Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: EC:1.1.1.3 (HSD)
 3,464 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

(1) An unusual accumulation of S-adenosyl-L-methionine in Chromatium D was associated with a marked growth inhibition by L-methionine. The inhibition was overcome by L-isoleucine, L-leucine, L-phyenylalanine, L-threonine, L-valine and putrescien. Based on their effects, these compounds are classified into 3 types. (2) L-Isoleucine, L-leucine, L-phyenylalanine and L-valine (Type I) inhibited the L-methionine uptake and consequently prevented the bacterium from the unusual accumulation of S-adenosyl-L-methionine even in the presence of L-methionine in the medium. Putrescine (Type II) stimulated the consumption of S-adenosyl-L-methionine, but did not influence the L-methionine uptake. Hence, the effect of putrescine would be explained by the action to diminish the intracellular level of S-adenosyl-L-methionine. L-Threonine (Type III) neither inhibited the L-methionine uptake nor affected the content of S-adenoxyl-L-methionine due to the addition of L-methionine. (3) The specific activity of homoserine kinase (EC 2.7.1.39) was greatly lowered by the addition of L-methionine under conditions in which Chromatium D unusually accumulates S-adenoxyl-L-methionine. Homoserine dehydrogenase (EC 1.1.1.3) activity was inhbitied by S-adenosyl-L-methionine (50% inhibition index, 3.5 mM). These facts strongly suggest that the growth inhibition by L-methionine is associated with the L-threonine deficiency caused by the unusual accumulation of S-adenosyl-L-methionine.
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PMID:Mechanism of inhibition of Chromatium D growth by L-methionine. Regulation of L-threonine biosynthesis by the intracellular level of S-adenosylmethionine. 0 2

Both activities of the aspartokinase--homoserine I (AK-HSD) of Escherichia coli are inhibited by threonine. Careful threonine binding studies have now been done which have allowed us to distinguish the various effects of threonine on the enzyme. The ultrafiltration technique of H. Paulus ((1969) Anal. Biochem. 32, 101) for measuring ligand binding was shown to be comparable with equilibrium dialysis techniques. Reduction in error by utilization of this procedure enabled us to obtain evidence for two different sets of threonine sites by direct binding studies. The binding data were mathematically consistent with two independent classes of threonine sites, each of which contained four sites per tetramer and had a Hill coefficient of about 2.3--2.5. KD for the second set of sites was five- to tenfold greater than the high affinity sites, depending upon conditions. The data now suggest that the sequential model for site--site interactions adequately describes the cooperativity of threonine binding to the high affinity set of sites.
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PMID:Threonine inhibition of the aspartokinase--homoserine dehydrogenase I of Escherichia coli. Threonine binding studies. 2 50

In the presence of l-threonine, the allosteric effector, most of the antigenic determinants situated in the aspartokinase region of the wild-type enzyme become unavailable to the antibodies raised against a fragment of the enzyme containing this region and devoid of homoserine dehydrogenase activity. The cross-reactivities of the antibodies raised against this fragment (extracted from a nonsense mutant) and a fragment endowed with homoserine dehydrogenase activity but devoid of aspartokinase activity (obtained by limited proteolysis) with the corresponding antigens were studied. The conclusion is drawn that the two fragments, which share an overlapping sequence of molecular weight about 17,000, share at least two antigenic determinants.
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PMID:The threonine-sensitive homoserine dehydrogenase and aspartokinase activities of Escherichia coli K12. Distribution and accessibility to antibodies of some epitopes of the bifunctional enzyme. 4 8

In Escherichia coli K12 the biosynthetic pathway of lysine, methionine and threonine is characterized by three isofunctional aspartokinases and two homoserine dehydrogenases. A single polypeptide chain carries the threonine-sensitive aspartokinase and homoserine dehydrogenase (AK I-HDH I), and a different polypeptide chain carries the methionine-repressible aspartokinase and homoserine dehydrogenase (AK II-HDH II). Immuno-adsorbants prepared with rabbit antibodies against AK I-HDH I bind the lysine-sensitive aspartokinase (AK III), the AK II-HDH II, and the homoserine kinase (HSK), an enzyme of the threonine biosynthetic pathway. Saturation of the immunoadsorbant with AK I-HDH I results in a decreased binding capacity for the other enzymes. Displacement of bound AK III or HSK can be obtained with pure AK I-HDH I, showing that the affinity of the antibodies to homologous antigens is higher than to heterologous ones. Immunoadsorbants prepared with anti-HSK antibodies show the same type of recognition: binding of the three aspartkinases and a capacity to displace the heterologous antigens bound. Accordingly, the same antibodies, implicated in the binding of the homologous antigen, bind the other enzymes. None of the other enzymes of the pathway, or the other kinases tested are recognized by the two immunoadsorbants. It can be postulated that in E. coli K12, duplication of a common ancestor gene gave rise to the three aspartokinases and to the homoserine kinase; two of the genes coding for the aspartokinases fused with those coding for the homoserine dehydrogenases. Indicating that only few epitopes are shared by these enzymes, by conventional immuno-diffusion techniques no precipitation lines appeared with antibodies against AK I-HDH I and the other proteins.
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PMID:Immunological cross reactivity of four enzymes involved in the biosynthetic pathway of lysine, methionine and threonine in Escherichia coli K12. 6 12

The dehydrogenase activity of the aspartokinase I-homoserine dehydrogenase I complex isolated from Escherichia coli K12 is subject to a cooperative activation by K+ or Rb+, which is characterized by a Hill coefficient of approximately 2. Ionic strength has little effect on the Hill coefficient for this activation process; however, high ionic strength appears to increase the enzyme's affinity for K+ and decrease its affinity for Rb+. The Vmax of the K+-activated dehydrogenase is greater than that of the Rb+-activated dehydrogenase. The results of a study of the competition between K+ and Rb+ in the activation process suggest the presence of an activated species containing both K+ and Rb+. The cooperative activation by K+ is antagonized by Na+ via a process that is noncooperative with respect to Na+. The MgATP-2- complex, a substrate for the kinase activity of aspartokinase I-homoserine dehydrogenase I, has a marked effect on the K+ activation of the dehydrogenase activity. Kinetic studies of this effect of MgATP-2- on the K+ requirement of the dehydrogenase at pH 8.9 indicate that: (a) activation by a monovalent cation is essential in the presence as well as in the absence of MgATP-2-; (b) the concentration of K+ required to activate fully the dehydrogenase is reduced in the presence of MgATP-2-; (c) activation of the dehydrogenase by K+ is noncooperative in the presence of MgATP-2-; and (d) the maximum velocity for the dehydrogenase catalyzed oxidation of homoserine is greater in the presence of MgATP-2- than in its absence. Based on these results, a simple model consistent with these data is proposed. Destruction of the kinase activity and the threonine sensitivity of the aspartokinase-homoserine dehydrogenase complex by treatment with 5,5'-dithiobis(2-nitrobenzoic acid) or by incubation at pH 9 also converts the K+ activation of the dehydrogenase from a cooperative to a noncooperative process. Marked protection of the enzyme against loss of threonine sensitivity at pH 9 is afforded by MgATP-2- plus K+ and homoserine. The apparent molecular radius of the enzyme complex as determined by gel filtration at pH 8.85 in the presence of threonine or MgATP-2- plus K+ and homoserine is dependent on the enzyme concentration. The observed apparent molecular radii of 70 A at high enzyme concentrations and 61 A at low enzyme concentrations are consistent with the enzyme's undergoing a concentration-dependent dissociation from a tetrameric to a dimeri
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PMID:Aspartokinase I-homoserine dehydrogenase I of Escherichia coli K12 (lambda). Activation by monovalent cations and an analysis of the effect of the adenosine triphosphate-magnesium ion complex on this activation process. 16 50

Six enzymes involved in the conversion of aspartate to threonine have been extracted from Escherichia coli and separated from each other. Two of these enzymes, aspartokinase and homoserine dehydrogenase, have also been partially purified from Rhodopseudomonas spheroides. In an attempt to determine whether small changes in the kinetic properties of individual enzymes are important to the regulation of metabolic flux through a coupled reaction system, the partially purified enzymes were recombined in a variety of ways under reaction conditions designed to resemble the in vivo situation. These conditions include: use of an entire metabolic system rather than a single reaction; high enzyme concentrations at the same relative concentrations as found in the cell; and low, steady-state concentrations of substrates and products. Metabolic flux was followed spectrophotometrically and the concentrations of aspartic semialdehyde, hemoserine, O-phosphohomoserine, and threonine were measured. The results indicate that the threonine concentration is of major importance in regulating metabolic flux by inhibiting aspartokinase, the first reaction in threonine in the pathway. When threonine-insensitive aspartokinases were used, concentrations reached higher levels and the rate of NADPH oxidation remained higher. The fact that neither aspartic semialdehyde nor homoserine accumulated as the threonine concentration increased and the lack of correlation between changes in metabolic flux and ADP/ATP or NADPH/NADP ratios indicate that more subtle forms of metabolic regulation, such as "reverse cascade", secondary feedback sites, or "energy charge", are of little regulatory importance in this isolated, metabolic system. The results also emphasize the need for caution in projecting in vivo control mechanisms from in vitro experiments.
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PMID:Regulation of a metabolic system in vitro: synthesis of threonine from aspartic acid. 17 64

The kinase active site of the aspartokinase-homoserine dehydrogenase enzyme complex of Excherichia coli has been affinity labeled both with substrates aspartate and adenosine triphosphate and feedback inhibitor threonine. Co(III) exchange-inert adducts of aspartokinase and inhibitor or substrates were produced in situ by oxidation of Co(II) with H2O2. Emzyme-Co(III)-adenosine 5'-triphosphate (ATP), enzyme-Co(III)-aspartate, and enzyme-Co(III)-threonine ternary adducts were produced in this manner. The formation of the enzyme-Co(III)-threonine adduct leads us to conclude that threonine inhibits the kinase activity of this enzyme complex by binding in the first coordination sphere of the catalytic metal ion cofactor, a conclusion which is consistent with evidence derived from previous nuclear magnetic resonance data obtained in this laboratory. The quaternary adducts formed by H2O2 oxidation in the presence of aspartokinase, Co(II), ATP, aspartate, and threonine comprised a mixture of both ezyme-Co(III)-ATP-aspartate and enzyme-Co(III)-ATP-threonine adducts. The formation of the quaternary aspartate-containing adduct was unexpected, since the presence of threonine was expected to prevent access of the aspartate to the active site; most significantly however, the the sum of the numbers of aspartate plus threonine molecules incorporated per active site is one. We believe that this shows direct steric overlap between the metal-adjacent binding sites for aspartate and threonine. Aspartate or threonine can not occupy the kinase active site simultaneously; this conclusion is consistent with the direct competitive inhibition of aspartate by threonine observed in steady-state kinetic studies.
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PMID:Cobalt(III) affinity-labeled aspartokinase. Formation of substrate and inhibitor adducts. 18 15

The nature of the feedback inhibition of the bifunctional enzyme, aspartokinase I-homoserine dehydrogenase I of Escherichia coli was studied using 13C nuclear magnetic resonance (NMR). Since aspartokinase is activated by Mn(II), the interaction of the inhibitor L-threonine (specifically enriched to 90% 13C in the carboxyl carbon) with the metal-enzyme complex was studied. Spin-lattice (T1) and spin-spin (T2) relaxation times were determined by the partially relaxed Fourier transform method and line-width measurements respectively at 20 MHz. The pronounced broadening of the DL-threonine carboxyl peak in the presence of the Mn(II)-enzyme complex indicates that an L-threonine binding site is close to the metal binding site of the kinase active site. The non-identity of (T1)*M and (T2)*M indicates that conditions of fast exchange prevail. The (T1)*M/(T2)*M ratio was used to estimate a correlation time of 2.0 ns for the dipolar interaction at 25 degrees C. An estimate for the distance between Mn(II) and the threonine carboxyl carbon of 4.4 A (0.44 nm) was obtained. This 13C NMR study has thus located one of the two classes of threonine regulatory sites which exist per subunit; the threonine site identified here is at the aspartokinase active site, adjacent to the catalytic metal site.
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PMID:Nuclear-magnetic-relaxation studies of the interaction of inhibitor with the threonine-sensitive aspartokinase of Escherichia coli. 18 63

The aspartokinase activity of the aspartokinase-homoserine dehydrogenase complex of Escherichia coli was affinity labeled with substrates ATP, aspartate, and feedback inhibitor threonine. Exchange-inert ternary adducts of Co(III)-aspartokinase and either ATP, aspartate or threonine were formed by oxidation of corresponding Co(II) ternary complexes with H2O2. The ternary enzyme-Co(III)-threonine adduct (I) had 3.8 threonine binding sites per tetramer, one-half that of the native enzyme. The binding of threonine to I was still cooperative as determined by equilibrium dialysis (nH = 2.2) or by studying inhibition of residual dehydrogenase activity (nH = 2.7). Threonine still protected the SH groups of I against 5,5'-dithiobis(2-nitrobenzoate) (DTNB) reaction but the number of SH groups reacting with thiol reagents (DTNB) was reduced by 1-2 per subunit in the absence of threonine. This suggests either that Co(III) is bound to the enzyme via sulfhydryl groups or that 1-2SH groups are buried or rendered inaccessible in I. The binding of threonine to sites not blocked by the affinity labeling produced changes in the circular dichroism of the complex comparable to changes produced by threonine binding to native enzyme and also protected against proteolytic digestion. The major conformational changes produced by threonine are thus ascribable to binding at this one class of regulatory sites. The interactions of kinase substrates with various aspartokinase-Co(III) complexes containing ATP, aspartate, or threonine and a threonine-insensitive homoserine dehydrogenase produced by mild proteolysis were studied. The inhibition of homoserine dehydrogenase by kinase substrates is not due to binding of these inhibitors at the kinase active site but was shown to be due to binding to sites within the dehydrogenase domain of the enzyme. L-alpha-Aminobutyrate, a presumed threonine analogue, also inhibits the dehydrogenase by binding at the same or similar sites in the dehydrogenase domain and not at threonine regulatory site.
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PMID:Interaction of substrates and inhibitors with the homoserine dehydrogenase of kinase-inactivated aspartokinase I. 19 65

The distance between aspartokinase and homoserine dehydrogenase active sites was determined using fluorescence energy transfer between modified substrates. The fluorescent 1,N(6)-ethenoadenosine 5'-triphosphate was bound at the kinase active site by Co(III) affinity labeling. Reduced thionicotinamide adenine dinucleotide phosphate quenched the fluorescence of bound nucleotide. Fluorescence depolarization measurements led to a delimitation of the value of the dipolar orientation factor to the range 0.3 to 2.8. The distance between the fluorescent probe and the quencher was 29 +/- 4 A. In the presence of threonine, this distance increased to 36 +/- 5 A. Threonine binding either increased the intersite distance by ca. 7 A or caused a reorientation of the probe at the dehydrogenase site.
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PMID:Fluorescence energy transfer between heterologous active sites of affinity-labeled aspartokinase of Escherichia coli. 19 66


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