Potentiation of postjunctional cholinergic sensitivity of rat diaphragm muscle by high-energy-phosphate adenine nucleotides

Summary The cholinergic sensitivity of rat diaphragm muscle, measured as the magnitude of depolarization responses to repetitive, iontophoretic pulses of acetylcholine (ACh) onto neuromuscular endplates, is increased by addition of ATP to the perfusion medium. Depolarization responses begin to increase within the first min after addition of 10mm ATP and plateau at 60% above control levels (mean value) after 4 to 6 min. Neither the magnitude nor the time course of the potentiations corresponds to changes in resting potential or membrane resistance. Other nucleotides are equally or less effective at the same concentration: ATP-ADP>UTP>AMP=GTP (=no added nucleotide control) The duration of the individual ACh responses does not increase during continuous exposure to the active nucleotides for up to 15 min except when the muscle is pretreated with eserine.Mild enzymatic predigestion of the muscle with collagenase and then protease, increasing the availability of the postjunctional membrane to bath-applied drugs, decreases the variability and increases the magnitude of the potentiation to a given dose of ATP. The dose-response curve for ATP is then more than half-maximal at 1mm and the ranking of the other nucleotides relative to ATP is the same as without predigestion.There is an optimum Ca⁺⁺ concentration for the potentiation between zero and 2mm: potentiation is enhanced in Ca⁺⁺-free medium, partially blocked in twice-normal Ca⁺⁺ medium, and totally blocked in Ca⁺⁺-free medium 10 min after a 5 min exposure to 2.5mm EGTA. The similar Ca⁺⁺ dependence of ACh receptor activation in the absence of added nucleotide suggests that ATP directly facilitates receptor activation by ACh. This facilitory action could be one of the physiological roles for the ATP released from stimulated phrenic nerve.     

Modulation of postjunctional cholinergic sensitivity of rat diaphragm muscle by cyclic adenosine monophosphate.

Addition of 2.5 mM cyclic adenosine monophosphate (cAMP) to the solution bathing a rat diaphragm muscle alters the magnitude of depolarization responses to iontophoretic pulses of acetylcholine (ACh) at neuromuscular endplates. Alterations are repeatable with small variability on a given preparation for initial and repeat experiments on both hemidiaphragms, but are different on each preparation. Five min after addition of the nucleotide solution, increases (potentiations) of up to 30% above control levels and decreases (attenuations) to 50% below control levels are observed. The effects on sensitivity to ACh of dibutyryl cAMP (1.25 mM), monobutyryl cAMP (0.25 mM), and cAMP (2.5 mM) in Ca++ -free solution are a function of whether the experiment is an initial one on that preparation or a repeat experiment after 10 or more minutes of perfusion flow. In all three cases, initial exposure attenuates sensitivity (means at 5 min: --30, --10, and --20%, respectively) and repeat exposure potentiates sensitivity (mean: 20% at 5 min, 15% at 5 min, and 10% at 2 min respectively). A concentration of dibutyryl cAMP (0.25 mM) which is without effect on sensitivity alone, produces a large, transient potentiation (mean: 45% at 1 min) in conjunction with 0.5 mM theophylline. A decrease in the rate of desensitization is observed during exposure to 0.25 mM cAMP. The results are interpreted in terms of a physiological mechanism whereby receptor activity at the postjunctional membrane is modulated by cAMP formed from prejunctionally released ATP.     

Modulation of postjunctional cholinergic sensitivity of rat diaphragm muscle by cyclic adenosine monophosphate

Summary Addition of 2.5 mM cyclic adenosine monophosphate (cAMP) to the solution bathing a rat diaphragm muscle alters the magnitude of depolarization responses to iontophoretic pulses of acetylcholine (ACh) at neuromuscular endplates. Alterations are repeatable with small variability on a given preparation for initial and repeat experiments on both hemidiaphragms, but are different on each preparation. Five min after addition of the nucleotide solution, increases (potentiations) of up to 30% above control levels and decreases (attenuations) to 50% below control levels are observed. The effects on sensitivity to ACh of dibutyryl cAMP (1.25 mM), monobutyryl cAMP (0.25 mM), and cAMP (2.5 mM) in Ca⁺⁺-free solution are a function of whether the experiment is an initial one on that preparation or a repeat experiment after 10 or more minutes of perfusion flow. In all three cases, initial exposure attenuates sensitivity (means at 5 min: –30, –10, and –20%, respectively) and repeat exposure potentiates sensitivity (means: 20% at 5 min, 15% at 5 min, and 10% at 2 min respectively). A concentration of dibutyryl cAMP (0.25 mM) which is without effect on sensitivity alone, produces a large, transient potentiation (mean: 45% at 1 min) in conjunction with 0.5 mM theophylline. A decrease in the rate of desensitization is observed during exposure to 0.25 mM cAMP. These results are interpreted in terms of a physiological mechanism whereby receptor activity at the postjunctional membrane is modulated by cAMP formed from prejunctionally released ATP.     

Chemotaxis of rat mast cells toward adenine nucleotides.

Rat mucosal mast cells express P2 purinoceptors, occupation of which mobilizes cytosolic Ca2+ and activates a potassium conductance. The primary function of this P2 system in mast cell biology remains unknown. Here, we show that extracellular ADP causes morphological changes in rat bone marrow-cultured mast cells (BMMC) typical of those occurring in cells stimulated by chemotaxins, and that the nucleotides ADP, ATP, and UTP are effective chemoattractants for rat BMMC. ADP was also a chemotaxin for murine J774 monocytes. The nucleotide selectivity and pertussis toxin sensitivity of the rat BMMC migratory response suggest the involvement of P2U receptors. Poorly hydrolyzable derivatives of ADP and ATP were effective chemotaxins, obviating a role for adenosine receptors. Buffering of external Ca2+ at 100 nM or reduction of the electrical gradient driving Ca2+ entry (by elevating external K+) blocked ADP-driven chemotaxis, suggesting a role for Ca2+ influx in this process. Anaphylatoxin C5a was a potent chemotaxin (EC50 approximately 0.5 nM) for J774 monocytes, but it was inactive on rat BMMC in the presence or absence of laminin. Ca2+ removal or elevated [K+] had modest effects on C5a-driven chemotaxis of J774 cells, implicating markedly different requirements for Ca2+ signaling in C5a- vs ADP-mediated chemotaxis. This is supported by the observation that depletion of Ca2+ stores with thapsigargin completely blocked migration induced by ADP but not C5a. These findings suggest that adenine nucleotides liberated from parasite-infested tissue could participate in the recruitment of mast cells by intestinal mucosa.     

Stimulation of glycogenolysis by adenine nucleotides in the perfused rat liver.

Infusion of adenine nucleotides and adenosine into perfused rat livers resulted in stimulation of hepatic glycogenolysis, transient increases in the effluent perfusate [3-hydroxybutyrate]/[acetoacetate] ratio, and increased portal vein pressure. In livers perfused with buffer containing 50 microM-Ca2+, transient efflux of Ca2+ was seen on stimulation of the liver with adenine nucleotides or adenosine. ADP was the most potent of the nucleotides, stimulating glucose output at concentrations as low as 0.15 microM, with half-maximal stimulation at approx. 1 microM, and ATP was slightly less potent, half-maximal stimulation requiring 4 microM-ATP. AMP and adenosine were much less effective, doses giving half-maximal stimulation being 40 and 20 microM respectively. Non-hydrolysed ATP analogues were much less effective than ATP in promoting changes in hepatic metabolism. ITP, GTP and GDP caused similar changes in hepatic metabolism to ATP, but were 10-20 times less potent than ATP. In livers perfused at low (7 microM) Ca2+, infusion of phenylephrine before ATP desensitized hepatic responses to ATP. Repeated infusions of ATP in such low-Ca2+-perfused livers caused homologous desensitization of ATP responses, and also desensitized subsequent Ca2+-dependent responses to phenylephrine. A short infusion of Ca2+ (1.25 mM) after phenylephrine infusion restored subsequent responses to ATP, indicating that, during perfusion with buffer containing 7 microM-Ca2+, ATP and phenylephrine deplete the same pool of intracellular Ca2+, which can be rapidly replenished in the presence of extracellular Ca2+. Measurement of cyclic AMP in freeze-clamped liver tissue demonstrated that adenosine (150 microM) significantly increased hepatic cyclic AMP, whereas ATP (15 microM) was without effect. It is concluded that ATP and ADP stimulate hepatic glycogenolysis via P2-purinergic receptors, through a Ca2+-dependent mechanism similar to that in alpha-adrenergic stimulation of hepatic tissue. However, adenosine stimulates glycogenolysis via P1-purinoreceptors and/or uptake into the cell, at least partially through a mechanism involving increase in cyclic AMP. Further, the hepatic response to adenine nucleotides may be significant in regulating hepatic glucose output in physiological and pathophysiological states.     

Net uptake of adenine nucleotides by newborn rat liver mitochondria

In newborn rat liver, the adenine nucleotide content (ATP + ADP + AMP) of mitochondria increases severalfold within 2 to 3 h of birth. The net increase in mitochondrial adenines suggests a novel mechanism by which mitochondria are able to accumulate adenine nucleotides from the cytosol (J. R. Aprille and G. K. Asimakis, 1980, Arch. Biochem. Biophys.201, 564.). This was investigated further in vitro. Isolated newborn liver mitochondria incubated with 1 mM ATP for 10 min at 30 °C doubled their adenine nucleotide content with effects on respiratory functions similar to those observed in vivo: State 3 respiration and adenine translocase activity increased, but uncoupled respiration was unchanged. The mechanism for net uptake of adenine nucleotides was found to be specific for ATP or ADP, but not AMP. Uptake was concentration dependent and saturable. The apparent K_m′s for ATP and ADP were 0.85 ± 0.27 mM and 0.41 ± 0.20 mM, respectively, measured by net uptake of [¹⁴C]ATP or [¹⁴C]ADP. The specific activities of net ATP and ADP uptake averaged 0.332 ± 0.062 and 0.103 ± 0.002 nmol/min/mg protein, respectively. ADP was a competitive inhibitor of net ATP uptake. If P_i was omitted from the incubations, net uptake of ATP or ADP was reduced by 51%. Either mersalyl or N-ethylmaleimide severely inhibited the accumulation of adenine nucleotides. Net ATP uptake was stoichiometrically dependent on MgCl₂, suggesting that Mg²⁺ is accumulated along with ATP (or ADP). Uptake was energy dependent as indicated by the following results: Net AdN uptake (especially ADP uptake) was stimulated by the addition of an oxidizable substrate (glutamate) and inhibited by FCCP (an uncoupler). Antimycin A had no effect on net ATP uptake but inhibited net ADP uptake, suggesting that ATP was able to serve as an energy source for its own accumulation. If carboxyatractyloside was added to inhibit the exchange translocase, thereby preventing rapid access of exogenous ATP to the matrix, net ATP uptake was inhibited; carboxyatractyloside had no effect on ADP uptake. It was concluded that the net uptake of adenine nucleotides from the extramitochondrial space occurs by a specific transport process distinct from the classic adenine nucleotide exchange translocase. The accumulation of adenine nucleotides may regulate matrix reactions which are allosterically affected by adenines or which require adenines as a substrate.     

5''-Nucleotidase from rat heart membranes. Inhibition by adenine nucleotides and related compounds.

ADP and ATP and their analogues were evaluated as inhibitors of 5'-nucleotidase purified from heart plasma membrane. ADP analogues are more powerful inhibitors than the corresponding ATP analogues. The most powerful inhibitor found is adenosine 5'-[alpha beta-methylene]diphosphate (AOPCP) for which the enzyme shows a Ki of 5 nM at pH 7.2. Measurements of pKi values for ADP and AOPCP as a function of pH indicate that the major inhibitory species of both nucleotides is the dianion. In the physiological range of pH values, AOPCP is a more powerful inhibitor than ADP principally because a higher percentage of AOPCP exists in the dianion form. The methylenephosphonate analogue of AMP (ACP), though not a substrate, is a moderately effective inhibitor. The corresponding analogues of ADP (ACPOP) and ATP (ACPOPOP) are as good inhibitors as ADP and ATP respectively. The thiophosphate analogues of ADP all inhibit 5'-nucleotidase, although not as powerfully as ADP, the most effective of these analogues being adenosine 5'-O-(1-thiodiphosphate) diastereoisomer B (ADP[alpha S](B)]. Other nucleotides inhibit the enzyme, but none is as effective as AOPCP. Inorganic tripolyphosphate and methylenediphosphonate are better inhibitors of the enzyme than is inorganic pyrophosphate. Inorganic thiophosphate is a better inhibitor than is orthophosphate. Hill plots of the ADP and AOPCP inhibition yield slopes close to 1; Hill plots of the ATP inhibition yield slopes of about 0.6. MgADP- is not an inhibitor, and MgATP2- is at best a very weak inhibitor of the enzyme.     

Identification of guanine and adenine nucleotides as activators of glucose-1,6-bisphosphatase activity from rat skeletal muscle.

Glucose-1,6-bisphosphatase activity in rat skeletal muscle extracts was lost after exhaustive dialysis or precipitation with ammonium sulfate. Most of the original activity was recovered when the boiled extract was added to the ammonium sulfate precipitate. Qualitative analysis of the boiled extract revealed that the activator was either a nucleoside or a nucleotide. The results show that at concentrations between 0.05 and 1 mM, only guanine and adenosine derivatives are effective as activators, the former being more powerful. However, only guanosine, ADP, and AMP have an activating effect at the concentrations found in the boiled extract. The results of assays in vitro suggest that adenine nucleotides could be physiological modulators of glucose-1,6-bisphosphatase activity during muscle contraction.     

The release of alanine by rat diaphragm muscle in vitro.

Z discs were isolated from Lethocerus flight muscle by removing the contractile proteins from myofibrils with a solution of high ionic strength. The protein composition of the Z discs was analysed by sodium dodecyl sulphate/polyacrylamide-gel electrophoresis; the major proteins were alpha-actinin, actin and tropomyosin. Z lines were selectively removed from intact myofibrils by digestion with crude lipase and chymotrypsin, but not by purified lipase.     

Purine salvage to adenine nucleotides in different skeletal muscle fiber types.

Rates of purine salvage of adenine and hypoxanthine into the adenine nucleotide (AdN) pool of the different skeletal muscle phenotype sections of the rat were measured using an isolated perfused hindlimb preparation. Tissue adenine and hypoxanthine concentrations and specific activities were controlled over a broad range of purine concentrations, ranging from 3 to 100 times normal, by employing an isolated rat hindlimb preparation perfused at a high flow rate. Incorporation of [(3)H]adenine or [(3)H]hypoxanthine into the AdN pool was not meaningfully influenced by tissue purine concentration over the range evaluated (approximately 0.10-1.6 micromol/g). Purine salvage rates were greater (P < 0.05) for adenine than for hypoxanthine (35-55 and 20-30 nmol x h(-1) x g(-1), respectively) and moderately different (P < 0.05) among fiber types. The low-oxidative fast-twitch white muscle section exhibited relatively low rates of purine salvage that were approximately 65% of rates in the high-oxidative fast-twitch red section of the gastrocnemius. The soleus muscle, characterized by slow-twitch red fibers, exhibited a high rate of adenine salvage but a low rate of hypoxanthine salvage. Addition of ribose to the perfusion medium increased salvage of adenine (up to 3- to 6-fold, P < 0.001) and hypoxanthine (up to 6- to 8-fold, P < 0.001), depending on fiber type, over a range of concentrations up to 10 mM. This is consistent with tissue 5-phosphoribosyl-1-pyrophosphate being rate limiting for purine salvage. Purine salvage is favored over de novo synthesis, inasmuch as delivery of adenine to the muscle decreased (P < 0.005) de novo synthesis of AdN. Providing ribose did not alter this preference of purine salvage pathway over de novo synthesis of AdN. In the absence of ribose supplementation, purine salvage rates are relatively low, especially compared with the AdN pool size in skeletal muscle.     

Regulation of mammalian asparagine synthetase by adenine nucleotides.

Initial velocity kinetic data indicate that ADP and AMP are inhibitors of mammalian liver asparagine synthetase. The non-product nucleotide ADP is a much more potent inhibitor than AMP, although both apparently compete for the same site. This modifier site, however, does not overlap spatially with the substrate site for ATP. Both ADP and AMP are V_max inhibitors, but ADP also raises the K_m for ATP. Adenylate energy charge, calculated at various levels of ATP and ADP show typical correlations with activity, but with AMP these correlations are weak and atypical.     

Translocation and binding of adenine nucleotides by rat liver mitochondria partially depleted of phospholipids.

1. Rat liver mitochondria were partially depleted of their phospholipids using phospholipase A prepared from porcine pancreas (substrate specificity, cardiolipin greater than phosphatidylethanolamine greater than phosphatidylcholine) or from Crotalus adamanteus venom (substrate specificity, phosphatidylethanolamine = phosphatidylcholine greater than cardiolipin). 2. Removal of only about 1% of the mitochondrial phospholipid with the pancreatic enzyme leads to 50% and 25% losses in ADP and ATP translocation, respectively. Concomitant with the loss in translocation is a decline in the ability of both carbonylcyanide m-chlorophenylhydrazone and Ca2+ to stimulate ATP translocation. 3. To achieve comparable losses in ADP and ATP translocation with the venom enzyme, it is necessary to remove about 8% of the total mitochondrial phospholipid. Following such treatment, carbonylcyanide m-chlorophenylhydrazone and Ca2+ are still capable of stimulating ATP translocation. 4. Control experiments involving treatment of the mitochondria with the products of phospholipase digestion indicate that the effects observed on the translocase reflect a loss of phospholipid from the membrane. 5. Binding studies indicate that the loss in adenine nucleotide translocation following phospholipase treatment cannot be accoundted for by an altered ability to bind adenine nucleotides to atractyloside-sensitive sites. 6. The data are interpreted in terms of a mechanism of adenine nucleotide translocation involving a lipoprotein carrier system, consisting of the translocator protein and phospholipids, possibly cardiolipin and phosphatidylethanolamine.     

Power fatigue of the rat diaphragm muscle.

We hypothesized that decrements in maximum power output (W(max)) of the rat diaphragm (Dia) muscle with repetitive activation are due to a disproportionate reduction in force (force fatigue) compared with a slowing of shortening velocity (velocity fatigue). Segments of midcostal Dia muscle were mounted in vitro (26 degrees C) and stimulated directly at 75 Hz in 400-ms-duration trains repeated each second (duty cycle = 0.4) for 120 s. A novel technique was used to monitor instantaneous reductions in maximum specific force (P(o)) and W(max) during fatigue. During each stimulus train, activation was isometric for the initial 360 ms during which P(o) was measured; the muscle was then allowed to shorten at a constant velocity (30% V(max)) for the final 40 ms, and W(max) was determined. Compared with initial values, after 120 s of repetitive activation, P(o) and W(max) decreased by 75 and 73%, respectively. Maximum shortening velocity was measured in two ways: by extrapolation of the force-velocity relationship (V(max)) and using the slack test [maximum unloaded shortening velocity (V(o))]. After 120 s of repetitive activation, V(max) slowed by 44%, whereas V(o) slowed by 22%. Thus the decrease in W(max) with repetitive activation was dominated by force fatigue, with velocity fatigue playing a secondary role. On the basis of a greater slowing of V(max) vs. V(o), we also conclude that force and power fatigue cannot be attributed simply to the total inactivation of the most fatigable fiber types.     

Differential adenosine sensitivity of diaphragm and skeletal muscle arterioles.

The hyperemic response in exercising skeletal muscle is dependent on muscle fiber-type composition and fiber recruitment patterns, but the vascular control mechanisms producing exercise hyperemia in skeletal muscle remain poorly understood. The purpose of this study was to test the hypothesis that arterioles from white, low-oxidative skeletal muscle are less responsive to adenosine-induced dilation than are arterioles from diaphragm (Dia) and red, high-oxidative skeletal muscle. Second-order arterioles (2As) were isolated from the white portion of gastrocnemius muscle (WG; low-oxidative, fast-twitch muscle tissue) and two types of high-oxidative skeletal muscle [Dia and red portion of gastrocnemius muscle (RG)] of rats. Results reveal that 2As from all three types of muscle dilated in response to the endothelium-dependent dilator acetylcholine (WG: 48 +/- 3%, Dia: 51 +/- 3%, RG: 74 +/- 3%). In contrast, adenosine dilated only 2As from WG (48 +/- 4%) and Dia (46 +/- 5%) but not those from RG (5 +/- 5%). Thus adenosine-induced dilator responses differed among 2As of these different types of muscle tissue. However, the results do not support our hypothesis because 2As from Dia and WG dilated in response to adenosine, whereas 2As from RG did not. We conclude that the adenosine responsiveness of 2As from rat skeletal muscle cannot be predicted only by the fiber-type composition or oxidative capacity of the skeletal muscle tissue wherein the arteriole lies.