Difference between revisions of "Team:Hong Kong-CUHK/methods"
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<p><font face="Times New Roman" size="4pt">Our first construct is called the MFO, which stands for the magnetosome forming operon. </p></font> | <p><font face="Times New Roman" size="4pt">Our first construct is called the MFO, which stands for the magnetosome forming operon. </p></font> | ||
− | <p><font face="Times New Roman" size="4pt">From research papers, we found that there are different operons that are used to produce and regulate the magnetosome formation. And among them, it is the mamAB operon that is the crucial operon that is needed for the production of magnetosome. Other operons like mamGFDC, mamXY, mms6 et cetera are more frequently used for regulating the size and shape and the biominerlization that facilitate the formation of magnetosome | + | <p><font face="Times New Roman" size="4pt">From research papers, we found that there are different operons that are used to produce and regulate the magnetosome formation. And among them, it is the mamAB operon that is the crucial operon that is needed for the production of magnetosome. Other operons like mamGFDC, mamXY, mms6 et cetera are more frequently used for regulating the size and shape and the biominerlization that facilitate the formation of magnetosome[1]. </p> |
<p><font face="Times New Roman" size="4pt">Therefore, in our project this year, we would only insert the mamAB operon from MSG to our bacteria Azotobacter Vinelandii, hoping to test on using minimal number of genes to produce functional magnetosome. This aims at assisting the magnetosome formation progress making it easier to form for future research developments. </p></font> | <p><font face="Times New Roman" size="4pt">Therefore, in our project this year, we would only insert the mamAB operon from MSG to our bacteria Azotobacter Vinelandii, hoping to test on using minimal number of genes to produce functional magnetosome. This aims at assisting the magnetosome formation progress making it easier to form for future research developments. </p></font> | ||
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<p><font face="Times New Roman" size="4pt">Hence, in order to put our gene of interest (mamAB operon) into a vector, we need to produce a template first and put it into E .coli (the strand of E. coli we are using is BL21). The template which we used is a vector which includes J13002 (consists of the constitutive promoter R0040 and the RBS); the flanking sequences; and the double terminator. All in between the multiple restriction sites. </p></font> | <p><font face="Times New Roman" size="4pt">Hence, in order to put our gene of interest (mamAB operon) into a vector, we need to produce a template first and put it into E .coli (the strand of E. coli we are using is BL21). The template which we used is a vector which includes J13002 (consists of the constitutive promoter R0040 and the RBS); the flanking sequences; and the double terminator. All in between the multiple restriction sites. </p></font> | ||
− | <p><font face="Times New Roman" size="4pt">Flanking sequences are actually the first 250 bp and also last 250 bp of the whole linkage of genes which we want to “flip into” our template. Therefore in order to flip in the first half of the mamAB operon, in other words, the one starting with mamH and ends with mamN, we need to have a total of two flanking sequences. This is done by making the first 250bp of mamH as the first flanking sequence and also the last 250 bp of mamN as the second flanking sequence in the template. As BL21 (the strand of E. coli) has a special enzyme RecA, therefore it is able to perform in vivo homologous recombination | + | <p><font face="Times New Roman" size="4pt">Flanking sequences are actually the first 250 bp and also last 250 bp of the whole linkage of genes which we want to “flip into” our template. Therefore in order to flip in the first half of the mamAB operon, in other words, the one starting with mamH and ends with mamN, we need to have a total of two flanking sequences. This is done by making the first 250bp of mamH as the first flanking sequence and also the last 250 bp of mamN as the second flanking sequence in the template. As BL21 (the strand of E. coli) has a special enzyme RecA, therefore it is able to perform in vivo homologous recombination[2].</p></font> |
<p><font face="Times New Roman" size="4pt">With these homologous parts as our template, we can then flip in both parts of the mamAB operon into the vector which should be much easier than ligating such a long mamAB operon into the vector by usual method. As vectors by usual method usually can’t uphold more than 10kb gene of interest. </p></font> | <p><font face="Times New Roman" size="4pt">With these homologous parts as our template, we can then flip in both parts of the mamAB operon into the vector which should be much easier than ligating such a long mamAB operon into the vector by usual method. As vectors by usual method usually can’t uphold more than 10kb gene of interest. </p></font> |
Revision as of 14:39, 18 September 2015