Mechanism of the reaction catalyzed by mandelate racemase. 1. Chemical and kinetic evidence for a two-base mechanism

The fate of the alpha-hydrogen of mandelate in the reaction catalyzed by mandelate racemase has been investigated by a mass spectroscopic method. The method entails the incubation of (R)- or (S)-[alpha-1H]mandelate in buffered D2O to a low extent of turnover (about 5-8%), esterification of the resulting mixture of mandelates with diazomethane, derivatization of the methyl esters with a chiral derivatizing agent, and quantitation of the isotope content of the alpha-hydrogen of both substrate and product by gas chromatography/mass spectrometric analysis. No significant substrate-derived alpha-protium was found in the product for racemization in either direction. In addition, in the (R) to (S) direction almost no exchange (less than or equal to 0.4%) of the alpha-hydrogen in the remaining (R) substrate pool occurred, but in the (S) to (R) direction 3.5-5.1% exchange of the alpha-hydrogen in the remaining substrate (after 5.1-7.2% net turnover) was found. Qualitatively similar results were obtained in the (S) to (R) direction in H2O when (S)-[alpha-2H]mandelate was used as substrate. In other experiments, an overshoot in the progress curve was observed when the racemization of either enantiomer of [alpha-1H]mandelate in D2O was monitored by following the change in ellipticity of the reaction mixture; the magnitude of the overshoot was greater in the (R) to (S) than in the (S) to (R) direction. All of the available data indicate that the reaction catalyzed by mandelate racemase proceeds by a two-base mechanism, in contrast to earlier proposals.     

Symmetry and asymmetry in mandelate racemase catalysis

Kinetic properties of mandelate racemase catalysis (Vmax, Km, deuterium isotope effects, and pH profiles) were all measured in both directions by the circular dichroic assay of Sharp et al. [Sharp, T. R., Hegeman, G. D., & Kenyon, G. L. (1979) Anal. Biochem. 94, 329]. These results, along with those of studying interactions of mandelate racemase with resolved, enantiomeric competitive inhibitors [(R)- and (S)-alpha-phenylglycerates], indicate a high degree of symmetry in both binding and catalysis. Racemization of either enantiomer of mandelate in D2O did not show an overshoot region of molecular ellipticity in circular dichroic measurements upon approach to equilibrium. Both the absence of such an overshoot region and the high degree of kinetic symmetry are consistent with a one-base acceptor mechanism for mandelate racemase. On the other hand, results of irreversible inhibition with partially resolved, enantiomeric affinity labels [(R)- and (S)-alpha-phenylglycidates] reveal a "functional asymmetry" at the active site. Mechanistic proposals, consistent with these results, are presented.     

Cloning, DNA sequence analysis, and expression in Escherichia coli of the gene for mandelate racemase from Pseudomonas putida

The gene for mandelate racemase (EC 5.1.2.2) from Pseudomonas putida (ATCC 12633) was cloned in Pseudomonas aeruginosa (ATCC 15692). The selection for the cloned gene was based upon the inability of P. aeruginosa to grow on (R)-mandelate as sole carbon source by virtue of the absence of mandelate racemase in its mandelate pathway. Fragments of P. putida DNA obtained by digestion of chromosomal DNA with Sau3A were ligated into the BamHI site of the Gram-negative vector pKT230 and transformed into the P. aeruginosa host. A transformant able to utilize (R)-mandelate as sole carbon source was characterized, and the plasmid was found to contain approximately five kilobase pairs of P. putida DNA. Subcloning of this DNA revealed the position of the gene for the racemase within the cloned DNA from P. putida. The dideoxy-DNA sequencing procedure was used to determine the sequence of the gene and its translated sequence. The amino acid sequence and molecular weight for mandelate racemase deduced from the gene sequence (38 570) are in excellent agreement with amino acid composition and molecular weight data for the polypeptide recently determined with enzyme isolated from P. putida; these recent determinations of the polypeptide molecular weight differ significantly from the originally reported value of 69,500 [Fee, Judith A., Hegeman, G.D., & Kenyon, G.L. (1974) Biochemistry 13,2528], which was used to demonstrate that alpha-phenylglycidate, an active site directed irreversible inhibitor, binds to the enzyme with a stoichiometry of 1:1.(ABSTRACT TRUNCATED AT 250 WORDS)     

Synthesis of the enzymes of the mandelate pathway by Pseudomonas putida. II. Isolation and properties of blocked mutants

Hegeman, G. D. (University of California, Berkeley). Synthesis of the enzymes of the mandelate pathway by Pseudomonas putida. II. Isolation and properties of blocked mutants. J. Bacteriol. 91:1155-1160. 1966.-Mutants of Pseudomonas putida blocked in early reactions of the pathway for oxidation of d-mandelate were isolated and partially characterized. The specific genetic lesions in these mutants made normal inducer-metabolites of the pathway nonmetabolizable. Under the conditions of gratuitous enzyme synthesis so obtained, it could be shown that the d and l isomers of mandelate are equipotent inducers, and that the synthesis of the first five enzymes of the mandelate pathway is coordinate. Further experiments with the blocked mutants showed that benzoylformate, the third intermediate of the pathway, acts as an inducer without prior conversion to mandelate, and that there is no inducible, concentrating permease for mandelate.     

Mechanism of the reaction catalyzed by mandelate racemase. 3. Asymmetry in reactions catalyzed by the H297N mutant

The two preceding papers [Powers, V. M., Koo, C. W., Kenyon, G. L., Gerlt, J. A., & Kozarich, J. W. (1991) Biochemistry (first paper of three in this issue); Neidhart, D. J., Howell, P. L., Petsko, G. A., Powers, V. M., Li, R., Kenyon, G. L., & Gerlt, J. A. (1991) Biochemistry (second paper of three in this issue)] suggest that the active site of mandelate racemase (MR) contains two distinct general acid/base catalysts: Lys 166, which abstracts the alpha-proton from (S)-mandelate, and His 297, which abstracts the alpha-proton from (R)-mandelate. In this paper we report on the properties of the mutant of MR in which His 297 has been converted to asparagine by site-directed mutagenesis (H297N). The structure of H297N, solved by molecular replacement at 2.2-A resolution, reveals that no conformational alterations accompany the substitution. As expected, H297N has no detectable MR activity. However, H297N catalyzes the stereospecific elimination of bromide ion from racemic p-(bromomethyl)mandelate to give p-(methyl)-benzoylformate in 45% yield at a rate equal to that measured for wild-type enzyme; the unreacted p-(bromomethyl)mandelate is recovered as (R)-p-(hydroxymethyl)mandelate. At pD 7.5, H297N catalyzes the stereospecific exchange of the alpha-proton of (S)- but not (R)-mandelate with D2O solvent at a rate 3.3-fold less than that observed for incorporation of solvent deuterium into (S)-mandelate catalyzed by wild-type enzyme. The pD dependence of the rate of the exchange reaction catalyzed by H297N reveals a pKa of 6.4 in D2O, which is assigned to Lys 166.(ABSTRACT TRUNCATED AT 250 WORDS)     

Redefining the minimal substrate tolerance of mandelate racemase. Racemization of trifluorolactate

Mandelate racemase (EC 5.1.2.2) from Pseudomonas putida catalyzes the interconversion of the enantiomers of mandelic acid and a variety of aryl- and heteroaryl-substituted mandelate derivatives, suggesting that β,γ-unsaturation is a requisite feature of substrates for the enzyme. We show that β,γ-unsaturation is not an absolute requirement for catalysis and that mandelate racemase can bind and catalyze the racemization of (S)-trifluorolactate (k(cat) = 2.5 ± 0.3 s(-1), K(m) = 1.74 ± 0.08 mM) and (R)-trifluorolactate (k(cat) = 2.0 ± 0.2 s(-1), K(m) = 1.2 ± 0.2 mM). The enzyme was shown to catalyze hydrogen-deuterium exchange at the α-postion of trifluorolactate using (1)H NMR spectrocsopy. β-Elimination of fluoride was not detected using (19)F NMR spectroscopy. Although mandelate racemase bound trifluorolactate with an affinity similar to that exhibited for mandelate, the turnover numbers (k(cat)) were markedly reduced by ～318-fold, resulting in catalytic efficiencies (k(cat)/K(m)) that were ~400-fold lower than those observed for mandelate. These observations suggested that chemical steps on the enzyme were likely rate-determining, which was confirmed by demonstrating that the rates of mandelate racemase-catalyzed racemization of (S)-trifluorolactate were not dependent upon the solvent microviscosity. Circular dichroism spectroscopy was used to measure the rates of nonenzymatic racemization of (S)-trifluorolactate at elevated temperatures. The values of ΔH(?) and ΔS(?) for the nonenzymatic racemization reaction were determined to be 28.0 (±0.7) kcal/mol and -15.7 (±1.7) cal K(-1) mol(-1), respectively, corresponding to a free energy of activation equal to 33 (±4) kcal/mol at 25 °C. Hence, mandelate racemase stabilizes the altered trifluorolactate in the transition state (ΔG(tx)) by at least 20 kcal/mol.     

Selection and characterization of a mutant of the cloned gene for mandelate racemase that confers resistance to an affinity label by greatly enhanced production of enzyme

The plasmid pSCR1 containing the gene for mandelate racemase (EC 5.1.2.2) from Pseudomonas putida (ATCC 12633) allows Pseudomonas aeruginosa (ATCC 15692) to grow on (R)-mandelate as its sole carbon source [Ransom, S. C., Gerlt, J. A., Powers, V. M., & Kenyon, G. L. (1988) Biochemistry 27, 540]; the chromosome of the P. aeruginosa host apparently does not contain the gene for mandelate racemase but does contain genes for the remaining enzymes in the mandelate pathway and enables growth on (S)-mandelate as carbon source. However, in the presence of alpha-phenylglycidate, an active-site-directed irreversible inhibitor (affinity label) of mandelate racemase, P. aeruginosa transformed with pSCR1 can utilize (S)-mandelate but not (R)-mandelate as carbon source. This inhibition of growth on (R)-mandelate provides a metabolic selection for mutants that are resistant to alpha-phenylglycidate. When (R)-mandelate is used as carbon source and alpha-phenylglycidate is present, a few colonies of P. aeruginosa transformed with pSCR1 grow slowly and appear on plates after several days. The plasmid isolated from these cells confers resistance to alpha-phenylglycidate on newly transformed cells of P. aeruginosa. This resistance to the affinity label is not due to a mutation within the primary structure of the enzyme. A single base change (C----A) located 87 bp upstream of the initiation codon for the gene for mandelate racemase was detected in three independent isolates of alpha-phenylglycidate-resistant colonies and appears responsible for a 30-fold increase in the amount of mandelate racemase encoded by the gene contained in the plasmid.(ABSTRACT TRUNCATED AT 250 WORDS)     

Degradation of mandelate and 4-hydroxymandelate by Rhizobium leguminosarum biovar trifolii TA1

Rhizobium leguminosarum biovar trifolii TA1 grows on 4-hydroxymandelate and enzymes involved in its catabolism are inducible. Strain TA1 does not grown on mandelate or cis, cis-muconate, but spontaneous mutants capable of growth on these substrates were isolated. Enzymes involved in mandelate degradation were also inducible. The presence of intermediates of the mandelate and hydroxymandelate pathways resulted in a significant decrease in some of the enzymes involved in their degradation. Succinate and acetate, end products of the pathways, and glucose caused reductions in the levels of enzymes in the mandelate and hydroxymandelate pathways.     

Fermentation of mandelate to benzoate and acetate by a homoacetogenic bacterium

A strictly anaerobic, Gram-positive, rod-shaped bacterium, strain AmMan1, was isolated from freshwater sediment with mandelate (-hydroxy-phenylacetate) as sole carbon and energy source, and was assigned to the genus Acetobacterium. Only the d-enantiomer of mandelate was degraded, and was fermented to acetate and benzoate. Non-aromatic growth substrates (pyruvate, lactate, malate, glycerol, ethylene glycol, and H₂/CO₂) were fermented to acetate as sole product. Methoxylated aromatics were demethoxylated to the corresponding phenols. The guanine-plus-cytosine content of the DNA was 36.5±1.5%. Carbon monoxide dehydrogenase, dichlorophenol indophenol-reducing lactate dehydrogenase, NAD-dependent mandelate dehydrogenase, phosphate acetyl transferase, acetate kinase, and pyruvate- or phenylglyoxylate-dependent benzylviologen reductase were measured in mandelate-and/or lactate-grown cells, respectively. A pathway of the homoacetogenic fermentation of mandelate is suggested as another example of incomplete substrate oxidation by homoacetogenic bacteria.     

Synthesis of the enzymes of the mandelate pathway by Pseudomonas putida. 3. Isolation and properties of constitutive mutants

Hegeman, G. D. (University of California, Berkeley). Synthesis of the enzymes of the mandelate pathway by Pseudomonas putida. III. Isolation and properties of constitutive mutants. J. Bacteriol. 91:1161-1167. 1966.-Mutants of Pseudomonas putida constitutive for the synthesis of l(+)-mandelate dehydrogenase were obtained after mandelate- or benzoylformate-limited growth in a chemostat. When grown in media noninducing for the wild type, the mutants are capable of coordinate, constitutive synthesis of the first five enzymes of the mandelate pathway. Later enzymes of the pathway that were examined are normally repressed. The constitutive mutants have two other noteworthy properties: they are superinducible by some compounds which induce the mandelate group enzymes in the wild type, or as a result of exhaustion of the carbon and energy source of the medium in which they are grown; and they exhibit a decreased specificity of induction, being inducible by a wide range of compounds devoid of inductive function for the wild type. These results, together with other evidence indicating that the five mandelate group enzymes comprise a regulatory unit, are discussed and evaluated in the context of the general problem of the regulation of complex dissimilatory pathways.     

Inhibition of cellular cholesterol esterification can decrease low density lipoprotein receptor number in human fibroblasts

In fibroblasts deprived of exogenous cholesterol to induce low density lipoprotein receptors there is a continuing flux of cholesterol esterification. The structurally unrelated inhibitors of acyl-CoA; cholesterol acyl-transferase, progesterone, trimethylcyclohexanyl mandelate and 3-[decyldimethylsilyl]-N-[2-(4-methylphenyl)-1-phenylethyl] propanamide, (58035), could all inhibit this basal rate of esterification within 1h of addition. Exposure of cholesterol-deprived fibroblasts for 17h to progesterone or trimethylcyclohexanyl mandelate caused decreased specific binding and metabolism of low density lipoprotein. The effect was not a direct inhibition of lipoprotein binding; it was time dependent and followed from the reversible inhibition of cholesterol esterification by these two compounds. The irreversible inhibition of esterification by 58035 left the receptor number unaffected. The results indicate that down regulation of low density lipoprotein receptors is initiated by accumulation of cholesterol in a specific intracellular pool. Inhibition of cholesterol esterification by progesterone and trimethylcyclohexanyl mandelate causes accumulation of cholesterol in this pool but 58035 does not.     

The effect of a non-metabolizable analog on mandelate catabolism in Pseudomonas putida

Dl-2,3,4,5,6-pentafluoromandelic acid (PFM) specifically inhibits the growth of Pseudomonas putida (ATCC 12633) on medium containing mandelate as sole carbon and energy source by competitive inhibition of mandelate dehydrogenase. PFM is not metabolized and is neither an inducer of the mandelate catabolic enzymes nor an antagonist of induction. Mutants resistant to the inhibitory effects of PFM (PFM^r) were isolated; most prove to be superinducible, i.e. synthesize coordinately the mandelatespecific catabolic enzymes at elevated levels following induction. In at least one case the PFM^r mutation maps very near the structural genes that encode the enzymes functional in the first two steps of mandelate catabolism. It is reasoned that the PFM^r mutation is of the promotor type. Resistance to substrate analogs such as PFM offers a general method for isolation of regulatory mutants in catabolic metabolism.Dedicated to Prof. Roger Y. Stanier on the occasion of his 60th birthday     

Co-production of biofuel,bioplastics and biochemicals during extended fermentation of Halomonas bluephagenesis

Halomonas bluephagenesis TD1.0 was engineered to produce the biofuel propane, bioplastic poly-3-hydroxybutyrate (PHB), and biochemicals mandelate and hydroxymandelate in a single, semi-continuous batch fermentation under non-sterile conditions. Multi-product separation was achieved by segregation of the headspace gas (propane), fermentation broth ([hydroxy]mandelate) and cellular biomass (PHB). Engineering was performed by incorporating the genes encoding fatty acid photodecarboxylase (CvFAP) and hydroxymandelic acid synthase (SyHMAS) into a H. bluephagenesis hmgCAB cassette knockout to channel flux towards (hydroxy)mandelate. Design of Experiment strategies were coupled with fermentation trials to simultaneously optimize each product. Propane and mandelate titres were the highest reported for H. bluephagenesis (62 g/gDCW and 71 ± 10 mg/L respectively) with PHB titres (69% g/gDCW) comparable to other published studies. This proof-of-concept achievement of four easily separated products within one fermentation is a novel achievement probing the versatility of biotechnology, further elevating H. bluephagenesis as a Next Generation Industrial Biotechnology (NGIB) chassis by producing highly valued products at a reduced cost.     

Initial reactions involved in the dissimilation of mandelate by Rhodotorula graminis.

Rhodotorula graminis utilized DL-mandelate, L(+)-mandelate, and D(-)-mandelate as sole sources of carbon and energy. Growth on these aromatic substrates resulted in the induction of an NAD-dependent D(-)-mandelate dehydrogenase and a dye-linked L(+)-mandelate dehydrogenase, each catalyzing the stereospecific conversion of its respective enantiomer of mandelate to benzoylformate. Benzoylformate was oxidized to benzaldehyde, which was dehydrogenated to benzoate by an NAD-dependent benzaldehyde dehydrogenase. Benzoate was further metabolized through p-hydroxybenzoate and the protocatechuate branch of the beta-ketoadipate pathway.     

Synthesis of the enzymes of the mandelate pathway by Pseudomonas putida. I. Synthesis of enzymes by the wild type

Hegeman, G. D. (University of California, Berkeley). Synthesis of the enzymes of the mandelate pathway by Pseudomonas putida. I. Synthesis of enzymes by the wild type. J. Bacteriol. 91:1140-1154. 1966.-The control of synthesis of the five enzymes responsible for the conversion of d(-)-mandelate to benzoate by Pseudomonas putida was investigated. The first three compounds occurring in the pathway, d(-)-mandelate, l(+)-mandelate, and benzoylformate, are equipotent inducers of all five enzymes. A nonmetabolizable inducer, phenoxyacetate, also induces synthesis of these enzymes; but, unlike the metabolizable inducer-substrates, it does not elicit synthesis of enzymes that mediate steps in the pathway beyond benzoate. Under conditions of semigratuity, dl-mandelate elicits immediate synthesis at a steady rate of the first two enzymes of the pathway, but two enzymes which act below the level of benzoate are synthesized only after a considerable lag. Succinate and asparagine do not significantly repress the synthesis of the enzymes responsible for mandelate oxidation.     

Hydroxamates as substrates and inhibitors for FMN-dependent 2-hydroxy acid dehydrogenases

Long-chain hydroxy acid oxydase (HAO) is a member of a flavoenzyme family with significant amino acid sequence similarity and strongly conserved three-dimensional structure; in particular, active-site amino acids involved in catalysis are invariant, with one exception, and numerous enzymatic studies suggest an identical chemical mechanism involving an intermediate carbanion for all family members. Known physiological substrates are a variety of L-2-hydroxy acids. Peroxisomal HAO differs from the other family members in that its actual physiological substrate is not known; it was first described as an L-amino acid oxidase, and recently was identified as an enzyme that converts creatol (hydroxycreatinine) to methylguanidine (a metabolite involved in a variety of uremic syndromes). Creatol (2-amino-5-hydroxy-1-methyl-4(5H)imidazolone) is not a 2-hydroxy acid. We show in this work that 2-hydroxyphenyl acetohydroxamate (HYPAH, the hydroxamate of mandelic acid), a compound that bears similarity both to mandelate (one of the best substrates known) and to creatol, is turned over by HAO, but between 10- and 100-fold less efficiently than mandelate itself. The compound also binds to the active site of homologous flavocytochrome b(2) (L-lactate dehydrogenase). Comparative pH-rate studies for mandelate and its hydroxamate suggest that HYPAH may bind in its ionized form. Both pH-rate profiles are bell-shaped curves, as are those determined for two other family members, flavocytochrome b(2) and mandelate dehydrogenase; while the group with an acid pK(a) between 5 and 6 is most likely the active-site histidine (the residue which abstracts the substrate C2 proton), the identity of the basic group is less clear. It has been proposed to be one of the active site arginines (Lehoux, I., and Mitra, B. (1999) Biochemistry38, 5836-5848); we suggest as an alternative that it could be the lysine residue that interacts with the flavin N1 and O2 positions and stabilizes the negative charge of reduced flavin. In addition to these studies, we have found that HAO is competitively inhibited by benzohydroxamate, which is one atom shorter than HYPAH; its affinity is nearly 100-fold lower than that of the substrate, in contrast to the strong inhibition it exerts on mandelate racemase (Maurice, St. M., and Bearne, S. L. (2000) Biochemistry39, 13324-13335). In the latter case, the 100-fold higher affinity compared to mandelate was proposed to arise from the fact that the hydroxamate can mimic the enolic intermediate which lies on the reaction pathway after C2 proton abstraction. Thus our results do not support the existence of a similar enolic intermediate for HAO (and probably its homologues), although they do not disprove it.     

Molecular dynamics perspective on the thermal stability of mandelate racemase

Mandelate racemase from Pseudomonas putida is a promising candidate for the dynamic kinetic resolution of α-hydroxy carboxylic acids. In the present study, the thermal stability of mandelate racemase was investigated through molecular dynamics simulations in the temperature range of 303–363 K, which can guide the design of mandelate racemase with higher stability. The basic features such as radius of gyration, surface accessibility, and secondary structure content suggested the instability of mandelate racemase at high temperatures. With increase in temperature, α-helix content reduced significantly, especially the α-helices exposed to the environment. At the simulation time scale considered, intra-protein hydrogen bonds, hydrogen bonds between protein and water decreased at 363 K, while the number of salt-bridges increased. The long-distance networks remarkably changed at 363 K. A considerable number of long-lived (percentage existence time higher than 90%) hydrogen bonds and Cα contacts were lost. Root mean square fluctuation analysis revealed regions with high fluctuation, which should be helpful in the reengineering of mandelate racemase for enhanced thermal stability.     

Mandelate pathway of Pseudomonas putida: sequence relationships involving mandelate racemase, (S)-mandelate dehydrogenase, and benzoylformate decarboxylase and expression of benzoylformate decarboxylase in Escherichia coli

The genes that encode the five known enzymes of the mandelate pathway of Pseudomonas putida (ATCC 12633), mandelate racemase (mdlA), (S)-mandelate dehydrogenase (mdlB), benzoylformate decarboxylase (mdlC), NAD(+)-dependent benzaldehyde dehydrogenase (mdlD), and NADP(+)-dependent benzaldehyde dehydrogenase (mdlE), have been cloned. The genes for (S)-mandelate dehydrogenase and benzoylformate decarboxylase have been sequenced; these genes and that for mandelate racemase [Ransom, S. C., Gerlt, J. A., Powers, V. M., & Kenyon, G. L. (1988) Biochemistry 27, 540] are organized in an operon (mdlCBA). Mandelate racemase has regions of sequence similarity to muconate lactonizing enzymes I and II from P. putida. (S)-Mandelate dehydrogenase is predicted to be 393 amino acids in length and to have a molecular weight of 43,352; it has regions of sequence similarity to glycolate oxidase from spinach and ferricytochrome b2 lactate dehydrogenase from yeast. Benzoylformate decarboxylase is predicted to be 499 amino acids in length and to have a molecular weight of 53,621; it has regions of sequence similarity to enzymes that decarboxylate pyruvate with thiamin pyrophosphate as cofactor. These observations support the hypothesis that the mandelate pathway evolved by recruitment of enzymes from preexisting metabolic pathways. The gene for benzoylformate decarboxylase has been expressed in Escherichia coli with the trc promoter, and homogeneous enzyme has been isolated from induced cells.     

Evidence for induced synthesis of an active transport factor for mandelate in Pseudomonas putida

1. At low concentrations of mandelate there is a lag before induction of the mandelate regulon begins at a sub-maximum rate. Cells preinduced with a saturating concentration of inducer do not exhibit this lag when they are transferred to sub-maximum inducer concentrations and are able to maintain a high rate of induction under these conditions. 2. Chloramphenicol was used to show that a protein is synthesized during the lag period that is probably responsible for the maintenance effects observed in batch and continuous cultures. 3. Direct measurements appear to show that induced cells possess an active transport factor for mandelate, sensitive to dinitrophenol, and this is presumably responsible for the maintenance effect. Mandelate is accumulated unchanged against a concentration gradient from media containing low concentrations. At higher external concentrations no accumulation occurs and only a rapid equilibration is noted. Uninduced cells merely equilibrate mandelate.     

Regulation of pathways degrading aromatic substrates in Pseudomonas putida. Enzymic response to binary mixtures of substrates

1. Induction constants (K(ind)) and repression constants (K(rep)), which are a measure of the affinity of the inducers or repressors for the induction systems, were measured for mandelate, benzoate and p-hydroxybenzoate in Pseudomonas putida. 2. From these results, the enzymic response of the organism to media containing pairs of these substrates was predicted. Nitrogen-limited chemostats, operated at high growth rates, were used to investigate these predictions in cells grown first on one aromatic substrate with the second added later. 3. In general, the values of K(ind) and K(rep) predicted quite accurately the response to substrate mixtures. Thus, in the presence of mandelate and either benzoate or p-hydroxybenzoate, the enzymes of mandelate metabolism were repressed almost completely, and the bacteria were fully induced for the alternative substrate (benzoate or p-hydroxybenzoate), which was preferentially utilized for growth. When benzoate and p-hydroxybenzoate were the two substrates in the mixture, the enzymes for metabolism of the latter were strongly repressed and growth took place mainly on benzoate. 4. The enzymic response to mixed substrates did not result in the metabolism of the better growth substrate, but in the substrate requiring the synthesis of fewer enzymes. Thus benzoate is used in preference to mandelate although the latter supports a faster growth rate. It is nevertheless considered that, with our present knowledge of the natural habitat of the organism, it is impossible to decide whether protein economy or growth rate was the factor determining the evolution of this control system.