# Identification of Receptor Binding Proteins of Yersinia Phage φR1-37 and Enterocoliticin That Use the Same Bacterial Surface Receptor

**Authors:** Mikael Skurnik, Rahime Tetik, Muhammad Suleman Qasim, Jana Sachsenröder, Ralf Dieckmann, Carlos G. Leon-Velarde, Göran Widmalm, Eckhard Strauch, Arnab Bhattacharjee

PMC · DOI: 10.3390/v18030291 · Viruses · 2026-02-27

## TL;DR

This study identifies a shared sugar-binding protein motif used by a phage and a bacteriocin to target the same bacterial receptor in Yersinia.

## Contribution

The discovery of a conserved, novel sugar-binding motif that explains shared receptor specificity in two anti-Yersinia agents.

## Key findings

- The receptor-binding proteins Gp298 and Orf39 share a conserved 80–85 amino acid motif.
- Structural models confirm high similarity in the RBP domains despite overall structural differences.
- The motif is widely present in phage tail proteins, indicating a specialized carbohydrate recognition structure.

## Abstract

The bacterium Yersinia enterocolitica serotype O:3 is targeted by two distinct agents, the bacteriophage φR1-37 and the bacteriocin-like enterocoliticin (a tailocin), which both utilize the lipopolysaccharide (LPS) outer core (OC) hexasaccharide as their primary host receptor. In order to understand this convergent recognition mechanism, we first characterized the enterocoliticin system, reporting the complete sequence of its large, biosynthetic gene cluster. Most of the 42 predicted gene products were functionally annotated by homology to known gene products. We then focused on identifying the receptor-binding proteins (RBPs) responsible for host attachment of both agents in order to elucidate a possible shared mechanism of binding. For phage φR1-37, the receptor binding complex was identified as the inseparable Gp298 tail fiber protein and its Gp297 trimerization chaperone, confirming its function as the RBP. Based on sequence identity with Gp298, the Orf39 gene product of the enterocoliticin cluster was predicted to be its corresponding RBP. An analytical comparison of the predicted RBPs revealed a highly conserved homologous region spanning 80–85 amino acid residues, which presents the only structural explanation for their identical receptor specificity. To resolve the binding mechanism, we generated high-confidence trimeric structural models for the Gp298 and Orf39 proteins using AlphaFold3-multimer. These models validated the high structural similarity of the RBP domains, despite global dissimilarity of the complete trimeric structures. Further docking simulations with a pentasaccharide ligand (generated by CarbBuilder) provided suggestive molecular models for the protein-carbohydrate interactions within the OC region. Intriguingly, a database search using the identified binding site motif revealed their wide and diverse presence in various phage tail proteins, suggesting that this motif is a specialized, common structure for carbohydrate recognition. This work identifies a conserved, novel sugar-binding motif as the molecular basis of host recognition for these key anti-Yersinia biologics.

## Linked entities

- **Genes:** orf39 (hypothetical protein) [NCBI Gene 803727]
- **Proteins:** orf39 (hypothetical protein)
- **Species:** Yersinia enterocolitica (taxon 630)

## Full-text entities

- **Chemicals:** carbohydrate (MESH:D002241), LPS (MESH:D008070), sugar (MESH:D000073893), enterocoliticin (-)
- **Species:** Yersinia (genus) [taxon 444888], Yersinia phage phiR1-37 (species) [taxon 331278]

## Full text

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## Figures

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## References

84 references — full list in the complete paper: https://tomesphere.com/paper/PMC13030884/full.md

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Source: https://tomesphere.com/paper/PMC13030884