Increase In Mitochondrial Volume Density Research Articles

Knockdown of the SDHB Subunit Induces Mitochondrial Remodeling in Human Airway Smooth Muscle Cells

Succinate dehydrogenase (SDH) is a mitochondrial enzyme that serves a dual role in mitochondrial respiration: catalyzing the oxidation of succinate to fumarate in the tricarboxylic acid (TCA) cycle and transferring electrons from succinate to ubiquinone as complex II in the electron transport chain (ETC). SDH is composed of four subunits (SDHA-SDHD) and the loss of SDHB subunit, specifically, has been shown to increase oxidative stress. As a part of the catalytic core of the SDH complex, the SDHB subunit mediates electron transfer to ubiquinone. In human airway smooth muscle (hASM) cells with siRNA-mediated knockdown of SDHB, the maximum velocity of the SDH reaction (SDHmax) is decreased. Moreover, SDHB-knockdown leads to an increase in mitochondrial volume density, indicating a role of SDH in mitochondrial remodeling. However, the impact of SDHB-knockdown on mitochondrial dynamics has not been explored. Therefore, we hypothesize that SDHB-knockdown promotes mitochondrial fragmentation as part of mitochondrial remodeling in hASM cells. To investigate this hypothesis, bronchiolar tissue samples were collected in female and male patients undergoing lung surgery with no current history of smoking or respiratory diseases, the smooth muscle layer was dissected and hASM cells were dissociated. The targeted knockdown of SDHB was achieved by siRNA-mediated knockdown. Mitochondria in hASM cells were labeled with MitoTracker Green (200 nM) and imaged in 3D with a Z optical slice of 0.5 μm using an oil-immersion ×60/1.4 NA objective on a Nikon Eclipse A1 laser scanning confocal system. Optical slices were deconvolved to enhance contrast and the MitoTracker labeling was thresholded to create binary images, which were then reconstructed in 3D. From these images, the mitochondrial complexity index (MCI) was calculated to quantify the extent of fragmentation. To identify the signaling pathway involved in mitochondrial fragmentation, the expression and phosphorylation of dynamin-related protein 1 (DRP1) was quantified by Western blot. Mitochondrial fragmentation is associated with increased phosphorylation of DRP1 at Ser616 (pDRP1s616). Furthermore, mitophagy was assessed by determining the mitochondrial expression of PINK1 and the phosphorylation of Parkin at Ser65 (pParkinS65). Mitochondrial biogenesis was also evaluated through the expression of PGC1α, NRF1/2 and TFAM. Our results show that SDHB-knockdown increased mitochondrial fragmentation (reduced MCI) in hASM cells, and increased pDRP1s616 phosphorylation and its translocation to mitochondria. SDHB-knockdown also increased mitochondrial expression of PINK1 and pParkins65 phosphorylation indicating activation of mitophagy. We also confirmed that SDHB-knockdown increased expression of PGC1α, NRF1/2 and TFAM consistent with mitochondrial biogenesis. These findings unveil the mechanisms underlying SDHB-knockdown-mediated mitochondrial remodeling. Supported by NIH grant R01-HL157984 (GCS). This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.

TNFα Reduces the Maximum Respiratory Capacity of Mitochondria in Human Airway Smooth Muscle Cells

Previously, we reported that airway inflammation mediated by pro‐inflammatory cytokines such as TNFα induces hypercontractility and increased ATP consumption in human airway smooth muscle (hASM). We also found that TNFα induces an increase in maximum O2 consumption rate as well as mitochondrial biogenesis and an increase in mitochondrial volume density. However, when normalized to mitochondrial volume, maximum O2 consumption rate per mitochondrion is reduced in hASM after TNFα exposure. Unfortunately, standard respirometry (e.g., Seahorse) measures only the averaged maximum O2 consumption rate of a large number of cells. In the present study, we used a quantitative histochemical technique to determine the maximum velocity of the succinate dehydrogenase reaction (SDHmax) together with mitochondrial volume density in individual hASM cells. SDH is a key enzyme in the tricarboxylic acid (TCA) cycle as well as complex II in the electron transport chain (ETC), and SDHmax reflects the maximum respiratory capacity of individual mitochondrion. We hypothesized that TNFα decreases SDHmax per mitochondrion in hASM cells. hASM cells were dissociated from bronchial biopsies obtained during thoracic surgeries in patients with no history of asthma or chronic obstructive pulmonary disease. The hASM cells were treated with TNFα (20 ng/ml) or vehicle (DMSO) for 24 h, and SDHmax was measured using a solution containing 80 mM succinate (maximum substrate concentration) and 1.5 mM nitro blue tetrazolium (NBT) as the reaction indicator. As the SDH reaction proceeded, the hASM cells were imaged in 3D (Z optical slice of 0.5 μm) using an oil‐immersion ×60/1.4 NA objective on a Nikon Eclipse A1 laser scanning confocal system. The change in optical density (OD), reflecting the accumulation of NBT diformazan reaction product in the hASM cell, was measured every 15 s over a 10 min period. Based on the Beer‐Lambert equation, the slope of the change in OD was used to determine SDHmax expressed as mM fumarate/L tissue/min. To determine mitochondrial volume density, the same hASM cells were also loaded with MitoTracker Green (500 nM) and imaged in 3D. We found that mitochondria were more fragmented after TNFα exposure although mitochondrial volume density increased. When SDHmax was normalized to mitochondrial volume, we found that SDHmax per mitochondrion decreased in hASM cells, consistent with the reduction in maximum O2 consumption per mitochondrion that we previously observed. Thus, the increased energetic demand induced by inflammation (TNFα) are met by mitochondrial fragmentation leading to biogenesis and an increase in mitochondrial volume density rather than an increase in mitochondrial respiratory capacity.

TNFα Exposure Decreases Mitochondrial O2 Consumption in Motor Neurons

Neuroinflammation triggers a homeostatic response that is mediated by pro‐inflammatory cytokines such as TNFα. We hypothesize that in a motor neuron‐like cell line, NSC‐34, TNFα decreases mitochondrial O2 consumption. NSC‐34 cells were differentiated by serum depletion (~24 h) until neurite structures (>50 μm) were observed. The cells were then exposed to TNFα (20 ng/ml) for 24 h. To determine mitochondrial volume density, the cells were loaded with MitoTracker Green and imaged in 3D using a Nikon A1R confocal microscope (60x oil immersion 1.4 NA). After treatment with TNFα, mitochondria appeared fragmented but mitochondrial volume density increased by ~50%, as compared to control untreated cells. A Agilent Seahorse XF Analyzer was used to determine the O2 consumption of treated and untreated cells during a stress test that determines basal respiration, ATP production and maximum respiration. O2 consumption was normalized to mitochondrial volume density in both treated and untreated groups. After TNFα exposure, basal respiration, ATP production and maximum respiration decreased per mitochondrion. However, overall O2 consumption of the cells was unchanged after TNFα exposure due to an offsetting increase in mitochondrial volume density. Using MitoSox, we also measured reactive oxygen species (ROS) formation in treated and untreated NSC‐34 cells. ROS is a byproduct of mitochondrial O2 consumption, and can cause cellular damage. After TNFα exposure, ROS formation increased compared to untreated cells. We conclude that mitochondrial biogenesis and an increase in mitochondrial volume density represent a homeostatic mechanism to reduce O2 consumption the per mitochondrion, thereby damping ROS formation while maintaining overall cellular O2 consumption and ATP production.Support or Funding InformationSupported by NIH grant AG44615 and HL105355.

TNFα Decreases Succinate Dehydrogenase Activity in Motor Neurons

Inflammation triggers a homeostatic response that is mediated by pro‐inflammatory cytokines such as TNFα. We hypothesize that in a motor neuron‐like cell line, NSC‐34, TNFα decreases mitochondrial function, specifically succinate dehydrogenase (SDH) activity, which is a key enzyme in the tricarboxylic acid (TCA) cycle as well as complex II in the electron transport chain (ETC). Experiments were performed on cultured NSC‐34 cells that were differentiated by serum depletion until neurite structures (>50 μm) were observed. The differentiated cells were treated with TNFα (20 ng/ml) for 24 h. To measure the maximum velocity of the SDH reaction (SDHmax), cells were incubated in a solution containing 80 mM succinate and 1.5 mM nitro blue tetrazolium (NBT), the reaction indicator. As the SDH reaction proceeded, images were acquired every 15 s using a 40× objective on an Olympus IX71 inverted microscope. Linearity of the SDH reaction was confirmed across the 8‐min period, and SDHmax was determined and expressed as mM fumarate/L tissue/min. To determine mitochondrial volume density, the cells were loaded with MitoTracker Green and imaged in 3D using a confocal microscope. The cell volume occupied by labeled mitochondria was determined from 3D reconstructions of 1 mm optical slices. In NSC‐34 cells exposed to TNFα, we found that mitochondrial volume density increased, and mitochondria were fragmented as compared to untreated controls. We also found that TNFα exposure decreased SDHmax when normalized for mitochondrial volume density. In other cell types, we found that TNFα‐induces an increase in PGC1a and Drp1 expression and a decrease in Mfn2 expression, all of which affect mitochondrial structure. In related studies, we also found that TNFα exposure decreases O2 consumption per mitochondrion in NSC‐34 cells. We conclude that by reducing the redox potential (SDHmax) of mitochondria, O2 consumption per mitochondrion is reduced, thereby damping ROS formation. The impact of this homeostatic response is offset by mitochondrial biogenesis and an increase in mitochondrial volume density, thereby maintaining overall cellular O2 consumption and ATP production but at reduced cost of ROS formation.Support or Funding InformationSupported by NIH grants AG44615 and HL105355.

Effect of TNFα on Mitochondrial Function and Mitochondrial Biogenesis in Human Airway Smooth Muscle

Airway inflammation is a key aspect of asthma and is associated with airway smooth muscle (ASM) hyperreactivity as well as airway remodeling. Proinflammatory cytokines, such as TNFα mediate this airway inflammatory response. Previously, we found that TNFα induces an increase airway smooth muscle (ASM) force and ATP hydrolysis. In response, TNFα may also induce an increase in ATP production in ASM. This could be achieved by either an increase in mitochondrial function and/or mitochondrial biogenesis. We previously found that TNFα decreases mitochondrial Ca2+ influx. Since dehydrogenase enzymes in the TCA cycle are Ca2+ dependent, this would tend to reduce mitochondrial function in response to agonist stimulation. We also found that TNFα increases mitochondrial fragmentation, an initial step in mitochondrial biogenesis. We hypothesized that TNFα increases mitochondrial biogenesis and decreases mitochondrial function in human ASM.Human ASM cells were isolated from lung specimens incidental to patient surgery. The patients were normal as evaluated by a clinical pathologist (no history of asthma or COPD). hASM cells were exposed to TNFα (20 ng/ml) for 24 h. To examine mitochondrial biogenesis, protein expression of porin (an indicator of mitochondrial density) and PGC1α (a regulator of mitochondria biogenesis) were determined by Western blot analysis. In addition, the relative number of copies of human mitochondrial DNA (mtDNA) was determined by PCR and normalized to nuclear DNA. Mitochondrial function was assessed by measuring O2 Consumption Rate (OCR – using a Seahorse Bioscience XF24 Analyzer), succinate dehydrogenase (SDH) activity (using a quantitative histochemical technique) and mitochondrial membrane potential – (DYm – using TMRM and confocal microscopy). OCR and SDH activity measurements were normalized to mitochondrial volume density. Results were analyzed by one‐way ANOVA with post hoc analysis when justified.We found that TNFα increases mitochondrial biogenesis as indicated by an increase in porin and PGC1α protein expression in hASM and an increase in mtDNA copy numbers. We also found that TNFα decreases mitochondrial membrane potential in hASM cells, and also decreases OCR and SDH activity when normalized for the increase in mitochondrial volume density induced by TNFα. In a normal homeostatic response, an increase in hASM force and ATP hydrolysis (energy demand) would be met by increased mitochondrial ATP production. Our results indicate that TNFα disrupts this normal homeostatic response by reducing mitochondrial Ca2+ influx and thereby reducing mitochondrial TCA activity. However, TNFα increase the number of mitochondria to compensate the decrease in mitochondrial TCA activity.Support or Funding InformationSupported by NIH grant HL126451This abstract is from the Experimental Biology 2019 Meeting. There is no full text article associated with this abstract published in The FASEB Journal.

Evolutionary Consequences of Altered Atmospheric Oxygen in Drosophila melanogaster

Twelve replicate populations of Drosophila melanogaster, all derived from a common ancestor, were independently evolved for 34+ generations in one of three treatment environments of varying PO2: hypoxia (5.0–10.1 kPa), normoxia (21.3 kPa), and hyperoxia (40.5 kPa). Several traits related to whole animal performance and metabolism were assayed at various stages via “common garden” and reciprocal transplant assays to directly compare evolved and acclimatory differences among treatments. Results clearly demonstrate the evolution of a greater tolerance to acute hypoxia in the hypoxia-evolved populations, consistent with adaptation to this environment. Greater hypoxia tolerance was associated with an increase in citrate synthase activity in fly homogenate when compared to normoxic (control) populations, suggesting an increase in mitochondrial volume density in these populations. In contrast, no direct evidence of increased performance of the hyperoxia-evolved populations was detected, although a significant decrease in the tolerance of these populations to acute hypoxia suggests a cost to adaptation to hyperoxia. Hyperoxia-evolved populations had lower productivity overall (i.e., across treatment environments) and there was no evidence that hypoxia or hyperoxia-evolved populations had greatest productivity or longevity in their respective treatment environments, suggesting that these assays failed to capture the components of fitness relevant to adaptation.

Chronic electrical stimulation drives mitochondrial biogenesis in skeletal muscle of a lizard,Varanus exanthematicus

We investigated the capacity for phenotypic plasticity of skeletal muscle from Varanus exanthematicus, the savannah monitor lizard. Iliofibularis muscle from one leg of each lizard was electrically stimulated for 8 weeks. Both stimulated and contralateral control muscles were collected and processed for electron microscopy. We used stereological analysis of muscle cross-sections to quantify the volume densities of contractile elements, sarcoplasmic reticulum, mitochondria and intracellular lipids. We found that mitochondrial volume density was approximately fourfold higher in the stimulated muscle compared to controls, which were similar to previously reported values. Sarcoplasmic reticulum volume density was reduced by an amount similar to the increase in mitochondrial volume density while the volume density of contractile elements remained unchanged. Intracellular lipid accumulation was visibly apparent in many stimulated muscle sections but the volume density of lipids did not reach a significant difference. Although monitor lizards lack the highly developed aerobic metabolism of mammals, they appear to possess the capacity for muscle plasticity.

Deficiency in parvalbumin, but not in calbindin D-28k upregulates mitochondrial volume and decreases smooth endoplasmic reticulum surface selectively in a peripheral, subplasmalemmal region in the soma of Purkinje cells

The Ca 2+-binding proteins parvalbumin (PV) and calbindin D-28k (CB) are key players in the intracellular Ca 2+-buffering in specific cells including neurons and have profound effects on spatiotemporal aspects of Ca 2+ transients. The previously observed increase in mitochondrial volume density in fast-twitch muscle of PV−/− mice is viewed as a specific compensation mechanism to maintain Ca 2+ homeostasis. Since cerebellar Purkinje cells (PC) are characterized by high expression levels of the Ca 2+ buffers PV and CB, the question was raised, whether homeostatic mechanisms are induced in PC lacking these buffers. Mitochondrial volume density, i.e. relative mitochondrial mass was increased by 40% in the soma of PV−/− PC. Upregulation of mitochondrial volume density was not homogenous throughout the soma, but was selectively restricted to a peripheral region of 1.5 μm width underneath the plasma membrane. Accompanied was a decreased surface of subplasmalemmal smooth endoplasmic reticulum (sPL-sER) in a shell of 0.5 μm thickness underneath the plasma membrane. These alterations were specific for the absence of the “slow-onset” buffer PV, since in CB−/− mice neither changes in peripheral mitochondria nor in sPL-sER were observed. This implicates that the morphological alterations are aimed to specifically substitute the function of the slow buffer PV. We propose a novel concept that homeostatic mechanisms of components involved in Ca 2+ homeostasis do not always occur at the level of similar or closely related molecules. Rather the cell attempts to restore spatiotemporal aspects of Ca 2+ signals prevailing in the undisturbed (wildtype) situation by subtly fine tuning existing components involved in the regulation of Ca 2+ fluxes.

Complementary action of the PGC-1 coactivators in mitochondrial biogenesis and brown fat differentiation

Mitochondria play an essential role in the ability of brown fat to generate heat, and the PGC-1 coactivators control several aspects of mitochondrial biogenesis. To investigate their specific roles in brown fat cells, we generated immortal preadipocyte lines from the brown adipose tissue of mice lacking PGC-1alpha. We could then efficiently knockdown PGC-1beta expression by shRNA expression. Loss of PGC-1alpha did not alter brown fat differentiation but severely reduced the induction of thermogenic genes. Cells deficient in either PGC-1alpha or PGC-1beta coactivators showed a small decrease in the differentiation-dependant program of mitochondrial biogenesis and respiration; however, this increase in mitochondrial number and function was totally abolished during brown fat differentiation when both PGC-1alpha and PGC-1beta were deficient. These data show that PGC-1alpha is essential for brown fat thermogenesis but not brown fat differentiation, and the PGC-1 coactivators play an absolutely essential but complementary function in differentiation-induced mitochondrial biogenesis.

Cytological effects of platelet-derived growth factor on mitochondrial ultrastructure in fibroblasts

The goal of this study was to evaluate morphofunctional changes in mitochondrial ultrastructure after platelet-derived growth factor application in fibroblasts as an indicator of mitochondrial activation in processes like wound healing. NRK-49F fibroblasts were synchronized, incubated with PDGF (platelet-derived growth factor) and studied by electron microscopy. Volume density ( V v ), numerical density ( N v ) and surface density ( S v ) were measured by stereological analysis. Application of PDGF on NRK-49F caused an increase in mitochondrial volume density by 57% and surface area of cristae per mitochondrion by 65%. The numerical density of the mitochondria was decreased in the PDGF-treated cells by 23%, but at the same time their mean volume was increased. Furthermore, the mitochondria had a complex and highly variable shape both in control and PDGF-treated cells, possibly indicating the existence of a mitochondrial reticulum. The results demonstrated that biochemically active membrane systems in fibroblast mitochondria are enlarged as a direct effect of small doses of platelet-derived growth factor and support the concept that this factor and related peptides serve as mitogens for connective tissue forming cells. Thus, in mitogenic processes like wound healing, the high energy demand of fibroblasts is provided by the increase of the inner surface of mitochondria.

Morphometric analysis of myocardium from copper-deficient pigs

Volume densities and ultrastructure of mitochondria and myofibrils from hearts of copper-deficient pigs were evaluated in two studies. Weaned male pigs (21 d of age) were fed purified diets with adequate copper (Study 1: 7.1 mg Cu/Kg, n=4; Study 2: 8.4 mg Cu/Kg, n=6) or no copper added (Study 1:1.2 mg Cu/kg, n=4; Study 2: 0.84 mg Cu/Kg, n=5). Pigs in both studies fed the copper-deficient diet developed symptoms of copper deficiency, including decreased levels of the micronutrient in liver, heart and plasma, and increased heart to body weight ratio. Morphometric evaluation revealed a significant increase in mitochondrial volume density and in the ratio of mitochondria to myofibril volume densities in copper-deficient hearts. The myofibril volume density and the heart to body weight ratio was positively correlated in study 1, suggesting that the enlarged hearts of the Cu deficient pigs were due to an increase in the volumes of both mitochondria and myofibril compartments. Mitochondria in areas appeared vacuolated and cristae were fragmented in the copper-deficient pig myocardium as opposed to the normal parallel array of these structures. Separated myofilaments and deposits of glycogen granules were also evident in the copper-deficient pig heart. These results suggest that copper-deficiency alters the ultrastructural characteristics of the pig heart in a similar manner as previously reported for the laboratory rat.

Operation Everest II: structural adaptations in skeletal muscle in response to extreme simulated altitude

Alterations in skeletal muscle structure were investigated in 6 male subjects who underwent 40 days of progressive decompression in a hypobaric chamber simulating an ascent to the summit of Mount Everest. Needle biopsies were obtained from vastus lateralis of 5 subjects before and immediately after confinement in the chamber, and were examined for various structural and ultrastructural parameters. In addition, total muscle area was calculated in 6 subjects from CT scans of the thighs and upper arms. Muscle area at these sites was found to decrease significantly (by 13 and 15%) as a result of the hypobaric confinement. This was substantiated by significant (25%) decreases in cross sectional fibre areas of the Type I fibres and 26% decreases (non significant) in Type II fibre area. Capillary to fibre ratios remained unchanged following hypoxia as did capillary density although there was a trend (non significant) towards an increase in capillary density. There were no significant increases in mitochondrial volume density or other morphometric parameters. These data indicate that chronic, severe hypoxia on its own does not result in an increase in absolute muscle capillary number or a de novo synthesis of mitochondria. The trends toward an increase in capillary density and mitochondrial volume density were interpreted as being secondary occurrences in response to the pronounced muscle atrophy which occurred.

Long-term high-protein diet induces biochemical and ultrastructural changes in rat liver mitochondria.

We have shown in previous work that long-term high-protein diet treatment (420 days) induces important biochemical and stereological changes in rat liver mitochondria. In this paper we have studied the time course for these changes in rats fed a high-protein diet for 30, 90, 180, and 420 days. The liver carbamoyl-phosphate synthetase I (ammonia), which represents 15-20% of the mitochondrial protein, increased ca. 2.5-fold in 30 days, with no further significant changes during the treatment. This increase was accompanied by an increment in the serum urea levels and a diminution in the half-life of blood urea, which could be interpreted as compensatory mechanisms for detoxification of blood and for maintaining osmotic pressure. The stereological study indicates that there is an enlargement of individual mitochondria in rats fed the high-protein diet, and that the maximum enlargement occurred at 90 days of treatment. The analysis of data shows, however, that the increase in mitochondrial volume density was due mainly to proliferation of normal mitochondria. These mitochondria were functionally normal as demonstrated by the unaltered P:O ratio during treatment. The total content of liver amino acids was increased, and the taurine/glycine ratio (which has been related to metabolic stress) was greatly increased. The possible correlation between the increases of both liver taurine levels and cell volume is discussed.

Low-temperature adaptation of oxidative energy production in cold-water fishes

This paper addresses the possibility that oxidative energy production in fish muscle is limited by low temperatures. Data are used from species that seasonally acclimatize to low temperatures, and from animals that have adapted to low temperatures over an evolutionary period. It is likely that the inhibitory effect of declining temperatures on the potential rate of oxidative energy production is compensated for largely by increasing the volume of mitochondria in the cell (volume density). For fishes that acclimatize, this increase in mitochondrial volume density may offset diffusion limitations. This is less likely for species that have adapted to low temperatures, because these animals have also developed large-diameter muscle cells. It is suggested that the stimuli for increasing cellular mitochondrial volume density, be they diffusion limitations or catalytic limitations, have not totally been overcome by increased mitochondrial volume density. In addition, a further restriction is concurrently placed upon maximum rates of oxygen uptake by the cell because the increase in mitochondrial volume density occurs at the expense of myofibrillar volume. This has the effect of reducing the maximum rate at which ATP can be used by working muscle.

Acute effects of endurance exercise on mitochondrial distribution and skeletal muscle morphology.

Biopsies of vastus lateralis from seven well-trained males were studied 1 month before and 15-30 min after a 100-km race. The distribution of interfibrillar mitochondria was analyzed to determine whether a long bout of exercise induced a redistribution of mitochondria. Capillary densities and mean fiber areas were also estimated. Capillary density and mean interfibrillar mitochondrial volume density were found to be significantly correlated with running time in the race. An earlier study on these biopsies found that the mean volume densities of interfibrillar and subsarcolemmal mitochondria did not change after a race, but the volume densities of lipid droplets and interfibrillar glycogen decreased significantly. In the present study, volume density of interfibrillar mitochondria [Vv(mi,fim)] before the race was highest with a value of 0.098 +/- 0.007 near the fiber border, and decreased progressively with distance to 0.045 +/- 0.004 at the fiber center. After the race, Vv(mi,fim) was unchanged at the fiber border, but was significantly higher (0.062 +/- 0.005) in the center of the fiber. This increase in mitochondrial volume density was attributable to the shrinkage of the fibers from consumption of energy stores, which was relatively greater for interfibrillar glycogen than for subsarcolemmal glycogen. Thus the primary effect of this extended bout of endurance exercise on vastus lateralis was the nearly complete depletion of the interfibrillar glycogen and lipids, but there was no evidence of an acute redistribution of mitochondria.

Quantitative analysis of muscle cell changes in compensatory hypertrophy and work-induced hypertrophy.

The cytological characteristics of two modes of muscle hypertrophy were studied in the extensor digitorum longus muscle of the rat. Comprensatory hypertrophy (CH) was produced by tenotomy of the tibialis anterior muscle and work-induced hypertrophy (WIH) was produced by forced swimming of the animal. While both methods produced an increase in muscle weight and cell size, these two parameters did not correlate. Morphometric analyses of the hypertrophied muscle cells demonstrated that in CH-muscle there was an increase in mitochondrial volume density, a decrease in myofibrillar volume density and no change in sarcotubular or nuclear volume density. WIH-muscle demonstrated an increase in sarcotubular volume density but no change in mitochondrial, myofibrillar or nuclear volume density. It is concluded that in CH-muscle, the cell volume increase is attributable to mitochondrial volume increase and that there is no increase in the contratile myofibrillar component of the cell. WIH-muscle, on the other hand, has a cell volume increase which is attributable to a proportional increase in these organelles.

Morphometric study of ultrastructural changes induced in rat liver by chronic alcohol intake.

Stereologic method was applied to the study of ultrastructural changes induced in rat liver by chronic ethanol feeding. In rats given alcohol (40% of total calories) for 8 to 9 months and an adequate diet, the following significant changes were observed: a 25% increase in mitochondrial volume density, a 34% decrease in rough endoplasmic reticulum surface density, a 54% increase in smooth endoplasmic reticulum density. The observed increase in surface density of the whole endoplasmic reticulum was slightly under the significant threshold. There was no increase in fat droplet volume density; this may be attributable to the low fat (7.5% of total calories) and high protein (17.9% of total calories) content of the diet.