Crystal structure of heat-labile enterotoxin from Escherichia coli with increased thermostability introduced by an engineered disulfide bond in the A subunit.

Cholera toxin (CT) produced by Vibrio cholerae and heat-labile enterotoxin (LT-I), produced by enterotoxigenic Escherichia coli, are AB5 heterohexamers with an ADP-ribosylating A subunit and a GM1 receptor binding B pentamer. These toxins are among the most potent mucosal adjuvants known and, hence, are of interest both for the development of anti-diarrheal vaccines against cholera or enterotoxigenic Escherichia coli diarrhea and also for vaccines in general. However, the A subunits of CT and LT-I are known to be relatively temperature sensitive. To improve the thermostability of LT-I an additional disulfide bond was introduced in the A1 subunit by means of the double mutation N40C and G166C. The crystal structure of this double mutant of LT-I has been determined to 2.0 A resolution. The protein structure of the N40C/G166C double mutant is very similar to the native structure except for a few local shifts near the new disulfide bond. The introduction of this additional disulfide bond increases the thermal stability of the A subunit of LT-I by 6 degrees C. The enhancement in thermostability could make this disulfide bond variant of LT-I of considerable interest for the design of enterotoxin-based vaccines.     

Structural characterization of the O-specific polysaccharide from the lipopolysaccharide of the fish pathogen Aeromonas bestiarum strain P1S

The O-specific polysaccharide obtained by mild-acid degradation of lipopolysaccharide of Aeromonas bestiarum P1S was studied by sugar and methylation analyses along with ¹H and ¹³C NMR spectroscopy. The sequence of the sugar residues was determined using ¹H,¹H NOESY and ¹H,¹³C HMBC experiments. The O-specific polysaccharide was found to be a high-molecular-mass polysaccharide composed of tetrasaccharide repeating units of the structureSince small amounts of a terminal Quip3N residue were identified in methylation analysis, it was assumed that the elucidated structure also represented the biological repeating unit of the O-specific polysaccharide.     

Functional interaction of Escherichia coli heat-labile enterotoxin with blood group A-active glycoconjugates from differentiated HT29 cells

Human colon adenocarcinoma cells (HT29-ATCC) and the clone HT29-5F7 were cultured under conditions that differentiate cells to a polarized intestinal phenotype. Differentiated cells showed the presence of junctional complexes and intercellular lumina bordered by microvilli. Intestinal brush border hydrolase activities (sucrase, aminopeptidase N, lactase and maltase) were detected mainly in differentiated HT29-ATCC cells compared with the differentiated clone, HT29-5F7. The presence of non-GM1 receptors of Escherichia coli heat-labile enterotoxin (LT-I) on both types of differentiated HT29 cells was indicated by the inability of cholera toxin B subunit to block LT-I binding to the cells. Binding of LT-I to cells, when GM1 was blocked by the cholera toxin B subunit, was characterized by an increased number of LT-I receptors with respect to undifferentiated control cells. Moreover, both types of differentiated cells accumulated higher amounts of cyclic AMP in response to LT-I than undifferentiated cells. Helix pomatia lectin inhibited the binding of LT-I to cells and the subsequent production of cyclic AMP. LT-I recognized blood group A-active glycosphingolipids as functional receptors in both HT29 cell lines and the active pro-sucrase form of the glycoprotein carrying A-blood group activity present in HT29-ATCC cells. These results strongly suggest that LT-I can elicit an enhanced functional response using blood group A-active glycoconjugates as additional receptors on polarized intestinal epithelial cells.     

Structurally diverse dehydroshikimate dehydratase variants participate in microbial quinate catabolism

Quinate and shikimate can be degraded by a number of microbes. Dehydroshikimate dehydratases (DSDs) play a central role in this process, catalyzing the conversion of 3‐dehydroshikimate to protocatechuate, a common intermediate of aromatic degradation pathways. DSDs have applications in metabolic engineering for the production of valuable protocatechuate‐derived molecules. Although a number of Gram‐negative bacteria are known to catabolize quinate and shikimate, only limited information exists on the quinate/shikimate catabolic enzymes found in these organisms. Here, we have functionally and structurally characterized a putative DSD designated QuiC1, which is present in some pseudomonads. The QuiC1 protein is not related by sequence with previously identified DSDs from the Gram‐negative genus, Acinetobacter, but instead shows limited sequence identity in its N‐terminal half with fungal DSDs. Analysis of a Pseudomonas aeruginosa quiC1 gene knock‐out demonstrates that it is important for growth on either quinate or shikimate. The structure of a QuiC1 enzyme from P. putida reveals that the protein is a fusion of two distinct modules: an N‐terminal sugar phosphate isomerase‐like domain associated with DSD activity and a novel C‐terminal hydroxyphenylpyruvate dioxygenase‐like domain. The results of this study highlight the considerable diversity of enzymes that participate in quinate/shikimate catabolism in different microbes.     

Monoclonal antibodies detecting different epitopes on the Forssman glycolipid hapten

Two hybridomas, derived by fusing mouse myeloma cells with spleen cells from a rat immunized with mouse mammary tumors, have been shown to produce antibodies that recognize cell surface antigens on mesenchymal cells in a variety of tissues. Evidence presented in this report suggests that these antibodies detect overlapping epitopes on the Forssman glycolipid hapten (GalNAc alpha 1-3GalNAc beta 1-3Gal alpha 1-4Gal beta 1-4Glc beta 1-1Cer). One antibody (33B12) reacts with the terminal sugar sequence GalNAc alpha 1-3GalNAc and is specific for Forssman. The other antibody (117C9) recognizes the internal sugar sequence GalNAc beta 1-3Gal. The terminal sugar sequence GalNAc beta 1-3Gal in globoside, as well as the internal sugar sequence GalNAc beta 1-4Gal in asialo-GM1, is not recognized as an antigenic determinant by 117C9. Nevertheless, the 117C9 antibody does not react exclusively with the Forssman antigen. In a lipid extract fractionated by Folch partition of mouse mammary tumors, the antibody also detects other glycolipids.     

Purification and Characterization of a Novel β-<Emphasis Type="SmallCaps">d</Emphasis>-Galactosides-Specific Lectin from <Emphasis Type="Italic">Clitoria ternatea</Emphasis>

A lectin present in seeds of Clitoria ternatea agglutinated trypsin-treated human B erythrocytes. The sugar specificity assay indicated that lectin belongs to Gal/Gal NAc-specific group. Hence the lectin, designated C. ternatea agglutinin (CTA), was purified by the combination of acetic acid precipitation, salt fractionation and affinity chromatography. HPLC gel filtration, SDS-polyacrylamide gel electrophoresis and mass spectrometry indicated that the native lectin is composed of two identical subunits of molecular weight 34.7 kDa associated by non covalent bonds. The N-terminal sequence of CTA shared homology with Glycine max and Pisum sativum. Complete sequence was also found to be homologous to S-64 protein of Glycine max, suggesting that CTA probably exhibits both hemagglutination and probably sugar uptake activity. The carbohydrate binding specificity of the lectin was investigated by quantitative turbidity measurements, and percent inhibition assays. Based on these assays, we conclude that CTA binds β-d-galactosides, and also may has an extended specificity towards non-reducing terminal Neu5Acα2,6Gal.     

d-CpCpGpG and d-GpGpCpC self-complementary duplexes: Nmr studies of the helix-coil transition

We have monitored the helix-coil transition of the self-complementary d-CpCpGpG and d-GpGpCpC sequences (20mM strand concentration) at the base pairs, sugar rings, and backbone phosphates by 360-MHz proton and 145.7-MHz phosphorus nmr spectroscopy in 0.1M phosphate solution between 5 and 95°C. The guanine 1-imino Watson-Crick hydrogen-bonded protons, characteristic of the duplex state, are observed below 10°C, with solvent exchange occurring by transient opening of the tetranucleotide duplexes. The cytosine 4-amino Watson-Crick hydrogen-bonded protons resonate 1.5 ppm downfield from the exposed protons at the same position in the tetranucleotide duplexes, with slow exchange indicative of restricted rotation about the C-N bond below 15°C. The guanine 2-amino exchangeable protons in the tetranucleotide sequence exhibit very broad resonances at low temperatures and narrow average resonances above 20°C, corresponding to intermediate and fast rotation about the C-N bond, respectively. Solvent exchange is slower at the amino protons compared to the imino protons since the latter broaden out above 10°C. The well-resolved nonexchangeable base proton chemical shifts exhibit helix-coil transition midpoints between 37 and 42°C. The transition midpoints and the temperature dependence of the chemical shifts at low temperatures were utilized to differentiate between resonances located at the terminal and internal base pairs while the H-5 and H-6 doublets of individual cytosines were related by spin decoupling studies. For each tetranucleotide duplex, the cytosine H-5 resonances exhibit the largest chemical shift change associated with the helix-coil transition, a result predicted from calculations based on nearest-neighbor atomic diamagnetic anisotropy and ring current contributions for a B-DNA duplex. There is reasonable agreement between experimental and calculated chemical shift changes for the helix-coil transition at the internal base pairs but the experimental shifts exceed the calculated values at the terminal base pairs due to end-to-end aggregation at low temperatures. Since the guanine H-8 resonances of the CpCpGpG and d-CpCpGpG sequences exhibit upfield shifts of 0.6–0.8 and <0.1 ppm, respectively, on duplex formation, these RNA and DNA tetranucleotides with the same sequence must adopt different base-pair overlap geometries. The large chemical shift changes associated with duplex formation at the sugar H-1′ triplets are not detected at the other sugar protons and emphasize the contribution of the attached base at the 1′ position. The coupling sum between the H-1′ and the H-2′ and H-2″ protons equals 15–17 Hz at all four sugar rings for the d-CpCpGpG and d-GpGpCpC duplexes (25°C), consistent with a C-3′ exo sugar ring pucker for the deoxytetranucleotides in solution. The temperature dependent phosphate chemical shifts monitor changes in the ω,ω′ angles about the O-P backbone bonds, in contrast to the base-pair proton chemical shifts, which monitor stacking interactions.     

Structural analysis of the exopolysaccharide produced by <Emphasis Type="Italic">Streptococcus thermophilus</Emphasis> ST1 solely by NMR spectroscopy

The use of lactic acid bacteria in fermentation of milk results in favorable physical and rheological properties due to in situ exopolysaccharide (EPS) production. The EPS from S. thermophilus ST1 produces highly viscous aqueous solutions and its structure has been investigated by NMR spectroscopy. Notably, all aspects of the elucidation of its primary structure including component analysis and absolute configuration of the constituent monosaccharides were carried out by NMR spectroscopy. An array of techniques was utilized including, inter alia, PANSY and NOESY-HSQC TILT experiments. The EPS is composed of hexasaccharide repeating units with the following structure: → 3)[α-d-Glcp-(1 → 4)]-β-d-Galp-(1 → 4)-β-d-Glcp-(1 → 4)[β-d-Galf-(1 → 6)]-β-d-Glcp-(1 → 6)-β-d-Glcp-(1 →, in which the residues in square brackets are terminal groups substituting backbone sugar residues that consequently are branch-points in the repeating unit of the polymer. Thus, the EPS consists of a backbone of four sugar residues with two terminal sugar residues making up two side-chains of the repeating unit. The molecular mass of the polymer was determined using translational diffusion experiments which resulted in M_w = 62 kDa, corresponding to 64 repeating units in the EPS.     

Secretory glycoproteins of the rat subcommissural organ are N-linked complex-type glycoproteins. Demonstration by combined use of lectins and specific glycosidases,and by the administration of tunicamycin

Summary Two experimental protocols were used to investigate the secretory glycoproteins of the subcommissural organ (SCO). Protocol I: Lectins, specific exoglycosidases and immunocytochemistry were sequentially applied to the same section or to adjacent semithin sections of the rat SCO fixed in Bouin's fluid and embedded in methacrylate. Lectins used: concanavalin A (con A), wheat germ agglutinin, Limulus polyphemus agglutinin, Ricinus communis agglutinin and Arachis hypogeae agglutinin. Glycosidases used: neuroaminidase, -galactosidase, -mannosidase, -glucosidase and -N-acetyl-glucosaminidase. For immunocytochemistry an antiserum against bovine Reissner's fiber (AFRU) was used. Lectins and glycosidases were used in sequences that allowed the cleaved sugar residue to be identified as well as that appearing exposed as a terminal residue. This approach led to the following conclusions: (1) the terminal sugar chain of the secreted glycoproteins has the sequence sialic acid-galactose-glucosamine-; (2) the con A-binding material present in the rough endoplasmic reticulum corresponds to mannose; (3) the apical secretory granules and Reissner's fibers displayed a strong con A affinity after removing sialic acid, thus indicating the presence of internal mannosyl residues in the secreted material; (4) after removing most of the sugar moieties the secretory material continued to be strongly immunoreactive with AFRU. Protocol II: Rats were injected into the lateral ventricle with Tunicamycin and killed 12, 24, 50 and 60 h after the injection. The SCO of rats from the last two groups showed a complete absence of con A binding sites. The results from the two experiments confirm that the secretory glycoproteins of the rat SCO are N-linked complex-type glycoproteins with the conformation previously suggested (Rodríguez et al. 1986).Supported by Grant I/63-476 from the Stiftung Volkswagenwerk, Federal Republic of Germany, Grant S-89-01 from the Dirección de Ivestigaciones, Universidad Austral de Chile, and Grant 0890/88 from FONDECYT, Chile     

Glycan structures of the structural subunit (HtH1) of <Emphasis Type="Italic">Haliotis tuberculata</Emphasis> hemocyanin

The oligosaccharide structures of the structural subunit HtH1 of Haliotis tuberculata hemocyanin (HtH) were studied by mass spectral sequence analysis of the glycans. The proposed structures are based on MALDI-TOF-MS data before and after treatment with the specific exoglycosidases β1-3,4,6-galactosidase and α1-6(>2,3,4) fucosidase followed by sequence analysis via electrospray ionization MS/MS-spectra. In total, 15 glycans were identified as a highly heterogeneous group of structures. As in most molluscan hemocyanins, the glycans of HtH1 contain a terminal MeHex, but more interestingly, a novel structural motif was observed: MeHex[Fuc(α1-3)-]GlcNAc, including thus MeHex and (α1-3)-Fuc residues being linked to an internal GlcNAc residue. While the functional unit (FU) c (HtH1-c) is completely lacking any potential glycosylation site, FU-h possesses a second exposed sugar attachment site between beta-strands 8 and 9 within the beta sandwich domain compared to the other FUs. The glycosylation pattern/sites show a high degree of conservation. In FU-h two prominent potential glycosylation sites can be detected. The finding that HtH1 is not able to form multidecameric structures in vivo could be explained by the presence of the exposed glycan on the surface of FU-h.     

Isolation of cholera toxin receptors from a mouse fibroblast and lymphoid cell line by immune precipitation

Cholera toxin receptors have been isolated from both a mouse fibroblast (Balbc/3T3) and mouse lymphoid cell line labeled by the galactose oxidase borotritiide technique. Tritiated receptor-toxin complexes solubilized in NP40 were isolated by addition of toxin antibody followed by a protein A-containing strain of Staphylococcus aureus. In both cell types by far the major species of toxin receptor isolated was ganglioside in nature, although galactoproteins were also present in the immune complexes. Whether the galactoproteins form part of a toxin-receptor complex or are artifacts of the isolation procedure is presently unclear. The relative specificity of cholera toxin for a carbohydrate sequence in a glycolipid suggests that the toxin might prove a useful tool in establishing the function and organization of glycolipids in membranes. For example, interaction of cholera toxin with the mouse lymphoid cell line was shown to result in patching and capping of bound toxin, raising the possibility that the glycolipid receptor interacts indirectly with cytoskeletal elements. Cholera toxin might also be used to select for mutant fibroblasts lacking the toxin receptor and therefore having an altered glycolipid profile. Such mutants might prove useful in establishing the relationship (if any) between modified glycolipid pattern and other aspects of the transformed phenotype. Attempts to isolate mutants, based on the expectation that growth of cells containing the toxin receptor would be inhibited by the increase in cAMP levels normally induced by cholera toxin, proved unsuccessful. Cholera toxin failed to inhibit significantly the growth of either Balbc or Swiss 3T3 mouse fibroblasts although it markedly elevated cAMP levels.     

The Absence of TIR-Type Resistance Gene Analogues in the Sugar Beet (Beta vulgaris L.) Genome

The majority of known plant resistance genes encode proteins with conserved nucleotide-binding sites and leucine-rich repeats (NBS-LRR). Degenerate primers based on conserved NBS-LRR motifs were used to amplify analogues of resistance genes from the dicot sugar beet. Along with a cDNA library screen, the PCR screen identified 27 genomic and 12 expressed NBS-LRR RGAs (nlRGAs) sugar beet clones. The clones were classified into three subfamilies based on nucleotide sequence identity. Sequence analyses suggested that point mutations, such as nucleotide substitutions and insertion/deletions, are probably the primary source of diversity of sugar beet nlRGAs. A phylogenetic analysis revealed an ancestral relationship among sugar beet nlRGAs and resistance genes from various angiosperm species. One group appeared to share the same common ancestor as Prf, Rx, RPP8, and Mi, whereas the second group originated from the ancestral gene from which 12C1, Xa1, and Cre3 arose. The predicted protein products of the nlRGAs isolated in this study are all members of the non-TIR-type resistance gene subfamily and share strong sequence and structural similarities with non-TIR-type resistance proteins. No representatives of the TIR-type RGAs were detected either by PCR amplification using TIR type-specific primers or by in silico screening of more than 16,000 sugar beet ESTs. These findings suggest that TIR type of RGAs is absent from the sugar beet genome. The possible evolutionary loss of TIR type RGAs in the sugar beet is discussed. These authors (Yanyan Tian, Longjiang Fan) contributed equally to this work.     

Novel export control of a Legionella Dot/Icm substrate is mediated by dual,independent signal sequences

The Legionella pneumophila Dot/Icm T4SS injects ～ 300 protein effector proteins into host cells. Dot/Icm substrates have been proposed to contain a carboxy‐terminal signal sequence that is necessary and sufficient for export, although both traits have been demonstrated for only a small fraction of these proteins. In this study, we discovered that export of the substrate SidJ is mediated by dual signal sequences that include a conventional C‐terminal domain and a novel internal motif. The C‐terminal signal sequence facilitates secretion of SidJ into host cells at early points of infection, whereas the internal signal sequence mediates secretion at later time points. Interestingly, only the internal signal sequence is necessary for complementation of the intracellular growth defect of a ΔsidJ mutant. Although this is the first report of a Dot/Icm substrate being secreted by an internal signal sequence, many other substrates may be exported in a similar manner. In addition, efficient translocation of SidJ is dependent on the chaperone‐like type IV adaptors IcmS/IcmW. Five IcmS/IcmW binding domains that are distinct from both signal sequences were elucidated and, interestingly, only secretion mediated by the internal signal sequence requires IcmS/IcmW. Thus, Legionella employs multiple sophisticated molecular mechanisms to regulate the export of SidJ.     

C-terminal sequencing by mass spectrometry: application to gelatine-derived proline-rich peptides

Protonated peptides derived from proline‐rich proteins (PRP) are often difficult to sequence by standard collision‐induced dissociation (CID) mass spectrometry (MS) due to preferential amide bond cleavage N‐terminal to proline. In connection with bovine spongiform encephalopathy regulations, proteolytic products derived from the PRP collagen have been suggested as markers for contamination of animal feedstuffs with processed animal protein (Fernandez Ocaña, M. et al., Analyst 2004, 129, 111–115). Herein, we report the identification of these marker peptides using the strategy of C‐terminal sequencing by CID MS from their sodium and lithium adducts. Upon fragmentation a new cationized peptide was produced that is one C‐terminal amino acid shorter in length. This dissociation pathway allowed for the facile identification of the C‐terminal residue by matrix‐assisted laser desorption/ionization tandem time‐of‐flight mass spectrometry. Each newly formed cationized peptide was further fragmented by up to seven stages of electrospray ionization ion trap MS. Proline‐rich C‐terminal sequence tags were established which permitted successful database identification of collagen alpha type I proteins.     

Production and Isolation of Levan by Use of Levansucrase Immobilized on the Ceramic Support SM-10

The complete amino acid sequence of rye seed chitinase-a (RSC-a) has been analyzed. RSC-a was cleaved with cyanogen bromide and the resulting three fragments, CB1, CB2, and CB3, were separated by gel filtration. The amino acids of the N-terminal fragment CB1 were sequenced by analyzing the peptides produced by digestion with trypsin, lysylendopeptidase, or pepsin of reduced S-carboxymethyl ated or S-aminoethylated CB1. The sequences of fragments CB2 and CB3 were established by sequencing the tryptic peptides from reduced S-carboxymethylated CB2 and CB3, and by aligning them with the sequence of rye seed chitinase-c (RSC-c) to maximize sequence homology. The complete amino acid sequence of RSC-a was established by connecting these three fragments.

RSC-a consists of 302 amino acid residues including hydroxyproline residues, and has a molecular mass of 31,722 Da. RSC-a is basic protein with a cysteine-rich amino terminal domain, indicating that this enzyme belongs to class I chitinases. The amino acid sequence of RSC-a showed that the sequence from Gly60 to C-terminal Ala302 in this enzyme corresponds to that of RSC-c belonging to class II chitinases with 92% identity, and that RSC-a has high similarity to other plant class I chitinases but a longer hinge region and an extra disulfide bond.     

Structural identification of metabolites produced by the NodB and NodC proteins of Rhizobium leguminosarum

The Rhizobium nodulation genes nodABC are involved in the synthesis of lipo-chitin oligosac-charides. We have analysed the metabolites which are produced in vivo and in vitro by Rhizobium strains which express the single nodA, nodB and nodC genes or combinations of the three. In vivo radioactive labelling experiments, in which D-[1-¹⁴C]-glucosamine was used as a precursor, followed by mass spectrometric analysis of the purified radiolabelled metabolic products, showed that Rhizobium strains that only express the combination of the nodB and nodC genes do not produce lipo-chitin oligosaccharides but instead produce chitin oligomers (mainly pentamers) which are devoid of the N-acetyl group on the non-reducing terminal sugar residue (designated NodBC metabolites). Using the same procedure we have shown that when the nodL gene is expressed in addition to the nodBC genes the majority of metabolites contain an additional O-acetyl substituent on the non-reducing terminal sugar residue (designated NodBCL metabolites). The NodBC and NodBCL metabolites purified after in vivo labelling were compared with the radiolabelled metabolites produced in vitro by Rhizobium bacterial cell lysates to which UDP-N-acetyl-D-[U-¹⁴C]-glucosamine was added using thin-layer chromatography. The results show that the lysates of strains which expressed the nodBC or nodBCL genes can also produce NodBC and NodBCL metabolites. The same results were obtained when the NodB and NodC proteins were produced separately in two different strains. On the basis of these and other recent results, we propose that NodB is a chitin oilgosaccharide deacetylase, NodC an N-acetylglucosaminyltransferase and, by default, NodA is involved in lipie attachment.     

Secretory glycoproteins of the rat subcommissural organ are N-linked complex-type glycoproteins. Demonstration by combined use of lectins and specific glycosidases, and by the administration of Tunicamycin

Two experimental protocols were used to investigate the secretory glycoproteins of the subcommissural organ (SCO). Protocol I: Lectins, specific exoglycosidases and immunocytochemistry were sequentially applied to the same section or to adjacent semithin sections of the rat SCO fixed in Bouin's fluid and embedded in methacrylate. Lectins used: concanavalin A (con A), wheat germ agglutinin, Limulus polyphemus agglutinin, Ricinus communis agglutinin and Arachis hypogeae agglutinin. Glycosidases used: neuroaminidase, beta-galactosidase, alpha-mannosidase, alpha-glucosidase and beta-N-acetyl-glucosaminidase. For immunocytochemistry an antiserum against bovine Reissner's fiber (AFRU) was used. Lectins and glycosidases were used in sequences that allowed the cleaved sugar residue to be identified as well as that appearing exposed as a terminal residue. This approach led to the following conclusions: (1) the terminal sugar chain of the secreted glycoproteins has the sequence sialic acid-galactose-glucosamine-; (2) the con A-binding material present in the rough endoplasmic reticulum corresponds to mannose; (3) the apical secretory granules and Reissner's fibers displayed a strong con A affinity after removing sialic acid, thus indicating the presence of internal mannosyl residues in the secreted material; (4) after removing most of the sugar moieties the secretory material continued to be strongly immunoreactive with AFRU. Protocol II: Rats were injected into the lateral ventricle with Tunica-mycin and killed 12, 24, 50 and 60 h after the injection. The SCO of rats from the last two groups showed a complete absence of con A binding sites. The results from the two experiments confirm that the secretory glycoproteins of the rat SCO are N-linked complex-type glycoproteins with the conformation previously suggested (Rodríguez et al. 1986).     

The role of arabinokinase in arabinose toxicity in plants

Plant cell wall polymers are synthesized by glycosyltransferases using nucleotide sugars as substrates. Most UDP‐sugars are synthesized from UDP‐glucose via de novo pathways but salvage pathways work in parallel to recycle sugars, which have been released during cell wall polymer and glycoprotein turnover. Here we report on the cloning and biochemical analysis of two arabinokinases in Arabidopsis. Arabinokinase is a 100 kDa protein located in the cytosol with a putative N‐terminal glycosyltransferase domain and a C‐terminal sugar‐1‐kinase domain. This unique structure is highly conserved in the plant kingdom. Arabinokinase has a high affinity for l ‐arabinose, which is the only sugar substrate of this GHMP (galactose; homoserine; mevalonate; phosphomevalonate) kinase. Plants that were knocked‐out for arabinokinase and the previously described ara1‐1 mutant were characterized. The ARA1‐1 mutant form of the enzyme carries a point mutation in an α‐helix. The mutation is close to the substrate binding site and changes the K_m value for arabinose from 80 μm in the wild type to 17 000 μm in ARA1‐1. The previous arabinose toxicity explanation is challenged by knockout plants in arabinokinase that accumulate higher levels of arabinose but do not show signs of arabinose toxicity. Analysis of marker genes from sugar signalling pathways (SnRK1 and Tor) suggest that ara1‐1 misinterprets its carbon energy status. Although glucose is present in ara1‐1 similar to wild type levels, it constitutively changes gene expression as typically found in wild type plants only under starvation conditions. Furthermore, ara1‐1 shows increased expression of marker genes for programmed cell death as found in other lesion mimic mutants.     

Crystal structure of a non-toxic mutant of heat-labile enterotoxin, which is a potent mucosal adjuvant.

Two closely related bacterial toxins, heat-labile enterotoxin (LT-I) and cholera toxin (CT), not only invoke a toxic activity that affects many victims worldwide but also contain a beneficial mucosal adjuvant activity that significantly enhances the potency of vaccines in general. For the purpose of vaccine design it is most interesting that the undesirable toxic activity of these toxins can be eliminated by the single-site mutation Ser63Lys in the A subunit while the mucosal adjuvant activity is still present. The crystal structure of the Ser63Lys mutant of LT-I is determined at 2.0 A resolution. Its structure appears to be essentially the same as the wild-type LT-I structure. The substitution Ser63Lys was designed, based on the wild-type LT-I crystal structure, to decrease toxicity by interfering with NAD binding and/or catalysis. In the mutant crystal structure, the newly introduced lysine side chain is indeed positioned such that it could potentially obstruct the productive binding mode of the substrate NAD while at the same time its positive charge could possibly interfere with the critical function of nearby charged groups in the active site of LT-I. The fact that the Ser63Lys mutant of LT-I does not disrupt the wild-type LT-I structure makes the non-toxic mutant potentially suitable, from a structural point of view, to be used as a vaccine to prevent enterotoxigenic E. coli infections. The structural similarity of mutant and wild-type toxin might also be the reason why the inactive Ser63Lys variant retains its adjuvant activity.