Magnesium hydride acts as a convenient hydrogen supply to prolong the vase life of cut roses by modulating nitric oxide synthesis

•The vase life of cut roses was prolonged by MgH2.•MgH2 was more convenient than hydrogen-rich water (HRW) by water electrolysis.•Rose flower redox homeostasis was reestablished by MgH2.•MgH2 treatment prolonged cut rose vase-life but was dependent on NO. Hydrogen-rich water (HRW), normally produced...

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Bibliographic Details
Published in:Postharvest biology and technology 2021-07, Vol.177, p.111526, Article 111526
Main Authors: Li, Ying, Li, Longna, Wang, Shu, Liu, Yuhao, Zou, Jianxin, Ding, Wenjiang, Du, Hongmei, Shen, Wenbiao
Format: Article
Language:English
Subjects:
Antioxidants
Electrolysis
Flowers
Horticulture
Hydrides
Hydrogen
Hydrogen gas
Lipid peroxidation
Lipids
Magnesium
Magnesium hydride
Medical research
Moisture content
Nitrate reductase
Nitric oxide
Peroxidation
Releasing
Rose
Vase life
Water content
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Summary:•The vase life of cut roses was prolonged by MgH2.•MgH2 was more convenient than hydrogen-rich water (HRW) by water electrolysis.•Rose flower redox homeostasis was reestablished by MgH2.•MgH2 treatment prolonged cut rose vase-life but was dependent on NO. Hydrogen-rich water (HRW), normally produced by water electrolysis, is a major method for hydrogen gas (H2) delivery, and had beneficial outcomes in postharvest preservation of cut roses. Since the preparation of HRW is complicated and required a H2 generator, the development of a convenient hydrogen supply in horticulture is required. In this report, magnesium hydride (MgH2), a H2-releasing material used in hydrogen industry and medical research, was tested. Compared to HRW produced by electrolysis, release of H2 by MgH2 hydrolysis was more convenient and flexible. Similar to conventional HRW, MgH2 could contribute H2 and prolong the vase life of cut roses. This beneficial role of MgH2 was verified by the observed increase in water content, decreased lipid peroxidation, and increased antioxidant levels. Pharmacologic experiments showed that MgH2 mimicked the cut flower response of nitric oxide (NO)-releasing compound by triggering an increase in endogenous NO production. In contrast, the positive effects of MgH2 on cut flower vase life and lipid peroxidation were impaired by a NO scavenger and its synthetic inhibitor. This indicated a requirement for NO in the MgH2-mediated pathway for prolonged vase life of cut rose flowers. Therefore, this study identifies a new opportunity for the application of H2-releasing materials as an alternative approach for more convenient and flexible hydrogen supply in horticulture.
ISSN:0925-5214
1873-2356
DOI:10.1016/j.postharvbio.2021.111526