Difference between revisions of "Cohen-Boyer-Berg experiment"
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A population of ''E. coli'' cells were then transformed to incorporate the plasmids into their cells and grown on media containing tetracycline to select for the cells that contained the plasmid conferring tetracycline resistance. These could then be screened to identify the cells with plasmids that had incorporated the Xenopus DNA. | A population of ''E. coli'' cells were then transformed to incorporate the plasmids into their cells and grown on media containing tetracycline to select for the cells that contained the plasmid conferring tetracycline resistance. These could then be screened to identify the cells with plasmids that had incorporated the Xenopus DNA. | ||
| − | [[File:Transform-ecori-dna-and-plasmid.png]] | + | [[File:Transform-ecori-dna-and-plasmid.png|500px]] |
Above, the mixture of plasmids with and without the insert are introduced into ''E. coli'' cells. The cells are then raised on media containing tetracycline so that cells without a plasmid (gray) do not grow. Individual colonies can be picked and tested for the presence of the insert (yellow) or just the plasmid without the insert (blue). Once a colony is found that contains the insert it can be grown in large numbers<ref>The cells are theoretically genetically identical to each other so this is referred to as "cloning" the DNA of interest.</ref> and the DNA purified to yield the inserted plasmid. | Above, the mixture of plasmids with and without the insert are introduced into ''E. coli'' cells. The cells are then raised on media containing tetracycline so that cells without a plasmid (gray) do not grow. Individual colonies can be picked and tested for the presence of the insert (yellow) or just the plasmid without the insert (blue). Once a colony is found that contains the insert it can be grown in large numbers<ref>The cells are theoretically genetically identical to each other so this is referred to as "cloning" the DNA of interest.</ref> and the DNA purified to yield the inserted plasmid. | ||
The end result was a bacteria that stably replicated a fragment of amphibian ribosomal DNA. | The end result was a bacteria that stably replicated a fragment of amphibian ribosomal DNA. | ||
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| + | =References and Footnotes= | ||
<references/> | <references/> | ||
Revision as of 21:00, 12 July 2014
In 1973 the first living genetically engineered transgenic organism was made in the Cohen-Boyer-Berg experiment.
A plasmid (pSC101[1]) containing a gene conferring resistance to tetracycline (Tcr) and an origin of replication was cut at a single site with the restriction enzyme EcoRI.
DNA from an African clawed frog (Xenopus laevis) was also cut with EcoRI and this yielded a range of DNA fragments including a large number of ribosomal DNA (that codes for rRNA) fragments[2] with matching "sticky ends".
Above, the sites that are recognized and cut by EcoRI are shown by DNA base letters and red lines respectively. Below is a schematic of the cut DNA showing the overhanging "sticky ends".
The cut plasmid and Xenopus DNA were mixed together with a ligase to repair the cut site, incorporating the Xenopus rRNA fragment into a fraction of the plasmids.
A population of E. coli cells were then transformed to incorporate the plasmids into their cells and grown on media containing tetracycline to select for the cells that contained the plasmid conferring tetracycline resistance. These could then be screened to identify the cells with plasmids that had incorporated the Xenopus DNA.
Above, the mixture of plasmids with and without the insert are introduced into E. coli cells. The cells are then raised on media containing tetracycline so that cells without a plasmid (gray) do not grow. Individual colonies can be picked and tested for the presence of the insert (yellow) or just the plasmid without the insert (blue). Once a colony is found that contains the insert it can be grown in large numbers[3] and the DNA purified to yield the inserted plasmid.
The end result was a bacteria that stably replicated a fragment of amphibian ribosomal DNA.
References and Footnotes
- ↑ The plasmid is named pSC101 because it was the 101st plasmid isolated by Stanley Cohen.
- ↑ Ribosomal DNA sequences are present in many copies in the genome and in Xenopus these contain two EcoRI sites close together.
- ↑ The cells are theoretically genetically identical to each other so this is referred to as "cloning" the DNA of interest.
