Optimal energy and redox metabolism in the cyanobacterium Synechocystis sp. PCC 6803 (original) (raw)

2022, bioRxiv (Cold Spring Harbor Laboratory)

Cyanobacteria represent an attractive platform for the sustainable production of chemicals and fuels. However, the obtained rates, yields, and titers are below those required for commercial application. Carbon metabolism alone cannot achieve maximal accumulation of end-products, since an efficient production of target molecules entails energy and redox balance, in addition to carbon flow. The interplay between cofactor regeneration and heterologous metabolite overproduction in cyanobacteria is not fully explored. Here, we applied stoichiometric metabolic modelling of the cyanobacterium Synechocystis sp. PCC 6803, in order to investigate the optimality of energy and redox metabolism, while overproducing bio-alkenes-isobutene, isoprene, ethylene and 1-undecene. Our network-wide analysis indicates that the rate of NADP+ reduction, rather than ATP synthesis, controls ATP/NADPH ratio, and thereby chemical production. The simulation implies that energy and redox balance necessitates gluconeogenesis, and that acetate metabolism via phosphoketolase serves as an efficient carbon-and energy-recycling pathway. Furthermore, we show that an auxiliary pathway, composed of serine, one-carbon and glycine metabolism, supports cellular redox homeostasis and ATP cycling, and that the Synechocystis metabolism is controlled by few key reactions carrying a high flux. The study also revealed non-intuitive metabolic pathways to enhance isoprene, ethylene and 1-undecene production. We conclude that metabolism of ATP and NAD(P)H is entwined with carbon and nitrogen metabolism, and cannot be assessed in isolation. We envision that the presented here in-depth metabolic analysis will guide the a priori design of Synechocystis as a host strain for an efficient manufacturing of target products.