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| ==Joe Liang== | | {{Smolke_Top}} |
| Graduate Student at [http://openwetware.org/wiki/Smolke Smolke Lab] <br/>
| | ==Joe C. Liang== |
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| Department of Chemical Engineering, MC 210-41<br/>
| | [[Image:Joe.jpg|right|thumb]] |
| California Institute of Technology<br/>
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| Pasadena, CA 91125-4100<br/>
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| (626)395-2753<br/>
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| jliang @ caltech . edu
| | Ph.D. Candidate <br/> |
| | Bioengineering -- [http://openwetware.org/wiki/Smolke Smolke Lab] <br/> |
| | Y2E2 Building, MC 4200 <br/> |
| | 473 Via Ortega <br/> |
| | Stanford, CA 94305 <br/> |
| | Phone: (650) 721-5884 <br/> |
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| ==Education== | | ==Education== |
| Ph.D Student, Chemical Engineering, Caltech, 2006-present <br/> | | Ph.D, Candidate, Chemical Engineering, Caltech, 2008-present <br/> |
| B.S, Chemical Engineering wiht Applied Physical Science Emphasis, University of California at Berkeley, 2006<br/> | | M.S, Chemical Engineering, Caltech, 2008 <br/> |
| | B.S, Chemical Engineering, UC Berkeley, 2006<br/> |
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| ==Research Interest== | | ==Research Interest== |
| RNA aptamers are known to have high molecular discriminating ability. One classic example is that the theophylline aptamers does not respond in the presense of caffeine despite structurally differing in merely one methyl group. This superior sensitivity of aptmaers distinguishing metabolites is a nice trait to be incorporated in a synthetic biological regulartory network, which usually consists of many structurally similar intermeidates. However, the application of using aptamers in a synthetic pathway has been severely limited by the ability to effectivly generate functional aptamers ''in vivo''. Traditional ''in vitro'' ''SELEX'' usually takes weeks in selection and characterizaion of working aptamers and requires further screening for ''in vivo'' activities.
| | I am developing enabling technologies that support generation of RNA devices. |
| In the Smolke lab, we have developed several portable, modular, and tunable engineered RNA-based switch platform that can adopt to different conformations upon binding of various molecular inputs and subsequently modulates the level of target gene expression. We can use the exisiting sensor domain of these switch platforms and implement it as a selection tool to screen library to generate aptamers for other strucually similar molecules. The eventual goal is to incorporate these platforms as part of the regulatory network in a syntheitc biological pathway and redirect molecular fluxes to generate medicinal valuable intermediates that are too costly to be synthesized chemically.
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| ==Publication== | | ==Publications== |
| <biblio>
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| #liang1 [http://www.cs.caltech.edu/cbsss/finalreport/yjunction_group.pdf ''Y-Junction Carbon Nanotube Implementation of Intramolecular Electronic NAND Gate'']
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| <br>Benjamin Gojman, Happy Hsin, Joe Liang, Natalia Nezhdanova, Jasmin Saini
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| #liang2 ''Evaluation of Two Computational Models Based on Different Effective Core Potentials for Use in Organocesium Chemistry''
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| <br>Streitwieser, A.; Liang, J. C.-Y.; Jayasree, E. G.; Hasanayn, F. J. Chem. Theory and Comput.; (Article); 2007; 3(1); 127-131
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| </biblio>
| | # Liang JC, Smolke CD. 2011. Rational design and tuning of ribozyme-based devices. In: Hartig J, editor. Methods in Molecular Biology. In press. |
| | | # Win MN, Liang JC, Smolke CD. 2010. Frameworks for programming RNA devices. In: Mayer G, editor. The Chemical Biology of Nucleic Acids. U.K.: John Wiley & Sons, Ltd. pp. 323-38. |
| =Honors and Awards=
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