In situ studies on AMP deaminase as a control system of the adenylate energy charge in yeasts

The role of AMP deaminase reaction in the stabilization of the adenylate energy charge was investigated using permeabilized yeast cells. The addition of P_i or Zn²⁺, which inhibits AMP deaminase, remarkably retarded the depletion of total adenylate pool and the recovery of the adenylate energy charge. Polyamine, an activator of the enzyme, decreased total adenylates, resulting in the enhanced recovery of the energy charge in situ. AMP deaminase can act as a regulatory enzyme in the system that stabilizes the adenylate energy charge in yeast cells under the conditions of severe metabolic stress.     

Major determinants of purine excretion from human lymphoblasts

WI-L2 B lymphoblasts deficient in hypoxanthine-guanine phosphoribosyltransferase (HGPRT) excreted amounts of hypoxanthine two to three times larger than CEM T lymphoblasts deficient in HGPRT, despite similar growth rates. ATP consumption occurred at a higher rate in WI-L2 cells than in CEM cells when cultivated in a glucose-free buffer, because of higher RNA synthesis in WI-L2 cells. The introduction of actinomycin D and azaserine resulted in lower hypoxanthine excretion in WI-L2 cells than in CEM cells, not in parallel with changes of the adenylate pool size. When the energy charge was high, de novo purine synthesis was a major determinant for purine excretion. The adenylate pool ratio (AMP/ATP) change caused by the introduction of oligomycin was greater during ATP depletion and recovery in WI-L2 cells than in CEM cells. WI-L2 cells were observed to have AMP deaminase activity three to four times higher than CEM cells. The major component of AMP deaminase in these cells was liver type. The higher rate of RNA synthesis caused greater changes of (AMP/ATP) and required higher AMP deaminase activity for recovery. When the energy charge was low, AMP deaminase was a major determinant for purine excretion.     

The pathway of adenylate catabolism in Azotobacter vinelandii. Evidence for adenosine monophosphate nucleosidase as the regulatory enzyme.

Cell-free, dialyzed extracts from Azotobacter vinelandii rapidly dephosphorylate [U-14C]ATP to labeled ADP and AMP, which is then degraded to hypoxanthine, the end product of AMP catabolism under the experimental conditions which were used. The intermediates of the pathway from ATP to hypoxanthine have been identified by thin layer chromatography and quantitated by the 14-C content. The concentrations of intermediates present during the production of hypoxanthine are consistent with AMP nucleosidase being responsible for AMP degradation in these extracts. This result was confirmed in experiments which utilized rabbit antibody prepared against purified AMP nucleosidase. The antibody inhibited AMP nucleosidase activity in cell-free extracts but did not inhibit adenine demanase or adenosine deaminase from the same extracts. In the presence of antibody prepared against purified AMP nucleosidase, the dialyzed extracts showed a marked reduction in the production of hypoxanthine from ATP. Other enzymes which could be responsible theoretically for the conversion of AMP to hypoxanthine were not detected by standard assay procedures. These results are consistent with AMP degradation proceeding by way of AMP nucleosidase to yield adenine and ribose 5-phosphate. The adenine is then converted to hypoxanthine by adenine deaminase. Both of these enzymes were present in sufficient quantities to account for the observed rates of hypoxanthine formation. The rate of hypoxanthine formation decreases during the time course of the [U-14-C]ATP degradation experiments, even though the concentration of AMP remains high. This decrease in the rate of hypoxanthine formation as a function of time is attributed to the decreasing ATP and increasing P0-4 concentrations, since ATP is an activator of AMP nucleosidase and P0-4 is an inhibitor. These observations suggest that the in vivo activity of AMP nucleosidase could also be regulated by changes in the relative ratios of ATP:AMP:P0-4.     

Adenine nucleotide metabolism in Azotobacter vinelandii. Two metabolic pathways of AMP degradation

AMP-degrading pathways in Azotobacter vinelandii cells were investigated. AMP nucleosidase (EC 3.2.2.4) was rapidly synthesized and reached a maximum at 24 h, while the activity of 5-nucleotidase (EC 3.1.3.5) specific for AMP, which was negligible during the logarithmic phase of the growth, first appeared in 24 h-cultures, and reached a maximum after complete exhaustion of sucrose from the growth medium (70 h).Cell-free extracts of A. vinelandii of 48 h-cultures hydrolyzed AMP to ribose 5-phosphate and adenine in the presence of ATP, and adenine was deaminated to hypoxanthine. When ATP was excluded, AMP was dephosphorylated to adenosine, which was further metabolized to inosine, and finally to hypoxanthine. Hypoxanthine thus formed was reutilized for the salvage synthesis of IMP under the conditions where 5-phosphoribosyl 1-pyrophosphate was able to be supplied. These results suggest that the levels of ATP can determine the rate of AMP degradation by the AMP nucleosidase- and 5-nucleotidase-pathways. The role of ATP in the AMP degradation was discussed in relation to the regulatory properties of AMP nucleosidase, inosine nucleosidase (EC 3.2.2.2) and adenosine deaminase (EC 3.5.4.4).     

Effect of adenine nucleotides on the reaction catalyzed by pyruvate,orthophosphate dikinase in maize

The effect of adenine nucleotides in pyruvate, orthophosphate dikinase (EC 2.7.9.1, ATP, pyruvate, orthophosphate phosphotransferase)_was studied with the enzyme furified from maize, and with the enzyme obtained from mesophyll chloroplast extracts during assay in the direction of pyruvate conversion to phosphoenolpyruvate. (1) In studies with the purified enzyme, the relationship of initial velocity to ATP concentrations follows Michaelis-Menten kinetics, and the K_m value for ATP was 22.8 μM (± 5.1 μM, n = 5). (2) AMP was a competitive inhibitor with respect to ATP, and its K_i value was 35.8 μM (± μM, n = 4). There was no inhibition of catalysis by ADP up to a concentration of 460 μM. (3) The theoretical response of the enzyme to change in the adenylate energy charge was calculated from the kinetic constants for ATP and AMP. The experimentally obtained values were similar to the theoretical response when varying energy charge was generated by addition of appropriate amounts of ATP, ADP and AMP in assays with the purified enzyme. The response of the enzyme to energy charge at different pH values (pH 7.0, 7.5, and 8.0) was similar, although the activity of the enzyme at pH 7.0 was about 40% of that at pH 8.0. (4) When mesophyll chloroplast extracts of maize, which contain high levels of adenylate kinase, were used as the source of the enzyme and the adenylate energy charge was generated by addition of different concentrations of ATP and AMP, the influence on catalysis was similar to that with the purified enzyme. (5) The data show that the effect of varying energy chage on the activity of the dikinase is not typical of a U-type enzyme, in contrast to phosphoglycerate kinase (EC 2.7.2.3, ATP: 3-phospho-D-glycerate 1-phosphotransferase), which is more strongly regulated. (6) Evidence is presented for competition between the dikinase and phosphoglycerate kinase for ATP in mesophyll chloroplast extracts of maize. (7) When the effect of adenylate energy charge on the state of activation and the direct effect on catalysis of the dikanase are combined, the total capacity for catalysis is very dependent on the energy charge.     

Regulation of cytosol 5'-nucleotidase by adenylate energy charge

In the physiological range of the adenylate energy charge in liver (0.7-0.9), th rate of AMP-hydrolysis catalysed by rat liver cytosol 5'-nucleotidase (5'-ribonucleotide phosphohydrolase, EC 3.1.3.5) increased sharply with decreasing energy charge. In addition, a decrease in the concentration of Pi caused marked acceleration of the AMP-hydrolysing activity over the physiological range of adenylate energy charge. These responses seem to serve to protect the cells against a metabolic stress which could result from sudden utilization of ATP by removal of AMP. The AMP-hydrolysing activity of this enzyme decreased sharply as the size of the adenine nucleotide pool decreased in the physiological range. This effect may be a self-limiting response to prevent excess depletion of the pool. IMP-hydrolysing activity of this enzyme increased with increasing adenylate energy charge. But no marked response to its variation within the physiological range was observed. On the basis of the data obtained in this study, the IMP-hydrolysing activity of the cytosol 5'-nucleotidase in rat liver cells seems to be comparable to that of AMP deaminase reaction, but the AMP-hydrolysing activity was estimated to be less than 10% of AMP deaminase reaction at energy charge value of about 0.7. This strongly suggests that the AMP leads to IMP leads to inosine pathway is more significant that the AMP leads to adenosine leads to inosine pathway in rat liver.     

Coordination of adenylate energy charge and phosphorylation state during ischemia and under physiological conditions in rat liver and kidney

The relation of the adenylate energy charge $\text{(}\text{ATP}\text{+}\text{1}\text{2}\text{ADP/ATP}\text{+}\text{ADP}\text{+}\text{AMP}\text{)}$ to the phosphorylation state (ATP)/(ADP)(HPO₄^2?) in rat liver and kidney was analyzed. Under physiological conditions and in ischemia, the two regulatory parameters, calculated from reported values for adenine nucleotides and inorganic phosphate (P_i) and from new observations, were closely coordinated. Energy charge was an inverse linear function of P_i and -log (1 - energy charge) was a positive linear function of log phosphorylation state. To evaluate experimental data with known energy charge, but unknown P_i, and to determine the theoretical relation between energy charge and phosphorylation state, P_i was estimated from a) the regression equation: P_i, μmol/g wet wt tissue = 1.05 - energy charge/0.073 and b) the empirical relationship: (P_i/2P_a) + energy charge = k, where P_a = σAMP + 2ADP + 3ATP and k = 1. With both estimates, the relation between phosphorylation state and energy charge for the experimental data was, within error, the same as that observed with measured P_i and concordant with theoretical values. Over the physiological range of energy charge (～0.85 – 0.95, log phosphorylation state ～3.3 – 4.3), apparent ΔG_ATP (×2) was closer to the range of ΔG observed by Wilson $\text{et al}$ (Biochem. J. $\text{140}$:57, 1974) for transfer of two electrons from mitochondrial NAD to the cytochrome c couple than the ΔG_ATP (×2) they reported, supporting their conclusion that near-equilibrium exists between the mitochondrial respiratory chain and the cytoplasmic phosphorylation state under physiological conditions. From evidence presented, it is postulated that the phosphorylation state is regulated by the adenylate energy charge.     

Stimulation of hepatic fatty acid synthetase activity in chick embryo by cycloheximide

The regulation of hypoxanthine transport activity by Chinese hamster lung fibroblasts grown in culture was examined in wild-type clones and 8-azaguanine-resistant mutant clones which lack hypoxanthine-guanine phosphoribosyltransferase. Hypoxanthine transport activity increases with increased rates of cellular growth expressed as viable cell number, total cell protein, and DNA synthesis. The transport activity for hypoxanthine declines when the fibroblasts approach confluence or after exposure to cycloheximide or actinomycin D. In vivo incubation of either fibroblast subline with 100 μm dibutyryl cyclic AMP decreases transport activity over 50%, whereas exposure to 10 μm dibutyryl cyclic GMP increases hypoxanthine uptake by 40%. A synergistic effect is observed when fibroblasts are incubated with a phosphodiesterase inhibitor (3-isobutyl-1-methylxanthine or theophylline) plus glucagon, an adenylate cyclase stimulator. Such additions result in a 70% decrease in the cellular transport capacity. Stimulation of hypoxanthine transport by 40% is observed following incubation with insulin. Addition of all agents produces maximum changes in the rate of hypoxanthine transport only after a 6-h in vivo incubation with the fibroblasts. These findings suggest that hypoxanthine transport is regulated by the intracellular concentration of cyclic nucleotides. This control may occur at the level of gene expression for a hypoxanthine transport protein.     

Relation between energy production and adenine nucleotide metabolism in human blood platelets

The relation between ATP production and adenine nucleotide metabolism was investigated in human platelets which were starved by incubation in glucose-free, CN^?-containing medium and subsequently incubated with different amounts of glucose. In the absence of mitochondrial energy production (blocked by CN^?) and glycogen catabolism (glycogen almost completely consumed during starvation), lactate production increased proportionally with increasing amounts of glucose. The generated ATP was almost completely consumed in the various ATP-consuming processes in the cell except for a fixed portion (about 7%) that was reserved for restoration of the adenylate energy charge. During the first 10 min after glucose addition, the adenine nucleotide pool remained constant. Thereafter, when the glycolytic flux, measured as lactate formation, was more than 3.5 μmol · min^?1 · 10^?11 cells, the pool increased slightly by resynthesis from hypoxanthine-inosine and then stabilized; at a lower flux the pool decreased and metabolic ATP and energy charge declined to values found during starvation. Between moments of rising and falling adenylate energy charges, periods of about 10 min remained in which the charge was constant and ATP supply and demand had reached equilibrium. This enabled comparison between the adenylate energy charge and ATP regeneration velocity. A linear relation was obtained for charge values between 0.4 and 0.85 and ATP regeneration rates between 0.6 and 3.5 ATP equiv. · min^?1 · 10^?11 cells. These data indicate that in starved platelets ATP regeneration velocity and energy charge are independent and that each appears to be subject to the availability of extracellular substrate.     

Effect of Temperature Stress on Adenylate Pools and Energy Charge in a Psychrophilic Bacterium, Vibrio sp. ABE-1

The adenylate energy charge in the psychrophilic bacterium Vibriosp. ABE-1 remained unchanged while the cells grew, althoughthe ATP pool varied in parallel with the growth rates underdifferent temperature conditions (0–20°C). However,at a nonpermissive temperature (25°C), the bacteria couldnot grow, the energy charge decreased due to temporary disappearanceof ATP, and before long, both the number of viable cells andthe energy charge decreased. Phosphoribosyl pyrophosphate synthetase, an ATP-utilizing enzyme,could be efficiently controlled by the energy charge at permissivetemperatures, but was regulated little or not at all at a nonpermissivetemperature (25°C). The regulation possibly arose from inhibitionof the enzyme activity by ADP or AMP, and especially by thereaction product AMP. (Received December 18, 1982; Accepted April 16, 1983)     

Adenylate kinase bound to the envelope membranes of spinach chloroplasts.

The activity of adenylate kinase (ATP:AMP phosphotransferase, EC 2.7.4.3) in both the forward (2ADP → ATP + AMP) and backward (ATP + AMP → 2ADP) reactions was found to be associated with the envelope membranes which were isolated from spinach chloroplasts. Sonication and repeated washing in a medium of high ionic strength were unable to release the enzymes from the envelope membranes. Adenylate kinase bound to the envelope is stable in the cold and inactivated by heat and acid treatments. The enzyme requires magnesium ion as an activator. The pH-activity profile of the forward reaction catalyzed by membrane-bound adenylate kinase gave a maximal activity at pH 8.5. The apparent Michaelis constant, K_m, value for ADP in the forward reaction was estimated to be 1.3 ± 0.2 × 10^?4m. A Lineweaver-Burk plot of the forward reaction gave a straight line when the reciprocal of the reaction rate was plotted versus the reciprocal, and not the square of the reciprocal, of the concentration of substrate ADP. This favors the view that the adenylate kinase bound to the chloroplast envelope has a single or equivalent binding site of Mg-ADP^?. The probable involvement of adenylate kinase bound to the chloroplast envelope in controlling the energy pool and adenylate translocation in chloroplasts is suggested.     

The Effect of Adenine Nucleotides on Purified Phosphoenolpyruvate Carboxylase from the CAM Plant Crassula argentea

The effects of adenine nucleotides on phosphoenolypyruvate carboxylase were investigated using purified enzyme from the CAM plant, Crassula argentea. At 1 millimolar total concentration and with limiting phosphoenolpyruvate, AMP had a stimulatory effect, lowering the K_m for phosphoenolpyruvate, ADP caused less stimulation, and ATP decreased the activity by increasing the K_m for phosphoenolpyruvate. Activation by AMP was not additive to the stimulation by glucose 6-phosphate. Furthermore, AMP increased the K_a for glucose 6-phosphate. Inhibition by ATP was competitive with phosphoenolpyruvate. In support of the kinetic data, fluorescence binding studies indicated that ATP had a stronger effect than AMP on phosphoenolpyruvate binding, while AMP was more efficient in reducing glucose 6-phosphate binding. As free Mg²⁺ was held constant and saturating, these effects cannot be ascribed to Mg²⁺ chelation. Accordingly, the enzyme response to the adenylate energy charge was basically of the “R” type (involving enzymes of ATP regenerating sequences) according to D. E. Atkinson's (1968 Biochemistry 7: 4030-4034) concept of energy charge regulation. The effect of energy charge was abolished by 1 millimolar glucose 6-phosphate. Levels of glucose 6-phosphate and of other putative regulatory compounds of phosphoenolpyruvate carboxylase were determined in total leaf extracts during a day-night cycle. The level of glucose 6-phosphate rose at night and dropped sharply during the day. Such a decrease in glucose 6-phosphate concentration could permit an increased control of phosphoenolpyruvate carboxylase by energy charge during the day.     

, -Methylene-adenosine-5'-triphosphate--effects of a competitive inhibitor of adenylate cyclase on cyclic AMP accumulation and lipolysis in isolated fat cells

The rapid, transient rise in the intracellular concentration of cyclic AMP which follows addition of L-epinephrine to isolated fat cells is completely prevented by an ATP analog, α,β-methylene-adenosine-5′-triphosphate [Ap(CH₂)pp], a competitive inhibitor of adenylate cyclase activity in liver and fat cell membrane preparations. The concentration of cyclic AMP falls distinctly below that in the basal state after incubating fat cells for seven minutes in the presence of Ap(CH₂)pp. The results are consistent with the view that the ATP analog is also an effective $\text{in vivo}$ inhibitor of adenylate cyclase activity, and that intracellular cyclic AMP levels are normally delicately balanced by very rapid processes of synthesis and degradation. Epinephrine-induced lipolysis in fat cells is not inhibited but is instead enhanced by Ap(CH₂)pp. This is probably explained by the ability of the analog to act (like ATP) as a high-energy phosphate donor, an effect which is independent of its inhibition of adenylate cyclase activity. The predominant effect of this compound on glucose oxidation by fat cells also appears to be the result of this property since its effects are mimicked by ATP.     

The relationship of cAMP levels and the rate of pool labelling of cAMP and related bases, nucleosides and nucleotides to the HeLa cell cycle.

Cellular cAMP levels as well as the rate of pool labelling of cAMP and related bases, nucleosides and nucleotides were determined in synchronized cultures of HeLa cells after pulse-labelling with [¹⁴C]adenine. The cAMP levels were found to be maximal in G 1 and minimal in G 2 and mitosis, as previously reported by others. The rate of labelling of the cAMP pools, however, was found to be maximal in G 2 and decreased to a minimum in G 1. This suggests that the rate of cAMP synthesis is highest when pool level is lowest and vice versa. A comparison of cAMP levels and the rate of 5′AMP pool labelling throughout the HeLa cell cycle indicated an inverse relationship. Such a relationship emphasizes the role of the cyclic 3′,5′-phosphodiesterase activity during the cell cycle. The kinetics of pool labelling of IMP, ATP, and hypoxanthine throughout the cell cycle suggested that the adenylate energy charge fluctuated as a function of the cell cycle. The apparent activation of the adenylate cyclase during G 2 and mitosis as reflected by the increased rate of cAMP pool labelling suggests that the super phosphorylation of H 1 histone during G 2-mitotic transition may be mediated by cAMP-dependent phosphokinases.     

Role of CFTR’s intrinsic adenylate kinase activity in gating of the Cl− channel

The cystic fibrosis transmembrane conductance regulator (CFTR) is a Cl^?channel in the ATP-binding cassette (ABC) transporter protein family. CFTR features the modular design characteristic of ABC transporters, which includes two membrane-spanning domains forming the channel pore, and two ABC nucleotide-binding domains that interact with ATP and contain the enzymatic activity coupled to normal gating. Like other ABC transporters CFTR is an ATPase (ATP + H₂O → ADP + P_i). Recent work has shown that CFTR also possesses intrinsic adenylate kinase activity (ATP + AMP ? ADP + ADP). This finding raises important questions: How does AMP influence CFTR gating? Why does ADP inhibit CFTR current? Which enzymatic activity gates CFTR in vivo? Are there implications for other ABC transporters? This minireview attempts to shed light on these questions by summarizing recent advances in our understanding of the role of the CFTR adenylate kinase activity for channel gating.     

In vitro adenine nucleotide catabolism in African catfish spermatozoa

It has been shown recently that African catfish (Clarias gariepinus) spermatozoa possess relatively low ATP content and low adenylate energy charge (AEC). One of the possible explanations for this phenomenon is that the spermatozoa actively catabolize adenine nucleotides. A relatively high rate of such catabolism could then contribute to the low ATP concentration and low adenylate energy charge observed in the spermatozoa in vitro. To check this hypothesis, we investigated ATP content and adenine nucleotide catabolism in African catfish spermatozoa stored at 4 °C in the presence of glycine as an energetic substrate. Our results indicate that the storage of African catfish sperm at 4 °C in the presence of glycine causes time-dependent ATP depletion. In contrast to ATP, the AMP content increases significantly during the same period of sperm storage, while the ADP increases only slightly. Moreover, a significant increase of inosine and hypoxanthine content was also found. Hypoxanthine was accumulated in the storage medium, but xanthine was found neither in spermatozoa nor in the storage medium. It indicates that hypoxanthine is not converted to xanthine, probably due to lack of xanthine oxidase activity in catfish spermatozoa. Present results suggest that adenine nucleotides may be converted to hypoxanthine according to the following pathway: ATP→ADP→AMP (adenosine/IMP)→inosine→hypoxanthine. Moreover, hypoxanthine seems to be the end product of adenine nucleotide catabolism in African catfish spermatozoa. In conclusion, our results suggest that a relatively high rate of adenine nucleotide catabolism contributes to the low ATP concentration and low adenylate energy charge observed in African catfish spermatozoa in vitro.     

Purine catabolism in plants : purification and some properties of inosine nucleosidase from yellow lupin (lupinus luteus L.) seeds

Inosine nucleosidase (EC 3.2.2.2), the enzyme which hydrolyzes inosine to hypoxanthine and ribose, has been partially purified from Lupinus luteus L. cv. Topaz seeds by extraction of the seed meal with low ionic strength buffer, ammonium sulfate fractionation, and chromatography on aminohexyl-Sepharose, Sephadex G-100, and hydroxyapatite.

Molecular weight of the native enzyme is 62,000 as judged by gel filtration. The inosine nucleosidase exhibits optimum activity around pH 8. Energy of activation for inosine hydrolysis estimated from Arrhenius plot is 14.2 kilocalories per mole. The K_m value computed for inosine is 65 micromolar.

Among the inosine analogs tested, the following nucleosides are substrates for the lupin inosine nucleosidase: xanthosine, purine riboside (nebularine), 6-mercaptopurine riboside, 8-azainosine, adenosine, and guanosine. The ratio of the velocities measured at 500 micromolar concentration of inosine, adenosine, and guanosine was 100:11:1, respectively. Specificity (V_max/K_m) towards adenosine is 48 times lower than that towards inosine.

In contrast to the adenosine nucleosidase activity which is absent from lupin seeds and appears in the cotyledons during germination (Guranowski, Pawełkiewicz 1978 Planta 139: 245-247), the inosine nucleosidase is present in both lupin seeds and seedlings.

     

AMP deaminase from baker's yeast. Purification and some regulatory properties.

AMP deaminase (AMP aminohydrolase, EC 3.5.4.6) was found in extract of baker's yeast (Saccharomyces cerevisiae), and was purified to electrophoretic homogeneity using phosphocellulose adsorption chromatography and affinity elution by ATP. The enzyme shows cooperative binding of AMP (Hill coefficient, nH, 1.7) with an s0.5 value of 2.6 mM in the absence or presence of alkali metals. ATP acts as a positive effector, lowering nH to 1.0 and s0.5 to 0.02 mM. P1 inhibits the enzyme in an allosteric manner: s0.5 and nH values increase with increase in Pi concentration. In the physiological range of adenylate energy charge in yeast cells (0.5 to 0.9), the AMP deaminase activity increases sharply with decreasing energy charge, and the decrease in the size of adenylate pool causes a marked decrease in the rate of the deaminase reaction. AMP deaminase may act as a part of the system that protects against wide excursions of energy charge and adenylate pool size in yeast cells. These suggestions, based on the properties of the enzyme observed in vitro, are consistent with the results of experiments on baker's yeast in vivo reported by other workers.     

Study of the regulation of oxidation and CO2 assimilation in intact Nitrobacter winogradskyi cells

1. Changes of the adenine nucleotides in resting and growing Nitrobacter winogradskyi cells were measured in connection with regulating processes during nitrite oxidation and endogenous respiration.
2. After the addition of nitrite to endogenously respiring cells the ATP pool increased strongly during the first 60 sec at the expense of the ADP pool. At this point the energy charge was approx. 0.55. After the first 90 sec the ATP pool dropped, oscillating, to a lower level. The CO₂ assimilation began at this point.
3. Under a nitrogen atmosphere the AMP pool increased and the ATP pool decreased. With a value of approx. 0.17 the energy charge was extremely low. When oxygen was added the Nitrobacter cells began to oxidize stored NADH. The ATP pool increased in a few seconds whereas the AMP pool decreased. The P/O ratio of endogenously respiring cells equaled 0.6 under these conditions.
4. During the changeover from anaerobic to aerobic conditions and in the presence of nitrite the nitrite oxidation and CO₂ assimilation, opposed to aerobic conditions, were inhibited at first after the nitrite addition. The changeover of the respiratory chain enzymes from a reduced to an oxidized charge and the ATP increase were delayed in comparison with experiments without nitrite. According to these findings the endogenous respiration must be almost nil while nitrite oxidizing cells are growing.

     

Adenine nucleotides and the xanthophyll cycle in leaves

The relationships among the leaf adenylate energy charge, the xanthophyll-cycle components, and photosystem II (PSII) fluorescence quenching were determined in leaves of cotton (Gossypium hirsutum L. cv. Acala) under different leaf temperatures and different intercellular CO₂ concentrations (C_i). Attenuating the rate of photosynthesis by lowering the C_i at a given temperature and photon flux density increased the concentration of high-energy adenylate phosphate bonds (adenylate energy charge) in the cell by restricting ATP consumption (A.M. Gilmore, O. Björkman 1994, Planta 192, 526–536). In this study we show that decreases in photosynthesis and increases in the adenylate energy charge at steady state were both correlated with decreases in PSII photo-chemical efficiency as determined by chlorophyll fluorescence analysis. Attenuating photosynthesis by decreasing C_i also stimulated violaxanthin-de-epoxidation-dependent nonradiative dissipation (NRD) of excess energy in PSII, measured by nonphotochemical fluorescence quenching. However, high NRD levels, which indicate a large trans-thylakoid proton gradient, were not dependent on a high adenylate energy charge, especially at low temperatures. Moreover, dithiothreitol at concentrations sufficient to fully inhibit violaxanthin de-epoxidation and strongly inhibit NRD, affected neither the increased adenylate energy charge nor the decreased PSII photo-chemical efficiency that result from inhibiting photosynthesis. The build-up of a high adenylate energy charge in the light that took place at low C_i and low temperatures was accompanied by a slowing of the relaxation of non-photochemical fluorescence quenching after darkening. This slowly relaxing component of nonphotochemical quenching was also correlated with a sustained high adenylate energy charge in the dark. These results indicate that hydrolysis of ATP that accumulated in the light may acidify the lumen and thus sustain the level of NRD for extended periods after darkening the leaf. Hence, sustained nonphotochemical quenching often observed in leaves subjected to stress, rather than being indicative of photoinhibitory damage, apparently reflects the continued operation of NRD, a photoprotective process.Abbreviations A antheraxanthin - adenylate kinase (myokinase), ATP:AMPphosphotransferase - C_i intercellular CO₂ concentration - DPS de-epoxidation state of violaxanthin, ([Z+A]/[V+A+Z]) - DTT dithiothreitol - pH trans-thylakoid proton gradient - [2ATP+ADP] - F steady-state fluorescence in the presence of NRD - F_M maximal fluorescence in the absence of NRD - F_M maximal fluorescence in the presence of NRD - NRD nonradiative energy dissipation - PET photosynthetic electron transport rate - PFD photon flux density - _PSII photon yield of PSII photochemistry at the actual reduction state in the light or dark - Q_A the primary electron acceptor of PSII - [ATP+ADP+AMP] - SV_N Stern-Volmer nonphotochemical quenching - V violaxanthin - Z zeaxanthin We thank Connie Shih for skillful assistance in growing plants and for conducting HPLC analyses. A Carnegie Institution Fellowship to A.G. is also gratefully acknowledged.