Team:Heidelberg/Project Natural promoters
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== Results == | == Results == | ||
- | After cloning | + | After cloning the natural promoters in our screening plasmid pSMB_MEASURE, they were tested in different cell lines with appropriate induction substances. The transfected cells were measured by flow cytometry and TECAN. Thereby, the c-Jun promoter and the CYP1A1 promoter were tested by flow cytometry and the LDL receptor promoter, HSP70 promoter and HMG CoA synthase promoter were measured by TECAN. The CYP1A1 measurement could not be analyzed, due to the low cell number. In Fig. 2, the flow cytometry measurement data of the c-Jun promoter is displayed, which was induced by Epidermal Growth Factor for three hours. The results present an induction of more than 100%. |
- | + | Fig. 3 presents the TECAN results of the both SREBP responsive promoters, LDL receptor and HMG CoA synthase promoter. | |
- | + | ||
- | [[image:HD09_1110_c-jun2.png|left|thumb|650px|'''Figure 2: Flow cytometry results of the natural promoter c-Jun (Ap-1).''' HeLa cells were cotransfected with the natural c-Jun promoter coupled to GFP and a reference plasmid including the promoter JeT coupled to mCherry. The relative fluorescence (REU) of GFP relative to our reference promoter JeT is measured 3 hours after induction with EGF (diluted 1:2000 in DMEM++). The standard deviation is indicated by the error bars.''']] | + | [[image:HD09_1110_c-jun2.png|left|thumb|650px|'''Figure 2: Flow cytometry results of the natural promoter c-Jun (Ap-1).''' HeLa cells were cotransfected with the natural c-Jun promoter coupled to GFP and a reference plasmid including the promoter JeT coupled to mCherry. The relative fluorescence (REU) of GFP, relative to our reference promoter JeT, is measured 3 hours after induction with EGF (diluted 1:2000 in DMEM++). The standard deviation is indicated by the error bars.''']] |
[[image:HD09_LDL_HMG_CoA.png|left|thumb|650px|'''Figure 3: TECAN results of the natural LDL receptor promoter and HMG CoA synthase promoter.''' The natural LDL receptor promoter and HMG CoA synthase promoter are coupled to GFP and were cotransfected with a reference plasmid, which includes the standard promoter JeT coupled to mCherry, into HeLa cells. The GFP fluorescence relative to JeT is measured after the induction with Lipo Deficient Serum medium. The error bars represent the standard deviation.]] | [[image:HD09_LDL_HMG_CoA.png|left|thumb|650px|'''Figure 3: TECAN results of the natural LDL receptor promoter and HMG CoA synthase promoter.''' The natural LDL receptor promoter and HMG CoA synthase promoter are coupled to GFP and were cotransfected with a reference plasmid, which includes the standard promoter JeT coupled to mCherry, into HeLa cells. The GFP fluorescence relative to JeT is measured after the induction with Lipo Deficient Serum medium. The error bars represent the standard deviation.]] | ||
== Discussion == | == Discussion == | ||
- | The evaluation of the c-Jun natural promoter looks very promising. The flow cytometry measurement should be repeated at least three times, which could not be accomplished in the given time frame. Besides, this measurement could be also analyzed by fluorescence microscopy and image analysis for validation. The TECAN measurement of the SREBP responsive promoters, LDL receptor and HMG CoA synthase promoter, show a significant induction. This should also be validated by microscopy and flow cytometry. Unfortunately, the appropriate induction conditions for the other natural promoters could not | + | The evaluation of the c-Jun natural promoter looks very promising. The flow cytometry measurement should be repeated at least three times, which could not be accomplished in the given time frame. Besides, this measurement could be also analyzed by fluorescence microscopy and image analysis for validation. The TECAN measurement of the SREBP responsive promoters, LDL receptor and HMG CoA synthase promoter, show a significant induction. This should also be validated by microscopy and flow cytometry. Unfortunately, the appropriate induction conditions for the other natural promoters could not be established in the remaining time. |
== Methods == | == Methods == | ||
- | The different natural promoter inserts (see table 1) were integrated in the [https://2009.igem.org/Team:Heidelberg/Project_Measurement#A_promoter_measurement_kit_for_use_in_mammalian_systems pSMB_MEASURE]. For this purpose, the promoters of the ordered plasmids/genomic DNA were amplified by PCR and primers with BBb standard. These PCR products were digested by restriction enzymes and purified. The purified inserts were ligated into the pSMB_MEASURE plasmid and transformed into DH5alpha bacterial cells. After mini-preparation the plasmids were sequenced, which revealed the right sequences. The natural promoters were transfected in different cell lines and induced with appropriate substances, which is presented in table 1. The analysis | + | The different natural promoter inserts (see table 1) were integrated in the [https://2009.igem.org/Team:Heidelberg/Project_Measurement#A_promoter_measurement_kit_for_use_in_mammalian_systems pSMB_MEASURE]. For this purpose, the promoters of the ordered plasmids/genomic DNA were amplified by PCR and primers with BBb standard. These PCR products were digested by restriction enzymes and purified. The purified inserts were ligated into the pSMB_MEASURE plasmid and transformed into DH5alpha bacterial cells. After mini-preparation, the plasmids were sequenced, which revealed the right sequences. The natural promoters were transfected in different cell lines and induced with appropriate substances, which is presented in table 1. The analysis was made by flow cytometry or TECAN measurement. More details about the method are found in the [https://2009.igem.org/Team:Heidelberg/Notebook_natural_promoters_overview Notebook]. |
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Latest revision as of 21:31, 21 October 2009
Natural PromotersIntroductionEukaryotic promoters are very complex and difficult to characterize. They usually lie upstream of their target gene, but they can have regulatory elements that are several kilobases away from the promoter. Fig. 1 shows some of the factors involved in the transcriptional regulation of polymerase II [1]. For our assay we want to utilize several natural promoters to sense certain conditions in the cell, such as hypoxia, DNA damage and heat. The selection criteria for these promoters are that they have to be very specific to a transcription factor and they have to be easily induced and inhibited. These natural promoters will give us a chance to start testing and fine-tuning our output system early on which can then be applied to our synthetic promoters. ResultsAfter cloning the natural promoters in our screening plasmid pSMB_MEASURE, they were tested in different cell lines with appropriate induction substances. The transfected cells were measured by flow cytometry and TECAN. Thereby, the c-Jun promoter and the CYP1A1 promoter were tested by flow cytometry and the LDL receptor promoter, HSP70 promoter and HMG CoA synthase promoter were measured by TECAN. The CYP1A1 measurement could not be analyzed, due to the low cell number. In Fig. 2, the flow cytometry measurement data of the c-Jun promoter is displayed, which was induced by Epidermal Growth Factor for three hours. The results present an induction of more than 100%. Fig. 3 presents the TECAN results of the both SREBP responsive promoters, LDL receptor and HMG CoA synthase promoter.
DiscussionThe evaluation of the c-Jun natural promoter looks very promising. The flow cytometry measurement should be repeated at least three times, which could not be accomplished in the given time frame. Besides, this measurement could be also analyzed by fluorescence microscopy and image analysis for validation. The TECAN measurement of the SREBP responsive promoters, LDL receptor and HMG CoA synthase promoter, show a significant induction. This should also be validated by microscopy and flow cytometry. Unfortunately, the appropriate induction conditions for the other natural promoters could not be established in the remaining time. MethodsThe different natural promoter inserts (see table 1) were integrated in the pSMB_MEASURE. For this purpose, the promoters of the ordered plasmids/genomic DNA were amplified by PCR and primers with BBb standard. These PCR products were digested by restriction enzymes and purified. The purified inserts were ligated into the pSMB_MEASURE plasmid and transformed into DH5alpha bacterial cells. After mini-preparation, the plasmids were sequenced, which revealed the right sequences. The natural promoters were transfected in different cell lines and induced with appropriate substances, which is presented in table 1. The analysis was made by flow cytometry or TECAN measurement. More details about the method are found in the Notebook.
References[1] Alberts, B. et al: „Molekularbiologie der Zelle“ (Book. 4th edition, 2004. WILEY-VCH) Chapter 6, p. 357-359. [2] Clarke N., Arenzana N., Hai T., Minden A., Prywes R. Epidermal Growth Factor Induction of the c-jun Promoter by a Rac Pathway. Mol Cell Biol 18, 1065–1073 (1998). [3] Hoffman L. M., Garcha K., Karamboulas K., Cowan M. F., Drysdale L. M., Horton W. A., Underhill T. M. BMP action in skeletogenesis involves attenuation of retinoid signaling. J Cell Biol 174, 101–113 (2006). [4] Castoreno A. B., Wang Y., Stockinger W., Jarzylo L. A., Du H., Pagnon J. C., Shieh E. C., Nohturfft A. Transcriptional regulation of phagocytosis-induced membrane biogenesis by sterol regulatory element binding proteins. Proc Natl Acad Sci U S A 102, 13129–13134 (2005). [5] Schmidt M., Heimberger T., Gruensfelder P., Schler G., Hoppe F. Inducible promoters for gene therapy of head and neck cancer: an in vitro study. Eur Arch Otorhinolaryngol 261, 208–215 (2004). [6] Jorgensen, E. C. B. and Autrup, H. Autoregulation of human CYP1A1 gene promoter activity in HepG2 and MCF-7 cells. Carcinogenesis 17, 435-441 (1996). [7] Schreiber T. D., Köhle C., Buckler F., Schmohl S., Braeuning A., Schmiechen A., Schwarz M., Münzel P.A. Regulation of CYP1A1 expression by the antioxidant Tert butylhydroquinone. Drug Metabolism And Disposition 43, 1096–1101 (2006).
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