Nina O. L. Seto

The structural basis for specificity in human ABO(H) blood group biosynthesis

The human ABO(H) blood group antigens are produced by specific glycosyltransferase enzymes. An N-acetylgalactosaminyltransferase (GTA) uses a UDP-GalNAc donor to convert the H-antigen acceptor to the A antigen, whereas a galactosyltransferase (GTB) uses a UDP-galactose donor to convert the H-antigen acceptor to the B antigen. GTA and GTB differ only in the identity of four critical amino acid residues. Crystal structures at 1.8–1.32 Å resolution of the GTA and GTB enzymes both free and in complex with disaccharide H-antigen acceptor and UDP reveal the basis for donor and acceptor specificity and show that only two of the critical amino acid residues are positioned to contact donor or acceptor substrates. Given the need for stringent stereo- and regioselectivity in this biosynthesis, these structures further demonstrate that the ability of the two enzymes to distinguish between the A and B donors is largely determined by a single amino acid residue.

Germline antibody recognition of distinct carbohydrate epitopes.

High-resolution structures reveal how a germline antibody can recognize a range of clinically relevant carbohydrate epitopes. The germline response to a carbohydrate immunogen can be critical to survivability, with selection for antibody gene segments that both confer protection against common pathogens and retain the flexibility to adapt to new disease organisms. We show here that antibody S25-2 binds several distinct inner-core epitopes of bacterial lipopolysaccharides (LPSs) by linking an inherited monosaccharide residue binding site with a subset of complementarity-determining regions (CDRs) of limited flexibility positioned to recognize the remainder of an array of different epitopes. This strategy allows germline antibodies to adapt to different epitopes while minimizing entropic penalties associated with the immobilization of labile CDRs upon binding of antigen, and provides insight into the link between the genetic origin of individual CDRs and their respective roles in antigen recognition.

Sequential Interchange of Four Amino Acids from Blood Group B to Blood Group A Glycosyltransferase Boosts Catalytic Activity and Progressively Modifies Substrate Recognition in Human Recombinant Enzymes

The human blood group A and B glycosyltransferase enzymes are highly homologous and the alteration of four critical amino acid residues (Arg-176 → Gly, Gly-235 → Ser, Leu-266 → Met, and Gly-268 → Ala) is sufficient to change the enzyme specificity from a blood group A to a blood group B glycosyltransferase. To carry out a systematic study, a synthetic gene strategy was employed to obtain their genes and to allow facile mutagenesis. Soluble forms of a recombinant glycosyltransferase A and a set of hybrid glycosyltransferase A and B mutants were expressed in Escherichia coli in high yields, which allowed them to be kinetically characterized extensively for the first time. A functional hybrid A/B mutant enzyme was able to catalyze both A and B reactions, with thek cat being 5-fold higher for the A donor. Surprisingly, even a single amino acid replacement in glycosyltransferase A with the corresponding residue from glycosyltransferase B (Arg-176 → Gly) produced enzymes with glycosyltransferase A activity only, but with very large (11-fold) increases in the k cat and increased specificity. The increases observed in k cat are among the largest obtained for a single amino acid change and are advantageous for the preparative scale synthesis of blood group antigens.

A Single Point Mutation Reverses the Donor Specificity of Human Blood Group B-synthesizing Galactosyltransferase

Blood group A and B antigens are carbohydrate structures that are synthesized by glycosyltransferase enzymes. The final step in B antigen synthesis is carried out by an α1–3 galactosyltransferase (GTB) that transfers galactose from UDP-Gal to type 1 or type 2, αFuc1→2βGal-R (H)-terminating acceptors. Similarly the A antigen is produced by an α1–3N-acetylgalactosaminyltransferase that transfersN-acetylgalactosamine from UDP-GalNAc to H-acceptors. Human α1–3 N-acetylgalactosaminyltransferase and GTB are highly homologous enzymes differing in only four of 354 amino acids (R176G, G235S, L266M, and G268A). Single crystal x-ray diffraction studies have shown that the latter two of these amino acids are responsible for the difference in donor specificity, while the other residues have roles in acceptor binding and turnover. Recently a novelcis-AB allele was discovered that produced A and B cell surface structures. It had codons corresponding to GTB with a single point mutation that replaced the conserved amino acid proline 234 with serine. Active enzyme expressed from a synthetic gene corresponding to GTB with a P234S mutation shows a dramatic and complete reversal of donor specificity. Although this enzyme contains all four “critical” amino acids associated with the production of blood group B antigen, it preferentially utilizes the blood group A donor UDP-GalNAc and shows only marginal transfer of UDP-Gal. The crystal structure of the mutant reveals the basis for the shift in donor specificity.

ABO(H) blood group A and B glycosyltransferases recognize substrate via specific conformational changes.

The final step in the enzymatic synthesis of the ABO(H) blood group A and B antigens is catalyzed by two closely related glycosyltransferases, an α-(1→3)-N-acetylgalactosaminyltransferase (GTA) and an α-(1→3)-galactosyltransferase (GTB). Of their 354 amino acid residues, GTA and GTB differ by only four “critical” residues. High resolution structures for GTB and the GTA/GTB chimeric enzymes GTB/G176R and GTB/G176R/G235S bound to a panel of donor and acceptor analog substrates reveal “open,” “semi-closed,” and “closed” conformations as the enzymes go from the unliganded to the liganded states. In the open form the internal polypeptide loop (amino acid residues 177-195) adjacent to the active site in the unliganded or H antigen-bound enzymes is composed of two α-helices spanning Arg180-Met186 and Arg188-Asp194, respectively. The semi-closed and closed forms of the enzymes are generated by binding of UDP or of UDP and H antigen analogs, respectively, and show that these helices merge to form a single distorted helical structure with alternating α-310-α character that partially occludes the active site. The closed form is distinguished from the semi-closed form by the ordering of the final nine C-terminal residues through the formation of hydrogen bonds to both UDP and H antigen analogs. The semi-closed forms for various mutants generally show significantly more disorder than the open forms, whereas the closed forms display little or no disorder depending strongly on the identity of residue 176. Finally, the use of synthetic analogs reveals how H antigen acceptor binding can be critical in stabilizing the closed conformation. These structures demonstrate a delicately balanced substrate recognition mechanism and give insight on critical aspects of donor and acceptor specificity, on the order of substrate binding, and on the requirements for catalysis.

Characterization of cysteine residues and disulfide bonds in proteins by liquid chromatography/electrospray ionization tandem mass spectrometry

Cysteine residues and disulfide bonds are important for protein structure and function. We have developed a simple and sensitive method for determining the presence of free cysteine (Cys) residues and disulfide bonded Cys residues in proteins (<100 pmol) by liquid chromatography/electrospray ionization tandem mass spectrometry (LC/ESI-MS/MS) in combination with protein database searching using the program Sequest. Free Cys residues in a protein were labeled with PEO-maleimide biotin immediately followed by denaturation with 8 M urea. Subsequently, the protein was digested with trypsin or chymotrypsin and the resulting products were analyzed by capillary LC/ESI-MS/MS for peptides containing modified Cys and/or disulfide bonded Cys residues. Although the MS method for identifying disulfide bonds has been routinely employed, methods to prevent thiol-disulfide exchange have not been well documented. Our protocol was found to minimize the occurrence of the thiol-disulfide exchange reaction. The method was validated using well-characterized proteins such as aldolase, ovalbumin, and beta-lactoglobulin A. We also applied this method to characterize Cys residues and disulfide bonds of beta 1,4-galactosyltransferase (five Cys), and human blood group A and B glycosyltransferases (four Cys). Our results demonstrate that beta 1,4-galactosyltransferase contains one free Cys residue and two disulfide bonds, which is in contrast to work previously reported using chemical methods for the characterization of free Cys residues, but is consistent with recently published results from x-ray crystallography. In contrast to the results obtained for beta 1,4-galactosyltransferase, none of the Cys residues in A and B glycosyltransferases were found to be involved in disulfide bonds.

Differential Recognition of the Type I and II H Antigen Acceptors by the Human ABO(H) Blood Group A and B Glycosyltransferases.

The human ABO(H) blood group A and B antigens are generated by the homologous glycosyltransferases A (GTA) and B (GTB), which add the monosaccharides GalNAc and Gal, respectively, to the cell-surface H antigens. In the first comprehensive structural study of the recognition by a glycosyltransferase of a panel of substrates corresponding to acceptor fragments, 14 high resolution crystal structures of GTA and GTB have been determined in the presence of oligosaccharides corresponding to different segments of the type I (α-l-Fucp-(1→2)-β-d-Galp-(1→3)-β-d-GlcNAcp-OR, where R is a glycoprotein or glycolipid in natural acceptors) and type II (α-l-Fucp-(1→2)-β-d-Galp-(1→4)-β-d-GlcNAcp-OR) H antigen trisaccharides. GTA and GTB differ in only four “critical” amino acid residues (Arg/Gly-176, Gly/Ser-235, Leu/Met-266, and Gly/Ala-268). As these enzymes both utilize the H antigen acceptors, the four critical residues had been thought to be involved strictly in donor recognition; however, we now report that acceptor binding and subsequent transfer are significantly influenced by two of these residues: Gly/Ser-235 and Leu/Met-266. Furthermore, these structures show that acceptor recognition is dominated by the central Gal residue despite the fact that the l-Fuc residue is required for efficient catalysis and give direct insight into the design of model inhibitors for GTA and GTB.

Enzymatic synthesis of blood group A and B trisaccharide analogues.

Glycosyltransferases A and B utilize the donor substrates UDP-GalNAc and UDP-Gal, respectively, in the biosynthesis of the human blood group A and B trisaccharide antigens from the O(H)-acceptor substrates. These enzymes were cloned as synthetic genes and expressed in Escherichia coli, thereby generating large quantities of enzyme for donor specificity evaluations. The amino acid sequence of glycosyltransferase A only differs from glycosyltransferase B by four amino acids, and alteration of these four amino acid residues (Arg-176-->Gly, Gly-235-->Ser, Leu-266-->Met and Gly-268-->Ala) can change the donor substrate specificity from UDP-GalNAc to UDP-Gal. Crossovers in donor substrate specificity have been observed, i.e., the A transferase can utilize UDP-Gal and B transferase can utilize UDP-GalNAc donor substrates. We now report a unique donor specificity for each enzyme type. Only A transferase can utilize UDP-GlcNAc donor substrates synthesizing the blood group A trisaccharide analog alpha-D-Glcp-NAc-(1-->3)-[alpha-L-Fucp-(1-->2)]-beta-D-Galp-O-(CH2 )7CH3 (4). Recombinant blood group B was shown to use UDP-Glc donor substrates synthesizing blood group B trisaccharide analog alpha-D-Glcp-(1-->3)-[alpha-L-Fucp-(1-->2)]-beta-D-Galp-O-(CH2) 7CH3 (5). In addition, a true hybrid enzyme was constructed (Gly-235-->Ser, Leu-266-->Met) that could utilize both UDP-GlcNAc and UDP-Glc. Although the rate of transfer with UDP-GlcNAc by the A enzyme was 0.4% that of UDP-GalNAc and the rate of transfer with UDP-Glc by the B enzyme was 0.01% that of UDP-Gal, these cloned enzymes could be used for the enzymatic synthesis of blood group A and B trisaccharide analogs 4 and 5.

Synthesis of the acceptor analog alphaFuc(1-->2)alphaGal-O(CH2)7 CH3: a probe for the kinetic mechanism of recombinant human blood group B glycosyltransferase.

We report the chemical synthesis of αFuc(1→2)αGal-O(CH2)7CH3 (1) an analog of the natural blood group (O)H disaccharide αFuc(1→2)βGal-OR. Compound 1 was a good substrate for recombinant blood group B glycosyltransferase (GTB) and was used as a precursor for the enzymatic synthesis of the blood group B analog αGal(→3)[αFuc(1→2)]αGal-O(CH2)7CH3 (2). To probe the mechanism of the GTB reaction, kinetic evaluations were carried out employing compound 1 or the natural acceptor disaccharide αFuc(1→2)βGal-O(CH2)7CH3 (3) with UDP-Gal and UDP-GalNAc donors. Comparisons of the kinetic constants for alternative donor and acceptor pairs suggest that the GTB mechanism is Theorell-Chance where donor binding precedes acceptor binding. GTB operates with retention of configuration at the anomeric center of the donor. Retaining reactions are thought to occur via a double-displacement mechanism with formation of a glycosyl-enzyme intermediate consistent with the proposed Theorell-Chance mechanism.

Natural and recombinant A and B gene encoded glycosyltransferases

. The human blood group A and B synthesizing enzymes are glycosyltransferases that catalyse the transfer of a monosaccharide residue from UDP‐GalNAc and UDP‐Gal donors, respectively, to αFuc1,2‐Gal terminated blood group H acceptors. Extensive investigations of their substrate specificity and physical properties have been carried out since their initial discovery. These studies demonstrated a rigid specificity for the acceptor structure, crossover in donor specificity and immunological similarity along with chromatographic differences. Cloning of the enzymes has shown that they are highly homologous, differing in only four of their 354 amino acids. Changing the residues Arg176→Gly, Gly235→Ser, Leu266→Met and Gly 268→Ala converts the enzyme specificity from blood group A to blood group B glycosyltransferase. Structure function investigations have been carried out by systematic interchange and modification of these four critical amino acids. These studies have shown that donor specificity is attributed to the last two amino acids. Mutants have also been produced with greatly enhanced turnover rates as well as hybrid A/B enzymes that catalyse both reactions efficiently.