Difference between revisions of "Part:BBa K2992024"
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The BgaR-BgaL system of <i>C. perfringens</i> comprises the transcriptional regulator BgaR belonging to the AraC-family and the β-galactosidase BgaL which are transcribed in a regulated fashion from the divergent P<i>gaR</i> -P<i>gaL</i> promoter. The BgaR-BgaL system regulates the expression of carbohydrate metabolic genes in response to lactose concentrations (Hartman and Melville 2011). This parts entry represents the RBS and 5’-UTR predicted to regulate <i>bgaL</i>. Our group has recently utlised the BgaRL regulatory system in order to generate a tightly regulate inducible system for CRISPR-Cas mutagenesis in the genus <i>Clostridium</i> (Cañadas et al., 2019). In our project, we use the P<i>gaR</i> -P<i>gaL</i> regulatory system comprised of the divergent promoter and associated 5’-UTRs in conjunction with their cognate transcriptional regulator <i>bgaR</i> (hyperlinks and descriptions) to drive the expression of our volatile and FAST reporter genes in an inducible fashion. Doing so helps us fulfil our goal of generating reporter strains for the prediction of botulinum neurotoxin production following food manufacture. <br><br> | The BgaR-BgaL system of <i>C. perfringens</i> comprises the transcriptional regulator BgaR belonging to the AraC-family and the β-galactosidase BgaL which are transcribed in a regulated fashion from the divergent P<i>gaR</i> -P<i>gaL</i> promoter. The BgaR-BgaL system regulates the expression of carbohydrate metabolic genes in response to lactose concentrations (Hartman and Melville 2011). This parts entry represents the RBS and 5’-UTR predicted to regulate <i>bgaL</i>. Our group has recently utlised the BgaRL regulatory system in order to generate a tightly regulate inducible system for CRISPR-Cas mutagenesis in the genus <i>Clostridium</i> (Cañadas et al., 2019). In our project, we use the P<i>gaR</i> -P<i>gaL</i> regulatory system comprised of the divergent promoter and associated 5’-UTRs in conjunction with their cognate transcriptional regulator <i>bgaR</i> (hyperlinks and descriptions) to drive the expression of our volatile and FAST reporter genes in an inducible fashion. Doing so helps us fulfil our goal of generating reporter strains for the prediction of botulinum neurotoxin production following food manufacture. <br><br> | ||
===Characterisation=== | ===Characterisation=== | ||
− | + | The Plac system is an inducible promoter system utilizing the lactose operon from C. Perfringens. This allowed us to test the maximum and minimum reporter expression range. See our [https://2019.igem.org/Team:Nottingham/Results results page] for more information. | |
+ | |||
+ | https://static.igem.org/mediawiki/parts/e/e3/Plac_diagram.png | ||
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Revision as of 20:35, 21 October 2019
5-UTR containing RBS for bgaL from C. perfringens
5’UTR containing RBS predicted to regulate bgaL in C. perfringens.
Usage and Biology
The BgaR-BgaL system of C. perfringens comprises the transcriptional regulator BgaR belonging to the AraC-family and the β-galactosidase BgaL which are transcribed in a regulated fashion from the divergent PgaR -PgaL promoter. The BgaR-BgaL system regulates the expression of carbohydrate metabolic genes in response to lactose concentrations (Hartman and Melville 2011). This parts entry represents the RBS and 5’-UTR predicted to regulate bgaL. Our group has recently utlised the BgaRL regulatory system in order to generate a tightly regulate inducible system for CRISPR-Cas mutagenesis in the genus Clostridium (Cañadas et al., 2019). In our project, we use the PgaR -PgaL regulatory system comprised of the divergent promoter and associated 5’-UTRs in conjunction with their cognate transcriptional regulator bgaR (hyperlinks and descriptions) to drive the expression of our volatile and FAST reporter genes in an inducible fashion. Doing so helps us fulfil our goal of generating reporter strains for the prediction of botulinum neurotoxin production following food manufacture.
Characterisation
The Plac system is an inducible promoter system utilizing the lactose operon from C. Perfringens. This allowed us to test the maximum and minimum reporter expression range. See our results page for more information.
Sequence and Features
- 10COMPATIBLE WITH RFC[10]
- 12COMPATIBLE WITH RFC[12]
- 21COMPATIBLE WITH RFC[21]
- 23COMPATIBLE WITH RFC[23]
- 25COMPATIBLE WITH RFC[25]
- 1000COMPATIBLE WITH RFC[1000]
References
Cañadas, I., Groothuis, D., Zygouropoulou, M., Rodrigues, R. and Minton, N. (2019). RiboCas: A Universal CRISPR-Based Editing Tool for Clostridium. ACS Synthetic Biology, 8(6), pp.1379-1390
Minton, N., Ehsaan, M., Humphreys, C., Little, G., Baker, J., Henstra, A., Liew, F., Kelly, M., Sheng, L., Schwarz, K. and Zhang, Y. (2016). A roadmap for gene system development in Clostridium. Anaerobe, 41, pp.104-112. 2019 RiboCas - update
Hartman, A., Liu, H. and Melville, S. (2010). Construction and Characterization of a Lactose-Inducible Promoter System for Controlled Gene Expression inClostridium perfringens. Applied and Environmental Microbiology, 77(2), pp.471-478.
Zuker, M. (2003). Mfold web server for nucleic acid folding and hybridization prediction. Nucleic Acids Research, 31(13), pp.3406-3415.