Preparation and some properties of submitochondrial particles from tightly coupled mung bean mitochondria

Osmotic shock was found to be better than freezing and thawing, a French press, or sonic oscillation for the preparation of submitochondrial particles from mung bean (Phaseolus aureus) hypocotyl mitochondria. Particles prepared by osmotic shock rapidly oxidize reduced nicotinamide adenine dinucleotide and succinate, but they oxidize malate slowly. NADH oxidation was slightly stimulated by cytochrome c, ATP, and ADP; succinate oxidation was markedly increased by ATP, slightly by ADP and cytochrome c; and malate oxidation required the addition of NAD⁺ NADH oxidation is inhibited weakly by amytal, completely by antimycin A and KCN, but not by rotenone. Chlorsuccinate, malonate, antimycin A, and KCN inhibit succinate oxidation. The action of antimycin A and KCN is incomplete, while chlorsuccinate and malonate were competitive inhibitors. Antimycin A combined stoichiometrically with particle protein in the ratio of 0.23 millimicromole per milligram of protein.     

The Effect of Respiratory Inhibitors on NADH, Succinate and Malate Oxidation in Corn Mitochondria

The effect of a series of respiratory inhibitors on the oxidation of NADH in state 4 and state 3 conditions was studied with corn shoot mitochondria. Comparisons were made using malate and succinate as substrates. The inhibitors, rotenone, amytal, antimycin A and cyanide, inhibited oxidation of NADH in state 3 but rotenone and amytal did not inhibit oxidation in state 4. The inhibition by antimycin A was partially overcome by the presence of cytochrome c. The results indicate the presence of alternative pathways available for NADH oxidation depending on the metabolic condition of the mitochondria. Under state 4 conditions, NADH oxidation bypasses the amytal and rotenone sensitive sites but under state 3 conditions a component of the NADH respiration appears to be oxidized by an internal pathway which is sensitive to these inhibitors. Still a third pathway for NADH oxidation is dependent on the addition of cytochrome c and is insensitive to antimycin A. Succinate oxidation was sensitive to cyanide and antimycin A under both state 4 and state 3 conditions as well as amytal and rotenone under state 3 conditions but was not inhibited by amytal and rotenone under state 4 conditions. Malate oxidation was inhibited by cyanide, rotenone and amytal under both state 4 and state 3 conditions. Antimycin A inhibited state 3 but did not appreciably alter state 4 rates of malate oxidation. With all substrates tested inhibition by antimycin A was greatly facilitated by preswelling the mitochondria for 10 min. This was interpreted to indicate that swelling increases the accessibility of antimycin A to the site of inhibition.     

The oxidation of malate and exogenous reduced nicotinamide adenine dinucleotide by isolated plant mitochondria

Exogenous NADH oxidation by cauliflower (Brassica oleracea L.) bud mitochondria was sensitive to antimycin A and gave ADP/O ratios of 1.4 to 1.9. In intact mitochondria, NADH-cytochrome c reductase activity was only slightly inhibited by antimycin A. The antimycin-insensitive activity was associated with the outer membrane. Malate oxidation was sensitive to both rotenone and antimycin A and gave ADP/O values of 2.4 to 2.9. However in the presence of added NAD⁺, malate oxidation displayed similar properties to exogenous NADH oxidation. In both the presence and absence of added NAD⁺, malate oxidation was dependent on inorganic phosphate and inhibited by 2-n-butyl malonate.     

Inhibition of anion transport across the mitochondrial membrane by amytal

It has been found that amytal competitively inhibits succinate (+ rotenone) oxidation by intact uncoupled mitochondria. Similar results were obtained in metabolic state 3, the K_i value being 0.45 mM. Amytal did not effect succinate oxidation by broken mitochondria and submitochondrial particles (at a concentration which inhibited succinate oxidation by intact mitochondria). Amytal inhibited the swelling of mitochondria suspended in ammonium succinate or ammonium malate but was without effect on the swelling of mitochondria in ammonium phosphate and potassium phosphate in the presence of valinomycin+carbonylcyanide p-trifluoromethoxyphenylhydrazone.Using [¹⁴C] succinate and [¹⁴C] citrate it has been shown that amytal inhibited the succinate/succinate, succinate/P_i, succinate/malate, and citrate/citrate and citrate/malate exchanges. Amytal inhibited P_i transport across mitochondrial membrane only if preincubated with mitochondria. Other barbiturates: phenobarbital, dial, veronal were found to inhibit [¹⁴C]succinate/anion (P_i, succinate, malonate, malate) exchange reactions in a manner similar to amytal. It is concluded that barbiturates non-specifically inhibit the dicarboxylate carrier system, tricarboxylate carrier and P_i translocator. It is postulated that the inhibition of succinate oxidation by barbiturates is caused mainly by the inhibition of succinate and P_i translocation across the mitochondrial membrane.     

Glyceollin: a site-specific inhibitor of electron transport in isolated soybean mitochondria

The glyceollin inhibition of electron transport by isolated soybean and corn mitochondria was similar to that of rotenone, acting at site I between the internal NADH dehydrogenase and coenzyme Q. Coupled state 3 malate oxidation was inhibited by glyceollin and rotenone with apparent K_i values of about 15 and 5 micromolar, respectively. Carbonylcyanide m-chlorophenyl hydrazone uncoupled state 4 malate oxidation was also inhibited by glyceollin and rotenone, but uncoupled succinate and exogenous NADH state 4 oxidation was only slightly inhibited by both compounds. Glyceollin also inhibited ferricyanide reduction with malate as the electron donor, with an apparent K_i of 5.4 micromolar, but failed to inhibit such reduction with succinate or externally added NADH as electron donors. Glyceollin did not inhibit state 4 oxidation of malate, succinate, or exogenous NADH. Glyceollin did not act as a classical uncoupler or as an inhibitor of oxidative phosphorylation.     

Adenylate control of respiration in plants: the contribution of rotenone-insensitive electron transport to ADP-limited oxygen consumption by soybean mitochondria

The aim was to test the hypothesis that rotenone-insensive electron transport (bypass of complex I) may underlie rapid state 4 (ADP-limited) mitochondrial respiration. A comparison of mitochondria from soybean ( Glycine max L. cv. Bragg) cotyledons and nodules showed that ADP-sufficient (state 3) malate plus pyruvate oxidation by mitochondria from 7-day-old cotyledons was inhibited 50% by rotenone and state 4 rates were rapid, whereas nodule mitochondria were 80% inhibited by rotenone and had slower state 4 rates of malate plus pyruvate oxidation. Respiration of malate alone (pH 7.6) by cotyledon mitochondria was slow, especially in the absence of ADP; subsequent addition of pyruvate dramatically increased state 4 oxygen uptake concomitant with a rapid rise in mitochondrial NADH (determined by fluorimetry). Rotenone had no effect on this increased rate of state 4 respiration. The rate of malate oxidation by nodule mitochondria was relatively rapid compared with cotyledon mitochondria. The addition of pyruvate in state 4 caused a slow increase in matrix NADH and only a slight stimulation of oxygen uptake. Rotenone inhibited state 4 malate plus pyruvate oxidation by 50% in these mitochondria. From a large number of cotyledon and nodule mitochondrial preparations, a close correlation was found between the rate of state 4 oxygen uptake and rotenone-resistance. During cotyledon development increased rotenone-resistance was associated with an increase in the alternative oxidase. Addition of pyruvate to cotyledon mitochondria, during state 4 oxidation of malate in the presence of antimycin A, significantly stimulated O₂ uptake and also almost eliminated respiratory control. Such combined operation of the rotenone-insensitive bypass and the alternative oxidase in vivo will significantly affect the extent to which adenylates control the rate of electron transport.     

Stimulation by quinones of cyanide-resistant respiration in rat liver and heart mitochondria

It was shown that hydrophilic benzo- and naphthoquinones stimulate the cyanide-resistant respiration in liver and muscle mitochondria when succinate or NADH and glutamate or malate are used as oxidation substrates. The substrate-dependent oxygen uptake in the presence of cyanide is initiated by menadione, vicasol, 1.2-naphthoquinone, coenzyme Q0 and duroquinone. Rotenone and antimycin A do not inhibit the cyanide-resistant respiration. Oxidation of glutamate and malate in the course of CN-resistant respiration is inhibited by ortho- and bathophenanthroline and p-chloromercurybenzoate, whereas succinate oxidation by tenoyltrifluoroacetone, carboxin and pentachlorophenol. Superoxide dismutase, Cu2+ and catalase inhibit the CN-resistant respiration in the presence of quinones. Addition of catalase to the experimental cell causes O2 release.     

The relationship between energy generation and cholesterol side-chain cleavage reaction in the mitochondria from human term placenta

1. The interrelationship between progesterone (from cholesterol) biosynthesis and oxidative phosphorylation in human placental mitochondria was examined. 2. ADP and ATP stimulated the malate, succinate and alpha-ketoglutarate-supported progesterone biosynthesis probably via the energy-dependent pyridine nucleotide transhydrogenase activation. The effect of ADP was abolished by rotenone and antimycin in the presence of malate or alpha-ketoglutarate. 3. In the non-energized state of mitochondria malate may supported progesterone biosynthesis by the malic enzyme-dependent pathway. 4. The inhibitory effects of antimycin or cyanide, and the stimulatory effect of rotenone on the succinate-supported progesterone biosynthesis indicate that the succinate to malate conversion is a necessary condition for the stimulation of progesterone biosynthesis from cholesterol. 5. alpha-Ketoglutarate plus malonate did support progesterone biosynthesis also in the presence of ADP or ATP and to a lesser degree in the presence of DNP and rotenone. Arsenate in the presence of alpha-ketoglutarate, malonate, dinitrophenol and rotenone did not affect significantly progesterone biosynthesis. These results indicate that NADPH may be generated also by a non-energy-dependent transhydrogenation in placental mitochondria.     

A Comparison of Purified Host Specific Toxin from Helminthosporium maydis, Race T, and Its Acetate Derivative on Oxidation by Mitochondria from Susceptible and Resistant Plants

NADH or succinate oxidation and malate oxidation were differentially affected in mitochondria from both susceptible and resistant corn by a purified and chemically characterized preparation of host-specific toxin from Bipolaris (Helminthosporium) maydis, race T. NADH and succinate oxidation by susceptible T corn mitochondria were stimulated 50 to 200% with apparent uncoupling from the cytochrome chain at approximately 10(-9)m toxin (5 to 20 ng/ml). Significant inhibition of malate oxidation was observed at slightly higher toxin concentrations, but oxidation was still coupled to ADP utilization. Inhibition of malate oxidation also was observed in N corn (resistant) and soybean mitochondria at approximately 1,000-fold greater concentrations, but stimulation of NADH and succinate oxidation was not found at any toxin concentration tested.A fully acetylated toxin derivative at approximately 1 microgram per milliliter also caused stimulation of NADH or succinate oxidation in T corn mitochondria, but not those of N corn or soybean mitochondria at 100 micrograms per milliliter. Malate oxidation was inhibited to the same extent by toxin acetate with mitochondria from T corn, N corn, and soybean. The blocking of hydroxyl groups in race T toxin by acetyl functions eliminated selectivity toward malate oxidation only. The data suggest that inhibition of malate oxidation is either a separate or secondary effect of selective action of toxin on T corn mitochondria, perhaps by interference with transport in or out of the matrix. Sensitivity of T, but not N, corn mitochondria to purified toxin decays within minutes after pellets are suspended in aqueous osmotica, with no obvious change in mitochondrial integrity. The action of race T toxin seems to involve a labile process, such as ion gradient(s), or an unstable structural conformation of T corn mitochondria.     

Metabolic fate of fatty acids in the carnitine cycle of brown adipose tissue mitochondria.

Freshly isolated mitochondria from brown adipose tissue are uncoupled with respect to oxidative phosphorylation. When these mitochondria oxidize[U-minus 14-C] palmitic acid in the presence of malate the label is found in three major fractions. Polar lipids, rich in acyl carnitines, remain in the mitochondrial pellet. A large fraction, rich in tricarboxylic acid cycle intermediates, is exported to the suspending medium, as is a third, smaller fraction containing ketone bodies and beta-hydroxy-beta-methylglutaric acid. Prevention of oxygen uptake by addition of rotenone or antimycin prevents accumulation of cycle intermediates, increases formation of acyl carnitiness and increases beta-hydroxybutyrate relative to acetoacetate. Rotenone and antimycin do not prevent formation of labeled phosphatidylcholine. Partial suppression of oxygen uptake by benzene-1,2,3-tricarboxylic acid, amytal or malonate leads to results between these extremes. Addition of lysophosphatidylcholine had minimal effects on export of cycle intermediates, but increased formation of ketone bodies and particularly of acyl carnitines. The significance of lysophosphatidylcholine as an endogenous modifier of mitochondrial metabolism is discussed.     

L-lactate oxidation by skeletal muscle mitochondria

1. Mitochondria isolated from rat skeletal muscle possess lactate dehydrogenase which is involved in direct oxidation of L-lactate in the presence of external NAD. 2. L-lactate oxidation can be stimulated in a reversible manner by ADP. 3. Mitochondrial lactate oxidation is sensitive to oxamate-inhibitor of LDH, alpha-cyano-3-hydroxy-cinnamate-pyruvate translocase inhibitor and respiratory chain inhibitors (rotenone, antimycin A, KCN). 4. In the same conditions the mitochondria did not oxidize pyruvate in the absence of malate, whereas, oxidize pyruvate plus external NADH in an uncoupling manner.     

The effect of rotenone on respiration in pea cotyledon mitochondria

Respiration utilizing NAD-linked substrates in mitochondria isolated from cotyledons of etiolated peas (Pisum sativum L. var. Homesteader) by sucrose density gradient centrifugation exhibited resistance to rotenone. The inhibited rate of α-ketoglutarate oxidation was equivalent to the recovered rate of malate oxidation. (The recovered rate is the rate following the transient inhibition by rotenone.) The inhibitory effect of rotenone on malate oxidation increased with increasing respiratory control ratios as the mitochondria developed. The cyanide-resistant and rotenone-resistant pathways followed different courses of development as cotyledons aged. The rotenone-resistant pathway transferred reducing equivalents to the cyanide-sensitive pathway. Malic enzyme was found to be inhibited competitively with respect to NAD by rotenone concentrations as low as 1.67 micromolar. In pea cotyledon mitochondria, rotenone was transformed into elliptone. This reduced its inhibitory effect on intact mitochondria. Malate dehydrogenase was not affected by rotenone or elliptone. However, elliptone inhibited malic enzyme to the same extent that rotenone did when NAD was the cofactor. The products of malate oxidation reflected the interaction between malic enzyme and malate dehydrogenase. Rotenone also inhibited the NADH dehydrogenase associated with malate dehydrogenase. Thus, rotenone seemed to exert its inhibitory effect on two enzymes of the electron transport chain of pea cotyledon mitochondria.     

Effects of selected inhibitors on electron transport in Neisseria gonorrhoeae.

The electron transport system of Neisseria gonorrhoeae was partially characterized by using spectrophotometric, spectroscopic, and oxygen consumption measurements. The effects of selected electron transport inhibitors (amytal, rotenone, 2-heptyl-4-hydroxyquinoline, antimycin A1, and potassium cyanide [KCN]) on electron transfer in whole-cell and sonically treated whole-cell preparations of N. gonorrhoeae were examined. The oxidation of reduced nicotinamide adenine dinucleotide, measured as a decrease in absorbance at 340 nm, was inhibited by each of the compounds tested. Oxygen consumption stimulated by reduced nicotinamide adenine dinucleotide was also inhibited, whereas oxygen uptake stimulated by succinate and malate was inhibited by KCN alone, suggesting the presence of a KCN-sensitive terminal oxidase. Room temperature optical difference spectra indicate an operational electron bypass around the amytal-rotenone-binding site. Difference spectra in the presence of 2-heptyl-4-hydroxyquinoline suggest a possible site of interaction of this compound at the substrate side of cytochrome b. Reduced-minus-oxidized spectra of ascorbate-tetramethyl-p-phenylenediamine suggest the participation of b-, a-, and d-type cytochromes in terminal oxidase activity. Hence, N. gonorrhoeae appears to have an electron transport chain containing cytochrome c, two b-type cytochromes (one of which has an oxidase function), and possibly a- and d-type cytochromes. An abbreviated chain exists through which succinate and malate can be oxidized directly by a KCN-sensitive component.     

Studies of the mitochondria from Eimeria tenella and inhibition of the electron transport by quinolone coccidiostats.

Intact but fragile mitochondria were isolated from unsporulated oocysts of Eimeria tenella. The mitochondria respired in response to succinate, malate plus pyruvate, and L-ascorbate at rates of 1.00, 0.40, and 0.25 mu1 O2/min/mg protein, respectively. Spectrophotometric analyses of the cytochromes in mitochondria and whole oocysts revealed b-type and o-type cytochromes, at roughly similar levels, but no cytochrome c could be detected. The mitochondrial respiration was inhibited by cyanide, azide, carbon monoxide, antimycin A, and 2-heptyl-4-hydroxyquinoline-N-oxide, but was relatively resistant to rotenone and amytal. The quinolone coccidiostats buquinolate, amquinate, methyl benzoquate, and decoquinate were identified as very powerful inhibitiors of succinate and malate plus pyruvate supported respiration in E. tenella mitochondria. None of these four drugs exhibited any inhibitory effect on chicken liver mitochondria. Only 3 pmol of the quinolones per mg mitochondrial protein was needed to achieve 50% inhibition. The inhibition could not be reversed by coenzymes Q6 or Q10. Since the quinolones did not affect L-ascorbate-supported respiration or the activities of submitochondrial succinate dehydrogenase and NADH dehydrogenase, the site of action of the quinolone coccidiostats was tentatively identified as probably near cytochrome b in E. tenella mitochondria. Mitochondria isolated from an E. tenella amquinate-resistant mutant were much less susceptible to quinolone coccidiostats; 50% inhibition was attained by 300 pmol of the drugs/mg mitochondrial protein. The results suggest that the mechanisms of action of quinolone coccidiostats is by inhibiting the cytochrome-mediated electron transport in the mitochondria of coccidia. 2-Hydroxynaphthoquinone coccidiostats were identified as inhibitors of mitochondrial respiration of both E. tenella and chicken liver. They inhibited submitochondrial succinate dehydrogenase and NADH dehydrogenase of E. tenella, and remained equally active against the mitochondrial function of E. tenella amquinolate-resistant mutant.     

External alternative NADH dehydrogenase of Saccharomyces cerevisiae: a potential source of superoxide

Three rotenone-insensitive NADH dehydrogenases are present in the mitochondria of yeast Saccharomyces cerevisiae, which lack complex I. To elucidate the functions of these enzymes, superoxide production was determined in yeast mitochondria. The low levels of hydrogen peroxide (0.10 to 0.18 nmol/min/mg) produced in mitochondria incubated with succinate, malate, or NADH were stimulated 9-fold by antimycin A. Myxothiazol and stigmatellin blocked completely hydrogen peroxide formation with succinate or malate, indicating that the cytochrome bc(1) complex is the source of superoxide; however, these inhibitors only inhibited 46% hydrogen peroxide formation with NADH as substrate. Diphenyliodonium inhibited hydrogen peroxide formation (with NADH as substrate) by 64%. Superoxide formation, determined by EPR and acetylated cytochrome c reduction in mitochondria was stimulated by antimycin A, and partially inhibited by myxothiazol and stigmatellin. Proteinase K digestion of mitoplasts reduced 95% NADH dehydrogenase activity with a similar inhibition of superoxide production. Mild detergent treatment of the proteinase-treated mitoplasts resulted in an increase in NADH dehydrogenase activity due to the oxidation of exogenous NADH by the internal NADH dehydrogenase; however, little increase in superoxide production was observed. These results suggest that the external NADH dehydrogenase is a potential source of superoxide in S. cerevisiae mitochondria.     

A malate-oxaloacetate shuttle linking cytosolic fatty acid α-oxidation to the mitochondrial electron transport chain in uncoupled fresh potato slices

The possible existence of a malonate-sensitive dicarboxylate-mediated electron shuttle between microsomal NAD-linked fatty acid α-oxidation and the mitochondrial electron transport chain in uncoupled fresh potato slices was investigated. Uncoupled slice respiration is inhibited by benzylmalonate and butylmalonate, inhibitors of dicarboxylate transport into mitochondria. Uncoupled slice respiration is also inhibited by rotenone, an indication of intramitochondrial NADH oxidation. Since fatty acid α-oxidation per se is rotenone insensitive, rotenone and benzylmalonate inhibition of the oxidation of carboxyl-labeled myristate in slices points to a dicarboxylic acid shuttle linking microsomal fatty acid a-oxidation with intramitochondrial NADH dehydrogenase.
Malonute inhibits both respiration and ¹⁴CO², release from carboxyl-labeled myristate in fresh uncoupled slices, as do inhibitors of dicarboxylate transport. Mitochondrial studies show that malonate inhibits malate oxidation but not malate dehydrogenase per se. Furthermore, malonate inhibits malate transport more severely than malate oxidation. Accordingly, mulonate inhibition of uncoupled slice respiration in the absence of tricarboxylic acid cycle activity is attributed to its interference with mitochondrial malate transport, and its consequent curtailment of a putative malate-OAA shuttle linked to cytosolic NAD-mediated fatty acid α-oxidation.     

Localization at Complex I and Mechanism of the Higher Free Radical Production of Brain Nonsynaptic Mitochondria in the Short-Lived Rat Than in the Longevous Pigeon

Free radical production and leak of brain nonsynaptic mitochondria were higher with pyruvate/malate than with succinate in rats and pigeons. Rotenone, antimycin A, and myxothiazol maximally stimulated free radical production with pyruvate/malate but not with succinate. Simultaneous treatment with myxothiazol plus antimycin A did not decrease the stimulated rate of free radical production brought about independently by any of these two inhibitors with pyruvate/malate. Thenoyltrifluoroacetone did not increase free radical production with succinate. No free radical production was detected at Complex IV. Free radical production and leak with pyruvate/malate were higher in the rat (maximum longevity 4 years) than in the pigeon (maximum longevity 35 years). These differences between species disappeared in the presence of rotenone. The results localize the main free radical production site of nonsynaptic brain mitochondria at Complex I. They also suggest that the low free radical production of pigeon brain mitochondria is due to a low degree of reduction of Complex I in the steady state in this highly longevous species.     

Cytokinin modification of mitochondrial function

6-Benzylaminopurine, 6-(Δ²-isopentenylamino)purine, 6-furfurylaminopurine, rotenone, and antimycin A inhibited oxidation of NADH by mitochondrial sonicates or submitochondrial particles (but not by intact mitochondria) from pea (Pisum sativum L., cult. Alaska) stems and mung bean (Vigna radiata L. Wilczak) hypocotyls. The above purine cytokinins can interfere with electron transport from NADH to the cytochrome system in the inner mitochondrial membrane. Adenine did not inhibit oxidation by sonicated mitochondria, and zeatin was almost ineffective. Zeatin scarcely inhibited state 3 malate respiration by intact mitochondria, but the O-formyl and O-n-propionyl esters of zeatin and the O-acetyl ester of 2-chlorozeatin were more active. Perhaps zeatin is ineffective because it does not get into the inner membranes of the isolated mitochondria, whereas the esters and other cytokinins mentioned above do. N-4-(2-chloropyridyl)-N′-Phenylurea, which has cytokinin-like effects on plant growth and development, inhibited NADH oxidation by sonicated mitochondria. It also inhibited malate, succinate, and NADH oxidation by intact mitochondria; in contrast, the latter two oxidations were not decreased by purine cytokinins.     

Cyanide-resistant Respiration of Sweet Potato Mitochondria

The oxidation of malate and succinate by sweet potato mitochondria (Ipomoea batatas [L.] Lam.) was blocked only partly by inhibitors of complexes III (2-heptyl-4-hydroxyquinoline-N-oxide) and IV (cyanide and azide). The respiration insensitive to inhibitors of complexes III and IV was inhibited by salicylhydroxamic acid. Essentially complete inhibition was obtained with inhibitors of complex I (rotenone, amytal, and thenoyltrifluoroacetone) and complex II (thenoyltrifluoroacetone). The observations indicated that electrons were transferred to the cyanide-resistant pathway from ubiquinone or from nonheme iron (iron-sulfur) proteins of complexes I and II before reaching the b cytochromes. In contrast, the oxidation of exogenous NADH did not involve the alternate pathway, as indicated by complete inhibition by inhibitors of complexes III and IV and the absence of an effect of inhibitors of complexes I and II. Hence, electrons from exogenous NADH appear to pass directly to complex III in sweet potato mitochondria.     

Studies of the Growth in Culture of Plant Cells

Mitochondria have been isolated from sycamore cells (Acer pseudoplatanusL.) grown in suspension culture, and resemble those of otherplant tissues. Malate, succinate, and NADH are oxidized withrespiratory control. The respiration is partially inhibitedby antimycin A and KCN, but not by amytal and rotenone. Octylguanidine,oligomycin, and uncouplers all affect the coupled respiration. The proportion of the respiration resistant to KCN was foundto change during the life of the culture, being greatest duringthe lag phase and least during the linear phase. The relationshipof these changes in the electron transport pathways to the changingdemand of the culture for phosphorylated and other intermediatesis discussed.