Antioxidants reduce peroxyl-mediated inhibition of mitochondrial transcription

Alteration of mitochondrial DNA homeostasis in drug-induced liver injury

Mitochondrial DNA (mtDNA) encodes for 13 proteins involved in the oxidative phosphorylation (OXPHOS) process. In liver, genetic or acquired impairment of mtDNA homeostasis can reduce ATP output but also decrease fatty acid oxidation, thus leading to different hepatic lesions including massive necrosis and microvesicular steatosis. Hence, a severe impairment of mtDNA homeostasis can lead to liver failure and death. An increasing number of investigations report that some drugs can induce mitochondrial dysfunction and drug-induced liver injury (DILI) by altering mtDNA homeostasis. Some drugs such as ciprofloxacin, antiretroviral nucleoside reverse-transcriptase inhibitors and tacrine can inhibit hepatic mtDNA replication, thus inducing mtDNA depletion. Drug-induced reduced mtDNA levels can also be the consequence of reactive oxygen species-mediated oxidative damage to mtDNA, which triggers its degradation by mitochondrial nucleases. Such mechanism is suspected for acetaminophen and troglitazone. Other pharmaceuticals such as linezolid and tetracyclines can impair mtDNA translation, thus selectively reducing the synthesis of the 13 mtDNA-encoded proteins. Lastly, some drugs might alter the mtDNA methylation status but the pathophysiological consequences of such alteration are still unclear. Drug-induced impairment of mtDNA homeostasis is probably under-recognized since preclinical and post-marketing safety studies do not classically investigate mtDNA levels, mitochondrial protein synthesis and mtDNA oxidative damage.

The effect of aging and increasing ascorbate concentrations on respiratory chain activity in cultured human fibroblasts

The specific activities of Complexes I-III, II-III, and IV of the respiratory chain, and citrate synthase, were determined in mitochondrial sonicates of six control passage 5 fibroblast cultures, cultivated in growth medium containing fetal calf serum as the only source of ascorbate. The enzymes were also assayed in serially subcultured fibroblasts which were characterized as aged at passage 20 and beyond. Results indicated a significant loss of all enzyme activities in aged cells at passage 20, 25, and 30. Further studies involved maintenance of serially subcultured cells in serum free media to which increasing ascorbate concentrations (100, 200, and 300 micromol 1(-1)) were added. Results indicated that ascorbate at 100 micromol 1(-1) was not sufficient to restore any of the enzyme activities in aged cells. An ascorbate concentration of 200 micromol 1(-1) however, could totally restore Complex IV and citrate synthase activities, but had no effect on complexes I-III and II-III activities which required 300 micromol 1(-1) ascorbate to be partially or totally restored respectively. In conclusion, this study demonstrates an age related drop in mitochondrial respiratory chain activity in cultured human fibroblasts. Enzyme activities could be completely or partially restored in the presence of double or triple normal human plasma ascorbate concentrations.

Influence of long-term food restriction on sleep pattern in male rats

The present purpose was to determine the effects of different schedules of long-term food restriction (FR) applied to rats from weaning to the 8th week. Rats were distributed into FR and ad libitum groups at weaning and fed at 7 am, at 7 pm, and finally, restricted rats fed ad libitum. The restricted rats started with 6 g/day and the food was increased by 1 g per week until reaching 15 g/day by adulthood. The rats were implanted with electrodes to record electrocorticogram/eletromyogram signals. Their wake-sleep cycles were monitored over 3 consecutive days (72 h of recording). The FR group fed at 7 am showed an increase in awake time, and decrease in slow wave sleep (SWS) and paradoxical sleep (PS) during the three light periods compared with the control recordings whereas in the dark periods, these sleep parameters were the opposite. The restricted group fed in the evening showed no statistical significances at diurnal periods; however, a significant decrease was observed in the dark recordings for awake time, but the SWS and PS were increased in relation to controls. The analysis of the 24-h period demonstrated that both FR groups presented increase in SWS time. After being FR, the rats were fed ad libitum and their sleep was monitored for 3 additional days. During the first dark recording, the decrease in awake time and increase in SWS were still present; however, as ad libitum food continued, these sleep parameters returned to control values, reestablishing the normal sleep pattern. These results suggest that dietary restriction, regardless to the feeding schedule, caused increase in total sleep time, during the active period.

Compromised liver mitochondrial function and complex activity in low feed efficient broilers are associated with higher oxidative stress and differential protein expression

Variations in broiler growth and efficiency have been explained in part by differences in mitochondrial function and biochemistry in broilers. To further our knowledge in this regard, 2 experiments were carried out to determine the relationships of a) mitochondrial function and activities of various electron transport chain (ETC) complexes; b) production of H2O2, a reactive oxygen species (ROS), and its association with protein oxidation; and c) mitochondrial protein expression in liver of a single line male broilers with low or high feed efficiency (FE, n = 5 to 8 per group). Mitochondrial function and complex activities were measured polarographically and spectrophotometrically, respectively. H2O2 was measured fluorimetrically, whereas oxidized protein (carbonyls) and specific mitochondrial proteins were analyzed using Western blots. Mitochondrial function (ETC coupling) and activities of ETC complexes (I, II, III, and IV) were higher in high FE compared with low FE broilers. H2O2 and protein carbonyls were higher in the livers of low FE broilers than in high FE broilers. Whereas the expression of 4 immunoreactive proteins [NAD3 (complex I), subunit VII (complex III), cytochrome c oxidase subunits (COX) II, and COX IVb (complex IV)] were higher in low FE liver mitochondria and 2 proteins [subunit 70 (complex II) and a-ATP synthase (complex V)] were higher in high FE birds, there were no differences between groups in the expression of 18 other mitochondrial proteins. In conclusion, increases in oxidative stress in low FE broilers were caused by or may contribute to differences in mitochondrial function (ETC coupling and complex activities) or the differential expression of steady-state levels of some mitochondrial proteins in the liver. Understanding the role of oxidative stress in Low FE broilers will provide clues in understanding the cellular basis of feed efficiency.

Low Feed Efficient Broilers Within a Single Genetic Line Exhibit Higher Oxidative Stress and Protein Expression in Breast Muscle with Lower Mitochondrial Complex Activity

The objectives of this study were to determine the effects of low or high feed efficiency (FE) on a) protein oxidation, b) the activities of various respiratory chain complexes, and c) expression of various mitochondrial proteins in male broilers within a single genetic line. Tissue homogenate or mitochondria were isolated from breast muscle of broilers with high (0.80 +/- 0.01) and low FE (0.62 +/- 0.02). The complex activities were measured spectrophotometrically, and the levels of oxidized protein (carbonyl) and immunoreactive mitochondrial proteins were analyzed using Western blots. Protein carbonyl levels were higher in low FE compared with high FE broilers breast muscle, which indicated enhanced protein oxidation in low FE mitochondria. Activities of all respiratory chain complexes (I, II, III, IV) were higher in high FE compared with low FE broilers for breast mitochondria. Whereas the expression of immunoreactive proteins was higher in low FE muscle mitochondria for 5 mitochondrial proteins [core I, cyt c1, cyt b (complex III), COX II (cytochrome c oxidase subunit II, complex IV), and adenine nucleotide translocator (ANT1)], there were no differences between groups in the expression of 9 other respiratory chain protein subunits associated with complexex I, II, III, IV, and V. SDS-PAGE revealed a protein band of 47 kDa that was expressed at a higher level in low FE compared with high FE mitochondria. The differential expression of certain mitochondrial proteins and the 47-kDa band might be a compensatory response either to the lower complex activities or increased protein oxidation observed in low FE birds.

Patterns of cellular gene expression in cells infected with cytopathic or non-cytopathic bovine viral diarrhea virus

Bovine viral diarrhea virus (BVDV) infection in cattle is responsible for mucosal disease; an invariably fatal syndrome characterized by the recovery of two BVDV strains: cytopathic (cp) or noncytopathic (ncp). To understand the cellular responses to cp BVDV infection, we carried out differential display-polymerase chain reaction (DD-PCR) analysis of gene expression in infected cells. Altered expression of 14 genes involved in several functions was observed in cells infected with cp BVDV: (1) immune regulation, such as CD46, FKBP-12, and osteopontin (OPN); (2) apoptosis-related cysteine proteases like calpain; (3) signaling plasma membrane proteins such as integrin beta1, and prion protein; and (4) unknown function genes. Northern blot analysis of the expression of these genes in ncp BVDV infected cells revealed that while the expression of some genes was affected as in cp BVDV infected cells, others show a clearly contrary change. We postulate that a cause-effect relationship may exist between the differential gene expression alterations that characterize cp and ncp BVDV infections and the unique diseases associated with each BVDV biotype.

Heart and breast muscle mitochondrial dysfunction in pulmonary hypertension syndrome in broilers (Gallus domesticus)

This study was conducted to determine function and defects in electron transport in muscle mitochondria of meat chickens (broilers) with pulmonary hypertension syndrome (PHS). The respiratory control ratio (RCR, indicative of respiratory chain coupling) was higher in the control than in PHS breast and heart muscle mitochondria, but there were no differences in the ADP/O (an index of oxidative phosphorylation). Sequential additions of ADP improved the RCR in the control breast muscle mitochondria and the ADP/O in PHS breast and heart muscle mitochondria. Basal hydrogen peroxide production, (an indicator of electron leak), was higher in PHS breast and heart muscle mitochondria than in controls and differences in electron leak in PHS mitochondria were magnified by inhibiting electron transport at Complex I and III (cyt b(562)). Complex I activity was lower in PHS heart mitochondria but there was no difference in Complex II activity. Thus, compared to controls, PHS mitochondria exhibited site-specific defects in electron transport within Complex I and III that could contribute to lower respiratory chain coupling. Additionally, it appears that healthy broilers may exhibit higher basal levels of electron leak compared to other avian species. Together, these findings provide insight into inefficient cellular use of oxygen that may contribute to the development of PHS in broilers.

Association of mitochondrial function with feed efficiency within a single genetic line of male broilers

Studies were conducted to determine relationships between feed efficiency and mitochondrial function and biochemistry. After feed efficiency (FE; gain:feed) was determined in broiler breeder males between 6 and 7 wk of age, mitochondria were isolated from breast and leg muscle from birds with high FE (0.83+/-0.01, n = 6) and low FE (0.64+/-0.01, n = 7). Respiratory chain coupling, assessed by the respiratory control ratio (RCR), was greater in high FE breast, and leg mitochondria provided NADH-linked, but not FADH-linked, energy substrates. There were no differences, however, in the adenosine diphosphate to oxygen (ADP:O) ratio (an index of oxidative phosphorylation) when mitochondria were provided either energy substrate. Electron leak, as determined by generation of H202, was greater in the low FE than in high FE breast mitochondria. Electron leak increased following inhibition of electron transport at Complex I (with rotenone) and Complex III (with antimycin A) in low FE but not in high FE breast mitochondria. There were no differences in basal electron leak in leg mitochondria between groups, but H202 generation was elevated (P < 0.07) compared to basal values in low FE leg mitochondria after Complex I inhibition. The activities of Complexes I and II were greater in high FE breast and leg muscle mitochondria compared to those in low FE mitochondria. The results indicate that lower respiratory chain coupling in low FE muscle mitochondria may be due to lower activities of Complexes I and II and defects in electron leak and provide insight into cellular mechanisms associated with the phenotypic expression of feed efficiency in broilers.

Mitochondrial DNA in aging and degenerative disease

The mitochondrial DNA encodes only a few gene products compared to the nuclear DNA. These products, however, play a decisive role in determining cell function. Should this DNA mutate spontaneously or be damaged by free radicals the functionality of the gene products will be compromised. A number of mitochondrial genetic diseases have been identified. Some of these are quite serious and involve the central nervous system as well as muscle, heart, liver and kidney. Aging has been characterized by a gradual increase in base deletions in this DNA. This increase in deletion mutation has been suggested to be the cumulative result of exposure to free radicals.

Lung mitochondrial dysfunction in pulmonary hypertension syndrome. I. Site-specific defects in the electron transport chain

The main objectives of this study were to determine a) site-specific defects in the electron transport chain of lung mitochondria of broilers with pulmonary hypertension syndrome (PHS), b) if these defects are attenuated by high dietary vitamin E, and c) if these defects have a genetic basis. In Experiment 1, lung mitochondria were isolated from broilers with and without PHS fed diets containing 15 IU and 100 IU dl-alpha-tocopherol acetate/kg (VE); the four treatments were control, VE, PHS, and VE-PHS, respectively. Hydrogen peroxide (H2O2) generation in isolated lung mitochondria was monitored by dichlorofluorosein (DCF) fluorescence in response to chemicals that inhibit electron flow at specific sites on the electron transport chain using a 96-well microplate with Cytoflour (excitation/emission 480/530 nm). Basal H2O2 production was higher in PHS than in control mitochondria. Differences in H2O2 production between control and PHS were magnified by inhibition of Complexes I and III (Coenzyme Q) of the respiratory chain in mitochondria. Functional defects in PHS mitochondria were attenuated by high dietary VE. In Experiment 2, basal H2O2 production and that following inhibition of Complexes I and III were lower in lung mitochondria isolated from broilers selected for genetic resistance to PHS than in nonselected birds in the base population. The results of this study indicate that site-specific defects in Complexes I and III may underlie lung mitochondrial dysfunction in broilers with PHS, that these defects are attenuated by high dietary vitamin E, and that these defects may be related to genetic predisposition to PHS.

Accumulation of 4-hydroxynonenal-modified proteins in hippocampal CA1 pyramidal neurons precedes delayed neuronal damage in the gerbil brain

It has been proposed that reactive oxygen species and lipid peroxidation have a role in the delayed neuronal death of pyramidal cells in the CA1 region. To explore the in situ localization and serial changes of 4-hydroxy-2-nonenal-modified proteins, which are major products of membrane peroxidation, we used immunohistochemistry of the gerbil hippocampus after transient forebrain ischemia with or without preconditioning ischemia. The normal gerbil hippocampus showed weak immunoreactivity for 4-hydroxy-2-nonenal-modified proteins in the cytoplasm of CA1 pyramidal cells. 4-hydroxy-2-nonenal immunoreactivity showed no marked changes after preconditioning ischemia. In the early period after ischemia and reperfusion, there was a transient increase of nuclear 4-hydroxy-2-nonenal immunoreactivity in CA1 pyramidal neurons. In contrast, cytoplasmic immunoreactivity transiently disappeared during same period and then increased markedly from 8h to seven days. One week after ischemia, 4-hydroxy-2-nonenal immunoreactivity was observed within reactive astrocytes in the CA1 region. Early nuclear accumulation of 4-hydroxy-2-nonenal in CA1 neurons may indicate a possible role in signal transduction between the nucleus and cytoplasm/mitochondria, while delayed accumulation of 4-hydroxy-2-nonenal-modified proteins in the cytoplasm may be related to mitochondrial damage. We conclude that 4-hydroxy-2-nonenal may be a key mediator of the oxidative stress-induced neuronal signaling pathway and may have an important role in modifying delayed neuronal death.

Consequences of aging on mitochondrial respiratory chain enzymes in cultured human fibroblasts treated with ascorbate

The activities of mitochondrial respiratory chain enzymes with and without ascorbate pretreatment were assayed in 10- to 20-week-old cultures of human fibroblasts. Aging was associated with a significant loss of respiratory chain enzyme activities. The presence of ascorbate in the medium reduced the rate of loss of these enzymes. Free radical-mediated injuries may also contribute to aging since the changes seen in respiratory chain enzyme activities are similar to those seen in oxidatively stressed cells. This study demonstrates an age-related decline in mitochondrial respiratory chain activity as well as a protective role for ascorbate in aging.

In vitro differentiation of human monocytes to macrophages results in depletion of antioxidants and increase in n-3 fatty acids levels

The lipid composition and alpha-tocopherol content of human monocytes were investigated before and after their differentiation to macrophages. The total lipid and protein content per number of cells increased after the differentiation of monocytes by approximately four-fold; a two-fold increase in docosahexaenoic and docosapentaenoic acids and a two-fold decrease in linoleic acid were also noted. As opposed to an initial monocytic vitamin E content of 4.75 pmol/10(6) cells, macrophagic vitamin E levels were undetectable. Changes in vitamin E and fatty acids contents in macrophages, with respect to monocytes, appear to reflect the lipid composition of fetal calf serum, that is low in vitamin E and has a proportionally higher docosahexaenoic acid content than adult human serum.

Purine catabolism: links to mitochondrial respiration and antioxidant defenses?

Type I diabetes in rodents is associated with a spectrum of liver mitochondrial abnormalities ranging from evidence of oxidative stress and altered antioxidant defenses to frank defects in respiration rates and respiratory control ratios. To better address the myriad changes in redox metabolism in these mitochondria, we have applied new chromatographic techniques that enable simultaneous analysis of multiple components of pathways of interest (e.g., purine catabolites and oxidation by-products). We report here a portion of these results, which, in conjunction with other reported data, suggest that purine catabolism may contribute to mitochondrial antioxidant defenses by producing the antioxidant urate. In liver mitochondria from diabetic rats, increases in uric acid (threefold) and its direct precursor xanthine (sixfold) were observed in moderate diabetes, but levels fell essentially to normal in severe disease. Failure to maintain elevated xanthine and uric acid occurred contemporaneously with progressive mitochondrial dysfunction. Regression analysis revealed altered precursor-product relationships between xanthine, its precursors, and uric acid. An independent set of studies in isolated rat liver mitochondria showed that mitochondrial respiration was associated with essentially uniform decreases (approximately 30%) in all purine catabolites measured (urate, xanthine, hypoxanthine, guanine, guanosine, and xanthosine). That result suggests the potential for steady production of urate. Taken together, the two studies raise the possibility that purine catabolism may be a previously unappreciated component of the homeostatic response of mitochondria to oxidant stress and may play a critical role in slowing progressive mitochondrial dysfunction in certain disease states.

Oxidative insult specifically decreases levels of a mitochondrial transcript

The effects of oxidative insult, applied with hydrogen peroxide, on gene transcript levels in a human lymphocyte cell line (Molt-17) were investigated using mRNA differential display. Several cDNA fragments corresponding to putatively up- or down-regulated transcripts were isolated. One of these was found to hybridize to two discrete transcripts on Northern blots of Molt-17 cell RNA. The more abundant transcript, that has previously been demonstrated to correspond to the mRNA for mitochondrial ATPase subunits 8 and 6, was unaffected by the hydrogen peroxide treatment. In contrast, levels of the rarer, larger transcript were consistently reduced in a rapid, sustained, and dose-dependent manner following hydrogen peroxide treatment. Prior supplementation of the cells with beta carotene provided some protection against the reduction in levels of this transcript following hydrogen peroxide treatment. In contrast, vitamins C and E had no effect at the concentrations tested. We have now cloned the cDNA corresponding to this stress-responsive transcript and demonstrated that it is an incompletely processed product of the mitochondrial genome encompassing ATPase subunits 8 and 6 plus the adjacent gene for cytochrome c oxidase subunit 3. This decrease in one specific mitochondrial transcript may represent a novel mechanism for differential expression of mitochondrially-encoded genes.

Simultaneous analysis of the majority of low-molecular-weight, redox-active compounds from mitochondria

Studies of the interaction between oxidative stress and mitochondrial dysfunction are complicated by analytical limitations, especially the need to assess multiple parameters in relatively small samples. We have addressed this problem by developing a methodology for the simultaneous analysis of the majority of low-molecular-weight, redox-active compounds from mitochondria using HPLC separations followed by coulometric array detection. The method described should also be applicable for the study of redox-active compounds in other subcellular organelles as well as in intact cells and tissues. The protocol described enables simultaneous measurement of antioxidants (e.g., tocopherols, ascorbate, lipoates, uric acid, and glutathione), markers of oxidative stress (e.g., o-tyrosine, m-tyrosine, nitrotyrosine, dityrosine, glutathione disulfide, and 8-hydroxydeoxyguanosine) as well as other metabolites (e.g., purines and indoles). In all, ca. 600 redox active compounds can be detected, most with a limit of detection of approximately 5 pg on column. Results, including analytical parameters, from a study of liver mitochondria from control and diabetic rats are presented to demonstrate utility of this methodology.

Age-related mitochondrial DNA deletions: effect of dietary restriction

Results from quantitative PCR analysis of the frequency of deleted mitochondrial genomes in male Fischer 344 rats reveal an age-related rise in this molecular abnormality. We used this model to examine the ability of dietary restriction (DR) to prevent this potentially pathogenic change. DR prevented age-related increase in frequency of mitochondrial deletions in the liver. In contrast, however, DR had no effect on the age-related increase in deletion frequency in the brain. These data suggest that the effects of DR on age-related accumulation of mitochondrial DNA deletions may be tissue specific.

Dietary restriction augments resistance to oxidant-mediated inhibition of mitochondrial transcription

The exquisite sensitivity of mitochondrial transcription to oxidant stress suggests that chronic, low level oxidative stress may impair mitochondrial gene expression during the aging process. In this study, we assessed the effects of age and of life-prolonging, anti-oxidative dietary restriction (DR) regimens on sensitivity of mitochondrial transcription to oxidant stress. Studies were carried out using liver mitochondria isolated from male Fischer 344 rats of different ages (6, 12, 18, or 24 months) fed ad libitum (AL) or maintained on DR. Transcriptional capacity was assessed in isolated mitochondria challenged with different doses of either hydrophilic or hydrophobic peroxyl radicals generated by AAPH [2,2'-azobis-(2-amidino-propane) hydrochloride] or AMVN [2, 2'-azobis-(2,4,-dimethyl-valeronitrile), respectively]. The most striking effect was that DR increased resistance to AMVN nearly 400% at 6 months and nearly 700% at 24 months, relative to resistance in AL rats. Results also suggest that resistance to both AAPH and AMVN was decreased slightly in older AL rats, but was maintained in the DR rats. These results show that DR augments the defense systems that protect one of the mitochondria's most vulnerable systems. This augmentation is one of the largest magnitude effects of DR yet observed against oxidative challenge.

Induction of megamitochondria by some chemicals inducing oxidative stress in primary cultured rat hepatocytes

Effects of hydrazine, hydrogen peroxide and bromobenzene, inducers of free radicals, and those of erythromycin and cycloheximide, inhibitors of protein synthesis on structural changes of mitochondria in primary monolayer culture of rat hepatocytes were examined using laser confocal microscope and electron microscope. After 22 h of incubation of hepatocytes with 0.2 mM hydrogen peroxide or 10 microg ml-1 of erythromycin, mitochondria became extremely enlarged. Mitochondria of hepatocytes isolated from control rats became slightly to moderately enlarged in the presence of 2 mM hydrazine, while those of hepatocytes isolated from phenobarbital-pretreated animals became extremely enlarged in the presence of 2 mM hydrazine. Cycloheximide (0.5-10.0 microg ml-1) and bromobenzene (0.1-1.0 mM) failed to induce structural changes of mitochondria. The level of cytochrome P-450 in freshly prepared hepatocytes from phenobarbital-treated rats was 2.5 times higher than that from the control rats, and remained about three times higher than the latter after 22 h of incubation with 2 mM hydrazine. The level of malondialdehyde was invariably elevated when megamitochondria were induced. These results may suggest that oxidative stress is intimately related to the mechanism of the formation of megamitochondria and that the inhibition of cytoplasmic protein synthesis seems not to contribute the phenomenon. However, the detailed mechanism by which free radicals may induce megamitochondria remains to be elucidated.

Postischemic accumulation of lipid peroxidation products in the rat brain: immunohistochemical detection of 4-hydroxy-2-nonenal modified proteins

We report an immunohistochemical study on the distribution and alterations of 4-hydroxy-2-nonenal (HNE)-modified proteins, an indicator of lipid peroxidation, in the rat brain after 3 h of middle cerebral artery (MCA) occlusion followed by reperfusion. HNE immunoreactivity was not observed in intact neurons, but it appeared in some shrunken neurons within the infarcted zone at 3 h after reperfusion. The number of HNE-positive neurons increased with the spread of the infarcted area. The pyramidal neurons in the third layer of the frontoparietal cortex were HNE-positive and the intensity of their HNE immunoreactivity was highest at 24 h after reperfusion. At 48 h, HNE-positive neurons were observed in the medial part of the striatum, the lateral side of the frontoparietal cortex, and at the boundary between the infarcted and noninfarcted zones. In addition, strong HNE immunoreactivity was seen in microglia (identified by OX-42 immunostaining). This method seems to be useful to follow the progress of lipid peroxidation at the cellular level after ischemic injury.

Brain and skeletal muscle bioenergetic failure in familial hypobetalipoproteinaemia

OBJECTIVE

To determine whether a multisystemic bioenergetic deficit is an underlying feature of familial hypobetalipoproteinaemia.

METHODS

Brain and skeletal muscle bioenergetics were studied by in vivo phosphorus MR spectroscopy (31P-MRS) in two neurologically affected members (mother and son) and in one asymptomatic member (daughter) of a kindred with familial hypobetalipoproteinaemia. Plasma concentrations of vitamin E and coenzyme Q10 (CoQ10) were also assessed.

RESULTS

Brain 31P-MRS disclosed in all patients a reduced phosphocreatine (PCr) concentration whereas the calculated ADP concentration was increased. Brain phosphorylation potential was reduced in the members by about 40%. Skeletal muscle was studied at rest in the three members and during aerobic exercise and recovery in the son and daughter. Only the mother showed an impaired mitochondrial function at rest. Both son and daughter showed an increased end exercise ADP concentration whereas the rates of postexercise recovery of PCr and ADP were slow in the daughter. The rate of inorganic phosphate recovery was reduced in both cases. Plasma concentration of vitamin E and CoQ10 was below the normal range in all members.

CONCLUSIONS

Structural changes in mitochondrial membranes and deficit of vitamin E together with reduced availability of CoQ10 can be responsible for the multisystemic bioenergetic deficit. Present findings suggest that CoQ10 supplementation may be important in familial hypobetalipoproteinaemia.

Oxidant-mediated repression of mitochondrial transcription in diabetic rats

Diabetes-associated mitochondrial dysfunction is recognized, but the underlying mechanisms are unknown. Using isolated liver mitochondria from streptozotocin-induced diabetic Sprague-Dawley rats, we showed that diabetes can result in a > 95% loss in mitochondrial transcriptional capacity. Decreased transcription correlated well with both disease status, as indicated by serum lipemia and ketone levels, and with increased resistance of the mitochondrial transcription system to oxidative stress imposed by the hydrophilic AAPH [2,2'-azobis-(2-amidino-propane) hydrochloride] or the hydrophobic AMVN [2,2'-azobis-(2,4,-dimethyl-valeronitrile)]. The onset of AAPH- or AMVN-induced lipid peroxidation was also delayed; this suggests that liver mitochondrial membranes from diabetics have increased resistance to peroxyl radical-mediated lipid peroxidation. Lipid peroxidation induced endogenously was increased, however, suggesting a state of increased oxidative stress likely exists in vivo. Furthermore, changes in the rate of lipid peroxidation occurring during the propagation phase were also affected by diabetes. This implies possible changes in lipid composition or structure. Analysis indicated that the factors protecting mitochondria from lipid peroxidation differ from those involved in protecting the transcription system, and that both are independent of free radical scavenger levels. These results suggested that diabetes alters mitochondrial exposure and/or response to reactive species and provided clues to the role of oxidant stress in the development of diabetes-associated mitochondrial dysfunction.

Defects at center P underlie diabetes-associated mitochondrial dysfunction

Detailed respiration studies on isolated liver mitochondria from streptozotocin-induced diabetic Sprague-Dawley rats revealed a disease-associated decrease in the ADP/O ratio, a marker for mitochondrial ability to couple the consumption of oxygen to the phosphorylation of ADP. This decrease was observed following induction of respiration with glutamate/malate, succinate, or duroquinol, which enter the electron transport chain selectively at complexes I (NADH dehydrogenase), II (succinate dehydrogenase), or III (cytochrome bc1 complex), respectively. These data, coupled with studies using respiratory inhibitors (most importantly antimycin A and myxothiazol), localize at least a portion of this defect to a single site within the electron transport chain (center P in the Q-cycle portion of complex III). These results suggest that liver mitochondria from diabetic animals may generate increased levels of reactive oxygen species at the portion of the electron transport chain already established as the major site of mitochondrial free radical generation. The reduction in the ADP/O ratio occurred in mitochondria that do not have overt defects in the respiratory control ratio or in State 3 and State 4 respiration. The data in this paper suggest that defects in center P of the electron transport chain likely increase mitochondrial exposure to oxidants in the diabetic. This data may partially explain the evidence of altered exposure and/or response to reactive species in mitochondria from diabetics. This work thus provides further clues to the interaction between oxidative stress and diabetes-associated mitochondrial dysfunction.

Age- and peroxidative stress-related modifications of the cerebral enzymatic activities linked to mitochondria and the glutathione system

The aging brain undergoes a process of enhanced peroxidative stress, as shown by reports of altered membrane lipids, oxidized proteins, and damaged DNA. The aims of this review are to examine: (1) the possible contribution of mitochondrial processes to the formation and release of reactive oxygen species (ROS) in the aging brain; and (2) the age-related changes of antioxidant defenses, both enzymatic and nonenzymatic. It will focus on studies investigating the role of the electron transfer chain as the site of ROS formation in brain aging and the alterations of the glutathione system, also in relation to the effects of exogenous pro-oxidant agents. The possible role of peroxidative stress in age-related neurodegenerative diseases will also be discussed.

In utero ethanol exposure elicits oxidative stress in the rat fetus

Prior studies in our laboratory have shown that exposure of cultured fetal rat hepatocytes to ethanol (E) blocks epidermal growth factor-dependent replication and that this is paralleled by cell membrane damage, mitochondrial dysfunction, membrane lipid peroxidation (LP), and enhanced generation of reactive oxygen species. These measures of E-mediated oxidative stress (OS) were mitigated by treatment with antioxidants, and cell replication could be normalized by maintaining cell glutathione (GSH) pools. We have now extended these studies to an in vivo model. Rats were administered E (4 g/kg, po) at 12-hr intervals on days 17 and 18 of gestation and killed on day 19, 1 hr following a final dose of E (a total of 5 doses). Fetal and maternal brain and liver were assayed for signs of OS. The 2-day in utero E exposure increased membrane LP in fetal brain as evidenced by increased malondialdehyde (MDA) levels from 1.76 +/- 0.12 SE (nMol/mg protein) to 2.00 +/- 0.08 (p < 0.05) and conjugated dienes from 0.230 +/- 0.006 SE (OD223/mg lipid) to 0.282 +/- 0.006 (p < 0.05). In fetal liver, MDA levels increased from 2.39 +/- 0.08 SE (nMol/mg protein) to 2.87 +/- 0.08 (p < 0.05), whereas dienes differed significantly only between ad libitum controls and the E and pair-fed control groups (p < 0.05). E decreased GSH levels in fetal brain by 19%, from 19.88 +/- 0.72 to 16.13 +/- 1.06 (nMol/mg protein) (p < 0.05). A 10% decrease in GSH was seen in fetal liver (p < 0.05).(ABSTRACT TRUNCATED AT 250 WORDS)