Application of microchip phosphate-affinity electrophoresis to measurement of protease activity in complex samples.

We previously demonstrated microchip phosphate-affinity electrophoresis (µPAE) for activity measurement of kinases and phosphatases. In the current work, we extend the µPAE application to a protease: caspase-3 (CASP3). We designed a substrate peptide modified with both a fluorescent tag for label and a phosphate tag for separation. The CASP3 cleavage reaction split the two tags and made the fluorescent fragment migrate electrophoretically. The CASP3 activity was correlated with the amount of the migrating fragment. This assay was proven to be compatible with a crude cell lysate.

Rapid microRNA detection using power-free microfluidic chip: coaxial stacking effect enhances the sandwich hybridization.

We present a new method for rapid microRNA detection with a small volume of sample using the power-free microfluidic device driven by degassed PDMS. Target microRNA was detected by sandwich hybridization taking advantage of the coaxial stacking effect. This method allows us to detect miR-21 in 20 min with a 0.5 µL sample volume at a limit of detection of 0.62 nM. Since microRNAs can act as cancer markers, this method might substantially contribute to future point-of-care cancer diagnosis.

Activity measurement of protein kinase and protein phosphatase by microchip phosphate-affinity electrophoresis.

We previously proposed microchip-based phosphate-affinity electrophoresis (µPAE) and demonstrated its application to activity measurement of a tyrosine kinase, c-Src. In this study, we extended the µPAE application to a serine/threonine kinase, protein kinase A (PKA), and to a tyrosine phosphatase, leukocyte antigen-related protein tyrosine phosphatase (LAR PTPase). For standard peptide samples, we obtained linear calibration plots, and the limits of detection were 1.2% (PKA) and 1.5% (LAR PTPase) product peptides in the total peptides. The µPAE was also proven to be effective for unpurified enzyme reaction products.

SNP genotyping of unpurified PCR products by sandwich-type affinity electrophoresis on a microchip with programmed autonomous solution filling.

We demonstrate rapid single-nucleotide polymorphism (SNP) genotyping on a poly(dimethylsiloxane)-glass microchip. Sandwich-type affinity electrophoresis was employed to achieve sufficient specificity for reliable genotyping of unpurified PCR products. We tested three SNPs in different genes: CYP2D6 of artificial templates, and ALDH3A1 and CYP1A1 of human genomic samples. The target sequences were amplified by asymmetric PCR. For each SNP, we prepared a capture probe-poly(dimethylacrylamide) (CP-PDMA) conjugate and allele-specific, fluorescently-labeled detection probes (DPs). Prior to the electrophoresis, necessary solutions--the amplified sample, the CP-PDMA conjugate, the DPs, and a washer--were autonomously filled into their own regions of the microchannel in contact with each other. For precise control of this filling process, we have extended our published technique to a "programmed" version, in which additional passive stop valves synchronized the solution contacting events. Then we electrophoretically carried out a target DNA hybridization step, a DP hybridization step, and a washing step at the CP-PDMA conjugate region. This 3-step electrophoresis was completed in 2 min. The formation of the sandwich hybridization complex (CP-target-DP) was evaluated by fluorescence. Normalized fluorescence values of the different genotypes were clearly and reproducibly discriminated. The assay format presented here will be suitable for SNP genotyping at the point of care.

Phosphate-affinity electrophoresis on a microchip for determination of protein kinase activity.

We describe microchip-based phosphate-affinity electrophoresis (microPAE) for separation of peptides aimed at determination of kinase activity. The microPAE exploits two recently published technologies: autonomous sample injection for PDMS microchips and a phosphate-specific affinity ligand, Phos-tag. We prepared a fluorescently labeled substrate peptide, specific to human c-Src, and its phosphorylated form. We synthesized a Phos-tag-poly(dimethylacrylamide) conjugate. The conjugate and the sample solutions were autonomously injected into a PDMS-glass hybrid microchip. The two solutions were contacted together in the microchannel. When the peptides were electrophoresed into the Phos-tag-poly(dimethylacrylamide) region, the phosphorylated peptide was specifically trapped, and separated from the nonphosphorylated peptide in 10 s. The results were quantified by the areas of the fluorescence peaks. The calibration plot obtained with standard samples showed an excellent linearity and a LOD of 0.9% phosphorylated peptide among the total peptides. For c-Src-reacted samples, the results from the microPAE were in good agreement with those from matrix-assisted laser desorption/ionization time-of-flight mass spectrometry. The microPAE was also successful in the presence of inhibitors for c-Src. The measured 50% inhibitory concentration values for staurosporine, PP2, and SU6656 were in good agreement with the literature values.

Phosphorylation of Rho-associated kinase (Rho-kinase/ROCK/ROK) substrates by protein kinases A and C.

Rho-associated kinase (Rho-kinase/ROCK/ROK) is a serine/threonine kinase and plays an important role in various cellular functions. The cAMP-dependent protein kinase (protein kinase A/PKA) and protein kinase C (PKC) are also serine/threonine kinases, and directly and/or indirectly take part in the signal transduction pathways of Rho-kinase. They have similar phosphorylation site motifs, RXXS/T and RXS/T. The purpose of this study was to identify whether sites phosphorylated by Rho-kinase could be targets for PKA and PKC and to find peptide substrates that are specific to Rho-kinase, i.e., with no phosphorylation by PKA and PKC. A total of 18 substrates for Rho-kinase were tested for phosphorylation by PKA and PKC. Twelve of these sites were easily phosphorylated. These results mean that Rho-kinase substrates can be good substrates for PKA and/or PKC. On the other hand, six Rho-kinase substrates showing no or very low phosphorylation efficiency (<20%) for PKA and PKC were identified. Kinetic parameters (K(m) and k(cat)) showed that two of these peptides could be useful as substrates specific to Rho-kinase phosphorylation.

Mass-tag technology responding to intracellular signals as a novel assay system for the diagnosis of tumor.

A novel mass spectrometry-based assay system for determining protein kinase activity employing mass-tagged substrate peptide probes was used for the diagnosis of tumors. Two peptide probes (H-type and D-type) were synthesized containing the same substrate peptide sequence for protein kinase C (PKC). The molecular weights of the two probes differ because of the incorporation of deuterium into the acetyl groups of the D-type probe. The lysates of the normal and tumor tissue were prepared and reacted with the H- and D-type peptide probes, respectively. The PKC activities of the normal and tumor tissues can be compared simply and directly by calculating the phosphorylated ratio to each peptide probe, obtained from the peak intensity of the mass spectrum after mixing of the two reaction solutions. The phosphorylation ratio for the reaction of the H-type peptide probe with the tumor tissue lysate (B16 melanoma) was more than three times higher than that of the D type peptide probe with the normal skin tissue lysate. These results show that the novel assay system for detecting protein kinase activity using mass-tag technology can be a simple and useful means to profile protein kinase activity for cell or tissue lysate samples, and can be applied to the diagnosis of tumors.

A MutS protein-immobilized au electrode for detecting single-base mismatch of DNA.

A novel electrochemical biosensor was developed to detect gene mutation by using a DNA-mismatch binding protein: MutS from Escherichia coli. The MutS protein was immobilized onto an Au-electrode surface via complex formation between a histidine tag of the MutS protein and a thiol-modified nitrilotriacetic acid chemically adsorbed on the Au-electrode surface. When a target double-stranded DNA having a single-base mismatch was captured by the MutS protein on the electrode, some electrostatic repulsion arose between polyanionic DNA strands and anionic redox couple ions. Consequently, their redox peak currents on a cyclic voltammogram with the Au electrode drastically decreased, depending on the concentration of the target DNA, according to the redox couple-mediated artificial ion-channel principle. By using this assay, one can detect all types of single-base mismatch and single-base deletion.

Development of a fluorescence peptide chip for the detection of caspase activity.

Proteases play a key role in cell functions, and it is very important to monitor their activities for drug screening and diagnosis of diseases. In the present study, a new class of fluorescence probe, into which a fluorophore and a quencher have been introduced, was developed and applied to the on-chip detection of caspase-3 activity. This probe is non fluorescent in the absence of caspase-3. However, when it is treated with active caspase-3, the fluorescence intensity increases dependent on the caspase-3 activity due to the cleavage of the quencher-containing moiety on a glass slide. This caspase-dependent increase in the fluorescence intensity was also detected when the glass slide immobilizing the probe peptide was treated with cell lysate stimulated by staurosporine (STP), which is an apoptosis-inducing agent. On the other hand, such an increase was not detected in the case of control cell lysate without STP-stimulation. The developed system is a rapid and sensitive method and is useful for the direct measurement of protease activity on a glass array.

Gene mutation assay using a MutS protein-modified electrode.

A novel electrochemical biosensor for gene mutation detection was developed using a DNA mismatch recognizing protein MutS from E. coli. The MutS protein was immobilized onto an Au electrode by coordination of His-tag at its C-terminus to vacant sites of Ni(II)-nitrilotriacetato complex attached to the surface of electrode. When a target DNA duplex having a mismatch site was captured by the MutS protein on the electrode, the electrostatic repulsion arose between polyanionic DNA duplexes and negatively-charged ferrocyanide/ferricyanide redox couple ions. Consequently, their redox peak currents on a cyclic voltammogram with the Au electrode drastically decreased depending on the concentration of the target DNA according to the redox couple-mediated artificial ion-channel principle. Using this assay, we could detect GT mismatch and deletion mutation in the double-stranded DNA.