Polyamine oxidation by enzymes from Hordeum vulgare and Pisum sativum seedlings

The properties of the amine oxidases of barley leaves and pea seedling cotyledons have been compared using a colorimetric assay in which the hydrogen p     

Effects of anaerobiosis on carbohydrate oxidation by roots of Pisum sativum

The aim of this work was to discover the effects of anaerobiosis on the breakdown of sugars by the apical 6 mm of the roots of 5-day-old seedlings of Pisum sativum. Estimates of the maximum catalytic activities of alcohol dehydrogenase, lactate dehydrogenase, phosphoenolpyruvate carboxylase and NADP-specific malic enzyme showed them to be comparable to that of phosphofructokinase. Metabolism of sucrose-[U-¹⁴C] by excised apices was restricted by anoxia mainly to conversion to ethanol, CO₂ alanine and glycolytic intermediates. Measurements of metabolites over a period of 240 min after transfer of excised apices to nitrogen showed a marked and continual accumulation of ethanol, a smaller continual accumulation of alanine, a small initial rise in lactate and no detectable accumulation of malate or pyruvate. The rates of CO₂ production, of accumulation of ethanol and alanine, and of the labelling of these compounds by sucrose-[¹⁴C] declined markedly during the first 240 min of anaerobiosis. The conclusion is that under anaerobic conditions carbohydrate metabolism in the pea root apex is largely restricted to alcoholic fermentation, and, to a lesser degree, to alanine production.     

Lipoxygenase in dark-grown Pisum sativum

Lipid oxidizing activity has been detected in acetone powders from both dark- and light-grown dwarf pea seedlings. This activity has been shown by several methods to be due to lipoxygenase. The enzyme from dark-grown seedlings has been purified 5·7-fold by ammonium sulphate precipitation and gel filtration. CM-cel-lulose chromatography of the purified enzyme yielded four active fractions. The properties of the four lipoxy-genase isoenzymes are described.     

Homoserine dehydrogenase in Pisum sativum and Ricinus communis

Homoserine dehydrogenase was extracted from Ricinus communis and Pisum sativum. The kinetic parameters of the forward and reverse reactions were determined. In the forward reaction only the enzyme from Ricinus is inhibited by threonine. The response to K⁺ is different for the enzyme from the two sources.     

Separation and properties of two ornithine carbamoyltransferases from Pisum sativum seedlings

Two ornithine carbamoyltransferases were separated from pea seedlings on DEAE-cellulose. The two enzymes have different pH-activity curves. Lineweaver-Burk plots for both enzymes are linear for carbamoyl phosphate and the Michaelis constants are of the same order of magnitude. The plot for ornithine was linear for one enzyme but a concave down for the other indicating negative cooperativity. The presence of two ornithine carbamoyltransferases is consistent with the presence of two pools for ornithine (one catabolic and the other anabolic previously suggested to exist in plant materials.     

De novo synthesis of acetylcholinesterase in roots of Pisum sativum

Pisum sativum seeds contain a conserved acetylcholinesterase (AChE) which is active during the early stages of germination. The enzyme activity soon disappears and reappears after 72 hr of germination. A protein devoid of catalytic ability, but exhibiting similar chromatographic and electrophoretic properties as the active AChE, could be detected after 24 hr of germination. The pattern of incorporation of labelled amino acids into AChE and the influence of cycloheximide revealed that the AChE found in the roots from 72 hr onwards was entirely new. During this period of growth, the AChE protein accounts for 4–10% of the total proteins in the root tissue.     

Sucrose metabolism by roots of Pisum sativum

The aim of this work was to relate [¹⁴C]-sucrose metabolism to the activities of sucrose synthetase and acid and alkaline invertases in roots of Pisum sativum. We fed [U-¹⁴C]-sucrose to 5-day-old plants and then excised the apical 6 mm of the roots and dissected the regions 6–24 mm from the root apices into stele and cortex. The detailed distribution of ¹⁴C in these parts of the roots was determined at the end of the feeding period and after a chase. The data indicate that sucrose arriving in the stele is divided between storage, conversion to polysaccharide, and consumption in respiration, whereas sucrose arriving in the rest of the root is used in respiration or converted to polysaccharide or hexose so rapidly that little is stored. Fractionation of carefully prepared extracts of pea roots, tubers of Solanum tuberosum, and spadices of Arum maculatum showed that sucrose synthetase was recovered in the soluble fraction. The results are discussed in relation to the roles of the aforementioned enzymes.     

Purification and properties of glycollate oxidase from Pisum sativum leaves

A rapid and efficient method for the isolation of glycollate oxidase from pea leaves is described. The method utilizes the unusually high isoelectric point (pH 9·6) which has been determined for the enzyme using isoelectric focusing. The enzyme is apparently homogeneous by polyacrylamide gel electrophoresis and has a MW of ca 100000. Some properties of the enzyme are described.     

Chromatographic analysis of isoflavonoid accumulation in stressed Pisum sativum

High-performance liquid chromatography has been used to study isoflavonoid accumulation in copper(II) chloride stressed Pisum sativum. Liquiritigenin, isoliquiritigenin, formononetin, pseudobaptigenin, afrormosin and anhydropisatin have been identified in addition to the pterocarpan phytoalexin pisatin. The relationships of these metabolites to isoflavonoid biosynthesis and stress response in pea are discussed.     

Characterization of chromatin from Triticum aestivum

Chromatin was isolated from wheat seedlings using chromatin aggregation in the presence of cations and dispersion in the absence of these cations. The preparation contained some contaminating RNA. The protein, DNA and RNA moieties were separated from each other by ion exchange chromatography on hydroxyapatite in the presence of 5 M urea and 2 M NaCl. The histone and non-histone proteins were subsequently separated on CM-cellulose and the histones partially separated from one another. The various protein fractions were characterized by urea-acetic acid and sodium dodecyl sulphate polyacrylamide gel electrophoresis.     

Separate monophenolase and o-diphenolase enzymes in Triticum aestivum

Monophenolase and o-diphenolase activities of polyphenol oxidase are usually thought to be a part of the same enzyme complex. It has now been demonstrated that the two catalytic activities of the polyphenol oxidase of wheat grains are separable and reside in different enzymes. The electrophoretically separated monophenolase enzyme showed specificity only for monophenol (l-tyrosine) after its elution from acrylamide gels. Further, this enzyme is confined to the endosperm tissue and is undetectable in the embryonic region of the seedling.     

Peroxidase changes during the cessation of elongation in Pisum sativum stems

The cessation of cell elongation in intact P. sativum epicotyls is accompanied by an increase in both soluble and cell wall peroxidases. These pero     

Proteolytic and trypsin inhibitory activities in extracts of germinating Pisum sativum seeds

A rise in azoglobulytic activity and a fall in trypsin-inhibitory activity has been detected in extracts of germinating pea seeds free from microbial infection. By investigating the subcellular distribution of protease activity, trypsin-inhibitory activity and the effect of the inhibitor on endogenous protease activity, no convincing evidence could be obtained to suggest that the trypsin-inhibitory activity was involved in the regulation of proteases during germination.     

RNA polymerase activity in isolated Triticum aestivum embryos during germination

A gradual decrease in the total activity of DNA-dependent RNA polymerase in isolated wheat embryos began 6 hr after germination and continued for up to 48 hr. DEAE-cellulose column chromatography indicated the presence of two RNA polymerase fractions (major and minor) in the resting embryos, only one of which (major) could be detected in the embryos germinated for 48 hr. The major RNA polymerase fraction was tentatively identified as nucleoplasmic (RNA polymerase II).     

Identification of cadaverine in Pisum sativum

Cadaverine has been identified in normal young peas and in saline grown (necrotic) peas by GLC and MS. Its concentration was at least of 5 gm/g fresh plant in both cases. Analysis of the alkaloidal extracts failed to reveal any lupinine, anabasine or other pyridine alkaloids in normal or necrotic, salt grown, peas.     

Purification and properties of sucrose-6-phosphatase from Pisum sativum shoots

Sucrose-6-phosphatase from pea shoots, which was purified to homogeneity, consists of two similar sub-units each with an MW of about 55 000. The pH optimum was at 6.8; the K_m for sucrose-6-phosphate was 250 μM and the K_m for magnesium was 175 μM. The enzyme was specific for sucrose-6-phosphate and was not inhibited by sucrose except at very high concentrations.     

DNA polymerase activity and DNA synthesis in roots of pea (Pisum sativum) seedlings

Soluble DNA polymerase (DNA polymerase-α) and chromatin-bound DNA polymerase (DNA polymerase-β) have been assayed in serial sections cut from the roots of 5-day-old pea seedlings. The activity of DNA polymerase-α is high in regions of the root which exhibit high rates of DNA replication, and declines during cell differentiation and maturation. The activity of DNA polyrnerase-β is low in cells which show high rates of DNA replication, and increases during differentiation and maturation.     

Control of glutamate dehydrogenase from Pisum sativum roots

-Glutamate dehydrogenase (GDH) was found in soluble and particulate (mitochondrial) fractions of pea roots. The activity of NADH-dependent GDH in fresh mitochondrial extract was increased about 10-fold by addition of zinc, manganese or calcium, but high concentrations of zinc were inhibitory. During storage, GDH activity of the mitochondrial extract slowly increased. The NADH activity was inhibited by citrate and other chelating agents. NADH-dependent reductive amination was also inhibited by glutamate, the product of the reaction; by contrast NADPH dependent activity was relatively unaffected by zinc, chelating agents or glutamate. Sensitivity (of NADH-GDH) to glutamate was lost on purification, but was restored when the enzyme was immobilized by binding to an insoluble support (AE cellulose). Glutamate appears to change the affinity of the enzyme for 2-oxoglutarate.     

Properties of acetylcholinesterase from Pisum sativum

Acetylcholinesterase (AChE) from Pisum sativum purified 28 fold showed two closely moving protein bands on polyacrylamide gel electrophoresis, both     

Threonine-sensitive aspartate kinase and homoserine dehydrogenase from Pisum sativum

Aspartate kinase and two homoserine dehydrogenases were partially purified from 4-day-old pea seedlings. A sensitive method for measuring aspartate kinase activity is described. Aspartate kinase activity was dependent upon ATP, Mg²⁺ or Mn²⁺, and aspartate. The aspartate kinase was inhibited in a sigmoidal manner by threonine and K_i for threonine was 0·57 mM. The enzyme could be desensitized to the inhibitor and threonine protected the enzyme against thermal inactivation. Aspartate kinase activity was enhanced by isoleucine, valine and alanine. Homoserine, methionine and lysine were without effect. The homoserine dehydrogenase activity which was associated with aspartate kinase during purification could be resolved into two peaks by gel filtration. The activity of both peaks was inhibited by aspartate and cysteine and one was inhibited by threonine.