Co-operative mutagenic actions of bisulfite and nitrogen nucleophiles.

The combined effect of bisulfite and a nitrogen nucleophile, i.e. semicarbazide, methoxyamine or hydroxylamine, to chemically modify cytosine and to cause mutation and inactivation of bacteriophage lambda was investigated. A rapid transamination of cytidine with each of the amines took place in the presence of bisulfite, and the reaction product was solely the N(4)-transaminated 5,6-dihydrocytidine-6-sulfonate. Modifications of cytidine with bisulfite alone and with the nitrogen nucleophile alone were much slower reactions than those using a combination of bisulfite and the nucleophile. Whereas the product of the modification with the bisulfite/semicarbazide, 5,6-dihydro-4-semicarbazido-2-ketopyrimidine ribofuranoside-6-sulfonate, is convertible to 4-semicarbazido-2-ketopyrimidine ribofuranoside by treatment with a phosphate buffer, the products of the modification with the bisulfite/methoxyamine and with the bisulfite/hydroxylamine, i.e. 4-methoxy-5,6-dihydrocytidine-6-sulfonate and 4-hydroxy-5,6-dihydrocytidine-6-sulfonate, were stable in phosphate buffer.Inactivation and the “clear” mutation of bacteriophage lambda were observed when the phage was treated with sodium bisulfite in the presence of semicarbazide, methoxyamine or hydroxylamine. Under the conditions used, only very small increases in the mutation frequency were obtained by treatment of the phage with bisulfite alone or with the base alone. It was concluded that the residues, 5,6-dihydro-4-semicarbazido-2-ketopyrimidine-6-sulfonate, 4-methoxy-5, 6-dihydrocytosine-6-sulfonate and 4-hydroxy-5,6-dihydrocytosine-6-sulfonate in DNA are the causes of the mutation.When phage that had been inactivated by the semicarbazide/bisulfite reagent was subsequently treated with a phosphate buffer, a reactivation took place. The rate of the reactivation increased as the concentration of phosphate in the buffer increased. This reactivation was not accompanied by change in the mutation frequency. No reactivation was observed after a similar incubation when the prior inactivation had been induced by either methoxyamine/bisulfite or hydroxylamine/bisulfite. These results indicate that the 4-semicarbazido-2-ketopyrimidine residue is also mutagenic but is less lethal than the corresponding 5,6-dihydro-6-sulfonate structure.These results offer the first clear example of the co-operative mutagenic action of two different reagents.     

Uridine-cytidine kinase. Kinetic studies and reaction mechanism.

The initial velocity pattern has been determined for uridine-cytidine kinase purified from the murine mast cell neoplasm P815. With either uridine or cytidine as phosphate acceptor, and ATP as phosphate donor, the pattern observed was one of intersecting lines, ruling out a ping-pong reaction mechanism, and suggesting that the reaction probably proceeds by the sequential addition of both substrates to the enzyme to form a ternary complex, followed by the sequential release of the two products. This pattern was obtained whether the reaction was run in 0.01 m potassium phosphate buffer, pH 7.5, or in 0.1 m Tris-HCl, pH 7.2. When analyzed by the Sequen computer program, the data indicated an apparent K_m of the enzyme for uridine of 1.5 × 10^?4m, an apparent K_m for cytidine of 4.5 × 10^?5m, and a K_m for ATP, with uridine or cytidine as phosphate acceptor, of 3.6 × 10^?3m or 2.1 × 10^?3m, respectively. The V was 1.83 μmol phosphorylated/min/mg enzyme protein for the uridine kinase reaction and 0.91 μmol for the cytidine kinase reaction.     

Metabolism of 4-N-Hydroxy-Cytidine in Escherichia coli

4-N-hydroxy-cytidine was found to substitute for uridine as a pyrimidine supplement for the growth of Escherichia coli Bu⁻. Measurement of the incorporation of 4-N-hydroxy-cytidine-2-¹⁴C into ribonucleic acid and deoxyribonucleic acid revealed that this compound was converted to cytidine or uridine before utilization. Two pathways for metabolism were considered: (i) the reduction of 4-N-hydroxy-cytidine to cytidine followed by deamination, (ii) the direct hydrolysis of hydroxylamine from 4-N-hydroxy-cytidine to yield uridine. A threefold increase in cytidine (deoxycytidine) deaminase (EC 3.5.4.5) activity, when the cells were grown on 4-N-hydroxy-cytidine, suggested the involvement of this enzyme. More direct proof was obtained by purifying the deaminase 185-fold and finding that it released hydroxylamine from 4-N-hydroxy-cytidine at one-fiftieth the rate at which ammonia was removed from cytidine. This result is consistent with the slower rate of growth of the Bu⁻ cells on 4-N-hydroxy-cytidine than cytidine and suggests that the second pathway is the major route for utilization of this compound.     

Studies on uridine diphosphate-galactose pyrophosphatase and uridine diphosphate-galactose: glycoprotein galactosyltransferase activities in microsomal membranes.

Rat liver microsomes showed very active uridine diphosphate-galactose pyrophosphatase activity leading to the hydrolysis of uridine diphosphate-galactose into galactose1-phosphate and finally into galactose. The activity was observed in presence of buffers with wide ranges of pH. Different concentrations of divalent cations, such as Mn²⁺, Mg²⁺, and Ca²⁺ had no significant effect on the enzyme activity. A number of nucleotides and their derivatives inhibited the pyrophosphatase activity. Of these, different concentrations of uridine monophosphate, cytidine 5′-phosphate and cytidine 5′-diphosphate have slight or no effect; cytidine 5′-triphosphate, adenosine 5′-triphosphate, guanosine 5′-triphosphate, cytidine 5′-diphosphate-glucose and guanosine 5′-diphosphate-glucose showed strong inhibitory effect whereas cytidine 5′-diphosphate-choline showed a moderate effect on the pyrophosphatase. All these nucleotides also showed variable stimulatory effects on uridine diphosphate-galactose:glycoprotein galactosyltransferase activity in the microsomes which could be partly related to their inhibitory effects on uridine diphosphate-galactose pyrophosphatase. Among them uridine monophosphate, cytidine 5′-phosphate, and cytidine 5′-diphosphate stimulated galactosyltransferase activity without showing appreciable inhibition of pyrophosphatase, cytidine 5′-diphosphate-choline, although did not inhibit pyrophosphatase as effectively as cytidine 5′-triphosphate, guanosine 5′-triphosphate, adenosine 5′-triphosphate, cytidine 5′-diphosphate-glucose, and guanosine 5′-diphosphate-glucose but stimulated galactosyltransferase activity as well as those. The fact that cytidine 5′-diphosphate-choline stimulated galactosyltransferase more effectively than cytidine 5′-phosphate, cytidine 5′-diphosphate, and cytidine 5′-triphosphate suggested an additional role of the choline moiety in the system. It has been also shown that cytidine 5′-diphosphate-choline can affect the saturation of galactosyltransferase enzyme at a much lower concentration of uridine diphosphate-galactose. Most of the pyrophosphatase and galactosyltransferase activities were solubilized by deoxycholate and the membrane pellets remaining after solubilization still retained some galactosyltransferase activity which was stimulated by cytidine 5′-diphosphate-choline. In different membrane fractions a concerted effect of both uridine diphosphate-galactose pyrophosphatase and glycoprotein:galactosyltransferase enzymes on the substrate uridine diphosphate-galactose is indicated and their eventual controlling effects on the glycopolymer synthesis in vitro or in vivo need careful evaluation.     

THE INACTIVATION OF BACTERIOPHAGE BY MERCURY BICHLORIDE; THE REACTIVATION OF BICHLORIDE-INACTIVATED PHAGE

1. The inactivation of antistaphylococcus bacteriophage suspended in infusion broth at pH 7.6 and 22°C. by HgCl₂ proceeds according to the equation dP/dt = k [HgCl₂] [P_o – P_i] over the range studied. 2. This inactivation can be reversed by precipitation of Hg⁺⁺ with H₂S. In the present experiments the inactivation was carried out until only some 5 per cent of the initial phage remained active. After reactivation the [P] had increased to 100 per cent of the initial [P].     

Some kinetic studies on ribonucleosides degradation by extracts of penicillium citrinum

Cell-free extracts of 3–4 days old mats of nitrate-grown Penicillium citrinum catalyze the hydrolytic cleavage of the N-glycosidic bonds of inosine, guanosine and adenosine optimally at pH 4, 0.1 M citrate buffer. The same extracts catalyze the hydrolytic deamination of cytidine at a maximum rate in 0.08 M Tris-acetate buffer pH 6.5, 40°C and 50°C were the most suitable degrees for purine nucleoside hydrolysis and cytidine deamination, respectively. The incubation of the extracts at 60°C, in the absence of cytidine caused a loss in the deaminating activity, while freezing and thawing had no effect on both activities. The deaminating activity seems to be cytidine specific as neither cytosine, adenine, adenosine nor guanosine could be deaminated. Uridine competively inhibited this activity, while ammonia had no effect. The apparent K_m value of this enzyme for cytidine was 1.57×10^?3M and its K_i value for uridine was 7.8×10^?3M. The apparent K_m values of the N-glycosidic bond cleaving enzyme for inosine, guanosine and adenosine were 13.3, 14.2 and 20×10^?3 M, respectively.     

Bhargavaea indica sp. nov., a member of the phylum Firmicutes, isolated from Arabian Sea sediment

A Gram-positive, aerobic, coccoid-rod shaped, non-motile, catalase- and oxidase-positive bacterium, designated strain KJW98^T, was isolated from the marine sediment of Karwar jetty, west coast of India. The strain was β-haemolytic, non-endospore-forming and grew with 0–8.5% (w/v) NaCl, at 15–48°C and at pH 6.5–9.0, with optimum growth with 0.5% (w/v) NaCl, at 42°C and at pH 7.0–8.0. Phylogenetic analyses based on 16S rRNA and gyrB gene sequences showed that strain KJW98^T forms a lineage within the genus Bhargavaea. The G+C content of the genomic DNA was 55 mol%. The DNA-DNA relatedness values of strain KJW98^T with B. beijingensis DSM 19037^T, B. cecembensis LMG 24411^T and B. ginsengi DSM 19038^T were 43.2, 39 and 26.5%, respectively. The major fatty acids were anteiso-C_15:0 (37.7%), iso-C_15:0 (19.7%), anteiso-C_17:0 (17.0%) and iso-C_16:0 (11.1%). The predominant menaquinone was MK-8 and the cell-wall peptidoglycan was of A4α type with L-lysine as the diagnostic diamino acid. The major polar lipids were diphosphatidylglycerol and phosphatidylglycerol. The phenotypic, genotypic and DNA-DNA relatedness data indicate that strain KJW98^T should be distinguished from the members of the genus Bhargavaea, for which the name Bhargavaea indica sp. nov. is proposed with the type strain KJW98^T (=KCTC 13583^T =LMG 25219^T).     

Bacteriophage P2-lambda interference. III. Essential role of an early step in the initiation of lambda replication.

Induction of bacteriophage λ in the presence of a P2 prophage results in inactivation of cellular transfer RNA, inhibition of amino acid and uridine incorporation in the host, as well as inhibition of phage replication. A red gam double mutation allows λ to escape from interference, and a mutation in gene O or P abolishes the effects on the host.It is shown here that phage and plasmid DNA extracted from cells undergoing P2-λ interference are still active in a transfection assay. Mutations in bacterial gene dna B or in phage site ori suppress the inhibition of amino acid incorporation, whereas genes dnaE and dna G have no such effect. Derepression of bacterial exonuclease VIII totally suppresses the interference, and mutations in genes recA and lexA, which control the SOS functions, suppress it partially if the λ phage is red⁺. Our results suggest that P2-λ interference is due to the action of old at an early step of the initiation of λ replication.     

Inactivation of rat ovarian 20α-hydroxysteroid dehydrogenase by N-alkylmaleimides

A series of N-alkylmaleimides, varying in chain length from N-ethylmaleimide and N-butyl to N-octyl, inclusive, was shown to effectively inactivate rat ovarian 20α-hydroxysteroid dehydrogenase at pH 7.7, 25 °C. The apparent second-order rate constants for inactivation were observed to increase with increasing chain length of the N-alkylmaleimide used. Positive chain length effects were also indicated by the K_d values for N-alkylmaleimides calculated from double-reciprocal plots resulting from the saturation kinetics observed in the inactivation reactions. The maximum rate constant for inactivation at enzyme saturation was 0.3 min^?1 for each maleimide studied. NADP-and coenzyme-competitive inhibitors such as 3-aminopyridine adenine dinucleotide phosphate and various adenosine derivatives protected the enzyme against maleimide inactivation, whereas no protection was observed with the steroid substrate, 20α-hydroxypregn-4-en-3-one. The pH profile for maleimide inactivation indicated the involvement of an enzyme functional group with a pK_a near 8.0. Sulfhydryl modification was also indicated by fluorescein mercuric acetate inactivation and titration experiments. Inactivation of the enzyme by a lysine-modifying reagent exhibited a pH profile differing from that observed in the maleimide inactivation process. It is proposed that N-alkylmaleimides inactivate the enzyme through covalent modification of sulfhydryl groups located in a nonpolar region of the enzyme.     

Selective modification of cytidine, uridine, guanosine and pseudouridine residues in Escherichia coli leucine transfer ribonucleic acid

The specificity of methoxyamine for the cytidine residues in an Escherichia coli leuoine transfer RNA (tRNA₁^leu is described in detail. Of the six non-hydrogen-bonded cytidine residues in the clover-leaf model of this tRNA, four are very reactive (C-35, 53, 85 and 86) and two are unreactive (C-67 and 79).The specificity of l-cyclohexyl-3-[2-morpholino-(4)-ethyl]carbodiimide methotosylate for the uridine, guanosine and pseudouridine residues in the leucine tRNA was also investigated. The carbodiimide completely modified four uridine residues (U-33, 34, 50 and 51) and partially modified G-37 and Ψ-39. For technical reasons, the sites of partial modification in loop I of the tRNA were difficult to establish. There was no modification of base residues in loop IV nor of U-59 at the base of stem e of the tRNA.The modification patterns described for the leucine tRNA are compared with those observed for the E. coli initiator tRNA₁^met and su⁺_III tyrosine tRNA. Several general conclusions regarding tRNA conformation are made. In particular, the evidence supporting a diversity of anticodon loop structures amongst tRNAs is discussed.     

Structure-function relationship in Escherichia coli initiation factors. Environment of the Cys residue and evidence for a hydrophobic region in initiation factor IF3 by fluorescence and ESR spectroscopy

The reactions of rabbit muscle pyruvate kinase with 5′-p-fluorosulfonylbenzoyl adenosine (5′-FSBA) and 5′-p-fluorosulfonylbenzoyl guanosine (5′-FSBG) from pH 7.0 to 8.0 exhibit biphasic inactivation kinetics. These reactions are characterized by three events: a fast reaction yielding partially active enzyme (with 67% of its original activity for the 5′-FSBA reaction and 45% for the 5′-FSBG reaction) which is reactivated by dithiothreitol, and two slower reactions yielding fully inactive enzymes; the product of only one of the two slower reactions is reactivated by dithiothreitol. These reactions are termed fast dithiothreitol-sensitive, slow dithiothreitol-sensitive, and dithiothreitol-insensitive inactivations. The rates of all three phases of the reactions with 5′-FSBA and 5′-FSBG increase as the pH is raised. The 5′-FSBG reaction can be described in terms of initial reaction with a single ionizable group of pK_a 7.80, 8.60, and 7.94 for the fast dithiothreitol-sensitive, slow dithiothreitol-sensitive, and dithiothreitol-insensitive reactions, respectively; pH-independent rate constants of 0.173, 0.133, and 0.0165 min^?1 are calculated for these three phases of the overall reaction. The pH dependence of the dithiothreitol-insensitive inactivation by 5′-FSBA coincides with that for 5′-FSBG, but the data for the dithiothreitol-sensitive reactions with 5′-FSBA indicate that the reaction in each phase occurs at more than one site over the pH range tested. Differential protection by ligands against inactivation by 5′-FSBA and 5′-FSBG at pH 7.4 and 8.0 indicates that, for the fast dithiothreitol-sensitive reactions, the cysteine residues participating in the two reactions are not identical, although in both cases modification has been attributed to formation of a disulfide. For 5′-FSBA, the partial inactivation appears to result from modification of cysteine residues at the noncatalytic nucleotide site, whereas for 5′-FSBG the inactivation is due to modification within the catalytic metal-nucleotide site. Reaction with 5′-FSBG seems to occur at the same locus for both the fast and slow dithiothreitol-sensitive phases, with the rate difference being ascribable to negative cooperativity among subunits. For the slow dithiothreitol-sensitive inactivation by 5′-FSBA, protection by Mg²⁺ and by Mg²⁺ plus ADP suggests that the targets of modification include the active-site cysteine that is modified by 5′-FSBG. The dithiothreitol-insensitive inactivation, shown to be due to reaction of 5′-FSBA with a tyrosine, may result from reaction of both nucleotide analogs with the same residue, although differential protection by the natural ligands suggests that 5′-FSBA and 5′-FSBG bind to two subsites within the active site.     

Effect of CO2 on labelling of nerve and liver cells by nucleic acid precursors

In vivo experiments in mice demonstrated that 5% CO₂ content in the air inhaled did not change the labelling in autoradiograms from animals injected with [³H]uridine, [³H]orotic acid, [³H]hypoxanthine, [³H]lysine or [³H]cytidine. At 20% CO₂ content there was a significant decrease in labelling of brain cells with [³H]uridine and [³H]cytidine, but not following [³H]lysine; there was no labelling of nerve cells with [³H]orotic acid or [³H]hypoxanthine, but a control group was not included. The labelling of choroid plexus and hepatocytes was independent of the CO₂ concentration. A comparison of in vivo and in vitro experiments at 20% CO₂ content showed a similar significant decrease in labelling of brain cells with [³H]uridine and [³H]cytidine. It is concluded that a metabolic change is the most appropriate explanation of the CO₂ effect.     

Bacteriophage P2-lambda interference: II. Effects on the host under the control of lambda genes O and P

Induction of bacteriophage lambda in the presence of a P2 prophage causes a drastic inhibition of protein synthesis through transfer RNA inactivation, and then a shut-off of uridine incorporation. It has also been found to trigger a peculiar process of host killing.We have investigated the dependence of these effects with respect to the genetic determinants of interference. We have shown, moreover, that genes O and P, which control the initiation of phage replication, are required for P2-λ interference. The way the host tRNA can be inactivated through the expression of those genes, which are all concerned with DNA metabolism, is discussed.     

Chain growth rate of -galactosidase during exponential growth and amino acid starvation

S_d phage were incubated in 1 m-O-methylhydroxylamine. At various time-intervals, samples of modified phage were isolated and disrupted either by heating or by treatment with detergent. Changes in viscosity and buoyant density of disrupted preparations took place in the course of modification. Three transient synchronous drops in viscosity and buoyant density levels were observed with minima at five minutes, one and three hours of modification. The specific viscosity of the preparations at minima was 10 to 20% that of the disrupted unmodified phage.Properties of the phage preparation isolated during the third period of decreased viscosity were studied in more detail. This preparation, subjected to thermal disruption, gives a single DNA-containing band in Cs₂SO₄ gradient centrifugation corresponding to a buoyant density of 1.37 g/cm³ (cf. 1.39, 1.29 and 1.43 g/cm³ for whole phage, phage ghosts and native phage DNA, respectively).The band contains practically all the ³⁵S label that was present in the starting phage, suggesting that it corresponds to a complex of phage DNA with protein. Electron microscopy revealed complexes as thick strands of 50 to 300 Å diameter bonded to globular particles of varying size.In four hours of modification, the viscosity and buoyant density of disrupted phage returned to values characteristic of unmodified preparations. The DNA band contained no ³⁵S label. Electron microscopy of the substance of this band revealed fibres of 20 Å diameter.A possible explanation of the results is based on the assumption of pre-existing non-covalent interaction of C₍₄₎—NH₂ moieties of cytidine residues with nucleophilic groupings of coating protein within the virion. It is assumed that it is this interaction that holds DNA in “non-native” conformation within intact phage particles and thus explains its peculiar properties discovered earlier. In the present case, the interaction determines the formation of DNA-protein crosslinks under O-methylhydroxylamine treatment via the earlier postulated intermediate product of cytosine modification. Restoration of “normal” physical properties of disrupted phage after more prolonged modification is explained by cleavage of the DNA-protein cross-links due to reaction of the postulated intermediate with O-methylhydroxylamine affording N₍₄₎-methoxy-6-methoxy-amino-5,6-dihydrocytidine residues.     

Inactivation of transfecting DNA by physical and chemical agents: influence of genotypes of phage lambda and host cells

Inactivation of λ₁₁c and its purified DNA by UV irradiation, γ-rays of ¹³⁷Cs (in conditions of indirect action), nitrous acid, hydroxylamine and N-methyl-N′-nitro-N-nitrosoguanidine (MNNG) was studied. The biological activity of isolated phage DNA was measured by the calcium transfection procedure. 14 different recipient strains of Escherichia coli K12 were used, including mutants deficient in excision and recombination repair (uvrA6, uvrB5, uvrC34, polA1, recA13, recC38, recD34, recA13B21C22, recA56uvrA6, exrA and recB21C22sbcB15).Whole phage was more resistant to the action of γ-rays than was isolated DNA. On the other hand, the chemical agents HNO₂ and MNNG inactivated phage much faster than isolated DNA. Of all mutations of the host cell only polA1 considerably increased the sensitivity of phage DNA to UV irradiation, γ-rays and MNNG. The mutations uvr^? affected the inactivation kinetics under UV action. In all other cases the genotype of the host cell was indifferent for the inactivation kinetics of phage DNA, even if it belonged to recombination deficient mutant λ red3 int6 (in which only UV and γ inactivation was studied). Possible reasons for the low efficiency of the host-cell repair toward the damage caused to λ DNA by different agents are discussed.     

Purification and characterization of L-amino acid oxidase from the solid-state grown cultures of Aspergillus oryzae ASH

L-Amino acid oxidase (L-AAO) was purified from the solid state-grown cultures of A. oryzae ASH (JX006239.1) by fractional salting out, followed by ion exchange and gel filtration chromatography, to its molecular homogeneity, displaying 3.38-fold purification in comparison with the crude enzyme. SDS-PAGE revealed the enzyme to be a homo-dimer with ～55-kDa subunits, with approximate molecular weight on native PAGE of 105–110 kDa. Two absorption maxima, at 280 nm and 341 nm, for the apoproteinic and FMN prosthetic group of the enzyme, respectively, were observed, with no detected surface glycosyl residues. The enzyme had maximum activity at pH 7.8–8.0, with ionic structural stability within pH range 7.2–7.6 and pH precipitation point (pI) 4.1–5.0. L-AAO exhibited the highest activity at 55°C, with plausible thermal stability below 40°C. The enzyme had T _1/2 values of 21.2, 8.3, 3.6, 3.1, 2.6 h at 30, 35, 40, 50, 60°C with Tm 61.3°C. Kinetically, A. oryzae L-AAO displayed a broad oxidative activity for tested amino acids as substrates. However, the enzyme had a higher affinity towards basic amino acid L-lysine (K _m 3.3 mM, K _cat 0.04 s^?1) followed by aromatic amino acids L-tyrosine (K _m 5.3 mM, K _cat 0.036 s^?1) and L-phenylalanine (K _m 6.6 mM), with 1ow affinity for the S-amino acid L-methionine (K _m 15.6 mM). The higher specificity of A. oryzae L-AAO to L-lysine as substrate seems to be a unique property comparing to this enzyme from other microbes. The enzyme was significantly inhibited by hydroxylamine and SDS, with slight inhibition by EDTA. The enzyme had a little effect on AST and ALT, with no effect on platelet aggregation and blood hemolysis in vivo with an obvious cytotoxic effect towards HepG2 (IC₅₀ 832.2 μg/mL) and MCF-7 (IC₅₀, 370.6 μg/mL) tumor cells in vitro.     

Effect of Ascorbic Acid on the Degradation of Cyanocobalamin and Hydroxocobalamin in Aqueous Solution: A Kinetic Study

The degradation kinetics of 5 × 10⁻⁵ M cyanocobalamin (B₁₂) and hydroxocobalamin (B_12b) in the presence of ascorbic acid (AH₂) was studied in the pH range of 1.0–8.0. B₁₂ is degraded to B_12b which undergoes oxidation to corrin ring cleavage products. B_12b alone is directly oxidized to the ring cleavage products. B₁₂ and B_12b in degraded solutions were simultaneously assayed by a two-component spectrometric method at 525 and 550 nm without interference from AH₂. Both degrade by first-order kinetics and the values of the rate constants at pH 1.0–8.0 range from 0.08 to 1.05 × 10⁻⁵ s⁻¹ and 0.22–7.62 × 10⁻⁵ s⁻¹, respectively, in the presence of 0.25 × 10⁻³ M AH₂. The t_1/2 values of B₁₂ and B_12b range from 13.7 to 137.5 h and 2.5–87.5 h, respectively. The second-order rate constants for the interaction of AH₂ with B₁₂ and B_12b are 0.05–0.28 × 10⁻² and 1.10–30.08 × 10⁻² M⁻¹ s⁻¹, respectively, indicating a greater effect of AH₂ on B_12b compared to that of B₁₂. The k_obs–pH profiles for both B₁₂ and B_12b show the highest rates of degradation around pH 5. The degradation of B₁₂ and B_12b by AH₂ is affected by the catalytic effect of phosphate ions on the oxidation of AH₂ in the pH range 6.0–8.0.KEY WORDS: ascorbic acid, cyanocobalamin, degradation, hydroxocobalamin, kinetics, two-component spectrometry     

Studies of a reactive histidine of dyphosphopyridine nucleotide-linked isocitrate dehydrogenase from bovine heart.

Diphosphopyridine nucleotide-linked isocitrate dehydrogenase from bovine heart was inactivated at neutral pH by bromoacetate and diethyl pyrocarbonate and by photooxidation in the presence of methylene blue or rose bengal. Inactivation by diethyl pyrocarbonate was reversed by hydroxylamine. Loss of activity by photooxidation at pH 7.07 was accompanied by progressive destruction of histidine with time; loss of 83% of the enzyme activity was accompanied by modification of 1.1 histidyl residues per enzyme subunit. The pH-rate profiles of inactivation by photooxidation and by diethyl pyrocarbonate modification showed an inflection point around pH 6.6, in accord with the pK_a for a histidyl residue of a protein. Partial protection against inactivation by photooxidation or diethyl pyrocarbonate was obtained with substrate (manganous isocitrate or magnesium isocitrate) or ADP; the combination of substrate and ADP was more effective than the components singly. As demonstrated by differential enzyme activity assays between pH 6.4 and pH 7.5 with and without 0.67 mm ADP, modification of the reactive histidyl residue of the enzyme caused a preferential loss of the positive modulation of activity by ADP. The latter was particularly apparent when substrate partially protected the enzyme against inactivation by rose bengal-induced photooxidation.     

The pH dependence of the affinity,kinetics and cooperativity of ligand binding to the root effect haemoglobin of the goldfish Carassius auratus

• 1.1. The binding of O₂ to goldfish haemoglobin showed a strong pH dependence P₅₀=5.5 mmHg; n = 2.4 at pH 8.0 and P₅₀ = 170 mmHg; n = 1.0 at pH 5.5 such that the protein is only 50% saturated in a solution of air equilibrated buffer at pH 5.5.
• 2.2. The binding of CO is cooperative at high pH (n = 2.8; L = 1000; K_R = 0.1 μM; K_T = 4 μM) and non-cooperative (n = 1) at pH 5.5.
• 3.3. The rate of O₂ dissociation is extremely fast and pH dependent; being 30 sec⁻¹ at pH 8.0 and 400 sec⁻¹ at pH 6.0 at 1°C. At 23°C the rate of this process is too fast to obtain accurate data using stopped-flow techniques.
• 4.4. Partial photolysis of the oxyhaemoglobin species leads to homogeneous recombination kinetics at pH 8.0 with an associated rate constant of 4.7 × 10⁷ M⁻¹ sec⁻¹. At pH < 7.5 the recombination process occurs in two steps. One rate is equal to that observed at pH 8.0. The slower process is favoured at low pH.
• 5.5. Photolysis of the CO haemoglobin complex indicates that, at high pH, combination of CO with deoxyhaemoglobin is cooperative, whilst recombination with Hb(CO)₃ is non-cooperative and occurs at a rate of 1.2 × 10⁶ M⁻¹ sec⁻¹.
• 6.6. At neutral pH recombination of CO with partially linganded haemoglobin occurs in a two-step process. The proportion contributed by each of these two steps in pH dependent.
• 7.7. The functioning of this Root effect haemoglobin is discussed in terms of the two state-model of cooperativity in which the αβ chain heterogeneity is minimal

     

Biochemical characterization and high-level production of oxidized polyvinyl alcohol hydrolase from Sphingopyxis sp. 113P3 expressed in methylotrophic Pichia pastoris

The Sphingopyxis sp. 113P3 gene oph, encoding oxidized polyvinyl alcohol hydrolase (OPH), was optimized with the preferred codons of Pichia pastoris and ligated into the pPIC9K vector behind the α-factor signal sequence. The vector was then transfected into P. pastoris GS115 and genomic integration was confirmed. Large-scale production of recombinant protein was performed by induction with 14.4 g/L methanol at 22 °C in a 3-L bioreactor. The maximal OPH activity obtained was 68.4 U/mL, which is the highest activity reported. The optimal pH and temperature of recombinant OPH were 8.0 and 45 °C, respectively. OPH activity was stable over a pH range of 5.0–8.5, and at a maximal temperature of 45 °C. The K _cat /K _m of recombinant OPH was 598 mM^?1 s^?1, which was 4.27-fold higher than that of recombinant OPH derived from Escherichia coli. The improved catalytic efficiency of OPH expressed in recombinant P. pastoris makes it favorable for industrial applications.