Abstract
Cyanobacteria are widely-diverse prokaryotes that colonize our planet. They use solar energy to assimilate huge amounts of atmospheric CO2 and produce a large part of the biomass and oxygen that sustain most life forms. Cyanobacteria are therefore increasingly studied for basic research objectives, as well as for the photosynthetic production of chemicals with industrial interests. One potential approach to reduce the cost of future bioproduction processes is to couple them with wastewater treatment, often polluted with urea, which in any case is cheaper than nitrate. As of yet, however, research has mostly focused on a very small number of model cyanobacteria growing on nitrate. Thus, the genetic inventory of the cyanobacterial phylum is still insufficiently employed to meaningfully select the right host for the right purpose. This review reports what is known about urea transport and catabolism in cyanobacteria, and what can be inferred from the comparative analysis of the publicly available genome sequence of the 308 cyanobacteria. We found that most cyanobacteria mostly harbor the genes encoding the urea catabolytic enzymes urease (ureABCDEFG), but not systematically, together with the urea transport (urtABCDE). These findings are consistent with the capacity of the few tested cyanobacteria that grow on urea as the sole nitrogen source. They also indicate that urease is important for the detoxification of internally generated urea (re-cycling its carbon and nitrogen). In contrast, several cyanobacteria have urtABCDE but not ureABCDEFG, suggesting that urtABCDE could operate in the transport of not only urea but also of other nutrients. Only four cyanobacteria appeared to have the genes encoding the urea carboxylase (uc) and allophanate hydrolase (ah) enzymes that sequentially catabolize urea. Three of these cyanobacteria belongs to the genera Gloeobacter and Gloeomargarita that have likely diverged early from other cyanobacteria, suggesting that the urea carboxylase and allophanate hydrolase enzymes appeared in cyanobacteria before urease.
Highlights
Cyanobacteria are ancient Gram-negative prokaryotes that perform the plant-like oxygen-evolving photosynthesis, which are regarded as the producers of our oxygenic atmosphere (Schopf, 2011), and the ancestor of plant chloroplasts (Archibald, 2009)
This review summarizes what is known about urea transport and catabolism in cyanobacteria, and what can be inferred from the comparative analysis of the publicly available genome sequence of 308 cyanobacteria
We report what is known about urea transport and catabolism in cyanobacteria, and what can be inferred from the comparative analysis of the publicly available genome sequence of 308 cyanobacteria
Summary
Cyanobacteria are ancient Gram-negative prokaryotes that perform the plant-like oxygen-evolving photosynthesis (here we consider the cyanobacterial phylum as consisting only of oxygenic phototrophs; Soo et al, 2017), which are regarded as the producers of our oxygenic atmosphere (Schopf, 2011), and the ancestor of plant chloroplasts (Archibald, 2009). Cyanobacterial Urea Transport and Catabolism waters (fresh, brackish and marine) soils and rocks of our planet, cyanobacteria have evolved as morphologically and metabolically widely-diverse microorganisms that are of high interest for basic and applied research, for a review see Cassier-Chauvat and Chauvat (2018). Attesting to their wide diversity, their genomes are widely diverse in size (and GC content, ranging from 30 to 60%), probably as the result of gain-and-loss of genes transferred by plasmids, insertion sequences and/or phages. Far research has mostly focused on a few model strains with well-established genetics and cyanobacterial diversity which has been insufficiently explored
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