Preservation of energy-linked functions of insect mitochondria by simple freezing methods.

Attempts are made to preserve some energy-linked functions of mitochondria isolated from the fat body of the cockroach Nauphoeta cinerea. The ability of mitochondria to sustain appreciable levels of oxidation, phosphorylation, respiratory control and 2, 4-DNP-stimulation of respiration which are normally lost during incubation at 30°C for 2 hrs or during aging at 0–2°C for 48 hrs can be preserved effectively by storing mitochondrial suspensions in sucrose - EDTA medium for 1 week at - 20°C and at least 3 weeks at -196°C (liquid nitrogen temperature). DMSO (dimethyl sulfoxide; 10% v/v) was found to be ineffective as an aid to preservation at 0–2°C, a significant aid at -20°C and unnecessary at -196°C. With slight variations (for flight muscle mitochondria which requires DMSO at -196°C), this procedure is also effective for mitochondria isolated from other tissues of various insect species. EDTA was found to be an essential ingredient of the isolation medium and therefore for all storage procedures. Both lyophilization and the preincubation of mitochondria with nupercaine (400 μM) have deleterious effects.     

Effects of hypothermia on canine kidney mitochondria

The effect of hypothermia on the function of isolated dog kidney cortex mitochondria was determined with an FAD- and NAD⁺-linked substrate. In dog kidney mitochondria, temperatures of 10 °C or less suppress ADP stimulation of respiration but have little or no effect upon uncoupler, Ca²⁺ or valinomycin-K⁺ stimulation of respiration. This suggests that the adenine nucleotide translocase which catalyses the transport of ADP into the mitochondria limits the rate of respiration and generation of ATP at 10 °C in kidneys undergoing preservation. The coupling of oxidation to phosphylation, as determined by measuring the amount of ATP formed at low temperatures, indicates, however, that mitochondria are fully coupled at both 10 and 5 °C. The respiratory control index at 15 °C is greater (with pyruvate plus malate) than at 30 or 10 °C and suggests that 15 °C may be the optimum perfusion temperature for maintaining adenine nucleotide levels in the perfused kidney.     

Roles of DNA repair and membrane integrity in heat resistance of Deinococcus radiodurans

To study the effects of heat shock on Deinococcus radiodurans and the role of DNA repair in high temperature resistance, different strains of D. radiodurans (wild type, recA, irrE, and pprA) were treated with temperatures ranging from 40 to 100?°C under wet and dry conditions. The mutant strains were more sensitive to wet heat of ≥60?°C and dry heat of ≥80?°C than the wild type. Both wild-type and DNA repair-deficient strains were much more resistant to high temperatures when exposed in the dried state as opposed to cells in suspension. Molecular staining techniques with the wild-type strain revealed that cells in the dried state were able to retain membrane integrity after drying and subsequent heat exposure, while heat-exposed cells in suspension showed significant loss of membrane integrity and respiration activity. The results suggest that the repair of DNA damage (e.g., DNA double-strand breaks by RecA and PprA) is essential after treatment with wet heat at temperatures >60?°C and dry heat >80?°C, and the ability of D. radiodurans to stabilize its plasma membrane during dehydration might represent one aspect in the protection of dried cells from heat-induced membrane damage.     

Short‐term high temperature treatment reduces viability and inhibits respiration and DNA repair enzymes in Araucaria angustifolia cells

We evaluated the effect of global warming on Araucaria angustifolia (Bert.) O. Kuntze, a critically endangered native tree of Southern Brazil, by studying the effects of short‐term high temperature treatment on cell viability, respiration and DNA repair of embryogenic cells. Compared with control cells grown at 25°C, cell viability was reduced by 40% after incubation at 30 and 37°C for 24 and 6 h, respectively, while 2 h at 40 and 42°C killed 95% of the cells. Cell respiration was unaffected at 30–37°C, but dramatically reduced after 2 h at 42°C. The in vitro activity of enzymes of the base excision repair (BER) pathway was determined. Apurinic/apyrimidine endonuclease, measured in extracts from cells incubated for 2 h at 42°C, was completely inactivated while lower temperatures had no effect. The activities of three enzymes of the mitochondrial BER pathway were measured after 30‐min preincubation of isolated mitochondria at 25–40°C and one of them, uracil glycosylase, was completely inhibited at 40°C. We conclude that cell viability, respiration and DNA repair have different temperature sensitivities between 25 and 37°C, and that they are all very sensitive to 40 or 42°C. Thus, A. angustifolia will likely be vulnerable to the short‐term high temperature events associated with global warming.     

Respiration and Mitochondrial Activity in Zea mays Roots As Affected by Osmotic Stress

Studies were made of metabolism in highly vacuolated and slightlyvacuolated Zea mays root tissue both during and after plasmolysis. Plasmolysis resulted in decreased respiration and carbon dioxideevolution from glucose and an increased sucrose synthesis. Inhibitionof respiration during plasmolysis in both the highly vacuolatedand slightly vacuolated tissue was not relieved by supply ofglucose, organic acids, or uncouplers of oxidative phosphorylation.Mitochondria isolated from plasmolysed tissue were tightly coupled,but activity in vitro was inhibited by exposure to a high negativeosmotic potential. It is suggested that low TCA cycle activityin vivo must be due either to inhibition of mitochondrial activityor to reduced flow of carbon through the glycolytic pathway. A low potential for TCA cycle activity after deplasmolysis issuggested, as addition of pyruvate stimulated carbon dioxideevolution but not oxygen uptake, which was severely decreased.This was presumably due to severe mitochondrial damage as shownby their activity in vitro. However, it is not clear whetherrespiration in vivo is rate limited by rapid leakage of metabolicintermediate (reported earlier) or by lysis of mitochondria. Deplasmolysis did not damage mitochondria from slightly vacuolatedtissue, a result which was consistent with respiratory measurementsmade in vivo. The data show that mitochondria in vacuolated tissue are damagedduring and after deplasmolysis and not before. It is suggestedthat lysis of mitochondria occurs in vivo as a result of a sharpincrease in the osmotic potential of the cell fluids.     

Studies on the mechanism of freezing damage to mouse liver. IV. Effects of ultrarapid freezing on structure and function of isolated mitochondria

Mouse liver mitochondria isolated in 0.25 m sucrose were subjected to progressively increasing cooling rates by quench-thaw from liquid nitrogen, isopentane at ?155 °C, and liquid propane at ?185 °C. Structural damage, assessed by electron microscopy and by quantitation of supernatant protein, increased progressively with the cooling rate. Oxidative phosphorylation (with succinate as substrate) was destroyed at all three cooling rates, while acceptorless respiration (succinoxidase) showed a progressive increase with cooling rate, suggesting uncoupling. The succinate cytochrome c reductase system showed no functional damage. Dimethyl sulfoxide, 10–20% by volume, markedly improved structural preservation of the mitochondria, but did not restore oxidative phosphorylation, and further increased the degree of uncoupling.Upon resuspending the mitochondria in 0.15 m KCl prior to quench-thaw, the succinate cytochrome c reductase system displayed an optimal recovery after isopentane quench-thaw, with a sharp decline at still higher cooling rates, as had been encountered in tissue slice experiments, suggesting a compartmental ice-transition in mitochondria over this range of cooling rates. Structurally, however, the KCl-resuspended mitochondria were equally and maximally disrupted by all three quench-thaw procedures. Sixty percent of the mitochondrial protein was extruded into the supernate, far above the levels released from sucrose-suspended mitochondria by quench-thaw and significantly above the 45% released by sonication. Compared to isotonic KCl, isotonic sucrose was thus providing full cryoprotection for the reductase complex and moderate protection for mitochondrial structure. The discrepancies among the several structural and functional indicators of mitochondrial damage leave little possibility that a single compartmental ice-transition, occurring over this range of cooling rates, could provide a coherent explanation for freezing damage to liver mitochondria.     

Cyanide-and rotenone-resistant respiration in mitochondria of sugar beet taproots during plant growth and development

Effects of cyanide and rotenone were examined on respiration (oxygen uptake) in mitochondria isolated from sugar beet (Beta vulgaris L.) taproots at various stages of plant growth and development. In mitochondria from growing and cool-stored taproots, the ability of cyanide-resistant, salicylhydroxamic acid-sensitive alternative oxidase (AO) to oxidize malate, succinate, and other substrates of tricarboxylic acid cycle (TCA) was low and constituted less than 10% compared to predominant activity of the cytochrome oxidase pathway during State 3 respiration. Artificial aging of storage tissue (2-day incubation of tissue sections under high humidity at 20°C) substantially activated AO, but the highest capacity (V _alt) of this pathway of mitochondrial oxidation was only observed in the presence of pyruvate and a reducing agent dithiothreitol. At the same time, mitochondria from growing taproots exhibited high rates of rotenone-resistant respiration, and these rates gradually declined during plant growth and development. The slowest rates of this respiration were observed during oxidation of NAD-dependent TCA substrates in mitochondria from dormant storage organ. The results are discussed in relation to significance of alternative electron transport pathways during growth and storage of sugar beet taproots.     

Mitochondrial function in Antarctic notothenioid fishes that differ in the expression of oxygen-binding proteins

State III respiration rates were measured in mitochondria isolated from hearts of Antarctic notothenioid fishes that differ in the expression of hemoglobin (Hb) and myoglobin (Mb). Respiration rates were measured at temperatures between 2 and 40°C in Gobionotothen gibberifrons (+Hb/+Mb), Chaenocephalus aceratus (–Hb/–Mb) and Chionodraco rastrospinosus (–Hb/+Mb). Blood osmolarity was measured in all three species and physiological buffers prepared for isolating mitochondria and measuring respiration rates. Respiration rates were higher in mitochondria from G. gibberifrons compared to those from C. aceratus at 2°C, but were similar among all species at temperatures between 10 and 26°C. Respiration rates were significantly lower in icefishes at 35 and 40°C compared to G. gibberifrons. The respiratory control ratio of isolated mitochondria was lower in C. aceratus compared to G. gibberifrons at all temperatures below 35°C. At 35 and 40°C, mitochondria were uncoupled in all species. The Arrhenius break temperature of state III respiration was similar among all three species (30.5 ± 0.9°C) and higher than values previously reported for Antarctic notothenioids, likely due to the higher osmolarity of buffers used in this study. These results suggest that differences in mitochondrial structure, correlated with the expression of oxygen-binding proteins, minimally impact mitochondrial function.     

Metabolite profiling reveals tissue- and temperature-specific metabolomic responses in thermoregulatory male florets of Dracunculus vulgaris (Araceae)

The male part of the spadix of Dracunculus vulgaris exhibits a degree of temperature regulation by inversely controlled heat production over a 20–35 °C range of tissue temperature. To clarify the effects of temperature on cellular metabolism, comparative analysis was performed using 51 metabolites from two distinct tissues (florets and pith) of thermogenic male spadices that had been temperature clamped at either 20 (to produce high respiration) or 35 °C (to produce low respiration). Principal component analysis and hierarchical clustering analysis showed that changes in metabolites in the florets, but not in the pith, were associated with temperature change. The energy charge in the florets treated at 20 °C was significantly higher than that of the florets treated at 35 °C. This indicated the presence of an increased energy-producing pathway that ultimately led to an increased level of thermogenesis at 20 °C. Intriguingly, succinate, a direct substrate for complex II in the mitochondrial respiratory chain, was the metabolite most significantly affected in our analysis, with its concentration in the florets 3.5 times higher at 20 than at 35 °C. However, the mitochondria fed with succinate showed that state 2 and 3 respirations and the capacity of the alternative and cytochrome pathways were all significantly higher at 35 than at 20 °C. Taken together, the results show that the male florets are the primary sites for temperature-induced changes in metabolomic pathways, although succinate-stimulated mitochondrial respiration, per sé, is not the control mechanism for thermoregulation in D. vulgaris.     

Ultrastructural studies of muscle cells and vascular endothelium immediately after freeze-thaw injury

Little is known about the ultrastructural changes which occur in vascular endothelium immediately after an in vivo freezethaw insult, although most investigators will agree that tissue viability relates directly to the degree of vascular damage. In this study an electron microscopic examination of an in vivo model for frostbite injury was initiated. The horseradish peroxidase technique was utilized to follow early alterations in capillary flow and the independent effects of hypoxia, cooling to 2 °C, supercooling, and a single freeze-thaw insult were assessed. No precipitous changes in muscle cell mitochondria or capillary endothelium were detected as a result of brief hypoxia, cooling at 2 °C, or supercooling to ?13 °C. Reducing the temperature by 1 °C/min until freezing occurred, continuing to cool for 10 min postheat of fusion, and rapidly rewarming resulted in consistent mitochondrial damage in muscle cells and marked degeneration of associated capillaries. Peroxidase injected iv prior to thawing was rarely localized in the capillaries of previously frozen muscle. Since peroxidase was found in the capillaries of unfrozen legs of the same animals, it is inferred that little or no flow occurred in most capillaries postthaw. Ultrastructural integrity of capillaries immediately after thawing may be a good index for predicting tissue loss.“In conducting the research described in this report, the investigators adhered to the ‘Guide for Laboratory Animal Facilities and Care,’ as promulgated by the Committee on the Guide for Laboratory Animal Facilities and Care of the Institute of Laboratory Animal Resources, National Academy of Sciences-National Research Council.”     

Ability of human leukocytic pyrogen to enhance phytohemagglutinin induced murine thymocyte proliferation

Human leukocytic pyrogen, a monokine produced by stimulated human mononuclear phagocytes, will enhance the murine thymocyte proliferation response to phytohemagglutinin (lymphocyte activating factor (LAF) activity). During all steps of purification of human LP, pyrogenicity and LAF activity are coincidental suggesting a single identity for the two monokines. The LAF assay for human LP is highly sensitive and can detect human LP at a concentration of 10^?12M. Further experiments suggests that human LP and LAF activities could be destroyed by heating to 70 °C. Furthermore, while in vivo pyrogenicity of human LP can be blocked by ibuprofen, the in vitro LAF activity of the same molecule is unaffected by ibuprofen. Immune rabbit serum directed against human LP could also block in vitro LAF activity either by preincubation with LP or by blocking during culture.     

Effects of high-temperature stress on various biomembranes of leaf cells in situ and in vitro

The sensitivity of photosynthetic and respiratory functions to supraoptimal temperature stress was compared after heating of leaves, protoplasts and membrane systems of spinach (Spinacia oleracea L. cv. Monatol) and lettuce (Valerianella locusta [L.] Betcke) in situ and in vitro.

After heating of whole leaves or protoplasts, endogenous respiration was not or only slightly affected at temperatures which caused a marked decrease of photosynthesis. This was manifested when mitochondria and thylakoids were isolated from heat-treated leaves. In the presence of exogenous substrates, mitochondrial electron transport and phosphorylation were even somewhat stimulated compared to the controls.

Inactivation of net CO₂ uptake of whole leaves following heat stress and of the photochemical activities of chloroplast membranes isolated from heat-treated leaves of the same origin occurred nearly simultaneously. In protoplasts, photosynthesis was inactivated at temperatures far below those which caused drastic changes in the integrity of the tonoplast and the plasmalemma. This indicates that damage occurring within the chloroplasts rather than alterations in the compartmentation of the cell is responsible for the high sensitivity of photosynthesis to supraoptimal temperature stress.

Mitochondria and thykaloids isolated from the same preparation of intact leaves under comparable conditions and subjected to heat treatment in vitro, however, were inactivated nearly in the same temperature range. Thus, mitochondria are much more stable within their cytoplasmic environment.

     

Heat induced infertility of boars: The inter-relationship between depressed sperm output and fertility and an estimation of the critical air temperature above which sperm output is impaired

Eight groups of Large-White gilts were each inseminated with different numbers of normal motile sperm, in the range 0.28–7.0 × 10⁹. A significant (P < 0.05) relationship between conception rate and the number of motile sperm inseminated was shown. This relationship can be used to equate output of motile sperm with levels of fertility of boars. The optimal number of motile sperm for conception following intra-cervical insemination was near 5 × 10⁹ and the threshold number, below which animals did not conceive, was c. 4 × 10⁸.In a second experiment, three Large-White boars were subjected to graded thermal treatment (air temperature was increased by 1°C per day for 20 days, from a basal level of 20°C to a maximal level of 40°C) and responses of ejaculate and other physiological characteristics were monitored. Scrotal surface temperature, respiration rate and rectal temperature increased (P < 0.05) beyond basal levels at air temperatures of 30°C, 33°C and 35°C, respectively. Motility of sperm in ejaculates decreased when air temperature reached 30°C and this response was presumed to reflect hyperthermia in epididymal tissues, consistent with increasing scrotal surface temperature at this same air temperature. Motility fell below a pre-treatment level of about 93%, to 19% (P < 0.05), 3 weeks after heating. Volumes of seminal plasma and gel in ejaculates were also lower (P < 0.05) following heating. Changes in daily sperm production were minor and, as a result, daily motile sperm production levels paralleled changes in motility. Proportions of abnormal types of sperm increased (P < 0.05) to maximal levels in the last week of heating and all returned to pretreatment values 5 weeks later. High proportions of sperm with kinoplasmic droplets appeared in ejaculates collected after heating (P < 0.05), evidence that epididymal cell types in the boar are sensitive to heat.As a result of heat treatment, normal motile sperm production decreased from control levels (1.28 × 10¹⁰·day^?1) to 0.15 × 10¹⁰·day^?1, 3 weeks after heating ceased. However, the results suggest that normal sperm output by Large-White boars can be maintained at air temperatures as high as 29°C.By relating the results of both experiments, it is concluded that fertility of the boars in the second experiment (if mated once daily) would be depressed for about 5 weeks after heat treatment ceased. The findings support many field reports which indicate a contribution of boars to lower conception rates of sows during and immediately following summer and the results can be used in formulating strategies to circumvent this widespread problem.     

Neutrophil migration in canines: In vivo comparison of granulocyte function following 24-hour storage at 6 or 20 °C of leukocyte concentrates or of granulocytes purified by counterflow centrifugation-elutriation

The use of granulocyte-rich concentrates from leukapheresis purified by counterflow centrifugation—elutriation to obtain pure granulocytes for transfusion studies in cyclo-phosphamide-induced neutropenic animal models is reported. Our data for granulocyterich leukapheresis concentrates indicate that room temperature (20 °C) appears to be preferred to 6 °C for short-term granulocyte storage. The data also indicate that although the granulocytes isolated by counterflow centrifugation—elutration may retain in vitro functions of chemotaxis, phagocytosis, and bactericidal activity, the in vivo function of migration into skin chambers for isolated granulocytes is seriously impaired after storage for 18 to 24 hr at both 6 and 20 °C. This loss of in vivo function of stored granulocytes occurs in isolated granulocytes obtained by both counterflow centrifugation-elutriation and dextran sedimentation, and it is not observed in the leukocyte concentrates held at 20 °C. The results of these studies are fourfold. First, freshly isolated granulocytes display no apparent loss of either in vivo or in vitro function. Second, granulocytes isolated by counterflow centrifugation-elutriation or dextran sedimentation and stored at 6 or 20 °C are severely impaired in terms of their in vivo chemotactic function but display no loss of in vitro efficacy. Third, 20 °C storage of granulocyte-rich leukapheresis concentrates for 18 to 24 hr is superior to 6 °C storage. Fourth, in vitro analysis may be limited in its ability to indicate in vivo function as a measure of success in granulocyte preservation studies.     

Inhibition of photosynthesis by chilling in the light

The photosynthetic activity of leaf slices from Spinacia oleracea L., Cucumis sativus L. and Nerium oleander L. was measured in 25° C immediately after preincubation for 2.5 h at various photon flux densities (PFD) with chilling at 4°C, or at a moderate (450 μmol m⁻² s⁻¹) PFD with various temperatures below 25°C. Inhibition of photosynthesis was evident in C. sativus and 45°C-grown N. oleander after preincubation at 4°C at all PFD. The inhibition was most severe at fluxes in excess of the moderate PFD under which the plants were grown. Photosynthesis in S. oleracea and 20°C-grown N. oleander was not inhibited at 4°C unless the PFD was in excess of this moderate PFD. The inhibition of photosynthesis was initiated in C. sativus below 13°C, and in 45°C-grown N. oleander below 8°C. A phase transition in the polar lipids from the thylakoids of these plants was detected at about the same temperatures. For S. oleracea and 20°C-grown N. oleander preincubated under the same conditions, there was no inhibition of photosynthesis and no phase transition above 0°C. These results show that some component of photosynthesis was disrupted in the light at temperatures below that of the phase transition in the thylakoid polar lipids.     

Influence of growth temperature on respiratory characteristics of mitochondria from callus-forming potato tuber discs

The uninhibited respiration of mitochondria, isolated from potato tuber discs (Solanum tuberosum L. cv. Bintje) incubated on a callus-inducing medium at 28°C, is higher than that of mitochondria from tissue incubated at 8°C. This respiration is composed of a CN-sensitive and a CN-resistant part. The capacity of the CN-resistant alternative oxidase pathway is larger in mitochondria from 28°C tissue than in mitochondria from 8°C tissue (35% and 8% of uninhibited respiration, respectively). The alternative pathway is operative both in mitochondria from 28°C tissue and 8°C tissue.

The observed difference in uninhibited respiration, is not only caused by lower values of respiration via the alternative pathway in mitochondria from 8°C tissue, but also by lower values of respiration via the cytochrome pathway.

A positive correlation has been demonstrated between the incubation temperature (ranging from 4-37°C) and the relative capacity of respiration via alternative pathway in the mitochondria. Induction of alternative pathway is not directly correlated with growth (in terms of increase in fresh weight) of the potato tuber discs.

     

H2O2 production and cytochrome c peroxidase activity in mitochondria isolated from the trypanosomatid hemoflagellate Crithidia fasciculata

H₂O₂ production by coupled mitochondrial fractions from the protozoan, Crithidia fasciculata, has been measured spectrophotometrically by the formation of the stable enzyme-substrate complex with yeast cytochrome c peroxidase. H₂O₂ formation was observed with succinate, l-α-glycerophosphate, l-proline, α-ketoglutarate, and with endogenous substrate. The maximum rate of H₂O₂ generation obtained with each substrate in the presence of antimycin A was about 10% of the state 4 rate of O₂ respiration, and only 1–2% of the carbonylcyanide m-fluorophenylhydrazone-uncoupled respiratory rate. Therefore, excess O₂ uptake due to the formation of H₂O₂ cannot satisfactorily account for the low ADP:O ratios previously reported.Cytochrome c peroxidase activity was measured in mitochondrial preparations by recording the decrease in absorbance at 550 nm during the oxidation of horse heart ferrocytochrome c which was observed after addition of H₂O₂. The distribution of activity after sonic disruption of mitochondrial preparations was that expected for a soluble enzyme. The activity was proportional to the amount of enzyme protein added, and was abolished by heating at 100 °C for 3 min. Total cytochrome c peroxidase activity in mitochondrial fractions isolated from C. fasciculata was calculated to be 0.3% that of isolated yeast mitochondria, but it is suggested that the in vivo activity may be considerably higher than this estimate.     

Thermotolerance and trehalose accumulation induced by heat shock in yeast cells of Candida albicans

Candida albicans yeast cells growing exponentially on glucose are extremely sensitive to severe heat shock treatments (52.5°C for 5 min). When these cultures were subjected to a mild temperature preincubation (42°C), they became thermotolerant and displayed higher resistance to further heat stress. The intracellular content of trehalose was very low in exponential cells, but underwent a marked increase upon non-lethal heat exposure. The accumulation of trehalose is likely due to heat-induced activation of the trehalose-6-phosphate synthase complex, whereas the external trehalase remained practically unmodified. After a temperature reversion shift (from 42°C to 28°C), the pool of trehalose was rapidly mobilized without any concomitant change in trehalase activity. These results support an important role of trehalose in the mechanism of acquired thermotolerance in C. albicans and seem to exclude the external trehalase as a key enzyme in this process.     

In vitro growth environment produces lipidomic and electron transport chain abnormalities in mitochondria from non-tumorigenic astrocytes and brain tumours

The mitochondrial lipidome influences ETC (electron transport chain) and cellular bioenergetic efficiency. Brain tumours are largely dependent on glycolysis for energy due to defects in mitochondria and oxidative phosphorylation. In the present study, we used shotgun lipidomics to compare the lipidome in highly purified mitochondria isolated from normal brain, from brain tumour tissue, from cultured tumour cells and from non-tumorigenic astrocytes. The tumours included the CT-2A astrocytoma and an EPEN (ependymoblastoma), both syngeneic with the C57BL/6J (B6) mouse strain. The mitochondrial lipidome in cultured CT-2A and EPEN tumour cells were compared with those in cultured astrocytes and in solid tumours grown in vivo. Major differences were found between normal tissue and tumour tissue and between in vivo and in vitro growth environments for the content or composition of ethanolamine glycerophospholipids, phosphatidylglycerol and cardiolipin. The mitochondrial lipid abnormalities in solid tumours and in cultured cells were associated with reductions in multiple ETC activities, especially Complex I. The in vitro growth environment produced lipid and ETC abnormalities in cultured non-tumorigenic astrocytes that were similar to those associated with tumorigenicity. It appears that the culture environment obscures the boundaries of the Crabtree and the Warburg effects. These results indicate that in vitro growth environments can produce abnormalities in mitochondrial lipids and ETC activities, thus contributing to a dependency on glycolysis for ATP production.