Introduction

In amyotrophic lateral sclerosis (ALS) motor neuron degeneration leads to muscle atrophy, with death usually occurring as a result of respiratory failure, in 3–5 years. However, the survival time is extremely variable; some patients can live beyond 10 years since diagnosis, while others undergo a very rapid disease progression.

The first disease event, observed in both patients and transgenic mouse models, is the destruction of the neuromuscular junction. This led to formulate the “dying-back” hypothesis, according to which defects of neuromuscular functions occur before motor neurons (MNs) anomalies1, 2. Several pieces of evidence indeed indicate that, before the clinical onset and during the disease progression, the skeletal muscles of ALS patients undergo futile cycles of denervation and re-innervation, along with MNs degeneration3. When the MNs start degenerating, surrounding axons sprout from surviving neurons to re-innervate the muscle fibres and compensate the missing synapses. Muscle fibres are broadly classified into slow-twitch (type I) and fast-twitch (type II) based on the myosin heavy chain (MHC) gene expression and on the metabolic path (oxidative/glycolytic) used for ATP production4. Since all muscle fibres in a motor unit (MU) are of the same type, when the MUs enlarge, the skeletal muscle is reorganized in clustering of fibres of the same metabolic type (fibre type grouping). Ultimately these MUs lose their innervation and start undergoing atrophy. Type I and type II fibres are innervated by different MNs; interestingly both in ALS patients and in the SOD1G85R transgenic mouse model, the number of large-calibre axons (innervating type II fibres) in the spinal cord is significantly lower than in controls, whereas the number of small-calibre axons (innervating type I fibres) is preserved5, 6. It is noteworthy that specific muscles (e.g. the extrinsic eye muscles and the bladder detrusor muscle) are selectively spared in ALS, suggesting that the corresponding MNs, in charge of their innervation, are relatively resistant to neurodegeneration. Consistently with these observations, in the SOD1G93A mouse, muscles enriched in slow-twitch fibres undergo denervation at later stages, compared with those housing more fast-twitch fibres7. A strategy designed to target early muscle denervation could plausibly represent a valuable tool to delay disease progression.

Preclinical evidence obtained in the SOD1G93A mouse model indicated that the histone deacetylase 4 (HDAC4) increases in the skeletal muscle during the denervation process, and constitutively blocks the re-innervation signalling8. In turn, denervation induces the up-regulation of MIR206, which promotes re-innervation by suppressing muscular HDAC4 protein levels. Accordingly, in the SOD1G93A mouse model, suppression of the MIR206-dependent HDAC4 down-regulation accelerates disease progression, whereas MIR206 over-expression boosts the regeneration of neuromuscular synapses after acute nerve injury8. HDAC4 inhibition through MIR206 has been, indeed, proposed as a reasonable therapeutic strategy in ALS. In ALS patients, the muscular HDAC4 levels positively correlate with the disease progression and severity, thus supporting its role also in human tissues9. Taken together, these observations suggest that the skeletal muscle, and the local molecular signalling, may represent valuable therapeutic targets in ALS10.

The aim of this study was hence to define the molecular signalling acting in the skeletal muscle of patients during the disease progression, in the attempt to identify suitable molecular markers implicated in skeletal muscle resistance to denervation and atrophy, and in the modulation of muscle re-innervation during early stages of ALS. To address these issues, we have focused on: 1. the MIR206/HDAC4 interplay underlying the human skeletal muscle response during ALS evolution; 2. the structural changes that occur during the disease progression in the muscle tissue of ALS patients, stratified per relevant clinical variables. The functional role of MIR206 has been further validated in vitro, using primary cultures of satellite cells isolated from the skeletal muscle of ALS patients and controls.

Results

Clinical stratification of ALS patients

Based on the available information (see Table 1) about the clinical evolution of the disease, ALS patients were categorized into two groups: ‘slow’, i.e. ≥4 years of duration of disease without requiring respiratory supports (N = 6), and ‘rapid’ (N = 5), i.e. <4 years of disease progression without respiratory support or death occurring <4 years from symptoms onset. The average disease duration significantly changed between the two groups (P = 0.0269), being 66.5 months (range 48–134) and 25 months (range 12–39), in the slow and rapid group, respectively. Patients in the slow group showed a significantly reduced age of onset (mean age = 50.5 years), compared with those in the rapid group (mean age = 65 years, P = 0.0466). ALS patients were then alternatively stratified based on the duration of the disease at biopsy (i.e. time passed since the onset of symptoms until the muscle biopsy). According to this criterion, patients were stratified into ‘early’, i.e. less than one year (N = 4) and ‘late’, i.e. more than one year (N = 9).

Table 1 Detailed ALS patient and specimen data.

Gene and protein expression in skeletal muscle tissues

Eight genes and eleven microRNAs involved in the HDAC4 regulatory signalling have been analyzed in all the available tissue samples by qPCR. HDAC4, MYOG, MYOD1, PAX7 and PAX3 transcript levels resulted significantly increased in ALS patients compared with controls (Fig. 1A). Consistently, also HDAC4 protein levels increased in ALS samples compared with controls (Fig. 1B). None of the analyzed microRNAs showed a significant difference in expression levels, between patients and controls (Supplementary Fig. 1).

Figure 1
figure 1

Expression profile of skeletal muscle biopsies of ALS patients and controls. (A) The diagrams plot the relative transcript levels of the genes analyzed by reverse qPCR, calculated according to the 2−ΔΔCt method, using ACTB as housekeeping gene for normalization. All data were expressed as mean fold change ± SD across replicates, with control values set to 1. Unpaired t-test was used to detect the statistical significance between ALS and controls values; *P ≤ 0.05, **P ≤ 0.01, ****P ≤ 0.0001. (B) Quantitative analysis of western blot for HDAC4 protein expression in muscle specimens of ALS patients and controls. Relative protein content was determined by optical density of the HDAC4 bands normalized to stain free gel.

Thereafter, gene expression data were also analyzed considering patients’ stratification. Results of differential gene expression according to the disease duration (i.e. patients categorized into slow and rapid groups) are displayed in Fig. 2A and B. In particular, HDAC4, MYOD1, PAX3 and MYF5 were up-regulated only in the slow group, compared with controls, while MYOG and PAX7 increased in both groups. FGFBP1 levels were very variable, reaching a significant up-regulation over controls only in the rapid group. Among the tested microRNAs, MIR133A, MIR29C, MIR9 and MIR208B were significantly up-regulated in the ALS slow group, whereas MIR1 and MIR208B expression was lower in the rapid group, than in controls. Interestingly, the expression of MIR499, MIR29C and MIR208B was significantly lower in the ALS rapid group than in the slow one.

Figure 2
figure 2

Molecular evaluation on the basis of the clinical stratification of ALS patients. Relative expression trend of genes (A) and microRNAs (B) in slow (with ≥4 years of disease progression without requiring respiratory support) and rapid (with <4 years of disease progression) ALS groups compared with controls. Relative expression trend of genes (C) and microRNAs (D) of early (less than one year from symptom onset to muscle biopsy) and late (more than one year from symptom onset to muscle biopsy) ALS groups and controls. All data were expressed as mean fold change ± SD across replicates, with control values set to 1. Unpaired t-test was used to detect the statistical significance between ALS and controls values; *P ≤ 0.05, **P ≤ 0.01, ***P ≤ 0.001.

We then comparatively analyzed gene expression data in patients stratified based on disease duration at biopsy (i.e. within early and late patients’ groups). The results showed that, within one year from the onset of symptoms, the genes involved in regeneration (PAX7 and PAX3) and re-innervation (HDAC4, MYOG, MYOD1 and FGFBP1) pathways are activated in the affected skeletal muscle (Fig. 2C). The expression of MIR206, MIR155, MIR23A, MIR133A, MIR133B, MIR29C and MIR9 increased only in the early stage group, compared with controls (Fig. 2D). MIR206 and MIR9 expression levels also significantly changed between the early and the late groups. Interestingly, MIR206 levels inversely correlated with the time from symptoms onset to muscle biopsy (R = −0.8309, P = 0.0106) (Fig. 3A). Conversely, MIR9 expression did not correlate with the progression of the disease (data not shown). Also, we did not find any statistically significant correlation between either of HDAC4 transcript (Fig. 3B) and protein levels and the disease duration (data not shown).

Figure 3
figure 3

Correlation and expression analysis based on MIR206 expression levels. Pearson’s correlation test of MIR206 (A) and HDAC4 (B) relative expression levels of ALS patients with the time from symptoms onset to muscle biopsy.

Gene expression during in vitro myogenic differentiation

Satellite cells derived from ALS patients and controls were induced towards myogenic differentiation in vitro for 14 days. Thereafter, the expression of the genes involved in the myogenic differentiation process (HDAC4, MYOG, MYOD1, MEF2C, MYF5, PAX7 and PAX3) was analyzed in time course, after 1 and 2 weeks of induction. The expression trends, during in vitro differentiation, were very similar in ALS and controls for all tested genes (Supplementary Fig. 2). When comparing the gene expression levels between cells from ALS patients and controls at each time point (i.e. expression analysis between matched ALS and control cultures at each single time point), we found significant differences in selected genes: MYOD1, PAX7, PAX3 and MYF5 showed increased levels in ALS patients, compared with controls, while HDAC4, MYOG and MEF2C levels were lower in the ALS group than in controls (Fig. 4A). PAX7, MYOD1 and MYF5 represent early markers of stem cell activation, while MYOG, MEF2C and HDAC4 are known to increase in later stages of the differentiation process (Fig. 4B). Therefore, the expression profiles observed in our sample seemed to suggest that the myogenic differentiation slows down in ALS cells compared with controls.

Figure 4
figure 4

ALS and controls cell cultures display a different response to myogenic induction. (A) Relative transcript levels of the genes involved in proliferation, activation and differentiation processes, analyzed in time course. All data were expressed as mean fold change ± SD across replicates, with control values set to 1. Unpaired t-test was used to detect the statistical significance; *P ≤ 0.05. (B) Scheme of the putative molecular signature of myogenic conversion: the expression of differentiation markers increase while satellite cells turn into terminally differentiated myocytes, at the start of the myogenic induction and after 1 and 2 weeks.

Functional characterization of MIR206 in cells

In order to validate the functional effect of MIR206 in the myogenic process, we performed a MIR206 mimic assay in ALS and control satellite cells. The mimic construct was transfected in cells during the administration of myogenic medium for 1 week. The expression of the tested targets (HDAC4, PAX7 and PAX3 genes) and of the genes involved in the MIR206/HDAC4 interplay (MYOD1, MEF2C, MYF5 and FGFBP1) was significantly reduced upon the MIR206 mimic treatment in control cells (Fig. 5A). In ALS cell cultures, only MYOD1 levels significantly decreased after MIR206 mimic, while MYOG and FGFBP1 showed increased expression trends (Fig. 5B). HDAC4 protein levels were significantly reduced after MIR206 mimic treatment, in both ALS and controls (Fig. 5C). Therefore, although HDAC4 transcript levels did not change, MIR206 over-expression was apparently able to modulate protein expression also in ALS cells, during the course of myogenic differentiation.

Figure 5
figure 5

MIR206 mimic effects in primary cultures of ALS patients and controls. Controls and ALS cultures induced along myogenic differentiation, were transfected with MIR206 mimic for 1 week. The graphs show the effects of MIR206 over-expression on the expression of the genes involved in regeneration and innervation pathways, in controls (A) and ALS (B) cultures. All data are expressed as mean fold change ± SD across replicates, with mock treated cells values set to 1. Unpaired t-test was used to detect the statistical significance between samples; *P ≤ 0.05, **P ≤ 0.01, ***P ≤ 0.001. (C) Quantitative analysis of western blot for HDAC4 protein expression in ALS patients and controls cultures treated upon MIR206 over-expression. HDAC4 relative protein content was determined by optical density of the HDAC4 bands normalized to stain free gel.

Morphological assessment of skeletal muscles

The down-regulation of MIR208B and MIR499 observed in the rapid-versus-slow progression groups, is known to be associated with fibre type switch in the skeletal muscles11. This prompted us to perform the morphological assessment comparing patients in the rapid group (N = 5) with those in the slow group (N = 3). To define the distribution of fibre types I and II, and the percentage of atrophic fibres, we performed histological analysis on skeletal muscle biopsies from quadriceps and deltoid muscles of ALS patients (Fig. 6A).

Figure 6
figure 6

Histological analysis of ALS patients. (A) Representative images that showed the pattern of muscle fibre atrophy, with different fibre types stained differently. Differences in the fibre type ratio is detected between ALS patients in the slow group (left panels) and those in the rapid group (right panels). The hematoxylin-eosin staining (top panels) and the ATPase staining (bottom panels) highlighted the atrophy pattern and fibre composition. (B) The bar-graph illustrates the percentage of type I, type II and atrophic fibres in the skeletal muscle sections of rapid and slow ALS patients. An overall number of >1000 muscle fibres was counted for each assessed patient.

The results of fibre quantification (Fig. 6B and Supplementary Table 1) showed that the percentage of type I fibres is greater in the slow than in the rapid group (mean 48,38–25,84% respectively, P = 0.0421). The percentage of type II fibres did not change between the groups. Interestingly, in the rapid group the percentage of atrophic fibres inversely correlated with the amount of both types of fibres (RI fibres = −0.9548, P = 0.0115; RII fibres = −0.947, P = 0.0145), whereas in the slow group, it inversely correlated only with the amount of type II fibres (RII fibres = −0,864, though this correlation is not significant). Our data indicated also that the percentage of type II fibres in the rapid group is lower than the percentage of type I fibres, the latter being mainly spared from atrophy in the slow group, while preferentially damaged in the rapid one.

Discussion

Amyotrophic lateral sclerosis (ALS) is a fatal neurodegenerative disorder, for which, to date, no effective therapy has been found. The mean survival of patients from symptom onset is 3 to 5 years12, but the disease progression and severity are extremely variable. Some patients have a milder and protracted course of illness, while others need respiratory support as early as within one year from the onset. An exact estimate of the rate of long surviving patients is not available; recent population-based studies have reported a 5-years survival rate ranging from 22 to 52% of patients13. Several variables, including predominance of upper motor neuron signs, spinal onset, male sex and younger age, have been already analyzed to establish associations with a longer life expectancy, but the results are not univocal. Based on the extant literature, the age and site of symptoms’ onset are the strongest prognostic predictors. In fact, in several population-based studies, younger age at onset has been found to predict long-term survival of ALS patients, whereas bulbar onset has been invariably identified as a negative prognostic predictor13.

In this study, we have used an in vitro model to investigate the response of the skeletal muscle during the disease progression. We have specifically found that the skeletal muscle of ALS patients showing a longer survival period expresses higher levels of microRNAs involved in the regulation of the slow-to-fast fibre type switch profile, compared with patients with a rapid disease progression. Moreover, we observed that the expression of molecular markers of skeletal muscle denervation tends to decrease within the first year since clinical onset.

In particular, we demonstrated that genes encoding myogenic regulatory factors (HDAC4, MYOG, MYOD, PAX3 and PAX7) are consistently up-regulated in the skeletal muscle of ALS patients, more intensely within the first year since the onset of symptoms. These data may suggest that during the early stages of ALS, the molecular signalling implied in muscular regeneration is activated. In addition, the expression of MIR206 and MIR9 was significantly different between patients in early and late stages of disease progression. These data further indicated that the skeletal muscle of ALS patients activates an early response to denervation, which decreases over time at later stages. Also HDAC4 activation seemed to occur within one year from symptoms’ onset. HDAC4 up-regulation has been already described as a response to skeletal muscle denervation in the SOD1G93A ALS mouse model, in which it induces MYOG up-regulation. This, on turn, triggers the molecular cascade associated with muscular atrophy8. MYOG activates, indeed, the transcription of MIR206, establishing a negative feedback loop able to inhibit HDAC4. Finally, HDAC4 inhibition induces the expression of FGFBP1, which promotes re-innervation and regeneration of the neuromuscular junction8. In humans HDAC4 is up-regulated in ALS patients featuring a rapidly progressive disease compared with long-term survivors, while MIR206 is up-regulated in both patient groups, although its levels do not correlate with the disease progression9. Interestingly, our data indicated that HDAC4 transcript and protein are increased in all patients, regardless of the time passed since the onset of symptoms at the time of muscle biopsy. Apparently, HDAC4 levels grow up until six months of disease duration and then it reaches a constant trend. In the early stage of the disease, also FGFBP1 and MYOG are activated demonstrating that the pathway described in mice8 is active also in humans. However, after one year from symptoms onset, FGFBP1 and MIR206 levels decrease, which may cause the muscle to be less prone to react to denervation and muscular atrophy. Indeed, our data indicated that MIR206 up-regulation is detectable in the affected muscle within one year from the clinical onset, and becomes less evident as the disease progresses to a later stage.

In our study, the intracellular levels of MIR206 could be efficiently modulated in ALS muscle satellite cells, in which MIR206 over-expression is associated with HDAC4 protein down-regulation. Indeed, upon mimicking MIR206 in cells, the expression of transcription factors downstream to HDAC4 decreased.

Our data also showed an up-regulation of MIR208B and MIR499 in the skeletal muscles of patients with a slow progression of the disease. MIR208B and MIR499 play redundant roles in the specification of muscle fibre identity, by activating slow-, and repressing fast-myofibre molecular programs11. MIR208B and MIR499 genes are encoded within introns of two type I Myosin Heavy Chain (MyHC) genes (MYH7 gene coding for MyHC-β/slow and MYH7B gene coding for MyHC-slow tonic, respectively). Double knockout mice for both miRNAs displayed a marked slow-to-fast switch in fibre type profile and MyHC expression, while muscle-specific over-expression of MIR499 led to a complete fast-to-slow switch in the MyHC profile11. On this regard, the histological analysis of muscle biopsies of ALS patients showed that type I fibres in the slow group are mainly spared from atrophy, while being preferentially damaged in the rapid one. Slow and fast fibres in the skeletal muscle are innervated by different MNs. Interestingly, both in ALS patients and in the SOD1G85R transgenic mouse model, the axons of neurons innervating type I fibres are selectively spared5, 6. Moreover, a recent study on the SOD1G93A mouse, demonstrated the occurrence of a fast-to-slow shift in the fibre type composition, at later stages of the disease14. Altogether these data suggested that the muscle fibres and the corresponding MNs collaborate to counteract skeletal muscle atrophy during early stages of ALS pathogenesis. This may lead to a slow muscle phenotype in long surviving patients, similarly to what occurs in mutant mice at final stages. The intrinsic properties of muscle cells, together with the pattern of impulse activity imposed on muscle fibres, play a dominant role in determining fibre type composition in regenerating muscles, which, in turn, respond differently to the same stimulation pattern15.

The skeletal muscle can regenerate after injury, due to the activation and proliferation of satellite cells. Normally quiescent, these myogenic precursors are activated during damage and start expressing specific myogenic transcription factors16. In line with previous evidence in the literature17, 18, our data indicated that satellite cells from ALS patients tend to respond slower to in vitro myogenic induction. These cells displayed opposite expression trends between genes associated with regeneration and early differentiation (PAX3 and PAX7), and markers of terminal differentiation (MYOG and MEF2C). This may suggest that, as a result, the skeletal muscle could not be able to effectively repair and regenerate, leading to severe muscle atrophy and weakness. The muscle regeneration process is indeed hampered or, at least, delayed in ALS patients. Different studies performed on ALS satellite cultures, already demonstrated that ALS-derived myoblasts are unable to fully differentiate into myotubes17, 18, and that myotubes from ALS patients have decreased levels of the MYOG protein18.

In this scenario, MIR206 seems to play an essential role during the pathogenesis of ALS skeletal muscle impairment and regeneration, by regulating PAX7, PAX3 and HDAC4 levels, hence altering the balance between cell proliferation and differentiation19.

In conclusion, our study allowed identifying a complex molecular network acting in the skeletal muscle of ALS patients, plausibly affecting both re-innervation and muscle regeneration. Re-innervation and muscle repair are inherently inter-dependent processes, as the skeletal muscle plays an active role in maintaining neuromuscular junction stability. MIR206 seems to link these processes, as its over-expression enhances the muscle regenerative potential during ALS progression8. An over-expression of MIR208B and MIR499 could instead make the skeletal muscle more resistant to denervation and ALS progression (Fig. 7).

Figure 7
figure 7

Schematic representation of possible therapeutic targets in the skeletal muscle at the neuromuscular junction. We identified three muscular microRNAs as potential therapeutic targets in ALS patients. Their targeted over-expression in the skeletal muscle could act on several fronts: (1) promote the regeneration process of the muscle itself, (2) increase the signals aimed at promoting the re-innervation by the motor neuron and (3) lead to a slowdown of the atrophy process by promoting the conversion of the muscle fibres in the more resistant slow type.

Targeting muscular microRNAs could represent a valuable strategy aimed at restoring the molecular pathways improving motor performance and enhancing the production of growth factors (such as FGFBP1) able to facilitate the re-innervation process and delay ALS progression.

Materials and Methods

Patients and specimens

14 ALS patients and 24 age- and sex-matched healthy controls have been enrolled in this study, which was approved by the ethics committee of the Università Cattolica del Sacro Cuore [protocol P/774/CE/2012]. All the following experiments were performed in accordance with relevant guidelines and regulations. All patients provided a written informed consent prior to all investigations. ALS diagnosis was performed according to the revised El Escorial criteria. The functional impairment was assessed using the revised ALS Functional Rating Scale (ALSFRS-R), which rates the performance of activities of daily living and scores from 0 (total disability) to 48 (no disability), based on a 12-item scale. Muscle strength was measured by manual muscle testing according to the grading system proposed by the Medical Research Council (MRC score), ranging from 0 (no visible movement) to 5 (normal muscle strength).

Detailed clinical data of ALS patients are provided in Table 1. Briefly, the ALS sample included six males and eight females, aged 30-to-71 (average age: 57 ± 12) years at biopsy. All patients were Caucasian. Genetic testing was performed to assess the presence of mutations in the ALS-associated SOD1, TARDBP, FUS, ANG, ATXN2 and C9orf72 genes. Three patients carried SOD1 and C9orf72 mutations.

Age- and sex- matched control individuals were selected among patients undergoing orthopaedic surgery for traumatic injury and without positive history for muscle weakness, nor any neurological disorders.

A skeletal muscle specimen was collected through an open biopsy performed either in the deltoid muscle (four ALS patients) or in the quadriceps (nine ALS patients). Upon collection, the tissue specimens were stored in liquid nitrogen for histological analyses, in Allprotect tissue reagent (Qiagen) for protein isolation, in RNA later (Qiagen) for RNA extraction, and in culture medium for cells isolation.

Cell cultures

Primary satellite cells were isolated from muscle specimens (six patients and six controls), through enzymatic digestion. Briefly the tissue was mechanically fragmented and digested with collagenase/dispase (Roche). The tissue homogenate was then separated through a 40 µm mesh filter and seeded into culture plates. Satellite cells were maintained in RPMI 1640 medium (EuroClone), supplemented with 1% L-glutamine (EuroClone), 1% antibiotics (penicillin 100 IU/ml, streptomycin 100 mg/ml, EuroClone) and 15% fetal bovine serum (Gibco).

The myogenicity of the cell populations was assessed by immunofluorescence using an antibody against desmin (Thermo Fisher Scientific, #PA5-17182), specifically expressed in myogenic cells, and counting the number of desmin-positive cells. Cultures displaying over 70% myogenic cells were selected for further in vitro experiments. To induce the myogenic differentiation, cells were shifted to RPMI 1640 medium with 5% horse serum (EuroClone).

RNA isolation and quantitative Real Time PCR

Total RNA was isolated from muscle specimens and cultured cells using the TRIzol reagent method (Invitrogen), according to manufacturers’ protocols. RNA purity and concentration were quantified using an UV spectrophotometer (DU 800, Beckman Coulter). The expression of selected mRNA and microRNA was analyzed using reverse transcription quantitative real-timePCR (qPCR). 1 μg of total RNA was reverse-transcribed, using SuperScript III First-Strand Kit (Invitrogen), and subsequently quantified with StepOne system (Applied Byosistem), using specific FAM-labelled TaqMan probes (Thermo Fisher Scientific) for ACTB, HDAC4, MYOG, MYOD1, MEF2C and PAX7. For the determination of MYF5, FGFBP1 and PAX3 transcript levels, we used SybrGreen technology (Life Technologies).

For microRNAs analysis, 10 ng of total RNA was reverse-transcribed, using the TaqMan MicroRNA Reverse Transcription kit (Life Technologies), and subsequently quantified using specific FAM-labelled TaqMan probes (Thermo Fisher Scientific) for U6, MIR206, MIR155, MIR23A, MIR133A, MIR133B, MIR1, MIR499, MIR208B, MIR29C, MIR9 and MIR223.

The FAM-labelled TaqMan probes and the sequences of the primers used in SybrGreen technology are listed in Supplementary Table 2. The 2−ΔΔCt method was applied to calculate fold differences in gene expression using the housekeeping genes (ACTB and U6, for genes and microRNAs expression, respectively) for data normalization.

Protein extraction and Western Blot analysis

20–30 mg of frozen tissues were homogenated in 200 μl modified lysis buffer (25 mM Tris-HCl pH 7.6, 2 mM EDTA pH 8, 250 mM Sucrose, 0.1% TritonX-100, 5 mM DTT, 1 mM PMSF, 200 mM SOV4, 10 mM NaF, protease inhibitor cocktail 1X; Sigma-Aldrich). A standard RIPA buffer (25 mM Tris-HCl, 1% NP-40, 1% Na-deoxycholate, 150 mM NaCl, 1 mM PMSF, 1 mM NaF, 1 mM Na3VO4, protease inhibitor cocktail 1X; Sigma-Aldrich) was instead used for the extraction of total proteins from cell cultures. Protein samples were quantified by the Pierce BCA Protein Assay Kit (Thermo Fisher Scientific) and stored at −20 °C.

20 µg of lysate samples were separated on Mini-PROTEAN TGX Stain-Free Gels (4–20%, Bio-Rad). The gel was transferred to a nitrocellulose membrane (Bio-Rad) for 10 min using the Trans-Blot Turbo Transfer System (Bio-Rad) with Trans-Blot Turbo Mini Transfer Packs (Bio-Rad). The membrane was activated for 1 minute and then incubated with an antibody against HDAC4 (Cell Signaling, #2072) at a dilution of 1:500. Immune complexes were detected using the ChemiDoc Touch Imaging System (Bio-Rad)after incubation with Clarity Western ECL Substrate (Bio-Rad). HDAC4 protein expression was quantified and normalized to stain free gel loading using ImageLab software (version 5.2.1, Bio-Rad).

Histological analysis

Frozen biopsies were cut into 10 micrometers-thick slices using a cryostat. Sections were stained using the following histochemical techniques: hematoxylin and eosin, nicotinamide adenine dinucleotide dehydrogenase tetrazolium reductase and ATPase at pH 4.3, 4.6 and 9.4.An overall number of >1000 muscle fibres was counted for each assessed biopsy, using the Stereo Investigator system (Stereo Investigator software, Version 9). Fibres below 40 micrometers in diameter were considered atrophic.

microRNA mimic treatments

MicroRNA mimicry was performed in primary satellite cell cultures. To this aim, cells were plated at a 50% seeding density, andgrownuntil 80–90% confluent. Myogenic induction was then initiated by replacing the growth medium with the differentiation medium (see above) for 1 week. The MIR206 mimic (Qiagen), was added to medium [50 nM] and transfected in cells using the FuGENE HD transfection reagent (Promega), at the beginning and after 4 days of myogenic induction. Cells treated only with transfection reagent (mock) were used as controls. After 1 week, cells were collected and protein and RNA extracted; the effects of treatments were then evaluated by qPCR and western blot.

Statistical analysis

Data were analyzed using GraphPad Prism software version 6.0. All data are shown as means ± standard deviation (SD). Statistical differences between groups were analyzed using unpaired Student’s t-test. Correlations were calculated using the Pearson’s correlation test. All statistics were two-tailed and the level of significance was set at P = 0.05.