Hirotaka Uzawa

A novel sugar-probe biosensor for the deadly plant proteinous toxin, ricin

Because of the illegal use of highly toxic ricin from the castor-oil plant, Ricinus communis, in bioterrorism and suspected white powder cases, anti-terrorism measures for the toxin are urgently required. Here we demonstrate a facile and sensitive detection method using synthetic analogues of beta-lactosyl- and beta-d-galactosyl ceramides as the ligands based on the fact that ricin binds cell-surface oligosaccharides. Sugar-probes having lipoic acids as anchor functions were synthesized via either a chemical or chemoenzymatic way and were immobilized on the sensor chips by a self-assembled monolayer technique. Surface plasmon resonance (SPR) analysis using these carbohydrate probes allowed us to detect the toxin in a highly sensitive and facile manner (10 pg/mL, 5 min), being the best benchmark as a method for detecting the toxin. In addition, a visual monitoring method was developed, in which sugar-coated Au nanoparticles were utilized for discriminating ricin from other proteins in a facile manner, taking 10-30 min for judgment.

Synthesis of an artificial glycoconjugate polymer carrying Pk-antigenic trisaccharide and its potent neutralization activity against Shiga-like toxin.

Fluorescence-labeled glycoconjugate polymers carrying carbohydrate segments of a globotriaosyl ceramide (Gb3) were synthesized and subjected to biological assays using Escherichia coli O-157 strains and Shiga-like toxins (Stx-I and Stx-II). For the fluorescence labeling, a new polymerizable fluorescent monomer with a TBMB carbonyl chromophore (Ex. 325 nm, Em. 410 nm) was designed. A glycosyl monomer of the trisaccharide segment of Gb3 was prepared from p-nitrophenyl beta-lactoside and copolymerized with acrylamide and the fluorescent monomer to prepare a fluorescence-labeled glycoconjugate copolymer carrying [alpha-D-galactopyranosyl-(1-->4)-beta-D-galactopyranosyl]-(1-->4)-beta- D-glucopyranoside. The polymer showed potent neutralization activity against Stx-I and also binding activity onto E. coli O-157 strains.

Localized Surface Plasmon Resonance Detection of Biological Toxins Using Cell Surface Oligosaccharides on Glyco Chips

We have detected biological toxins using localized surface plasmon resonance (LSPR) and synthetic glycosyl ceramides (β-lactoside, globosyl trisaccharide (Gb3), or GM1 pentasaccharide) attached to gold (Au) nanoparticles. The particle diameters ranged from 5-100 nm. The detection sensitivity for three toxins (ricin, Shiga toxin, and cholera toxin) was found to depend not only on the attached glycoside but also on the diameter of the Au nanoparticles. For the detection of ricin, the 20-nm β-lactoside-coated Au nanoparticle exhibited the highest LSPR response, whereas 40-nm Gb3- and GM1-coated Au nanoparticles gave the best results for Shiga toxin and cholera toxin, respectively. In addition, a blocking process on the nanoparticle surface greatly improved the detection sensitivity for cholera toxin. The LSPR system enabled us to detect ricin at 30 ng/mL, Shiga toxin at 10 ng/mL, and the cholera toxin at 20 ng/mL.

Glycochips from polyanionic glycopolymers as tools for detecting shiga toxins

An alternating layer‐by‐layer adsorption methodology was applied to the assembly of glycochips by using synthetic polyanionic glycopolymers. Three glycochips carrying globobioside (Gb2), β‐lactoside (β‐Lac), or α‐D‐mannoside (α‐Man) residues were prepared, and used for the detection of Shiga toxins, Stx‐1 and Stx‐2, by using surface plasmon resonance (SPR). Using this method, we could confirm that both Stx‐1 and Stx‐2 show binding specificity for the Gb2 glycochip as well as a weak affinity for the β‐Lac glycochip. The affinity constants of these toxins depended strongly on the sugar content of the Gb2 polymer used to prepare the glycochip. Greater affinity was observed for chips with a higher sugar content (up to 43 %) in the Gb2 glycopolymer. The maximal affinity constants of Stx‐1 and Stx‐2 (Ka=108–109 M−1) enabled highly sensitive and facile analysis (10 ng mL−1, 30 min). When Gb2 glycopolymers were used as competitors, Stx‐1 and Stx‐2 behaved differently from one another in terms of their SPR response; this allowed us to perform discriminative analysis between the two toxins.

Synthesis of artifical glycoconjugate polymers carrying biologically active trisaccharides with α-d-galactopyranosyl (1→3) and (1→4)-linkage

Abstract Starting from p -nitrophenyl-β-lactoside, two types of neoglycoconjugate carrying either a trisaccharide segment of globotriaosyl ceramide (Gb3) or its regioisomeric Galα1,3Galβ1,4Glc were synthesized via a common intermediate. The former polymer carrying the Gb3 trisaccharide showed strong neutralization activity against Shiga-like toxin-I in the assay using human ACHN cells.

Determination of ricin by nano liquid chromatography/mass spectrometry after extraction using lactose‐immobilized monolithic silica spin column

Ricin is a glycosylated proteinous toxin that is registered as toxic substance by Chemical Weapons convention. Current detection methods can result in false negatives and/or positives, and their criteria are not based on the identification of the protein amino acid sequences. In this study, lactose-immobilized monolithic silica extraction followed by tryptic digestion and liquid chromatography/mass spectrometry (LC/MS) was developed as a method for rapid and accurate determination of ricin. Lactose, which was immobilized on monolithic silica, was used as a capture ligand for ricin extraction from the sample solution, and the silica was supported in a disk-packed spin column. Recovery of ricin was more than 40%. After extraction, the extract was digested with trypsin and analyzed by LC/MS. The accurate masses of molecular ions and MS/MS spectra of the separated peptide peaks were measured by Fourier transform-MS and linear iontrap-MS, respectively. Six peptides, which were derived from the ricin A-(m/z 537.8, 448.8 and 586.8) and B-chains (m/z 701.3, 647.8 and 616.8), were chosen as marker peptides for the identification of ricin. Among these marker peptides, two peptides were ricin-specific. This method was applied to the determination of ricin from crude samples. The monolithic silica extraction removed most contaminant peaks from the total ion chromatogram of the sample, and the six marker peptides were clearly detected by LC/MS. It takes about 5 h for detection and identification of more than 8 ng/ml of ricin through the whole handling, and this procedure will be able to deal with the terrorism using chemical weapon.

Use of Lactose against the Deadly Biological Toxin Ricin

Developing a technology for detecting and decontaminating biological toxins is needed. Ricin from Ricinus communis is a highly poisonous toxin; it was formerly used for an assassination in London and in postal attacks in the United States. Ricin is readily available from castor beans and could be used as a biological agent. We propose using glycotechnology against the illegal use of ricin. Lactose (a natural ligand of this toxin) was incorporated into polyacrylamide-based glycopolymers at variable sugar densities (18-100%) and evaluated with surface plasmon resonance (SPR) spectroscopy and the real agent, ricin. Glycopolymers (18-65% lactose densities) effectively interfered with the toxin-lactoside adhesion event (>99% efficiency within 20 min). This supported the notion of using the mammary sugar lactose against a deadly biological toxin.

Synthesis of 6′-sulfodisaccharides by β-N-acetylhexosaminidase-catalyzed transglycosylation

Presulfated N-acetylglucosaminyl donor (pNP beta-D-6-SO3-GlcNAc) was applied for the synthesis of sulfosugars using the beta-N-acetylhexosaminidase-catalyzed transglycosylation, to afford the critically stereocontrolled sulfodisaccharides carrying the 6-sulfo GlcNAc residue at the non-reducing sides in one step.

Molecular design, synthesis and bioactivity of glycosyl hydrazine and hydrazone derivatives: notable effects of the sugar moiety.

Assuming that the water solubility of our previous hydrazone derivatives would improve after modification with sugars while keeping or modulating their notable biological activities, we designed and synthesized some glycosyl hydrazine and hydrazone derivatives. Bioassay results indicated that the antitumor activity of our previously prepared hydrazones reduced or disappeared after modification with sugars. On the contrary, some glycosyl derivatives displayed much better antifungal activity against selected fungi. Obviously, a small sugar can change the biological activity of hydrazones significantly.

N-Acetyl-6-sulfo-d-glucosamine as a promising mimic of N-Acetyl neuraminic acid

6-Sulfo-D-GlcNAc with a molecular geometry close to that of N-acetylneuraminic acid (Neu5Ac) was hypothesized to serve as a simple Neu5Ac mimic possessing high potential in biochemical and medicinal applications. The hypothesis was evidenced with a neuraminidase inhibition assay using p-nitrophenyl (pNP) 3-, 4-, and 6-sulfo-beta-D-GlcNAc (4, 5 and 2a) and 6-sulfo-beta-D-Glc 6, in which only pNP 6-sulfo-beta-D-GlcNAc 2a was found to show substantial activity.