Abstract
Cyanobacteria perform plant-like oxygenic photosynthesis to convert inorganic carbon into organic compounds and can also use internal carbohydrate reserves under specific conditions. A mutant collection with defects in different routes for sugar catabolism was studied to analyze which of them is preferentially used to degrade glycogen reserves in light-exposed cells of Synechocystis sp. PCC 6803 shifted from high to low CO2 conditions. Mutants defective in the glycolytic Embden–Meyerhof–Parnas pathway or in the oxidative pentose-phosphate (OPP) pathway showed glycogen levels similar to wild type under high CO2 (HC) conditions and were able to degrade it similarly after shifts to low CO2 (LC) conditions. In contrast, the mutant Δeda, which is defective in the glycolytic Entner-Doudoroff (ED) pathway, accumulated elevated glycogen levels under HC that were more slowly consumed during the LC shift. In consequence, the mutant Δeda showed a lowered ability to respond to the inorganic carbon shifts, displayed a pronounced lack in the reactivation of growth when brought back to HC, and differed significantly in its metabolite composition. Particularly, Δeda accumulated enhanced levels of proline, which is a well-known metabolite to maintain redox balances via NADPH levels in many organisms under stress conditions. We suggest that deletion of eda might promote the utilization of the OPP shunt that dramatically enhance NADPH levels. Collectively, the results point at a major regulatory contribution of the ED pathway for the mobilization of glycogen reserves during rapid acclimation to fluctuating CO2 conditions.
Highlights
Cyanobacteria evolved oxygenic photosynthesis approximately 2.7 billion years ago (Hohmann-Marriott and Blankenship, 2011)
To analyze which glucose catabolic route is mainly responsible for the mobilization of glycogen reserves during high CO2 (HC) to low CO2 (LC) shifts, cells of the Synechocystis wild type (WT) and a set of mutants defective in specific key enzymes of the oxidative pentose-phosphate (OPP), the glycolytic EMP or ED pathways were compared under different CO2 availability
At different time points samples were taken for glycogen and metabolome analysis, while the growth of the cultures was monitored via measurements of optical densities at 750 nm (OD750)
Summary
Cyanobacteria evolved oxygenic photosynthesis approximately 2.7 billion years ago (Hohmann-Marriott and Blankenship, 2011) By this process, they can efficiently convert inorganic carbon (Ci), either as CO2 or bicarbonate into organic material at the expense of light energy. The CalvinBenson-Bassham (CBB) cycle is the main Ci incorporating route with ribulose 1,5-bisphosphate carboxylase/oxygenase (RubisCO) as key enzyme, which incorporates either CO2 into ribulose 1,5-bisphosphate (RuBP) leading to two molecules 3-phosphoglycerate (3PGA) or O2 into RuBP resulting in the appearance of 3PGA and 2-phosphoglycolate (2PG) The latter intermediate turned out to be toxic for the CBB cycle and associated metabolic pathways (e.g., Flügel et al, 2017) and must be efficiently recycled via the photorespiratory 2PG metabolism, which likely evolved in parallel with oxygenic photosynthesis in ancient cyanobacteria (Eisenhut et al, 2008a). PCC 6803 (hereafter Synechocystis) is mainly regulated at the transcriptional level due to the action of several regulatory proteins such as NdhR, CmpR, CyAbrB2, and SbtB (reviewed in Hagemann et al, 2021)
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