Creatine kinase and mechanical and mitochondrial functions in hereditary and diabetic cardiomyopathies

To determine whether the development of cardiomyopathies is associated with alterations in creatine kinase function, the functional properties of cardiac contractile apparatus and mitochondria were studied in two different models of cardiomyopathies, the Syrian hamster (hereditary dilated cardiomyopathy, strain UM-X7.1, 200 days old) and the diabetic rat (4-6 weeks after injection of streptozotocin) using ventricular skinned fibers. After Triton X-100 treatment, the hereditary cardiomyopathic fibers demonstrated decreased maximal calcium-activated tension and unchanged calcium sensitivity, whereas fibers from diabetic hearts exhibited unchanged maximal tension and increased calcium sensitivity, when compared with their respective controls. In both cases myofibrillar creatine kinase appeared unchanged. The functional properties of total tissue mitochondria were evaluated using saponin-skinned fibers. Coupling between oxidation and phosphorylation was not altered in cardiomyopathies. Respiration rate (per unit of tissue dry weight) was normal in hereditary cardiomyopathy but was considerably lower in diabetic fibers compared with control fibers. In both models of cardiomyopathies, creatine-stimulated respiration was significantly lower than in controls, thus indicating the depression of functional activity of mitochondrial creatine kinase.     

Structural and functional changes in heart mitochondria from sucrose-fed hypertriglyceridemic rats

In the heart of sugar-induced hypertriglyceridemic (HTG) rats, cardiac performance is impaired with glucose as fuel, but not with fatty acids. Accordingly, the glycolytic flux and the transfer of energy diminish in the HTG heart, in comparison to control heart. To further explore the biochemical nature of such alteration in the HTG heart, the components of the non-glycolytic energy systems involved were evaluated. Total creatine kinase (CK) activity in the myocardial tissue was depressed by 30% in the HTG heart whereas the activity of the mitochondrial CK (mitCK) isoenzyme fraction that is functionally associated with oxidative phosphorylation decreased in isolated HTG heart mitochondria by 45%. Adenylate kinase (AK) was 20% lower in the HTG heart. In contrast, respiratory rates with 2-oxoglutarate (2-OG) and pyruvate/malate (pyr) were significantly higher in HTG heart mitochondria than in control mitochondria. 2-OG dehydrogenase activity was also higher in HTG mitochondria. Respiration with succinate was similar in both groups. Content of cytochromes b, c + c1 and a + a3, and cytochrome c oxidase activity, were also similar in the two kinds of mitochondria. A larger content of saturated and monounsaturated fatty acids was found in the HTG mitochondrial membranes with no changes in phospholipids composition or cholesterol content. Mitochondrial membranes from HTG hearts were more rigid, which correlated with the generation of higher membrane potentials. As the mitochondrial function was preserved or even enhanced in the HTG heart, these results indicated that deficiency in energy transfer was associated with impairment in mitCK and AK. This situation brought about uncoupling between the site of ATP production and the site of ATP consumption (contractile machinery), in spite of compensatory increase in mitochondrial oxidative capacity and membrane potential generation.     

Postnatal development of energy metabolism in the rat brain

The activities of cytochrome c oxidase and F0F1-ATPase as well as the content of cytochromes cc1, aa3, and b were investigated in free brain mitochondria in the course of postnatal development and aging. The results show an increase of Vmax of both enzymes during postnatal development (between day 5 and 30). During the following phase ending at the age of 6 months, a decrease of F0F1-ATPase and cytochrome c oxidase activity occurs. From 6 to 12 months of age the activity of these enzymes did not change. The KM for both enzymes remained unchanged during the whole period observed. The content of cytochromes increased from the low values found in young rats, reached the highest values at around one month, and decreased till the age of 3 months. Later, their content in brain mitochondria did not markedly change. Our results suggest that the metabolic maturation of brain mitochondria differs in several aspects from the same process in other tissues, mainly in the time course. This is probably due to the unique role of neural tissue in the organism.     

Influence of mitochondrial creatine kinase on the mitochondrial/extramitochondrial distribution of high energy phosphates in muscle tissue: evidence for a leak in the creatine shuttle

The influence of mitochondrial creatine kinase on subcellular high energy systems has been investigated using isolated rat heart mitochondria, mitoplasts and intact heart and skeletal muscle tissue.In isolated mitochondria, the creatine kinase is functionally coupled to oxidative phosphorylation at active respiratory chain, so that it catalyses the formation of creatine phosphate against its thermodynamic equilibrium. Therefore the mass action ratio is shifted from the equilibrium ratio to lower values. At inhibited respiration, it is close to the equilibrium value, irrespective of the mechanism of the inhibition. The same results were obtained for mitoplasts under conditions where the mitochondrial creatine kinase is still associated with the inner membrane.In intact tissue increasing amounts of creatine phosphate are found in the mitochondrial compartment when respiration and/or muscle work are increased. It is suggested that at high rates of oxidative phosphorylation creatine phosphate is accumulated in the intermembrane space due to the high activity of mitochondrial creatine kinase and the restricted permeability of reactants into the extramitochondrial space. A certain amount of this creatine phosphate leaks into the mitochondrial matrix.This leak is confirmed in isolated rat heart mitochondria where creatine phosphate is taken up when it is generated by the mitochondrial creatine kinase reaction. At inhibited creatine kinase, external creatine phosphate is not taken up. Likewise, mitoplasts only take up creatine phosphate when creatine kinase is still associated with the inner membrane. Both findings indicate that uptake is dependent on the functional active creatine kinase coupled to oxidative phosphorylation.Creatine phosphate uptake into mitochondria is inhibited with carboxyatractyloside. This suggests a possible role of the mitochondrial adenine nucleotide translocase in creatine phosphate uptake.Taken together, our findings are in agreement with the proposal that creatine kinase operates in the intermembrane space as a functional unit with the adenine nucleotide translocase in the inner membrane for optimal transfer of energy from the electron transport chain to extramitochondrial ATP-consuming reactions.     

Structural and functional changes in heart mitochondria from sucrose-fed hypertriglyceridemic rats

In the heart of sugar-induced hypertriglyceridemic (HTG) rats, cardiac performance is impaired with glucose as fuel, but not with fatty acids. Accordingly, the glycolytic flux and the transfer of energy diminish in the HTG heart, in comparison to control heart. To further explore the biochemical nature of such alteration in the HTG heart, the components of the non-glycolytic energy systems involved were evaluated. Total creatine kinase (CK) activity in the myocardial tissue was depressed by 30% in the HTG heart whereas the activity of the mitochondrial CK (mitCK) isoenzyme fraction that is functionally associated with oxidative phosphorylation decreased in isolated HTG heart mitochondria by 45%. Adenylate kinase (AK) was 20% lower in the HTG heart. In contrast, respiratory rates with 2-oxoglutarate (2-OG) and pyruvate/malate (pyr) were significantly higher in HTG heart mitochondria than in control mitochondria. 2-OG dehydrogenase activity was also higher in HTG mitochondria. Respiration with succinate was similar in both groups. Content of cytochromes b, c + c₁ and a + a₃, and cytochrome c oxidase activity, were also similar in the two kinds of mitochondria. A larger content of saturated and monounsaturated fatty acids was found in the HTG mitochondrial membranes with no changes in phospholipids composition or cholesterol content. Mitochondrial membranes from HTG hearts were more rigid, which correlated with the generation of higher membrane potentials. As the mitochondrial function was preserved or even enhanced in the HTG heart, these results indicated that deficiency in energy transfer was associated with impairment in mitCK and AK. This situation brought about uncoupling between the site of ATP production and the site of ATP consumption (contractile machinery), in spite of compensatory increase in mitochondrial oxidative capacity and membrane potential generation.     

The "SUN" family: UTH1, an ageing gene, is also involved in the regulation of mitochondria biogenesis in Saccharomyces cerevisiae

Since it was shown in previous work that NCA3 (one of the four genes of the SUN family) is involved in mitochondrial protein synthesis regulation, the effect of the other members of this gene family was tested. UTH1 (but not SUN4 or SIM1) was also shown to interfere with mitochondria biogenesis. In Deltauth1 cells, cytochromes aa(3), c, and b were lowered by 25 and 15%, respectively. In the double-null mutant Deltauth1Deltanca3, only cytochrome aa(3) was lowered by 50% relative to the wild type. However, the ratio of cellular respiration to cytochrome oxidase was greatly enhanced in the double-null mutant. Measurements on whole lysed cells showed that another mitochondrial enzyme, citrate synthase, was also lowered in Deltauth1 and Deltauth1Deltanca3 whereas hexokinase was not. Electron micrographs showed no difference in global mitochondria content in Deltauth1Deltanca3, but mitochondria appeared less dense to electrons compared to the wild type. Cardiolipin and mtDNA were equivalent in parental and mutant strains. Measurements on isolated mitochondria showed that the cyt aa(3)/cyt b ratio was also lowered in Deltauth1Deltanca3, but the control exerted by the oxidase on the respiratory flux was higher. The activity of other mitochondrial complexes versus oxidase was equivalent in mutants compared to the wild type. These results suggest that the protein equipment could be lowered in mitochondria from strains inactivated for UTH1.     

Inhibition of the mitochondrial permeability transition by creatine kinase substrates. Requirement for microcompartmentation

Mitochondria from transgenic mice, expressing enzymatically active mitochondrial creatine kinase in liver, were analyzed for opening of the permeability transition pore in the absence and presence of creatine kinase substrates but with no external adenine nucleotides added. In mitochondria from these transgenic mice, cyclosporin A-inhibited pore opening was delayed by creatine or cyclocreatine but not by beta-guanidinopropionic acid. This observation correlated with the ability of these substrates to stimulate state 3 respiration in the presence of extramitochondrial ATP. The dependence of transition pore opening on calcium and magnesium concentration was studied in the presence and absence of creatine. If mitochondrial creatine kinase activity decreased (i.e. by omitting magnesium from the medium), protection of permeability transition pore opening by creatine or cyclocreatine was no longer seen. Likewise, when creatine kinase was added externally to liver mitochondria from wild-type mice that do not express mitochondrial creatine kinase in liver, no protective effect on pore opening by creatine and its analog was observed. All these findings indicate that mitochondrial creatine kinase activity located within the intermembrane and intercristae space, in conjunction with its tight functional coupling to oxidative phosphorylation, via the adenine nucleotide translocase, can modulate mitochondrial permeability transition in the presence of creatine. These results are of relevance for the design of creatine analogs for cell protection as potential adjuvant therapeutic tools against neurodegenerative diseases.     

Myocardial cytochrome oxidase activity is decreased following carbon monoxide exposure

Carbon monoxide (CO) inhalation often leads to cardiac dysfunction, dysrhythmias, ischemia, infarction, and death. However, the underlying mechanism of CO toxicity is poorly understood. We hypothesize that inhaled CO interrupts myocardial oxidative phosphorylation by decreasing the activity of myocardial cytochrome oxidase (CcOX), the terminal oxidase of the electron transport chain. Male C57Bl6 mice were exposed to either 1000 ppm (0.1%) CO or air for 3 h. Cardiac ventricles were harvested and mitochondria were isolated. CcOX kinetics and heme aa(3) content were measured. V(max), K(m), and turnover number were determined. Levels of CcOX subunit I message and protein were evaluated. Carboxyhemoglobin (COHb) levels were measured and tissue hypoxia was assessed with immunohistochemistry for pimonidazole hydrochloride. CO significantly decreased myocardial CcOX activity and V(max) without altering K(m). Heme aa(3) content and CcOX I protein levels significantly decreased following CO exposure while enzyme turnover number and CcOX I mRNA levels remained unchanged. CO exposure increased COHb levels without evidence of tissue hypoxia as compared to sham and hypoxic controls. Decreased CcOX activity following CO inhalation was likely due to decreased heme aa(3) and CcOX subunit I content. Importantly, myocardial CcOX impairment could underlie CO induced cardiac dysfunction.     

Diaphragm and cardiac mitochondrial creatine kinases are impaired in sepsis.

Previous studies indicate that ATP formation by the electron transport chain is impaired in sepsis. However, it is not known whether sepsis affects the mitochondrial ATP transport system. We hypothesized that sepsis inactivates the mitochondrial creatine kinase (MtCK)-high energy phosphate transport system. To examine this issue, we assessed the effects of endotoxin administration on mitochondrial membrane-bound creatine kinase, an important trans-mitochondrial ATP transport system. Diaphragms and hearts were isolated from control (n = 12) and endotoxin-treated (8 mg.kg(-1).day(-1); n = 13) rats after pentobarbital anesthesia. We isolated mitochondria using techniques that allow evaluation of the functional coupling of mitochondrial creatine kinase MtCK activity to oxidative phosphorylation. MtCK functional activity was established by 1) determining ATP/creatine-stimulated oxygen consumption and 2) assessing total creatine kinase activity in mitochondria using an enzyme-linked assay. We examined MtCK protein content using Western blots. Endotoxin markedly reduced diaphragm and cardiac MtCK activity, as determined both by ATP/creatine-stimulated oxygen consumption and by the enzyme-linked assay (e.g., ATP/creatine-stimulated mitochondrial respiration was 173.8 +/- 7.3, 60.5 +/- 9.3, 210.7 +/- 18.9, was 67.9 +/- 7.3 natoms O.min(-1).mg(-1) in diaphragm control, diaphragm septic, cardiac control, and cardiac septic samples, respectively; P < 0.001 for each tissue comparison). Endotoxin also reduced diaphragm and cardiac MtCK protein levels (e.g., protein levels declined by 39.5% in diaphragm mitochondria and by 44.2% in cardiac mitochondria; P < 0.001 and P = 0.009, respectively, comparing sepsis to control conditions). Our data indicate that endotoxin markedly impairs the MtCK-ATP transporter system; this phenomenon may have significant effects on diaphragm and cardiac function.     

Decrease of oxidative activities in brown adipose tissue mitochondria of cold acclimated rats on short term exposure to heat stress

Exposure of rats to the cold (4-5 degrees C) caused large (2-3-fold) increases in the mass of interscapular brown adipose tissue (BAT), its mitochondrial content and the basal metabolic rate of the animals. The rate of substrate oxidation by BAT mitochondria also increased about 3-fold. When cold-acclimated animals were exposed to heat (37 degrees C), the BMR decreased by half in 3 h, the earliest time interval tested. Mitochondrial substrate oxidation, as well as substrate-dependent H2O2 generation, showed a proportionate decrease in rates. In these mitochondria, activities of cytochrome c reductases, but not dehydrogenases with NADH, alpha-glycerophosphate and succinate as substrates, also showed a significant decrease. The concentration of cytochromes aa3 and b, but not cytochrome c, also decreased in BAT mitochondria from 12-h heat-exposed animals, while the change in concentration of cytochrome b alone was found as early as 3 h of heat exposure. These results identify the change in cytochromes as a mechanism of regulation of oxidative activities in BAT mitochondria under conditions of acute heat stress.     

Specific inhibition of ATP-ADP translocase in cardiac mitoplasts by antibodies against mitochondrial creatine kinase

Mitochondrial creatine kinase was purified from rat hearts and used to produce antibodies in chicken and rabbits. Antibodies were purified to a high degree of homogeneity by an affinity chromatography method. Chicken antibodies against mitochondrial creatine kinase inhibited this enzyme in rat-heart mitochondrial inner membrane and matrix preparation, and simultaneously blocked oxidative phosphorylation. Under these conditions respiratory chain activities remained unchanged, but adenine nucleotide translocase was inhibited. Removal of mitochondrial creatine kinase from the membrane by pretreatment with 0.15 M KCl and 20 mM ADP completely abolished the effect of antibodies against mitochondrial creatine kinase on oxidative phosphorylation. Noninhibitory antibodies from rabbit with high affinity to rat mitochondrial creatine kinase inhibited neither creatine kinase activity nor oxidative phosphorylation. These data show close and specific spatial arrangement of mitochondrial creatine kinase and adenine nucleotide translocase in mitochondria. It is supposed that there is a fixed orientation of these proteins in the cardiolipin domain in the membrane and that their interaction may occur by a frequent collision due to their lateral movement.     

The role of the mitochondrial creatine kinase system for myocardial function during ischemia and reperfusion.

The subcellular distribution of ATP, ADP, creatine phosphate and creatine was studied in normoxic control, isoprenaline-stimulated and potassium-arrested guinea-pig hearts as well as during ischemia and after reperfusion. The mitochondrial creatine phosphate/creatine ratio was closely correlated to the oxidative activity of the hearts. This was interpreted as an indication of a close coupling of mitochondrial creatine kinase to oxidative phosphorylation. To further investigate the functional coupling of mitochondrial creatine kinase to oxidative phosphorylation, rat or guinea-pig heart mitochondria were isolated and the mass action ratio of creatine kinase determined at active or inhibited oxidative phosphorylation or in the presence of high phosphate, conditions which are known to change the functional state of the mitochondrial enzyme. At active oxidative phosphorylation the mass action ratio was one-third of the equilibrium value whereas at inhibited oxidative phosphorylation (N2, oligomycin, carboxyatractyloside) or in the presence of high phosphate, the mass action ratio reached equilibrium values. These findings show that oxidative phosphorylation is essential for the regulation of the functional state of mitochondrial creatine kinase. The functional coupling of the mitochondrial creatine kinase and oxidative phosphorylation indicated from the correlation of mitochondrial creatine phosphate/creatine ratios with the oxidative activity of the heart in situ as well as from the deviation of the mass action ratio of the mitochondrial enzyme from creatine kinase equilibrium at active oxidative phosphorylation in isolated mitochondria is in accordance with the proposed operation of a creatine shuttle in heart tissue.     

Protein degradation during yeast sporulation. Enzyme and cytochrome patterns.

The levels of several enzymes have been studied during sporulation of Saccharomyces cerevisia. The specific activities of ribonuclease and aminopeptidase I raised several-fold after transfer of the cells to sporulation medium, whereas the specific activities of phosphofructokinase, glucose-6-phosphate dehydrogenase, tryptophan synthase and pyruvate decarboxylase were not significantly altered. The specific activities of NAD-dependent glutamate dehydrogenase, isocitrate lyase, malate dehydrogenase and fructose bisphosphatase all decreased from the onset of sporulation. The inactivation of these latter enzymes was inhibited by cycloheximide and by inhibitors of energy metabolism. Hexokinase, alcohol dehydrogenase and glutamate oxaloacetate transaminase were partially lost from the cells during the period of ascus maturation. None of the enzyme changes observed proved to be 'sporulation-specific' in that it occurred exclusively in sporulating diploid yeast cells. Therefore it is postulated that the meiotic events and the metabolic changes required for ascospore formation are under separate genetic control in this organism. During sporulation, the cellular content of cytochromes b, c, and aa3 was reduced to 20% or less of that present in vegetative derepressed cells. Since the relative percentage of total to cycloheximide-insensitive mitochondrial protein synthesis was not significantly altered throughout sporulation, and the pattern of mitochondrially synthesized polypeptides was rather similar both in vegetative and in sporulating cells, it appeared that not only degradation but also synthesis and therefore turnover of the mitochondrially coded polypeptides of cytochromes b and aa3 took place during sporulation. The activity ratio of cytochrome c oxidase to F1-ATPase in submitochondrial particles isolated from vegetative cells and from purified asci was almost identical. This indicates that the loss of membrane-bound mitochondrial cytochromes during sporulation is probably due to a nonselective degradation of inner mitochondrial membrane proteins.     

Thyroid hormones and the creatine kinase system in cardiac cells

The paper reviews the current evidence on the role of thyroid hormones in regulating the creatine kinase energy transfer system at multiple structures in cardiac cells. 1) Thyroid hormones modulate the overall synthesis of phosphocreatine (PCr) by increasing the rate of mitochondrial oxidative phosphorylation. 2) Thyroid hormones regulate the total activity of creatine kinase and its isoenzyme distribution. In comparison with normal thyroid state (euthyroidism), hypothyroidism is characterized by decreased total creatine kinase activity owing to diminished fraction of creatine kinase. On the other hand, hyperthyroidism, while causing no change in total creatine kinase activity, leads to increased fractions of neonatal isoforms of creatine kinase, and, in case of prolonged hyperthyroidism, to decreased fraction of mitochondrial creatine kinase. The latter change is associated with partial uncoupling between mitochondrial creatine kinase and adenine nucleotide translocase reflected by decreased PCr/O ratio. 3) Hyperthyroidism leads to increased passive sarcolemmal permeability due to which the leakage of creatine along its concentration gradient occurs. As a result of (i) increased sarcolemmal permeability for creatine, (ii) uncoupling of mitochondrial PCr synthesis, and (iii) increased energy utilization rate the steady state intracellular PCr content decreases under hyperthyroidism which, in turn, increases the myocardial susceptibility to hypoxic damage. Thyroid state also modulates the protective effects of exogenous PCr on energetically depleted myocardium.     

Decreased mitochondrial creatine kinase activity in dystrophic chicken breast muscle alters creatine-linked respiratory coupling

Dystrophic chicken breast muscle mitochondria contain significantly less mitochondrial creatine kinase than normal breast muscle mitochondria. Breast muscle mitochondria from normal 16- to 40-day-old chickens contain approximately 80 units of mitochondrial creatine kinase per unit of succinate:INT (p-iodonitrotetrazolium violet) reductase, a mitochondrial marker, while dystrophic chicken breast muscle mitochondria contain 36-44 units. Normal chicken heart muscle mitochondria contain about 10% of the mitochondrial creatine kinase per unit of succinate:INT reductase as normal breast muscle mitochondria. The levels in heart muscle mitochondria from dystrophic chickens are not affected significantly. Evidence is presented which shows that the reduced level of mitochondrial creatine kinase in dystrophic breast muscle mitochondria is responsible for an altered creatine linked respiration. First, both normal and dystrophic breast muscle mitochondria respire with the same state 3 and state 4 respiration. Second, the post-ADP state 4 rate of respiration of normal breast muscle mitochondria in the presence of 20 mM creatine continues at the state 3 rate. However, the state 4 rate of dystrophic breast muscle mitochondria and mitochondria from other muscle types with a low level of mitochondrial creatine kinase, such as heart muscle and 5-day-old chicken breast muscle, is slower than the state 3 rate. Third, dystrophic breast mitochondria synthesize ATP at the same rate as normal breast muscle mitochondria but rates of creatine phosphate synthesis in 20-50 mM Pi are reduced significantly. Finally, increasing concentrations of Pi displace mitochondrial creatine kinase from mitoplasts of normal and dystrophic breast muscle mitochondria with the same apparent KD, indicating that the outer surface of the inner mitochondrial membrane and the mitochondrial creatine kinase from dystrophic muscle are not altered.     

Substrate-dependent functional defects and altered mitochondrial respiratory capacity in hearts from guinea pigs with iron deficiency anemia

Iron deficiency anemia was induced by dietary means in weanling guinea pigs. A 25% higher ventricular wall mass per 100 g body mass was seen after 6 weeks of feeding. Myocardial performance was determined in isolated perfused hearts using an isovolumic Langendorff preparation. All hearts exhibited a 25% decrease in left ventricular developed pressure (LVDP) and decreased dP/dt when substrate was switched from 10 mM pyruvate to 16.6 mM glucose. The glucose reduction in LVDP resulted from decreased systolic pressure, which completely reversed when hearts again metabolized pyruvate. With glucose as substrate, left ventricular developed pressure-end diastolic volume relationships were indistinguishable. However, with pyruvate, iron-deficient hearts appeared to be less responsive to the increased energy demands required by elevated diastolic volumes. Rates of state 3 respiration were 18% below control with glutamate + malate as substrate, and 38% lower with pyruvate + malate in mitochondria isolated from anemic animals. No differences in respiration were noted with succinate. Cytochrome a + a3 content, cytochrome oxidase activity and total mitochondrial protein content appeared to be unchanged. In contrast, cytochromes b, c + c1, and the flavoproteins were significantly decreased. The data suggest that iron deficiency anemia induces cardiac hypertrophy with a fixed but defective mitochondrial population, potentially placing the heart in an energetic imbalance. These differences in mitochondrial function were expressed by decreased myocardial performance when the heart metabolizes pyruvate, an exclusively aerobic substrate.     

Dual Electron Microscopic Localization of Mitochondrial Creatine Kinase in Brain Mitochondria

Mitochondrial creatine kinase in brain mitochondria appears to be located at two different intramitochondrial sites. By using immunogold-labeling techniques, a peripheral immunoreactivity was localized between the two boundary membranes, while an additional, central immunoreactivity was found at the crista surface. The peripheral enzyme was accessible to the antibodies after treatment of the brain mitochondria with 100-300 μg digitonin/mg mitochondrial protein, which left 75% of the activity bound to the membranes. Electron microscopic analyses revealed that 43% of the labeled, peripheral creatine kinase was bound at those places where outer membrane vesicles remained attached to the inner envelope membrane, suggesting that the enzyme is in involved in contact formation between outer and inner mitochondrial membranes. Postembedding staining of mitochondria on thin sections of brain tissue or in the isolated state led to the observation of a second location of creatine kinase inside the mitochondria, along the cristae, which was not accessible to the antibodies in isolated, digitonin-treated mitochondria.     

Affinity modification of creatine kinase and ATP-ADP translocase in heart mitochondria: determination of their molar stoichiometry

Oxidized dialdehyde analogs of ADP or ATP (oADP and oATP) were shown to inhibit irreversibly adenine nucleotide translocator (T) and creatine kinase (CK) in heart mitochondria. Inactivation of T and CK was parallel with carboxyatractyloside - sensitive and (ADP + phosphocreatine) - sensitive incorporation of o[3H]ADP into mitochondria, respectively. o[3H]ADP incorporation sensitive to CAT or ADP+phosphocreatine was used to determine T and CK contents in mitochondria. T content in cardiac mitochondria from rat, rabbit, dog, and chicken was calculated to be 2.6 - 2.9 moles/mole cyt.aa3. The same value of T/cyt.aa3 ratio was found in liver mitochondria with lower cytochrome aa3 content. In all types of cardiac mitochondria CK content was found to be 2.4 - 2.6 moles/mole cyt.aa3. The data show that T and CK are present in molar ratio 1:1 in all types of cardiac mitochondria.     

Respiratory activities in chloramphenicol-treated tobacco cells

Chloramphenicol (CAP) inhibited tobacco cell growth as shown by a reduction (34%) of cell mass 4 days after treatment. The rates of cell respiration were slightly higher than control under coupled conditions. However, CAP-treated cells showed a decreased maximal capacity of the cytochrome pathway (48%) and an increased maximal capacity of alternative path (56%) 4 days after treatment. In purified mitochondria, the rates of NADH or malate oxidation under state 4 conditions were not significantly changed by CAP treatment. However, the state 3 rates were 34–40% lower in CAP-treated than in control mitochondria. Succinate oxidation decreased by 31–46% under both state 4 and state 3 conditions after CAP treatment. The activities of complexes I, III, and IV, which contain mitochondrially encoded subunits, decreased by about 50% in CAP-treated mitochondria. There was also a decrease in the contents of mitochondrial cytochromes. Unexpectedly, the activities of complex II and the matrix-facing rotenone-insensitive NADH dehydrogenase, which are thought to be nuclear-encoded, also declined. The activities of external NADH dehydrogenase, NAD-linked malic enzyme, and fumarase remained unchanged after CAP treatment. There was a slight increase in the activity and protein level of alternative oxidase. An electrochemical gradient across the mitochondrial membranes was observed by Rhodamine 123 staining in CAP-treated cells. However, the morphology of most of the mitochondria changed from spherical to vermicular. A method for purifying a high yield of intact mitochondria from tobacco cell suspension cultures is described.