Publication of IMPRS-LS student Quirin Emslander
Emslander, Q., Vogele, K., Braun, P., Stender, J., Willy, C., Joppich, M., Hammerl, J.A., Abele, M., Meng, C., Pichlmair, A., Ludwig, C., Bugert, J.J., Simmel, F.C., and Westmeyer, G.G.
Cell Chem Biol, 2022, online ahead of print.
doi: 10.1016/j.chembiol.2022.06.003
Cell-free production of personalized therapeutic phages targeting multidrug-resistant bacteria
Bacteriophages are potent therapeutics against biohazardous bacteria, which rapidly develop multidrug resistance. However, routine administration of phage therapy is hampered by a lack of rapid production, safe bioengineering, and detailed characterization of phages. Thus, we demonstrate a comprehensive cell-free platform for personalized production, transient engineering, and proteomic characterization of a broad spectrum of phages. Using mass spectrometry, we validated hypothetical and non-structural proteins and could also monitor the protein expression during phage assembly. Notably, a few microliters of a one-pot reaction produced effective doses of phages against enteroaggregative Escherichia coli (EAEC), Yersinia pestis, and Klebsiella pneumoniae. By co-expressing suitable host factors, we could extend the range of cell-free production to phages targeting gram-positive bacteria. We further introduce a non-genomic phage engineering method, which adds functionalities for only one replication cycle. In summary, we expect this cell-free methodology to foster reverse and forward phage engineering and customized production of clinical-grade bacteriophages.