Production and Role of Molecular Hydrogen in Plants
Molecular hydrogen (hydrogen gas; H2) is gaining prominence in the scientific literature as well as the popular media. Early studies suggest the use of H2 treatment for a wide range of human diseases, from COVID-19 to various neurodegenerative diseases. Moreover, its biological activity also appears...
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Hancock, John edt Production and Role of Molecular Hydrogen in Plants Basel MDPI Books 2022 1 electronic resource (128 p.) text txt rdacontent computer c rdamedia online resource cr rdacarrier Molecular hydrogen (hydrogen gas; H2) is gaining prominence in the scientific literature as well as the popular media. Early studies suggest the use of H2 treatment for a wide range of human diseases, from COVID-19 to various neurodegenerative diseases. Moreover, its biological activity also appears to have therapeutic and regulatory effects in plants. Accordingly, it has been suggested to be useful in agricultural settings. H2 has effects on a range of physiological events in plants. It has been shown to have effects on seed germination, plant growth, and development. It has also been found to be involved in plant stress responses and to be protective against abiotic stress. It also has beneficial effects during the post-harvest storage of crops. Therefore, its use in the agricultural setting has great potential as it appears to be safe, with no toxicity or harm to the environment. One of the conundrums of the use of H2 is how it induces these effects in plants and plant cells. It is difficult to envisage how it works based on a classical receptor mechanism. There is evidence that it may act as a direct antioxidant, by scavenging hydroxyl radicals, or via enhancing the plant’s innate antioxidant system as a signaling molecule. It has also been reported to exert effects through action on heme oxygenase, cross-talk with other signaling molecules, and regulating the expression of various genes. However, how H2 fits into, and integrates with, other signaling pathways is not clearly understood. Future work is needed to elucidate the mechanism and significance of the interaction of H2 with these and other cellular systems. English Technology: general issues bicssc History of engineering & technology bicssc antioxidants heme oxygenase hydrogen gas hydrogenase hydroxyl radicals molecular hydrogen nitric oxide reactive oxygen species Chinese chive storage quality antioxidant capacity hydrogen nanobubble water vase life senescence-associated enzymes cut carnation flowers glucosamine sucrose starch gene expression sugar metabolism amylose cadmium field quality hydrogen-based agriculture rice Wuzhimaotao (Ficus hirta Vahl) hydrogen transcription factors secondary metabolism phytohormones signaling pathways phenylpropanoid biosynthesis and metabolism Chinese herbal medicine carbendazim degradation glutathione metabolism detoxification system redox balance cut flower flower industry postharvest quality postharvest technique the fourth industrial revolution 3-0365-5097-6 3-0365-5098-4 Hancock, John oth |
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Production and Role of Molecular Hydrogen in Plants |
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Production and Role of Molecular Hydrogen in Plants |
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Production and Role of Molecular Hydrogen in Plants |
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Production and Role of Molecular Hydrogen in Plants |
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Production and Role of Molecular Hydrogen in Plants |
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Production and Role of Molecular Hydrogen in Plants |
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Production and Role of Molecular Hydrogen in Plants |
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production and role of molecular hydrogen in plants |
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MDPI Books |
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2022 |
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1 electronic resource (128 p.) |
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3-0365-5097-6 3-0365-5098-4 |
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AT hancockjohn productionandroleofmolecularhydrogeninplants |
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(CKB)5680000000080789 (oapen)https://directory.doabooks.org/handle/20.500.12854/92117 (EXLCZ)995680000000080789 |
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Production and Role of Molecular Hydrogen in Plants |
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