Factors Affecting the Activity of Cellulases Isolated from the Rumen Digesta of Sheep

Sodium phosphate buffer was used to extract cellulases from the plant solids fraction of rumen contents. The mixed cellulase preparation had maximal activity at pH 6.9 and 49°C. The V_max and the apparent K_m for wheaten hay cellulose were 19.8 glucose units/min and 6.35 mg/ml, respectively, and for microcrystalline cellulose (Sigmacell) at the same enzyme concentration, they were 33 glucose units/min and 27.5 mg/ml, respectively. For these assays a glucose unit was defined as nanomoles of glucose plus twice the nanomoles of cellobiose. Consideration of thermodynamic and kinetic data suggested that the hydrolysis of a relatively labile arabino-xylan comprising 3% of the wheaten hay cellulose was dependent on prior removal of the protecting β-1,4-glucose chains at the outer surface of the cellulose preparation. Sequential removal of structural polysaccharides from the plant cell wall rendered the latter more susceptible to cellulase activity. Cellulase activity was stimulated by increasing the concentration of phosphate from 5 to 50 mM. The stimulation was magnified in the presence of cell-free rumen fluid. Cellulase activity was not stimulated by calcium, magnesium, iron, zinc, manganese, copper, or cobalt ions and was unaffected by the chelators ethylenediaminetetraacetic acid and ethyleneglycol-bis (β-aminoethyl ether)-N,N′-tetraacetic acid. O-phenanthroline inhibited activity by 30 to 50%, but this may have been due to nonchelate properties. Anaerobic conditions or thiol protective agents were not essential for either the activity or stability of the cellulases during assay. An ultrafiltrable inhibitor of cellulase activity was detected in cell-free rumen fluid.     

Kinetics of Manganese Oxidation by Cell-Free Extracts of Bacteria Isolated from Manganese Concretions from Soil

A study of the kinetics of Mn²⁺ oxidation catalyzed by cell extracts of two bacterial isolates (E₁, Pseudomonas III [new isolate] and E₄, Citrobacter freundii) isolated from the core of manganese concretions from Greek soils is presented. The reaction velocity of Mn²⁺ oxidation was determined from the rate of consumption of Mn²⁺. The oxidation of Mn²⁺ was followed by measuring changes in Mn²⁺ concentration by activation analysis and by atomic absorption spectrophotometry. The reaction velocity was directly proportional to cell extract concentration when the reaction time was 1 h. At longer reaction times, the relationship deviated from linearity because substrate concentration became limiting. The rate of Mn²⁺ oxidation increased with the Mn²⁺ concentration. Analysis of the results by application of the integrated Michaelis equation for determining Michaelis constants and maximal velocities either in the presence (K_m = 3.33 μmol/ml and V_max = 1.25 μmol/ml·h) or in the absence of maleate buffer (K_m = 2.52 μmol/ml and V_max = 2.04 μmol/ml·h) indicated a strong affinity between the oxidizing system and manganese. All results in this study are consistent with an enzymatic manganese-oxidizing system and give an indication of the mechanism of biological Mn²⁺ oxidation in soil which differs from that in the marine environment.     

De Novo Purine Synthesis in Nitrogen-Fixing Nodules of Cowpea (Vigna unguiculata [L.] Walp.) and Soybean (Glycine max [L.] Merr.)

Partially purified, cell-free extracts from nodules of cowpea (Vigna unguiculata L. Walp. cv. Caloona) and soybean (Glycine max L. Merr. cv. Bragg) showed high rates of de novo purine nucleotide and purine base synthesis. Activity increased with rates of nitrogen fixation and ureide export during development of cowpea plants; maximum rates (equivalent to 1.2 micromoles N₂ per hour per gram fresh nodule) being similar to those of maximum nitrogen fixation (1-2 micromoles N₂ per hour per gram fresh nodule). Extracts from actively fixing nodules of a symbiosis not producing ureides, Lupinus albus L. cv. Ultra, showed rates of de novo purine synthesis 0.1% to 0.5% those of cowpea and soybean. Most (70-90%) of the activity was associated with the particulate components of the nodule, but up to 50% was released from this fraction by osmotic shock. The accumulated end products with particulate fractions were inosine monophosphate and aminoimidazole carboxamide ribonucleotide. Further metabolism to purine bases and ureides was restricted to the soluble fraction of the nodule extract. High rates of inosine monophosphate synthesis were supported by glutamine as amide donor, lower rates (10-20%) by ammonia, and negligible rates with asparagine as substrate.     

The reductive enzymatic cleavage of thiosulfate

Summary Methods presently used for the enzymatic assay of the thiosulfate cleaving reaction in bacterial cell-free systems are critically examined. Conditions under which strong acids are used to terminate the reaction and to release H₂S proved to be unsuitable. A non-enzymatic production of H₂S under such conditions is demonstrated. A reliable procedure for the measurement of H₂S production from the enzymatic cleavage of thiosulfate is described. This method was used to measure the thiosulfate cleaving reaction catalyzed by cell-free extracts of phototrophic bacteria of the genusChromatium. As reductants, hydrogen-hydrogenase/methyl viologen system, reduced glutathione or dihydrolipoate were used. The same extract fraction catalyzed the rhodanese reaction.     

Fluorescent nucleotide triphosphate substrates for snake venom phosphodiesterase

The procedure described utilizes a crude cell-free extract from the yeast Saccharomyces cerevisiae as enzymatic source for the synthesis of coproporphyrin III from [¹⁴C]δ-aminolevulinic acid with a high yield of conversion (?60%). Both specific radioactivity and total radioactivity of coproporphyrin III can be adjusted fairly well. This procedure is not time consuming for yeast acellular extracts or porphyrin ester preparations. The acellular extracts can be stored frozen (?30°C) for at least 1 year without loss of enzymatic activity. The same procedure can be used for [¹⁴C]protoporphyrin preparation.     

Preparation of ADP-Glucose with an Enzyme from Arthrobacter simplex

For the purpose of enzymatic preparation of ADP-glucose (ADPG), bacterial screening was performed to find a strain having a high activity of ADPG pyrophosphorylase which catalyzes the synthesis of ADPG from ATP and glucose-1-phosphate. A cell-free extract of Arthrobacter simplex IFO 12069 showed a strong enzyme activity for the synthesis of ADPG, which was isolated from the reaction solution by ion-exchange column chromatography and identified by paper and thin-layer chromatography. The enzyme activity of the bacterium reached a maximum in the late logarithmic phase under aerobic growth conditions. Some factors affecting the ADPG synthesis, e.g. reaction pH, substrate concentrations, divalent cations, inhibitors and activators, were studied with an ammonium sulfate fraction, 30~50% saturation as the enzyme preparation.     

Purification and characterization of l-allo-threonine aldolase from Aeromonas jandaei DK-39

l-allo-Threonine aldolase (l-allo-threonine acetaldehyde-lyase), which exhibited specificity for l-allo-threonine but not for l-threonine, was purified from a cell-free extract of Aeromonas jandaei DK-39. The purified enzyme catalyzed the aldol cleavage reaction of l-allo-threonine (K_m=1.45 mM, V_max=45.2 μmol min⁻¹ mg⁻¹). The activity of the enzyme was inhibited by carbonyl reagents, which suggests that pyridoxal-5′-phosphate participates in the enzymatic reaction. The enzyme does not act on either l-serine or l-threonine, and thus it can be distinguished from serine hydroxy-methyltransferase (l-serine:tetrahydrofolate 5,10-hydroxy-methyltransferase, EC 2.1.2.1) or l-threonine aldolase (EC 4.1.2.5).     

Abscisic Aldehyde Is an Intermediate in the Enzymatic Conversion of Xanthoxin to Abscisic Acid in Phaseolus vulgaris L. Leaves

The enzymatic conversion of xanthoxin to abscisic acid by cell-free extracts of Phaseolus vulgaris L. leaves has been found to be a two-step reaction catalyzed by two different enzymes. Xanthoxin was first converted to abscisic aldehyde followed by conversion of the latter to abscisic acid. The enzyme activity catalyzing the synthesis of abscisic aldehyde from xanthoxin (xanthoxin oxidase) was present in cell-free leaf extracts from both wild type and the abscisic acid-deficient molybdopterin cofactor mutant, Az34 (nar2a) of Hordeum vulgare L. However, the enzyme activity catalyzing the synthesis of abscisic acid from abscisic aldehyde (abscisic aldehyde oxidase) was present only in extracts of the wild type and no activity could be detected in either turgid or water stressed leaf extracts of the Az34 mutant. Furthermore, the wilty tomato mutants, sitiens and flacca, which do not accumulate abscisic acid in response to water stress, have been shown to lack abscisic aldehyde oxidase activity. When this enzyme fraction was isolated from leaf extracts of P. vulgaris L. and added to extracts prepared from sitiens and flacca, xanthoxin was converted to abscisic acid. Abscisic aldehyde oxidase has been purified about 145-fold from P. vulgaris L. leaves. It exhibited optimum catalytic activity at pH 7.25 in potassium phosphate buffer.     

Geranylpyrophosphate: p-hydroxybenzoate geranyltransferase activity in extracts of Lithospermum erythrorhizon cell cultures

The enzymatic formation of m-geranyl-p-hydroxybenzoic acid from geranylpyrophosphate and p-hydroxybenzoic acid was investigated in cell-free extracts of Lithospermum erythrorhizon cell cultures. The reaction required the presence of a divalent cation, magnesium being the most effective activator. The enzyme showed a very broad pH optimum between pH 7.1 and 9.3. It was highly specific for both p-hydroxybenzoic acid and geranylpyrophosphate, and the apparent K_m values for these two substrates were 0.014 and 0.56 mM, respectively. The activity was located in the pellet of a 100 000 g centrifugation, showing that the enzyme is bound to membranes or microsomes. Shikonin-producing cultures contained an activity of this enzyme 35 times higher than non-producing cultures, suggesting that this enzyme is of regulatory importance in shikonin biosynthesis.     

Lipid Peroxidation by the Manganese Peroxidase of Phanerochaete chrysosporium Is the Basis for Phenanthrene Oxidation by the Intact Fungus

The manganese peroxidase (MnP) of Phanerochaete chrysosporium supported Mn(II)-dependent, H₂O₂-independent lipid peroxidation, as shown by two findings: linolenic acid was peroxidized to give products that reacted with thiobarbituric acid, and linoleic acid was peroxidized to give hexanal. MnP also supported the slow oxidation of phenanthrene to 2,2′-diphenic acid in a reaction that required Mn(II), oxygen, and unsaturated lipids. Phenanthrene oxidation to diphenic acid by intact cultures of P. chrysosporium occurred to the same extent that oxidation in vitro did and was stimulated by Mn. These results support a role for MnP-mediated lipid peroxidation in phenanthrene oxidation by P. chrysosporium.     

Manganese substrate complexes of phosphofructokinase studies by pulsed magnetic resonance

The formation of binary, ternary, and quaternary complexes between phosphofructokinase, manganese, and substrates has been demonstrated by use of pulsed nuclear magnetic resonance techniques. A Scatchard plot of the interaction of manganese with phosphofructokinase as determined by electron paramagnetic resonance shows two types of manganese binding sites. Phosphofructokinase seems to contain one or two of the metal binding sites with K_d = 20 μm and ?_b ≦ 4, and perhaps, as many as 14 binding sites with K_d ~ 0.8 mm and ?_b ≦ 12 ± 2 per enzyme. Addition of ATP or ADP results in a further enhancement of the relaxation rate indicating ternary complex formation. The concentration of ATP and ADP which results in half maximal change of enhancement is 30–100 μm and 80 μm, respectively. No change in the water proton relaxation rate was detected upon addition of fructose-6-P or fructose-1,6-bisphosphate. A quaternary complex was detected by proton relaxation measurements upon addition of fructose-6-P to a reaction mixture containing β, γ-methylene ATP, manganese, and enzyme with 50 μm fructose-6-P required to obtain the half maximal observed effect. This evidence for a quaternary complex is consistent with a sequential reaction mechanism for phosphofructokinase.     

Characterization of a Manganese Superoxide Dismutase from the Higher Plant Pisum sativum

A manganese-containing superoxide dismutase (EC 1.15.1.1) was fully characterized from leaves of the higher plant Pisum sativum L., var. Lincoln. The amino acid composition determined for the enzyme was compared with that of a wide spectrum of superoxide dismutases and found to have a highest degree of homology with the mitochondrial manganese superoxide dismutases from rat liver and yeast. The enzyme showed an apparent pH optimum of 8.6 and at 25°C had a maximum stability at alkaline pH values. By kinetic competition experiments, the rate constant for the disproportionation of superoxide radicals by pea leaf manganese superoxide dismutase was found to be 1.61 × 10⁹ molar⁻¹·second⁻¹ at pH 7.8 and 25°C. The enzyme was not sensitive to NaCN or to H₂O₂, but was inhibited by N₃⁻. The sulfhydryl reagent p-hydroxymercuribenzoate at 1 mm concentration produced a nearly complete inhibition of the manganese superoxide dismutase activity. The metal chelators o-phenanthroline, EDTA, and diethyldithiocarbamate all inhibited activity slightly in decreasing order of intensity. A comparative study between this higher plant manganese superoxide dismutase and other dismutases from different origins is presented.     

Carboxylation of phosphoenolpyruvate by extracts of Neisseria gonorrhoeae.

The enzymatic carboxylation of phosphoenolpyruvate by cell-free extracts of Neisseria gonorrhoeae was examined and determined to be similar to the reaction catalyzed by phosphoenolpyruvate carboxylase (PEPC). This was shown by the irreversibility of the reaction and nucleotide independency. The enzyme was found to have some characteristics different from the other bacterial PEPCs reported. The enzyme showed catalytic activity in the presence of cobalt ions as well as magnesium and manganese ions, was not inhibited by succinate in fresh extracts, and displayed a low Michaelis constant for bicarbonate (0.27 mM), as compared with other PEPCs. The significance of this low Michaelis constant is discussed with respect to the growth of the organism and the importance of this enzyme to protein and nucleic acid synthesis.     

Characterization of Ethanol Production from Xylose and Xylitol by a Cell-Free Pachysolen tannophilus System

Whole cells and a cell extract of Pachysolen tannophilus converted xylose to xylitol, ethanol, and CO₂. The whole-cell system converted xylitol slowly to CO₂ and little ethanol was produced, whereas the cell-free system converted xylitol quantitatively to ethanol (1.64 mol of ethanol per mol of xylitol) and CO₂. The supernatant solution from high-speed centrifugation (100,000 × g) of the extract converted xylose to ethanol, but did not metabolize xylitol unless a membrane fraction and oxygen were also present. Fractionation of the crude cell extract by gel filtration resulted in an inactive fraction in which ethanol production from xylitol was fully restored by the addition of NAD⁺ and ADP. The continued conversion of xylose to xylitol in the presence of fluorocitrate, which inhibited aconitase, demonstrated that the tricarboxylic acid cycle was not the source of the electrons for the production of xylitol from xylose. Therefore, the source of the electrons is indirectly identified as an oxidative pentose-hexose cycle.     

Non-pyridine nucleotide dependent l-(+)-glutamate oxidoreductase in Azotobacter vinelandii

l-(+)-Glutamate oxidation that is non-pyridine nucleotide dependent is readily carried out by a membrane-bound enzyme in Azotobacter vinelandii strain O. Enzyme activity concentrates in a membranous fraction that is associated with the Azotobacter electron transport system. This l-glutamate oxidation is not dependent on externally added NAD⁺, NADP⁺, FAD, or FMN for activity. O₂, phenazine methosulfate and ferricyanide all served as relatively good electron acceptors for this reaction; while cytochrome c and nitrotetrazolium blue function poorly in this capacity. Paper chromatographic analyses revealed that the 2,4-dinitrophenylhydrazine derivative formed from the enzymatic oxidation of l-glutamate was α-ketoglutarate, while microdiffusion studies indicated that ammonia was also a key end product. These findings suggest that the overall reaction is an oxidative deamination. Ammonia formation was found to be stoichiometric with the amount of oxygen consumed (2 : 1 respectively, on a molar basis). The oxidation of glutamate was limited to the l-(+)-enantiomer indicating that this reaction is not the generalized type carried out by the l-amino acid oxidase. This oxidoreductase is functionally related to the Azotobacter electron transport system: (a) the activity concentrates almost exclusively in the electron transport fraction; (b) the l-glutamate oxidase activity is markedly sensitive to electron transport inhibitors, i.e. 2-n-heptyl-4-hydroxyquinoline-N-oxide, cyanide, and 4,4,4-trifluoro-1-(2-thienyl)-1,3-butanedione; and (c) spectral studies on the Azotobacter R₃ fraction revealed that a substantial amount of the flavoprotein (non-heme iron) and cytochrome (a₂, a₁, b₁, c₄ and c₅) are reduced by the addition of l-glutamate.     

An inducible lactone hydrolase yielding 2,5-diphenyl-3-hydroxy-4-oxo-2-hexendioic acid from pulvinic acid

The metabolism of vulpinic acid by an unclassified soil micro-organism was studied. A new compound, 2,5-diphenyl-3-hydroxy-4-oxo-2-hexendioic acid (DHOHA) was isolated from the reaction mixture of a cell-free preparation and pulvinic acid. The existence of a hydrolase which catalyses the conversion of vulpinic acid to pulvinic acid was detected in cell-free preparation, and an inducible lactone hydrolase capable of converting pulvinic acid to DHOHA was purified 130-fold and characterized. This enzyme had a MW of ca 34 000, a K_m for pulvinic acid at pH optimum (pH 7.0) less than 10 ^{? 6} M, pI = 5.0, and was inhibited by p-chloromercuriphenylsulfonate and diethylpyrocarbonate. The enzyme was highly specific for pulvinic acid. The initial degradative steps proposed for this organism are vulpinic acid → pulvinic acid → DHOHA.     

In Vitro ATP Regeneration from Polyphosphate and AMP by Polyphosphate:AMP Phosphotransferase and Adenylate Kinase from Acinetobacter johnsonii 210A

In vitro enzyme-based ATP regeneration systems are important for improving yields of ATP-dependent enzymatic reactions for preparative organic synthesis and biocatalysis. Several enzymatic ATP regeneration systems have been described but have some disadvantages. We report here on the use of polyphosphate:AMP phosphotransferase (PPT) from Acinetobacter johnsonii strain 210A in an ATP regeneration system based on the use of polyphosphate (polyP) and AMP as substrates. We have examined the substrate specificity of PPT and demonstrated ATP regeneration from AMP and polyP using firefly luciferase and hexokinase as model ATP-requiring enzymes. PPT catalyzes the reaction polyP_n + AMP → ADP + polyP_n−1. The ADP can be converted to ATP by adenylate kinase (AdK). Substrate specificity with nucleoside and 2′-deoxynucleoside monophosphates was examined using partially purified PPT by measuring the formation of nucleoside diphosphates with high-pressure liquid chromatography. AMP and 2′-dAMP were efficiently phosphorylated to ADP and 2′-dADP, respectively. GMP, UMP, CMP, and IMP were not converted to the corresponding diphosphates at significant rates. Sufficient AdK and PPT activity in A. johnsonii 210A cell extract allowed demonstration of polyP-dependent ATP regeneration using a firefly luciferase-based ATP assay. Bioluminescence from the luciferase reaction, which normally decays very rapidly, was sustained in the presence of A. johnsonii 210A cell extract, MgCl₂, polyP_n=35, and AMP. Similar reaction mixtures containing strain 210A cell extract or partially purified PPT, polyP, AMP, glucose, and hexokinase formed glucose 6-phosphate. The results indicate that PPT from A. johnsonii is specific for AMP and 2′-dAMP and catalyzes a key reaction in the cell-free regeneration of ATP from AMP and polyP. The PPT/AdK system provides an alternative to existing enzymatic ATP regeneration systems in which phosphoenolpyruvate and acetylphosphate serve as phosphoryl donors and has the advantage that AMP and polyP are stabile, inexpensive substrates.     

Investigation of structural effects and behaviour of Pseudomonas aeruginosa amidase encapsulated in reversed micelles

The acetohydroxamic acid synthesis reaction was studied using whole cells, cell-free extract and purified amidase from the strains of Pseudomonas aeruginosa L10 and AI3 entrapped in a reverse micelles system composed of cationic surfactant tetradecyltrimethyl ammonium bromide. The specific activity of amidase, yield of synthesis and storage stability were determined for the reversed micellar system as well as for free amidase in conventional buffer medium. The results have revealed that amidase solutions in the reverse micelles system exhibited a substantial increase in specific activity, yield of synthesis and storage stability. In fact, whole cells from P. aeruginosa L10 and AI3 in reverse micellar medium revealed an increase in specific activity of 9.3- and 13.9-fold, respectively, relatively to the buffer medium. Yields of approximately 92% and 66% of acetohydroxamic acid synthesis were obtained for encapsulated cell free extract from P. aeruginosa L10 and AI3, respectively. On the other hand, the half-life values obtained for the amidase solutions encapsulated in reverse micelles were overall higher than that obtained for the free amidase solution in buffer medium. Half-life values obtained for encapsulated purified amidase from P. aeruginosa strain L10 and encapsulated cell-free extract from P. aeruginosa strain AI3 were of 17.0 and 26.0 days, respectively. As far as the different sources biocatalyst are concerned, the data presented in this work has revealed that the best results, in both storage stability and biocatalytic efficiency, were obtained when encapsulated cell-free extract from P. aeruginosa strain AI3 at w₀ of 10 were used. Conformational changes occurring upon encapsulation of both strains enzymes in reverse micelles of TTAB in heptane/octanol were additionally identified by FTIR spectroscopy which clarified the biocatalysts performances.     

Microbial transformation of ginsenoside Rg3 to ginsenoside Rh2 by <Emphasis Type="Italic">Esteya vermicola</Emphasis> CNU 120806

In the present investigation, we successfully employed a cell-free extract of Esteya vermicola CNU 120806 to convert ginsenoside Rg3 to Rh2. Three important factors including pH, temperature and substrate concentration were optimized for the preparation of Rh₂. The optimal condition was obtained as follows: 50°C, pH 5.0 and substrate concentration of 3 mg ml⁻¹. The yield of conversion was up to 90.7%. In order to identify the specificity of the β-glucosidase activity of Esteya vermicola CNU 120806, ginsenoside Re (protopanaxatriol saponins) was treated under the same reaction system. Interestingly, no new metabolite was generated, which elucidated that the enzymatic process only occurred by hydrolysis of the terminal glucopyranosyl moieties at the C-3 carbon of ginsenoside Rg₃. The crude enzyme extract can be used for commercial ginsenoside Rh₂ preparation.     

Manganese Oxidation by Spores and Spore Coats of a Marine Bacillus Species

Bacillus sp. strain SG-1 is a marine bacterial species isolated from a near-shore manganese sediment sample. Its mature dormant spores promote the oxidation of Mn²⁺ to MnO₂. By quantifying the amounts of immobilized and oxidized manganese, it was established that bound manganese was almost instantaneously oxidized. When the final oxidation of manganese by the spores was partly inhibited by NaN₃ or anaerobiosis, an equivalent decrease in manganese immobilization was observed. After formation of a certain amount of MnO₂ by the spores, the oxidation rate decreased. A maximal encrustment was observed after which no further oxidation occurred. The oxidizing activity could be recovered by reduction of the MnO₂ with hydroxylamine. Once the spores were encrusted, they could bind significant amounts of manganese, even when no oxidation occurred. Purified spore coat preparations oxidized manganese at the same rate as intact spores. During the oxidation of manganese in spore coat preparations, molecular oxygen was consumed and protons were liberated. The data indicate that a spore coat component promoted the oxidation of Mn²⁺ in a biologically catalyzed process, after adsorption of the ion to incipiently formed MnO₂. Eventually, when large amounts of MnO₂ were allowed to accumulate, the active sites were masked and further oxidation was prevented.