Volume 7, Issue 1 (Suppl)

J Biotechnol Biomater

ISSN: 2155-952X JBTBM, an open access journal

Enzymology & Mol. Biology 2017

Biotechnology Congress 2017

March 20-21, 2017

Page 57

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conference

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March 20-21, 2017 Rome, Italy

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15

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World Congress on

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International Conference on

Biotechnology And Biotech Industries Meet

Enzymology and Molecular Biology

Bromoperoxidase mimicking bromination catalysts

H

aloperoxidases are enzymes that are able to catalyze the oxidation of halide ions by using hydrogen peroxide. Catalytic

activities of haloperoxidases have received great attention because of their capability to halogenate a variety of organic

compounds. Vanadium bromoperoxidase (V-BrPO), which is a naturally occurring enzyme in marine algae, is a kind of

haloperoxidase. V-BrPO catalyzes two-electron oxidation of the bromide ion in the presence of hydrogen peroxide, leaving a

bromonium cation-like species. V-BrPO has been demonstrated to perform the catalytic bromination of organic compounds.

Bromination reaction is one of the most fundamental reactions in organic synthesis, providing important precursors and

substrates in various coupling reactions. Conventional bromination reaction is performed by using hazardous and toxic

elemental bromine. Considerable efforts have been focused on developing a versatile bromination method with a bromide

ion as a bromide source instead of bromine. So, the V-BrPO mimicking bromination reaction systems induced by a vanadium

catalyst and hydrogen peroxide have attracted much attention. These catalytic systems, however, require a stoichiometric

amount of a strong oxidant to generate the bromonium-like species. A more practical catalytic bromination reaction system

without the use of hazardous reagents needs to be developed. From the view point of green chemistry perspective, molecular

oxygen is regarded as the best candidate for oxidants. We embarked upon the development of an environmentally-favorable

catalytic method for selective bromination of a wide range of substrates. In this presentation, bromoperoxidase mimicking

versatile and practical bromination catalytic systems by the combination of a commercially available inexpensive ligand-free

vanadium catalyst and a Brønsted acid or a Lewis acid under molecular oxygen will be described.

Biography

Toshiyuki Moriuchi received his Bachelor’s degree in 1991 and Doctoral degree in 1995 under the supervision of Professor Toshikazu Hirao, from Osaka University.

He became an Assistant Professor at Osaka University and was a Post-doctoral Fellow at California Institute of Technology with Professor Jacqueline K Barton

(1996-1997). He was promoted to the position of Associate Professor in 2004. His current research interests focuses on the development of novel artificial bio-

conjugated systems based on self-organization of biomolecules and redox-active

π

-conjugated systems for functionalized catalysts and materials. He received the

Inoue Research Award for Young Scientists in 1997 and HGCS Japan Award of Excellence 2011 in the year 2012.

moriuchi@chem.eng.osaka-u.ac.jp

Toshiyuki Moriuchi

Osaka University, Japan

Toshiyuki Moriuchi, J Biotechnol Biomater 2017, 7:1(Suppl)

http://dx.doi.org/10.4172/2155-952X.C1.069