Your search keyword '"Masaya Ishikawa"' showing total 21 results

1. Effect of Mixing Erythritol and Its Fluorine Analogues to Suppress Supercooling

Author

Masaya Ishikawa, Satoru Tsukada, Xudong Tang, Daiju Wada, Katsuyoshi Hoshino, and Junichi Ryu

Subjects

Chemistry, QD1-999

Published

2024

2. 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

3. Design of Mixed-Signal LSI with Analog Spiking Neural Network and Digital Inference Circuits for Reservoir Computing.

Author

Satoshi Moriya, Hideaki Yamamoto, Masaya Ishikawa, Yasushi Yuminaka, Yoshihiko Horio, Jordi Madrenas, and Shigeo Sato

Published

2024

4. Image Processing Methods and the Utility of Diffusion Models for Architectural Exterior Inspection by Day and Night.

Author

Masaya Ishikawa, Nobuhiro Okada, and Takuya Ikeda

Published

2024

5. Magnetact Animals: A Simple Kinetic Toy Kit for a Creative Online Workshop for Children.

Author

Kentaro Yasu and Masaya Ishikawa

Published

2021

6. Construction of environment for the evaluation of the subjectivity of brightness suitable for indoor activities.

Author

Kenji Okamoto, Masaya Ishikawa, Takayuki Misu, and Masao Isshiki

Published

2016

7. Complex-valued online classifier.

Author

Masaya Ishikawa and Kazuyuki Murase

Published

2016

8. 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

9. Research on Image Processing Methods and Deep Learning Models in Structural Exterior Inspection

Author

Masaya Ishikawa, Nobuhiro Okada, and Takuya Ikeda

Published

2022

10. Generation of human induced pluripotent stem cell-derived functional enterocyte-like cells for pharmacokinetic studies

Author

Hiroyuki Kusuhara, Sylvia Leo, Takayuki Honjo, Shinpei Yoshida, Ryunosuke Ishibe, Teruhiko Watanabe, Nobuaki Shiraki, Shoen Kume, Masaya Ishikawa, Tomoka Shimada, Kazuya Maeda, and Keita Iino

Subjects

0301 basic medicine, Adult, Male, Enterocyte, induced pluripotent stem cells, Cell Culture Techniques, enterocyte, Biology, Biochemistry, Article, Cell Line, 03 medical and health sciences, Young Adult, 0302 clinical medicine, in vitro differentiation, Intestine, Small, Genetics, medicine, ATP Binding Cassette Transporter, Subfamily G, Member 2, Cytochrome P-450 CYP3A, Humans, Progenitor cell, Induced pluripotent stem cell, intestine, Cells, Cultured, CYP3A4, Cell Differentiation, Cell Biology, Metabolism, Middle Aged, human model, Embryonic stem cell, drug development, Small intestine, Cell biology, Culture Media, Neoplasm Proteins, 030104 developmental biology, medicine.anatomical_structure, Enterocytes, Female, Efflux, Collagen, pharmacokinetics, 030217 neurology & neurosurgery, Developmental Biology

Abstract

Summary We aimed to establish an in vitro differentiation procedure to generate matured small intestinal cells mimicking human small intestine from human-induced pluripotent stem cells (iPSCs). We previously reported the efficient generation of CDX2-expressing intestinal progenitor cells from embryonic stem cells (ESCs) using 6-bromoindirubin-3′-oxime (BIO) and (3,5-difluorophenylacetyl)-L-alanyl-L-2-phenylglycine tert-butyl ester (DAPT) to treat definitive endodermal cells. Here, we demonstrate the generation of enterocyte-like cells by culturing human iPSC-derived intestinal progenitor cells on a collagen vitrigel membrane (CVM) and treating cells with a simple maturation medium containing BIO, DMSO, dexamethasone, and activated vitamin D3. Functional tests further confirmed that these iPSC-derived enterocyte-like cells exhibit P-gp- and BCRP-mediated efflux and cytochrome P450 3A4 (CYP3A4)-mediated metabolism. We concluded that hiPS cell-derived enterocyte-like cells can be used as a model for the evaluation of drug transport and metabolism studies in the human small intestine., Highlights • hiPSC-derived intestinal progenitors are differentiated into enterocytes • The collagen vitrigel membrane supports hiPSCs to mature into functional enterocytes • iPSC-derived enterocytes show efflux transporter and metabolizing enzyme activities • iPSC-derived enterocytes can be used as a human small intestine model, We established a culture procedure to generate hiPSC-derived enterocyte-like cells that can be used as a model for the evaluation of drug transport and metabolism studies in the human small intestine.

Published

2021

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

Author

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

Subjects

hippocampus, Micro Reports, microglia, slice culture, Mice, Transgenic, Green fluorescent protein, Extracellular matrix, Micro Report, time‐lapse imaging, Mice, Slice preparation, Organ Culture Techniques, Live cell imaging, Animals, Pharmacology (medical), Wafer, Pharmacology, Chemistry, Collagen membrane, Inverted microscope, imaging, Membranes, Artificial, Mice, Inbred C57BL, Psychiatry and Mental health, Clinical Psychology, Membrane, Animals, Newborn, Collagen, Biomedical engineering

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., Live imaging of organotypic slice cultures has been a useful method to study cell dynamics. One remaining issue with live imaging of slice cultures is the low transparency of commonly used polytetrafluoroethylene membranes. Here we report that slice culture membranes made of collagen can solve the issue of low transparency, facilitating live imaging of small cellular structures such as microglial processes.

Published

2020

12. Preferential freezing avoidance localized in anthers and embryo sacs in wintering Daphne kamtschatica var. jezoensis flower buds visualized by MRI

Author

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

Abstract

To explore diversity in cold hardiness mechanisms, high resolution magnetic resonance imaging (MRI) was used to visualize freezing behaviors in wintering flower buds of Daphne kamtschatica var. jezoensis, which have no bud scales surrounding well-developed florets. MRI images showed that anthers remained stably supercooled to -14 ∼ -21°C or lower whilst most other tissues froze by -7°C. Freezing of some anthers detected in MRI images at ∼ -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 behaviors. Filaments likely work as the ice blocking barrier that prevents ice intrusion from extracellularly frozen calyx tubes to connecting unfrozen anthers. Unique freezing behaviors 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) whilst the remaining tissues tolerate extracellular freezing.

Published

2021

13. Conformational dependence of integrin-binding peptides derived from homologous loop regions in the laminin α chains

Author

Keisuke Hamada, Yuji Yamada, Fumihiko Katagiri, Masaya Ishikawa, Motoyoshi Nomizu, Yamato Kikkawa, and Jun Kumai

Subjects

Cell, Integrin, Molecular Conformation, 010402 general chemistry, 01 natural sciences, Biochemistry, Peptides, Cyclic, Protein Structure, Secondary, Cell Line, Structure-Activity Relationship, Protein Domains, Structural Biology, Laminin, Drug Discovery, medicine, Homologous chromosome, Cell Adhesion, Humans, Amino Acid Sequence, Cell adhesion, Molecular Biology, Integrin binding, Pharmacology, chemistry.chemical_classification, biology, 010405 organic chemistry, Organic Chemistry, General Medicine, Cyclic peptide, 0104 chemical sciences, Peptide Conformation, medicine.anatomical_structure, chemistry, Biophysics, biology.protein, Molecular Medicine, Integrin alpha2beta1, Protein Binding

Abstract

Laminin α chains (α1-α5 chains) are expressed in a tissue- and developmental stage-specific manner and have diverse chain-specific biological functions. Especially, laminin globular (LG) modules (LG1-LG5) located at the C-terminus of the α chains play a critical role in the biological activities of laminins. Each LG module is composed of a 14-stranded β-sheet (A-N) sandwich structure. We previously screened cell attachment activity of the loop regions between the E and F strands in the LG modules using 17 homologous peptides (EF peptides) and found that four active EF peptides bind to integrin α2β1. One of the four peptides, G4EF1 demonstrated improved cell attachment activity when cyclized. Here, we focused on the remaining three integrin α2β1-binding EF peptides (G5EF1, G3EF3, and G5EF5) and analyzed the relationship between their peptide conformation and cell attachment activity. First, we determined their active core sequences and found that G5EF1z (IGLEIVDGKVLFHVNN), G3EF3z (LLVTLEDGHIALST), and G5EF5z (KVLTEQVL) are the core sequences. Cyclic peptides of the core sequences (cycloG5EF1z, cycloG3EF3z, and cycloG5EF5z) enhanced integrin-mediated cell adhesion activity compared with their linear peptides. The results indicated that cell adhesion activity of the integrin α2β1-binding EF peptides is conformation dependent and that the loop structure is critical for their activity. This suggests that conformation of the loop regions plays an important role for the activities of the LG modules.

Published

2020

14. 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

15. Ice Nucleation Activity in Plants: The Distribution, Characterization, and Their Roles in Cold Hardiness Mechanisms

Author

Masaya, Ishikawa, Hideyuki, Yamazaki, Tadashi, Kishimoto, Hiroki, Murakawa, Timothy, Stait-Gardner, Kazuyuki, Kuchitsu, and William S, Price

Subjects

Species Specificity, Infrared Rays, Thermography, Acclimatization, Cold-Shock Response, Freezing, Ice, Biological Assay, Plants, Magnetic Resonance Imaging, Signal Transduction

Abstract

Control of freezing in plant tissues is a key issue in cold hardiness mechanisms. Yet freeze-regulation mechanisms remain mostly unexplored. Among them, ice nucleation activity (INA) is a primary factor involved in the initiation and regulation of freezing events in plant tissues, yet the details remain poorly understood. To address this, we developed a highly reproducible assay for determining plant tissue INA and noninvasive freeze visualization tools using MRI and infrared thermography. The results of visualization studies on plant freezing behaviors and INA survey of over 600 species tissues show that (1) freezing-sensitive plants tend to have low INA in their tissues (thus tend to transiently supercool), while wintering cold-hardy species have high INA in some specialized tissues; and (2) the high INA in cold-hardy tissues likely functions as a freezing sensor to initiate freezing at warm subzero temperatures at appropriate locations and timing, resulting in the induction of tissue-/species-specific freezing behaviors (e.g., extracellular freezing, extraorgan freezing) and the freezing order among tissues: from the primary freeze to the last tissue remaining unfrozen (likely INA level dependent). The spatiotemporal distributions of tissue INA, their characterization, and functional roles are detailed. INA assay principles, anti-nucleation activity (ANA), and freeze visualization tools are also described.

Published

2018

16. The Induction of Cold Acclimation: The Role of Abscisic

Author

Lawrence V. Gusta, Masaya Ishikawa, Albert J. Robertson, and Martin J. T. Reaney

Subjects

Horticulture, Cold acclimation, Biology

Published

2018

17. Ice Nucleation Activity in Plants: The Distribution, Characterization, and Their Roles in Cold Hardiness Mechanisms

Author

Hiroki Murakawa, William S. Price, Tadashi Kishimoto, Masaya Ishikawa, Hideyuki Yamazaki, Timothy Stait-Gardner, and Kazuyuki Kuchitsu

Subjects

0106 biological sciences, 0301 basic medicine, Ice nucleation activity, Chemistry, 01 natural sciences, Plant tissue, 03 medical and health sciences, Freezing behavior, 030104 developmental biology, Biophysics, Supercooling, Hardiness (plants), Freezing tolerance, 010606 plant biology & botany

Abstract

Control of freezing in plant tissues is a key issue in cold hardiness mechanisms. Yet freeze-regulation mechanisms remain mostly unexplored. Among them, ice nucleation activity (INA) is a primary factor involved in the initiation and regulation of freezing events in plant tissues, yet the details remain poorly understood. To address this, we developed a highly reproducible assay for determining plant tissue INA and noninvasive freeze visualization tools using MRI and infrared thermography. The results of visualization studies on plant freezing behaviors and INA survey of over 600 species tissues show that (1) freezing-sensitive plants tend to have low INA in their tissues (thus tend to transiently supercool), while wintering cold-hardy species have high INA in some specialized tissues; and (2) the high INA in cold-hardy tissues likely functions as a freezing sensor to initiate freezing at warm subzero temperatures at appropriate locations and timing, resulting in the induction of tissue-/species-specific freezing behaviors (e.g., extracellular freezing, extraorgan freezing) and the freezing order among tissues: from the primary freeze to the last tissue remaining unfrozen (likely INA level dependent). The spatiotemporal distributions of tissue INA, their characterization, and functional roles are detailed. INA assay principles, anti-nucleation activity (ANA), and freeze visualization tools are also described.

Published

2018

18. Freezing behaviours in wintering Cornus florida flower bud tissues revisited using MRI

Author

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

Subjects

Microscopy, Cornus, Freezing, Flowers, Magnetic Resonance Imaging

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

19. Ice nucleation activity in various tissues of Rhododendron flower buds: their relevance to extraorgan freezing

Author

Masaya Ishikawa, Mikiko Ishikawa, Takayuki Toyomasu, Takayuki Aoki, and William S. Price

Subjects

Stem bark, Rhododendron japonicum, Rhododendron, cold hardiness, Ice nucleation activity, Bud, Water source, Osmolality, Plant Science, azalea, lcsh:Plant culture, Biology, Extraorgan freezing, Botany, lcsh:SB1-1110, anti-nucleation activity, Supercooling, Water content, Original Research, Flower buds, Azalea

Abstract

Wintering flower buds of cold hardy Rhododendron japonicum cooled slowly to subfreezing temperatures are known to undergo extraorgan freezing, whose mechanisms remain obscure. We revisited this material to demonstrate why bud scales freeze first in spite of their lower water content, why florets remain deeply supercooled and how seasonal adaptive responses occur in regard to extraorgan freezing in flower buds. We determined ice nucleation activity (INA) of various flower bud tissues of using a test tube-based assay. Irrespective of collection sites, outer and inner bud scales that function as ice sinks in extraorgan freezing had high INA levels whilst florets that remain supercooled and act as a water source lacked INA. The INA level of bud scales was not high in late August when flower bud formation was ending, but increased to reach the highest level in late October just before the first autumnal freeze. The results support the following hypothesis: the high INA in bud scales functions as the subfreezing sensor, ensuring the primary freezing in bud scales at warmer subzero temperatures, which likely allows the migration of floret water to the bud scales and accumulation of icicles within the bud scales. The low INA in the florets helps them remain unfrozen by deep supercooling. The INA in the bud scales was resistant to grinding and autoclaving at 121°C for 15 min, implying the intrinsic nature of the INA rather than of microbial origin, whilst the INA in stem bark was autoclaving labile. Anti-nucleation activity (ANA) was implicated in the leachate of autoclaved bud scales, which suppresses the INA at millimolar levels of concentration and likely differs from the colligative effects of the solutes. The tissue INA levels likely contribute to the establishment of freezing behaviors by ensuring the order of freezing in the tissues: from the primary freeze to the last tissue remaining unfrozen.

Published

2015

20. OsATG7 is required for autophagy-dependent lipid metabolism in rice postmeiotic anther development

Author

Takamitsu Kurusu, Shigeru Hanamata, Chikako Yagi, Noriko Nagata, Takashi Yamamoto, Nobutaka Kitahata, Akio Miyao, Hirohiko Hirochika, Hiroaki Shimada, Amane Makino, Kazuki Saito, Hiroyuki Ishida, Tetsu Kinoshita, Nori Kurata, Kazuyuki Kuchitsu, Tomoko Koyano, Takahiko Kubo, Yuhei Noguchi, Takayuki Ohnishi, Yozo Okazaki, Daichi Ando, Masaya Ishikawa, Shinya Wada, Takamitsu Kurusu, Shigeru Hanamata, Chikako Yagi, Noriko Nagata, Takashi Yamamoto, Nobutaka Kitahata, Akio Miyao, Hirohiko Hirochika, Hiroaki Shimada, Amane Makino, Kazuki Saito, Hiroyuki Ishida, Tetsu Kinoshita, Nori Kurata, Kazuyuki Kuchitsu, Tomoko Koyano, Takahiko Kubo, Yuhei Noguchi, Takayuki Ohnishi, Yozo Okazaki, Daichi Ando, Masaya Ishikawa, and Shinya Wada

Published

2015

21. Factors contributing to deep supercooling capability and cold survival in dwarf bamboo (Sasa senanensis) leaf blades.

Author

Masaya Ishikawa, Asuka Oda, Reiko Fukami, and Akira Kuriyama

Subjects

BAMBOO, HARDINESS of plants, EFFECT of cold on plants, FROST resistance of plants, SUPERCOOLING, FREEZE-thaw cycles

Abstract

Wintering Sasa senanensis, dwarf bamboo, is known to employ deep supercooling as the mechanism of cold hardiness in most of its tissues from leaves to rhizomes. The breakdown of supercooling in leaf blades has been shown to proceed in a random and scattered manner with a small piece of tissue surrounded by longitudinal and transverse veins serving as the unit of freezing. The unique cold hardiness mechanism of this plant was further characterized using current year leaf blades. Cold hardiness levels (LT20: the lethal temperature at which 20% of the leaf blades are injured) seasonally increased from August (-11°C) to December (-20°C). This coincided with the increases in supercooling capability of the leaf blades as expressed by the initiation temperature of low temperature exotherms (LTE) detected in differential thermal analyses (DTA). When leaf blades were stored at -5°C for 1-14 days, there was no nucleation of the supercooled tissue units either in summer or winter. However, only summer leaf blades suffered significant injury after prolonged supercooling of the tissue units. This may be a novel type of low temperature-induced injury in supercooled state at subfreezing temperatures. When winter leaf blades were maintained at the threshold temperature (-20°C), a longer storage period (1-7 days) increased lethal freezing of the supercooled tissue units. Within a wintering shoot, the second or third leaf blade from the top was most cold hardy and leaf blades at lower positions tended to suffer more injury due to lethal freezing of the supercooled units. LTE were shifted to higher temperatures (2-5°C) after a lethal freeze-thaw cycle. The results demonstrate that the tissue unit compartmentalized with longitudinal and transverse veins serves as the unit of supercooling and temperature- and time-dependent freezing of the units is lethal both in laboratory freeze tests and in the field. To establish such supercooling in the unit, structural ice barriers such as development of sclerenchyma and biochemical mechanisms to increase the stability of supercooling are considered important. These mechanisms are discussed in regard to ecological and physiological significance in winter survival. [ABSTRACT FROM AUTHOR]

Published

2015