HIGH CO ₂ LEVELS OVERCOME THE NIGHTTIME LETHALITY OF CIRCADIAN MUTANTS IN CYANOBACTERIA

Cyanobacteria have adapted to daily fluctuations in light intensity through a circadian clock that aligns their physiology and metabolism to the external daytime. In the model cyanobacterium Synechococcus elongatus PCC 7942, the rhythm generated by a molecular pacemaker is converted into a global transcriptional oscillation by the central regulator RpaA. Mutants in RpaA and other components have been instrumental in elucidating the clock’s molecular architecture and physiological role. Extensive evidence suggests that one of the central functions of circadian regulation is to prevent the accumulation of reactive oxygen species (ROS) during nighttime. However, circadian mutants are unable to grow under natural day/night cycles and require constant illumination, hindering our ability to study the clock function during the night, a phase where circadian regulation is critical for redox homeostasis. Here, we show that the darkness lethality phenotype of circadian mutants can be overcome by high CO ₂ levels. When grown under a 3% CO ₂ atmosphere, RpaA-null mutants exhibited growth rates similar to the wt. An analysis of the ROS levels under different CO ₂ and light intensity conditions revealed carbon scarcity to be the most significant contributor to redox stress. Nighttime ROS accumulation can be modulated by CO ₂ abundance, an observation that will allow the characterization of heretofore lethal mutants in circadian regulation. The dispensability of the circadian clock in a high CO ₂ environment suggests that the clock may have evolved as an adaptation to the decrease in atmospheric CO ₂ levels that occurred after the Great Oxygenation Events, in the Paleoproterozoic era.