摘要:SummaryA rigid cell wall defines the morphology of most bacteria. MreB, a bacterial homologue of actin, plays a major role in coordinating cell wall biogenesis and defining cell shape.Spiroplasmaare wall-less bacteria that robustly grow with a characteristic helical shape. Paradoxal to their lack of cell wall, theSpiroplasmagenome contains five homologs of MreB (SpMreBs). Here, we investigate the function of SpMreBs in forming a polymeric cytoskeleton. We found that,in vivo,Spiroplasmamaintain a high concentration of all MreB isoforms. By leveraging a heterologous expression system that bypasses the poor genetic tractability ofSpiroplasma, we found that SpMreBs produced polymeric filaments of various morphologies. We characterized an interaction network between isoforms that regulate filament formation and patterning. Therefore, our results support the hypothesis where combined SpMreB isoforms would form an inner polymeric cytoskeletonin vivothat shapes the cell in a wall-independent manner.Graphical abstractDisplay OmittedHighlights•The fiveSpiroplasmaMreB isoforms are extremely abundant proteinsin vivo•Each isoform produces filaments when expressed in a heterologous system•SpMreBs form an interaction network that regulates filament length and shapeBiological sciences; Molecular biology; Cell biology; Biomechanics
