Multiple Alternative Promoters and Alternative Splicing Enable Universal Transcription-Based Logic Computation in Mammalian Cells
Open access
Date
2020Type
- Journal Article
Abstract
Multi-input logic gene circuits can enable sophisticated control of cell function, yet large-scale synthetic circuitry in mammalian cells has relied on post-transcriptional regulation or recombinase-triggered state transitions. Large-scale transcriptional logic, on the other hand, has been challenging to implement. Inspired by a naturally found regulatory strategy of using multiple alternative promoters, followed by alternative splicing, we developed a scalable and compact platform for transcriptional OR logic using inputs to those promoters. The platform is extended to implement disjunctive normal form (DNF) computations capable of implementing arbitrary logic rules. Specifically, AND logic is implemented at individual promoters using synergistic transcriptional inputs, and NOT logic via microRNA inputs targeting unique exon sequences driven by those promoters. Together, these regulatory programs result in DNF-like logic control of output gene expression. The approach offers flexibility for building complex logic programs in mammalian cells. Show more
Permanent link
https://doi.org/10.3929/ethz-b-000454851Publication status
publishedExternal links
Journal / series
Cell ReportsVolume
Pages / Article No.
Publisher
ElsevierOrganisational unit
03860 - Benenson, Yaakov (ehemalig) / Benenson, Yaakov (former)
03860 - Benenson, Yaakov (ehemalig) / Benenson, Yaakov (former)
Funding
175760 - Multi-input synthetic gene circuits: reduction to practice (SNF)
More
Show all metadata