Team:Waterloo/Deliver
From 2014.igem.org
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<h2>Design</h2> | <h2>Design</h2> | ||
<h3>Strain Considerations</h3> | <h3>Strain Considerations</h3> | ||
- | <p>To test our system in the lab, a Level 1 organism was used as a safety precaution. Staphylococcus epidermidis (ATCC 12228) is a close relative of Staphylococcus aureus and is able to conjugate with S. aureus populations (Forbes and Schaberg, 1983).</p> | + | <p>To test our system in the lab, a Level 1 organism was used as a safety precaution. Staphylococcus epidermidis (ATCC 12228) is a close relative of <i>Staphylococcus aureus</i> and is able to conjugate with <i>S. aureus</i> populations (Forbes and Schaberg, 1983).</p> |
- | h3>Conjugation Machinery</h3> | + | <h3>Conjugation Machinery</h3> |
- | <p>The plasmid pGO1 is of the few gram positive conjugative plasmids studied. The entire 54 kb plasmid has been sequenced by Caryl and O’Neill (2009) (Accession: NC 012547.1). The parts of the pGO1 conjugative plasmid sufficient for trans-species conjugation include a ~ 14 kb trs gene cluster, and a ~2 kb region containing the oriT and a gene which encodes for a nickase protein (Climo et al., 1996).</p> | + | <p>The plasmid pGO1 is of the few gram positive conjugative plasmids studied. The entire 54 kb plasmid has been sequenced by Caryl and O’Neill (2009) (Accession: NC 012547.1). The parts of the pGO1 conjugative plasmid sufficient for trans-species conjugation include a ~ 14 kb trs gene cluster, and a ~2 kb region containing the <i>oriT</i> and a gene which encodes for a nickase protein (Climo et al., 1996).</p> |
<h3>Experiment</h3> | <h3>Experiment</h3> | ||
- | <p>In order to test the conjugation machinery in S. epidermidis, we sought to construct a conjugative plasmid containing the oriT region and trs region from pGO1. The plasmid should maintain a low copy number to ensure a lower metabolic load imposition which would increase the chance of acceptance by the cell. The low copy, theta replicating oriV from the Staphylococcal plasmid pSK41 (BBa_K1323018) was a great candidate. An erythromycin resistance gene (BBa_K1323011) was chosen as the selection marker and DsRed (BBa_K1323015) (Figure X) was chosen as a reporter to track the movement of the plasmid. </p> | + | <p>In order to test the conjugation machinery in <i>S. epidermidis</i>, we sought to construct a conjugative plasmid containing the oriT region and <i>trs</i> region from pGO1. The plasmid should maintain a low copy number to ensure a lower metabolic load imposition which would increase the chance of acceptance by the cell. The low copy, theta replicating oriV from the <i>Staphylococcal</i> plasmid pSK41 (BBa_K1323018) was a great candidate. An erythromycin resistance gene (BBa_K1323011) was chosen as the selection marker and DsRed (BBa_K1323015) (Figure X) was chosen as a reporter to track the movement of the plasmid. </p> |
</p> | </p> |
Revision as of 02:03, 18 October 2014
Deliver
Overview: Delivering Antibiotic Susceptibility in vivo
In order to modify a MRSA population and in turn, have the population able to propagate the modification, a method of delivery is essential. Conjugation, the horizontal transfer of genetic material between bacterial cells, is the proposed method for this delivery.
We decided to use conjugation as our mode of delivery because it has a large carrying capacity. Our silencing systems are quite large and therefore need the appropriate delivery mechanism. While a Staphylococcus virus would be more efficient at transferring DNA to a recipient cell, there are no Staphylococcus viruses that have been found with a carrying capacity large enough to handle our silencing systems.
Conjugation is a transfer of genetic material between prokaryotes by cell-to-cell contact. This process is well characterized in gram-negative bacteria, such as E. coli, but it is less characterized in gram-positive bacteria like Staphylococcus aureus. To infer information on the gram-positive process, microbiologists usually use the gram-negative process as a template (Grohmann et al, 2003).
The conjugation process in both gram-positive and gram-negative bacteria all share underlying similarities. For example, an origin of transfer (oriT) is required for all plasmid conjugation. A multiprotein complex that binds to the origin of transfer is called the relaxosome. The proteins involved in the relaxosome are coded within a tra/trs region that can be found on the plasmid or on the chromosome. The relaxosome is recognized by DNA relaxes which are able to perform a single or double stranded cut (depending on the type of system). The DNA released from the cut is then available to transfer to the recipient cells (Grohmann et al, 2003).
Design
Strain Considerations
To test our system in the lab, a Level 1 organism was used as a safety precaution. Staphylococcus epidermidis (ATCC 12228) is a close relative of Staphylococcus aureus and is able to conjugate with S. aureus populations (Forbes and Schaberg, 1983).
Conjugation Machinery
The plasmid pGO1 is of the few gram positive conjugative plasmids studied. The entire 54 kb plasmid has been sequenced by Caryl and O’Neill (2009) (Accession: NC 012547.1). The parts of the pGO1 conjugative plasmid sufficient for trans-species conjugation include a ~ 14 kb trs gene cluster, and a ~2 kb region containing the oriT and a gene which encodes for a nickase protein (Climo et al., 1996).
Experiment
In order to test the conjugation machinery in S. epidermidis, we sought to construct a conjugative plasmid containing the oriT region and trs region from pGO1. The plasmid should maintain a low copy number to ensure a lower metabolic load imposition which would increase the chance of acceptance by the cell. The low copy, theta replicating oriV from the Staphylococcal plasmid pSK41 (BBa_K1323018) was a great candidate. An erythromycin resistance gene (BBa_K1323011) was chosen as the selection marker and DsRed (BBa_K1323015) (Figure X) was chosen as a reporter to track the movement of the plasmid.
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