International Journal of Molecular Biotechnology

Phage display is a potential technology used in many areas including identification of therapeutic peptides for antiviral purposes. By inserting degenerated oligonucleotides into the phage genes encoding coat proteins, large and diverse peptide libraries can be expressed on the surface of phages. Following incubation of the generated library with a target of interest (viral proteins), selective phages with enriched affinity for such target can be separated and sequenced to determine the identity of the displayed peptides. The identified displayed peptides can be as therapeutic agent against those specific viral diseases. This technology can be used for any microbial diseases however, this review briefly covers the general overview of proteomic phage display and its application in identification of peptide inhibitors against viral diseases.

Arap, Marco Antonio. "Phage display technology: applications and innovations." Genetics and Molecular Biology. 2005; 28.1: 1–9.

Huang R, Pershad K, et al. Phage‐Displayed Combinatorial Peptides. Amino Acids, Peptides and Proteins in Organic Chemistry: Volume 4: Protection Reactions, Medicinal Chemistry, Combinatorial Synthesis. 2011 Mar 18; 4: 451–71.

Hamzeh-Mivehroud M, Alizadeh AA, et al. Phage display as a technology delivering on the promise of peptide drug discovery. Drug discovery today. 2013 Dec 1; 18 (23–24): 1144–57.

MANUAL I. Ph. D. Phage Display Libraries.

Fukunaga K, Taki M. Practical tips for construction of custom peptide libraries and affinity selection by using commercially available phage display cloning systems. Journal of nucleic acids. 2012 Oct; 2012.

Castel G, Chtéoui M, Heyd B, Tordo N. Phage display of combinatorial peptide libraries: application to antiviral research. Molecules. 2011 Apr 26; 16 (5): 3499–518.

Rajik M, Omar AR, et al. A novel peptide inhibits the influenza virus replication by preventing the viral attachment to the host cells. International journal of biological sciences. 2009; 5 (6): 543.

Sticht J, Humbert M, et al. A peptide inhibitor of HIV-1 assembly in vitro. Nature structural & molecular biology. 2005 Aug; 12 (8): 671–7.

Lü X, Yao M, et al. Identification of peptides that bind hepatitis C virus envelope protein E2 and inhibit viral cellular entry from a phage-display peptide library. International journal of molecular medicine. 2014 May 1; 33 (5): 1312–8.

Amin A, Zaccardi J, et al. Identification of constrained peptides that bind to and preferentially inhibit the activity of the hepatitis C viral RNA-dependent RNA polymerase. Virology. 2003 Aug 15; 313 (1): 158–69.

Desjobert C, de Soultrait VR, et al. Identification by phage display selection of a short peptide able to inhibit only the strand transfer reaction catalyzed by human immunodeficiency virus type 1 integrase. Biochemistry. 2004 Oct 19; 43 (41): 13097–105.

Tran T, Hoffmann S, et al. Insights into human Lck SH3 domain binding specificity: different binding modes of artificial and native ligands. Biochemistry. 2005 Nov 15; 44 (45): 15042–52.

Díaz‐Valdés N, Manterola L, et al. Improved dendritic cell‐based immunization against hepatitis C virus using peptide inhibitors of interleukin 10. Hepatology. 2011 Jan; 53 (1): 23–31.