Engineering Epigenetic Regulation Using Synthetic Read-Write Modules

Highlights

• A synthetic epigenetic regulatory system in human cells using m6A DNA modification

• Engineered writers and readers of m6A enable construction of regulatory circuits

• Read-write circuits drive spatial propagation and hallmarks of chromatin spreading

• Read-write circuits enable epigenetic memory of transcriptional states

Summary

Chemical modifications to DNA and histone proteins are involved in epigenetic programs underlying cellular differentiation and development. Regulatory networks involving molecular writers and readers of chromatin marks are thought to control these programs. Guided by this common principle, we established an orthogonal epigenetic regulatory system in mammalian cells using N6-methyladenine (m6A), a DNA modification not commonly found in metazoan epigenomes. Our system utilizes synthetic factors that write and read m6A and consequently recruit transcriptional regulators to control reporter loci. Inspired by models of chromatin spreading and epigenetic inheritance, we used our system and mathematical models to construct regulatory circuits that induce m6A-dependent transcriptional states, promote their spatial propagation, and maintain epigenetic memory of the states. These minimal circuits were able to program epigenetic functions de novo, conceptually validating “read-write” architectures. This work provides a toolkit for investigating models of epigenetic regulation and encoding additional layers of epigenetic information in cells.