Biomod/2011/Caltech/DeoxyriboNucleicAwesome/Progress/System Design
System Design
Domain Level Design
Overall domain level design is illustrated in figure 1. Following abbreviation will be frequently used: walker [W], walker inhibitor [WI], track 1 [TR1], probe for track 1 [PTR1], track 2 [TR2], probe for track 2 [PTR2], cargo 1 [C1], cargo attacher [CA], probe for cargo attacher [PCA], cargo goal inhibitor [CGI], cargo goal 1 [CG1], probe for cargo goal [PCG], walker goal [WG], and probe for walker goal [PWG].
- Main article: Domain Level Project Design
Sequence Level Design
- Main article: Sequence Design
With our overall design in mind, we must design DNA sequences, down to the base level, which undergo the interactions that we desire, without forming secondary structures and binding in unintended ways. We approach this through a combination of pre-generated noninteracting sequences, and trial-and-error design using NUPACK simulation software.
Origami Layout
Random walking playground and cargo sorting playground were designed using a rectangular orgiami.
- Main Article: List of Origami Layouts
Experimental Design
Verification of Mechanisms through Gel Experiments
- Main article: Gel Experiments
Before constructing our origami and observing how it behaves, we run a large number of experiments observable through Gel Electrophoresis to verify that many of our mechanisms behave as we expect them to.
Verification of Mechanisms through Fluorescent Spectroscopy
- Main article: SPEX Experiments
Various DNA strands were tagged with fluorophores and quenchers in order to investigate different mechanisms more directly, both in solution and on origami.
Verification of Mechanisms through Atomic Force Microscopy
- Main article: AFM Experiment
- Main article: AFM Imaging
Walkers tagged with biotins were planted onto DNA origami, attempts were made to observe random walking on the origami directly under AFM.