Co-option of an ancestral peptidase controls developmental patterning in multicellular cyanobacteria.
Xiaomei Xu, Anaïs Scholivet, Stéphanie Champ, Matthieu Bergé, Zulihumaer Yeerkenjiang, Jonas Desjardins, Yann Denis, Badreddine Douzi, Deborah Byrne, Emmanuel Talla, Amel Latifi
Abstract
Open AccessSpatial patterning in multicellular organisms is commonly explained by Turing-type reaction-diffusion systems, but the maturation of diffusible inhibitors remains poorly understood. In the cyanobacterium Nostoc PCC 7120, nitrogen deprivation triggers a pattern of nitrogen-fixing heterocysts regulated by HetR and inhibitory peptides, including PatX. We uncover the post-translational mechanism controlling PatX maturation, demonstrating its export and subsequent processing by the peptidase PatP. We identify HRGTGR, a PatX-derived hexapeptide, as the direct inhibitor of HetR, linking maturation to suppressed differentiation. Genomic analyses reveal that patP is ancient and conserved across all cyanobacteria, predating the patX-hetR module found only in filamentous clades. We therefore propose that this ancient peptidase was co-opted to process a new ligand, transforming a proteolytic event into a spatial patterning mechanism. This repurposing parallels eukaryotic signaling, underscoring a universal principle in the emergence of multicellular organization and providing a model for how complex patterns evolve from "simple" components.