Your search keyword '"Masaya Ishikawa"' showing total 4 results

1. A live imaging‐friendly slice culture method using collagen membranes

Author

Ari Ogaki, Tasuku Araki, Masaya Ishikawa, Yuji Ikegaya, and Ryuta Koyama

Subjects

hippocampus, imaging, microglia, slice culture, time‐lapse imaging, Therapeutics. Pharmacology, RM1-950, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Abstract Aim Organotypic brain slice culture preserves the geographical position of neurons and neuronal circuits. The slice cultures also maintain both non‐neuronal cell types and the surrounding extracellular matrix. The interface method has been widely used for slice cultures, in which brain slices are placed on semiporous polytetrafluoroethylene (PTFE) membranes. However, a low optical transparency of PTFE membrane makes it difficult to perform live imaging of deep regions of slice cultures using an inverted microscope. To overcome the issue, we evaluated the suitability of using collagen membranes for slice cultures, especially focusing on live imaging of the cellular dynamics of green fluorescent protein (GFP)‐expressing microglia. Methods Entorhinohippocampal slices were cultured on either collagen or PTFE membranes. The influence of membrane type on the ability to observe deep regions of slice cultures was examined by live imaging using an inverted microscope. Results Collagen membranes were thinner and had better optical transparency compared with PTFE membranes. There were no differences in cell viability, density of neurons or microglia. The densify of visible short branches of microglia in live imaging was higher in collagen membranes than PTFE membranes. Conclusion Collagen membranes are suitable for live imaging of cellular dynamics in slice cultures using an inverted microscope.

Published

2020

2. Preferential freezing avoidance localised in anthers and embryo sacs in winteringDaphne kamtschaticavar.jezoensisflower buds visualised by magnetic resonance imaging

Author

Masaya Ishikawa, Hiroyuki Ide, Tetsuya Tsujii, Timothy Stait‐Gardner, Hikaru Kubo, Norihisa Matsushita, Kenji Fukuda, William S. Price, and Yoji Arata

Subjects

Physiology, Freezing, Ice, Daphne, Flowers, Plant Science, Magnetic Resonance Imaging

Abstract

To explore diversity in cold hardiness mechanisms, high resolution magnetic resonance imaging (MRI) was used to visualise freezing behaviours in wintering Daphne kamtschatica var. jezoensis flower buds, which have naked florets and no bud scales. MRI images showed that anthers remained stably supercooled to the range from -14 to -21°C or lower while most other tissues froze by -7°C. Freezing of some anthers detected in MRI images between -14 and -21°C corresponded with numerous low temperature exotherms and also with the 'all-or-nothing' type of anther injuries. In ovules/pistils, only embryo sacs remained supercooled at -7°C or lower, but slowly dehydrated during further cooling. Cryomicroscopic observation revealed ice formation in the cavities of calyx tubes and pistils but detected no ice in embryo sacs or in anthers. The distribution of ice nucleation activity in floral tissues corroborated the tissue freezing behaviours. Filaments likely work as the ice blocking barrier that prevents ice intrusion from extracellularly frozen calyx tubes to connecting unfrozen anthers. Unique freezing behaviours were demonstrated in Daphne flower buds: preferential freezing avoidance in male and female gametophytes and their surrounding tissues (by stable supercooling in anthers and by supercooling with slow dehydration in embryo sacs) while the remaining tissues tolerate extracellular freezing.

Published

2022

3. Freezing behaviours in winteringCornus floridaflower bud tissues revisited using MRI

Author

William S. Price, Masaya Ishikawa, Hiroki Murakawa, Hideyuki Yamazaki, Yoji Arata, Kazuyuki Kuchitsu, and Hiroyuki Ide

Subjects

0106 biological sciences, 0301 basic medicine, Ice nucleation activity, Physiology, Bud, Stamen, Plant Science, Biology, 01 natural sciences, Microscopic observation, 03 medical and health sciences, Freezing behavior, Mri image, 030104 developmental biology, Botany, Biophysics, Ovule, Supercooling, 010606 plant biology & botany

Abstract

How plant tissues control their water behaviours (phase and movement) under subfreezing temperatures through adaptative strategies (freezing behaviours) is important for their survival. However, the fine details of freezing behaviours in complex organs and their regulation mechanisms are poorly understood, and non-invasive visualization/analysis is required. The localization/density of unfrozen water in wintering Cornus florida flower buds at subfreezing temperatures was visualized with high-resolution magnetic resonance imaging (MRI). This allowed tissue-specific freezing behaviours to be determined. MRI images revealed that individual anthers and ovules remained stably supercooled to -14 to -21 °C or lower. The signal from other floral tissues decreased during cooling to -7 °C, which likely indicates their extracellular freezing. Microscopic observation and differential thermal analyses revealed that the abrupt breakdown of supercooled individual ovules and anthers resulted in their all-or-nothing type of injuries. The distribution of ice nucleation activity in flower buds determined using a test tube-based assay corroborated which tissues primarily froze. MRI is a powerful tool for non-invasively visualizing unfrozen tissues. Freezing events and/or dehydration events can be located by digital comparison of MRI images acquired at different temperatures. Only anthers and ovules preferentially remaining unfrozen are a novel freezing behaviour in flower buds. Physicochemical and biological mechanisms/implications are discussed.

Published

2016

4. Extraorgan freezing in wintering flower buds of Cornus officinalis Sieb. et Zucc

Author

Masaya Ishikawa and Akira Sakai

Subjects

biology, Physiology, Cold resistance, Cornaceae, Botany, Ice nucleus, Flor, Plant Science, Cornus officinalis, Supercooling, biology.organism_classification, Vascular tissue

Published

1985