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Massively parallel RNA device engineering in mammalian cells with RNA-Seq

Author

Listed:
  • Joy S. Xiang

    (443 Via Ortega, MC 4245, Stanford University)

  • Matias Kaplan

    (443 Via Ortega, MC 4245, Stanford University)

  • Peter Dykstra

    (443 Via Ortega, MC 4245, Stanford University)

  • Michaela Hinks

    (443 Via Ortega, MC 4245, Stanford University)

  • Maureen McKeague

    (McGill University
    Department of Chemistry, McGill University)

  • Christina D. Smolke

    (443 Via Ortega, MC 4245, Stanford University
    Chan Zuckerberg Biohub)

Abstract

Synthetic RNA-based genetic devices dynamically control a wide range of gene-regulatory processes across diverse cell types. However, the limited throughput of quantitative assays in mammalian cells has hindered fast iteration and interrogation of sequence space needed to identify new RNA devices. Here we report developing a quantitative, rapid and high-throughput mammalian cell-based RNA-Seq assay to efficiently engineer RNA devices. We identify new ribozyme-based RNA devices that respond to theophylline, hypoxanthine, cyclic-di-GMP, and folinic acid from libraries of ~22,700 sequences in total. The small molecule responsive devices exhibit low basal expression and high activation ratios, significantly expanding our toolset of highly functional ribozyme switches. The large datasets obtained further provide conserved sequence and structure motifs that may be used for rationally guided design. The RNA-Seq approach offers a generally applicable strategy for developing broad classes of RNA devices, thereby advancing the engineering of genetic devices for mammalian systems.

Suggested Citation

  • Joy S. Xiang & Matias Kaplan & Peter Dykstra & Michaela Hinks & Maureen McKeague & Christina D. Smolke, 2019. "Massively parallel RNA device engineering in mammalian cells with RNA-Seq," Nature Communications, Nature, vol. 10(1), pages 1-16, December.
  • Handle: RePEc:nat:natcom:v:10:y:2019:i:1:d:10.1038_s41467-019-12334-y
    DOI: 10.1038/s41467-019-12334-y
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    Cited by:

    1. Yage Ding & Cristina Tous & Jaehoon Choi & Jingyao Chen & Wilson W. Wong, 2024. "Orthogonal inducible control of Cas13 circuits enables programmable RNA regulation in mammalian cells," Nature Communications, Nature, vol. 15(1), pages 1-16, December.

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