Vitamin E at high doses improves survival, neurological performance, and brain mitochondrial function in aging male mice
Male mice receiving vitamin E (5.0 g alpha-tocopherol acetate/kg of food) from 28 wk of age showed a 40% increased median life span, from 61 +/- 4 wk to 85 +/- 4 wk, and 17% increased maximal life span, whereas female mice equally supplemented exhibited only 14% increased median life span. The alpha-tocopherol content of brain and liver was 2.5-times and 7-times increased in male mice, respectively. Vitamin E-supplemented male mice showed a better performance in the tight-rope (neuromuscular function) and the T-maze (exploratory activity) tests with improvements of 9-24% at 52 wk and of 28-45% at 78 wk. The rates of electron transfer in brain mitochondria, determined as state 3 oxygen uptake and as NADH-cytochrome c reductase and cytochrome oxidase activities, were 16-25% and 35-38% diminished at 52-78 wk. These losses of mitochondrial function were ameliorated by vitamin E supplementation by 37-56% and by 60-66% at the two time points considered. The activities of mitochondrial nitric oxide synthase and Mn-SOD decreased 28-67% upon aging and these effects were partially (41-68%) prevented by vitamin E treatment. Liver mitochondrial activities showed similar effects of aging and of vitamin E supplementation, although less marked. Brain mitochondrial enzymatic activities correlated negatively with the mitochondrial content of protein and lipid oxidation products (r2 = 0.58-0.99, P < 0.01), and the rates of respiration and of complex I and IV activities correlated positively (r2 = 0.74-0.80, P < 0.01) with success in the behavioral tests and with maximal life span.
Hippocampal mitochondrial dysfunction in rat aging
Navarro A, Ló pez-Cepero JM, Bá ndez MJ, Sá nchez-Pino M-J, Gó mez C, Cadenas E, Boveris A. Hippocampal mitochondrial dysfunction in rat aging. Am J Physiol Regul Integr Comp Physiol 294: R501-R509, 2008. First published December 12, 2007 doi:10.1152/ajpregu.00492.2007.-Hippocampus mitochondrial dysfunction with impaired electron transfer and increased oxidative damage was observed upon rat aging. Hippocampal mitochondria of aged (12 mo) and senescent (20 mo) rats showed, compared with young (4 mo) rats, marked decreases in the rate of state 3 respiration with NAD-dependent substrates (32-51%) and in the activities of mitochondrial complexes I (57-73%) and IV (33-54%). The activity of mitochondrial nitric oxide synthase was also decreased, 53-66%, with age. These losses in enzymatic activity were more marked in the hippocampus than in brain cortex or in whole brain. The histochemical assay of mitochondrial complex IV in the hippocampus showed decreased staining upon aging. Oxidative damage, determined as the mitochondrial content of thiobarbituric-acid reactive substances (TBARS) and protein carbonyls, increased in aged and senescent hippocampus (66 -74% in TBARS and 48 -96% in carbonyls). A significant statistical correlation was observed between mitochondrial oxidative damage and enzymatic activity. Mitochondrial dysfunction with shortage of energy supply is considered a likely cause of dysfunction in aged hippocampus. mitochondrial nitric oxide synthase; reduced nicotinamide adenide dinucleotide dehydrogenase; cytochrome oxidase; oxidative damage MAMMALIAN AGING is characterized by a gradual and continuous loss, starting at full adulthood, of the quality of physiological functions and responses. The losses are more marked in the functions that depend on the integrated response of the central nervous system (19) than in the functions of the renal or cardiovascular systems. Mitochondria were brought to attention in mammalian aging biology because of the central role of mitochondria in producing biochemical energy (ATP) to meet cellular requirements in aerobic cells and to the decline of basal metabolic rate and of physical performance that are characteristic of aging (32).The free radical theory of aging, based on the pioneer works of Gerschman et al. (18) and Harman (20), considers that aging is caused by the continuous inactivation of biologically essential macromolecules and subcellular structures due to chemical modifications produced by reactions mediated by oxygen free radicals. When the free radical theory of aging is focused in mitochondria, it emerges as the mitochondrial theory of aging (6,21,32,47). Mitochondria are considered likely pacemakers of tissue aging because of their continuous production of superoxide radical (O 2•Ϫ ) and of nitric oxide (NO) and to the mitochondrial sensitivity to free radical-mediated oxidative damage (32).Aged mammalian brain shows a decreased capacity to produce ATP by oxidative phosphorylation, and it is considered that this decreased capacity for energy production ...
Mitochondria and calcium flux as targets of neuroprotection caused by minocycline in cerebellar granule cells
This is a PDF file of an unedited manuscript that has been accepted for publication. As a service to our customers we are providing this early version of the manuscript. The manuscript will undergo copyediting, typesetting, and review of the resulting proof before it is published in its final form. Please note that during the production process errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. A c c e p t e d M a n u s c r i p t 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 Garcia-Martinez EM et al., 2 AbstractMinocycline, an antibiotic of the tetracycline family, has attracted considerable interest for its theoretical therapeutic applications in neurodegenerative diseases. However, the mechanism of action underlying its effect remains elusive. Here we have studied the effect of minocycline under excitotoxic conditions. Fluorescence and bioluminescence imaging studies in rat cerebellar granular neuron cultures using fura-2/AM and mitochondria-targeted aequorin revealed that minocycline, at concentrations higher than those shown to block inflammation and inflammation-induced neuronal death, inhibited NMDA-induced cytosolic and mitochondrial rises in Ca 2+ concentrations in a reversible manner. Moreover, minocycline added in the course of NMDA stimulation decreased Ca 2+ intracellular levels, but not when induced by depolarization with a high K + medium. We also found that minocycline, at the same concentrations, partially depolarized mitochondria by about 5-30 mV, prevented mitochondrial Ca 2+ uptake under conditions of environmental stress, and abrogated NMDAinduced reactive oxygen species (ROS) formation. Consistently, minocycline also abrogates the rise in ROS induced by 75 M Ca 2+ in isolated brain mitochondria. In search for the mechanism of mitochondrial depolarization, we found that minocycline markedly inhibited state 3 respiration of rat brain mitochondria, although distinctly increased oxygen uptake in state 4. Minocycline inhibited NADH-cytochrome c reductase and cytochrome c oxidase activities, whereas the activity of succinate-cytochrome c reductase was not modified, suggesting selective inhibition of complex I and IV. Finally, minocycline affected activity of voltage-dependent anion channel (VDAC) as determined in the reconstituted system. Taken together, our results indicate that mitochondria are a critical factor in minocycline-mediated neuroprotection.
-Female rats were treated with FSH (40 IU/kg) on the first and second diestrus days (D1 and D2) and with LH (40 IU/kg) on the proestrus (P) day to synchronize and maximize ovarian changes. Follicle area increased by 50% from D1 to P, and the estrus (E) phase showed multiple corpora lutea and massive apoptosis. Increased oxygen uptakes (42-102%) were determined in ovary slices and in isolated mitochondria in active state 3 along the proliferation phase (D1-D2-P) that returned to initial values in the E phase. Mitochondrial content and the electron transfer activities of complexes I and IV were also maximal in the P phase (20 -79% higher than in D1). Production of NO by mitochondrial nitric oxide synthase (mtNOS), biochemically determined, and the mtNOS functional activity in regulating state 3 oxygen uptake were also maximal at P and 79 -88% higher than at D1. The moderately increased rate of NO in the proliferative phase is associated with mitochondrial biogenesis, whereas the high rate of NO generation by mtNOS at phase P appears to trigger mitochondria-dependent apoptosis. The calculated fraction of ovary mitochondria in state 3 was at a minimal value at the P phase. Mitochondrial oxidative damage, with increased thiobarbituric acid-reactive substances and protein carbonyls, indicates progressive mitochondrial dysfunction between phases P and E. The roles of mitochondria as ATP provider, as a source of NO to signal for mitochondrial proliferation and mitochondria-dependent apoptosis, and as a source of O 2 Ϫ and H2O2 appear well adapted to serve the proliferation-apoptosis sequence of the ovarian cycle. ovarian follicle; oxygen uptake; mitochondrial nitric oxide synthase; respiratory chain; oxidative damage OVARIAN CYCLE AND FOLLICULAR DEVELOPMENT are controlled by circulatory feedback between the ovarian hormones and the hypothalamic-pituitary axis (12) and the hormonal predominance of a dominant follicle determines its morphological changes and growth (13) by increasing diameter and the number of granulosa cells (28) whereas nondominant follicles become atretic.During each cycle, the increased FSH concentration recruits growing antral follicles, and the concept of "cyclic recruitment" has been proposed to describe this rescue of follicles from degeneration (27). Follicles in the antral stage express receptors for FSH and become dependent on FSH stimulation for survival, proliferation, and expression of the LH receptor that after stimulation by the hypophysis reach ovulation and formation of the corpus luteum. The number of corpora lutea formed depends, in a ratio of one to one, on the number of follicles that responded to the LH signal. In physiological conditions, FSH stimulates ovarian follicular growth, and LH controls their hormonal secretory capacity, with FSH and LH maximal levels at the end of the proestrus phase with maximal follicular growth simultaneous to ovulation. A decrease in the levels of LH pulse results in follicular cell death and in abortion of the generation of corpora lutea (10). The co...
Rotenone and pyridaben were tested on activities and properties of rat brain mitochondria determining Ki (inhibitor concentration at half maximal inhibition) and Imax (% of inhibition at maximal inhibitor concentration). The assayed activities were complexes I, II and IV, respiration in states 3, 3u (uncoupled) and 4, biochemical and functional activities of mitochondrial nitric oxide synthase (mtNOS), and inner membrane potential. Selective inhibitions of complex I activity, mitochondrial respiration and membrane potential with malate-glutamate as substrate were observed, with a Ki of 0.28-0.36 nmol inhibitor/mg of mitochondrial protein. Functional mtNOS activity was half-inhibited at 0.70-0.74 nmol inhibitor/mg protein in state 3 mitochondria and at 2.52-2.98 nmol inhibitor/mg protein in state 3u mitochondria. This fact is interpreted as an indication of mtNOS being structurally adjacent to complex I with an intermolecular mtNOS-complex I hydrophobic bonding that is stronger at high Δψ and weaker at low Δψ.
High doses of vitamin E improve mitochondrial dysfunction in rat hippocampus and frontal cortex upon aging
Rat aging from 4 to 12 mo was accompanied by hippocampus and frontal cortex mitochondrial dysfunction, with decreases of 23 to 53% in tissue and mitochondrial respiration and in the activities of complexes I and IV and of mitochondrial nitric oxide synthase (mtNOS) (P < 0.02). In aged rats, the two brain areas showed mitochondria with higher content (35-78%) of oxidation products of phospholipids and proteins and with higher (59-95%) rates of O(2)(-) and H(2)O(2) production (P < 0.02). Dietary supplementation with vitamin E (2.0 or 5.0 g/kg of food) from 9 to 12 mo of rat age, restored in a dose-dependent manner, the decreases in tissue and mitochondrial respiration (to 90-96%) and complexes I and IV and mtNOS activities (to 86-88%) of the values of 4-mo-old rats (P < 0.02). Vitamin E prevented, by 73-80%, the increases in oxidation products, and by 62-68%, the increases in O(2)(-) and H(2)O(2) production (P < 0.05). High resolution histochemistry of cytochrome oxidase in the hippocampal CA1 region showed higher staining in vitamin E-treated rats than in control animals. Aging decreased (19%) hippocampus mitochondrial mass, an effect that was restored by vitamin E. High doses of vitamin E seem to sustain mitochondrial biogenesis in synaptic areas.
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