Reconstitution in a minimal synthetic bacterium reveals distinct Mollicute MreB-based motility systems driven by orthogonal force directions

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Abstract

MreB, a bacterial actin homolog, is widely conserved in bacteria where it functions as a scaffold for a peptidoglycan synthesis. Intriguingly, members of the cell wall-lacking Mollicutes retain multiple mreB genes despite the absence of peptidoglycan. Previous work demonstrated that two MreB isoforms from Spiroplasma can reconstitute swimming motility in the minimal synthetic bacterium syn3B, indicating that MreB was repurposed for motility. Here, we expressed seven MreBs from Haloplasma contractile , an early-diverging Mollicutes, in syn3B. Approximately 50% of cells elongated, and 15% exhibited curving and coiling movements that resembled Haloplasma but differed from Spiroplasma motility. Systematic analysis of isoform combinations revealed that movement requires specific MreB pairs, and that additional isoforms enhance motility efficiency. Cryo-electron tomography showed membrane-associated ribbons composed of MreB filaments. Mathematical modeling demonstrated that Haloplasma - and Spiroplasma -type movements can be reproduced by altering only the direction of force generation. Thus, diversification of force orientation within an actin homolog enabled independent evolution of distinct motility systems in Mollicutes.

Teaser

MreB a bacterial actin can drive motility of a minimal synthetic bacterium by mechanisms distinct from eukaryotic actin.

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