MicroRNA-7450 regulates non-thermal plasma-induced chicken Sertoli cell apoptosis via adenosine monophosphate-activated protein kinase activation

Non-thermal plasma treatment is an emerging innovative technique with a wide range of biological applications. This study was conducted to investigate the effect of a non-thermal dielectric barrier discharge plasma technique on immature chicken Sertoli cell (SC) viability and the regulatory role of microRNA (miR)-7450. Results showed that plasma treatment increased SC apoptosis in a time- and dose-dependent manner. Plasma-induced SC apoptosis possibly resulted from the excess production of reactive oxygen species via the suppression of antioxidant defense systems and decreased cellular energy metabolism through the inhibition of adenosine triphosphate (ATP) release and respiratory enzyme activity in the mitochondria. In addition, plasma treatment downregulated miR-7450 expression and activated adenosine monophosphate-activated protein kinase α (AMPKα), which further inhibited mammalian target of rapamycin (mTOR) phosphorylation in SCs. A single-stranded synthetic miR-7450 antagomir disrupted mitochondrial membrane potential and decreased ATP level and mTOR phosphorylation by targeting the activation of AMPKα, which resulted in significant increases in SC lethality. A double-stranded synthetic miR-7450 agomir produced opposite effects on these parameters and ameliorated plasma-mediated apoptotic effects on SCs. Our findings suggest that miR-7450 is involved in the regulation of plasma-induced SC apoptosis through the activation of AMPKα and the further inhibition of mTOR signaling pathway.

during the early stages of incubation 5 and for the improvement in chicken growth and male reproductive capacity, particularly sperm quality 6 . We have a hypothesis that the plasma treatment may affect SCs in prepubertal chickens, which were more proliferative than those in pubertal chickens 7 and play an important role in regulating spermatogenesis and supporting germ cell development 8 . The present study was carried out with the objectives to investigate the effect of non-thermal plasma treatment on immature chicken Sertoli cell (SC) viability and growth in vitro and the exploration of plasma exposure condition before its in vivo application.
SCs play an important physiological role in the testes, where they support, nourish, and protect germ cells and are required for the appropriate differentiation of germ cells 8 . Each SC provides support to a limited number of differentiating germ cells in the seminiferous tubule and provides them with growth factors, binding proteins, and energy in the form of lactate, thereby promoting germ cell growth and differentiation into spermatozoa; therefore, the number of SCs is important for spermatozoa production 9 . The proliferation of immature SCs affects the final number of mature SCs, which in turn determines testicular size and spermatogenesis competence in the male reproductive system 10 . SCs are highly sensitive to internal signals such as systemic energy levels, growth factors, and hormones 11,12 and exhibit increased metabolism that allows them to support germ cells 13 . Strikingly, mammalian SCs are relatively resistant to apoptosis in response to DNA damage. It has been shown that SCs easily survive high doses of radiation exposure in developing rat testes 14 and that a mild apoptotic SC response is observed following exposure to ionizing radiation in human fetuses 15 . Thus, the exposure condition of plasma should be sufficiently optimized when it is applied on SCs, based on the facts that dose-dependent effects of plasma on many types of normal and cancer cells (including fibroblasts 16 , endothelial cells 17 , epithelial cells 18 , myoblasts 19 , keratinocytes 20 , and various tumor cells 21 , etc.).
The controlled delivery of reactive species (atoms, radicals, ions, electrons, ultraviolet photons, and reactive oxygen and nitrogen species, etc.) produced in non-thermal atmospheric pressure plasma to the surface and interior of plasma-treated living cells or tissues results in biological responses such as altered metabolism and programmed cell death 22,23 . Abundant evidence from recent studies has shown that plasma-generated reactive oxygen species (ROS) effectively induce biological effects that vary from increased cell proliferation 17 to cell apoptosis in many types of normal cells 24,25 and cancer cells 26 . There are numerous possibilities regarding how plasma influences cells at a molecular 27 and genetic 28 level. However, knowledge of cellular signaling events following plasma treatment of eukaryotic cells or tissues is still rudimentary. In the present study, we investigated the molecular and cellular mechanisms of non-thermal DBD plasma-induced in vitro effects on chicken SCs, with particular emphasis on the roles of intracellular ROS and energy metabolism in regulating gene expression and cellular signaling pathways, which may provide a potential reference for the vivo application in future.
MicroRNAs (miRNAs) control a wide range of biological processes, including cell proliferation, migration, differentiation, apoptosis, and metabolism, by mediating RNA silencing and regulating gene expression at the post-transcriptional level 29,30 . Recent studies have demonstrated that miRNAs repress the expression of SC target genes, thereby controlling SC physiology in functions such as proliferation, maturation, apoptosis, formation of tight junctions and the blood-testis barrier, and hormone responses in the seminiferous epithelium cycle 12,31 . Ablation of SC dicer, which is an enzyme essential for SC maturation and survival and is ultimately required to sustain germ cell development, leads to infertility. This observation indicates that miRNA expression in SCs is important in supporting germ cell development 32 . Our previous work with miRNA arrays found that overdoses of non-thermal plasma treatment in immature chicken SCs cultured in vitro downregulate miR-7450, whose predicted target gene is adenosine monophosphate-activated protein kinase α (AMPKα; unpublished data). AMPK is a key sensor and regulator of cellular energy homeostasis. Activated AMPK inhibits cell growth and induces cell apoptosis via the suppression of mammalian target of rapamycin (mTOR) signaling pathway [33][34][35] , which is regulated by the lysosomal permeabilization, protein synthesis and transcription, and activated phosphorylation on serine 2448 36 . In SCs, the AMPK-mTOR signaling pathway has been found to be involved in the disruption of polarity 37 , autophagy, and programmed cell death induced by toxic substances 38,39 . The present study aimed to elucidate the role of miR-7450 in the regulation of non-thermal plasma-mediated effects on SCs through the AMPK-mTOR signaling pathway.

Results
Effect of non-thermal plasma on chicken SC viability and apoptosis. Exposure to 11.7 kV of non-thermal plasma for 30 s increased SC viability and growth ( Fig. 1C; Supplementary Fig. S1), while prolonged plasma exposure of more than 60 s exerted inhibitory effects on cell viability and significant cell apoptosis (Fig. 1C,E; Supplementary Fig. S1). SC viability and growth decreased after exposure to varying plasma potentials (11.7-27.6 kV) for 120 s ( Fig. 1D; Supplementary Fig. S2). These plasma treatments induced significant increases in the number of dead SCs (Fig. 1F), and non-thermal plasma inflicted both time-and dose-dependent damage on chicken SCs cultured in vitro. Considering less than half percentages of cell viability, we used an intensity of 22.0 kV and exposure duration of 120 s for all further mechanistic analyses of plasma-induced apoptotic effects on SCs.
Green fluorescence of JC-1 dye indicates a decrease in mitochondrial membrane potential, which is observed early in cell apoptosis, and mitochondrial depolarization occurring during apoptosis is indicated by an increase in the green/red fluorescence intensity ratio. SCs exposed to 22.0 kV of non-thermal plasma for 120 s displayed significantly increased JC-1 green fluorescence intensity (Fig. 1G) and exhibited a 4.32-fold increase in the green/red fluorescence intensity ratio compared to that in the control group (p < 0.001; Fig. 1H), this indicated that plasma treatment significantly decreased the mitochondrial membrane potential of SCs and increased the mitochondrial depolarization occurring in cell apoptosis.
Effect of non-thermal plasma on mitochondria activity, mitochondrial respiratory enzyme, and ATP level. Mitochondrial fluorescence intensity in plasma-treated SCs decreased 0.82-fold (p < 0.001; Effect of non-thermal plasma on miR-7450 level and gene and protein expression of AMPKα and mTOR. Our previous work using miRNA arrays found that overdoses of non-thermal plasma treatment downregulated miR-7450 level in chicken SCs cultured in vitro. Here we performed RT-PCR analysis of miR-7450 and the expression of its target gene (AMPKα, which was predicted by miRDB; http://www.mirdb.org/) and a downstream kinase mTOR. Plasma treatment induced a 0.27-fold decrease in miR-7450 level (p < 0.001; Fig. 5A), but a Relative viability in SCs exposed to 11.7 kV for different durations. (D) Relative viability in SCs exposed to different potentials for 120 s. (E) Flow cytometric analysis of cell apoptosis in SCs exposed to 11.7 kV for different durations. (F) Flow cytometric analysis of cell apoptosis in SCs exposed to different potentials for 120 s. (G) JC-1 staining of SCs exposed to 22.0 kV of plasma for 120 s. Scale bar: 50 μm. (H) Relative green/red fluorescence intensity for JC-1 staining. Data are represented as the mean ± SD (n = 3 per group). *p < 0.05; **p < 0.01, according to one-way ANOVA and LSD test. respectively. However, significantly differential mRNA expression of AMPKα and mTOR in SCs after plasma treatment was not reflected on corresponding protein expression in western blot analyses (Figs 3A, 5B), this discrepancy can be explained by the facts that transcription, mRNA decay, translation, and protein degradation are key processes determining steady state protein abundance, which result in the unnecessary correlation between mRNA levels and corresponding protein expression 40-44 . Effect of miR-7450 agomir and antagomir on SC viability and apoptosis. Neither negative control produced statistically significant effects when compared with the mock group (p > 0.05; Fig. 6). Compared to the mock group, the miR-7450 antagomir (a single-stranded synthetic miR-7450 inhibitor) significantly inhibited SC viability and growth in transfected cells, but the miR-7450 agomir (a double-stranded synthetic miR-7450 mimic) showed a 0.15-fold increase in SC viability (p < 0.001; Fig. 6A; Supplementary Fig. S3). Moreover, the miR-7450 agomir weakened the inhibitory effect of non-thermal plasma treatment on SC viability, with a 0.35-fold decrease when compared to that in the miR-7450 agomir-transfected group (p < 0.001; Fig. 6A). Compared with the mock group, miR-7450 antagomir significantly increased apoptotic and dead SCs (58.3%), but the miR-7450 agomir did not show any significant differences (Fig. 6B), which indicated that miR-7450 agomir had no damage effect on SC growth. In addition, non-thermal plasma treatment at 22.0 kV for 120 s exhibited 56.4% apoptotic and dead cells (Fig. 1F), but miR-7450 agomir reduced cell apoptosis induced by plasma treatment, showing 27.4% apoptotic and dead cells (Fig. 6B).
The miR-7450 antagomir significantly increased JC-1 green fluorescence intensity (Fig. 6C), which indicates a decrease in mitochondrial membrane potential of SCs, and produced a 11.02-fold increase in the green/red fluorescence intensity ratio, which shows an increase in mitochondrial depolarization occurring in cell apoptosis, compared to that in the mock group (p < 0.001; Fig. 6D). Conversely, the miR-7450 agomir increased JC-1 red fluorescence intensity (Fig. 6C), resulting in a 0.87-fold decrease in the green/red fluorescence intensity ratio (p = 0.002; Fig. 6D), this indicated that miR-7450 agomir transfected SCs had higher mitochondrial membrane potential and percentage of mitochondria within a population than the mock-transfected (Lipofectamine ® RNAiMAX Regent only) group. In addition, miR-7450 agomir significantly weakened the inhibitory effect of non-thermal plasma treatment on mitochondrial membrane potential of SCs, showing increased JC-1 green fluorescence intensity (Fig. 6C) and a 10.50-fold increase in the green/red fluorescence intensity ratio (p < 0.001; Fig. 6D) when compared to that in the miR-7450 agomir-transfected group.
Beside the facts that transcription, mRNA decay, translation, and protein degradation can control steady state protein levels [40][41][42][43] , a multitude of post-translational modifications also control protein turnover and abundance. Among those post-translational mechanisms, miRNAs are known to simultaneously repress hundreds of genes by inhibiting mRNA translation into protein 45 . Although the results showed significantly differential mRNA expression of AMPKα and mTOR in SCs after miR-7450 agomir and antagomir transfection was not reflected on corresponding protein expression in western blot analyses (Figs 3F, 5D), but significant changes of AMPKα and mTOR phosphorylation level were found. Post-translational phosphorylation status modulates the mechanisms which control cell function and affect protein levels 46 .
In order to show the specificity of miR-7450 on target genes, mRNA expression of POU class 1 homeobox 1 (POU1F1), which is not a target gene of miR-7450, was analyzed in transfected SCs. The result showed that the miR-7450 agomir and antagomir had no significant effect on POU1F1 mRNA expression (Supplementary Figure S4). In order to exclude the possible systematic bias in SCs transfected with agomir and antagomir, we analyzed the mRNA expression of an unrelated target gene of miR-7450 (phosphodiesterase 10 A, PDE10A; Supplementary Figure S4). The result showed that the miR-7450 agomir decreased PDE10A mRNA expression (p = 0.006), but increased in the miR-7450 antagomir-transfected SCs (p = 0.001). The plasma treatment did not change PDE10A mRNA expression in SCs compared to that in the miR-7450 agomir-transfected group.

Discussion
Short exposure to non-thermal plasma (30 s) at 11.7 kV increased immature chicken SC viability and growth, whereas prolonged plasma exposure or intensity inhibited cell viability and induced apoptosis of SCs. In a previous study, we found that inappropriate non-thermal DBD plasma treatment caused chicken embryo death in a dose-dependent manner, while optimized plasma treatment promoted embryonic development during the early stages of incubation 5 . In addition, non-thermal plasma affects sperm quality in roosters in a time-and dose-dependent manner, and optimal exposure conditions with respect of increased sperm quality have been established 6 . Immature SCs play an important physiological role in the testes for supporting germ cell development and regulating spermatogenesis 8 . In vitro experiments have revealed that low-dose plasma treatments enhance cell proliferation 17,18 but that high doses induce apoptotic effects 16,19,21 in many types of normal and cancer cells. Moreover, prolonged plasma exposure increase cell apoptosis 47 , decrease cell viability 48 , and cause cell toxicity 17 . These previous studies have suggested that inappropriate plasma treatment can affect SC viability and induce time-and dose-dependent apoptosis in chicken SCs cultured in vitro. Thus, the exposure condition of plasma should be sufficiently optimized for its application on SC growth in vitro and the possible in vivo application in male chickens.
The diffusion and delivery of plasma-generated ROS or stimulation of intracellular ROS-generating mechanisms as a result of non-thermal DBD plasma treatment 26,49 has been suggested to regulate cell biological function 17 . Excessive ROS accumulation damages cellular proteins and DNA, resulting in reduced cell viability, proliferation and differentiation 24,48 , and even in cell apoptosis 26 . Our results showed that non-thermal plasma exposure excessively increases intracellular ROS levels and significantly increases MDA activity in SCs. These effects are regulated via the reduction of cellular antioxidant enzymes 21,49 but the increase of mRNA expression of NOX4, which mediates the mitochondrial dysfunction, inducing ROS release 50 . NRF2 controls the homeostasis of ROS by promoting detoxification of superoxide and peroxides through SOD, PRDX, GPx, and CAT 51-53 . NRF2 is suppressed under a basal condition through binding to KEAP1, which in turn facilitates the ubiquitination and subsequent proteolysis of NRF2 54 . Our results show that plasma exposure improved the KEAP1 level but reduced the NRF2 level and mRNA expression and activity of antioxidant enzymes (SOD, CAT, GPx, and PRDX) in SCs. These findings indicate the formation of excessive ROS and the impaired antioxidant defense through disruption of the NRF2-KEAP1 signaling pathway, result in the plasma-mediated apoptosis of chicken SCs.
Mitochondria are primarily affected early in the apoptotic process and act as central coordinators of cell death 55 . Cell growth has been found to be positively correlated with mitochondrial respiratory enzyme activity and ATP production 56 . The levels of intracellular ROS increase as a byproduct of the mitochondrial respiratory chain 57 . Kaushik et al. showed that plasma-generated ROS activate mitochondrial-mediated apoptosis by decreasing metabolic viability, intracellular ATP level, and mitochondrial membrane potentials 58 . Plasma exposure induces the mitochondrial membrane potential reduction, mitochondrial enzymatic dysfunction and morphological changes 59 , which are resulted from the DNA oxidative damage and the disruption of DNA transcription and ATP release in mitochondria induced by the mitochondrial ROS production 58 . The findings here showed that non-thermal plasma treatment inhibits mitochondrial respiratory enzyme activity and increases JC-1 green fluorescence intensity via a low mitochondrial membrane potential, confirming induced SC apoptosis via the ROS-mediated mitochondria-dependent death pathway. Moreover, plasma exposure of SCs was found to inhibit ATP production via the downregulation of mRNA expression of ATP synthase subunits and ATP5A protein level. However, the ATP level in the present study contrast those with obtained in another study where plasma increases the ATP secretion and induces fluctuations in ATP level that are regarded as the representative secreted damage-associated molecular patterns in carcinoma cells 26 .
Cellular energy level can be mediated by the energy-sensing and regulatory pathway of AMPK-mTOR 35 . AMPK is involved in the renewal of cellular mitochondrial content by activating the biogenesis of new mitochondria, resulting in the inhibition of respiratory chain enzymes, which in turn decreases the level of intracellular ATP 60 . Specific deletion of AMPKα in mouse SCs leads to dysregulated energy metabolism with altered ATP production 61 . mTOR promotes cellular ATP production and mitochondrial metabolism and biogenesis 62 . In the present study, plasma exposure of chicken SCs increased AMPKα mRNA level and activated AMPKα phosphorylation via the downregulation of miR-7450 expression (as miRNAs induce mRNA degradation and therefore translation repression in the post-transcriptional regulation of gene expression 29,30 ), whereas it reduced mTOR mRNA level and mTOR phosphorylation. AMPK activation suppresses the mTOR signaling pathway, further regulating cell growth and even inducing cell apoptosis [33][34][35] . The AMPK-mTOR signaling pathway has been reported to be involved in the disruption of SC polarity 37 , autophagy, and apoptosis in SCs under conditions of stress and mitochondrial dysfunction 38,39 . These findings reveal that plasma-downregulated miR-7450 expression may be involved in chicken SC apoptosis because of reduced mitochondrial metabolism and ATP production via regulation of the AMPK-mTOR signaling pathway. miRNAs act as important regulators in SC proliferation, maturation, and apoptotic mechanisms via the modulation of transcription factors 12,31 and therefore also play a crucial role in spermatogenesis. Significant changes in the expression of eight miRNAs involved in both azoospermia and non-obstructive azoospermia were found to be probably due to cytotoxicity and junction injury in SCs 63 . SC-specific deletion of dicer leads to male infertility and progressive testicular degeneration due to the absence of mature spermatozoa 32 . Transgenic mice overexpressing miR-471 in SCs suffer from compromised SC-SC adhesion at the blood-testis barrier, increased germ cell apoptosis, and impaired fertility in vivo 64 . A recent in vitro study has shown that an miR-1285 inhibitor directly upregulates AMPK expression via a 3′-UTR target site, which correlates with decreased levels of ATP and mTOR phosphorylation; this inhibited the cell viability and proliferation of immature boar SCs 12 . In the present study, we found that the miR-7450 antagomir decreased mitochondrial membrane potential, respiratory enzyme activity, ATP level, and mTOR phosphorylation through the targeting of AMPKα activation, which resulted in significant SC death. However, the miR-7450 agomir produced opposite effects on these parameters and ameliorated plasma-induced apoptotic effects. These findings help elucidate the role of miR-7450 in the regulation of non-thermal plasma-mediated SC apoptosis via AMPKα activation and the further inhibition of the mTOR signaling pathway.
Taken together, the exposure condition of non-thermal plasma should be sufficiently optimized when used for chicken SC growth in vitro, based on the fact that inappropriate plasma treatment induces SC apoptosis, which possibly results from the excess production of ROS via the suppression of antioxidant defense systems and the decrease of cellular energy metabolism through the inhibition of ATP release and respiratory enzyme activity in the mitochondria, a process mediated by the involvement of miR-7450 through targeting on the activation of AMPK signaling pathway. These findings provide a reference for the condition optimization of plasma technique and the potential mechanisms prior to its in vivo application for controlling the SC number and sperm production of cocks.

Materials and Methods
Culture of chicken SCs. Testes were obtained under sterile conditions from immature male chickens (Korean native chicken, approximately 30 days old) raised on a chicken farm (Jeju National University, Jeju, Republic of Korea). Animal handling protocols were approved by the Institutional Committee for Ethics in Animal Experiments of Jeju National University and all experiments were performed in accordance with the institution guidelines. SCs were isolated from the testes, evaluated for purity, and cultured using previously described methods 7 . They were counted and seeded to an appropriate density (2 × 10 5 cells/ml) in Dulbecco's modified Eagle's medium/nutrient mixture F-12 (1:1) supplemented with antibiotics and 5% fetal bovine serum (Gibco, Thermo Fisher Scientific, Waltham, MA) at 37 °C in a humidified atmosphere containing 5% CO 2 . After the first 12 h, residual germ cells were removed as previously described 7 . SCs were cultured for approximately 48 h to 70-80% confluence prior to use in experiments.
Non-thermal plasma treatment. A cell culture plate or dish was placed on the glass dielectric barrier of the plasma reactor. This allowed SCs to be directly exposed to non-thermal plasma propagating from the tip of electrode needles at varying durations and potentials following our previously described method 4,5 . Briefly, the non-thermal dielectric barrier discharge plasma reactor had two disk-shaped electrodes (100 mm) and a glass dielectric barrier (5 mm) (Fig. 1A). Sixteen needles (thickness: 1 mm; length: 2.5 mm) were evenly distributed on the surface of upper electrode. The distance gap from the needle tip to the surface of culture medium was 20 mm. Operating frequency of high voltage alternating current was 60 Hz. Argon flow rate was 2 l/min. The voltage was measured using a high voltage probe (1000×, P6015, Tektronix, Beaverton, OR, USA) and recorded by a digital oscilloscope (TBS1064, Tektronix). The discharge powers dissipated in the plasma reactor at different applied voltages were determined using a voltage-charge Lissajous plot. The applied voltage (11.7 to 27.6 kV) is corresponding to the exponentially increase of discharge power (0.05 to 14.28 W) (Fig. 1B). Plasma conditions were as follows: 11.7 kV for 30, 60, 120, and 180 s and 11.7, 16.4, 22.0, and 27.6 kV for 120 s. Afterward, plasma-treated SCs were returned to the cell incubator for 3 h before analysis. Untreated SCs were used as the control group. The live-cell growth status was recorded by photography using an IncuCyte Zoom System (Essen BioScience, Inc., Ann Arbor, MI).

Analysis of cell viability and apoptosis. Cell viability was detected with Cell
Cell apoptosis was evaluated using annexin V/propidium iodide (PI) staining. SCs were washed with ice-cold phosphate buffered saline (PBS), centrifuged (100 × g) for 5 min at 4 °C, resuspended in 1× binding buffer of an Annexin V-fluorescein isothiocyanate Apoptosis Detection Kit (BD Biosciences, San Joes, CA). Five microliters of fluorescein isothiocyanate-labelled annexin V and 5 µl of PI were added to a 490 µl suspension and were gently mixed. After incubation at 25 °C for 15 min in the dark, SCs were analyzed using BD Accuri TM C6 Flow Cytometer (BD Biosciences).
Cell mitochondrial membrane potential analysis. Mitochondrial depolarization occurring in apoptosis is indicated by an increase in the green/red fluorescence intensity ratio following JC-1 dye staining. Detection of altered cell mitochondrial membrane potential was performed using a JC-1 staining kit (Sigma-Aldrich, St. Louis, MO). SCs were washed with PBS and stained with 2 µg/ml of JC-1 dye at 37 °C for 30 min in the dark. Photographs were taken using a fluorescence microscope (Olympus IX70, Tokyo, Japan) equipped with a digital camera (DP71, Olympus) at 520 nm excitation/596 nm emission. Fluorescence intensities were analyzed using ImageJ software (Rasband WS, National Institutes of Health).

ROS production and antioxidant enzyme analysis. Intracellular ROS production was detected using
DCFDA dye (Sigma-Aldrich), and MitoSOX Red (Thermo Fisher Scientific) was used for mitochondrial superoxide detection. SCs were separately stained with 15 µM DCFDA for 15 min and 5 µM MitoSOX Red for 10 min at 37 °C, followed by staining with 1 µg/ml of DAPI (Sigma-Aldrich) for 10 min. Fluorescence images of SCs were taken using a fluorescence microscope (Olympus IX70) at 492 nm excitation/520 nm emission for DCFDA, 510 nm /580 nm for MitoSOX Red, and 340 nm /488 nm for DAPI. Fluorescence intensities were analyzed using ImageJ.
SCs were assayed for MDA, SOD, CAT, and GPx levels using kits from Sigma-Aldrich and BioVision (Milpitas, CA) following the manufacturer's instructions. Total ROS level was measured using the OxiSelect In Vitro ROS/ RNS Assay Kit (Cell Biolabs, San Diego, CA). The fluorescence intensity of 2' ,7'-dichlorodihydrofluorescein (DCF) is proportional to the total ROS level within the sample. The optical densities were measured using the GloMax Discover Multimode Detection System (Promega). Units of MDA (nmole/mg protein), SOD and CAT (U/mg protein), GPx level (mU/mg protein), and ROS (nmole DCF/mg protein) were expressed.
Mitochondrial staining and respiratory enzyme and ATP analysis. SCs were stained using a Cell Navigator Mitochondrion Staining Kit (Green Fluorescence; AAT Bioquest, Inc., Sunnyvale, CA) at 37 °C in a 5% CO 2 incubator for 1 h. The cells were then photographed using a fluorescence microscope at 485 nm excitation/525 nm emission. Fluorescence intensities were analyzed using ImageJ. Mitochondria were isolated and purified from SCs using a Qproteome Mitochondria Isolation Kit (QIAGEN, Valencia, CA), according to the manufacturer's instructions. The NADH level and enzymatic activities of cytochrome c oxidase and ATP synthase in SCs were measured using an NAD + /NADH Quantitation Colorimetric Kit (BioVision), Cytochrome Oxidase Activity Colorimetric Assay Kit (BioVision), and ATP Synthase Activity Assay Kit (Novagen, Merck KGaA, Darmstadt, Germany), according to the manufacturers' instructions. Optical densities were measured using the GloMax Discover Multimode Detection System. SC protein level was measured using the Bicinchoninic Acid Protein Assay Kit (Sigma-Aldrich) and adjusted to equal protein concentrations using PBS. ATP concentrations in SCs were assayed using a kit from Invitrogen (Thermo Fisher Scientific), following the manufacturer's procedures. The light unit values of ATP level were determined using a luminometer (Sirius L Tube Luminometer, Titertek Berthold, Germany). Unit of ATP (nmole/ mg protein) was expressed.
RT-PCR analysis. SC total RNA isolation and purification was performed using a MiniBEST Universal RNA Extraction Kit (TaKaRa Bio Inc., Kusatsu, Shiga, Japan). RT-PCR analysis for mRNA expression was performed using a PrimeScript TM RT Reagent Kit (TaKaRa) and SYBR ® Premix Ex Taq TM II (TaKaRa), according to the manufacturers' protocols. Reverse transcription was performed at 37 °C for 15 min, and enzyme inactivation was performed at 85 °C for 5 s. The conditions used for RT-PCR were as follows: 40 cycles of initial denaturation at 95 °C for 30 s, followed by denaturation at 95 °C for 5 s and annealing for 30 s at the indicated temperatures (Supplementary Table S1).
RT-PCR analysis for miRNA expression was performed using a Mir-X TM miRNA qRT-PCR SYBR ® Kit (TaKaRa), according to the manufacturer's protocol. Reverse transcription was performed at 37 °C for 1 h, and enzyme inactivation was performed at 85 °C for 5 min. Ninety microliters of RNase-free dH 2 O was then added to dilute the cDNA. The following conditions were used for RT-PCR: 40 cycles of initial denaturation at 95 °C for 10 s, followed by denaturation at 95 °C for 5 s and annealing at 60 °C for 20 s. Primer sequences used for RT-PCR are shown in Supplementary Table S1.
The cycle threshold value was calculated based on triplicate measurements. The equivalent dilutions was determined according to the standard curve and then normalized against a housekeeping gene (β-actin for mRNA, U6 for miRNA). Relative expression levels were calculated using the 2 −ΔΔCT method.
Western blotting. For extraction of total protein, SCs were scraped and resuspended in a lysis buffer (5 mM phosphate buffer, pH 7.2, 0.1% Triton X-100, 10 mM sodium fluoride, 1 mg/l chymostatin, and 1 mM phenylmethylsulfonyl fluoride) at 4 °C for 30 min prior to centrifugation for 10 min at 11000 × g. Protein concentration was measured using the Bicinchoninic Acid Protein Assay Kit and adjusted to equal protein concentration using lysis buffer. Western blotting was performed using protein samples extracted from three independent cell cultures for each group. SC protein was separated using a sodium dodecyl sulfate-polyacrylamide gel electrophoresis (12%) and then transferred to polyvinylidene fluoride membranes via wet electrophoretic transfer (Bio-Rad, Hercules, CA). Membranes were blocked in PBS-0.08% Tween containing 5% skim milk or 3% BSA for 2 h at room temperature and subsequently incubated with primary detection antibodies at 4 °C overnight. The following antibodies were used: anti-NRF2 (mouse monoclonal; Santa Cruz Biotechnology; 1:200), anti-KEAP1 (mouse monoclonal; Santa Cruz Biotechnology; 1:200), anti-PRDX4 (mouse monoclonal; Santa Cruz Biotechnology; 1:200), anti-ATP5A (rabbit polyclonal; Abcam; 1:250), anti-phospho-AMPKα (Thr172, p-AMPKα; rabbit polyclonal; Cell Signaling Technology; 1:1,000), anti-AMPKα (rabbit polyclonal; Cell Signaling Technology; 1:1,000), anti-phospho-mTOR (Ser2448, p-mTOR; rabbit monoclonal; Cell Signaling Technology; 1:1,000), anti-mTOR (rabbit polyclonal; Cell Signaling Technology; 1:1,000), anti-beta actin (rabbit polyclonal; Bioss; 1:1,000). Secondary antibodies were goat anti-mouse (Santa Cruz Biotechnology; 1: 5,000) and goat anti-rabbit (Abcam; 1: 5,000) immunoglobulin G conjugated to horseradish peroxidase. Membranes were rinsed three times for 5 min. After incubation with the secondary antibody for 2 h at room temperature, protein bands were visualized via SuperSignal West Pico Plus Chemiluminescent Substrate (Thermo Fisher Scientific). Intensity of bands was analyzed using ImageJ. The densitometric values of the NRF2, KEAP1, PRDX4, and ATP5A bands were normalized against the relevant β-actin. The densitometric values for p-AMPKα, AMPKα, p-mTOR, and mTOR bands were normalized against the β-actin prior to the calculation of the p-AMPKα/AMPKα and p-mTOR/mTOR ratios. Statistical analysis. Data are represented as the mean ± standard deviation (SD) of three independent experiments. Statistical analysis was performed using the Statistical Package for the Social Sciences (SPSS version 16.0; SPSS, Chicago, IL). Statistically significant differences among treatment groups were determined by one-way ANOVA and Fisher's least significant difference (LSD) tests. P-values of < 0.05 were considered significant.