Energetics of beta-oxidation. Reduction potentials of general fatty acyl-CoA dehydrogenase, electron transfer flavoprotein, and fatty acyl-CoA substrates

We have determined reduction potentials for porcine mitochondrial general fatty acyl-CoA dehydrogenase (GAD) and electron transfer flavoprotein (ETF) using an anaerobic spectroelectrochemical titration method. Computer simulation techniques were used to analyze the absorbance data. Nernst plots of the simulated data gave E'0, 7.1, quinone/semiquinone = -0.014 V and E'0, 7.1, semiquinone/hydroquinone = -0.036 V for ETF and E'0, 7.1, quinone/semiquinone = -0.155 V and E'0, 7.1, semiquinone/hydroquinone = -0.122 V for GAD. Using these techniques we have also determined a conditional reduction potential of -0.156 V for the chromophore producing fatty acyl-CoA substrate beta-2-furylpropionyl-CoA. From this value and our previous determination of the equilibrium constant for the transhydrogenation reaction between beta-2-furylpropionyl-CoA and the oxidized substrate crotonyl-CoA (Keq = 10.4), we have determined a reduction potential of -0.126 V for the butyryl-CoA/crotonyl-CoA couple. In light of the structural similarity between butyryl-CoA and octanoyl-CoA, the optimal substrate for GAD, the reduction potential for octanoyl-CoA should be similar to that for butyryl-CoA; i.e. fatty acyl-CoA substrates and GAD are essentially isopotential. The ability of octanoyl-CoA to reduce GAD quantitatively (Keq = 9.0) poses a dilemma in light of the nearly equal reduction potentials. We postulate that the stable charge-transfer complex formed between enzyme and optimal product is significantly lower in energy than enzyme and product and thus is responsible for pulling the reaction toward completion.     

Regulation of the butyryl-CoA dehydrogenase by substrate and product binding

Until now, workers in the field of fatty acid metabolism have suggested that the substrates are isopotential with the enzymes and that the reactions are forced to completion by the formation of charge-transfer complexes [Gustafson, W. G., Feinberg, B. A., & McFarland, J. T. (1986) J. Biol. Chem. 261, 7733-7741]. To date, no experimental evidence for this hypothesis exists. The work presented here shows that the butyryl-CoA/crotonyl-CoA couple is not isopotential with the enzymes with which it interacts. The potential of the butyryl-CoA/crotonyl-CoA couple (E ' = -0.013 V) is significantly more positive than the potential of either of the enzymes with which it interacts, bacterial butyryl-CoA dehydrogenase (E ' = -0.079 V) and mammalian general acyl-CoA dehydrogenase (E ' = 0.133 V). These data imply that the regulation of enzyme potential is essential for any electron transfer from substrate to enzyme to occur in mammalian or bacterial systems. In support of this assertion, a significant shift in potential for bacterial butyryl-CoA dehydrogenase (an analogue of the mammalian enzyme) in the presence of butyryl-CoA and crotonyl-CoA is reported. The potential is shifted positive by 60 mV. Larger potential shifts will undoubtedly be observed with the mammalian enzyme, which would be consistent with the catalytic direction of electron transfer.     

Catalysis and binding in L-ribulose-5-phosphate 4-epimerase: a comparison with L-fuculose-1-phosphate aldolase.

L-Ribulose-5-phosphate (L-Ru5P) 4-epimerase and L-fuculose-1-phosphate (L-Fuc1P) aldolase are evolutionarily related enzymes that display 26% sequence identity and a very high degree of structural similarity. They both employ a divalent cation in the formation and stabilization of an enolate during catalysis, and both are able to deprotonate the C-4 hydroxyl group of a phosphoketose substrate. Despite these many similarities, subtle distinctions must be present which allow the enzymes to catalyze two seemingly different reactions and to accommodate substrates differing greatly in the position of the phosphate (C-5 vs C-1). Asp76 of the epimerase corresponds to the key catalytic acid/base residue Glu73 of the aldolase. The D76N mutant of the epimerase retained considerable activity, indicating it is not a key catalytic residue in this enzyme. In addition, the D76E mutant did not show enhanced levels of background aldolase activity. Mutations of residues in the putative phosphate-binding pocket of the epimerase (N28A and K42M) showed dramatically higher values of K(M) for L-Ru5P. This indicates that both enzymes utilize the same phosphate recognition pocket, and since the phosphates are positioned at opposite ends of the respective substrates, the two enzymes must bind their substrates in a reversed or "flipped" orientation. The epimerase mutant D120N displays a 3000-fold decrease in the value of k(cat), suggesting that Asp120' provides a key catalytic acid/base residue in this enzyme. Analysis of the D120N mutant by X-ray crystallography shows that its structure is indistinguishable from that of the wild-type enzyme and that the decrease in activity was not simply due to a structural perturbation of the active site. Previous work [Lee, L. V., Poyner, R. R., Vu, M. V., and Cleland, W. W. (2000) Biochemistry 39, 4821-4830] has indicated that Tyr229' likely provides the other catalytic acid/base residue. Both of these residues are supplied by an adjacent subunit. Modeling of L-Ru5P into the active site of the epimerase structure suggests that Tyr229' is responsible for deprotonating L-Ru5P and Asp120' is responsible for deprotonating its epimer, D-Xu5P.     

Mechanism,mutagenesis, and chemical rescue of a beta-mannosidase from cellulomonas fimi

The chemical mechanism of a retaining beta-mannosidase from Cellulomonas fimi has been characterized through steady-state kinetic analyses with a range of substrates, coupled with chemical rescue studies on both the wild-type enzyme and mutants in which active site carboxyl groups have been replaced. Studies with a series of aryl beta-mannosides of vastly different reactivities (pK(a)(lg) = 4-10) allowed kinetic isolation of the glycosylation and deglycosylation steps. Substrate inhibition was observed for all but the least reactive of these substrates. Br?nsted analysis of k(cat) revealed a downward breaking plot (beta(lg) = -0.54 +/- 0.05) that is consistent with a change in rate-determining step (glycosylation to deglycosylation), and this was confirmed by partitioning studies with ethylene glycol. The pH dependence of k(cat)/K(m) follows an apparent single ionization of a group of pK(a) = 7.65 that must be protonated for catalysis. The tentative assignment of E429 as the acid-base catalyst of Man2A on the basis of sequence alignments with other family 2 glycosidases was confirmed by the increased turnover rate observed for the mutant E429A in the presence of azide and fluoride, leading to the production of beta-mannosyl azide and beta-mannosyl fluoride, respectively. A pH-dependent chemical rescue of E429A activity is also observed with citrate. Substantial oxocarbenium ion character at the transition state was demonstrated by the alpha-deuterium kinetic isotope effect for Man2A E429A of alpha-D(V) = 1.12 +/- 0.01. Surprisingly, this isotope effect was substantially greater in the presence of azide (alpha-D(V) = 1.166 +/- 0.009). Likely involvement of acid/base catalysis was revealed by the pH dependence of k(cat) for Man2A E429A, which follows a bell-shaped profile described by pK(a) values of 6.1 and 8.4, substantially different from that of the wild-type enzyme. The glycosidic bond cleaving activity of Man2A E519A and E519S nucleophile mutants is restored with azide and fluoride and appears to correlate with the corresponding "glycosynthase" activities. The contribution of the substrate 2-hydroxyl to stabilization of the Man2A glycosylation transition state (DeltaDeltaG() = 5.1 kcal mol(-1)) was probed using a 2-deoxymannose substrate. This value, surprisingly, is comparable to that found from equivalent studies with beta-glucosidases despite the geometric differences at C-2 and the importance of hydrogen bonding at that position. Modes of stabilizing the mannosidase transition state are discussed.     

Structural features of ring C of 20-oxo steroids and the interaction with cortisone reductase

Kinetic measurements were made with cortisone reductase (20-dihydrocortisone-NAD(+) oxidoreductase, EC 1.1.1.53) and a series of substrates which differed in shape, size and electronic character in the region adjacent to C-11, C-14 and C-18. Structural changes at C-11 in these substrates resulted in up to 660-fold changes in the apparent K(m) value, up to 200-fold changes in the apparent V(max.) value and up to 800-fold changes in the ratio of these kinetic constants. It is suggested that interactions important for substrate function normally occur between the enzyme and the C ring in the region of C-11, that these interactions arise from so-called hydrophobic forces between the generally hydrophobic C ring portion of the substrate and a hydrophobic region of the enzyme, but that when the substrate contains a polar substituent in this portion of the molecule, then polar interactions with polar moieties of the enzyme can also be important. It is further suggested that the part of the enzyme that interacts with the region of C-11 in the substrate is flexible, and that substrate binding involves at least some degree of induced fit.     

Enzymes hydrolyzing ApppA and/or AppppA in higher plants. Purification and some properties of diadenosine triphosphatase, diadenosine tetraphosphatase, and phosphodiesterase from yellow lupin (Lupinus luteus) seeds

Three distinct enzymes hydrolyzing either ApppA or AppppA, or both, were separated and purified from yellow lupin seed extracts. Two of the enzymes were purified to homogeneity. These enzymes differ greatly in their catalytic and physical properties. One hydrolase, with a native molecular weight of 41,000, exhibits broad pH (from 5-8) optimum for activity, requires Mg2+ for activity, is inhibited by zinc ions (I0.5 = 25 microM) and hydrolyses ApppA (V = 1), ApppC (V = 0.38), ApppG (V = 0.2), and ribose(5')pppA (V = 0.2). The enzyme exhibits much lower activity with AppppA (V = 0.1), and ApppppA, AppppppA, ppppA, and ATP are hydrolyzed 25- to 100-fold slower then ApppA. ADP was always one of the products of the reactions catalyzed by the enzyme. AppA, NAD, NADP, FAD, cAMP, and p-nitrophenyl-thymidine 5'-phosphate were not hydrolyzed by the enzyme. The enzyme is diadenosine 5',5"'-P1, P3-triphosphatase. The second hydrolase, composed of one polypeptide chain of a molecular weight 18,000-18,500, exhibits optimal activity in the pH range from 7.5-9, requires Mg2+ for activity, is inhibited by calcium ions (I0.5 for calcium depends on the concentration of Mg2+ and is 35-180 microM in the presence of 0.5-10 mM Mg2+, respectively), and hydrolyzes AppppA (V = 1, Km = 1 microM), ApppppA (V = 0.42, Km = 1.8 microM), AppppppA (V = 0.34), AppppU (V = 0.73), AppppC (V = 0.67), AppppG (V = 0.27), and ppppA. ATP was always one of the products of the reactions catalyzed by the enzyme. Dinucleoside di- and triphosphates, ATP, cAMP, and p-nitrophenylthymidine 5'-phosphate were not hydrolyzed by the enzyme. This enzyme is diadenosine 5',5"'-P1,P4-tetraphosphatase (EC 3.6.1.17). The third hydrolase, composed of one polypeptide chain of a molecular weight of 56,000, exhibits maximal activity at pH 9-10.5, does not require Mg2+ ions for activity, is inhibited neither by divalent cations (Mg2+, Ca2+, Zn2+, Co2+, Mn2+, or Ni2+) nor by EDTA, and uses as substrates all compounds which are substrates for the diadenosine 5',5"'-P1,P3-triphosphatase and diadenosine 5',5"'-P1,P4-tetraphosphatase. In addition, the enzyme hydrolyzes p-nitrophenyl-thymidine 5'-phosphate, p-nitrophenylthymidine 3'-phosphate, bis-p-nitrophenylphosphate, ADP, AppA, NAD, NADP, and FAD, but not cAMP. With the exception of p-nitrophenylphosphate derivatives all other substrates of the enzyme yield AMP as one of the products of hydrolysis. This enzyme has a specificity similar to that of phosphodiesterases (EC 3.1.4.1) from other sources. With the lupin phosphodiesterase, ApppA (V = 1, Km = 2.2 microM) and AppppA (V = 1, Km = 2.0 microM) are better substrates than NAD (V = 0.8, Km = 9.6 microM), AppA (V = 0.4), ApppppA (V = 0.6), and AppppppA (V = 0.34).     

NADPH- and hydroperoxide-supported 17beta-estradiol hydroxylation catalyzed by a variant form (432L, 453S) of human cytochrome P450 1B1

Human cytochrome P450 1B1 (CYP1B1) catalyzes the hydroxylation of 17beta-estradiol (E(2)) at C-4, with a lesser activity at C-2. The E(2) 4-hydroxylase activity of human CYP1B1 was first observed in studies of MCF-7 breast cancer cells. Sequencing of polymerase chain reaction products revealed that CYP1B1 expressed in MCF-7 cells was not the previously characterized enzyme but a polymorphic form with leucine substituted for valine at position 432 and serine substituted for asparagine at position 453. To investigate the NADPH- and organic hydroperoxide-supported E(2) hydroxylase activities of the 432L, 453S form of human CYP1B1, the MCF-7 CYP1B1 cDNA was cloned and the enzyme was expressed in Sf9 insect cells. In microsomal assays supplemented with human NADPH:cytochrome P450 oxidoreductase, the expressed 432L, 453S form catalyzed NADPH-supported E(2) hydroxylation with a similar preference for 4-hydroxylation as the 432V, 453N form, with maximal rates of 1.97 and 0.37 nmol (min)(-1)(nmol cytochrome P450)(-1) for 4- and 2-hydroxylation, respectively. Cumeme hydroperoxide efficiently supported E(2) hydroxylation by both the 432V, 453N and 432L, 453S forms at several-fold higher rates than the NADPH-supported activities and with a lesser preference for E(2) 4- versus 2-hydroxylation (2:1). The hydroperoxide-supported activities of both forms were potently inhibited by the CYP1B1 inhibitor, 3,3',4, 4',5,5'-hexachlorobiphenyl. These results indicate that the 432V, 453N and 432L, 453S forms of CYP1B1 have similar catalytic properties for E(2) hydroxylation, and that human CYP1B1 is very efficient in catalyzing the hydroperoxide-dependent formation of catecholestrogens.     

Inhibition of uridine phosphorylase by pyrimidine nucleoside analogs and consideration of substrate binding to the enzyme based on solution conformation as seen by NMR spectroscopy

Some 3'- and/or 5'-substituted pyrimidine nucleosides, as well as anhydropyrimidine nucleosides, which have no flexibility about the N-glycosidic bond were studied as inhibitors of thymidine phosphorylase and uridine phosphorylase. The conformation of some analogs was also investigated in order to obtain information on substrate binding to the enzyme. The above compounds, including the potential anti-(human immunodeficiency virus) agent, 3'-azido-2',3'-dideoxy-5-methyluridine were not substrates for either thymidine phosphorylase or uridine phosphorylase. (The only exception was arabinofuranosyl-5-ethyluracil, which proved to be a poor substrate for uridine phosphorylase). The phosphorolysis of thymidine by thymidine phosphorylase was slightly or not at all altered by these pyrimidine nucloside analogs. The lowest Ki was obtained in the case of 3'-azido-2',3'-dideoxy-5-methyluridine and the highest in the case of 2'-deoxylyxofuranosyl-5-ethyluracil, when studying the analogs with flexible structure as inhibitors of uridine phosphorylase. The Ki for 2,3'- and 2,5'-anhydro-2'-deoxy-5-ethyluridine was 5-6 orders of magnitude higher than that for 2,2'-anhydro-5-ethyluridine. Competitive inhibition was observed in all cases. For these three molecules computer-aided molecular modelling predicts the following glycosidic torsion angles chi (O4,-C1,-N1-C2): 109 degrees for 2,2'-anhydro-5-ethyluridine, and 78 degrees and 71 degrees for 2,3'- and 2,5'-anhydro-2'-deoxy-5-ethyluridine respectively. These values are corroborated by high-resolution 13C- and 1H-NMR studies. 2'-Deoxy-5-ethyluridine is predicted to have a syn conformation with chi = 46 degrees and delta E about 2.5 kJ/mol over the minimum energy (in anti position, chi = -147 degrees). 1H and 13C data including homonuclear Overhauser enhancements complete the information about the solution conformation. Considering the Ki values obtained, it is likely that substrates of uridine phosphorylase will bind to the enzyme in the same conformation as 2,2'-anhydro-5-ethyluridine. The greater than 30 degrees deviation from the N-glycosidic torsion angle of 2,2'-anhydro-5-ethyluridine results in much higher Ki values.     

Substrate and inhibitor profile of BACE (beta-secretase) and comparison with other mammalian aspartic proteases.

The full-length and ectodomain forms of beta-site APP cleavage enzyme (BACE) have been cloned, expressed in Sf9 cells, and purified to homogeneity. This aspartic protease cleaves the amyloid precursor protein at the beta-secretase site, a critical step in the Alzheimer's disease pathogenesis. Comparison of BACE to other aspartic proteases such as cathepsin D and E, napsin A, pepsin, and renin revealed little similarity with respect to the substrate preference and inhibitor profile. On the other hand, these parameters are all very similar for the homologous enzyme BACE2. Based on a collection of decameric substrates, it was found that BACE has a loose substrate specificity and that the substrate recognition site in BACE extends over several amino acids. In common with the aspartic proteases mentioned above, BACE prefers a leucine residue at position P1. Unlike cathepsin D etc., BACE accepts polar or acidic residues at positions P2'0 and P1 but prefers bulky hydrophobic residues at position P3. BACE displays poor kinetic constants toward its known substrates (wild-type substrate, SEVKM/DAEFR, K(m) = 7 microm, K(cat) = 0.002 s(-1); Swedish mutant, SEVNL/DAEFR, K(m) = 9 microm, K(cat) = 0.02 s(-1)). A new substrate (VVEVDA/AVTP, K(m) = 1 microm, K(cat) = 0.004) was identified by serendipity.     

Potentiometric titrations and oxidation-reduction potentials of manganese and copper-zinc superoxide dismutases.

Bovine erythrocyte superoxide dismutase and two manganese-containing superoxide dismutases have been reduced by the indirect coulometric titration method with methylviologen as the mediator-titrant. On the basis of the titration data the manganese-containing superoxide dismutases contain 1 g-atom of metal per mol of enzyme (dimer). E0' = +0.31 V for the enzyme from Escherichia coli which exhibits a complicated pH dependence above neutral pH. The Bacillus stearothermophilus manganese-containing enzyme has an E0' = +0.26 V and delta Em/pH is 50 mV. Bovine erythrocyte superoxide dismutase exhibits anomalous behavior in the coulometric titration curves, which is indicative of two nonequivalent copper centers in the enzyme. Addition K3Fe(CN)6 or K2IrCl6 to the enzyme solution, prior to coulometric titration, indicates that these anions bind preferentially to one of the copper centers.     

76 The Pneumocystis sam:smt, an atypical fungal enzyme protein

Pneumocystis , an opportunistic fungal protist, causes a type of pneumonia in immunocompromised individuals such as AIDS patients. Rat-derived P. carinii and human-derived P. jiroveci contain a large number of sterols with C-24 alkyl groups. S-Adenosyl-L-methionine:sterol C-24 methyl transferase (SAM:SMT) is the enzyme that transfers methyl groups from SAM to the C-24 position of the sterol side chain. An alkyl group at the C-24 sterol side chain position appears to be essential for the organism to proliferate. Thus SAM:SMT, which is absent in mammals, is an attractive target for chemotherapeutic attack against the pathogen. The P. carinii erg6 gene that codes for SAM:SMT has been sequenced, cloned, and the protein expressed in E. coli . Since bacteria do not synthesize sterols, and do not have SAM:SMT, the P. carinii erg6 gene product expressed in E. coli would only transmethylate exogenously provided sterol substrates. The P. carinii recombinant SAM:SMT is unique because lanosterol, a central intermediate in sterol biosynthesis, is its preferred substrate for enzyme activity. Most SAM:SMT from other organisms do not bind lanosterol and prefer other sterol substrates produced from lanosterol. Furthermore, it appears that this unusual P. carinii SAM:SMT can also methylate cholesterol, which is readily scavenged from the lungs of its rat host. The recombinant enzyme protein is being purified by affinity chromatography techniques, which will be used to obtain definitive structural analyses of the sterol compounds formed by the enzyme reaction using different sterols substrates and allow detailed structural analysis of this unusual SAM:SMT enzyme protein.     

Superoxide organic chemistry within the liposomal bilayer, part II: a correlation between location and chemistry

Coumarin ester derivatives 1, substituted at C-4 and/or C-12 with alkyl chains, were synthesized and intercalated within DMPC liposomal bilayers. By correlating the 13C chemical shift with medium polarity [E(T)(30)], the relative location of these substrates within the liposomal bilayer was determined. The length of the alkyl chain substituents clearly influences the lipophilicity of the substrates and their location and orientation within the liposome: Superoxide readily saponifies the C-12 esteric linkage of 1, when this reaction site lies in a polar region of the liposome (E(T)(30) > 45 kcal/mol), to give the corresponding 7-hydroxy coumarin derivatives 2. However, when C-12 lies deeper and is hence less available to O(2)(*-), the lactonic carbon C-2, which lies in a shallower region (E(T)(30) = 43-49), is the preferred site for superoxide-mediated cleavage. When coumarin 1 is disubstituted with long chains at both C-12 and C-4, these derivatives lie deep within the bilayer and react only slowly with O(2)(*-). These results indicate there is indeed a correlation between location within the bilayer and substrate reactivity. Contrary to the suggestion of Dix and Aikens (Chem. Res. Toxicol.6:2-18; 1993) superoxide can penetrate deep within the liposomal bilayer. Nevertheless, its concentration drops precipitously (to approximately 16% of what it is near the interface) below E(T) values of 38, thereby precluding substantial reaction with many highly lipophilic substrates. This work also confirms the findings of others that reactions of small oxy-radicals occur within cellular membranes and appear to be of significant biological importance.     

Mechanistic and stereochemical studies of a unique dehydration catalyzed by CDP-4-keto-6-deoxy-D-glucose-3-dehydrase: a pyridoxamine 5'-phosphate dependent enzyme isolated from Yersinia pseudotuberculosis.

CDP-4-keto-6-deoxy-D-glucose-3-dehydrase (E1) purified from Yersinia pseudotuberculosis is a pyridoxamine 5'-phosphate (PMP) dependent enzyme which catalyzes the C-O bond cleavage at C-3 of a CDP-4-keto-6-deoxy-D-glucose substrate, a key step in the formation of 3,6-dideoxyhexoses. Since enzyme E1 utilizes the PMP cofactor in a unique manner, it is essential to establish its role in E1 catalysis. When an incubation was conducted in [18O]H2O, incorporation of 18O into positions C-3 and C-4 of the recovered substrate was observed. This result not only provided the evidence necessary to reveal the reversibility of E1 catalysis but also lent credence to the formation of a delta 3,4-glucoseen intermediate. In view of E1 catalysis being initiated by a C-4' deprotonation of the PMP-substrate complex, the stereochemical course of this step was examined using chemically synthesized (4'S)- and (4'R)-[4'-3H]PMP as probes. Our results clearly demonstrated that the stereochemistry of this deprotonation is pro-S specific, which is in agreement with the stereochemical consistency found with other vitamin B6 phosphate dependent enzymes. The fact that reprotonation at C-4' of the PMP-delta 3,4-glucoseen complex in the reverse direction of E1 catalysis was also found to be pro-S stereospecific strongly suggested that enzyme E1, like most of its counterparts, has the si face of its cofactor-substrate complex exposed to solvent and accessible to active-site catalytic groups as well.(ABSTRACT TRUNCATED AT 250 WORDS)     

Stereospecific labilization of the C-4' pro-S hydrogen of pyridoxamine 5'-phosphate in aspartate aminotransferase

In the course of a half-reaction of enzymic transamination, the aldimine adduct formed between the coenzyme pyridoxal 5'-phosphate and the amino acid substrate tautomerizes to the ketimine intermediate which is then hydrolyzed to the oxo acid product and the pyridoxamine 5'-phosphate form of the enzyme. In the reverse half-reaction the tautomerization is initiated by the removal of a proton from the pro-S position at C-4' of the PMP moiety of the ketimine intermediate. The present study investigates the question whether the pro-S hydrogen at C-4' of PMP is labilized by its active site environment independently of the formation of the ketimine intermediate, i.e. in the absence of substrate. Reconstitution of apoaspartate aminotransferase (mitochondrial isoenzyme from chicken) with [4'-3H] PMP results indeed in a stereospecific exchange of pro-S 3H with solvent water. The exchange follows first order kinetics (t 1/2 = 23 min at pH 7.5 and 25 degrees C). Unbound PMP showed no measurable exchange. Rigorous control experiments excluded the possibility that the observed exchange was due to a transamination reaction of the enzyme with contaminating oxo acid substrates. The newly observed stereospecific exchange reaction allows to investigate the acid/base properties of C-4' and the modulating effects of its active site environment independently of the preceding and following steps of enzymic transamination.     

Dehydroquinate synthase: the use of substrate analogues to probe the early steps of the catalyzed reaction

The early steps of the proposed mechanistic pathway for dehydroquinate synthase have been probed with a series of substrate analogues. These analogues, 3-9, are structurally prohibited from undergoing the beta-elimination of inorganic phosphate that represents the committed step in the conversion of the substrate 3-deoxy-D-arabino-heptulosonate 7-phosphate (1) to dehydroquinate (2). In agreement with previous observations, the analogues that possess shortened side chains (3,5, and 6) bind more tightly to the enzyme than those (4 and 7-9) that are more nearly isosteric with the substrate. Two hitherto unrecognized factors that influence binding have been identified: (i) carbacylic analogues bind 25-100 times more tightly than the corresponding oxacyclic materials (indeed, the carbacyclic phosphonate 5 has a Ki value of 8 x 10(-10)M) and (ii) the side chain appears to be bound in a gauche conformation similar to the most stable conformation of the cis-vinylhomophosphonate 8. These trends in binding can be rationalized by considering the behavior of the analogues in the first two chemical steps of the mechanism: NAD+-mediated oxidation at C-5 and enolization at C-6 (the first part of the E1cB elimination of inorganic phosphate). Direct spectrophotometric determination of the equilibrium level of enzyme-bound NADH indicates that the carbacyclic analogues are more readily oxidized than the oxacyclic compounds, and this predictable difference in redox behavior is reflected in the observed differences in binding. The gauche conformation of the C-7 side chain appears to be required for proton abstraction from C-6, since only those analogues that can adopt this conformation undergo enzyme-catalyzed exchange of the C-6 proton with the solvent. This conformation positions one of the peripheral oxygens of the phosphate (or phosphonate) group close to the C-6 proton. Taken together with other data, these results suggest that the enzyme exploits this substrate base in the enolization, which occurs through an intramolecular proton transfer. The loss of Pi then completes the beta-elimination.     

Competitive inhibition of lipolytic enzymes. IV. Structural details of acylamino phospholipid analogues important for the potent inhibitory effects on pancreatic phospholipase A2

1-Acyl-2(R)-acylamino phospholipids are effective competitive inhibitors of porcine pancreatic phospholipase A2 (EC 3.1.1.4, Bonsen et al. (1972) Biochim. Biophys. Acta 270, 364-382). By systematically varying the substituent at C-1 and the acyl chain length at C-2, a series of phospholipid analogues was obtained for which the inhibitory power was determined in a detergent-containing and occasionally also in a detergent-free micellar substrate system. The recently proposed kinetic model applicable to water-insoluble inhibitors (Ransac et al. (1990) Biochim. Biophys. Acta 1043, 57-66) allowed a quantitative comparison of the inhibitory power Z of the various substrate analogues. The most powerful inhibitors of the enzyme were found to possess the general 2-(R)-structure: (formula; see text) Using as substrate (R)-1,2-didodecanoylglycero-3-phosphocholine in mixed micelles with sodium taurodeoxycholate, the inhibitor molecule with m = 4 and n = 11 showed a Z-value of 15,000. This implies an affinity of the inhibitor for the active site of the enzyme higher than 4 orders of magnitude stronger as compared with the substrate molecule. Slightly higher and lower m-values resulted in a sharp drop of the inhibitory power, which suggests that the enzyme must possess a rather short, but well-defined hydrophobic binding pocket for the C-1 alkyl chain. Variation of n (keeping m = 2 constant) resulted in inhibitors with nearly equal Z-values for n = 11, 13 and 15. Most probably the binding cleft on the enzyme for the C-2 acylamino chain is longer, more losely constructed and contributing less to the overall binding energy. Several members of the 2-acylamino phospholipids are water-soluble and possess relatively high critical micelle concentrations. Their inhibitory power could be tested not only in micellar substrate dispersions but also in assay systems where both the inhibitor and substrate are molecularly dispersed. It appeared that these water-soluble phospholipid analogues are effective inhibitors of the enzyme only after incorporation into an organized substrate/water interface. In contrast, in molecularly dispersed substrate solutions the same molecules have completely lost their inhibitory power. These observations support our kinetic model of lipolysis and interfacial inhibition.     

Elucidation of the order of oxidations and identification of an intermediate in the multistep clavaminate synthase reaction

The enzyme clavaminate synthase (CS) catalyzes the formation of the first bicyclic intermediate in the biosynthetic pathway to the potent beta-lactamase inhibitor clavulanic acid. Our previous work has led to the proposal that the cyclization/desaturation of the substrate proclavaminate proceeds in two oxidative steps, each coupled to a decarboxylation of alpha-ketoglutarate and a reduction of dioxygen to water [Salowe, S. P., Marsh, E. N., & Townsend, C. A. (1990) Biochemistry 29, 6499-6508]. We have now employed kinetic isotope effect studies to determine the order of oxidations for CS purified from Streptomyces clavuligerus. By using (4'RS)-[4'-3H,1-14C]-rac-proclavaminate, a primary T(V/K) = 8.3 +/- 0.2 was measured from [3H]water release data, while an alpha-secondary T(V/K) = 1.06 +/- 0.01 was determined from the changing 3H/14C ratio of the product clavaminate. Values for the primary and alpha-secondary effects of 11.9 +/- 1.7 and 1.12 +/- 0.07, respectively, were obtained from the changing 3H/14C ratio of the residual proclavaminate by using new equations derived for a racemic substrate bearing isotopic label at both primary and alpha-secondary positions. Since only the first step of consecutive irreversible reactions will exhibit a V/K isotope effect, we conclude that C-4' is the initial site of oxidation in proclavaminate. As expected, no significant changes in the 3H/14C ratio of residual substrate were observed with [3-3H,1-14C]-rac-proclavaminate. However, two new tritiated compounds were produced in this incubation, apparently the result of isotope-induced branching brought about by the presence of tritium at the site of the second oxidation. One of these compounds was identified by comparison to authentic material as dihydroclavaminate, a stable intermediate that normally remains enzyme-bound. On the basis of the body of information available and the similarities to alpha-ketoglutarate-dependent dioxygenases, a comprehensive mechanistic scheme for CS is proposed to account for this unusual enzymatic transformation.     

15-Hydroxy-prostanoate dehydrogenase. Prostaglandins as substrates and inhibitors

Determination of Michaelis constnats and maximum reaction rates for a series of prostaglandin dehydrogenase substrates showed that the enzyme is stereospecific with regard to configuration at C-15. Substituents of the cyclopentane ring did not markedly affect the properties as a substrate, whereas the nature of the carboxyl side chain proved important. A noncompetitive inhibition was produced between prostaglandin B compounds and a synthetic epimer of prostaglandin E1, 15-R-prostaglandin E1.     

L-methionine decarboxylase from Dryopteris filix-mas: purification, characterization, substrate specificity, abortive transamination of the coenzyme, and stereochemical courses of substrate decarboxylation and coenzyme transamination

L-Methionine decarboxylase from the male fern Dryopteris filix-mas has been purified 256-fold from acetone powder extracts to very near homogeneity. The enzyme is membrane-associated and requires detergent for solubilization during the initial extraction. The enzyme is a homodimer of subunit Mr 57,000 and shows a pH optimum at approximately 5.0 with 20 mM (2S)-methionine as substrate. The specific activity, kcat, for methionine is approximately 50 mol s(-1) (mol of active site)(-1) at pH 4.5 and below. A wide range of straight- and branched-chain (2S)-alkylamino acids are substrates for the enzyme. The values for the rate of decarboxylation, Vmax, and for the apparent Michaelis constant, Km, however, vary with structure and with the chirality at C-3. The pH dependence of V and V/K has been examined for three substrates: (2S)-methionine, valine, and leucine. Pyridoxal 5'-phosphate (PLP) is required for activity, and in the absence of excess PLP, the activity of the enzyme in incubations reduced with respect to time. The addition of PLP fully restores the activity, indicating that an abortive decarboxylation-transamination accompanies the normal decarboxylation reaction. The occurrence of the abortive reaction was confirmed by showing that [35S]methionine is converted to labeled 3-(methylthio)propionaldehyde while [4'-3H]PLP is converted to labeled pyridoxamine 5'-phosphate (PMP). The decarboxylation of (2S)-methionine gave 3-(methylthio)-1-aminopropane. Preparation of the N-camphanamide derivative of the amine allowed the C-1 methylene protons to be distinguished by 1H NMR spectroscopy. Synthetic samples of the camphanamide were prepared in which each of the C-1 methylene protons was replaced by deuterium. When (2S)-methionine and the C-2 deuteriated isotopomer were incubated with the enzyme in deuterium oxide and protium oxide, respectively, and the products were converted to their camphanamide derivatives and analyzed by 1H NMR spectroscopy, it was evident that decarboxylation occurred with retention of configuration at C-2. When the decarboxylation of six other substrates was studied, examination of the N-camphanamide derivatives of the amines indicated that decarboxylation occurred stereospecifically and, by analogy, with retention of configuration at C-2. When tritiated pyridoxal phosphate was incubated with the enzyme, tritiated pyridoxamine phosphate was formed. Analysis of the chirality of the methylene group at C-4' indicated that, during abortive transamination, protonation occurred from the 4'-si face of the coenzyme, the same stereochemical result as that obtained for several bona fide transaminase enzymes.(ABSTRACT TRUNCATED AT 400 WORDS)     

Studies of electron-transfer properties of salicylate hydroxylase from Pseudomonas cepacia and effects of salicylate and benzoate binding

The pH dependence of the redox behavior of salicylate hydroxylase from Pseudomonas cepacia as well as the effects of salicylate, benzoate, and chloride binding is described. At pH 7.6 in 0.02 M potassium phosphate buffer E1(0')(EFl ox/EFl.-) is -0.150 V and E2(0')(EFl.-/EFl red H-) is -0.040 V versus the standard hydrogen electrode (SHE). A maximum of 5% of FAD anion semiquinone is thermodynamically stabilized under these conditions. However, in coulometric and dithionite titrations more semiquinone is kinetically formed, indicating slow transfer of the second electron. The potential/pH dependence is consistent with a two-electron, one-proton transfer. Upon salicylate binding the midpoint potential is shifted 0.020 V negative from -0.094 to -0.114 V vs SHE at pH 7.6. A maximum of 7% of the neutral semiquinone is stabilized both in potentiometric and coulometric titrations. This small potential shift indicates that the substrate is bound nearly to the same extent to all three oxidation states of the enzyme. It is clear that the substrate binding does not make the reduction of the flavin thermodynamically more favorable. In contrast to salicylate, the potential shift caused by the effector, benzoate, is much more significant. (A maximum potential shift of -0.07 V is calculated.) Benzoate binds most tightly to the oxidized form and is least tightly bound to the two-electron-reduced form of the enzyme. For the reduction of the free enzyme the transfer of the second electron or the transfer of the proton is rate limiting, as is shown by the kinetic formation of the anionic semiquinone.(ABSTRACT TRUNCATED AT 250 WORDS)