This study(doi: https://doi.org/10.1002/mlf2.70089) was led by Prof. Jian Xu (Qingdao Institute of Bioenergy and Bioprocess Technology, Chinese Academy of Sciences) in collaboration with Prof. Hongzhou Lu (Shenzhen Third People’s Hospital) and Prof. Jiadong Huang (University of Jinan). To address the lack of rapid and quantitative phage susceptibility test (PST) methods for precision phage therapy, scientists developed a ramanome-based PST (RPST), which uses label-free Raman spectroscopy to capture the biochemical remodeling that bacteria undergo during phage infection. Because these molecular-level changes occur within minutes—well before bacterial lysis becomes visible—RPST can classify infection outcomes within approximately 1 h, compared with the 11–21 h required by conventional plaque assays (Fig. 1).

To identify conserved ramanome biomarkers that distinguish infected from uninfected bacterial populations, scientists analyzed ramanomes from multiple representative phage-host systems, including T1- and T4-infected Escherichia coli strains, across multiple time points and MOI conditions. Four spectral regions capturing changes in nucleic acids, proteins, and lipids were identified as conserved biomarkers of phage infection across all systems tested (Fig. 2). These biomarkers showed sustained, progressive shifts in phage-susceptible bacteria, while resistant strains showed only transient responses that quickly returned to baseline—enabling clear discrimination between susceptible and resistant populations.

To achieve robust and generalizable infection classification, the four biomarkers were integrated into a Composite Infection Index (CII) using a random forest model. Cross-validation demonstrated excellent performance, with an average AUC of 0.995 and a mean accuracy of 0.965 (Fig. 3). RPST successfully distinguished susceptible and resistant bacterial populations and achieved 96.0% concordance with conventional plaque assays across 25 phage-host systems spanning four clinically relevant bacterial species.

Beyond binary susceptibility testing, RPST enabled quantitative ranking of phage potency. Because the CII accurately reflected the fraction of infected cells in a population, it directly captures how effectively different phages infect the same host—information that plaque assays alone cannot resolve (Fig. 4). Critically, by tracking CII over time at different phage-to-bacterium ratios, RPST also determined the minimum phage dose at which infection can sustain and propagate through a bacterial population, a key parameter for predicting whether a phage will work under realistic clinical conditions (Fig. 5). Together, these findings establish RPST as a rapid, quantitative, and dynamic phenotypic framework for phage susceptibility test and precision phage therapy.

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References

DOI

10.1002/mlf2.70089

Original Source URL

https://doi.org/10.1002/mlf2.70089

Funding information

This work· was supported by the National Natural Science Foundation of China (Nos. 32030003 and 32571695) and the Young Scientists in Basic Research Program from the Chinese Academy of Sciences (No. YSBR‐111).

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mLife is an open access microbiology journal, sponsored by the Institute of Microbiology of the Chinese Academy of Sciences, in cooperation with the Chinese Society for Microbiology. The journal aims to publish novel and high-impact discoveries in a wide spectrum of disciplines in microbiology. mLife has been indexed by ESCI, PubMed, Scopus, DOAJ, CSCD, CAS, Google Scholar, etc.