Imperial/Cell-Free/Whatis

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== References ==
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# Yoshihiro Shimizu, Yutetsu Kuruma, Bei-Wen Ying, So Umekage, Takuya Ueda (2006) Cell-free translation systems for protein engineering FEBS Journal 273 (18), 4133–4140. doi:10.1111/j.1742-4658.2006.05431.x
# Yoshihiro Shimizu, Yutetsu Kuruma, Bei-Wen Ying, So Umekage, Takuya Ueda (2006) Cell-free translation systems for protein engineering FEBS Journal 273 (18), 4133–4140. doi:10.1111/j.1742-4658.2006.05431.x
# Noireaux V, Bar-Ziv R, Godefroy J, Salman H, and Libchaber A. Toward an artificial cell based on gene expression in vesicles. Phys Biol 2005 Sep 15; 2(3) P1-8. doi:10.1088/1478-3975/2/3/P01 pmid:16224117.
# Noireaux V, Bar-Ziv R, Godefroy J, Salman H, and Libchaber A. Toward an artificial cell based on gene expression in vesicles. Phys Biol 2005 Sep 15; 2(3) P1-8. doi:10.1088/1478-3975/2/3/P01 pmid:16224117.
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Revision as of 13:38, 25 October 2007


What is Cell-Free?

Cell-free systems (CFS) are based on cell transcription-translation extracts (1), and are essentially non-viable biological systems. Two components define the characteristics of these in vitro translation machineries - the kind of cell extract used, as well as the type of compartmentalization that the cell extract is put in.

Together, cell-free systems can have numerous advantages over in vivo protein synthesis - gene and polymerase concentrations can be controlled, reporter measurements are quantitative, and a large parameter space can be studied (1). In the context of synthetic biology, this means that CFS could allow the realization of new potential in simple constructs, as well as provide the flexibility to functionalize and establish simplistic controls for the system.

As a forward step to stricter quality control, as well as the specifications of our projects necessitating a cell-free environment, part of our contributions to iGEM involve the investigation and characterization of cell-free expression systems as a new chassis for the Registry.


Types of Extracts

Icgems-cellextract.png In vitro synthesis of proteins using cell-free extracts consists of two main processes - transcription of DNA into messenger RNA (mRNA) and translation of mRNA into polypeptides. Coupled transcription-translation systems usually combine a bacteriophage RNA polymerase and promoter (T7, T3, or SP6) with eukaryotic or prokaryotic extracts. In addition, the [http://www.nature.com/nbt/journal/v19/n8/full/nbt0801_732.html PURE] system is a reconstituted CFS for synthesizing proteins using recombinant elements (2).


Comparison between different types of cell extracts

Properties
Rabbit Reticulocyte Lysate
Wheat Germ Extract
E. coli Extract
Reconstituted Extract
Types
Eukaryotic
Eukaryotic
Prokaryotic
Artificial
Uses
Widely used for in-vitro translation
Mostly used for in-vitro translation
Mostly used for coupled transcription-translation
Used for in-vitro translation
Templates
  • mRNAs from viruses or eukaryotes
  • Capped or un-capped mRNAs
  • mRNAs from viruses or eukaryotes
  • Capped mRNAs
  • Viral mRNAs with stable secondary structures
  • Un-capped mRNAs
  • Plasmid or linear DNAs
  • Capped or uncapped mRNAs
Post-translational modifications
Yes
Yes
No
Yes


Types of Compartmentalization

Previous research has been done to optimize cell extracts for in vitro protein synthesis. Their endogenous genetic content is removed so that exogenous DNAs or mRNAs can be expressed. Nuclease activity has been reduced and degradation of certain amino acids has been identified. ATP regenerating systems have also been added to improve the energy supply. Different strategies of compartmentalization have been explored to prolong the lifespan of CFS.

Icgems-bulksol.png

Batch-mode CFS

  • Transcription-translation reaction is carried out in bulk solution. Expression is usually limited by nutrient (nucleotides and amino acids) and energy supplies.
Icgems-exchange.png

Continuous-exchange CFS

  • Transcription-translation reaction is separated from feeding solution by a dialysis membrane. Expression is sustained by diffusion of nutrients from the feeding soltuion to the reaction. Wastes generated by the reaction is diluted in the feeding solution.
Icgems-vesicles.png

Vesicle-encapsulated CFS

  • The reaction is separated from feeding solution by a phospholipid bilayer. Expression is maintained for a longer time period than batch-mode CFS because of exchange of materials between the reaction and the feeding solution across the membrane. More reliable exchange of materials is established by inserting a non-specific pore protein with a suitable channel size into the phospholipid bilayer(3).


On to next stage: | Cell-Free vs. Cell >>


References

  1. Noireaux V, Bar-Ziv R, and Libchaber A. Principles of cell-free genetic circuit assembly. Proc Natl Acad Sci U S A 2003 Oct 28; 100(22) 12672-7. doi:10.1073/pnas.2135496100 pmid:14559971.
  2. Yoshihiro Shimizu, Yutetsu Kuruma, Bei-Wen Ying, So Umekage, Takuya Ueda (2006) Cell-free translation systems for protein engineering FEBS Journal 273 (18), 4133–4140. doi:10.1111/j.1742-4658.2006.05431.x
  3. Noireaux V, Bar-Ziv R, Godefroy J, Salman H, and Libchaber A. Toward an artificial cell based on gene expression in vesicles. Phys Biol 2005 Sep 15; 2(3) P1-8. doi:10.1088/1478-3975/2/3/P01 pmid:16224117.
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