Team:HZAU-China/Labnotes
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<p class="highlighttext"><span style="font-weight:bold;">2.Construction of gene circuit three: </span>Firstly, we used standard method of biobrick connection to put the coding sequence of LacI protein behind lox66 because the length of lox66 was 34bp and it was too small to purify from the enzyme-digested product and then put it in front of LacI protein. Due to the same reason, we put the product of previous step behind PLtet01 promoter to finish this gene circuit. Compared to construction of other gene circuits, it seemed that this gene circuit was the simplest job we’ve made since that we only tried once and took almost eight days to finish this work. </p> | <p class="highlighttext"><span style="font-weight:bold;">2.Construction of gene circuit three: </span>Firstly, we used standard method of biobrick connection to put the coding sequence of LacI protein behind lox66 because the length of lox66 was 34bp and it was too small to purify from the enzyme-digested product and then put it in front of LacI protein. Due to the same reason, we put the product of previous step behind PLtet01 promoter to finish this gene circuit. Compared to construction of other gene circuits, it seemed that this gene circuit was the simplest job we’ve made since that we only tried once and took almost eight days to finish this work. </p> | ||
<p class="highlighttext"><span style="font-weight:bold;">3.Construction of gene circuit two: </span>we constructed this gene circuit by following the method we’ve mentioned above. The only difference from the construction of gene circuit three is that we put the coding sequence of tetR protein behind lox71. By the way, lox66 and lox71 are two recombination sites which are recognized specifically by Cre protein. To our surprise, when we did double-digest to this circuit for verification, we found that the length of product of enzyme-digested was not right and there was an extra stripe that we didn’t know what it was. Results are shown in the figure.4. According to the results, we had another assumption to explain the phenomenon: there were some recombination systems in DH-5α, resulting in homologous recombination of two strains which had synclastic lox71 site. Definitely, We’ve done a lot of work to verify our assumption which will be explained in the part of characterization.</p> | <p class="highlighttext"><span style="font-weight:bold;">3.Construction of gene circuit two: </span>we constructed this gene circuit by following the method we’ve mentioned above. The only difference from the construction of gene circuit three is that we put the coding sequence of tetR protein behind lox71. By the way, lox66 and lox71 are two recombination sites which are recognized specifically by Cre protein. To our surprise, when we did double-digest to this circuit for verification, we found that the length of product of enzyme-digested was not right and there was an extra stripe that we didn’t know what it was. Results are shown in the figure.4. According to the results, we had another assumption to explain the phenomenon: there were some recombination systems in DH-5α, resulting in homologous recombination of two strains which had synclastic lox71 site. Definitely, We’ve done a lot of work to verify our assumption which will be explained in the part of characterization.</p> | ||
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+ | <h6>July</h6> | ||
+ | <p class="highlighttext"><span style="font-weight:bold;">Content: </span>eight gene circuits’ construction</p> | ||
+ | <p class="highlighttext"><span style="font-weight:bold;">1.Construction of gene circuit four: </span>we used standard method of biobrick connection to put the coding sequence of mCherry protein behind Pλ promoter. And when we planned to construct the part CFP expression controlled by PLlacI promoter, we didn’t find CFP with LVA tag in the Plate Kits, so we decided to get this part through PCR which means that we added a LVA tag behind the coding sequence of CFP. And then, we used standard method of biobrick to connect PLlacI promoter with the coding sequence of CFP to finish the whole circuit.</p> | ||
+ | <p class="highlighttext"><span style="font-weight:bold;">2.Construction of gene circuit five: </span>Because of the complex stem-loop structure of RNA aptamer, it was very hard to get this part by overlapping PCR. So, we find a company to help us to synthetize the sequence of RNA aptamer, and we standardize RNA aptamer and also we connected it with the promoter (lambda cI regulated).</p> | ||
+ | <p class="highlighttext"><span style="font-weight:bold;">3.Construction of gene circuit seven (the second repressilator (quorum sensing)): </span>We divided this circuit into four parts: AiiA protein generator, LuxI protein generator, LuxR protein generator and GFP generator. Both the parts GFP expression controlled by LuxR promoter and luxR protein generator under Plambda regulation were found in Plate Kits. As for another two parts, we did them the same thing as the construction of gene circuit three.</p> | ||
+ | <p class="highlighttext"><span style="font-weight:bold;">4.Construction of gene circuit six and eight: </span>4.Construction of gene circuit six and eight: These two gene circuits are familiar in their structure and then, we constructed them simultaneously. Firstly, we divided the circuit into two parts: riboswitch and Cre protein with double terminators. When it came to the synthesis of riboswitch, we designed four specific primers which had almost 20 overlapping sequence and conducted twice PCR to get our riboswitch (more details are shown in our protocol). Then, we connected both of them by the standard method of biobrick connection.</p> | ||
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Revision as of 12:24, 9 October 2014
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Labnotes
Parts connection and standardization:
Author: Zheng Yihui
Members: Zheng Yihui, Zhang Yajing, Liu Zhixiang, Luo Xudong, Guo Xiaoxue, Wang Lu, Li Siqi.
Introduction:
We have eight gene circuits to construct (as shown in the figure.1), and after finishing these circuits, we will integrate some of them into one plasmid to form two repressilators and two detection devices (as shown in the figure.2a and figure.2b).
May
Content: we found the parts we needed in the Plate Kits and did a lot of transformations to get the plasmid for subsequent experiments.
Parts list: BBa_J06602 BBa_E0420 BBa_K886000 BBa_R1051 BBa_P0412 BBa_R0040 BBa_P0451 BBa_R0011 BBa_R0051 BBa_I714075 BBa_J61047 BBa_R0063 BBa_K516022 BBa_K805016 BBa_J37032 BBa_K081019 BBa_K773003 BBa_I13602 BBa_R0061 BBa_R0062 BBa_R0063 BBa_C0060 BBa_B0015 BBa_I718016 BBa_I0462 BBa_P0440 BBa_E0022 BBa_J01010
June
Content: eight gene circuits’ construction
Construction details:
1.Construction of gene circuit one: we used standard method of biobrick connection to put the coding sequence of cI protein behind PLlacI promoter. But we failed to construct it because of some unknown reasons. The sequence results showed that there is either a pretty long and unknown segment which insert into the coding sequence of cI protein or deficiency of the sequence of PLlacI promoter(as shown in the figure.3). So, we had an assumption that there were little LacI proteins in DH-5α, and it was not much enough to repress PLlacI promoter, resulting in the overexpression of cI protein which may restrain the growth of host.
2.Construction of gene circuit three: Firstly, we used standard method of biobrick connection to put the coding sequence of LacI protein behind lox66 because the length of lox66 was 34bp and it was too small to purify from the enzyme-digested product and then put it in front of LacI protein. Due to the same reason, we put the product of previous step behind PLtet01 promoter to finish this gene circuit. Compared to construction of other gene circuits, it seemed that this gene circuit was the simplest job we’ve made since that we only tried once and took almost eight days to finish this work.
3.Construction of gene circuit two: we constructed this gene circuit by following the method we’ve mentioned above. The only difference from the construction of gene circuit three is that we put the coding sequence of tetR protein behind lox71. By the way, lox66 and lox71 are two recombination sites which are recognized specifically by Cre protein. To our surprise, when we did double-digest to this circuit for verification, we found that the length of product of enzyme-digested was not right and there was an extra stripe that we didn’t know what it was. Results are shown in the figure.4. According to the results, we had another assumption to explain the phenomenon: there were some recombination systems in DH-5α, resulting in homologous recombination of two strains which had synclastic lox71 site. Definitely, We’ve done a lot of work to verify our assumption which will be explained in the part of characterization.
July
Content: eight gene circuits’ construction
1.Construction of gene circuit four: we used standard method of biobrick connection to put the coding sequence of mCherry protein behind Pλ promoter. And when we planned to construct the part CFP expression controlled by PLlacI promoter, we didn’t find CFP with LVA tag in the Plate Kits, so we decided to get this part through PCR which means that we added a LVA tag behind the coding sequence of CFP. And then, we used standard method of biobrick to connect PLlacI promoter with the coding sequence of CFP to finish the whole circuit.
2.Construction of gene circuit five: Because of the complex stem-loop structure of RNA aptamer, it was very hard to get this part by overlapping PCR. So, we find a company to help us to synthetize the sequence of RNA aptamer, and we standardize RNA aptamer and also we connected it with the promoter (lambda cI regulated).
3.Construction of gene circuit seven (the second repressilator (quorum sensing)): We divided this circuit into four parts: AiiA protein generator, LuxI protein generator, LuxR protein generator and GFP generator. Both the parts GFP expression controlled by LuxR promoter and luxR protein generator under Plambda regulation were found in Plate Kits. As for another two parts, we did them the same thing as the construction of gene circuit three.
4.Construction of gene circuit six and eight: 4.Construction of gene circuit six and eight: These two gene circuits are familiar in their structure and then, we constructed them simultaneously. Firstly, we divided the circuit into two parts: riboswitch and Cre protein with double terminators. When it came to the synthesis of riboswitch, we designed four specific primers which had almost 20 overlapping sequence and conducted twice PCR to get our riboswitch (more details are shown in our protocol). Then, we connected both of them by the standard method of biobrick connection.