Abstract
The detection and quantification of specific proteins in complex mixtures is a major challenge for proteomics. For example, the development of disease-related biomarker panels will require fast and efficient methods for obtaining multiparameter protein profiles. We established a high throughput, label-free method for analyzing serum using surface plasmon resonance imaging of antibody microarrays. Microarrays were fabricated using standard pin spotting on bare gold substrates, and samples were applied for binding analysis using a camera-based surface plasmon resonance system. We validated the system by measuring the concentrations of four serum proteins using part of a 792-feature microarray. Transferrin concentrations were measured to be 2.1 mg/ml in human serum and 1.2 mg/ml in murine serum, which closely matched ELISA determinations of 2.6 and 1.2 mg/ml, respectively. In agreement with expected values, human and mouse albumin levels were measured to be 24.3 and 23.6 mg/ml, respectively. The lower limits of detection for the four measurements ranged from 14 to 58 ng/ml or 175 to 755 pm. Where purified target proteins are not available for calibration, the microarrays can be used for relative protein quantification. We used the antibody microarray to compare the serum protein profiles from three liver cancer patients and three non-liver cancer patients. Hierarchical clustering of the serum protein levels clearly distinguished two distinct profiles. Thirty-nine significant protein changes were detected (p < 0.05), 10 of which have been observed previously in serum. alpha-Fetoprotein, a known liver cancer marker, was observed to increase. These results demonstrate the feasibility of this high throughput approach for both absolute and relative protein expression profiling.
Highlights
The detection and quantification of specific proteins in complex mixtures is a major challenge for proteomics
SPRI has been used to monitor a wide range of molecular interactions including carbohydrate-protein, peptide-protein, 1 The abbreviations used are: SPR, surface plasmon resonance; SPRI, surface plasmon resonance imaging; a positive control. ␣-Fetoprotein (AFP), ␣-fetoprotein; hepatic cell carcinoma (HCC), hepatocellular carcinoma; kfwd, kinetic on-rate constant; krev, kinetic off-rate constant; RIU, refractive index unit; RIU, microrefractive index unit; TIGR MeV, The Institute for Genomic Research Multiexperiment Viewer; ISB, Institute for Systems Biology
This study of serum samples found that accurate, absolute proteomics quantification could be obtained from a high throughput microarray system
Summary
The detection and quantification of specific proteins in complex mixtures is a major challenge for proteomics. We established a high throughput, label-free method for analyzing serum using surface plasmon resonance imaging of antibody microarrays. SPR1 imaging monitors protein-binding microarrays in a manner that is label-free, real time, and reusable. Binding events at predefined positions increase the local refractive index, changing the reflectance pattern across the surface This pattern is recorded in real time using a charge-coupled device camera (see Fig. 1.) Protein concentrations in a sample solution are determined by monitoring the changing of the refractive index that is caused by interaction of capture molecules on the surface with the targeted proteins [11]. The ProteomicProcessorTM (Plexera Bioscience, Bothell, WA) is a Kretschmann configuration SPRI instrument that can monitor the binding kinetics on a 1350-feature microarray with good detection limits (ϳ0.3 ng of protein/cm2) and a time resolution of 1 s [12]. SPRI has been used to monitor a wide range of molecular interactions including carbohydrate-protein, peptide-protein, 2464 Molecular & Cellular Proteomics 7.12
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