Full Text

Turn on search term navigation

1. Introduction

Amyotrophic lateral sclerosis (ALS) is an incurable, chronic neurodegenerative disease characterized by selective death of motoneurons in the motor cortex, brainstem, and spinal cord, which controls muscle action [1]. This disease is phenotypically characterized by loss of muscle tone, paresis, muscle atrophy, and spasticity [2]. These degenerative changes result in the patient’s loss of overall ability to initiate and control voluntary movements, with the exception of the eyes. Approximately 90% of ALS is a sporadic form of disease (sALS), for which the etiology is unknown, and the remaining percentage is a genetically determined form (fALS). In clinical terms, both forms are virtually identical. Since 1993, the study of the etiology of fALS has focused on mutations in the gene encoding superoxide dismutase type 1 (SOD1), which occurs in nearly one-fifth of all cases of familial form of the disease [3,4]. The discovery of the role of mutations in the SOD1 gene in the etiology of ALS has contributed to constructing the most suitable animal test model of the disease (type fALS), containing the human SOD1 G93A transgene described by Gurney [5], where glycine is changed to alanine at position 93. The similarity in the course of ALS between the human and animal form allows the study of the pathomechanisms of the disease and testing the factors that may mitigate its course, or even extend the life span, in ALS animals. Notably, causes of neurodegeneration in ALS occur outside of the nervous system. Overexpression of hSOD1 G93A in skeletal muscle not only initiates motoneuron death [6], but also causes profound muscle atrophy [6,7]. Additional support for the view that muscle plays a key role in ALS pathogenesis has been provided by the observations that the destruction of neuromuscular junctions is linked to oxidative stress induced by tissue-specific breakdown of muscle mitochondria [8].

Identification of abnormalities in skeletal muscle at the early stage of ALS, preceding the onset of the disease, seems to be important for diagnosis and treatment of patients. Our previous study showed that skeletal muscle in rats bearing the hSOD1 G93A transgene already showed evidence of oxidative stress at the early stages of disease [9,10]. In addition, the ALS rats exhibited an impairment of insulin signaling and iron metabolism in the skeletal muscle that preceded muscle atrophy [11]. Other symptoms, observed in skeletal muscle, are characteristic for the early stage of disease including the upregulation of proteasome activity and autophagy activation [12], reduction of mechanical properties of gastrocnemius-soleus muscle group [13], the impairment of l-type Ca⁽²⁺⁾ channel—a key regulator of both mass and force of skeletal muscle [14]—loss of forelimb strength (grip test) [15], abnormal mitochondrial dynamics [16], and other morphological and functional mitochondria abnormalities [17].

Mitochondrial dysfunction and oxidative stress are associated with the development of neurodegenerative diseases [18,19,20,21,22,23]; however, the relationship between these factors and skeletal muscle strength dysfunction at the early stage of ALS is not completely understood.

Mitochondrial dysfunction has been observed in skeletal muscles of hSOD1 G93A mice, which are related to mutation in SOD1. SOD1 mutations are associated with misfolding and mislocalization of the SOD1 protein. While the normal SOD1 protein is usually found in the cytosol, mutant SOD1 accumulates within mitochondria and appears to contribute to many of the mitochondrial perturbations such as impaired adenosine triphosphate (ATP) production, altered calcium buffering, and initiation of apoptosis [24,25,26,27]. Luo et al. demonstrated that SOD1 G93A formed aggregates in mitochondria of skeletal muscle, and this aggregation led to mitochondrial depolarization, disruption of the mitochondrial network, and dynamics in skeletal muscle [16] Moreover, dysfunctional mitochondria can be a source of reactive oxygen species (ROS) generation and cellular oxidative stress [28,29,30]. In addition, Xiao et al. showed an increased ROS generation prior to the onset of ALS symptoms (at the age of 2 months), whereas the onset of ALS symptoms (at the age of four months) was associated with drastic increase in ROS generation [31]. Decrease in oxidative stress seems to be one of the most important strategies for treating ALS disease and other neuromuscular disorders [32,33,34]. Regulation of metal homeostasis and decrease in oxidative stress, similar to the benefits of swim training, leads to the prolongation of the lifespan of transgenic mice [35,36]. Deforges et al. [15] documented that swim training delays the onset of the first symptoms of the disease, sustains the motor function, and increases the life span of ALS mice by about 25 days. Similar results were obtained in our recent studies [36]. In contrast to running exercise, large-scale motoneurons are activated by swimming. The swimming-based program is a high frequency exercise associated with high hindlimb movement amplitude (373.9 ± 47.6 cycles min⁻¹ and 4.86 ± 0.40 cm), preferentially activating a sub-population of large motoneurons [37], which may play an important role in the protection of muscle fibers in ALS. Biochemical and physiological changes induced by exercise have been quite well defined. Data have shown that swimming exercise modifies mitochondria structure and function due to reduction of oxidative stress, improvement of mitochondrial bioenergetics, and regulation of the concentration of mitochondrial cholesterol [36,38,39].

We hypothesized that at the early stages of the disease, swim training is already a modulator of cellular metabolism via changing muscle bioenergetics, and modulating the oxidative stress can influence the reduction in muscle strength. We also proposed checking which of the parameters are correlated with the reduction in muscle strength in ALS mice, which may be used as potential biomarker of the early phase of the disease. Therefore, the aim of this study was to investigate the effects of swim training and ALS disease on mitochondrial bioenergetics, oxidative stress, and on changes in muscle strength of hSOD1 G93A mice at the early stage of the disease.

2. Results

The progression of ALS leads to muscle weakness and atrophy, which are associated with deterioration in muscle strength. Therefore, to assess the effects of swim training on the grip strength of ALS mice, we subjected both wild-type (WT) and hSOD1 G93A mouse groups to a regimen of exercise. Over time, untrained mice lost grip strength as a result of the progression of the disease. According to the expectations, we observed that swim training maintained the grip strength in ALS mice (Figure 1).

As we postulated that the decline in the bioenergetics in muscles is a factor favoring the progression of the disease, we decided to measure the activities of individual enzymes or protein complexes involved in oxidative metabolism. The activity of citrate synthase (CS), the first enzyme in the tricarboxylic acid (TCA) cycle, was reduced in the ALS I group of mice (0.385 ± 0.02 μmol/min/mg of protein), compared with the corresponding WT mice (0.540 ± 0.03 μmol/min/mg of protein) (Figure 2). Additionally, there was a small association of swim training with an increase in CS activity (ALS I SWIM vs. ALS I) (p = 0.0048, LSD post hoc test) (Figure 2).

The activity of total malate dehydrogenase (MDH) increased in the ALS I and ALS I SWIM groups (7.018 ± 0.21 and 5.982 ± 0.19 μmol/min/mg of protein, respectively) vs. the ALS 0 group (4.300 ± 0.09 μmol/min/mg of protein) (p = 0.0001) and corresponding WT group of mice (p = 0.0001). However, swim training was associated with a decrease in MDH activity (ALS I SWIM vs. ALS I) (p = 0.0003). No changes in MDH enzyme activity were observed in the WT groups of mice (Figure 3A). The activity of mitochondrial malate dehydrogenase (mMDH) increased in the ALS I and ALS I SWIM groups (4.685 ± 0.20 and 3.904 ± 0.17 μmol/min/mg of protein, respectively) vs. the ALS 0 group (3.265 ± 0.11 μmol/min/mg of protein) and corresponding WT group of mice. However, there was a swim-training-associated decrease in mMDH activity (ALS I SWIM vs. ALS I) (p = 0.0054). No changes in mitochondrial MDH activity were observed in the WT groups of mice (Figure 3B). The activity of cMDH increased in the ALS I and ALS I SWIM groups (2.333 ± 0.11 and 2.077 ± 0.11 μmol/min/mg of protein, respectively) vs. the ALS 0 group (1.166 ± 0.08 μmol/min/mg of protein) (p = 0.0001) and corresponding WT group of mice (p = 0.0001). The activity of cMDH was higher in WT I vs. WT 0 group of mice (Figure 3C).

Cytochrome c oxidase (COX) activity increased in the ALS I and ALS I SWIM groups (0.257 ± 0.01 and 0.243 ± 0.01 μmol/min/mg of protein, respectively) vs. the ALS 0 group (0.171 ± 0.01 μmol/min/mg of protein) (p = 0.0001) and corresponding WT group of mice (p = 0.0001). No changes in the activity of this enzyme were observed in the WT groups of mice (0.153 ± 0.01, 0.165 ± 0.01, and 0.166 ± 0.01 μmol/min/mg of protein in WT 0, WT I, and WT I SWIM, respectively) (Figure 4).

As MDH activity is correlated with COX activity (R = 0.84, p = 0.000002), we think that this is a compensatory response, whereby there are no alterations in mitochondrial respiration (Table 1). The grip strength was correlated only with the activity of CS (R = 0.68, p = 0.005).

Oxidative stress is another factor that accompanies the development of ALS. Therefore, we decided to measure the concentration of sulfhydryl (SH) groups in the skeletal muscle of ALS and WT mice. In symptomatic ALS mice (ALS I), we observed lower SH groups concentration compared with the ALS 0 group of mice (472.4 ± 23.96 and 579.9 ± 11.57 nmol/g of tissue, respectively) (p = 0.0019). The level of SH groups was also higher in ALS 0, as compared with the trained ALS mice (497.6 ± 21.92 nmol/g of tissue) (p = 0.0299) (Figure 5). There were no significant changes in the level of SH groups in any WT group of mice (586.0 ± 15.30, 552.2 ± 18.54 and 549.0 ± 16.02 nmol/g of tissue in WT 0, WT I, and WT I SWIM, respectively) (Figure 5). The concentration of SH groups was significantly correlated with COX activity (R = –0.79, p = 0.000003).

3. Discussion

In this study, we demonstrated that at the symptomatic stage of ALS, the mouse skeletal muscle experiences increased oxidative stress, changes in energy metabolism enzyme activities, and a significant reduction in muscle strength compared to WT animals and ALS mice without disease symptoms. Swim training significantly decreased the decline in muscle strength in ALS animals. For the first time, we indicated that only CS activity is correlated with changes in muscle strength in ALS animals with the first symptoms of the disease (Figure 6).

In the group of ALS mice showing the first symptoms of the disease, we noticed the mutual relations between COX and MDH activity and the level of SH groups and between COX and MDH isoenzymes activities.

3.1. Effect of ALS on Energy Metabolism and Oxidative Stress in Symptomatic ALS Mice

Decreased energy metabolism is a characteristic sign of ALS disease [40]. Reduced activity of the TCA cycle, glucose metabolism, the level of TCA C4 intermediates and mitochondrial respiration, as well as ATP production by oxidative phosphorylation (OXPHOS) system lead to defects in skeletal muscle energy metabolism of ALS mice, and are some of the important factors of disease progression [40]. For this reason, we measured mitochondrial bioenergetics parameters in skeletal muscle of WT and ALS mice. Our data showed that the function of the electron transport chain (ETC) did not differ in the studied groups, but significant changes were observed in CS, MDH, and COX activities. Conversely, we showed that bioenergetics of mitochondria in skeletal muscle of hSOD1 G93A mice were significantly reduced in mice at the terminal stage of disease compared to WT and asymptomatic groups of mice. Decreased CS and elevated COX activities were also observed in skeletal muscle of the ALS mice at the terminal stage [36]. Tefera et al. demonstrated that, even at the first stage of the disease, the mRNA levels of other TCA enzymes, e.g., 2-oxoglutarate (OGDH) and succinate dehydrogenases, were significantly reduced but has no significant changes in OGDH activity [40]. Decreased activity of CS was noticed in muscle from ALS patients compared with healthy controls [41,42]. CS activity is generally used as a marker of mitochondrial content [43], but activity of this enzyme is limited by the availability of oxaloacetate (OAA) [40]. Reduced glucose metabolism in skeletal muscle of hSOD1 G93A mice, reported by Charbonnier [26], may help understand the changes in enzymatic activity. In ALS, reduced CS activity may be related to impaired glucose metabolism and decreased availability of OAA, which may not necessarily reflect the true amount of mitochondrial content in the muscles.

Other parameters describing mitochondrial bioenergetic efficiency and oxidative capacity, OXPHOS coupling efficiency (OCE), and MDH and COX activity were not in the line with changes in CS activity in the skeletal muscle of ALS mice. The lack of changes in OCE suggests that the ETC system is still coupled and can function, owning to the alternative process of proton supplying to the respiratory chain at the symptomatic stage of disease. Hydrogen can be alternatively sourced from amino acids (glutamate, isoleucine, and valine) [40]; however, the concentration of amino acids was not measured in this study. OCE (1−oxygen consumption before ADP and after ADP addition) is an indirect measurement of the ADP/ATP ratio [44]. Sustained function of mitochondrial respiration is in agreement with COX activity. We showed that significant elevation of the enzyme activity was also seen at the terminal stage of disease, as well as by increased protein content of COX subunits [36]. To the best of our knowledge, there are no data showing COX activity in mouse skeletal muscle in the hSOD1 G93A model compared to the control group. However, in skeletal muscle in patients with ALS, lower values of this enzyme activity were recorded [41,42]. These discrepancies may be due to the differences between the animal model of the disease and patients with ALS. The ratio of COX to CS activity at 0.5 to 0.7 AU in ALS groups corresponds to that described by Patel et al. [45] and confirms the discrepancy in the directions of changes for the activity of both oxygen metabolism enzymes following ALS.

As mentioned above, CS activity is limited by the availability of OAA [40]. To check whether under the condition of disturbed glucose metabolism the compensatory delivery of this metabolite from malate occurs, and whether further steps of the TCA cycle are maintained, we measured the activity of MDH. The increased activity of MDH isoenzymes in skeletal muscle of ALS mice compared with WT was observed. Notably, an increase in the activity of MDH and COX in the skeletal muscle of ALS mice was accompanied by a decrease in CS activity. According to Tefera et al. (2016) [40], maintaining the ATP production capacity by mitochondria appears to be neuroprotective and delays muscle wasting. The compensatory mechanism resulting in an increase in MDH activity seems to maintain the production of OAA in the muscles, and thus the Krebs cycle. This, in turn, supplies hydrogen to the respiratory chain and for the production of ATP. The lack of changes in OXPHOS coupling efficiency seen in our experiments confirms the potential compensation mechanism in mitochondrial bioenergetics.

Mitochondria, in addition to the bioenergetic function, under pathological conditions are also considered as the main cellular source of free radicals generation and oxidative stress [28,29,30]. The presence of the oxidative stress in ALS has been repeatedly reported [10,30]. In the present study, we also documented the decreased concentration of SH groups in ALS mice at the symptomatic stage of the disease, supporting the similar observation obtained in the skeletal muscle of ALS animals during the progression of disease [10,11,22,36]. We found a significant negative correlation between COX and MDH activities and SH group level in the ALS groups. Our data may suggest that increased oxygen energy metabolism in ALS animals is accompanied by increased ROS generation and elevated oxidative stress in the skeletal muscle of hSOD1 G93A mice.

Tefera et al. suggested that TCA in skeletal muscle might be slowed in hSOD1 G93A mice with concomitant decrease in muscle strength [40]. As such, we ascertained which of the markers of mitochondrial bioenergetics are correlated with changes in skeletal muscle strength and whether swim training influences these parameters at the symptomatic stage of the disease.

3.2. Effect of Swim Training on Changes in Muscle Strength, Oxidative Stress, and Energy Metabolism in Symptomatic ALS Mice

Swim training increases the lifespan of hSOD1 G93A mice by about 10%–13% [15,36]. From a clinical point of view, not only prolongation of lifespan, but also sustained functionality and inhibition of muscle waste are critical elements of therapy. In agreement with previously published data, swim training significantly decreases the reduction in muscle strength clearly visible at the symptomatic stage of ALS [15]. Swim training is characterized by non-weight bearing exercises that minimize damage to muscle fibers [46], reduces oxidative stress, and improves muscle energy metabolism at terminal stage of the disease [36]. However, swim training had no significant effect on oxidative stress or MDH and COX activity, and had no influence on oxygen consumption by mitochondrial respiratory chain at the symptomatic stage of the disease. Conversely, CS activity in skeletal muscle of ALS mice was significantly higher as a result of swim training and was significantly positively correlated with the muscle strength test. There are no data showing the effect of swim training on COX activity in the skeletal muscle of ALS mice.

4. Materials and Methods 4.1. Animals

The experiments with animals (project No. 2013/09/NZ7/02538) were approved by the Local Ethics Committee (Resolution No. 11/2013 of 22 April 2013) and in accordance with the approval of the Polish Ministry of the Environment (Decision No. 155/2012).

Transgenic male mice with the G93A human SOD1 mutation B6SJL-Tg (SOD1^G93A) 1Gur/J (ALS mice) (n = 24) and wild-type male mice B6SJL (n = 24) were purchased from The Jackson Laboratory (Bar Harbor, ME, USA). The mice were housed in an environmentally controlled room (23 ± 1 °C with a 12 h light/dark cycle); the mice received standard mice chow and water ad libitum. After acclimatization, the mice were randomly divided into the following groups according to disease progression and training status: ALS 0: ALS untrained mice with no visible signs of the disease (n = 8), ALS I: ALS untrained (n = 8), and ALS I SWIM: and ALS trained mice (n = 8). Corresponding groups of wild-type (WT) untrained and trained mice were created: WT 0: WT untrained mice (n = 8), WT I: WT untrained mice (n = 8), and WT I SWIM: WT trained mice (n = 8).

The mice were euthanized by cervical dislocation. The mice from the ALS 0 and WT 0 groups were euthanized on the 70th day of life. The mice from the ALS I group were euthanized when we observed the first symptoms of disease (116 ± 2 days of life). The ALS I SWIM, WT I, and WT I SWIM mice were euthanized at the same age as the ALS I group.

4.2. Swim Training Protocol

Starting at 10 weeks of age, the transgenic (group ALS I SWIM) and the control mice (group WT I SWIM) underwent the training procedure according to Deforges et al. [15] with slight modification described by Flis et al. [36].

4.3. Grip Strength

Grip strength (n = 8 in each group) was tested once a week between 70 and 105 days of life. The time during which the animals were able to sustain their weight holding onto a metal rail suspended midair was recorded, with the maximum time being 180 s. Each mouse was subjected to three trials with a resting period between tests.

4.4. Isolation of Skeletal Muscle Mitochondria

The thigh muscle mitochondria were isolated, as previously described by Makinen and Lee [47] with slight modifications described by Flis et al. [36]. The muscles were rapidly removed, trimmed of visible connective tissue, weighed, and placed in 10 mL of ice-cold mitochondrial isolation buffer A (100 mM KCl, 50 mM Tris, 5 mM MgCl₂, 5 mM EDTA, pH 7.4). The muscles were minced with scissors, incubated for 1 min with protease (10 mL of isolation buffer per 1 g of tissue, supplemented with protease (0.2 mg/mL)). After 1 min. of incubation, the same volume of buffer A was added and homogenized using a Teflon pestle homogenizer. The homogenate was centrifuged at 700× g for 10 min. The supernatant was decanted and centrifuged at 4 000× g for 10 min. The mitochondrial pellet was resuspended in 30 mL of suspension buffer B (100 mM KCl, 50 mM Tris, 1 mM MgCl₂, 1 mM EDTA, pH 7.4, supplemented with 0.5 % BSA) and centrifuged at 10,000× g for 10 min. After this washing step had been repeated twice, the final mitochondrial pellet was resuspended in buffer MRB (250 mM mannitol, 5 mM HEPES, 0.5 mM EGTA, pH 7.4) (skeletal muscle mass (mg) × 0.2 mL). All the steps were performed at 4 °C.

4.5. High-Resolution Respirometry

Respiration was measured at 37 °C in a high-resolution respirometer (Oroboros, Oxygraph; Innsbruck, Austria) according to [36]. Freshly isolated skeletal muscle mitochondria (0.1 mg of mitochondrial protein) were added to 2 mL of the respiration medium (110 mM sucrose, 60 mM K-lactobionate, 0.5 mM EGTA, 0.1 % BSA essentially fatty acid free, 3 mM MgCl₂, 20 mM taurine, 10 mM KH₂PO₄, 20 mM K-HEPES, pH 7.1). For the assessment of mitochondrial respiration, the following protocol was used: (1) Non-phosphorylating LEAK respiration was assessed by injecting 2 mM L-malic acid (neutralized with KOH) as NADH (N)-linked substrates, called state NL; (2) OXPHOS capacity was induced by adding 5 mM ADP and 10 mM of glutamic acid (neutralized with KOH), called state NP; and (3) OXPHOS coupling efficiency (OCE), calculated with the formula (1 − (state NL)/(state NP)), reflects the coupling of respiration supported by electron transferring flavoprotein (ETF) with malate as substrate before (state NL) and after the addition of ADP and glutamic acid (state NP). The OCE was calculated as a measure of mitochondrial quality and control.

4.6. Measurement of Cytochrome c Oxidase, Citrate Synthase and Malate Dehydrogenase Activities

All enzymes activities were measured spectrophotometrically (Cecil CE9200, Cecil Instruments Limited, Cambridge, UK) in thigh muscles homogenates. The enzymes activities are expressed as μmol/minute/mg of protein. The cytochrome c oxidase (COX) activity was measured at 37 °C, according to Reference [48]. Briefly, 20 μL of homogenate (1:10, 5%) was incubated for 2 min in 960 μL of buffer (10 mM potassium phosphate buffer, 0.01% Triton-X100, pH 7.2). Next 20 μL of reduced cytochrome c was added to initiate the reaction. The reactions were conducted in duplicate and absorbance was read at 550 nm.

The citrate synthase (CS) activity was measured at 37 °h in duplicate according to Reference [49]. Briefly, 10 μL of homogenate (1:10, 5%) was incubated for 2 min in 970 μL of buffer (50 mM Tris-HCl, 1 mM EDTA, 0.01% Triton-X100, pH 7.8) supplemented with 10 μL of freshly made DTNB (10 mM) and 10 μL acetylCoA (50 mM). Next 10 μL of freshly made oxaloacetic acid (10 mM) was added to initiate the reaction. The reactions were conducted in duplicate and absorbance was read at 412 nm.

The malate dehydrogenase (MDH) activity was measured at 30 °C according to [50]. Briefly, 10 μL of homogenate (1:10, 5%) was incubated for 2 min in 970 μL of buffer (50 mM Tris-HCl, 5 mM EDTA, 0.01% Triton-X100, pH 7.6) supplemented with 10 μL of freshly made NADH (20 mM). Next 8.5 μL of freshly made oxaloacetic acid (20 mM) was added to initiate the reaction. The reactions were conducted in duplicate and absorbance was read at 340 nm. The mitochondrial MDH (mMDH) activity was assessed after 2 min preincubation of 20 μL homogenate (1:10, 5%) with 98% ethanol (1:1 vol). The cytosolic MDH (cMDH) was calculated as the difference between MDH and mMDH activities.

4.7. Manifestation of Oxidative Stress

The sulfhydryl groups (SH) [51] were measured in the skeletal muscles homogenates. Briefly, 20 μL of homogenate (5%) was added to 200 μL of buffer (10 mM potassium phosphate buffer, pH 8.0). Next 30 μL of SDS (10 %) and 30 μL of DTNB (1 mM) were added. The measurements were conducted in duplicate. After this, the probes were mixed and incubated for 30 min in 37 °C. The absorbance was measured at 412 nm in microplate reader Thermo Scientific Multiscan Go (ThermoFisher Scientific, Vartaa, Finland). The values of the sulfhydryl groups (mmol/g of tissue) were calculated against sample blank (without DTNB) from the standard curve of reduced glutathione.

4.8. Data Analysis

Statistical analyses were performed using a software package Statistica v. 13.0 (StatSoft Inc., Tulsa, OK, USA). The results are expressed as the mean ± standard error (SE). The differences between the group means for tissue-based assays were performed using two-way ANOVA. The changes in mean scores of grip strength over time points were tested using the repeated measures ANOVA. If a difference was detected in the ANOVA model, the significant differences were determined using the Tukey’s post-hoc test. To verify the significance of the small, swim training associated changes (ALS TER vs. ALS SWIM), the Least Significant Difference (LSD) post-hoc test was used. The results were considered statistically significant when p < 0.05. A Pearson product-moment correlation coefficient was computed to assess the relationship between obtained results.

5. Conclusions

Amyothropic lateral sclerosis disease significantly reduces the muscle strength even at the early stage of the disease. ALS is also related to increased oxidative stress and modulation of muscle metabolism. Swim training significantly slows the reduction in muscle strength and increases CS activity in skeletal muscle. Our findings indicate that swim training is a modulator of skeletal muscle energy metabolism with concomitant improvement of skeletal muscle function in ALS mice (Figure 6).

View Image - Figure 1. The effects of swim training on grip strength in the ALS mice. Swim training maintained grip strength in ALS mice. There were significant differences between the groups: * p <0.05 vs. symptomatic ALS mice (ALS I), # p <0.05 vs. ALS I SWIM; A p <0.05, between the indicated time points and 11 week in ALS I group (LSD post hoc test). The data are presented as the means ± SEM (n = 8 in each group). (n = 8 for each group).

Figure 1. The effects of swim training on grip strength in the ALS mice. Swim training maintained grip strength in ALS mice. There were significant differences between the groups: * p <0.05 vs. symptomatic ALS mice (ALS I), # p <0.05 vs. ALS I SWIM; A p <0.05, between the indicated time points and 11 week in ALS I group (LSD post hoc test). The data are presented as the means ± SEM (n = 8 in each group). (n = 8 for each group).

View Image - Figure 2. Citrate synthase activity in skeletal muscle of ALS and WT mice. Citrate synthase (CS) was measured in skeletal muscle homogenates. There were significant differences between the groups: * p = 0.0048, # p = 0.0075 vs. ALS I SWIM (LSD post hoc test); a p = 0.0007 between the indicated ALS and corresponding WT groups. The data are presented as the means ± SEM (n = 8 in each group).

Figure 2. Citrate synthase activity in skeletal muscle of ALS and WT mice. Citrate synthase (CS) was measured in skeletal muscle homogenates. There were significant differences between the groups: * p = 0.0048, # p = 0.0075 vs. ALS I SWIM (LSD post hoc test); a p = 0.0007 between the indicated ALS and corresponding WT groups. The data are presented as the means ± SEM (n = 8 in each group).

View Image - Figure 3. Malate dehydrogenase activity in skeletal muscle of ALS and WT mice. Total malate dehydrogenase (MDH) (A), mitochondrial malate dehydrogenase (mMDH) (B), and cytosolic malate dehydrogenase (cMDH) (C) were measured in skeletal muscle homogenates. There were significant differences between the groups: * p = 0.0001 vs. ALS 0, # p = 0.0054 vs. ALS I, $ p = 0.0357 vs. ALS 0, & p = 0.04 vs. WT 0; a p = 0.000, b p = 0.0009 between the indicated ALS and corresponding WT groups. The data are presented as the means ± SEM (n = 8 in each group).

Figure 3. Malate dehydrogenase activity in skeletal muscle of ALS and WT mice. Total malate dehydrogenase (MDH) (A), mitochondrial malate dehydrogenase (mMDH) (B), and cytosolic malate dehydrogenase (cMDH) (C) were measured in skeletal muscle homogenates. There were significant differences between the groups: * p = 0.0001 vs. ALS 0, # p = 0.0054 vs. ALS I, $ p = 0.0357 vs. ALS 0, & p = 0.04 vs. WT 0; a p = 0.000, b p = 0.0009 between the indicated ALS and corresponding WT groups. The data are presented as the means ± SEM (n = 8 in each group).

View Image - Figure 4. Cytochrome c oxidase activity in skeletal muscle of ALS and WT mice. The activity of COX was measured in skeletal muscle homogenates. There were significant differences between the groups: * p = 0.0001 vs. ALS 0; a p = 0.0001 between the indicated ALS and corresponding WT groups. The data are presented as the means ± SEM (n = 8 in each group).

Figure 4. Cytochrome c oxidase activity in skeletal muscle of ALS and WT mice. The activity of COX was measured in skeletal muscle homogenates. There were significant differences between the groups: * p = 0.0001 vs. ALS 0; a p = 0.0001 between the indicated ALS and corresponding WT groups. The data are presented as the means ± SEM (n = 8 in each group).

View Image - Figure 5. Oxidative stress parameters (sulfhydryl groups) in skeletal muscle homogenates of the ALS and WT mice. Sulfhydryl groups were measured in skeletal muscle homogenates. There were significant differences between the groups: * p = 0.0019 vs. ALS 0, # p = 0.03 vs. ALS 0; and a p = 0.038 between the indicated ALS and corresponding WT groups. The data are presented as the means ± SEM (n = 8 in each group).

Figure 5. Oxidative stress parameters (sulfhydryl groups) in skeletal muscle homogenates of the ALS and WT mice. Sulfhydryl groups were measured in skeletal muscle homogenates. There were significant differences between the groups: * p = 0.0019 vs. ALS 0, # p = 0.03 vs. ALS 0; and a p = 0.038 between the indicated ALS and corresponding WT groups. The data are presented as the means ± SEM (n = 8 in each group).

View Image - Figure 6. Skeletal muscle mitochondrial energy metabolism modulation in ALS untrained and ALS swim-trained mice, based on Desseille et al. [26], Tefera et al. [40] and our results. Black arrows indicate changes observed in skeletal muscle of ALS mice at symptomatic stage of disease vs. ALS 0 or WT. Red arrows indicate swim-training-induced changes in skeletal muscle of ALS mice at symptomatic stage of disease vs. untrained symptomatic ALS mice. ↑-increased; ↓-decreased; ---no changes. CS-citrate synthase, IDH-Isocitrate dehydrogenase, OGDH-2-oxoglutarate dehydrogenase, MDH-malate dehydrogenase, I, II, III, IV-complexes of mitochondrial electron transfer chain.

Figure 6. Skeletal muscle mitochondrial energy metabolism modulation in ALS untrained and ALS swim-trained mice, based on Desseille et al. [26], Tefera et al. [40] and our results. Black arrows indicate changes observed in skeletal muscle of ALS mice at symptomatic stage of disease vs. ALS 0 or WT. Red arrows indicate swim-training-induced changes in skeletal muscle of ALS mice at symptomatic stage of disease vs. untrained symptomatic ALS mice. ↑-increased; ↓-decreased; ---no changes. CS-citrate synthase, IDH-Isocitrate dehydrogenase, OGDH-2-oxoglutarate dehydrogenase, MDH-malate dehydrogenase, I, II, III, IV-complexes of mitochondrial electron transfer chain.

	WT			ALS
	0	I	I SWIM	0	I	I SWIM
state NL	27.86 ± 2.06	29.43 ± 1.18	30.06 ± 1.96	23.87 ± 1.78	28.96 ± 1.12	29.84 ± 1.16
state NP	410.1 ± 38.53	492.5 ± 19.78	434.6 ± 47.36	371.4 ± 41.26	424.2 ± 38.54	379.7 ± 29.95
OCE	0.930 ± 0.006	0.931 ± 0.007	0.933 ± 0.008	0.920 ± 0.013	0.920 ± 0.010	0.928 ± 0.005

Author Contributions

Conceptualization, D.J.F. and W.Z.; Formal analysis, D.J.F., K.D., J.J.K., K.C., M.H.-G., J.A., M.R.W. and W.Z.; Funding acquisition, W.Z.; Investigation, D.J.F., K.D., J.J.K., K.C. and W.Z.; Supervision, J.J.K. and W.Z.; Validation, D.J.F., K.D. and J.J.K.; Visualization, D.J.F.; Writing-original draft, D.J.F. and W.Z.; Writing-review & editing, K.D., J.J.K., K.C., M.H.-G., J.A. and M.R.W.

Acknowledgments

This study was supported by grants from the National Science Centre, Poland (DEC-2013/09/NZ7/02538) and Polish Ministry of Science and Higher Education (DSRiK/2018).

Conflicts of Interest

The authors declared that there is no conflict of interest regarding the publication of this article.

© 2019 by the authors. Licensee MDPI, Basel, Switzerland. This article is an open access article distributed under the terms and conditions of the Creative Commons Attribution (CC BY) license (http://creativecommons.org/licenses/by/4.0/).

References

1. Andersen, P.M. Amyotrophic lateral sclerosis associated with mutations in the CuZn superoxide dismutase gene. Curr. Neurol. Neurosci. Rep. 2006, 6, 37-46.

2. Rowland, L.P. Diagnosis of amyotrophic lateral sclerosis. J. Neurol. Sci. 1998, 160 (Suppl. 1), S6-S24.

3. Rosen, D.R.; Siddique, T.; Patterson, D.; Figlewicz, D.A.; Sapp, P.; Hentati, A.; Donaldson, D.; Goto, J.; O'Regan, J.P.; Deng, H.X.; et al. Mutations in Cu/Zn superoxide dismutase gene are associated with familial amyotrophic lateral sclerosis. Nature 1993, 362, 59-62.

4. Pansarasa, O.; Bordoni, M.; Diamanti, L.; Sproviero, D.; Gagliardi, S.; Cereda, C. SOD1 in Amyotrophic Lateral Sclerosis: "Ambivalent" Behavior Connected to the Disease. Int. J. Mol. Sci. 2018, 19.

5. Gurney, M.E.; Pu, H.; Chiu, A.Y.; Dal Canto, M.C.; Polchow, C.Y.; Alexander, D.D.; Caliendo, J.; Hentati, A.; Kwon, Y.W.; Deng, H.X.; et al. Motor neuron degeneration in mice that express a human Cu,Zn superoxide dismutase mutation. Science 1994, 264, 1772-1775.

6. Wong, M.; Martin, L.J. Skeletal muscle-restricted expression of human SOD1 causes motor neuron degeneration in transgenic mice. Hum. Mol. Genet. 2010, 19, 2284-2302. [Green Version]

7. Dobrowolny, G.; Aucello, M.; Rizzuto, E.; Beccafico, S.; Mammucari, C.; Boncompagni, S.; Belia, S.; Wannenes, F.; Nicoletti, C.; Del Prete, Z.; et al. Skeletal muscle is a primary target of SOD1G93A-mediated toxicity. Cell Metab. 2008, 8, 425-436.

8. Dupuis, L.; Gonzalez de Aguilar, J.L.; Echaniz-Laguna, A.; Eschbach, J.; Rene, F.; Oudart, H.; Halter, B.; Huze, C.; Schaeffer, L.; Bouillaud, F.; et al. Muscle mitochondrial uncoupling dismantles neuromuscular junction and triggers distal degeneration of motor neurons. PLoS ONE 2009, 4, e5390.

9. Halon, M.; Sielicka-Dudzin, A.; Wozniak, M.; Ziolkowski, W.; Nyka, W.; Herbik, M.; Grieb, P.; Figarski, A.; Antosiewicz, J. Up-regulation of ferritin ubiquitination in skeletal muscle of transgenic rats bearing the G93A hmSOD1 gene mutation. Neuromuscul. Disord. NMD 2010, 20, 29-33.

10. Halon, M.; Kaczor, J.J.; Ziolkowski, W.; Flis, D.J.; Borkowska, A.; Popowska, U.; Nyka, W.; Wozniak, M.; Antosiewicz, J. Changes in skeletal muscle iron metabolism outpace amyotrophic lateral sclerosis onset in transgenic rats bearing the G93A hmSOD1 gene mutation. Free Radic. Res. 2014, 48, 1363-1370.

11. Halon-Golabek, M.; Borkowska, A.; Kaczor, J.J.; Ziolkowski, W.; Flis, D.J.; Knap, N.; Kasperuk, K.; Antosiewicz, J. hmSOD1 gene mutation-induced disturbance in iron metabolism is mediated by impairment of Akt signalling pathway. J. Cachexia Sarcopenia Muscle 2018.

12. Olivan, S.; Calvo, A.C.; Gasco, S.; Munoz, M.J.; Zaragoza, P.; Osta, R. Time-Point Dependent Activation of Autophagy and the UPS in SOD1G93A Mice Skeletal Muscle. PLoS ONE 2015, 10, e0134830.

13. Dibaj, P.; Schomburg, E.D.; Steffens, H. Contractile characteristics of gastrocnemius-soleus muscle in the SOD1G93A ALS mouse model. Neurol. Res. 2015, 37, 693-702.

14. Beqollari, D.; Romberg, C.F.; Dobrowolny, G.; Martini, M.; Voss, A.A.; Musaro, A.; Bannister, R.A. Progressive impairment of CaV1.1 function in the skeletal muscle of mice expressing a mutant type 1 Cu/Zn superoxide dismutase (G93A) linked to amyotrophic lateral sclerosis. Skelet Muscle 2016, 6, 24.

15. Deforges, S.; Branchu, J.; Biondi, O.; Grondard, C.; Pariset, C.; Lecolle, S.; Lopes, P.; Vidal, P.P.; Chanoine, C.; Charbonnier, F. Motoneuron survival is promoted by specific exercise in a mouse model of amyotrophic lateral sclerosis. J. Physiol. 2009, 587, 3561-3572. [Green Version]

16. Luo, G.; Yi, J.; Ma, C.; Xiao, Y.; Yi, F.; Yu, T.; Zhou, J. Defective mitochondrial dynamics is an early event in skeletal muscle of an amyotrophic lateral sclerosis mouse model. PLoS ONE 2013, 8, e82112.

17. Dupuis, L.; Gonzalez de Aguilar, J.L.; Oudart, H.; de Tapia, M.; Barbeito, L.; Loeffler, J.P. Mitochondria in amyotrophic lateral sclerosis: A trigger and a target. Neurodegener. Dis. 2004, 1, 245-254.

18. Chen, D.; Wang, Y.; Chin, E.R. Activation of the endoplasmic reticulum stress response in skeletal muscle of G93A*SOD1 amyotrophic lateral sclerosis mice. Front. Cell. Neurosci. 2015, 9, 170.

19. Watanabe, S.; Ilieva, H.; Tamada, H.; Nomura, H.; Komine, O.; Endo, F.; Jin, S.; Mancias, P.; Kiyama, H.; Yamanaka, K. Mitochondria-associated membrane collapse is a common pathomechanism in SIGMAR1- and SOD1-linked ALS. EMBO Mol. Med. 2016, 8, 1421-1437.

20. Mahoney, D.J.; Kaczor, J.J.; Bourgeois, J.; Yasuda, N.; Tarnopolsky, M.A. Oxidative stress and antioxidant enzyme upregulation in SOD1-G93A mouse skeletal muscle. Muscle Nerve 2006, 33, 809-816.

21. Martin, L.J.; Fancelli, D.; Wong, M.; Niedzwiecki, M.; Ballarini, M.; Plyte, S.; Chang, Q. GNX-4728, a novel small molecule drug inhibitor of mitochondrial permeability transition, is therapeutic in a mouse model of amyotrophic lateral sclerosis. Front. Cell. Neurosci. 2014, 8, 433.

22. Martin, L.J. The mitochondrial permeability transition pore: A molecular target for amyotrophic lateral sclerosis therapy. Biochim. Biophys. Acta 2010, 1802, 186-197. [Green Version]

23. Szymanski, J.; Janikiewicz, J.; Michalska, B.; Patalas-Krawczyk, P.; Perrone, M.; Ziolkowski, W.; Duszynski, J.; Pinton, P.; Dobrzyn, A.; Wieckowski, M.R. Interaction of Mitochondria with the Endoplasmic Reticulum and Plasma Membrane in Calcium Homeostasis, Lipid Trafficking and Mitochondrial Structure. Int. J. Mol. Sci. 2017, 18.

24. Derave, W.; Van Den Bosch, L.; Lemmens, G.; Eijnde, B.O.; Robberecht, W.; Hespel, P. Skeletal muscle properties in a transgenic mouse model for amyotrophic lateral sclerosis: Effects of creatine treatment. Neurobiol. Dis. 2003, 13, 264-272.

25. Browne, S.E.; Bowling, A.C.; Baik, M.J.; Gurney, M.; Brown, R.H., Jr.; Beal, M.F. Metabolic dysfunction in familial, but not sporadic, amyotrophic lateral sclerosis. J. Neurochem. 1998, 71, 281-287.

26. Desseille, C.; Deforges, S.; Biondi, O.; Houdebine, L.; D'Amico, D.; Lamaziere, A.; Caradeuc, C.; Bertho, G.; Bruneteau, G.; Weill, L.; et al. Specific Physical Exercise Improves Energetic Metabolism in the Skeletal Muscle of Amyotrophic-Lateral- Sclerosis Mice. Front. Mol. Neurosci. 2017, 10, 332.

27. Bowling, A.C.; Schulz, J.B.; Brown, R.H., Jr.; Beal, M.F. Superoxide dismutase activity, oxidative damage, and mitochondrial energy metabolism in familial and sporadic amyotrophic lateral sclerosis. J. Neurochem. 1993, 61, 2322-2325.

28. Mancuso, C.; Scapagini, G.; Curro, D.; Giuffrida Stella, A.M.; De Marco, C.; Butterfield, D.A.; Calabrese, V. Mitochondrial dysfunction, free radical generation and cellular stress response in neurodegenerative disorders. Front. Biosci. 2007, 12, 1107-1123.

29. Bhat, A.H.; Dar, K.B.; Anees, S.; Zargar, M.A.; Masood, A.; Sofi, M.A.; Ganie, S.A. Oxidative stress, mitochondrial dysfunction and neurodegenerative diseases; a mechanistic insight. Biomed. Pharmacother. 2015, 74, 101-110.

30. Guo, C.; Sun, L.; Chen, X.; Zhang, D. Oxidative stress, mitochondrial damage and neurodegenerative diseases. Neural Regen. Res. 2013, 8, 2003-2014.

31. Xiao, Y.; Karam, C.; Yi, J.; Zhang, L.; Li, X.; Yoon, D.; Wang, H.; Dhakal, K.; Ramlow, P.; Yu, T.; et al. ROS-related mitochondrial dysfunction in skeletal muscle of an ALS mouse model during the disease progression. Pharmacol. Res. 2018, 138, 25-36.

32. Barber, S.C.; Mead, R.J.; Shaw, P.J. Oxidative stress in ALS: A mechanism of neurodegeneration and a therapeutic target. Biochim. Biophys. Acta 2006, 1762, 1051-1067. [Green Version]

33. Weishaupt, J.H.; Bartels, C.; Polking, E.; Dietrich, J.; Rohde, G.; Poeggeler, B.; Mertens, N.; Sperling, S.; Bohn, M.; Huther, G.; et al. Reduced oxidative damage in ALS by high-dose enteral melatonin treatment. J. Pineal Res. 2006, 41, 313-323.

34. Gandhi, S.; Abramov, A.Y. Mechanism of oxidative stress in neurodegeneration. Oxid. Med. Cell. Longev. 2012, 2012, 428010.

35. Tokuda, E.; Furukawa, Y. Copper Homeostasis as a Therapeutic Target in Amyotrophic Lateral Sclerosis with SOD1 Mutations. Int. J. Mol. Sci. 2016, 17.

36. Flis, D.J.; Dzik, K.; Kaczor, J.J.; Halon-Golabek, M.; Antosiewicz, J.; Wieckowski, M.R.; Ziolkowski, W. Swim Training Modulates Skeletal Muscle Energy Metabolism, Oxidative Stress, and Mitochondrial Cholesterol Content in Amyotrophic Lateral Sclerosis Mice. Oxid. Med. Cell. Longev. 2018, 2018, 5940748.

37. Grondard, C.; Biondi, O.; Pariset, C.; Lopes, P.; Deforges, S.; Lecolle, S.; Gaspera, B.D.; Gallien, C.L.; Chanoine, C.; Charbonnier, F. Exercise-induced modulation of calcineurin activity parallels the time course of myofibre transitions. J. Cell. Physiol. 2008, 214, 126-135.

38. Flis, D.J.; Olek, R.A.; Kaczor, J.J.; Rodziewicz, E.; Halon, M.; Antosiewicz, J.; Wozniak, M.; Gabbianelli, R.; Ziolkowski, W. Exercise-Induced Changes in Caveolin-1, Depletion of Mitochondrial Cholesterol, and the Inhibition of Mitochondrial Swelling in Rat Skeletal Muscle but Not in the Liver. Oxid. Med. Cell. Longev. 2016, 2016, 3620929.

39. Ziolkowski, W.; Vadhana, M.S.D.; Kaczor, J.J.; Olek, R.A.; Flis, D.J.; Halon, M.; Wozniak, M.; Fedeli, D.; Carloni, M.; Antosiewicz, J.; et al. Exercise-induced heart mitochondrial cholesterol depletion influences the inhibition of mitochondrial swelling. Exp. Physiol. 2013, 98, 1457-1468. [Green Version]

40. Tefera, T.W.; Wong, Y.; Barkl-Luke, M.E.; Ngo, S.T.; Thomas, N.K.; McDonald, T.S.; Borges, K. Triheptanoin Protects Motor Neurons and Delays the Onset of Motor Symptoms in a Mouse Model of Amyotrophic Lateral Sclerosis. PLoS ONE 2016, 11, e0161816.

41. Russell, A.P.; Wada, S.; Vergani, L.; Hock, M.B.; Lamon, S.; Leger, B.; Ushida, T.; Cartoni, R.; Wadley, G.D.; Hespel, P.; et al. Disruption of skeletal muscle mitochondrial network genes and miRNAs in amyotrophic lateral sclerosis. Neurobiol. Dis. 2013, 49, 107-117.

42. Crugnola, V.; Lamperti, C.; Lucchini, V.; Ronchi, D.; Peverelli, L.; Prelle, A.; Sciacco, M.; Bordoni, A.; Fassone, E.; Fortunato, F.; et al. Mitochondrial respiratory chain dysfunction in muscle from patients with amyotrophic lateral sclerosis. Arch. Neurol. 2010, 67, 849-854.

43. Larsen, S.; Nielsen, J.; Hansen, C.N.; Nielsen, L.B.; Wibrand, F.; Stride, N.; Schroder, H.D.; Boushel, R.; Helge, J.W.; Dela, F.; et al. Biomarkers of mitochondrial content in skeletal muscle of healthy young human subjects. J. Physiol. 2012, 590, 3349-3360. [Green Version]

44. Van Schaardenburgh, M.; Wohlwend, M.; Rognmo, O.; Mattsson, E.J.R. Exercise in claudicants increase or decrease walking ability and the response relates to mitochondrial function. J. Transl. Med. 2017, 15, 130. [Green Version]

45. Patel, B.P.; Safdar, A.; Raha, S.; Tarnopolsky, M.A.; Hamadeh, M.J. Caloric restriction shortens lifespan through an increase in lipid peroxidation, inflammation and apoptosis in the G93A mouse, an animal model of ALS. PLoS ONE 2010, 5, e9386.

46. Venditti, P.; Di Meo, S. Effect of training on antioxidant capacity, tissue damage, and endurance of adult male rats. Int. J. Sports Med. 1997, 18, 497-502.

47. Makinen, M.W.; Lee, C.P. Biochemical studies of skeletal muscle mitochondria. I. Microanalysis of cytochrome content, oxidative and phosphorylative activities of mammalian skeletal muscle mitochondria. Arch. Biochem. Biophys. 1968, 126, 75-82.

48. Wharton, D.C.; Tzagoloff, A. Cytochrome C oxidase from beef heart mitochondria. In Methods in Enzymol; Estabrook, R.W., Pullman, M.E., Eds.; Academic Press: New York, NY, USA, 1967; Volume 10, pp. 245-250.

49. De Lisio, M.; Kaczor, J.J.; Phan, N.; Tarnopolsky, M.A.; Boreham, D.R.; Parise, G. Exercise training enhances the skeletal muscle response to radiation-induced oxidative stress. Muscle Nerve 2011, 43, 58-64.

50. Schantz, P.G. Plasticity of human skeletal muscle with special reference to effects of physical training on enzyme levels of the NADH shuttles and phenotypic expression of slow and fast myofibrillar proteins. Acta Physiol. Scand. Suppl. 1986, 558, 1-62.

51. Rice-Evans, C.A.; Diplock, A.T.; Symons, M.C.R. Techniques in Free Radical Research; Elsevier: Amsterdam, The Netherlands, 1991; Volume 22.

AuthorAffiliation

¹ Department of Bioenergetics and Nutrition, Gdansk University of Physical Education and Sport, 80-336 Gdansk, Poland

² Department of Neurobiology of Muscle, Gdansk University of Physical Education and Sport, 80-336 Gdansk, Poland

³ Department of Bioenergetics and Physiology of Exercise, Faculty of Health Sciences, Medical University of Gdansk, 80-211 Gdansk, Poland

⁴ School of Postgraduate Studies, Gdansk University of Physical Education and Sport, 80-336 Gdansk, Poland

⁵ Department of Physiotherapy, Faculty of Health Sciences, Medical University of Gdansk, 80-211 Gdansk, Poland

⁶ Department of Biochemistry, Gdansk University of Physical Education and Sport, 80-336 Gdansk, Poland

⁷ Nencki Institute of Experimental Biology, 02-093 Warsaw, Poland

* Correspondence: [email protected]

^† These authors contributed equally to this work.

Word count: 6819

Show less

© 2019. This work is licensed under https://creativecommons.org/licenses/by/4.0/ (the “License”). Notwithstanding the ProQuest Terms and Conditions, you may use this content in accordance with the terms of the License.

Abstract

Translate

In clinical terms, both forms are virtually identical. Since 1993, the study of the etiology of fALS has focused on mutations in the gene encoding superoxide dismutase type 1 (SOD1), which occurs in nearly one-fifth of all cases of familial form of the disease [3,4]. [...]the aim of this study was to investigate the effects of swim training and ALS disease on mitochondrial bioenergetics, oxidative stress, and on changes in muscle strength of hSOD1 G93A mice at the early stage of the disease. 2. Results The progression of ALS leads to muscle weakness and atrophy, which are associated with deterioration in muscle strength. [...]to assess the effects of swim training on the grip strength of ALS mice, we subjected both wild-type (WT) and hSOD1 G93A mouse groups to a regimen of exercise. According to the expectations, we observed that swim training maintained the grip strength in ALS mice (Figure 1).

Details

Title

Swim Training Modulates Mouse Skeletal Muscle Energy Metabolism and Ameliorates Reduction in Grip Strength in a Mouse Model of Amyotrophic Lateral Sclerosis

Author

Flis, Damian Jozef; Dzik, Katarzyna; Kaczor, Jan Jacek; Cieminski, Karol; Halon-Golabek, Malgorzata; Antosiewicz, Jedrzej; Mariusz Roman Wieckowski; Ziolkowski, Wieslaw

Publication year

2019

Publication date

2019

Publisher

MDPI AG

ISSN

16616596

e-ISSN

14220067

Source type

Scholarly Journal

Language of publication

English

DOI

https://doi.org/10.3390/ijms20020233

ProQuest document ID

2331908787

Swim Training Modulates Mouse Skeletal Muscle Energy Metabolism and Ameliorates Reduction in Grip Strength in a Mouse Model of Amyotrophic Lateral Sclerosis

Jump to:

Full Text

Abstract

Details

Suggested sources