Dual role of human cytochrome P450 3A4 residue Phe-304 in substrate specificity and cooperativity.

The structural basis of cooperativity of progesterone hydroxylation catalyzed by human cytochrome P450 3A4 has been investigated. A recent study suggested that substitution of larger side chains at positions Leu-211 and Asp-214 partially mimics the action of effector by reducing the size of the active site. Based on predictions from molecular modeling that Phe-304 in the highly conserved I helix is involved in both effector and substrate binding, a tryptophan residue was substituted at this position. The purified F304W mutant displayed hyperbolic progesterone hydroxylase kinetics, indicating a lack of homotropic cooperativity. However, the mutant remained responsive to stimulation by alpha-naphthoflavone, exhibiting a 2-fold decrease in the K(m) value for progesterone 6beta-hydroxylation in the presence of 25 microM effector. Combining substitutions to yield the triple mutant L211F/D214E/F304W maintained the V(max) and decreased the K(m) for progesterone 6beta-hydroxylation, minimized stimulation by alpha-naphthoflavone, and decreased the rate of alpha-naphthoflavone oxidation to one-eighth of the wild type. Interestingly, the DeltaA(max) for spectral binding of alpha-naphthoflavone was unaltered in L211F/D214E/F304W. Overall, the results suggest that progesterone and alpha-naphthoflavone are oxidized at separate locations within the P450 3A4 binding pocket, although both substrates appear to have equal access to the reactive oxygen.

2,2',3,3',6,6'-hexachlorobiphenyl hydroxylation by active site mutants of cytochrome P450 2B1 and 2B11.

The structural basis of species differences in cytochrome P450 2B-mediated hydroxylation of 2,2',3,3',6,6'-hexachlorobiphenyl (236HCB) was evaluated by using 14 site-directed mutants of cytochrome P450 2B1 and three point mutants of 2B11 expressed in Escherichia coli. To facilitate metabolite identification, seven possible products, including three hydroxylated and four dihydroxylated hexachlorobiphenyls, were synthesized by direct functionalization of precursors and Ullmann and crossed Ullmann reactions. HPLC and GC/MS analysis and comparison with authentic standards revealed that 2B1, 2B11, and all their mutants produced 4, 5-dihydroxy-236HCB and 5-hydroxy-236HCB, while 2B11 L363V and 2B1 I114V mutants also catalyzed hydroxylation at the 4-position. The amount of products formed by 2B1 mutants I114V, F206L, L209A, T302S, V363A, V363L, V367A, I477A, I477L, G478S, I480A, and I480L was smaller than that of the wild type. I477V exhibited unaltered 236HCB metabolism, and I480V produced twice as much dihydroxy product as the wild type. For 2B11, substitution of Val-114 or Asp-290 with Ile decreased the product yields. Replacement of Leu-363 with Val dramatically altered the profile of 236HCB metabolites. In addition to an increase in the overall level of hydroxylation, the mutant mainly catalyzed hydroxylation at the 4-position. Incubation of P450 2B1 with 5-hydroxy-236HCB produced 4,5-dihydroxy-236HCB, which indicates that 4,5-dihydroxy-236HCB may be formed by a direct hydroxylation of 5-hydroxy-236HCB. The findings from this study demonstrate the importance of residues 114, 206, 209, 302, 363, 367, 477, 478, and 480 in 2B1 and 114, 290, and 363 in 2B11 for 236HCB metabolism.

Use of the steroid derivative RPR 106541 in combination with site-directed mutagenesis for enhanced cytochrome P-450 3A4 structure/function analysis.

RPR 106541 (20R-16alpha,17alpha-[butylidenebis(oxy)]-6al pha, 9alpha-difluoro-11beta-hydroxy-17beta-(methylthio)androst a-4-en-3-one) is an airway-selective steroid developed for the treatment of asthma. Two metabolites produced by human liver microsomes were identified as R- and S-sulfoxide diastereomers based on liquid chromatography/mass spectrometry analysis, proton nuclear magnetic resonance, and cochromatography with standards. Sulfoxide formation was determined to be cytochrome P-450 (CYP) 3A4-dependent by correlation with CYP3A4-marker nifedipine oxidase activity, inhibition by cyclosporin A and troleandomycin, and inhibition of R- (70%) and S- (64%) sulfoxide formation by anti-3A antibody. Expressed CYP2C forms catalyzed RPR 106541 sulfoxidation; however, other phenotyping approaches failed to confirm the involvement of CYP2C forms in these reactions in human liver microsomes. Expressed CYP3A4 catalyzed the formation of the sulfoxide diastereomers in a 1:1 ratio, whereas CYP3A5 displayed stereoselectivity for formation of the S-diastereomer. The high rate of sulfoxidation by CYP3A4 and the blockage of oxidative metabolism at the electronically favored 6beta-position provided advantages for RPR 106541 over other substrates as an active site probe of CYP3A4. Therefore, oxidation of RPR 106541 by various CYP3A4 substrate recognition site (SRS) mutants was assessed. In SRS-4, A305V and F304A showed dramatically reduced rates of R-diastereomer formation (83 and 64% decreases, respectively), but S-diastereomer formation was affected to a lesser extent. A370V (SRS-5) showed decreased formation of the R-sulfoxide (52%) but increased formation of the S-diastereomer. In the SRS-2 region, the most dramatic change in sulfoxide ratios was observed for L210A. In conclusion, the structure of RPR 106541 imposes specific constraints on enzyme binding and activity and thus represents an improved CYP3A4 probe substrate.

Use of chimeric enzymes and site-directed mutagenesis for identification of three key residues responsible for differences in steroid hydroxylation between canine cytochromes P-450 3A12 and 3A26.

Canine cytochromes P-450 3A12 and 3A26 differ by 22 out of 503 amino acid residues. Chimeric constructs and site-directed mutants were used to identify the residues responsible for the much higher rates of steroid hydroxylation by 3A12. Six initial 3A12/3A26 hybrids were generated using convenient restriction sites, and site-directed mutagenesis was used to restore full 3A12 activity to two of the hybrids. One pair of 3A12/3A26 chimeras indicated that the first four residue differences between 3A12 and 3A26 were at least partially responsible for the differences in progesterone hydroxylation. Conversion in one of the hybrids of the Ile-187 residue found in 3A26 to the Thr in 3A12 conferred 3A12 levels of progesterone 6beta-hydroxylase activity. Analysis of another chimera identified key residues within an internal PstI fragment (codons 331-459) containing six amino acid residue differences. Subsequent site-directed mutagenesis of 3A26 residues Ser-368 and Val-369 to Pro and Ile, respectively, restored the rate of formation of 6beta-hydroxyprogesterone by the hybrid to that of 3A12. The simultaneous conversion of 3A26 residues 187, 368, and 369 to those of 3A12 conferred greater than a third of the progesterone 6beta-hydroxylase activity and all of the testosterone and androstenedione 6beta-hydroxylase activity of 3A12. Addition of the carboxyl terminal 44 3A12 residues to the 3A26 triple mutant doubled progesterone 6beta-hydroxylase activity. This is the first study to use catalytically distinct cytochromes P-450 3A from the same species in the elucidation of structure-function relationships.

Analysis of human cytochrome P450 3A4 cooperativity: construction and characterization of a site-directed mutant that displays hyperbolic steroid hydroxylation kinetics.

Cytochrome P450 3A4 is generally considered to be the most important human drug-metabolizing enzyme and is known to catalyze the oxidation of a number of substrates in a cooperative manner. An allosteric mechanism is usually invoked to explain the cooperativity. Based on a structure-activity study from another laboratory using various effector-substrate combinations and on our own studies using site-directed mutagenesis and computer modeling of P450 3A4, the most likely location of effector binding is in the active site along with the substrate. Our study was designed to test this hypothesis by replacing residues Leu-211 and Asp-214 with the larger Phe and Glu, respectively. These residues were predicted to constitute a portion of the effector binding site, and the substitutions were designed to mimic the action of the effector by reducing the size of the active site. The L211F/D214E double mutant displayed an increased rate of testosterone and progesterone 6beta-hydroxylation at low substrate concentrations and a decreased level of heterotropic stimulation elicited by alpha-naphthoflavone. Kinetic analyses of the double mutant revealed the absence of homotropic cooperativity with either steroid substrate. At low substrate concentrations the steroid 6beta-hydroxylase activity of the wild-type enzyme was stimulated by a second steroid, whereas L211F/D214E displayed simple substrate inhibition. To analyze L211F/D214E at a more mechanistic level, spectral binding studies were carried out. Testosterone binding by the wild-type enzyme displayed homotropic cooperativity, whereas substrate binding by L211F/D214E displayed hyperbolic behavior.

Analysis of four residues within substrate recognition site 4 of human cytochrome P450 3A4: role in steroid hydroxylase activity and alpha-naphthoflavone stimulation.

Sequence alignment of human cytochrome P450 3A4 with bacterial enzymes of known structure has provided a basis from which to predict residues involved in substrate oxidation. Substitutions were made at four residues (I301, F304, A305, and T309) predicted to be located within the highly conserved substrate recognition site 4. Site-directed mutants engineered to contain carboxy-terminal histidine tags were expressed in Escherichia coli and purified on a metal affinity column. The integrity of each protein was assessed by SDS-polyacrylamide gel electrophoresis and immunoblotting. Functional analysis was performed using progesterone and testosterone as substrates and alpha-naphthoflavone as an activator. In testosterone hydroxylase assays, all of the mutants displayed rates of total product formation similar to wild-type 3A4, with several mutants showing small differences in specific products formed. However, with progesterone as the substrate, mutants F304A, A305V, and T309A exhibited altered product ratios and/or changes in the rates of product formation. F304A and A305V also displayed altered flavonoid stimulation that resulted in product ratios dramatically different from wild-type 3A4. Therefore, the kinetics of progesterone hydroxylation of these mutants and the wild-type enzyme were further assessed, and the data were analyzed with the Hill equation. Results with wild-type 3A4 and F304A indicated that at high progesterone concentrations, hydroxylation rates and product ratios are independent of the presence of alpha-NF. This suggests that progesterone may be equivalent to alpha-NF as an activator. In contrast, A305V exhibited autoactivation by progesterone but inhibition by alpha-NF.

Structural determinants of progesterone hydroxylation by cytochrome P450 2B5: the role of nonsubstrate recognition site residues.

The highly related rabbit cytochromes P450 2B4 and 2B5 differ in only 12 amino acid positions, but only 2B5 has activity toward progesterone. Previously, simultaneous site-directed mutagenesis of four key substrate recognition site (SRS) residues (114, 294, 363, and 367) was shown to result in interconversion of the androstenedione hydroxylase specificities of cytochrome P450 2B4 and 2B5. However, the progesterone metabolite profiles of the 2B4 quadruple mutant or of a quintuple mutant in which residue 370 was also mutated to the 2B5 residue were not identical to that of P450 2B5. Therefore, single mutants of P450 2B5 at the remaining seven positions were constructed, expressed in Escherichia coli, and studied with progesterone as the substrate. The single mutants at positions 120 and 221, which are outside any known SRS, exhibited a significant alteration in progesterone hydroxylation. Based on these results, Ile-114, Arg-120, Ser-221, Ser-294, Ile-363, and Val-367 in cytochrome P450 2B4 were replaced simultaneously with Phe, His, Pro, Thr, Val, and Ala, respectively, from 2B5. This yielded a mutant with a very similar progesterone metabolite profile to that of 2B5, although the total activity was lower. An additional substitution at residue 370 produced a multiple mutant P450 2B4 I114F-R120H-S221P-S294T-I363V-V367A- T370M with very similar or identical substrate specificity, regio- and stereospecificity and kinetic properties to that of P450 2B5 wild type.

Functional interaction between amino-acid residues 242 and 290 in cytochromes P-450 2B1 and 2B11.

Previous studies have revealed the functional importance of the negatively charged amino-acid residue Asp-290 of the phenobarbital-inducible dog liver cytochrome P-450 (P-450) 2B11 (Harlow, G.R. and Halpert J.R. (1996) Arch. Biochem. Biophys. 326, 85-92). A search for P-450 2B11 residues capable of forming a charge pair with Asp-290 suggested the positively charged residue Lys-242 as a likely candidate. Replacement of Lys-242 with Asp in a P-450 2B11 fusion protein with rat NADPH-cytochrome P-450 reductase (reductase) resulted in very low holoenzyme expression levels in Escherichia coli, as did replacement of Asp-290 with Lys. Remarkably, however, expression levels of the double mutant Lys-242 --> Asp/Asp-290 --> Lys were dramatically increased above either single replacement alone. Similarly, the pair-wise substitutions Lys-242 --> Leu/Asp-290 --> Ile in P-450 2B11 and Leu-242 --> Lys/Ile-290 --> Asp in P-450 2B1 showed greater holoenzyme expression levels than the constituent single mutants, providing further evidence for the close proximity of these residues within the three-dimensional structure of these two enzymes. These results support the hypothesis that a functional interaction exists between residues 242 and 290, which may help to coordinate the relative positions of proposed helices G and I. All of the mutant combinations, including the additional P-450 2B11 double mutants Tyr-242/Asn-290 and Tyr-242/Ser-290, displayed altered stereoselectivity of androstenedione hydroxylation.

Alanine-scanning mutagenesis of a putative substrate recognition site in human cytochrome P450 3A4. Role of residues 210 and 211 in flavonoid activation and substrate specificity.

Alanine-scanning mutagenesis was performed on amino acid residues 210-216 of cytochrome P450 3A4, the major drug-metabolizing enzyme of human liver. Mutagenesis of this region, which has been proposed to align with the C-terminal ends of F-helices from cytochromes P450BM-3, P450terp, and P450cam, served as a test of the applicability of the substrate recognition site model of Gotoh (Gotoh, O. (1992) J. Biol. Chem. 267, 83-90) to P450 3A4. The results, using two steroid substrates, indicated that substitution of Ala for Leu210 altered the responsiveness to the effector alpha-naphthoflavone and the regioselectivity of testosterone hydroxylation. Replacement of Leu211 by Ala also decreased the stimulation by alpha-naphthoflavone, whereas mutations at residues 212-216 had little effect. The diminished flavonoid responses of the 210 and 211 mutants were observed over a wide range of progesterone and alpha-naphthoflavone concentrations. Further characterization was performed with the additional effectors beta-naphthoflavone, flavone, and 4-chromanone. The finding that P450 3A4 with one altered residue, Leu210 --> Ala, can have both an altered testosterone hydroxylation profile and response to flavonoid stimulation provides evidence that the substrate binding and effector sites are at least partially overlapping.

Isolation, heterologous expression and functional characterization of a novel cytochrome P450 3A enzyme from a canine liver cDNA library.

A cDNA encoding a new member of the cytochrome P450 3A subfamily, P450 3A26, has been isolated from phenobarbital-induced canine liver. The sequence encodes a protein of 503 amino acids with 33 nucleotide differences conferring 22 amino acid substitutions when compared with the previously identified canine CYP3A12 enzyme. Nine of the amino acid differences are within the substrate recognition sites (SRSs) identified for P450 family 2, with five residue substitutions clustered within SRS-6. To facilitate heterologous expression in Escherichia coli, the N-terminus of 3A26 was modified. The expressed protein comigrated with a 3A-immunoreactive protein in dog liver microsomes with a slightly greater electrophoretic mobility on sodium dodecyl sulfate-polyacrylamide gel electrophoresis than 3A12, which suggests that 3A26 corresponds to a previously noted but never characterized 3A enzyme in dogs. Functional characterization of 3A26 was undertaken with use of progesterone, testosterone and androstenedione as substrates. Assays of expressed 3A26 and 3A12 demonstrated that 3A26 displays low steroid hydroxylase activity. Identification of an additional canine 3A enzyme should increase our understanding of xenobiotic metabolism in this important animal model. These findings also suggest that 3A26 and 3A12 may be an interesting model system for the investigation of structure-function relationships involved in steroid metabolism catalyzed by members of the cytochrome P450 3A subfamily.

Escherichia coli expression and substrate specificities of canine cytochrome P450 3A12 and rabbit cytochrome P450 3A6.

High level Escherichia coli expression of cytochromes P450 3A12 and 3A6 has facilitated the characterization of proteins which exhibit limited activity as purified hepatic enzymes in reconstituted systems. Three 3A12 and two 3A6 constructs modified at the 5'-end to encode the bovine 17 alpha-sequence (Barnes et al., Proc. Natl. Acad. Sci. U.S.A. 88: 5597-5601, 1991), or related sequences, exhibited expression levels ranging from 2 to 89 nmol of cytochrome P450 liter-1. Recombinant canine 3A12 catalyzed steroid 6 beta-hydroxylation and erythromycin demethylation at rates comparable to those obtained in phenobarbital-induced canine liver microsomes. In contrast, 3A12 troleandomycin demethylase activity (2.5 nmol/min/nmol) was significantly lower than that of canine phenobarbital-induced liver microsomes (6.6 nmol/min/nmol). This difference in activity suggests that at least two 3A forms, which may differ functionally, are present within the canine liver. Purification of recombinant rabbit 3A6 revealed that homogeneous and E. coli-solubilized membrane preparations of 3A6 exhibit similar metabolic rates and identical substrate specificities; 3A activity was modulated by 25 microM alpha-naphthoflavone, which stimulated an unidentified progesterone metabolite 9-fold in 3A6 reconstituted systems in contrast to the 4-fold stimulation of 3A12. Furthermore, 25 microM alpha-naphthoflavone inhibited erythromycin demethylation 64 and 33% by purified recombinant 3A6- or 3A6-solubilized membrane fractions, respectively; 3A12-mediated erythromycin demethylation in solubilized membrane fractions was resistant to flavonoid inhibition. These results indicate that, although 3A substrate specificities are highly conserved between species, functional differences exist between canine 3A12 and rabbit 3A6, which may be utilized to better understand 3A structure-function relationships.

Mutagenesis study of Asp-290 in cytochrome P450 2B11 using a fusion protein with rat NADPH-cytochrome P450 reductase.

Asp-290 of the phenobarbital-inducible dog liver cytochrome P450 (P450) 2B11 was mutated to nine other amino acid residues by site-directed mutagenesis, and the functional significance of the unique negative charge in P450 2B11 at that position was studied. To facilitate the analysis of mutated P450 2B11 enzymes heterologously expressed in Escherichia coli, an enzymatically active fusion enzyme was genetically engineered between the cDNAs for P450 2B11 and rat liver NADPH-cytochrome P450 reductase using a Ser-Thr linker as previously described (Fisher et al., 1992, Proc. Natl. Acad. Sci. USA 89, 10817-10821). Sonicated whole-cell lysates of E. coli cells expressing the wild-type fusion protein were able to catalyze the 16-hydroxylation of androstenedione (AD) in the absence of added reductase, and exhibited activities and androstenedione metabolite profiles very similar to those of purified and reconstituted enzyme preparations. The substitution of Ala, Glu, Gly, Met, Asn, Arg, Ser, Thr, or Val for Asp-290 of P450 2B11 resulted in decreased AD hydroxylase activities as assessed using solubilized membranes. Replacement of Asp-290 with Glu yielded the highest activity (55% of wild type), while substituting the positively charged amino acid Arg created an enzyme with the lowest activity (< 1% of wild-type activity). Regioselectivity of AD hydroxylation was not affected although the stereoselectivity of hydroxylation at the 16 carbon position was altered in some cases. The use of the fused enzyme to study the effects of site-directed mutagenesis has resulted in the demonstration of the importance of size and charge at position 290 for enzymatic activity of P450 2B11.

Arabidopsis mutants deficient in T-DNA integration.

Arabidopsis thaliana mutants originally isolated as hypersensitive to irradiation were screened for the ability to be transformed by Agrobacterium transferred DNA (T-DNA). One of four UV-hypersensitive mutants and one of two gamma-hypersensitive mutants tested showed a significant reduction in the frequency of stable transformants compared with radioresistant controls. In a transient assay for T-DNA transfer independent of genomic integration, both mutant lines took up and expressed T-DNA as efficiently as parental lines. These lines are therefore deficient specifically in stable T-DNA integration and thus provide direct evidence for the role of a plant function in that process. As radiation hypersensitivity suggests a deficiency in repair of DNA damage, that plant function may be one that is also involved in DNA repair, possibly, from other evidence, in repair of double-strand DNA breaks.

Characterization of the progesterone 21-hydroxylase activity of canine cytochrome P450 PBD-2/P450 2B11 through reconstitution, heterologous expression, and site-directed mutagenesis.

Canine hepatic cytochrome P450 PBD-2 metabolizes 2,2',4,4',5,5'-hexachlorobiphenyl and catalyzes the 21-hydroxylation of progesterone, thereby distinguishing PBD-2 as unique among 2B P450s. Heterologous expression of the PBD-2 cDNA, P450 2B11, in COS and yeast systems produced a protein capable of androstenedione metabolism; however, this P450 did not metabolize progesterone in a manner consistent with PBD-2. Modification of PBD-2 reconstitution parameters resulted in significantly increased catalytic activities and further emphasized differences between PBD-2 and the heterologously expressed enzyme. Subsequent Escherichia coli expression of 2B11 generated a protein that possessed substrate specificities indistinguishable from those of PBD-2 and provided a system in which the determinants of 2B11 progesterone 21-hydroxylation could be examined via site-directed mutagenesis. Site-directed mutants of 2B11 expressed in E. coli revealed that substitution of Ile with Val at position 363 converted 2B11 into a highly active and specific progesterone 16 alpha-hydroxylase. Mutants Val-114 --> Ile, Asp-290 --> Ile, and Ile-365 --> Phe exhibited decreased progesterone 21- and 16 alpha-hydroxylase activities, in accordance with decreases in androstenedione hydroxylase activities. In contrast, replacement of Ile-365 with Val or Leu resulted in much greater changes in progesterone than androstenedione hydroxylation. Thus, the combination of P450 reconstitution techniques, heterologous expression, and site-directed mutagenesis has revealed PBD-2 to be an important progesterone 21-hydroxylase in canine liver and has identified several amino acid residues that alter progesterone metabolism by 2B11.

Radiation-sensitive mutants of Arabidopsis thaliana.

Five Arabidopsis mutants have been isolated on the basis of hypersensitivity of leaf tissue to UV light. For each mutant, the UV-hypersensitive phenotype (uvh) was inherited as a single recessive Mendelian trait. In addition, each uvh mutant represented a separate complementation group. Three of the mutations producing the UV hypersensitive phenotype have been mapped relative to either genetic markers or physical microsatellite polymorphisms. Locus UVH1 is linked to nga76 on chromosome 5, UVH3 to GL1 on chromosome three, and UVH6 to nga59 on chromosome 1. Each uvh mutant has a characteristic pattern of sensitivity based on UV sensitivity of leaf tissue, UV sensitivity of root tissue, and ionizing radiation sensitivity of seeds. On the basis of these patterns, possible molecular defects in these mutants are discussed.

Identification of high affinity binding sites for LexA which define new DNA damage-inducible genes in Escherichia coli.

A multi-step screening procedure was devised to identify new operators for the LexA repressor in the sequenced portions of the genomes of Escherichia coli and its plasmids and bacteriophages. Sequence analysis methods were employed initially to distinguish true LexA operators from "operator-like" sequences stored within the GenBank and EMBL databases. The affinity of purified LexA protein for cloned DNA fragments containing several of the prospective new sites was then assessed using quantitative electrophoretic mobility shift assays and site-directed mutagenesis. Calculated binding affinities were compared directly with values determined for known and mutant LexA operators in concurrent experiments. Three E. coli chromosomal segments (near pyrC, hsdS and ntrla) and two bacteriophage sequences (near the P1 cre and lambda oop genes) bound LexA protein specifically. These sites and most others identified in the screening are located immediately upstream of known genes and/or large open reading frames. These results and additional transcription data demonstrate that several of the sequences define new DNA damage-inducible (din) genes and include the previously uncharacterized dinD locus. Furthermore, the search identified an SOS gene within the genome of P1 which encodes a protein that is homologous to UmuD', the RecA-promoted cleavage product of the umuD gene. The success of the combinatorial approach described here suggests that analogous searches for new regulatory sequences within the E. coli genome and the genomes of other organisms will also yield favorable results.

Site-directed mutagenesis of putative substrate recognition sites in cytochrome P450 2B11: importance of amino acid residues 114, 290, and 363 for substrate specificity.

Eleven amino acid residues unique to dog cytochrome P450 (P450) 2B11, compared with rat 2B1 and 2B2, rabbit 2B4 and 2B5, and mouse 2B10, in the putative substrate recognition sites [J. Biol. Chem. 267:83-90 (1992)] were mutated to the residues found in 2B1 or 2B5. The mutants were expressed initially in COS cells and screened for activity toward androstenedione and 2,2',4,4',5,5'-hexachlorobiphenyl (245-HCB). P450 2B11 mutants V107I, M199L-N200E-V204R, V234I, A292L, Q473R, and I475S showed no differences from wild-type P450 2B11 in metabolite profiles with either substrate. Mutants V114I, D290I, and L363V exhibited altered androstenedione metabolite profiles and were expressed in Escherichia coli for further study with androstenedione, testosterone, 7-ethoxycoumarin, (R)- and (S)-warfarin, and 245-HCB. With V114I, hydroxylation of steroids and warfarin and 2-hydroxylation of 245-HCB were decreased, whereas 7-ethoxycoumarin O-dealkylation and 3-hydroxylation of 245-HCB were unaltered. For D290I, activities toward all substrates were decreased, except for 16 beta-hydroxylation of testosterone. The activity of L363V was increased 5-6-fold for 16 alpha-hydroxylation of androstenedione and testosterone but was decreased to 40-50% of wild-type activity with 7-ethoxycoumarin and warfarin and to 6-8% of control for 2-hydroxylation of 245-HCB. Alignment of P450 2B11 with P450 101 and super-imposition of the 11 mutated 2B11 residues on a P450 101 three-dimensional model suggest that only residues 114, 290, and 363 represent substrate contact residues, in excellent agreement with the experimental results. The data indicate the importance of the three residues 114, 290, and 363 in substrate specificity and regio- and stereoselectivity of P450 2B11 and also demonstrate that the effects of the mutations vary considerably with different substrates.

Isolation of uvh1, an Arabidopsis mutant hypersensitive to ultraviolet light and ionizing radiation.

A genetic screen for mutants of Arabidopsis that are hypersensitive to UV light was developed and used to isolate a new mutant designated uvh1. UV hypersensitivity in uvh1 was due to a single recessive trait that is probably located on chromosome 3. Although isolated as hypersensitive to an acute exposure to UV-C light, uvh1 was also hypersensitive to UV-B wavelengths, which are present in sunlight that reaches the earth's surface. UV-B damage to both wild-type and uvh1 plants could be significantly reduced by subsequent exposure of UV-irradiated plants to photoreactivating light, showing that photoreactivation of UV-B damage is important for plant viability and that uvh1 plants are not defective in photoreactivation. A new assay for DNA damage, the Dral assay, was developed and used to show that exposure of wild-type and uvh1 plants to a given dose of UV light induces the same amount of damage in chloroplast and nuclear DNA. Thus, uvh1 is not defective in a UV protective mechanism. uvh1 plants were also found to be hypersensitive to ionizing radiation. These results suggest that uvh1 is defective in a repair or tolerance mechanism that normally provides plants with resistance to several types of DNA damage.