The use of phage display peptide libraries for basic and translational research.

Phage display is a molecular technique, whereby genes are displayed in a functional form on the outer surfaces of bacteriophages by fusion to viral coat proteins. The gene product is encoded by a plasmid contained within the virus, which can be recovered and sequenced, linking the genetic information to the function of the protein. Phage display offers a powerful tool for the identification of short peptides or single chain antibodies that can bind and regulate the function of target proteins.

Identification of cancer targets and therapeutics using phage display.

Phage display is a well-established approach for the identification of bioactive peptides and antibody fragments through the use of high diversity libraries. One major advantage of phage display lies in its ability to rapidly identify target-specific reagents with pharmacological activity as agonists or antagonists. Peptides and antibodies have several clinical advantages over traditional small-molecule chemotherapeutics, including specificity, selectivity and potency.

Assembly of high-affinity insulin receptor agonists and antagonists from peptide building blocks.

Insulin is thought to elicit its effects by crosslinking the two extracellular alpha-subunits of its receptor, thereby inducing a conformational change in the receptor, which activates the intracellular tyrosine kinase signaling cascade. Previously we identified a series of peptides binding to two discrete hotspots on the insulin receptor. Here we show that covalent linkage of such peptides into homodimers or heterodimers results in insulin agonists or antagonists, depending on how the peptides are linked.

Peptides identify multiple hotspots within the ligand binding domain of the TNF receptor 2.

BACKGROUND: Hotspots are defined as the minimal functional domains involved in protein:protein interactions and sufficient to induce a biological response. RESULTS: Here we describe the use of complex and high diversity phage display libraries to isolate peptides (called Hotspot Ligands or HSPLs) which sub-divide the ligand binding domain of the tumor necrosis factor receptor 2 (TNFR2; p75) into multiple hotspots. We have shown that these libraries could generate HSPLs which not only subdivide hotspots on protein and non-protein targets but act as agonists or antagonists.

Peptides identify the critical hotspots involved in the biological activation of the insulin receptor.

We used phage display to generate surrogate peptides that define the hotspots involved in protein-protein interaction between insulin and the insulin receptor. All of the peptides competed for insulin binding and had affinity constants in the high nanomolar to low micromolar range. Based on competition studies, peptides were grouped into non-overlapping Sites 1, 2, or 3.