RyanModlin (Talk | contribs) |
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<div id="Sep3Yea" class="buttoncontent15"> | <div id="Sep3Yea" class="buttoncontent15"> | ||
− | <p>Our colony PCR primers arrived, so we were able to check whether loxP was properly cut out using colony PCR. We made inoculations of E. coli carrying our pOPPY-XLR2-yX plasmid. We also made streak plates and liquid cultures using colonies from our previous round of YMC. We tested our “yeast miniprep protocol” using these liquid cultures, but received very weird (negative) DNA concentrations when we NanoDropped the products. We also intended to perform a miniprep on the E. coli carrying our pOPPY-XLR2-yX plasmid, but we had contamination in our negative control so we repeated the inoculations. These also ended up having contamination, so we asked our TA, McKenna Hicks, to give us a refresher on aseptic technique before repeating them again. We saw growth on our streak plates. We repeated the recircularization of pOPPY-XLR2-yX using site-directed mutagenesis, and plated transformed E. coli on LB/AMP to select for transformants.</p> | + | <p>Our colony PCR primers arrived, so we were able to check whether loxP was properly cut out using colony PCR. We made inoculations of <i>E. coli</i> carrying our pOPPY-XLR2-yX plasmid. We also made streak plates and liquid cultures using colonies from our previous round of YMC. We tested our “yeast miniprep protocol” using these liquid cultures, but received very weird (negative) DNA concentrations when we NanoDropped the products. We also intended to perform a miniprep on the <i>E. coli</i> carrying our pOPPY-XLR2-yX plasmid, but we had contamination in our negative control so we repeated the inoculations. These also ended up having contamination, so we asked our TA, McKenna Hicks, to give us a refresher on aseptic technique before repeating them again. We saw growth on our streak plates. We repeated the recircularization of pOPPY-XLR2-yX using site-directed mutagenesis, and plated transformed <i>E. coli</i> on LB/AMP to select for transformants.</p> |
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<div id="Sep3Bio" class="buttoncontent15"> | <div id="Sep3Bio" class="buttoncontent15"> | ||
− | <p>After having a sufficient amount of our genes and having received our restriction enzymes (EcoR1-HF and Sca1), we were able to begin assembling our BioBricks together. We followed the protocols provided by iGEM for our restriction digest, ligation, and transformation. We began with the restriction digest protocol and adjusted for a lack of resources. Since we did not have the ideal buffer that iGEM recommended (NEB Buffer 2), we used the buffer we had in stock - CutSmart Buffer. One drawback of the buffer was its enzymatic activity of 50% for PstI, so to account for this, we doubled the amount of enzyme used. We then double digested the | + | <p>After having a sufficient amount of our genes and having received our restriction enzymes (EcoR1-HF and Sca1), we were able to begin assembling our BioBricks together. We followed the protocols provided by iGEM for our restriction digest, ligation, and transformation. We began with the restriction digest protocol and adjusted for a lack of resources. Since we did not have the ideal buffer that iGEM recommended (NEB Buffer 2), we used the buffer we had in stock - CutSmart Buffer. One drawback of the buffer was its enzymatic activity of 50% for PstI, so to account for this, we doubled the amount of enzyme used. We then double digested the Psb1C3 backbone and both the 7-dehydrocholesterol reductase (Delta7) gene and the adrenodoxin-NADP+ reductase (ADR) gene, which we then ligated together to create a plasmid.</p> |
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<div id="Sep3Rib" class="buttoncontent15"> | <div id="Sep3Rib" class="buttoncontent15"> | ||
− | <p>Over the weekend our final Y. lipolytica plating showed a large amount of growth, indicating that our old stock was indeed competent. Our E. coli amplification, however, showed no growth. It was found that this was because of an error in the media used. To save time, we thawed our previous glycerol stock of transformed cells and used it to inoculate a culture for outgrowth and plasmid isolation. DNA yields of this culture were lower than previous amplifications. We reasoned that this was due to the glycerol stock not having been plated on selective media before freezing. This would have resulted in some population of non-transformants existing in the stock and lowering plasmid yields. To remedy this, we plated our glycerol stock on selective media to isolate colonies and inoculated cultures with these colonies. We left these cultures to incubate over the weekend. <br><br> | + | <p>Over the weekend our final <i>Y. lipolytica</i> plating showed a large amount of growth, indicating that our old stock was indeed competent. Our <i>E. coli</i> amplification, however, showed no growth. It was found that this was because of an error in the media used. To save time, we thawed our previous glycerol stock of transformed cells and used it to inoculate a culture for outgrowth and plasmid isolation. DNA yields of this culture were lower than previous amplifications. We reasoned that this was due to the glycerol stock not having been plated on selective media before freezing. This would have resulted in some population of non-transformants existing in the stock and lowering plasmid yields. To remedy this, we plated our glycerol stock on selective media to isolate colonies and inoculated cultures with these colonies. We left these cultures to incubate over the weekend. <br><br> |
We began PCR experiments to amplify our riboswitch inserts in anticipation of our Gibson Assembly trials. Trials initially showed mixed results, which was perplexing since all PCR trials used the same primers and overhangs, but were confirmed as successful on 0.8% agarose gels by the end of the week. Nanodrop analysis gave the following concentrations of PCR products in the table below. <br><br> | We began PCR experiments to amplify our riboswitch inserts in anticipation of our Gibson Assembly trials. Trials initially showed mixed results, which was perplexing since all PCR trials used the same primers and overhangs, but were confirmed as successful on 0.8% agarose gels by the end of the week. Nanodrop analysis gave the following concentrations of PCR products in the table below. <br><br> | ||
<img src="https://static.igem.org/mediawiki/2018/1/10/T--UCSC--Ribo-Table.png" style="width:90%; float:center !important"><br><br> | <img src="https://static.igem.org/mediawiki/2018/1/10/T--UCSC--Ribo-Table.png" style="width:90%; float:center !important"><br><br> | ||
− | We also began out first Gibson Assembly experiments with our amplified inserts and linearized plasmid backbone. After this, we used PCR to confirm the presence of our pOPPY_GFP plasmids by using two of our Sanger sequencing primers and running the generated amplicons against a ladder on a 1.5% agarose gel. We also attempted a series of transformations of E. coli using our 5 Gibson Assembly products. <br><br> | + | We also began out first Gibson Assembly experiments with our amplified inserts and linearized plasmid backbone. After this, we used PCR to confirm the presence of our pOPPY_GFP plasmids by using two of our Sanger sequencing primers and running the generated amplicons against a ladder on a 1.5% agarose gel. We also attempted a series of transformations of <i>E. coli</i> using our 5 Gibson Assembly products. <br><br> |
We also sent off our first samples for Sanger sequencing at the UC Berkeley DNA sequencing facility. With results coming in at the end of the week. Our reads indicated that our GFP gene was functional with no detected SNPs that would hinder our experiments.</p> | We also sent off our first samples for Sanger sequencing at the UC Berkeley DNA sequencing facility. With results coming in at the end of the week. Our reads indicated that our GFP gene was functional with no detected SNPs that would hinder our experiments.</p> | ||
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<div id="Sep10Ove" class="buttoncontent16"> | <div id="Sep10Ove" class="buttoncontent16"> | ||
− | <p>Another busy week of lab work! Several teammates spent their week with our new best friends: E. coli and Y. lipolytica. We only have a little over a month until the Giant Jamboree! It’s crazy to think about how far our team has come. Speaking of, we received an invitation to speak at TEDx Oakland! We’ve been busy preparing for the TEDx San Jose talk, and we’ve even more excited now knowing that we have two opportunities to discuss our project with the community.</p> | + | <p>Another busy week of lab work! Several teammates spent their week with our new best friends: <i>E. coli</i> and <i>Y. lipolytica</i>. We only have a little over a month until the Giant Jamboree! It’s crazy to think about how far our team has come. Speaking of, we received an invitation to speak at TEDx Oakland! We’ve been busy preparing for the TEDx San Jose talk, and we’ve even more excited now knowing that we have two opportunities to discuss our project with the community.</p> |
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<div id="Sep10Gib" class="buttoncontent16"> | <div id="Sep10Gib" class="buttoncontent16"> | ||
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<div id="Sep10Bio" class="buttoncontent16"> | <div id="Sep10Bio" class="buttoncontent16"> | ||
− | <p> | + | <p>Having observed positive results of a team member using electrocompetent <i>E. coli</i> cells we decided to use these cells to perform our transformations with. We transformed the electrocompetent <i>E. coli</i> cells the DNA of our ADR, and Delta7 plasmid. We transformed with electrocompetent <i>E. coli</i> three times during the week and each yielded unsuccessful results, made evident in the absence of growth on the plates. </p> |
<p>To analyze our results, we first tested the legitimacy of using electrocompetent cells and performed a transformation using the chemicompetent <i>E. coli</i> cells and the ligated Delta7 and ADR plasmids; the results were still unsuccessful. The next step we took was to adjust the protocol again, adding the enzymes and DNA at once within one tube, rather than adding them later in a separate enzyme mastermix.</p> | <p>To analyze our results, we first tested the legitimacy of using electrocompetent cells and performed a transformation using the chemicompetent <i>E. coli</i> cells and the ligated Delta7 and ADR plasmids; the results were still unsuccessful. The next step we took was to adjust the protocol again, adding the enzymes and DNA at once within one tube, rather than adding them later in a separate enzyme mastermix.</p> | ||
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<div id="Sep10Yea" class="buttoncontent16"> | <div id="Sep10Yea" class="buttoncontent16"> | ||
− | <p>We made | + | <p>We made inoculations using the <i>E. coli</i> carrying pOPPY-XLR2-yX in LB/AMP and the yeast from the previous round of YMC in YNB-CSM-Leu. Colony PCR on <i>E. coli</i> showed bands indicating two colonies had successful transformants. We made streak plates using the two successful transformants, and then went on to make liquid cultures from these colonies. We miniprepped the pOPPY-XLR2-yX plasmid and then performed PCR, mistakenly using Q5 polymerase rather than OneTaq. Q5 polymerase could do the job just fine, it is just much more expensive than OneTaq for simply verifying the size of a fragment! </p> |
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<div id="Sep10Rib" class="buttoncontent16"> | <div id="Sep10Rib" class="buttoncontent16"> | ||
− | <p></p> | + | <p>We isolated more stock of our D17 plasmid for further Gibson Assembly trials. These were miniprepped out to concentrations of ~450 and ~500ng/uL. In order to get growth from the rest of our aptameric inserts, we redid streak plates with higher depositions of transformant. We also redid a transformation of D17 into DH5α to test if our sample of cells was properly competent. These new transformations were unsuccessful, we eventually found this was because of an error in the creation of competent cell stocks.</p> |
+ | <p>While more chemicompetent cell cultures were being produced, we used electrocompetent stocks to preform more transformations on <i>E. coli</i> with our recircularized plasmids. We wrote up a new protocol for electroporation and ran tests to optimize our procedure. </p> | ||
+ | <p>We ran another 50uL linearization PCR to restock and checked this on a gel. Then, we performed 5 more transformations to get our recircularized stocks into <i>E. coli</i>.</p> | ||
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<div id="Sep10Oth" class="buttoncontent16"> | <div id="Sep10Oth" class="buttoncontent16"> | ||
− | <p>We attempted a yeast plasmid miniprep yet again, this time using S. cerevisiae containing a backbone pXRL2 connected to five progesterone pathway genes. Despite the improvement in our previous attempt, this attempt yielded an unusable sample. We concluded that our procedures may be inadequate.</p> | + | <p>We attempted a yeast plasmid miniprep yet again, this time using <i>S. cerevisiae</i> containing a backbone pXRL2 connected to five progesterone pathway genes. Despite the improvement in our previous attempt, this attempt yielded an unusable sample. We concluded that our procedures may be inadequate.</p> |
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<div id="Sep17Rib" class="buttoncontent17"> | <div id="Sep17Rib" class="buttoncontent17"> | ||
− | <p></p> | + | <p>Over the course of this week we were able to get platings of <i>E. coli</i> transformed with all 5 of our pOPPY_GFP series plasmids. Growth of these transformants, however, was inconsistent, with multiple platings being required to get colonies for each sample. By the end of the week, only transformants carrying pOPPY_GFP(2), (4), and (5) were able to be isolated enough to grow monoclonal liquid cultures. Upon plasmid isolation and PCR testing with the Rib(f)2 and Rib(r)1 primers our gel images suggested the presence of D17 plasmid in our pOPPY_GFP(3) transformants. Considering these troubling results as well as the fact that liquid cultures were failing to grow, we opted to discard these samples and begin the next week with new transformations.</p> |
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<div id="Sep17Oth" class="buttoncontent17"> | <div id="Sep17Oth" class="buttoncontent17"> | ||
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<div id="Sep24Bio" class="buttoncontent18"> | <div id="Sep24Bio" class="buttoncontent18"> | ||
− | <p>With an absence of successful results from the transformations, we decided to alter the restriction digest protocol again. One of the edits included using the 3.1 NEB buffer, rather than the CutSmart buffer. Using the NEB buffer, PstI had 100% enzymatic activity, whereas EcoRI had 50% so we used twice as much of EcoRI. Using the newly made protocol, we performed a double restriction digest and ligation to get the plasmids for P450scc and 3BH. We transformed the ligations with electrocompetent and chemicompetent <i>E. coli</i> cells, and we then got four colonies on the electrocompetent E.coli plate for the | + | <p>With an absence of successful results from the transformations, we decided to alter the restriction digest protocol again. One of the edits included using the 3.1 NEB buffer, rather than the CutSmart buffer. Using the NEB buffer, PstI had 100% enzymatic activity, whereas EcoRI had 50%, so we used twice as much of EcoRI. Using the newly made protocol, we performed a double restriction digest and ligation to get the plasmids for Cholesterol side-chain cleavage enzyme (P450scc) and 3-beta-hydroxy-Delta(5)-steroid dehydrogenase (3BH). We transformed the ligations with electrocompetent and chemicompetent <i>E. coli</i> cells, and we then got four colonies on the electrocompetent <i>E. coli</i> plate for the plasmid of P450scc. The other plates, which were our transformed chemicompetent <i>E. coli</i>, and our electrocompetent <i>E. coli</i> with 3BH ligation failed. Since we had four colonies that contained our P450scc plasmid, we index plated them, inoculated them into liquid media, and miniprepped out the plasmid. To confirm if the <i>E. coli</i> actually had our P450scc Biobrick plasmid, we performed a colony PCR, and a restriction digest. Both the colony PCR and restriction digest had inconclusive results, and we were not able to tell if the plasmid was actually our P450scc BioBrick. </p> |
<p>None of the transformations were working, so we tried to alter our restriction digest protocol again. This time instead of using the buffer CutSmart, we used the 3.1 NEB buffer. In this buffer Pst1 has 100% activity, but EcoR1 has 50%, so we used twice as much EcoR1 this time instead of twice as much Pst1. With this new restriction digest protocol we performed a double restriction digest and ligation to get us the plasmids for P450scc and 3BH. We transformed these ligations with electrocompetent and chemicompetent <i>E. coli</i> cells, and this time we got four colonies on the electrocompetent <i>E.coli</i> plate for the BioBrick plasmid of P450scc! The other plates which were our transformed chemicompetent <i>E. coli</i>, and our electrocompetent <i>E. coli</i> with 3BH ligation failed. Since we had four colonies that contained our P450scc plasmid we index plated them, inoculated them into liquid media and miniprepped out the plasmid. To confirm if the <i>E. coli</i> actually had our P450scc Biobrick, we performed a colony PCR, and a restriction digest. Both the colony PCR and restriction digest had inconclusive results, and we were not able to tell if the plasmid was actually our P450scc BioBrick. </p> | <p>None of the transformations were working, so we tried to alter our restriction digest protocol again. This time instead of using the buffer CutSmart, we used the 3.1 NEB buffer. In this buffer Pst1 has 100% activity, but EcoR1 has 50%, so we used twice as much EcoR1 this time instead of twice as much Pst1. With this new restriction digest protocol we performed a double restriction digest and ligation to get us the plasmids for P450scc and 3BH. We transformed these ligations with electrocompetent and chemicompetent <i>E. coli</i> cells, and this time we got four colonies on the electrocompetent <i>E.coli</i> plate for the BioBrick plasmid of P450scc! The other plates which were our transformed chemicompetent <i>E. coli</i>, and our electrocompetent <i>E. coli</i> with 3BH ligation failed. Since we had four colonies that contained our P450scc plasmid we index plated them, inoculated them into liquid media and miniprepped out the plasmid. To confirm if the <i>E. coli</i> actually had our P450scc Biobrick, we performed a colony PCR, and a restriction digest. Both the colony PCR and restriction digest had inconclusive results, and we were not able to tell if the plasmid was actually our P450scc BioBrick. </p> | ||
<p>Using newly procured T4 DNA ligase and buffer to prevent any implications, since the buffer has a limited, low amount of freeze-thaw cycles. Then we chose colonies from the plates which were isolated and ran a yeast transformation for TEF1, but found that overgrowth had occurred and the results were no longer fit to continue with. </p> | <p>Using newly procured T4 DNA ligase and buffer to prevent any implications, since the buffer has a limited, low amount of freeze-thaw cycles. Then we chose colonies from the plates which were isolated and ran a yeast transformation for TEF1, but found that overgrowth had occurred and the results were no longer fit to continue with. </p> | ||
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<div id="Sep24Rib" class="buttoncontent18"> | <div id="Sep24Rib" class="buttoncontent18"> | ||
− | <p></p> | + | <p>New platings for all 5 transformant population showed successful growth, although colonies were still too clustered to be isolated. We also discovered that our final homologous arm primers had not been ordered, and so attempted to isolate our gene inserts using some restriction sites that were near the binding site of our designed primers. These transformations were unsuccessful, though we were able to produce a glycerol stock of <i>E. coli</i> containing our pOPPY_GFP(1) plasmid.</p> |
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<div id="Sep24Oth" class="buttoncontent18"> | <div id="Sep24Oth" class="buttoncontent18"> | ||
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<div id="Oct1Gib" class="buttoncontent19"> | <div id="Oct1Gib" class="buttoncontent19"> | ||
− | <p></p> | + | <p>After receiving the <i>lox-ura-lox</i> from IDT, we began our KLD reactions. We ran our KLD reaction with our new clean D17 in the PCR machine. Using the product, we plated the mix on a high copy plate and let it incubate overnight. The next day, we confirmed its growth and began preparation for colony PCR.</p> |
+ | <p> We also attempted to transform our pXRl2 gibson with our desired genes and perform PCR on p450. Both failed.</p> | ||
</div> | </div> | ||
<div id="Oct1Bio" class="buttoncontent19"> | <div id="Oct1Bio" class="buttoncontent19"> | ||
− | <p>Since we were successful in making a colony that contained the | + | <p>Since we were successful in making a colony that contained the Psb1C3 backbone with the electrocompetent <i>E. coli</i>, we did another double digest, ligation, and transformation with the genes 3BH and Delta7. We also did another restriction digest to confirm if the P450scc plasmid that was miniprepped was correct, and we did not get the bands we expected. We had bands at 2.8kb and 1.2kb when we expected bands at 3.2kb and 800bp. Since we were not getting our BioBricks, we consulted one of our PI’s, as to why our transformations were not working. He assumed there was too much salt when we electroporated our cells, which would kill them and explained why we may not get growth on our plates. We did the math and he was right;.There was way too much salt in the DNA that we were transforming our electrocompetent <i>E. coli</i> with and would explain why we rarely ever got growth on transformations performed with electrocompetent <i>E. coli</i> cells. From then on we only transformed with chemicompetent <i>E. coli</i> cells. We tried to perform a transformation with chemicompetent <I>E.coli</i> cells with a ligated plasmid of 3BH. We did these transformations with different concentrations of DNA to see if the amount of DNA that we transformed with was the problem. There was no growth on the plates, so it may not be that the amount of DNA that was the problem. </p> |
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<div id="Oct1Yea" class="buttoncontent19"> | <div id="Oct1Yea" class="buttoncontent19"> | ||
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<div id="Oct1Rib" class="buttoncontent19"> | <div id="Oct1Rib" class="buttoncontent19"> | ||
− | <p></p> | + | <p>Considering our poor results using Gibson Assembly, we reasoned that our experiments could be improved now that our new set of primers had come in, including one that would allow us to linearize D17 without the 1bp mismatch we had discovered earlier. Repeating the Gibson Assembly trial and amplifying with PCR suggested the presence of both pOPPY_GFP as well as D17 in each GA sample, despite digest with a 5,000-fold excess of DpnI. </p> |
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<div id="Oct1Oth" class="buttoncontent19"> | <div id="Oct1Oth" class="buttoncontent19"> | ||
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<div id="Oct8Ove" class="buttoncontent20"> | <div id="Oct8Ove" class="buttoncontent20"> | ||
− | <p>We sent out our improved terminator BioBrick for sequencing on October 10th. This is so exciting! We’ve all been working so hard that the little victories mean the most. Both our yeast-mediated cloning team and our Gibson Assembly team accomplished big tasks this week and set themselves up for an even busier next week! The competition is less than a month away | + | <p>We sent out our improved terminator BioBrick for sequencing on October 10th. This is so exciting! We’ve all been working so hard that the little victories mean the most. Both our yeast-mediated cloning team and our Gibson Assembly team accomplished big tasks this week and set themselves up for an even busier next week! The competition is less than a month away and lab work is high priority now. </p> |
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<div id="Oct8Gib" class="buttoncontent20"> | <div id="Oct8Gib" class="buttoncontent20"> | ||
− | <p></p> | + | <p>We did several rounds of colony PCRs, most of which failed. On the last round, colony #4 and colony #17 of 30 both showed up on the gel at the right height. We then created liquid cultures of our successful colonies and grew them up over night. The cultures didn’t grow so we performed a few experiments to try to get it to grow. We created several tests that included longer incubation time, leaving the caps slightly open, and tilting it while it shakes. Nothing worked.</p> |
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<div id="Oct8Bio" class="buttoncontent20"> | <div id="Oct8Bio" class="buttoncontent20"> | ||
− | <p>Since the transformation protocols were not working, we tried a new technique to create our plasmid. We decided to do a KLD reaction | + | <p>Since the transformation protocols were not working, we tried a new technique to create our plasmid. We decided to do a KLD (Kinase, Ligase and DpnI enzymes) reaction and hope that our plasmid was made. We performed a KLD transformation because other members of our team were successful in making plasmids this way. When we performed a transformation with this technique with our gene P450scc, there were 15 colonies. We proceeded to inoculate five of the biggest <i>E. coli</i> colonies into liquid media in preparation for a miniprep. We performed a double digest of the miniprepped plasmid and ran it on a gel along with the non-digested miniprepped plasmid to confirm if the plasmids were our BioBrick. For some reason there were no bands in the restriction digest lanes, but in the undigested plasmid lanes there were bands at around 4kb which means that there is some insert in our plasmid. We will perform more double digest to confirm if the P450scc plasmids are correct. </p> |
− | <p>In comparing Tsynth8 and Tsynth30 for use in yeast, both demonstrated increased heterologous protein expression and transcript levels greater than 2-fold over the commonly used CYC1 terminator [cite study]. However, specifically for use in Y. lipolytica, Tsynth8 showed 3-fold greater protein expression than Tsynth30. In addition, Tsynth8 had slightly lower cryptic promoter activity and a lower tendency for transcript read-through, which would signal insufficient transcript termination. Most significantly, Tsynth8 could be ordered as a sequence from IDT; whereas Tsynth30, with it’s extended TA efficiency region, could not.</p> | + | <p>In comparing Tsynth8 and Tsynth30 for use in yeast, both demonstrated increased heterologous protein expression and transcript levels greater than 2-fold over the commonly used CYC1 terminator [cite study]. However, specifically for use in <i>Y. lipolytica</i>, Tsynth8 showed 3-fold greater protein expression than Tsynth30. In addition, Tsynth8 had slightly lower cryptic promoter activity and a lower tendency for transcript read-through, which would signal insufficient transcript termination. Most significantly, Tsynth8 could be ordered as a sequence from IDT; whereas Tsynth30, with it’s extended TA efficiency region, could not.</p> |
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<div id="Oct8Rib" class="buttoncontent20"> | <div id="Oct8Rib" class="buttoncontent20"> | ||
− | <p></p> | + | <p>All 5 transformant populations with our new Gibson Assembly product showed growth after overnight incubation. We selected 10 isolated colonies from each plate as well as 2 from a D17 control plate to create an index plate as well as perform colony PCR. After imaging, we selected colonies 2, 16, 27, 32, 43, and 51 as likely carriers of pOPPY_GFP(1)--pOPPY_GFP(5) and D17, respectively. All continued experiments up to this point have been focused on growing cultures of these colonies, isolating their plasmids, sequencing, and transforming into our Yali cell line.</p> |
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<div id="Oct8Oth" class="buttoncontent20"> | <div id="Oct8Oth" class="buttoncontent20"> | ||
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<p class="section-title week" id="OGA"><span style="font-size: 150%">OEPCR and Gene Amplification</span></p> | <p class="section-title week" id="OGA"><span style="font-size: 150%">OEPCR and Gene Amplification</span></p> | ||
− | < | + | <object style="width: 100%; height: 80vh" data="https://static.igem.org/mediawiki/2018/8/82/T--UCSC--OEPCR_Notebook.pdf"></object> |
<br> <br> | <br> <br> | ||
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<p class="section-title week" id="BT"><span style="font-size: 150%">Biobrick and Terminator</span></p> | <p class="section-title week" id="BT"><span style="font-size: 150%">Biobrick and Terminator</span></p> | ||
− | < | + | <object style="width: 100%; height: 80vh" data="https://static.igem.org/mediawiki/2018/6/63/T--UCSC--Biobrick_Notebook.pdf"></object> |
+ | <object style="width: 100%; height: 80vh" data="https://static.igem.org/mediawiki/2018/6/63/T--UCSC--Terminator_Notebook.pdf"></object> | ||
<br> <br> | <br> <br> | ||
<p class="section-title week" id="R"><span style="font-size: 150%">Riboswitch</span></p> | <p class="section-title week" id="R"><span style="font-size: 150%">Riboswitch</span></p> | ||
− | < | + | <object style="width: 100%; height: 80vh" data="https://static.igem.org/mediawiki/2018/3/35/T--UCSC--Riboswitch_Notebook.pdf"></object> |
<br> <br> | <br> <br> | ||
<p class="section-title week" id="O"><span style="font-size: 150%">Other</span></p> | <p class="section-title week" id="O"><span style="font-size: 150%">Other</span></p> | ||
<object style="width: 100%; height: 80vh" data="https://static.igem.org/mediawiki/2018/5/58/T--UCSC--Dante_Notebook.pdf"></object> | <object style="width: 100%; height: 80vh" data="https://static.igem.org/mediawiki/2018/5/58/T--UCSC--Dante_Notebook.pdf"></object> | ||
+ | <object style="width: 100%; height: 80vh" data="https://static.igem.org/mediawiki/2018/b/b2/T--UCSC--Homologous_Arms_Notebook.pdf"></object> | ||
<br> <br> | <br> <br> | ||
Latest revision as of 03:50, 18 October 2018