Ssutton: PTL Logic
I am working to develop a new type of logic, called Post-Translational Logic, or PTL. PTL devices regulate the post-translational modifications of proteins to define system state and control cell function.
Current synthetic biological circuits make use of protein-DNA and RNA-RNA interactions to control gene expression in bacteria-- such circuits are Protein-DNA logic, or PDL. A brief comparison of the two types of logic is as follows:
PDL
- Engineered around gene expression
- Typical parts: transcriptional regulators, translational regulators
- Typical signal: PoPS, resulting in desired cellular concentrations of proteins.
- Easier to engineer than PTL
- Slow response time (hours)
- Uses one subset of cellular functions
PTL
- Engineered around protein modifications
- Typical parts: kinases, phosphorylation sites, docking sites
- Typical signa: rate of modification, resulting in desired state of proteins.
- More difficult to engineer than PDL
- Fast response time (seconds)
- Explores a new set of applications
In designing PTL logic, I am working to answer the following questions:
- What is a PTL part?
- What is a PTL device?
- What signals are passed between devices?
- What are device performance specifications?
Below I will describe some of my ideas.
The most intuitive definition of a PTL device is illustrated as follows.
The problem with the above system is that the output of one device can only be received by a device that contains compatible Docking and PO4 parts. The figure below illustrates points of part-part interactions, with red line connecting parts that must be compatibile.
This defeats the purpose of a universal signal carrier, and limits the utility and versatility of PTL devices. Note that we encountered the same problem when defining PDL devices and signals.
A solution is to re-draw the device boundaries such that all corresponding parts are within the same devices: