedures. LIC is another high-throughput DNA assembly method which would provide an alternative to Gibson assembly.</p>
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      <p class="text-center"><img src="https://static.igem.org/mediawiki/2015/4/48/Week7_3.jpeg"></p>
 
       <p class="text-center"><a href="dropbox.com/#week8" class="file__link">Go to the Lab Notebook</a></p>
 
       <p class="text-center"><a href="dropbox.com/#week8" 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 13:14, 16 September 2015


<!DOCTYPE html> Yale iGem 2015: Notebook

Lab Notebook