Team:Heidelberg/Project SaO
From 2009.igem.org
Line 31: | Line 31: | ||
For <span style="font-size:6mm;">output</span>, we suggest using a variety of fluorescent proteins (with non-overlapping spectra) coupled to localization tags. We were able to provide two FPs (GFP and mCherry) as well as four localization sequences (1x [[Team:Heidelberg/Eucaryopedia#Sar-1|Endoplasmic reticulum]]; 1x [[Team:Heidelberg/Eucaryopedia#NLS|Nucleus]]; 2x [[Team:Heidelberg/Eucaryopedia#GPI|Plasma membrane]]). We show that combining our FPs with out lcalization sequences works, and thus provide future users with the possibility to visualize at least 6 different promoters simultaneously. | For <span style="font-size:6mm;">output</span>, we suggest using a variety of fluorescent proteins (with non-overlapping spectra) coupled to localization tags. We were able to provide two FPs (GFP and mCherry) as well as four localization sequences (1x [[Team:Heidelberg/Eucaryopedia#Sar-1|Endoplasmic reticulum]]; 1x [[Team:Heidelberg/Eucaryopedia#NLS|Nucleus]]; 2x [[Team:Heidelberg/Eucaryopedia#GPI|Plasma membrane]]). We show that combining our FPs with out lcalization sequences works, and thus provide future users with the possibility to visualize at least 6 different promoters simultaneously. | ||
- | + | We also established methods for promoter [[Team:Heidelberg/Project_Measurement|<span style="font-size:5mm;">measurement</span>]] in eukaryotes utilizing microscopy, flow cytometry (FACS) and qRT-PCR. Promoter activity was not measured by microscopy before; we established this technique in order to be able to measure protein levels in different compartments and thus make the output legible. <!--determine the activity of the promoters developed utilizing both approaches in more than one mammalian cell line, besides providing [[Team:Heidelberg/Project_Measurement#A promoter measurement kit for use in mammalian systems|measurement and normalization devices]], as well as a device that allows the integration of any Biobrick-β (BBb)-compatible block in a plasmid and its transfection into eukaryotic cells in a working form. All together, a standard method to characterize any promoter using such parts was established and [[Team:Heidelberg/Project_Measurement#Two units for promoter activity in mammalian cells|units]] describing promoter strength (as measured using these methods) were also defined.--> | |
:<!--As a further attempt, we tried to establish a [[Team:Heidelberg/stables|cell line]] that overcomes the variability in measurements caused by drawbacks of transient transfection by allowing the stable integration of inserts at a predetermined integration site in the genome of the cell line in use. Such an approach helps eliminating epigenetic variability in gene expression control. Although, this part was never realized in its final form, we are proud to have introduced the value of such a concept to the emerging field of eukaryotic promoter research and our own experimental observations have further strengthened our belief in the need of such a cell line in the future.--> Not only to overcome challenges for promoter measurement, but also to lay the foundations for the proposed drug-screening assay as well as any other synthetic biology idea in mammalian cells, we emphasize the importance of [[Team:Heidelberg/stables|stable cell line creation]]. | :<!--As a further attempt, we tried to establish a [[Team:Heidelberg/stables|cell line]] that overcomes the variability in measurements caused by drawbacks of transient transfection by allowing the stable integration of inserts at a predetermined integration site in the genome of the cell line in use. Such an approach helps eliminating epigenetic variability in gene expression control. Although, this part was never realized in its final form, we are proud to have introduced the value of such a concept to the emerging field of eukaryotic promoter research and our own experimental observations have further strengthened our belief in the need of such a cell line in the future.--> Not only to overcome challenges for promoter measurement, but also to lay the foundations for the proposed drug-screening assay as well as any other synthetic biology idea in mammalian cells, we emphasize the importance of [[Team:Heidelberg/stables|stable cell line creation]]. |
Revision as of 18:08, 20 October 2009
Outlook and summaryThe emergence of interest in manipulatable eukaryotic systems has posed much pressure on the development of methods to help understand and characterize eukaryotic gene regulation. Those methods go beyond the already rather sophisticated methodology still being established in prokaryotes to investigate and thereafter engineer these cells as needed [1]. For one thing, the design of promoters exclusively responsive to one transcription factor (TF) within eukaryotic cells could certainly help improve our understanding of the key components of one pathway or the other, while eliminating the cross-talk often observed with many naturally occurring promoters. Such promoters have often posed a challenge to researchers studying signal transduction in eukaryotic systems because of the different types of TFs a single regulatory element can bind, and a single TF having multiple target regulatory regions [2]. With the emergence of systematized research and attempts for modeling biological systems, the availability of data with minimal experimental variability and highly accurate experimental conditions has also contributed to the need for such finely-tuned promoters. Once such exclusive promoters could be available and methods for their characterization established, it is not so hard to imagine the revolutionary effect they could have on eukaryotic research. Some of many applications could be:
Over the last three months we have been able to devise two independent methods to design eukaryotic promoters of desired selectivity and strength. The two methods referred to are based on different principles, one being a biochemical method (RA-PCR) and the other an in silico method (HEARTBEAT). Noteworthy is that the in silico method resulted in a tool that not only helps design promoters of required selectivity, but also helps evaluate the quality of promoters as well as provide online users (of our wiki) to use the same principle to design their own through an elegant Graphical User Interface (GUI). Also, we propose ways to combine the two methods. By applying these methods, we have been able to generate a library of constitutive promoters of varying strengths as well as a selection of specific promoters. For output, we suggest using a variety of fluorescent proteins (with non-overlapping spectra) coupled to localization tags. We were able to provide two FPs (GFP and mCherry) as well as four localization sequences (1x Endoplasmic reticulum; 1x Nucleus; 2x Plasma membrane). We show that combining our FPs with out lcalization sequences works, and thus provide future users with the possibility to visualize at least 6 different promoters simultaneously. We also established methods for promoter measurement in eukaryotes utilizing microscopy, flow cytometry (FACS) and qRT-PCR. Promoter activity was not measured by microscopy before; we established this technique in order to be able to measure protein levels in different compartments and thus make the output legible.
References[1] Venter M., Synthetic promoters: genetic control through cis engineering, Trends in Plant Science, 12:118-124 [2] Carey M., Smale S. T., Hughes H., Transcriptional Regulation in Eukaryotes: Concepts, Strategies and Techniques. New York:CSHL, p. 18-25 (2000) |