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Yeast Display Systems

a display system and protein technology, applied in the field of protein display libraries and library screening, can solve the problems of difficult to determine the actual affinity of a target protein for the phage display protein, require post-translational modifications, and not always identify the target protein that binds the library with very high affinity

Inactive Publication Date: 2011-11-10
NOVARTIS AG
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Benefits of technology

The present invention provides methods and compositions for displaying modified polypeptides on host cells. The host cells have a cell surface molecule attached to the surface of the cell and a first nucleic acid encoding a display polypeptide comprising a modified polypeptide. An adapter molecule is contacted with the host cell and the display polypeptide, which binds specifically to the cell surface molecule and does not bind to the display molecule. The display polypeptide is then incubated under conditions wherein the host cell exports the display polypeptide outside the host cell. The invention allows for the display of a modified polypeptide on host cells with high efficiency and specificity. The host cells may be yeast cells or mammalian cells.

Problems solved by technology

However, one major drawback of this method is that target proteins that bind the library with very high affinity are not always identified because the conditions required to elute the bound phase usually denature the phage particle such that it becomes impossible to identify the protein of interest.
Another draw back of phage display libraries is the requirement that the target protein be immobilized on a solid surface, which can lead to difficulties in determining the actual affinity of a target protein for the phage display protein.
Furthermore, some proteins of interest require post-translational modifications, such as glycosylation, methylation, or disulfide binding, that cannot be achieved when expressed in a phage particle.
This method solves many of the drawbacks associated with phage display but has its own problems.
One problem with bacterial display is that the bacterial capsule can cause steric hindrance to proteins displayed on the bacterial surface.
Also, bacteria do not contain the machinery to properly fold eukaryotic proteins, so the protein of interest may not always be expressed within the bacterium.
Similar to the problem in phage, bacteria cannot provide post-translational modifications, like disulfide binding, to a eukaryotic protein.
One potential drawback of this system is that avidin non-specifically binds all biotin.
Another potential drawback is that avidin contains four binding sites, which may cause steric hindrance thus preventing the biotinylated protein library from binding to the cell surface bound avidin.
Additionally, this method contains the added complication of having to biotinylate the protein library within the yeast cell.
Such kits would be difficult to use in such a biotin / avidin display system.
The prior art lacks a simple, efficient system capable of specifically binding a secreted protein library using an adapter molecule that binds to the protein library and to the surface of a eukaryotic cell through different binding moieties.

Method used

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Examples

Experimental program
Comparison scheme
Effect test

example 1

Yeast Display Using InaD / NorpA Interaction in Pichia pastoris

The protein display system for P. pastoris was developed to display a fibronectin type 111 domain (Fn10), by fusing a hybrid secretion sequence (MFalpha / HSA) or a yeast leader sequence (MFalpha1) at N-terminus of Fn10 and fusing the NorpA ligand to its C-terminus. Once expressed, the Fn10 was secreted from the cell and the NorpA ligand bound specifically to the PDZ domain of InaD through disulfide bonds. The InaD was fused to the C-terminus of the Agap2 protein. The Aga2p-InaD fusion protein served as the adapter protein, and the N-terminal Aga2p bound Aga1p, which was immobilized on the surface of the cell. Aga2p bound specifically to Aga1p through disulfide bonds.

The three component system consisting of the Fn10-NorpA fusion protein, the

Aga2p-InaD fusion protein, and the Aga1p cell surface protein were cloned into pPIC expression vectors, under the control of an inducible promoter. The inducible promoter used was the A...

example 2

Switch System to Secrete or Display Fibronectins on the Surface of Pichia pastoris

One variant of the above display system enables the choice between secretion and display of proteins from P. pastoris. To achieve this, the fibronectin construct consisting of the MFalpha1 / HSA hybrid leader followed by fibronectin fused at the C-terminus to the NorpA ligand sequence is cloned into pPlCHOLl-C instead of pPlCHOLl-1. The resulting vector is named pPlCHOLl-C Mfalpha1Hsa-Fn10-NorpA (FIG. 8). The key difference between the two vectors is the promoter, which in pPlCHOLl-1 is the AOX1 promoter induced by methanol, and in the pPlCHOLl-C is the Cup1 promoter induced by copper. To display the fibronectin on the surface of P. pastoris, AGA1 and AGA2-InaD are induced with methanol, while pPlCHOL1-C is induced with copper. This allows for the capture of the secreted fibronectin on the surface of yeast mediated through the tight InaD / NorpA interaction. For secretion of the fibronectin without displa...

example 3

Yeast Display Using InaD / NorpA Interaction in Saccharomyces cerevisiae

This example describes using the InaD / NorpA system with other yeast strains such as Saccharomyces cerevisiae

Strains and Media

Escherichia coil Top10 (Invitrogen, Carlsbad, Calif.) was used as the host strain for recombinant DNA manipulation. The S. cerevisiae strain EBY100 (Invitrogen Co., Carlsbad, Calif.) was used for the production of the fusion proteins AGA2-InaD and MSalpha1 / HSA-Fn10-NorpA or pYS6CT*MFalpha1-HSA-NorpA. E. coli was cultivated LB medium (1% tryptone, 0.5% yeast extract, and 0.5% sodium chloride) containing 100 u / g / mL ampicillin or 100 ug / ml Blasticidin. EBY 100 was cultivated in CM medium-URA.

Construction of Expression Plasmids

The InaD anchor gene was synthesized by Geneart (Germany) and subcloned in frame with the AGA2 anchor protein into the expression vector pYD NBC1 (derivative of pYD1Invitrogen) using HindIII and EcoRI restriction sites. The resulting vector was named pYD_NBC1 AGA2-InaD (...

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Abstract

The present invention relates to the field of protein display libraries and library screening. In preferred embodiments, the present invention provides a three component system for display comprising a cell surface molecule, an adapter molecule and a display molecule.

Description

FIELDThe present invention relates to the field of protein display libraries and library screening. More specifically, the present invention relates to the production of proteins for display on cell surfaces.BACKGROUNDProtein binding domains can be predicted from sequence data, however re-designing proteins with improved or altered binding affinities often requires testing of a number of variants of the re-designed protein. Currently the best method for obtaining proteins with desired binding affinities is to generate and screen a protein library including such variants that can include rationally redesigned proteins, randomly altered proteins, or a combination thereof. Libraries of many types of protein, such as immunoglobulins and scaffold proteins and receptors or receptor ligands have successfully been constructed and screened for binding affinity.There are many methods to screen libraries, but one of the most common methods is the phage display method, which comprises fusion of...

Claims

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Application Information

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Patent Type & Authority Applications(United States)
IPC IPC(8): C40B30/04C40B50/06C40B40/02
CPCC07K2319/035C07K2319/70C07K2319/912C40B50/06C12N15/81C40B40/08C12N15/1037C12N15/70C12Q1/02C40B40/10C07K14/395C07K14/78C12N15/815C40B30/04C40B40/02
Inventor LOEW, ANDREAS
Owner NOVARTIS AG
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