Effects of an autocrine factor deficit on the survival and energy metabolism of CTLL-2 cells under oxidative stress conditions in culture

An increasing body of data shows that survival of mammalian cells is under the control of growth factors and autocrine survival factors (AF). We studied the effects of an AF deficit on the survival, intracellular ATP content and the transmembrane potential of mitochondria in IL-2-dependent CTLL-2 cells following oxidative stress. We show that cells cultivated under conditions of AF deficit became more susceptible to oxidative injury in comparison with CTLL-2 cells cultivated without an AF deficit (the control cells); their death occurred at lower H₂O₂ concentrations than in the case of control cells. The ATP content in CTLL-2 cells decreased under an AF deficit even without stress; treatment of these cells with hydrogen peroxide led to an additional significant decrease of ATP content, which was accompanied by injury of the cell membrane (blebbing) and by a sharp fall in mitochondrial potential. Cell death after oxidative stress under conditions of AF deficit was shown to proceed along both the apoptosis and necrosis pathways.     

Influence of autocrine factor deficit in culture on survival and energy metabolism of CTLL-2 cells under oxidative stress

A lot of data has shown recently that survival of mammalian cells is under a control of growth factors and autocrine survival factors (AF). We studied the influence of AF deficit on survival, intracellular ATP content, and transmembrane potential of mitochondria of IL-2-dependent CTLL-2 cells under oxidative stress. CTLL-2 cells cultivated under deficit of AF have been shown to be more susceptible to oxidative injury in comparison with the cells cultivated without deficit of AF (control); they died at smaller concentrations of H2O2 than control cells did. The ATP content in CTLL-2 cells was decreased under AF deficit conditions even without any stress and treatment of the cells by hydrogen peroxide resulted in additional large decrease of it. ATP depression was accompanied by disruption of cell membrane (blebbing) and drop of mitochondrial potential. Cell death under oxidative stress in the presence of AF deficit has been shown to proceed by both apoptosis and necrosis.     

Autocrine factor participation in defence of cytotoxic CTLL-2 cells from oxidative stress

The role of autocrine factors (AF) secreted by cytotoxic IL-2-dependent CTLL-2 cells along with pyruvate in cell defense from oxidative stress was investigated. The addition of conditioned medium (CM) containing pyruvate and AF into CTLL-2 cell cultures increased significantly cell survival under oxidative stress condition. The kinetics of hydrogen peroxide removal from cell cultures under oxidative stress in the case of CM addition has been obtained. The removal of H2O2 mostly by means of its reaction with pyruvate that is contained in CM has been shown at the beginning of oxidative stress (up to 15 min). Pyruvate content in CM was determined as 138 +/- 7 microM. Cell filtration on column with Bio-Gel P-10 was used for removal pyruvate from CM. Three fractions of CM (A, B and C) were obtained as a result of gel filtration. Pyruvate was not detected in any fraction. The fraction A was eluted from column as the first one and contained the largest molecules. Cell survival test showed the fraction B to have the highest ability to protect CTLL-2 cells under oxidative stress. The fraction A supported cell survival to a less degree and fraction C was shown to have no protective ability. The addition of the fraction B to the cell cultures resulted in preservation of significantly higher intracellular ATP level in the cells under oxidative stress than in the control ones. Moreover, AF of the fraction B was shown to react directly with hydrogen peroxide and inactivate it in the absence of cells. AF of the fraction A did not have such properties.     

Change in energy metabolism of ascites cancer cells with a decrease in pH]

In Hank's balanced salt solution EL-4 ascites thymoma cells possessed endogenous respiration which was sufficient for the maintenance of their ATP level: pH decrease down to 6.0 had no effect either on endogenous respiration or the ATP level. Glucose had no influence on the respiration of EL-4 cells but inhibited that of Ehrlich ascites carcinoma (EAC) cells by 40% (Crabtree effect); respiration of the both cell lines was strongly (4-fold) inhibited after simultaneous addition of glucose, lactate and pH decrease. EL-4 cells had no endogenous glycolysis; EAC cells showed a low level of glycolysis only after pH decrease. Glucose addition led to activation of glycolysis (both inhibited 2-fold after a decrease of pH down to 6.0. The respiration inhibition at pH 7.3 and 6.0 caused no decrease of ATP depletion when glucose was present in the medium; this result may be due to suppression of ATP consumption. Incubation of EL-4 cells under respiration and glycolysis deficiency conditions resulted in a sharp ATP depletion; pH decrease delayed this depletion.     

Erythrocyte adenosine triphosphate depletion during voluntary hyperventilation

Chronic hypophosphatemia in humans is associated with a slow depletion of adenosine triphosphate (ATP) and 2,3-diphosphoglycerate (2,3-DPG) in erythrocytes, combined with shape alteration, impaired deformability, and viability of the cells. Likewise, incubation of erythrocytes in alkaline solution is associated with ATP depletion. Since in hyperventilation both hypophosphatemia and alkalosis are present, we have investigated red cell organic phosphates, shape, deformability, and osmotic fragility before, during, and after 20 min of voluntary hyperventilation. On the average, red cell ATP decreased by 42%, the blood pH increased by 0.2 units, and plasma inorganic phosphorus decreased by 46% compared with the initial values. Red cell 2,3-DPG, shape, deformability, and osmotic fragility remained unchanged. After the end of hyperventilation ATP increased rapidly to control values in parallel with the normalization of the blood pH, whereas inorganic plasma phosphorus remained at the low level observed during hyperventilation. It is concluded that the combined effects of hypophosphatemia and alkalosis in acute hyperventilation lead to an isolated fall of red cell ATP, which occurs as rapid as after total inhibition of red cell glycolysis in vitro.     

碱中毒对小鼠皮质GABA能神经元特性和编码能力的影响

目的:研究碱中毒对小鼠皮质GABA能神经元内在特性和编码能力的影响,探讨碱中毒引起大脑功能障碍的机制。方法:选择17-22天FVB-Tg小鼠行脑片体外培养,实验对象分为碱中毒组和对照组。DIC光学显微镜下选择皮层II-III层GABA神经元,运用Axo Patch 200 B放大器全细胞模式,记录并分析神经元内在特性(包括阈电位、绝对不应期)的改变;记录与去极化脉冲相对应的峰值,分析GABA能神经元的编码能力。结果:1.阈电位峰值在对照组分别是24.58±0.68,25.44±0.82,27.02±0.78,27.55±0.74和28.66±0.79毫伏,碱中毒组分别是28.32±0.78,30.10±0.91,32.22±0.80,32.88±0.76和33.54±0.74毫伏,碱中毒组阈电位升高;绝对不应期在对照组和碱中毒组分别是4.15±0.06和5.09±0.08毫秒,碱中毒绝对不应期延长。2.两组在相同去极化刺激下诱发的连续峰值波形发生明显改变,碱中毒组产生峰值的能力下降。结论:1、碱中毒使皮质GABA能神经元动阈电位升高和绝对不应期延长;2、碱中毒降低皮质GABA能神经元编码峰值能力。     

An increase in the ATP levels occurs in cerebellar granule cells en route to apoptosis in which ATP derives from both oxidative phosphorylation and anaerobic glycolysis

Although it is recognized that ATP plays a part in apoptosis, whether and how its level changes en route to apoptosis as well as how ATP is synthesized has not been fully investigated. We have addressed these questions using cultured cerebellar granule cells. In particular, we measured the content of ATP, ADP, AMP, IMP, inosine, adenosine and l-lactate in cells undergoing apoptosis during the commitment phase (0-8 h) in the absence or presence of oligomycin or/and of citrate, which can inhibit totally the mitochondrial oxidative phosphorylation and largely the substrate-level phosphorylation in glycolysis, respectively. In the absence of inhibitors, apoptosis was accompanied by an increase in ATP and a decrease in ADP with 1:1 stoichiometry, with maximum ATP level found at 3 h apoptosis, but with no change in levels of AMP and its breakdown products and with a relatively low level of l-lactate production. Consistently, there was an increase in the cell energy charge and in the ratio ([ATP][AMP])/[ADP]². When the oxidative phosphorylation was completely blocked by oligomycin, a decrease of the ATP content was found both in control cells and in cells undergoing apoptosis, but nonetheless cells still died by apoptosis, as shown by checking DNA laddering and by death prevention due to actinomycin D. In this case, ATP was provided by anaerobic glycolysis, as suggested by the large increase of l-lactate production. On the other hand, citrate itself caused a small decrease in ATP level together with a huge decrease in l-lactate production, but it had no effect on cell survival. When ATP level was further decreased due to the presence of both oligomycin and citrate, death occurred via necrosis at 8 h, as shown by the lack of DNA laddering and by death prevention found due to the NMDA receptor antagonist MK801. However, at a longer time, when ATP level was further decreased, cells died neither via apoptosis nor via glutamate-dependent necrosis, in a manner similar to something like to energy catastrophe. Our results shows that cellular ATP content increases in cerebellar granule cell apoptosis, that the role of oxidative phosphorylation is facultative, i.e. ATP can also derive from anaerobic glycolysis, and that the type of cell death depends on the ATP availability.     

An increase in the ATP levels occurs in cerebellar granule cells en route to apoptosis in which ATP derives from both oxidative phosphorylation and anaerobic glycolysis

Although it is recognized that ATP plays a part in apoptosis, whether and how its level changes en route to apoptosis as well as how ATP is synthesized has not been fully investigated. We have addressed these questions using cultured cerebellar granule cells. In particular, we measured the content of ATP, ADP, AMP, IMP, inosine, adenosine and L-lactate in cells undergoing apoptosis during the commitment phase (0-8 h) in the absence or presence of oligomycin or/and of citrate, which can inhibit totally the mitochondrial oxidative phosphorylation and largely the substrate-level phosphorylation in glycolysis, respectively. In the absence of inhibitors, apoptosis was accompanied by an increase in ATP and a decrease in ADP with 1:1 stoichiometry, with maximum ATP level found at 3 h apoptosis, but with no change in levels of AMP and its breakdown products and with a relatively low level of L-lactate production. Consistently, there was an increase in the cell energy charge and in the ratio ([ATP][AMP])/[ADP](2). When the oxidative phosphorylation was completely blocked by oligomycin, a decrease of the ATP content was found both in control cells and in cells undergoing apoptosis, but nonetheless cells still died by apoptosis, as shown by checking DNA laddering and by death prevention due to actinomycin D. In this case, ATP was provided by anaerobic glycolysis, as suggested by the large increase of L-lactate production. On the other hand, citrate itself caused a small decrease in ATP level together with a huge decrease in L-lactate production, but it had no effect on cell survival. When ATP level was further decreased due to the presence of both oligomycin and citrate, death occurred via necrosis at 8 h, as shown by the lack of DNA laddering and by death prevention found due to the NMDA receptor antagonist MK801. However, at a longer time, when ATP level was further decreased, cells died neither via apoptosis nor via glutamate-dependent necrosis, in a manner similar to something like to energy catastrophe. Our results shows that cellular ATP content increases in cerebellar granule cell apoptosis, that the role of oxidative phosphorylation is facultative, i.e. ATP can also derive from anaerobic glycolysis, and that the type of cell death depends on the ATP availability.     

Phosphorus nuclear magnetic resonance studies of phosphorus metabolites in frog muscle.

31P-nuclear magnetic resonance was applied to living muscles of bullfrogs, and the time courses of metabolic changes of ATP, creatine phosphate, inorganic phosphate, and sugar phosphates were studied under anaerobic and aerobic conditions. A decrease in creatine phosphate was observed in the resting muscle under anaerobic conditions with a concomitant decrease in the intracellular pH, while the ATP level remained constant. With the use of 2,4-dinitro-1-fluorobenzene and iodoacetic acid, ATP disappeared quickly. When the resting muscle was perfused with oxygen-saturated glucose-Ringer's solution, the amount of creatine phosphate increased gradually. These findings indicate that anaerobic glycolysis is insufficient for even the resting energy consumption whereas oxidative phosphorylation is sufficient. The effects of tetanic stimulation on living muscles were also studied. When glycolysis and oxidative phosphorylation were suppressed, the intracellular energy store was depleted by the tetanic contraction. Anaerobic glycolysis produced rapid recovery of the energy store level, although it was insufficient to reach the initial level. Aerobic oxidative phosphorylation produced sufficient energy to reach the initial level, and this level was never exceeded. This finding suggests the existence of a regulatory mechanism for the energy store level.     

Mitochondrial UCP4 attenuates MPP+- and dopamine-induced oxidative stress,mitochondrial depolarization,and ATP deficiency in neurons and is interlinked with UCP2 expression

Mitochondrial uncoupling proteins (UCPs) uncouple oxidative phosphorylation from ATP synthesis. We explored the neuroprotective role of UCP4 with its stable overexpression in SH-SY5Y cells, after exposure to either MPP⁺ or dopamine to induce ATP deficiency and oxidative stress. Cells overexpressing UCP4 proliferated faster in normal cultures and after exposure to MPP⁺ and dopamine. Differentiated UCP4-overexpressing cells survived better when exposed to MPP⁺ with decreased LDH release. Contrary to the mild uncoupling hypothesis, UCP4 overexpression resulted in increased absolute ATP levels (with ADP/ATP ratios similar to those of controls under normal conditions and ADP supplementation) associated with increased respiration rate. Under MPP⁺ toxicity, UCP4 overexpression preserved ATP levels and mitochondrial membrane potential (MMP) and reduced oxidative stress; the preserved ATP level was not due to increased glycolysis. Under MPP⁺ toxicity, the induction of UCP2 expression in vector controls was absent in UCP4-overexpressing cells, suggesting that UCP4 may compensate for UCP2 expression. UCP4 function does not seem to adhere to the mild uncoupling hypothesis in its neuroprotective mechanisms under oxidative stress and ATP deficiency. UCP4 overexpression increases cell survival by inducing oxidative phosphorylation, preserving ATP synthesis and MMP, and reducing oxidative stress.     

Autocrine factors in defense of cytotoxic CTLL-2 cells from oxidative stress

The role of pyruvate and autocrine polypeptide factors (APF) secreted by cytotoxic IL-2-dependent CTLL-2 cells in cell defense from oxidative stress was investigated. The addition of a conditioned medium (CM) containing pyruvate and APF into CTLL-2 cell cultures significantly increased the cell survival under oxidative stress conditions induced by hydrogen peroxide (H₂O₂). The kinetics of (H₂O₂) removal from cell cultures with added CM has been registered. It has been shown that, at the beginning of oxidative stress (less than 15 min), H₂O₂ was mostly removed by means of its reaction with pyruvate contained in CM. Pyruvate content in CM was estimated as 138 ± 7 μM. Gel filtration on a column with Bio-Gel P-10 was used to eliminate pyruvate from CM. Gel filtration resulted in three CM fractions (A, B, and C) corresponding to three chromatogram peaks. Pyruvate was not detected in any fraction. The fraction A was the first to be eluted from the column and contained the largest molecules. In the cell survival test, fraction B had the highest protective ability for CTLL-2 cells under oxidative stress. Fraction A supported cell survival to a lesser degree and fraction C did not show any protective abilities. Fraction B added to cells under oxidative stress kept intracellular ATP content at a significantly higher level then in control cells. Moreover, it was found that APF from fraction B was able to react with H₂O₂ directly and inactivate it in the absence of cells. APF from fraction A did not have such properties.     

Rapid stereospecific stimulation of lymphocytic metabolism by interleukin 2

IL 2 maintains the viability of IL 2-dependent CTLL-2 cells. IL 2, a lymphocytotrophic factor, stimulates the cellular metabolism of IL 2 receptor-bearing CTLL-2 murine cytolytic T cells. Both aerobic (oxygen consumption) and anaerobic (lactic acid production) metabolism of CTLL-2 cell are stimulated by rIL 2. The effects of IL 2 upon murine T cells is blocked by an anti-IL 2 receptor monoclonal antibody but not by other monoclonal antibodies that bind to other proteins upon CTLL-2 cells. Changes in aerobic and anaerobic cellular metabolism occur rapidly after interaction with IL 2, whereas the effects on the cell cycle are relatively slow and may be dependent upon antecedent metabolic stimulation by IL 2. This effect of IL 2 on cell viability appears to be mediated by a direct effect on important aerobic and anaerobic metabolic pathways.     

Metabolic arrest and its regulation in anoxic eel hepatocytes

Some vertebrates depress overall metabolism in an abrupt and reversible fashion when challenged with anoxia, ensuring stabilization of cellular [ATP] and long-term survival, but little is known about the eliciting stimuli (e.g., change in O2, adenylates) and downstream effectors responsible for metabolic arrest. Accordingly, eel (Anguilla anguilla) hepatocytes were treated with inhibitors of putative components of the oxygen/metabolite-sensing pathway(s) and exposed to anoxia (Po2=0 mmHg). Anoxia in untreated cells caused a remarkable 85-fold decrease in ATP production rate, but cellular ATP levels stabilized following an initial steep drop. Reoxygenation of cells after 4 h of anoxia caused a fast metabolization of accumulated lactate and reestablishment of preanoxic ATP levels. Unlike physiological anoxia, pharmacological inhibition of the electron transport chain in the presence of oxygen caused extensive cellular ATP depletion, though no loss in viability. In contrast, cellular lactate (i.e., ATP) production rate was affected similarly by either treatment, suggesting that anaerobic glycolysis is regulated by a stimulus other than oxygen tension per se, whereas the continuous matching of ATP consumption and a rapidly ceasing mitochondrial ATP supply require a physiological relevant change in oxygen tension. Protein kinases, notably kinase C (PKC) and A (PKA), have been proposed as key downstream regulators of stress-induced defense mechanisms, but anoxic cell viability, metabolic rate, and [ATP] were not significantly affected by inhibitors of PKC and PKA. Likewise, inhibition of the upstream PKC-activating enzymes phospholipase C (PLC) and phosphatidylinositol 3-kinase (PI 3-K) had no effect on recorded parameters. Anoxic cell survival in complex organisms may, in vivo, also depend on stress hormones released from distant oxygen-sensing cells. Accordingly, adrenaline elevated anaerobic energy production but, apparently, also elevated ATP consumption because cellular ATP levels during oxygen deprivation were slightly lowered by adrenergic stimulation.     

Energetics of Anaerobic Sodium Transport by the Fresh Water Turtle Bladder

Certain of the metabolic events associated with anaerobic sodium transport by the isolated bladder of the fresh water turtle have been investigated. The data suggest that energy for this transport arises from glycolysis and that endogenous glycogen was the major and perhaps the sole source of substrate. The rate of anaerobic glycolysis, as determined by lactate formation, correlates well with the rate as determined by glycogen utilization. Using lactate formation as the index of anaerobic glycolysis, a linear relationship was observed between glycolysis and net anaerobic sodium transport. In the absence of sodium transport, glycolysis decreased by approximately 45 per cent. Tissue ATP concentrations were maintained at about the same level under anaerobic as under aerobic conditions. Finally if it is assumed that in the conversion of glycogen to lactate anaerobically, 3 moles of ATP are generated per mole of glucose residue, an average of over 15 equivalents of sodium were transported for every mole of ATP generated.     

Physiological consequences of prolonged aerial exposure in the American eel,Anguilla rostrata: blood respiratory and acid-base status

Summary The physiological consequences of prolonged air-exposure on blood respiratory and acid-base properties were examined in the American eel (Anguilla rostrata). Eels displayed a low capacity for aerial gas transfer as indicated by pronounced increases and decreases in arterial CO₂ and O₂ tensions, respectively. The increase in arterial CO₂ tension contributed to severe extracellular acidosis. The decrease in arterial O₂ tension, combined with a marked reduction in red blood cell pH and concomitant Bohr and Root effects, caused arterial O₂ content to decline to levels that were insufficient to support metabolic requirements, aerobically. Consequently, the rate of anaerobic glycolysis increased during air-exposure as suggested by a gradual elevation of blood lactate levels after 12 h. Increased anaerobic glycolysis and associated ATP hydrolysis and/or degradation of internal ATP stores further depressed blood pH as metabolic acid, produced by these processes, entered the circulation. Unlike other fishes previously examined, red blood cell pH was not regulated preferentially during the extracellular acidosis but simply conformed to the in vitro relationship between red blood cell and whole blood pH. Although capable of surviving prolonged air-exposure, the results demonstrate nevertheless and perhaps not surprisingly that eels, unlike true amphibious fishes that utilize gills or buccal epithelia for gas transfer, are not particularly well-adapted for gas exchange in air but do display an unusual tolerance to hypoxemia.Symbols and abbreviations B buffer value - Hct hematocrit - RBC red blood cell     

Anaerobic Glycolysis Protection against 1-Methy-4-Phenylpyridinium (MPP<Superscript>+</Superscript>) Toxicity in C6 Glioma Cells

The neurotoxin 1-methy-4-phenylpyridinium (MPP⁺) is used for its’ capacity to induce Parkinsonism through its inhibitory effects on mitochondrial complex I. This inhibition disrupts cellular energy formation and aerobic glycolysis. The objective of this study was to demonstrate that the toxic effect of mitochondrial aerobic pathway inhibition with MPP⁺ can be reduced by stimulating anaerobic glycolysis using glucose supplementation. In this study, C6 Glioma cell viability was examined in the presence of different concentrations of MPP alone and with the addition of glucose. The results obtained indicate that there was a significant increase (P < 0.001) in cell viability in cells treated with glucose and MPP⁺ verses cells treated with MPP⁺ alone. Fluorometric analysis using 100 uM Rhodamine 123 indicated mitochondrial membrane potential was not restored in MPP⁺ treated cells with glucose; however, normal cell viability was confirmed using 2 ug/ml Fluorescein diacetate. This dual fluorescence indicated mitochondrial damage from MPP⁺ while glucose augmented cell survival. Further confirmation of cell survival upon damage to the mitochondria was evident in TUNEL staining. Positive staining was prominent only in MPP⁺ treatment groups alone, while control and co-treated groups exhibited little to no TUNEL staining. ATP measurements of all MPP⁺ treated groups exhibited a significant (P < 0.001) decrease verses control. Groups co-treated with MPP⁺ and glucose revealed a significant increase (250 μM group: P < 0.001) in ATP. It was concluded from this study that glucose supplementation was able to sustain cellular viability and ATP production through anaerobic glycolysis despite the inhibitory effect of MPP⁺ on aerobic glycolysis.     

The effect of pH and pO2 changes in the blood on the energy metabolism of human erythrocytes in old age

Changes in pH and pO2 of the blood have been studied for age peculiarities of their effect on the glycolysis rate and the content of ATP and 2,3-diphosphoglycerate (2,3-DPG) in erythrocytes (in vitro). The fresh venous blood of practically healthy young (aged 20-29) and old (aged 75-85) people was used. Acidosis was shown to induce inhibition of glycolysis and decrease of the ATP and 2.3-DPG concentrations in erythrocytes, while alkalosis and hypoxemia-an increase of the glycolysis rate and 2.3-DPG content. In the both cases changes in the indices studied were considerably lower in old people as compared to young ones.     

Impaired mitochondrial Ca2+ homeostasis in respiratory chain-deficient cells but efficient compensation of energetic disadvantage by enhanced anaerobic glycolysis due to low ATP steady state levels

Energy-producing pathways, adenine nucleotide levels, oxidative stress response and Ca(2+) homeostasis were investigated in cybrid cells incorporating two pathogenic mitochondrial DNA point mutations, 3243A>G and 3302A>G in tRNA(Leu(UUR)), as well as Rho(0) cells and compared to their parental 143B osteosarcoma cell line. All cells suffering from a severe respiratory chain deficiency were able to proliferate as fast as controls. The major defect in oxidative phosphorylation was efficiently compensated by a rise in anaerobic glycolysis, so that the total ATP production rate was preserved. This enhancement of glycolysis was enabled by a considerable decrease of cellular total adenine nucleotide pools and a concomitant shift in the AMP+ADP/ATP ratios, while the energy charge potential was still in the normal range. Further important consequences were an increased production of superoxide which, however, was neither escorted by major changes in the antioxidative defence systems nor was it leading to substantial oxidative damage. Most interestingly, the lowered mitochondrial membrane potential led to a disturbed intramitochondrial calcium homeostasis, which most likely is a major pathomechanism in mitochondrial diseases.     

Autophagy Is a Protective Mechanism for Human Melanoma Cells under Acidic Stress

Cyclic hypoxia and alterations in oncogenic signaling contribute to switch cancer cell metabolism from oxidative phosphorylation to aerobic glycolysis. A major consequence of up-regulated glycolysis is the increased production of metabolic acids responsible for the presence of acidic areas within solid tumors. Tumor acidosis is an important determinant of tumor progression and tumor pH regulation is being investigated as a therapeutic target. Autophagy is a cellular catabolic pathway leading to lysosomal degradation and recycling of proteins and organelles, currently considered an important survival mechanism in cancer cells under metabolic stress or subjected to chemotherapy. We investigated the response of human melanoma cells cultured in acidic conditions in terms of survival and autophagy regulation. Melanoma cells exposed to acidic culture conditions (7.0 < pH < 6.2) promptly accumulated LC3+ autophagic vesicles. Immunoblot analysis showed a consistent increase of LC3-II in acidic culture conditions as compared with cells at normal pH. Inhibition of lysosomal acidification by bafilomycin A1 further increased LC3-II accumulation, suggesting an active autophagic flux in cells under acidic stress. Acute exposure to acidic stress induced rapid inhibition of the mammalian target of rapamycin signaling pathway detected by decreased phosphorylation of p70S6K and increased phosphorylation of AMP-activated protein kinase, associated with decreased ATP content and reduced glucose and leucine uptake. Inhibition of autophagy by knockdown of the autophagic gene ATG5 consistently reduced melanoma cell survival in low pH conditions. These observations indicate that induction of autophagy may represent an adaptation mechanism for cancer cells exposed to an acidic environment. Our data strengthen the validity of therapeutic strategies targeting tumor pH regulation and autophagy in progressive malignancies.     

Apoptosis may contribute to false-positive results in the in vitro micronucleus test performed in extreme osmolality, ionic strength and pH conditions

Conditions in which clastogens produce positive responses have been increasingly challenged, and several situations have been described in which clastogenic responses would be considered not to be relevant. For example, extreme culture conditions lead to high variations of pH, osmolality or ionic strength. Apoptosis is induced in extreme culture conditions and contributes to false-positive results in the in vitro micronucleus test performed with CTLL-2 cells. These cells can enter apoptosis when exposed to apoptosis stimuli or after IL-2 deprivation, whereas the CTLL-2 Bcl2 cell line is protected from apoptosis due to the over-expression of the apoptosis inhibitor Bcl2 in bcl2-transfected CTLL-2 cells. The two cell lines were treated in extreme culture conditions of either pH or osmolality or were submitted to high ionic strength. The apoptosis level was measured in parallel with the in vitro micronucleus test using the annexin V-FITC method. Data obtained in the two cell lines suggested that apoptosis caused by extreme culture condition induces the formation of micronucleated cells, which leads to false-positive results in the in vitro micronucleus test.