Abstract
The development of phage engineering technology has led to the construction of a novel type of phage display library—a collection of nanofiber materials with diverse molecular landscapes accommodated on the surface of phage particles. These new nanomaterials, called the “landscape phage”, serve as a huge resource of diagnostic/detection probes and versatile construction materials for the preparation of phage-functionalized biosensors and phage-targeted nanomedicines. Landscape-phage-derived probes interact with biological threat agents and generate detectable signals as a part of robust and inexpensive molecular recognition interfaces introduced in mobile detection devices. The use of landscape-phage-based interfaces may greatly improve the sensitivity, selectivity, robustness, and longevity of these devices. In another area of bioengineering, landscape-phage technology has facilitated the development and testing of targeted nanomedicines. The development of high-throughput phage selection methods resulted in the discovery of a variety of cancer cell-associated phages and phage proteins demonstrating natural proficiency to self-assemble into various drug- and gene-targeting nanovehicles. The application of this new “phage-programmed-nanomedicines” concept led to the development of a number of cancer cell-targeting nanomedicine platforms, which demonstrated anticancer efficacy in both in vitro and in vivo experiments. This review was prepared to attract the attention of chemical scientists and bioengineers seeking to develop functionalized nanomaterials and use them in different areas of bioscience, medicine, and engineering.
Highlights
Filamentous bacteriophages, remarkably tolerant of dramatic structural alteration, are in every respect the perfect material for bioengineering
This review focuses on Ff phage display vectors, as precursors of landscape phages and as major workhorses in phage nanobiotechnology
To construct this type of viral chimera, an alien DNA fragment is inserted into a gene encoding one of the phage coat proteins in such a way that the encoded “foreign” peptide is genetically fused to a coat protein and, by these means, exposed on the surface of the phage particle
Summary
Filamentous bacteriophages (shortly phages), remarkably tolerant of dramatic structural alteration, are in every respect the perfect material for bioengineering. This review focuses on Ff phage display vectors, as precursors of landscape phages and as major workhorses in phage nanobiotechnology It considers those aspects of the structure and life cycle of Ff phages that are of direct practical interest to chemical scientists and bioengineers seeking to develop phage virions. After the discovery of penicillin in 1928 [6] and its triumphal introduction in the the interest interest in in the the practical practical applications applications of of phages phages as as antibacterial antibacterial agents agents faded, faded, along along with with increasing increasing the interest in phages as tools for fundamental biological studies [7]. These small male-specific filamentous coliphages incorporate a single-stranded circular circular. Because these phages code for a code for a small proteins, reproduction of the mostly supported by host bacteria.
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