Cas9 & Cpf1 secretion
and activity
Difference between revisions of "Template:Team:Utrecht/MainBody"
| Line 848: | Line 848: | ||
{ | { | ||
jQuery("#link-" + i).removeClass("selected"); | jQuery("#link-" + i).removeClass("selected"); | ||
| + | jQuery("#link-" + i).removeClass("pulsing"); | ||
jQuery("#popover-" + i).dxPopover("hide"); | jQuery("#popover-" + i).dxPopover("hide"); | ||
jQuery("#figure-" + i).fadeOut("5"); | jQuery("#figure-" + i).fadeOut("5"); | ||
| Line 869: | Line 870: | ||
{ | { | ||
jQuery("#link-" + i).removeClass("selected"); | jQuery("#link-" + i).removeClass("selected"); | ||
| + | jQuery("#link-" + i).removeClass("pulsing"); | ||
jQuery("#popover-" + i).dxPopover("hide"); | jQuery("#popover-" + i).dxPopover("hide"); | ||
jQuery("#figure-" + i).fadeOut("5"); | jQuery("#figure-" + i).fadeOut("5"); | ||
| Line 1,046: | Line 1,048: | ||
<br><br> | <br><br> | ||
Additionally, together with team Wageningen_UR a final experiment was done to verify that the protein in the medium was indeed secreted instead of due to involuntary cell lysis (see <a onclick="return change_page('collaborations', 1)" href="collaborations">Collaborations</a>). | Additionally, together with team Wageningen_UR a final experiment was done to verify that the protein in the medium was indeed secreted instead of due to involuntary cell lysis (see <a onclick="return change_page('collaborations', 1)" href="collaborations">Collaborations</a>). | ||
| − | This experiment was done in duplo, by members from both team Wageningen_UR and team Utrecht, individually, to provide independent verification of the result. This final experiment was done according to a collaboration protocol that was shared with the Wageningen_UR team | + | This experiment was done in duplo, by members from both team Wageningen_UR and team Utrecht, individually, to provide independent verification of the result. This final experiment was done according to a collaboration protocol that was shared with the Wageningen_UR team <a target=_BLANK href="https://static.igem.org/mediawiki/2017/4/40/UuProtocolCollaborationWageningen.pdf" class="pdf pdf-inline"></a>. |
<br><br> | <br><br> | ||
<b>Endonuclease activity assay</b> | <b>Endonuclease activity assay</b> | ||
| Line 1,545: | Line 1,547: | ||
We could then substitute these three concentrations for their expressions in the expression of the target chain concentration. Making further quasi steady state assumptions on the formation of the pre-cleavage and post-cleavage complexes reduces the expression by two more dependencies. This was done in mathematica notebook, found <a target=_BLANK href="https://static.igem.org/mediawiki/2017/2/21/UuModelingQSSAWorkouts.txt" class="url_external">here</a>. | We could then substitute these three concentrations for their expressions in the expression of the target chain concentration. Making further quasi steady state assumptions on the formation of the pre-cleavage and post-cleavage complexes reduces the expression by two more dependencies. This was done in mathematica notebook, found <a target=_BLANK href="https://static.igem.org/mediawiki/2017/2/21/UuModelingQSSAWorkouts.txt" class="url_external">here</a>. | ||
<br><br> | <br><br> | ||
| − | + | ||
| + | The resulting expression shows that the concentration of target chain depends on: 1) The concentrations of its production relative to the production of the protease chain. 2) The concentration of protease chain. 3) The concentration of substrate. 4) How much cleaved target chain is available to trap said substrate. | ||
| + | <br><br> | ||
| + | The fraction of the total target chain that is cleaved is a saturation function that depends on substrate and protease chain concentrations with respect to how quickly the function's saturation point is attained. We can minimize the cleaved target chain fraction, and the occurrence of substrate trapping with it, by simply having a target chain amount that is much larger than that of the substrate. | ||
| + | <br><br> | ||
| + | In short, the more substrate there is available per target chain, the less signal per substrate molecule we can get as ineffectual target chain concentration increases. | ||
| + | <br><br> | ||
| + | The equations suggest that there is a theoretical optimum for the production rates of both chains, relative to the substrate concentration in the system. Due to time constraints, the expression for this optimum could not be given. The methods given in the mathematica script provided here should be able to reach this solution, given enough time. The meaning of such an optimum, however, is questionable. As the substrate concentrations in our toolkit may differ greatly depending on severity of infection and chance, optimization through growth-rates would need to be different per sample. In conclusion, the only effective optimization of protein productions is to make sure that the protein concentrations greatly exceed the sample concentration of DNA sequence we wish to detect. | ||
<br><br> | <br><br> | ||
| Line 2,209: | Line 2,218: | ||
{ | { | ||
jQuery("#link-" + i).removeClass("selected"); | jQuery("#link-" + i).removeClass("selected"); | ||
| + | jQuery("#link-" + i).removeClass("pulsing"); | ||
jQuery("#popover-" + i).dxPopover("hide"); | jQuery("#popover-" + i).dxPopover("hide"); | ||
jQuery("#figure-" + i).fadeOut("5"); | jQuery("#figure-" + i).fadeOut("5"); | ||
| Line 2,230: | Line 2,240: | ||
{ | { | ||
jQuery("#link-" + i).removeClass("selected"); | jQuery("#link-" + i).removeClass("selected"); | ||
| + | jQuery("#link-" + i).removeClass("pulsing"); | ||
jQuery("#popover-" + i).dxPopover("hide"); | jQuery("#popover-" + i).dxPopover("hide"); | ||
jQuery("#figure-" + i).fadeOut("5"); | jQuery("#figure-" + i).fadeOut("5"); | ||
| Line 3,886: | Line 3,897: | ||
{ | { | ||
jQuery("#link-" + i).removeClass("selected"); | jQuery("#link-" + i).removeClass("selected"); | ||
| − | |||
jQuery("#figure-" + i).fadeOut("5"); | jQuery("#figure-" + i).fadeOut("5"); | ||
} | } | ||
| Line 3,918: | Line 3,928: | ||
{ | { | ||
jQuery("#link-" + i).removeClass("selected"); | jQuery("#link-" + i).removeClass("selected"); | ||
| − | |||
jQuery("#figure-" + i).fadeOut("5"); | jQuery("#figure-" + i).fadeOut("5"); | ||
} | } | ||
Revision as of 02:43, 2 November 2017
<!DOCTYPE html>
Comparison of endonuclease activity for Cas9 and Cpf1 that has been produced in, and excreted by, HEK293 cells.
MESA two-component system replication
Details on the MESA two-component system, explanation of its relation to our design and the results of its reproduction.
OUTCASST system production
Detailed explanation of the OUTCASST mechanism, experimental progress and technical prospects.
Modeling and
mathematics
mathematics
Ordinary differential equations, cellular automaton and an object based model for optimal linker-length estimation.
InterLab study participation
Results and details of our measurements for the iGEM 2017 InterLab Study.
Stakeholders & opinions
Interviews and dialogues with stakeholders, potential users, third parties and experts relating to pathogen detection or DNA-based diagnostics.
Risks & safety-issues
Implications and design considerations relating to safety in the usage and implementation of OUTCASST as a diagnostics tool.
Design & integration
OUTCASST toolkit and product design with factors such as bio-safety and user-friendliness taken into account.
Outreach
Videos we made for the dutch public, together with 'de Kennis van Nu'.
Meet our team
About us, our interests and roles in the team and our supervisors.
Sponsors
A listing of our sponsors, how they assisted us and our gratitude for their assistance.
Collaborations
Read about our exchanges with other iGEM teams and government agencies.
Achievements
A short description of all that we have achieved during our participation in the iGEM.
Attributions
A thank-you for everyone that assited us, both in and outside the lab.
×
