Capsular specificity in temperate phages of Klebsiella pneumoniae is driven by diverse receptor-binding enzymes

Aleksandra Otwinowska; Janusz Koszucki; Vyshakh R. Panicker; Jade Leconte; Sebastian Olejniczak; Kathryn E. Holt; Edward J. Feil; Eduardo P. C. Rocha; Bogna Smug; Barbara Maciejewska; Zuzanna Drulis-Kawa; Rafal J. Mostowy

doi:10.1371/journal.pbio.3003716

Capsular specificity in temperate phages of Klebsiella pneumoniae is driven by diverse receptor-binding enzymes

Aleksandra Otwinowska, Janusz Koszucki, Vyshakh R. Panicker, Jade Leconte, Sebastian Olejniczak, Kathryn E. Holt, Edward J. Feil, Eduardo P. C. Rocha, Bogna Smug, Barbara Maciejewska, Zuzanna Drulis-Kawa, Rafal J. Mostowy

Research output: Contribution to journal › Article › peer-review

Abstract

Virulent bacteriophages infecting Klebsiella pneumoniae often show capsule-driven host tropism due to the presence of capsule-specific depolymerases. Yet for temperate phages the genetic and functional basis of such capsular specificity remains less well understood. Depolymerases appear unexpectedly rare in prophage genomes, raising unresolved questions about which prophage genes mediate capsular specificity, whether this apparent scarcity reflects biological or ecological differences versus annotation limitation, and whether prophage-encoded receptor-binding proteins (RBPs) are functionally active. To address these questions, we analysed 3,900 Klebsiella genomes from diverse ecological niches to identify prophage-encoded proteins mediating capsular specificity. We conducted a genome-wide association study (GWAS) correlating prophage protein clusters (from 8,105 prophages) with confidently assigned bacterial K-loci. GWAS revealed statistically supported predictors of capsular specificity for 16 of the 35 most diverse K-loci analysed. These predictors were dominated by diverse RBPs, including classical [Formula: see text]-helix depolymerases (6 predictors), SGNH-domain hydrolases predicted to deacetylate polysaccharides (6 predictors), and structurally novel RBPs lacking known depolymerase folds (2 predictors). Nearly one-third of K-loci yielded no statistically significant predictors. A targeted experimental screen of 50 candidate prophage depolymerases showed that 34 failed to yield detectable recombinant expression, and neither sequence similarity, structural prediction, nor prophage genomic context reliably predicted activity. Of the 14 active enzymes, 5 targeted a K-type different from that predicted of their bacterial host, and enzyme specificity was not consistently explained by sequence or structural homology. Comparison with GWAS predictions revealed that 10 of the 12 strongest GWAS predictors were experimentally validated, while 2 remained inconclusive. Together, these results highlight the intrinsic difficulty of predicting activity and capsular specificity of prophage-encoded RBPs from genomic information alone. Finally, analysis of 4,598 high-completeness prophages revealed that SGNH-domain hydrolases are among the most prevalent enzymatic domains in prophage RBPs. Two SGNH-domain RBPs identified by GWAS were experimentally confirmed as active esterases, supporting capsule deacetylation as a widespread alternative to polysaccharide depolymerisation in temperate phages. Our findings reveal that Klebsiella prophages encode structurally diverse RBPs, suggesting temperate phages may rely not only on depolymerisation but also on capsule modification-such as deacetylation-for infection. This also suggests that capsule modification may contribute to phage-host interactions in ways not fully captured by current K-locus assignments, with potential implications for phage specificity, competition and vaccine design.

Original language	English
Pages (from-to)	e3003716
Number of pages	35
Journal	PLoS Biology
Volume	24
Issue number	4
DOIs	https://doi.org/10.1371/journal.pbio.3003716
Publication status	Published - 28 Apr 2026

Data Availability Statement

All input data and intermediate files generated by the workflow and required to reproduce the results, but not provided as Supporting Information, are publicly available in Figshare under the following DOI: - https://doi.org/10.6084/m9.figshare.29181188. These include genome assemblies for 3,911 Klebsiella isolates (whole-genome nucleotide sequences, CDS and predicted protein FASTA files), corresponding GenBank annotation files, isolate metadata tables, contig information, and the IQ-TREE bacterial phylogeny in Newick format. The repository further contains sequences and annotations for 8,105 detected prophages (genome, CDS and protein FASTA files and GenBank files), together with prophage metadata, protein cluster assignments (including representative sequences) and functional annotation tables derived from HH-suite analyses. All analysis scripts and workflows are archived in Zenodo: - Analysis pipeline (Zenodo archive): https://doi.org/10.5281/zenodo.18682073 - Figure generation pipeline (Zenodo archive): https://doi.org/10.5281/zenodo.18699826 For convenience, the corresponding GitHub repositories are also available at: https://github.com/bioinf-mcb/mgg_gwas https://github.com/rmostowy/klebs-gwas-figs.

Funding

This work was supported by the Polskie Powroty programme of the Narodowa Agencja Wymiany Akademickiej (NAWA; https://nawa.gov.pl/en) awarded to RM, an Installation Grant from the European Molecular Biology Organisation (EMBO; https://www.embo.org) awarded to RM, and grant no. 2020/38/E/NZ8/00432 from the Narodowe Centrum Nauki (NCN; https://www.ncn.gov.pl/en) awarded to RM. Support from the INCEPTION project (PIA/ANR-16-CONV-0005) awarded to EPCR and the Laboratoire d’Excellence IBEID Integrative Biology of Emerging Infectious Diseases (ANR-10-LABX-62-IBEID) awarded to EPCR is also acknowledged. Italian strains were collected as part of the SpARK project funded under the 2016 Joint Programming Initiative on Antimicrobial Resistance call ‘Transmission dynamics’ (Medical Research Council (MRC) reference no. MR/R00241X/1) awarded to EJF. We gratefully acknowledge the Polish high-performance computing infrastructure PLGrid (https://plgrid.pl/; HPC centres: CI TASK and ACK Cyfronet AGH) for providing computational resources and support under grants no. PLG/2023/016559 and PLG/2024/017016 awarded to RM. The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 3 Good Health and Well-being

ASJC Scopus subject areas

General Neuroscience
General Immunology and Microbiology
General Biochemistry,Genetics and Molecular Biology
General Agricultural and Biological Sciences

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10.1371/journal.pbio.3003716Licence: CC BY

Cite this

Otwinowska, A., Koszucki, J., Panicker, V. R., Leconte, J., Olejniczak, S., Holt, K. E., Feil, E. J., Rocha, E. P. C., Smug, B., Maciejewska, B., Drulis-Kawa, Z., & Mostowy, R. J. (2026). Capsular specificity in temperate phages of Klebsiella pneumoniae is driven by diverse receptor-binding enzymes. PLoS Biology, 24(4), e3003716. https://doi.org/10.1371/journal.pbio.3003716

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title = "Capsular specificity in temperate phages of Klebsiella pneumoniae is driven by diverse receptor-binding enzymes",

abstract = "Virulent bacteriophages infecting Klebsiella pneumoniae often show capsule-driven host tropism due to the presence of capsule-specific depolymerases. Yet for temperate phages the genetic and functional basis of such capsular specificity remains less well understood. Depolymerases appear unexpectedly rare in prophage genomes, raising unresolved questions about which prophage genes mediate capsular specificity, whether this apparent scarcity reflects biological or ecological differences versus annotation limitation, and whether prophage-encoded receptor-binding proteins (RBPs) are functionally active. To address these questions, we analysed 3,900 Klebsiella genomes from diverse ecological niches to identify prophage-encoded proteins mediating capsular specificity. We conducted a genome-wide association study (GWAS) correlating prophage protein clusters (from 8,105 prophages) with confidently assigned bacterial K-loci. GWAS revealed statistically supported predictors of capsular specificity for 16 of the 35 most diverse K-loci analysed. These predictors were dominated by diverse RBPs, including classical [Formula: see text]-helix depolymerases (6 predictors), SGNH-domain hydrolases predicted to deacetylate polysaccharides (6 predictors), and structurally novel RBPs lacking known depolymerase folds (2 predictors). Nearly one-third of K-loci yielded no statistically significant predictors. A targeted experimental screen of 50 candidate prophage depolymerases showed that 34 failed to yield detectable recombinant expression, and neither sequence similarity, structural prediction, nor prophage genomic context reliably predicted activity. Of the 14 active enzymes, 5 targeted a K-type different from that predicted of their bacterial host, and enzyme specificity was not consistently explained by sequence or structural homology. Comparison with GWAS predictions revealed that 10 of the 12 strongest GWAS predictors were experimentally validated, while 2 remained inconclusive. Together, these results highlight the intrinsic difficulty of predicting activity and capsular specificity of prophage-encoded RBPs from genomic information alone. Finally, analysis of 4,598 high-completeness prophages revealed that SGNH-domain hydrolases are among the most prevalent enzymatic domains in prophage RBPs. Two SGNH-domain RBPs identified by GWAS were experimentally confirmed as active esterases, supporting capsule deacetylation as a widespread alternative to polysaccharide depolymerisation in temperate phages. Our findings reveal that Klebsiella prophages encode structurally diverse RBPs, suggesting temperate phages may rely not only on depolymerisation but also on capsule modification-such as deacetylation-for infection. This also suggests that capsule modification may contribute to phage-host interactions in ways not fully captured by current K-locus assignments, with potential implications for phage specificity, competition and vaccine design.",

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T1 - Capsular specificity in temperate phages of Klebsiella pneumoniae is driven by diverse receptor-binding enzymes

AU - Otwinowska, Aleksandra

AU - Koszucki, Janusz

AU - Panicker, Vyshakh R.

AU - Leconte, Jade

AU - Olejniczak, Sebastian

AU - Holt, Kathryn E.

AU - Feil, Edward J.

AU - Rocha, Eduardo P. C.

AU - Smug, Bogna

AU - Maciejewska, Barbara

AU - Drulis-Kawa, Zuzanna

AU - Mostowy, Rafal J.

PY - 2026/4/28

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N2 - Virulent bacteriophages infecting Klebsiella pneumoniae often show capsule-driven host tropism due to the presence of capsule-specific depolymerases. Yet for temperate phages the genetic and functional basis of such capsular specificity remains less well understood. Depolymerases appear unexpectedly rare in prophage genomes, raising unresolved questions about which prophage genes mediate capsular specificity, whether this apparent scarcity reflects biological or ecological differences versus annotation limitation, and whether prophage-encoded receptor-binding proteins (RBPs) are functionally active. To address these questions, we analysed 3,900 Klebsiella genomes from diverse ecological niches to identify prophage-encoded proteins mediating capsular specificity. We conducted a genome-wide association study (GWAS) correlating prophage protein clusters (from 8,105 prophages) with confidently assigned bacterial K-loci. GWAS revealed statistically supported predictors of capsular specificity for 16 of the 35 most diverse K-loci analysed. These predictors were dominated by diverse RBPs, including classical [Formula: see text]-helix depolymerases (6 predictors), SGNH-domain hydrolases predicted to deacetylate polysaccharides (6 predictors), and structurally novel RBPs lacking known depolymerase folds (2 predictors). Nearly one-third of K-loci yielded no statistically significant predictors. A targeted experimental screen of 50 candidate prophage depolymerases showed that 34 failed to yield detectable recombinant expression, and neither sequence similarity, structural prediction, nor prophage genomic context reliably predicted activity. Of the 14 active enzymes, 5 targeted a K-type different from that predicted of their bacterial host, and enzyme specificity was not consistently explained by sequence or structural homology. Comparison with GWAS predictions revealed that 10 of the 12 strongest GWAS predictors were experimentally validated, while 2 remained inconclusive. Together, these results highlight the intrinsic difficulty of predicting activity and capsular specificity of prophage-encoded RBPs from genomic information alone. Finally, analysis of 4,598 high-completeness prophages revealed that SGNH-domain hydrolases are among the most prevalent enzymatic domains in prophage RBPs. Two SGNH-domain RBPs identified by GWAS were experimentally confirmed as active esterases, supporting capsule deacetylation as a widespread alternative to polysaccharide depolymerisation in temperate phages. Our findings reveal that Klebsiella prophages encode structurally diverse RBPs, suggesting temperate phages may rely not only on depolymerisation but also on capsule modification-such as deacetylation-for infection. This also suggests that capsule modification may contribute to phage-host interactions in ways not fully captured by current K-locus assignments, with potential implications for phage specificity, competition and vaccine design.

AB - Virulent bacteriophages infecting Klebsiella pneumoniae often show capsule-driven host tropism due to the presence of capsule-specific depolymerases. Yet for temperate phages the genetic and functional basis of such capsular specificity remains less well understood. Depolymerases appear unexpectedly rare in prophage genomes, raising unresolved questions about which prophage genes mediate capsular specificity, whether this apparent scarcity reflects biological or ecological differences versus annotation limitation, and whether prophage-encoded receptor-binding proteins (RBPs) are functionally active. To address these questions, we analysed 3,900 Klebsiella genomes from diverse ecological niches to identify prophage-encoded proteins mediating capsular specificity. We conducted a genome-wide association study (GWAS) correlating prophage protein clusters (from 8,105 prophages) with confidently assigned bacterial K-loci. GWAS revealed statistically supported predictors of capsular specificity for 16 of the 35 most diverse K-loci analysed. These predictors were dominated by diverse RBPs, including classical [Formula: see text]-helix depolymerases (6 predictors), SGNH-domain hydrolases predicted to deacetylate polysaccharides (6 predictors), and structurally novel RBPs lacking known depolymerase folds (2 predictors). Nearly one-third of K-loci yielded no statistically significant predictors. A targeted experimental screen of 50 candidate prophage depolymerases showed that 34 failed to yield detectable recombinant expression, and neither sequence similarity, structural prediction, nor prophage genomic context reliably predicted activity. Of the 14 active enzymes, 5 targeted a K-type different from that predicted of their bacterial host, and enzyme specificity was not consistently explained by sequence or structural homology. Comparison with GWAS predictions revealed that 10 of the 12 strongest GWAS predictors were experimentally validated, while 2 remained inconclusive. Together, these results highlight the intrinsic difficulty of predicting activity and capsular specificity of prophage-encoded RBPs from genomic information alone. Finally, analysis of 4,598 high-completeness prophages revealed that SGNH-domain hydrolases are among the most prevalent enzymatic domains in prophage RBPs. Two SGNH-domain RBPs identified by GWAS were experimentally confirmed as active esterases, supporting capsule deacetylation as a widespread alternative to polysaccharide depolymerisation in temperate phages. Our findings reveal that Klebsiella prophages encode structurally diverse RBPs, suggesting temperate phages may rely not only on depolymerisation but also on capsule modification-such as deacetylation-for infection. This also suggests that capsule modification may contribute to phage-host interactions in ways not fully captured by current K-locus assignments, with potential implications for phage specificity, competition and vaccine design.

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SP - e3003716

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ER -

Capsular specificity in temperate phages of Klebsiella pneumoniae is driven by diverse receptor-binding enzymes

Abstract

Data Availability Statement

Funding

UN SDGs

ASJC Scopus subject areas

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