Covalent heme binding to CYP4B1 via Glu310 and a carbocation porphyrin intermediate

Recently we found that CYP4B1, and several other members of the CYP4 family of enzymes, are covalently linked to their prosthetic heme group through an ester linkage. In the current study, we mutated a conserved CYP4 I-helix residue, E310 in rabbit CYP4B1, to glycine, alanine, and aspartate to examine the effect of these mutations on the extent of covalent heme binding and catalysis. All mutants expressed well in insect cells and were isolated as a mixture of monomeric and dimeric forms as determined by LC/ESI-MS of the intact proteins. Rates of metabolism decreased in the order E310 > A310 > G310 > D310, with the A310 and G310 mutants exhibiting alterations in regioselectivity for omega-1 and omega-2 hydroxylation of lauric acid, respectively. In marked contrast to the wild-type E310 enzyme, the G310, A310, and D310 mutants did not bind heme covalently. Uniquely, the acid-dissociable heme obtained from the D310 mutant contained an additional 16 amu relative to heme and exhibited the same chromatographic behavior as the monohydroxyheme species released upon base treatment of the covalently linked wild-type enzyme. Expression studies with H(2)(18)O demonstrated incorporation of the heavy isotope from the media into the monohydroxyheme isolated from the D310 mutant at a molar ratio of approximately 0.8:1. These data show (i) that E310 serves as the site of covalent attachment of heme to the protein backbone of rabbit CYP4B1; (ii) this I-helix glutamate residue influences substrate orientation in the active site of CYP4B1; and (iii) the mechanism of covalent heme attachment most likely involves a carbocation species located on the porphyrin.     

General methods for enriching aldoses with oxygen isotopes

Synthetic methods are described for enriching 4-, 5-, and 6-carbon aldoses with oxygen isotopes. The general approach includes exchange between H2(1)8O and the aldehyde group of an aldose, exchange of O-1 onto C-2 of both of the 2-epimeric aldoses formed by molybdate-resin epimerization, and chain extension using cyanide addition. These methods make possible the production of all 16 aldohexoses enriched at 5 of the 6 oxygen atoms, all 8 aldopentoses enriched at 4 of the 5 oxygen atoms, and the four aldotetroses enriched at 2 of the 4 oxygen atoms. The general applicability of these methods is illustrated by the synthesis of a group of 22 different, 18O-enriched, biologically important D-aldoses having 4, 5, and 6 carbon atoms. The group includes D-[1-, 2-, 3-, 4-, O]glucose, D-[1-, 2-, 3-, 4-, and 6-18O]mannose, D-[1-, 2-, 3-, and 5-18O]arabinose, D-[1- abd 2- 18O] erythorose, and D-[1- and 2-18O]threose. The g.l.c.-m.s. characterization of these sugars with respect to the position and degree of 18O-enrichment is reported. The potential of the methods for producing aldoses having oxygen labels at multiple positions, or aldoses labeled simultaneously with oxygen, hydrogen, and carbon isotopes is discussed.     

3-hydroxy-3-methylglutaryl-coenzyme A synthase reaction intermediates: detection of a covalent tetrahedral adduct by differential isotope shift 13C nuclear magnetic resonance spectroscopy

Binding of [1,2-(13)C]acetyl-CoA to wild-type 3-hydroxy-3-methylglutaryl-coenzyme A (HMG-CoA) synthase is characterized by large upfield shifts for C1 (184 ppm, Deltadelta = 20 ppm) and C2 (26 ppm, Deltadelta = 7 ppm) resonances that are attributable to formation of the covalent [1,2 -(13)C]acetyl-S-enzyme reaction intermediate. NMR spectra of [1, 2-(13)C]acetyl-S-enzyme prepared in H(2)(16)O versus H(2)(18)O indicate a 0.055 ppm upfield shift of the C1 resonance in the presence of the heavier isotope. The magnitude of this (18)O-induced (13)C shift suggests that the 184 ppm resonance is attributable to a reaction intermediate in which C1 exhibits substantial carbonyl character. No significant shift of the C2 resonance occurs. These observations suggest that, in the absence of second substrate (acetoacetyl-CoA), enzymatic addition of H(2)(18)O to the C1 carbonyl of acetyl-S-enzyme occurs to transiently produce a tetrahedral species. This tetrahedral adduct exchanges oxygen upon backward collapse to re-form the sp(2)-hybridized thioester carbonyl. In contrast with HMG-CoA synthase, C378G Zoogloea ramigera beta-ketothiolase, which also forms a (13)C NMR-observable covalent acetyl-enzyme species, exhibits no (18)O-induced shift. Formation of the [(13)C]acetyl-S-enzyme reaction intermediate of HMG-CoA synthase in D(2)O versus H(2)O is characterized by a time-dependent isotope-induced upfield shift of the C1 resonance (maximal shift = 0. 185 ppm) in the presence of the heavier isotope. A more modest upfield shift (0.080 ppm) is observed for C378G Z. ramigera beta-ketothiolase in similar experiments. The slow kinetics for the development of the deuterium-induced (13)C shift in the HMG-CoA synthase experiments suggest a specific interaction (hydrogen bond) with a slowly exchangeable proton (deuteron) of a side chain/backbone of an amino acid residue at the active site.     

Autocatalytic mechanism and consequences of covalent heme attachment in the cytochrome P4504A family

The prosthetic heme group in the CYP4A family of cytochrome P450 enzymes is covalently attached to an I-helix glutamic acid residue. This glutamic acid is conserved in the CYP4 family but is absent in other P450 families. As shown here, the glutamic acid is linked, presumably via an ester bond, to a hydroxyl group on the heme 5-methyl group. Mutation of the glutamic acid to an alanine in CYP4A1, CYP4A3, and CYP4A11 suppresses covalent heme binding. In wild-type CYP4A3 68% of the heme is covalently bound to the heterologously expressed protein, but in the CYP4A3/E318D mutant, 47% of the heme is unchanged, 47% is present as noncovalently bound 5-hydroxymethylheme, and only 6% is covalently bound to the protein. In the CYP4A3/E318Q mutant, the majority of the heme is unaltered, and <2% is covalently linked. The proportion of covalently bound heme in the recombinant CYP4A proteins increases with time under turnover conditions. The catalytic activity is sensitive in some, but not all, CYP4A enzymes to the extent of covalent heme binding. Mutations of Glu(318) in CYP4A3 decrease the apparent k(cat) values for lauric acid hydroxylation. The key conclusions are that (a) covalent heme binding occurs via an ester bond to the heme 5-methyl group, (b) covalent binding of the heme is mediated by an autocatalytic process, and (c) fatty acid oxidation is sensitive in some CYP4A enzymes to the presence or absence of the heme covalent link.     

Structural design of the active site for covalent attachment of the heme to the protein matrix: studies on a thermostable cytochrome P450

The molecular basis of the post-translational modification involving covalent attachment of the heme with a glutamic acid observed in some enzymes of the CYP4 family of heme monooxygenases has been investigated using site-directed mutagenesis of CYP175A1 from Thermus thermophilus. Earlier studies of CYP4 as well as the G248E mutant of CYP101A1 showed covalent linkage of the heme to a conserved glutamic acid of helix I. We have introduced Glu/Asp at the Leu80 position in the β-turn of CYP175A1, on the basis of molecular modeling studies, to assess whether formation of such a covalent linkage is limited only to helix I or whether such modification may also take place with the residue that is spatially located at a position appropriate for activation by the heme peroxidase reaction. Tandem mass spectrometry analyses of the tryptic digest of the wild type and mutants of CYP175A1 were conducted to identify any heme-bound peptide. Tryptic digestion of the L80E mutant of CYP175A1 preincubated with H(2)O(2) showed formation of GLE(-heme)TDWGESWKEARK supporting covalent linkage of Glu80 with the heme in the mutant enzyme. No such heme-bound peptides were found if the sample was not preincubated in H(2)O(2), indicating no activation of the Glu by the heme peroxidase reaction, as proposed earlier. The wild type or L80D mutant of the enzyme did not give any heme-bound peptide. Thus, the results support the idea that covalent attachment of the heme to an amino acid in the protein matrix depends on the structural design of the active site.     

Comparative cytochrome P450 proteomics in the livers of immunodeficient mice using 18O stable isotope labeling

Quantitative changes in cytochrome P450 (CYP) proteins involved in drug metabolism as a consequence of drug treatment are important parameters in predicting the fates and pharmacological consequences of xenobiotics and drugs. In this study we undertook comparative P450 proteomics using liver from control and 1,4-bis-2-(3,5-dichloropyridyloxybenzene) (TCPOBOP)-dosed mice. The method involved separation of microsomal proteins by SDS-PAGE, trypsin digestion, and postdigest 18O/16O labeling followed by nano-LC-MS/MS for peptide identification and LC-MS for relative quantification. Seventeen P450 proteins were identified from mouse liver of which 16 yielded data sufficient for relative quantification. All the P450s detected were unambiguously identified except the highly homologous CYP2A4/2A5. With the exception of CYP2A12, -2D10, and -2F2, the levels of all the P450s quantified were affected by treatment with TCPOBOP (3 mg/kg). CYP1A2, -2A4/5, -2B10, -2B20, -2C29, -2C37, -2C38, -3A11, and -39A1 were up-regulated, and CYP2C40, -2E1, -3A41, and -27A1 down-regulated. The response of CYP2B20 to stimulation has not been distinguished previously from that of CYP2B10 because of the poor discrimination between these two proteins (they share 87% sequence identity). Differential response to chemical stimulation by closely related members of the CYP2C subfamily was also observed.     

Fixation of O(2) during Photorespiration: Kinetic and Steady-State Studies of the Photorespiratory Carbon Oxidation Cycle with Intact Leaves and Isolated Chloroplasts of C(3) Plants

Mass spectrometric techniques were used to trace the incorporation of [¹⁸O]oxygen into metabolites of the photorespiratory pathway. Glycolate, glycine, and serine extracted from leaves of the C₃ plants, Spinacia oleracea L., Atriplex hastata, and Helianthus annuus which had been exposed to [¹⁸O]oxygen at the CO₂ compensation point were heavily labeled with ¹⁸O. In each case one, and only one of the carboxyl oxygens was labeled. The abundance of ¹⁸O in this oxygen of glycolate reached 50 to 70% of that of the oxygen provided after only 5 to 10 seconds exposure to [¹⁸O]oxygen. Glycine and serine attained the same final enrichment after 40 and 180 seconds, respectively. This confirms that glycine and serine are synthesized from glycolate.

The labeling of photorespiratory intermediates in intact leaves reached a mean of 59% of that of the oxygen provided in the feedings. This indicates that at least 59% of the glycolate photorespired is synthesized with the fixation of molecular oxygen. This estimate is certainly conservative owing to the dilution of labeled oxygen at the site of glycolate synthesis by photosynthetic oxygen. We examined the yield of ¹⁸O in glycolate synthesized in vitro by isolated intact spinach chloroplasts in a system which permitted direct sampling of the isotopic composition of the oxygen at the site of synthesis. The isotopic enrichment of glycolate from such experiments was 90 to 95% of that of the oxygen present during the incubation.

The carboxyl oxygens of 3-phosphoglycerate also became labeled with ¹⁸O in 20- and 40-minute feedings with [¹⁸O]oxygen to intact leaves at the CO₂ compensation point. Control experiments indicated that this label was probably due to direct synthesis of 3-phosphoglycerate from glycolate during photorespiration. The mean enrichment of 3-phosphoglycerate was 14 ± 4% of that of glycine or serine, its precursors of the photorespiratory pathway, in 10 separate feeding experiments. It is argued that this constant dilution of label indicates a constant stoichiometric balance between photorespiratory and photosynthetic sources of 3-phosphoglycerate at the CO₂ compensation point.

Oxygen uptake sufficient to account for about half of the rate of ¹⁸O fixation into glycine in the intact leaves was observed with intact spinach chloroplasts. Oxygen uptake and production by intact leaves at the CO₂ compensation point indicate about 1.9 oxygen exchanged per glycolate photorespired. The fixation of molecular oxygen into glycolate plus the peroxisomal oxidation of glycolate to glyoxylate and the mitochondrial conversion of glycine to serine can account for up to 1.75 oxygen taken up per glycolate.

These studies provide new evidence which supports the current formulation of the pathway of photorespiration and its relation to photosynthetic metabolism. The experiments described also suggest new approaches using stable isotope techniques to study the rate of photorespiration and the balance between photorespiration and photosynthesis in vivo.

     

31P and 13C NMR studies of oxygen transfer during catalysis by 3-deoxy-D-manno-octulosonate cytidylyltransferase from Escherichia coli

[18O]3-Deoxy-D-manno-octulosonate (KDO), labeled at the anomeric oxygen, was prepared by exchange with [18O]H2O and used to follow the route of oxygen transfer during cytidine 5'-monophosphate-3-deoxy-D-manno-octulosonate (CMP-KDO) formation catalyzed by 3-deoxy-D-manno-octulosonate cytidylyl-transferase (CMP-KDO synthetase). The 31P-NMR signal of the phosphoryl group of CMP-KDO (-5.85 ppm), which appeared as a single resonance when CMP-KDO formation took place with unenriched KDO, appeared as two peaks when CMP-KDO formation took place in the presence of a mixture of [16O]-and [18O]KDO. These results demonstrate the retention of 18O during CMP-KDO formation. Confirmation that the labeled oxygen in CMP-KDO was retained in the "bridge" position between CMP and KDO came from 13C-NMR studies of CMP-KDO formed in the presence of 90% [2-13C, 18O] KDO. The prominent C-2 KDO resonance in CMP-KDO, which is normally a doublet at 101.4 ppm (Kohlbrenner, W.E., and Fesik, S.W. (1985) J. Biol. Chem. 260, 14695-14700), appeared as four peaks when a mixture of [2-13C,16O]- and [2-13C, 18O]KDO was used, confirming the direct bonding of 18O to the C-2 of KDO in CMP-KDO. These results are consistent with a nucleophilic displacement mechanism for CMP-KDO formation.     

3-Deoxy-D-manno-octulosonate-8-phosphate synthase catalyzes the C-O bond cleavage of phosphoenolpyruvate

The mechanism of 3-deoxy-D-manno-octulosonate-8-phosphate (KDO8P) synthase was investigated. When [18O]-PEP specifically labeled in the enolic oxygen is a substrate for KDO8P synthase, the 18O is recovered in Pi. This indicates that the KDO8P synthase reaction proceeds with C-O bond cleavage of PEP similar to that observed in the 3-deoxy-D-arabino-heptulosonate-7-phosphate synthase catalyzed condensation of PEP and erythrose-4-phosphate (1). No evidence for a covalent enzyme-PEP intermediate could be obtained. No [32P]-Pi exchange into PEP nor scrambling of bridge 18O to non-bridging positions in [18O]-PEP was observed in the presence or absence of arabinose-5-phosphate or its analog ribose-5-phosphate. Bromopyruvate inactivated KDO8P synthase in a time dependent process. It is likely that bromopyruvate reacts with a functional group at the PEP binding site since PEP, but not arabinose-5-phosphate, protects against inactivation.     

Phospholipids chiral at phosphorus. Synthesis of chiral phosphatidylcholine and stereochemistry of phospholipase D

Chirally labeled 1,2-dipalmitoyl-sn-glycero-3-phosphocholines (DPPC) with known configuration were synthesized by N-methylation of chirally labeled 1,2-dipalmitoyl-sn-glycero-3-phosphoethanolamine (DPPE). Transphosphatidylation of (RP)- and (SP)-[18O]DPPC catalyzed by phospholipase D from cabbage gave (RP)- and (SP)-[18O]DPPE, respectively, as indicated by 31P nuclear magnetic resonance (NMR) analysis of [18O]DPPE. Therefore, phospholipase D catalyzes transphosphatidylation with overall retention of configuration at phosphorus. The steric course of hydrolysis of DPPC catalyzed by the same enzyme was elucidated by the following procedures. Hydrolysis of (RP)-[17O, 18O]DPPC by phospholipase D gave 1,2-dipalmitoyl-sn-glycero-3-[ 16O , 17O, 18O]phosphate ( [ 16O , 17O, 18O] DPPA ) with unknown configuration. The latter compound was then converted to 1-[ 16O , 17O, 18O]phospho-(R)-propane-1,2-diol by a procedure involving no P-O bond cleavage [ Bruzik , K., & Tsai, M.-D. (1984) J. Am. Chem. Soc. 106, 747-754]. The configuration of the phosphopropane -1,2-diol was determined as RP by 31P NMR analysis following ring closure and methylation [ Buchwald , S. L., & Knowles, J. R. (1980) J. Am. Chem. Soc. 102, 6601-6603]. The results indicated that hydrolysis of DPPC catalyzed by phospholipase D also proceeds with retention of configuration at phosphorus. Our results therefore support a two-step mechanism involving a phosphatidyl-enzyme intermediate in the reactions catalyzed by phospholipase D from cabbage.     

Identification of the interactions between cytochrome P450 2E1 and cytochrome b5 by mass spectrometry and site-directed mutagenesis

The reaction cycles of cytochrome P450s (P450) require input of two electrons. Electrostatic interactions are considered important driving forces in the association of P450s with their redox partners, which in turn facilitates the transfer of the two electrons. In this study, the cross-linking reagent, 1-ethyl-3-[3-dimethylaminopropyl]carbodiimide hydrochloride (EDC), was used to covalently link cytochrome P450 2E1 (CYP2E1) with cytochrome b(5) (b(5)) through the formation of specific amide bonds between complementary charged residue pairs. Cross-linked peptides in the resulting protein complex were distinguished from non-cross-linked peptides using an (18)O-labeling method on the basis that cross-linked peptides incorporate twice as many (18)O atoms as non-cross-linked peptides during proteolysis conducted in (18)O-water. Subsequent tandem mass spectrometric (MS/MS) analysis of the selected cross-linked peptide candidates led to the identification of two intermolecular cross-links, Lys(428)(CYP2E1)-Asp(53)(b(5)) and Lys(434)(CYP2E1)-Glu(56)(b(5)), which provides the first direct experimental evidence for the interacting orientations of a microsomal P450 and its redox partner. The biological importance of the two ion pairs for the CYP2E1-b(5) interaction, and the stimulatory effect of b(5), was confirmed by site-directed mutagenesis. Based on the characterized cross-links, a CYP2E1-b(5) complex model was constructed, leading to improved insights into the protein interaction. The described method is potentially useful for mapping the interactions of various P450 isoforms and their redox partners, because the method is relatively rapid and sensitive, and is capable of suggesting not only protein interacting regions, but also interacting orientations.     

Escherichia coli tyrosyl- and methionyl-tRNA synthetases display sequence similarity at the binding site for the 3'-end of tRNA

Covalent modification of Escherichia coli tyrosyl-tRNA synthetase (TyrRS) by the 2',3'-dialdehyde derivative of tRNATyr (tRNAox) resulted in a time-dependent inactivation of both ATP-PPi exchange and tRNA aminoacylation activities of the enzyme. In parallel with the inactivation, covalent incorporation of approximately 1 mol of [14C]tRNATyrox/mol of the dimeric synthetase occurred. Intact tRNATyr protected the enzyme against inactivation by the tRNA dialdehyde. Treatment of the TyrRS-[14C]tRNATyr covalent complex with alpha-chymotrypsin produced two labeled peptides (A and B) that were isolated and identified by sequence analysis. Peptides A and B are adjacent and together span residues 227-244 in the primary structure of the enzyme. The three lysine residues in this sequence (lysines-229, -234, and -237) are labeled in a mutually exclusive fashion, with lysine-234 being the most reactive. By analogy with the known three-dimensional structure of the homologous tyrosyl-tRNA synthetase from Bacillus stearothermophilus, these lysines should be part of the C-terminal domain which is presumed to bind the cognate tRNA. Interestingly, the labeled TyrRS structure showed significant similarities to the structure around the lysine residue of E. coli methionyl-tRNA synthetase which is the most reactive toward tRNAMetf(ox) (lysine-335) [Hountondji, C., Blanquet, S., & Lederer, F. (1985) Biochemistry 24, 1175-1180].     

Stereochemistry of hydrolysis by snake venom phosphodiesterase.

[18O]Adenosine 5'-O-phosphorothioate-O-p-nitrophenyl ester was prepared by saponification of the bis (-O,O-p-nitrophenyl ester) with K18OH. Only the diastereoisomer with the Rp configuration si a substrate for snake venom phosphodiesterase. The asymmetrically labeled [18O]adenosine 5'-O-phosphorothioate formed in this reaction was converted enzymatically to [18O]adenosine 5'-(1-thiodiphosphate) with the Sp configuration. The position of the 18O label, either bridging [1,2-mu-18O] or nonbridging [1-18O] was then determined. The results show that the reaction catalyzed by snake venom phosphodiesterase takes place with retention of configuration at phosphorus. This indicates that the hydrolysis proceeds via a covalent nucleotide enzyme intermediate.     

Catalysis of intermolecular oxygen atom transfer by nitrite dehydrogenase of Nitrobacter agilis

Nitrobacter agilis, which contains a very active nitrite dehydrogenase, was studied in vivo under anaerobic conditions by the 15N NMR technique. When incubated with equimolar 15NO3- and unlabeled nitrite (or 15NO2- and unlabeled nitrate) the bacterium catalyzed an isotope exchange reaction at rates about 10% those observed in the nitrite oxidase assay. When incubated with 18O-labeled 15NO2- and 18O-labeled 15NO3-, the 18O was observed to exchange at similar rates from both species into water. Finally, when incubated with equimolar [18O]nitrate and 15NO2-, intermolecular 18O transfer was observed to result in formation of double labeled nitrate and nitrite at similar rates. 18O was transferred from nitrate to a 15N species or to water at approximately equal rates under the conditions of the experiments. It is argued that the enzyme responsible for these exchange reactions is nitrite dehydrogenase and not nitrate reductase. This work and the related experiments of DiSpirito and Hooper (DiSpirito, A.A., and Hooper, A.B. (1986) J. Biol. Chem. 261, 10534-10537) represent the first demonstrations of intermolecular oxygen atom transfer among oxotransferases. Mechanistic implications are discussed.     

Early biosynthetic pathway to abscisic acid in Cercospora cruenta

A new biosynthetic intermediate of ABA, (2Z,4E)-gamma-ionylideneacetaldehyde, was isolated from young mycelia of Cercospora cruenta. Under an (18)O2 atmosphere, an oxygen atom of this endogenous aldehyde was exclusively labeled. Similarly, three (18)O atoms were incorporated into the ABA molecule recovered after prolonged incubation; selectively labeled were one of the carboxyl oxygen atoms and the two on the ring portion of ABA. A feeding experiment with [1-(13)C]glucose proved the exclusive operation of the mevalonate pathway for the formation of both ABA and beta-carotene. These results suggest that (2Z,4E)-gamma-ionylideneacetaldehyde can be a key ABA biosynthetic intermediate formed by the oxidative cleavage of a carotenoid precursor.     

Active site characteristics of CYP4B1 probed with aromatic ligands.

The active site topography of rabbit CYP4B1 has been studied relative to CYP2B1 and CYP102 using a variety of aromatic probe substrates. Oxidation of the prochiral substrate cumene by CYP4B1, but not CYP2B1 or CYP102, resulted in the formation of the thermodynamically disfavored omega-hydroxy metabolite, 2-phenyl-1-propanol, with product stereoselectivity for the (S)-enantiomer. Reaction of CYP4B1, CYP2B1, and CYP102 with phenyldiazene produced spectroscopically observable sigma-complexes for each enzyme. Subsequent oxidation of the CYP2B1 and CYP102 complexes followed by LC/ESI--MS analysis yielded heme pyrrole migration patterns similar to those in previous literature reports. Upon identical treatment, no migration products were detected for CYP4B1. Intramolecular deuterium isotope effects for the benzylic hydroxylation of o-xylene-alpha-(2)H(3), p-xylene-alpha-(2)H(3), 2-(2)H(3),6-dimethylnaphthalene, and 4-(2)H(3),4'-dimethylbiphenyl were determined for CYP4B1 and CYP2B1 to further map their active site dimensions. These probes permit assessment of the ease of equilibration, within P450 active sites, of oxidizable methyl groups located between 3 and 10 A apart [Iyer et al. (1997) Biochemistry 36, 7136--7143]. Isotope effects for the CYP4B1-mediated benzylic hydroxylation of o- and p-xylenes were fully expressed (k(H)/k(D) = 9.7 and 6.8, respectively), whereas deuterium isotope effects for the naphthyl and biphenyl derivatives were both substantially masked (k(H)/k(D) approximately equal to 1). In contrast, significant suppression of the deuterium isotope effects for CYP2B1 occurred only with the biphenyl substrate. Therefore, rapid equilibration between two methyl groups more than 6 A apart is impeded within the active site of CYP4B1, whereas for CYP2B1, equilibration is facile for methyl groups distanced by more than 8 A. Collectively, all data are consistent with the conclusion that the active site of CYP4B1 is considerably restricted relative to CYP2B1.     

Three hydroxylations incorporating molecular oxygen in the aerobic biosynthesis of ubiquinone in Escherichia coli.

The biosynthetic origin of the oxygen atoms of ubiquinone 8 from aerobically grown Escherichia coli was studied by 18O labeling. An apparatus was developed which allowed the growth of cells under a defined atmosphere. Mass spectral analysis of ubiquinone 8 from cells grown under highly enriched 18O2 showed that three oxygen atoms of the quinone are derived from molecular oxygen. It was established that the molecular oxygen is incorporated into the two methoxyl groups (at C-5 and C-6) and one of the carbonyl positions of the ubiquinone molecule by demonstrating that only one of the incorporated oxygens will exchange with water under acidic conditions that specifically catalyze the exchange of carbonyl, but not methoxyl, oxygens. That the C-4 carbonyl oxygen is derived from molecular oxygen was shown by the incorporation of three atoms of 18O2 into ubiquinone 8 biosynthesized from added 4-hydroxybenzoic acid. Comparison of ubiquinone 8 and menaquinone 8 from E. coli grown under 18O2 confirmed that the labeled carbonyl oxygen of the [18O2]ubiquinone 8 is incorporated biosynthetically and not by chemical exchange in the cell. It is concluded that the three hydroxylation reactions involved in the pathway for the aerobic biosynthesis of ubiquinone are all catalyzed by monooxygenases. The implications of this study for the anaerobic biosynthesis of ubiquinone 8 in E coli are discussed.     

An isotope coding strategy for proteomics involving both amine and carboxyl group labeling

This paper describes a heavy isotope coding strategy for the analysis of all types of tryptic peptides, including those that are N-terminally blocked and from the C-terminus of proteins. The method exploits differential derivatization of amine and carboxyl groups generated during proteolysis as a means of coding. Carboxyl groups produced during proteolysis incorporate 18O from H218O. Peptides from the C-terminus of proteins were not labeled with 18O unless they contained a basic C-terminal amino acid. Primary amines from control and experimental samples were differentially acylated after proteolysis with either 1H3- or 2H3-N-acetoxysuccinamide. When these two types of labeling were combined, unique coding patterns were achieved for peptides arising from the C-termini and blocked N-termini of proteins. This method was used to (1) distinguish C-terminal peptides in model proteins, (2) recognize N-terminal peptides from proteins in which the amino terminus is acylated, and (3) identify primary structure variations between proteins from different sources.     

Multiple-ligand binding in CYP2A6: probing mechanisms of cytochrome P450 cooperativity by assessing substrate dynamics

The contribution of ligand dynamics to CYP allosterism has not been considered in detail. On the basis of a previous study, we hypothesized that CYP2A6 and CYP2E1 accommodate multiple xylene ligands. As a result, the intramolecular ( k H/ k D) obs values observed for some xylene isomers are expected to be dependent on ligand concentration with contributions from [CYP.xylene] and [CYP.xylene.xylene], etc. To explore this possibility and the utility of kinetic isotope effects in characterizing allosteric CYP behavior, steady state kinetics, product ratios, and ( k H/ k D) obs values for CYP2E1 and CYP2A6 oxidation of m-xylene-alpha- (2)H 3 and p-xylene-alpha- (2)H 3 were determined. Evidence is presented that CYP2A6 accommodates multiple ligands and that intramolecular isotope effect experiments can provide insight into the mechanisms of multiple-ligand binding. CYP2A6 exhibited cooperative kinetics for m-xylene-alpha- (2)H 3 oxidation and a concentration-dependent decrease in the m-methylbenzylalcohol:2,4-dimethylphenol product ratio (9.8 +/- 0.1 and 4.8 +/- 0.3 at 2.5 microM and 1 mM, respectively). Heterotropic effects were observed as well, as incubations containing both 15 microM m-xylene-alpha- (2)H 3 and 200 microM p-xylene resulted in further reduction of the product ratio (2.4 +/- 0.2). When p-xylene (60 microM) was replaced with deuterium-labeled d 6- p-xylene (60 microM), an intermolecular competitive inverse isotope effect on 2,4-dimethylphenol formation [( k H/ k D) obs = 0.49] was observed, indicating that p-xylene exerts heterotropic effects by residing in the active site simultaneously with m-xylene. The data indicate that there is a concentration-dependent decrease in the reorientation rate of m-xylene, as no increase in ( k H/ k D) obs was observed in the presence of an increased level of metabolic switching. That is, the accommodation of a second xylene molecule in the active site leads to a decrease in substrate dynamics.