Most bacteria with a rod-shaped morphology contain an actin-like cytoskeleton consisting of MreB polymers, which form helical spirals underneath the cytoplasmic membrane to direct peptidoglycan synthesis for the elongation of the cell wall. In contrast, MreB of Streptomyces coelicolor is not required for vegetative growth but has a role in sporulation. Besides MreB, S. coelicolor encodes two further MreB-like proteins, Mbl and SCO6166, whose function is unknown. Whereas MreB and Mbl are highly similar, SCO6166 is shorter, lacking the subdomains IB and IIB of actin-like proteins. Here, we showed that MreB and Mbl are not functionally redundant but cooperate in spore wall synthesis. Expression analysis by semiquantitative reverse transcription-PCR revealed distinct expression patterns. mreB and mbl are induced predominantly during morphological differentiation. In contrast, sco6166 is strongly expressed during vegetative growth but switched off during sporulation. All genes could be deleted without affecting viability. Even a ⌬mreB ⌬mbl double mutant was viable. ⌬sco6166 had a wild-type phenotype. ⌬mreB, ⌬mbl, and ⌬mreB ⌬mbl produced swollen, prematurely germinating spores that were sensitive to various kinds of stress, suggesting a defect in spore wall integrity. During aerial mycelium formation, an Mbl-mCherry fusion protein colocalized with an MreB-enhanced green fluorescent protein (MreB-eGFP) fusion protein at the sporulation septa. Whereas MreB-eGFP localized properly in the ⌬mbl mutant, Mbl-mCherry localization depended on the presence of a functional MreB protein. Our results revealed that MreB and Mbl cooperate in the synthesis of the thickened spore wall, while SCO6166 has a nonessential function during vegetative growth.The peptidoglycan (PG) layer, consisting of long glycan strands cross-linked by short peptides, is a major determinant of bacterial cell shape (51). Most species with a complex, nonspherical morphology contain the actin-like MreB protein, which belongs to the HSP70-actin-sugar kinase (ASHKA) superfamily of proteins (4, 48). MreB was shown to polymerize into a dynamic helical filament underneath the cytoplasmic membrane spanning the long axis of the cells (11,17,25,30,33). In rod-shaped bacteria, MreB is thought to interact with other proteins to position a cell wall-synthesizing complex at the lateral cell wall (16,17,32). The incorporation of new PG at the lateral wall results in cell elongation, thus determining rod-shaped morphology. Gram-negative bacteria seem to have a single mreB gene, usually in an operon with mreC and mreD.
