Scalable genetically-encoded technologies that enable the construction of systems that receive, process, and transmit molecular information are essential to advancing basic biological research, applied biomedical research, and biotechnology. Such enabling technologies will significantly advance our ability to monitor, interface with, and program the dynamic cellular state. An interdisciplinary approach spanning the areas of engineering, molecular biology, and biochemistry will be applied to develop modular and programmable RNA-based platforms to build user-defined sensing-actuation systems that will translate a molecular input into a change in cellular function. By coupling RNA structure-function relationships, engineering design strategies, and computational modeling tools, frameworks will be developed for constructing ligand-controlled RNA regulatory systems that will be utilized to respond to and manipulate molecular information in living systems. Our goals are to develop the experimental and computational frameworks for the reliable construction and programming of integrated RNA-based control systems that exhibit user-defined regulatory properties. These systems will be utilized to advance our understanding of effective strategies for integrating functional network and control system architectures.
Specific aims are to: 1. Develop a trans-ribozyme switch platform. This will include: (i) developing a trans-ribozyme platform that exhibits biologically relevant cleavage efficiencies and binding affinities;(ii) developing an associated trans-ribozyme expression system for effective regulation of target protein levels in vivo;(iii) developing a trans-ribozyme switch platform. 2. Develop computational tools for programming switch properties. This will include: developing (i) computational models of ligand-controlled RNA regulatory systems to predict parameters critical to system response, (ii) an in silico framework for the prediction of in vivo folding parameters from sequence, (iii) a sequence-to-function framework for the forward design of switch properties. 3. Develop cell-based screens and selections for new switch functions. This will include: developing cell-based (i) screening and (ii) selection strategies for new ribozyme switches;(iii) implementing these strategies for the generation of ribozyme switches with new sensory or response properties. 4. Examine the effects of introducing controlled perturbations to the yeast pheromone-responsive MAPK pathway. This will include: examining the effects of (i) titrating MAPK proteins with cis- ribozyme switches and (ii) introducing controlled perturbations to the MAPK pathway with trans- ribozyme switches on signaling through the pathway and system response.

Public Health Relevance

Basic biological research, applied biomedical research, and biotechnology are limited by our ability to get information into and out from living systems, and to act on information inside living systems. This research will result in genetically-encoded technologies that will be used to receive, process, and transmit molecular information. Such technologies will significantly impact our ability to monitor, interface with, and program the dynamic cellular state, thereby resulting in an enhanced understanding of biological processes leading to disease and frameworks for constructing targeted molecular therapeutics.

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Project (R01)
Project #
1R01GM086663-01
Application #
7567196
Study Section
Special Emphasis Panel (ZRG1-GGG-J (10))
Program Officer
Bender, Michael T
Project Start
2009-01-02
Project End
2012-12-31
Budget Start
2009-01-02
Budget End
2009-12-31
Support Year
1
Fiscal Year
2009
Total Cost
$226,102
Indirect Cost
Name
Stanford University
Department
Biomedical Engineering
Type
Schools of Medicine
DUNS #
009214214
City
Stanford
State
CA
Country
United States
Zip Code
94305
Mathur, Melina; Xiang, Joy S; Smolke, Christina D (2017) Mammalian synthetic biology for studying the cell. J Cell Biol 216:73-82
Wang, Yen-Hsiang; McKeague, Maureen; Hsu, Tammy M et al. (2016) Design and Construction of Generalizable RNA-Protein Hybrid Controllers by Level-Matched Genetic Signal Amplification. Cell Syst 3:549-562.e7
McKeague, Maureen; Wong, Remus S; Smolke, Christina D (2016) Opportunities in the design and application of RNA for gene expression control. Nucleic Acids Res 44:2987-99
Townshend, Brent; Kennedy, Andrew B; Xiang, Joy S et al. (2015) High-throughput cellular RNA device engineering. Nat Methods 12:989-94
Church, George M; Elowitz, Michael B; Smolke, Christina D et al. (2014) Realizing the potential of synthetic biology. Nat Rev Mol Cell Biol 15:289-94
Chang, Andrew L; McKeague, Maureen; Smolke, Christina D (2014) Facile characterization of aptamer kinetic and equilibrium binding properties using surface plasmon resonance. Methods Enzymol 549:451-66
Kennedy, Andrew B; Vowles, James V; d'Espaux, Leo et al. (2014) Protein-responsive ribozyme switches in eukaryotic cells. Nucleic Acids Res 42:12306-21
Galloway, Kate E; Franco, Elisa; Smolke, Christina D (2013) Dynamically reshaping signaling networks to program cell fate via genetic controllers. Science 341:1235005
Galanie, Stephanie; Siddiqui, Michael S; Smolke, Christina D (2013) Molecular tools for chemical biotechnology. Curr Opin Biotechnol 24:1000-9
Kennedy, Andrew B; Liang, Joe C; Smolke, Christina D (2013) A versatile cis-blocking and trans-activation strategy for ribozyme characterization. Nucleic Acids Res 41:e41

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