Peter Peizhi Luo

Adapter-directed display: a modular design for shuttling display on phage surfaces.

A novel adapter-directed phage display system was developed with modular features. In this system, the target protein is expressed as a fusion protein consisting of adapter GR1 from the phagemid vector, while the recombinant phage coat protein is expressed as a fusion protein consisting of adapter GR2 in the helper phage vector. Surface display of the target protein is accomplished through specific heterodimerization of GR1 and GR2 adapters, followed by incorporation of the heterodimers into phage particles. A series of engineered helper phages were constructed to facilitate both display valency and formats, based on various phage coat proteins. As the target protein is independent of a specific phage coat protein, this modular system allows the target protein to be displayed on any given phage coat protein and allows various display formats from the same vector without the need for reengineering. Here, we demonstrate the shuttling display of a single-chain Fv antibody on phage surfaces between multivalent and monovalent formats, as well as the shuttling display of an antigen-binding fragment molecule on phage coat proteins pIII, pVII, and pVIII using the same phagemid vectors combined with different helper phage vectors. This adapter-directed display concept has been applied to eukaryotic yeast surface display and to a novel cross-species display that can shuttle between prokaryotic phage and eukaryotic yeast systems.

Yeast surface display of antibodies via the heterodimeric interaction of two coiled-coil adapters

A novel adapter-directed yeast display system with modular features was developed. This display system consists of two modules, a display vector and a helper vector, and is capable of displaying proteins of interest on the surface of Saccharomyces cerevisiae through the interaction of two small adapters that are expressed from the display and helper vectors. In this report, an anti-VEGF scFv antibody gene was cloned into the display vector and introduced alone into yeast S. cerevisiae cells. This led to the expression and secretion of a scFv antibody that was fused in-frame with the coiled-coil adapter GR1. For display purposes, a helper vector was constructed to express the second coiled-coil adapter GR2 that was fused with the outer wall protein Cwp2, and this was genetically integrated into the yeast genome. Co-expression of the scFv-GR1 and GR2-Cwp2 fusions in the yeast cells resulted in the functional display of anti-VEGF scFv antibodies on the yeast cell surfaces through pairwise interaction between the GR1 and GR2 adapters. Visualization of the co-localization of GR1 and GR2 on the cell surfaces confirmed the adapter-directed display mechanism. When the adapter-directed phage and yeast display modules are combined, it is possible to expand the adapter-directed display to a novel cross-species display that can shuttle between phage and yeast systems.

Parallel selection of antibody libraries on phage and yeast surfaces via a cross-species display

We created a cross-species display system that allows the display of the same antibody libraries on both prokaryotic phage and eukaryotic yeast without the need for molecular cloning. Using this cross-display system, a large, diverse library can be constructed once and subsequently used for display and selection in both phage and yeast systems. In this article, we performed the parallel phage and yeast selection of an antibody maturation library using this cross-display platform. This parallel selection allowed us to isolate more unique hits than single-species selection, with 162 unique clones from phage and 107 unique clones from yeast. In addition, we were able to shuttle yeast hits back to Escherichia coli cells for affinity characterization at a higher throughput.

Antibody Engineering Using Phage Display with a Coiled-Coil Heterodimeric Fv Antibody Fragment

A Fab-like antibody binding unit, ccFv, in which a pair of heterodimeric coiled-coil domains was fused to VH and VL for Fv stabilization, was constructed for an anti-VEGF antibody. The anti-VEGF ccFv showed the same binding affinity as scFv but significantly improved stability and phage display level. Furthermore, phage display libraries in the ccFv format were constructed for humanization and affinity maturation of the anti-VEGF antibody. A panel of VH frameworks and VH-CDR3 variants, with a significant improvement in affinity and expressibility in both E. coli and yeast systems, was isolated from the ccFv phage libraries. These results demonstrate the potential application of the ccFv antibody format in antibody engineering.