Characterization of a Metal-independent CAZy Family 6 Glycosyltransferase from Bacteroides ovatus

The myriad functions of complex carbohydrates include modulating interactions between bacteria and their eukaryotic hosts. In humans and other vertebrates, variations in the activity of glycosyltransferases of CAZy family 6 generate antigenic variation between individuals and species that facilitates resistance to pathogens. The well characterized vertebrate glycosyltransferases of this family are multidomain membrane proteins with C-terminal catalytic domains. Genes for proteins homologous with their catalytic domains are found in at least nine species of anaerobic commensal bacteria and a cyanophage. Although the bacterial proteins are strikingly similar in sequence to the catalytic domains of their eukaryotic relatives, a metal-binding Asp-X-Asp sequence, present in a wide array of metal ion-dependent glycosyltransferases, is replaced by Asn-X-Asn. We have cloned and expressed one of these proteins from Bacteroides ovatus, a bacterium that is linked to inflammatory bowel disease. Functional characterization shows it to be a metal-independent glycosyltransferase with a 200-fold preference for UDP-GalNAc as substrate relative to UDP-Gal. It efficiently catalyzes the synthesis of oligosaccharides similar to human blood group A and may participate in the synthesis of the bacterial O-antigen. The kinetics for GalNAc transfer to 2′-fucosyl lactose are characteristic of a sequential mechanism, as observed previously for this family. Mutational studies indicate that despite the lack of a metal cofactor, there are pronounced similarities in structure-function relationships between the bacterial and vertebrate family 6 glycosyltransferases. These two groups appear to provide an example of horizontal gene transfer involving vertebrates and prokaryotes.The structures of complex glycans are determined by the specificities of the glycosyltransferases (GTs)² that catalyze their biosynthesis. GTs fall into two groups that differ in mechanism, based on whether the anomeric configuration of the donor substrate (α for most UDP-sugars) is retained or inverted in the product (1–3). They are classified into 90 different families in the CAZy data base based on sequence similarities (4, 5), but the majority of those that have been structurally characterized fall into one of two fold types, designated GT-A and GT-B (2). The retaining GTs of CAZy family 6 (GT6) have a GT-A fold and catalyze the transfer of either galactose or GalNAc into an α-linkage with the 3-OH group of β-linked galactose or GalNAc. GT6 includes the histo-blood group A and B GTs (GTA and GTB), the α-galactosyltransferase (α3GT) that catalyzes the synthesis of the xenoantigen or α-gal epitope, Forssman glycolipid synthase, isogloboside 3 synthase, and their homologues from other vertebrates (6). GT6 enzymes from vertebrates are type-2 membrane proteins with N-terminal cytosolic domains, a transmembrane helix, a spacer, and a C-terminal catalytic domain (6). Crystallographic studies of recombinant catalytic domains of GTA, GTB, and α3GT have provided detailed information about their interactions with substrates, metal cofactor, and inhibitors (7–9). Most GT-A fold GTs, including those in the GT6 family, require divalent metal ions, such as Mn²⁺, for catalytic activity; their metal dependence is linked to a shared DXD sequence motif. Residues of this motif interact with the metal ion and both the ribose and phosphates of the donor substrate to produce an appropriate substrate orientation and conformation for catalysis and to stabilize the UDP leaving group (3, 7–10).Mammalian members of GT6 are responsible for variations in glycan structures between different species and individuals as the result of selective enzyme inactivation in certain species (α3GT, Forssman glycolipid synthase, and isogloboside 3 synthase) or the inheritance of multiple alleles at one locus that encode enzymes with different substrate specificity (GTA and GTB) or are inactive (11–14). The presence of circulating antibodies against glycan structures that are subject to interspecies and individual variability has been linked to resistance to pathogens that also carry the glycans; these antibodies are thought to arise from exposure to potential pathogens, including enveloped viruses and bacteria that carry structurally similar glycans (11).In addition to the well characterized enzymes discussed previously, atypical members of the GT6 family have been identified in mammals that have sequence changes in highly conserved regions of the active site, including the DXD motif (6). However, no glycosyltransferase activity was detected in recombinant forms of two of these, and their functions are unclear (6). Although GT6 members are widely distributed among vertebrates, no homologues have been found in other eukaryotes (6). However, GT6 members have been identified in several bacterial species (15–17). GT6 enzymes from Escherichia coli O86, and Helicobacter mustelae that appear to function in the biosynthesis of the lipopolysaccharide O-antigen have been cloned and expressed by Wang and co-workers (16, 17) and found to have specificities similar to those of human GTB and GTA, respectively. These enzymes have been applied in the enzymatic synthesis of oligosaccharides. Other homologues are encoded by Hemophilus somnus, Psychroacter sp., PRwf-1 (15), Francisella philomiragia, and three Bacteroides species, Bacteroides ovatus, Bacteroides caccae, and Bacteroides stercoris, as well as a cyanophage, PSSM-2 (15). Genes for other homologues from unidentified species are present in the marine metagenome (18, 19) and human gut metagenome (20, 21). The phage and bacterial enzymes are substantially truncated at the N terminus relative to the catalytic domains of vertebrate GT6 representatives and are smaller than the reported minimal functional unit of a primate α3GT (22). When bacterial and vertebrate GT6 amino acid sequences are aligned (Fig. 1 and supplemental Figs. S1 and S2), it can be seen that the metal-binding DXD of the eukaryotic GTs is replaced by NXN (where X is Ala, Gly, or Ser) in the bacterial homologues. The cyanophage GT6 member and related proteins in the marine metagenome, however, retain the DXD motif. This conspicuous difference in the bacterial proteins is particularly interesting, since, in the mammalian enzymes, the aspartates of the DXD and adjacent residues are crucial for catalytic activity (10, 23).Open in a separate windowFIGURE 1.An alignment of selected bacterial, cyanophage and mammalian GT6 amino acid sequences. Abbreviations and Interpro sequence IDs (in parentheses) are as follows. HuA, human histo-blood group A synthase (A1EAJ6); Bova, bovine α1,3-galactosyltransferase ({"type":"entrez-protein","attrs":{"text":"P14769","term_id":"120970","term_text":"P14769"}}P14769); PSSM2, cyanophage PSSM-2 ({"type":"entrez-protein","attrs":{"text":"Q58M87","term_id":"75096044","term_text":"Q58M87"}}Q58M87); Bs, B. stercoris (B0NSM3); Bo1, B. ovatus GT1 (A7LVT2); Bo2, B. ovatus GT2 (A7M0P3); Bc, B. caccae (A5ZC71). The boxed regions in the alignment identify regions that have been shown to be involved in interactions with substrates and cofactor and in catalysis in bovine α1,3-galactosyltransferase and histo-blood group A and B enzymes. These are labeled (below) as follows. A, interactions with uracil; B, interactions with the galactose moiety of UDP-Gal; C, interactions with Mn²⁺, phosphates, and galactose; D, interactions with acceptor substrate; E, interactions with Gal or GalNAc of donor substrate; F, interactions with monosaccharide of donor substrate and acceptor and catalysis; The arrow (above) denotes the intron/exon boundary in vertebrate GT6s, and the asterisks indicate the residues in BoGT6a that were subjected to mutagenesis.B. ovatus is a Gram-negative commensal bacterium that inhabits the distal mammalian gut and has been implicated in the pathology of inflammatory bowel disease in humans (24). The B. ovatus genome contains two genes that encode GT6 representatives (Fig. 1). We selected one of these for initial investigation, and designate it BoGT6a (family 6 glycosyltransferase 1 of Bacteroides). The gene for this protein was amplified by PCR and cloned and expressed in His-tagged form in E. coli BL21(DE3). Assays with a variety of substrates show that its substrate specificity is similar to that of human GTA. Previous studies of the activities of bacterial enzymes were conducted in the presence of Mn²⁺ (16, 17), but we find that the B. ovatus enzyme does not require divalent metal ions for activity and is fully active in EDTA. Despite this striking difference, BoGT6a is similar to its metal-dependent relatives in catalytic properties; also, the effects of amino acid substitutions for residues corresponding to several that act in substrate binding and catalysis in vertebrate GT6 glycosyltransferases suggest that they have similar structure-function relationships. These results indicate that the metal cofactor is not a conserved feature in the GT6 family. They also raise questions about the catalytic mechanism of prokaryotic GT6 members and the evolutionary relationship between bacterial, phage, and vertebrate enzymes.