Balanced contribution of glycolytic and adenylate pool in supply of metabolic energy in platelets

When platelets are treated with H2O2 the metabolic ATP content decreases sharply (Holmsen, H., and Robkin, L. (1977) J. Biol. Chem. 252, 1752-1757). Here we report that the loss of metabolic energy is fully recovered in phosphorylated glycolytic intermediates. A mixture of antimycin A/2-deoxy-D-glucose/D-gluconic acid-1,5-lactone blocks mitochondrial ATP resynthesis and prevents the entry of sugars into the glycolytic sequence. The energy-rich phosphates in the adenylate and the glycolytic pool are then consumed in a specific order. First, the glycolytic pool is consumed at a rate of 4.5 mumol of ATP equivalents/min/10(11) cells, and metabolic ATP and ADP are kept stable; then the consumption of the glycolytic pool decreases and metabolic ATP and ADP are consumed, together keeping up with the same rate of energy consumption. Thrombin stimulation increases the energy consumption to about 17 mumol of ATPeq/min/10(11) cells which is now furnished by both the glycolytic and the adenylate pool, again with a preferential consumption of the former. The results show that H2O2 triggers a shift of energy-rich phosphates from the adenylate to the glycolytic pool and that the latter remains rapidly accessible to energy consumption thereby stabilizing the level of metabolic ATP. The adenylate energy charge is independent of the distribution of energy among the two pools, which extends its importance to the regulation of energy supply and demand beyond the adenylate pool.     

Energy aspects of the growth of Escherichia coli synchronized by starvation

The quantitative determination of adenyl nucleotides based on the separation of their dansyl derivatives by thin layer chromatography has made it possible to study the dynamics of changes in the pool of ATP, ADP and AMP in Escherichia coli K-12 during its synchronous growth after glucose starvation. The energy parameters (the adenylate pool, energy charge, teh ATP/ADP ratio, the rates of oxygen uptake and ATP generation, the economic coefficients of oxygen and ATP utilization) were compared with changes in the growth characteristics (the rate of growth and biomass concentration). This comparison allowed the authors to draw the conclusion about the uncoupled constructive and energy metabolism and about the possible regulatory role of energy parameters in the synchronised culture growth.     

Changes of Adenylate Pool and Energy Charge E. C. in Relation to the Germination of Chinese Cabbage Seeds

The changes of adenylate pool (ATP, ADP, AMP) and energy charge (E. C.) were determined in germinating seeds of Chinese cabbage. The dry seeds contained a few ATP, most of the adenylate was in the form of AMP. After 1 h of inhibition, most of AMP was converted to ATP, and E. C. value increased rapidly. If the inhibition continued for two hours, the level of ATP increased about 35-fold, and E. C. value reached 0.51. After 24 h of germination, the ATP level in the non- germinating seeds was lower 4 times than that in the germinating seeds and E. C. value was lower too. If the seeds germinated in 3% O2, the ATP level dropped. As the seeds were transfered to air, the adenylate pool and E. C. value increased to the level of the control, then the percentage germination reached 76%. When the seeds were treated with 3% O2, 5 × 10-4 M 2, 4-dinitro phenol, 1 × 10-5 M earbonyl cyanid m-chlorophenyl hydrozone and 5 × 10-3 M iodoaeetie acid at the first 1–2 h, they inhibited the production of ATP and decreased E. C. value. Iodoaeetic acid was the most effective one among the four inhibitors. It was shown that the rate of germination was closely related to the energy charge and the adenylate pool.     

Effect of temperature on the ATP pool and adenylate energy charge in Escherichia coli

The effect of cultivation temperature on the ATP pool and adenylate energy charge (EC) in Escherichia coli has been studied in both batch and continuous cultures. In batch culture, μ_max and the ATP pool increased with increasing growth temperatures between 27–42°C (from 0.26 to 0.62 h⁻¹, and from 5.1 to 8.2 nmol/mg dry wt., respectively). In continuous culture at a constant dilution rate (D = 0.2 h⁻¹), with increasing growth temperatures between 28–43°C, the ATP pool increased about 2-fold (from 4.2 to 8.1 nmol/mg dry wt) and the EC from 0.80 to 0.99.     

Role of adenine nucleotides in the regulation of bacterial energy metabolism: theoretical problems and experimental pitfalls

The effect of growth rate on ATP pool and adenylate energy charge (EC) value of Escherichia coli has been studied in batch culture on different media (mu max varying from 0.1 h-1 to 1.2 h-2) and in continuous culture at dilution rates (D = mu) from 0.045 h-1 to 0.310 h-1. Within the limits of error both ATP pool and EC values did not change with alterations in the relative growth rate of E. coli. The effect of in vivo EC values on experimental errors in ATP, ADP and AMP measurements with the luciferin-luciferase method, and, subsequently, on measurements of different ratios between adenylates, as in the case of adenylate kinase in vivo equilibrium, is discussed.     

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.     

Relationship between ATP and energy charge during lethal metabolic stress of the marine isopod Cirolana borealis

The relationship between ATP and energy charge was studied in individuals of Cirolana borealis under heavy metabolic stress caused by anoxia or exposure to toluene. Prolonged anoxia led to a lowering of the ATP content to about 10% after 4 days, with a simultaneous decrease in energy charge to about 0.25. A lowering of the total adenylate pool reduced the fall in energy charge somewhat, but this effect was marked only in late anoxia when the individuals had become inactive. Exposure to 0.14 mM toluene for 8 days led to a similar decrease in ATP and energy charge. Exposure to 1.4 mM toluene for 24 h led to only slight changes in the adenine nucleotide pool, although the individuals became narcotized within a few hours. The energy charge associated with moribund individuals thus varied much. The mechanism of energy charge stabilization through reduction of the adenine nucleotide pool as ATP declined seemed to be of little significance for the survival of the individuals.     

Effect of glycolysis on the metabolism of adenylates in human erythrocytes

The ATP content in human erythrocytes depleted without glucose falls down to half of the initial value within 2-3 hours and reaches practically zero within more than 10 hours. The ADP content increases 2-3-fold during the 1st hour after depletion and then slowly decreases. The AMP content increases 10-fold during several hours, but the rate of this process constantly decreases. The adenylate pool decreases at a constant rate ranging from 0.13 to 0.25 mmol/l cell. h; this is accompanied by accumulation of IMP. Addition of glucose to depleted erythrocytes results in partial recovery of the ATP level within 1-2 hours. The sooner glucose addition after the depletion, the greater the recovery. Simultaneously the ADP and AMP levels drastically decrease to new constant values. The decline of the adenylate pool ceases and the rate of IMP accumulation increases. Normally, the [ATP]/adenylate pool ratio lies within the small interval 0.85-0.94 irrespective of significant individual differences in the absolute values of [ATP]. This ratio is decreased during depletion and restored to the initial value after glucose addition. The mass-action ratio of the adenylate kinase reaction changes greatly during depletion and restoration of erythrocyte ATP.     

The role of adenosine monophosphate nucleosidase in the regulation of adenine nucleotide levels in Azotobacter vinelandii during aerobic-anaerobic transitions

When cultures of Azotobacter vinelandii are made anaerobic the adenylate pool size remains constant or increases slightly while the adenylate energy charge decreases. Under these conditions, cell growth stops but the cells remain viable for at least 5 h with the decreased energy charge. The changes in the adenylate pool during the aerobic-anaerobic transition include: the formation of adenylates as a result of RNA degradation; the degradation of a portion of the excess AMP to form hypoxanthine by the sequential actions of AMP nucleosidase and adenine deaminase; an increase in the total adenylate pool which is stabilized at approximately 1.5 times the level in growing cells; and stabilization of the adenylate energy charge at a value near 0.3. The degradation of AMP is regulated by AMP nucleosidase, an allosteric enzyme which is activated by MgATP^2? and inhibited by P_i. The in vivo activity of AMP nucleosidase was estimated by measuring the rate of hypoxanthine formation in the culture or by measuring the activity of purified enzyme at the concentrations of AMP, ATP, and P_i found in the cells. The maximum estimated in vivo rate of AMP degradation was less than 3% of the catalytic capacity of AMP nucleosidase. Thus ample activity is present for rapid adjustments of the AMP levels in these cells. Expression of AMP nucleosidase catalytic activity is tightly controlled since high constant concentrations of intracellular AMP can be maintained for extended time periods at low adenylate energy charge values. Under these conditions controlled degradation of AMP can occur to maintain a constant AMP concentration.     

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.     

What determines the intracellular ATP concentration

Analysis is made of the mechanisms that control the intracellular ATP level. The balance between energy production and expenditure determines the energy charge of the cell and the ratio of [ATP] to the adenylate pool. The absolute ATP concentration is determined by the adenylate pool, which, in its turn, depends on the balance between the rates of AMP synthesis and degradation. Experimental data are discussed that demonstrate an increase in the adenylate pool in response to activation of energy-consuming processes. A hypothesis is proposed according to which variation in the adenylate pool and absolute ATP concentration affords a cell the possibility of additional control over processes fulfilling useful work. A mechanism involved in this regulation is described using human erythrocytes as an example. The hypothesis explains why different metabolic pathways (protein and DNA syntheses, polysaccharide synthesis, and lipid synthesis) use different trinucleotides (GTP, UTP, and CTP, respectively) as an energy source. This allows the cell to independently control these metabolic processes by varying the individual nucleotide pools.     

Response of nucleoside diphosphate kinase to the adenylate energy charge

The reaction catalyzed by nucleoside diphosphate kinase responds to the energy charge of the adenylate pool. The velocity is maximal at a charge of 1.0, and decreases sharply with a decrease in the charge. This response may control the flow of phosphate from ATP into the other nucleotide pools and thus participate in the regulation of macromolecular synthesis by the energy level of the cell, as reflected in the charge of the adenylate pool.     

A bimodal germination response to temperature in cocklebur seeds. II. ATP and adenylate pool

Abstract. The mechanism involved in a bimodal germination-temperature response in pre-soaked cocklebur (Xanthium pennsylvanicum Wallr.) seeds was studied with special reference to adenylate metabolism. Exposure to either low (optimal at 8°C) or high (optimal at 34°C) temperature which was effective in inducing the germination of the seeds brought about the accumulation of ATP in them. The ATP level remained unchanged at temperatures around 23°C. Pretreatment with KCN, stimulating germination even at 23°C, subsequently increased the ATP content, total adenylate pool and energy charge (EC) in the axial tissue prior to germination above those of the untreated controls. The lower the treatment temperature, the greater the inhibitory effect of KCN on ATP formation. An increase in germination following an increasing duration of pre-soaking at 8°C was comparable to increasing both the ATP content and total adenylate pool of axes, but not the EC value. Similarly, changes in germination following an increased exposure duration at 8°C correlated with changes in ATP content rather than EC value in the axes. Unlike the case of chilling, an increase in ATP level in response to 34°C was greater in the early period of water imbibition, during which times its germination-stimulating effect appeared more striking than in the later period, and it occurred without a concomitant rise in EC value because of the increased supply of AMP. Such a supply of AMP was reduced in the presence of benzohydroxamic acid or propyl gallale, inhibitors of an alternative respiratory pathway. It was thus concluded that both low temperature, coupled with warm temperature, and high temperature, by itself, can induce seed germination by increasing the ATP level as well as the total adenylate pool, but not the EC value, in the axial tissue. Further, that increases in both the ATP level and the adenylate pool especially are required for seed germination to proceed, probably depending on the activities of the cytochrome and alternative respiration pathways, respectively.     

Effect of transient focal ischemia of mouse brain on energy state and NAD levels: no evidence that NAD depletion plays a major role in secondary disturbances of energy metabolism

It has been proposed that NAD depletion resulting from excessive activation of poly(ADP-ribose) polymerase is responsible for secondary energy failure after transient cerebral ischemia. However, this hypothesis has never been verified by measurement of ATP and NAD levels in the same tissue sample. In this study, we therefore investigated the effect of transient focal cerebral ischemia on the temporal profiles of changes in the levels of energy metabolites and NAD. Ischemia was induced in mice by occluding the left middle cerebral artery using the intraluminal filament technique. Animals were subjected to 1-h ischemia, followed by 0, 1, 3, 6, or 24 h of reperfusion. During ischemia, ATP levels, total adenylate pool, and adenylate energy charge dropped to approximately 20, 50, and 40% of control, respectively, whereas NAD levels remained close to control. Energy state recovered transiently, peaking at 3 h of recovery (ATP levels and total adenylate pool recovered to 78 and 81% of control). In animals subjected to reperfusion of varying duration, the extent of ATP depletion was clearly more pronounced than that of NAD. The results imply that depletion of NAD pools did not play a major role in secondary disturbances of energy-producing metabolism after transient focal cerebral ischemia. Changes in ATP levels were closely related to changes in total adenylate pool (p<0.001). The high energy charge after 6 h of reperfusion (0.90 versus a control value of 0.93) and the close relationship between the decline of ATP and total adenylate pool suggest that degradation or a washout of adenylates (owing to leaky membranes) rather than a mismatch between energy production and consumption is the main causative factor contributing to the secondary energy failure observed after prolonged recovery.     

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.     

Oxygen deficiency and its effect on the adenylate system in Acetobacter in the submerse acetic fermentation

Summary It is well known that Acetobacter is extremely sensitive in high total concentrations (GK)¹ of ethanol and acetic acid. In the acetator, at a total concentration (GK) of 13%, ATP pool and growth show reverse behaviour. During the stationary, acidifying phase, the extracellular adenylate concentration amounts to 70% of the total edenylate pool (AN=ATP+ADP+AMP). In this range, the average value of the intracellular energy charge [EC=(ATP+1/2ADP)/(ATP+ADP+AMP)] is 0.82.After 45 s of interruption of aeration, the EC of the total culture dropped to a value of 0.58. After several weeks of storage, the EC of the inoculum amounted to 0.50.     

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.     

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.     

ATP content and adenylate energy charge ofBacillus stearothermophilus during growth

The ATP content and the adenylate energy charge of the thermophileBacillus stearothermophilus were determined during growth.Bacillus subtilis was used for comparison to determine whether there were differences in the ATP content and adenylate energy charge between a mesophile and a thermophile. Both the ATP content and the adenylate energy charge were lower in the thermophile than in the mesophile. These lower values may reflect a decreased activation energy required for the metabolic coupling when growth is occurring at the higher temperatures characteristic of the thermophile.     

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.