Adenylate and Nicotinamide Nucleotides in Developing Wheat Grains

Contents of ATP and ADP per grain increased during grain developmentup to 21–35 d after anthesis (DAA). A sharp increase inAMP level was observed at 42 DAA. Of the four nicotinamide nucleotides,NAD was most abundant. Energy charge values were more than 0.7during active grain filling stages and less than 0.6 when rateof starch deposition was low. Triticum aestivum L. (Wheat), adenylates, nicotinamide nucleotides, energy charge, grain, starch     

The response and recovery of nitrogen fixation activity in soybean to water deficit at different reproductive developmental stages

Soybean (Glycine max [L.] Merr.) N₂ fixation is a primary plant mechanism responsible for meeting plant-N demand during seed development. Nitrogen fixation is recognized as a drought-sensitive mechanism; however, N₂ fixation response to water deficit and N₂ fixation recovery at different reproductive stages are not well documented. We tested the hypothesis that water deficit during late reproductive stages would inhibit N₂ fixation and lead to the breakdown of essential leaf proteins and an inability to recover N₂ fixation. Acetylene reduction activity (ARA) and N redistribution response to a 5-d drought period at flowering (R2), early seed fill (R5), and late seed fill (R6) were evaluated in one genotype (Hendricks, maturity group 0). Control plants maintained high rates of nodule activity until late seed fill. Plants drought stressed at R2 and R5 recovered ARA after rewatering and in some cases had higher nitrogenase activity than control plants during mid-seed fill. Recovery of ARA on plants stressed at R2 and R5 was associated with higher shoot N concentration than control plants at maturity. Drought stress at R6 reduced ARA, and the inability to recover ARA after stress alleviation at R6 resulted in decreased individual seed mass, which was likely caused by an acceleration of leaf N redistribution and a shorter seed-fill period. Results emphasized the importance of soybean N₂ fixation during late seed development on seed yield and that the ability to recover N₂ fixation following drought is dependent upon crop developmental stage.     

Effect of shortened photosynthetic period on C-assimilate translocation and partitioning in reproductive soyeans

Starch accumulation rate in leaves of vegetative soybeans is inversely related to the length of the daily photosynthetic period. However, it is not known whether a similar response would be observed during reproductive growth. Soybeans (Glycine max L. Merr. cv Amsoy 71) were grown to three stages of reproductive growth (beginning seed, mid seed-fill, and late seed-fill) under 12-hour daylengths, and then shifted to 6-hour photosynthetic periods (12-hour photoperiods) for 4 days. One and 4 days after treatment, a mid-canopy leaf was pulsed with ¹⁴CO₂, and sampled for radiolabeled starch and water-soluble compounds at 0.5, 1, 3, 9, and 21 hours after labeling.

Plants exposed to the 6-hour photosynthetic periods at the beginning seed stage retained and incorporated significantly more label as starch than did those given 12-hour photosynthetic periods. However, plants exposed to the shortened photosynthetic periods at the late seed-fill stage partitioned less label into starch. Plants exposed at mid seed-fill gave a variable response.

Shortened photosynthetic periods resulted in preferential partitioning of recently fixed carbon to the seed at the expense of the pod wall. The results of these experiments suggest that the increased sink demand present during late reproductive growth may be of greater importance in control of leaf starch accumulation than is the length of the daily photosynthetic period.

     

Adenine nucleotide contents in callus-forming potato tuber discs with different respiratory characteristics

ATP content (per g fresh weight) and energy charge were higher during incubation at 8°C than at 28°C in the early stages of callus induction of potato tuber discs ( Solanum luberosum L. cv. Bintje). After a transfer from 28°C to 8°C, ATP content increased while a sharp decline in ATP content was observed after a transfer from 8°C to 28°C. ADP and AMP pools did not increase correspondingly. When the callus discs had entered the logarithmic growth phase, the energy charge was maintained within relatively narrow limits (0.77–0.80) at all culture temperatures.     

Calcium,phosphorus and adenylate levels and Na(+)-K(+)-ATPase activities of prawn,Macrobrachium nipponense,during the moult cycle

Changes in calcium and phosphorus concentrations, adenylate (AMP, ADP and ATP) levels, and ratios and ATPase activities of Macrobrachium nipponense were investigated during the moult cycle. Ca level in the exoskeleton was lowest in early postmoult (stage A), increasing at stages B and through intermoult (stage C) and peaking in premoult (stage D1 and D2). The P concentrations in the exoskeleton and muscle in late premoult and early postmoult stages were higher than those at other moult stages, and were lowest in the intermoult. Muscle adenylate energy charge (AEC) changed with moult stages, and was in agreement with the change in inorganic P level in the muscle. AEC may be a direct indicator of energy metabolic activity during the moult cycle. ATP/ADP and ATP/AMP ratios in premoult and postmoult stages were higher than that in intermoult stage. Na(+)-K(+)-ATPase activities of gills, muscles and hepatopancreatic of prawns were higher in early postmoult and late premoult animals, whereas they were lower in late postmoult, intermoult and early premoult animals. Gill residual ATPase activity was significantly higher in postmoult animals, while the peak value of hepatopancreatic residual ATPase activity appeared in intermoult stage.     

Adenylic nucleotides and energy charge during the embryonic development of Bufo arenarum

The contents of ATP, ADP and AMP were determined by HPLC and adenylic energy charge (AEC) was estimated during different stages of the embryonic development of Bufo arenarum up to the tailbud stage. All the developmental stages studied showed a high ATP content (about 1.04-1.48 nmol/emb.). The concentration of ADP was low (0.025-0.041 nmol/emb.) but rose slightly at the neural tube stage. AMP was undetectable before the tailbud stage. AEC values were almost constant (about 0.987-0.992) throughout the period studied. Only a fall at the tailbud stage could be detected which can be related to this more advanced cellular differentiation stage.     

Changes in protein and carbohydrate content during development of seeds and siliquas of rapeseed (Brassica napus L.)

Abstract

A study was made on the changes observed in the protein, starch and soluble sugar content during development of siliquas and seeds of rapeseed grown in central Italy.

Concentration of starch and soluble sugars in the seed increases to 75 per cent dry matter during the first few weeks of pod development and then drops to minimum values. The protein increases steadily until maturity, when a level of 0.85 mg per seed is reached, equivalent to 18 per cent dry matter. The protein and starch in the hull? decrease continuously during development, while in the initial stages the soluble sugars are accumulated until they account for 33 per cent dry matter, after which they decline towards maturity.     

Chronic environmental pollution alters adenylate levels in needles and fine roots of Scots pine

Contents of ATP, ADP, AMP, inorganic phosphate, and values of ATP/ADP ratio, adenylate energy charge (AEC), phosphorylation potential (PP) and adenylate kinase activity were analysed in needles and fine roots of Scots pine trees grown at the polluted and control (free of acute air pollution) site. Also chemical properties of the soil and mineral elements in needles from both sites were analysed. In comparison with the control, developing needles from the polluted site contained less ATP, the same amount of ADP and more AMP, and had lower values of ATP/ADP, AEC and PP. In one-year-old needles from the polluted site no change or a decrease in ATP was recorded, while ADP decreased, AMP increased, AEC did not change, and ATP/ADP ratio and PP were higher. In fine roots from the polluted site AMP level was higher, while ATP, ADP, ATP/ADP ratio, PP and AEC were lower than in the control.     

Adenine nucleotides as allosteric effectors of pea seed glutamine synthetase

The effects of adenine nucleotides on pea seed glutamine synthetase (EC 6.3.1.2) activity were examined as a part of our investigation of the regulation of this octameric plant enzyme. Saturation curves for glutamine synthetase activity versus ATP with ADP as the changing fixed inhibitor were not hyperbolic; greater apparent Vmax values were observed in the presence of added ADP than the Vmax observed in the absence of ADP. Hill plots of data with ADP present curved upward and crossed the plot with no added ADP. The stoichiometry of adenine nucleotide binding to glutamine synthetase was examined. Two molecules of [gamma-32P]ATP were bound per subunit in the presence of methionine sulfoximine. These ATP molecules were bound at an allosteric site and at the active site. One molecule of either [gamma-32P]ATP or [14C]ADP bound per subunit in the absence of methionine sulfoximine; this nucleotide was bound at an allosteric site. ADP and ATP compete for binding at the allosteric site, although ADP was preferred. ADP binding to the allosteric site proceeded in two kinetic phases. A Vmax value of 1.55 units/mg was measured for glutamine synthetase with one ADP tightly bound per enzyme subunit; a Vmax value of 0.8 unit/mg was measured for enzyme with no adenine nucleotide bound at the allosteric site. The enzyme activation caused by the binding of ADP to the allosteric sites was preceded by a lag phase, the length of which was dependent on the ADP concentration. Enzyme incubated in 10 mM ADP bound approximately 4 mol of ADP/mol of native enzyme before activation was observed; the activation was complete when 7-8 mol of ADP were bound per mol of the octameric, native enzyme. The Km for ATP (2 mM) was not changed by ADP binding to the allosteric sites. ADP was a simple competitive inhibitor (Ki = 0.05 mM) of ATP for glutamine synthetase with eight molecules of ADP tightly bound to the allosteric sites of the octamer. Binding of ATP to the allosteric sites led to marked inhibition.     

Interrelationships between the membrane-bound ATP-dependent energy systems of the gastric mucosa and the gastric cytoprotective effect of beta-carotene on the development of gastric mucosal damage produced by 0.6 M HCl in rats

The effects of different doses (0.01-0.1-1.0-10.0/mg/kg-1) of beta-carotene were studied on gastric secretory responses of 4 hr pylorus-ligated rats: development of gastric mucosal damage (as assessed by number and severity of lesions) produced by intragastric administration of 0.6 M HCl; tissue level of adenosine triphosphate (ATP), adenosine diphosphate (ADP), adenosine monophosphate (AMP), adenylate pool (ATP + ADP + AMP), ratio of ATP X ADP-1, "energy charge" (ATP + 0.5 ADP X X (ATP + ADP + AMP)-1) (during the development of gastric mucosal damage by 0.6 M HCl and of gastric cytoprotection by beta-carotene. It was found that beta-carotene did not decrease the gastric secretory responses of 4 hr pylorus-ligated rats; The development of gastric mucosal damage could be decreased dose-dependently by the administration of beta-carotene; the ATP transformation could be decreased by beta-carotene; the tissue levels of cAMP and AMP could be increased significantly and dose-dependently by beta-carotene; the ratio of ATP X ADP-1 could be increased significantly and dose-dependently by beta-carotene; the values of adenylate pool and "energy charge" remained unchanged.(ABSTRACT TRUNCATED AT 250 WORDS)     

5''-ADENINE MONONUCLEOTIDES TN SYNAPTOSOMAL PREPARATIONS FROM GUINEA PIG NEOCORTEX: THEIR CHANGE ON INCUBATION, SUPERFUSION AND STIMULATION

–(l) The contents of potassium and of ATP, ADP and AMP of homogenates of guinea pig neocortex in 0.32 M-SUCROSE, and of synaptosomal preparations derived therefrom, were determined and effects of incubation, superfusion and stimulation of the preparation were examined. The synaptosome preparations in M-SUCTOSe carried a smaller content of 5′-nucleotide per unit protein than did the homogenate from which they were derived. However, the proportion of synaptosomal nucleotides present as ATP was markedly greater than in the homogenate as a whole, the adenylate energy-charge being 83% greater in the synaptosomes than in the homogenate. Dilution of the synaptosomal preparation from the 1 M-sucrose to isotonic sucrose, decreased the contcnt of ATP per unit protein, but did not change the sum ATP + ADP + AMP. (2) Examined as deposited beds during 5 to 20 min incubation in oxygenated glucose-bicarbonate salines, synaptosomal K content and adenylate energy charge increased. These changes were sustained during a subsequent 40 min of incubation and also during superfusion. During such continued superfusion, electrical stimulation caused diminution of the ATP and the adenylate energy charge of the beds, as also did superfusion with fluids of increased K-content. (3) Lactate formation by the superfused beds was relatively stable during 30 min incubation. By electrical stimulation, the rate of lactate formation was increased by up to 30%. Increase in the potassium content of superfusion fluids could however increase lactate production 2.4-fold. The basis for these actions is discussed.     

Energy Metabolism of Rickettsia typhi: Pools of Adenine Nucleotides and Energy Charge in the Presence and Absence of Glutamate

The obligate intracellular bacterium Rickettsia typhi was examined for its ability to generate and maintain an adenylate energy charge in an extracellular environment. Freshly purified organisms were incubated, at 34 degrees C and pH 7.4, with or without glutamate and various other metabolites, and the levels of ATP, ADP, and AMP were determined. Of the metabolites tested, glutamate and glutamine were the most effective for the generation of ATP. In the presence of glutamate, there was a rapid increase in the level of ATP, followed by a moderate decrease during 150 min of incubation. The energy charge increased from a level of 0.2 to 0.5 to about 0.7 to 0.75, and then slowly declined to about 0.45 to 0.6. In the absence of glutamate, after an occasional initial surge in ATP level as the temperature was changed from 4 to 34 degrees C, there was a sharp decline in both ATP and energy charge (to 0.1 and sometimes to 0.01). The rickettsiae maintained their ability to regenerate their energy charge upon the addition of glutamate for about 30 min, but this ability declined with further incubation. In contrast to Escherichia coli, the decline in ATP in R. typhi was accompanied by a sharp increase in the level of AMP and the total adenylate pool. No adenine or adenosine was recovered from rickettsiae incubated with labeled AMP, ADP, or ATP. From these experiments and the demonstration reported elsewhere that rickettsiae transport the adenine nucleotides, it can be concluded that the adenylate energy charge in R. typhi is governed by the salvage of the adenine nucleotides rather than their unphosphorylated precursors. Thus, R. typhi undergoes greater shifts in energy charge than other bacteria, a phenomenon which may account for their instability in an extracellular environment. Under optimal conditions the adenylate energy charge of R. typhi approaches levels that border on those generally regarded as adequate for growth.     

Variations in the Adenylate Energy Charge During Phased Growth (Cell Cycle) of Candida utilis Under Energy Excess and Energy-Limiting Growth Conditions

The variations in the levels of adenine nucleotides during the phased growth (cell cycle) of the yeast Candida utilis growing under nitrogen, sulfate, or iron limitation with glycerol as carbon source have been determined. Synchronous cultures were obtained by the continuous phasing technique, and the results were compared with those of chemostat cultures growing at similar growth rates and under the same types of nutrient limitation. Whereas the chemostat experiments indicated only the average energy status of cultures growing at random, results from phased cultures showed that the adenylate energy charge, defined as (ATP + (1/2)ADP)/(ATP + ADP + AMP) (where ATP, ADP, and AMP signify adenosine 5'-triphosphate, -diphosphate, and -monophosphate, respectively), varied during the phased growth of the yeast. These variations were related to the stage of development of the cells and to the type of nutrient limitation. In every case the energy charge dropped to a low value during the first half of the phasing cycle (cell cycle). Whereas the energy charge was maintained at relatively high levels (ranging from 0.78 to 0.94), for sulfate- or nitrogen-limited cultures, it was very low when iron was the growth-limiting nutrient (0.44 to 0.78). In spite of the low energy charge, the yeast continued to grow under iron limitation. The main component of the adenylate pool of the iron-limited culture was ADP and not ATP as observed with other types of nutrient limitation. It is concluded that under iron limitation the growth of the organism is limited by energy and that under energy-limited growth the energy charge of a growing organism is maintained at low levels. The reason for maintaining a low energy charge in an energy-limited culture is discussed.     

Energy potential of the cerebral cortex in the pre-agonal and post-resuscitation period after acute blood loss

In experiments on dogs it was revealed that during the preagonal period, after a four-hour hypovolemic hypotension, the content of ATP was reduced in the gray matter of the brain by 38 percent, and of ADP and AMP increased by 121 percent and 875 percent, respectively. Reflecting these shifts the energy charge potential decreased from 0.931 to 0.733 (P less than 0.05). At the early and remote postrescucitation period the content of metabolites and of energy charge potential failed to differ from the initial level.     

Intracellular adenylate pools and protein degradation during zoosporangial differentiation in Allomyces arbuscula

In Allomyces arbuscula Butl., strain Bali, the ratio of protein to dry weight remained constant in exponentially growing but decreased in differentiating cultures. The adenylate pools (ATP, ADP, AMP) and energy charge which integrates them, increased during zoospore germination and stabilized around 0.9 during differentiation. The level of ATP increased early during the induction of zoosporangia for up to 1 h and then declined. The ADP and AMP remained low for most of the time except for a transient increase in ADP (first 30 min induction). The energy charge was low in spores. The rate of turnover of proteins during growth and differentiation was more or less similar for up to 1.5 h after transfer. Subsequently very little turnover of proteins occurred in the growing plants. In differentiating plants, the rate of degradation was maintained and by the end of the 4 h experimental period 30% of the vegetative proteins were degraded. The intracellular ammonium showed a peak between 30 to 60 min of induction and was higher in the differentiating mycelia than in actively growing plants, while the glutamate pool remained around 1 μmol (mg protein)⁻¹ in both types of plants. The physiological role of these protein degradation products is discussed.     

Changes in concentration of adenosine triphosphate and adenosine diphosphate in individual preimplantation sheep embryos.

Concentrations of ATP and ADP were measured in 156 sheep embryos by means of an ultramicrofluorescence assay. Stages of preimplantation development measured included unfertilized oocytes through blastocyst-stage embryos. ATP concentrations remained constant through the 8-cell stage; then ATP decreased significantly (p < 0.025) at the morula stage and remained low through the blastocyst stage. ADP concentrations did not change throughout the embryonic stages measured. Decreased levels of ATP with constant levels of ADP caused the ATP:ADP ratio to decrease significantly (p < 0.025) between the 8-cell and morula stages. We suggest that the increase in glucose uptake by sheep embryos observed at the morula stage of development may be due, in part, to a decrease in the ATP:ADP ratio.     

Control of Lipid Synthesis during Soybean Seed Development: Enzymic and Immunochemical Assay of Acyl Carrier Protein

During soybean seed (Glycine max, var Am Soy 71) development, the rate of lipid biosynthesis per seed increases greatly. As the seed reaches maturity, lipid synthesis declines. To study the controls over the oil synthesis and storage process, we have chosen acyl carrier protein (ACP) as a representative marker for the fatty acid synthetase pathway. We have quantitated soybean ACP levels by both enzymic and immunochemical methods. Escherichia coli acyl-ACP synthetase was used as an assay for enzymically active ACP. Total ACP protein was determined by immunoassay using antibodies prepared in rabbits against spinach ACP. These antibody preparations also bind ACP isolated from soybeans, allowing development of a radioimmunoassay based on competition with [³H]palmitoyl-ACP. The enzymic and immunochemical measurement of ACP at various stages of seed development have indicated that ACP activity and ACP antigen increase markedly in correlation with the in vivo increase in lipid synthesis. These results indicate that a major control over the increase in lipid synthesis arises through regulation of the levels of the fatty acid biosynthetic proteins. However, as the seed reaches maturity and lipid biosynthesis declines, ACP per seed remains relatively high. In the mature seed, we found that more than 95% of the ACP is localized in the cotyledons, less than 5% is in the axis, and less than 1% is in the seed coat.     

Rapid Increase in Adenosine 5'-Triphosphate during Early Wheat Embryo Germination

The ATP content of isolated wheat (Triticum aestivum L. var. Polk) embryos increases 5-fold during the first 30 minutes and 10-fold during the first hour of germination to 80% of maximum. The ATP level remains at approximately 800 nanomoles per gram of tissue during the next 15 hours. ADP, AMP, and total adenosine phosphates decrease between 1 and 6.5 hours, while adenylate energy charge increases from 0.6 to 0.8 and remains constant. The rapid increase in ATP during imbibition is consistent with the energy requirement for polyribosome formation and protein synthesis during the first hours of germination. A method for determining nanomole quantities of ATP in tissue extracts by isotopic dilution of γ-³²P-ATP in the hexokinase reaction is outlined.     

PURINE NUCLEOTIDE METABOLISM IN THE CAT BRAIN AFTER ONE HOUR OF COMPLETE ISCHEMIA

—Complete cerebral ischemia was produced in normothermic anaesthetized cats by clamping the innominate and the left subclavian arteries combined with lowering the blood pressure. After 1 h of ischemia, ATP was no longer present in detectable amounts. Total adenine nucleotides were reduced to 34 per cent of the normal level. The breakdown of guanine nucleotides was less marked, with small amounts of GTP still being present at the end of the ischemic period. In animals with signs of functional recovery after 3–7 h of recirculation, ATP was resynthesized to 62 per cent of the control level. Total adenine nucleotides increased to 68 per cent and the adenylate energy change—[ATP + 1/2 ADP]/[AMP + ADP + ATP]—was re-established to within 7 per cent of the pre-ischemic value. Radiochromatography of nucleotides following intravenous injection of [¹⁴C]formate indicated a marked enhancement of postischemic purine de novo synthesis. Purine nucleosides and free bases which accumulated during ischemia, were partially re-utilized by salvage pathways: adenosine was rephosphorylated to AMP by adenosine kinase (EC 2.7.1.20); inosine and hypoxanthine were re-used via IMP in a reaction mediated by hypoxanthine phosphoribosyltransferase (EC 2.4.2.8).