Yoshie Harada scite author profile

Cellular functions are fundamentally regulated by intracellular temperature, which influences biochemical reactions inside a cell. Despite the important contributions to biological and medical applications that it would offer, intracellular temperature mapping has not been achieved. Here we demonstrate the first intracellular temperature mapping based on a fluorescent polymeric thermometer and fluorescence lifetime imaging microscopy. The spatial and temperature resolutions of our thermometry were at the diffraction limited level (200 nm) and 0.18–0.58 °C. The intracellular temperature distribution we observed indicated that the nucleus and centrosome of a COS7 cell, both showed a significantly higher temperature than the cytoplasm and that the temperature gap between the nucleus and the cytoplasm differed depending on the cell cycle. The heat production from mitochondria was also observed as a proximal local temperature increase. These results showed that our new intracellular thermometry could determine an intrinsic relationship between the temperature and organelle function.

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Imaging of single fluorescent molecules and individual ATP turnovers by single myosin molecules in aqueous solution

Funatsu¹,

Harada²,

Tokunaga³

et al. 1995

Nature

1,020

762

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Visualization of single actin filaments by fluorescence microscopy led to the development of new in vitro assays for analysing actomyosin-based motility at the molecular level. The ability to manipulate actin filaments with a microneedle or an optical trap combined with position-sensitive detectors has enabled direct measurements of nanometre displacements and piconewton forces exerted by individual myosin molecules. To elucidate how myosin generates movement, it is necessary to understand how ATP hydrolysis is coupled to mechanical work at the level of the single molecule. But the most sensitive microscopic ATPase assay available still requires over 1,000 myosins. To enhance the sensitivity of such assays, we have refined epifluorescence and total internal reflection microscopies to visualize single fluorescent dye molecules. We report here that this approach can be used directly to image single fluorescently labelled myosin molecules and detect individual ATP turnover reactions. In contrast to previously reported single fluorescent molecule imaging methods, which used specimens immobilized on an air-dried surface, our method allows video-rate imaging of single molecules in aqueous solution, and hence can be applied to the study of many types of enzymes and biomolecules.

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Direct observation of single kinesin molecules moving along microtubules

Vale¹,

Funatsu²,

Pierce

et al. 1996

Nature

700

533

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Kinesin is a two-headed motor protein that powers organelle transport along microtubules. Many ATP molecules are hydrolysed by kinesin for each diffusional encounter with the microtubule. Here we report the development of a new assay in which the processive movement of individual fluorescently labelled kinesin molecules along a microtubule can be visualized directly; this observation is achieved by low-background total internal reflection fluorescence microscopy in the absence of attachment of the motor to a cargo (for example, an organelle or bead). The average distance travelled after a binding encounter with a microtubule is 600 nm, which reflects a approximately 1% probability of detachment per mechanical cycle. Surprisingly, processive movement could still be observed at salt concentrations as high as 0.3 M NaCl. Truncated kinesin molecules having only a single motor domain do not show detectable processive movement, which is consistent with a model in which kinesin's two force-generating heads operate by a hand-over-hand mechanism.

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Hydrophilic Fluorescent Nanogel Thermometer for Intracellular Thermometry

et al. 2009

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The first methodology to measure intracellular temperature is described. A highly hydrophilic fluorescent nanogel thermometer developed for this purpose stays in the cytoplasm and emits stronger fluorescence at a higher temperature. Thus, intracellular temperature variations associated with biological processes can be monitored by this novel thermometer with a temperature resolution of better than 0.5 degrees C.

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Mechanochemical coupling in actomyosin energy transduction studied by in vitro movement assay

Harada

Sakurada

Aoki

et al. 1990

Journal of Molecular Biology

501

412

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Yoshie Harada

Intracellular temperature mapping with a fluorescent polymeric thermometer and fluorescence lifetime imaging microscopy

Imaging of single fluorescent molecules and individual ATP turnovers by single myosin molecules in aqueous solution

Direct observation of single kinesin molecules moving along microtubules

Hydrophilic Fluorescent Nanogel Thermometer for Intracellular Thermometry

Mechanochemical coupling in actomyosin energy transduction studied by in vitro movement assay

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