Defoliation induces fructan 1-exohydrolase II in Witloof chicory roots. Cloning and purification of two isoforms, fructan 1-exohydrolase IIa and fructan 1-exohydrolase IIb. Mass fingerprint of the fructan 1-exohydrolase II enzymes.

The cloning of two highly homologous chicory (Cichorium intybus var. foliosum cv Flash) fructan 1-exohydrolase cDNAs (1-FEH IIa and 1-FEH IIb) is described. Both isoenzymes could be purified from forced chicory roots as well as from the etiolated "Belgian endive" leaves where the 1-FEH IIa isoform is present in higher concentrations. Full-length cDNAs were obtained by a combination of reverse transcriptase-polymerase chain reaction (PCR), PCR and 5'- and 3'-rapid amplification of cDNA ends using primers based on N-terminal and conserved amino acid sequences. 1-FEH IIa and 1-FEH IIb cDNA-derived amino acid sequences are most homologous to a new group of plant glycosyl hydrolases harboring cell wall-type enzymes with acid isoelectric points. Unlike the observed expression profiles of chicory 1-FEH I, northern analysis revealed that 1-FEH II is expressed when young chicory plants are defoliated, suggesting that this enzyme can be induced at any developmental stage when large energy supplies are necessary (regrowth after defoliation).

Purification and properties of NAD-dependent glutamate dehydrogenase from Phycomyces spores.

The NAD-dependent glutamate dehydrogenase from Phycomyces spores was purified more than 300-fold. Estimation of Mr by gel filtration gave a value of 98,000 whereas after SDS-PAGE one major band of Mr 54,000 was found, suggesting that the enzyme is a dimer. The enzyme was virtually dependent on the presence of AMP for activity and showed half-maximal activation at 9.5 and 43 microM-AMP in the direction of animation and deamination respectively. ADP was nearly as effective at 20-fold higher concentrations. Other nucleotide monophosphates were ineffective and nucleoside triphosphates were slightly inhibitory. Hyperbolic kinetics were found for all substrates yielding Km values of about 10 mM for ammonium, 1 mM for 2-oxoglutarate and 0.1 mM for NADH in the direction of amination, and 10 mM for glutamate and 0.7 mM for NAD in the direction of deamination.

Glycerol formation after the breaking of dormancy of Phycomyces blakesleeanus spores. Role of an interconvertible glycerol-3-phosphatase.

The breaking of dormancy of Phycomyces blakesleeanus spores by a heat shock was followed by a transient production of glycerol, which culminated within 5-10 min and was terminated at 20 min. Extracts of spores contained a magnesium-dependent glycerol-3-phosphatase active on both L-glycerol 3-phosphate and dihydroxyacetone phosphate but having more affinity for the first substrate than for the second. In extracts from dormant spores, the phosphatase was profoundly inhibited by physiological concentrations of inorganic phosphate, which induced cooperativity for the substrate, whereas the enzyme from heat-activated spores was much less inhibited and this difference in kinetic properties persisted after gel filtration of the enzymic preparation. When measured at 1 mM phosphate and 0.1 mM glycerol 3-phosphate, the phosphatase activity was undetectable in dormant spores, increased sharply during the heat treatment and the following 5 min at 25 degrees C, then fell again to a low value by 20 min. A similar transient activation of the enzyme was observed following the breaking of dormancy by incubation of the spores in the presence of 0.1 M ammonium acetate. Incubation of a cell-free extract or of the partially purified glycerol-3-phosphatase in the presence of ATP-Mg and the catalytic subunit of cyclic-AMP-dependent protein kinase released the enzyme from inhibition by phosphate and endowed it with the same kinetic properties as did the heat treatment of the spores. It appears therefore most likely that phosphorylation of glycerol-3-phosphatase by cyclic-AMP-dependent protein kinase causes its activation and that this transient process explains the equally transient formation of glycerol by the spores after the heat shock.

Trehalase activity and cyclic AMP content during early development of Mucor rouxii spores.

Incubation of Mucor rouxii sporangiospores in complex medium under aerobic conditions resulted in a transient 20-fold increase in trehalase activity. Maximum activity was reached after 15 min. Simultaneously, the cyclic AMP (cAMP) content increased approximately eightfold, reaching a maximum within 10 min. Increases in trehalase activity and cAMP content were also observed under anaerobic conditions (CO2). The extent of trehalase activation and the changes in cAMP content, during both aerobic and anaerobic incubation, varied with the medium used. Trehalase was activated in vitro by a cAMP- and ATP-dependent process. An even faster activation was obtained when cAMP was replaced by the catalytic subunit of beef heart protein kinase. The coincidence of, and the correlation between, increased cAMP contents and trehalase activities support the involvement of a cAMP-dependent phosphorylation in the in vivo regulation of trehalase activity.

Trehalose metabolism in dormant and activated spores of Phycomyces blakesleeanus Burgeff.

Evidence is obtained for the existence of two different localizations of trehalase (α,α-trehalose glucohydrolase, EC 3.2.1.28) in Phycomyces spores: one inside the cell, and one in the periplasmic region. The latter enzyme is sensitive to 0.1 mol l(-1) HCl treatment and its activity can be regulated by external pH changes. The periplasmic form of the enzyme is involved in the metabolism of added labelled trehalose. This sugar is hydrolyzed externally to glucose which is found mainly in the incubation medium and which is partly absorbed by the spores. During incubation trehalose leaks out from both dormant and activated spores and is subsequently hydrolyzed to glucose. The intracellular trehalase is probably involved in the breakdown of endogenous trehalose in spores. After heat activation the hydrolysis of endogenous trehalose is stimulated even without an important increase in activity of intracellular trehalase. Additional treatments which break dormancy of spores without a significant activation of trehalase are the following: heating of HCl-treated spores and treatment of spores with reducing substances (e.g. Na2S2O4 and NaHSO3).

Cell wall carbohydrates in Phycomyces blakeslesanus Burgeff.

The carbohydrate composition of the cell walls from spores, mycelium and sporangiophores of Phycomyces blakesleeanus was analyzed. Spore wall polysaccharides contained over 50% glucose, about 20% uronic acids, 10% mannose and 10% amino-sugars. During the growth of the hyphae amino-sugars became the main carbohydrate (45%); uronic acids contributed some 25%, glucose and fructose 10% and galactose nearly 6%. Sporangiophores contained almost 90% aminosurgars and some 6% uronic acids. Traces of rhamnose were found in all wall preparations. A similar picture emerged from studies on the incorporation of [U-14C]-glucose into wall materials. Furthermore we looked for a GDP-fucose synthesizing system and found an increasing activity during early germination. This rise in activity was inhibited by cycloheximide but only by 5-fluorouracil.

Effect of 5-fluorouracil and cycloheximide on the early development of Phycomyces blakesleeanus spores and the activity of N-acetylglucosamine synthesizing enzymes.

The development of germinating Phycomyces spores was not inhibited by 5-fluorouracil (1mM) until the emergence of the germination tube. Fluorouracil was incorporated into RNA as efficiently as uracil; it did not inhibit the synthesis of proteins and the increase in respiratory activity during early development. Cycloheximide inhibited development as well as the increase in respiration and protein synthesis. This suggested that protein synthesis or some other cycloheximide dependent process, but no mRNA synthesis, was needed for the first developmental stages. The activity of two enzymes involved in the synthesis of N-acetylglucosamine increased markedly during germination. THis increase was inhibited by both 5-fluorouracil and cycloheximide; this suggested that those enzymes were synthesized on mRNA formed during germination.

Glucose metabolism of dormant and heat-activated spores of Phycomyces blakesleeanus burgeff.

The metabolism of [(14)C]glucose has been studied in Phycomyces spores during dormancy, activation, and the initial stages of germination. Dormant spores are able to take up and metabolize exogenous glucose into different products; the major part of it goes to trehalose synthesis (up to 60% when the external glucose concentration exceeds 10(-3) M). During activation itself (i.e. a prolonged treatment at 50°) there is a general increase of glucose uptake and metabolism, without major changes in the relative rates of (14)C-label distribution in the different fractions (as compared to the metabolism of dormant spores), except for a drop in material insoluble in 80% ethanol and a still higher percentage (73%) going to trehalose synthesis. In the early hours of germination we find an enhancement of the uptake and metabolism of glucose. Trehalose synthesis is practically switched off within 2 h whereas the major part of glucose (65%) is metabolized to CO2 and ethanol-insoluble proteinaceous material.