# Single-cell RNA-seq reveals a key role for Vibrio cholerae Mak toxins in Tetrahymena pyriformis killing and bacterial survival

**Authors:** Jonah M. Moon, M. Mozammel Hoque, Dana Ronin, Parisa Noorian, Joyce To, Scott A. Rice, Diane McDougald, Gustavo Espinoza-Vergara

PMC · DOI: 10.3389/fmicb.2025.1729243 · 2026-01-22

## TL;DR

This study shows that Vibrio cholerae uses Mak toxins to resist predation by Tetrahymena pyriformis and survive in expelled food vacuoles, linking environmental survival to bacterial virulence.

## Contribution

The study identifies Mak toxins as key factors in V. cholerae's resistance to protozoan grazing and survival in food vacuoles using single-cell RNA-seq.

## Key findings

- Mak toxins are differentially expressed in V. cholerae cells exposed to Tetrahymena pyriformis.
- V. cholerae mutants lacking Mak toxins fail to kill T. pyriformis and show reduced survival in food vacuoles.
- Single-cell RNA-seq reveals 11 distinct gene expression clusters in V. cholerae under protozoan exposure.

## Abstract

In the environment, Vibrio cholerae employs multiple strategies to resist predation by heterotrophic protozoa. For example, V. cholerae biofilms release toxic compounds, such as ammonium and pyomelanin, which can kill protists, such as Tetrahymena pyriformis. V. cholerae has also been shown to survive intracellularly and can escape as viable cells inside protozoan-expelled food vacuoles (EFVs). We previously reported that V. cholerae encased in EFVs are hyperinfectious, establishing an important link between anti-protozoal strategies and bacterial virulence. Although the intracellular resistance and escape of V. cholerae in EFVs have been reported, the molecular mechanisms behind this remain poorly understood. Here, we used single-cell transcriptomics of V. cholerae exposed to T. pyriformis and captured a total of 5,344 bacterial cells with heterogeneous gene expression. Cells with the same pattern of gene expression were grouped, resulting in 11 clusters of cells with a unique gene expression profile. Genes encoding outer membrane proteins, F1F0-Na+/H+ ATPase, metabolites, and toxins showed differential expression among the clusters. Furthermore, the motility-associated killing factor (Mak) toxins were differentially expressed. The V. cholerae mutants ΔmakA, ΔmakB, and ΔmakE were not capable of killing T. pyriformis, and ΔmakA and ΔmakE showed reduced survival inside EFVs compared to the wild type. These findings identify Mak toxins as key mediators of V. cholerae resistance to protozoan grazing and survival within EFVs. More broadly, our results provide mechanistic insight into grazing resistance, reveal factors facilitating persistence in EFVs, and underscore the interplay between environmental survival strategies and virulence in pathogenic bacteria.

## Linked entities

- **Genes:** makA (alpha-pore-forming cytotoxin MakA) [NCBI Gene 61411183], makB (alpha-pore-forming cytotoxin subunit MakB) [NCBI Gene 61411184], makE (alpha-pore-forming cytotoxin subunit MakE) [NCBI Gene 61411182]
- **Species:** Vibrio cholerae (taxon 666), Tetrahymena pyriformis (taxon 5908)

## Full-text entities

- **Chemicals:** ammonium (MESH:D064751), Mak toxins (-), pyomelanin (MESH:C023793)
- **Species:** Tetrahymena pyriformis (species) [taxon 5908], Vibrio cholerae (species) [taxon 666]

## Figures

5 figures with captions in the complete paper: https://tomesphere.com/paper/PMC12872930/full.md

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Source: https://tomesphere.com/paper/PMC12872930