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Reprogramming Cellular Behavior with RNA Controllers Responsive to Endogenous Proteins

This study explores how RNA controllers can alter cellular behavior by coupling endogenous protein levels with targeted gene expression through alternative RNA splicing. The design involves combining minigenes, aptamers, and genes of interest to achieve specific gene expression patterns. Modularity and multi-input processing allow for combinatorial control schemes, with potential applications in gene therapy, diagnostics, cancer treatment, and drug discovery. The modularity of output allows for the detection of disease markers and targeted cell death induction. The research highlights the potential of synthetic RNA devices to link disease-associated pathways to cell fate decisions, offering a new approach to biological control and functionality.

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Reprogramming Cellular Behavior with RNA Controllers Responsive to Endogenous Proteins

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  1. Reprogramming Cellular Behavior with RNA Controllers Responsive to Endogenous Proteins Stephanie J. Culler, Kevin G. Hoff, Christina D. Smolke SCIENCE Nov. 2010 Presented by: Andrew Yang and Tina Stutzman 3/2/2011

  2. Introduction: RNA control device couples endogenous protein level with targeted gene expression through alternative RNA splicing - Actuation - RNA splicing = introns cut out of transcript to make mature mRNA - Sensing - Aptamers = short pieces of RNA that specifically bind to targets, ex. proteins Input: Endogenous Protein Sensing and Actuation: Specific Aptamer Output: Gene Expression

  3. Controller Design: Minigene + Aptamer + Gene of Interest • Three-exon, two-inton minigene • Middle exon alternatively spliced • Aptamer in intron, protein binds specific aptamer • Splicing pattern altered

  4. Optimal location of input module in introns • Bacteriophage coat protein = MS2 • 3 and 10 increase expression • 6 decreases expression • Flow cytometry(top right) • qRT-PCR (bottom right)

  5. Modularity: Sensor integrated into NF-κB pathway responds to TNF-αstimulation • NF-κB: immune responses, cell adhesion, proliferation, apoptosis • Stimulated with tumor necrosis factor-α(TNF-α) • p65-3 increased gene expression (exon exclusion) • P50-3 decreased gene expression (exon inclusion)

  6. Modularity: Sensor integrated into β-catenin pathway responds to LTD4stimulation • β-catenin: part of Wnt signalling pathway • Stimulated with leukotriene D4(LTD4) • Position 3 did not respond to stimulation • Position 6 increased expression

  7. Multiple Inputs • MS2-DsRed Device • Devices containing the WT aptamer in either position displayed significant increases in gene expression S J Culler et al. Science 2010;330:1251-1255

  8. Fig. 3 RNA devices implement combinatorial control schemes through multi-input processing. Fig. 3 RNA devices implement combinatorial control schemes through multi-input processing. Multiple Inputs • Experiment: Detect heterologous MS2-DsRed and endogenous NF-κB p50 • TNF-α stimulation led to a decrease in gene expression and exon exclusion, whereas expression of MS2-DsRed led to a significant increase • “…in both positions showed a ~30 to 45% increase…synergistic effect on the output signal S J Culler et al. Science 2010;330:1251-1255

  9. Modularity of Output: RNA devices detect endogenous markers of disease and trigger targeted cell death. (B and C) Mechanisms of the β-catenin– (β-cat-6) (B) and NF-κB–responsive (p65-3) (C) devices fused to a suicide gene-therapy output module (HSV-TK), which controls cell survival in response to detection of disease markers and GCV, a pro-drug trigger. S J Culler et al. Science 2010;330:1251-1255

  10. Modularity of Output: RNA devices detect endogenous markers of disease and trigger targeted cell death. (D) Dose-response curves of cell-survival percentages for the β-catenin– and NF-κB–responsive devices fused to HSV-TK indicate a decrease in cell survival S J Culler et al. Science 2010;330:1251-1255

  11. Critiques • It’s “modular”, but… • Aptamer specific behavior? • P50-3 decreased GOI expression while p65-3 increased • “probably through steric hindrance or recruitment of components involved in spliceosome…” • Aptamer location in intron? • Can’t predict effects of aptamer location • Must determine “optimal input-module location within intronic sequence space” for each regulatory device • But is it really modular? • “We selected the SMN1 minigene because key regulatory sequences are located in its exon regions, such that insertion of synthetic sequences into intronic regions is not likely to strongly affect splicing patterns” • Many proteins don’t bind RNA

  12. Relevance to 20.385 • Beyond engineering at the transcriptional level • Growing body of synthetic RNA molecules • Offers additional biological control and functionality

  13. Significance • “a new synthetic device based on RNA can respond sensitively to alterations in the levels of endogenous signaling molecules, and so can potentially link disease-associated pathways to cell fate decisions.” • Applications: • Gene and cellular therapy • Diagnostics • Cancer treatment • Drug discovery • RNA is an apt molecule for such devices, given its versatile sensing functions and the ease with which RNA molecules can be designed.  • Smolke lab: Designing ‘intelligent’ therapeutic molecules • “construction of ligand-regulated RNA-based regulators of gene expression”

  14. Statistical Information – gene expression device response (+ligand) device response (-ligand) = Relative expression (fold) mutant device response (+ligand) mutant device response (-ligand)

  15. qRT-PCR Analysis • “…ratio of the mean expression levels of the exon 7 excluded isoform to the exon 7 included isoform for the wildtype device relative to the same ratio for the mutant control device under the indicated ligand condition + the average error.”

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