Ki-Cheol Han

Selective Utilization of Fructose to Glucose by Candida magnoliae, an Erythritol Producer

Candida magnoliae isolated from honeycomb is an industrially important yeast with high erythritol-producing ability. Erythritol has been used as functional sugar substitute for various foods. In order to analyze the physiological properties of C. magnoliae, a study on sugar utilization pattern was carried out. The fermentation kinetics of glucose and fructose revealed that C. magnoliae has the discrepancy in glucose and fructose utilization when it produces erythritol. In contrast to most yeasts, C. magnoliae showed preference for fructose to glucose as a carbon source, deserving the designation of fructophilic yeast. Such a peculiar pattern of sugar utilization in C. magnoliae seems to be related to the evolutionary environment.

Highly sensitive detection of a bio-threat pathogen by gold nanoparticle-based oligonucleotide-linked immunosorbent assay

Francisella (F.) tularensis causes the zoonotic disease tularemia and categorized as one of the highest-priority biological agents. The sensing approaches utilized by conventional detection methods, including enzyme-linked immunosorbent assay (ELISA), are not sensitive enough to identify an infectious dose of this high-risk pathogen due to its low infective dose. As an attempt to detect F. tularensis with high sensitivity, we utilized the highly sensitive immunoassay system named gold nanoparticle-based oligonucleotide-linked immunosorbent assay (GNP-OLISA) which uses antibody-gold nanoparticles conjugated with DNA strands as a signal generator and RNA oligonucleotides appended with a fluorophore as a quencher for signal amplification. We modified the GNP-OLISA for the detection F. tularensis to utilize one antibody for both the capture of the target and for signal generation instead of using two different antibodies, which are usually employed to construct the antibody sandwich in the ELISA. The GNP-OLISA showed 37-fold higher sensitivity compared with ELISA and generated very consistent detection results in the sera. In addition, the detection specificity was not affected by the presence of non-target bacteria, suggesting that GNP-OLISA can be used as a sensitive detection platform for monitoring high-risk pathogens thereby overcoming the limit of the conventional assay system.

An approach to multiplexing an immunosorbent assay with antibody-oligonucleotide conjugates.

Early detection of cancer biomarkers provides clinically valuable information. While the conventional enzyme-linked immunosorbent assay (ELISA) has been routinely used for individual cancer markers, methods for simultaneous determination of multiple markers within a single sample are still in demand. Here, we present a novel oligonucleotide-linked immunosorbent assay (OLISA) with a multiplexing capability on the same microwell plate-based system as in ELISA. Employing a DNA oligonucleotide that is covalently conjugated to the detection antibody and a complementary RNA oligonucleotide which is appended with a fluorophore and a quencher, degradation of the RNA in the DNA-RNA duplex by RNase H is exploited for fluorescent signal generation. Iterative cycles of DNA-RNA duplexation and subsequent degradation of the RNA in the duplex by RNase H further lead to amplification of the detection signal in OLISA. Moreover, the use of antibody-oligonucleotide conjugates enables multiplexing of OLISA, which is successfully demonstrated by tethering DNA molecules to detection antibodies and by performing assays for three common cancer markers including α-fetoprotein, prostate-specific antigen, and carcinoembryonic antigen. With the simple procedure and reliable detection performance, the developed multiplex OLISA has a wide potential for use in analysis of a panel of biomarkers in clinical diagnostics.

Novel 6-N-arylcarboxamidopyrazolo[4,3-d]pyrimidin-7-one derivatives as potential anti-cancer agents.

A novel series of 3,5,6-trisubstituted pyrazolo[4,3-d]pyrimidin-7-one derivatives, especially 6-N-arylcarboxamidopyrazolo[4,3-d]pyrimidin-7-ones were synthesized and evaluated for their in vitro anticancer activities against various human cancer cell lines. The inhibitory activities for several kinases have also been tested. The prepared compounds library exhibited significant anticancer activity towards HT-29 colon and DU-145 prostate cancer cell lines. The structure-activity relationships of the 6-N-arylcarboxamidopyrazolo[4,3-d]pyrimidin-7-one scaffold at R(1), R(2) and R(3) have been elucidated. Among the synthesized compounds, 12b was the most active compound with GI(50) value of 0.44microM and 1.07microM against HT-29 and DU-145 cell lines, respectively, and 13a was the most selective compound towards colon cancer cell line.

Computational approach to the identification of novel Aurora-A inhibitors.

Aurora kinase A has been emerging as a key therapeutic target for the design of anticancer drugs. For the purpose of finding biologically active and novel compounds and providing new ideas for drug-design, we performed virtual screening using commercially available databases. A three-dimensional common feature pharmacophore model was developed with the HipHop program provided in the Catalyst software package, and this model was used as a query for screening the databases. A recursive partitioning (RP) model was developed as a filtering system, which was able to classify active and inactive compounds. Eventually, a step-wise virtual screening procedure was conducted by applying the common feature pharmacophore and the RP model in succession to discover novel potent Aurora-A inhibitors. A total of 68 compounds were selected for testing of their in vitro anticancer activities against various human cancer cell lines. Based on the activity data, we have identified fifteen compounds that warrant further investigation. Several compounds have a high inhibition rate (above 80% at 10 μM) and a GI₅₀ lower than 5 μM for the cell lines DU145 and HT29. Enzyme assay for these compounds identified hits with micro molar activity. Compound C11 has the highest activity (IC₅₀ = 5.09 μM). The hits obtained from this screening scheme could be potential drug candidates after further optimization.

Menadione and ethacrynic acid inhibit the hypoxia-inducible factor (HIF) pathway by disrupting HIF-1α interaction with p300

Hypoxia is a general characteristic of most solid malignancies and intimately related to neoplastic diseases and cancer progression. Homeostatic response to hypoxia is primarily mediated by hypoxia inducible factor (HIF)-1α that elicits transcriptional activity through recruitment of the CREB binding protein (CBP)/p300 coactivator. Targeted blockade of HIF-1α binding to CBP/p300 would thus constitute a novel approach for cancer treatment by suppressing tumor angiogenesis and metastasis. Here, we identified inhibitors against the interaction between HIF-1α and p300 by a fluorescence polarization-based assay employing a fluorescently-labeled peptide containing the C-terminal activation domain of HIF-1α. Two small molecule inhibitors, menadione (MD) and ethacrynic acid (EA), were found to decrease expression of luciferase under the control of hypoxia-responsive elements in hypoxic cells as well as to efficiently block the interaction between the full-length HIF-1α and p300. While these compounds did not alter the expression level of HIF-1α, they down-regulated expression of a HIF-1α target vascular endothelial growth factor (VEGF) gene. Considering hypoxia-induced VEGF expression leading to highly aggressive tumor growth, MD and EA may provide new scaffolds for development of tumor therapeutic reagents as well as tools for a better understanding of HIF-1α-mediated hypoxic regulation.

Recent Advances in Designing Substrate-Competitive Protein Kinase Inhibitors

Protein kinases play central roles in cellular signaling pathways and their abnormal phosphorylation activity is inseparably linked with various human diseases. Therefore, modulation of kinase activity using potent inhibitors is an attractive strategy for the treatment of human disease. While most protein kinase inhibitors in clinical development are mainly targeted to the highly conserved ATP-binding sites and thus likely promiscuously inhibit multiple kinases including kinases unrelated to diseases, protein substrate-competitive inhibitors are more selective and expected to be promising therapeutic agents. Most substrate-competitive inhibitors mimic peptides derived from substrate proteins, or from inhibitory domains within kinases or inhibitor proteins. In addition, bisubstrate inhibitors are generated by conjugating substrate-competitive peptide inhibitors to ATP-competitive inhibitors to improve affinity and selectivity. Although structural information on protein kinases provides invaluable guidance in designing substrate-competitive inhibitors, other strategies including bioinformatics, computational modeling, and high-throughput screening are often employed for developing specific substrate-competitive kinase inhibitors. This review focuses on recent advances in the design and discovery of substrate-competitive inhibitors of protein kinases.

Elongated oligonucleotide-linked immunosorbent assay for sensitive detection of a biomarker in a microwell plate-based platform

The immunoassay is a representative method for detecting disease biomarkers and pathogenic biological agents. While the conventional enzyme-linked immunosorbent assay (ELISA) has been routinely used for the analysis of biological samples, methods with higher sensitivity are still in demand because the detection of low-level biomarkers is important for early diagnosis of lethal diseases. In this study, we developed a sensitive immunoassay called elongated oligonucleotide-linked immunoassay (EOLISA), employing long DNA oligonucleotides (80-mer), a fluorogenic RNA probe and RNase H for signal amplification. The elongated DNA oligonucleotides led to a highly amplified fluorescence signal via iterative cycles of DNA-RNA duplexation and subsequent degradation of the RNA in the duplex by RNase H. The immunoassay was evaluated for sensitive detection of fatty acid binding protein (FABP) in the 0-1 ng mL(-1) range. When compared with ELISA, EOLISA showed about 10-fold improved detection sensitivity. With its simple procedure and reliable detection performance in the conventional platform, the proposed immunoassay is expected to have potential applications in clinical diagnostics.

An immunoassay utilizing the DNA-coated polydiacetylene micelles as a signal generator

Immunoassay is an important technique to detect the disease biomarkers and pathogenic biological agents which often present at low levels in clinical samples. To improve sensitivity of the immunoassay, here we described the DNA-coated, nano-sized micelles in which the DNA strands play a role as signal generators in an immunoassay. This micelle-based immunoassay was evaluated for quantitation of a liver cancer biomarker and the sensitivity of the method was compared with those of the conventional methods.

Stemness-Attenuating miR-503-3p as a Paracrine Factor to Regulate Growth of Cancer Stem Cells

Cancer stem cells (CSCs) with self-renewal abilities endorse cellular heterogeneity, resulting in metastasis and recurrence. However, there are no promising therapeutics directed against CSCs. Herein, we found that miR-503-3p inhibited tumor growth via the regulation of CSC proliferation and self-renewal. miR-503-3p, isolated from human adipose stem cell- (ASC-) derived exosomes, suppressed initiation and progression of CSCs as determined by anchorage-dependent (colony formation) and anchorage-independent (tumorsphere formation) assays. The expression of pluripotency genes was significantly decreased in miR-503-3p-treated CSCs. Furthermore, xenografts, which received miR-503-3p, exhibited remarkably reduced tumor growth in vivo. Thus, miR-503-3p may function as a stemness-attenuating factor via cell-to-cell communications.