Julie Michaud

infections.

Chondroitin synthase KfoC is a bifunctional enzyme which polymerizes the capsular chondroitin backbone of Escherichia coli K4, composed of repeated β3N-acetylgalactosamine (GalNAc)-β4-glucuronic acid (GlcA) units. Sugar donors UDP-GalNAc and UDP-GlcA are the natural precursors of bacterial chondroitin synthesis. We have expressed KfoC in a recombinant strain of Escherichia coli deprived of 4-epimerase activity, thus incapable of supplying UDP-GalNAc in the bacterial cytoplasm. The strain was also co-expressing mammal galactose β-glucuronyltransferase, providing glucuronyl-lactose from exogenously added lactose, serving as a primer of polymerization. We show by the mean of NMR analyses that in those conditions, KfoC incorporates galactose, forming a chondroitin-like polymer composed of the repeated β3-galactose (Gal)-β4-glucuronic acid units. We also show that when UDP-GlcNAc 4-epimerase KfoA, encoded by the K4-operon, was co-expressed and produced UDP-GalNAc, a small proportion of galactose was still incorporated into the growing chain of chondroitin.

Abstract Soluble fragments of peptidoglycan called muropeptides are released from the cell wall of bacteria as part of their metabolism or as a result of biological stresses. These compounds trigger immune responses in mammals and plants. In bacteria, they play a major role in the induction of antibiotic resistance. The development of efficient methods to produce muropeptides is, therefore, desirable both to address their mechanism of action and to design new antibacterial and immunostimulant agents. Herein, we engineered the peptidoglycan recycling pathway of Escherichia coli to produce N ‐acetyl‐β‐D‐glucosaminyl‐(1→4)‐1,6‐anhydro‐ N ‐acetyl‐β‐D‐muramic acid (GlcNAc‐anhMurNAc), a common precursor of Gram‐negative and Gram‐positive muropeptides. Inactivation of the hexosaminidase nagZ gene allowed the efficient production of this key disaccharide, providing access to Gram‐positive muropeptides through subsequent chemical peptide conjugation. E. coli strains deficient in both NagZ hexosaminidase and amidase activities further enabled the in vivo production of Gram‐negative muropeptides containing meso ‐diaminopimelic acid, a rarely available amino acid.

ABSTRACT Many proteobacteria, such as Escherichia coli , contain two main types of quinones, benzoquinones represented by ubiquinone (UQ) and naphthoquinones such as menaquinone (MK) and dimethyl-menaquinone (DMK). MK and DMK function predominantly in anaerobic respiratory chains, whereas UQ is the major electron carrier used for reduction of dioxygen. However, this division of labor is probably not so stric. Indeed, a pathway that produces UQ under anaerobic conditions in an UbiU-, UbiV- and UbiT-dependent manner has been recently discovered in E. coli while its physiological relevance is not yet understood because of the presence of MK and DMK in this bacterium. In the present study, we established that UQ 9 is the single quinone of P. aeruginosa and that is required for growth under anaerobic respiration (denitrification). We demonstrated that ORFs PA3911, PA3912 and PA3913 , which are homologues to the E. coli ubiT, ubiV and ubiU genes, respectively, were essential for UQ 9 biosynthesis and thus for denitrification in P. aeruginosa . These three genes were hereafter called ubiT Pa , ubiV Pa and ubiU Pa . We showed that UbiV Pa accommodates a [4Fe-4S] cluster. Moreover, we demonstrated that UbiU Pa and UbiT Pa were able to bind UQ and that the isoprenoid tail of UQ was the structural determinant for the recognition by these Ubi proteins. Since the denitrification metabolism of P. aeruginosa is believed to be important for pathogenicity in cystic fibrosis patients, our results highlight the O 2 -independent UQ biosynthesis pathway as a new possible target to develop innovative antibiotics.

Abstract Isoprenoid quinones represent a class of redox lipids involved in many critical cellular functions, including ATP synthesis through electron transport chains. They thus occupy a pivotal role in the bioenergetics of all three domains of life. The diversity of quinone types observed across microbial taxa has long supported their use as chemotaxonomic markers in microbial systematics. More recently, variations in quinone repertoires have been linked to metabolic adaptations and a novel quinone was discovered. Despite a revived interest in the role of quinones, a unified perspective on the distribution of quinones in Bacteria is currently lacking. In this study, quinone biosynthetic pathways were systematically annotated in 26,264 high quality genomes of bacterial species, and specific information on quinones produced by over 6,000 bacterial species was extracted by text mining the abstracts of thousands of articles. The results were mapped onto a phylogenetic tree, providing the most comprehensive overview of quinone distribution in Bacteria to date. This enabled us to highlight the surprisingly dynamic evolutionary history of the two menaquinone-producing pathways. Moreover, the identification and experimental validation of a deeply branching ubiquinone pathway in Desulfobacterota represents the first occurrence of such a pathway outside the Pseudomonadota and provides insights into the nature of the ancestral UQ pathway. The updated compendium of bacterial quinones is a valuable resource to facilitate the prediction of quinone structural features from genomic data, to establish correlations between quinone structures and cellular traits, and to explore the evolution of quinone repertoires in connection with the diversification of microbial metabolisms.