Yui Umehara scite author profile

Exogenous nucleic acids showed low efficiency regarding cellular uptake and low stability in biological conditions; therefore, a number of techniques have been developed to improve their basic properties. One of the best solutions is the application of nanosized particles consisting of oligonucleotides that penetrate the cell membrane without any additives and exhibit high stability in cells. In this report, we employed a simple approach to address the basic properties of nanoparticles of oligonucleotides in biological systems. We prepared BODIPY-labeled oligonucleotides that carried an exclusive modification at the strand end. BODIPY shows high hydrophobicity and fluorescent emission; therefore, the oligonucleotides formed nanosized aggregates in aqueous solution and their behaviors in cells or tissues were easily tracked. Detailed experiments revealed that aggregate formation was indispensable for the high cellular uptake of the oligonucleotides via scavenger-receptor-mediated endocytosis. In addition, the aggregates provided an efficient gene regulation in living cells and tumor tissues transplanted into mice.

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Confined Singlet Oxygen in Mesoporous Silica Nanoparticles: Selective Photochemical Oxidation of Small Molecules in Living Cells

Nakamura

Son

Umehara

et al. 2016

Bioconjugate Chem.

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Chemical conversion of specific bioactive molecules by external stimuli in living cells is a powerful noninvasive tool for clarification of biomolecular interactions and to control cellular functions. However, in chaotic biological environments, it has been difficult to induce arbitrary photochemical reactions on specific molecules because of their poor molecular selectivity. Here we report a selective and nontoxic photochemical reaction system utilizing photoactivated mesoporous silica nanoparticles to control biological functions. Methylene blue modification within nanoparticle pores for photosensitization produced singlet oxygen confined to the pore that could mediate selective oxidation of small molecules without any damage to living cells. This intracellular photochemical system produced bioactive molecules in situ and remotely controlled the cell cycle phase. We also confirmed that this photoreaction could be applied to control cell cycle phase in tumor tissue transplanted in mice. The cell cycle phase in the cells in mice, to which our system was administered, was arrested at the G2/M phase upon photoirradiation. We demonstrate a simple and promising method for the exogenous conversion of an intracellular biomolecule to another functional compound.

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Biological reduction of nitroimidazole-functionalized gold nanorods for photoacoustic imaging of tumor hypoxia

et al. 2019

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Tracking the Oxygen Status in the Cell Nucleus with a Hoechst‐Tagged Phosphorescent Ruthenium Complex

et al. 2018

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Molecular oxygen in living cells is distributed and consumed inhomogeneously, depending on the activity of each organelle. Therefore, tractable methods that can be used to monitor the oxygen status in each organelle are needed to understand cellular function. Here we report the design of a new oxygen-sensing probe for use in the cell nucleus. We prepared "Ru-Hoechsts", each consisting of a phosphorescent ruthenium complex linked to a Hoechst 33258 moiety, and characterized their properties as oxygen sensors. The Hoechst unit shows strong DNA-binding properties in the nucleus, and the ruthenium complex shows oxygen-dependent phosphorescence. Thus, Ru-Hoechsts accumulated in the cell nucleus and showed oxygen-dependent signals that could be monitored. Of the Ru-Hoechsts prepared in this study, Ru-Hoechst b, in which the ruthenium complex and the Hoechst unit were linked through a hexyl chain, showed the most suitable properties for monitoring the oxygen status. Ru-Hoechsts are probes with high potential for visualizing oxygen fluctuations in the nucleus.

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Yui Umehara

Aggregate Formation of BODIPY-Tethered Oligonucleotides That Led to Efficient Intracellular Penetration and Gene Regulation

Confined Singlet Oxygen in Mesoporous Silica Nanoparticles: Selective Photochemical Oxidation of Small Molecules in Living Cells

Biological reduction of nitroimidazole-functionalized gold nanorods for photoacoustic imaging of tumor hypoxia

Tracking the Oxygen Status in the Cell Nucleus with a Hoechst‐Tagged Phosphorescent Ruthenium Complex

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