Tomoko Okada

Carbohydrate immobilized on a dendrimer-coated colloidal gold surface for fabrication of a lectin-sensing device based on localized surface plasmon resonance spectroscopy.

Carbohydrate-mediated functions in biological systems have generated considerable interest in recent years. We have developed a device bearing immobilized carbohydrates on a colloidal gold surface and applied this device to the detection of carbohydrate-binding molecules by using localized surface plasmon resonance (LSPR) spectroscopy. The sensing device was constructed by using cyanuric chloride as an amine-linker between an amino residue of a polyamidoamine (PAMAM) dendrimer-coated colloidal gold surface and the amino residue of a 12-aminododecyl glycoside. After optimizing the construction of the device, we characterized its LSPR-based sensing capability. Binding specificity with lectins and linear range responses were obtained with the device. Our LSPR-based sensing device thus provides a label-free, low-cost detection method for use as a laboratory research tool or in medical glycan arrays.

Fluorescence emission and polarization for analyzing binding of ruthenium metalloglycocluster to lectin and tetanus toxin C-fragment.

We have designed and synthesized ruthenium complexes bearing clustered galactose Ru(bpy-2Gal)(3) and glucose Ru(bpy-2Glc)(3). Changes in fluorescence emission (FE) and fluorescence polarization (FP) of the metalloglycoclusters were measured by adding each lectin (peanut agglutinin (PNA), Ricinus communis agglutinin 120 (RCA), concanavalin A (ConA), or wheat germ agglutinin (WGA)) or tetanus toxin c-fragment (TCF). Following the addition of PNA and ConA, the FE spectra of Ru(bpy-2Gal)(3) and Ru(bpy-2Glc)(3) showed new emission peaks, respectively. In addition, Ru(bpy-2Gal)(3) and Ru(bpy-2Glc)(3) exclusively increased the FP values by addition of PNA and ConA. Since other combinations of the metalloglycoclusters and lectin caused little change, specific bindings of galactose to PNA and glucose to ConA were confirmed by the FE and FP measurement. From the FP analyses, the dissociation constants (K(d)) of Ru(bpy-2Gal)(3) to PNA and Ru(bpy-2Glc)(3) to ConA were calculated to be ca. 6.1 x 10(-6) M and 1.8 x 10(-5) M. Furthermore, the FP analyses proved specific binding of Ru(bpy-2Gal)(3) to TCF.

Evaluation of interaction forces between profilin and designed peptide probes by atomic force microscopy.

We evaluated the binding affinity of peptide probes for profilin (protein) using force curve measurement techniques and atomic force microscopy (AFM). The peptide probes designed and synthesized for this investigation were H-A3GP5GP5GP5G-OH (1), H-A3GP5G-OH (2), H-A3G7-OH (3), and H-A3G-OH (4). Each peptide probe was immobilized on a cantilever tip, and the interaction force to profilin, immobilized on a mica substrate, was examined by force curve measurements. The retraction forces obtained showed a sequence-dependent affinity of the peptide probe for profilin. The retraction force for peptide probe 1 was the largest of the four probes examined, and it confirmed that peptide probe 1 has high affinity for profilin. The single molecular retraction force between peptide probe 1 and profilin was estimated to be 96 pN, as determined by Gaussian fitting to the histogram of the retraction forces.

Development of lipid A-imprinted polymer hydrogels that selectively recognize lipopolysaccharides.

To remove lipopolysaccharide (LPS) from pure water, we developed polymer hydrogels that selectively recognize LPS. A molecular imprinting technique was used to prepare the polymer hydrogels. We prepared the polymer hydrogels with LPS-binding sites by using acryloyllysine and acryloylphenylalanine as functional monomers and used lipid A as a template because it is the biologically active part of LPS and contains two phosphate groups. Co-existence of n-octane during the polymerization process was highly effective in promoting the formation of LPS-accessible sites on the surface of the hydrogels. Both an electrostatic and a hydrophobic interaction between the lipid A portion of LPS and the recognition site of the imprinted hydrogel are necessary for LPS recognition. The adsorption isotherm of LPS to the lipid A-imprinted hydrogels was Langmuir-type; the saturated adsorption capacity and the adsorption constant, calculated by applying an equation for Langmuir-type adsorption isotherms, were 1.0 × 10(-11)mol/cm(2) and 2.5 × 10(5)M(-1), respectively. The imprinted hydrogels selectively recognized toxic LPS in a competition experiment in which two other kinds of LPS with similar chemical structures to that of the LPS of E. coli (toxic LPS) were adsorbed to the lipid A-imprinted hydrogels.

Switchable binding affinity of mannose tethered to collagen peptide by temperature-dependent triple-helix formation.

Novel glycopeptides were created with a view to regulate the bindings of carbohydrates to lectins as a means of controlling biological function. We synthesized glycopeptides containing mannose (Man) tethered to a collagen peptide moiety (MPOG10: -(Pro-Hyp-Gly)10- or MGPP10: -(Gly-Pro-Pro)10-). Circular dichroism spectra showed formation of a triple helical structure for MPOG10, and the melting temperature indicates that MPOG10 forms a more stable triple helical structure than MGPP10 in phosphate buffered saline (PBS). At 25 °C, fluorescence polarization (FP) values of MPOG10 and MGPP10 increased following the addition of concanavalin A (ConA), and the addition of α-methyl-mannose (MeMan) to a mixed solution of each glycopeptide with ConA resulted in a decrease in FP values. These results confirm that the previous increase in FP values observed was caused by ConA binding to Man on MPOG10 or MGPP10. The binding affinity of MPOG10 was higher than that of MGPP10, and the dissociation constant of MPOG10 to ConA was 1.9 × 10(-5) (mol/L). The observed binding of MPOG10 to ConA at 25 °C was reduced at higher temperature (50 °C). Therefore, the enhanced binding affinity of MPOG10 to ConA could be accounted for by formation of a clustered Man moiety triggered by the formation of a more stable triple helical structure of MPOG10 compared with MGPP10.

Fabrication of various tip-size AFM probes for evaluating single-molecular retraction force between actin and anti-actin

The authors fabricated a probe tip with various sizes and examined the size dependency of the probe tip on the distribution of retraction forces between actin and anti-actin. Probe tips of various sizes were fabricated by two-photon polymerization methods on a micro cantilever of an atomic force microscope (AFM). The authors succeeded in fabricating a spherical tip having a smooth surface and the tip size varied between phi 0.8 and 5.5 microm. Anti-actin was immobilized on the fabricated probe tips and force curves were measured against an actin-immobilized mica substrate by AFM to analyze the retraction forces. The histograms of retraction forces showed that the single-molecular retraction force between actin and anti-actin was ca. 350-400 pN. It was observed that the average retraction forces for each tip size correlated with the square of the tip radius.

Fluorescence emission and polarization analyses for evaluating binding of ruthenium metalloglycoclusters to lectins and tetanus toxin C-fragment

We develop a fluorescent ruthenium metalloglycocluster for use as a powerful molecular probe in evaluating the binding between carbohydrates and lectins by fluorescence emission (FE) and fluorescence polarization (FP) analyses. Changes in the FE and FP of these metalloglycoclusters are measured following the addition of lectin [peanut agglutinin (PNA), Ricinus communis agglutinin 120, Concanavalin A (ConA), or wheat germ agglutinin] or tetanus toxin c-fragment (TCF). After the addition of PNA, the FE spectrum of [Ru(bpy-2Gal)(3)] shows a new emission peak and the FP value of [Ru(bpy-2Gal)(3)] increases. Similarly, the FE spectrum of [Ru(bpy-2Glc)(3)] shows a new emission peak and the FP value increases on addition of ConA. Because other combinations of metalloglycoclusters and lectins show little change, specific binding of galactose to PNA and that of glucose to ConA are confirmed by the FE and FP measurements. Resulting dissociation constants (K(d)) prove that the metalloglycoclusters with highly clustered carbohydrates show higher affinity for the respective lectins than those with less clustered carbohydrates. Furthermore, specific binding of [Ru(bpy-2Gal)(3)] to TCF was confirmed by the FP measurement.

Immobilization of carbohydrate clusters on a quartz crystal microbalance sensor surface

The immobilization of carbohydrates on gold surfaces is a prerequisite technology for carbohydrate-related studies, including those of carbohydrate-biomolecule interactions. Glycolipid domains in cell membranes, such as lipid rafts, are thought to play an important role in cell biology through their carbohydrate portions. To understand the recognition of glycolipid domains such as receptors for bacterial toxins and viruses, we immobilized clusters of carbohydrates on a gold surface by using polyamidoamine (PAMAM) dendrimers as a scaffold. The PAMAM dendrimers were adsorbed on the gold-coated surface of a quartz crystal microbalance (QCM) sensor and were observed by means of QCM with dissipation (QCM-D). After adsorption of the PAMAM dendrimers, lysoganglioside-GM(1) and 12-aminododecyl-N-acetylglucosaminide (GlcNAc-C12-NH(2)) were immobilized on the amino groups of PAMAM dendrimers by means of an NH(2) cross-linker. Immobilization of the carbohydrates was confirmed by observation of their specific interaction with anti-ganglioside GM(1) antibody or wheat germ agglutinin (WGA). Surfaces with different GlcNAc-C12-NH(2) cluster sizes and densities were prepared by varying the size of the PAMAM dendrimers or the concentration of GlcNAc-C12-NH(2) immobilized on the dendrimers, respectively. Analysis of the binding between the GlcNAc-C12-NH(2)-immobilized surface and WGA revealed that the size of the PAMAM dendrimers influenced the GlcNAc-C12-NH(2)-WGA interaction, with larger dendrimers resulting in higher WGA binding constants.

Intricate Recognition of Glycolipid-Like Compounds by HIV-1 Envelope Proteins Evaluated with Surface Plasmon Resonance Imaging

Fusion of human immunodeficiency virus (HIV) to the cell membrane occurs by the specific binding of an envelope protein of HIV-1 (gp120 and gp160) and a glycosphingolipid of the cell membrane. In this study, quantitative and array-based affinity evaluation of gp120 and gp160 was performed by surface plasmon resonance (SPR) and the SPR imaging technique using a substrate immobilized with glycolipid-like compounds (Gb3, GM3, and Lac). Quantitative affinity evaluation showed that gp160 specifically bound to Gb3 and Lac compared with GM3, whereas gp120 showed lower binding affinity and specificity. Array-based evaluation showed that gp160 binds to Gb3 more favorably than Lac and GM3.

Fluorescence Emission and Polarization Analyses for Evaluating Binding of Ruthenium Metalloglycocluster to Lectin and Tetanus Toxin C-Fragment

We have developed a fluorescent ruthenium metalloglycocluster as a powerful molecular probe for evaluating a binding event between carbohydrates and lectins by fluorescence emission (FE) and fluorescence polarization (FP) analysis. The fluorescent ruthenium metalloglycoclusters, [Ru(bpy-2Gal)3] and [Ru(bpy-2Glc)3], possess clustered galactose and glucose surrounding the ruthenium center. Changes in FE and FP of these metalloglycoclusters were measured by adding each lectin (Peanut agglutinin (PNA), Ricinus communis agglutinin 120 (RCA), Concanavalin A (ConA), or Wheat germ agglutinin (WGA)) or tetanus toxin c-fragment (TCF). Following the addition of PNA, the FE spectrum of [Ru(bpy- 2Gal)3] showed new emission peak and the FP value of [Ru(bpy-2Gal)3] increased. Similarly, the FE spectrum of [Ru(bpy-2Glc)3] showed new emission peak and the FP value increased following the addition of ConA. Since other combinations of the metalloglycoclusters and lectin caused little change, specific bindings of galactose to PNA and glucose to ConA were proved by the FE and FP measurement. From nonlinear least-squares fitting, dissociation constants (Kd) of [Ru(bpy-2Gal)3] to PNA was 6.1 μM, while the Kd values of [Ru(bpy)2(bpy-2Gal)] to PNA was ca. 10-4 M. Therefore, the clustered carbohydrates were proved to increase affinity to lectins. Furthermore, the FP measurements proved specific binding of [Ru(bpy-2Gal)3] to TCF.