Team:Berkeley Wetlab/Project Overview

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What is Cell Surface Display?

Schematic.jpg

cell surface display drawing

Cell surface display is a system for exposing proteins/peptides to the extracellular environment by anchoring them to the outermembrane of a cell. This is done by fusing a protein or peptide of interest to a protein domain that naturally inserts itself into the outer membrane. Genetic devices for cell surface display are generally composed of three basic components:

  1. Passenger domain: the protein or peptide exposed to the extracellular environment. Typically passengers are proteins/peptides that would not naturally reside on the outermembrane of E.coli, but are put there by a cell surface display device.
  2. Displayer domain: the domain that anchors the passenger to the outer membrane.
  3. Structural Spacer Element: a link between the passenger and the displayer.

The Problem

Certain functions cannot be engineered into E. coli without a cell surface display system. However, success in building a functional cell surface display system currently relies on a trial and error approach that is not guided by design principles. While it is almost certain that for a given passenger, a combination of displayer and structural spacers exists that leads to functional display, it is not clear what this combination is or how to chose such a combination rationally.

Our Goal

To create basic design principles for cell surface display which can serve as guidelines for future iGEM teams (and others) attempting to build systems that involve cell surface display.

Our Approach

We made passengers representative of the major types of protiens/peptides people have tried to display in the past. Made many display systems in a combinatorial fashion to come up stemployed a combinatorial method, testing many variations of display and spacers for each passenger, in order to come . Because this requires the construction of a very large number of parts, we developed a high throughput automated assembly method. The data generated by this method allows future investigators to estimate the number of combinations that must be constructed in order to find functional display, and helps investigators chose subsets of combinations within the design space that are most likely to yield success.

Passengers
Displayers
Spacers