Affiliation:
1. Department of Chemistry, North Eastern Regional Institute of Science and Technology, Nirjuli, Itanagar-791109 (AP) India
Abstract
Background:
Epoxides are widely useful in various fields such as pharmaceuticals, pesticides,
cosmetics, polymer synthesis, fragrance compounds, and food additives. However, the synthesis
of epoxides involves heavy metal catalysts and toxic, unstable organic catalysts which causes
serious environmental and safety concerns. In recent years, biocatalysts have received a great deal
of interest in the synthesis of olefin-derived epoxides due to their mild reaction conditions, environmental
friendliness, good selectivity, and sustainability. This study focuses on catalases as a
biocatalyst for potential epoxidation reactions of olefins.Objective: To determine the possibility of
using biocatalyst catalase from a novel source Sechium edule (squash) for epoxidation of olefins
in the presence of H2O2.
Methods:
UV-Vis spectrophotometer was used to monitor the formation of epoxide from substrates-
cyclohexene, cinnamic acid, cinnamaldehyde, furfural in acetonitrile solvent and a suitable
aliquot of the enzyme solution in the presence of H2O2. The products formed were analyzed using
FTIR and GC-MS. For the immobilized enzyme, chitosan beads activated with TPP were used in
place of the enzyme and a similar procedure was followed for the analysis.
Results:
Four different olefin substrates (cyclohexene, cinnamic acid, cinnamaldehyde, and furfural)
were selected to study the catalysis reaction of epoxidation by the catalase enzyme. The course
of the epoxidation was monitored by UV-Vis, FTIR, and GC-MS methods. However, under optimized
reaction conditions and spectral analysis, further confirmed by GC-MS, data showed only
epoxide formation from cyclohexene. CAT completely catalyzed other olefins like furfural, cinnamic
acid, and cinnamaldehyde into its degraded products biochemically. Therefore, cyclohexene
was selected for further immobilization studies and the identified metabolites of olefins and their
degradation mechanism. Major biodegradation products of cinnamic acid were found to be styrene(
m/z 104.0) and benzaldehyde(m/z 105.0). GC-MS data of biotransformation of cinnamaldehyde,
identified 2,4 dimethyl benzaldehyde(m/z 133) as the main product. The catalytic biotransformation
of furfural investigated by GC-MS data identified 2,5 dimethyl benzaldehyde (m/z 133),
dodecanol (m/z 181) and Pentanoic acid, 5 hydroxy, 2,4 dibutyl phenyl ester(m/z 306) as the major
product. Three major oxidized products were detected in GC-MS data from the epoxidation of
cyclohexene viz., cyclohexane diol(m/z 116), cyclohexene epoxide-1-ol(m/z 110), cyclohexene
epoxide-1-one(m/z 110).
Conclusion:
In this investigation, catalase purified from Sechium edule(squash) was developed as
an efficient catalytic tool for the biotransformation of olefins and selective epoxidation of cyclohexene.
Under optimized conditions, the experimental results revealed the main products found in
cinnamaldehyde as benzaldehyde (m/z 133.0) and cinnamic acid as benzaldehyde (m/z 133), styrene
(m/z 104.0) and benzoic acid (m/z 122.0), while the data from furfural oxidation could not be
justified from previous studies. The optimal concentration of CH3CN solvent for cyclohexene
epoxidation was found to be 4 mM. Enzymatic characterization of free and immobilized catalase
on chitosan was investigated using cyclohexene as a variable substrate and found to be 0.017 mM,
83.33 μmol/min for Km and Vmax values, pH 6.8 and 30˚C for free CAT and 0.03 mM, 200
μmol/min, pH 7.6 and 35˚C for immobilized one. Immobilization increases the thermal stability of
the CAT and changes the pH to alkalinity. The possible oxidation of cyclohexene was deduced as
the radical chain mechanism for the generation of epoxide with the key products obtained as cyclohexane
diol(m/z 116), cyclohexene epoxide-1-ol(m/z 110) and cyclohexene epoxide-1-one(m/z
110). The reusability of the biocatalytic tool opens up the opportunity to reduce the cost of various
catalytic reactions. Further studies can focus on the separation and advancement of epoxide yields,
improved immobilization strategy for maximum repetitive cycles, and chemo-enzymatic epoxidation
on biological olefins.
Publisher
Bentham Science Publishers Ltd.
Subject
Organic Chemistry,Analytical Chemistry,Catalysis