Production of chiral epoxides: Epoxide hydrolase-catalyzed enantioselective hydrolysis

Chiral epoxides are highly valuable intermediates, used for the synthesis of pharmaceutical drugs and agrochemicals. They have broad scope of market demand because of their applications. A major challenge in modern organic chemistry is to generate such compounds in high yields, with high stereo- and regio-selectivities. Epoxide hydrolases (EH) are promising biocatalysts for the preparation of chiral epoxides and vicinal diols. They exhibit high enantioselectivity for their substrates, and can be effectively used in the resolution of racemic epoxides through enantioselective hydrolysis. The selective hydrolysis of a racemic epoxide can produce both the corresponding diols and the unreacted epoxides and vicinal diol has prompted researchers to explore their use in the synthesis of epoxides and diols with high ee values.     

Structure-activity relationships of epoxides: induction of sister-chromatid exchanges in V79 cells by enantiomeric epoxides.

Analysis of SCE frequencies in Chinese hamster V79 cells was used to investigate the influence of the stereoisomeric forms of epoxides in mammalian genotoxicity tests. The SCE-inducing potency of 12 pairs of (R)- and (S)-enantiomeric epoxides which differed in the degree of substitution of the oxirane ring was determined. Of these, 2 pairs of epoxides failed to induce SCE. Different SCE-inducing potencies between the (R)- and (S)-enantiomers were shown for 5 epoxides. This study demonstrates that stereoselectivity might play an important role in genotoxicity testing of chemicals with asymmetric C atoms.     

Epoxides: comparison of the induction of SOS repair in Escherichia coli PQ37 and the bacterial mutagenicity in the Ames test

The genotoxicity of 51 epoxides is studied with the SOS-Chromotest using Escherichia coli PQ37 as tester strain. The results obtained with this test system are compared with results of the Ames test. Out of 51 epoxides, 39 are shown to be mutagenic in Salmonella typhimurium whereas only 27 mutagenic epoxides induced the SOS response in Escherichia coli PQ37.     

Alkylation products of DNA bases by simple epoxides

The reaction products of a series of epoxides with deoxyribonucleosides were characterized using ultraviolet, and NMR spectroscopy. The epoxides included structural analogues which are known to differ extensively in their mutagenic potency: propylene oxide, glycidol, epichlorohydrin, trichloropropylene oxide and styrene oxide. Trichloropropylene oxide, epichlorohydrin and glycidol reacted with deoxyguanosine producing a major adduct of 1,7-(or 1,9-)dialkylguanine. All of the epoxides produced a 7-alkylguanine adduct, with the possible exception of styrene oxide. Propylene oxide, glycidol and epichlorohydrin reacted with deoxyadenosine at N-6. Glycidol, trichloropropylene oxide and styrene oxide reacted with deoxycytidine at N-3. It was concluded that the structurally related epoxides tend to react largely in a uniform way with nucleic acid bases. Thus, the reaction rates rather than the major adducts explain the differential mutagenicity of the epoxides.     

Structure-activity relationships of epoxides: induction of sister-chromatid exchanges in Chinese hamster V79 cells

Analysis of SCE frequencies in Chinese hamster V79 cells was used to investigate structure-activity relationships of epoxides in mammalian cells. For this purpose the SCE-inducing potency of 58 epoxides was determined. Of these, 16 failed to induce SCE in V79 cells. According to the substitution of the oxirane ring the results show general agreement with results obtained in the Ames test. Mono-substituted epoxides had the highest genotoxic potency compared to di- and tri-substituted epoxides. In detail, there are differences in genotoxic potency between bacteria and mammalian cells which can be explained by differences in the cellular uptake of the compounds and by detoxification reactions.     

Formation and metabolism in vitro of 5,6-epoxides of cholesterol and beta-sitosterol

The formation of 5alpha,6alpha- and 5beta,6beta-epoxides of cholesterol and beta-sitosterol in rat liver subcellular fractions has been studied. The results show that the epoxidation seems to occur only in connection with the nonspecific tissue oxidation of the sterols. The beta-epoxides were formed in three- to fourfold excess over the alpha-epoxides. Both cholesterol epoxides were efficiently converted by a microsomal hydrolase into the 3beta,5alpha,6beta-triol. The conversion was less extensive with beta-sitosterol epoxides, especially the beta-epoxide. The possible biological significance in the formation of the sterol epoxides and the triols was evaluated by their ability to inhibit the microsomal cholesterol 7alpha-hydroxylase. Only the cholesterol epoxides and especially the beta-epoxide were active in this respect.     

Asymmetric ring opening of terminal epoxides via kinetic resolution catalyzed by new bimetallic chiral (salen)Co complexes

The highly enantioselective hydrolytic kinetic resolution (HKR) of racemic terminal epoxides by new bimetallic chiral (salen)Co provides a operationally very simple protocol for the synthesis of enantiomerically enriched terminal epoxides (>99% ee) and diols. Optically pure chlorohydrins have been synthesized in one step by ring‐opening reactions of terminal epoxides with HCl using kinetic resolution. © 2005 Wiley‐Liss, Inc. Chirality     

Epoxide hydrolases from yeasts and other sources: versatile tools in biocatalysis

Major characteristics, substrate specificities and enantioselectivities of epoxide hydrolases from various sources are described. Epoxide hydrolase activity in yeasts is discussed in more detail and is compared with activities in other microorganisms. Constitutively produced bacterial epoxide hydrolases are highly enantioselective in the hydrolysis of 2,2- and 2,3-disubstituted epoxides. A novel bacterial limonene-1,2-epoxide hydrolase, induced by growth on monoterpenes, showed high activities and selectivities in the hydrolysis of several substituted alicyclic epoxides. Constitutively produced epoxide hydrolases are found in eukaryotic microorganisms. Enzymes from filamentous fungi are useful biocatalysts in the resolution of aryl- and substituted alicyclic epoxides. Yeast epoxide hydrolase activity has been demonstrated for the enantioselective hydrolysis of various aryl-, alicyclic- and aliphatic epoxides by a strain of Rhodotorula glutinis. The yeast enzyme, moreover, is capable of asymmetric hydrolysis of meso epoxides and performs highly enantioselective resolution of unbranched aliphatic 1,2-epoxides. Screening for other yeast epoxide hydrolases shows that high enantioselectivity is restricted to a few basidiomycetes genera only. Resolution of very high substrate concentrations is possible by using selected basidiomycetes yeast strains.     

Interspecies differences in the enantioselectivity of epoxide hydrolases in Cryptococcus laurentii (Kufferath) C.E. Skinner and Cryptococcus podzolicus (Bab'jeva & Reshetova) Golubev

Isolates representing Cryptococcus laurentii and Cryptococcus podzolicus, originating from soil of a heathland indigenous to South Africa, were screened for the presence of enantioselective epoxide hydrolases for 2,2-disubstituted epoxides. Epoxide hydrolase activity for the 2,2-disubstituted epoxide (+/-)-2-methyl-2-pentyl oxirane was found to be abundantly present in all isolates. The stereochemistry of the products formed by the epoxide hydrolase enzymes from isolates belonging to the two species (11 isolates representing C. laurentii and 23 isolates representing C. podzolicus) was investigated. The enantiopreferences of the epoxide hydrolases for 2,2-disubstituted epoxides of these two species were found to be opposite. All strains of C. laurentii preferentially hydrolysed the (S)-epoxides while all C. podzolicus isolates preferentially hydrolysed the (R)-epoxides of (+/-)-2,2-disubstituted epoxides. These findings indicate that the stereochemistry of the products formed from 2,2-disubstituted epoxides by the epoxide hydrolase enzymes of these yeasts should be evaluated as additional taxonomic criterion within the genus Cryptococcus. Also, the selectivity of some epoxide hydrolases originating from isolates of C. podzolicus was high enough to be considered for application in biotransformations for the synthesis of enantiopure epoxides and vicinal diols.     

Biotechnological production of enantiopure epoxides by enzymatic kinetic resolution

Enantiopure epoxides are high value-added synthons for the production of pharmaceuticals, agrochemicals, as well as versatile fine chemicals and have broad scope of market demand for their applications. A major challenge in conventional organic synthesis is to generate such compounds in high enantiopurity with reasonable yield. Among possible chemical and biological technologies for enantiopure epoxide preparation, enzymatic kinetic resolution has been paid much attention with respect to its high enantioselectivity. Epoxide hydrolase (EH) has shown promising characteristics for the preparation of enantiopure epoxides and vicinal diols during enantioselective hydrolysis of racemic epoxides. EH is readily available from microbial resources thus it is being employed for biohydrolysis of a variety of epoxides. Recent technical progress in EH-catalyzed enantioselective hydrolysis is summarized in terms of exploration of novel EH, its functional improvement, high throughput assay, and preparative scale resolution process.     

Detoxication of aliphatic epoxides by diol formation and glutathione conjugation

The Ames procedure with Salmonella typhimurium strain TA100 was used to follow the detoxication by rat liver fractions of two series of aliphatic epoxides. The epoxides employed were 3-chloro-, 3,3-dichloro- and 3,3,3-trichloropropylene oxides and also p-methoxyphenyl-, phenyl- and p-nitrophenylglycidyl ethers. In our procedure with preincubation of the epoxides with rat liver fractions prior to the Ames tests, there was more detoxication of both systems by glutathione conjugation (non-enzymatic and transferase promoted) than by the hydrolase pathways. Non-enzymatic reaction with glutathione was more pronounced for the chloro series than for the glycidyl ethers. An HPLC system was developed which was capable of quantitative measurements of the phenylglycidyl ethers together with their diol and glutathione conjugate products. A comparison of the HPLC and Ames test results indicates that the glutathione transferase reported to be present in Salmonella could be playing a role in detoxication by the Ames test. Diols were measured more readily by HPLC than by use of the Ames test in the microsomal fraction and were detected in the cytosol with the glycidyl ethers while they were not by the Ames procedure. However, all three epoxides were converted to a greater extent to their glutathione conjugates than to their diols. Thus, while literature references question the availability of the glutathione detoxication system for epoxides produced by membrane-bound enzymes, such detoxication would be of primary importance where direct-acting environmental epoxides come into contact with the cytosolic enzymes prior to possible reaction with bionucleophiles.     

Mutagenicity of Epoxides of Polycyclic Hydrocarbons correlates with Carcinogenicity of Parent Hydrocarbons

MANY chemical carcinogens are mutagenic¹ and some non-mutagenic carcinogens are metabolized to mutagenic derivatives^2,3. Recent work^4–6 has confirmed that epoxides are intermediates in the metabolism of the aromatic double bonds of carcinogenic polycyclic hydrocarbons to hydroxylated derivatives, as Boyland suggested⁷. In addition to chemical reactions with nucleic acids and histone⁸, epoxides derived from polycyclic hydrocarbons bind more extensively to the nucleic acids of cells in culture than the parent hydrocarbons⁹. Hydrocarbon epoxides are also more active in inducing malignant transformation in vitro of hamster embryo and mouse prostate cells¹⁰ although, in whole animals, they were less potent carcinogens than the hydrocarbons themselves^11–13. As potential mutagens, polycyclic hydrocarbon epoxides are therefore of particular interest, mainly because of the support positive results would give to the somatic mutation theory of carcinogenesis. In the work described here we have tested K-region epoxides of hydrocarbons for their ability to cause host range mutations of T₂h⁺ bacteriophage, specifically because there is no possibility, in this test system, of the epoxides being further metabolized. The epoxides tested were phenanthrene 9,10-oxide (Ph-E), benz(a)anthracene 5,6-oxide (BA-E), dibenz(a,h)anthracene 5,6-oxide (DBA-E), 7-methylbenz(a)anthracene 5,6-oxide (7-MeBA-E), 3-methylcholanthrene 11,12-oxide (MCA-E) and chrysene 5,6-oxide (Ch-E). Ethylene oxide and propylene oxide were used as examples of aliphatic epoxides which do not increase the frequency of host range mutants of T₂ bacteriophage and ethyl methanesulphonate (EMS) was used as a known mutagen¹⁴.     

An Overview on the Enhancement of Enantioselectivity and Stability of Microbial Epoxide Hydrolases

Epoxide hydrolases (EHs; 3.3.2.x) catalyze the enantioselective ring opening of racemic epoxides to the corresponding enantiopure vicinal diols and remaining equivalent unreacted epoxides. These epoxides and diols are used for the synthesis of chiral drug intermediates. With an upsurge in the methods for identification of novel microbial EHs, a lot of EHs have been discovered and utilized for kinetic resolution of racemic epoxides. However, there is still a constraint on the account of limited EHs being successfully applied on the preparative scale for industrial biotransformations. This limitation has to be overcome before application of identified functional EHs on large scale. Many strategies such as optimizing reaction media, immobilizing EHs and laboratory-scale directed evolution of EHs have been adopted for enhancing the industrial potential of EHs. In this review, these approaches have been highlighted which can serve as a pathway for the enrichment of already identified EHs for their application on an industrial scale in future studies.     

Bacterial mutagenicity investigation of epoxides: drugs,drug metabolites,steroids and pesticides

Although it has been observed that many epoxides are ultimate mutagens, surprisingly little is known about epoxides to which man may be extensively exposed, e.g., physiological compounds, drugs, drug metabolites and pesticides. We have now investigated 35 such and related epoxides for mutagenicity, using reversion of his^?Salmonella typhimurium TA98 and TA100 as biological end-point. None of the tested steroids (12 compounds), vitamin K epoxides (3 compounds) and pesticides (dieldrin, endrin, HEOM (1,2,3,4,9,9-hexachloro-6,7-epoxy-1,4,4a5,6,7,8,8a-octahydro-1,4-methanonaphthalene), heptachlor epoxide) showed any mutagenic activity. Negative results were also obtained with the antibiotics oleandomycin, anti-capsin and asperlin, the cardiotonic drug resibufogenin, the widely used parasympatholytic drugs butylscopolamine and scopolamine, the sedatives valtratum, didovaltratum and acevaltratum, the tranquilizer oxanamide as well as with the drug metabolites carbamazepine 10,11-oxide and diethylstilbestrol α,β-oxide. Three barbiturate epoxides, formed by metabolism of allobarbital, alphenal and secobarbital, caused weak but reproducible mutagenic effects at high concentrations. The cytostatic agent ethoglucide was the only drug having substantial mutagenic activity. Its mutagenic potency was similar to those of the control epoxides styrene 7,8-oxide, p-bromostyrene 7,8-oxide and m-bromostyrene 7,8-oxide, but much lower than those of benzo[a]pyrene 4,5-oxide, benzo[e]pyrene 4,5-oxide and 7,12-dimethylbenz[a]-anthracene 5,6-oxide.Some epoxides were also tested in other Salmonella typhimurium strains or in the presence of rat-liver S9 mix. Positive results were only obtained with compounds that had already been detected as mutagens in the direct test with strain TA100.     

Comparative mutagenicity of aliphatic epoxides in Salmonella

37 aliphatic epoxides comprising 6 subclasses (unsubstituted aliphatic epoxides, halogenated aliphatic epoxides, glycidyl esters, glycidates, glycidyl ethers and diglycidyl ethers) were tested, under code, for mutagenicity in Salmonella strains TA98, TA100, TA1535 and TA1537 and/or TA97 with and without metabolic activation using a standardized protocol. The 4 halogenated aliphatic epoxides and the 4 diglycidyl ethers were all mutagenic. The 2 glycidates were negative in all strain/activation systems used while all 5 glycidyl esters were mutagenic. 3 of the 8 unsubstituted aliphatic epoxides and 11 of the 12 glycidyl ethers were mutagenic. Glycidol also was mutagenic whereas 9,10-epoxyoctadecanoic acid, 2-ethylhexyl ester was not mutagenic. Of the 28 mutagenic compounds, all but neodecanoic acid, 2,3-epoxypropyl ester and 2-ethylhexyl glycidyl ether were detected in TA100 without activation. The latter two were detected only with activation in TA100 and TA1535. The majority of the other 26 chemicals were also mutagenic in TA1535 without activation. Good intra- and interlaboratory reproducibility was seen in the results of each of the 4 chemicals tested in more than one set of experiments. The current results confirm and extend the observations of other investigators regarding structural effects on the mutagenicity of members of the aliphatic epoxide class of chemicals.     

Cytogenetic and antineoplastic effects by newly synthesised steroidal alkylators in lymphocytic leukaemia P388 cells in vivo

Volatile organic compounds (VOCs) exert their carcinogenic activity through the production of epoxide metabolites. Because of their high reactivity some epoxides are also produced in the chemical industry for the synthesis of other compounds. Therefore, human exposure to VOCs epoxides does occur and may be an important human health concern. In this study, the in vitro genotoxic potential of epoxides originating from 1,3-butadiene (3,4-epoxy-1-butene: EB; 1,2:3,4-diepoxybutane: DEB), isoprene (3,4-epoxy-2-methyl-1-butene: IO), styrene (styrene-7,8-oxide: SO), propylene (propylene oxide: PO) and 1-butene (1,2-epoxy-butane: BO) in human peripheral blood mononuclear cells (PBMCs) and promyelocytic leukaemia cells (HL60) was measured with the comet assay (single-cell gel electrophoresis, SCGE). The effect of inclusion of foetal calf serum (FCS, 5%) in the cell-culture medium and different durations of exposure (2h, 24h) were also investigated. All epoxides tested produced DNA damage in a concentration range that did not reduce cell viability. HL60 cells were more resistant than PBMCs to the DNA damage induced by the different epoxides. With the exception of IO, the treatment for 24h resulted in an increase of DNA damage. FCS slightly protected PBMCs from the genotoxic effects induced by IO and BO, whilst no such effect was noted for the other compounds. Overall, the dose-dependent effects that were seen allowed us to define a genotoxicity scale for the different epoxides as follows: SO>EB>DEB>IO>PO>BO, which is in partial agreement with the International Agency for Research on Cancer (IARC) classification of the carcinogenic hazards.     

环氧化物的生物不对称合成

手性环氧化物是有机化学合成中重要的中间体;与以往化学合成方法相比,手性环氧化物的生物合成有其独特之优点;本文从直接加氧、间接环氧和酶解拆分三个途径全面地介绍该领域的研究成果和最新进展,并对其未来的发展和方向进行了展望 。     

Molecular engineering of epoxide hydrolase and its application to asymmetric and enantioconvergent hydrolysis

Safety and regulatory issues favor increasing use of enantiopure compounds in pharmaceuticals. Enantiopure epoxides and diols are valuable intermediates in organic synthesis for the production of optically active pharmaceuticals. Enantiopure epoxide can be prepared using epoxide hydrolase (EH)-catalyzed asymmetric hydrolysis of its racemate. Enantioconvergent hydrolysis of racemic epoxides by EHs possessing complementary enantioselectivity and regioselectivity can lead to the formation of enantiopure vicinal diols with high yield. EHs are cofactor-independent and easy-to-use catalysts. EHs will attract much attention as commercial biocatalysts for the preparation of enantiopure epoxides and diols. In this paper, recent progress in molecular engineering of EHs is reviewed. Some examples and prospects of asymmetric and enantioconvergent hydrolysis reactions are discussed as supplements to molecular engineering to improve EH performance.     

Role of epoxide hydrolases in lipid metabolism

Epoxide hydrolases (EH), enzymes present in all living organisms, transform epoxide-containing lipids to 1,2-diols by the addition of a molecule of water. Many of these oxygenated lipid substrates have potent biological activities: host defense, control of development, regulation of blood pressure, inflammation, and pain. In general, the bioactivity of these natural epoxides is significantly reduced upon metabolism to diols. Thus, through the regulation of the titer of lipid epoxides, EHs have important and diverse biological roles with profound effects on the physiological state of the host organism. This review will discuss the biological activity of key lipid epoxides in mammals. In addition, the use of EH specific inhibitors will be highlighted as possible therapeutic disease interventions.     

Epoxy acetylenic lipids: Their analogues and derivatives

Currently, approximately 250 natural acetylenic epoxy structures are known. The present review describes research concerning biologically active epoxy acetylenic lipids and related compounds isolated from different sources. Intensive searches for new classes of pharmacologically potent agents produced by living organisms have resulted in the discovery of dozens of such compounds that possess high anticancer, cytotoxic, antibacterial, antiviral, and other activities. Acetylenic epoxides primarily belong to a class of molecules containing triple bond(s) and epoxy group(s) belonging to different lipid classes and/or other groups. This review emphasises natural and synthetic acetylenic epoxides and other related compounds as important sources of leads for drug discovery. The present review is the first article devoted to natural acetylenic epoxides.