Team:Uppsala/reporter-genes
From 2013.igem.org
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<h1>Chromoproteins in Lactobacillus </h1> | <h1>Chromoproteins in Lactobacillus </h1> | ||
- | <p>There are many things we take for granted when working with bacteria such as E. coli. An initial problem when learning to work with Lactobacillus is to simply be able to do successful transformations of plasmids, | + | <p>There are many things we take for granted when working with bacteria such as E. coli. An initial problem when learning to work with Lactobacillus is to simply be able to do successful transformations of plasmids, something that is more difficult and cumbersome to do compared to E. coli. To see if you have been able to master a transformation with Lactobacillus some basic reporter genes that reflects visible light makes the validation process a lot easier.</p> |
<img class="method-plasmid" src="https://static.igem.org/mediawiki/2013/9/9b/Uppsala2013_reporter-plasmid.jpg"> | <img class="method-plasmid" src="https://static.igem.org/mediawiki/2013/9/9b/Uppsala2013_reporter-plasmid.jpg"> | ||
- | <p>Above is a picture of one of our chromo proteins and RBS fused together with two of our synthetic promoters, CP11(lank ) and CP29(lank). These are characterised and has been shown to work both in E. coli and Lactobacillus. We wanted to see if our | + | <p>Above is a picture of one of our chromo proteins and RBS fused together with two of our synthetic promoters, CP11(lank ) and CP29(lank). These are characterised and has been shown to work both in E. coli and Lactobacillus. We wanted to see if our chromoproteins could work as visual reporters. The construct has been shown to work fine with our shuttle vector in E. coli as can clearly be seen in the picture with blue bacterial colonies. We have however not yet been able to transform it into Lactobacillus.</p> |
Revision as of 08:49, 29 September 2013
Reporter genes
One of the most fundamental parts required in a new chassi is a reporter gene. Unfortunately, some fluorescent proteins do not work well in Lactobacillus, possibly due to lower levels of internal pH in the cytosol.
One popular fluorescent protein that do work is mCherry. We have created a biobricked version of mCherry codon optimized for Lactobacillus reuteri, however it should work well in most species in the Lactobacillus genus. The gene has been modified in accordance with the Freiburgh fusion standard 25. Because of time constraints we have not yet had time to characterise it but it has been used in non-biobrick format by other researchers with positive results
Prefix
gaattccgcggccgcttctagatggccggc...
Suffix
... accggttaatactagtagcggccgctgcag
Chromoproteins in Lactobacillus
There are many things we take for granted when working with bacteria such as E. coli. An initial problem when learning to work with Lactobacillus is to simply be able to do successful transformations of plasmids, something that is more difficult and cumbersome to do compared to E. coli. To see if you have been able to master a transformation with Lactobacillus some basic reporter genes that reflects visible light makes the validation process a lot easier.
Above is a picture of one of our chromo proteins and RBS fused together with two of our synthetic promoters, CP11(lank ) and CP29(lank). These are characterised and has been shown to work both in E. coli and Lactobacillus. We wanted to see if our chromoproteins could work as visual reporters. The construct has been shown to work fine with our shuttle vector in E. coli as can clearly be seen in the picture with blue bacterial colonies. We have however not yet been able to transform it into Lactobacillus.