Biological dehalogenation and halogenation reactions

Chemosphere 52 (2003) 299–312 www.elsevier.com/locate/chemosphere

Review

Biological dehalogenation and halogenation reactions Karl-Heinz van P
ee *, Susanne Unversucht Institut f€ur Biochemie, TU Dresden, D-01062 Dresden, Germany Received 19 February 2002; received in revised form 19 November 2002; accepted 19 November 2002

Abstract A large number of halogenated compounds is produced by chemical synthesis. Some of these compounds are very toxic and cause enormous problems to human health and to the environment. Investigations on the degradation of halocompounds by microorganisms have led to the detection of various dehalogenating enzymes catalyzing the removal of halogen atoms under aerobic and anaerobic conditions involving different mechanisms. On the other hand, more than 3500 halocompounds are known to be produced biologically, some of them in great amounts. Until 1997, only haloperoxidases were thought to be responsible for incorporation of halogen atoms into organic compounds. However, recent investigations into the biosynthesis of halogenated metabolites by bacteria have shown that a novel type of halogenating enzymes, FADH2 -dependent halogenases, are involved in biosyntheses of halogenated metabolites. In every gene cluster coding for the biosynthesis of a halogenated metabolite, isolated so far, one or several genes for FADH2 -dependent halogenases have been identified. Ó 2002 Elsevier Science Ltd. All rights reserved. Keywords: Dehalogenation; Dehalogenase; Halogenation; Halogenase; Haloperoxidase

Contents 1. 2.

3.

Introduction . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Dehalogenation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.1. Hydrolytic dehalogenation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.2. Thiolytic dehalogenation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.3. Intramolecular substitution . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.4. Dehydrohalogenation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.5. Dehalogenation by hydration . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.6. Dehalogenation by methyltransfer . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.7. Oxidative dehalogenation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.8. Reductive dehalogenation . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 2.8.1. Reductive dehalogenation under aerobic conditions. . . . . . . . . . . . . . . . . . . . 2.8.2. Anaerobic reductive dehalogenation (halorespiration) . . . . . . . . . . . . . . . . . . Halogenation. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.1. Halogenated metabolites . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.2. Halogenating enzymes . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

*

Corresponding author. Tel.: +49-351-463-4494; fax: +49-351-463-35506/5508. E-mail address: [email protected] (K.-H. van P
ee).

0045-6535/03/$ - see front matter Ó 2002 Elsevier Science Ltd. All rights reserved. doi:10.1016/S0045-6535(03)00204-2

300 300 300 300 301 301 302 302 302 302 302 303 304 304 304

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3.2.1. Haloperoxidases. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.2.2. Perhydrolases. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 3.3. FADH2-dependent halogenases . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . 4. Conclusions. . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . References . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

1. Introduction Halogenated organic compounds are widely used as pharmaceuticals, herbicides, fungicides, insecticides, flame retardants, intermediates in organic synthesis, solvents etc. Additionally, many halogenated compounds are produced as by-products during chemical synthesis, such as dioxins, polychlorinated biphenyls and pentachlorophenol. Since many of these halocompounds show toxic or even carcinogenic effects and many of them are often difficult to degrade, many investigations were conducted to analyse the fate of these compounds in the environment. Studies on the degradation of different halogenated aliphatic and aromatic compounds led to the detection and elucidation of a variety of dehalogenases and dehalogenation mechanisms (Janssen et al., 1994; Fetzner, 1998). However, halogenated compounds are not only man-made, but also synthesized in nature by a large number of different organisms (Gribble, 1998). Until today, over 3500 halogen-containing metabolites have been isolated. Some of these halogenated metabolites have great importance as antibiotics such as chloramphenicol, 7-chlorotetracyclin, or vancomycin. However, until recently (van P
ee, 1996), very little was known about the enzymes catalyzing the incorporation of halogen atoms during the biosynthesis of these compounds.

2. Dehalogenation 2.1. Hydrolytic dehalogenation The first bacterial dehalogenase was purified in 1960 by Jensen. This enzyme catalyzes the dechlorination of chloroacetate and 2-chloropropionic acid. Similar 2haloacid dehalogenases were subsequently isolated from many different bacteria such as Moraxella sp., Pseudomonas sp., and Xanthobacter autotrophicus (Van der Ploeg et al., 1991). 2-Haloacid dehalogenases catalyze a substitution of the halogen with water as the nucleophile resulting in the formation of an alcohol (Fig. 1). No other cofactor is required. The best studied hydrolytic halogenase is the haloalkane dehalogenase from the 1,2-dichloroethane-

Cl C

+

H2O

304 307 307 309 310

OH + HCl C

Fig. 1. Hydrolytic dehalogenation. In hydrolytic dehalogenation reactions, the halogen is displaced by water in a nucleophilic replacement reaction.

degrading bacterium Xanthobacter autotrophicus GJ10. The reaction mechanism of this enzyme was elucidated by X-ray crystallographic analysis (Verschueren et al., 1993) and site-directed mutagenesis (Pries et al., 1994). The enzyme belongs to the a=b hydrolase fold family and contains a catalytic triad consisting of one histidin and two aspartate residues which are involved in the nucleophilic substitution of the halide ion by water. The removal of the halide ion is additionally facilitated by two tryptophan residues (Fig. 2; Kennes et al., 1995). During degradation of 4-chlorobenzoic acid by Nocardia species, 4-hydroxybenzoic acid was isolated as an intermediate in the degradation pathway (Klages and Lingens, 1979). During investigation of the enzyme from Pseudomonas sp. CBS3, it could be shown that the hydroxyl group was derived from water and not from molecular oxygen (M€ uller et al., 1984). For hydrolytic substitution of chloride by a hydroxyl group at an aromatic system, activation by coenzyme A ester formation is required. The first step in 4-chlorobenzoate degradation, the formation of 4-chlorobenzoyl-coenzyme A, is catalyzed by a ligase. The second step, the actual dehalogenation reactions, is catalyzed by 4-chlorobenzoylcoenzyme A dehalogenase and 4-hydroxybenzoyl-coenzyme A is hydrolyzed by a thioesterase (Fig. 3; Luo et al., 2001).

2.2. Thiolytic dehalogenation Methylotrophic bacteria such as Methylophilus sp., Methylobacterium sp. and Hyphomicrobium sp. isolated with dichloromethane as growth substrate produce an inducible glutathione S-transferase which catalyzes the formation of an unstable S-chloromethyl glutathione intermediate. This intermediate is hydrolyzed to glutathione, chloride, and formaldehyde (Fig. 4; Leisinger

K.-H. van P
ee, S. Unversucht / Chemosphere 52 (2003) 299–312

O

Trp175

C

OH

301

O C

S CoA

+ ATP, CoA-SH Cl

O - O

N

HN

N H

4-CBA:CoA ligase

H

H N

O

+ H2O - HCl dehalogenase O C

Asp124

His289

Cl

Trp 125

O - O H

Asp260

Cl

C C Cl H2 H HN 2

O

OH

C + H2O, - CoA-SH thioesterase

Trp175

OH

OH

Fig. 3. Hydrolytic dehalogenation of 4-chlorobenzoic acid (4-CBA) involving activation by formation of a coenzyme A ester.

N H Cl

Cl C CH 2 H2 O

- O

N

HN

H

HN

H N

O H

His289

Asp260

Trp 125

O

O

Asp124 Trp175

Cl

O

-

O

Asp260

HN

N H Cl C CH 2 H2 HN OH + NH O - O H N

His289

S CoA

Trp 125

2.3. Intramolecular substitution Haloalkohol dehalogenases, also known as halohydrin dehalogenases or halohydrin hydrogen–halide lyases which have been isolated from Arthrobacter sp. and other bacteria, catalyze the intramolecular nucleophilic displacement of a halogen by a vicinal hydroxyl function in halohydrins to yield epoxides (Fig. 5; Van Hylckama Vileg et al., 2001). Although these enzymes show sequence homology with the family of short-chain dehydrogenases/reductases, they do not require NAD(P)þ as a coenzyme. They have the same two active site amino acid residues serine and tyrosine with the lysine residue of the short-chain dehydrogenases/reductases replaced by an arginine residue. These enzymes are also able to catalyze the reverse reaction, the halogenation of epoxides to haloalcohols (Nakamura et al., 1991).

Asp124

2.4. Dehydrohalogenation

Fig. 2. Mechanism of haloalkane dehalogenase. Two tryptophan residues are involved in removing the halogen atom.

et al., 1994; Marsh and Ferguson, 1997; Gisi et al., 1998).

Cl CH 2 + GSH - HCl Cl

The first two steps in the degradation of lindane (chexachlorocyclohexane) by Pseudomonas paucimobilis are catalyzed by a dehydrohalogenase. The elimination of hydrochloric acid catalyzed by this enzyme leads to

+ H2 O GS GS C Cl - HCl H2

CH2OH

O H C H

Fig. 4. Thiolytic dehalogenation of dichloromethane catalyzed by a glutathione transferase.

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H H C Cl haloalcohol dehalogenase H C OH - HCl H C Cl H

+ H2O

H H C OH H C O H C H

Cl + H2O C C COOH H H

H H C O H C H C Cl H

haloalcohol dehalogenase - HCl

Cl

Cl

- HCl

Cl

Cl

Cl

Cl

- HCl

Cl Cl

H H C OH H C OH H C Cl H

Cl

Cl

Cl

Cl

+ H2O - HCl

HO

Cl

Cl

OH

+ H2O - HCl

O C C COOH H H2

epoxide hydrolase

Cl Cl

- HCl

Fig. 7. Dehalogenation by addition of water onto a double bond.

Fig. 5. Intramolecular nucleophilic displacement of a halogen by a vicinal hydroxyl group catalyzed by haloalcohol dehalogenases. These enzymes can also catalyze the reverse reaction, the halogenation of the epoxides to haloalcohols.

Cl

Cl HC C COOH O H2 H

HO

Cl

Cl

Cl

Fig. 6. Dehalogenation of lindane as an example of dehydrohalogenation with formation of a double bond.

the formation of a double bond (Fig. 6; Imai et al., 1991). 2.5. Dehalogenation by hydration In a coryneform bacterium, isolated with 3-chloroacrylate as the carbon source, two dehalogenases have been detected. The dehalogenation reactions catalyzed by these enzymes, are proposed to proceed by addition of water to the double bond yielding an unstable intermediate from which malonate semialdehyde is formed (Fig. 7; Van Hylckama Vileg and Janssen, 1992). 2.6. Dehalogenation by methyltransfer Dehalogenation by methyltransfer was found in aerobic and strictly anaerobic methylotrophic bacteria using chloromethane or dichloromethane as the sole

carbon source (Meßmer et al., 1996; Vanelli et al., 1998). Coulter et al. (1999) described a methyltransferase that contains a corrinoid-bound cobalt atom. In the active state the cob(II)alamin is oxidized to the cob(III)alamin state by methylation by halomethane and is reduced by demethylation by the methyl group acceptor ion which can be a halide or bisulfide ion (Fig. 8).

2.7. Oxidative dehalogenation Oxidative dehalogenation reactions can be found in pathways for the degradation of haloaliphatic as well as haloaromatic compounds. These reactions are catalyzed by monooxygenases with a broad substrate specificity like methane monooxygenase from Methylococcus capsulatus Bath or Methylococcus trichosporium (Yokota et al., 1986; Fox et al., 1990) or by dioxygenases like the two-component 4-chlorophenylacetate 3,4-dioxygenase from Pseudomonas sp. CBS3 (Fig. 9; Schweizer et al., 1987). Lignin and manganese peroxidase from the lignindegrading basidiomycete Phanerochaete chrysosporium were also found to catalyze an oxidative dechlorination reaction of pentachlorophenol to produce tetrachloro1,4-benzoquinone (Reddy and Gold, 2000).

2.8. Reductive dehalogenation 2.8.1. Reductive dehalogenation under aerobic conditions During degradation of pentachlorophenol by Sphingomonas chlorophenolica under aerobic conditions, tetra-

E---cob(II)alamin CH3X

CH3Y

X

Y E---CH3cob(III)alamin

Fig. 8. Dehalogenation of chloromethane catalyzed by a cobalamin-containing methyltransferase; CH3 X can be CH3 Cl, CH3 Br or CH3 I, and Y can be Cl , Br , I or HS .

K.-H. van P
ee, S. Unversucht / Chemosphere 52 (2003) 299–312

O OH C CH2 + O2 + NADH +

H+

4-chlorophenylacetate 3,4-dioxygenase

Cl

303

O OH C CH2

Cl

O H

OH H

- HCl O OH C CH2

OH OH Fig. 9. Oxidative dehalogenation of 4-chlorophenylacetate catalyzed by the two-component system of 4-chlorophenylacetate 3,4dioxygenase.

OH

OH

Cl

Cl

Cl

Cl

+ GSH - HCl

Cl

Cl

Cl

H SG

OH

O + H

-

S

C H2 Enzyme

OH Enzyme

Cl

Cl

Cl

+ GS-S C H2 H OH + GSH S

C H2 Enzyme + GS-SG

Fig. 10. Reductive dehalogenation of tetrachlorohydroquinone under aerobic conditions catalyzed by a glutathione transferase.

chlorohydroquinone is produced by a monooxygenase reaction catalyzed by pentachlorophenol hydroxylase. The thus formed tetrachlorohydroquinone is dehalogenated in a reductive dehalogenation reaction catalyzed by tetrachlorohydroquinone dehalogenase to trichlorohydroquinone (Fig. 10; Kiefer et al., 2002). A similar tetrachlorohydroquinone reductive dehalogenase system was also found in the white rot fungus Phanerochaete chrysosporium (Reddy and Gold, 2001). Tetrachlorohydroquinone dehalogenase is a member of the glutathione

S-transferase family like the enzyme involved in dichloromethane dehalogenation. Lignin peroxidases from white rot fungi such as Phanerochaete chrysosporium can also catalyze the reductive dehalogenation of carbon tetrachloride via a mechanism involving one electron oxidation of veratryl alcohol to the veratryl alcohol cation radical. This radical is reduced by oxalacetate resulting in a one-electron oxidation of oxalacetate. The remaining electron can then be used to catalyze reduction reactions such as the reductive dechlorination of carbon tetrachloride (Shad et al., 1993). A different type of reductive dehalogenation reaction is catalyzed by the NADH-dependent enzyme maleylacetate reductase which has been isolated from several Pseudomonas strains and Ralstonia eutropha (Fig. 11; M€ uller et al., 1996). 2.8.2. Anaerobic reductive dehalogenation (halorespiration) In halorespiration, reductive dehalogenation is coupled to energy metabolism. Here a halogenated compound, like tetrachloroethene and trichloroethene, serves as a terminal electron acceptor during the oxidation of an electron rich compound, like hydrogen or an organic substrate (Schuhmacher et al., 1997; Wohlfahrt and Diekert, 1997). The reductive dehalogenases isolated from several bacteria such as Dehalococcoides ethenogenes or Desulfitobacterium dehalogenans catalyzing these reactions contain a cobalamin cofactor and iron– sulfur clusters (Fig. 12; Van de Pas et al., 1999; Magnuson et al., 2000).

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ee, S. Unversucht / Chemosphere 52 (2003) 299–312

OH O OH C C CH2 CH2 C O + maleylacetate reductase C O + NAD + + HCl CH + NADH + H CH C Cl CH C C HO O HO O O

Fig. 11. NADH-dependent reductive dehalogenation of 2-chloromaleylacetate to 3-oxoadipate under aerobic conditions.

Cl

Cl

C C Cl Cl

corrinoid-dependent PCE reductive dehalogenase

Cl

Cl

-

C C Cl Cl - Cl

H

Cl

C C Cl Cl

.

H+

Cl

C C Cl Cl

Fig. 12. Corrinoid-dependent reductive dehalogenation of tetrachloroethene (PCE) under anaerobic conditions coupled to energy metabolism (halorespiration).

shown that the deschloro derivative did not show any antimicrobial activity against the different microorganisms tested in contrast to the chlorinated compound (Sancelme et al., 1994). 3.2. Halogenating enzymes Although a large number of halogenated organic compounds has been isolated, not much is known about the mechanisms by which fluorine, chlorine, bromine, or iodine atoms are incorporated into organic compounds. The elucidation of some biosynthetic pathways, like 7chlorotetracyclin (McCormick, 1997) or pyrrolnitrin biosynthesis (Kirner et al., 1998) showed that the halogenation reactions in these pathways must be catalyzed by enzymes with substrate specificity and regioselectivity (Fig. 14).

3. Halogenation 3.1. Halogenated metabolites The synthetic diversity of nature is also reflected in a large number of naturally produced halogenated compounds discovered in many different organisms. Until today, more than 3500 halogenated metabolites have been isolated from bacteria, fungi, marine algae, lichens, higher plants, mammals and insects (Gribble, 2001). Whereas brominated metabolites are predominant in the marine environment, chlorine-containing metabolites are preferentially produced by terrestrial organisms. Although fluorine is the most abundant halogen in EarthÕs crust, biologically produced fluorinated metabolites are quite rare (Murphy et al., 2003), as is the case with iodinated metabolites (Gribble, 1996). The chemical structures of naturally produced halogenated compounds show a high degree of variability, with compounds containing a single or several halogen atoms (Fig. 13). Halogen atoms in organic compounds are important for biological activity. Nogami et al. (1987) for example showed that the biological activity of several pyrrolomycins is dependent on number, type and position of halide ion in the organic compound, and for the antitumor compound rebeccamycin it could be

3.2.1. Haloperoxidases The first halogenating enzyme was detected in the fungus Caldariomyces fumago (Shaw and Hager, 1959), the producer of caldariomycin (Fig. 15). For the catalysis of halogenation reactions, this enzyme requires hydrogen peroxide and halide ions (only chloride, bromide and iodide) and was thus named chloroperoxidase. During characterization of chloroperoxidase, a photospectroscopic enzyme assay was developed that is based on the chlorination or bromination of monochlorodimedone, a synthetic compound with structural similarity to 2-chloro-1,3-cyclopentanedione, an intermediate in caldariomycin biosynthesis (Fig. 15; Hager et al., 1966). Using this assay many other chloro-, bromo-, and iodoperoxidases were subsequently detected and isolated from bacteria, fungi, marine algae, marine invertebrates, and mammals (Neidleman and Geigert, 1986). Biochemical characterization showed that chloroperoxidase from Caldariomyces fumago contains a heme group, is able to exhibit catalase activity and additionally catalyzes P450-type reactions (Dunford, 1999). Elucidation of the three-dimensional structure (Sundaramoorthy et al., 1998) and biomimetic studies

K.-H. van P
ee, S. Unversucht / Chemosphere 52 (2003) 299–312 OH OH RO HO NH 2 O

HO

O

O

O

chloroeremomycin: R =

OH OH O

Cl

OH

HOCH2

H NH NH N O H H H O NH2

OH OCH3 rebeccamycin

H

balhimycin: R = H

OH O

Cl O

H OH

O OH H

CH3 H

N H

N

O

H O Cl H N O N N H H O H NH H H

Cl H O

O

CH OH O 2 O Cl

O H

HO

H N

O

O

305

Cl

HO NH 2 O

N H

O

S

NH2

thienodolin Cl

N(CH3)2 OH NH2

Cl

HO

Cl

N H

O

Cl OH

Cl O

Cl

N H

OH Cl

7-chlorotetracycline

pyoluteorin

pentachloropseudilin

Fig. 13. Examples of naturally produced halocompounds.

CH3

O

Cl OH

CH3

O OH

Cl

NH2 OH

OH

OH O O

O

OH

CH3

H

OH

O

4-ketoanhydro-7-chlorotetracycline

4-ketoanhydrotetracycline Cl

NH2 OH O O

Cl H O

NH2 OH

CH3

H

N(CH3)2 OH

NH2 OH

OH

OH O O

O

4-aminoanhydro-7-chlorotetracycline

NH2 OH

O

OH OH O

O

7-chlorotetracycline

Fig. 14. Partial 7-chlorotetracycline biosynthetic pathway showing 4-ketoanhydrotetracycline, the substrate for the halogenating enzyme (McCormick, 1997).

(Wagenknecht and Woggon, 1997) revealed the reaction mechanisms showing that heme-type haloperoxidases produce free hypohalous acid as the halogenating agent in the presence of H2 O2 and halide ions (Fig. 16). A different type of haloperoxidases, originally isolated from a marine alga, was found to require vanadium ions for its halogenating activity (Vilter, 1984). Vanadium-containing haloperoxidases were subsequently

isolated from marine algae, lichen, and fungi (Almeida et al., 2001). Investigation of the reaction mechanism and elucidation of the X-ray structure of chloroperoxidase from the fungus Curvularia inaequalis showed that this type of haloperoxidases also produces hypohalous acids as the halogenating agent (Fig. 17; Franssen, 1994; Messerschmidt et al., 1997).

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H

Cl

OH

HO

Cl H

Cl H O

O

caldariomycin

O

O

2-chloro-1,3-cyclopentanedione monochlorodimedone Cl

Cl H O

O

Cl

O

O

BPO H2O2 / Br

Br

O

O

Fig. 15. Chemical structures of caldariomycin, 2-chloro-1,3-cyclopentanedione, an intermediate in caldariomycin biosynthesis, and the synthetic compound monochlorodimedone. Halogenation of monocglorodimedone was used for many years as the standard assay in the search for halogenating enzymes.

H2C

H2C

CH2

CH2

CH2 His

Glu

Glu

Glu H2C O C

- O

His H

O C

- OH

O C

- O

His

H

H

O

+

-O

-O O H 3+

Fe

3+

S C H2 Cys

Fe S C H2 Cys -H2O

H2O2

Glu

Glu

H2C

H2C

CH2 His

H O -O

3+

Fe S C H2 Cys

+

CH2

O C

- O

His

O C

- O O

H2O

4+

Fe S

3+

Fe

C H2 Cys

S C H2 Cys

H2O -HOCl

Cl Glu

H2C

H2C

CH2

CH2 His

Glu

H2C

Glu

O C

His

- O H

Cl O 3+

Fe S C H2 Cys

-H2O

CH2

O C

- O H3O +

-O

His 3+

- O Cl

Cl

Fe S C H2 Cys

O C

H3O +

-O 3+

Fe S C H2 Cys

Fig. 16. Reaction mechanism of heme-containing haloperoxidases showing the formation of hypohalous acid. Only the heme ion without the porphyrin ring system is shown.

K.-H. van P
ee, S. Unversucht / Chemosphere 52 (2003) 299–312

5+

ENZ- V native enzyme

H2O2

H

Br

5+

ENZ-V -OOH +

H

+

307

5+

ENZ-V -O Br H2O

H

+

5+

Br2

ENZ- V + HO Br native enzyme

Br3-

+A-H -H2O A-Br Fig. 17. Reaction mechanism of vanadium-containing haloperoxidases.

This fact makes it very unlikely that haloperoxidases and perhydrolases are involved in the biosyntheses of halogenated metabolites. Interestingly, whereas the involvement of haloperoxidases, like myeloperoxidase, in defense mechanisms, where unspecific halogenation occurs, has been well established (Albert et al., 2001), the involvement of haloperoxidases in biosyntheses of halogenated metabolites has not been shown so far. From these observations it can be concluded that other halogenating enzymes than haloperoxidases must exist.

3.2.2. Perhydrolases A further type of halogenating enzymes requiring hydrogen peroxide was isolated from halogenated metabolite-producing Pseudomonas and Streptomyces strains using the monochlorodimedone assay (van P
ee, 1996). These halogenating enzymes contain neither a heme group nor any metal ions. Although they require hydrogen peroxide for their halogenating activity, they are not peroxidases. The three-dimensional structure of these halogenating enzymes shows a catalytic triad consisting of a serine, an aspartate and a histidine residue (Hecht et al., 1994) revealing that they belong to the a=b hydrolase fold enzyme family. In the presence of H2 O2 they can act as perhydrolases. During catalysis, an acyl-enzyme intermediate is formed by reaction of acetic or another short-chained carboxylic acid with the serine residue at the active site (Picard et al., 1997). In the presence of H2 O2 , perhydrolysis of the acyl-enzyme intermediate results in the formation of peracids, which can oxidize halide ions to hypohalous acids which then act as the halogenating agent (Fig. 18; Hofmann et al., 1998). Thus, heme- and vanadium-containing haloperoxidases and also perhydrolases are halogenating enzymes without any substrate specificity and regioselectivity.

3.3. FADH2 -dependent halogenases Dairi et al. (1995) cloned the biosynthetic gene cluster for 7-chlorotetracycline biosynthesis and in a complementation experiment they identified a gene region that contained the gene for the halogenating enzyme involved in 7-chlorotetracycline biosynthesis. The amino acid sequence deduced from the nucleotide sequence showed no similarity to haloperoxidases or perhydrolases. Cloning and sequencing of the pyrrolnitrin biosynthetic gene cluster revealed that it contains four open reading frames. When introduced into E. coli this bacterium produces pyrrolnitrin (Hammer et al., 1997).

Ser CH2 Asp

His

Asp

HO

CH2

His

H2O2

O H2O

+

H O C

Ser

Ser

C O

CH3

CH2 Asp

His HO

HO

O

CH3

C

CH3

O

O

H

+

Cl

+ H -O

+

H O C

CH3 + A

Cl + H2O

A

H

C

HOCl +

O

Fig. 18. Reaction mechanism perhydrolases.

O

CH3

308

K.-H. van P
ee, S. Unversucht / Chemosphere 52 (2003) 299–312 COOH

COOH

PrnA

NH2

N H

N H

Cl

tryptophan

NH2

7-chlorotryptophan PrnB

Cl PrnC

Cl

NH2 N H

NH2 N H

Cl

aminopyrrolnitrin

monodechloroaminopyrrolnitrin

PrnD

Cl

Cl

NO2 N H

pyrrolnitrin

Fig. 19. Pyrrolnitrin biosynthetic pathway.

Biochemical and molecular genetic studies demonstrated that two of the four genes coded for two different halogenating enzymes (PrnA and PrnC) required for pyrrolnitrin biosynthesis (Fig. 19; Kirner et al., 1998). Neither PrnA nor PrnC shows any similarity to haloperoxidases or perhydrolases. However, whereas PrnA has also no similarity to the halogenase from the 7chlorotetracycline biosynthetic pathway, PrnC shows

NADH + FAD + H

+

significant similarity to this enzyme (Hammer et al., 1997; van P
ee, 2001). Elucidation of the biosynthetic pathway for pyrrolnitrin biosynthesis in Pseudomonas fluorescens revealed that regioselective chlorination of tryptophan to 7-chlorotryptophan, catalyzed by tryptophan 7-halogenase (PrnA), is the first step in pyrrolnitrin biosynthesis. The second halogenase, monodechloroaminopyrrolnitrin 3-halogenase (PrnC), catalyzes the regioselective chlorination of monodechloroaminopyrrolnitrin in the 3-position of the pyrrole ring resulting in aminopyrrolnitrin formation (Fig. 19). Due to their different substrate specificities and regioselectivities, the two halogenases cannot substitute each other during pyrrolnitrin biosynthesis (Kirner et al., 1998). During purification of the tryptophan 7- and monodechloroaminopyrrlonitrin halogenase, it became evident that a second enzyme, whose gene was not part of the pyrrolnitrin biosynthetic gene cluster, was required for halogenating activity. This enzyme was identified as a flavin reductase. This flavin reductase produces FADH2 from FAD and NADH which is required by the halogenases. Thus the new type of halogenating enzymes was named FADH2 -dependent halogenases (Keller et al., 2000). In addition to FADH2 , halide ions (chloride or bromide) and oxygen are necessary for the halogenation reaction. There is obviously no specificity required between the flavin reductase and the halogenase, since the original flavin reductase from Pseudomonas fluorescens can be substituted by reductases from other bacteria, like E. coli or Thermus thermophilus (Keller et al., 2000).

Reductase

FADH2 + NAD

+

Halogenase + FADH2

Halogenase-FADH2

Halogenase-FADH2 + O2

Halogenase-FADHOOH

COOH

COOH Halogenase-FADHOOH N H

NH2

- FAD, H2O

N H

O

+

tryptophan

Cl , + H

COOH

COOH

Cl

N H

NH2

NH2

- H2 O

HO Cl

N H

NH2

7-chlorotryptophan Fig. 20. Hypothetical reaction mechanism of FADH2 -dependent halogenases.

K.-H. van P
ee, S. Unversucht / Chemosphere 52 (2003) 299–312

309

Fig. 21. Alignment of the conserved region of FADH2 -dependent halogenases containing two tryptophan residues. PrnA-P and PrnAM: PrnA from Pseudomonas fluorescens and from Myxoccocus fulvus, respectively (Hammer et al., 1999); RebH: Halogenase from Saccharotrix aerocolonigenes (Sanchez et al., 2002); PrnC-P and PrnC-M: PrnC from Pseudomonas fluorescens and from Myxococcus fulvus; respectively (Hammer et al., 1999); Cts4: halogenase from Streptomyces aureofaciens (Dairi et al., 1995); PltA: halogenase A from Pseudomonas fluorescens Pf-5 (Nowak-Thompson et al., 1999); PltM: halogenase M from Pseudomonas fluorescens Pf-5 (NowakThompson et al., 1999); ere-ORF10: halogenase from Amycolatopsis orientalis (van Wageningen et al., 1998); BhaA: halogenase from Amycolatopsis mediterranei (Pelzer et al., 1999); ComH: halogenase from Streptomyces lavendulae (Chiu et al., 2001); AvilH: halogenase from Streptomyces viridochromogenes (Weitnauer et al., 2001); AdpC: halogenase from Anabena sp. 90 (Rouhiainen et al., 2000); Clm: halogenase from Streptomyces venezuelae (Piraee and Vining, 2001).

H2 CH3 H C H N C C C C OCH3 Cl O HC H C 2 Cl N S C Cl CH3 Fig. 22. Chemical structure of barbamide. In barbamide biosynthesis the involvement of a radical halogenation mechanism is discussed.

A postulated mechanism which takes the cofactor requirements of these halogenases into account is shown in Fig. 20. In this mechanism, we propose that activation of the organic substrate in a monooxygenase-like reaction involving a halogenase-flavin hydroperoxide intermediate is necessary to allow the incorporation of the halide as a nucleophile. Oxygen is removed by specific elimination of water resulting in reformation of a double bond. To allow regioselective incorporation of halide ions, they have to be specifically positioned at the active site. Interestingly, all FADH2 -dependent halogenases that have been detected so far contain two conserved tryptophan residues (Fig. 21). These two tryptophan residues might be involved in halide binding, as could be shown for haloalkane dehalogenases, where two tryptophan residues facilitate the removal of a halide ion from the halogenated substrate during the dehalogenation reaction (Fig. 2; Verschueren et al., 1993). Genes for FADH2 -dependent halogenases have been found in every biosynthetic gene cluster for halogenated metabolites that has been cloned and sequenced so far,

like 7-chlorotetracycline (Dairi et al., 1995), pyrrolnitrin (Hammer et al., 1997, 1999), chloroeremomycin (van Wageningen et al., 1998); balhimycin (Pelzer et al., 1999), pyoluteorin (Nowak-Thompson et al., 1999), rebeccamycin (Zehner et al., 2000; Sanchez et al., 2002), anabaenopeptilides (Rouhiainen et al., 2000), chloramphenicol (Piraee and Vining, 2001), avilamycin A (Weitnauer et al., 2001), and complestatin (Chiu et al., 2001). This clearly demonstrates that FADH2 -dependent halogenases play a major role in biosyntheses of halogenated metabolites. However, investigations on the biosynthesis of fluoroacetate showed that the incorporation of the fluoride ion is catalyzed by a different mechanism that involves nucleophilic substitution by fluoride of S-adenosylmethionine which is subsequently degraded to fluoroacetate (OÕHagan et al., 2002). A different halogenation mechanism must be involved in the biosynthesis of barbamide (Fig. 22) by the cyanobacetreium Lyngbya majuscula, since it could be shown by labelling experiments that a double bond, necessary for the reaction catalyzed by FADH2 -dependent halogenases, cannot exist during barbamide biosynthesis (Sitachitta et al., 2000). In this case a radical mechanism is discussed (Hartung, 1999). 4. Conclusions There is large variety in dehalogenating enzymes and mechanisms for the degradation of halogenated compounds. These enzymes and the organisms capable of growth on halogenated compounds using these

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compounds either as carbon or energy source or in co-metabolic reactions, were detected by screening for growth or the ability to degrade specific halogenated compounds. Thus, it is not surprising that many different dehalogenating enzymes with varying substrate specificities were detected and isolated. However, in the case of halogenating enzymes the situation was quite different. Here usually a halogenated metabolite with biological activity was the starting point. Since these halogenated metabolites are produced by more or less complicated biosynthetic pathways, the substrates for the halogenating enzymes were only known in very few cases. Thus, looking for a halogenating enzyme meant to look for an enzymatic activity without a specific assay. Using the monochlorodimedone assay led to selection for unspecific enzymes that accepted a wide variety of substrates and therefore lacked substrate specificity–– haloperoxidases and perhydrolases. The detection of FADH2 -dependent halogenases that show substrate specificity and regioselectivity solved this problem only partially. The genes for FADH2 -dependent halogenases can now be detected rather easily using genetic probes, however, halogenating activity can still only be shown, if the natural substrate or one with a similar structure, is known and available. Although, this might slow down the detection of new halogenating enzymes, it can be predicted that specific enzymatic halogenation will develop an important synthetic tool for the production of fine chemicals and compounds with biological activity. The question, whether there is any connection between biological halogenation and dehalogenation, can still not be answered. There are no data available showing that biological halogenation led to the development of dehalogenating enzymes. Additionally, similarities between halogenating and dehalogenating enzymes have not yet been found. The only cases where a similarity in the reaction mechanism could be postulated, are the reversible intramolecular substitution reaction catalyzed by halohydrin dehalogenases (Van Hylckama Vileg et al., 2001), the halogenation reaction catalyzed by FADH2 -dependent halogenases, and the postulated involvement of two tryptophan residues in the halogenation reaction catalyzed by FADH2 -dependent halogenases as shown for haloalkane dehalogenase from Xanthobacter autrophicus and the transhalogenation reaction catalyzed by halomethane:bisulfide/halide ion methyltransferase (Coulter et al., 1999).

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