Difference between revisions of "Team:Warwick/Modelling2"
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<br>It would be possible to create 2D and 3D structures using these Origami structures as a glue to hold the cells together but would require hundreds of different zinc fingers to prevent the wrong parts being bonded to one another. | <br>It would be possible to create 2D and 3D structures using these Origami structures as a glue to hold the cells together but would require hundreds of different zinc fingers to prevent the wrong parts being bonded to one another. | ||
<br>This shows how a simple shape could be made by using E.coli (black squares) by connecting them with DNA origami (red crosses). In order for a shape to be made each piece of E.coli needs to express a different zinc finger so that it can only be bonded to a specific piece of origami (no non-specific bonding). | <br>This shows how a simple shape could be made by using E.coli (black squares) by connecting them with DNA origami (red crosses). In order for a shape to be made each piece of E.coli needs to express a different zinc finger so that it can only be bonded to a specific piece of origami (no non-specific bonding). | ||
| − | <br>We only have four zinc fingers which means that we don’t have many options for patterns we could make, but given enough time and resources we could easily optimise more zinc fingers so more complex shapes could be made. Future iGEM teams could create more zinc fingers which could be combined with our structures so that as time prgresses a database of different shaped and sized oligonucleotide adehsives can be made. Our project could then be used as a stepping stone to create complex 2D and eventually 3D shapes and structures. | + | <br>We only have four zinc fingers which means that we don’t have many options for patterns we could make, but given enough time and resources we could easily optimise more zinc fingers so more complex shapes could be made. |
| + | <br>Future iGEM teams could create more zinc fingers which could be combined with our structures so that as time prgresses a database of different shaped and sized oligonucleotide adehsives can be made. Our project could then be used as a stepping stone to create complex 2D and eventually 3D shapes and structures. | ||
</p> | </p> | ||
Revision as of 11:22, 6 August 2015
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DNA Origami Glue
How it would work
It would be possible to create 2D and 3D structures using these Origami structures as a glue to hold the cells together but would require hundreds of different zinc fingers to prevent the wrong parts being bonded to one another.
This shows how a simple shape could be made by using E.coli (black squares) by connecting them with DNA origami (red crosses). In order for a shape to be made each piece of E.coli needs to express a different zinc finger so that it can only be bonded to a specific piece of origami (no non-specific bonding).
We only have four zinc fingers which means that we don’t have many options for patterns we could make, but given enough time and resources we could easily optimise more zinc fingers so more complex shapes could be made.
Future iGEM teams could create more zinc fingers which could be combined with our structures so that as time prgresses a database of different shaped and sized oligonucleotide adehsives can be made. Our project could then be used as a stepping stone to create complex 2D and eventually 3D shapes and structures.
DNA Origami
This shows how the DNA strands come together. Three double stranded strings of DNA are denatured and then when slowly cooled will come together to form the Y shape. However after the denaturing each strand of DNA has an equal chance of bonding to the original piece of DNA as it does to the correct origami side. Therefore the more complex the structure the less likely it is that that structure will fully form.
Minimum Size of Plasmids
ADD DESCRIPTION...............................................................
Probability of Formation
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