20.109 Research Proposal for Derek Ju and Alvin Chen

Project Overview

Our goal is to rewire a bacterium to "miniprep" itself, when given some sort of an external stimuli (such as sensing of dense cell growth). This project will serve the following purposes:

• Make the research process easier, cheaper, and more efficient for scientists working with bacteria.
• Most laboratory strains have been genetically modified for scientific use; however our bacteria would be the first to be modified to do an experiment on itself.
• Self-lysing of cells when dense cell growth is encountered - less chance for environmental contamination if genetically engineered bacteria escape from the lab
• Serve as an example of a way synthetic biology can be used for cellular control
• Be an application of using irreversible switches within genetic circuits
• Be an example of sensors being built into bacteria

Background

Cell-cell signaling:

• Need two devices: Sender device and Reciever device. Current devices are based on Lux system of V. Fischeri or analogs. http://partsregistry.org/cgi/partsdb/pgroup.cgi?pgroup=Signalling
  • Sender: BBa_F1610
  • Reciever: BBa_F2620 http://www.nature.com/nbt/journal/v26/n7/full/nbt1413.html. Characterization of this part by Drew Endy

Polymerases Per Second (PoPs)

• Standard unit for signal via which information is transmitted in transcription-based logic devices. (http://openwetware.org/wiki/PoPS.
• Common intracellular signal carrier for transcription-based devices. BBa_F2620 output is PoPs, so we'd have to have a trigger with PoPs input.
• No in vivo technique for measuring PoPs directly, but can do it indirectly (look at endy paper above)

Leucine Zipper

• Clump cells together (pros/cons to this?)

Reporters

• attaching GFP, RFP etc to gene circuits would allow for quick, easy determination of whether it's working
• Good for debugging
• Should only be for experimental design, final product should not have this

Lysozyme Gene (which?)

RNase A Gene (which?)

How to isolate only DNA?

How does miniprep work?

• What does each buffer, spin column, etc do?
• How much does it cost?

Research Problems and Goals

Project Details and Methods

In order to complete our project, we will attempt to incorporate several new genes into E. coli, which will encode for various proteins.

1. We will insert a gene encoding for a binding protein that will be attached to the membrane of the bacteria. This protein will most likey contain leucine zippers and as a result the bacteria will lump together in culture.
2. The attachment of the binding proteins to eachother will indicate clumping of cells, which will release a signal to toggle a "genetic switch". This switch will be a collection of genes, which when combined creatively, can have an input and output.
3. The activation of the genetic switch will lead to expression of a gene encoding for lysozyme, which will lyse the cell.
4. The activation of the genetic switch will lead to expression of a gene encoding for RNAse A, which will degrade the RNA in the cell.

Predicted Outcomes

Resources Needed

• Appropriate DNA sequences for genes, signal sequences, etc
• Standard plasmid for transformation into E. coli, such as pSK1A2
• Some of the DNA for the genetic switches can be retrieved from the Biobricks foundation

References

• http://www.nature.com/nature/journal/v403/n6767/abs/403339a0.html
  • Proteins bind to promoter regulatory sites to repress or activate expression. This results in two stable states: proteins (repressor) repress their own repressor, so they will remain stably expressed. But, switching is controllable switching: dominant repressor (state) can be de-activated with addition of inducer (IPTG, thermal shock, etc). This allows expression of the other repressor, and enables controllable state change of the system
• http://www.ncbi.nlm.nih.gov/pubmed/3289117?dopt=Abstract
  • Leucine zippers are a common structures that have key functions within binding proteins.