The response of primary cultured adult mouse sensory neurons to ethanol,propanol, acetaldehyde and acrolein treatments

Primary cultures of adult mouse sensory neurons maintained for 8 days in vitro (8 div), in both the presence of non-neuronal cell (NNC) outgrowth and in NNC-reduced cultures, were exposed to doses of ethanol, propanol, acetaldehyde and acrolein. The effects on cell viability were monitored: LD50’s of 600 μM acrolein and 100 mM propanol were obtained after 24 h exposures and after 48 h with 1 mM acetaldehyde and 500 mM ethanol. Morphological effects were evident by scanning electron microscopy with sub-acute doses for each agent, using both lower concentrations and shorter exposures. Membrane pitting of the perikaryon and a reduction in the proportion of neurons bearing neurites were common signs of toxic insult. The neurites of treated cells were thicker and more irregular than those of untreated cells; this proved a good indicator of specific neurotoxicity rather than merely a cytotoxic response. Fetal calf serum in the medium lessened the response of neurons to ethanol treatments. Comparison with other in vitro studies suggests these primary cultures are a more sensitive system than established cell lines of neuronal origin for use in neurotoxicity testing.     

The response of primary cultured adult mouse sensory neurons to ethanol, propanol, acetaldehyde and acrolein treatments

Primary cultures of adult mouse sensory neurons maintained for 8 days in vitro (8 div), in both the presence of non-neuronal cell (NNC) outgrowth and in NNC-reduced cultures, were exposed to doses of ethanol, propanol, acetaldehyde and acrolein. The effects on cell viability were monitored: LD50's of 600 microM acrolein and 100 mM propanol were obtained after 24 h exposures and after 48 h with 1 mM acetaldehyde and 500 mM ethanol. Morphological effects were evident by scanning electron microscopy with sub-acute doses for each agent, using both lower concentrations and shorter exposures. Membrane pitting of the perikaryon and a reduction in the proportion of neurons bearing neurites were common signs of toxic insult. The neurites of treated cells were thicker and more irregular than those of untreated cells; this proved a good indicator of specific neurotoxicity rather than merely a cytotoxic response. Fetal calf serum in the medium lessened the response of neurons to ethanol treatments. Comparison with other in vitro studies suggests these primary cultures are a more sensitive system than established cell lines of neuronal origin for use in neurotoxicity testing.     

A comparison between acute exposures to ethanol and acetaldehyde on neurotoxicity, nitric oxide production and NMDA-induced excitotoxicity in primary cultures of cortical neurons

Chronic exposure of primary neuronal cultures to ethanol has been shown to potentiate N-methyl-D-aspartate (NMDA) receptor-mediated processes, such as nitric oxide (NO) formation and excitotoxicity. In the present study, we compared the effects of acute ethanol and acetaldehyde on NMDA receptor-mediated excitotoxicity and NO production in primary cultures of rat cortical neurons. The delayed cell death induced by NMDA (300 mM, 25 min) was evaluated by morphological examination and by measuring the release of the cytotoxic indicator, lactate dehydrogenase, in the culture media 24 hours after the NMDA exposure. The accumulation of nitrite, as an index of NO production, was also measured 24 hours after NMDA treatment. NMDA caused a dose-dependent cell death and nitrite accumulation, both effects were blocked by pretreatment of MK-801 (100 microM). Acute exposure to ethanol (1-1000 mM) or acetaldehyde (0.1-1 mM) for 35 minutes did not affect neuronal viability in the following 24-hr period. However, acute exposure to acetaldehyde (> or =10 mM) was neurotoxic. Neither ethanol nor acetaldehyde changed basal nitrite levels in the culture media. Acute ethanol (50-400 mM, 10 min) given before the NMDA treatment (25 min) resulted in a concentration-dependent suppression of the delayed cell death. The NMDA-induced NO production was, however, not affected by ethanol. Neither the NMDA excitotoxicity nor NO production was affected by acute ethanol given after NMDA treatment. Acute acetaldehyde (0.01-0.5 mM, 10 min) given before or after NMDA treatment had no effect on delayed NMDA neurotoxicity and NO production. Our data suggest that acute exposure to ethanol is not neurotoxic and is even protective against delayed NMDA-excitotoxicity when given before but not after NMDA treatment. Neither NO nor metabolism of ethanol to acetaldehyde is required for ethanol-mediated suppression of NMDA excititoxicity. Acetaldehyde, on the other hand, is toxic by itself at low concentrations (> or =10 mM). Furthermore, acute exposure to non-toxic concentrations of acetaldehyde could not protect cortical neurons against NMDA-induced excitotoxicity.     

Effects of chronic exposure to ethanol on the physical and functional properties of the plasma membrane of S49 lymphoma cells

The effects of chronic exposure to ethanol on the physical and functional properties of the plasma membrane were examined with cultured S49 lymphoma cells. The beta-adrenergic receptor-coupled adenylate cyclase system was used as a probe of the functional properties of the plasma membrane. Steady-state fluorescence anisotropy of diphenylhexatriene and the lipid composition of the plasma membrane were used as probes of the physical properties of the membrane. Cells were grown under conditions such that the concentration of ethanol in the growth medium remained stable and oxidation of ethanol to acetaldehyde was not detected. Chronic exposure of S49 cells to 50 mM ethanol or growth of cells at elevated temperature resulted in a decrease in adenylate cyclase activity. There were no changes in the density of receptors or in the affinity of beta-adrenergic receptors for agonists or antagonists following chronic exposure to ethanol. The fluorescence anisotropy of diphenylhexatriene was lower in plasma membranes prepared from cells that had been treated with 50 mM ethanol than in membranes prepared from control cells. However, this change was not associated with changes in the fatty acid composition or the cholesterol to phospholipid ratio of the plasma membrane. There was a small but statistically significant decrease in the amount of phosphatidylserine and an increase in the amount of phosphatidylethanolamine. These changes cannot account for the decrease in anisotropy. In contrast to the effect of ethanol, a decrease in adenylate cyclase activity following growth of S49 cells at 40 degrees C was not associated with a change in anisotropy.     

Effect of acute ethanol on beta-endorphin secretion from rat fetal hypothalamic neurons in primary cultures

To characterize the effect of ethanol on the hypothalamic beta-endorphin-containing neurons, rat fetal hypothalamic neurons were maintained in primary culture, and the secretion of beta-endorphin (beta-EP) was determined after ethanol challenges. Constant exposure to ethanol at doses of 6-50 mM produced a dose-dependent increase in basal secretion of beta-EP from these cultured cells. These doses of ethanol did not produce any significant effect on cell viability, DNA or protein content. The stimulated secretion of beta-EP following constant ethanol exposure is short-lasting. However, intermittent ethanol exposures maintained the ethanol stimulatory action on beta-EP secretion for a longer time. The magnitude of the beta-EP response to 50 mM ethanol is similar to that of the beta-EP response to 56 mM of potassium. Ethanol-stimulated beta-EP secretion required extracellular calcium and was blocked by a calcium channel blocker; a sodium channel blocker did not affect ethanol-stimulated secretion. These results suggest that the neuron culture system is a useful model for studying the cellular mechanisms involved in the ethanol-regulated hypothalamic opioid secretion.     

Inhibition of plasma membrane and mitochondrial transmembrane potentials by ethanol

The actions of ethanol and its primary oxidative metabolite, acetaldehyde, on plasma membrane and mitochondrial transmembrane potentials were examined in rat brain using fluorescence techniques. Subchronic treatment of adult rats with ethanol resulted in a significant depolarization of both the plasma and mitochondrial membranes when the mean blood ethanol level of the rats was 59±11 mM (mean±SEM, n=6). Acute dosing of animals (4.5 g/kg, i.p.) failed to show any significant alterations. Various concentrations of ethanol, added in vitro to a crude synaptosomal preparation isolated from the rat cerebrocortex (P₂) from untreated animals, depolarized both the plasma and mitochondrial transmembrane potentials in a dose-related manner. Addition of acetaldehyde in vitro did not reveal any significant effects on plasma or mitochondrial transmembrane potential.     

Teratogenicity of acetaldehyde invitro: Relevance to the fatal alcohol syndrome

Day 10 rat embryos grown $\text{in}$$\text{vitro}$ showed significant retardation in growth and development when culture media contained acetaldehyde. A concentration-response range for acetaldehyde-induced embryotoxicity was defined, from no effect at 5μM to complete lethality at 100μM. The relative teratogenicity of ethanol and acetaldehyde, and the potential roles of these compounds in producing the Fetal Alcohol Syndrome are discussed.Despite intensive investigation into alcohol teratogenicity, the mechanism that produces the Fetal Alcohol Syndrome (FAS) remains unknown. Observed anomalies may result from direct embryonic exposure to ethanol or one of its metabolites, or from some indirect effect such as altered placental function or maternal nutritional status. Use of $\text{in}$$\text{vitro}$ techniques allows study of direct embryonic exposures in the absence of indirect influences. Under such conditions, ethanol has been found to exert direct embryotoxicity (1). Rat embryos, grown as cultured explants and subjected to ethanol concentrations of 32.5 or 65mM, were retarded in growth and development when compared to untreated controls. In this paper, we report direct embryotoxic effects of acetaldehyde, the primary metabolite of ethanol, at concentrations as low as 25μM.Acetaldehyde teratogenicity has not been extensively studied. Veghelyi et al. (2) and Lambert, Papp and Nishiura (3) employed a combination of ethanol and disulfiram (an inhibitor of acetaldehyde-oxidizing enzymes). Teratogenic effects exceeded expectations based upon assumption of an additive interaction between these two compounds, and were attributed to elevated maternal blood acetaldehyde. O'Shea and Kauffman (4,5) and Dreosti et al. (6) administered acetaldehyde to pregnant animals by injection. Treatment resulted in retarded growth and development, decreased DNA synthesis, and increased frequencies of malformation and resorption. While these studies imply a role for acetaldehyde in alcohol-induced teratogenesis, indirect effects through altered maternal or placental factors cannot be eliminated. We present here the first concentration-response data for direct ebryonic exposure to acetaldehyde.     

The three-dimensional aspect of mammalian lung multilamellar bodies

The three-dimensional aspect of rat and monkey lung multilamellar bodies was demonstrated in lipid retained thin sections. The glutaraldehyde and urea lipid retention embedment and an Epon 812 resin polar dehydrant procedure were utilized to retain lamellar lipids for precise morphological study. The unextracted multilamellar bodies were found to conform to a general, though complex, threedimensional structure. A model that demonstrated that structure was derived. Freezeetch and extracted material were shown to support the model. Mature multilamellar bodies were from 1.2–1.6 μ in diameter and were 1.0–1.6 μ high. Each body contained a matrix core that included from 2–25 vesicular bodies and was in contact with the limiting membrane at the matrix plate. Most bodies had from 25–70 lamellae attached for 360 ° to the projection plate. Microtubules were seen in communication with the matrix core. When sectioned in longitudinal section, lamellae projected from the base plate and coursed parallel to the limiting membrane of the top half of the body. Any cross-section produced circular lamellae without apparent attachment. Oblique sections sometimes produced both ‘stacked’ and ‘circular’ lamellae. Four postulates of multilamellar body formation were discussed in light of these findings.     

Toxicity of ethanol and acetaldehyde in hepatocytes treated with ursodeoxycholic or tauroursodeoxycholic acid

In hepatocytes ethanol (EtOH) is metabolized to acetaldehyde and to acetate. Ursodeoxycholic acid (UDCA) and tauroursodeoxycholic acid (TUDCA) are said to protect the liver against alcohol. We investigated the influence of ethanol and acetaldehyde on alcohol dehydrogenase (ADH)-containing human hepatoma cells (SK-Hep-1) and the protective effects of UDCA and TUDCA (0.01 and 0.1 mM). Cells were incubated with 100 and 200 mM ethanol, concentrations in a heavy drinker, or acetaldehyde. Treatment with acetaldehyde or ethanol resulted in a decrease of metabolic activity and viability of hepatocytes and an increase of cell membrane permeability. During simultaneous incubation with bile acids, the metabolic activity was better preserved by UDCA than by TUDCA. Due to its more polar character, acetaldehyde mostly damaged the superficial, more polar domain of the membrane. TUDCA reduced this effect, UDCA was less effective. Damage caused by ethanol was smaller and predominantly at the more apolar site of the cell membrane. In contrast, preincubation with TUDCA or UDCA strongly decreased metabolic activity and cell viability and led to an appreciable increase of membrane permeability. TUDCA and UDCA only in rather high concentrations reduce ethanol and acetaldehyde-induced toxicity in a different way, when incubated simultaneously with hepatocytes. In contrast, preincubation with bile acids intensified cell damage. Therefore, the protective effect of UDCA or TUDCA in alcohol- or acetaldehyde-treated SK-Hep-1 cells remains dubious.     

Chronic ethanol increases liver plasma membrane fluidity

Purified plasma membrane fractions of cultured well-differentiated Reuber H35 hepatoma cells were studied after growth in the presence or absence of ethanol. Growth of cells in the presence of ethanol significantly increased plasma membrane 5'-nucleotidase activity but did not influence sodium-potassium adenosinetriphosphatase activity. Fluorescence polarization of lipophilic probes was used to study membrane lipid structure. Steady-state polarization of diphenylhexatriene (DPH), a probe of the hydrophobic core, was significantly lower in plasma membranes from cells grown in 80 mM ethanol for 3 weeks, compared to controls. Decreased polarization of DPH in plasma membranes was observed after 3-weeks growth of cells in as little as 1 mM ethanol. A 1-h exposure to 80 mM ethanol had no effect. Altered DPH polarization was due to a decrease in the order parameter of the probe. The rotational correlation time of the probe was virtually unchanged. Chronic ethanol treatment of cells did not alter the polarization of the membrane surface probe trimethylammoniodiphenylhexatriene. Plasma membranes from cells grown in 80 mM ethanol had decreased contents of both phospholipid and unesterified cholesterol, but the cholesterol to phospholipid ratio was unchanged. The percentages of sphingomyelin and phosphatidylserine in plasma membrane phospholipids were significantly decreased after ethanol treatment, while the phosphatidylcholine/sphingomyelin ratio was increased by 42%. Vesicles prepared from total plasma membrane lipids of ethanol-treated cells, as well as vesicles prepared from polar lipids alone, showed the same alterations in DPH polarization as did plasma membranes. The importance of ethanol metabolism in the observed plasma membrane changes was demonstrated in two ways.(ABSTRACT TRUNCATED AT 250 WORDS)     

Destruction of highly purified cytochromes P-450 associated with metabolism of fluorinated ether anesthetics

The effects of ethanol and acetaldehyde on rat intestinal microvillus membrane integrity and glucose transport function were examined in vitro with purified membrane vesicles. Ethanol could influence glucose transport function by alterations in the conformation of the carrier, the lipid environment surrounding the carrier, or in the transport driving force (Na⁺ electrochemical gradient). Due to the rapid nature of glucose uptake, transport was assayed with the use of an apparatus that permitted uptake measurements as early as 1 s. Ethanol (340 mm) partially and acetaldehyde (44 mm) completely inhibited concentrative glucose uptake throughout the 1-min time course. Their inhibitory effects were reversible and irreversible, respectively. Kinetic measurements made during the initial rate of uptake (at 2 s) with various concentrations of glucose (0.05–8 mm) showed that ethanol and acetaldehyde both caused a decrease in V. Although ethanol did not substantially alter the transport K_m, acetaldehyde increased the K_m almost 50%. To determine whether ethanol or acetaldehyde directly interfered with glucose carrier function, uptake was measured in the presence of equilibrated Na⁺. Only acetaldehyde had a significant inhibitory effect under these conditions. Membrane permeability, as determined by efflux of preloaded 6-carboxyfluorescein dye, increased upon exposure of the vesicles to ethanol or acetaldehyde. Membrane fluidity measurements by fluorescence polarization showed that only acetaldehyde had a significant fluidizing effect. These results indicate that ethanol and acetaldehyde acted to perturb membrane integrity and inhibited glucose uptake indirectly by allowing the Na⁺ gradient to dissipate. Acetaldehyde, which had a stronger inhibitory effect than ethanol, appeared also to directly inhibit carrier function.     

Morphological characterization of renal cell lines (BGM and VERO) exposed to low doses of lead nitrate

The response to lead nitrate has been assessed in two cell lines of renal origin. The range of toxic concentrations was determined by Neutral Red assay after 24-h of exposure. Morphological changes in the Buffalo Green Monkey (BGM) and VERO cell lines after exposure to subcytotoxic doses (1.38 mM and 1.04 mM, respectively) equivalent to EC10 (effective concentrations 10%) of lead nitrate were evaluated at the ultrastructural level by transmission microscopy. The most notable finding in treated cells was the presence of inclusion bodies in the form of irregular granules of varying size in both cytoplasm and lysosomes. Cell membrane integrity was not affected. The number of phagolysosomes and myeline figures associated to the inclusion bodies was higher than in the control cultures. We conclude that the phagolysosomic mechanism fails to digest this metal ion and the BGM and VERO renal cell lines can be considered as useful tools for toxicological studies involving lead nitrate.     

Effect of chronic ethanol exposure on the electric membrane properties of DRG neurons in cell culture

Neural cell cultures of adult mouse dorsal root ganglia were utilized to investigate the effects of chronic ethanol exposure on neuronal electric membrane properties (EMP). After 12 days of exposure to various ethanol concentrations, the EMP of the neurons were determined in ethanol-free medium. Significant changes in a number of EMP were observed. Of particular physiological significance were decreased specific membrane resistance, increased specific membrane capacitance, relatively little change in membrane time constant, and increased electrical excitability. Various features of the action potential were also affected, e.g., reduced overshoot, afterhyperpolarization, and rate of rise. In preliminary experiments, EMP were determined at varying periods after the cultures had been withdrawn from ethanol medium and maintained in ethanol-free medium. These results indicated that the altered EMP persisted as long as one (C_m) to two (R_m) weeks after ethanol withdrawal. A possible mechanism for these ethanol-induced changes in EMP was suggested, utilizing the membrane expansion theory of anesthesia. Because of few previous reports demonstrating significant electrophysiological effects of ethanol at pharmacological concentrations, the neural cell culture system provides a useful new experimental model for studying the action of chronic ethanol exposure on neuronal EMP and the physical basis of the tolerance and withdrawal phenomena found in alcoholism and addiction in general. After being maintained for 12 days in culture media containing various concentrations of ethanol, non-neuronal cell survival was observed to have decreased in an approximately linear manner with increasing ethanol levels. By contrast, neuron survival was not affected until ethanol concentrations greater than 0.34 g % were used. This decreased cell survival due to chronic exposure to physiological levels of ethanol has not been reported previously. Neural cell cultures may therefore be useful for investigating the cellular pathology of chronic alcoholism and fetal alcohol syndrome.     

The high resolution ultrastructure of the periodicity and architecture of lipid-retained and extracted lung multilamellar body laminations

The three-dimensional aspect of rat and monkey lung multilamellar bodies was demonstrated in lipid retained thin sections. The glutaraldehyde and urea lipid retention embedment and an Epon 812 resin polar dehydrant procedure were utilized to retain lamellar lipids for precise morphological study. The unextracted multilamellar bodies were found to conform to a general, though complex, threedimensional structure. A model that demonstrated that structure was derived. Freezeetch and extracted material were shown to support the model. Mature multilamellar bodies were from 1.2–1.6 μ in diameter and were 1.0–1.6 μ high. Each body contained a matrix core that included from 2–25 vesicular bodies and was in contact with the limiting membrane at the matrix plate. Most bodies had from 25–70 lamellae attached for 360 ° to the projection plate. Microtubules were seen in communication with the matrix core. When sectioned in longitudinal section, lamellae projected from the base plate and coursed parallel to the limiting membrane of the top half of the body. Any cross-section produced circular lamellae without apparent attachment. Oblique sections sometimes produced both ‘stacked’ and ‘circular’ lamellae. Four postulates of multilamellar body formation were discussed in light of these findings.     

Selective fetal malnutrition: The effect of ethanol and acetaldehyde upon in vitro uptake of alpha amino isobutyric acid by human placenta

Uptake of alpha amino isobutyric acid was measured in human placental villus tissue exposed $\text{in vitro}$ to ethyl alcohol (ethanol) (0.3 g/dl–2 g/d1) or acetaldehyde (50 μM-20 mM). Ethanol and acetaldehyde significantly inhibited uptake of amino acid at higher, pharmacologic concentrations (2 g/dl and 2–20 mM respectively). Inhibition by 10 mM acetaldehyde was partially reversible. The results suggest that the human placenta is resistant to acute ethanol-associated effects upon amino acid transport $\text{in vitro}$. However, both ethanol and its major circulating metabolite, acetaldehyde, may still alter placental function during $\text{in vivo}$ chronic exposure.     

In vitro tolerance to inhibition by ethanol of N-methyl-D-aspartate-induced depolarization in locus coeruleus neurons of behaviorally ethanol-tolerant rats

Intracellular recordings were made in pontine slice preparations of the rat brain containing the locus coeruleus (LC). Ethanol at 100 mM, but not at 10 or 30 mM inhibited depolarizing responses to pressure-applied N-methyl-D-aspartate (NMDA) in LC neurons of ethanol-naive rats. Ethanol (100 mM) had a similar effect in LC neurons of ethanol-naive rats, of rats treated with ethanol for 14 days (3 g/kg daily, i.p.) and of rats treated with equicaloric amounts of saccharose (5 g/kg daily, i.p.). The blood concentration of ethanol was markedly decreased at 4 h, and was below the detection limit at 24 h after the last injection. Behavioral measurements in the open-field system demonstrated the development of tolerance in rats receiving ethanol for 14 days. Moreover, an anxiety-related reaction was shown to develop when the acute effect of the last ethanol injection vanished. Therefore, in subsequent in vitro experiments, ethanol (10 mM) was continuously present in the superfusion medium in order to mimic a steady blood concentration and to prevent a withdrawal-like situation. Under these conditions, ethanol (100 mM) still continued to inhibit the NMDA-induced depolarization in slices of untreated rats, but became ineffective in slices of ethanol-treated rats at 4 h after the last injection. By contrast, a supersensitivity to ethanol developed in brain slices at 24 h after the last ethanol injection. In conclusion, in vitro tolerance between systemically and locally applied ethanol at LC neurons could only be demonstrated when a low concentration of ethanol was added to the superfusion medium to simulate the blood concentration of this compound.     

Ethanol production from H2 and CO2 by a newly isolated thermophilic bacterium, Moorella sp. HUC22-1

The thermophilic bacterium, Moorella sp. HUC22-1, newly isolated from a mud sample, produced ethanol from H(2) and CO(2) during growth at 55 degrees C. In batch cultures in serum bottles, 1.5 mM ethanol was produced from 270 mM H(2) and 130 mM CO(2) after 156 h, whereas less than 1 mM ethanol was produced from 23 mM fructose after 33 h. Alcohol dehydrogenase and acetaldehyde dehydrogenase activities were higher in cells grown with H(2) and CO(2) than those grown with fructose. The NADH/NAD(+) and NADPH/NADP(+) ratios in cells grown with H(2) and CO(2) were also higher than those in cells grown with fructose. When the culture pH was controlled at 5 with H(2) and CO(2) in a fermenter, ethanol production was 3.7-fold higher than that in a pH-uncontrolled culture after 220 h.     

Effect of oxygen on the metabolism of Zymomonas mobilis

The specific growth rate of the ethanol producing bacterium Zymomonas mobilis was 25–40% lower in the presence of oxygen than under anaerobic conditions, provided the cultures were supplied with a low substrate concentration (20 g glucose/l). However, the molar growth yield of these cultures was not influenced by oxygen. With washed cell suspensions, an oxygen consumption could be initiated by the addition of either glucose, fructose, or ethanol. Cell extracts catalyzed the oxidation of NADH with oxygen at a molar ratio of 2:1. Further experiments showed that this NADH oxidase is located in the cell membrane. The specific oxygen consumption rates of cell suspensions correlated with the intracellular NADH oxidizing activities; both levels decreased with increasing concentrations of the fermentation end-product ethanol. The addition of 5 mM NaCN completely inhibited both the intracellular oxygen reduction and also the oxygen consumption of whole cells. Both catalase and superoxide dismutase were present even in anaerobically grown cells. Aeration seemed to have little effect on the level of catalase, but the superoxide dismutase activity was 5-fold higher in cells grown aerobically. Under aerobic conditions considerable amounts of acetaldehyde and acetic acid were formed in addition to the normal fermentation products, ethanol and carbon dioxide.Dedicated to Professor Dr. H. G. Schlegel on the occasion of his 60th birthday