Preservation of energy-linked functions of insect mitochondria by simple freezing methods.

Attempts are made to preserve some energy-linked functions of mitochondria isolated from the fat body of the cockroach Nauphoeta cinerea. The ability of mitochondria to sustain appreciable levels of oxidation, phosphorylation, respiratory control and 2, 4-DNP-stimulation of respiration which are normally lost during incubation at 30°C for 2 hrs or during aging at 0–2°C for 48 hrs can be preserved effectively by storing mitochondrial suspensions in sucrose - EDTA medium for 1 week at - 20°C and at least 3 weeks at -196°C (liquid nitrogen temperature). DMSO (dimethyl sulfoxide; 10% v/v) was found to be ineffective as an aid to preservation at 0–2°C, a significant aid at -20°C and unnecessary at -196°C. With slight variations (for flight muscle mitochondria which requires DMSO at -196°C), this procedure is also effective for mitochondria isolated from other tissues of various insect species. EDTA was found to be an essential ingredient of the isolation medium and therefore for all storage procedures. Both lyophilization and the preincubation of mitochondria with nupercaine (400 μM) have deleterious effects.     

Effects of Sclerin on Energy-linked Functions and Phospholipase Activity in Mitochondria Isolated from Rat Liver and Some Plants

Sclerin (SCL) not only elevated the respiratory control ratio and ADP/O ratio in mitochondria isolated from rat liver and some plants, but was effective in maintaining the energy-linked functions in these mitochondria during aging. There was a close relationship in the effect of SCL between the liberation of fatty acid and maintenance of the energy-linked functions in mitochondria during aging. The liberation of fatty acid was mainly due to the digestion of mitochondrial phospholipids by endogenous phospholipase. SCL had no effect on the activity of phospholipase and rather raised the level of endogenous phospholipase in mitochondria during aging at 30°C. The activity of phospholipase in mitochondria was inhibited by ATP, but stimulated by DNP. It was supposed that SCL inhibits the activity of phospholipase through ATP or high-energy intermediates which is maintained in mitochondria during aging. SCL had a protective effect on the activity of DNP-activated ATPase in mitochondria stored in the cold, and, at a very low concentration, stimulated the ATP-driven NAD reduction by mitochondria.     

Age-dependent behavior loss in adult Drosophila melanogaster

The use of Drosophila as an organism in which to study aging has been limited by the fact that few biomarkers of aging exist in the adult. In this paper we examine behavior loss relative to longevity in wild-type populations maintained at 22°C and 29°C to determine whether behavior loss—that is, loss of ability to perform certain innate behavioral responses within a defined test interval—can be used as biomarkers of aging. We find that under controlled conditions behavior loss can be used as a landmark of aging in populations maintained at either 22°C or 29°C. The ability to perform normal geotactic and phototactic responses is lost during the reproductive phase of the adult populations, whereas motor activity is not lost until well into the death phase. We feel that the use of behavior loss, together with other parameters of longevity in Drosophila, will allow comparisons to be made between different strains or between different environmental conditions to test their effect on aging. In the companion paper we demonstrate the use of behavior loss to identify a mutation which may accelerate the aging process.     

Temperature-induced changes in lipid composition and transition temperature of flight muscle mitochondria of Schistocerca gregaria

The lipid composition of flight muscle mitochondria was determined in adult male $\text{Schistocerca gregaria}$ acclimated for 30 days at 31°C and 45°C respectively. Locusts held at 31°C showed lower levels of phosphatidylcholine and higher levels of phosphatidylethanolamine than the 45°C-acclimated insects. A trend towards an increased cholesterol:phospholipid ratio was also observed at the higher temperature. Wide angle X-ray diffraction procedures indicated a difference of 5°C in the lipid phase transition temperatures of mitochondrial preparations derived from the two groups of insects with the 45°C-acclimated samples demonstrating the higher transition temperature.     

Operation of the Permeability Transition Pore in Rat Heart Mitochondria in Aging

The functioning of the mitochondrial permeability transition pore (mPTP) is involved in the mechanism of programmed cell death and mitochondrial dysfunction observed with aging. In this work, the functional state of heart mitochondria isolated from young (mature and 2–3-month-old) and old (20–22-month-old) rats under conditions of mPTP opening was studied. In the mitochondria of old rats, the rates of Ca²⁺ and TPP⁺ absorption decreased by 40 and 42%, respectively, the threshold concentration of Ca²⁺ decreased by 20%, and the swelling rate of mitochondria from old animals was by 40% higher than that of mitochondria from young ones. In the heart mitochondria of old animals, the content and production of reactive oxygen species (ROS) varied, the superoxide anion content was increased, and the level of hydroperoxide (H₂O₂) increased at a threshold calcium concentration. Electron microscopy revealed a decrease in the number of cristae in mitochondria of the rat heart during aging. To study the potential role of proteins modulating the mPTP functioning, the content of 2',3'-cyclonucleotide-3'-phosphodiesterase (CNPase) and translocator protein (TSPO) in the heart mitochondria of rats of different ages was measured. A significant age-related decrease in the level of CNPase and an increase in the amount of TSPO were detected. The role of these proteins in mitochondrial dysfunction observed during aging is discussed.     

Effects of hypothermia on canine kidney mitochondria

The effect of hypothermia on the function of isolated dog kidney cortex mitochondria was determined with an FAD- and NAD⁺-linked substrate. In dog kidney mitochondria, temperatures of 10 °C or less suppress ADP stimulation of respiration but have little or no effect upon uncoupler, Ca²⁺ or valinomycin-K⁺ stimulation of respiration. This suggests that the adenine nucleotide translocase which catalyses the transport of ADP into the mitochondria limits the rate of respiration and generation of ATP at 10 °C in kidneys undergoing preservation. The coupling of oxidation to phosphylation, as determined by measuring the amount of ATP formed at low temperatures, indicates, however, that mitochondria are fully coupled at both 10 and 5 °C. The respiratory control index at 15 °C is greater (with pyruvate plus malate) than at 30 or 10 °C and suggests that 15 °C may be the optimum perfusion temperature for maintaining adenine nucleotide levels in the perfused kidney.     

Program-like aging and mitochondria: instead of random damage by free radicals

As recently suggested, the target of rapamycin (TOR) pathway, rather than molecular damage by free radicals, drives aging and diseases of aging. But may mitochondria nevertheless contribute to aging? Here, I discuss aimless program‐like aging (versus altruistic program), conflict between the cell and mitochondria, cell murder (versus cell suicide) and the role of mitochondria in aging. In particular, life‐long selection among mitochondria may yield “selfish” (malignant) mitochondria resistant to autophagy. And TOR may create an intra‐cellular environment that is permissive for such selfish mitochondria. In theory, pharmacologic inhibitors of the TOR pathway may reverse accumulation of defective mitochondria, while also inhibiting the aging process. J. Cell. Biochem. 102: 1389–1399, 2007. © 2007 Wiley‐Liss, Inc.     

Mitochondrial function in Antarctic notothenioid fishes that differ in the expression of oxygen-binding proteins

State III respiration rates were measured in mitochondria isolated from hearts of Antarctic notothenioid fishes that differ in the expression of hemoglobin (Hb) and myoglobin (Mb). Respiration rates were measured at temperatures between 2 and 40°C in Gobionotothen gibberifrons (+Hb/+Mb), Chaenocephalus aceratus (–Hb/–Mb) and Chionodraco rastrospinosus (–Hb/+Mb). Blood osmolarity was measured in all three species and physiological buffers prepared for isolating mitochondria and measuring respiration rates. Respiration rates were higher in mitochondria from G. gibberifrons compared to those from C. aceratus at 2°C, but were similar among all species at temperatures between 10 and 26°C. Respiration rates were significantly lower in icefishes at 35 and 40°C compared to G. gibberifrons. The respiratory control ratio of isolated mitochondria was lower in C. aceratus compared to G. gibberifrons at all temperatures below 35°C. At 35 and 40°C, mitochondria were uncoupled in all species. The Arrhenius break temperature of state III respiration was similar among all three species (30.5 ± 0.9°C) and higher than values previously reported for Antarctic notothenioids, likely due to the higher osmolarity of buffers used in this study. These results suggest that differences in mitochondrial structure, correlated with the expression of oxygen-binding proteins, minimally impact mitochondrial function.     

Membrane energization at subzero temperatures: calcium uptake and oxonol-V responses

The use of aprotic solvents for preserving the electron transport properties of mitochondria at subzero temperatures is based upon the use of binary water and ethylene glycol mixtures or upon ternary and quaternary mixtures that include dimethyl sulfoxide and the lower aliphatic alcohols. In order to better preserve the respiratory control properties of mitochondria at subzero temperatures, detailed studies have been made of the effects of these mixtures on the respiratory control and electron transport from NADH or succinate of mitochondrial preparations. It is found that ADP is not metabolized at a measurable rate below 0 °C, but that Ca²⁺ is rapidly taken up and can thus be used to assay respiratory control ratios down to ?8 °C. In the region below ?8 °C the charge-sensitive probe oxonol-V has been used to evaluate energy coupling. By using Ca²⁺ to stimulate respiration at 0 °C good results are obtained with ethylene glycol/water alone and optimal results are obtained with a quaternary mixture. A mixture that freezes at ?21 °C gives about 50% inhibition of the respiratory control ratio for electron transport at 0 °C with NADH or succinate as substrates. The mixtures permit low-temperature studies of mitochondrial functions under conditions of minimal respiratory rate, including the kinetics of electron transfer reactions, the formation of intermediate compounds, and the rapid freeze-trapping of mitochondrial reactions for analytical chemistry or ³¹P NMR.     

Measurement of matrix enzyme activity in isolated mitochondria made permeable with toluene.

Mitochondria isolated from rat liver and heart were made permeable to normally nonpentrating substrates and cofactors by treatment with toluene. The optimal conditions for preparing stable, permeable mitochondria were 2% toluene for 2 min at 4 °C in a buffered, isotonic medium containing 8.5% polyethylene glycol (Mr 6000–7500). Without polyethylene glycol, the toluene-treated mitochondria were unstable and released their matrix enzymes. The treated mitochondria were particularly unstable in dilute suspension under normal assay conditions of their enzyme activities. The levels of matrix enzyme activities unmasked by toluene treatment of mitochondria were very close to those of sonicated mitochondria under identical assay conditions. Mitochondria made permeable with toluene lost only small amounts of their protein and retained a major fraction of the nucleotides and coenzymes. Electron microscopic examination of toluenetreated mitochondria indicated that they were relatively intact with swollen and vesiculated cristae membranes. Such preparations will allow the study of mitochondrial enzymes at approximate in vivo concentrations.     

Characterization of freeze-thaw induced ultrastructural damage to endothelial cells in vitro

Summary The pathophysiology of endothelial cells is important to a variety of vascular conditions including coagulation and hemostasis resulting from clinical frostbite. Use of an in vitro model system demonstrated that when bovine endothelial cells were frozen at 1°C or 20°C/min and thawed immediately (20°C/min), a variety of ultrastructural alterations occurred. Membraneous structures were most extensively damaged, with mitochondria the most sensitive organelle. Low amplitude mitochondrial swelling, first evident at 0°C, progressed to high amplitude swelling by −10°C (frozen). In addition, the rough endoplasmic reticulum was dilated and formed large vesicles with a homogeneous matrix. Nuclear changes first occurred at −15°C. These included separation and distortion of the nuclear membrane, changes in chromatin distribution, and disruption of the nucleolus. Scanning electron microscopy revealed perforated plasma membranes in some cells at −10°C (frozen) and in most cells by −20°C. Cultures frozen at 20°C/min revealed mostly the same ultrastructural damage noted at 1°C/min except a higher percentage of cells exhibited alterations. Data from the recovery index and lactic dehydrogenase (LDH) release correlated well with observed ultrastructural changes. Early swelling of mitochondria and dilation of rough endoplasmic reticulum was not lethal in the absence of freezing. Increased swelling in cytoplasmic organelles coupled with nuclear alterations at −15°C resulted in a decreased survival rate and release of significant quantities of LDH by −20°C. No unique morphological changes were temperature specific, but the total number of cells that displayed alterations increased as temperature decreased. The views, opinions or findings, or both, contained in this report are those of the authros and should not be construed as indicative of an official Department of the Army position, policy, or decision unless so designated by other official documentation.     

Effect of salicylic acid on the development of induced Thermotolerance and induction of heat shock protein synthesis in the <Emphasis Type="Italic">Arabidopsis thaliana</Emphasis> cell culture

Salicylic acid (SA) could be involved in the development of tolerance to abiotic stresses, to heat shock in particular. Under normal conditions (26°C), treatment with SA improved the tolerance of heterotrophic Arabidopsis thaliana (L.) Heynh culture to severe heat shock (50°C). Under mild heat shock (37°C) inducing the development of thermotolerance, the presence of SA, in contrast, reduced the capability of arabidopsis cells to tolerate high temperature (50°C) and simultaneously suppressed induction of HSP synthesis (Hsp101 and Hsp17.6) important for the development of induced thermotolerance. Since SA suppressed cell respiration and activated the alternative pathway of electron transport, SA is supposed, by modulating mitochondria functions, to be an endogenous regulator of plant stress gene expression.     

Thermal acclimation,mitochondrial capacities and organ metabolic profiles in a reptile (<Emphasis Type="Italic">Alligator mississippiensis</Emphasis>)

Reptiles thermoregulate behaviourally, but change their preferred temperature and the optimal temperature for performance seasonally. We evaluated whether the digestive and locomotor systems of the alligator show parallel metabolic adjustments during thermal acclimation. To this end, we allowed juvenile alligators to grow under thermal conditions typical of winter and summer, providing them with seasonally appropriate basking opportunities. Although mean body temperatures of alligators in these groups differed by approximately 10°C, their growth and final anatomic status was equivalent. While hepatic mitochondria isolated from cold-acclimated alligators had higher oxidative capacities at 30°C than those from warm-acclimated alligators, the capacities did not differ at 20°C. Cold acclimation decreased maximal oxidative capacities of muscle mitochondria. For mitochondria from both organs and acclimation groups, palmitate increased oligomycin-inhibited respiration. GDP addition reduced palmitate-uncoupled rates more in liver mitochondria from warm- than cold-acclimated alligators. In muscle mitochondria, carboxyatractyloside significantly reduced palmitate-uncoupled rates. This effect was not changed by thermal acclimation. The aerobic capacity of liver, skeletal muscle and duodenum, as estimated by activities of cytochrome c oxidase (COX), increased with cold acclimation. At acclimation temperatures, the activities of COX and citrate synthase (CS) in these organs were equivalent. By measuring COX and CS in isolated mitochondria and tissue extracts, we estimated that cold acclimation did not change the mitochondrial content in liver, but increased that of muscle. The thermal compensation of growth rates and of the aerobic capacity of the locomotor and digestive systems suggests that alligators optimised metabolic processes for the seasonally altered, preferred body temperature. The precision of this compensatory response exceeds that typically shown by aquatic ectotherms whose body temperatures are at the mercy of their habitat.     

Comparison of the effect of temperature on kidney cortex mitochondria from rabbit,dog, pig,and human: Arrhenius plots of ADP-stimulated respiration

The effect of temperature on the rate of ADP-stimulated respiration of mitochondria from dog, rabbit, pig, and human kidney cortex mitochondria was plotted according to the Arrhenius relationship. The temperature at which the plot demonstrated a break was at 15 °C for mitochondria from dog, pig, and human kidneys. The discontinuity occurred at 10 °C or less for mitochondria from rabbit kidneys. This difference suggests that mitochondria from rabbit kidneys undergo a lipid-phase transition at lower temperatures than for other species commonly used in experimental renal preservation. The implications of this difference suggest caution in using results obtained with rabbit kidneys for comparison to results obtained from hypothermic renal preservation of other species kidneys. Apparent fluidization of dog kidney mitochondrial membranes with adamantine abolished the discontinuity in the Arrhenius plot.     

The effect of fluidity of membrane lipids on freeze-thaw survival of yeast.

One approach to studying the importance of membranes in freeze-thaw damage is to modify their composition and study the effect of this modification on survival after freeze-thaw damage. Fatty acid desaturase auxotrophs of yeast cells were enriched with two fatty acids having substantially different physical properties thus resulting in cells whose membranes had very different physical properties. The fatty acids were stearolic acid (mp = +45 °C) and linolenic acid (mp = ?10 °C). Electron-spin resonance studies showed that membranes containing the latter fatty acid were more fluid than those containing stearolic acid. The yeast were grown under either anaerobic or aerobic conditions. In the former case, the mitochondria appear as membraneous shells with little, if any, internal membrane structure; thus, the plasma and tonoplast membranes are the primary membranes. Yeast cells grown under these conditions survived freezethaw damage (?196 °C) significantly better when the fatty acid composition was mainly stearolic acid rather than linolenic acid. The absolute survival depended on the freezing rate and the differences in survival became small at fast rates. With yeast cells grown under aerobic conditions, when functional mitochondria are formed, the pattern in freeze-thaw survival reversed; cells with γ-linolenic acid in their membranes survived significantly better than cells containing stearolic acid.     

Evidence that Tuber Respiration is the Pacemaker of Physiological Aging in Seed Potatoes (Solanum tuberosum L.)

Storage temperatures greater than 4 °C (that is, heat-unit accumulation) increase respiration and accelerate physiological aging of seed tubers. The degree of apical dominance is a good indicator of physiological age (PAGE). As seed age advances, apical dominance decreases, resulting in more stems, greater tuber set, and shifts in tuber size distribution. Herein we provide evidence that tuber respiration rate may constitute the “pacemaker” of aging. Tubers exposed to a brief high-temperature age-priming treatment initially in storage, followed by holding at 4 °C for the remainder of a 190–200-day storage period, maintained a higher basal metabolic (respiration) rate throughout storage compared with tubers stored the entire season at 4 °C. Tubers thus “remembered” the age-priming treatment as reflected by their elevated respiration rate. Moreover, reducing the respiration rate of age-primed seed by subsequently storing it at 3.5 % O₂ (4 °C) until planting significantly attenuated the effects of the aging treatment on apical dominance, tuber set, and size distribution. The effect of the age-priming treatment on the magnitude of the respiratory response was the same whether given at the beginning or toward the end of storage. However, moving the age-priming treatment progressively later in the storage season effectively decreased its impact on plant growth and development. These results underscore the importance of time in the aging process. Exposure of seed to a high-temperature age-priming treatment at the beginning or end of storage elevated respiration (the pacemaker) to the same extent; however, the timing of these treatments resulted in vastly different physiological ages. The longer the respiration rate of tubers remains at an elevated level, the greater their PAGE at planting. Thus, an accurate but impractical measure of PAGE may be the respiratory output from vine kill to subsequent planting. Respiration appears to be the pacemaker of PAGE and production, and storage conditions that affect respiration may “set the clock speed” that will ultimately determine the PAGE at planting.     

Mitochondrial protein alteration in active brown fat: A sodium dodecyl sulfate-polyacrylamide gel electrophoretic study

The polypeptide composition of mitochondria isolated from the brown adipose tissue of control rats (bred at 22°C) or cold-exposed animals (bred at 6°C) was compared using sodium dodecyl sulfate-polyacrylamide gel electrophoresis. A striking increase in the content of an unknown polypeptide (apparent molecular weight 32,000 daltons) was found after cold adaptation, a phenomenon which was reversed during re-adaptation to a normal temperature. This protein seems to be localized in the membrane fraction of the mitochondria.     

Adenine nucleotide translocation in liver mitochondria of hypothyroid rats.

In measurements using a disc filtration method, liver mitochondria obtained from hypothyroid rats translocate external ADP at 0 °C via the atractyloside-sensitive carrier much more slowly than do mitochondria from normal rats, confirming the findings of Portnay et al. (Biochem. Biophys. Res. Commun. 55, 17, 1973). The hypothyroid mitochondria contain 60% more ATP + ADP than do mitochondria from normals, but the excess nucleotides are not exchangeable and so do not contribute to translocation. A decrease in the first-order rate constant accounts for the decreased velocity. Neither a decrease in the number of translocator sites nor changes in ADP phosphorylation or ATPase activity seem to account for the abnormal kinetics of translocation. Although the filtration method limits the maximal translocation rate observed in normal mitochondria at temperatures above 17 °C that induce a fluid membrane state, no such transition is seen in mitochondria from hypothyroid rats up to 35 °C, indicating that the translocator is in an altered environment in hypothyroidism. Injecting a hypothyroid rat once with l-thyroxine corrects the abnormal compartmentation and produces a temperature-rate relationship like that in normal mitochondria in 3 days, a period which would accommodate the hormone actions reported on translation, membrane phospholipid synthesis, or fatty acid desaturation.     

Time- and temperature-dependent autolysis of urinary bladder epithelium during ex vivo preservation

Morphological and functional preservation of urinary bladder epithelium–urothelium after extirpation from an organism enables physiological studies of that tissue and provides the basis for successful organ transplantations. The aim of this study was to determine the optimal temperature for maintaining urothelium in ex vivo conditions. Mouse urinary bladders were kept at the three temperatures usually used for maintaining tissue during transportation: at the temperature of melting ice (1°C), at room temperature (22–24°C), and at the body temperature of most mammals (37°C). Autolytic structural changes were followed with electron microscopy, while destruction of cytoskeleton and intercellular junctions was observed by immunolabeling. The first ultrastructural changes, swelling of mitochondria and necrosis of individual cells, became evident 30 min after extirpation if the tissue was kept at 1°C. After 60 and 120 min in ex vivo conditions, the most severe changes with increasing plasma membrane ruptures were detected at 1°C, while at room temperature only mild changes were detected. At 37°C, the extent of ultrastructural changes was between those of the other two experimental temperatures. Autolytic destruction of cytoskeleton and intercellular junctions was not observed before 2 h after extirpation. After 4 h, severe degradation of cytokeratin 20 and microtubules were found at 1°C and 37°C, while being almost undisturbed at room temperature. On the other hand, the reduction of desmoplakin and ZO-1 labeling was more evident at 37°C than at 1°C and room temperature. These findings provide evidence that room temperature is most appropriate for short ex vivo preservation of urothelial tissue.