A Simple Cranial Window Technique for Optical Monitoring of Cerebrocortical Microcirculation and NAD/NADH Redox State. Effect of Mitochondrial Electron Transport Inhibitors and Anoxic Anoxia

Abstract: Fluorescence of NADH and vascular volume of the brain cortex of chloralose-anesthetized cats were measured by surface fluororeflectometry. A cranial window and superfusion technique was elaborated for the topical inhibition of mitochondrial electron transport in the brain cortex by amytal (inhibits at site I) and cyanide (inhibits at site III). The changes in NAD/NADH redox state and CVV evoked by these electron transport inhibitors were compared with those elicited by anoxic anoxia. Amytal (10^-3-10^-1 M ) and cyanide (10^-5-10^-2 M ) resulted in a concentration-dependent and reversible increase in cortical NAD reduction and vascular volume, but the cerebrocortical vessels were almost completely dilatated long before maximum NAD reduction was reached. Cyanide at 10^-2 M increased cortical NAD reduction and vascular volume as much as anoxic anoxia. Amytal at 10^-1 M induced approximately half of the NAD reduction evoked by 10^-2 M cyanide or anoxic anoxia, but resulted in only slightly less vasodilatation than that following cyanide and anoxic anoxia. Since amytal inhibits mitochondrial electron transport at site I—and cyanide and anoxia at site III—but induces a comparable degree of vasodilatation, it is concluded that cytochrome oxidase cannot be the single molecular oxygen sensor in the brain cortex.     

Anoxia-Induced Changes in Pyridine Nucleotide Redox State in Cortical Neurons and Astrocytes

NAD(P)H autofluorescence was used to verify establishment of metabolic anoxia using primary cultures of cortical neurons and astrocytes. Cells on cover slips were placed in a chamber and O₂ was displaced by continuous infusion of argon. Perfusion with medium at PO₂ < 0.4 mm Hg caused an increase in NAD(P)H fluorescence, albeit to levels lower than that obtained with cyanide. Addition of the nitric oxide-generating agent DETA-NO to the hypoxic medium further increased fluorescence to the level with cyanide. Fluorescence under anoxia remained high in the presence of glucose, but declined in neurons and not in astrocytes when glucose was substituted with 2-deoxyglucose. Reoxygenation of neurons resulted in a decline in fluorescence and a loss in fluorescent gradient between fully reduced and fully oxidized (plus respiratory uncoupler). We conclude that (1) DETA-NO is useful for generating metabolic anoxia in the presence of argon (2) Exogenous glucose is necessary to maintain NAD(P)H in a reduced state during metabolic anoxia in neurons but not astrocytes (3) Neurons undergo a partially irreversible decline in NAD(P)H fluorescence during metabolic anoxia and reoxygenation that could contribute to prolonged metabolic failure. Special issue dedicated to John P. Blass.     

Some factors influencing sodium extrusion by internally dialyzed squid axons

Squid giant axons were internally dialyzed by a technique previously described. In an axon exposed to cyanide seawater for 1 hr and dialyzed with an ATP-free medium, the Na efflux had a mean value of 1.3 pmole/cm²sec when [Na]_i was 88 mM, in quantitative agreement with flux ratio calculations for a purely passive Na movement. When ATP at a concentration of 5–10 mM was supplied to the axoplasm by dialysis, Na efflux rose almost 30-fold, while if phosphoarginine, 10 mM, was supplied instead of ATP, the Na efflux rose only about 15-fold. The substitution of Li for Na in the seawater outside did not affect the Na efflux from an axon supplied with ATP, while a change to K-free Na seawater reduced the Na efflux to about one-half. When special means were used to free an axon of virtually all ADP, the response of the Na efflux to dialysis with phosphoarginine (PA) at 10 mM was very small (an increment of ca. 3 pmole/cm²sec) and it can be concluded that more than 96% of the Na efflux from an axon is fueled by ATP rather than PA. Measurements of [ATP] in the fluid flowing out of the dialysis tube when the [ATP] supplied was 5 mM made it possible to have a continuous measurement of ATP consumption by the axon. This averaged 43 pmole/cm²sec. The ATP content of axons was also measured and averaged 4.4 mM. Estimates were made of the activities of the following enzymes in axoplasm: ATPase, adenylate kinase, and arginine phosphokinase. Values are scaled to 13°C.     

The use of the tetrazolium salt XTT for the estimation of biological activity of activated sludge cultivated under steady-state and transient regimes

The tetrazolium salt 3′-{1-[(phenylamino)-carbonyl]-3,4-tetrazolium}-bis (4-methoxy-6-nitro) benzenesulfonic acid hydrate (XTT) was used as a tool for estimating the activity of the electron transport system (ETS) in activated sludge cultivated under steady-state and transient regimes in chemostat culture. Production of formazan by reduction of XTT depended on the initial concentration of the XTT following a saturation law and was proportional to live cell biomass. Addition of cyanide (KCN) to activated sludge gave an initial 1.5-fold increase in XTT reduction, while addition of 3,5-dichlorophenol (3,5-DCP) reduced this value drastically. At steady-state and transient regimes of an activated sludge chemostat, oxygen uptake rate (OUR) and XTT reduction rate were highly correlated and indicated significant variations depending on the growth conditions.     

Calcium measurement in the periphery of an axon

Aequorin was microinjected into squid giant axons, the axons were stimulated, and the change in light emission was followed. This response was compared with that found when the axon, in addition to being microinjected with aequorin, is also injected with the dye phenol red. Large concentrations of phenol red injected into axons result in a high probability that photons emitted by aequorin, when it reacts with Ca in the core of the axoplasm, will be absorbed before they escape from the axon; photons produced by the aequorin reaction at the periphery of the axoplasm are much less likely to be absorbed. This technique thus favors observing changes in Cai taking place in the periphery of the axon. Stimulation in 50 mM Ca seawater of an aequorin-phenol red-injected axon at 180 s-1 for 1 min produces a scarcely detectable change in Cai; the addition of 2 mM cyanide (CN) to the seawater produces an easily measureable increase in Cai, suggesting that mitochondrial buffering in the periphery is substantial. Making the pH of the axoplasm of a normal axon alkaline with 30 mM NH4+ -50 mM Ca seawater, reduces the resting glow of the axon but results in an even more rapid increase in Cai with stimulation. In a phenol red-injected axon, this treatment results in a measureable response to stimulation in the absence of CN.     

Effect of arterial hypoxia on the cerebrocortical redox state, vascular volume, oxygen tension, electrical activity and potassium ion concentration.

The effect of different degrees of arterial hypoxia on cerebrocortical NAD/NADH redox state, reflectance, oxygen tension, extracellular potassium ion concentration, ECoG and arterial blood pressure was investigated in rats. The results may be summarized as follows. a) The decrease of cortical pO2 preceded the dilatation of cortical vessels by 15-20 sec but the changes in cortical extracellular potassium ion concentration, ECoG and arterial blood pressure started later than the vasodilatation. These results give further support to the regulatory role of cortical pO2 decrease in the initiation of cerebrocortical vasodilatation during arterial hypoxia. b) Since the K+ concentration of the brain cortex and the ECoG did not change in mild arterial hypoxia, the significant NAD reduction obtained in this experimental group is likely to be of cytoplasmic origin. The same conclusion applies to the initial periods of severe arterial hypoxia. On the basis of the extent of NAD reduction during various degrees of arterial hypoxia it is concluded that about 30% of the NAD reduction occurring in anoxia is of cytoplasmic origin. c) When the animals were ventilated with a gas mixture containing 4-7% oxygen, the brain cortex became nearly anoxic, partly because of the gradual decrease of arterial blood pressure. Finally, the mechanism of potassium leakage is identical under prolonged severe arterial hypoxaemia and on anoxic terminal depolarization.     

The effect of intermediate respiratory chain inhibitors upon the tetrazolium-reductase activity of human polymorphonuclear leukocytes.

Intact human phagocytes are capable of reducing tetrazolium salts in their cytoplasm. The exact mechanism that reduces the dye is not well understood. It has been suggested that increased NADH and stimulation of NADH-oxidase may be responsible for tetrazolium reduction. This reaction is insensitive to terminal respiratory inhibitors such as cyanide, but the effect of intermediate respiratory inhibitors has not been explored. Amytal and Antimycin A were used in blood from 60 healthy subjects to study its effect upon the biochemical and histochemical tetrazolium-reductase reactions. It was found that Amytal and Antimycin block the reaction, while azide and cyanide have no effect. It was concluded that electrons are trapped between cytochromes b and C₁ and that this portion of the respiratory chain is essential for tetrazolium reduction. Since CoQ is the main constituent of that portion of the chain, we assume that this compound could be of prime importance in the biochemical events that lead to intracytoplasmic tetrazolium reduction. The possibility of CoQ participation in some phagocytic functions and in phagocytic disorders is discussed.     

Carbon monoxide-induced localized toxic anoxia in the rat brain cortex.

A new method has been developed for the determination of maximal reduction of NAD in the rat cerebral cortex. NADH fluorescence (450 nm) induced by 366-nm light and UV reflectance were measured by a time-sharing light pipe fluorometer. The redox state of the cortical surface was altered by perfusion of oxygen or carbon monoxide through a Teflon chamber adjacent to the dura. This study examines changes caused by local perfusion with the two gases in normoxia, hypoxia, and anoxia. Alternation of topical carbon monoxide and oxygen becomes effective in altering the intracellular redox state at 15% inspired oxygen and caused 20% changes at zero inspired oxygen. Conversely, topical application of oxygen to the systemically anoxic tissue causes oxidation of reduced NAPH in the cells within the field of fluorometric observation equivalent to that caused by breathing approximately 8% oxygen systemically.     

Long-term anoxia tolerance in leaves of Acorus calamus L. and Iris pseudacorus L

Mature green leaves of Acorus calamus and Iris pseudacorus have been shown to survive at least 28 d of total anoxia in the dark during the growing season, increasing up to 75 d and 60 d in overwintering leaves in A. calamus and I. pseudacorus, respectively. During the period of anaerobic incubation the glycolytic rate is reduced, carbohydrate reserves are conserved and ethanol levels in the tissues reached an equilibrium. Prolonged anoxia significantly suppressed leaf capacity for respiration and photosynthesis. After 28 d of anoxia, respiratory capacity was reduced in A. calamus and I. pseudacorus by 80% and 90%, respectively. The photosynthetic capacity of leaves decreased by 83% in A. calamus and by 97% in I. pseudacorus after 28 d of anoxia. This reduction in photosynthetic capacity was accompanied by a modification of the chlorophyll fluorescence pattern indicating damage to the PSII reaction centre and subsequent electron transport. Chlorophyll content was only slightly reduced after 28 d under anoxia and darkness in A. calamus, whereas there was a 50% reduction in I. pseudacorus. On return to air A. calamus leaves that endured 28 d of anoxia recovered full photosynthetic activity within 7 d while those of I. pseudacorus had a lag phase of 3-10 d. This well-developed ability to endure prolonged periods of oxygen deprivation in both these species is associated with a down-regulation in metabolic activity in response to the imposition of anaerobiosis. It is suggested that when leaf damage eventually does take place in these species after protracted oxygen deprivation, it is anoxic rather than post-anoxic stress that is responsible.     

EXPERIMENTALLY INDUCED CHROMOSOME ABERRATIONS IN PLANTS : II. THE EFFECT OF CYANIDE AND OTHER HEAVY METAL COMPLEXING AGENTS ON THE PRODUCTION OF CHROMOSOME ABERRATIONS BY X-RAYS

The discovery of Lilly and Thoday, that the presence of potassium cyanide (KCN) increases the production of chromosome aberrations by x-rays in anoxia, but has no effect on the production of chromosome aberrations by x-rays in air, was confirmed. In the presence of cyanide, the effect of a given dose of x-rays in nitrogen was found to be even greater than the effect of the same dose of x-rays in air. The cyanide effect on x-ray breakage in nitrogen was obtained at cyanide concentrations as low as 2 x 10^–5 M. The breakage obtained after the combined x-ray-cyanide treatments was of the x-ray type, as evidenced by the distribution of breaks within and between the chromosomes. A number of other heavy metal complexing agents as well as some other compounds were tested for their ability to increase x-ray breakage in nitrogen and air. Of these compounds only cupferron proved to be effective. The results are discussed and it is concluded that the increased x-ray breakage in the presence of cyanide or cupferron cannot be due to an accumulation of peroxides. Instead it is suggested that the cyanide effect may be due to a complex formation between the active agents and heavy metals, presumably iron, within the chromosomes. The consequences of this hypothesis on the concept of the "oxygen effect," are discussed.     

Sodium transport inhibition by selective mitochondrial inhibitors in the urinary bladder of the toad

The effects of selective mitochondrial inhibitors on the short-circuit current and oxygen consumption displayed by the isolated urinary bladder of the toad was studied. Three types of compounds were used: (a) electron transfer inhibitors, Amytal, Cyanide and Antimycin A; (b) energy transfer inhibitors Guanidine, Oligomycin and Rutamycin; and (c) uncoupling agents, Carbonyl cyanide m-chlorophenylhydrazone and 2–4 dinitrophenol. The kinetics of inhibition of oxygen consumption indicated that the inhibitors tested were effectively reaching the mitochondria of the bladder cells. Different kinetics of inhibition of short-circuit current were obtained with the various inhibitors tested. Uncouplers and electron transfer inhibitors rapidly blocked the short-circuit current; energy transfer inhibitors only produced a slow and partial inhibition. A site of energy-coupling, tentatively identified with the intermediate formed in the energy transfer reactions closest to the electron transfer chain, is proposed.     

Sodium extrusion by internally dialyzed squid axons

A method has been developed which allows a length of electrically excitable squid axon to be internally dialyzed against a continuously flowing solution of defined composition. Tests showed that diffusional exchange of small molecules in the axoplasm surrounding the dialysis tube occurred with a half-time of 2–5 min, and that protein does not cross the wall of the dialysis tube. The composition of the dialysis medium was (mM): K isethionate 151, K aspartate 151, taurine 275, MgCI₂ 4–10, NaCl 80, KCN 2, EDTA 0.1, ATP 5–10, and phosphoarginine 0–10. The following measurements were made: resting Na influx 57 pmole/cm²sec (n = 8); resting potassium efflux 59 pmole/ cm²sec (n = 4); stimulated Na efflux 3.1 pmole/cm²imp (n = 9); stimulated K efflux 2.9 pmole/cm²imp (n = 3); resting Na efflux 48 pmole/cm²sec (n = 18); Q ₁₀ Na efflux 2.2 (n = 5). Removal of ATP and phosphoarginine from the dialysis medium (n = 4) or external application of strophanthidin (n = 1) reversibly reduced Na efflux to 10–13 pmole/cm²sec. A general conclusion from the study is that dialyzed squid axons have relatively normal passive permeability properties and that a substantial fraction of the Na efflux is under metabolic control although the Na extrusion mechanism may not be working perfectly.     

Mechanism of the cerebrocortical vasodilatation during anoxia.

The possible role of cerebrocortical ion homeostasis, NAD/NADH redox state and of cortical oxygen tension was investigated in the initiation of hypoxic cortical vasodilatation. In addition, changes in cerebrocortical extracellular concentrations of Na+, K+, and Cl- during anoxia were studied. The results were as follows. a) The cerebrocortical reflectance decrease, e.g. cerebral vasodilatation, lagged behind the cortical pO2 decrease by 1-2 sec, but preceded the decrease of arterial blood pressure and ECoG as well as the extracellular Na+, K+, Cl- increases by 20-30 sec. Since the cortical pO2 decreased first and the ion changes lagged behind the onset of vasodilatation by 20-30 sec, it is suggested that the CBF increase in hypoxia is mediated via the cortical pO2 decrease. b) A significant NAD reduction was already present after 20 sec. of nitrogen breathing. Since the ECoG and MABP decreased, and K+ activity increased much later than this, it is presumed that the NAD reduction during the first 30-40 sec of anoxia indicates an increased rate of glycolysis, but not mitochondrial hypoxia. c) In the predepolarization phase a 17% K+, 4% Na+, 5% Cl- increase is probably the result of a reduction of the extracellular spaces caused by water movement and by the migration of Na+ and Cl- from the extracellular to the intracellular space. The large K+, Na+, Cl- changes during terminal depolarization can be interpreted as a result of the failure of the membrane bound Na+ -K+ pump and of the altered ion permeability of the cell membranes.     

In situ accumulation of calcium by organelles of squid axoplasm

Existing morphological and physiological evidence indicates that axoplasm of squid axons sequesters calcium by both mitochondrial and non-mitochondrial buffers. The present work demonstrates that essentially all of the non-mitochondrial component is located in organelles. Extruded axoplasm was loaded with varying amounts of calcium by mixing with small volumes of solutions containing pH buffered ⁴⁵Ca. Ethyleneglycol-bis(β-amino-ethyl ether)N,N′-tetraacetic acid (EGTA) or diethylenetriamine pentaacetic acid (DTPA) was used to stabilize the free calcium. The axoplasm was then sucked up in a polyethylene tube and centrifuged at 100,000 g for 2–3 hours to produce a loose pellet comprising 10–20% of the axoplasm volume. After centrifugation, the tube was frozen, sliced into segments, and counted by liquid scintillation. No significant pellet accumulation of exogenous calcium occurred at physiological concentrations of free calcium (ca. 50 nM); however, a threshold for accumulation existed at 150–200 nM. Essentially complete pellet sequestration of the exogenous load occurred at a free calcium concentration above 1 μM. About half of the pellet buffering capacity was sensitive to carbonyl cyanide, p-trifluoromethoxy phenylhydrazone (FCCP). Variation of exogenous load between 0.1 – 3 mmole/kg axoplasm did not affect the buffering capacity of either the FCCP sensitive or insensitive components when the free calcium concentration was above threshold.     

Mechanisms of hydrogen peroxide formation in leukocytes: the NAD(P)H oxidase activity of myeloperoxidase.

The NADPH oxidase activity of polymorphonuclear leukocyte granules has not previously been attributed to myeloperoxidase because of its relative insensitivity to cyanide and its activation by aminotriazole. However it has been found that the NAD(P)H oxidase activity of myeloperoxidase or horseradish peroxidase was little affected by 2.0 mM cyanide although the peroxidase activity was nearly completely inhibited by 0.1 mM cyanide. Furthermore, the NAD(P)H oxidase activity of myeloperoxidase was considerably enhanced by aminotriazole although the peroxidase activity was inhibited.     

SPATIAL PATTERNS OF THREADLIKE ELEMENTS IN THE AXOPLASM OF THE GIANT NERVE FIBER OF THE SQUID (LOLIGO PEALII L.) AS DISCLOSED BY DIFFERENTIAL INTERFERENCE MICROSCOPY AND BY ELECTRON MICROSCOPY

The giant nerve fiber of the squid (Loligo pealii L.) has been investigated in situ, and in fresh and fixed preparations, by differential interference microscopy and electron microscopy. A continuous, three-dimensional network, composed of threadlike elements, was disclosed in the axoplasm. The threadlike elements in the axoplasm are twisted as a whole into a steep, right-handed helix. In a peripheral ectoplasmic region, the elements are more parallel to one another and more densely packed than in a central endoplasmic core. The threadlike elements can be resolved into a hierarchy of decreasing order of size. Successive levels of the hierarchy are formed by the association of smaller elements into larger ones. The following levels in the hierarchy of network elements have been distinguished: 1–3-µ-wide threads, 0.1–0.35-µ-wide strands, and 70–250-A-wide unit-filament strands. The differential interference microscope selects, from the network, threads oriented at a specific angle to the long axis of the axon. The specific angle depends upon the orientation of the long axis of the axon relative to the direction of shear. It is postulated that the network configuration is expressed in the solid-state properties of the axoplasm essential for the normal functioning of the nerve fiber.     

The involvement of superoxide anions in the nitro blue tetrazolium chloride reduction mediated by NADH and phenazine methosulfate

Oxygen inhibits competitively the reduction of nitro blue tetrazolium chloride (nitro BT) by NADH and phenazine methosulfate (PMS). The oxygen-dependent inhibition is stronger in the presence of superoxide dismutase, whereas cyanide counteracts the oxygen interference. On the other hand, the oxidation of NADH mediated by PMS and dioxygen is affected only marginally by superoxide dismutase and cyanide. Therefore, it is concluded that the involvement of superoxide anions occurs at the level of nitro BT reduction via a nitro blue tetrazolinyl radical, as has been suggested by Picker and Fridovich [1984) Arch. Biochem. Biophys. 228, 155-158) and not at the level of PMS oxidation. The inhibition of the oxygen interference in the nitro BT reduction by cyanide is dependent on the cyanide concentration, whereas in nitrogen cyanide has no effect on the reduction. It is caused by competition between cyanide and oxygen to reduce or oxidize the nitro BT radical to either formazan with concomitant cyanogen production or nitro BT, respectively. For the histochemical localization and analysis of electropherograms of NAD(P)+-dependent dehydrogenase activities, the interference of oxygen can be avoided by anaerobic incubations or by the use of 5 mM nitro BT when incubating aerobically.     

Mitochondria and other calcium buffers of squid axon studied in situ

Continuous nondestructive monitoring of intracellular ionized calcium in isolated squid axons by differential absorption spectroscopy (using arsenazo III and antipyrylazo III) was used to study uptake of calcium by carbonyl cyanide, p-trifluoromethoxy-phenylhydrazone (FCCP)- and (or) cyanide (CN)-sensitive and insensitive constituents of axoplasm. Known calcium loads imposed on the axon by stimulation produced proportional increments of free axoplasmic calcium. Measurement of increments in ionized calcium as a function of load confirmed earlier reports of buffering in normal and FCCP- and (or) CN-poisoned axons. Measurement of rates of calcium uptake by presumed mitochondria showed little uptake at ambient Ca below 200--400 nM, with sigmoidal rise to about 20--30 mumol/kg axoplasm per min (calculated to be about 200 mmol/kg mitochondrial protein per min) at 50 micrometer, indicating a functional threshold for presumed mitochondrial uptake well above physiological ionized calcium concentration. Treatment of stimulated axons with cyanide, to release calcium from presumed mitochondria, showed that the sensitivity to cyanide decreased progressively with time after stimulation (t 1/2 = 3--10 min) implying transfer of sequestered calcium into a less metabolically labile form.     

Sulfide and cyanide induced mortality and anaerobic metabolism in the arcid blood clam Scapharca inaequiv alvis

1. The survival and metabolic adjustments of the blood clam S. inaequivalvis have been determined at environmental anoxia and tissue anoxia induced by sulfide and cyanide.2. Times to 50% mortality were established in clams placed in oxygenated seawater with and without dissolved sulfide or free cyanide or deoxygenated seawater with and without dissolved sulfide.3. Anaerobic metabolism was studied in live animals and in red blood cells incubated in vitro. Tissue anoxia due to sulfide and cyanide caused greater changes in the levels of aspartate and the pyruvate derivatives, compared to environmental anoxia.     

Differences in the altered energy metabolism of hemorrhagic shock and hypoxemia.

The effect of hemorrhagic shock, hypoxemia, and anoxia on the levels of adenine and pyridine nucleotides of liver and kidney was assessed. ATP levels in liver and kidney of animals in shock or animals subjected to 7 min of anoxia decreased by 85 and 73%, respectively. Under hypoxic conditions (arterial PO2 AT 18 MMHg), the decrease was only 62 and 48% in liver and kidney, respectively. Tissue NAD levels decreased and NADH levels increased during shock but were found to be essentially unaltered during experimental hypoxemia. Thus, shock produced greater alterations in adenine and pyridine nucleotides than did hypoxemia alone, indicating that stagnant hypoxemia due to shock is more deleterious to energy metabolism than is severe hypoxemia with an otherwise normal circulation. The results also suggest that if an anterial PO2 OF 18 MMHg represents the initial stages of tissue hypoxia, then tissue ATP levels are a more sensitive indicator of this than NAD levels.