Team:UT Dallas/project part3

From 2013.igem.org

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<b>The Com System</b><br>
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<b>How They Work:</b> Quorum sensing molecules are naturally used by <i>S. mutans</i> to regulate population growth and competency. At normal levels, Competency Stimulating Peptide (CSP) allows a local population of <i>S. mutans</i> to share plasmids and grow. When the concentration of CSP gets high CSP activates a genetic pathway that causes some cells to activate cell-death. This allows the colony to remain at sustainable levels. We can take advantage of this natural population control to cause the equilibrium concentration of <i>S. mutans</i> in the oral cavity to decrease drastically. <i>E. coli</i> can produce CSP constitutively at a high rate. When placed in the mouth, these engineered <i>E. coli</i> will raise the concentration of CSP and cause the death of any nearby <i>S. mutans</i> cells. The natural quorum signaling system involves five gene products encoded by: ComA, ComB, ComC, ComD, ComE. The comC gene encodes a competence-stimulating peptide (CSP) precursor. ComC and ComDE lie adjacent on the chromosome and, together with their gene products, constitute a peptide (CSP)-signaling system including a generating pathway (comC) and a responding pathway (comDE).<br><br>
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<b>How it Works</b><br>
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At normal levels, Competence Stimulating Peptide (CSP) allows a local population of S. Mutans to share plasmids and grow stronger. However, when the concentration of CSP gets too high it activates a genetic pathway that causes some cells to activate cell-death. The quorum signaling system involves five gene products encoded by:<br>
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cslAB (comAB) <br>
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<b>comCDE</b> <br>
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<b>What We Did:</b> We attempted to isolate the genes from the <i>S. mutans</i> natural quorum signaling system.
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The comC gene encodes a competence-stimulating peptide (CSP) precursor. ComC and ComDE lie adjacent on the chromosome and, together with their gene products, constitute a peptide (CSP)- signaling system including a generating pathway (comC) and a responding pathway (comDE). The other two genes, cslA and cslB, are located in a separate region of the chromosome and encode a CSP-specific secretion apparatus consisting of an ATP-binding cassette (ABC) transporter (ComA) and its accessory protein (ComB), which are involved in the processing and export of the CSP.<br>
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<b>What We Did</b><br>
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We attempted to use these  quorum sensing molecules which are naturally used by S. Mutans to regulate population growth, competency, and many other uses that are undiscovered. When placed in the mouth, these E. Coli cells will then raise the concentration of CSP and cause the death of any nearby s. mutans cells.<br>
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Latest revision as of 23:37, 27 September 2013

How They Work: Quorum sensing molecules are naturally used by S. mutans to regulate population growth and competency. At normal levels, Competency Stimulating Peptide (CSP) allows a local population of S. mutans to share plasmids and grow. When the concentration of CSP gets high CSP activates a genetic pathway that causes some cells to activate cell-death. This allows the colony to remain at sustainable levels. We can take advantage of this natural population control to cause the equilibrium concentration of S. mutans in the oral cavity to decrease drastically. E. coli can produce CSP constitutively at a high rate. When placed in the mouth, these engineered E. coli will raise the concentration of CSP and cause the death of any nearby S. mutans cells. The natural quorum signaling system involves five gene products encoded by: ComA, ComB, ComC, ComD, ComE. The comC gene encodes a competence-stimulating peptide (CSP) precursor. ComC and ComDE lie adjacent on the chromosome and, together with their gene products, constitute a peptide (CSP)-signaling system including a generating pathway (comC) and a responding pathway (comDE).

What We Did: We attempted to isolate the genes from the S. mutans natural quorum signaling system.