Mutant mono-oxygenase cytochrome P-450 .sub.cam

Abstract

A mutant of the mono-oxygenase cytochrome P-450.sub.cam in which the tyrosine residue at position 96 and/or the cysteine residue at positon 334 is replaced by the residue of any amino acid except phenylalanine.

Description

BACKGROUND OF THE INVENTION

Mono-oxygenases catalyse the selective oxidation of non-functionalised hydrocarbons using oxygen.sup.1, and are therefore of great interest for potential use in organic synthesis. However, progress in this area has been hampered by the difficulty in isolating sufficient quantities of enzyme and the associated electron-transfer proteins. Despite the availability of amino acid sequences of more than 150 different cytochrome P-450 mono-oxygenases, to date structural data of only three are available.sup.2,3,4, and few have been successfully over-expressed in bacterial systems.sup.5.

One cytochrome P-450 mono-oxygenase, which is soluble and can be expressed in sufficient quantities, is the highly specific P-450.sub.cam from P.putida which catalyses the regio- and stereo-selective hydroxylation of camphor (1) to 5-exo-hydroxycamphor.sup.6. The high resolution crystal structure of P-450.sub.cam has been determined.sup.2, and since the mechanism of action of this bacterial enzyme is believed to be very similar to that of its mammalian counterparts, it has been used as a framework on which models of mammalian enzymes are based.

The nucleotide sequence and corresponding amino acid sequence of P-450.sub.cam have been described.sup.5. The location of an active site of the enzyme is known and structure-function relationships have been investigated.sup.13, 14. Mutants of P-450.sub.cam have been described, at the 101 and 185 and 247 positions.sup.15, and at the 87 position.sup.16. A mutant in which tyrosine 96 has been changed to phenyl alanine-96 has been described.sup.12,17,18. But in all these cases the papers report effects of the mutations on the mechanisms of known oxidation reactions. There is no teaching or suggestion that mutation might be used to provide biocatalysts for oxidation of different substrates.

SUMMARY OF THE INVENTION

In an attempt to find new biocatalysts, we have initiated a project which aims to redesign the active site of P-450.sub.cam, such that it is able to carry out specific oxidations of organic molecules which are not substrates for the wild-type protein. Our initial aim was to incorporate an "aromatic pocket" into the P-450.sub.cam active site, which would encourage the binding of substrates containing aromatic side-chains.

In addition, a surface residue remote from the active site was identified (cysteine-334) with effects on protein handling and stability. The cysteine is responsible for unwanted dimerisation of the protein during purification and an alanine residue was therefore substituted for the cysteine in order to improve both of these properties.

The three dimensional structure of P-450.sub.cam shows the active site to provide close van der Waals contact with the hydrophobic groups of camphor as shown in FIG. 1. Three aromatic residues (Y96, F87 and F98) are grouped together and line the substrate binding pocket, with a hydrogen bond between tyrosine 96 and the camphor carbonyl oxygen maintaining the substrate in the correct orientation to ensure the regio-and stereo-specificity of the reaction. Replacement of any of these aromatic residues with a smaller, hydrophobic non-aromatic side-chain could provide the desired "aromatic pocket".

Molecular modelling was used to investigate the likely effects of point mutations to the three aromatic residues. The program GRID.sup.7 was used to calculate an energy of interaction between an aromatic probe and possible mutants of cytochrome P-450.sub.cam where these residues were changed to alanine (F87A, Y96A and F98A). The results were then examined graphically using the molecular modelling package Quanta.sup.8.

The mutant F98A appeared to have the strongest binding interaction within the active site cavity accessible to the aromatic probe, with that of Y96A being slightly smaller, and that of F87A being substantially less. It was decided in the first instance to mutate tyrosine 96 to alanine as it is more central to the binding pocket, whereas phenylalanine 98 is in a groove to one side. Also, removal of tyrosine 96 should decrease the specificity of the enzyme towards camphor due to the loss of hydrogen bonding to the substrate.

According to one aspect of the present invention a mutant of the mono-oxygenase cytochrome P-450.sub.cam is provided in which the tyrosine residue at position 96 and/or the cysteine residue at position 334 is replaced by the residue of any amino acid except phenylalanine.

According to another aspect of the present invention a mutant of the mono-oxygenase cytochrome P-450.sub.cam is provided in which the tyrosine residue at position 96 and/or the cysteine residue at position 334 is replaced by another amino acid residue, which mutant has the property of catalysing the oxidation of any one of the following:- polycyclic aromatic hydrocarbons, linear or branched alkanes, diphenyl and biphenyl compounds including halogenated variants of such compounds and halogenated hydrocarbons.

According to yet another aspect of the present invention a method is provided of oxidising a compound selected from a polycyclic aromatic hydrocarbon, a linear or branched alkane, a diphenyl or biphenyl compound including a halogenated variant of such a compound or a halogenated hydrocarbon, the method comprising contacting the selected one of the compounds under oxidising conditions with mono-oxygenase cytochrome P-450.sub.cam in which the tyrosine residue at position 96 and/or the cysteine residue at position 334 is replaced by another amino acid residue.

Preferably the amino acid is selected from any one of the following: alanine, arginine, asparagine, aspartic acid, cysteine, glutamic acid, glutamine, glycine, histidine, isoleucine, leucine, lysine, methionine, proline, serine, threonine, tryptophan, tyrosine and valine except that in the case of the tyrosine residue at position 96, the amino acid is not tyrosine and in the case of the cysteine residue at position 334, the amino acid is not cysteine.

The amino acid which replaces tyrosine at position 96 is conveniently one of the small hydrophobic amino acids, e.g. alanine, glycine, valine, leucine or isoleucine, with alanine being preferred as exemplified below.

Alternatively the amino acid replacing tyrosine at position 96 may be one of the charged amino acids, e.g. a negatively charged acid such as aspartic acid or glutamic acid for hydrogen bonding to a positively charged substrate; or a positively charged compound such a lysine, arginine or histidine for hydrogen bonding to a negatively charged substrate which are not members of the camphor family.

The mutation at position 96 is believed to be the key which enables the mutant enzymes to catalyse the oxidation of a relatively wide range of organic substrates. Other amino acids adjacent to the active site of the enzyme may also be mutated in order to change the shape and specificity of the active site. These other amino acids include those at positions 87, 98, 185, 244, 247, 295 and 297. It is envisaged that the amino acid at one or more of these positions may be replaced by: a small hydrophobic amino acid so as to enlarge the active site; or a large hydrophobic amino acid so as to reduce the size of the active site; or by an amino acid having an aromatic ring to bond to a corresponding aromatic ring of a substrate.

Regarding the oxidising reactions, the conditions are described in the literature references attached. The enzyme system typically includes putidaredoxin and putidaredoxin reductase together with NADH as co-factors in addition to the mutant enzyme. Various classes of organic compounds are envisaged:

i) The organic compound is an aromatic compound, either a hydrocarbon or a compound used under conditions in which it does not inactivate or denature the enzyme. Since the mutation has been effected with a view to creating an aromatic-binding pocket in the surface of the enzyme, the mutant enzyme is capable of catalysing oxidation of a wide variety of aromatic compounds. Oxidation of example aromatic and polyaromatic compounds is demonstrated in the experimental section below and is believed very surprising given that the wild-type enzyme catalyses the oxidisation of only members of the camphor family. ii) The organic compound may be a hydrocarbon, e.g. aliphatic or alicyclic, carrying a functional group. An aromatic protective group is added to the functional group prior to the oxidation reaction and removed from the functional group after the oxidation reaction. A suitable aromatic group is a phenyl group. The aromatic protection group is expected to hold the substrate in place. Thus the protecting group serves two purposes: firstly it makes the substrate more hydrophobic and hence increases binding to the hydrophobic enzyme pocket; secondly it holds the substrate in place at the active site. Thus, with the correct aromatic protection group, both regio-and stereo-selective hydroxylation of the substrate may be achieved. The example of cyclohexylbenzene is described in the experimental section below.

Examples of monofunctionalised hydrocarbons are cyclohexyl, cyclopentyl and alkyl derivatives (Scheme 1). The oxidation products of these compounds are valuable starting materials for organic synthesis, particularly when produced in a homochiral form. A range of aromatic protecting groups are envisaged, e.g. benzyl or naphtyl ethers and benzoyl or naphthoyl esters and amides (Scheme 1). Of interest are also benzoxazole groups as carboxyl protecting groups and N-benyl oxazolidine groups as aldehyde protecting groups. Both can be easily cleaved after the enzymatic oxidation and have previously been described in the literature for the microbial oxidations of aldehydes and acids.

iii) The organic compound is a C5 to C12 aliphatic or alicyclic hydrocarbon. Oxidation of cyclohexane and linear hydrocarbons is demonstrated in the experimental section below and once again it is believed quite surprising given that the wild-type enzyme catalyses the oxidation of only members of the camphor family. iv) The organic compound is a halogenated aliphatic or alicyclic hydrocarbon. Oxidation of lindane (hexachlorocyclohexane) is also described below.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a showing that the three dimensional structure of P-450.sub.cam shows the active site to provide close van der Waals contact with the hydrophobic groups of camphor. FIG. 2 is a gas chromatograph of diphenylmethane (A) and hydroxylated product formed following incubation with P-450.sub.cam Y96A mutant.

Based on the above considerations, mutant proteins were constructed which contained alanine, lysine, valine, or phenylalanine instead of tyrosine at position 96 (Y96). Additional mutants were constructed in which these active site replacements were combined with the surface mutation of cysteine at position 334 to alanine. Lastly several active site mutations and the surface mutation were combined in one protein to constitute a multiple mutant enzyme. The genes encoding cytochrome P-450.sub.cam, and its natural electron-transfer partners puridaredoxin and putidaredoxin reductase, were amplified from the total cellular DNA of P. Putida using the polymerise chain reaction (PCR). The expression vector/E. coli host combinations employed were pRH1091.sup.9 in strain JM109 for P-450.sub.cam, pUC 118 in strain JM109 for putidaredoxin, and pGLW11 in strain DH5.sup.oc for putidaredoxin reductase. Oligonucleotide-directed site-specific mutagenesis was carried out using an M13mp19 subclone by the method of Zoller and Smith.sup.10, and mutant selection was by the method of Kunkel.sup.11.

The mutant Y96A was shown to catalyse the hydroxylation of camphor (1), although compared to the wild-type enzyme the reaction was less selective, similar to that reported for the mutant Y96F.sup.12. This decrease in selectivity can be attributed to the loss of the hydrogen bond between Y96 and camphor. The properties of wild-type and Y96A proteins were further investigated with a variety of binding and activity assays.

Binding of potential substrates was investigated by spectroscopic methods. The wild-types enzyme in the absence of substrate is in the 6-co-ordinated, low-spin form with a weakly bound water occupying the sixth co-ordination site, and shows a characteristic Soret maximum at 391 nm. Binding of the substrate analogues adamantanone (2), adamantane (3) and norbornane (4) also fully converted the haem to the high-spin form. However, diphenylmethane (5) did not give a shift in the absorption spectrum.

The Y96A mutant, while giving the same results for compounds (3) and (4), was not fully converted to the high-spin form even when (1) and (2) were added in excess. Most interestingly however, and in contrast to the wild-type, Y96A showed partial conversion to the haem to the high-speed form with diphenylmethane, indicating binding of this compound to the mutant protein.

As expected, the dissociation constants (K.sub.app) for camphor and adamantanone are increased in Y96A. On the other hand, the K.sub.app values for the hydrophobic substrates adamantane and norbornane are reduced, indicating that the enzyme pocket has become more selective for hydrophobic substrates. The greatest change in binding was obtained with diphenylmethane, which bound poorly to wild-type protein, but showed greatly enhanced affinity for the Y96A mutant (Table 1).

Once binding of diphenylmethane by the Y96A protein had been established, catalytic substrate turnover was investigated. The mutant protein was reconstituted with putidaredoxin and putidaredoxin reductase. Diphenylmethane (5) was added and the mixture was incubated with NADH and oxygen.

A solution containing 10 .mu.M putidaredoxin, 2 .mu.M putidaredoxin reductase, 1 .mu.M cytochrome P-450.sub.cam mono-oyxgenase (wild-type or mutant) and 1 mM diphenylmethane in 100 mM KC1, 20 mM KH.sub.2 PO.sub.4 pH7.4 was preincubated at 25.degree. C. in a shaker for 5 min. The enzymatic reaction was initiated by firstly adding NADH to a total concentration of 2 mM. Further four aliquots of NADH (to increase the NADH concentration by 1 mM each time) were added in intervals of 5 min and the reaction quenched after 30 min by adding 0.5 ml chloroform. The chloroform layer was analysed by gas chromatography.

Organic extracts of the crude incubation mixture were analysed by gas chromatography. Only one major new peak was detected by GC (see FIG. 2), which had the same retention time as an authentic sample of para-hydroxydiphenylmethane (6). The other aromatic hydroxylation products, the ortho and meta isomers, had different retention times. Further confirmation of the identity of the product as structure (6) was provided by mass spectrometry, which gave the correct mass peak at 184.

Using the above experimental techniques, the inventors have investigated a considerable number of organic compounds as substrates for both the wild-type P-450.sub.cam enzyme and also the mutant version Y96A. Further work has included mutants designated Y96V; Y96L; Y96F; C334A; the combined mutant F87A, Y96G, F193A and the combined active site and surface mutants of Y96A, C334A; Y96V, C334A; Y96L, C334A; Y96F, C334A; F87A, Y96G, F193A, C334A.

The results for Y96A are set out in Table 2, in which structurally related molecules are grouped together. Those substrates where oxidation has been demonstrated by means of NADH turnover are marked with a + sign.

Spin high/low: numbers shows the percentage of P-450 (OD.sub.417 0.2-0.4) converted from the low- to high-spin equilibrium state in the presence of 200 .mu.M test compound, in phosphate buffer (40 mM phosphate, 68 mM potassium, pH 7.4). Spin state equilibrium is assessed with a UV/vis spectrophotometer: low spin at OD.sub.417 and high spin at OD392 nd; not done.

Vs DTT: numbers show the percentage displacement of DTT (200 .mu.M) bound to P-450 by competition with test compounds (200 .mu.M) in phosphate buffer. DTT binding to P-450 results in absorbance peaks at OD374 and OD.sub.461, so displacement is measured with a UV/vis spectrophotometer.

Examples are included in Table 2(a) to 2(h) for each class of compounds identified in points (i) to (iv) above.

Reaction products for some substrate compounds have been purified by high performance liquid chromatography and identified by mass spectroscopy, nuclear magnetic resonance, and/or co-elution. Table 3 details the NADH consumption for oxidation of small linear, branched and cyclic hydrocarbons by the mutant Y96A, C334A. Table 4(a) to 4(h) details the product distributions for mutant and substrate combinations where this has been elucidated to date.

__________________________________________________________________________Scheme 1Hydrocarbons ##STR1## ##STR2## ##STR3## ##STR4## ##STR5##--Z Protecting Group__________________________________________________________________________--OH ##STR6## ##STR7##--NH.sub.2 ##STR8##--COOH ##STR9## ##STR10##--CHO ##STR11##__________________________________________________________________________ TABLE 1______________________________________ K.sub.app (.mu.M).sup.a WT Y96A______________________________________ ##STR12## 1 6.3 12 ##STR13## 2 12 28 ##STR14## 3 8.4 1.4 ##STR15## 4 330 92 ##STR16## 5 >1500.sup.b 73______________________________________ .sup.a Values are the average of two independent measurements using the method of Sligar (S. G. Sligar, Biochemistry, 1976, 15, 5399-5406). The value of K.sub.app is strongly dependent on the concentration of K.sup.+ in the buffer. At [K.sup.+ ] > 150 mM. K.sub.app for camphor is 0.6 .mu.M for both wildtype and Y96A. Data in this table were determined at [K.sup. ] = 70 mM in phosphate buffer, pH 7.4, in order to avoid salting out of substrates at higher ion concentrations. .sup.b Saturation not reached. TABLE 2(a)__________________________________________________________________________ Wild type Mutant Y96A Wild type Mutant Y96AP450cam-substrate Interactions .DELTA.Spin .DELTA.Spin NADH NADHSubgroup: 1-ring high/low Vs DTT high/low Vs DTT turnover? GC? turnover? GC?__________________________________________________________________________ ##STR17## Benzene -- -- -- -- ##STR18## Toluene -- -- 30 30 ##STR19## Ethylbenzene -- -- 40 40 ##STR20## Styrene -- -- 30 30 ##STR21## Cyclohexene -- 5 40 40 ##STR22## 1,3-Cyclohexadiene nd nd nd nd ##STR23## 1,4-Cyclohexadiene -- 5 15 20 ##STR24## Cyclohexane -- -- 60 60 + ##STR25## Hexane -- -- 70 60 + ##STR26## Methylcyclohexane -- -- 70 60 ##STR27## (S)-(+)-Carvone 10 60 10 80__________________________________________________________________________ TABLE 2(b)__________________________________________________________________________ Wild type Mutant Y96A Wild type Mutant Y96A .DELTA.Spin .DELTA.Spin NADH NADHP450cam-substrate interactions high/ high/ turn- turn-Subgroup: 2-ring, Naphthalene low Vs DTT low Vs DTT over? GC? over? GC?__________________________________________________________________________ ##STR28## Naphthalene -- -- 15 20 ##STR29## 1-Ethylnaphthalene -- -- 5 20 ##STR30## 2-Ethylnaphthalene -- -- 10 20 ##STR31## 2-Naphthylacetate -- 5 -- 5 ##STR32## 1-Naphthylacetate -- 5 -- 5 ##STR33## 1-Naphthylpropionate -- 20 0 20 ##STR34## 1-Naphthylbutyrate -- 5 -- 5 ##STR35## Naphthylphenylketone -- 5 -- 5 ##STR36## 1,2-Dihydronaphthalene 5 20 30 90 ##STR37## 1,2,3,4-Tetrahydro naphthalene 5 10 40 40__________________________________________________________________________ TABLE 2(c)__________________________________________________________________________ Wild type Mutant Y96A Wild type Mutant Y96A .DELTA.Spin .DELTA.Spin NADH NADHP450cam-substrate interactions high/ high/ turn- turn-Subgroup: 2-ring, DPM low Vs DTT low Vs DTT over? GC? over? GC?__________________________________________________________________________ ##STR38## Diphenylmethane -- 5 45 nd + + ##STR39## Diphenylether 10 5 20 50 ##STR40## Benzophenone -- 20 -- 20 ##STR41## Cyclohexylphenylketone -- 30 60 nd ##STR42## Phenylbenzoate -- 5 -- -- ##STR43## N-Phenylbenzylamine 5 45 nd ##STR44## Bibenzyl -- -- 55 55 ##STR45## cis-Stilbene -- 20 40 50 ##STR46## Biphenyl -- 20 -- 90 ##STR47## Cyclohexylbenzene 20 20 80 nd ##STR48## trans-Stilbene -- -- -- -- ##STR49## Benzylether -- 5 55 nd__________________________________________________________________________ TABLE 2(d)__________________________________________________________________________ Wild type Mutant Y96A Wild type Mutant Y96A .DELTA.Spin .DELTA.Spin NADH NADHP450cam-substrate interactions high/ high/ turn- turn-Subgroup: 3-ring low Vs DTT low Vs DTT over? GC? over? GC?__________________________________________________________________________ ##STR50## Anthracene ##STR51## Phenanthrene -- -- 20 20 + ##STR52## Fluorene -- -- -- 50 ##STR53## 2-Fluorencarboxzaldehyde -- -- -- 50 ##STR54## 9-Fluorenone -- 20 -- 5 ##STR55## Anthrone -- 5 -- 5 ##STR56## Anthraquinone ##STR57## 2-Ethylanthraquinone__________________________________________________________________________ TABLE 2(e)__________________________________________________________________________ Wild type Mutant Y96A Wild type Mutant Y96A .DELTA.Spin .DELTA.Spin NADH NADHP450cam-substrate interactions high/ high/ turn- turn-Subgroup: 4,5-ring low Vs DTT low Vs DTT over? GC? over? GC?__________________________________________________________________________ ##STR58## Chrysene -- -- -- -- ##STR59## 1,2-Benzanthracene -- -- -- -- ##STR60## Fluoranthene -- 5 20 10 ##STR61## Pyrene* -- -- -- -- ##STR62## Perylene* -- -- -- --__________________________________________________________________________ TABLE 2(f)__________________________________________________________________________ Wild type Mutant Y96A Wild type Mutant Y96A .DELTA.Spin .DELTA.Spin NADH NADHP450cam-substrate interactions high/ high/ turn- turn-Subgroup: Cyclic Alkanes low Vs DTT low Vs DTT over? GC? over? GC?__________________________________________________________________________ ##STR63## cis-Decahydro- naphthalene nd nd nd nd ##STR64## trans-Decahydro naphthalene 20 10 90 70 ##STR65## Cyclohexane -- -- 60 60 + ##STR66## Methylcyclohexane 50 50 100 70__________________________________________________________________________ TABLE 2(g)__________________________________________________________________________ Wild type Mutant Y96A Wild type Mutant Y96A .DELTA.Spin .DELTA.Spin NADH NADHP450cam-substrate interactions high/ high/ turn- turn-Subgroup: n-Alkanes low Vs DTT low Vs DTT over? GC? over? GC?__________________________________________________________________________n-Pentane -- 5 55 40 +n-Hexane -- -- 60 40 +n-Heptane 5 5 60 40 +n-Octane -- 5 80 45 +n-Nonane -- -- 70 45 +n-Decane nd nd nd ndn-Undecane nd nd 20 20n-Dodecane nd nd 5 5CH.sub.3 (CH.sub.2).sub.14 CH.sub.3 n-Hexadecane -- -- -- --CH.sub.3 (CH.sub.2).sub.15 CH.sub.3 n-Heptadecane -- -- -- --CH.sub.3 (CH.sub.2).sub.11 OSO.sub.3,Na SDS -- 20 -- 60CH.sub.3 (CH.sub.2).sub.7 CH.dbd.CH(CH.sub.2).sub.7 CO.sub.2 H Oleic acid* -- 10? -- 20?[(CH.sub.3).sub.2 CH(CH.sub.2).sub.3 CH(CH.sub.3)(CH.sub.2).sub.3CH(CH.sub.3)CH.sub.2 CH.sub.2 --].sub.2 Squalene -- -- -- 20 ##STR67## Isoprene -- -- 10 10__________________________________________________________________________ TABLE 2(h)__________________________________________________________________________ Wild type Mutant Y96A Wild type Mutant Y96AP450cam-substrate interactions .DELTA.Spin .DELTA.Spin NADH NADHSubgroup: Camphor-like high/low Vs DTT high/low Vs DTT turnover? GC? turnover? GC?__________________________________________________________________________ ##STR68## (1R)-(-)-Camphorquinone 80 80 80 80 ##STR69## (1R)-(-)-Fenchone 40 70 50 80 ##STR70## Dicyclopentadiene 50 80 90 90__________________________________________________________________________ TABLE 3______________________________________Turnover of Small Alkanes by P450cam MutantsAll mutants listed below also contain the C334A mutation.Turnover rate measured as NADH consumption rate(nmole NADH/nmole P450cam/s).Alkane substrate:Main chain Wildlength Name type Y96A______________________________________C4 n-butane -- --C4 2-methyl butane background 4.6C4 2,3-dimethyl butane background 16.8C4 2,2-dimethyl butane background 14.0C5 n-pentane background 5.8C5 2-methyl pentane 3.8 11.7C5 3-methyl pentane 1.3 14.2C5 2,4-dimethyl pentane 0.2 12.6C5 2,2-dimethyl pentane 5.2 12.8C5 2,2,4-trimethyl pentane 0.9 5.3C5 3-ethyl pentane background 16.2C6 n-hexane background 6.0C6 2-methyl hexane background 10.6C7 n-heptane 2.7 4.4C7 2-methyl heptane background 2.1C7 4-methyl heptane 1.4 10.2C8 n-octane background 5.8C7 cycloheptane 4.4 42.5______________________________________ Product structures and distributions following oxidation of substrates with P450cam active site mutants. "background" - typical background NADH oxidation rate is 0.07 nmole NADH (nmole P450cam).sup.-1 sec.sup.-1 TABLE 4(a)__________________________________________________________________________Product structure and distributions following oxidation of substrateswith P450camactive site mutants. All mutants shown below also contain the C334Amutation.Cyclohexylbenzene Products (%) for mutants:Products WT Y96A Y96F Y96L Y96V__________________________________________________________________________ ##STR71## 3-ol 43 20 54 38 28 ##STR72## 3-ol 20 20 27 23 39 ##STR73## Trans- 4-ol 25 15 6 23 10 ##STR74## Cis- 4-ol 12 45 13 16 23Total products (area/10.sup.5) 0.8 7.4 1.1 10.4 12.5 ##STR75## ##STR76## ##STR77##__________________________________________________________________________ TABLE 4(b)______________________________________ Products (%) forPhenylcyclohexene mutants:Products WT Y96A______________________________________ ##STR78## 3-one (A) 24 25 ##STR79## 3-ol (B) 76 75Total products (area/10.sup.6) 42 36 ##STR80## ##STR81## ##STR82##______________________________________ TABLE 4(c)__________________________________________________________________________ Products (%) for mutants:Naphthalene F87A-F96G-Products WT Y96A Y96F Y96L Y96V F193A__________________________________________________________________________ ##STR83## 1-ol 100 100 100 100 100 100 ##STR84## 2-ol 0 0 0 0 0 0Total products (area/10.sup.5) (0.016) 1.1 2.4 0.7 1.4 0.1 ##STR85## ##STR86##__________________________________________________________________________ TABLE 4(d)______________________________________ Products (%) for mutants: F87A-Phenanthrene F96G-Products WT Y96A Y96F Y96L Y96V F193A______________________________________A 38 49 41 35.5 41 27B 15 23 31 41 38 41C 12 13 5 9 11 3D 35 15 23 14.5 10 29Total products 0.075 7.0 4.5 2.8 1.6 0.065(area/10.sup.6) ##STR87##______________________________________ TABLE 4(e)______________________________________Products (%) for mutants:Fluoranthene F87A-F96G-Products WT Y96A Y96F Y96L Y96V F193A______________________________________A 0 84 -- -- -- 0B 0 16 -- -- -- 100Total 0 2.7 -- -- -- 0.2products(area/10.sup.6)______________________________________ ##STR88## - TABLE 4(f)______________________________________Products (%) for mutants:Pyrene F87A-F96G-Products WT Y96A Y96F Y96L Y96V F193A______________________________________A 0 40 43 23 30 33B 0 43.6 29 64.5 55 40C 0 5 12.5 7.9 12 20D 0 11.4 15.5 4.6 3 7Total 0 1.2 1.5 1.5 1.6 0.02products(area/10.sup.6)______________________________________ ##STR89## - TABLE 4(g)______________________________________Lindane Products Products (%) for mutants(hexachlorocyclohexane) WT Y96A______________________________________A 100 100Turnover rate 7.5 43.5nmole NADH (nmolP450).sup.-1 s.sup.-1______________________________________ ##STR90## - TABLE 4(h)______________________________________ Products (%) for mutants: Y96F Y96A______________________________________Hexane Products2-hexanone 10 153-hexanone 16 282-hexanol 24 263-hexanol 50 32Relative activity 18.2 25.5(WT = 1)2-Methyl hexane Products2-methyl-2-hexanol 72 745-methyl-2-hexanone 16 142-methyl-3-hexanol 7 45-methyl-2-hexanol 5 8Relative activity 2.3 2.6(WT = 1)______________________________________

REFERENCES

1. "Cytochrome P-450: Structure, Mechanism, and Biochemistry", ed. P R Ortiz de Montellano, Plenum Press, New York, 1986. 2. T L Poulos, B C Finzel and A J Howard, J. Mol. Biol., 1987, 195, 687-700. 3. J A Peterason, U.-Y. Lu, J Geisselsoder, S Graham-Lorence, C Carmona, F Witney, and M C Lorence, J. Biol. Chem., 1992, 267, 14193-14203. 4. K G Ravichandran, S S Boddupali, C A Hasemann, J A Peterson, and J Deisenhofer, Science, 1993, 261, 731-736. 5. B P Unger, I C Gunsalus, and S G Sligar, J. Biol. Chem., 1986, 261, 1158-1163; J S Miles, A W Munro, B N Rospendowski, W E Smith, J McKnight, and A J Thomson, Biochem. J., 1992, 288, 503-509; T H Richardson, M J Hsu, T Kronbach, H J Barnes, G Chan, M R Waterman, B Kemper, and E F Johnson, Arch. Biochem. Biophys., 1993, 300, 510-516; S S Boddupalli, T Oster, R W Estabrook, and J A Peterson, J Biol. Chem., 1992, 267, 10375-10380; H Li K Darish and T L Poulos, J Biol. Chem., 1991, 266-11909-11914. 6. I C Gunsalus and G C Wagner, Methods Enzymol., 1978, 52, 166-188. 7. P J Goodford, J Med. Chem., 1985, 28, 849-857. 8. Quanta 4.0, Molecular Simulations Inc., 16 New England Executive Park, Burlington, Mass. 01803-5297. 9. J E Baldwin J M Blackburn, R J Heath, and J D Sutherland, Bioorg, Med. Chem. Letts. 1992, 2, 663-668. 10. M J Zoller and M Smith, Nucleic Acids Res., 1982, 10, 6487. 11. T A Kunkel, Proc. Natl. Acad. Sci., 1985, 82, 488-492. 12. C Di Primo, G Hui Bin Hoa, P. Douzou, and S Sligar, J. Biol. Chem., 1990, 265, 5361-5363. 13. D Filipovic, Biochemical and Biophysical Research Communications, Vol. 189, No. 1, 1992, Nov. 30, 1992, pages 488-495. 14. S G Sligar, D Filipovic, and P S Stayton, Methods in Enzymology, Vol. 206, pages 31-49. 15. P J Loida and S G Sligar, Protein Engineering, Vol. 6, No. 2, pages 207-212, 1993. 16. S F Tuck et al., The Journal of Biological Chemistry, Vol. 268, No. 1, Jan. 5, 1993, pages 269-275. 17. W M Atkins and S G Sligar, The Journal of Biological Chemistry, Vol. 263, No. 35, Dec. 15, 1988, pages 18842-18849. 18. W M Atkins and S G Sligar, Biochemistry 1990, 29, 1271-1275.

Claims

1. A mutant mono-oxygenase cytochrome P-450.sub.cam wherein the tyrosine residue at position 96 is replaced by the residue of a small hydrophobic amino acid.

2. The mutant of claim 1, wherein said mutant catalyzes the oxidation of a compound selected from the group consisting of a polycyclic aromatic hydrocarbon, a linear or branched alkane, a biphenyl compound and a halogenated hydrocarbon.

3. The mutant of claim 1, wherein the amino acid is selected from the group consisting of alanine, glycine, isoleucine, leucine, and valine.

4. The mutant of claim 1, wherein an amino acid residue at one or more of the positions 87, 98, 185, 244, 247, 295 or 297 is independently replaced by another amino acid residue.

5. The mutant of claim 2, wherein the amino acid is selected from the group consisting of alanine, glycine, isoleucine, leucine, and valine.

6. The mutant of claim 2, wherein an amino acid residue at one or more of the positions 87, 98, 185, 244, 247, 295 or 297 is independently replaced by another amino acid residue.

7. The mutant of claim 3, wherein an amino acid residue at one or more of the positions 87, 98, 185, 244, 247, 295 or 297 is independently replaced by another amino acid residue.

8. A method of oxidizing a compound selected from the group consisting of a polycyclic aromatic hydrocarbon, a linear or branched alkane, a biphenyl compound or a halogenated variant thereof and a halogenated hydrocarbon, comprising the step of contacting said compound under oxidizing conditions with mono-oxygenase cytochrome P-450.sub.cam wherein the tyrosine residue at position 96 is replaced by a small hydrophobic amino acid residue.

9. The method of claim 8, wherein the amino acid is selected from the group consisting of alanine, glycine, isoleucine, leucine, and valine.

10. The method of claim 8, wherein an amino acid residue at one or more of the positions 87, 98, 185, 244, 247, 295 or 297 is independently replaced by another amino acid residue.

11. The method of claim 9, wherein an amino acid residue at one or more of the positions 87, 98, 185, 244, 247, 295 or 297 is independently replaced by another amino acid residue.