Tomoko Mineno

Red Fluorescent Probe for Monitoring the Dynamics of Cytoplasmic Calcium Ions

The development of sophisticated fluorescent probes has contributed to the elucidation of the molecular mechanisms of many complex biological phenomena. In particular, fluorescence imaging of the calcium ion (Ca) has become an essential technique for the investigation of signaling pathways involving Ca as a second messenger. For example, changes in the intracellular Ca concentration have been found to be related to physiological responses in obesity, as well as immune responses and pathological responses in Alzheimer s disease. Because Ca signaling is involved in so many biological phenomena, it is expected that the simultaneous visualization of Ca and other biomolecules, that is, multicolor imaging, would be particularly informative. For this purpose, we require a fluorescent probe for Ca that operates in a different color window from that of probes for other molecules. Fluorescent Ca sensors can be categorized into twomain classes: those based on genetically encoded fluorescent proteins and those based on fluorescent small organic molecules. Although both types of sensors have certain advantages and drawbacks, small-molecule-based probes have the particular advantage that their AM ester form (cell-permeable acetoxymethyl ester derivative) can be readily bulk loaded into live cells with no need for transfection. Most currently used small-molecular fluorescent probes for Ca are fluorescein-based, such as Fluo-3, Fluo-4, Calcium Green-1, and Oregon Green 488 BAPTA-1, and emit green fluorescence (ca. 527 nm). There are also some redemitting fluorescent probes for Ca, such as Rhod-2 (ca. 576 nm), which is based on the rhodamine scaffold. These red-emitting fluorescent probes for Ca, including Rhod-2, are also widely used for biological studies; however, the cationic nature of the rhodamine scaffold generally causes Rhod-2 AM to localize into mitochondria. Although this behavior is useful for monitoring the Ca dynamics of mitochondria, the visualization of cytoplasmic Ca is much more important for research on Ca signaling. The influx of Ca into the cytoplasm from the extracellular environment and/or from intracellular stores (including the endoplasmic reticulum) triggers numerous cellular responses mediated by the interaction of Ca with various Ca-binding proteins, such as calmodulin and troponin C. Fura Red is a representative near-infrared fluorescent probe for Ca that is often used in biological research. However, it has extremely low fluorescence quantum efficiency (Ffl 0.013). Accordingly, the fluorescence signal is very small unless a high concentration of Fura Red or a high-powered laser is used. However, the use of a high dye concentration has a buffering effect on Ca, whereas the use of a high laser power causes rapid photobleaching of the dye and phototoxicity to the cells. Thus, a novel fluorescent probe for cytoplasmic Ca with strong emission in the long-wavelength region would be extremely useful, especially for multicolor imaging. In the present study, we designed and synthesized a novel and practical red-fluorescence-emitting probe suitable for monitoring cytoplasmic Ca and confirmed its usefulness for the visualization of stimulus-induced Ca oscillation in HeLa cells. As a fluorophore that emits in the red region, we chose TokyoMagenta (TM). The absorption and fluorescence wavelengths of this fluorescein analogue are 90 nm longer than those of fluorescein. TM was also expected to retain the advantages of the fluorescein scaffold, including cytoplasmic localization. For the development of the red fluorescent probe, we chose a combination of 2-Me-substituted TM as the fluorescent moiety and 1,2-bis(o-aminophenoxy)ethaneN,N,N’,N’-tetraacetic acid (BAPTA) as a specific chelator for Ca, and synthesized CaTM-1 (Figure 1; see also Scheme S1 in the Supporting Information). The fluorescence-activation ratio of CaTM-1 in the presence/absence of Ca is 5.6:1 (Figure 2a,b, Table 1). To further improve this ratio, we decided on the strategy of decreasing the energy of the highest occupied molecular orbital (HOMO) of the fluorophore to obtain a high level of [*] T. Egawa, K. Hirabayashi, Dr. Y. Koide, C. Kobayashi, Dr. N. Takahashi, Dr. T. Terai, Dr. T. Ueno, Dr. T. Komatsu, Dr. Y. Ikegaya, Prof. N. Matsuki, Prof. T. Nagano, Dr. K. Hanaoka Graduate School of Pharmaceutical Sciences The University of Tokyo 7-3-1 Hongo, Bunkyo-ku, Tokyo 113-0033 (Japan) E-mail: khanaoka@mol.f.u-tokyo.ac.jp

Acylated glycosides of hydroxy fatty acid methyl esters generated from the crude resin glycoside (pharbitin) of seeds of Pharbitis nil by treatment with indium(III) chloride in methanol.

Treatment of the crude ether-insoluble resin glycoside (convolvulin) from seeds of Pharbitis nil (Pharbitis Semen), called pharbitin, with indium(III) chloride in methanol provided seven oligoglycosides of hydroxy fatty acid methyl esters partially acylated by 2-methyl-3-hydroxybutyric (nilic) and 2S-methylbutyric acids. Their structures were elucidated on the basis of NMR and MS data and chemical conversions.

Identification of novel selective P2Y6 receptor antagonists by high-throughput screening assay

Aims: The P2Y6 nucleotide receptor is widely involved in inflammatory responses, and is a promising molecular target for the treatment of inflammatory diseases. Although several P2Y6 receptor antagonists have been developed and evaluated thus far, none has successfully been developed into a therapeutic drug. In this study, we explored new promising compounds that inhibit the human P2Y6 receptor. Main methods: High‐throughput screening (HTS) was used to study the effects of various compounds on human P2Y6 receptors expressed in 1321N1 human astrocytoma cells by monitoring intracellular Ca2 + concentration ([Ca2 +]i) levels using an FDSS7000 real‐time fluorescence detector. IL‐8 concentration was measured by enzyme‐linked immunosorbent assay. Key findings: Among structurally diverse chemical libraries totalling 141,700 compounds, 43 compounds with an inhibitory activity against the P2Y6 receptor were identified. Further studies using a dose‐response assay, receptor selectivity assay, and chemokine measurement assay revealed the selective P2Y6 receptor inhibitor TIM‐38, which inhibited UDP‐induced [Ca2 +]i elevation in a dose‐dependent manner. TIM‐38 had an IC50 value of 4.3 &mgr;M and inhibited P2Y6 without affecting the response induced by four other human P2Y or muscarinic receptors. In addition, TIM‐38 inhibited UDP‐induced interleukin‐8 release in a dose‐dependent manner without affecting releases caused by other stimulus such as interleukin‐1&bgr; or tumour necrosis factor‐&agr;. Analyses of TIM‐38 derivatives revealed that the nitro moiety is vital to P2Y6 receptor inhibition. Significance: TIM‐38 acts as a novel structural antagonist of P2Y6 receptor and may be a good lead compound for developing a P2Y6 receptor‐targeted anti‐inflammatory drug.

Acylated Glycosidic Acid Methyl Esters Generated from the Convolvulin Fraction of Rhizoma Jalapae Braziliensis by Treatment with Indium(III) Chloride in Methanol.

Four hexaglycosides of methyl 3S,12S-dihydroxyhexadecanoate (1-4) were provided after treatment of the crude convolvulin fraction from Rhizoma Jalapae Braziliensis (the root of Ipomoea operculata (GOMES) MART., Convolvulaceae) with indium(III) chloride in methanol. The structures of 1-4 were elucidated on the basis of spectroscopic and chemical methods. Their sugar moieties were partially acylated with organic acids including (3S,9R)-3,6:6,9-diepoxydecanoic (exogonic) acid, (E)-2-methylbut-2-enoic (tiglic) acid, and isovaleric acid.

Chloramine-T-Mediated Oxidation of Benzylic Alcohols Using Indium(III) Triflate

The efficient oxidation of benzylic alcohols to carbonyl compounds was performed using chloramine-T and a catalytic amount of indium(III) triflate. The primary benzylic alcohols were converted to the corresponding aldehydes in a good yield, and the secondary benzylic alcohols were oxidized to ketones in a high yield. The optimized reaction conditions required 0.3 eq of indium(III) triflate and the use of acetonitrile as a solvent.