Immobilized sialyltransferase fused to a fungal biotin-binding protein: Production, properties, and applications.

A ß-galactoside α2,6-sialyltransferase (ST) from the marine bacterium Photobacterium sp. JT-ISH-224 with a broad acceptor substrate specificity was fused to a fungal biotin-binding protein tamavidin 2 (TM2) to produce immobilized enzyme. Specifically, a gene for the fusion protein, in which ST from Photobacterium sp. JT-ISH-224 and TM2 were connected via a peptide linker (ST-L-TM2) was constructed and expressed in Escherichia coli. The ST-L-TM2 was produced in the soluble form with a yield of approximately 15,000 unit/300 ml of the E. coli culture. The ST-L-TM2 was partially purified and part of it was immobilized onto biotin-bearing magnetic microbeads. The immobilized ST-L-TM2 onto microbeads could be used at least seven consecutive reaction cycles with no observed decrease in enzymatic activity. In addition, the optimum pH and temperature of the immobilized enzyme were changed compared to those of a free form of the ST. Considering these results, it was strongly expected that the immobilized ST-L-TM2 was a promising tool for the production of various kind of sialoligosaccharides.

Unique gangliosides synthesized in vitro by sialyltransferases from marine bacteria and their characterization: ganglioside synthesis by bacterial sialyltransferases.

On the basis of the results outlined in our previous report, bacterial sialyltransferases (ST) from marine sources were further characterized using glycosphingolipids (GSL), especially ganglio-series GSLs, based on the enzymatic characteristics and kinetic parameters obtained by Line weaver-Burk plots. Among them, GA1 and GA2 were found to be good substrates for these unique STs. Thus, new gangliosides synthesized by α2-3 and α2-6STs were structurally characterized by several analytical procedures. The ganglioside generated by the catalytic activity of α2-3ST was identified as GM1b. On the other hand, when enzyme reactions by α2-6STs were performed using substrates GA2 and GA1, very unique gangliosides were generated. The structures were identified as NeuAcα2-6GalNAcß1-4Galß1-4Glcß-Cer and NeuAcα2-6Galß1-3GalNAcß1-4Galß1-4Glcß-Cer, respectively. The synthesized ganglioside NeuAcα2-6GalNAcß1-4Galß1-4Glcß-Cer showed binding activity to the influenza A virus {A/Panama/2007/99 (H3N2)} at a similar level to purified sialyl(α2-3)paragloboside (S2-3PG) and sialyl(α2-6)paragloboside (S2-6PG) from mammalian sources. The evidence suggests that these STs have unique features, including substrate specificities restricted not only to lacto-series but also to ganglio-series GSLs, as well as catalytic potentials for ganglioside synthesis. This evidence demonstrates that effective in vitro ganglioside synthesis could be a valuable tool for selectively synthesizing sialic acid (Sia) modifications, thereby preparing large-scale gangliosides and permitting the exploration of unknown functions.

Isolation of fucosyltransferase-producing bacteria from marine environments.

Fucose-containing oligosaccharides on the cell surface of some pathogenic bacteria are thought to be important for host-microbe interactions and to play a major role in the pathogenicity of bacterial pathogens. Here, we screened marine bacteria for glycosyltransferases using two methods: a one-pot glycosyltransferase assay method and a lectin-staining method. Using this approach, we isolated marine bacteria with fucosyltransferase activity. There have been no previous reports of marine bacteria producing fucosyltransferase. This paper thus represents the first report of fucosyltransferase-producing marine bacteria.

Loss-of-function mutation in bi-functional marine bacterial sialyltransferase.

An α2,3-sialyltransferase produced by Photobacterium phosphoreum JT-ISH-467 is a bi-functional enzyme showing both α2,3-sialyltransferase and α2,3-linkage specific sialidase activity. To date, the crystal structures of several sialyltransferases have been solved, but the roles of amino acid residues around the catalytic site have not been completely clarified. Hence we performed a mutational study using α2,3-sialyltransferase cloned from P. phosphoreum JT-ISH-467 as a model enzyme to study the role of the amino acid residues around the substrate-binding site. It was found that a mutation of the glutamic acid at position 342 in the sialyltransferase resulted in a loss of sialidase activity, although the mutant showed no decrease in sialyltransferase activity. Based on this result, it is strongly expected that the Glu342 of the enzyme is an important amino acid residue for sialidase activity.

Engineering of novel tamavidin 2 muteins with lowered isoelectric points and lowered non-specific binding properties.

The avidin-biotin interaction is widely employed as a universal tool in numerous biotechnological applications. In avidin-biotin technology, non-specific binding to biological macromolecules is a hindrance. The major origin of this non-specific binding is the electrical charge of the surface of biotin-binding proteins. Tamavidin 2, a fungal avidin-like protein that binds biotin with an extremely high affinity, can be produced as a soluble recombinant protein in Escherichia coli. The isoelectric point of tamavidin 2 is 7.4-7.5, lower than avidin (10.0), and slightly higher than that of streptavidin (6.0-7.5). Here, we genetically engineered charge mutants of tamavidin 2 to reduce non-specific binding. By substituting an acidic residue (glutamic acid) for basic residues (arginine and lysine), we constructed three mutant proteins (muteins) and confirmed their high-level production in soluble form in E. coli, as well as that of tamavidin 2. We then tested these proteins for non-specific binding to salmon sperm DNA, glycoproteins (integrin and fibronectin), and IgG from human sera. The muteins showed lower non-specific binding than tamavidin 2 to these macromolecules. In particular, one mutein, tamavidin-R104EK141E, which had the lowest isoelectric point (5.8-6.2) among avidin, streptavidin and tamavidin 2, displayed the lowest non-specific binding. The affinity of this mutein to biotin was high, comparable with that of tamavidin 2. These findings indicate that tamavidin-R104EK141E has the potential to serve as a robust tool in the numerous applications of biotin-binding proteins.

A CMP-N-acetylneuraminic acid synthetase purified from a marine bacterium, Photobacterium leiognathi JT-SHIZ-145.

A cytidine 5'-monophospho-N-acetylneuraminic acid (CMP-Neu5Ac) synthetase was found in a crude extract prepared from Photobacterium leiognathi JT-SHIZ-145, a marine bacterium that also produces a ß-galactoside α2,6-sialyltransferase. The CMP-Neu5Ac synthetase was purified from the crude extract of the cells by a combination of anion-exchange and gel filtration column chromatography. The purified enzyme migrated as a single band (60 kDa) on sodium dodecylsulfate-polyacrylamide gel electrophoresis. The activity of the enzyme was maximal at 35 °C at pH 9.0, and the synthetase required Mg(2+) for activity. Although these properties are similar to those of other CMP-Neu5Ac synthetases isolated from bacteria, this synthetase produced not only CMP-Neu5Ac from cytidine triphosphate and Neu5Ac, but also CMP-N-glycolylneuraminic acid from cytidine triphosphate and N-glycolylneuraminic acid, unlike CMP-Neu5Ac synthetase purified from Escherichia coli.

A recombinant α-(2→3)-sialyltransferase with an extremely broad acceptor substrate specificity from Photobacterium sp. JT-ISH-224 can transfer N-acetylneuraminic acid to inositols.

We confirmed that a recombinant α-(2→3)-sialyltransferase cloned from Photobacterium sp. JT-ISH-224 recognizes inositols having a structure corresponding to the C-3 and C-4 of a galactopyranoside moiety, such as epi-, 1d-chiro, myo-, and muco-inositol, as acceptor substrates, and that the enzyme can transfer N-acetylneuraminic acid (Neu5Ac) from cytidine 5'-monophospho-N-acetylneuraminic acid (CMP-Neu5Ac) to them. After purifying the reaction products, the structures were confirmed by use of NMR spectroscopy and mass spectrometry. From these results, it was clearly shown that the α-(2→3)-sialyltransferase from Photobacterium sp. JT-ISH-224 recognizes acceptor substrates through the cis-diol structure corresponding to the 3- and 4-position of the galactopyranoside moiety.

Enzymatic synthesis of unique sialyloligosaccharides using marine bacterial alpha-(2-->3)- and alpha-(2-->6)-sialyltransferases.

We investigated the acceptor substrate specificities of marine bacterial alpha-(2-->3)-sialyltransferase cloned from Photobacterium sp. JT-ISH-224 and alpha-(2-->6)-sialyltransferase cloned from Photobacterium damselae JT0160 using several saccharides as acceptor substrates. After purifying the enzymatic reaction products, we confirmed their structure by NMR spectroscopy. The alpha-(2-->3)-sialyltransferase transferred N-acetylneuraminic acid (Neu5Ac) from cytidine 5'-monophospho-N-acetylneuraminic acid (CMP-Neu5Ac) to the beta-anomeric hydroxyl groups of mannose (Man) and alpha-Manp-(1-->6)-Manp, and alpha-(2-->6)-sialyltransferase transferred N-acetylneuraminic acid to the 6-OH groups of the non-reducing end galactose residues in beta-Galp-(1-->3)-GlcpNAc and beta-Galp-(1-->6)-GlcpNAc.

Efficient synthesis of 6'-sialyllactose, 6,6'-disialyllactose, and 6'-KDO-lactose by metabolically engineered E. coli expressing a multifunctional sialyltransferase from the Photobacterium sp. JT-ISH-224.

We have previously reported the efficient conversion of lactose into 3'-sialyllactose by high cell density cultures of a genetically engineered Escherichia coli strain expressing the Neisseria meningitidis gene for alpha-(2-->3)-sialyltransferase [Fierfort, N.; Samain, E. J. Biotechnol. 2008, 134, 261-265.]. First attempts to use a similar strategy to produce 6'-sialyllactose with a strain expressing alpha-(2-->6)-sialyltransferase from the Photobacterium sp. JT-ISH-224 led to the production of a trisaccharide that was identified as KDO-lactose (2-keto-3-deoxy-manno-octonyllactose). This result showed that alpha-(2-->6)-sialyltransferase was able to use CMP-KDO as sugar donor and preferentially used CMP-KDO over CMP-Neu5Ac. By reducing the expression level of the sialyltransferase gene and increasing that of the neuABC genes, we have been able to favour the formation of 6'-sialyllactose and to prevent the formation of KDO-lactose. However, in this case, a third lactose derivative, which was identified as 6,6'-disialyllactose, was also produced. Formation of 6,6'-disialyllactose was mainly observed under conditions of lactose shortage. On the other hand, when the culture was continuously fed with an excess of lactose, 6'-sialyllactose was almost the only product detected and its final concentration was higher than 30g/L of culture medium.

Visualization of sialic acid produced on bacterial cell surfaces by lectin staining.

Oligosaccharides containing N-acetylneuraminic acid on the cell surface of some pathogenic bacteria are important for host-microbe interactions. N-acetylneuraminic acid (Neu5Ac) plays a major role in the pathogenicity of bacterial pathogens. For example, cell surface sialyloligosaccharide moieties of the human pathogen Haemophilus influenzae are involved in virulence and adhesion to host cells. In this study, we have established a method of visualizing Neu5Ac linked to a glycoconjugate on the bacterial cell surface based on lectin staining. Photobacterium damselae strain JT0160, known to produce a-2,6-sialyltransferase, was revealed to possess Neu5Ac by HPLC. Using the strain, a strong Sambucus sieboldiana lectin-binding signal was detected. The bacteria producing α-2,6-sialyltransferases could be divided into two groups: those with a lot of α-2,6-linked Neu5Ac on the cell surface and those with a little. In the present study, we developed a useful method for evaluating the relationship between Neu5Ac expression on the cell surface and the degree of virulence of marine bacteria.

An alpha2,6-sialyltransferase cloned from Photobacterium leiognathi strain JT-SHIZ-119 shows both sialyltransferase and neuraminidase activity.

We cloned, expressed, and characterized a novel beta-galactoside alpha2,6-sialyltransferase from Photobacterium leiognathi strain JT-SHIZ-119. The protein showed 56-96% identity to the marine bacterial alpha2,6-sialyltransferases classified into glycosyltransferase family 80. The sialyltransferase activity of the N-terminal truncated form of the recombinant enzyme was 1477 U/L of Escherichia coli culture. The truncated recombinant enzyme was purified as a single band by sodium dodecyl sulfate polyacrylamide gel electrophoresis through 3 column chromatography steps. The enzyme had distinct activity compared with known marine bacterial alpha2,6-sialyltransferases. Although alpha2,6-sialyltransferases cloned from marine bacteria, such as Photobacterium damselae strain JT0160, P. leiognathi strain JT-SHIZ-145, and Photobacterium sp. strain JT-ISH-224, show only alpha2,6-sialyltransferase activity, the recombinant enzyme cloned from P. leiognathi strain JT-SHIZ-119 showed both alpha2,6-sialyltransferase and alpha2,6-linkage-specific neuraminidase activity. Our results provide important information toward a comprehensive understanding of the bacterial sialyltransferases belonging to the group 80 glycosyltransferase family in the CAZy database.

Sialyltransferases of marine bacteria efficiently utilize glycosphingolipid substrates.

Bacterial sialyltransferases (STs) from marine sources were characterized using glycosphingolipids (GSLs). Bacterial STs were found to be beta-galacotoside STs. There were two types of STs: (1) ST obtained from strains such as ishi-224, 05JTC1 (#1), ishi-467, 05JTD2 (#2), and faj-16, 05JTE1 (#3), which form alpha2-3 sialic acid (Sia) linkages, named alpha2-3ST, (2) ST obtained from strains such as ISH-224, N1C0 (#4), pda-rec, 05JTB2 (#5), and pda-0160, 05JTA2 (#6), which form alpha2-6 Sia linkages, named alpha2-6ST. All STs showed affinity to neolacto- and lacto-series GSLs, particularly in neolactotetraosyl ceramide (nLc(4)Cer). No large differences were observed in the pH and temperature profiles of enzyme activities. Kinetic parameters obtained by Lineweaver-Burk plot analysis showed that #3 and #4 STs had practical synthetic activity and thus it became easily possible to achieve large-scale ganglioside synthesis (100-300 muM) using these recombinant enzymes. Gangliosides synthesized from nLc(4)Cer by alpha2-3 and alpha2-6STs were structurally characterized by several analytical and immunological methods, and they were identified as IV(3)alphaNeuAc-nLc(4)Cer(S2-3PG) and IV(6)alphaNeuAc-nLc(4)Cer (S2-6PG), respectively. Further characterization of these STs using lactotetraosylceramide (Lc(4)Cer), neolactohexaosylceramide (i antigen), and IV(6)kladoLc(8)Cer (I antigen) showed the synthesis of corresponding gangliosides as well. Synthesized gangliosides showed binding activity to the influenza A virus [A/panama/2007/99 (H3N2)] at a similar level to purified S2-3PG and S2-6PG from mammalian sources. The above evidence suggests that these STs have unique features, including substrate specificities restricted to lacto- and neolactoseries GSLs, as well as catalytic potentials for ganglioside synthesis. This demonstrates that efficient in vitro ganglioside synthesis could be a valuable tool for selectively synthesizing Sias modifications, thereby permitting the exploration of unknown functions.

Tamavidin, a versatile affinity tag for protein purification and immobilization.

Tamavidin 2 is a fungal avidin-like protein that binds biotin with high affinity and is highly produced in soluble form in Escherichia coli. By contrast, widely used biotin-binding proteins avidin and streptavidin are rarely produced in soluble form in E. coli. In this study, we describe an efficient system for one-step purification and immobilization of recombinant proteins using tamavidin 2 as an affinity tag. A bacterial sialyltransferase and soybean agglutinin were fused to tamavidin 2 and expressed in E. coli and tobacco BY-2 cells, respectively. High-level expressions of the fusion proteins were detected (80 mg l(-1)E. coli culture for bacterial sialyltransferase-tamavidin 2 and 2 mg l(-1) BY-2 cell culture for soybean agglutinin-tamavidin 2). To immobilize and purify the fusion proteins, biotinylated magnetic microbeads were incubated with the soluble extract from each recombinant host producing the fusion protein and then washed thoroughly. As the result, both fusion proteins were immobilized tightly on the microbeads without substantial loss of activity and simultaneously highly purified (90-95% purity) on the microbeads. Biotin with a longer linker contributed to higher affinity between the fusion protein and biotin. These results suggest that tamavidin fusion technology is a powerful tool for production, purification, and immobilization of recombinant proteins.

Crystal structure of alpha/beta-galactoside alpha2,3-sialyltransferase from a luminous marine bacterium, Photobacterium phosphoreum.

Alpha/beta-galactoside alpha2,3-sialyltransferase produced by Photobacterium phosphoreum JT-ISH-467 is a unique enzyme that catalyzes the transfer of N-acetylneuraminic acid residue from cytidine monophosphate N-acetylneuraminic acid to acceptor carbohydrate groups. The enzyme recognizes both mono- and di-saccharides as acceptor substrates, and can transfer Neu5Ac to both alpha-galactoside and beta-galactoside, efficiently. To elucidate the structural basis for the broad acceptor substrate specificity, we determined the crystal structure of the alpha2,3-sialyltransferase in complex with CMP. The overall structure belongs to the glycosyltransferase-B structural group. We could model a reasonable active conformation structure based on the crystal structure. The predicted structure suggested that the broad substrate specificity could be attributed to the wider entrance of the acceptor substrate binding site.

Crystal structure of Vibrionaceae Photobacterium sp. JT-ISH-224 alpha2,6-sialyltransferase in a ternary complex with donor product CMP and acceptor substrate lactose: catalytic mechanism and substrate recognition.

Sialyltransferases are a family of glycosyltransferases that catalyze the transfer of N-acetylneuraminic acid residues from cytidine monophosphate N-acetylneuraminic acid (CMP-NeuAc) as a donor substrate to the carbohydrate groups of glycoproteins and glycolipids as acceptor substrates. We determined the crystal structure of Delta16psp26ST, the N-terminal truncated form of alpha2,6-sialyltransferase from Vibrionaceae Photobacterium sp. JT-ISH-224, complexed with a donor product CMP and an acceptor substrate lactose. Delta16psp26ST has three structural domains. Domain 1 belongs to the immunoglobulin-like beta-sandwich fold, and domains 2 and 3 form the glycosyltransferase-B structure. The CMP and lactose were bound in the deep cleft between domains 2 and 3. In the structure, only Asp232 was within hydrogen-binding distance of the acceptor O6 carbon of the galactose residue in lactose, and His405 was within hydrogen-binding distance of the phosphate oxygen of CMP. Mutation of these residues greatly decreased the activity of the enzyme. These structural and mutational results indicated that Asp232 might act as a catalytic base for deprotonation of the acceptor substrate, and His405 might act as a catalytic acid for protonation of the donor substrate. These findings are consistent with an in-line-displacement reaction mechanism in which Delta16psp26ST catalyzes the inverting transfer reaction. Unlike the case with multifunctional sialyltransferase (Delta24PmST1) complexed with CMP and lactose, the crystal structure of which was recently reported, the alpha2,6 reaction specificity of Delta16psp26ST is likely to be determined by His123.

A beta-galactoside alpha2,6-sialyltransferase produced by a marine bacterium, Photobacterium leiognathi JT-SHIZ-145, is active at pH 8.

A gene encoding a sialyltransferase produced by Photobacterium leiognathi JT-SHIZ-145 was cloned, sequenced, and expressed in Escherichia coli. The sialyltransferase gene contained an open reading frame of 1494 base pairs (bp) encoding a predicted protein of 497 amino acid residues. The deduced amino acid sequence of the sialyltransferase had no significant similarity to mammalian sialyltransferases and did not contain sialyl motifs, but did show high homology to another marine bacterial sialyltransferase, a beta-galactoside alpha2,6-sialyltransferase produced by P. damselae JT0160. The acceptor substrate specificity of the new enzyme was similar to that of the alpha2,6-sialyltransferase from P. damselae JT0160, but its activity was maximal at pH 8. This property is quite different from the properties of all mammalian and bacterial sialyltransferases reported previously, which have maximal activity at acidic pH. In general, both sialosides and cytidine-5'-monophospho-N-acetylneuraminic acid, the common donor substrate of sialyltransferases, are more stable under basic conditions. Therefore, a sialyltransferase with an optimum pH in the basic range should be useful for the preparation of sialosides and the modification of glycoconjugates, such as asialo-glycoproteins and asialo-glycolipids. Thus, the sialyltransferase obtained from P. leiognathi JT-SHIZ-145 is a promising tool for the efficient production of sialosides.

Purification, crystallization and preliminary crystallographic characterization of the alpha 2,6-sialyltransferase from Photobacterium sp. JT-ISH-224.

Sialyltransferases transfer sialic acid from cytidine-5-monophospho-N-acetylneuraminic acid (CMP-NeuAc) to the nonreducing termini of the oligosaccharyl structures of various glycoproteins and glycolipids. The newly cloned alpha2,6-sialyltransferase from Photobacterium sp. JT-ISH-224 (from the Vibrionaceae family) is composed of two domains: an unknown N-terminal domain and a catalytic C-terminal domain which shares significant homology with the Pasteurella multocida multifunctional sialyltransferase. The putative mature form of JT-ISH-224 alpha2,6-sialyltransferase was overproduced in Escherichia coli, purified and crystallized using the hanging-drop vapour-diffusion method at 293 K. The crystal belonged to space group P3(1)21 or P3(2)21, with unit-cell parameters a = b = 90.29, c = 204.33 A. X-ray diffraction data were collected to 2.5 A resolution.