# Phosphorylation State Dictates Bacterial Stressosome Assembly and Function

**Authors:** Elizabeth A. Martinez-Bond, Ivanna Lopez-Ayala, Mariya Lobanovska, Lisa Qiu, Virginia Garda, Zanlin Yu, Daniel A. Portnoy, Allison H. Williams

PMC · DOI: 10.21203/rs.3.rs-6735924/v1 · 2025-05-30

## TL;DR

This paper shows how phosphorylation controls the assembly and function of bacterial stressosomes, which are crucial for stress response and virulence in Listeria monocytogenes.

## Contribution

The study reveals specific phosphorylation sites that regulate stressosome structure and function, linking structural dynamics to bacterial adaptation and pathogenesis.

## Key findings

- Phosphorylation at T175 primes the stressosome for activation, while S56 phosphorylation destabilizes the core and releases RsbT.
- Phosphomimetic mutants resist oxidative stress but lose virulence, whereas phosphodeficient mutants are stress-sensitive but retain virulence.
- Phosphorylation at T209 modulates stressosome composition and fine-tunes the intensity of the stress response.

## Abstract

Bacterial pathogens rely on their ability to sense and respond to environmental stressors to survive and maintain virulence. The stressosome, a 1.8-megadalton nanomachine, serves as a critical sensor and regulator of the general stress response. It is composed of multiple copies of three proteins RsbR, RsbS, and the kinase RsbT which together orchestrate activation of downstream stress adaptation pathways. Using cryo-electron microscopy, we solved the atomic structure of five Listeria monocytogenes stressosomes, capturing structural mimics of the transition between inactive and activated states using phosphomimetic and phosphodeficient mutants. Our findings reveal that phosphorylation at specific residues T175 and T209 on RsbR, and S56 on RsbS dictates stressosome assembly, stoichiometry, and activation. Specifically, phosphorylation at T175 primes the stressosome for activation, while S56 phosphorylation destabilizes the core, triggering the release of RsbT to propagate the stress response. In contrast, phosphorylation at T209 modulates stressosome composition and appears to fine-tune the intensity of the stress response. Functional analyses reveal that phosphomimetic mutants (T209E, S56D) resist oxidative stress but lose virulence in host cell model, while phosphodeficient mutants (T175A, S56A) are stress-sensitive but retain virulence. These findings establish phosphorylation as a central regulatory switch linking structural dynamics to bacterial adaptation and pathogenesis, highlighting potential targets for antimicrobial intervention.

## Linked entities

- **Genes:** RsbR (positive regulator of sigma-B activity) [NCBI Gene 986201], rsbS (antagonist of RsbT) [NCBI Gene 938157], rsbT (switch protein/serine-threonine kinase; controls the activity of the anxiosome (stressosome)) [NCBI Gene 938168]
- **Proteins:** RsbR (positive regulator of sigma-B activity), rsbS (antagonist of RsbT), rsbT (switch protein/serine-threonine kinase; controls the activity of the anxiosome (stressosome))
- **Species:** Listeria monocytogenes (taxon 1639)

## Full-text entities

- **Species:** Listeria monocytogenes (species) [taxon 1639]
- **Mutations:** T209, S56, T209E, T175, T175A, S56D, S56A

## Figures

6 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12154155/full.md

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Source: https://tomesphere.com/paper/PMC12154155