Introduction

Asthma is a disease characterized by chronic inflammation of the large and small airways and estimated to affect 235 million people worldwide1. A defining feature of asthma is airway hyperresponsiveness (AHR), which underlies the exaggerated bronchoconstriction response of asthmatics. While it is clear that the airway smooth muscle (ASM) is essential in mediating airway constriction typical of AHR in asthma, there remains much debate concerning the root cause of altered ASM contraction and AHR. The mass of ASM is generally greater in the airway wall of asthmatics due to cellular hyperplasia or hypertrophy, but whether or not the ASM behaves differently in terms of contractility is still controversial. Asthmatic ASM does not appear to produce more force per cell2,3,4, but evidence from isolated human ASM cells suggests that asthmatic ASM exhibits greater shortening capacity5,6,7. Not all studies have reproduced this finding in whole ASM tissue2,4,8, suggesting that the mechanical properties of the surrounding extracellular tissue matrix may also be altered in asthma. In this regard it is notable that the ASM of asthmatics does appear to respond differently to strain induced by tidal breathing. In healthy individuals, deep inspiration causes a bronchodilatory effect that can prevent or alleviate airway narrowing, whereas this response is largely absent in asthmatics9,10,11,12,13.

Insights into the mechanisms that may underpin altered contractility of ASM are diverse and not fully conclusive. Some studies5,14,15, but not all6,16, show increased expression of myosin light chain kinase (MLCK) in ASM samples from asthmatics. Similarly, there may be increased abundance of myosin heavy chain in asthmatic ASM15, however not all studies prove this to be the case5,16. Other changes in asthmatic ASM cells may reside in the filamentous organization of the contractile apparatus as it has been proposed that the myosin thick filaments are less prone to disruption following mechanical strain4,17. Additionally, there is evidence that actin filament polymerization may underlie the altered behaviour of asthmatic ASM18,19. In this case, whereas mechanical stretch leads to shortening actin filaments and derangement of myosin filament assembly, in asthmatic ASM longer actin filaments are associated with refractoriness of thick myosin filament derangement following mechanical stretch, thus supporting greater force-generating capacity.

The WNT (wingless-integrase-1) signalling pathway consists of a family of secreted glycoproteins that are heavily modified before entering the extracellular space20,21. They regulate a plethora of functions, from embryonic development to the maintenance of adult tissue homeostasis22. WNT is broadly categorized into β-catenin-dependent (canonical) and -independent signalling (non-canonical). Non-canonical WNT signalling is actively utilized by airway smooth muscle. In ASM cell lines, transforming growth factor beta (TGF-β1) requires WNT-5A for the production of extracellular matrix (ECM) components such as fibronectin and collagen. Here, WNT-5A acts upon classical non-canonical mediators, increasing c-Jun N-terminal kinase (JNK) phosphorylation to enhance TGF-β1-mediated production of fibronectin23.

We have shown that WNT-5A protein expression is increased in ASM cells isolated from asthmatics compared to non-asthmatic individuals23 and WNT-5A expression has been associated with Th2-high asthma24. Historically, WNT-5A is known for its role in calcium homeostasis. Ectopic expression of WNT-5A increases the frequency of cytosolic calcium waves in Xenopus embryos25,26, due to activation of Ca2+/calmodulin-dependent protein kinase II (CamKII) and protein kinase C (PKC)27,28. In addition, WNT-5A directly promotes cellular adhesion and directional migration through effects on dynamics of cytoskeletal filaments and microtubules29. Here we test the hypothesis that WNT-5A modulates the contractile response of ASM and actin dynamics. We found that WNT-5A is able to increase maximum isometric contraction in isolated bovine tracheal smooth muscle strips. We provide evidence that this is mediated by rearranging actin filaments, as we found that in cultured human ASM cells, WNT-5A increases the F/G-actin actin, while no changes in expression of alpha-smooth muscle actin (α-SMA) or [Ca2+] handling were evident. Inhibition of Rho kinase (ROCK-I) completely abolished effects of WNT-5A in both human ASM as well as bovine smooth muscle strips. Finally, we found that WNT-5A knock down attenuates TGF-β1-induced α-SMA expression and that exogenous WNT-5A synergistically increased TGF-β1-induced α-SMA expression in human ASM cells.

Results

WNT-5A increases isometric contraction in bovine tracheal smooth muscle

Non-canonical WNT signalling is implicated in both cytoskeletal reorganization as well changes in calcium homeostasis, both of which may facilitate smooth muscle contraction. We hypothesized that WNT-5A increases ASM contraction by acting upon one of these systems. To test this, we pre-incubated recombinant WNT-5A for 48 hours with isolated bovine tracheal smooth muscle strips and subjected them to isometric tension measurements using histamine as the contractile agonist. We found that the maximal histamine-induced contractile force (Emax) was significantly higher for the muscle strips cultured with WNT-5A (Emax = 167.4 ± 16.7% of control; Fig. 1a). No difference in the sensitivity to histamine was found (pEC50 = 5.3 ± 0.14 and 5.44 ± 0.12, p=0.53, for the control and WNT-5A-treated group respectively). Interestingly, these changes were not associated with increases in smooth muscle myosin heavy chain (sm-MHC) or α-SMA protein abundance (Fig. 1b).

Figure 1
figure 1

WNT-5A potentiates histamine-induced maximum isometric tension.

(a) Organ-cultured bovine tracheal smooth muscle strips were pre-incubated with WNT-5A (500 ng/mL) for 48 hours and a cumulative dose-response curve to histamine for the maximum isometric tension was constructed. Data represents five independent experiments, each performed in duplicate. (b) Alpha smooth muscle actin and smooth muscle myosin heavy chain immunoblot of lysates from bovine tracheal smooth muscle strips, normalised against GAPDH. Strips were pre-incubated with WNT-5A (500 ng/mL) for 48 hours. Data represents six independent experiments. Cropped images are shown. Full-length blots are presented in Supplementary Fig. 1. α-SMA and GAPDH blots were derived from the same gel; SMMHC was run on a separate gel. Data is expressed as the mean ± SEM.

WNT-5A does not affect calcium handling in human airway smooth muscle cells

To elucidate the mechanisms contributing to the WNT-5A-enhanced contractile response we next used cultured human bronchial smooth muscle cell lines to assess the impact of WNT-5A on intracellular calcium release using fluorescence microscopy with the Fura-2 calcium indicator. We found that WNT-5A alone was insufficient to induce release of intracellular calcium. Conversely, as expected histamine exposure elicited rapid increase in cytosolic calcium (16.8 ± 0.27 fold of pre-stim; Fig. 2a). Pre-incubation of cells with WNT-5A (48 hours) had no impact on histamine-induced calcium release (Fig. 2b). Consistent with these observations WNT-5A pre-incubation had no effect on the gene expression profile for endoplasmic reticulum calcium channels and receptors: IP3R, SERCA2, nor any ryanodine receptor isoforms were differentially expressed following WNT-5A treatment (Fig. 2c). Together, the data suggests that, contrary to some non-smooth muscle cell types, WNT-5A has no (in)direct effect on calcium handling in cultured human ASM cells.

Figure 2
figure 2

Calcium handling is not affected by WNT-5A.

(a) Representative Fura-2 traces (left) and quantification (right) of intracellular calcium (Ca2+i) changes with respect to time of immortalized human airway smooth muscle cells exposed to WNT-5A (500 ng/mL) or histamine (10−4 M). 30–40 cells were simultaneously measured in the presence of extracellular Ca2+ and collectively determined the response. Data represents four independent experiments. *vs pre-stim. (b) Airway smooth muscle cells were pre-incubated with WNT-5A (500 ng/mL) for 48 hours and a dose-response curve to histamine for the maximum Ca2+i peak response was constructed. Data represents four independent experiments. (c) mRNA of airway smooth muscle cells pre-incubated with WNT-5A (500 ng/mL) for 24 hours was isolated and subjected to RT-qPCR. Data represents five independent experiments. Data is expressed as the mean ± SEM.

WNT-5A drives actin cytoskeletal reorganization

We next investigated links between WNT-5A and changes in the actin cytoskeleton. We first compared abundance of endogenous WNT-5A in contractile phenotype and synthetic/proliferative phenotype human ASM, using 7-day serum-starved ASM cells (contractile phenotype) and serum-fed cultures (synthetic/proliferative phenotype) as we have described30. As expected, serum-starvation induced accumulation of α-SMA and caveolin-1 (8.3 ± 1.5 fold of serum-fed and 6.0 ± 1.4 fold of serum-fed respectively; Fig. 3a). Interestingly, WNT-5A expression was also increased with prolonged serum starvation (1.8 ± 0.28 fold of serum-fed; Fig. 3a). We next investigated whether increasing concentrations of WNT-5A might affect α-SMA expression in human ASM cells, but we saw no evidence for a change in α-SMA abundance with increasing recombinant WNT-5A concentration (24 hours) (Fig. 3b).

Figure 3
figure 3

Involvement of WNT-5A in the regulation of alpha smooth muscle actin.

(a) Alpha smooth muscle actin, caveolin-1 and WNT-5A immunoblot of lysates from cultured human airway smooth muscle cells, normalised against GAPDH. Cell were grown to 50% confluence in serum-enriched (10% FBS) DMEM (serum-fed group) or grown to confluence and then serum-deprived in Ham’s F12 supplemented with ITS (serum-starved group) for 7 days. Cropped images are shown. Full-length blots are presented in Supplementary Fig. 1. α-SMA/GAPDH and caveolin-1/WNT-5A/GAPDH were derived from the same gel. Data represents four independent experiments. *vs serum-fed. (b) Airway smooth muscle actin immunoblot as performed in (a). Cells were treated with WNT-5A for 24 hours. Full-length blots are presented in Supplementary Fig. 1. Data represents three independent experiments. (c) Representative immunofluorescent images of a Phalloidin (F-actin, green) and DNAse I (G-actin, red) staining of airway smooth muscle cells exposed to WNT-5A (200 ng/mL) for 2 hours and the corresponding quantification. White arrowhead points to filamentous actin. Dashed line represents a single cell boundary. Horizontal line represents the mean. Data is expressed as the mean ± SEM.

We next investigated whether WNT-5A induced changes in the organizational structure of the actin cytoskeleton. We measured the effects of WNT-5A exposure in cultured human ASM cells by co-labelling F- and G-actin with fluorescently-conjugated phalloidin and DNAse I, respectively. Microscopy analysis revealed that treatment with recombinant WNT-5A increased polymerized actin, as revealed by increased phalloidin staining and reduced DNAse I labelling (Fig. 3c). Together, these data suggest WNT-5A drives actin cytoskeletal reorganization in human ASM and is associated with contractile phenotypic changes.

ROCK-I activation underlies WNT-5A-driven F-actin formation

RhoA-dependent activation of ROCK-I induces actin polymerization and stress fiber formation in many cell types31,32, among which airway smooth muscle. Thus, we treated human ASM cells with the highly selective ROCK inhibitor, Y27632 and thereafter performed a phalloidin and DNAse I staining. While Y27632 alone had little effect on baseline labelling of F-actin and G-actin, it entirely prevented accumulation of phalloidin-labelled F-actin that was otherwise induced by WNT-5A (Fig. 4a). To integrate these findings with our bovine model for smooth muscle contraction, we treated isolated bovine tracheal smooth muscle strips with WNT-5A and Y27632 for 48 hours and then subjected them to isometric tension measurements. Again, we found that while Y27632 alone had no effect on Emax or sensitivity to histamine, it completely abolished the effects of WNT-5A on histamine-induced force generation (Fig. 4b).

Figure 4
figure 4

ROCK activation underlies WNT-5A-induced actin polymerisation.

(a) Representative immunofluorescent images of a Phalloidin (F-actin, green) and DNAse I (G-actin, red) staining of airway smooth muscle cells exposed to WNT-5A (200 ng/mL) for 2 hours in the presence or absence of Y27632 (1.0 μM) and the corresponding quantification. White arrowhead points to filamentous actin. Dashed line represents a single cell boundary. Horizontal line represents the mean. (b) Organ-cultured bovine tracheal smooth muscle strips were pre-incubated with WNT-5A (500 ng/mL) and/or Y27632 (1.0 μM) for 48 hours and a cumulative dose-response curve to histamine for the maximum isometric tension was constructed. *vs Control, $ vs WNT-5A + Y27632. Data represents five independent experiments, each performed in duplicate. Data is expressed as the mean ± SEM.

WNT-5A is required for TGF-β1-induced actin polymerization

We have shown that WNT-5A is under direct control of TGF-β1 in the regulation of extracellular matrix proteins in human ASM cells23,33. Because TGF-β1 is also known to have an impact on cytoskeletal organization, we investigated whether TGF-β1 requires WNT-5A for its effects on filamentous actin dynamics. As expected, in human ASM TGF-β1 strongly induced F-actin accumulation with a concomitant reduction of cytosolic G-actin, as shown by phalloidin and DNAse I staining. This effect could be completely eliminated by addition of latrunculin A, a potent inhibitor of actin polymerization that stabilizes G-actin (Fig. 5a). To address the role of WNT-5A in this pathway, we inhibited WNT-5A expression by means of WNT-5A-specific small-interfering RNA (siRNA), which reached 67 ± 6% knockdown efficiency (Fig. 5c). Interestingly, silencing WNT-5A expression using siRNA effectively blocked F-actin formation induced by TGF-β1 (Fig. 5b), underlying the regulatory role of WNT-5A in TGF-β1-induced actin polymerization.

Figure 5
figure 5

WNT-5A mediates TGF-β1 induced actin polymerization.

Representative immunofluorescent images of a Phalloidin (F-actin, green) and DNAse I (G-actin, red) staining of airway smooth muscle cells exposed to TGF-β1 (2 ng/mL) for 48 hours in the presence or absence of (a) latrunculin A (0.1 μM), or (b) WNT-5A-specific siRNA. White arrowhead points to filamentous actin. Dashed line represents a single cell boundary. Horizontal line represents the mean. (c) mRNA of airway smooth muscle cells pre-incubated with WNT-5A siRNA or control siRNA (30 pmol) for 36 hours was isolated and subjected to RT-qPCR. *vs control siRNA. Data represents three independent experiments. Data is expressed as the mean ± SEM.

Actin polymerization induced by WNT-5A is essential for TGF-β1-mediated actin expression

Many smooth muscle-specific promoter regions are under direct control of actin-binding proteins and as such, increasing actin polymerization can enhance the promoter activity of these genes, for example α-SMA34. We investigated whether F-actin formation induced by WNT-5A is required for the transcriptional control of α-SMA (a known target gene for TGF-β1). To confirm that actin cytoskeletal reorganization is required for α-SMA expression, we treated human ASM cells with TGF-β1 and latrunculin A. Indeed, we found that latrunculin A completely blocked induction of α-SMA protein accumulation following exposure to TGF-β1 (48 hours) (0.26 fold of TGF-β1; Fig. 6a). To extend on these findings we treated our cell cultures with WNT-5A siRNA and found that this was associated with marked attenuation of α-SMA protein accumulation induced by TGF-β1 (0.44 fold of TGF-β1; Fig. 6b). In line with this, addition of recombinant WNT-5A with TGF-β1 resulted in a seemingly synergistic effect, where α-SMA abundance reached higher levels than the sum of the treatments alone (2.12 fold of TGF-β1; Fig. 6c). These data suggest that WNT-5A induced polymerization is critical for TGF-β1-mediated induction of α-SMA.

Figure 6
figure 6

TGF-β1-induced actin expression utilises WNT-5A.

(a) Alpha smooth muscle actin immunoblot of lysates from cultured human airway smooth muscle cells, normalised against GAPDH. Cells were treated with TGF-β1 (2 ng/mL) for 48 hours in the presence or absence of latrunculin A (0.1 μM). Cropped images are shown. Full-length blots are presented in Supplementary Fig. 1. α-SMA and GAPDH were derived from the same gel. Data represents four independent experiments. *vs control, $ vs TGF-β1. (b) Alpha smooth muscle actin immunoblot performed as in (a). Cells were transfected with a WNT-5A-specific siRNA construct or scrambled negative control siRNA and treated with TGF-β1 (2 ng/mL) for 48 hours. Full-length blots are presented in Supplementary Fig. 1. Data represents six independent experiments. *vs control siRNA, $ vs control siRNA + TGF-β1. (c) Alpha smooth muscle actin immunoblot performed as in (a). Cells were treated with TGF-β1 (2 ng/mL) for 48 hours in the presence or absence of WNT-5A (200 ng/mL). Full-length blots are presented in Supplementary Fig. 1. Data represents three independent experiments. *vs control, $ vs TGF-β1. Data is expressed as the mean ± SEM.

Discussion

In this study we explored the role of non-canonical WNT signalling, focusing on the well-studied family member WNT-5A, in the regulation of cytoskeletal reorganization, mobilization of intracellular calcium and airway smooth muscle contraction. We found that in bovine tracheal smooth muscle strips, pre-treatment with WNT-5A increases maximum isometric tension induced by histamine, while there was no change in the abundance of α-smooth muscle actin or smooth muscle myosin heavy chain. It appears that modulation of actin dynamics may underlie these results, as WNT-5A was sufficient to increase the presence of filamentous actin via activation of ROCK-I, but was without effect on calcium release or endoplasmic reticulum proteins that regulate calcium handling, in cultured human airway smooth muscle cell lines. In addition, blocking ROCK-I with Y27632 also diminished WNT-5A effects on histamine-induced bovine smooth muscle contraction. We further observed that WNT-5A is preferentially expressed in human ASM cells of a contractile phenotype, suggesting an association with contractility. To our knowledge, this is the first study that has implicated WNT signalling in airway smooth muscle contraction. There are no reports prior to ours that reveal a role for WNT-5A in airway smooth muscle actin cytoskeletal reorganization, however, a number of publications describing use of other model systems corroborate our findings. In a study on the development and elongation of the small intestine of mice, WNT-5A−/− mice displayed reduced smooth muscle thickness compared to wild type littermates. Also the number of subepithelial α-SMA-positive fibroblasts was lowered in WNT-5A mutant embryos35. In another study on the female reproductive tract of mouse pups, though smooth muscle cell layers developed normally in WNT-5A−/− mutants they were thinner than in wildtype mice36. In cardiac development on the other hand, WNT-5A−/− and WNT-11−/− double knock-out mice showed no differences in the mRNA levels for α-SMA or the actin-associated smooth muscle marker SM-2237, suggesting that WNT-5A effects on cytoskeletal protein expression may be tissue-specific.

In our study, neither direct exposure to WNT-5A nor pre-incubation invoked any change in calcium handling. These findings are interesting, as historically the Frizzled-2 receptor has been ascribed a role in regulating calcium mobilization38. At the same time, the Frizzled-2 receptor is one of the most highly expressed Frizzled isoforms in both human airway smooth muscle23 as well as in MRC-5 human lung fibroblasts39. We have also shown that WNT-5A can activate NFAT downstream signalling in human ASM, implying a role for calcium40. The nature of the actual downstream event that regulates calcium signalling may be dependent on the presence of additional receptor complexes, such as the receptor tyrosine kinase-like orphan receptor 2 (ROR2) that is critically involved in non-canonical WNT signalling. ROR2 is present in very low numbers under basal conditions in airway smooth muscle cells23.

We show that Rho kinase activation is required for WNT-5A-induced actin cytoskeletal reorganization and effects on bovine smooth muscle contraction. In this study we did not fully explore the potential underlying mechanisms for this effect, however, there is an extensive body of work on the regulation of smooth muscle differentiation, characterized by the increased expression of smooth muscle specific marker genes, including α-SMA. Many smooth muscle genes contain CArG cis-elements (CC(A/T)6GG) that are under direct control of the transcription, factor serum response factor (SRF)41,42,43. SRF activation is dependent on actin dynamics and depletion of the G-actin pool is permissive for its activation44, in part via Rho kinase-dependent effects34. SRF-dependent transcription is also controlled by its interaction with other transcription factors and co-activators, including myocardin-related transcription factors (MRTFs) that interact with G-actin. Indeed Rho signalling promotes actin polymerization, thus reducing G-actin pools and permitting nuclear localization of MRTF by limiting G-actin association to the amino-terminal RPEL domain of MRTF45. Of relevance to our work, TGF-β1 can signal through the Rho-actin-MRTF axis46,47 and we show that pharmacologic inhibition of Rho kinase prevented WNT-5A-induced F-actin formation and bovine tracheal smooth muscle contraction. Thus, our findings suggest that WNT-5A signaling may engage the MRTF-SRF relay to regulate expression of α-SMA.

In this study we report that TGF-β1-induced expression of α-SMA in human ASM cells is dependent on the activation of WNT-5A signaling, relying on mechanisms that modulate the actin cytoskeleton. However, WNT-5A alone is not sufficient to increase abundance of α-SMA. These findings are consistent with the notion that TGF-β1 recruits additional factors beyond WNT-5A to regulate α-SMA expression. Apart from TGF-β1-responsive CArG elements in the α-SMA promoter, there is also a TGF-β1 control element (TCE) that confers TGF-β1 responsiveness in both smooth muscle cells and fibroblasts41,48. Additionally, a Smad-binding element (SBE) is present in the α-SMA promoter and in fibroblasts, α-SMA expression is elevated following transfection with a Smad-3-expressing plasmid49. In epithelial cells Smad signaling is associated with epithelial-to-mesenchymal transition (EMT) that includes expression of α-SMA. Inhibition of Smad-3 by a virally induced Smad-3 double negative blocks TGF-β1-induced EMT, demonstrating an essential role for this pathway in TGF-β1-induced α-SMA expression50,51. Lack of activation of these promoter sites following exposure to WNT-5A alone may underlie its inability to induce α-SMA expression in human ASM.

It has been postulated that increased expression of α-SMA may contribute to the lack of effects caused by deep inspiration in individuals with asthma. However, to date unequivocal evidence for differences in total expression of αSMA in asthmatics and non-asthmatics is lacking15,16. A lot of effort has been directed towards finding candidate markers of the contractile machinery that are possibly changed in asthma, but perhaps an alternative attempt would be to direct our attention towards proteins that are not thought to be directly involved in contractile function. WNT-5A expression is increased in ASM cells isolated from mild to moderate asthmatics23 and this is associated with Th2-high asthma24. Even in the absence of changes directly related to contractile function, based on our findings changes in the expression of WNT-5A may affect ASM contractility and contribute to airway hyperresponsiveness.

In conclusion, we show that non-canonical WNT signalling via WNT-5A is a potent driver of actin cytoskeletal reorganization, shifting the F/G actin ratio in favour of filamentous actin. These findings result in increased maximum force generation following WNT-5A incubation in bovine tracheal smooth muscle strips. In addition, WNT-5A is actively utilised by TGF-β1, regulating TGF-β1-induced expression of α-SMA via ROCK-mediated actin polymerization. These findings may be of relevance for AHR in asthma.

Materials and Methods

Cell culture

Three human bronchial smooth muscle cell lines, immortalized by stable expression of human telomerase reverse transcriptase (hTERT), were used for all experiments. The primary cultured human bronchial smooth muscle cells used to generate each cell line were prepared as our laboratory has previously described from macroscopically healthy segments of second- to fourth-generation main bronchus obtained after lung resection surgery from patients with a diagnosis of adenocarcinoma52. Patients gave informed consent for secondary use of resected material for research purposes. All procedures and consent forms were approved by the Human Research Ethics Board (University of Manitoba) and in accordance with local and national guidelines. Up to 30th passage cells were used for all experiments. Cells were grown in uncoated 100/20 mm tissue culture dishes (GBO, #664160) in Dulbecco’s Modified Eagle’s Medium (DMEM) (GIBCO, #42430-082) supplemented with 200 units/mL Penicillin-Streptomycin (GIBCO, #15070-063), 2.5 μg/mL antimycotic (GIBCO, #15290-026) and 10% vol/vol Fetal Bovine Serum (FBS) (Thermo Scientific, #SV30180.03).

Antibodies and chemicals

The following antibodies were used: GAPDH (western blot 1:3000, Santa Cruz, #sc-47724), α-smooth muscle actin (western blot 1:1000, immunohistochemistry 1:100, Abcam, #ab5694), smooth muscle myosin heavy chain (western blot 1:400, Thermo Scientific, #MS1438), Caveolin-1 (western blot 1:1000, Santa Cruz, #sc-894), WNT-5A (western blot 1:500, Abcam, #ab72583), peroxidase-conjugated anti-mouse IgG (western blot 1:3000, Sigma-Aldrich, #A9044), peroxidase-conjugated anti-rabbit IgG (western blot 1:3000, Sigma-Aldrich, #A0545).

Other reagents used include the following: recombinant TGF-β1 (R&D Systems, #240-B), recombinant WNT-5A (R&D Systems, #645-WN), WNT-5A siRNA (Qiagen, #SI00051779), Negative control siRNA (Qiagen, #SI03650318), X-tremeGENE siRNA transfection reagent (Roche, #04476093001), Alexa Fluor® 488-conjugated Phalloidin (Molecular Probes, #A12379), Alexa Fluor® 594-conjugated Deoxyribonuclease I (Molecular Probes, #D12372), ProLong® Gold Antifade Mountant (Molecular Probes, #P36930), Fura-2 AM (Molecular Probes, #F-14185), Histamine (Sigma Aldrich, #H7250), Bovine Serum Albumin (Sigma Aldrich, #A7030), Fetal Bovine Serum (FBS) (Thermo Scientific, #SV30180.03), Y-27632 (Tocris, #1254) and latrunculin A (Tocris, #3973). All other chemicals were of analytical grade.

Western blot analysis

Cells were washed with PBS and incubated with RIPA lysis buffer (65 mM Tris, 155 mM NaCl, 1% Igepal CA-630, 0.25% sodium deoxycholate, 1 mM EDTA, pH 7.4 and a mixture of protease inhibitors: 1 mM Na3VO4, 1 mM NaF, 10 μg/ml leupetin, 10 μg/ml Pepstatin A, 10 μg/ml Aprotinin). Cells were then scraped from the plate and kept on ice for 15 min. Lysates were vortexed vigorously and finally centrifuged for 10 min at 10.000 g. Protein content of the supernatant fractions was determined with a BCA protein assay kit (Thermo Scientific, #23225) and subsequently subjected to SDS-PAGE, using 10% running gels. Separated proteins were transferred to PVDF membranes (Carl Roth, 0.45 μm, #T830.1), which were then blocked with ROTI®-Block blocking solution (Carl Roth, #A151.2) for 2 hours at room temperature. Membranes were incubated with primary antibodies overnight at 4 °C in TBST (50 mM Tris-HCl, 150 mM NaCl, 0.05% (w/v) Tween-20, pH 7.4). The next day, after washing in TBST, membranes were incubated with HRP-conjugated secondary antibody for 2 hours at room temperature. Finally, blots were developed using enhanced chemiluminescence substrate (Perkin Elmer, #NEL105001EA). Digital images were quantified by densitometry using LI-COR Image Studio Lite software.

RT-qPCR

Cells were washed with PBS and incubated with lysis buffer before being scraped from the plate. Isolation of mRNA was performed with a NucleoSpin® RNA isolation kit (Macherey-Nagel, # 740955.250) according to the manufacturer’s instructions. Equal amounts of cDNA were synthesized using AMV reverse transcriptase (Promega, #A3500) and diluted 15 times with RNAse-free ddH2O. Quantitative real-time PCR was performed on an Illumina Eco Real-Time PCR system using SYBR green as the DNA binding dye (Roche, #04913914001). PCR cycling was performed with denaturation at 94 °C for 30 sec, annealing at 60 °C for 30 sec and extension at 72 °C for 30 sec for 45 cycles. Analysis of RT-qPCR data was done using LinRegPCR analysis software53,54. 18S ribosomal RNA, B2M and RPL13A were used as reference loci for accurate normalization of the RT-qPCR data. Primer sequences are listed in Table 1. Total RNA yield was determined with a NanoDrop ND-1000 spectrophotometer and samples were normalized accordingly.

Table 1 Primer sequences used.

Immunofluorescence

Cells were cultured in Lab-Tek 8-chambered coverglass slides (Thermo Scientific, #155409). After treatment, cells were washed in warm PBS and fixed in 4% paraformaldehyde (PFA) plus 4% sucrose in PBS for 15 min. Cells were then incubated with PBS containing 0.3% Triton X-100 for 2 min and then blocked in 5% BSA in PBS for 1 hour at RT. After blocking, cells were incubated with Alexa Fluor 488-conjugated Phalloidin (1:500) and Alexa Fluor® 594-conjugated Deoxyribonuclease I (1:500) diluted in 1% BSA in PBS for 1 hour at RT. Finally, cells were washed in ddH2O and mounted with ProLong® Gold antifade. Sections were imaged using the TissueFAXS imaging system (TissueGnostics).

Mean fluorescence intensity of phalloidin and DNAse I stainings were digitally analysed with ImageJ. Following a 300 px background subtraction, images were thresholded and the integrated density per area from the appropriate channel was calculated, using the perimeter of the cell boundary. For each data set, each replicate represents the mean of eight analysed cells. Values are expressed as arbitrary units (a.u.).

[Ca2+]i measurements

Cells were loaded with Fura-2 in the presence of Pluronic acid (GIBCO, #24040-032) by incubation at 37 °C for 1 h in 5 μM Fura-2 AM in Ca2+ (1.3 mM)-containing Hanks’ buffered salt solution without phenol red (Molecular Probes, #14065) and additionally buffered with 20 mM HEPES (Sigma Aldrich, #H3375) (HHBSS, pH 7.4). The cells were then washed and allowed to incubate at room temperature for 30 min to allowed for complete de-esterification of the Fura-2 AM. Cells were visualized with an inverted microscope equipped with fluorescence optics and a 40x objective lens. Fluorescence was detected with a computer controlled monochromatic excitation light source (PILL Polychrome V, TILL Photonics) and an Andor iXon DV885 EM CCD camera (TILL Photonics). A 340/380 nm ratio image was generated following background subtraction. Fluorescence emission was quantified using Andor iQ Live cell imaging software (Andor Technology). This experiment has been performed at the UMCG Microscopy and Imaging Center (UMIC), which is sponsored by NWO-grants 40-00506-98-9021 (TissueFAXS) and 175-010-2009-023 (Zeiss 2p), University of Groningen.

Isometric tension measurements

Bovine tracheae were obtained from a local slaughterhouse and transported to the laboratory in Krebs-Henseleit (KH) buffer (118 mM NaCl, 5.6 mM KCl, 1.18 mM MgSO4, 2.5 mM CaCl2, 1.28 mM NaH2PO4, 25 mM NaHCO3, 5.5 mM Glucose, pregassed with 5% CO2 and 95% O2, pH 7.4). After dissection of the smooth muscle layer and removal of the mucosa and connective tissue, tracheal smooth muscle strips were prepared while incubated in gassed KH-buffer at room temperature. Strips were cut with a length of 1 cm and width of 2 mm. Tissue strips were washed once in sterile DMEM supplemented NaHCO3 (7 mM), HEPES (10 mM), sodium pyruvate (1 mM), non-essential amino acids (GIBCO, #11140-050, 1:100), gentamycin (45 mg/mL), Penicillin-Streptomycin (200 units/mL), antimycotic (2.5 μg/mL) and transferred into suspension culture flasks. Strips were maintained in culture in an incubator shaker (37 °C, 55 RPM) for 3 days.

After washing with KH-buffer, strips were mounted for isometric recording (Grass force-displacement transducer FT03) in 20 mL water-jacketed organ baths, containing KH-buffer at 37 °C, continuously gassed with 5% CO2 and 95% O2, pH 7.4. During a 90 min equilibration period with washouts every 30 min, resting tension was gradually adjusted to 3 g. Muscle strips were then pre-contracted with 20 and 40 mM isotonic KCl. After washing, tension was re-adjusted to 3 g and cumulative dose response curves were constructed by stepwise increasing the concentration of isotonic histamine.

Statistical analysis

All data represent the mean ± SEM, of at least three independent experiments. Comparisons between two groups were made using an unpaired Student’s t-test. Comparisons between three or more groups with one independent variable were performed using a one-way ANOVA followed by Dunnett’s or Tukey’s post hoc test. Groups with two independent variables were compared with a two-way ANOVA. A value of p < 0.05 was considered significant, where *represents p < 0.05, **p < 0.01 and ***p < 0.001. Analyses were performed with GraphPad Prism (GraphPad Software, Inc.).

Additional Information

How to cite this article: Koopmans, T. et al. Regulation of actin dynamics by WNT-5A: implications for human airway smooth muscle contraction. Sci. Rep. 6, 30676; doi: 10.1038/srep30676 (2016).