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==Systems biology and synthetic biology==
*'''Discussion leader: George W.
<br />
*'''Systems biology as a foundation for genome-scale synthetic biology [http://www.sciencedirect.com/science?_ob=ArticleURL&_udi=B6VRV-4KPX8RY-1&_user=709071&_coverDate=10%2F31%2F2006&_rdoc=1&_fmt=&_orig=search&_sort=d&view=c&_acct=C000039638&_version=1&_urlVersion=0&_userid=709071&md5=7a316893fbee50cab2742cc3b6de73b4  link]
**This article discusses the connection between systems biology and synthetic biology, specifically how modern advances  in systems biology aid the development of the nascent field of synthetic biology
**One current approach taken by systems biologists is to 'reconstruct' a system
***This is done by first incorporating every relevant reaction into a stoichiometric matrix
***From this, a set of parameters can be identified
***By applying 'flux balance analysis' to this model, a concrete model that accurately predicts temporal evolution of the system can be achieved
***Requires many parameters to be defined as well as a 'demand reaction' to drive the system, which is unknown in most cases outside of exponential growth
**Much of the software developed for systems biology will be useful in the pursuit of computational analysis in synthetic biology
**In order to deal with unknown parameters, synthetic biologists can use directed evolution to make a system conform to known parameters; in short, make the system imitate the model
**New experimental techniques are always improving parameter estimation and system reconstruction, and these will clearly benefit both systems and synthetic biologists
**Maybe we can use some of these techniques in our own work?
***Developing our own 'reconstruction' seems unlikely to be feasible, although if we're working with a known system, we may be able to use others' results
***The OptStrain strategy may be feasible if we do metabolic engineering, but I doubt we'll be doing a qualitatively new pathway, so this is likely unnecessary
<br />
*'''Modular approaches to expanding the functions of living matter [http://www.nature.com/nchembio/journal/v2/n6/abs/nchembio789.html link]
**This article describes many techniques used by modern synthetic biologists to achieve novel function in biological systems
**The first section describes how we can take advantage of machinery already present in the cell to engineer qualitatively different function from anything naturally occurring
***Elowitz' repressilator shows oscillation from mutual repression, a system never observed in nature
****This system is extremely sensitive to noise, so is difficult to accurately model except on a gross population level
***Collins' bistable switch permits epigenetic memory, allowing novel response to various stimuli
***Leibler's work systematized topological consequences of several repressors and promoters
****By analyzing 512 different topologies, many useful logical functions were derived
***V. fischeri's quorum sensing permits tumor infiltration, and the familiar bullseye spatial differentiation can be achieved by separation into two functional halves, signal sending and receiving
**The second section explores various unnatural machinery introduced to the cell
***Voigt et. al. were able to create a bacterial camera by incorporating an engineered photoreceptor
***Goulian et. al. modified chemotaxis receptors in E. coli to respond to a variety of attractors
***Hellinga's dead-end eliminaton algorithm permits creation of proteins that recognize novel substrates, such as TNT and serotonin
***Lim et. al. combined two scaffold proteins to link the input of one to the output of the other, a connection completely absent in the natural system
***Schultz has been able to expand the genetic code, potentially providing radically different protein structures and functions from anything in nature
**Perhaps one of the more interesting ideas present in the article is that of post-transcriptional regulation, as this provides tools independent of genetic manipulation to control and regulate
***Smolke's caffeine sensor uses RNA aptamers to suppress target mRNA from transcription in the presence/absence of a specific ligand (in this case, caffeine)
****Not only does this give extremely rapid suppression of the target mRNA, but it also provides orthogonal suppression of any number of targets, as the aptamers can be finely-tuned for a wide range of inducers/suppressors
***Collins et. al. have been able to repress RBSs with specific sequences directly before them designed to form a hairpin with the RBS; only when RNA that binds the suppressor sequence is present is the RBS free to bind to the ribosome
***Rackham and Chin have created functionally new ribosomes that do not interact with the original genome at all
****These can bind to new RBSs that won't interfere with the original ribosomes
****Orthogonal ribosomes can be used to create logical circuits
**There was no dearth of examples in this article, all of which are important to be aware of, and some of which might be useful in our own project
***Orthogonal function seems paramount in development of large-scale complex systems, since unpredicted interaction between disparate parts will swiftly render them at best impaired, at worst non-functional
***Combinations of pre- and post- transcriptional regulation allow control of the system on multiple timescales
*'''[[User:George Washington|George Washington]] 16:29, 2 April 2008 (EDT)'''

Latest revision as of 13:29, 2 April 2008

CHE.496: Biological Systems Design Seminar

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Systems biology and synthetic biology

  • Discussion leader: George W.


  • Systems biology as a foundation for genome-scale synthetic biology link
    • This article discusses the connection between systems biology and synthetic biology, specifically how modern advances in systems biology aid the development of the nascent field of synthetic biology
    • One current approach taken by systems biologists is to 'reconstruct' a system
      • This is done by first incorporating every relevant reaction into a stoichiometric matrix
      • From this, a set of parameters can be identified
      • By applying 'flux balance analysis' to this model, a concrete model that accurately predicts temporal evolution of the system can be achieved
      • Requires many parameters to be defined as well as a 'demand reaction' to drive the system, which is unknown in most cases outside of exponential growth
    • Much of the software developed for systems biology will be useful in the pursuit of computational analysis in synthetic biology
    • In order to deal with unknown parameters, synthetic biologists can use directed evolution to make a system conform to known parameters; in short, make the system imitate the model
    • New experimental techniques are always improving parameter estimation and system reconstruction, and these will clearly benefit both systems and synthetic biologists
    • Maybe we can use some of these techniques in our own work?
      • Developing our own 'reconstruction' seems unlikely to be feasible, although if we're working with a known system, we may be able to use others' results
      • The OptStrain strategy may be feasible if we do metabolic engineering, but I doubt we'll be doing a qualitatively new pathway, so this is likely unnecessary


  • Modular approaches to expanding the functions of living matter link
    • This article describes many techniques used by modern synthetic biologists to achieve novel function in biological systems
    • The first section describes how we can take advantage of machinery already present in the cell to engineer qualitatively different function from anything naturally occurring
      • Elowitz' repressilator shows oscillation from mutual repression, a system never observed in nature
        • This system is extremely sensitive to noise, so is difficult to accurately model except on a gross population level
      • Collins' bistable switch permits epigenetic memory, allowing novel response to various stimuli
      • Leibler's work systematized topological consequences of several repressors and promoters
        • By analyzing 512 different topologies, many useful logical functions were derived
      • V. fischeri's quorum sensing permits tumor infiltration, and the familiar bullseye spatial differentiation can be achieved by separation into two functional halves, signal sending and receiving
    • The second section explores various unnatural machinery introduced to the cell
      • Voigt et. al. were able to create a bacterial camera by incorporating an engineered photoreceptor
      • Goulian et. al. modified chemotaxis receptors in E. coli to respond to a variety of attractors
      • Hellinga's dead-end eliminaton algorithm permits creation of proteins that recognize novel substrates, such as TNT and serotonin
      • Lim et. al. combined two scaffold proteins to link the input of one to the output of the other, a connection completely absent in the natural system
      • Schultz has been able to expand the genetic code, potentially providing radically different protein structures and functions from anything in nature
    • Perhaps one of the more interesting ideas present in the article is that of post-transcriptional regulation, as this provides tools independent of genetic manipulation to control and regulate
      • Smolke's caffeine sensor uses RNA aptamers to suppress target mRNA from transcription in the presence/absence of a specific ligand (in this case, caffeine)
        • Not only does this give extremely rapid suppression of the target mRNA, but it also provides orthogonal suppression of any number of targets, as the aptamers can be finely-tuned for a wide range of inducers/suppressors
      • Collins et. al. have been able to repress RBSs with specific sequences directly before them designed to form a hairpin with the RBS; only when RNA that binds the suppressor sequence is present is the RBS free to bind to the ribosome
      • Rackham and Chin have created functionally new ribosomes that do not interact with the original genome at all
        • These can bind to new RBSs that won't interfere with the original ribosomes
        • Orthogonal ribosomes can be used to create logical circuits
    • There was no dearth of examples in this article, all of which are important to be aware of, and some of which might be useful in our own project
      • Orthogonal function seems paramount in development of large-scale complex systems, since unpredicted interaction between disparate parts will swiftly render them at best impaired, at worst non-functional
      • Combinations of pre- and post- transcriptional regulation allow control of the system on multiple timescales
  • George Washington 16:29, 2 April 2008 (EDT)
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