Difference between revisions of "Team:SDU-Denmark/Tour52"
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+ | <div class="thumbcaption”>Figure 2: Fluorescence microscopy images: (A) pSB1C3-T25-GFP, (B) pSB1C3-T18-GFP and (C) pSB1C3-T18 transformed into TOP10 (<i>E. coli</i> K12-strain). Both (A) and (B) show, as expected, green fluorescence. | ||
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Revision as of 16:53, 18 September 2015
"Alone we can do so little; together we can do so much." - Helen Keller
In order to make a great screening for peptide aptamers you need a well-functioning screening system. Our screening system, is the bacterial two-hybrid system. This is system is based on the reconstitution of the adenylate cyclase and allows detection of protein-protein interaction. In this page we validate the function of the two-hybrid system.
Control ExperimentTo validate that our T18 and T25 domain constructs in fact can be used to study protein-protein interactions, we made a control experiment, where the leucine zipper region from the GCN4 yeast protein was fused to the T18 and T25 domains (T18-Zip+T25-Zip). Leucine zippers are known to interact by forming homodimers. If the system indeed works, their interaction will lead to functional complementation between the T18 and T25 domains. This leads to the synthesis of cAMP. By using a cAMP-induced reporter system, one can observe whether or not there is an interaction.
When working with the bacterial two-hybrid system, it is necessary to use a strain with a deficiency in the gene encoding the adenylate cyclase, cyaA. For this purpose we constructed the Escherichia coli K12-strain, MG1655 cyaA. We also used the cyaA-deficient E. coli K12-strain BTH101 (MC1061-derived). This was for the purpose to exploit the lacZ-derived reporter system. The lacZ gene encodes a -Galactosidase which is positively controlled by cAMP. Our goal was to use the RFP reporter system (BBa_K861173) in the MG1655 cyaA-strain. However, this control experiment was carried out in the BTH101-strain.