Aptameric system for the highly selective and ultrasensitive detection of protein in human serum based on non-stripping gold nanoparticles

A novel approach is proposed in this study for the development of an aptameric assay system for protein based on non-stripping gold nanoparticles (NPs)-triggered chemiluminescence (CL) upon target binding. The strategy chiefly depends on the formation of a sandwich-type immunocomplex among the capture antibody immobilized on the polystyrene microwells, target protein and aptamer-functionalized gold NPs. Introduction of target protein into the assay system leads to the attachment of gold NPs onto the surface of the microwells and thus the assembled gold NPs could trigger the reaction between luminol and AgNO(3) with a CL emission. Further signal amplification was achieved by a simple gold metal catalytic deposition onto the gold NPs. Such an amplified CL transduction allowed for the detection of model target IgE down to the 50 fM, which is better than most existing aptameric methods for IgE detection. This new protocol also provided a good capability in discriminating IgE from nontarget proteins such as IgG, IgA, IgM and interferon. The practical application of the proposed gold NPs-based immunoassay was successfully carried out for the determination of IgE in 35 human serum samples. Overall, the proposed assay system exhibits excellent analytical characteristics (e.g., a detection limit on the attomolar scale and a linear dynamic range of 4 orders of magnitude), and it is also straightforward to adapt this strategy to detect a spectrum of other proteins by using different aptamers. This new CL strategy might create a novel technology for developing simple biosensors in the sensitive and selective detection of target protein in a variety of clinical, environmental and biodefense applications.

Comparative image analysis of EGF immunoreaction in rat submandibular gland using 3,3'-diaminobenzidine with metal enhancer substrate

We have shown the efficacy of image analysis using 3,3'-diaminobenzidine (DAB) with a metal enhancer substrate for demonstrating quantitative differences in the amount of epidermal growth factor (EGF) in the submandibular gland from normal, castrated, and testosterone propionate (TP) treated castrated rats. Immunohistochemical determination of EGF visualized by DAB-nickel reagent was performed with image analysis using a computed image analyzer system (ACAS 570). Immunohistochemistry for EGF disclosed positive staining in granular convoluted tubule cells in the tissue sections from each experimental group. Using the tools of a competent data program installed in the ACAS 570 software, we measured quantitative differences among the experimental glands examined. Castration was shown to elicit a significant reduction in the EGF-positive area and staining intensity, and administration of TP to the castrated animals restored these parameters to levels greater than those of normal rats. Our study demonstrates that a simple, inexpensive, commercially available metal enhancer substrate can be applied accurately to the computer assisted quantification of histochemical hormone-induction studies.

Localization of apoptotic cells in the human epidermis by an in situ DNA nick end-labeling method using confocal reflectant laser microscopy

We describe an immunohistochemical method that allows the detection of apoptotic cells in human epidermis by use of confocal laser reflectance and antibody-immunogold-silver complexes. For this purpose, the site of free 3'-OH DNA ends was detected by the reflectance from heavy metal products (anti-digoxigenin antibody-immunogold-silver complexes) instead of 3, 3'-diaminobenzidine (DAB) reaction products in the conventional in situ nick end-labeling of DNA strand breaks (ISEL) technique. Localization of double-stranded DNA was demonstrated by the autofluorescence of methyl green. The ISEL technique using confocal reflectant laser microscopy (CRLM) clearly showed the most intense reflectance in the nuclei of granular cells, in contrast to only a weaker reflectance in those of basal cells. On the other hand, the extent of autofluorescence of methyl green was significantly more intense in the nuclei of basal cells and showed a reciprocal relation to that of the reflectance. Therefore, granular cells were most prone to apoptosis and did not contain double-stranded DNA, as indicated by the lack of stainability with methyl green. In addition, this method demonstrating the simultaneous localization of both free 3'-OH DNA ends and double-stranded DNA proved to have a wide range of applications, including the study of other DNA autolytic processes.