Kathryn J. Wright

Mitochondrial structure and function are disrupted by standard isolation methods.

Mitochondria regulate critical components of cellular function via ATP production, reactive oxygen species production, Ca2+ handling and apoptotic signaling. Two classical methods exist to study mitochondrial function of skeletal muscles: isolated mitochondria and permeabilized myofibers. Whereas mitochondrial isolation removes a portion of the mitochondria from their cellular environment, myofiber permeabilization preserves mitochondrial morphology and functional interactions with other intracellular components. Despite this, isolated mitochondria remain the most commonly used method to infer in vivo mitochondrial function. In this study, we directly compared measures of several key aspects of mitochondrial function in both isolated mitochondria and permeabilized myofibers of rat gastrocnemius muscle. Here we show that mitochondrial isolation i) induced fragmented organelle morphology; ii) dramatically sensitized the permeability transition pore sensitivity to a Ca2+ challenge; iii) differentially altered mitochondrial respiration depending upon the respiratory conditions; and iv) dramatically increased H2O2 production. These alterations are qualitatively similar to the changes in mitochondrial structure and function observed in vivo after cellular stress-induced mitochondrial fragmentation, but are generally of much greater magnitude. Furthermore, mitochondrial isolation markedly altered electron transport chain protein stoichiometry. Collectively, our results demonstrate that isolated mitochondria possess functional characteristics that differ fundamentally from those of intact mitochondria in permeabilized myofibers. Our work and that of others underscores the importance of studying mitochondrial function in tissue preparations where mitochondrial structure is preserved and all mitochondria are represented.

Mitochondrial functional impairment with aging is exaggerated in isolated mitochondria compared to permeabilized myofibers

Mitochondria regulate cellular bioenergetics and apoptosis and have been implicated in aging. However, it remains unclear whether age‐related loss of muscle mass, known as sarcopenia, is associated with abnormal mitochondrial function. Two technically different approaches have mainly been used to measure mitochondrial function: isolated mitochondria and permeabilized myofiber bundles, but the reliability of these measures in the context of sarcopenia has not been systematically assessed before. A key difference between these approaches is that contrary to isolated mitochondria, permeabilized bundles contain the totality of fiber mitochondria where normal mitochondrial morphology and intracellular interactions are preserved. Using the gastrocnemius muscle from young adult and senescent rats, we show marked effects of aging on three primary indices of mitochondrial function (respiration, H2O2 emission, sensitivity of permeability transition pore to Ca2+) when measured in isolated mitochondria, but to a much lesser degree when measured in permeabilized bundles. Our results clearly demonstrate that mitochondrial isolation procedures typically employed to study aged muscles expose functional impairments not seen in situ. We conclude that aging is associated with more modest changes in mitochondrial function in sarcopenic muscle than suggested previously from isolated organelle studies.

Alterations in intrinsic mitochondrial function with aging are fiber type‐specific and do not explain differential atrophy between muscles

To determine whether mitochondrial dysfunction is causally related to muscle atrophy with aging, we examined respiratory capacity, H2O2 emission, and function of the mitochondrial permeability transition pore (mPTP) in permeabilized myofibers prepared from four rat muscles that span a range of fiber type and degree of age‐related atrophy. Muscle atrophy with aging was greatest in fast‐twitch gastrocnemius (Gas) muscle (−38%), intermediate in both the fast‐twitch extensor digitorum longus (EDL) and slow‐twitch soleus (Sol) muscles (−21%), and non‐existent in adductor longus (AL) muscle (+47%). In contrast, indices of mitochondrial dysfunction did not correspond to this differential degree of atrophy. Specifically, despite higher protein expression for oxidative phosphorylation (oxphos) system in fast Gas and EDL, state III respiratory capacity per myofiber wet weight was unchanged with aging, whereas the slow Sol showed proportional decreases in oxphos protein, citrate synthase activity, and state III respiration. Free radical leak (H2O2 emission per O2 flux) under state III respiration was higher with aging in the fast Gas, whereas state II free radical leak was higher in the slow AL. Only the fast muscles had impaired mPTP function with aging, with lower mitochondrial calcium retention capacity in EDL and shorter time to mPTP opening in Gas and EDL. Collectively, our results underscore that the age‐related changes in muscle mitochondrial function depend largely upon fiber type and are unrelated to the severity of muscle atrophy, suggesting that intrinsic changes in mitochondrial function are unlikely to be causally involved in aging muscle atrophy.

Exercise training from late middle age until senescence does not attenuate the declines in skeletal muscle aerobic function

We previously showed that 7 wk of treadmill exercise training in late-middle-aged rats can reverse the modest reductions in skeletal muscle aerobic function and enzyme activity relative to values in young adult rats (Exp Physiol 93: 863-871, 2008). The purpose of the present study was to determine whether extending this training program into senescence would attenuate the accelerated decline in the muscle aerobic machinery normally seen at this advanced age. For this purpose, 29-mo-old Fisher 344 Brown-Norway rats underwent 5 or 7 mo of treadmill exercise training. Training resulted in greater exercise capacity during an incremental treadmill exercise test and reduced percent body fat in 34- and 36-mo-old rats and improved survival. Despite these benefits at the whole body level, in situ muscle aerobic capacity and muscle mass were not greater in the trained groups at 34 mo or 36 mo of age. Similarly, the trained groups did not have higher activities of citrate synthase (CS) or Complex IV in homogenates of either the plantaris (fast twitch) or the soleus (slow twitch) muscles at either age. Finally, protein expression of CS (a marker of mitochondrial content) and peroxisome proliferator-activated receptor-gamma coactivator-1 (relating to the drive on mitochondrial biogenesis) were not higher in the trained groups. Therefore, although treadmill training from late middle age into senescence had significant benefits on running capacity, survival, and body fat, it did not prevent the declines in muscle mass, muscle aerobic capacity, or mitochondrial enzyme activities normally seen across this age, revealing a markedly diminished plasticity of the aerobic machinery in response to endurance exercise at advanced age.

Slow twitch soleus muscle is not protected from sarcopenia in senescent rats

Although most literature suggests a relative protection of slow twitch muscle with aging, there is limited data in senescence when muscle atrophy and functional decline markedly accelerate. To address this issue we examined age-related changes in muscle mass, contractile function, mitochondrial enzyme activities, and myosin heavy chain (MHC) expression in the slow twitch soleus (Sol) and fast twitch gastrocnemius (Gas) muscle of young adult (YA) and senescent (SEN) rats. Muscle mass declined between YA and SEN in the Sol by 35% compared to 55% in the Gas muscle. After normalizing for muscle mass, tetanic force per g of muscle declined by 58% in Sol and by 36% in Gas muscle. Time-to-peak tension was increased only in the Gas (30%), whereas time-to-half relaxation was increased by 70% in Sol and 51% in Gas. Citrate synthase and complex IV activity declined in homogenates of Sol (30-36%) and red oxidative region of Gas (46-51%), but not white glycolytic region of Gas. Strikingly, the shift away from the dominant adult MHC isoform with aging was much greater in Sol (fibers positive for MHC fast: 11+/-2% in YA versus 36+/-3% in SEN) than in Gas (fibers positive for MHC slow: 12+/-1% in YA versus 26+/-3% in SEN) muscle. Collectively, these results show that the slow twitch Sol muscle undergoes large phenotypic alterations in very old age and for several measures (tetanic tension per g, time-to-half relaxation and shift in adult MHC expression) that is of greater magnitude than fast twitch muscle, underscoring the importance of including age-related changes in slow twitch muscle in seeking potential treatments for sarcopenia.

Exercise training initiated in late middle age attenuates cardiac fibrosis and advanced glycation end-product accumulation in senescent rats

While it has long been postulated that exercise training attenuates the age-related decline in heart function normally associated with increased fibrosis and collagen cross-linking, the potential benefits associated with exercise training initiated later in life are currently unclear. To address this question, Fischer 344 × Brown Norway F1 rats underwent treadmill-based exercise training starting in late middle age and continued into senescence (35 mo) and were compared with age-matched sedentary rats. Hearts were examined for fibrosis and advanced glycation end-products in the subendocardial layer of left ventricular cross-sections. Genes for collagen synthesis and degradation were assessed by polymerase chain reaction, and matrix metalloproteinase (MMP) activity was assessed by EnzChek® Gelatinase/Collagenase Assay Kit. Exercise training of late middle-aged rats attenuated fibrosis and collagen cross-linking, while also reducing age-related mortality between late middle age and senescence. This training was also associated with an attenuated advanced glycation end-product (AGE) accumulation with aging, suggesting a decrease in collagen cross-linking. Conversely, tissue inhibitor of matrix metalloproteinase-1 (TIMP1) gene expression, TIMP and MMP1 protein expression, and MMP activity increased with age but were not significantly impacted by exercise training. While our results demonstrate that exercise training in late middle age attenuates age-related mortality and cardiac fibrosis and is accompanied by attenuated AGE accumulation indicative of less collagen cross-linking, the mechanisms explaining this attenuated replacement fibrosis did not appear to involve altered TIMP1 expression, or MMP protein and activity.

Initiating exercise training in late middle age minimally protects muscle contractile function and increases myocyte oxidative damage in senescent rats.

Age-related loss of muscle mass and function exhibits a marked acceleration from late middle age to senescence and exercise training is one method that has been proposed to slow this process. The purpose of this study was to determine if long-term treadmill exercise training initiated at late middle age could increase endogenous antioxidant enzyme activity and attenuate the loss of skeletal muscle contractile properties in the gastrocnemius/plantaris (GAS/Plan) and soleus (SOL) muscles of senescent rats (34-36 mo) through a decrease in oxidative damage. Male Fisher 344 × Brown Norway F1-hybrid rats underwent 5-7 mo of treadmill training beginning at late middle age (29 mo). A 7 mo sedentary adult group was used to investigate age-related changes. Aging caused an increase in antioxidant enzyme activities; however, only SOD activity was further increased with exercise training. Exercise training did not attenuate the decrease in twitch or tetanic tension of the GAS/Plan or SOL. It did, however, prevent the increase in twitch half relaxation time of the SOL muscle only. Oxidative damage, as reflected in carbonyl content, was increased with age and even further with exercise training in the GAS muscle. Muscle fibre cross sectional area was decreased with age and even further with exercise training. Interestingly, small muscle fibres showed the highest accumulation of carbonyls. Overall, despite an augmentation of select antioxidant enzyme activities, exercise training from late middle age through to senescence had minimal benefits for muscle contractile properties, perhaps in part due to exacerbated oxidation.

Mitochondrial Function in Permeabilized Cardiomyocytes Is Largely Preserved in the Senescent Rat Myocardium

The aging heart is characterized by a progressive decline in contractile function and diastolic relaxation. Amongst the factors implicated in these changes is a progressive replacement fibrosis secondary to cardiomyoctye death, oxidative damage, and energetic deficit, each of which may be secondary to impaired mitochondrial function. Here, we performed an in-depth examination of mitochondrial function in saponin-permeabilized cardiomyocyte bundles, a preparation where all mitochondria are represented and their structure intact, from young adult (YA) and senescent (SEN) rats (n = 8 per group). When accounting for increased fibrosis (+19%, P<0.01) and proportional decrease in citrate synthase activity in the SEN myocardium (−23%, P<0.05), mitochondrial respiration and reactive oxygen species (H2O2) emission across a range of energized states was similar between age groups. Accordingly, the abundance of electron transport chain proteins was also unchanged. Likewise, except for CuZnSOD (−37%, P<0.05), the activity of antioxidant enzymes was unaltered with aging. Although time to mitochondrial permeability transition pore (mPTP) opening was decreased (−25%, P<0.05) in the SEN heart, suggesting sensitization to apoptotic stimuli, this was not associated with a difference in apoptotic index measured by ELISA. Collectively, our results suggest that the function of existing cardiac ventricular mitochondria is relatively preserved in SEN rat heart when measured in permeabilized cells.