Background
An increase in incidence trends for two major chronic diseases, asthma and obesity, and a plausible ‘association’ thereof was premised as early as 1999 [
1]. Epidemiological and fundamental research since then has confirmed asthma to be a major risk factor in obese individuals [
2‐
5], and yet an ambiguity remains in defining a definite ‘causal’ relationship. Rasmussen and Hancox [
6] in a recent review assessed the available literature on asthma and obesity, summarizing three plausible mechanisms that could explain the observed associations between the two chronic conditions; viz., (i) altered breathing mechanics in obese that contribute to the airway hyperresponsiveness (AHR), (ii) an underlying inflammatory pathway driven by adipose-secreted mediators or ‘adipokines’, and finally (iii) lifestyle changes contributing to gene-environmental interactions in those already pre-disposed to asthma. Several experimental animal (mouse) models of obesity exhibit adipokines to contribute to the airway inflammation antecedent to development of an asthma-like phenotype or trigger a heightened response post stimuli (reviewed in [
7,
8]. On the contrary, data in humans, investigating the same association is less conclusive, [
4,
6,
8,
9] and at times, conflicting [
10‐
12].
Though airway inflammation or ‘bronchitis’ is considered responsible for the physiologic consequences of asthma, it is the AHR that distinguishes it from other obstructive lung disorders [
13,
14]. Increased AHR has been reported in non-asthmatic obese individuals [
15] and in teenagers with high body mass index (BMI) [
16]. Indeed, while discussing their experimental diet-induced mouse models [
17], Shore et al., commented that innate AHR was a characteristic feature of obese mice independent of the modality of obesity induction. A recent study by Al-Alwan and co-workers [
18], reported that the inverse relation between adipose mass with lung function in obese asthmatics is attributed to the diminished respiratory compliance (compressed lungs in obese). But as rightly pointed out by Robert H. Brown [
19] the study failed to address the real question: why obese individuals are at risk to develop asthma?
In the past 15 years, the focal point of asthma-obesity research has been centred on investigating the inflammatory profile common to both diseases as the ‘causal’ link. The release of adipokines from adipose stores along with increase in pro-inflammatory mediators, a phenomenon termed ‘metabolic inflammation’, till date remains responsible for the obesity-derived systemic complications like type 2 diabetes, staetohepatitis and metabolic syndrome (30). Consequent studies have confirmed that obese individuals have increased levels of adipokines and increased markers of systemic inflammation (like C-reactive protein) which positively correlates to asthma development and severity (6, 9). IL-6 and TNF-α govern the chronic low-lying systemic inflammation characteristic of obesity by paracrine inhibition of the anti-inflammatory adipokine “adiponectin” (8, 9, 33). Indeed, sputum adiponectin levels are lower in asthmatics compared to healthy, and high sputum adiponectin was computed with lower odds of asthma development, implying an altered inflammatory state in the lungs to be the causal link (34). On the contrary, Sidleva et al., reported a 12-month observation study of obese asthmatic women post-bariatric surgery, where the extent of reduction in adiposity was directly associated with reduced AHR, independent of the airway inflammation (12).
It is evident from animal models, that obesity can induce AHR via immunological mechanisms [
7,
8]. Shore et al., reported that leptin, a pro-inflammatory adipokine directly correlated with the increased risk of asthma in obese [
6,
9,
20], when exogenously administered to ovalbumin-sensitized mice augments induction of AHR [
21]. This is in contrast to their subsequent studies where leptin-deficient obese mouse models developed innate AHR [
7,
22]. Again, diet-induced obese mice developed innate AHR, which was dependent on the amount of time the obesity existed rather than its onset or the body mass [
17]. The study showed a distinct effect of time on the inflammatory profile, where a significant quantity of serum leptin was measured in 30-week-old animals (compared to 22-week-old animals), which coincided with the measured AHR. Since human ASM cells express the receptor for leptin [
23], a recent study by our research group showed exogenous addition of leptin to ASM, in vitro, inhibits smooth muscle migration, proliferation and IL-13-induced eotaxin. Thus, in contrast to the mouse models, it is unlikely that leptin-induced inflammation be the causal factor in the asthma-obesity relationship. In accordance, a population-based birth cohort study from New Zealand failed to show any statistical significance between serum leptin and clinical markers of asthma [
10].
Besides leptin and adiponectin, adipokines consist of an array of mediators produced by adipocytes that include vinfastin, resistin, adipsin, in addition to eicasanoids and cytokines like IL-6, eotaxin and tumour necrosis factor alpha (TNFα), all of which have the potential to affect the ASM biology, dependent/independent of leptin [
9]. There is no evidence to indicate that increased secretion of adipokines from adipose mass from human subjects could modulate ASM biology into a diseased phenotype distinctive of asthma, characterised by hyperplasia, hypertrophy and hyperreactivity [
24]. Therefore, our current study was designed to identify a disease-defining role of adipocytes on ASM by engaging the entire array of mediators released, instead of segregating the effect of only “leptin” or “adiponectin”. Additionally, since visceral adipose tissue has been previously documented to be the main source of adiponectin [
25], along with a variation in leptin gene expression between the adipose sites [
26]; the study design also attempted to differentiate the effect of adipocytes isolated from different anatomical fat depots i.e. subcutaneous (extrathoracic) and visceral (intrathoracic), on ASM biology. The current study thus aimed to investigate the direct effect of adipocytes on ASM in an in vitro system, without the influence of circulating immune cells and other in vivo factors.
Methods
All human samples used in the study had informed consent from respective patients and approval (#08–3085) from the Hamilton Integrated Research Ethics Board, St. Joseph’s Healthcare (HiREB, Hamilton, Ontario, Canada).
Human adipocyte culture
Intrathoracic adipose tissue samples harvested from the mediastinum while extra-thoracic samples from the chest wall of the same patient, were collected during scheduled thoracic surgeries (refer to Table
1 for patient characteristics), and were processed separately (in parallel), as described [
27]. Isolated adipocytes were cultured with 1% FBS-supplemented media, until 80% confluence was attained. Thereafter, they were maintained in serum-free adipocyte media for 3 days. The conditioned supernatants were used for ASMC stimulation or stored at -80 °C for future experiments. Regular quality control checks were performed for assessing purity of the cells acquired through these established in vitro protocols.
Table 1
Subject Characteristics
Migration experiments, n | 6 |
Other experiments, n | 6 |
Males/Females | 2/4 |
Height, cm (mean ± SD) | 166 ± 7.5 |
Body mass index (mean ± SD) | 32.9 ± 6.1 |
Age in years (mean ± SD) | 69.5 ± 13.3 |
FEV1, % predicted | 75.33 ± 22 |
Human adipocyte and ASM co-culture
Smooth muscle tissue isolated from macroscopically disease-free areas of human bronchi (obtained from lung tissues resected for cancer), were grown to confluence as previously described [
28]. Experiments were conducted between passages 2–4. Human ASM cells (ASMC) were seeded at 10
5 cells/mL in the basolateral chamber of the Transwell
® inserts (3.0 μm pore-size, Corning Life Sciences, Tewksbury, MA) and maintained in 10% FBS-supplemented media for 3 days [
28]. Thereafter, isolated adipocytes from both sites [
27], were seeded separately on the apical chambers; the co-culture hereon was maintained in 1% FBS supplemented adipocyte media.
Proliferation assays
The proliferation of ASMCs was assessed by cell-counting as described elsewhere [
29]. Briefly, ASMCs were seeded at 10
5 cells/mL in a 24 well-plate maintained in 10% FBS RPMI for 24 h, following which a synchronization of the cell-cycle was allowed in serum-free conditions for 24 h. Subsequently, the ASMCs were challenged with either control or adipocyte-conditioned media for four days before counting using trypan blue exclusion method.
Migration assays
The effect of adipocyte-released mediators on the migrational property of ASMCs was assessed by Transwell® based migration protocol as previously described [
28]. Briefly, ASMCs serum-starved for 24 h, were seeded on to the apical chambers of a collagen-coated 8.0 μm pore Transwell® plate containing adipocyte-conditioned media in the basolateral chamber. The number of migrated cells stuck on the lower surface of the insert was counted and processed. 10 ng/mL PDGF was used as a positive control as per previous reports [
23,
28].
Bovine tracheal muscle bath techniques
Isometric contractility studies were performed with bovine tracheal strips standardized with 60 mM KCl [
23]. It was made sure that the tracheal strips did not have any residual traces of epithelium attached. The tissues were primed with adipocyte-conditioned media (or control) diluted (1:2) in Krebs-Ringer’s solution for 20 min and treated subsequently with either increasing strengths of carbachol (10
− 10 – 10
− 5 M), or isoproterenol (10
− 10 – 10
− 5 M). Each dose was added when the previous dose reached a plateau. After the last dose, the tissues were washed and a final KCl challenge was performed to verify the continued viability of the tissues.
Cytokine analysis
A Bio-Plex Pro Bead Assay (Bio-Rad, Mississauga, ON) was used to measure IL-6, TNF-α and eotaxin with results analysed on Bio-Plex Manager 6.0 Software (Bio-Rad Laboratories Inc., Mississauga, ON). The limits of detection were 1.54, 1.51 and 4.75 pg/mL for IL-6, eotaxin and TNF-α respectively.
Statistics
Comparisons of proliferation, migration and cytokine synthesis between the tested conditions were assessed using repeated measures analyses of variance (ANOVA) on GraphPad Prism version 7.0 (La Jolla, CA, USA), unless mentioned otherwise. Dose-response curves were constructed using non-linear regression. Results were expressed as mean ± standard error (SEM) from n = 2 technical repeats from samples collected from 6 individual donors. A P value < 0.05 was considered as significant.
Discussion
For the first time, we hereby report that human adipocytes (and secreted mediators) isolated from both subcutaneous (extra-thoracic) and visceral (intra-thoracic) adipose sites, do not affect the proliferative or the chemotactic responses of human ASMCs. In addition, they have negligible effect on the contractility, a property crucial to consider the hyper-responsiveness component of asthma. But adipocytes have the capability to stimulate ASMCs to release eotaxin and IL-6, which are pro-inflammatory in nature, thereby contributing to the chronic inflammatory state, archetypal for both asthma and obesity.
While obesity is now recognised as a pro-inflammatory systemic state, airway inflammation is considered to be pivotal component in asthma pathophysiology. However, in a study with 727 adult participants we failed to document any association between BMI and airway inflammation (measured by sputum cell counts) [
30]. In a subsequent study, elevated sputum IL-5 and submucosal airway eosinophilia (and not sputum) were documented to be significantly elevated in severe asthmatics with obesity [
31]. The detectable increase in IL-5 in the sputum, in the absence of any association with sputum eosinophils, could be attributed to an alternative source/pathway. In the current study, we observed that adipocyte-conditioned media as well as direct culture with adipocytes, stimulated ASM cells towards an inflammatory state (Fig.
4a, b). Adipocyte-conditioned media from both sites accounted for a significant release of both IL-6 and eotaxin from ASMCs post 24 h compared to control unconditioned media. Comparative to the conditioned media, a significant increase in eotaxin release was seen in the co-cultures for all tested conditions (
P = 0.0003, Two-way ANOVA), whereas IL-6 release was highly variable. The increase of eotaxin release in the co-culture could be attributed to the presence of 10% FBS in the media, which was absolutely required for sustenance of the co-culture. Nevertheless, the result provides initial evidence that adipocytes directly affect and maintain the inflammatory state of the ASMs. Increased eotaxin release from the adipocytes, classically known to recruit eosinophils into the tissue, could explain the increased sputum eosinophils into the submucosa and the associated IL-5 seen by Desai., et al. [
31]. In addition, a recent study demonstrated that the newly described tissue resident group 2 innate lymphoid cells (ILC2s) were activated upon calorie-intake, with secretion of IL-5 in situ [
32]. In particular, ILC2s resident in the visceral adipose tissue (VAT) sustained eosinophilia [
33]. Further, we recently documented increased abundance of IL5
+ ILC2s in the sputum of severe asthmatics compared to mild and healthy. Therefore, the role of these cells in substantiating the inflammatory state initiated by the adipocytes, and further contributing to asthma severity requires investigation.
The relationship between the documented increase in AHR with a higher adiposity index can be adequately explained by the changes in breathing mechanics, rather than ‘inflammation’ [
6,
34]. Shallow breathing (increased frequency, lower tidal volumes) and reduced deep inspirations in obese individuals lead to reduced lung volumes which has a profound effect on the ASM unloading, and thereby the AHR to methacholine [
35]. This can explain the innate AHR observed in non-asthmatic obese population [
15] but not the animal models [
7,
17], since the mice are ventilated at fixed tidal volume and ASM unloading does not occur during AHR measurements. If it is to be assumed that the mouse models closely mimic the disease progression in humans, then it is highly likely that changes in the ASM have a different etiology independent of the altered breathing mechanics. Consequently, the likelihood of increased adipose depots and their secreted products modulating the ASM biology was the main scope of this study.
Countering this study question, the data fails to show any significant modulatory effects of adipocytes and its secreted products on the ASM proliferation (Fig.
1), migration (Fig.
2) or contractility of bovine muscle strips (Fig.
3). These observations could therefore explain the results of Sutherland et al., where no apparent association between leptin and adiponectin levels with asthma was documented [
10]. Furthermore, the first randomised trial of a weight-loss regimen on improvement of asthma symptoms, showed a weak association of serum leptin with the measured total lung capacity and hyperreactivity pre- and post-intervention [
36].
Only low levels of leptin could be detected in the adipocyte-conditioned supernatants (data not shown) by ELISA, when compared to previously reported studies [
37,
38]. This is possibly due to differences in culture methods or likely due to lower concentrations of isolated adipocytes. Previously, eotaxin production by ASM stimulated by 100 ng/mL leptin (48 ± 46 pg/mL,
n = 5) was reported to be lesser that that produced by unstimulated cells (67 ± 74 pg/mL,
n = 5) [
23]. This is contrary to the significant amount of eotaxin production by ASM cultured with adipocyte-conditioned media containing a cocktail of adipokines (41 ± 16 pg/ml vs. control 17 ± 11 pg/ml,
P = 0.0067,
n = 6). It is therefore evident, that any plausible inflammatory mechanism that might affect the ASM in obese is factored in by one or more of the mediator(s) released and not just by leptin alone. In fact, it is increasingly being recognised that the stromal vascular fraction and the tissue matrix constituting the ‘non-fat cells’ of the adipose tissue contribute significantly to the inflammatory profile [
6,
8,
39]. There is an increase in macrophages present in the adipose tissue of the obese asthmatic individuals that have been demonstrated to release the major proportion of TNF-α and IL-6, in comparison to the adipocytes [
6,
8]. This is further confirmed since TNF-α was undetectable in our co-cultures with ‘isolated’ adipocytes. This warrants a need to further investigate the effect of the ‘non-fat’ cells, comprising the macrophages and tissue matrix components, in addition to the adipocytes, in modulating ASM towards a diseased phenotype. A study design with supernatants conditioned by the adipose tissue explants instead of isolated adipocytes might be more appropriate to investigate the defined objectives in the future. In addition, we acknowledge that measuring only leptin was a drawback of the current study, when an adipokine array is commercially available (adipokine microarrays should therefore be used in future experiments).
Considering the potential difference in mediators secreted at different sites [
26,
40,
41], the study for the first time addressed how intrathoracic and extrathoracic adipocytes could affect ASM biology. Intrathoracic adipose tissue was chosen as the visceral depot nearest the lung and extrathoracic samples were extracted from subcutaneous sites in the chest wall. In particular to the released adipokines, the intrathoracic samples showed a trend towards increased synthesis of eotaxin and IL-6 levels. Similar observations by Fain, et al.
, were reported where the adipokine synthesis by visceral fat was higher in comparison to subcutaneous fat, even though the former was mostly abdominal in origin [
38]. In our current study however, for all the experimental outcomes, there was no significant difference encountered in between the two depots which is in accordance with the recent observations by Fenger and co-workers, that higher risk of asthma with increasing obesity is independent of the distribution of adiposity [
42]. Again, a recent study reported similar trends for leptin and adiponectin expression by visceral and subcutaneous adipose tissue [
12]. In the light of the current discussion, it is important to indicate that the current study design did not distinguish between the BMI of the donors (out of the six donors, four had BMI > 32, one was overweight with BMI of 28.6 and another normal at 23). The authors remain aware that there are major differences in the adipocytes of lean and obese individuals with respect to morphology and adipokine synthesis. Again, sex of the donor was not considered in the study design either, even though sexual dimorphisms in the underlying mechanisms of obesity-asthma have been observed [
6,
40,
43]. The initial lay-out of the study was to assess the immediate effect of adipocytes from visceral and subcutaneous sources (from the vicinity of the airways) on ASM, without any further co-variables. Till date there are few mechanistic studies that investigate the direct influence of adipose tissue on the human ASM. Therefore, the data reported here is unique and provides direction to future studies.