Revision as of 02:04, 23 October 2010 by Cyu286 (Talk | contribs)

Tech Institute
Home Brainstorm Team Acknowledgements Project Human Practices Parts Notebook Calendar Protocol Safety Links References Media Contact
Our main project is to simulate mammalian skin using chitin in E. Coli. This process involves four major components: Lawn Formation, Chitin Synthesis, Bacterial Apoptosis, and lac-Operon Signaling.
A thick bacterial lawn is generated by plating ydgG knock-out mutants (acquired from the Keio Collection) in an enriched agar plate. The protein product of ydgG plays an integral role in AI-2 transport. ydgG knock-outs exhibit increased motility which should ultimately allow for a thick and level lawn.
The 3.5kbp Chitin Synthase III gene is extracted from the Saccharomyces Cerevisiae genome. Chitin Synthase III catalyzes the polymerization of chitin by transferring UDP-N-acetyl-D-glucosamine to an N(1,4 N-Acetyl-beta-D-glucosaminyl) to produce N+1(1,4 N-Acetyl-beta-D-glucosaminyl).
Apoptosis of cells is achieved by using the bacteriophage lysis cassette built by the Brown '08 iGEM Team. The cassette includes Holin, Endolysin, and Rz Protein genes. These enzymes puncture and degrade the cell membrane which results in lysing of the cell and the release of synthesized chitin.
Once the lawn is established, an IPTG solution is sprayed over the lawn to induce chitin synthesis (fast response) and apoptosis (slow response). IPTG mimics allolactose which binds to the LacI repressor, causing LacI to detach from DNA and allowing RNA Polymerase to begin transcription. This will allow for a build-up in chitin followed by apoptosis and subsequent release into the extracellular environment. Thus, any abrasions to the chitinous surface can be repaired by spraying IPTG.
In mammalian skin, mitosis occurs in the basal layer of the epithelial cells and cells travel outwards towards the surface of the skin as they mature. As the cells move further away from the basal layer, they begin to die due to lack of nutrients. As they die, their cytoplasm is released and the cells are filled with keratin, thus forming a continuously regenerating protective layer on the outer-most part of epithelial layer. Our project is modeled after this. The bacterial lawn produces chitin only at the top-most layer and these cells then undergo apoptosis to result in the formation of a chitinous layer at the surface of the lawn. The critical difference is that the bacterial colony is not internally controlled (controlled by IPTG spray), but this is something that can be remedied and a possible goal for future teams.


Medicinal Use:

  • Wound and burn treatment/healing
  • Hemostasis for orthopedic treatment of broken bones
  • Viscoelastic solutions for ophthamology and orthopedic surgery
  • Abdominal adhesion treatment
  • Antibacterial and antifungal agents
  • Tumor therapies
  • Microsurgery and neurosurgery
  • Treatment of chronic wounds, ulcers and bleeding (chitin powder)

Industrial Use:

  • Food/Pharmaceutical/Agricultural/Cosmetic thickener, stabilizer
  • Water resistant properties
  • Dietary supplement
  • Water purification
  • Biodegradable
  • Edible microcrystalline films used to preserve food
  • Sequestering of particles (i.e. oil)

Chassis Induction Chitin Apoptosis Modeling


First, the Chitin Synthase 3 (CHS3) gene was subcloned out of Saccharomyces Cerevisiae (Baker’s Yeast) cDNA (complementary DNA – contains no introns, thus can be used in prokaryotes) with biobrick restriction sites (EcoR1, Xbal1 on one end, and Spe1, Pst1 on the other). CHS3 was chosen as it was found to be the major enzyme (knockouts had 80% reduced Chitin) in its family and requires no co-enzyme or activating compounds. Upon running CHS3 through NEB Cutter V2.0, we found a PST1 restriction site which is incompatible with the biobrick standard (EcoR1, Xbal, Spe1, Pst1). To remove this Pst1 site, we inserted CHS3 into a biobrick vector plasmid, and performed site-directed mutagenesis (SDM).

Research revealed that chitin synthase is a transmembrane enzyme, and in order to simulate similar conditions, we decided to use the pMAL vector by NEB which contains a periplasmic membrane signal sequence. CHS3 was subcloned in to the pMAL-p5x NEB vector by first PCR’ing it out of the biobrick vector plasmid - on which it underwent SDM - with pMAL restriction sites (Nde1 and EcoR1) and ligated into the pMAL-p5x vector. Then, the CHS3 was again amplified with biobrick sites, but this time, with the periplasmic signal sequence native to the pMAL-p5x plasmid, and inserted into a standard biobrick vector. The entire part was then sequenced and submitted to the registry of standard parts.

A bacterial apoptosis cassette made by the Brown iGEM team in ‘08 was taken from the igem 2010 distribution kit and colony amplified.

3 constitutive promoters and 2 lac-inhibitor/lac-operon combination parts were taken from the registry and ligated in all 6 combinations through 3A Assembly. These combinations would express different levels of laci, thus exhibiting variable inductivity. These 6 constructs were then ligated with a reporter protein - green fluorescent protein - and characterized via an automated fluorescent microplate reader; fluorescence was used to determine the construct inductivity and expression level.

Then the data was used to fit our own theoretical kinetics model that accounts for IPTG diffusion through biofilm, external IPTG concentration, internal IPTG concentration, lac repressor concentration, repressor bound gene (DNA) concentration, unbound gene (DNA) concentration, mRNA concentration, enzyme concentration, substrate concentration, enzyme-substrate complex concentration, and final product concentration, as well as all the rate constants involved. Using the data acquired from the microplate reader, a final semi-empirical kinetics model was generated. Using this model, two different constructs were chosen; both with similar inductivity, but one with and the other without time delay.

The fast expression construct was ligated with Chitin Synthase, while the slow expression construct was ligated with the apoptosis cassette. Both plasmids were then transformed into a ChiA and tqsA double knockout strain of K12 Escherichia Coli. ChiA knockouts lack Chitinase, which is an enzyme that catabolizes chitin. tqsA knockouts have a disrupted quorum sensing mechanism that allows them to grow very thick lawns. The mutants were acquired from Keio collection (one from Northwestern, and the other from Yale respectively), and the Multiplex Automated Genome Engineering (MAGE) protocol developed by H. H. Wang. et al. was used to acquire double knockouts. The MAGE protocol is an accelerated evolution procedure where oligonucleotides are electroporated into the cells in order to introduce mutations in the genome during replication by binding as lagging strand primers.

The double knockout colonies with both constructs were then sprayed with IPTG, which first induced the fast chitin synthesis construct, which caused a buildup of chitin in cells in the top layer of the bacterial lawn. Then the slow apoptosis construct was induced, which then lysed the cells, and released a layer of chitin in the top layer of the bacterial lawn. This construct was then stained with Chitin-specific rhodamine probe by NEB as well as baclight by Invitrogen in order to ensure that the cells were producing chitin and lysing. The lawn was then imaged through a fluorescent confocal microscope.