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Revision as of 17:30, 13 October 2018
Synthetic Biology has come
a long way already...
2000
First genetic circuits
2010
Bacteria with synthetic genome
2013
Commercial Artemisinin production
2016
Light activated communication
in synthetic tissue
Yet, incredibly complex synthetic systems...
... that will define our century...
... require immense amount of
well defined biological parts...
However, characterization and novel
part creation is not an easy task...
... as Nature is immensly complex
A small protein of 100 amino acids
Has 20100 possible sequences
That's already a far greater number
than there are atoms in the known universe
That's already a far greater number
than there are atoms in the known universe
1
1
Current methods are relatively slow
compared to the data amount we need to explore!
We can either use traditional methods
and collect data for another hundred years...
...or take a step in another direction...
DNA library of uncharacterized
and unique catalytic biomolecules
Each different DNA molecule is
swiftly encapsulated into water droplets
Each different DNA molecule is
swiftly encapsulated into water droplets
dsad
Catalytic Biomolecule is produced
inside of the droplet
Recording Module measures the
activity of the Biomolecule…
…and then records it into the
biomolecule’s DNA sequence
The recorded activity and
sequence of biomolecule is
retrieved by Nanopore Sequencing
A characterized
biomolecule
A DNA library of well-characterized biological parts
dsad
dsad
With CAT-SEQ
it all becomes possible
2034
Readily accessible Synthetic Enzymes
2041
Engineered cells capable of Terraforming mars
2079
Cities fully powered by
Synthetic Plants
2095
First Aid kits for Limb Regrowth