Identification of essential amino acids in the bacterial alpha -mannosyltransferase aceA.

The alpha-mannosyltransferase AceA from Acetobacter xylinum belongs to the CaZY family 4 of retaining glycosyltransferases. We have identified a series of either highly conserved or invariant residues that are found in all family 4 enzymes as well as other retaining glycosyltransferases. These residues included Glu-287 and Glu-295, which comprise an EX(7)E motif and have been proposed to be involved in catalysis. Alanine replacements of each conserved residue were constructed by site-directed mutagenesis. The mannosyltransferase activity of each mutant was examined by both an in vitro transferase assay using recombinant mutant AceA expressed in Escherichia coli and by an in vivo rescue assay by expressing the mutant AceA in a Xanthomonas campestris gumH(-) strain. We found that only mutants K211A and E287A lost all detectable activity both in vitro and in vivo, whereas E295A retained residual activity in the more sensitive in vivo assay. H127A and S162A each retained reduced but significant activities both in vitro and in vivo. Secondary structure predictions of AceA and subsequent comparison with the crystal structures of the T4 beta-glucosyltransferase and MurG suggest that AceA Lys-211 and Glu-295 are involved in nucleotide sugar donor binding, leaving Glu-287 of the EX(7)E as a potential catalytic residue.

Identification of essential amino acid residues in the Sinorhizobium meliloti glucosyltransferase ExoM.

ExoM is a beta(1-4)-glucosyltransferase involved in the assembly of the repeat unit of the exopolysaccharide succinoglycan from Sinorhizobium meliloti. By comparing the sequence of ExoM to those of other members of the Pfam Glyco Domain 2 family, most notably SpsA (Bacillus subtilis) for whom the three-dimensional structure has been resolved, three potentially important aspartic acid residues of ExoM were identified. Single substitutions of each of the Asp amino acids at positions 44, 96, and 187 with Ala resulted in the loss of mutant recombinant protein activity in vitro as well as the loss of succinoglycan production in an in vivo rescue assay. Mutants harboring Glu instead of Asp-44 or Asp-96 possessed no in vitro activity but could restore succinoglycan production in vivo. However, replacement of Asp-187 with Glu completely inactivated ExoM as judged by both the in vitro and in vivo assays. These results indicate that Asp-44, Asp-96, and Asp-187 are essential for the activity of ExoM. Furthermore, these data are consistent with the functions proposed for each of the analogous aspartic acids of SpsA based on the SpsA-UDP structure, namely, that Asp-44 and Asp-96 are involved in UDP substrate binding and that Asp-187 is the catalytic base in the glycosyltransferase reaction.

Phytanyl-pyrophosphate-linked substrate for a bacterial alpha-mannosyltransferase.

The biochemical characterization of bacterial glycosyltransferases involved in the assembly of cell-wall-associated polysaccharides is often hindered by the lack of the appropriate undecaprenyl-pyrophosphate-linked acceptor substrate. In order to find a suitable synthetic substrate for the alpha1,3-mannosyltransferase AceA from Acetobacter xylinum, phytanyl-pyrophosphate-linked cellobiose was prepared. In the presence of GDP-[14C]mannose and recombinant AceA, the phytanyl-pyrophosphate-linked cellobiose afforded a 14C-labeled trisaccharide that was sensitive to alpha-mannosidase degradation in a fashion analogous to the natural undecaprenyl-pyrophosphate-linked cellobiose substrate. These results suggest that phytanyl-pyrophosphate-linked oligosaccharides may be useful substrates for other important bacterial glycosyltransferases.

Expression and biochemical characterisation of recombinant AceA, a bacterial alpha-mannosyltransferase.

Biosynthesis of repeat-unit polysaccharides and N-linked glycans proceeds by sequential transfer of sugars from the appropriate sugar donor to an activated lipid carrier. The transfer of each sugar is catalysed by a specific glycosyltransferase. The molecular basis of the specificity of sugar addition is not yet well understood, mainly because of the difficulty of isolating these proteins. In this study, the aceA gene product expressed by Acetobacter xylinum, which is involved in the biosynthesis of the exopolysaccharide acetan, was overproduced in Escherichia coli and its function was characterised. The aceA ORF was subcloned into the expression vector pET29 in frame with the S.tag epitope. The recombinant protein was identified, and culture conditions were optimised for production of the soluble protein. The results of test reactions showed that AceA is able to transfer one alpha-mannose residue from GDP-mannose to cellobiose-P-P-lipid to produce alpha-mannose-cellobiose-P-P-lipid. AceA was not able to use free cellobiose as a substrate, indicating that the pyrophosphate-lipid moiety is needed for enzymatic activity.

Expression and study of recombinant ExoM, a beta1-4 glucosyltransferase involved in succinoglycan biosynthesis in Sinorhizobium meliloti.

Here we report on the overexpression and in vitro characterization of a recombinant form of ExoM, a putative beta1-4 glucosyltransferase involved in the assembly of the octasaccharide repeating subunit of succinoglycan from Sinorhizobium meliloti. The open reading frame exoM was isolated by PCR and subcloned into the expression vector pET29b, allowing inducible expression under the control of the T7 promoter. Escherichia coli BL21(DE3)/pLysS containing exoM expressed a novel 38-kDa protein corresponding to ExoM in N-terminal fusion with the S-tag peptide. Cell fractionation studies showed that the protein is expressed in E. coli as a membrane-bound protein in agreement with the presence of a predicted C-terminal transmembrane region. E. coli membrane preparations containing ExoM were shown to be capable of transferring glucose from UDP-glucose to glycolipid extracts from an S. meliloti mutant strain which accumulates the ExoM substrate (Glcbeta1-4Glcbeta1-3Gal-pyrophosphate-polyprenol). Thin-layer chromatography of the glycosidic portion of the ExoM product showed that the oligosaccharide formed comigrates with an authentic standard. The oligosaccharide produced by the recombinant ExoM, but not the starting substrate, was sensitive to cleavage with a specific cellobiohydrolase, consistent with the formation of a beta1-4 glucosidic linkage. No evidence for the transfer of multiple glucose residues to the glycolipid substrate was observed. It was also found that ExoM does not transfer glucose to an acceptor substrate that has been hydrolyzed from the polyprenol anchor. Furthermore, neither glucose, cellobiose, nor the trisaccharide Glcbeta1-4Glcbeta1-3Glc inhibited the transferase activity, suggesting that some feature of the lipid anchor is necessary for activity.

Impaired cutaneous immune responses in Thy-1-deficient mice.

Thy-1 is a cell surface glycoprotein expressed mainly on brain and lymphoid tissue. Although the functions of Thy-1 are incompletely understood, evidence exists that Thy-1 participates in T cell activation. To examine the functional role of Thy-1 in cutaneous immune responses in vivo, Thy-1 gene-targeted mice (Thy-1-/-) and wild-type mice (Thy-1+/+) were immunized with the hapten oxazolone. After challenge with oxazolone, contact hypersensitivity responses in Thy-1-/- mice were reduced by 25% compared with Thy-1+/+ mice. Likewise, irritant dermatitis induced by croton oil was also decreased. In addition, Thy-1-/- mice showed a significantly reduced delayed-type hypersensitivity response after injection of allogeneic spleen cells into the hind footpads of allosensitized animals when compared with Thy-1+/+ mice. Moreover, proliferative responses to immobilized anti-CD3 were decreased in peripheral Thy-1-/- lymphocytes; this decrease was associated with a significantly reduced intracellular Ca2+ influx and protein tyrosine phosphorylation, indicating impairment of early lymphocyte activation. In contrast, the T cell proliferation induced by mitogens was normal, suggesting that Thy-1 expression weakly contributes to TCR-mediated T cell activation. Epidermal Langerhans cells and bone marrow-derived dendritic cells from Thy-1-/- mice exhibited a normal expression of costimulatory surface molecules as well as an unaltered ability to stimulate allogeneic T cells. Taken together, these findings demonstrate that a lack of Thy-1 expression does not generally compromise the immune system; however, Thy-1 expression may be involved in the fine-tuning of T cell-mediated immune responses.

The glycosylation and structure of human serum IgA1, Fab, and Fc regions and the role of N-glycosylation on Fcα receptor interactions.

The human serum immunoglobulins IgG and IgA1 are produced in bone marrow and both interact with specific cellular receptors that mediate biological events. In contrast to IgA1, the glycosylation of IgG has been well characterized, and its interaction with various Fc receptors (Fc Rs) has been well studied. In this paper, we have analyzed the glycosylation of IgA1 and IgA1 Fab and Fc as well as three recombinant IgA1 molecules, including two N-glycosylation mutants. Amino acid sequencing data of the IgA1 Fc O-glycosylated hinge region indicated that O-glycans are located at Thr228, Ser230, and Ser232, while O-glycan sites at Thr225 and Thr236 are partially occupied. Over 90% of the N-glycans in IgA1 were sialylated, in contrast to IgG, where < 10% contain sialic acid. This paper contains the first report of Fab glycosylation in IgA1, and (in contrast to IgG Fab, which contains only N-linked glycans) both N- and O-linked oligosaccharides were identified. Analysis of the N-glycans attached to recombinant IgA1 indicated that the Cα 2 N-glycosylation site contained mostly biantennary glycans, while the tailpiece site, absent in IgG, contained mostly triantennary structures. Further analysis of these data suggested that processing at one Fc N-glycosylation site affects the other. Neutrophil Fcα R binding studies, using recombinant IgA1, indicated that neither the tailpiece region nor the N-glycans in the C alpha 2 domain contribute to IgA1-neutrophil Fcα R binding. This contrasts with IgG, where removal of the Fc N-glycans reduces binding to the Fcγ R. The primary sequence and disulfide bond pattern of IgA1, together with the crystal structures of IgG1 Fc and mouse IgA Fab and the glycan sequencing data, were used to generate a molecular model of IgA1. As a consequence of both the primary sequence and S-S bond pattern, the N-glycans in IgA1 Fc are not confined within the inter-α-chain space. The accessibility of the Cα 2 N-glycans provides an explanation for the increased sialylation and galactosylation of IgA1 Fc over that of IgG Fc N-glycans, which are confined in the space between the two Cγ 2 domains. This also suggests why in contrast to IgG Fc, the IgA1 N-glycans are not undergalactosylated in rheumatoid arthritis.

Effect of serine O-glycosylation on cis-trans proline isomerization.

In order to examine the ability of an O-glycosylated serine residue preceding proline to stabilize a cis amide conformation in a fashion similar to that observed with aromatic amino acid residues, we prepared a series of glycosylated analogs of a small linear peptide which we have previous reported to contain a cis conformation of an amide bond between tyrosine and proline. The glycopeptides were prepared by incorporating glycosylated N alpha- (fluoren-9-yl) methoxycarbonyl (Fmoc) amino acids into a standard solid phase peptide synthesis protocol. The peptides and glycopeptides were analyzed using 2-dimensional NMR spectroscopy. Unlike the case where the residue preceding proline was tyrosine, no signals corresponding to a cis proline conformation were detected in the spectra of the two glycopeptides containing serine O-glycosylated with either beta-linked N-acetyl glucosamine or alpha-linked N-acetyl galactosamine in the position preceding proline.

Peptide anchor residue glycosylation: effect on class I major histocompatibility complex binding and cytotoxic T lymphocyte recognition.

This study extends our previous observation that glycopeptides bind to class I major histocompatibility complex (MHC) molecules and elicit carbohydrate-specific CTL responses. The Sendai virus nucleoprotein wild-type (WT) peptide (FAPGNYPAL) binds H-2Db using the P5-Asn as an anchor. The peptide K2 carrying a P5 serine substitution did not bind Db. Surprisingly, glycosylation of the serine (K2-O-GlcNAc) with N-acetylglucosamine (GlcNAc), a novel cytosolic O-linked glycosylation, partially restored peptide binding to Db. We argue that the N-acetyl group of GlcNAc may fulfil the hydrogen bonding requirements of the Db pocket which normally accomodates P5-Asn. Glycosylation of the P5-Asn residue itself abrogated binding similar to K2, probably for steric reasons. The peptide K2-O-GlcNAc readily elicited Db-restricted cytotoxic T lymphocytes (CTL), which did not cross-react with K2 or WT. However, all Db-restricted CTL raised against K2-O-GlcNAc cross-reacted strongly with another glycopeptide, K3-O-GlcNAc, where the GlcNAc substitution is on a neighboring P4-Ser. Furthermore, Db-restricted CTL clones raised against K2-O-GlcNAc or K3-O-GlcNAc displayed a striking TCR conservation. Our interpretation is that the carbohydrate of K2-O-GlcNAc not only mediates binding to Db, but also interacts with the TCR in such a way as to mimic K3-O-GlcNAc. This unusual example of molecular mimicry extends the known effects of peptide glycosylation from what we and others have previously reported: glycosylation may create a T cell neo-epitope, or, conversely, abrogate recognition. Alternatively, glycosylation may block peptide binding to MHC class I and finally, as reported here, restore binding, presumably through direct interaction of the carbohydrate with the MHC molecule.

Glycobiology: 'the function of sugar in the IgG molecule'.

Immunoglobulin G (IgG) is glycosylated in both the Fc and the Fab regions of the protein with a heterogeneous ensemble of structures (glycoforms) that is both highly reproducible (i.e. nonrandom) and site specific. In normal IgG, the 2 highly conserved oligosaccharides of the Fc region are found buried between the CH2 domains, forming specific protein-saccharide interactions with the Fc protein surface. One of the functions attributed to the Fc oligosaccharides of normal IgG is to maintain the conformational arrangements of the Fc domains as well as the hinge regions. These structural features are necessary for Fc effector functions such as Clq and monocyte binding. A hallmark of rheumatoid arthritis (RA) patients is a dramatic increase in the presence of serum IgG containing Fc oligosaccharides lacking an outer arm galactose residue (termed 'G0' glycoforms). The increased level of G0 has been shown to be directly related to the pathogenesis of RA. Nuclear magnetic resonance relaxation studies of the Fc region from normal and RA IgG, as well as examination of x-ray structures, show that the G0 oligosaccharides have an increased mobility resulting from the loss of binding between the G0 oligosaccharide and the Fc protein surface. From these observations it follows that regions of the protein surface that are normally covered by the oligosaccharide are revealed. The newly accessible protein surface could have lectin-like activity and also be inherently antigenic. In addition, the more mobile G0 oligosaccharide can be recognised by mannose binding protein. As the mannose binding protein can activate complement, and the Fc oligosaccharide would not normally be accessible to protein recognition, this finding might suggest a specific role for the G0 glycoform in inflammation when the appropriate IgG glycoforms are clustered.

Recognition of carbohydrate by major histocompatibility complex class I-restricted, glycopeptide-specific cytotoxic T lymphocytes.

Cytotoxic T cells (CTL) recognize short peptide epitopes presented by class I glycoproteins encoded by the major histocompatibility complex (MHC). It is not yet known whether peptides containing posttranslationally modified amino acids can also be recognized by CTL. To address this issue, we have studied the immunogenicity and recognition of a glycopeptide carrying an O-linked N-acetylglucosamine (GlcNAc) monosaccharide-substituted serine residue. This posttranslational modification is catalyzed by a recently described cytosolic glycosyltransferase. We show that glycosylation does not affect peptide binding to MHC class I and that glycopeptides can elicit a strong CTL response that is glycopeptide specific. Furthermore, glycopeptide recognition by cytotoxic T cells is dependent on the chemical structure of the glycan as well as its position within the peptide.

A peptide model for the heparin binding site of antithrombin III.

A peptide model for the heparin binding site of antithrombin III (ATIII) was synthesized to elucidate the structural consequences of heparin binding. This peptide [ATIII(123-139)] and a sequence-permuted analogue (ATIII random) showed similar conformational behavior (as analyzed by circular dichroism spectroscopy) in aqueous and organic media. In the presence of heparin, however, the peptide ATIII(123-139) assumed a stable conformation, whereas peptide ATIII random did not. Complex formation was saturable and sensitive to salt. The ATIII(123-139)-heparin complex contained beta-structure, rather than helical structure. This finding is incompatible with current models of heparin binding and suggests that heparin binding may induce nonnative structures at the binding site which could, in turn, lead to activation of ATIII. The peptide ATIII(123-139) was able to inhibit the binding of ATIII by heparin, consistent with the notion that this peptide may be a model for the heparin binding site.