Abstract
Airway epithelia have the challenging task of maintaining functional and structural homeostasis, even when exposed to various stress factors. Transcription factors of the FoxO family can fulfill this complex task, as they act as integration hubs that translate extrinsic and intrinsic information into a physiologically appropriate response. We could show that FoxO factors in Drosophila, mouse, and human airway epithelial cells (AECs) respond to stressors like hypoxia, temperature, or oxidative stress by nuclear translocation. A complex activation pattern is revealed in human cell culture systems, which differs between individual hFOXO factors and cell types. Studies with Drosophila showed that hypoxia was the only stressor that induced a dfoxo-dependent, local immune response activation. Since Drosophila has only one ortholog of FoxO, it was possible to show that the absence of dfoxo in the airways strongly increases the stress sensitivity of the airways. This stress sensitivity finds its counterpart in mouse models of chronic and acute asthma, with reduced mFoxO expression in the lung, particularly mFoxO1 and mFoxO3A. Finally, it is also reflected in asthma patients who show reduced hFOXO transcripts in their sputum samples. We conclude that active FoxO signaling in AECs is necessary to respond appropriately to stressors. Impaired FoxO signaling limits this ability and thus promotes disease development.
1 Introduction
Airway epithelial cells (AECs) form the barrier between the respiratory organs and the environment. Therefore, AECs are permanently exposed to physical stressors, pathogens, environmental pollutants, and allergens. A significant task of AECs is to orchestrate the lung’s responses to these environmental influences, thereby maintaining airway structural integrity and immune homeostasis (Hewitt & Lloyd, 2021; Weisberg et al, 2021; Whitsett & Alenghat, 2015). Impairment of these functions is associated with developing chronic lung diseases such as asthma, chronic obstructive pulmonary disease (COPD), or pulmonary fibrosis, supporting the hypothesis that these diseases are primarily epithelial (Celebi Sozener et al, 2020; Heijink et al, 2020; Hellings & Steelant, 2020; Lambrecht & Hammad, 2012). This interpretation is further supported by the fact that carriers of risk alleles for these diseases are particularly prone to develop deregulated epithelial immune functions (Hellings & Steelant, 2020; Pividori et al, 2019; Raby et al, 2023) and inappropriate repair responses (Burgoyne et al, 2021; Chung & Adcock, 2008). Significant disease hallmarks comprise airway remodeling and prolonged, persistent inflammatory reactions (McAlinden et al, 2019; Proud & Leigh, 2011; Spann et al, 2014; Zepp & Morrisey, 2019).
This central property of AECs to respond appropriately to a wide variety of intrinsic and extrinsic signals requires signaling systems that react to these signals and connect their activation with an appropriate cellular response. The transcription factors of the FoxO family precisely fulfill these requirements (Gui & Burgering, 2022; Orea-Soufi et al, 2022). They are critically involved in various cellular processes, including apoptosis, cell survival, oxidative stress responses, and energy metabolism (Graves & Milovanova, 2019). While the fruit fly Drosophila melanogaster has only one FoxO gene (dfoxo) (Junger et al, 2003), mammals have four FoxO factors (in humans: hFOXO1, hFOXO3, hFOXO4, and hFOXO6). In all these organisms, these factors act as integration hubs for different cellular signaling systems, such as the insulin and JNK pathways, responding to various signals (Cheng, 2019; Greer & Brunet, 2005; van der Vos & Coffer, 2011; Wagner et al, 2021).
The interest in FoxO factors is largely based on research efforts in two different scientific fields: aging and research on a broad spectrum of chronic diseases. In aging studies, increased FoxO activity usually correlates with a prolonged lifespan. This correlation initially found in models such as C. elegans and Drosophila (Giannakou et al, 2007; Sun et al, 2017), is further supported by the fact that hFOXO3A is the only human longevity gene identified to date (Donlon et al, 2022; Flachsbart et al, 2009). On the other hand, deregulation of hFOXO activities has been associated with various chronic human diseases (Manolopoulos et al, 2010; Orea-Soufi et al., 2022; van der Horst & Burgering, 2007; Xing et al, 2018). This causal relationship between altered hFOXO activity and disease pathogenesis has also been demonstrated for chronic lung diseases. Thus, a deficiency of the transcription factor hFOXO1 contributes to developing pulmonary hypertension (Savai et al, 2014; Selle et al, 2022). Deficiencies in hFOXO3, on the other hand, correlate with COPD and idiopathic pulmonary fibrosis (IPF) (Al-Tamari et al, 2018; Hwang et al, 2011). Moreover, alterations in the expression of hFOXO factors were associated with various cancer entities including lung cancer (Hornsveld et al, 2018; Jiramongkol & Lam, 2020; Mikse et al, 2010). In human respiratory epithelial cells, increased activation of the hFOXO signaling pathway directly controls an epithelial immune response, a mechanism first demonstrated in Drosophila (Becker et al, 2010; Seiler et al, 2013). Consistently, rhinoviral infection activates hFOXO3 in airway epithelia and helps to orchestrate antiviral responses (Gimenes-Junior et al, 2019). Recently, general aspects of FoxO biology in epithelial tissues were elucidated in Drosophila (Fink et al, 2016; Wagner et al., 2021).
To gain deeper insight into the importance of FoxO-mediated signaling in AECs, we performed analyses using Drosophila, mice, and humans. Our studies revealed the highly evolutionarily conserved activation of FoxO factors by various stressors in AECs. In human cells, nuclear translocation of hFOXO factors differed depending on the cell- and hFOXO type. Furthermore, dfoxo deficiency was associated with reduced stress tolerance in Drosophila. Indeed, the role of FoxO factors as hubs for the integration of stress signals was also evident in asthma mouse models, in which the amount of mFoxo transcripts was significantly reduced, and in asthma patients. These findings indicate that FoxO transcription factors are relevant in the pathogenesis of chronic inflammatory lung diseases.
2 Results
2.1 Hypoxia induces a dfoxo-dependent immune response in the Drosophila
Airways
Hypoxia is a vital airborne stressor that can induce a variety of responses. We have used the fruit fly Drosophila as a model to study these responses. To investigate which organs respond most strongly to a hypoxic episode, we used the LDH-Gal4/UAS-nGFP reporter strain, which induces nuclear expression of GFP under transcriptional control of the murine LDH-A enhancer and effectively monitors reactions to hypoxia in Drosophila (Lavista-Llanos et al, 2002). Hypoxia elicited a highly reproducible response in the airway epithelium but not in other organs (Figure 1A; background staining of the intestine represents autofluorescence caused by ingested food). This result suggests that the airway epithelium is the primary organ affected by hypoxia. In preliminary experiments, we observed that the epithelial immune system is susceptible to environmental cues. Therefore, we performed a transcript analysis of isolated tracheae, focusing on selected antimicrobial peptides (AMPs). We exposed Drosophila larvae to mild hypoxia (5 % O2 for 2 h) and found that some of the genes studied, namely cecropin, attacin, and drosomycin, were consistently and significantly up-regulated (p<0.05; Figure. 1B).
We then used the drosomycin-GFP (Drs-GFP) reporter line to elucidate the spatial dimension of this response. Here, the expression was strongly increased by hypoxic episodes (Figure 1C), and the expression appeared first in the most distal part of the airway system, where it was observed in most treated animals (yellow arrows; Figure 1C, D). Main branches showed little or no response under these conditions, whereas secondary and terminal branches showed strong fluorescence (red arrows; Figure. 1C, D). After prolonged hypoxia, all major branches (except the dorsal trunks) showed robust expression of this antimicrobial (antifungal) peptide gene. In contrast, other organ systems showed no induction of GFP expression in response to hypoxia (Figure. 1C, D). When adult animals were exposed to hypoxia, strong GFP expression was observed throughout the tracheal system (white arrows, Figure 1E). Detailed analysis revealed strong expression in tracheae close to the surface of the animal, namely those in the legs (Figure. 1F) and those regions immediately adjacent to the tracheal opening (Figure 1G).
To identify the underlying mechanism of this antimicrobial response flies expressing XFP-tagged transcription factors relevant to antimicrobial responses [UAS-relish-yfp, UAS-dorsal-gfp, UAS-dif-cfp (Bettencourt et al, 2004), and UAS-dfoxo-gfp] were targeted to the airways by crossing with ppk4-Gal4, a tracheal epithelium-specific driver line (Wagner et al, 2008). These animals were exposed to hypoxia. Neither Relish nor Dif or Dorsal showed any nuclear translocation following hypoxia. Under normoxic conditions, dfoxo-GFP localizes to the cytoplasm of airway epithelial cells (Figure 1H). In response to hypoxia, an almost complete translocation of dFoxo into the nucleus was observed (Figure 1I). Even after cessation of hypoxia, dFoxo-GFP remained in the nucleus for some time (usually more than 1h) before re-entering the cytoplasm.
Based on the above results, we tested whether dfoxo is necessary for hypoxia-induced expression of drosomycin in the trachea. In dFoxo-deficient animals (dfoxo21/21), hypoxia-induced drosomycin expression was absent, demonstrating that dfoxo is essential for this immune response (Figure 1J).
2.2 dfoxo translocation in response to different types of stimuli
Having shown that hypoxia is a major stressor capable of inducing dfoxo translation in the trachea, we investigated to what extent other stressors also induce this response. In parallel, we tested whether the other immune-related transcription factors, Dorsal and Relish, respond with nuclear translation. Ectopically expressed transcription factors labeled with GFP or YFP were introduced into the respiratory tract of Drosophila larvae using the Gal4/UAS system (Bettencourt et al., 2004). In the untreated control group, Dorsal, Relish, and dfoxo were localized in the cytoplasm (Figure 2A, A’, A’’). Starvation, oxidative stress, UV irradiation, cold stress, and heat stress resulted in a rapid translocation of dfoxo to the nucleus (Figure 2B-F). However, nuclear translocation of Relish (Figure 2B’-F’) and Dorsal (Figure 2B’’-F’’) was not observed, except for a partial nuclear translocation of Relish during starvation stress (Figure 2B’).
To analyze the underlying activation mechanisms, we also performed these studies when the JNK pathway was knocked down (induced mechanism with BskDN by co-expression of the dominant negative JNK allele (BskDN), Fig. 2G-K’). Under these conditions, the cold-(Fig. 2H, H’) and heat-induced (Fig. 2I, I’) translocation of dfoxo was not dependent on the JNK pathway, whereas hypoxia-induced dfoxo translocation was drastically reduced (Fig. 2K, K’).
2.3 Transcriptomic analyses of Drosophila airways upon dfoxo deregulation
We performed transcriptome analyses of isolated Drosophila larval airways to learn more about the processes involved in deregulated dfoxo expression. To this end, we analyzed the effects of dfoxo deficiency in dfoxo21/21 animals (Fig. 3A, B) and those of specific airway-targeted overexpression (Fig. 3C, D). dfoxo deficiency resulted in the upregulation of 1044 genes and the downregulation of 2133 genes (>1.5-fold, p<0.05). In contrast, dfoxo overexpression, specifically in the trachea (dfoxooe), resulted in the upregulation of 552 genes and the downregulation of 774 genes. In both experiments, control, and dfoxo21/21or dfoxooe tracheae were significantly separated in the corresponding PCA plots (Figure 3B, D). Overlaps between the different groups in the Venn diagram were particularly relevant (Figure 3E). We identified 265 genes that were downregulated in dFoxo-deficient tracheae and upregulated in dfoxooe tracheae. Enriched GO terms for biological processes in this cohort were mainly associated with cuticle development and muscle function and development. In addition, 81 genes were downregulated in dfoxooe flies and upregulated in dfoxo21/21 flies (Fig. 3E). We also found regulation in the same direction, including those that were downregulated (201 genes) or upregulated (62 genes) in both dfoxooeand dfoxo21/21 flies. All these overlaps were statistically significant (Fisher’s exact test, p<0.05; Fig. 3E). Genes downregulated in dfoxo21/21 flies were particularly interesting. The following KEGG pathways were enriched: various drug-related metabolic detoxification processes, glutathione metabolism, and amino acid metabolism (Figure 3F). Transcripts that were upregulated in dfoxo21/21airways were associated with the following KEGG pathways: DNA replication, Drug metabolism, and associated terms (Figure 3G). Figure 3H shows those transcripts related to the glutathione metabolism regulated in dfoxo21/21 airways. In addition, those heat shock proteins (Hsp) that show differential expression (compared to control airways) in dfoxo21/21 airways are also listed (Figure 3I).
2.4 Stress sensitivity of dfoxo deficient Drosophila
Having shown that various stressors activate dFoxo, we sought to test the hypothesis that dFoxo is essential for an adequate response to stressors. We compared dfoxo21/21 flies and their control counterparts (yw) after exposure to different stressors (Figure 4). It is known that daily exposure to cigarette smoke significantly shortens the lifespan of flies (Prange et al, 2018). Our experiment shows that this shortening was greater in dfoxo21/21 flies compared to control flies exposed to the same protocol (9 days for dfoxo21/21 flies versus 18 days median lifespan for control flies: Figure 4A). Drought stress also reduced the mean lifespan of adult flies. This lifespan-shortening effect was enhanced in dfoxo21/21 flies (32 h for dfoxo21/21 flies versus 46 h for control flies: Figure 4B). Finally, we examined the effects of hypoxia using a hypoxia-induced larval escape assay (Figure 4C) and the hypoxia recovery assay with adult flies (Figure 4D). In the former assay, dfoxo21/21 larvae were more sensitive to hypoxia than control larvae because they left the medium earlier (Figure 4C). In the latter assay, the dFoxo21/21 flies recovered much more slowly than the control flies (Figure 4D). Taken together, these experiments demonstrate the increased stress sensitivity of dfoxo-deficient animals.
2.5 Effects of hypoxia on hFOXO in human airway epithelial cells
We wondered whether the response to hypoxia observed in Drosophila would be similar in the human system. To analyze this, we first investigated whether the different hFOXO factors are expressed in the human lung. We took advantage of the human lung atlas (Vieira Braga et al, 2019) and evaluated the expression of the four hFOXO members (Figure 5A). hFOXO3 and, to a lesser extent, hFOXO1 and 4 showed broad expression in almost all cell types of the epithelium (Figure 5A). In contrast, hFOXO6 is expressed at much lower levels (Figure 5A). We used the lung epithelial cell line A549, exposed it to hypoxic conditions, and analyzed the translocation properties of the three major hFOXO factors, hFOXO1, 3, and 4, by immunohistochemistry (Figure 5B). hFOXO1 showed a robust nuclear translocation in response to hypoxia (Figure 5C), whereas the hypoxia-induced nuclear localization of hFOXO3 and hFOXO4 was less pronounced (Figure 5C). We then investigated the extent to which cytokines are also induced by hypoxia in A549 cells. We focused on two cytokines that were shown to react to stressors in airway epithelial cells reproducibly, CCL20 (Figure 5E) and CXCL8 (Figure 5F)(Guesdon et al, 2015; Ovrevik et al, 2009; Wolf & Moser, 2012). Both cytokines were significantly upregulated in our experiments in response to hypoxia.
2.5 Stress-induced nuclear translocation of hFOXO factors in human airway epithelial cells
Next, we used human cell lines representing different airway epithelial cell types to evaluate if the stressors identified in the Drosophila system also trigger the translocation of hFOXO factors (Figure 6). From many different cell lines of the human airway epithelium, we have selected two lines that differ as much as possible in their properties and origins and thus represent a large part of the diversity of these cell lines. One is the A549 line, a cancer cell line representing type 2 alveolar cells(Foster et al, 1998); the other is the BEAS-2B cell line, an immortalized airway epithelial cell line(Fujisawa et al, 2000). Under unstressed conditions, all hFOXO proteins (hFOXO1, hFOXO3, hFOXO4, and hFOXO6) were mostly restricted to the cytoplasm in both cell lines (Figure 6A, G, H). All tested stressors induced nuclear translocation of hFOXO1 in A549 cells (Figure 6A-F). Quantitative analysis of nuclear translocation of hFOXO proteins revealed striking differences between the two cell lines (Figure 6G, H). hFOXO1 underwent nuclear translocation in response to all stressors in A549 cells (Figure 6G), but only in response to oxidative stress in BEAS-2B cells (Figure 6H). hFOXO3A underwent nuclear translocation in response to oxidative stress, starvation, and UV irradiation in A549 cells (Figure 6G) but not in response to any stressor in BEAS-2B cells (Figure 6H). hFOXO4 (Figure 6G, H) and, to a lesser extent, hFOXO6 (Figure 6G, H) exhibited highly dynamic nuclear translocation following stress application in both cell lines, suggesting that cells in the upper (BEAS-2B) and lower (A549) airways respond differently to different stressors in terms of nuclear translocation of hFOXO proteins.
To validate this stress-induced nuclear translocation in an in vivo organ context, we challenged intact mouse tracheae with paraquat to induce oxidative stress. We focused on mFoxO1, which has shown a robust response to various stressors in cell culture experiments. Most of the mFoxO1 in untreated tracheae was in the cytoplasm and showed nuclear translocation in 52±4 % of the cells (Fig. 6I-K). After exposure to paraquat, a massive nuclear translocation of mFoxO1 (Fig. 6I-K) was observed in almost all cells (96±0.5 %; p<0.0001).
2.6 FoxO factors are reduced in airway epithelia of murine asthma models and in the sputum of asthmatic patients
So far we have shown that different stressors effectively activate FoxO signaling in the airway epithelia of flies, humans, and mice. Consequently, we asked whether the lung disease that is characterized by intense stress sensitivity, namely asthma, shows altered FoxO signaling in the airways. We analyzed different mouse models of asthma (acute and chronic, Figure 7). In the acute asthma model, mice were sensitized to ovalbumin (OVA) (Figure 7A–D). We considered the distal and proximal airways separately by physically separating and isolating these airways from each other. There were significant differences between the proximal and distal airways. A distal airway was defined as the segment of a terminal bronchiolus that, starting at the bronchioalveolar duct transition, extended up to five alveoli along the proximal direction (Wegmann et al, 2005). In untreated control mice, the relative expression of mFoxo factors was higher in proximal airways than in distal airways, and these differences were statistically significant for mFoxo4 and mFoxo6 (Figure 7C, D). The transcript levels of mFoxo genes were always reduced in OVA-treated mice. The transcript levels of mFoxo1 (Fig. 7A) in the proximal airways, mFoxo4 (Figure 7C), and mFoxo6 (Figure 7D) in the proximal and distal airways were significantly lower in OVA-treated mice than in control mice. Finally, we compared whole lung transcript levels between control mice and acute and chronic asthma models (Figures 7E-H). mFoxo expression was strongly reduced in entire lung tissue from mice with chronic experimental asthma (Figures 7E-H). Relative to the transcript levels in lung tissue from healthy mice (set to 100 % in 7E-H), the expression level of mFoxo1 (Figure 7E), mFoxo3 (Figure 7F), mFoxo4 (Figure 7G), and mFoxo6 (Figure 7H) in lungs from mice with chronic experimental asthma went down to 50 %, 47 %, 40 %, and 30 %, respectively, and all these reductions were statistically significant.
Finally, we wanted to see if these findings on the importance of FoxO factors in mouse and Drosophila models could also be observed in asthma patients. To this end, we compared the levels of hFOXO transcripts in sputum samples from asthmatic patients and healthy individuals. The levels of all four hFOXO factors were lower in sputum samples from asthmatic patients than in sputum samples from healthy controls (Figure 8A), and these differences were statistically significant for hFOXO1 and hFOXO3. We wanted to know whether hFOXO levels are also reduced in a matching well-defined experimental model of asthma. For this purpose, we used primary human epithelial cells from healthy donors and quantified the levels of hFOXO transcripts under control conditions and following Th2 priming by IL-4 treatment (Figure 8B). The transcript levels of all four hFOXO factors were strongly reduced in primary NHBEs stimulated with IL-4, and these differences were statistically significant for hFOXO1, hFOXO3, and hFOXO6, which showed reductions of 50 % or more (Figure 8B).
We propose that an appropriate FoxO signaling system is necessary to respond adequately to a wide range of stressors in the physiologically normal range, thereby maintaining homeostasis (Figure 8C). In asthmatics, however, this system is impaired, meaning that they can no longer react adequately to stressful situations. Thus, the transition from a physiological to a pathophysiological response occurs even in milder stress situations (Figure 8C).
3 Discussion
The present work identifies a phylogenetically highly conserved mechanism of cellular response to stressors in airway epithelial cells (AEC). These epithelial cells orchestrate the response of the whole organ to various stressors and thus enable the maintenance of the functional integrity of the entire organ. We showed that this critical task of maintaining a homeostatic situation depends on the activity of FoxO factors in these epithelial cells. Consequently, deregulation of the FoxO system in AECs can be associated with pathological conditions. We have demonstrated reduced levels of FoxO factors in asthma patients and experimental murine asthma models. This association is particularly true for FoxO1, which appears to be affected in the inflamed lungs of both species and has been linked to various diseases (Peng et al, 2020). In addition, we have shown that loss of FoxO signalling drastically reduces resistance to airborne stressors. To demonstrate the latter, we deliberately used the simple Drosophila model, in which only one dfoxo factor is present, which also fulfills crucial functions in the respiratory epithelium (Wagner et al., 2021). The reduced hFOXO activity that we have shown to correlate with asthma in various models also characterizes other chronic lung diseases. In pulmonary hypertension, pathology correlates with decreased hFOXO1 expression (Savai et al., 2014). It is also worth noting that deregulation of hFOXO1 in cells of the immune system such as macrophages may contribute to the pathogenesis of asthma (Chung et al, 2019). Reduced expression and activity of other hFOXO factors are also associated with lung diseases. For example, reduced hFOXO3A levels correlate with the development of COPD (Ganesan et al, 2013; Hwang et al., 2011; Pace et al, 2016) and IPF (Al-Tamari et al., 2018). This disease association is supported as hFOXO3 shows nuclear translocation in AECs from patients suffering from these diseases (Seiler et al., 2013). It is also worth mentioning that loss of hFOXO1 and hFOXO3A function is associated with several forms of lung cancer (Gao et al, 2018; Mikse et al., 2010; Wu et al, 2022).
Using the Drosophila system, we showed that reduced dfoxo levels and disease-related increased sensitivity to various stressors are causally linked. Following this line of thought, the reduced ability to respond appropriately to multiple stressors due to reduced hFOXO activity could lead to disease development in patients. Studies showing that FoxO factors orchestrate epithelial homeostasis, particularly in response to respiratory stressors and infections, are consistent with this interpretation (Gimenes-Junior et al., 2019; Pomies et al, 2016). Furthermore, skin epithelia defective in hFOXO1 expression have a reduced repair capacity (Mori et al, 2014), a finding that could also be applied to the lung epithelium. Further evidence supports the interpretation that hFOXO factors play a central role in various lung diseases. The main observation is that a reduced ability to repair damaged epithelia can be a decisive driver of a wide range of lung diseases. This interpretation applies in particular to chronic lung diseases such as COPD and IPF (Barnes et al, 2021), in which this reduced ability to repair can be triggered by the disease or acquired during the disease. The significance of hFOXO factors for the genesis of these diseases is an exciting topic for future research. Nevertheless, many indications already indicate that hFOXO factors are potential targets for specific interventions.
Our studies on the Th2 polarisation of NHBEs (Zissler et al, 2016) indicate a particularly close relationship between asthma and hFOXO factors. The polarization of primary epithelial cells induced by IL-4 treatment reduced the expression of all hFOXO factors, like that seen in asthma patients. This result means that the asthma-associated alteration of the airway epithelium, particularly the reduced repair capacity (Ijaz et al, 2014), is mediated by the reduced hFOXO expression in these cells.
The transcriptome analyses we performed comparing the airways of control animals with those of dfoxo-deficient Drosophila revealed a complete network of factors controlled by dfoxo in the airway. Other potential molecular targets associated with a higher prevalence of chronic inflammatory airway diseases are also part of this network. These include heat shock proteins, essential components of the molecular machinery that protects cells from stress (Son et al, 2018). The direct link between FoxO activation and the expression of HSP genes thus appears to be a central axis of the cellular stress response. Consequently, disruption of this axis also leads to reduced stress resistance (Donovan & Marr, 2016). In light of this information, it is unsurprising that altered expression of HSPs is associated with asthma (Hou et al, 2011). The increased occurrence of relevant HSPs is an excellent indicator of an actual cellular stress situation. On the other hand, reduced HSP activity leads to an inability to respond adequately to this stressful situation, which can then quickly lead to a pathological state. Thus, reduced hFOXO signaling via the impaired hFOXO-HSP axis could increase stress sensitivity (Donovan & Marr, 2016; Kim & Koh, 2017; Tower, 2011). Further studies should address the precise elucidation of this complex, FoxO-dependent network, and its significance for disease development.
The disease implication of deregulated FoxO expression in AECs is a direct consequence of the central physiological role of these transcription factors in adaptation to changing conditions, whether externally or internally induced. The fact that FoxO factors in airway epithelial cells respond to various stressors makes them ideal signaling hubs to adapt the cell response to a stress reaction. The phylogenetic conservation of this stress sensor system makes it possible to analyze its general properties in the simple Drosophila model. Here, we could also determine the causal relationship to reduced stress resistance.
In this study, we have selected a significant number of stressors that, at first glance, do not appear to be equally suitable in all systems but can provide us with information about the general stress response behavior of the AEC. For example, we chose paraquat as an oxidative stress generator because it can be used equally well in all systems (Drosophila, mouse, cell culture). Although heat and cold are extremely relevant stressors in Drosophila, they are only of limited significance in organisms of the same temperature, such as mice and humans. However, this does not apply to the respiratory air, which can bring such temperature differences to the AEC. In this context, we must realize that not all stressors are mediated via the same signaling pathway to FoxO activation. There is a differential response to the different stressors, particularly with the various hFOXO factors in humans.In contrast to the simple system of a single FoxO factor in Drosophila, the human system is complicated because four FoxO factors play this role. This presence of multiple FoxO factors means that the vertebrate system is characterized by high complexity, redundancy, and overlapping functions. In AECs, the four hFOXO factors showed specific response spectra toward different stressors. In particular, hFOXO1 responds very strongly with nuclear translation to various stressors. For the hFOXOs hFOXO3A and hFOXO4, the picture is somewhat more differentiated, as we observed responses to fewer stressors in each case, which also vary strongly between cell types. hFOXO6, on the other hand, generally shows low activation levels but is also expressed at shallow levels. Despite the wealth of information and structural differences leading to different activation modes, our knowledge of the interplay of hFOXO factors still needs to be more comprehensive (Potente et al, 2005; Spreitzer et al, 2022). This lack of information concerns the different targets and aspects, such as the complementarity of the action spectra or a functional substitution by compensatory effects. It can be concluded that the human lung is a very complex system in which the different hFOXO factors respond differently to stressors, and this response also differs between the cell types of the epithelium.
Our results show that FoxO factors in the airway epithelium respond to numerous stressors by translocating to the nucleus. In mammals, this response is FoxO factor- and cell type-specific, although there is considerable overlap. This observation suggests the mammalian lung has a highly complex and region-specific stress-sensing system based on FoxO factors. Furthermore, we have shown that a lack of dfoxo expression substantially enhances stress sensitivity, which may underlie the development of several chronic lung diseases. Therefore, FoxO factors and downstream and upstream signaling pathways in AECs are promising therapeutic targets for various chronic lung diseases.
Limitations of the study. We designed this study to identify phylogenetically conserved mechanisms of FoxO activation in airway epithelial cells. For this purpose, we used the experimental systems Drosophila, mouse, and patient material to work on the overall project’s partial aspects. We used Drosophila due to the presence of only one dfoxo gene for the general significance of the stress response. The mouse models partially reproduce the response characteristics to analyze acute and chronic asthma models and human material on the one hand for the stress responses of the different hFOXO factors and on the other hand to show the association with asthma using patient material. Although this experimental design provides a comprehensive overall picture, it also means that there are still gaps in the individual experimental systems that need to be closed by follow-up studies. This need for follow-up studies applies in particular to the part of human studies in which we have limited ourselves to available material.
4 Material and methods
4.1 Drosophila stocks, maintenance, and stress assays
Stocks and transgenic crossings were raised on standard cornmeal-agar medium at 21 °C at a relative humidity of at least 60 % in a 12 h:12 h light/dark cycle as described earlier (von Frieling et al, 2020; Wagner et al., 2021). The following strains used were supplied by the Bloomington and Kyoto/DGGR Stock Center or by scientists of the Drosophila research community: CantonS (BL1), w1118 (BL3605), Drs-GFP (BL55707), UAS-bskDN (BL6409), btl-Gal4 (Christian Klämbt, Münster, Germany), ppk4-Gal4 (Mike Welsh, Iowa, USA), UAS-foxo-gfp (Wagner et al, 2009), UAS-foxo (BL9575), UAS-foxo-TM (Marc Tatar, Brown University, USA), foxo21/21 (Ernst Hafen, Zuerich, Switzerland) (Junger et al., 2003), UAS-relish-yfp, LDH-Gal4/UAS-nGFP (Pablo Wappner, Buenoes Aires, Argentina), and UAS-dorsal-gfp (Tony Ip, Massachusetts, USA). To induce expression of either genes of interest or GFP fusion proteins in larval airways we used the binary Gal4/UAS expression system (Brand & Perrimon, 1993). dFoxo overexpression experiments were performed using the Target system employing the temperature-sensitive tubP-Gal80ts element (McGuire et al, 2004). Therefore, controls were maintained at 18°C, whereas activation was achieved by shifting the temperature to 30°C for 24h.
For all stress tests early 3rd instar larvae were used. Starvation, irradiation, and oxidative stress experiments were done in PBS at 21°C. Starvation experiments proceeded by incubation on PBS-soaked filters for 12 h. For irradiation experiments, larvae were exposed to UV light (254 nm, distance 1 cm) for 15 min with a following incubation in a medium up to 2 h. Oxidative stress was induced using the chemical paraquat (Methyl viologen dichloride hydrate, Sigma-Aldrich, Steinheim, Germany) 100 mM working concentration in a medium enriched solution. Larvae were incubated in the paraquat solution for 1 h and then transferred to medium for an additional hour. Temperature experiments were performed within the medium. Animals subjected to heat shock were incubated at 37°C for 30 min, translocation experiments were carried out immediately or the larvae remained for 90 min at room temperature. Cold treatment was performed at 4°C for 2 h. Hypoxia (1% O2) was applied for 4 h under otherwise normal conditions.
Hypoxia induced larval escape assays were performed as shown (Kallsen et al, 2015). For the hypoxia recovery assay, animals were briefly (15 s) anesthetized with N2 and the time to recovery was measured. For the desiccation assay animals were placed into empty vials under constant conditions and survival was monitored. For chronic cigarette smoke exposure, animals were subjected to daily doses of cigarette smoke, and their survival was also monitored daily. For hypoxia experiments, animals were subjected to 5% O2 for the indicated times. Microscopic analyses regarding Drosophila were done in vivo with early 3rd instar larvae using a SZX16 stereo microscope and a DP72 camera (Olympus, Hamburg, Germany), and a Zeiss 880 CLSM. Detection of GFP signals was done with an Ex 460-490nm.
4.2 Drosophila transcriptomics
Tracheae were manually isolated from 3rd instar larvae and processed as described earlier (Bossen et al, 2019; Kallsen et al., 2015; Prange et al., 2018). The dissected tissue was suspended in RNA Magic (Bio Budget) and homogenized in a bead mill using 1.4 mm zirconia beads (Biolabproducts, Bebensee, Germany). Total RNA input quality was evaluated on a TapeStation 4200 (Agilent, USA), and all samples showed a RIN score > 8. Samples were quantified with a fluorometric dye (Quant-IT, Thermofisher, USA) and between 187 and 500 ng per sample were used as input for the TruSeq stranded mRNA library kit (Illumina, USA) following the manufacturers manual. Resulting libraries showed a fragment size distribution of around 350 bp and were sequenced on a HiSeq 4000 (Illumina, USA) with 50bp single-end reads. Differential expression of sequencing data (GSE176540) was performed with the CLC genomic workbench software (http://www. clcbio.com/products/clc-genomics-workbench) (Qiagen, Hilden, Germany), using the Drosophila melanogaster reference genome (Release 6) (Hoskins et al, 2015). GO analyses were conducted by using the g:Profiler tool (Raudvere et al, 2019).
4.3 Cell culture (human-derived cell lines) and stress assays
The alveolar epithelium cell line A549 and the bronchial epithelial cell line BEAS-2B were cultured in RPMI (Biochrom, Berlin, Germany) supplemented with 10 % fetal calf serum, 100 U/ml penicillin, and 100 µg/ml streptomycin at 37°C with 5 % CO2. Stress experiments were performed in µ-Slides 8 well ibiTreat (Ibidi, Martinsried, Germany) with 2,5×104 cells per well, cells adhered to the slides overnight. Medium was replaced with either pure RPMI (unsupplemented control), RPMI with paraquat [20 mM] (oxidative stress) or PBS (starvation) and incubated for 1 h at 37°C with 5 % CO2. Induction of cold and heat stress took place for 1 h each at 41°C and 4°C, respectively. Exposure to UV light (254 nm, distance 1 cm) took place for 15 min with a following incubation up to 1 h. Hypoxic conditions were effectuated in a supplemented medium for 2 h and 5 % O2, by discharging of N2 into a gas-tight chamber. Immediately afterward cells were fixed with 3 % paraformaldehyde, permeabilized with 0,25 % Triton-X/PBS, blocked with 10 % BSA/PBS and incubated with primary antibodies: anti-FoxO1A antibody (rabbit polyclonal ChIP Grade), anti-FoxO3A antibody (rabbit polyclonal), anti-FoxO4 antibody (rabbit polyclonal); (abcam, Cambridge, UK) or anti-FoxO3 antibody (rabbit polyclonal); (Thermo Sci. / Pierce Biotech, Rockford, USA), secondary antibody: Alexa Fluor 488 goat anti-mouse IgG (Invitrogen, Karlsruhe, Germany). Nuclei were stained with Bisbenzimide H 33342 (Sigma-Aldrich, Deisenhofen, Germany).
Human cells (A549 and BEAS-2B) were investigated using the TCS Sp5 Inverted Confocal laser scanning microscope (Leica Microsystems, Wetzlar, Germany) and a 20x /0.70 HC Plan Apochromat, oil-objective. Antibody and Hoechst-signals were detected with excitation lines of 488 and 405 nm, respectively. All editing procedures were carried out with the Leica LAS AF Lite program. Quantification of the nuclear translocation in the A549 and BEAS-2B was performed using ImageJ software (Wayne Rasband, NIH). Randomly selected cells were photographed, and all images were taken with constant settings. Considering the area size, the average fluorescence intensity of the nucleus and cytoplasm was determined. The ratio between nucleus and cytoplasm are shown graphically and compared to the ratio of untreated control cells.
Relative quantification of human cytokine transcripts of CCL20 and CXCL8 (IL8) was performed by real-time PCR. Total RNA (A549 cells; standard incubation control and after 1,2,4 h at hypoxic conditions) was extracted using the NucleSpin RNA Kit (Macherey-Nagel, Düren, Germany) according to the manufacturer’s instructions. 500 ng of each RNA sample was transcribed into cDNA, using Oligo dt 12-18 primer mix, RNAse OUT, dNTP mix and SuperScript reverse transcriptase (Invitrogen, Darmstadt, Germany)). The human HPRT gen served as reference für relative expression. Statistical analysis: rato paired t-test, CCL20: n=7, CXCL8 n=6.
4.4 Detection of mFoxO1 nuclear translocation in AECs of the murine trachea
Three-month-old C57BL/6 female mice were used. All experiments were performed in accordance with the government guidelines for animal welfare of the Land Schleswig-Holstein. Mice were killed by an overdose of isoflurane and the trachea was explanted, opened along the tracheal muscle, and cut in half. One half was incubated for 30 min at 37 °C in 100 mM paraquat (Sigma-Aldrich, Taufkirchen, Germany) prepared in HEPES-buffered Ringer solution. The other half was incubated in HEPES-buffered Ringer solution lacking paraquat. Thereafter, the tissue was fixed with PBS containing 4 % paraformaldehyde and processed for immunohistochemistry with an anti-FoxO1 antibody (1:1000 in TBS, Thermo Fisher Scientific, Rockford, USA) at room temperature overnight followed by Alexa Fluor 555-conjugated donkey anti-rabbit IgG (1:500 in TBS, Invitrogen, Karlsruhe, Germany) for 1 h at room temperature and then Hoechst 33258 (1:10,000 in TBS; Sigma-Aldrich GmbH, Taufkirchen, Germany) for 10 min. Three-dimensional confocal image stacks of the epithelial layer were acquired and processed using the ImageJ “Cell Counter” Plugin. AECs were counted in 4 stimulated and 4 control pieces of the trachea. Approximately 200 nuclei were analyzed per piece.
4.5 Quantification of gene expression in mouse lung tissue
Animal experiments were performed using female C57BL/6J (Charles River, Sulzfeld, Germany) mice for expression analysis in proximal and distal airways and for expression analysis in acute and chronic asthma models. All animal studies were approved by the local animal ethics committee (for the acute asthma model: 13-3/20, for the chronic asthma model: 55-6/20; Behörde das Ministerium für Landwirtschaft, ländliche Räume, Europa und Verbraucherschutz Schleswig-Holstein).
Mice were subjected only to the standard mouse protocol for acute experimental allergic asthma (Bulek et al, 2009), while the other mice were exposed to the protocols for both acute and chronic experimental allergic asthma (Wegmann et al., 2005). In brief, mice were first systemically sensitized against ovalbumin (OVA) by intraperitoneal (i.p.) injection of 10 µg dissolved OVA in 100 µl PBS and 100 µl aluminium hydroxide as adjuvant on day 1, 14 and 21. On days 26-28, animals were exposed to OVA aerosol (1% OVA dissolved in PBS) in an airtight chamber for 20 min. For the chronic asthma model the sensitization was continued twice weekly for 12 weeks on. Control animals received an i.p injection with PBS on the same days and were treated with a PBS aerosol likewise. Lungs were filled with 600 µl RNAlater (Thermo Scientific, Darmstadt, Germany) dissected, and lungs were divided into proximal and distal parts if necessary. The tissue was transferred into RNA lysis buffer, snap-frozen in liquid nitrogen, and homogenized mechanically with the addition of liquid nitrogen. RNA isolation was performed from 30 mg using the RNeasy Micro Kit (Qiagen, Hilden, Germany) according to the manufacturer’s instructions. RNA concentration and purity were determined using a nanophotometer. Reverse transcription of the isolated RNA into cDNA was performed using the Maxima First Strand cDNA Synthesis Kit (Thermo Scientific, Darmstadt, Germany) according to the instructions of the manufacturer. Gene expression was determined by qRT-PCR on Light Cycler 480II (Roche, Mannheim, Germany) using 2.5 μl cDNA, SYBR Green Mastermix (Roche, Mannheim, Germany), and 10 pmol/μl of each primer. Expression of the gene rpl32 was used as a reference. The sequences of the primers were as follows: rpl32: for 5’-AAAATTAAGCGAAACTGGCG-3’, rev 5’-GAAGATGGTGATGGGCTTCC-3’; mfoxO1: for 5’-CTTCAAGGATAAGGGCGACA-3’, rev 5’-GACAGATTGTGGCGAATTGA-3’; mfoxO3a: for 5’-GCTAAGCAGGCCTCATCTCA-3’, rev 5’-TTGTGTCAGTTTGAGGGTCT-3’; mfoxO4: for 5’-TGTGCTCGCATCTCCTACTG-3’, rev 5’-GACTCAGGGATCTGGCTCAAA-3’; mfoxO6: for 5’-CAAGAGACTCACGCTCTCGC −3’, rev 5’-GCCGAATGGAGTTCTTCCAGC-3’.
4.6 Human study subjects, lung function testing, sputum sampling, and primary cell culture
Healthy subjects (n=12) and mild, well-controlled, allergic asthma patients along the GINA definition in season (n=9) in good health (FEV1% >70%) with a history of clinically significant hay fever during the grass-pollen season since more than two years were included. For asthmatic subjects, a GINA classification was performed. All subjects completed a Rhinoconjunctivitis Quality of Life Questionnaire (RQLQ), a lung function test, and a hypertonic saline sputum induction, performed in the Allergy Section, Department of Otolaryngology, TUM School of Medicine. Each participant provided written informed consent. This study was approved by the local ethics committee (5534/12). Baseline lung function was evaluated using a calibrated handheld pulmonary function testing device (Jaeger SpiroPro; Würzburg, Germany). The following parameters were recorded: VC, FEV1, FEV1/VC, and maximum expiratory flow 25% (MEF 25%). Bronchodilatator reversibility was tested after 400 µg of salbutamol.
Participants first inhaled salbutamol and consecutively nebulized hypertonic saline at increasing concentrations of 3%, 4%, and 5% NaCl every 7 min according to previous publications. During this procedure, participants cleaned their noses and rinsed their mouth to reduce squamous epithelium cells in the samples. Sputum was processed within one hour of collection. The selected sputum plugs, which contained as little saliva as possible were placed in a weighed Eppendorf tube and processed with 4x weight/volume of sputolysin working solution (Merck, Darmstadt, Germany). Afterwards, 2x weight/volume of phosphate-buffered saline (PBS) was added. Samples were filtered through a 70-µm mesh and centrifuged for 10 min at 790xg without break to remove the cells. Appropriate sputum samples were obtained from 12 healthy controls and 9 asthma patients during the grass-pollen season.
Primary NHBEs (Lonza, Walkersville, MD) of six genetically independent donors were grown as monolayers in 100% humidity and 5% CO2 at 37 1C in serum-free defined growth media (BEGM, Lonza). NHBEs (passage 3) were used at about 80% confluence in 6-well plates. To avoid gene expression changes or influences on the IL-4 signaling induced by growth factors in the BEGM medium, cells were rested in basal medium (BEBM) for 12 h, then stimulated with recombinant human IL-4 at 50 ng/mL (R&D Systems, Minneapolis, MN) in BEBM medium for 6 h or BEBM medium as control condition. For RNA analysis, harvested cells were lysed in RLT buffer (Qiagen, Hilden, Germany) containing 1% beta-mercaptoethanol (Roth, Karlsruhe, Germany) directly in the cell culture well.
Total RNA was extracted using RNeasy Mini Kit (Qiagen, Hilden, Germany) with on-column DNase digestion (Qiagen) for avoiding DNA contaminations. RNA quantification was performed by ultraviolet–visible spectrophotometry (Nanodrop Technologies, Wilmington, DE), for assessment of the RNA integrity by the RNA 6000 Nano Chip Kit with the Agilent 2100 Bioanalyzer (Agilent Technologies, Waldbronn, Germany), and samples with RIN number above 7.5 were used for micro-array analysis. Total RNA was amplified and Cy3-labeled by using the one-color Low Input Quick Amp Labeling Kit (Agilent Technologies) according to the manufacturer’s protocol. Hybridization to SurePrint G3 Human Gene Expression 8×60K Microarrays (Agilent Technologies) was performed with the Gene Expression Hybridization Kit (Agilent Technologies) as described before.
Data import using a standard baseline transformation to the median of all values was performed, including log transformation and computation of fold changes. Subsequently, a principle component analysis (PCA) was conducted and revealed a homogenous component distribution. Compromised array signals (array spot is non-uniform if pixel noise of feature exceeds threshold or above saturation threshold) were excluded from further analysis. For this analysis, we set the normalized values of each healthy donor in sputum samples to 1 and calculated the difference of FoxO1, FoxO3, FoxO4, and FoxO6 expression in sputum of the asthma patient. For analysis of FoxO1, FoxO3, FoxO4, and FoxO6 expression in primary normal human bronchial epithelial cells (NHBEs), we set the normalized values of medium conditions (in NHBEs) to 1 and calculated the difference in abundance of the IL-4 stimulated condition. The data discussed in this publication have been deposited in NCBI’s Gene Expression Omnibus (GEO) and are accessible through GEO Series accession number GSE167225.
For RNA quality assessment, RNA integrity numbers (RIN) were measured via Agilent 2100 Bioanalyzer (Agilent Technologies, Santa Clara, CA, USA). After quality assessment, isolated total RNA was subjected to reverse transcription using a high-capacity cDNA kit (Applied Biosystems, USA), following the manufactureŕs instructions. Real-time PCR profiles were visualized using the commercially available FastStart Universal SYBR Green Mastermix (Roche, SUI) and Qiagen human Primer Assays (Qiagen, Hilden, Germany) specific for FoxO1 and FoxO3 (the latter only in NHBEs), and quantified by the ViiA 7 Real-Time PCR System (Applied Biosystems, USA). The amount of FoxO1 and FoxO3 mRNA expression was normalized with endogenous control TFRH, GAPDH and ß-actin (housekeeping gene index, DCt values) and the relative quantification and calculation of range of confidence was performed using the comparative threshold cycle (2-DDCt) method (relative gene expression). All amplifications were carried out at least in duplicate.
All experimental procedures and analyses were conducted by blinded research staff. Non-parametric Mann–Whitney U tests were used to determine significant differences between patient groups. All statistical tests were performed two-sided.
Author contributions
T.R., H.H., and P. I. P. conceived the project. T.R., H.H., P.I.P., I.B., K.U., C.S.W., P.K. wrote the manuscript. K.U., J.B., X.N., U.Z. R.P. C.F., M.P. C.V., C.W., S.F., and A.A. performed all experiments, analyzed the data, and made the figures.
Acknowledgements
This work was supported by grants from the Deutsche Forschungsgemeinschaft (DFG) as part of the CRCs TR22 (TPA7) and 1182 (TPC2) and INST 257/591-1 FUGG as well as from the University Kiel in the program of the LeibnizCampus EvoLung.
Conflict of interest statement
All authors declare no conflict of interest.
Data availability statement
The data that support the findings of this study are available from the corresponding author upon reasonable request.
ORCID IDs
Karin Uliczka: 0009-0008-2114-6179
Judith Bossen: 0000-0002-6604-4570
Ulrich Zissler: 0000-0003-4826-3419
Christine Fink: 0000-0003-0083-2168
Xiao Niu: 0000-0001-5246-1376
Mario Pieper: 0000-0003-2589-6782
Ruben D. Prange: 0000-0001-6941-4509
Christina Vock: 0000-0003-3936-3426
Christina Wagner: 0009-0005-8121-0046
Mirjam Knop: 0009-0002-2530-9701
Ahmed Abdelsadik: 0000-0002-4782-6681
Sören Franzenburg: 0000-0001-6374-4910
Iris Bruchhaus: 0000-0002-3363-7409
Michael Wegmann: 0000-0002-1658-1554
Peter König: 0009-0000-7637-7451
Carsten Schmidt-Weber: 0000-0002-3203-8084
Petra Pfefferle: 0000-0002-3102-3737
Holger Heine: 0000-0001-8128-5068
Thomas Roeder: 0000-0002-3489-3834
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