Therapeutic Efficacy of Molecular Hydrogen: A New Mechanistic Insight

Author(s): Toru Ishibashi*.

Journal Name: Current Pharmaceutical Design

Volume 25 , Issue 9 , 2019


Background: Molecular hydrogen (H2) is now recognized as a therapeutic gas for the treatment of numerous diseases including neurodegenerative diseases, metabolic disorders, and inflammatory diseases. Nonpolar, neutral H2 is assumed to have health benefits facilitated by its passive diffusion across the human body immediately after administration and is considered a safe therapeutic inert gas that does not interfere with physiological enzymatic reactions. The effects of H2 on mammalian cells are assumed to be based on non-enzymatic reactions with reactive oxygen species (ROS) exhibiting extremely high reactivity. However, many reports on therapeutic applications of H2 have the limitation to regard H2 only as a scavenger for the hydroxyl radical and peroxynitrite.

Methods: Apart from this proposed principle, a new possible mechanism of H2 activation and consumption in mammalian cells is considered in this review, which is specifically focused on the mitochondrial complex I that has a close evolutionary relationship with energy-converting, membrane-bound [NiFe]-hydrogenases (MBH). Notably, the possibility that H2 may function as both electron and proton donor in the ubiquinone-binding chamber of complex I is discussed.

Results: H2 is proposed to act as the rectifier of the mitochondrial electron flow in the disordered or pathological state when the accumulation of electrons leads to ROS production, specifically during the re-supply of O2 after hypoxia in the mitochondria.

Conclusion: Furthermore, H2 is proposed to convert the quinone intermediates to the fully reduced ubiquinol, thereby increasing the antioxidant capacity of the quinone pool as well as preventing the generation of ROS.

Keywords: Molecular hydrogen, semiquinone, hydrogenase, rectifier of electron flow, mitochondrial respiratory complex, electron and proton donor.

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Year: 2019
Page: [946 - 955]
Pages: 10
DOI: 10.2174/1381612825666190506123038

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