A simple set-and-mix assay for screening of protein kinase inhibitors in cell lysates.

Here we developed a simple set-and-mix assay to perform high-throughput screening of protein kinase A (PKA) inhibitors from the LOPAC 1280 compound library. This assay is based on the color change of gold nanoparticles on aggregation induced by a cationic substrate peptide as coagulant. In spite of the simplicity of this assay system, this assay can be applied to drug screening based on cellular kinases. We successfully found several highly active inhibitors, including compounds that have not been reported before.

Gold nanoparticle-based colorimetric assay for cancer diagnosis.

A novel gold nanoparticle (GNP)-based colorimetric assay was developed for cancer diagnosis. This system is based on the noncrosslinking aggregation mechanism with a cationic protein kinase C (PKC) alpha-specific peptide substrate, which is used as a coagulant of citrate-coated GNP with anionic surface charges. The phosphorylation of peptide substrates by PKCalpha suppressed GNP aggregation, resulting in a red color, but in the case of non-phosphorylation, the color of the GNP solution changed from red to blue, indicating particle aggregation. Moreover, a correlation between the color change of the GNP dispersions and the level of activated PKCalpha was identified from experiments using cancer cell lines, or xenografted mouse cancer and normal mouse tissues. When our system was applied to human breast cancers and normal human breast tissues, cancer tissue lysates became red in color, indicating GNP dispersion, while all lysates from normal tissue turned the GNP solution blue. MALDI-TOF MS analysis and Western blotting experiment confirmed that these different results between cancer and normal tissues reflected the difference in PKCalpha activity. This study is the first report on the application of the GNP-based colorimetric assay to the diagnosis of cancer.

Design of polymeric carriers for cancer-specific gene targeting: utilization of abnormal protein kinase Calpha activation in cancer cells.

We succeeded in cancer cell specific gene expression by using a polyplex responsive to protein kinase Calpha, which is activated in various types of cancer cells.

Colorimetric enzymatic activity assay based on noncrosslinking aggregation of gold nanoparticles induced by adsorption of substrate peptides.

The mechanisms of colorimetric assays based on aggregation of gold nanoparticles (GNPs) have been separated into two categories, crosslinking, and noncrosslinking aggregation. The noncrosslinking aggregation has recently been emerging as a simple and rapid mechanism and has been applied to enzymatic activity assays and DNA detection. We report here the detailed study of an enzymatic activity assay for protein kinases based on noncrosslinking aggregation. The principle of the assay is to detect kinase activity by utilizing the difference of coagulating ability of a cationic substrate peptide and its phosphorylated form toward GNPs with anionic surface charge. The critical coagulation concentrations (CCCs) of the peptides were about 10(3) times lower than those of the metal cations with the same cationic charges. The multivalent coordination bonds of the functional groups of the peptides with the GNP surface will strongly support the adsorption of the peptide on the GNP surface. The effect of the GNP size (10, 20, 40, 60 nm) on the dynamic range of OD before and after aggregation was studied. The dynamic range became a maximum for 20 nm GNP among those studied. The difference of CCC between the phosphorylated and nonphosphorylated peptides was governed by (1) the ratio between the peptide concentration and the surface area concentration of GNP and (2) the net charge of the peptides. When the assay system was applied to the activity assessment of protein kinase A, the dynamic range of OD was largest for 20 nm GNPs. However, when the peptide concentration was lowered, the largest 60 nm GNP was advantageous because of its smaller specific surface area.