A soybean coproporphyrinogen oxidase gene is highly expressed in root nodules

In plants the enzyme coproporphyrinogen oxidase catalyzes the oxidative decarboxylation of coproporphyrinogen III to protoporphyrinogen IX in the heme and chlorophyll biosynthesis pathway(s).We have isolated a soybean coproporphyrinogen oxidase cDNA from a cDNA library and determined the primary structure of the corresponding gene. The coproporphyrinogen oxidase gene encodes a polypeptide with a predicted molecular mass of 43 kDa. The derived amino acid sequence shows 50% similarity to the corresponding yeast amino acid sequence. The main difference is an extension of 67 amino acids at the N-terminus of the soybean polypeptide which may function as a transit peptide.A full-length coproporphyrinogen oxidase cDNA clone complements a yeast mutant deleted of the coproporphyrinogen oxidase gene, thus demonstrating the function of the soybean protein.The soybean coproporphyrinogen oxidase gene is highly expressed in nodules at the stage where several late nodulins including leghemoglobin appear. The coproporphyrinogen oxidase mRNA is also detectable in leaves but at a lower level than in nodules while no mRNA is detectable in roots.The high level of coproporphyrinogen oxidase mRNA in soybean nodules implies that the plant increases heme production in the nodules to meet the demand for additional heme required for hemoprotein formation.     

In situ conversion of coproporphyrinogen to heme by murine mitochondria: terminal steps of the heme biosynthetic pathway.

Coproporphyrinogen oxidase (EC 1.3.3.3), protoporphyrinogen oxidase (EC 1.3.3.4), and ferrochelatase (EC 4.99.1.1) catalyze the terminal three steps of the heme biosynthetic pathway. All three are either bound to or associated with the inner mitochondrial membrane in higher eukaryotic cells. A current model proposes that these three enzymes may participate in some form of multienzyme complex with attendant substrate channeling (Grand-champ, B., Phung, N., & Nordmann, Y., 1978, Biochem. J. 176, 97-102; Ferreira, G.C., et al., 1988, J. Biol. Chem. 263, 3835-3839). In the present study we have examined this question in isolated mouse mitochondria using two experimental approaches: one that samples substrate and product levels during a timed incubation, and a second that follows dilution of radiolabeled substrate by pathway intermediates. When isolated mouse mitochondria are incubated with coproporphyrinogen alone there is an accumulation of free protoporphyrin. When Zn is added as a substrate for the terminal enzyme, ferrochelatase, along with coproporphyrinogen, there is formation of Zn protoporphyrin with little accumulation of free protoporphyrin. When EDTA is added to this incubation mixture with Zn, Zn protoporphyrin formation is eliminated and protoporphyrin is formed. We have examined the fate of radiolabeled substrates in vitro to determine if exogenously supplied pathway intermediates can compete with the endogenously produced compounds. The data demonstrate that while coproporphyrinogen is efficiently converted to heme in vitro when the pathway is operating below maximal capacity, exogenous protoporphyrinogen can compete with endogenously formed protoporphyrinogen in heme production.(ABSTRACT TRUNCATED AT 250 WORDS)     

A 70-amino acid zinc-binding polypeptide fragment from the regulatory chain of aspartate transcarbamoylase causes marked changes in the kinetic mechanism of the catalytic trimer.

Interaction between a 70-amino acid and zinc-binding polypeptide from the regulatory chain and the catalytic (C) trimer of aspartate transcarbamoylase (ATCase) leads to dramatic changes in enzyme activity and affinity for active site ligands. The hypothesis that the complex between a C trimer and 3 polypeptide fragments (zinc domain) is an analog of R state ATCase has been examined by steady-state kinetics, heavy-atom isotope effects, and isotope trapping experiments. Inhibition by the bisubstrate ligand, N-(phosphonacetyl)-L-aspartate (PALA), or the substrate analog, succinate, at varying concentrations of substrates, aspartate, or carbamoyl phosphate indicated a compulsory ordered kinetic mechanism with carbamoyl phosphate binding prior to aspartate. In contrast, inhibition studies on C trimer were consistent with a preferred order mechanism. Similarly, 13C kinetic isotope effects in carbamoyl phosphate at infinite aspartate indicated a partially random kinetic mechanism for C trimer, whereas results for the complex of C trimer and zinc domain were consistent with a compulsory ordered mechanism of substrate binding. The dependence of isotope effect on aspartate concentration observed for the Zn domain-C trimer complex was similar to that obtained earlier for intact ATCase. Isotope trapping experiments showed that the compulsory ordered mechanism for the complex was attributable to increased "stickiness" of carbamoyl phosphate to the Zn domain-C trimer complex as compared to C trimer alone. The rate of dissociation of carbamoyl phosphate from the Zn domain-C trimer complex was about 10(-2) that from C trimer.(ABSTRACT TRUNCATED AT 250 WORDS)     

Equilibrium kinetics of substrate-enzyme interactions in single crystals of cytoplasmic aspartate aminotransferase

Orthorhombic single crystals of cytoplasmic aspartate aminotransferase were examined alone or in the presence of substrates or inhibitors to quantitatively compare the interaction of ligands with the active-site chromophore between soluble and crystalline enzyme. As in enzyme solutions, equilibrium kinetic measurements can be made between substrates and single crystals of cytoplasmic aspartate aminotransferase. The absorption spectra of ligand-free enzyme forms and of enzyme-substrate or-inhibitor complexes are as distinctive as when the enzyme is in solution. The dissociation constants for glutamate with the pyridoxal form of the enzyme are identical to those in solution. The substrate analog erythro--hydroxyaspartate also binds with equal affinity to the active site in enzyme crystals as in solution; and the affinity of -ketoglutarate to bind in nonproductive complexes with the pyridoxal form of the enzyme is also unimpaired in the crystal (K _d =2 mM). In contrast to the affinity constants, the stoichiometry of the interactions does not appear to correlate to those in solution. In the presence of an amino acid plus keto acid substrates pair, the absorbance values of the enzyme-substrate complex(es) could be interpreted as for occupany of only half the available sites in the crystals. Yet an amino acid, cysteine sulfinate, and -keto acids such as , -difluorooxalacetate convert all active sites in the crystal to the pyridoxamine or pyridoxal form when added to the pyridoxal or pyridoxamine forms, respectively. This ability to completely undergo substrate-induced half-transamination and the apparently conflicting results in trapping half the sites in enzyme-substrate complexes are incorporated into a proposed reciprocating mechanism applicable only to the crystalline state of the enzyme and dictated by crystal packing forces rather than an intrinsic property of the enzyme. Active-site bound pyridoxal phosphate continues to behave as a pH indicator; nevertheless, the pK value of the single crystals is a pH unit (pK=7.15) higher than that in solution. This variation is interpreted as indication of a difference in the environment of the chromophore between the crystal and solution states. While the environmental difference does not significantly alter the affinity for substrates, it could account for the reduced rates in transformation of the enzyme-substrate complexes in half-transamination reactions in the crystalline state.     

Molecular mechanism of intramolecular electron transfer in dimeric sulfite oxidase

Sulfite oxidase (SOX) is a homodimeric molybdoheme enzyme that oxidizes sulfite to sulfate at the molybdenum center. Following substrate oxidation, molybdenum is reduced and subsequently regenerated by two sequential electron transfers (ETs) via heme to cytochrome c. SOX harbors both metals in spatially separated domains within each subunit, suggesting that domain movement is necessary to allow intramolecular ET. To address whether one subunit in a SOX dimer is sufficient for catalysis, we produced heterodimeric SOX variants with abolished sulfite oxidation by replacing the molybdenum-coordinating and essential cysteine in the active site. To further elucidate whether electrons can bifurcate between subunits, we truncated one or both subunits by deleting the heme domain. We generated three SOX heterodimers: (i) SOX/Mo with two active molybdenum centers but one deleted heme domain, (ii) SOX/Mo_C264S with one unmodified and one inactive subunit, and (iii) SOX_C264S/Mo harboring a functional molybdenum center on one subunit and a heme domain on the other subunit. Steady-state kinetics showed 50% SOX activity for the SOX/Mo and SOX/Mo_C264S heterodimers, whereas SOX_C264S/Mo activity was reduced by two orders of magnitude. Rapid reaction kinetics monitoring revealed comparable ET rates in SOX/Mo, SOX/Mo_C264S, and SOX/SOX, whereas in SOX_C264S/Mo, ET was strongly compromised. We also combined a functional SOX Mo domain with an inactive full-length SOX R217W variant and demonstrated interdimer ET that resembled SOX_C264S/Mo activity. Collectively, our results indicate that one functional subunit in SOX is sufficient for catalysis and that electrons derived from either Mo^(IV) or Mo^(V) follow this path.     

Steady-state kinetic mechanism of LodA,a novel cysteine tryptophylquinone-dependent oxidase

LodA is a novel lysine-ε-oxidase which possesses a cysteine tryptophylquinone cofactor. It is the first tryptophylquinone enzyme known to function as an oxidase. A steady-state kinetic analysis shows that LodA obeys a ping-pong kinetic mechanism with values of k_cat of 0.22 ± 0.04 s⁻¹, K_lysine of 3.2 ± 0.5 μM and K_O2 of 37.2 ± 6.1 μM. The k_cat exhibited a pH optimum at 7.5 while k_cat/K_lysine peaked at 7.0 and remained constant to pH 8.5. Alternative electron acceptors could not effectively substitute for O₂ in the reaction. A mechanism for the reductive half reaction of LodA is proposed that is consistent with the ping-pong kinetics.     

Molecular abnormalities of coproporphyrinogen oxidase in patients with hereditary coproporphyria

Genetic defects of coproporphyrinogen oxidase (CPO) lead to hereditary coproporphyria, an inherited autosomal dominant porphyria. The recent cloning of human cDNAs and of the gene encoding CPO permits deducing the primary structure of the CPO protein and elucidating the molecular basis of HC in some families.     

Theoretical study of the catalytic mechanism of catechol oxidase

The mechanism for the oxidation of catechol by catechol oxidase has been studied using B3LYP hybrid density functional theory. On the basis of the X-ray structure of the enzyme, the molecular system investigated includes the first-shell protein ligands of the two metal centers as well as the second-shell ligand Cys92. The cycle starts out with the oxidized, open-shell singlet complex with oxidation states Cu₂(II,II) with a μ-η²:η² bridging peroxide, as suggested experimentally, which is obtained from the oxidation of Cu₂(I,I) by dioxygen. The substrate of each half-reaction is a catechol molecule approaching the dicopper complex: the first half-reaction involves Cu(I) oxidation by peroxide and the second one Cu(II) reduction. The quantitative potential energy profile of the reaction is discussed in connection with experimental data. Since no protons leave or enter the active site during the catalytic cycle, no external base is required. Unlike the previous density functional theory study, the dicopper complex has a charge of +2.     

Roles of the conserved aspartate and arginine in the catalytic mechanism of an archaeal beta-class carbonic anhydrase

The roles of an aspartate and an arginine, which are completely conserved in the active sites of beta-class carbonic anhydrases, were investigated by steady-state kinetic analyses of replacement variants of the beta-class enzyme (Cab) from the archaeon Methanobacterium thermoautotrophicum. Previous kinetic analyses of wild-type Cab indicated a two-step zinc-hydroxide mechanism of catalysis in which the k(cat)/K(m) value depends only on the rate constants for the CO(2) hydration step, whereas k(cat) also depends on rate constants from the proton transfer step (K. S. Smith, N. J. Cosper, C. Stalhandske, R. A. Scott, and J. G. Ferry, J. Bacteriol. 182:6605-6613, 2000). The recently solved crystal structure of Cab shows the presence of a buffer molecule within hydrogen bonding distance of Asp-34, implying a role for this residue in the proton transport step (P. Strop, K. S. Smith, T. M. Iverson, J. G. Ferry, and D. C. Rees, J. Biol. Chem. 276:10299-10305, 2001). The k(cat)/K(m) values of Asp-34 variants were decreased relative to those of the wild type, although not to an extent which supports an essential role for this residue in the CO(2) hydration step. Parallel decreases in k(cat) and k(cat)/K(m) values for the variants precluded any conclusions regarding a role for Asp-34 in the proton transfer step; however, the k(cat) of the D34A variant was chemically rescued by replacement of 2-(N-morpholino)propanesulfonic acid buffer with imidazole at pH 7.2, supporting a role for the conserved aspartate in the proton transfer step. The crystal structure of Cab also shows Arg-36 with two hydrogen bonds to Asp-34. Arg-36 variants had both k(cat) and k(cat)/K(m) values that were decreased at least 250-fold relative to those of the wild type, establishing an essential function for this residue. Imidazole was unable to rescue the k(cat) of the R36A variant; however, partial rescue of the kinetic parameter was obtained with guanidine-HCl indicating that the guanido group of this residue is important.     

D-amino acid oxidase: structure,catalytic mechanism,and practical application

D-Amino acid oxidase (DAAO) is a FAD-dependent enzyme that plays an important role in microbial metabolism, utilization of endogenous D-amino acids, regulation of the nervous system, and aging in mammals. DAAO from yeasts Rhodotorula gracilis and Trigonopsis variabilis are used to convert cephalosporin C into 7-aminocephalosporanic acid, the precursor of other semi-synthetic cephalosporins. This review summarizes the recent data on the enzyme localization, physiological role, gene cloning and expression, and the studies on the enzyme structure, stability, catalytic mechanism, and practical applications.Translated from Biokhimiya, Vol. 70, No. 1, 2005, pp. 51–67.Original Russian Text Copyright © 2005 by Tishkov, Khoronenkova.     

Structure and mechanism of galactose oxidase: catalytic role of tyrosine 495

 The catalytic mechanism of the copper-containing enzyme galactose oxidase involves a protein radical on Tyr272, one of the equatorial copper ligands. The first step in this mechanism has been proposed to be the abstraction of a proton from the alcohol substrate by Tyr495, the axial copper ligand that is weakly co-ordinated to copper. In this study we have generated and studied the properties of a Y495F variant to test this proposal. X-ray crystallography reveals essentially no change from wild-type other than loss of the tyrosyl hydroxyl group. Visible spectroscopy indicates a significant change in the oxidised Y495F compared to wild-type with loss of a broad 810-nm peak, supporting the suggestion that this feature is due to inter-ligand charge transfer via the copper. The presence of a peak at 420 nm indicates that the Y495F variant remains capable of radical formation, a fact supported by EPR measurements. Thus the significantly reduced catalytic efficiency (1100-fold lower k _cat / K _m) observed for this variant is not due to an inability to generate the Tyr272 radical. By studying azide-induced pH changes, it is clear that the reduced catalytic efficiency is due mainly to the inability of Y495F to accept protons. This provides definitive evidence for the key role of Tyr495 in the initial proton abstraction step of the galactose oxidase catalytic mechanism. Received: 17 December 1996 / Accepted: 12 March 1997     

Crystal structure of the catalytic trimer of Methanococcus jannaschii aspartate transcarbamoylase

The catalytic trimer of Methanococcus jannaschii aspartate transcarbamoylase is extremely heat stable, maintaining 75% of its activity after heat treatment for 60 min at 75 degrees C. We undertook its structural analysis in order to understand the molecular basis of its thermostability and gain insight on how its catalytic function adapts to high temperature. Several structural elements potentially contributing to thermostability were identified. These include: (i) changes in the amino acid composition such as a decrease in the thermolabile residues Gln and Asn, an increase in the charged residues Lys and Glu, an increase in Tyr and a decrease in Ala residues; (ii) a larger number of salt bridges, in particular, the improvement of ion-pair networks; (iii) shortening of the N-terminus and shortening of three loops. An interesting feature of the crystal structure is the association of two crystallographically independent catalytic subunits into a staggered complex with an intertrimer distance of 33.8 A. The active site appears similar to Escherichia coli. Upon substrate binding, smaller changes in the global orientation of domains and larger conformational changes of the active site residues are expected as compared to E. coli.     

M42 aminopeptidase catalytic site: the structural and functional role of a strictly conserved aspartate residue

The M42 aminopeptidases are a family of dinuclear aminopeptidases widely distributed in Prokaryotes. They are potentially associated to the proteasome, achieving complete peptide destruction. Their most peculiar characteristic is their quaternary structure, a tetrahedron-shaped particle made of twelve subunits. The catalytic site of M42 aminopeptidases is defined by seven conserved residues. Five of them are involved in metal ion binding which is important to maintain both the activity and the oligomeric state. The sixth conserved residue, a glutamate, is the catalytic base deprotonating the water molecule during peptide bond hydrolysis. The seventh residue is an aspartate whose function remains poorly understood. This aspartate residue, however, must have a critical role as it is strictly conserved in all MH clan enzymes. It forms some kind of catalytic triad with the histidine residue and the metal ion of the M2 binding site. We assess its role in TmPep1050, an M42 aminopeptidase of Thermotoga maritima, through a mutational approach. Asp-62 was substituted with alanine, asparagine, or glutamate residue. The Asp-62 substitutions completely abolished TmPep1050 activity and impeded dodecamer formation. They also interfered with metal ion binding as only one cobalt ion is bound per subunit instead of two. The structure of Asp62Ala variant was solved at 1.5 Å showing how the substitution has an impact on the active site fold. We propose a structural role for Asp-62, helping to stabilize a crucial loop in the active site and to position correctly the catalytic base and a metal ion ligand of the M1 site.     

The enzyme pseudooxynicotine amine oxidase from Pseudomonas putida S16 is not an oxidase,but a dehydrogenase

The soil-dwelling bacterium Pseudomonas putida S16 can survive on nicotine as its sole carbon and nitrogen source. The enzymes nicotine oxidoreductase (NicA2) and pseudooxynicotine amine oxidase (Pnao), both members of the flavin-containing amine oxidase family, catalyze the first two steps in the nicotine catabolism pathway. Our laboratory has previously shown that, contrary to other members of its enzyme family, NicA2 is actually a dehydrogenase that uses a cytochrome c protein (CycN) as its electron acceptor. The natural electron acceptor for Pnao is unknown; however, within the P. putida S16 genome, pnao forms an operon with cycN and nicA2, leading us to hypothesize that Pnao may also be a dehydrogenase that uses CycN as its electron acceptor. Here we characterized the kinetic properties of Pnao and show that Pnao is poorly oxidized by O₂, but can be rapidly oxidized by CycN, indicating that Pnao indeed acts as a dehydrogenase that uses CycN as its oxidant. Comparing steady-state kinetics with transient kinetic experiments revealed that product release primarily limits turnover by Pnao. We also resolved the crystal structure of Pnao at 2.60 Å, which shows that Pnao has a similar structural fold as NicA2. Furthermore, rigid-body docking of the structure of CycN with Pnao and NicA2 identified a potential conserved binding site for CycN on these two enzymes. Taken together, our results demonstrate that although Pnao and NicA2 show a high degree of similarity to flavin containing amine oxidases that use dioxygen directly, both enzymes are actually dehydrogenases.     

Insight into the catalytic mechanism of arginine deiminase: functional studies on the crucial sites

Arginine deiminase (ADI) catalyzes the irreversible hydrolysis of arginine to citrulline and ammonia. It belongs to a newly classified superfamily of guanidino-group-modifying enzymes. Located in the catalytic center of Mycoplasma hominis ADI, some crucial sites (Asp160, Glu212, His268, and Asp270) are highly conserved among these enzymes. Here, we constructed five ADI single mutants D160E, E212D, H268F, H268Y, and D270E, and three double mutants D160E/D270E, D160E/E212D, and E212D/D270E, aiming to evaluate the contributions of these crucial residues to the structure, stability, and enzymatic activity of ADI, and to elucidate their roles in the catalytic process of this family of enzymes. Tryptophan emission fluorescence and circular dichroism were used to analyze the different effects of mutagenesis on these conserved residues on the secondary and tertiary structures of ADI. Urea-induced unfolding and trypsin digestion were applied to measure their stabilities against denaturants and proteases, respectively. Additionally, the enzymatic activities of ADI and its mutants were measured. Here, we report that all the mutations have little effect on the native structure of ADI. However, the substitutions on these crucial sites still interfere with the stability of ADI to different degrees. As these mutations impair both the substrate binding and the substrate induced conformational changes of ADI to different extents, most of the mutants except D160E (preserves about 30% of the enzymatic activity of wild type) have totally lost the enzymatic activity in the hydrolysis of arginine and the inhibitory ability on the proliferation of mouse melanoma cells.     

Oxygen pressurized X-ray crystallography: probing the dioxygen binding site in cofactorless urate oxidase and implications for its catalytic mechanism

The localization of dioxygen sites in oxygen-binding proteins is a nontrivial experimental task and is often suggested through indirect methods such as using xenon or halide anions as oxygen probes. In this study, a straightforward method based on x-ray crystallography under high pressure of pure oxygen has been developed. An application is given on urate oxidase (UOX), a cofactorless enzyme that catalyzes the oxidation of uric acid to 5-hydroxyisourate in the presence of dioxygen. UOX crystals in complex with a competitive inhibitor of its natural substrate are submitted to an increasing pressure of 1.0, 2.5, or 4.0 MPa of gaseous oxygen. The results clearly show that dioxygen binds within the active site at a location where a water molecule is usually observed but does not bind in the already characterized specific hydrophobic pocket of xenon. Moreover, crystallizing UOX in the presence of a large excess of chloride (NaCl) shows that one chloride ion goes at the same location as the oxygen. The dioxygen hydrophilic environment (an asparagine, a histidine, and a threonine residues), its absence within the xenon binding site, and its location identical to a water molecule or a chloride ion suggest that the dioxygen site is mainly polar. The implication of the dioxygen location on the mechanism is discussed with respect to the experimentally suggested transient intermediates during the reaction cascade.     

微生物法生产丙烯酰胺的研究（Ⅱ）—腈水合酶催化反应动力学与失活动力学

在以丙烯腈为原料 ,微生物转化生产丙烯酰胺的过程中 ,酶催化反应是过程的关键。为了了解酶催化的动力学 ,本研究以自由细胞的酶为催化剂 ,进行了腈水合酶的反应动力学和失活动力学的研究。首先研究了菌体浓度、温度、pH值、丙烯腈浓度、丙烯酰胺浓度等对腈水合酶催化反应速度的影响。结果表明 ,在这些因素中 ,温度和丙烯酰胺浓度是最主要的影响因素。 2 8℃时酶活为 5 6 5 9u mL(菌液 ) ,在 5℃时的反应速率仅为 2 8℃时的11 72 % ,相应的表观酶活为 6 6 3u mL(菌液 )。而在丙烯酰胺 45 %浓度条件下的酶活大约只有丙烯酰胺 5 %浓度下的酶活的 1 2。经过对不同温度下的反应速度的研究 ,得到腈水合酶水合反应的活化能为 6 5 5 7kJ·mol- 1 。本文进一步研究了自由细胞状态下 ,菌体浓度、pH值、温度、丙烯腈浓度、丙烯酰胺浓度对腈水合酶失活的影响 ,得到了失活动力学。结果表明 ,在这些因素中 ,对酶失活影响的最主要因素还是温度和丙烯酰胺浓度。尤其当丙烯酰胺浓度到达 35 %时 ,酶活下降得很快 ,在 5 5h后 ,酶活几乎为零。而在丙烯酰胺浓度为 10 %的情况下 ,5 5h的酶活仍然还存在约 5 0 %。试验结果还表明 ,丙烯腈对酶的稳定性的影响很小。经过数据处理 ,得到的 2 8℃的酶失活速率常数为 5℃下的 2 1 7     

Role of aspartate aminotransferase and mitochondrial dicarboxylate transport for release of endogenously and exogenously supplied neurotransmitter in glutamatergic neurons

Evoked release of glutamate and aspartate from cultured cerebellar granule cells was studied after preincubation of the cells in tissue culture medium with glucose (6.5 mM), glutamine (1.0 mM),d[³H] aspartate and in some cases aminooxyacetate (5.0 mM) or phenylsuccinate (5.0 mM). The release of endogenous amino acids and ofd-[³H] aspartate was measured under physiological and depolarizing (56 mM KCl) conditions both in the presence and absence of calcium (1.0 mM), glutamine (1.0 mM), aminooxyacetate (5.0 mM) and phenylsuccinate (5.0 mM). The cellular content of glutamate and aspartate was also determined. Of the endogenous amino acids only glutamate was released in a transmitter fashion and newly synthesized glutamate was released preferentially to exogenously suppliedd-[³H] aspartate, a marker for exogenous glutamate. Evoked release of endogenous glutamate was reduced or completely abolished by respectively, aminooxyacetate and phenylsuccinate. In contrast, the release ofd-[³H] aspartate was increased reflecting an unaffected release of exogenous glutamate and an increased psuedospecific radioactivity of the glutamate transmitter pool. Since aminooxyacetate and phenylsuccinate inhibit respectively aspartate aminotransferase and mitochondrial keto-dicarboxylic acid transport it is concluded that replenishment of the glutamate transmitter pool from glutamine, formed in the mitochondrial compartment by the action of glutaminase requires the simultaneous operation of mitochondrial keto-dicarboxylic acid transport and aspartate aminotransferase which is localized both intra- and extra-mitochondrially. The purpose of the latter enzyme apparently is to catalyze both intra- and extra-mitochondrial transamination of -ketoglutarate which is formed intramitochondrially from the glutamate carbon skeleton and transferred across the mitochondrial membrane to the cytosol where transmitter glutamate is formed. This cytoplasmic origin of transmitter glutamate is in aggreement with the finding thatd-[³H] aspartate readily labels the transmitter pool even when synthesis of endogenous transmitter is impaired in the presence of AOAA or phenylsuccinate.Special issue dedicated to Dr Elling Kvamme     

Redesign of the substrate specificity of Escherichia coli aspartate aminotransferase to that of Escherichia coli tyrosine aminotransferase by homology modeling and site-directed mutagenesis.

Although several high-resolution X-ray crystallographic structures have been determined for Escherichia coli aspartate aminotransferase (eAATase), efforts to crystallize E. coli tyrosine aminotransferase (eTATase) have been unsuccessful. Sequence alignment analyses of eTATase and eAATase show 43% sequence identity and 72% sequence similarity, allowing for conservative substitutions. The high similarity of the two sequences indicates that both enzymes must have similar secondary and tertiary structures. Six active site residues of eAATase were targeted by homology modeling as being important for aromatic amino acid reactivity with eTATase. Two of these positions (Thr 109 and Asn 297) are invariant in all known aspartate aminotransferase enzymes, but differ in eTATase (Ser 109 and Ser 297). The other four positions (Val 39, Lys 41, Thr 47, and Asn 69) line the active site pocket of eAATase and are replaced by amino acids with more hydrophobic side chains in eTATase (Leu 39, Tyr 41, Ile 47, and Leu 69). These six positions in eAATase were mutated by site-directed mutagenesis to the corresponding amino acids found in eTATase in an attempt to redesign the substrate specificity of eAATase to that of eTATase. Five combinations of the individual mutations were obtained from mutagenesis reactions. The redesigned eAATase mutant containing all six mutations (Hex) displays second-order rate constants for the transamination of aspartate and phenylalanine that are within an order of magnitude of those observed for eTATase. Thus, the reactivity of eAATase with phenylalanine was increased by over three orders of magnitude without sacrificing the high transamination activity with aspartate observed for both enzymes.(ABSTRACT TRUNCATED AT 250 WORDS)