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.     

Palmitate oxidation by in vivo and in vitro grown Mycobacterium lepraemurium.

Oxidation of palmitate by Mycobacterium lepraemurium isolated from C3H mice lepromata (in vivo) and also grown on Ogawa egg-yolk medium (in vitro) was investigated. Palmitate was found to be oxidized, after a lag period of about 8 h, by both the in vivo and in vitro grown bacilli. Cell-free extracts prepared from in vivo and in vitro grown cells catalysed an active oxidation of palmitate after a lag period of 3-4 h. The amount of ATP increased, with the increase in time during oxidation of palmitate by the cell-free extracts. The generation of ATP was strongly inhibited by the inhibitors rotenone, antimycin A and cyanide as well as by the uncouplers 2,4-dinitrophenol and 2,6-dibromophenol. These results indicated that oxidation of palmitate by the in vivo and in vitro grown M. lepraemurium is mediated through the respiratory chain using oxygen as the terminal electron acceptor.     

Simultaneous monitoring of intracellular ATP and oxygen levels in chondrogenic differentiation using a dual‐color bioluminescence reporter

A number of assay methods which measure cellular metabolic activity have only measured intracellular ATP levels because it has been speculated that ATP production and oxygen consumption are obligatorily coupled to each other under normal conditions. However, there exist many cases in which ATP production and oxygen consumption are uncoupled. Therefore, measurement of only intracellular ATP levels has a limit for understanding the overall metabolic states during various cellular functions. Here, we report a novel system for simultaneously monitoring intracellular ATP and oxygen levels using a red‐emitting Phrixothrix hirtus luciferase (PxRe) and a blue‐emitting Renilla luciferase (Rluc). Using this system, we monitored the dynamic changes in both intracellular ATP and oxygen levels during chondrogenesis. We found that the oxygen level oscillated at twice the frequency of ATP in chondrogenesis and the oxygen oscillations have an antiphase mode to the ATP oscillations; we also found an independent mode for the ATP oscillations. This result indicates that both mitochondrial and non‐mitochondrial respiration oscillate and thus play a role in chondrogenesis. This dual‐color monitoring system is useful for studying metabolic regulations that underlie diverse cellular processes. Copyright © 2013 John Wiley & Sons, Ltd.     

Membrane protein organization in ATP-depleted and irreversibly sickled red cells

It has been proposed that the spectrin-actin submembrane network participates in control of red cell shape and deformability. We have examined ATP- and calcium-dependent changes in organization of spectrin in the membrane employing cross-linking of the nearest membrane protein neighbors by spontaneous or catalyzed (CuSO₄, O-phenanthroline) intermolecular disulfide couplings and two-dimensional sodium dodecyl sulfate polyacrylamide gel electrophoresis. Cross-linking of fresh red cells resulted in the formation of spectrin and actin dimers and tetramers. ATP-depleted red cells differed from fresh cells in the presence of an additional reducible polymer of MW > 1 × 10⁶ selectively enriched in spectrin. This polymer formed spontaneously when red cells were depleted of ATP under aerobic conditions. After anaerobic ATP depletion, the polymer formed in ghosts after cross-linking by catalytic oxidation. Polymerization was prevented by maintenance of ATP and coincided with an ATP-dependent discocyte-echinocyte transformation. This suggests that, in ATP-depleted red cells, spectrin is rearranged to establish closer contacts, and that this may contribute to the discocyte-echinocyte transformation. The introduction of greater than 0.5 mM Ca⁺⁺ into ghosts by inclusion in hemolysis buffer or into fresh red cells (but not ATP-depleted red cells) by treatment with ionophore A23187 spontaneously produced a nonreducible polymer which others have attributed to transamidative cross-linking of spectrin, band 3, and other proteins. Spontaneous formation of both polymer types (reducible in aerobically ATP-depleted red cells and nonreducible in fresh, Ca⁺⁺ enriched red cells) resulted in stabilization (“autocatalytic fixation”) of spheroechinocytic shape. Irreversibly sickled cells, which have increased calcium and decreased ATP, and exhibit a permanent membrane deformation, failed to form any of the above polymers. This suggests that in contrast to normal cells depleted of ATP in vitro, fixation of ISC shape in vivo is not related to Ca- and ATP-dependent membrane protein polymerization. However, ISCs had an increased propensity to form the reducible, spectrin-rich polymer during a subsequent metabolic depletion in vitro. This was associated with transformation of ISCs into spheroechinocytes. Similar echinocytic ISCs were found to constitute 5–10% of the densest fractions of freshly separated ISCs. ISCs then exhibit sphero-echniocyte transformation, both in vitro and in vivo. We propose that this is due to spectrin reorganization that presumably results from the progressively increasing calcium and decreasing ATP of ISCs. These data provide evidence of altered spectrin organization in membranes of ATP-depleted, calcium-enriched red cells in vitro and in vivo.     

Evidence that tyrphostins AG10 and AG18 are mitochondrial uncouplers that alter phosphorylation-dependent cell signaling

Receptor agonists that initiate fluid secretion in salivary gland epithelial cells also increase protein phosphorylation. To assess contributions of tyrosine phosphorylation to secretion, changes in muscarinic receptor-initiated secretion (estimated from sodium pump-dependent increases in oxygen consumption) were measured in parotid acinar cells exposed to tyrosine kinase inhibitors. However, like the mitochondrial uncoupler carbonyl cyanide p-trifluoromethoxyphenyl hydrazone, tyrphostins AG10 and AG18 increased the rate of oxygen consumption and reduced cellular ATP by approximately 90% in the absence of the muscarinic agonist carbachol, indicating that these tyrphostins uncouple mitochondria. Exposure of isolated mitochondria to five structurally related tyrphostins demonstrated that their relative potencies as uncouplers differed from their in vitro kinase-inhibitory potencies due to different molecular requirements for the two effects. AG10 and AG18 blocked parotid phosphorylation events only at concentrations that reduced ATP content. The tyrosine kinase inhibitor genistein reduced ATP content by 15-20% and weakly uncoupled isolated mitochondria, but its inhibition of carbachol-mediated protein kinase Cdelta tyrosine phosphorylation and ERK1/2 activation appeared attributable to blocking tyrosine kinases directly. Carbachol itself rapidly reduced ATP content by 15-20%. Carbachol, 3'-O-(4-benzoyl)benzoyl adenosine 5'-triphosphate (P2X(7) receptor agonist), AG10, AG18, and carbonyl cyanide p-trifluoromethoxyphenyl hydrazone rapidly activated the fuel sensor AMP-activated protein kinase (AMPK); however, only AMPK activation by carbachol and BzATP was due to sodium pump stimulation. AG10 and AG18 also activated AMPK and/or uncoupled mitochondria in PC12, HeLa, and HEK293 cells. These studies demonstrate that some tyrosine kinase inhibitors produce cellular effects that are mechanistically different from their primary in vitro characterizations and, as do salivary secretory stimuli, promote rapid metabolic alterations that initiate secondary signaling events.     

Mutualism based on stress: selective synthesis and phosphorylation of a stress protein by an intracellular symbiont.

The effects of a temperature shift-up and various metabolic inhibitors on the protein synthesis of an endosymbiont isolated from the pea aphid were studied. The syntheses of at least three major polypeptides were stimulated transiently immediately after a temperature shift-up, and treatment with ethanol and heavy metals (Cd2+ and As2+). One of these proteins, the 63 kDa heat-shock protein (63-kDa HSP), was immunoprecipitated with antiserum raised against symbionin, which is selectively synthesized by the endosymbiont harbored by the aphid bacteriocytes. The 63 kDa heat-shock protein has a molecular mass of 800 kDa and is more acidic than symbionin. It was also shown that symbionin is subject to phosphorylation in vivo and in vitro after a temperature shift-up. It was thought likely that forms of environmental stress such as heat shock and metabolic inhibitors stimulate the synthesis of a phosphorylated form of symbionin. It was also suggested that the in vitro phosphorylation of symbionin is due to its own catalytic activity. Since symbionin is a homolog of the Escherichia coli groEL protein, a stress protein, it is likely that the endosymbiont suffers stress when harbored by the bacteriocytes and responds in a similar manner to environmental stress when outside these cells.     

Effects of Reserpine and Tetrabenazine on Catecholamine and ATP Storage in Cultured Bovine Adrenal Medullary Chromaffin Cells

The in vivo storage relationship between catecholamines and ATP in chromaffin vesicles of cultured bovine adrenal medulla cells was investigated using drugs that block vesicular catecholamine uptake. Three-day treatments with reserpine and tetrabenazine causing 85-90% depletion of catecholamines resulted in 41-46% reductions in cellular ATP content. Subcellular fractionation of reserpine-treated cells indicated that the ATP is lost from the chromaffin vesicle pool. This was confirmed in experiments using metabolic inhibitors to differentiate the vesicular and extravesicular ATP pools. The vesicular ATP loss was not proportional to that of catecholamines, resulting in a reduction by 50% in the chromaffin vesicle mole ratio of catecholamines to ATP after 48 h of treatment. In metabolic labeling studies, it was found that reserpine treatment reduced the incorporation of [3H]adenosine into vesicular ATP selectively, but it reduced the incorporation of 32Pi into both the vesicular and extravesicular pools. The reduction of the [3H]adenosine incorporation was not due to diminished vesicular nucleotide uptake resulting from low catecholamine levels, because when the catecholamines were depleted by tetrabenazine pretreatment followed by removal of the drug before labeling, no reduction in [3H]adenosine incorporation was observed. When present during the labeling, tetrabenazine was found to be a reversible inhibitor of plasma membrane adenosine uptake. The observed loss of adenine nucleotides from catecholamine-depleted chromaffin vesicles in vivo provides evidence that interactions between ATP and catecholamines are important in the vesicular storage of high concentration of these compounds.     

A symbiotic relationship of energy metabolism between a ‘non-glycolytic’ mammalian red cell and the liver

The red cell of newborn pig loses the ability to carry out glycolysis within a month after birth. The metabolic energy source for this ‘non-glycolytic’ mammalian red cell is unknown. Hepatectomy of an adult pig results in the loss of red cell ATP with a characteristic half-time of 7–8 h which is identical to the rate with which ATP disappears in the pig cells under in vitro substrate-free incubation. Exposure of pig red cells with either normal or depleted levels of ATP to isolated hepatocytes causes a net synthesis of red cell ATP during a 12 h incubation. These findings suggest that a symbiotic relationship of energy metabolism may exist between the red cell and the liver of the pig.     

Neurotensin receptor binding and neurotensin-induced growth signaling in prostate cancer PC3 cells are sensitive to metabolic stress

Neurotensin (NT) stimulates the proliferation of prostate cancer PC3 cells, which express high levels of its G protein-coupled receptor NTS1. To shed light on mechanisms that might serve to coordinate mitogenic responses to metabolic status, we studied the effects of metabolic inhibitors on NTS1 function. We also related these effects to cellular ATP levels and to the activation of AMP-activated protein kinase (AMPK). Glycolytic and mitochondrial inhibitors, at concentrations that reduced cellular ATP levels, altered NT binding to the cells, inhibited NT-induced inositol phosphate formation, and inhibited NT-induced DNA synthesis. For eight of the nine inhibitors, the potencies to alter NT receptor function correlated to the potencies to decrease cellular ATP levels. In keeping with its known role to oppose metabolic stress, AMPK was activated by the metabolic inhibitors. Accordingly, the AMPK activator AICAR elevated cellular ATP levels and produced effects on NTS1 function that were opposite to those for the metabolic inhibitors. These results indicate that metabolic stress inhibited NTS1 function by a mechanism that involved a fall in cellular ATP levels and that was opposed by activation of AMPK. In a broader context, these findings are compatible with the idea that one means by which cells might coordinate mitogenic signaling to metabolic status could involve changes in growth factor receptor function.     

Age-dependent metabolic changes in cultured human fibroblasts

Summary The effects of metabolic poisons on the ATP content of cultured human skin fibroblasts at selected in vitro and in vivo ages were studied. Potassium cyanide, iodacetemide, and Arsenate were used to inhibit ATP restoration by glycolysis and oxidative phosphorylation. Cells treated with these metabolic poisons showed an age-dependent change in their ATP content. The decrease in cellular ATP content after exposure to these drugs was taken as an estimate of ATP turnover. It was found that there was a decrease in the ATP turnover with increasing population doubling level (i.e. in vitro age), and cells cultured from a 68-yr-old donor had a lower ATP turnover than those cultured from a neonatal donor. This decreased ATP turnover correlates with a previous finding of a decreased ability of “older” cells to be stimulated to migrate in culture and suggests that there is a metabolic component to this age-related functional deficiency. This work was supported by National Institutes of Health grants 2, RO1 EY02523 and 1 RO1 1, AGO 1212 awarded to A.L. Muggleton-Harris.     

Hypoxia and stem cell‐based engineering of mesenchymal tissues

Stem cells have the ability for prolonged self‐renewal and differentiation into mature cells of various lineages, which makes them important cell sources for tissue engineering applications. Their remarkable ability to replenish and differentiate in vivo is regulated by both intrinsic and extrinsic cellular mechanisms. The anatomical location where the stem cells reside, known as the “stem cell niche or microenvironment,” provides signals conducive to the maintenance of definitive stem cell properties. Physiological condition including oxygen tension is an important component of the stem cell microenvironment and has been shown to play a role in regulating both embryonic and adult stem cells. This review focuses on oxygen as a signaling molecule and the way it regulates the stem cells' development into mesenchymal tissues in vitro. The physiological relevance of low oxygen tension as an environmental parameter that uniquely benefits stem cells' expansion and maintenance is described along with recent findings on the regulatory effects of oxygen on embryonic stem cells and adult mesenchymal stem cells. The relevance to tissue engineering is discussed in the context of the need to specifically regulate the oxygen content in the cellular microenvironment in order to optimize in vitro tissue development. © 2009 American Institute of Chemical Engineers Biotechnol. Prog., 2009     

Cellular hypoxia of pancreatic beta-cells due to high levels of oxygen consumption for insulin secretion in vitro

Cellular oxygen consumption is a determinant of intracellular oxygen levels. Because of the high demand of mitochondrial respiration during insulin secretion, pancreatic β-cells consume large amounts of oxygen in a short time period. We examined the effect of insulin secretion on cellular oxygen tension in vitro. We confirmed that Western blotting of pimonidazole adduct was more sensitive than immunostaining for detection of cellular hypoxia in vitro and in vivo. The islets of the diabetic mice but not those of normal mice were hypoxic, especially when a high dose of glucose was loaded. In MIN6 cells, a pancreatic β-cell line, pimonidazole adduct formation and stabilization of hypoxia-inducible factor-1α (HIF-1α) were detected under mildly hypoxic conditions. Inhibition of respiration rescued the cells from becoming hypoxic. Glucose stimulation decreased cellular oxygen levels in parallel with increased insulin secretion and mitochondrial respiration. The cellular hypoxia by glucose stimulation was also observed in the isolated islets from mice. The MIN6 cells overexpressing HIF-1α were resistant to becoming hypoxic after glucose stimulation. Thus, glucose-stimulated β-cells can become hypoxic by oxygen consumption, especially when the oxygen supply is impaired.     

Metabolic rate does not scale with body mass in cultured mammalian cells

The allometric scaling of metabolic rate with organism body mass can be partially accounted for by differences in cellular metabolic rates. For example, hepatocytes isolated from horses consume almost 10-fold less oxygen per unit time as mouse hepatocytes [Porter and Brand, Am J Physiol Regul Integr Comp Physiol 269: R226-R228, 1995]. This could reflect a genetically programmed, species-specific, intrinsic metabolic rate set point, or simply the adaptation of individual cells to their particular in situ environment (i.e., within the organism). We studied cultured cell lines derived from 10 mammalian species with donor body masses ranging from 5 to 600,000 g to determine whether cells propagated in an identical environment (media) exhibited metabolic rate scaling. Neither metabolic rate nor the maximal activities of key enzymes of oxidative or anaerobic metabolism scaled significantly with donor body mass in cultured cells, indicating the absence of intrinsic, species-specific, cellular metabolic rate set points. Furthermore, we suggest that changes in the metabolic rates of isolated cells probably occur within 24 h and involve a reduction of cellular metabolism toward values observed in lower metabolic rate organisms. The rate of oxygen delivery has been proposed to limit cellular metabolic rates in larger organisms. To examine the effect of oxygen on steady-state cellular respiration rates, we grew cells under a variety of physiologically relevant oxygen regimens. Long-term exposure to higher medium oxygen levels increased respiration rates of all cells, consistent with the hypothesis that higher rates of oxygen delivery in smaller mammals might increase cellular metabolic rates.     

Metabolic stages, mitochondria and calcium in hypoxic/ischemic brain damage

Cerebral hypoxia/ischemia leads to mitochondrial dysfunction due to lack of oxygen leaving the glycolytic metabolism as a main pathway for ATP production. Inhibition of mitochondrial respiration thus triggers generation of lactate and hydrogen ions (H+), and furthermore dramatically reduces ATP generation leading to disregulation of cellular ion metabolism with subsequent intracellular calcium accumulation. Upon reperfusion, when mitochondrial dysfunction is (at least partially) reversed by restoring cerebral oxygen supply, bioenergetic metabolism recovers and brain cells are able to re-institute their normal ionic homeostatic mechanisms. However, the initial restoration of normal mitochondrial function may be only transient and followed by a secondary, delayed perturbation of mitochondrial respiratory performance seen as a decrease in cellular ATP levels and known as "secondary energy failure". There have been several mechanisms considered responsible for delayed post-ischemic mitochondrial failure, the mitochondrial permeability transition (MPT) being one that is considered important. Although the amount of calcium available during early reperfusion in vivo is limited, relative to the amount needed to trigger the MPT in vitro; the additional intracellular conditions (of acidosis, high phosphate, and low adenine nucleotideae levels) prevailing during reperfusion, favor MPT pore opening in vivo. Furthermore, the cellular redistribution and/or changes in the intracellular levels of pro-apoptotic proteins can alter mitochondrial function and initiate apoptotic cell death. Thus, mitochondria seem play an important role in orchestrating cell death mechanisms following hypoxia/ischemia. However, it is still not clear which are the key mechanisms that cause mitochondrial dysfunction and lead ultimately to cell death, and which have more secondary nature to brain damage acting as aggravating factors.     

Oxygen availability regulates metabolism and gene expression in trout hepatocyte cultures

We studied the metabolic rate, cellular energetic state, hypoxia-inducible factor-1 (HIF-1) activation, and expression of enzymes involved in energy metabolism using rainbow trout (Oncorhynchus mykiss) hepatocytes over the oxygen range from 21 to 1 kPa. Oxygen dependence of these factors was assessed by gradually reducing oxygen supply to cells from 21 kPa to 10, 5, 2, and 1 kPa. Moreover, time course experiments for up to 20 h at oxygen tensions of 1 and 2 kPa were carried out. Reduction of oxygen from 21 kPa to 10, 5, 2, and 1 kPa decreased metabolic rate of the cells by 14, 24, 37, and 46%, respectively. This response was instantaneous and fully reversible upon reoxygenation. Cellular ATP content and the expression of all mRNAs studied decreased when oxygen was reduced from 21 to 5 and 2 kPa. The lowest ATP levels, approximately 43% of the initial value, were measured at 5 kPa of oxygen, whereas the reduction in mRNA amounts was most pronounced at 2 kPa. At 1 kPa oxygen tension, both ATP content and mRNA amounts returned to normoxic (21 kPa) levels with a concomitant activation of HIF-1, indicating reorganization of energy metabolism in adaptation of cells to low oxygen supply. These results show that oxygen has a direct regulatory effect on metabolism of trout hepatocyte cultures, supporting the view that oxygen has a profound role in metabolic regulation in cells.     

Correlation of structure and active transport in the teleost nephron.

In the present study we have extended our investigations concerning the correlation between ultrastructure and active transport in the isolated flounder nephron. The composition of the fish nephron is defined in ultrastructural terms and its behavior when incubated in vitro under short term and long term culture conditions is described. Using the in vitro system originally described by Forster, a variety of inhibitors and conditions which modify cell structure and function were tested. Ultrastructure was correlated with chlorphenol red dye transport. In general, conditions altering active transport also markedly altered cellular ultrastructure. The principal alterations consisted of membrane changes involving various organelles--most importantly the plasma membrane and the mitochondria. Conditions associated with irreversible cell injury could be rapidly produced by interference either with mitochondrial ATP synthesis or with the integrity of the plasma membrane. Both of these rapidly lead to irreversible events which are preceded by reversible structural changes. Organelle changes progress in a rather well-defined sequence of reversible and irreversible stages which are defined. One difference between the two types of interactions is the presence of intramitochondrial calcification which does not occur with direct modification of the mitochondrial electron transport system. The concept of utilizing long term explant organ cultures of fish nephrons for environmental studies is introduced.     

Purinergic signaling and kinase activation for survival in pulmonary oxidative stress and disease

Stimulus-induced release of endogenous ATP into the extracellular milieu has been shown to occur in a variety of cells, tissues, and organs. Extracellular ATP can propagate signals via P2 receptors that are essential for growth and survival of cells. Abundance of P2 receptors, their multiple isoforms, and their ubiquitous distribution indicate that they transmit vital signals. Pulmonary epithelium and endothelium are rich in both P2X and P2Y receptors. ATP release from lung tissue and cells occurs upon stimulation both in vivo and in vitro. Extracellular ATP can activate signaling cascades composed of protein kinases including extracellular signal-regulated kinase (ERK) and phosphatidylinositol-3-kinase (PI3K). Here we summarize progress related to release of endogenous ATP and nucleotide signaling in pulmonary tissues upon exposure to oxidant stress. Hypoxic, hyperoxic, and ozone exposures cause a rapid increase of extracellular ATP in primary pulmonary endothelial and epithelial cells. Extracellular ATP is critical for survival of these cells in high oxygen and ozone concentrations. The released ATP, upon binding to its specific receptors, triggers ERK and PI3K signaling and renders cells resistant to these stresses. Impairment of ATP release and transmission of such signals could limit cellular survival under oxidative stress. This may further contribute to disease pathogenesis or exacerbation.     

Investigation by amperometric methods of intracellular reduction of 2,6-dichlorophenolindophenol in normal and transformed hepatocytes in the presence of different inhibitors of cellular metabolism

The reduction of 2,6-dichlorophenolindophenol (DCIP) was measured by amperometric methods in Morris hepatoma 3924A cells, normal isolated rat hepatocytes and in mitochondria isolated from normal rat liver. The influence of aerobic and anaerobic atmospheres and of various inhibitors of cellular metabolism, especially of the respiratory chain (KCN, NaN3, oligomycin), on DCIP-reduction were studied using glucose, succinate, beta-hydroxybutyrate, alpha-keto-glutarate and oxalacetate as substrates. Under the influence of KCN and oligomycin the velocity of DCIP-reduction was increased in both cell types. Azide showed a similar effect on tumour cells and to a lower extent on hepatocytes. Using isolated mitochondria total DCIPred was increased by KCN and azide using various mitochondrial metabolites as substrates and with ADP/Pi present. The effects of KCN, azide and oligomycin could be explained by taking DCIP as an artificial coupling site in mitochondria which is only used when oxygen is absent or when the respiratory chain is blocked by inhibitors of cytochrome oxidase. Evaluation of the reaction kinetics revealed differences between normal and transformed cells in terms of the pseudo-first-order rate constants and the activity of overall oxidoreductases. The results apparently reflect quantitative differences in enzymatic equipment and the metabolic pathways predominating in normal and neoplastic cells.