Abstract
Extremely reduced oxygen (O2) levels are detrimental to myogenic differentiation and multinucleated myotube formation, and chronic exposure to high-altitude hypoxia has been reported to be an important factor in skeletal muscle atrophy. However, how chronic hypoxia causes muscle dysfunction remains unknown. In the present study, we found that severe hypoxia (1% O2) significantly inhibited the function of C2C12 cells (from a myoblast cell line). Importantly, the impairment was continuously manifested even during culture under normoxic conditions for several passages. Mechanistically, we revealed that histone deacetylases 9 (HDAC9), a member of the histone deacetylase family, was significantly increased in C2C12 cells under hypoxic conditions, thereby inhibiting intracellular autophagy levels by directly binding to the promoter regions of Atg7, Beclin1, and LC3. This phenomenon resulted in the sequential dephosphorylation of GSK3β and inactivation of the canonical Wnt pathway, impairing the function of the C2C12 cells. Taken together, our results suggest that hypoxia-induced myoblast dysfunction is due to aberrant epigenetic regulation of autophagy, and our experimental evidence reveals the possible molecular pathogenesis responsible for some muscle diseases caused by chronic hypoxia and suggests a potential therapeutic option.
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Introduction
Chronic high-altitude hypoxia contributes to the muscle atrophy observed in patients with pathologies associated with a hypoxic microenvironment, such as chronic obstructive pulmonary disease (COPD) and arteriosclerosis obliterans1. Some studies have reported that the hypoxia-induced inhibitory effect on muscle regeneration is a temporary and reversible process2, which seems to delay myogenic differentiation. By contrast, some studies have suggested that impaired regeneration under chronic hypoxia has long-lasting effects that may not be sufficiently reversed and results in muscle mass loss3,4; however, the underlying mechanism remains unclear.
Myogenesis is an essential step for muscle regeneration. In addition, myoblasts are required for this process because, by successfully differentiating and fusing with each other, they regenerate the characteristic multinucleated myofibers; they also play an important role in maintaining muscle structure and mass5. Some studies have shown that 1% O2 represses the myogenic differentiation of C2C12 (from a myoblast cell line)2,6, whereas a 3–6% O2 level can promote myogenesis7. Previous studies have reported that severe hypoxia negatively regulates myogenic differentiation by inhibiting MyoD or Myogenin in myoblasts in a manner that is dependent on3 or independent of6,8 hypoxia-inducible factor (HIF1α), a major contributor to the response to hypoxia signaling. Some studies have noted that myoblast differentiation is a reversible injury caused by hypoxia because myoblasts retain their capacity to proliferate or differentiate when normal oxygen levels are restored2. By contrast, other researchers believe that the effect of chronic hypoxia on muscle is perennial3,4. Furthermore, our laboratory previously confirmed that microenvironment-induced functional impairments can be transmitted to daughter cells in an epigenetically regulated manner9. However, the effects of chronic hypoxia on the functional alterations of myoblasts and the intrinsic underlying mechanism of its effects have been largely unexplored.
Acetylation of lysine residues on histones is a key process of the epigenetic regulation of DNA transcription10. The acetylation levels of lysine residues on histones are controlled by lysine acetyltransferases (KATs)/histone acetyltransferases (HATs) and histone deacetylases (HDACs). In the past several years, some studies have shown that HDACs respond to long-term hypoxia-induced gene transcriptional regulation11, adipocyte dysfunction12, and disease development13,14. Importantly, it has been demonstrated that histone deacetylase is involved in muscle-specific genes and in the regulation of muscle differentiation15,16. Therefore, we hypothesized that hypoxia might induce persistent changes in myoblasts via epigenetic regulation that causes subsequent muscle dysfunction.
In this study, we demonstrated that a high-altitude hypoxic microenvironment impaired the function of C2C12 in an epigenetically regulated manner. Mechanistically, we revealed that HDAC9 was significantly increased in the C2C12 due to hypoxia, thereby inhibiting intracellular autophagy by binding directly to the promoter regions of Atg7, Beclin1, and LC3. Decreased autophagy resulted in dephosphorylation of GSK3β and subsequent inactivation of the canonical Wnt pathway, impairing the myogenesis in the C2C12.
Results
Hypoxia inhibits the properties of C2C12 cells
To investigate the properties of the C2C12, myogenesis induction was performed. The C2C12 successfully formed myotubes and showed elevated expression of MyoG and MyoD (Supplementary Fig. 1), as indicated by qRT-PCR and western blotting. To investigate the effect of hypoxia on the function of myoblasts, the C2C12 cells were exposed to hypoxia (1% O2) or were maintained under standard conditions (21% O2). The morphology of the C2C12 was mostly unaltered under the hypoxic microenvironment; however, the number of granules was increased in the cytoplasm, and the nucleus was obviously visible (Fig. 1a). The viability and proliferation of the C2C12 were significantly reduced in the hypoxia group compared with the control groups, as shown by MTT and Edu analyses (Fig. 1b, c), indicating that although hypoxia promoted the viability of the C2C12 initially, the proliferation capacity was ultimately reduced after 7 days of exposure to hypoxia. Moreover, the number of apoptotic C2C12 was increased in the hypoxia group, as determined by flow cytometry (Fig. 1d).
We next examined the myogenesis of the C2C12 under normoxic and hypoxic conditions. The C2C12 cultured under hypoxic conditions for 7 days manifested severe inhibition of myogenesis, as indicated by reduced immunostaining and decreased expression of MyoG and MyoD (Fig. 1e, f), a finding consistent with previous reports2,17. Collectively, our results indicate that extremely low O2 levels inhibit the proliferation and differentiation capabilities of the C2C12 but promote apoptosis.
Hypoxia inhibits the myogenesis in C2C12 cells via HDAC9
Previous research has confirmed that the hypoxia-mediated inhibition of myogenic differentiation is reversible2. However, we observed lower expression levels of MyoG and MyoD in the C2C12 of passages 2, 4, and 6 under hypoxia compared with the same passages of C2C12 under normoxia (C2C12 cultured under hypoxic and normoxic conditions for 3 days were used as passage 1; Fig. 2a). The expression levels of MyoG and MyoD were almost the same with passaging, and they were lower than in the normal cells (Fig. 2b), indicating that the hypoxia-mediated inhibition of myogenesis in the C2C12 was consistent even when the cells were cultured under normoxic conditions for several passages.
Growing evidence suggests that the microenvironment changes the posttranscriptional modification of histones via acetylation18,19,20, which subsequently influences the function of cells12. Consequently, we compared the expression patterns of HDAC families between the C2C12 cultured under normoxic conditions and the C2C12 cultured under hypoxic conditions. The results showed that the expression levels of HDAC1, 2, 8, and 9 were continually elevated after exposure to hypoxia for 1 h, 24 h, and 7 days. In particular, the expression of HDAC9 increased nearly 5-fold in the hypoxia-exposed C2C12 compared with the normal control cells (Fig. 2c, Supplementary Fig. 2). Next, we focused on HDAC9 and examined the expression levels of HDAC9 at different time points under hypoxia. Western blotting analysis showed that the level of HDAC9 significantly increased under hypoxia, and this effect was also apparent in different passages (Fig. 2d, f). As hypoxia usually affects cell properties via hypoxia-inducible factors (HIFs)3,21, we also examined the expression levels of HIF1α and HIF2α at different time points in the cells under hypoxia. Western blotting analysis showed that HIF1α increased slightly after 1 h of hypoxia but then decreased continuously and almost disappeared after 72 h of hypoxia, and the expression pattern of HIF2α showed no correlation with the different time points of hypoxia (Supplementary Fig. 3). These results indicate that increased HDAC9 in the C2C12 has no close connection with HIFs; therefore, we did not study these factors in the other experiments.
HDAC9 has been found to prefer lysine 9, lysine 14, and lysine 18 of histone H322, which it acetylates to regulate gene function; therefore, we examined the acetylation sites of histones 3 and 4 after blocking the expression of HDAC9. The results showed that, compared to trichostatin A (TSA), sodium butyrate (NaB) had a strong effect on the simultaneous inhibition of HDAC9 expression and promotion of H3K9 acetylation (Supplementary Fig. 4). Lysine residue H3K9 showed the opposite expression pattern to upregulated HDAC9. Furthermore, H3K9 was also hypoacetylated (more than 2-fold) in different passages of the hypoxia-C2C12, despite the enhanced level of HDAC9 (Fig. 2e–g), suggesting that hypoxia-induced HDAC9 elevation leads to histone deacetylation at lysine residue 9 of histone H3.
Inhibition of HDAC9 rescues the hypoxia-induced impairment of myogenesis
The overexpression of HDAC9 in the C2C12 cultured under normoxic conditions significantly impaired their myogenesis. In contrast, the inhibition of HDAC9 expression in the C2C12 cultured under normoxic conditions partially enhanced their myogenesis, as confirmed by MyoG and MyoD expression (Supplementary Fig. 5, Fig. 3a). These data indicate that HDAC9 regulates the myogenesis in C2C12. We next investigated the therapeutic effect of downregulating HDAC9 on the functional recovery of the C2C12 cultured in hypoxia. We observed that the decreased expression levels of MyoG and MyoD induced by hypoxia were successfully rescued by NaB, suggesting that the therapeutic effect may be caused by the inhibited expression of the HDAC family that was induced by hypoxia (Fig. 3b).
Given that HDAC9 directly regulated the myogenesis in the C2C12 and that NaB is a broad-spectrum HDAC inhibitor, we next specifically downregulated the HDAC9 level in the C2C12 cultured in hypoxia. As expected, the decreased expression levels of MyoG and MyoD induced by hypoxia were also rescued after specifically downregulating HDAC9 (Fig. 3c). Collectively, these data indicate that the inhibited myogenesis of the C2C12 induced by hypoxia was likely due to the elevated HDAC9 level, and the downregulation of HDAC9 successfully rescued the C2C12 impaired by hypoxia.
HDAC9 inhibits myogenesis via the epigenetic regulation of autophagy
As autophagy is required to maintain cellular function and homeostasis under hypoxic conditions23,24,25, we next investigated the effect of hypoxia on autophagy in C2C12. The expression of LC3II was found in normal cells, and this expression was decreased after exposure to hypoxia for 7 days. In contrast, the expression of p62, which acts as specific cargo degraded by autophagy, was distinctly increased under the above hypoxic conditions compared with the control group (Fig. 4a). We next applied the autophagy-flux inhibitor chloroquine (CQ), which prevents lysosome degradation, thus increasing LC3II expression significantly when autophagy is active26. The CQ experiments showed that, in contrast to the cells cultured in normoxia, the cells cultured in hypoxia lacked the capacity for further autophagosome formation, as indicated by western blotting and immunostaining (Fig. 4a, b). Furthermore, we found fewer autophagosomes in the hypoxic cell group than in the normoxic cell group, as indicated by transmission electron microscopy (Fig. 4c). These results suggest that the autophagic activity was inhibited after long-term exposure of the cells to hypoxia. Moreover, the decline in the autophagic activity persisted from P2 to P6, showing the opposite effect of HDAC9. Accordingly, a lack of autophagy led to the accumulation of p62 in the passage 2 cells cultured under hypoxia but remained constant between P2 and P6 (Fig. 4d, Supplementary Fig. 6). Importantly, autophagy in the normal C2C12 was significantly activated and caused a decrease in p62 accumulation after the NaB treatment that downregulated HDAC9 in the presence or absence of CQ (Fig. 4e–g), as shown by western blotting and immunostaining analyses. These results indicate that HDAC9 and intracellular autophagy likely have a close relationship.
To examine whether HDAC9 directly regulates autophagy-related gene expression, we performed a chromatin immunoprecipitation (ChIP) assay. The results showed that HDAC9 was highly enriched at the promoters of Atg7, Beclin1, LC3a, and LC3b in the C2C12 (Fig. 4h), indicating that HDAC9 directly binds to the promoters of those autophagy-related genes. Accordingly, H3K9 was also highly enriched at the promoters of autophagy-related genes in the C2C12 (Fig. 4i), indicating that HDAC9 epigenetically regulates intracellular autophagy in C2C12.
Next, we tested whether the therapeutic effects of NaB or HDAC9 siRNA could rescue the hypoxia-impaired C2C12 directly by regulating autophagy. After Beclin1 was downregulated, the autophagy level decreased significantly and then suppressed the myogenic differentiation of C2C12, whereas overexpression of Beclin1 enhanced autophagy and myogenesis, as shown by qRT-PCR and western blotting (Supplementary Fig. 7, Fig. 5a). Then, we observed that activating autophagy in the C2C12 by upregulating Beclin1 or rapamycin could rescue the impaired myogenesis caused by hypoxia (Fig. 5b, Supplementary Fig. 8). More importantly, NaB could rescue myogenesis in the C2C12 after exposure to hypoxia, but this effect could be blocked by the downregulation of Beclin1 (Fig. 5c). Together, these results reveal that hypoxia reduced the myogenesis in the C2C12 mainly through HDAC9-mediated epigenetic inhibition of autophagy. We next assessed the mechanism by which autophagy regulates myogenesis.
Autophagy regulates myogenesis in C2C12 cells by activating the Wnt/β-catenin pathway
Wnts represent a class of secreted signaling proteins that modulate cell fate decisions, cell proliferation, and stem cell activity in a variety of embryonic and adult tissues. Many robust studies have reported that canonical Wnt signaling is important for regulating the muscle regeneration and myogenesis of myoblasts27,28. We also observed that the expression levels of phosphorylated GSK3β (p-GSK3β) and activated β-catenin (ac-β-catenin) were both decreased after exposure to hypoxia, as shown by immunostaining and western blotting. Furthermore, the levels of the CCND1 and Axin2 mRNAs, downstream intermediates in the Wnt/β-catenin pathway, were much lower in the hypoxic C2C12 (Fig. 6a–c), suggesting that the Wnt/β-catenin pathway was inactivated in hypoxia. More convincingly, we observed that activation of the canonical Wnt pathway by Wnt3a effectively rescued the impaired myogenesis in the C2C12 caused by hypoxia (Supplementary Fig. 9). These data indicate that inactivation of the Wnt/β-catenin pathway may contribute to the impaired function of the C2C12 caused by hypoxia.
Given that emerging studies have indicated that autophagy can contribute to regulation of the canonical Wnt pathway29, we first examined the expression of p-GSK3β and ac-β-catenin after regulating autophagy by lentivirus. Downregulation of Beclin1 in the normoxic C2C12 impaired the Wnt pathway, mimicking the phenotype of hypoxic C2C12. In contrast, recovering Beclin1 expression in the hypoxic cells reactivated the Wnt pathway, as confirmed by western blotting and TOPflash assays (Fig. 6d, e). These results suggest that the Wnt pathway was activated or inactivated depending on the level of autophagy. More importantly, we cultured C2C12 in normoxia and hypoxia for 72 h and visualized p-GSK3β and LC3 via confocal laser scanning microscopy. The results showed that LC3 could colocalize with p-GSK3β under both normoxic and hypoxic conditions. Notably, the merged images demonstrated that the colocalization of p-GSK3β and LC3 was lower in the hypoxic cell group due to the decreased expression levels of p-GSK3β and LC3 (Fig. 6f). Collectively, these results indicate that autophagy could directly regulate the canonical Wnt pathway, likely via phosphorylated GSK3β.
We then investigated whether autophagy regulates myogenic differentiation through the Wnt/β-catenin pathway. The results indicated that knockdown of the expression of β-catenin reduced the myogenesis in C2C12. Importantly, rapamycin could not recover the inhibited myogenesis after β-catenin was downregulated (Supplementary Fig. 10, Fig. 6g). Finally, to confirm the regulatory network of histone deacetylase, autophagy, and the canonical Wnt pathway, the C2C12 were treated with NaB, 3-MA, and DKK-1. Notably, NaB inhibited the expression of HDAC9 and promoted the expression of the remaining downstream genes, whereas the autophagy inhibitor 3-MA inhibited the expression of Beclin1 and ac-β-catenin. Furthermore, the canonical Wnt pathway inhibitor DKK-1 blocked only the expression of ac-β-catenin (Fig. 6h). Together, these results imply that the canonical Wnt pathway is under downstream regulation by HDAC9-mediated autophagy.
HDAC9 epigenetically regulated autophagy is also observed in ischemic muscle atrophy
To further verify our investigation conducted in vitro, we first developed an ischemic muscle atrophy model in mice. The sections from mouse gastrocnemius muscles were examined histologically to evaluate the effects of chronic ischemic hypoxia on tissue integrity. The results showed normoxically grown muscle fibers had uniform size and shape with peripherally placed nuclei (Fig. 7a). Muscle tissue from mice exposed to ischemic hypoxia for 21 days showed severe atrophy of muscle fibers with irregularity in fiber size and more space between them. However, no necrotic fiber or cell splitting could be observed in any of the micrographs (Fig. 7a). Furthermore, with increased duration of exposure to ischemic hypoxia, the ratio of rat gastrocnemius muscle weight/tibial length decreased significantly, decreasing by 22% during 21 days of hypoxia exposure (Fig. 7b). Calpains are a member of the Ca2+-activated cysteine proteases that play important roles in cell motility, cell proliferation, and apoptosis30. Some investigations have suggested that calpains are activated during atrophy31,32. In our study, we observed that the expression level of calpain increased obviously after exposure to hypoxia for 21 days (Fig. 7c), suggesting that the muscle is atrophied after exposure to chronic ischemic hypoxia.
Given that HDAC9 expression was increased in the C2C12 after exposure to hypoxia and subsequently affected cell functions via the regulation of autophagy, we next tested whether HDAC9 regulates the level of autophagy in an ischemic hypoxia mouse model. The expression of HDAC9 increased but the level of H3K9ac decreased in the ischemic hypoxia group, as shown by western blotting (Fig. 7d). As expected, autophagy was dramatically lost in the hypoxia mouse model, as indicated by decreased LC3 levels (Fig. 7e), as in the C2C12 cultured in hypoxia. More importantly, we also observed the same muscle atrophy and decreased autophagy levels in patients with chronic muscle atrophy caused by arteriosclerosis obliterans (Fig. 7f, g). Collectively, our results indicate that hypoxia inhibits the regeneration of muscle likely via autophagy that is epigenetically regulated by HDAC9 (Fig. 8).
Discussion
The effect of hypoxia on the myogenic process has been extensively studied. Several studies have provided credible data to show that less than 1% O2 level represses the proliferation and myogenesis of primary myoblasts and C2C12 in vitro2,6,33, raising the question of whether a long-term hypoxic microenvironment could permanently impair the myogenesis process. Some studies have demonstrated that myoblast differentiation is reversibly inhibited by hypoxia2, as myoblasts regain myogenesis capability when normal oxygen levels are restored. Conversely, our results revealed that the inhibitory effect on myogenesis caused by hypoxia was sustained in the C2C12 after six passages when normal oxygen was restored. We think the difference between the results from previous studies and those from our study may be due to the different culture conditions and observation methods. We previously reported that the microenvironment induces long-term effects on cell functions due to epigenetic regulation5. A previous report demonstrated that hypoxia-induced myogenic differentiation of embryonic stem cells is mediated by regulating HDAC634. Another study has also shown that myogenesis under hypoxia is correlated with the deacetylation of histones associated with the myoD promoter33,35,36,37. Therefore, we first screened 11 HDACs. The results showed that HDAC9 was significantly upregulated in response to hypoxia. Downregulation of HDAC9 by applying HDAC9 siRNA or the HDACs inhibitor NaB recovered the inhibitory effect of hypoxia on C2C12 myogenesis. Thus, we showed that chronic exposure to severe hypoxia-induced muscle dysfunction or mass loss likely through epigenetic regulation similar to that observed in hypoxia-induced Alzheimer’s disease38,39, pulmonary hypertension40, and cardiac tissue fibrosis41. Notably, we observed that the autophagy of the C2C12 was first enhanced after exposure to hypoxia and subsequently decreased after 6 h in hypoxic culture. However, the expression of HDAC9 was continuously increased after exposure to hypoxia. Therefore, we infer that HDAC9 likely regulates autophagy during long-term hypoxic exposure.
Autophagy24,42 is a primary survival pathway for recycling cellular material during periods of nutrient starvation and in response to hypoxia, endoplasmic reticulum stress, and other stresses, and it is essential for maintaining tissue homeostasis. Importantly, dysregulated autophagy is observed in the pathogenesis of myopathies and muscular dystrophies43,44. A recent study demonstrated that autophagy was significantly enhanced in response to short-term intermittent hypoxia-induced atrophy of skeletal muscle45. In that study, LC3II protein was increased (2.4-fold) in limb muscle after 4 days of intermittent exposure to hypoxia. However, the effect of hypoxia-induced autophagy on myoblast differentiation has not been well elucidated. In the present work, we found that long-term exposure to hypoxia reduced the level of autophagy in the C2C12 and that autophagy was suppressed with cell passages. However, we noticed that the level of autophagy in the C2C12 was increased significantly under a short-term (<6 h) hypoxic stimulus and then gradually declined with prolonged hypoxia (data not shown). This finding is in agreement with previous reports showing that acute exposure to hypoxia increases the expression of markers of autophagy45,46. Interestingly, we noted that the inhibition of autophagy by Beclin1 siRNA blocked the effect of the NaB on rescuing the function of the C2C12 in hypoxia. Importantly, we confirmed that HDAC9 directly bound to the promoters of Atg7, Beclin1, LC3a, and LC3b in C2C12. The abovementioned results suggest that autophagy, which is epigenetically regulated by HDAC9, is required to maintain the function of C2C12 in a chronic hypoxic microenvironment.
Some studies have shown that Wnt/β-catenin signaling is critical for the regulation of muscle development and the myogenic differentiation of myoblasts47,48,49. Conditional depletion of β-catenin in mice led to reduced muscle mass and fewer myofibers, as shown by Pax7-positive muscle progenitor cell staining50. Previous reports have demonstrated that Wnt/β-catenin signaling is essential for the multiple steps of myogenesis28,48,51,52, but few reports have indicated that Wnt/β-catenin signaling is not required during muscle regeneration53. In the present study, we revealed that autophagy maintained the functions of myoblast cell lines by regulating the phosphorylation of GSK3β, which is an important regulator for modulating β-catenin nuclear translocation in hypoxia. Although many researchers have demonstrated that GSK3β determines the activation of autophagy during different cytological processes54,55,56, autophagy-regulating GSK3β phosphorylation has been poorly described. Recently, some studies have shown that GSK3β phosphorylation is suppressed by Beclin1 siRNA in renal cells57. In combination with our results, we suggest that autophagy directly regulates the phosphorylation of GSK3β and thereby the activation of the Wnt/β-catenin pathway, which is critical for maintaining the myogenesis of C2C12.
Our data demonstrate that epigenetic regulation is critical for the sustained hypoxia-induced inhibitory effect on the myogenesis of myoblasts and that the activation of autophagy is a key step in rescuing the myogenic differentiation of myoblasts, which may provide a prospective strategy for treating myopathies caused by chronic hypoxia. Further studies are needed to explore how autophagy degrades phosphorylated GSK3β.
Materials and methods
C2C12 cell line culture and cell hypoxic model
Immortalized murine C2C12 myoblasts obtained from the Cell Bank of the Chinese Academy of Sciences (Shanghai, China), originally derived from C3H mouse leg muscle, were cultured on uncoated 6-well plates at 37 °C and 5% CO2 in high-glucose growth medium (4.5 g/l d-glucose) DMEM (GIBCO-BRL, Gaithersburg, MD, USA) supplemented with 10% fetal bovine serum (FBS, GIBCO-BRL), 2 mM l-glutamine (Life Technologies, Rockville, MD, USA), and 1% penicillin–streptomycin (GIBCO-BRL). After reaching confluence, C2C12 myoblasts were induced in differentiation medium (DMEM supplemented with 2% horse serum, 1 mM l-glutamine, 1% penicillin–streptomycin) for 2–3 days.
To establish hypoxia culture conditions, C2C12 myoblasts were placed in a hypoxic (1% O2, 5% CO2, 37 °C) incubator (Galaxy oxygen control incubator, RS Biotech, Irvine, UK) for 1, 3, 6, 12, 24, 72 h and 7 days. Control cells (Normal group) were incubated for equivalent time frames under normoxic conditions (21% O2, 5% CO2, 37 °C).
MTT assay
The viability of C2C12 myoblasts cultured under normoxic or hypoxic conditions was determined using a 3-(4,5-dimethylthiazol-2yl)-2,5-diphenyltetrazolium bromide (MTT) assay carried out for 8 days according to the manufacturer’s protocol (Sigma-Aldrich). Absorbance was determined at 490 nm with a microplate reader (Bio-Tek Instruments, Winooski, VT, USA). Experiments were performed in triplicate.
5-Ethynyl-2′-deoxyuridine assays
The proliferation of C2C12 myoblasts cultured under normoxic or hypoxic conditions was determined using an 5-Ethynyl-2′-deoxyuridine (EdU) DNA Proliferation in vitro Detection kit (RiboBio, Guangzhou, China) according to manufacturer´s instructions. Flow cytometry was performed on these cells previously labeled with EdU.
Apoptosis analysis
The apoptosis of C2C12 myoblasts cultured under normoxic or hypoxic conditions was determined using an apoptosis detection kit (BD Pharmingen) according to the manufacturer’s instructions. Flow cytometry was performed to analyze cell apoptosis, discriminating viable, dead, early apoptotic and late apoptotic cells, by detecting the Annexin-V and propidium iodide (PI) staining and comparing the percentages with the numbers determined for the control group.
Immunofluorescence staining
C2C12 cells cultured under normoxic or hypoxic conditions until confluence were subsequently maintained in differentiation medium for 3 days to promote myoblast fusion. The cells were then fixed with 4% paraformaldehyde for 15 min at 4 °C, permeabilized with 0.2% Triton X-100 in PBS for 10 min and blocked in 5% normal goat serum for 30 min. For immunofluorescence staining, C2C12 cells were incubated with Myosin (R&D system, 1:100, Minneapolis, MN, USA, MAB4470) or LC3I/II (Cell signal, 1:100, 12741) primary antibodies overnight at 4 °C. Subsequently, they were incubated with Cy3-/FITC-secondary antibody for 1 h at room temperature according to the manufacturer’s instructions.
qRT-PCR analysis
Total mRNA isolated from C2C12 cells using TRIzol (Invitrogen, Carlsbad, CA, USA) according to the manufacturer’s instructions was reverse-transcribed into cDNA. Real-time PCR detection was carried out using PrimescriptTM RT master mix (Takara Bio Inc., Otsu, Japan), SYBR Premix Ex TaqTMII (Takara Bio Inc.), and the CFX96 Trademark Real-time PCR detection system (Bio-Rad, California, USA). The expression levels of MyoG, MyoD, HDAC1-11, LC3, Beclin1, Atg7, Axin2, and CCND1 were examined with the primers (Sangon Biotech, China) listed in Supplementary Table 1. GAPDH served as a housekeeping gene. Experiments were performed in triplicate.
Western blotting analysis
C2C12 cells were harvested in RIPA lysis buffer (Beyotime Institute of Biotechnology, Shanghai, China). Whole-cell protein extracts were quantified using the BCA assay, separated by SDS-PAGE 8–12%, and then transferred to PVDF membranes (Millipore, Billerica, MA, USA). Antibodies included Myogenin (Abcam, 1:1000, ab124800, Cambridge, MA, USA), MyoD (Santa Cruz, 1:200, sc-377460), HDAC9 (Abcam, 1:1000, ab59718), HIF1α (Abcam, 1:1000, ab179483), HIF2α (Abcam, 1:1000, ab179825), H3K9 (Abcam, 1:1000, ab32129), H3K14, H3K18, H4K16 (Cell Signaling, 1:1000), LC3I/II (Cell Signal, 1:1000, 12741), Beclin1 (Cell Signal, 1:1000, 3738), Atg5 (Cell Signal, 1:1000, 12994), Atg7 (Cell Signal, 1:1000, 8558), Atg12 (Cell Signal, 1:1000, 4180), p62 (Cell Signaling, 1:1000, 23214), p-GSK3β Ser9 (Cell Signal, 1:1000, 9323), GSK3β (Cell Signal, 1:1000, 12456), and active-β-catenin (Millipore, 1:800, 05–665). Stripped membranes were reprobed with GAPDH (Abcam, 1:4000, ab181602) as a loading control. Signal detection was performed using the ECL Kit (Beyotime Institute of Biotechnology) after incubation with an anti-rabbit or anti-mouse IgG secondary antibody (CoWin Bioscience Co., Beijing, China). Experiments were performed in triplicate.
Transfection assay
siRNA duplex oligonucleotides against mouse HDAC9 (Gene-Pharma Co, Shanghai, China), β-catenin (Gene-Pharma Co, Shanghai, China), Beclin1 (Gene-Pharma Co), or the negative control (Gene-Pharma Co) were transfected into both normoxic and hypoxic C2C12 myoblasts at a final concentration of 50 nM using siPORTNeoFX. The medium was replaced 8 h later. Experiments were performed in triplicate.
Small molecule administration
To examine the effect of sodium butyrate (NaB) on the myogenesis of C2C12 cells, C2C12 cells were cultured under hypoxia with or without NaB (200 μM, sigma, 156-54-7). To examine the effect of NaB and Trichostatin A (TSA) on autophagy of C2C12 cells, C2C12 cells were cultured under normoxic conditions with or without NaB (200 μM) and TSA (100 nM, Sigma, 58880-19-6). Rapamycin (100 nM, Sigma, 53123-88-9), NaB (200 μM), 3-MA (5 mM, Sigma, 5142-23-4), and recombinant mouse DKK-1 (100 ng/ml, BioLegend, San Diego, CA, USA, 759604) were added to C2C12 cells cultured under normoxic or hypoxic conditions to examine the relationship between autophagy and the signaling pathways. All the cell samples for qRT-PCR and western blotting were collected according to the manufactures’ instructions.
Transmission electron microscope (TEM) analysis
C2C12 cells were collected with trypsin, washed with serum-free PBS and primarily fixed in 4% glutaraldehyde and 4% paraformaldehyde (Sigma, pH 7.2) overnight. After washing with PBS, the cells were progressively dehydrated in a graduated series of ethanol solutions (50, 70, 95, and 100%), and then embedded in situ in LX-812 resin (Ladd Research Industries Inc., USA). Subsequently, ultrathin sections (60 nm) were stained with 1% uranyl acetate (30 min) and lead citrate (10 min). The ultrastructure of the cells was then observed using an FEI Tecnai G12 Spirit BioTwin transmission electron microscope (FEI Company, USA) with an accelerating voltage of 100 kV. Digital images were captured on a Veleta CCD camera (Olympus-SIS, Germany).
Chromatin immunoprecipitation
We used a Chromatin immunoprecipitation (ChIP) assay kit (Merck Millipore, Billerica, MA, USA, 17–371) to confirm the binding between proteins and gene promoters according to the manufacturer’s protocol. Antibodies against HDAC9 (Abcam, ab59718) and polyclonal anti-Histone H3 (acetyl K9) (Abcam, ab10812) were used as detection antibodies, and normal rabbit IgG (Merck Millipore) was used as a negative control. All precipitated DNA samples were analyzed by qRT-PCR, and the results were normalized to the input value. The primers spanning the H3K9-/HDAC9-binding sites at the Atg7, Beclin1, LC3a, and LC3b promoter (Sangon biotech, China) are listed in Supplementary Table 2.
Hind limb ischemia model
Male 4-month mice were purchased from the Animal Center of Fourth Military Medical University, Xi’an, China. Sixteen mice were randomly and evenly divided into two groups (eight in each group) to receive either sham or femoral artery ligation surgery. Briefly, femoral artery was ligated at the proximal region just under the inguinal ligament and distally above the profunda femoris branch. A cut was then made between the ligation sites. All of the procedures that involved animals were approved by the Animal use and care committee of the Fourth Military Medical University (license number: SYXK 2012-0023).
Human subjects
Two arteriosclerosis obliteran patients (male), aged 48 and 53 years respectively were conducted by the Affiliated Hospital of Fourth Military Medical University because of their arteriosclerosis obliterans. Health human muscle samples were collected from two bone fracture patients caused by car accident aged 46 and 50 (male).
The clinical study was approved by the Ethics Committee of the Affiliated Hospital of Fourth Military Medical University, and written informed consent was obtained from all participants prior to sample collection.
Statistics
The data are presented as the mean ± s.d. Unpaired two-tailed Student’s t-tests were applied for comparisons between two groups, and one-way analysis of variance (ANOVA) with a Bonferroni post-test was used for multiple comparisons. All experiments were repeated more than three times, and representative experiments are shown. P values <0.05 were considered significant. *P < 0.05, **P < 0.01. Analytic tests were undertaken using SPSS17.0 software.
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Acknowledgements
This work was financially supported through grants from the by National Natural Science Foundation of China (31571532), Key R & D Plan projects of Shaanxi Province (2017ZDXM-SF-038) and National Natural Science Foundation of China (81271176 and 31601099).
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Z.Z. collected and organized the data. L.Z. and Y.Z. wrote the most manuscript and helped analyze the data. L.L. helped with the statistical design and ChIP analysis. J.Z. and Q.W. contributed to the C2C12 cell culture and identification. Z.J. designed the experiments and analyzed the data. W.L. developed the concept, supervised the project, conceived the experiments and revised the manuscript.
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Zhang, Z., Zhang, L., Zhou, Y. et al. Increase in HDAC9 suppresses myoblast differentiation via epigenetic regulation of autophagy in hypoxia. Cell Death Dis 10, 552 (2019). https://doi.org/10.1038/s41419-019-1763-2
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DOI: https://doi.org/10.1038/s41419-019-1763-2
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