IGEM:IMPERIAL/2007/Projects/In-Veso: Difference between revisions
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Unlike eukaryotic systems where transcription and translation occur sequentially, in E. coli systems, coupled transcription and translation occur simultaneously in the same tube under the same reaction conditions. This bacterial system gives efficient expression of either prokaryotic or eukaryotic gene products in a short amount of time. Capping of eukaryotic RNA is not required. Use of E.coli extract also eliminates cross-reactivity or other problems associated with endogenous proteins in eukaryotic lysates. In addition, the E. coli S30 extract system allows expression from DNA vectors containing natural E. coli promoter sequences (such as lac). | Unlike eukaryotic systems where transcription and translation occur sequentially, in E. coli systems, coupled transcription and translation occur simultaneously in the same tube under the same reaction conditions. This bacterial system gives efficient expression of either prokaryotic or eukaryotic gene products in a short amount of time. Capping of eukaryotic RNA is not required. Use of E.coli extract also eliminates cross-reactivity or other problems associated with endogenous proteins in eukaryotic lysates. In addition, the E. coli S30 extract system allows expression from DNA vectors containing natural E. coli promoter sequences (such as lac). | ||
==The In-Veso Technque== | |||
Write introduction to in-veso here. [[User:Dirk Van Swaay|Dirk]] 17:03, 26 July 2007 (EDT) | |||
==References== | ==References== | ||
Revision as of 14:03, 26 July 2007
In-Veso Gene Expression: Introduction
The E.coli In Vitro Gene Expression System
The in vitro expression of proteins in cell-free extracts is an important tool for molecular biologists and has a variety of applications. The use of in vitro translation systems can have advantages over in vivo gene expression when the over-expressed product is toxic to the host cell, when the product is insoluble or forms inclusion bodies, or when the protein undergoes rapid proteolytic degradation by intracellular proteases. [1] The big advantage of the in vitro approach in our projects, is that it enables the detection of biofilm on medical devices and the detection of spoilage in meat, without actually having to place E.coli in contact with the medical devices or the meat.
There are two approaches to in vitro protein synthesis based on the starting genetic material: RNA or DNA. Standard translation systems use RNA as a template; whereas coupled transcription-translation systems start with DNA templates, which are transcribed into RNA then translated. DNA templates for coupled transcription-translation systems can be easily generated by PCR. The most frequently used cell-free systems consist of extracts from rabbit reticulocytes, wheat germ and E.coli. For the purposes of our projects, the E.coli system looks more attractive than the eukaryotic systems.
Unlike eukaryotic systems where transcription and translation occur sequentially, in E. coli systems, coupled transcription and translation occur simultaneously in the same tube under the same reaction conditions. This bacterial system gives efficient expression of either prokaryotic or eukaryotic gene products in a short amount of time. Capping of eukaryotic RNA is not required. Use of E.coli extract also eliminates cross-reactivity or other problems associated with endogenous proteins in eukaryotic lysates. In addition, the E. coli S30 extract system allows expression from DNA vectors containing natural E. coli promoter sequences (such as lac).
The In-Veso Technque
Write introduction to in-veso here. Dirk 17:03, 26 July 2007 (EDT)
