Chiuan-Chian Chiou

Urinary 8-hydroxydeoxyguanosine and its analogs as DNA marker of oxidative stress: development of an ELISA and measurement in both bladder and prostate cancers

BACKGROUND 8-hydroxydeoxyguanosine (8-OHdG) is the most frequently detected and studied DNA lesion. Upon DNA repair, 8-OHdG is excreted in the urine. Urinary 8-OHdG is now considered as a biomarker of generalized, cellular oxidative stress and is linked to degenerative diseases including cancer. METHODS We developed a competitive enzyme-linked immunosorbent assay (ELISA) for urinary 8-OHdG by coating BSA conjugated 8-hydroxyguanine (8-OHG) on a microplate. Urine specimens containing 8-OHdG and monoclonal anti-8-OHdG antibody were incubated together in the microwell. Final quantification of bound anti-8-OHdG antibody was estimated by the addition of HRP-conjugated sheep-anti-mouse antibody. RESULTS The concentration range of the calibration curve was 0-60 ng/ml. The sensitivity of the assay was 0.5 ng/ml. The within-day precision and day-to-day precision were <10%. The ELISA correlated well with a commercial kit (r=0.9). Our assay measured not only 8-OHdG but also 8-OHG and 8-hyroxyguanine in urine. Increased urinary concentration of 8-OHdG and its analogs were detected in both patients with bladder cancer (70.5+/-38.2 ng/mg creatinine) and prostate cancer (58.8+/-43.4 ng/mg creatinine) as compared to the healthy control (36.1+/-24.5 ng/mg creatinine). CONCLUSION Our preliminary data suggest that the competitive ELISA for 8-OHdG and its analogs appears to be a simple method for quantifying the extent of oxidative stress and may have potential for identifying cancer risk.

Detection of rare mutant K-ras DNA in a single-tube reaction using peptide nucleic acid as both PCR clamp and sensor probe

The major problem of using somatic mutations as markers of malignancy is that the clinical samples are frequently containing a trace amounts of mutant allele in a large excess of wild-type DNA. Most methods developed thus far for the purpose of tickling this difficult problem require multiple procedural steps that are laborious. We report herein the development of a rapid and simple protocol for detecting a trace amounts of mutant K-ras in a single tube, one-step format. In a capillary PCR, a 17mer peptide nucleic acid (PNA) complementary to the wild-type sequence and spanning codons 12 and 13 of the K-ras oncogene was used to clamp-PCR for wild-type, but not mutant alleles. The designated PNA was labeled with a fluorescent dye for use as a sensor probe, which differentiated all 12 possible mutations from the wild-type by a melting temperature (Tm) shift in a range of 9 to 16°C. An extension temperature of 60°C and an opposite primer 97 nt away from the PNA were required to obtain full suppression of wild-type PCR. After optimization, the reaction detected mutant templates in a ratio of 1:10 000 wild-type alleles. Using this newly devised protocol, we have been able to detect 19 mutants in a group of 24 serum samples obtained from patients with pancreatic cancer. Taken together, our data suggest that this newly devised protocol can serve as an useful tool for cancer screening as well as in the detection of rare mutation in many diseases.

Integrating solid-state sensor and microfluidic devices for glucose, urea and creatinine detection based on enzyme-carrying alginate microbeads

A solid-state sensor embedded microfluidic chip is demonstrated for the detection of glucose, urea and creatinine in human serum. In the presented device, magnetic powder-containing enzyme-carrying alginate microbeads are immobilized on the surface of an electrolyte-insulator-semiconductor (EIS) sensor by means of a step-like obstacle in the microchannel and an external magnetic force. The sample is injected into the microchannel and reacts with the enzyme contained within the alginate beads; prompting the release of hydrogen ions. The sample concentration is then evaluated by measuring the resulting change in the voltage signal of the EIS sensor. The reaction time and alginate bead size are optimized experimentally using a standard glucose solution. The experimental results show that the device has a detection range of 2-8mM, 1-16mM and 10(-2)-10mM for glucose, urea and creatinine, respectively. Furthermore, it is shown that the device is capable of sequentially measuring all three indicators in a human serum sample. Finally, it is shown that the measured values of the glucose, urea and creatinine concentrations obtained using the device deviate from those obtained using a commercial kit by just 5.17%, 6.22% and 13.53%, respectively. This method can be extended to sequentially measure multiple blood indicators in the sample chip by replacing different types of enzyme in alginate bead and can address the enzyme preservation issue in the microfluidic device. Overall, the results presented in this study indicate that the microfluidic chip has significant potential for blood monitoring in point-of-care applications.

Expression of caspid protein VP1 for use as antigen for the diagnosis of enterovirus 71 infection

To produce enterovirus 71 antigen for diagnostic purposes, the gene encoding the entire capsid protein VP1 was amplified by reverse transcription‐polymerase chain reaction (RT‐PCR), cloned and expressed in Escherichia coli as a poly‐histidine fusion protein. Western blotting experiments with sera from patients with enterovirus 71 infection indicated that immunoglobulin G (IgG) and IgM antibodies bound to a single polypeptide VP1. According to these results, IgM anti‐VP1 appeared in sera of patients with a symptomatic enterovirus 71 acute infection, whereas IgG anti‐VP1 was present in sera of past infection. This finding suggests that detecting IgG and IgM immune responses against linear epitopes of recombinant VP1 is an effective means of determining the different phases of enterovirus 71 infection. In addition, sera containing coxsackie virus 16 (CA16) antibodies did not cross‐react with the recombinant VP1 of enterovirus 71, despite the homology between VP1 proteins of both viruses. Comparison with reference PCR and neutralization assays showed these antibody tests to be appropriate for the serodiagnosis of enterovirus 71 infection. J. Med. Virol. 61:228–234, 2000.

Single-tube reaction using peptide nucleic acid as both PCR clamp and sensor probe for the detection of rare mutations

The detection of rare mutant DNA from a background of wild-type alleles usually requires laborious manipulations, such as restriction enzyme digestion and gel electrophoresis. Here, we describe a protocol for homogeneous detection of rare mutant DNA in a single tube. The protocol uses a peptide nucleic acid (PNA) as both PCR clamp and sensor probe. The PNA probe binds tightly to perfectly matched wild-type DNA template but not to mismatched mutant DNA sequences, which specifically inhibits the PCR amplification of wild-type alleles without interfering with the amplification of mutant DNA. A fluorescein tag (which undergoes fluorescence resonance energy transfer with the adjacent fluorophore of an anchor probe when both are annealed to the template DNA) also allows the PNA probe to generate unambiguous melting curves to detect mutant DNA during real-time fluorescent monitoring. The whole assay takes about only 1 h. This protocol has been used for detecting mutant K-ras DNA and could be applied to the detection of other rare mutant DNAs.

Spin-coated Au-nanohole arrays engineered by nanosphere lithography for a Staphylococcus aureus 16S rRNA electrochemical sensor

The nanopatterning of gold nanoparticle (AuNP) arrays on an indium tin oxide (ITO) electrode using efficient and low-cost methods is described. This process used nanosphere lithography (NSL) encompassing the deposition of monolayered Polystyrene (PS) followed by a convective self-assembly drop coating protocol onto the ITO substrate that further acted as the mask after the AuNP assembly. The results showed that spin-coating allowed AuNPs to follow the contour and adhere to the PS nanospheres. The final products, after etching the PS, generated a highly ordered Au-nanohole array on an ITO substrate. The Au-nanohole arrays on the ITO electrode provided a greater surface area and successfully enhanced the peak current of electrochemical measurements by 82% compared with bare ITO and was used to detect Staphylococcus aureus 16S rRNA hybridization. In contrast to non-templated AuNP structures, the Au-nanohole arrays on the ITO electrode contributed to an optimum sensitivity improvement in DNA hybridization detection by 23%, along with an impressive limit of detection (LOD) of 10 pM. The high specificity of this distinguished structure was also achieved in the hybridization measurements of multi-analyte pathogens. These findings indicate that the combination of PS nanosphere lithography, followed by the spin-coating of AuNPs, leads to an inexpensive and simple engineering process that effectively generates uniform Au-nanohole arrays on ITO, which provides a greater surface area to optimize the electrochemical performance of the DNA biosensor.

Solid-state sensor incorporated in microfluidic chip and magnetic-bead enzyme immobilization approach for creatinine and glucose detection in serum

Solid-state sensors are stable and inexpensive electric transducers for biomedical measurement. This study proposes a microfluidic chip incorporated with a solid-state sensor for measuring glucose and creatinine in blood serum. Magnetic beads are employed to immobilize enzymes and deliver them in a micro-channel. Glucose and creatinine can be measured at 2–8 mM and 10−2 to 10 mM, respectively, which is a meaningful range in human blood. The immobilization approach also addresses the issue of the long-term preservation of enzymes in microfluidic devices. The proposed device is suitable for multi-target measurement in a point-of-care system.

Development of a magnetic bead-based method for the collection of circulating extracellular vesicles.

Cells release different types of extracellular vesicles (EVs). These EVs contain biomolecules, including proteins and nucleic acids, from their parent cells, which can be useful for diagnostic applications. The aim of this study was to develop a convenient procedure to collect circulating EVs with detectable mRNA or other biomolecules. Magnetic beads coated with annexin A5 (ANX-beads), which bound to phosphatidylserine moieties on the surfaces of most EVs, were tested for their ability to capture induced apoptotic bodies in vitro and other phosphatidylserine-presenting vesicles in body fluids. Our results show that up to 60% of induced apoptotic bodies could be captured by the ANX-beads. The vesicles captured from cultured media or plasma contained amplifiable RNA. Suitable blood samples for EV collection included EDTA-plasma and serum but not heparin-plasma. In addition, EVs in plasma were labile to freeze-and-thaw cycles. In rodents xenografted with human cancer cells, tumor-derived mRNA could be detected in EVs captured from serum samples. Active proteins could be detected in EVs captured from ascites but not from plasma. In conclusion, we have developed a magnetic bead-based procedure for the collection of EVs from body fluids and proved that captured EVs contain biomolecules from their parent cells, and therefore have great potential for disease diagnosis.

Detection of pandemic (H1N1) 2009 influenza virus by allele discrimination.

BACKGROUND The pandemic (H1N1) 2009 has become a threat of public health. To manage rapidly increased infections and disease control, a simple and reliable first-line screening test for viral infection is on urgent demand. METHODS Through comprehensive bioinformatics analysis, a single nucleotide polymorphism in nucleoprotein gene which differentiates swine lineage virus and human seasonal H1N1 virus was selected as target. A TaqMan probe-based allele discrimination analysis was designed to analyze clinical samples. In total, 93 clinical specimens and 39 viral isolates were used to test the assay efficacy. Traditional viral culture and molecular analysis were used as gold standard. RESULTS The testing results showed that the established assay has high sensitivity and specificity (92% and 100%) for pandemic (H1N1) 2009. The assay could detect as low as 5 copies of NP gene of pandemic (H1N1) 2009 or 2 viral particles of human seasonal H1N1. CONCLUSION This assay can be used as a first-line screening and confirmation test for pandemic (H1N1) 2009 virus and human seasonal flu in one-tube reaction. The assay can serve as a convenient method to reduce the burden of PCR manipulation for diagnostic laboratories when large amount of samples need to be analyzed in a short time.

Monitoring triplex DNA formation with fluorescence resonance energy transfer between a fluorophore-labeled probe and intercalating dyes.

Triplex-forming oligonucleotides (TFOs) are sequence-dependent DNA binders that may be useful for DNA targeting and detection. A sensitive and convenient method to monitor triplex formation by a TFO and its target DNA duplex is required for the application of TFO probes. Here we describe a novel design by which triplex formation can be monitored homogeneously without prelabeling the target duplex. The design uses a TFO probe tagged with a fluorophore that undergoes fluorescence resonance energy transfer with fluorescent dyes that intercalate into the target duplex. Through color compensation analysis, the specific emission of the TFO probe reveals the status of the triple helices. We used this method to show that triple helix formation with TFOs is magnesium dependent. We also demonstrated that the TFO probe can be used for detection of sequence variation in melting analysis and for DNA quantitation in real-time polymerase chain reaction.