UMLS:C0027960 - FACTA Search

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Query: UMLS:C0027960 (mole)
21,279 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The dihydrofolate synthetase (EC 6.3.2.12) responsible for catalyzing the synthesis of dihydrofolic acid from dihydropteroic acid and L-glutamic acid was purified about 130-fold from extracts of Serratia indica IFO 3759 by ammonium sulfate fractionation, DEAE-Sephadex column chromatography, Sephadex G-200 gel filtration, and DEAE-cellulose column chromatography. The enzyme preparation obtained was shown to be homogeneous by DEAE-cellulose column chromatography and ultracentrifugal analysis. The sedimentation coefficient of this enzyme was 3.9 S, and the molecular weight was determined to be about 47,000 by Sephadex G-100. The optimum pH for the reaction was 9.0. The enzymatic reaction required dihydropteroate, L-glutamate and ATP as substrates, and Mg2+ and K+ as cofactors. gamma-L-Glutamyl-L-glutamic acid cannot replace L-glutamic acid as the substrate. Neither pteroic acid nor tetrahydropteroic acid can be used as the substrate. ATP was partially replaced by ITP or GTP. The enzyme reaction was inhibited by the addition of AD, but not by AMP. One mole of dihydrofolate, 1 mole of ADP and 1 mole of orthophosphate were produced from each 1 mole of dihydropteroic acid, L-glutamic acid, and ATP by the following equation: 7,8-Dihydropteroic acid ml-Glutamic acid matp Mg2+, K+ leads to Dihydrofolic acid + ADP + Pi. These results suggest that the systematic name for the dihydrofolate synthetase is 7,8-dihydropteroate: L-glutamate ligase (ADP).
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PMID:Purification and properties of the dihydrofolate synthetase from Serratia indica. 0 96

1. The bound nucleotides of the beef-heart mitochondrial ATPase (F1) are lost during cold inactivation followed by (NH4)2SO4 precipitation. The release of tightly bound ATP parallels the loss of ATPase activity during this process. 2. During cold inactivation, the sedimentation coefficient (s20, w) of the ATPase first declines from 12.1 S to 9 S, then to 3.5 S. (NH4)2SO4 precipitation of the 9-S component also leads to dissociation into subunits with s20, w of 3.5 S. 3. The 9-S component still contains the bound nucleotides, which are removed when it dissociated into smaller subunits. 4. Reactivation of cold-inactivated ATPase by incubation at 30 degrees C is increased by the presence of 25% glycerol. ATP, however, does not have any clearcut effect on the degree of reactivation in the presence of glycerol. 5. ADP is an inhibitor of the reactivation, probably because it exchanges during reactivation for bound ATP giving rise to an inactive 12-S component. 6. The exchange of tightly bound nucleotides with added adenine nucleotides is more extensive and faster with cold-inactivated ATPase than with the native enzyme. During reactivation up to 1.6 moles of ATP and 1.0 mole ADP can exchange per mole enzyme. 7. Incubation with GTP, CTP or inorganic pyrophosphate induces an increased activity of the ATPase, which, however, soon declines in the presence of ATP. It also disappears on precipitation of GTP-treated enzyme with (NH4)2SO4.
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PMID:Nucleotide-binding properties of native and cold-treated mitochondrial ATPase. 12 64

About 10--20% of the total protein in the outer fiber fraction was solubilized by sonication in a solution containing 5 mM MES, 0.5 mM MgSO4, 1.0 mM EGTA, 1.0 mM GTP, and 0 or 50 mM KC1 at pH 6.7. The sonicated extract was shown by analytical centrifugation to consist largely of a 6 S component (tubulin dimer), having a molecular weight of 103,000, as determined by gel filtration, and possessing a colchicine-binding activity of 0.8 mole per tubulin dimer. The tubulin fraction failed to polymerize into microtubules by itself. Addition of a small amount of the ciliary outer fiber fragments or reconstituted short brain microtubules, however, induced polymerization, as demonstrated by viscosity of flow birefringence changes as well as light or electron microscopic observations. The growth of heterogeneous microtubules upon mixing outer fiber tubulin with DEAE-dextran-decorated brain microtubules was observed by electron microscopy. Microtubules were reconstituted from outer fiber tubulin without addition of any nuclei fraction when a concentrated tubulin fraction was warmed at 35degree. A few doublet-like microtubules or pairs of parallel singlet microtubules that were closely aligned longitudinally could be observed among many singlet microtubules. Unlike other fiber microtubules, the reconstituted polymers were depolymerized by exposure to Ca2+ ions, high or low ionic strength, colchicine, low temperature or SH reagents. No microtubules were assembled under these conditions.
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PMID:In vitro polymerization of flagellar and ciliary outer fiber tubulin into microtubules. 18 79

Guanine nucleotides bound to both the non-exchangeable sites (N sites) and exchangeable sites (E sites) of tubulin were completely released after 7 moles of SH groups per tubulin subunit (55,000 molecular weight) had reacted with PCMPS. The blockage of 2 moles of SH groups in the glycerol-reassembly buffer or 1 mole of SH groups in glycerol-free reassembly buffer resulted in complete loss of tubulin polymerizability. However, under both sets of experimental conditions, the amount of guanine nucleotides released from the E sites was less than 8% and the loss of total guanine nucleotides was only 5%. Addition of GSH did not induce reassociation of released guanine nucleotides, although it restored tubulin polymerizability. These results indicate that the loss of tubulin polymerizability on blockage of the SH groups was not due to dissociation of bound guanine nucleotides and that the binding sites of the nucleotides were independent of the SH groups in tubulin required for polymerization. Furthermore, blockage of SH groups did not change the ratio of GTP to GDP bound to tubulin.
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PMID:Relationship between tubulin SH groups and bound guanine nucleotides. 19 41

Microtubule formation from lamb brain tubulin isolated by affinity chromatography and freed of exchangeable nucleotide requires GTP for maximal rate and extent of polymerization. The nucleotide analogs guanylylmethylenediphosphate and guanylylimidodiphosphate fail to replace GTP; in addition, neither the presence of microtubule associated proteins nor 5 M glycerol relieves the GTP requirement. The relation of GTP concentration and microtubule formation shows an association constant K = 1 X 10(4) M-1; furthermore, GDP and guanylylimidodiphosphate are competitive inhibitors of GTP for polymerization. Using a rapid filter assay for microtubule formation that allows the quantitative analysis of early polymerization kinetics and correcting for GTP hydrolysis uncoupled from tubulin polymerization, a stoichiometry of two molecules of GTP hydrolyzed per mole of tubulin dimer incorporated into microtubules has been found.
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PMID:Stoichiometry of GTP hydrolysis and tubulin polymerization. 19 10

Radioactively labeled tubulin from Chinese hamster ovary (CHO) cells can be isolated by co-polymerization with nonradioactive porcine brain microtubule protein. 75% of the soluble tubulin in CHO extracts co-polymerizes with the porcine protein through several cycles, without preferential loss of either CHO or porcine subunits. After phosphocellulose chromatography of the co-polymerized microtubules, the CHO tubulin is radiochemically homogeneous, as judged by SDS-polyacrylamide gel electrophoresis. CHO tubulin purified in this way has 1 mole of nucleotide per mole of protein noncovalently bound at the non-exchangeable or N site. This-layer chromatography indicates that the N site nucleotide is entirely ribo-GTP. Label and chase experiments show that the N site GTP exchanges intracellularly with a half-time of 33 hr in growing cells which have a generation time of 17 hr, while the tubulin polypeptides are degraded with a half-time of 48 hr. Intracellular hydrolysis of the gamma-phosphate of the N site nucleotide can be detected but occurs very slowly, with a half-time of 24 hr. These results suggest that the N site nucleotide may function in vivo as a stable structural co-factor of the tubulin molecule and render improbable the possibility that it has a regulatory role in microtubule assembly.
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PMID:Turnover of tubulin and the N site GTP in Chinese hamster ovary cells. 56 16

A method is given for preparing tubulin with 1 mol of exchangeably bound [gamma-32P]GTP/mol of 6 S dimer. Bovine tubulin is shown to hydrolyze 1 mol of GTP/mol of 6 S dimer added to assembling microtubules at 37 degrees. Hydrolysis and assembly occur at the same rate and to the same extent. When microtubule-associated proteins (MAPs) are removed, both hydrolysis and assembly fail to occur. Readdition of the MAPs restores both activities. Tubulin with exchangeable GDP will co-assemble with GTP.tubulin even at equimolar levels. Exchangeability is demonstrated by pulse-chase experiments with GDP or GTP. GDP is also a potent inhibitor of assembly under these conditions, and the rate of assembly is reduced by 50% at 10 micron GDP. One mole of inorganic phosphate is released to the solvent per mole of exchangeable GTP hydrolyzed. An assembly mechanism is proposed in which exchangeable GTP is hydrolyzed without intermediate transphosphorylation of nonexchangeable GDP.
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PMID:Stoichiometry and role of GTP hydrolysis in bovine neurotubule assembly. 65 41

The interaction of the pyruvate dehydrogenase multienzyme complex from Escherichia coli with 8-anilino-1-naphthalenesulfonate (ANS), pyruvate, and acetyl-CoA has been investigated using equilibrium binding, steady-state fluorescence, and fluorescence lifetime measurements. The fluorescnece of ANS is greatly enhanced when bound to the enzyme complex and to the pyruvate dehydrogenase component of the complex. Approximately 22 molecules of ANS are bound to a molecule of the complex with a binding constant of 3.69 muM in 0.03 M potassium potassium phosphate (pH 7.0). Direct and competitive binding measurements indicate that about 42 pyruvate binding sites are present per mole of enzyme complex which has been stripped of thiamine diphosphate; the number of binding sites is reduced to 28,5 in the presence of a saturating concentration of thiochrome diphosphate, a thiamine diphosphate analogue. The dissociation constant for pyruvate to the enzyme complex in the presence of thiochrome diphosphate is 308 muM in 0.02 M potassium phosphate (pH 7.0). Pyruvate, thiochrome diphosphate, and acetyl-CoA all displace ANS from the enzyme complex. In the cases of pyruvate and thiochrome diphosphate, the concentration dependence of the displacements suggests the displacement is allosteric, while in the case of acetyl-CoA direct competition appears to be involved. GTP decreased the effect of acetyl-CoA to the enzyme complex indicate that 24-26 bound acetyl-CoA molecules per complex can be readily displaced by ANS, and the binding of acetyl-CoA to these sites displays positive cooperativity. Fluorescence energy transfer measurements between bound ANS on the pyruvate dehydrogenase enzyme and FAD on the dihydrolipoyl dehydrogenase enzyme indicate, assuming the emission and absorption dipoles are randomly oriented, that these two probes must be at least 58 A apart in the intact complex.
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PMID:Fluorescence energy transfer measurements between ligand binding sites of the pyruvate dehydrogenase multienzyme complex. 76 64

The binding of adenosine diphosphate-ribosylated elongation factor 2 (ADPRib-EF-2) to ribosomes was inhibited both in the presence and absence of GTP in proportion to the amounts of unmodified EF-2 added. Concomitant with this inhibition, an increase in the activity of ribosome-bound EF-2 in polyphenylalanine synthesis was observed. On the other hand, the addition of ADPRib-EF-2 reduced the rate of poly(Phe) synthesis observed in the presence of a saturating amount of EF-2 and increased the amount of EF-2 required for the half-maximal rate of poly(Phe) synthesis. Phe-tRNA, nonenzymatically bound to the ribosome in the presence of poly(U), inhibited the subsequent binding of ADPHRib-EF-2. The same ribosomal population appeared to preferentially bind either aminoacyl-tRNA or ADPRib-EF-2. The Scatchard plot of the binding of ADPRib-EF-2 to the ribosome in the presence of GTP revealed the presence of two ribosomal binding sites (or ribosomal populations) with apparent different affinities for the modified factor (K371 degrees d,1 = 6.6 nM and K37 degrees d,2 = 126 nM). At saturating concentrations of ADPRib-EF-2, a maximum of about 1 molecule of the factor was bound per ribosome. The binding of ADPRib-EF-2 to the ribosome was stimulated by GTP. The binding of radioactive GTP to the ribosome was observed concomitantly with the binding of ADPRib-EF-2. One mole of GTP was bound per mole of ADPRib-EF-2. No significant difference could be found in the binding of GTP to ribosome required in the presence of either EF-2 or ADPRib-EF-2. The binding of ADPRib-EF-2 to the ribosome required the presence of Mg2+ and reached a maximum at 5 mM. The binding was greatest at K+ concentrations below 20 mM. ADPRib-EF-2 was bound primarily to the large ribosomal subunit. A slight, but reproducible binding to the 40 S subunit was also observed. The addition of 40 S to 60 S subunits stimulated the binding of ADPRib-EF-2. GTP displayed a stimulatory effect on the binding only in the presence of recombined subunits. Human ADPRib-EF-2 was bound to rat liver ribosomes as efficiently as to human tonsil ribosomes, while the binding to Escherichia coli ribosomes was insignificant.
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PMID:Interactions of adenosine diphosphate-ribosylated elongation factor 2 with ribosomes. 78 67

The digestion of EF-Tu-GDP (or EF-Tu-GTP) by trypsin [EC 3.4.21.4] under native conditions has been shown to proceed through two different and characteristic stages. 1. In the first phase, the protein is transformed into a fragment (Fragment A) with a molecular weight of 39,000 by exposure to trypsin for a relatively short period of time. Fragment A is unable to catalyze the binding of aminoacyl-tRNA to ribosomes. The ability to promote two partial steps of the binding reaction, i.e., formation of the aminoacyl-tRNA-EF-Tu-GTP ternary complex as well as the methanol-stimulated, ribosome dependent GTPase reaction, was rapidly destroyed. On the other hand, the ability to interact with guanine nucleotides as well as EF-Ts survived well during prolonged digestion. 2. In the second phase of digestion, a nick is introduced in Fragment A to yield two subfragments (Fragments B and C). These two fragments exist as a hybrid molecule which migrates as a single peak on a Sephadex G-75 column, and which dissociates into Fragments B and C only in the presence of 6 M guanidine hydrochloride or 5% sodium dodecyl sulfate. The molecular weights of Fragments B and C, as determined by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate, were 22,000 and 12,000 respectively. The hybrid molecule still retained one mole of bound guanine nucleotide and was resistant to further tryptic digestion. 3. Three sulfhydryl groups of EF-Tu were found to be present in Fragment B, both by amino acid analysis of the purified fragments and also by electrophoresis of tryptic digests labeled with N-ethyl[14C]maleimide. 4. The tryptic digestion of EF-Tu-GDP (or EF-Tu-GTP) labeled with N-(1-anilinonaphthyl-4)maleimide (ANM) at SH2 (the second SH), caused a 30% decrease in the fluorescence emission during the first rapid phase of digestion. This indicates that destruction of the hydrophobic environment near SH2 of EF-Tu occurred in the early phase of tryptic digestion. 5. The kinetic studies on the reaction of ANM with EF-Tu before and after tryptic digestion indicated that both Fragment A and the hybrid molecule reacted with ANM in the presence of GTP three to four times more rapidly than in the presence of GDP. Thus, it appears that the ability to induce conformational transition near SH2 by a change of nucleotide ligands is still retained in the hybrid molecule consisting of Fragments B and C.
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PMID:Limited hydrolysis of the polypeptide chain elongation factor Tu by trypsin. Isolation and characterization of the polypeptide fragments. 93 63

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