Phage display is a laboratory technique for the study of protein interactions that uses bacteriophages (viruses that infect bacteria) to produce and "display" the proteins on their surfaces. Since the proteins remain attached to the surface of the phage, it is possible to isolate the phages displaying desirable proteins from among very large collections (libraries) of phages, using e.g. other protein or DNA molecules as baits. The DNA of the selected phages can then be sequenced to establish the identity of selected proteins. The phages themselves can be further propagated in bacteria to amplify or diversify the selected protein library, with potential for conducting directed evolution experiments with multiple rounds of selection and diversification.

Specifically, a gene encoding a protein of interest is inserted into a phage coat protein gene, causing the phage to "display" the protein on its outside while containing the gene for the protein on its inside. This couples the genotype (gene), phenotype (protein) in the context of an organism (phage) capable of replication. The phages displaying proteins of interest can then be selected using other proteins or DNA sequences in order to e.g., identify natural protein binding partners or antibodies with a high binding affinity.

The most common bacteriophages used in phage display are M13 and fd filamentous phage, though T4, T7, and λ phage have also been used.

Phage display was first described by George P. Smith in 1985, when he demonstrated the display of peptides on filamentous phage (long, thin viruses that infect bacteria) by fusing the virus's capsid protein to one peptide out of a collection of peptide sequences. This displayed the different peptides on the outer surfaces of the collection of viral clones, where the screening step of the process isolated the peptides with the highest binding affinity.

In 1988, Stephen Parmley and George Smith described biopanning for affinity selection and demonstrated that recursive rounds of selection could enrich for clones present at 1 in a billion or less. In 1990, Jamie Scott and George Smith described creation of large random peptide libraries displayed on filamentous phage.

Phage display technology was further developed and improved by groups at the Laboratory of Molecular Biology with Greg Winter and John McCafferty, The Scripps Research Institute with Richard Lerner and Carlos Barbas and the German Cancer Research Center with Frank Breitling and Stefan Dübel for display of proteins such as antibodies for therapeutic protein engineering.

Smith and Winter were awarded a half share of the 2018 Nobel Prize in chemistry for their contribution to developing phage display. A patent by George Pieczenik claiming priority from 1985 also describes the generation of peptide libraries.

In the case of M13 filamentous phage display, the DNA encoding the protein of interest is inserted into the gene encoding either the minor (pIII) or the major (pVIII) coat protein. The modified coat protein gene and the rest of the phage genome is then introduced into E. coli bacteria, which produce phage virions with the relevant protein fragment as part of their outer coat phage and the DNA encoding for these proteins packaged inside the phage.