The surface-sensitive optical technique of surface plasmon resonance (SPR) imaging is used to characterize ultrathin organic and biopolymer films at metal interfaces in a spatially resolved manner. Because of its high surface sensitivity and its ability to measure in real time the interaction of unlabeled biological molecules with arrays of surface-bound species, SPR imaging has the potential to become a powerful tool in biomolecular investigations. Recently, SPR imaging has been successfully implemented in the characterization of supported lipid bilayer films, the monitoring of antibody-antigen interactions at surfaces, and the study of DNA hybridization adsorption. The following is included in this review: (a) an introduction to the principles of surface plasmon resonance, (b) the details of SPR imaging instrumental design, (c) a short discussion concerning resolution, sensitivity, and quantitation in SPR imaging, (d) the details of DNA array fabrication on chemically modified gold surfaces, and (e) two examples that demonstrate the application of the SPR imaging technique to the study of protein-DNA interactions.
Surface plasmon resonance (SPR) imaging is a surface-sensitive spectroscopic technique for measuring interactions between unlabeled biological molecules with arrays of surface-bound species. In this paper, SPR imaging is used to quantitatively detect the hybridization adsorption of short (18-base) unlabeled DNA oligonucleotides at low concentration, as well as, for the first time, the hybridization adsorption of unlabeled RNA oligonucleotides and larger 16S ribosomal RNA (rRNA) isolated from the microbe Escherichia coli onto a DNA array. For the hybridization adsorption of both DNA and RNA oligonucleotides, a detection limit of 10 nM is reported; for large (1,500-base) 16S rRNA molecules, concentrations as low as 2 nM are detected. The covalent attachment of thiol-DNA probes to the gold surface leads to high surface probe density (10(12) molecules/cm2) and excellent probe stability that enables more than 25 cycles of hybridization and denaturing without loss in signal or specificity. Fresnel calculations are used to show that changes in percent reflectivity as measured by SPR imaging are linear with respect to surface coverage of adsorbed DNA oligonucleotides. Data from SPR imaging is used to construct a quantitative adsorption isotherm of the hybridization adsorption on a surface. DNA and RNA 18-mer oligonucleotide hybridization adsorption is found to follow a Langmuir isotherm with an adsorption coefficient of 1.8 x 10(7) M(-1).
The effect of a specifically adsorbed ion, phosphate, on the electrochemical response and adsorption properties of nanocrystalline TiO2 is examined. Phosphate is known to affect the ζ potential, as measured by electrophoretic mobility, by changing the charge of the oxide surface. The adsorption of a cationic probe molecule, thionine, onto TiO2 was monitored with an in-situ cell using UV−vis spectroscopy. The adsorption of the cationic dye molecule was found to be governed by changes in the ζ potential, whether the ζ potential was modified by pH or by changes in phosphate concentration. Onset potential measurements were used to estimate the flat-band potential of a Ti/TiO2 electrode. The flat-band potential results for the electrode showed a nearly Nernstian response to changes in the pH for a broad pH range. The addition of phosphate had no effect on the onset potential or on the shape of the photocurrent/potential curve. Flat-band potentials determined by Mott−Schottky analysis in the absence of phosphate were Nernstian only for pH 3−7, matching the pH dependence of the electrophoretic mobility results. With the addition of phosphate, impedance spectroscopy results showed additional space charge capacitance, peaking at potentials 150 mV positive of the flat-band potential. UV irradiation also resulted in an additional space charge capacitance. For both cases, the additional space charge capacitance was accompanied by a decrease in the resistance of the electrode, as shown in Nyquist plots. The change in film conductivity is believed to affect the space charge layer capacitance. Similarly, a decrease in film resistance was also seen with lower pH values. Currently, this change in TiO2 film conductivity with surface acidity is being investigated in our laboratory for application in fuel cell electrolytes.
In this paper, we describe the detection of bacterial cell-extracted 16S ribosomal RNA (rRNA) using an emerging technology, surface plasmon resonance (SPR) imaging of DNA arrays. Surface plasmon resonance enables detection of molecular interactions on surfaces in response to changes in the index of refraction, therefore eliminating the need for a fluorescent or radioactive label. A variation of the more common SPR techniques, SPR imaging enables detection from multiple probes in a reusable array format. The arrays developed here contain DNA probes (15-21 bases) designed to be complementary to 16S rRNA gene sequences of Escherichia coli and Bacillus subtilis as well as to a highly conserved sequence found in rRNAs from most members of the domain Bacteria. We report species-specific hybridization of cell-extracted total RNA and in vitro transcribed 16S rRNA to oligonucleotide probes on SPR arrays. We tested multiple probe sequences for each species, and found that success or failure of hybridization was dependent upon probe position in the 16S rRNA molecule. It was also determined that one of the probes intended to bind 16S rRNA also bound an unknown protein. The amount of binding to these probes was quantified with SPR imaging. A detection limit of 2 micro g ml-1 was determined for fragmented E. coli total cellular RNA under the experimental conditions used. These results indicate the feasibility of using SPR imaging for 16S rRNA identification and encourage further development of this method for direct detection of other RNA molecules.
Protein microarrays are an increasingly powerful technology in the hunt for new and novel diagnostic and prognostic biomarkers. Lending credit to the highly established DNA microarray, protein microarrays are versatile tools that utilize a variety of formats to facilitate the discovery of new biomarkers and our understanding of disease pathways. The aims of this review are: to detail a variety of protein microarray technologies currently used, including forward-phase technologies and reverse-phase technologies useful in both the discovery and validation of candidate biomarkers; to explore the strengths and weaknesses of various proteomic microarray platforms; to explain how bioinformatics helps compare data between microarray data sets; and to discuss the downstream applications of such technologies as they relate to the development of a highly personalized approach to medicine.
In this protocol, we used the T24 human bladder cancer cell line as a source of native antigens to construct fractionated lysate microarrays. Subsequently, these microarrays were used to compare the autoantibody responses of individuals with interstitial cystitis/painful bladder syndrome (IC/PBS) to those of normal female controls. To accomplish this, T24 cells were lysed under nondenaturing conditions to obtain native antigens. These native antigens were then fractionated in 2D using a PF-2D liquid chromatography; the first dimension separated the proteins by their isoelectric points, and the second separated them according to hydrophobicity. The resulting protein fractions were printed onto nitrocellulose-coated glass slides (PATH slides) to create a set of fractionated lysate microarrays. To compare the autoantibody responses of IC/PBS patients with normal controls, the fractionated lysate arrays were competitively hybridized with fluorescently labeled IgG samples purified from both IC/PBS and control sera. This protocol presents a detailed description of the creation and use of native antigen fractionated lysate microarrays for autoantibody profiling.
Protein glycosylation, the enzymatic linkage of mono- and poly-saccharides to proteins, is a critical determinant of protein function; however, there is a lack of tools for studying the glycosylation of specific proteins in complex samples. A new type of antibody-lectin sandwich assay enables the measurement of the glycosylation of specific proteins that have been captured from complex samples using antibody arrays combined with lectin-based detection probes. Antibody-lectin sandwich arrays have the potential to expand our understanding of the role of glycans and protein glycosylation in disease and to identify and investigate new biomarkers for early detection, disease prognosis and therapeutic response prediction. While antibody-lectin sandwich arrays yield less-detailed structural information regarding protein glycosylation than other available methods, they do provide a simple and reproducible method for investigating changes in protein abundance and glycosylation of multiple proteins and can be easily applied to large or small sample sets. By profiling protein and glycan variations, new disease-associated glycan alterations can be identified and validated for use as biomarkers.
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