Introduction
Chronic obstructive pulmonary disease (COPD) is marked by a progressive decline in lung function coupled with irreversible airflow obstruction. This condition is a growing worldwide health challenge and ranks as the third most prevalent cause of mortality on a global scale [
1]. Cigarette smoke (CS) stands as the primary contributing factor to COPD. As most COPD patients are elderly, and the anatomical and physiological features of lung aging exist in COPD patients, it is reasonable to refer to COPD as an aging-related disease [
2]. Both the impairment of mitochondrial function and the premature aging of the lungs have been suggested as pivotal factors in the development of COPD [
3,
4].
Mitochondrial dynamics and mitophagy are two main mechanisms by which mitochondrial quality and homeostasis are maintained [
3]. Two key proteins namely mitofusin 1 (MFN1) and mitofusin 2 (MFN2) orchestrates the fusion of the outer mitochondrial membranes, while optic atrophy 1 (OPA1) takes charge of merging the inner mitochondrial membranes [
5]. Conversely, the interaction between dynamin-related protein 1 (DRP1) and four receptor proteins orchestrates mitochondrial fission [
5]. The PTEN-induced kinase 1 (PINK1)–Parkinson Disease protein 2 (PARK2 or PRKN) pathway is a well-established mechanism for mitophagy [
6]. During mitophagy, damaged mitochondria are targeted for degradation. PARK2 is recruited and ubiquitinates specific proteins on the mitochondrial surface. This occurrence triggers the mobilization of protein sequestosome-1 (SQSTM1/p62) towards the mitochondria, facilitating a direct engagement with microtubule-associated protein 1A/1B-light chain 3 (LC3), thereby instigating the commencement of autophagosome formation [
6].
CS exposure induces mitochondrial dysfunction and triggers mitophagy, promoting mitochondrial injury and airway epithelial cell injury [
7]. In our earlier investigation, it was revealed that CS extract (CSE) has the ability to enhance DRP1 and MFF and to reduce the expressions of MFN2 and OPA1 within lung alveolar type II (ATII) cells (A549) [
8]. The crucial function of mitochondrial fusion in maintaining mitochondrial quality control has been confirmed by the employment of pharmaceutical compounds that promote mitochondrial fusion, like leflunomide and BGP-15 [
9,
10], but their role in COPD mitochondrial dynamics remains unknown.
Accumulation of senescent cells may contribute to aging-related diseases. Cellular senescence is mainly regulated by P53- and P16-mediated pathways [
11]. In the P53-mediated pathway, DNA damage or telomere shortening activates DNA repair kinase ataxia-telangiectasia mutated proteins (ATM), which phosphorylates H2A histone family member X (H2A.X, a histone H2A variant), and then activates P53 and P21, leading to cellular senescence. In the P16-mediated pathway, oxidative stress activates P16 which phosphorylates the retinoblastoma (Rb) protein, leading to the activation of P21 and cellular senescence. Ultimately, both routes lead to the buildup of senescent cells and the release of cytokines and chemokines recognized as the senescence-associated secretory phenotype (SASP) response [
12]. Components of SASP include interleukin (IL)-1, IL-6, chemokine (C-X-C motif) ligand 1 (CXCL)1 and CXCL8, which are all increased in COPD [
12]. Mice exposed to CS showed an increased expression of P16 in the lung [
13]. Klotho may function as an anti-aging protein in aging-related diseases guarding against inflammation and oxidative stress [
14], and its presence is diminished in airway epithelial cells of individuals with COPD [
15].
We hypothesized that exposing to CS could induce mitochondrial dysfunction by reducing MFN2 and OPA1 proteins leading to lung cellular senescence and that up-regulation of mitochondrial fusion proteins might prevent lung cellular senescence. In order to validate this hypothesis, we conducted a targeted investigation into the regulatory impacts of MFN2 and OPA1 on SASP and biomarkers of cellular senescence in CSE-exposed A549 cells by pharmacological induction and genetic overexpression (OE).
Materials and methods
A detailed ‘materials and methods’ is in the online supplement (see Additional file
1).
Collection of human lung tissues and culture of primary ATII cells
This research was approved by the Institutional Ethics Committee (No. KS1969) and written informed consent was signed by each subject in accordance with the Declaration of Helsinki. Lung tissues were obtained from newly diagnosed COPD patients or control subjects of no history of obstructive airways diseases with lung nodules or suspected lung cancer undergoing lung resection between July and August 2020 in Shanghai Chest hospital following a previous protocol [
16]. A total of 40 subjects were divided into non-smokers (n = 10), smokers without obstruction (n = 10) and COPD (n = 20) patients through a questionnaire and lung function tests. As the COPD patients and smokers were mostly male, we made all subjects including controls men in our research to avoid the influence by gender. Both smokers and COPD patients were active smokers.
Isolation of primary ATII cells was carried out using resected lung tissues in sterile condition. In brief, the lung pieces were minced with scissors and incubated in a solution containing trypsin (Gibco) and collagenase type I (Life technologies) for digestion, which was stopped using DNase I (KeyGen biotechnology), and then filtered through cell strainers at the size of 150 μm and 75 μm in tandem to collect the crude cell suspension. The residual lung tissues were digested and filtered again. The cell suspensions obtained from the two filtrations were centrifuged and resuspended with DMEM/F12 complete medium, and incubated at 37 °C, 5% CO2 for 1–2 h. The unadhered cells were aspirated, which was repeated three times, and then the ATII cells were gently collected and added to the culture dish coated with mouse IgG (Sigma) for 3 h, the unadhered cells were aspirated. Cells were resuspended in DMEM/F12K medium with 20% fetal bovine serum (FBS), 200U/ml penicillin and 200 µg/ml streptomycin. The medium was changed every other day. The cells were cultured until they were in good condition, and then subsequent experiments were performed.
Transmission electron microscopy (TEM) analysis in ATII cells of lung tissues
Lung tissue fragments were initially preserved using 2.5% glutaraldehyde, and subsequently exposed to 1% osmium tetroxide. Following dehydration, the tissue specimens were soaked and embedded in a solution composed of propylene oxide and SPI-pon812 embedding agent (SPI supplies, West Chester, PA, USA). Following high-temperature polymerization, ultrathin sections, ranging from 70 to 80 nanometers in thickness, were treated with uranyl acetate and lead citrate staining before being scrutinized using TEM (JEOL-1400 flash, Akishima, Tokyo, Japan). The evaluation of mitochondrial morphology and the number of authophagosome in ATII cells were conducted utilizing Image J software (National Institute of Health, Bethesda, USA). Freehand tool was used to trace the outer mitochondrial membrane of each mitochondrion to measure area, circularity and perimeter while a straight line along the major axis of each mitochondrion was drawn to measure length.
Cell line culture, CSE preparation and exposure, pharmacologic and genetic induction
The culture of A549 cells (Shanghai Institutes for Biological Sciences, China Academy of Science, Shanghai) and freshly prepared CSE followed the methods outlined in a prior description [
8]. Based on a preliminary study, A549 cells were subjected to 10% concentration of CSE to initiate cellular damage. Prior to this, cells were pretreated with either 10 µM of leflunomide (MFN2 promoter) (#S1247, Selleck, Shanghai, China) or 15µM BGP15 (OPA1 promoter) (#S8370, Selleck) for a duration of 2 h. Following this pre-treatment, the cells were subsequently exposed to vehicle or CSE for another 24 h. Lentivirus transduction was used for genetic induction. The plasmid sequences for human MFN2 overexpression (MFN2 OE) and OPA1 overexpression (OPA1 OE) were obtained from Lncbio-technology (Xuhui, Shanghai, China).
Cell viability and cell proliferation assay
Cell Counting Kit-8 (CCK8, Dojindo, Kumamoto, Japan) was conducted to assess cell viability, while EdU Cell Proliferation Kit with DAB (Beyotime, Shanghai, China) was utilized to evaluate cell proliferation. Both analyses were conducted in accordance to the manufacturer’s instructions, comparing responses to either vehicle or CSE.
Measurement of intracellular ROS and mitochondrial ROS (mtROS) and in cells
DCFH-DA (Sigma-Aldrich, St. Louis, MO, USA) was performed to examine the level of intracellular ROS and Mito SOX Red (Invitrogen, Life Technologies, Carlsbad, CA, USA) was employed for mitochondrial ROS (mtROS) respectively as previously described [
8].
Quantitative real-time PCR
TRIzol (Vazyme, Nanjing, Jiangsu, China) was used for isolation of total RNA from both human lung tissues and A549 cells. Subsequently, the RNA’s concentration and purity were evaluated. ChamQ Universal SYBR qPCR Master Mix (Vazyme, Nanjing, Jiangsu, China) was employed for quantitative real-time PCR for SASP components, utilizing an ABI ViiATM 7 System. The primer sequences for the cytokines as well as β-actin were documented in Table
1.
Table 1
Primer sequences of cytokines and β-actin
| Reverse | 5′-AGGTCCACGGGAAAGACACAGG-3′ |
IL-6 | Forward | 5′-CACTGGTCTTTTGGAGTTTGAG-3′ |
| Reverse | 5′-GGACTTTTGTACTCATCTGCAC-3′ |
CXCL1 | Forward | 5′-AAGAACATCCAAAGTGTGAACG-3 |
| Reverse | 5′-CACTGTTCAGCATCTTTTCGAT-3′ |
CXCL8 | Forward | 5′-AACTGAGAGTGATTGAGAGTGG-3′ |
| Reverse | 5′-ATGAATTCTCAGCCCTCTTCAA-3′ |
β-actin | Forward | 5′-GGCCAACCGCGAGAAGATGAC-3′ |
| Reverse | 5′-GGATAGCACAGCCTGGATAGCAAC-3′ |
Western Blot analysis in lung tissues and cells
By homogenization and lysis in RIPA Lysis Buffer (Beyotime), we extracted total proteins from lung tissues, primary ATII cells, and A549 cells. The protein content was quantified using a BCA kit (Beyotime). Western Blot analysis in lung tissues and cells was performed against DRP1, phosphorylated-DRP1 (p-DRP1) (Ser616), MFF, OPA1, MFN2 (1:1000, Cell Signaling Technology, Danvers, MA, USA), PINK1, PARK2, SQSTM1/p62, LC3b, P16, H2AX (1:1000, Abcam Cambridge, MA, USA), Klotho and GAPDH (1:1000, Proteintech, Wuhan, Hubei, China). Bands were developed by ECL chemiluminescent substrate (Millipore, Billerica, MA, USA).
Mitochondrial potential, mitophagy activity and morphology.
The cells were stained using JC-1 (Thermo Fisher Scientific, MA, USA) for membrane potential, mitophagy detection kit (Dojindo, Kumamoto, Japan) for mitophagy activity, and MitoTracker Green (Beyotime, Shanghai, China) and 4′,6-diamidino-2-phenylindole (DAPI, Beyotime) for morphology following the instructions provided by the manufacturer. The mitochondrial membrane potential was quantified based on the red/green fluorescence ratio. The mitophagy activity fluorescence and morphology was measured and imaged under a confocal laser microscope (Zeiss, Oberkochen, Germany). The ratio of MitoTracker area to cell area, mitochondrial fragmentation percentage and perinuclear mitochondrial compaction percentage were calculated as previously described [
7].
Mitochondrial respiratory chain (MRC) complexes activities and oxygen consumption rate (OCR)
MRC complexes I, III, and V activities within lung tissues were evaluated using an activity assay kit (Solarbio Life Sciences, Beijing, China) following the provided instructions. The mitochondrial OCR in cells was measured using the standard protocol established for XFe96 Extracellular Flux Analyzer (Seahorse Bioscience, North Billerica, MA, USA) following the manufacturer’s instruction.
Statistical analysis
Data are presented as mean ± SD. For correlation analysis, Pearson’s test was applied to normally distributed data, while Spearman’s rank test was used for non-normally distributed data. Additionally, Fisher’s exact test was employed for multiple composition ratio comparisons using SPSS software 20.0 (IBM, NY, USA). Utilizing GraphPad Prism 8, a comparison among multiple groups was conducted through One way ANOVA with Bonferroni’ s post hoc test (for equal variance) or Dunnett’ s T3 post hoc test (for unequal variance). Meanwhile, we applied a correction that controlled the false discovery rate using the two-stage step-up method of Benjamini, Krieger, and Yekutieli. p < 0.05 was set as a level considered statistically significant.
Discussion
Growing evidence supports that lung cellular senescence significantly contributes to the development CS-induced COPD [
17]. Mitochondrial dysfunction is recognized as a contributing factor to aging and cellular senescence in COPD pathogenesis. This study unveils a crucial connection between indicators of lung cellular senescence and impaired mitochondrial dynamics and mitophagy in COPD patients. We found increased mitochondrial fragmentation and autophagosomes, impaired mitochondrial function, increased SASP mediators mRNA expression, along with abnormal expression of mitochondria-related proteins (increased levels of DRP1, DRP1 phosphorylation, MFF, PARK2, SQSTM1/p62 and LC3b II /LC3b I, and decreased levels of MFN2, OPA1 and PINK1), elevated senescence-related proteins (P16 and H2A.X) and reduced anti-aging protein (Klotho) in lung tissues of COPD patients. Some similar results were identified in primary ATII cells derived from the lungs of COPD patients. Moreover, our investigation encompassed the utilization of pharmacological induction and genetic overexpression of two essential mitochondrial fusion proteins, MFN2 and OPA1. This strategic intervention resulted in the alleviation of oxidative stress, decrease in SASP mRNA levels, increase in mitochondrial fusion proteins, reduction in mitophagy, decrement in senescence-related proteins and improvement of mitochondrial morphology and OCR in CSE-exposed A549 cells. These results emphasized the potential significance of modulation of MFN2 and OPA1 in preventing mitochondrial dysfunction and lung cellular senescence in COPD, thus preventing the progress of COPD.
CS exposure induces senescence in lung epithelial cells, a phenomenon closely intertwined with oxidative stress and mitochondrial dysfunction and ultimately linked to the development of COPD [
18,
19]. The lung aging process in COPD is due to the accumulation of senescent cells in the lung together with the SASP response by the activation of nuclear factor-κB (NF-κB) [
20]. This response involves the activation of the NRLP3 inflammasome, which contributes to the release of IL-1β, further exacerbating the SASP response [
21]. Although the SASP signaling is designed to prompt the immune system to eliminate senescent cells, the waning efficiency of immune clearance due to aging leads to the accumulation of senescent cells. Consequently, the SASP, operating in a paracrine manner, induces senescence in neighboring cells and intensifies persistent inflammation, thereby fostering a cycle of chronic inflammation [
22]. In the current investigation, an elevation in the mRNA expression of SASP components was detected in both CS-induced COPD patients and CSE-exposed A549 cells. There was a decreased expression of Klotho in both lung tissues and primary ATII cells from smokers and COPD patients which is consistent with earlier data [
15], and there were enhanced levels of P16 and H2A.X in the lung of COPD patients and of P16 in smokers in comparison to non-smokers. These data confirmed cellular senescence in COPD patients and CSE-induced A549 cells.
Mitochondrial function relies significantly on maintaining a balance between mitochondrial dynamic and mitophagy, both of which exert a significant influence on cellular senescence [
23]. Our findings demonstrated that the cellular senescence was correlated with impaired mitochondrial dynamic and enhanced mitophagy. A larger cohort of subjects will allow segregation of the results according to whether COPD and smokers were current or active smokers and address the degree to which the observed changes in senescence markers is due to active smoking rather than COPD itself. A previous study has reported that knockdown of OPA1 or MFNs could increase the production of mitochondrial ROS and percentages of senescent cells in human bronchial epithelial cells (HBECs) [
24]. The current investigation also explored the impact of pharmacologic inducer (leflunomide and BGP15) or genetic induction of MFN2 and OPA1 on mitochondrial morphology and function as well as on lung cellular senescence. Both leflunomide and BGP15 treatment not only improved mitochondrial morphology and the oxidative phosphorylation (OXPHOS)-related parameters including intracellular ROS and mtROS, but also attenuated CSE-induced mRNA levels of SASP components and protein expression of P16 and H2A.X in A549 cells, while BGP15 improved basal and maximal OCR and ATP production. These OCR changes were more obviously in those reported after lentiviral-mediated overexpression of MFN2 and OPA1.
Our observation concerning the increased levels of p-DRP1/DRP1, DRP1 and MFF and the reduced levels of MFN2 and OPA1 in lung tissues and ATII cells of COPD patients and after CSE smoke exposure of A549 cells is in concordance with several other studies. Elevated mRNA and protein levels of DRP1 and FIS1, along with reduced expression of MFN2 and OPA1, were observed in human airway smooth muscle cells following a 24-hour exposure to CSE [
25]. Similarly, augmented DRP1 protein levels and diminished MFN2 protein levels were measured in 15-day CSE exposure of primary lung epithelial cells [
26]. Reduced expression of MFN1, MFN2 and OPA1 were also seen in alveolar epithelial cells in emphysema/COPD patients [
27]. Other conflicting data have been reported mainly in models of CSE exposure [
17,
19], but this may be explained by different CSE concentrations and exposure duration. In addition, in our CSE exposure cell models, the impaired mitochondrial fission and fusion protein levels could be prevented by up-regulation of MFN2 and OPA1.
In this study, the enhanced mitophagy was evidenced by the formation of autophagosomes and the elevated intensity of mitophagy fluorescence, along with the aberrant expression of mitophagy-related protein. Typically, PINK1 facilitates the recruitment of PARK2 to mitochondria, initiating the mitophagy process, wherein PARK2 can emerge as the decisive factor, exerting a more pronounced influence than PINK1 in COPD pathogenesis [
17]. Subsequently, PARK2 ubiquitinates and degrades MFN1/2, and interacts with LC3b II through the intermediary SQSTM1/p62 adaptor protein. This culminates in the formation of autophagosomes and triggers mitophagy, a process interlinked with oxidative stress [
28]. Impaired PARK2 translocation to damaged mitochondria was noted in the lung tissues of emphysema-afflicted mice, chronic smokers and COPD patients [
29]. Both decreased PARK2 protein [
30] and impaired autophagy [
31,
32] were observed in the lungs of COPD patients. In CS-exposed mice, there was a cooperative rise in the expression of PINK1 and PARK2 within the lung tissues [
33]. Acute exposure of whole CS or CSE to primary HBECs induced the autophagy-related proteins such as SQSTM1/p62 and LC3b [
34]. In the present study, there were decreased PINK1 protein levels, and increased PARK2, SQSTM1/p62 protein levels and increased ratios of LC3b II/I. Up-regulation of MFN2 and OPA1 effectively prevented the CSE-induced mitophagy in A549 cells. Nevertheless, the activity of mitophagy in COPD remains controversial, which may be due to difference in selection of patients or modelling methods, and requires further investigation.
Several in vivo and in vitro investigations have demonstrated mitochondrial dysfunction, including changes in mitochondrial morphology, impaired OXPHOS and energy production, declined mitochondrial membrane potential and increased mtROS production, as a pathological factor in the progression of COPD [
35]. Morphologically, mitochondria in bronchiolar epithelial cells were prone to be more fragmented and shorter in average size in COPD than that of control cases [
24]. The present study confirmed this data with increased numbers of fragmented mitochondria per cell and decreased mitochondrial size in lung tissues of COPD patients, and with increased mitochondrial fragmentation and declined mitochondrial membrane potential in primary ATII cells of COPD patients as well as in CSE-exposed cells, which may also indicate ferroptosis in COPD [
36]. These morphological changes in mitochondria in COPD patients could be related to the increased expression of DRP1 and MFF and decreased expression of OPA1 and MFN2 in the lung of COPD patients.
OXPHOS in mammals is regulated by the electron transport chain (ETC) formed by complexes I-V and two mobile electron carriers [
37]. Complex I and III are two major sources in the generation of ROS, while Complex V finally utilizes the proton gradient to convert ADP to ATP. There were reduced complex I, III and V activities in the lung of smokers and COPD patients as compared to non-smokers. Additionally, we identified reduced OCR and ATP production in CSE-exposed A549 cells in our study, which indicate impaired OXPHOS and energy production. These changes of mitochondria in COPD patients could be related to the abnormal expression of mitochondrial dynamics in lung tissues as well as in primary ATII cells of COPD patients.
Although this study has several strengths, we note some limitations. First, the subject cohorts are relatively small, which precludes separating subjects into current smokers and ex-smokers. Second, all subjects were males in the study because most of patients with both COPD and suspected lung cancer are male smokers, therefore, Subsequent investigations will be required to ascertain whether comparable outcomes manifest in females and in an independent validation group. Third, we repeated some results in primary human ATII cells. It would also be interesting to determine whether similar responses occur in primary human bronchial epithelial cells or lung fibroblasts. Last, we need to perform such interventions in COPD mouse models, which is under planning.
In conclusion, we explored the link between mitochondrial dynamics and lung cellular senescence in the pathogenesis of COPD. Deficiency of MFN2 and OPA1 induced by CS exposure leads to mitochondrial dysfunction and lung cellular senescence in COPD. Up-regulation of MFN2 and OPA1 could be a novel and promising therapeutic approach for delaying or reversing COPD progress.
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