Bis-(3’-5’)-cyclic dimeric guanosine monophosphate (c-di-GMP) plays a crucial role in bacterial signalling pathways, allowing bacterial cells to respond to various environmental stimuli. The prevalence of c-di-GMP and its potential applications underscore the necessity for developing tools and methods to regulate intracellular c-di-GMP levels. Optogenetic control of c-di-GMP dynamics is particularly attractive because it enables tuneable and spatiotemporal regulation of c-di-GMP metabolism. The development of sensitive optogenetic control systems requires highly active, light-responsive c-di-GMP synthases. Here we report an engineered, highly active photosensitive c-di-GMP synthase, BphS-13. This engineered c-di-GMP synthase was developed from a near-infrared (NIR) light-activable bacteriophytochrome c-di-GMP synthase, BphS, using a three-step directed evolution process that included error-prone PCR, in vitro homologous recombination, and site-directed mutagenesis. After two rounds of this directed evolution strategy, we generated a BphS variant with 13 mutations, referred to as BphS-13. The diguanylate cyclase (DGC) activity of BphS-13 was approximately 13 times higher than that of the original BphS, and it exhibited tightly regulated DGC activity in response to NIR light with minimal leakage in the dark. We then demonstrated the effectiveness of BphS-13 in controlling biofilm dynamics. Overall, this study highlights BphS-13 as a highly active and photosensitive tool for optogenetic applications in biotechnology and suggests its potential for precise control of gene expression, particularly given the lack of native c-di-GMP metabolism in mammalian cells.
