Ca2+-antagonists inhibit the N-methyltransferase-dependent synthesis of phosphatidylcholine in the heart.

Evidence indicates that, in addition to the L-type Ca2+ channel blockade, Ca2+-antagonists target other functions including the Ca2+-pumps. This study was conducted to test the possibility that the reported inhibition of heart sarcolemmal (SL) and sarcoplasmic reticular (SR) Ca2+-pumps by verapamil and diltiazem could be due to drug-induced depression of phosphatidylethanolamine (PE) N-methylation which modulates these Ca2+-transport systems. Three catalytic sites individually responsible for the synthesis of PE monomethyl (site I), dimethyl (site II) and trimethyl (phosphatidylcholine (PC), site III) derivates were examined in SL and SR membranes by employing different concentrations of S-adenosyl-L-methionine (AdoMet). Total methyl group incorporation into SL PE, in vitro, was significantly depressed by 10(-6)-10(-3) M verapamil or diltiazem at site III. The catalytic activity of site I was inhibited by 10(-3) M verapamil only, whereas the site II activity was not affected by these drugs. The inhibition induced by verapamil or diltiazem (10(-5) M) was associated with a depression of the Vmax value without any change in the apparent affinity for AdoMet. Both drugs decreased the SR as well as mitochondrial PE N-methylation at site III. A selective depression of site III activity was also observed in SL isolated from hearts of rats treated with verapamil in vivo. Furthermore, administration of [3H-methyl]-methionine following the treatment of animals with verapamil, reduced the synthesis of PC by N-methyltransferase. Verapamil also depressed the N-methylation-dependent positive inotropic effect induced by methionine in the isolated Langendorff heart. Both agents depressed the SL Ca2+-pump and although diltiazem also inhibited the SR Ca2+-pump, verapamil exerted a stimulatory effect. In addition, verapamil decreased SR Ca2+-release. These results suggest that verapamil and diltiazem alter the cardiac PE N-methyltransferase system. This action is apparently additional to the drugs' effect on L-type Ca2+ channels and may serve as a biochemical mechanism for the drugs' inhibition of the cardiac Ca2+-pumps and altered cardiac function.

Domoic acid-induced neurodegeneration resulting in memory loss is mediated by Ca2+ overload and inhibition of Ca2+ + calmodulin-stimulated adenylate cyclase in rat brain (review).

Domoic acid is a shellfish toxin which produces neurodegeneration and CNS dysfunction, notably a loss of short-term memory. This toxin was found in blue mussels (Mytilus edulis) cultivated in river water in the east coast of Prince Edward Island in Canada and caused human poisoning. The toxin was localized in the stomach of blue mussels, which was engorged with algae, Nitzschia pungens, that were filtered from the surrounding water. The toxin was isolated from contaminated mussels or phytoplankton, and identified chemically as domoic acid (DOM) which is a tricarboxylic amino acid. Due to its structural resemblance to glutamic, aspartic and kainic acids, DOM was considered to produce excitotoxicity by similar mechanism(s). However, the latest evidence indicates differences in its mode of action from these excitatory agonists. We propose that DOM induces toxicity via changes in intracellular concentration of Ca2+ ([Ca2+]i). Results of our studies demonstrate that DOM elevated [Ca2+]i in brain slices. Glucose deprivation and removal of Na+ from the Krebs-bicarbonate medium further elevated [Ca2+]i, suggesting a relationship between glucose metabolism (cell energy), Na+ and Ca2+ transfer across neuronal membrane. DOM-induced rise in [Ca2+]i was due to enhanced Ca2+ influx and its mobilization from the endoplasmic reticulum. In addition, diminished Ca2+-ATPase activity due to lack of ATP, and variable amounts and expression of calcium binding proteins (CaBP) appear to contribute to an elevation in [Ca2+]i in response to DOM. Most interestingly, DOM inhibited Ca2+ and calmodulin-stimulated adenylate cyclase activity in brain membranes, resulting in reduced level of cyclic AMP. Cyclic AMP is known to activate protein kinase A to enhance phosphorylation of Ca2+ channels, thereby, reducing Ca2+ influx to prevent the development of Ca2+ overload which is detrimental to neuronal cell function (neuroprotection). However, DOM reduced cyclic AMP level, diminishing the feedback control of cyclic AMP on Ca2+ influx via Ca2+ channels, thereby, allowing continuing enhanced Ca2+ influx, resulting in Ca2+ overload which adversely affects many intracellular processes to induce toxicity. Ca2+ and CaM-stimulated adenylate cyclase activity in brain is highly correlated with the acquisition and retention of memory in different organisms. Calcium binding proteins bind Ca2+ reversibly and provide intracellular Ca2+ buffering, thereby, protecting neuronal cell from damage by Ca2+ overload in response to DOM. DOM appears to interfere with the cross talk between Ca2+ and cyclic AMP which is necessary for neuronal cell function. We have also demonstrated that DOM stimulates GLU release from synaptosomes and may produce some of its toxic effects via excess GLU in the neuronal synapse. In conclusion, DOM-induced neurodegeneration resulting in a loss of memory is mediated by Ca2+ overload, inhibition of Ca2+ and CaM-stimulated adenylate cyclase activity, and/or by the enhanced GLU release in rat brain.

Effect of pH on domoic acid toxicity in mice.

Domoic acid is a shellfish toxin which produces gastrointestinal distress, followed by neurological symptoms such as headache, confusion, disorientation and severe deficits in short-term memory. Domoic acid is an amino acid which contains three carboxylic groups, and one imino group, and its solubility, rate of absorption, and elimination would vary depending on the protonation of these groups at different pH's. We propose that domoic acid toxicity varies with pH of administered domoic acid solution. Domoic acid toxicity was measured in mice as the onset times for scratching behaviour, seizure activity, and death, after the intraperitoneal administration of domoic acid at different pH's. Results of the present study show that the scratching behaviour, seizure activity, and death, occurred at 12, 40, and 55 min, after intraperitoneal administration of domoic acid at pH 3.7. Apparently, the onset times for three types of behaviours were relatively long, and well separated from each other. Domoic acid toxicity was lowest at pH 3.7, and highest at pH 7.4, with intermediate toxicity at other pH's. The onset time of scratching behaviour was not influenced by pH of domoic acid solution at three different doses. In contrast, the onset times for seizure activity, and death were significantly affected by pH of domoic acid, toxicity being higher at pH 7.4 than at pH 3.7. The pH effect on domoic acid toxicity diminished as the dose of domoic acid was increased. In fact, at 14.5 mg/kg domoic acid toxicity was similar at both pH's of 3.7 and 7.4. It is concluded that in vivo toxicity of domoic acid varies depending on pH of the administered solution. The differential toxicity of domoic acid at different pH may be related to its solubility, rate of absorption, and elimination, depending on the degree of protonation of domoic acid molecule. Domoic acid toxicity would also vary depending on the age of animal, receptor sensitivity and density in different regions of brain.

The release of glutamate and aspartate from rat brain synaptosomes in response to domoic acid (amnesic shellfish toxin) and kainic acid.

Kainic acid is known to stimulate the release of glutamate (GLU) and aspartate (ASP) from presynaptic neurons. It has been suggested that the enhanced release of these endogenous EAA's plays a significant role in the excitotoxic effects of KA. Domoic acid (DOM), a shellfish toxin, is structurally similar to KA, and has been shown to be 3-8 times more toxic than KA. In this study, effects of KA and DOM on the release of GLU and ASP from rat brain synaptosomes were investigated. Amino acid analysis was performed by the reversed phase HPLC, following derivatization with 9-fluorenylmethyl chloroformate (FMOC). Potassium chloride (40 mM) was used as a positive control, and stimulated GLU release from rat brain synaptosomes in presence or absence of Ca2+. DOM enhanced the release of GLU, whereas KA stimulated the release of both GLU and ASP from synaptosomes in the presence of Ca2+. However, their potency to stimulate GLU and ASP release was enhanced in absence of Ca2+. These results indicate that different mechanisms may be involved in the release of GLU and ASP in response to DOM and KA, and that neurotransmitter release appeared to be highly specific for these agonists. It would appear that DOM and KA may interact with different receptors on the presynaptic nerve terminal, and/or activate different subtypes of voltage-dependent Ca2+ channels to promote influx of Ca2+ which is targeted for different pools neurotransmitters.

Domoic acid inhibits adenylate cyclase activity in rat brain membranes.

Adenylate cyclase activity measured by the formation of cyclic AMP in rat brain membranes was inhibited by a shellfish toxin, domoic acid (DOM). The inhibition of enzyme was dependent on DOM concentration, but about 50% of enzyme activity was resistant to DOM-induced inhibition. Rat brain supernatant resulting from 105,000 x g centrifugation for 60 min, stimulated adenylate cyclase activity in membranes. Domoic acid abolished the supernatant-stimulated adenylate cyclase activity. The brain supernatant contains factors which modulate adenylate cyclase activity in membranes. The stimulatory factors include calcium, calmodulin, and GTP. In view of these findings, we examined the role of calcium and calmodulin in DOM-induced inhibition of adenylate cyclase in brain membranes. Calcium stimulated adenylate cyclase activity in membranes, and further addition of calmodulin potentiated calcium-stimulated enzyme activity in a concentration dependent manner. Calmodulin also stimulated adenylate cyclase activity, but further addition of calcium did not potentiate calmodulin-stimulated enzyme activity. These results show that the rat brain membranes contain endogenous calcium and calmodulin which stimulate adenylate cyclase activity. However, calmodulin appears to be present in membranes in sub-optimal concentration for adenylate cyclase activation, whereas calcium is present at saturating concentration. Adenylate cyclase activity diminished as DOM concentration was increased, reaching a nadir at about 1 mM. Addition of calcium restored DOM-inhibited adenylate cyclase activity to the control level. Similarly, EGTA also inhibited adenylate cyclase activity in brain membranes in a concentration dependent manner, and addition of calcium restored EGTA-inhibited enzyme activity to above control level.(ABSTRACT TRUNCATED AT 250 WORDS)

Effects of domoate, glutamate and glucose deprivation on calcium uptake by rat brain tissue in vitro.

The toxic effects of excitatory amino acids (EAAs) on the central nervous system appear to be mediated by calcium. Calcium uptake into rat brain tissue slices was studied in the absence and in the presence of domoate and glutamate. Calcium uptake into brain cytoplasm was enhanced by domoate in a concentration-dependent manner. Glutamate also stimulated calcium uptake. Calcium uptake into brain tissue was enhanced markedly by the removal of glucose from the Krebs-Henseleit-Ringer bicarbonate incubation medium. Stimulation of calcium uptake by glucose deprivation increased with incubation time, suggesting the depletion of energy stores, i.e. ATP, which is necessary for calcium transport in brain tissue. Replacement of NaCl with choline chloride in the incubation medium also enhanced calcium uptake into brain tissue cytosol. The removal of both glucose and NaCl from the medium produced an additive effect on calcium uptake, indicating independent mechanisms of action. NaF stimulated calcium uptake into brain tissue more in the presence of glucose than in its absence. Since NaF is an inhibitor of glucose metabolism, these results indicate that glucose metabolism is somehow linked to calcium transport in brain tissue. Since ATP is required by calcium pumps, which extrude as well as store calcium in nervous tissue cells, depletion of ATP, either in the absence of glucose or when glucose metabolism is blocked by NaF, may be responsible for the accumulation of calcium in the brain tissue cytosol, and for the neurotoxicity induced by domoate and glutamate.

A procedure for large-scale purification of domoic acid from toxic blue mussels (Mytilus edulis)

Pure domoic acid is required for use in research to investigate the biological effects of this new shellfish toxin. It may also prove to be a useful tool in studies exploring the basis of Alzheimer's disease. In this paper we describe a procedure which is effective in obtaining adequate quantities of pure domoic acid from blue mussel (Mytilus edulis). The procedure involves tissue homogenization, treatment of homogenate with chloroform and methanol, and separation of different phases with the addition of water. The aqueous-methanolic phase (upper layer) contains water soluble components including domoic acid, the chloroform phase (lower layer) contains lipoid moieties, and the interphase contains denatured proteins. The aqueous phase containing domoic acid was removed, rotory evaporated to get rid of methanol, followed by ultrafiltration to remove high molecular weight contaminants. The filtrate was lyophilized, resuspended in 1 N HCl, centrifuged and the resulting clear solution subjected to column chromatography on C18 reversed phase silica gel. Fractions containing domoic acid were pooled, and lyophilized. A brownish dry powder contained pure domoic acid with 60-65% yield from the original tissue homogenate. Another 10-15% of domoic acid was mixed with its isomer, and can be further resolved to obtain an overall recovery of 75-80% of the starting material.

Purification of domoic acid from toxic blue mussels (Mytilus edulis) and phytoplankton.

Domoic acid was the primary neurotoxin in blue mussel (Mytilus edulis) that caused poisoning in humans. Further research showed that the algae, Nitzschia pungens, was the source of this toxin. In this study, a method for the extraction and purification of domoic acid from contaminated mussels and phytoplankton was developed. Domoic acid was extracted from these sources by treatment with a mixture of chloroform and methanol (1:2, v/v). The resulting extract was subjected to ultrafiltration through a PM1 Millipore filter, followed by repeated high-performance liquid chromatography on a reversed-phase column. The purity and yield of domoic acid prepared by this method are compared with two previously described methods of extraction. The current method is relatively simple, rapid, and results in improved recovery with comparable purity of domoic acid.

Mechanism of adenylate cyclase activation by the rat lung cytoplasmic factors.

Epinephrine, histamine and prostaglandin E1 stimulated adenylate cyclase activity in lung membranes and their stimulation of the enzyme activity was completely blocked by propranolol, metiamide and indomethacin, respectively. A partially-purified activator from the adult rat lung also enhanced adenylate cyclase activity in membranes. However, stimulation of adenylate cyclase by the rat lung activator was not abolished by the above receptor antagonists. Further, epinephrine, NaF and Gpp(NH)p stimulated adenylate cyclase activity rather readily, whereas stimulation of the enzyme activity by the lung activator was evident after an initial lag phase of 10 min. Also, the lung activator produced additive activation of adenylate cyclase with epinephrine, NaF and Gpp(NH)p. These results indicate that the lung activator potentiates adenylate cyclase activity in membranes by a mechanism independent from those known for epinephrine, NaF and Gpp(NH)p. Incubation of lung membranes for 30 min at 40 degrees C resulted in a loss of adenylate cyclase activation by NaF and Gpp(NH)p. Addition of the released proteins to the heat-treated membranes did not restore the enzyme response to these agonists. However, heat treatment of lung membranes in the presence of 2-mercaptoethanol or dithiothreitol prevented the loss of adenylate cyclase response to NaF and Gpp(NH)p. N-ethylmaleimide abolished adenylate cyclase activation by epinephrine, NaF, Gpp(NH)p and the lung activator. These results indicate that the sulfhydryl groups are important for adenylate cyclase function in rat lung membranes.

Effects of premature weaning and diet on lung growth and appearance of adenylate cyclase activator in rat lung.

Early weaning of rat pups on day 16 to semi-ground Purina chow food and drinking water, ad libitum, delayed growth of body and lungs, and the appearance of adenylate cyclase activator (ACA) in lung after day 22. However, early weaning of pups to either milk or a gel diet containing semi-ground Purina chow food, agarose gel, water (30:1:69, w/w), and drinking water, restored lung and body growth and the appearance of ACA to control values. Early weaning of pups to dry semi-ground Purina chow food and drinking water also induced a transient rise in ACA on day 19. This early rise in ACA was completely absent in pups weaned on day 16 to milk, whereas it persisted in pups weaned similarly to a gel diet. Interestingly, lung glycogen decreased on day 19 in pups weaned early to dry semi-ground Purina chow food without (group 2) or with triiodothyronine administration (group 3), and on day 25 after normal weaning on day 22 (Nijjar, M.S. Biochim. Biophys. Acta 586: 464-472, 1979). These data indicate 1) that reduced food intake (starvation) in pups weaned on day 16 to dry semi-ground Purina chow food was responsible for the delayed growth of body and lung, and the delayed appearance of ACA in lung after day 22, and 2) that a change in diet from milk to Purina chow food and associated alterations in hormones, possibly cortisol and insulin, were responsible for the appearance of ACA in rat lung.(ABSTRACT TRUNCATED AT 250 WORDS)

Relationship between domoic acid levels in the blue mussel (Mytilus edulis) and toxicity in mice.

Monitoring of eastern blue mussels (Mytilus edulis), contaminated with domoic acid, involved mouse bioassays and quantitative analysis using HPLC. Mice undergo a typical scratching syndrome at sublethal as well as lethal doses of domoic acid. The onset of scratching behaviour and time of death in mice were inversely related to the dosage of domoic acid. An LD50 (i.p.) of 3.6 mg domoic acid/kg mouse was calculated. Toxic mussels held in tanks and flushed with uncontaminated sea water showed a decline in domoic acid concentration in mussel tissue with time. In addition, domoic acid concentrations in mussels from two infected rivers declined to negligible levels in 40-50 days under normal environmental conditions. The bulk of domoic acid and toxicity was located in the hepatopancreas which also contained large amounts of chlorophyll-A, an algae biomass indicator, relative to control mussels. These results support the conclusion that domoic acid was the primary causative factor in the shellfish poisonings from Prince Edward Island mussels in late 1987.

The rate of degradation of liver glycogen phosphorylase is specifically decreased in the C57BL/KsJ-db/db mouse.

We have recently demonstrated that the activity of liver glycogen phosphorylase, the rate-limiting enzyme of glycogenolysis, is elevated in genetically diabetic (db/db) mouse and that it is primarily due to the presence of increased amounts of this enzyme. In the present study, we examined the turnover of glycogen phosphorylase in vivo in order to elucidate the mechanism for this specific increase. The rate of phosphorylase synthesis was slightly decreased in the diabetic mouse compared to controls. However, the relative rates of synthesis were similar in these two groups. The rate of degradation of this enzyme was decreased 20% (p less than 0.05) in the diabetic mouse compared to controls. More importantly, the relative rate of degradation of phosphorylase was found to be lower in the diabetic animals. This indicates that the elevated concentration of phosphorylase in the liver of the db/db mouse is likely due to a specific decrease in its rate of degradation.

Endocrine control of cytosolic factors stimulating adenylate cyclase in rat lung.

Endocrine control of cytoplasmic factors modulating adenylate cyclase activity in rat lung membranes was investigated. Hypophysectomy, adrenalectomy and thyroidectomy showed an adverse effect on the body and organ weights. Lung protein, glycogen and DNA contents were decreased in the endocrine ablated animals which were restored to the normal values on hormone treatment. Phosphodiesterase and phosphorylase activities were increased and decreased in adrenalectomized and thyroidectomized animals, respectively. The activities of these enzymes were restored to normal values on hormone treatment. Adrenalectomy and thyroidectomy affected ATPases differently. Basal adenylate cyclase activity in rat lung membranes was not affected by adrenalectomy and hormone treatment. However, the total enzyme activity was increased by both dexamethasone (DEX) and thyroxine (T4) treatments. The activation of the particulate adenylate cyclase by the cytoplasmic factors was markedly decreased in the lung from hypophysectomized, adrenalectomized and thyroidectomized rats. This decrease in the cytoplasmic activation of adenylate cyclase was restored to or above the control values on hormone treatment. Alteration in the activation of enzyme by cytoplasmic factors did not appear to be due to the change in the responsiveness of the enzyme. Glucocorticoids appeared to have a specific effect on the cytoplasmic factors modulating the enzyme.

Relationship between the cytoplasmic activator of adenylate cyclase and glycogen metabolism in rat lung.

The role of cytoplasmic activator of adenylate cyclase in rat lung metabolism was investigated. Mouse adrenal tumor (MAT) cells undergo differentiation in response to choleratoxin which acts through cyclic AMP. The activator of adenylate cyclase from rat lung also produced cyclic AMP in a disrupted MAT cell preparation. However, unlike choleratoxin, it did not induce MAT cell differentiation in whole cells. These results suggest impermeability of MAT cells, and possibly other cells, to the activator. Thus, means of altering activator activity in lung cytoplasm were sought, and changes in activator activity were related to lung glycogen. Adrenalectomy (ADX) in rats led to a reduction in activator activity that was accompanied by an elevation in lung glycogen. Dexamethasone treatment of adrenalectomized rats reversed both of these effects. Streptozotocin-induced diabetes in rats elevated activator activity and lowered lung glycogen. Insulin treatment of the diabetic rats restored activator activity to the normal control values. Preweaning of rats on day 16 instead of day 22 increased activator activity on the 19th day over the controls and there was a concomitant decrease in lung glycogen. Feeding the separated pups with homogenized milk restored glycogen and activator activity to the control values. These results indicate that activator activity in rat lung cytoplasm was dependent on the circulating levels of cortisol and insulin, and that there appeared to be an inverse relationship between activator activity and glycogen level in rat lungs.

Further purification and partial characterization of the rat lung cytoplasmic factors modulating adenylate cyclase activity in plasma membrane.

The adult rat lung cytoplasm contains some factors which markedly stimulate adenylate cyclase activity in plasma membranes (Nijjar, M.S. Biochim. Biophys. Acta 584:43-50, 1979). Adenylate cyclase activator (ACA) was purified from rat lungs by DEAE-cellulose chromatography, preparative isoelectric focusing and by repeated high-performance liquid chromatography on a Sepharogel TSK 2000SW column. The final preparation showed about 200 fold purification in ACA activity over the original lung supernatant, and appeared to be homogeneous on the basis of its migration into a single band on SDS-polyacrylamide gel electrophoresis, and co-elution of ACA activity with protein from a gel exclusion column. ACA is an acidic (pI 4.8 +/- 0.1), heat labile, monomeric protein of 40,000 +/- 2,000 dalton molecular weight, and does not resemble calmodulin.

Role of cyclic adenosine monophosphate in rat lung development.

The objective of this study was to identify the biochemical mechanisms concerned with pulmonary growth and development. The data show that cyclic adenosine monophosphate (cAMP), adenylate cyclase, cAMP phosphodiesterase, and their regulation by intracellular modulators are important to the development of rat lungs. The presence in rat lung cytoplasm of factors modulating adenylate cyclase activity is described. These factors appear to be important physiologically as they are present in vivo, they appear in the cytoplasm at a specific age, and their activity is altered by diabetes and adrenalectomy and restored to original levels by administration of insulin and dexamethasone, respectively. The cytoplasmic activation of adenylate cyclase appears to be due to multiple proteins that can be resolved into less active components by DEAE-cellulose chromatography. Recombination of these proteins not only restored activity to the original level but actually resulted in more than additive activation, indicating some interdependence and positive cooperativity among the different components to maximally stimulate adenylate cyclase activity. The rat lung cytoplasmic activator protein regulates adenylate cyclase by a mechanism different from those reported for epinephrine, NaF, 5'-guanylimidophosphate, and calmodulin.

Phosphoinositide breakdown in isolated rat parotid membranes. Stimulation by cholinergic and alpha-adrenergic agonists.

Parotid gland membranes labelled with [3H]inositol were challenged with the cholinergic agonist, carbamylcholine, or with epinephrine in the presence of propranolol. Both agonists caused a significant breakdown of labelled phosphoinositides (17.5%) in membranes suspended in Krebs-Ringer bicarbonate buffer. This effect was abolished by the respective antagonists, atropine or phentolamine. The carbamylcholine-induced breakdown of labelled phosphoinositides did not require cytosol. The addition of cytosol alone, or the exposure of membranes to a medium of low ionic strength caused a significant breakdown of phosphoinositides (10-40%). No further breakdown due to the addition of carbamylcholine was observed under these conditions. It is suggested that neurotransmitter-induced breakdown of phosphoinositides is effected by membrane-associated enzyme(s) and can be observed only in a medium of high ionic strength.

The effect of maternal diabetes on the synthesis and secretion of phosphatidylcholine in fetal and maternal rat lungs in vitro.

Incorporation of (methyl-14C)choline into phosphatidylcholine and the release of prelabelled phosphatidylcholine was investigated in vitro using lung slices from pregnant rats and their offspring near term. Tissue from normal, diabetic and insulin-treated diabetic pregnant rats and their offspring was utilized to assess the effects of maternal diabetes on fetal lung maturation. The results show that the synthesis of phosphatidylcholine in fetal/newborn lungs through the cytidine 5'-diphosphocholine pathway was not affected by maternal diabetes. However, secretion of phosphatidylcholine from the lungs of fetuses of diabetic mothers was very much suppressed one day after parturition. Insulin treatment of the diabetic pregnant rats restored secretion of phosphatidylcholine from the fetal/newborn lungs to control values. These results suggest that an impaired secretion of phosphatidylcholine from the lungs of fetuses of diabetic mothers may be partly responsible for the higher incidence of respiratory distress syndrome among children of diabetic mothers. The results also revealed some correlation between the secretion of phosphatidylcholine from maternal lungs, maternal serum phospholipids and synthesis of phosphatidylcholine by fetal lungs during late gestation, suggesting a possible relationship between maternal phospholipid metabolism and fetal lung maturation.

Ventilation-induced release of phosphatidylcholine from neonatal-rat lungs in vitro.

Factors regulating the release of phosphatidylcholine (PC) from neonatal-rat lungs were investigated. The results show that the release of prelabelled PC from the newborn-rat lung was augmented by air ventilation at the onset of breathing. This response was mimicked in lungs of pups delivered 1 day before term and allowed to breathe for different time intervals. Anoxia further augmented the ventilation-enhanced PC release from the newborn-rat lungs. The ventilation-induced release of PC was not abolished by the prior treatment of pups in utero or mothers in vivo with phenoxybenzamine, propranolol or atropine, suggesting the lack of receptor stimulation in the ventilation-enhanced PC release at birth. The results also show that ventilation stimulated [methyl-14C]choline incorporation into lung PC, presumably to replenish the depleted surfactant stores. The ratio of adenylate cyclase/cyclic AMP phosphodiesterase activities, which reflects cyclic AMP levels in the developing rat lungs, did not change during the 120 min of air ventilation when the release of PC was much enhanced, implying that cyclic AMP may not be involved. This confirms our conclusion that stimulation of beta-adrenergic receptor was not involved in the air-ventilation-enhanced release of PC. Since the cell number or size did not change during 120 min of ventilation when the alveolar-cell surface was maximally distended, it is suggested that distension of alveolar wall by air ventilation at the onset of breathing may bring the lamellar bodies containing surfactant close to the luminal surface of alveolar type II cells, thereby enhancing their fusion and extrusion by exocytosis.