Background

Idiopathic pulmonary fibrosis (IPF) has characteristics of fibroblast proliferation and collagen-based extracellular matrix reconstruction [1, 2]. The clinical manifestation of IPF includes progressive and irreversible loss of pulmonary function, ultimately causing respiratory failure [3]. Bleomycin (BLM), an antineoplastic agent, has been found to cause pulmonary interstitial fibrosis [4]. BLM-induced pulmonary fibrosis is characterized by extracellular matrix deposition, alveolar injury and inflammatory cell infiltration [5, 6]. Thus, BLM-induced pulmonary fibrosis has been used to mimics the process of IPF [7, 8]. Several studies have demonstrated that TGF-β-mediated epithelial-mesenchymal transition (EMT) plays an important role in the pathogenesis of BLM-induced pulmonary fibrosis [5, 9, 10].

Vitamin D is essential for uptake of calcium and metabolism of bone. The children with vitamin D deficiency have greater risks of rickets [11]. In the recent years, vitamin D is famous for its non-classical actions, such as its antioxidative and anti-inflammatory effects and its regulation of cell proliferation [12,13,14,15]. After hydroxylated by cytochrome P450 (CYP)2R1 to form 25(OH)D3, vitamin D3 is then transformed by CYP27B1 to form 1,25 (OH)2D3, the active form of vitamin D3. 1,25 (OH)2D3, exerts its biological function by activating vitamin D receptor (VDR) [16, 17]. Several animal experiments found that supplementation with active vitamin D3 alleviated BLM-induced pulmonary interstitial fibrosis [18, 19]. On the other hand, vitamin D deficiency or insufficiency is quite common especially in children and old people [20, 21]. Several epidemiological reports demonstrated that vitamin D deficiency was associated with increased risks of infections in lungs [22, 23]. According to a recent study, vitamin D deficiency was positively associated with the mortality of patients with IPF [24]. Moreover, this report found that supplementation with cholecalciferol protected mice from BLM-induced lung fibrosis [24]. Nevertheless, whether vitamin D deficiency exacerbates BLM-induced pulmonary fibrosis needs to be further determined.

In the present study, we established two mouse models of vitamin D deficiency through either feeding vitamin D deficient (VDD) diet or Cyp27b1 gene knockout. The objective of this study was to investigate whether vitamin D deficiency aggravates BLM-induced pulmonary fibrosis using two different animal models. Our results indicated that both feeding VDD diet and Cyp27b1 gene knockout exacerbated BLM-induced pulmonary fibrosis. Mechanistically, vitamin D deficiency exacerbated pulmonary fibrosis partially through aggravating BLM-induced TGF-β/Smad2/3-mediated EMT in the lungs.

Material and methods

Chemicals and reagents

Bleomycin (BLM) was from Hisun Pfizer Pharmaceuticals Co. Ltd. (Shanghai, China). 25(OH) D detection kit was from DIAsource (Louvain-la-Neuve, Belgium). TRIzol reagent was from Molecular Research Center, Inc. (Cincinnati, OH, USA). RNase-free DNase was purchased from Promega Corporation (Madison, WI, USA). ECL detection kit and Bicinchoninic acid (BCA) protein assay reagents were from Thermo Scientific (Massachusetts, MA, USA). Antibodies against Lamin A/C, β-actin, E-cadherin and vimentin were from Cell Signaling Technology (Danvers, MA, USA). Antibodies against α-SMA and Phospho-Smad3 were from Abcam (Cambridge, UK).

Animals and treatments

The present study consists of two independent experiments. Experiment 1, male C57BL/6 J mice (4-week old) were from Beijing Vital River. All animals were kept with temperatures of 20–25 °C and humidity of 50%. All animals were fed standard diet and water freely. The circadian rhythm of 12 h light and 12 h darkness was maintained. After one week of adaptation, 40 mice were randomly divided into two groups: vitamin D deficient (VDD) and control (Ctrl). Mice of the VDD group were fed with vitamin D deficient fodder. Mice of the Ctrl group were fed with standard fodder. Five weeks later, mice of the Ctrl group and the VDD group were randomly divided into two subgroups, respectively (10 mice each subgroup): Ctrl, bleomycin (BLM), VDD, VDD + BLM. In the BLM and VDD + BLM groups, animals were intratracheally instilled with BLM (1.5 mg/kg). In the Ctrl and VDD groups, animals were treated with equal volume of saline in the same way. Experiment 2, wild-type (Cyp27b1+/+) and Cyp27b1 knockout (Cyp27b1−/−) mice were from Beijing Vital River. Mating wild-type mice with Cyp27b1 knockout mice produced Cyp27b1+/+, Cyp27b1+/− and Cyp27b1−/− mice. The genotype was confirmed by PCR analysis. All animals were fed with standard diet and water freely. The circadian rhythm of 12 h light and 12 h darkness was maintained. Six weeks after birth, mice each strain were randomly divided into 2 subgroups: Ctrl and BLM. In the BLM subgroup, mice were intratracheally instilled with BLM (1.5 mg/kg). In the Ctrl subgroup, mice were intratracheally instilled with equal volume of saline. All animals were sacrificed 2 weeks after BLM instillation. Serum 25(OH) D level was measured. The middle and lower lobes of right lung were sheared for histopathology and immunohistochemistry. The remainder tissues were collected for Western blots and real-time RT-PCR. The protocols of all animal experiments complied with the guidelines for humanitarian therapy by the Association of Laboratory Animal Sciences of Anhui Medical University and the Center for Laboratory Animal Sciences.

Histology and determination of fibrosis

Lung tissue was fixed with 4% paraformaldehyde, embedded in paraffin. Each wax block was sliced continuously and stained with hematoxylin and eosin (H&E) to evaluate the histological manifestations. The inflammation was evaluated using the score of 0–5 according to previous study [19]. The numbers of inflammatory cells in every field (× 200) were counted. Lung fibrosis was determined by Sirius red staining according to our previous study with minor modification [5]. Briefly, after been rehydrated, the slices were stained with Sirius red for 1.5 h. Then rinsed the dye gently for about 3–5 s. The slices were washed with distilled water, gradient ethanol and xylene (× 2) each for 1 min. The percentage of collagen deposition was quantified using Image-Pro® Plus software. The data were shown as Mean ± SEM (N = 6).

Immunohistochemistry

Lung was cut into sections (5 μm thick) according to the standard protocol [19, 25]. The slices were incubated with monoclonal antibodies against α-SMA (1000:1), ZEB1(200:1) and VDR (200:1) at 20–25 °C for 1 h and then 3–5 °C for 12 h (for α-SMA) or 18 h (for ZEB1 or VDR). After the color reaction, the slices were counterstained with hematoxylin. ZEB1- and VDR- positive nuclei and α-SMA-positive cells were counted at a magnification of × 400 (Leica, German). Fifteen visual fields were randomly selected for each slice.

Western blotting

To extract total protein from lung tissue, 450 μl buffer with PMSF and 50 mg lung tissue were used. The supernate was collected after 35 min grinding on ice and centrifugated for 15 min. The protein concentration of total pulmonary lysate was measured with the BCA protein assay reagents. In order to extract nuclear protein from lung tissue, 300 mg lung tissue was homogenized with 4 ml buffer A [25]. Supernate was gleaned after centrifugation for 40 s at 700 rpm. The mixed precipitate was gleaned after supernate was centrifuged for 25 min at 6500 rpm. Mixed precipitate was suspended in 105 μl lysis buffer B [25]. After maintaining a static position at 4 °C for 60 min, solution was stirred with electric stirring rod for 4 min. Supernate was gleaned after centrifugation for 10 min at 12000 rpm. The protein concentration of nuclear lysate was measured with the BCA protein assay reagents. For Western blotting, equivalent protein (8~22 μg) was separated by 10% SDS-PAGE and transferred to a polyvinylidene fluoride membrane. For total protein, membranes were incubated for 1~2 h using following antibodies: E- cadherin, vimentin, α-SMA, p-Smad3, or β-actin. For nucleoprotein, membranes were incubated with either VDR antibody for 18 h or Lamin A/C antibody for 12 h at 3–5 °C. After the membranes were washed for four times, second antibody was used to incubate for 1~2 h. Finally, signal was measured by ECL kit.

Isolation of Total RNA and real-time PCR

TRIzol reagent was used to collect total RNA from mouse lungs. After precipitating and washing, total RNA was determined by OD value to quantity as 0.5 μg/μl. RNA was then reverse-transcribed with AMV after digestion with RNA-free DNase. Specific primers (Table 1) and GoTaq1 qPCR master mix were used to carry out real-time PCR. The amplified reaction program was performed with the Light Cycler 480 Instrument. The specific process was referred to our previous experiments [19].

Table 1 Primers for RT-PCR

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Statistics

The raw data were presented as means ± S.E.M. ANOVA was used to calculate differences between different groups. All data were evaluated for significance using non-parametric tests techniques when those were not normally distributed. P < 0.05 and P < 0.01 were determined to demonstrate statistically significant. All statistical analyses were carried out with SPSS 19.0 software.

Results

Vitamin D deficiency aggravates BLM-induced pulmonary inflammation and interstitial fibrosis

Serum 25(OH) D concentrations were evaluated. It showed that serum 25 (OH) D concentration was significantly lower in VDD group than that of control group (Fig. 1a). Nuclear VDR level of lungs was accordingly reduced among VDD-fed mice (Fig. 1b and c). As shown in Fig. 2a, the relative weight of lungs was slightly increased in BLM-treated group. Numerous inflammatory cells were infiltrated in lungs of mice injected with BLM, accompanied by collapse of lung tissue and thickening of alveolar septum (Fig. 2b). Of interest, the relative weight of lungs was higher in VDD + BLM group than that of BLM group (Fig. 2a). Moreover, BLM-induced infiltration of inflammatory cells and pathological damage were aggravated in VDD diet fed mice (Fig. 2b-d). To further evaluate BLM-induced pulmonary fibrosis, pulmonary collagen (Col1α1 and Col1α2) mRNAs were measured by real-time RT-PCR. As expected, pulmonary Col1α1 and Col1α2 mRNAs were obviously upregulated in BLM-treated mice (Fig. 2e-f). Sirius red staining was performed for lung fibrosis. As shown in Fig. 2g and h, collagen deposition was discovered in the lungs in BLM-treated mice. Interestingly, BLM-induced upregulation of Col1α1 and Col1α2 mRNAs was aggravated in the lungs of VDD diet-fed mice (Fig. 2e and f). Correspondingly, BLM-induced collagen deposition, as determined by Sirius red staining, was aggravated in the lungs of VDD diet-fed mice (Fig. 2g and h, 2.27 ± 0.32 VS 7.34 ± 0.49, P < 0.01).

Fig. 1

figure1

Serum 25 (OH) D and nuclear VDR level. During the VDD group, animals were fed with vitamin D deficient fodder. During the Ctrl group, animals were fed with standard fodder. All animals except controls were injected with BLM (1.5 mg/kg) through the trachea. All animals were sacrificed 2 weeks after BLM. a Serum 25(OH) D concentrations were estimated using RIA. b and c Nuclear VDR was estimated using Western blot. All experiments were repeated for 3 times. Data were expressed as means ± SEM (N = 6). ** P < 0.01

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Fig. 2

figure2

Vitamin D deficiency aggravates BLM-induced pulmonary inflammation and interstitial fibrosis. In the VDD group, animals were fed with vitamin D deficient fodder. In the Ctrl group, animals were fed with standard fodder. All animals except controls were injected with BLM (1.5 mg/kg) through the trachea. All animals were sacrificed 2 weeks after BLM. a Relative lung weight was measured. b-d Pulmonary histopathological injury and inflammation were evaluated by H&E. b A representative picture. Original magnification: 200×. c Pulmonary pathological scores. d Inflammatory cells in the lungs. e-f Col1α1 and Col1α2 were estimated with real-time PCR. (G-H) Collagen deposition was evaluated using Sirius red staining. g A representative picture. Original magnification: 200×. h The area of collagen deposition was calculated. All data were expressed as means ± SEM (N = 6). **P < 0.01, *P < 0.05

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Vitamin D deficiency aggravated BLM-induced EMT in the lungs

The influences of vitamin D deficiency on BLM-induced EMT were evaluated. It showed that, pulmonary E-cadherin, an epithelial marker, was obviously downregulated in BLM-treated group (Fig. 3a and b). By contrast, pulmonary vimentin, a mesothelial marker, was slightly upregulated in BLM-treated mice (Fig. 3a and c). Although it had little effect on the expression of E-cadherin, vitamin D deficiency aggravated BLM-induced downregulation of E-cadherin in the lungs (Fig. 3a and b). Unexpectedly, vitamin D deficiency slightly upregulated the expression of pulmonary vimentin. Moreover, vitamin D deficiency aggravated BLM-induced upregulation of vimentin in the lungs (Fig. 3a and c). The effects of vitamin D deficiency on α-SMA, another EMT marker, were detected. As shown in Fig. 3a and d, pulmonary α-SMA was significantly upregulated in BLM-treated mice. IHC exhibited that α-SMA-positive cells were significantly increased in the lungs of mice treated with BLM (Fig. 3e-f). Unexpectedly, vitamin D deficiency upregulated the expression of pulmonary α-SMA (Fig. 3a, d-f). Moreover, vitamin D deficiency aggravated BLM-induced upregulation of α-SMA in the lung (Fig. 3a, d-f).

Fig. 3

figure3

Vitamin D deficiency aggravates BLM-induced EMT in the lungs. During the VDD group, animals were fed with vitamin D deficient fodder. During the Ctrl group, animals were fed with standard fodder. All animals except controls were injected with BLM (1.5 mg/kg) through the trachea. All animals were sacrificed 2 weeks after BLM. a-d Pulmonary E-cadherin, vimentin and α-SMA were detected using Western blot. a Representative gels for E-cadherin, vimentin and α-SMA and β-actin. Quantitative analyses of scanning densitometry for b E-cadherin, c vimentin and d α-SMA were performed. e Pulmonary α-SMA was measured using IHC. Original magnification: 200×. f α-SMA-positive cells were calculated. All data were expressed as means ± S.E.M. (N = 6). **P < 0.01, *P < 0.05

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Vitamin D deficiency aggravates BLM-induced TGF-β/Smad3 activation in the lungs

As expected, the expression of pulmonary Tgf-β1 mRNA was significantly upregulated in BLM-treated mice (Fig. 4a). The level of pulmonary p-Smad3 was accordingly elevated in BLM-treated mice (Fig. 4b and c). ZEB1, a downstream molecule of TGF-β/Smad3 signaling, was determined using IHC. As shown in Fig. 4d and e, ZEB1-positive cells were obviously elevated in BLM-treated mice. The effects of vitamin D deficiency on BLM-induced activation of TGF-β/Smad3 signaling were then analyzed. Of interest, vitamin D deficiency aggravated BLM-induced upregulation of Tgf-β1 mRNA in the lung (Fig. 4a). Moreover, vitamin D deficiency aggravated BLM-induced pulmonary Smad3 phosphorylation (Fig. 4b and c). In addition, vitamin D deficiency aggravated BLM-induced elevation of ZEB1-positive cells in the lungs (Fig. 4d and e).

Fig. 4

figure4

Vitamin D deficiency aggravates BLM-induced activation of TGF-β/Smad3 in the lungs. During the VDD group, animals were fed with vitamin D deficient fodder. During the Ctrl group, animals were fed with standard fodder. All animals except controls were injected with BLM (1.5 mg/kg) through the trachea. All animals were sacrificed 2 weeks after BLM. a Pulmonary Tgf-β1 mRNA was measured by real-time RT-PCR. b and c Phosphorylated Smad3 was detected using Western blot. Quantitative analysis of scanning densitometry for p-Smad3 was performed. d and e Pulmonary ZEB1 was measured using IHC. d A representative picture. Original magnification: 200×. e ZEB1-positive cells were calculated. All data were expressed as means ± SEM (N = 6). **P < 0.01, *P < 0.05

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Cyp27b1 gene knockout aggravates BLM-induced pulmonary inflammation and interstitial fibrosis

As shown in Fig. 5a, numerous inflammatory cells were infiltrated in lungs of Cyp27b1 wild-type mice injected with BLM, accompanied by collapse of lung tissue and thickening of alveolar septum. Of interest, pathological scores were higher in BLM-treated Cyp27b1+/− mice than in BLM-treated Cyp27b1 wild-type mice, with the highest pathological scores in BLM-treated Cyp27b1−/− mice (Fig. 5b). Moreover, BLM-induced the infiltration of inflammatory cells was aggravated in Cyp27b1 gene knockout mice (Fig. 5c). Pulmonary collagen deposition was determined using Sirius red staining. As shown in Fig. 5d, collagen deposition was discovered in the lungs of BLM-treated Cyp27b1 wild-type mice. Interestingly, the area of collagen deposition was larger in BLM-treated Cyp27b1+/− mice (4.38 ± 0.35) than that of BLM-treated Cyp27b1 wild-type mice (2.36 ± 0.27), with the most collagen deposition in BLM-treated Cyp27b1−/− mice (7.83 ± 0.45) (Fig. 5d-e, F = 58.868, P < 0.01).

Fig. 5

figure5

Cyp27b1 gene knockout aggravates BLM-induced pulmonary interstitial fibrosis. All animals were fed with standard fodder. All animals except controls were injected with BLM (1.5 mg/kg) through the trachea. All animals were sacrificed 2 weeks after BLM. a and b Pulmonary histopathological injury and inflammation were evaluated by H&E. a A representative picture. Original magnification: 200×. b Pulmonary pathological scores were evaluated. c Inflammatory cells in the lungs. d and e Collagen deposition was evaluated using Sirius red staining. d A representative picture. Original magnification: 200×. e The area of collagen deposition was calculated. All data were expressed as means ± SEM (N = 6). **P < 0.01, *P < 0.05

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Cyp27b1 gene knockout aggravates BLM-induced EMT in the lungs

The effects of Cyp27b1 gene knockout on BLM-induced EMT were evaluated. As expected, pulmonary E-cadherin, an epithelial marker, was obviously downregulated in BLM-treated Cyp27b1 wild-type mice (Fig. 6a and b). By contrast, pulmonary α-SMA, a mesothelial marker, was upregulated in BLM-treated Cyp27b1 wild-type mice (Fig. 6a and c). Interestingly, pulmonary E-cadherin was downregulated in Cyp27b1−/− mice. Moreover, Cyp27b1 knockout aggravated BLM-induced downregulation of E-cadherin in the lungs (Fig. 6a and b). Although it had little effect on pulmonary α-SMA, Cyp27b1 knockout aggravated BLM-induced downregulation of α-SMA in the lungs (Fig. 6a and c). IHC showed that α-SMA-positive cells were elevated in the lungs of Cyp27b1 wild-type mice treated with BLM (Fig. 6d and e). Unexpectedly, Cyp27b1 knockout upregulated pulmonary α-SMA. Moreover, Cyp27b1 knockout aggravated BLM-induced upregulation of α-SMA in the lung (Fig. 6d-e).

Fig. 6

figure6

Cyp27b1 gene knockout aggravates BLM-induced EMT. All animals were fed with standard fodder. All animals except controls were injected with BLM (1.5 mg/kg) through the trachea. All animals were sacrificed 2 weeks after BLM. a-c Pulmonary E-cadherin and α-SMA were detected using Western blot. a Representative gels for E-cadherin, α-SMA and β-actin. Quantitative analyses of scanning densitometry for b E-cadherin and c α-SMA were performed. d Pulmonary α-SMA was measured using IHC. Original magnification: 200×. e α-SMA-positive cells were calculated. All data were expressed as means ± S.E.M. (N = 6). **P < 0.01, *P < 0.05

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Cyp27b1 gene knockout aggravates BLM-induced TGF-β/Smad3 activation in the lungs

As expected, pulmonary p-Smad2 and p-Smad3 were elevated in BLM-treated Cyp27b1 wild-type mice (Fig. 7a-c). The effects of Cyp27b1 gene knockout on BLM-induced activation of Smad2/3 pathway were then analyzed. Of interest, Cyp27b1 gene knockout aggravated BLM-induced Smad2 and Smad3 phosphorylation in the lungs (Fig. 7a-c).

Fig. 7

figure7

Cyp27b1 gene knockout aggravates BLM-induced activation of TGF-β/Smad3 in the lungs. All animals were fed with standard fodder. All animals except controls were injected with BLM (1.5 mg/kg) through the trachea. All animals were sacrificed 2 weeks after BLM. Phosphorylated Smad2 and Smad3 were detected using Western blot. a Representative gels for p-Smad2, p-Smad3 and β-actin. Quantitative analysis of scanning densitometry for b p-Smad2 and c p-Smad3 were performed. Data were expressed as means ± SEM (N = 6). **P < 0.01, *P < 0.05

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Discussion

In the present study, we investigated the effects of feeding VDD diet, which resulted in vitamin D deficiency, on BLM-induced pulmonary fibrosis. The data showed that vitamin D deficiency exacerbated BLM-induced interstitial inflammation in the lungs. Moreover, vitamin D deficiency aggravated BLM-induced upregulation of pulmonary Col1α1 and Col1α2 mRNAs. In addition, vitamin D deficiency aggravated BLM-induced collagen deposition in the lungs, as determined by Sirius red staining. Results above exhibit the first experimental evidence that vitamin D deficiency exacerbates BLM-induced pulmonary fibrosis.

Accumulating data have demonstrated that TGF-β/Smad2/3-mediated EMT plays an important role in the development of BLM-induced pulmonary fibrosis [26, 27]. Indeed, our study showed that pulmonary TGF-β/Smad2/3 signaling was activated during BLM-induced lung fibrosis. Pulmonary E-cadherin, an epithelial marker, was obviously downregulated in BLM-treated mice. By contrast, vimentin and α-SMA, two mesothelial markers, were upregulated in the lungs of BLM-treated mice. In addition, numerous α-SMA-positive cells, as determined by IHC, were observed in pulmonary interstitium. An earlier in vitro study indicated that active vitamin D3 inhibited the expression of α-SMA and prevented the upregulation of fibronectin and collagen in TGF-β1-stimulated fibroblasts [28]. Recently, two reports indicated that calcitriol, the active form of vitamin D3, suppressed TGF-β1-stimulated EMT in human bronchial epithelial cells [29, 30]. In the present study, we investigated whether vitamin D deficiency aggravates Smad2/3-mediated EMT in BLM-induced lung fibrosis. Our results showed that vitamin D deficiency aggravated pulmonary TGF-β1 upregulation and subsequent Smad3 phosphorylation in BLM-induced lung fibrosis. Moreover, vitamin D deficiency aggravated upregulation of pulmonary ZEB1, a transcription factor for EMT, during BLM-induced lung fibrosis. Finally, vitamin D deficiency aggravated BLM-induced downregulation of pulmonary E-cadherin. By contrast, vitamin D deficiency aggravated BLM-induced upregulation of vimentin and α-SMA in the lungs. These results suggest that vitamin D deficiency exacerbates BLM-induced pulmonary fibrosis, at least partially, through aggravating TGF-β/Smad2/3-mediated EMT.

Cyp27b1 gene encodes CYP27B1, which is responsible for converting 25(OH)D3 into 1,25(OH)2D3, an active form of vitamin D3 [31, 32]. So Cyp27b1 gene knockout results in active vitamin D3 deficiency [33, 34]. An earlier study indicated that active vitamin D3 deficiency exacerbated radiation-induced bone marrow injury [35]. In the present study, we observed the effects of active vitamin D3 deficiency on BLM-evoked EMT and pulmonary fibrosis using a model of Cyp27b1 gene knockout mice. Of interest, Cyp27b1 knockout aggravated collagen deposition, as accessed by Sirius red staining, in BLM-induced pulmonary fibrosis. In addition, Cyp27b1 knockout aggravated BLM-induced downregulation of E-cadherin in the lungs. By contrast, Cyp27b1 knockout aggravated BLM-induced upregulation of α-SMA in the lungs. Finally, Cyp27b1 gene knockout aggravated BLM-induced pulmonary Smad2 and Smad3 phosphorylation. These results provide additional evidence that active vitamin D3 deficiency exacerbates Smad2/3 activation and subsequent EMT in BLM-induced pulmonary fibrosis.

The mechanism through which vitamin D deficiency aggravates TGF-β/Smad2/3-mediated EMT during BLM-induced pulmonary fibrosis remains obscure. An earlier report showed that active vitamin D3 inhibited renal fibrosis through promoting direct interaction VDR and Smad3 [36]. A recent study found that VDR, as a negative regulator of TGF-β/Smad3 pathway, inhibited Smad3-dependent transcription through stimulating formation of complexes between VDR and phosphorylated Smad3 in fibroblasts [37]. Indeed, the present experiment showed that pulmonary VDR signaling was inactivated in VDD-fed mice. Thus, it is speculated that VDR may be a regulator of EMT during BLM-induced pulmonary fibrosis. Indeed, an earlier report claimed that the truncated E-cadherin was elevated in biliary epithelial cells silenced for VDR [38]. Another study found that the expression of E-cadherin was downregulated in gut epithelial cells from VDR knockout mice [39]. In our present study, we claimed that pulmonary vimentin and α-SMA, two mesothelial markers, was upregulated in VDD-fed mice. By contrast, pulmonary E-cadherin, an epithelial marker, was slightly downregulated in Cyp27b1 gene knockout mice. Therefore, our present study does not exclude the direct role of VDR on EMT. Further study is necessary to explore whether long-term vitamin D deficiency induces pulmonary fibrosis through directly regulating EMT in the lungs.

VDR as a regulator of EMT during BLM-induced pulmonary fibrosis may have preventive and therapeutic implications. According to an epidemiological report, vitamin D deficiency was positively associated with the mortality of patients with IPF [24]. A recent animal experiment found that supplementation with calcitriol, an active vitamin D3, suppressed interstitial inflammation and EMT in the pathogenesis of BLM-induced lung fibrosis [19]. Another animal experiment indicated that supplementation with cholecalciferol, another active vitamin D3 protected mice from BLM-induced EMT and subsequent lung fibrosis [24]. In the present study, we showed that vitamin D deficiency aggravated BLM-induced TGF-β/Smad2/3 activation and EMT in the lungs. In addition, vitamin D deficiency exacerbated BLM-induced pulmonary fibrosis. Thus, vitamin D3 may be used as a potential adjuvant agent for pulmonary fibrosis especially in patients with low vitamin D status.

Conclusion

In summary, our present experiment investigated the effects of vitamin D deficiency on BLM-induced pulmonary fibrosis using two mouse models. We showed that feeding VDD diet, leading to vitamin D deficiency, exacerbated BLM-induced pulmonary fibrosis. Moreover, vitamin D deficiency aggravated TGF-β/Smad2/3 activation and subsequent EMT during BLM-induced pulmonary fibrosis. We found that Cyp27b1 gene knockout, leading to active vitamin D3 deficiency, exacerbated BLM-induced pulmonary fibrosis. In addition, Cyp27b1 gene knockout aggravated pulmonary TGF-β/Smad2/3 activation and subsequent EMT during BLM-induced lung fibrosis. Data above provide evidence that vitamin D deficiency exacerbates BLM-induced pulmonary fibrosis partially through aggravating TGF-β/Smad2/3-mediated EMT in the lungs.

Availability of data and materials

Data sharing is not applicable to this article as no datasets were generated or analyzed during the present study.

Abbreviations

BLM:

Bleomycin

CYP:

Cytochrome P450

EMT:

Epithelial–mesenchymal transition

IHC:

Immunohistochemistry

IPF:

Idiopathic pulmonary fibrosis

RT-PCR:

Reverse transcription-polymerase chain reaction

Transforming TGF-β:

Growth factor-beta

VDD:

Vitamin D deficient

VDR:

Vitamin D receptor

α-SMA:

alpha smooth muscle actin

References

1. 1.

Mora AL, Rojas M, Pardo A, Selman M. Emerging therapies for idiopathic pulmonary fibrosis, a progressive age-related disease. Nat Rev Drug Discov. 2017;16(11):755–72.

* CAS

* Article

* Google Scholar

2. 2.

Chanda D, Otoupalova E, Smith SR, Volckaert T, De Langhe SP, Thannickal VJ. Developmental pathways in the pathogenesis of lung fibrosis. Mol. Aspects. Med. 2019;65:56–69.

* CAS

* Article

* Google Scholar

3. 3.

Richeldi L, Collard HR, Jones M. Idiopathic pulmonary fibrosis. Lancet. 2017;389(10082):1941–52.

* Article

* Google Scholar

4. 4.

Adamson IY, Bowden DH. The pathogenesis of bleomycin-induced pulmonary fibrosis in mice. Am. J. Pathol. 1974;77(2):185–97.

* CAS

* PubMed

* PubMed Central

* Google Scholar

5. 5.

Zhao H, Qin HY, Cao LF, Chen YH, Tan ZX, Zhang C, et al. Phenyl butyric acid inhibits epithelial-mesenchymal transition during bleomycin-induced lung fibrosis. Toxicology Letters. 2015;232(1):213–20.

* CAS

* Article

* Google Scholar

6. 6.

Della Latta V, Cecchettini A, Del Ry S, Morales MA. Bleomycin in the setting of lung fibrosis induction: from biological mechanisms to counteractions. Pharmacol Res. 2015;97:122–30.

* CAS

* Article

* Google Scholar

7. 7.

Moeller A, Ask K, Warburton D, et al. The bleomycin animal model: a useful tool to investigate treatment options for idiopathic pulmonary fibrosis? Int J Biochem Cell Biol. 2008;40(3):362–82.

* CAS

* Article

* Google Scholar

8. 8.

Mouratis MA, Aidinis V. Modeling pulmonary fibrosis with bleomycin. Curr. Opin. Pulm. Med. 2011;17(5):355–61.

* CAS

* Article

* Google Scholar

9. 9.

Qian W, Cai X, Qian Q, Zhang W, Wang D. Astragaloside IV modulates TGF-β1-dependent epithelial-mesenchymal transition in bleomycin-induced pulmonary fibrosis. J Cell Mol Med. 2018;22(9):4354–65.

* CAS

* Article

* Google Scholar

10. 10.

Liu G, Wang Y, Yang L, Zou B, Gao S, Song Z, et al. Tetraspanin 1 as a mediator of fibrosis inhibits EMT process and Smad2/3 and beta-catenin pathway in human pulmonary fibrosis. J Cell Mol Med. 2019;23(5):3583–96.

* CAS

* Article

* Google Scholar

11. 11.

Lambert AS, Linglart A. Hypocalcaemic and hypophosphatemic rickets. Best Pract. Res. Clin. Endocrinol. Metab. 2018;32(4):455–76.

* CAS

* Article

* Google Scholar

12. 12.

Latimer CS, Brewer LD, Searcy JL, Chen KC, Popović J, Kraner SD, et al. Vitamin D prevents cognitive decline and enhances hippocampal synaptic function in aging rats. Proc. Natl. Acad. Sci. USA. 2014;111(41):E4359–66.

* CAS

* Article

* Google Scholar

13. 13.

Xu S, Chen YH, Tan ZX, Xie DD, Zhang C, Zhang ZH, et al. Vitamin D3 pretreatment regulates renal inflammatory responses during lipopolysaccharide-induced acute kidney injury. Sci. Rep. 2015;5:18687.

* CAS

* Article

* Google Scholar

14. 14.

Chen L, Yang R, Qiao W, Zhang W, Chen J, Mao L, et al. 1,25-Dihydroxyvitamin D exerts an antiaging role by activation of Nrf2-antioxidant signaling and inactivation of p16/p53-senescence signaling. Aging Cell. 2019;18(3):e12951.

* Article

* Google Scholar

15. 15.

Chaiprasongsuk A, Janjetovic Z, Kim TK, Jarrett SG, D'Orazio JA, Holick MF, et al. Protective effects of novel derivatives of vitamin D3 and lumisterol against UVB-induced damage in human keratinocytes involve activation of Nrf2 and p53 defense mechanisms. Redox Biol. 2019;24:101206.

* CAS

* Article

* Google Scholar

16. 16.

Fetahu IS, Höbaus J, Kállay E. Vitamin D and the epigenome. Front Physiol. 2014;5:164.

* Article

* Google Scholar

17. 17.

Pike JW, Meyer MB, Lee SM, Onal M, Benkusky NA. The vitamin D receptor: contemporary genomic approaches reveal new basic and translational insights. J. Clin. Invest. 2017;127(4):1146–54.

* Article

* Google Scholar

18. 18.

Zhang Z, Yu X, Fang X, Liang A, Yu Z, Gu P, et al. Preventive effects of vitamin D treatment on bleomycin-induced pulmonary fibrosis. Sci Rep. 2015;5:17638.

* CAS

* Article

* Google Scholar

19. 19.

Tan ZX, Chen YH, Xu S, et al. Calcitriol inhibits bleomycin-induced early pulmonary inflammatory response and epithelial-mesenchymal transition in mice. Toxicology letters. 2016;240(1):161–71.

* CAS

* Article

* Google Scholar

20. 20.

Matchar DB, Chei CL, Yin ZX, Koh V, Chakraborty B, Shi XM, et al. Vitamin D Levels and the Risk of Cognitive Decline in Chinese Elderly People: the Chinese Longitudinal Healthy Longevity Survey. J. Gerontol. A. Biol. Sci. Med. Sci. 2016;71(10):1363–8.

* CAS

* Article

* Google Scholar

21. 21.

Händel MN, Frederiksen P, Cohen A, Cooper C, Heitmann BL, Abrahamsen B. Neonatal vitamin D status from archived dried blood spots and future risk of fractures in childhood: results from the D-tect study, a population-based case-cohort study. Am.J. Clin. Nutr. 2017;106(1):155–61.

* Article

* Google Scholar

22. 22.

Belderbos ME, Houben ML, Wilbrink B, Lentjes E, Bloemen EM, Kimpen JL, et al. Cord blood vitamin D deficiency is associated with respiratory syncytial virus bronchiolitis. Pediatrics. 2011;127(6):e1513–20.

* Article

* Google Scholar

23. 23.

Łuczyńska A, Logan C, Nieters A, Elgizouli M, Schöttker B, Brenner H, et al. Cord blood 25(OH) D levels and the subsequent risk of lower respiratory tract infections in early childhood: the Ulm birth cohort. Eur J Epidemiol. 2014;29(8):585–94.

* Article

* Google Scholar

24. 24.

Tzilas V, Bouros E, Barbayianni I, Karampitsakos T, Kourtidou S, Ntassiou M, et al. Vitamin D prevents experimental lung fibrosis and predicts survival in patients with idiopathic pulmonary fibrosis. Pulm Pharmacol Ther. 2019;55:17–24.

* CAS

* Article

* Google Scholar

25. 25.

Fei J, Fu L, Hu B, et al. Obeticholic acid alleviate lipopolysaccharide-induced acute lung injury via its anti-inflammatory effects in mice. Int Immunopharmacol. 2019;66:177–84.

* CAS

* Article

* Google Scholar

26. 26.

Yan L, Song F, Li H, Li Y, Li J, He QY, et al. Submicron emulsion of cinnamaldehyde ameliorates bleomycin-induced idiopathic pulmonary fibrosis via inhibition of inflammation, oxidative stress and epithelial-mesenchymal transition. Biomed Pharmacother. 2018;102:765–71.

* CAS

* Article

* Google Scholar

27. 27.

Han Q, Lin L, Zhao B, Wang N, Liu X. Inhibition of mTOR ameliorates bleomycin-induced pulmonary fibrosis by regulating epithelial-mesenchymal transition. Biochem. Biophys. Res Commun. 2018;500(4):839–45.

* CAS

* Article

* Google Scholar

28. 28.

Ramirez AM, Wongtrakool C, Welch T, Steinmeyer A, Zügel U, Roman J. Vitamin D inhibition of pro-fibrotic effects of transforming growth factor beta1 in lung fibroblasts and epithelial cells. J. Steroid Biochem Mol. Biol. 2010;118(3):142–50.

* CAS

* Article

* Google Scholar

29. 29.

Fischer KD, Agrawal DK. Vitamin D regulating TGF-β induced epithelial-mesenchymal transition. Respir. Res. 2014;15:146.

* Article

* Google Scholar

30. 30.

Ricca C, Aillon A, Viano M, Bergandi L, Aldieri E, Silvagno F. Vitamin D inhibits the epithelial-mesenchymal transition by a negative feedback regulation of TGF-β activity. J Steroid Biochem Mol Biol. 2019;187:97–105.

* CAS

* Article

* Google Scholar

31. 31.

Jones G. Extrarenal vitamin D activation and interactions between vitamin D2, vitamin D3, and vitamin D analogs. Annu Rev Nutr. 2013;33:23–44.

* CAS

* Article

* Google Scholar

32. 32.

Adams JS, Rafison B, Witzel S, Reyes RE, Shieh A, Chun R, et al. Regulation of the extrarenal CYP27B1-hydroxylase. J. Steroid Biochem. Mol. Biol. 2014;144 Pt A:22–7.

* Article

* Google Scholar

33. 33.

Sun W, Chen L, Zhang W, Wang R, Goltzman D, Miao D. Active vitamin D deficiency mediated by extracellular calcium and phosphorus results in male infertility in young mice. Am. J. Physiol. Endocrinol. Metab. 2015;308(1):E51–62.

* CAS

* Article

* Google Scholar

34. 34.

Lindner J, Rausch S, Treptow S, Geldmeyer-Hilt K, Krause T, St-Arnaud R, et al. Endogenous Calcitriol Synthesis Controls the Humoral IgE Response in Mice. J. Immunol. 2017;199(12):3952–8.

* CAS

* Article

* Google Scholar

35. 35.

Zhang ZL, Ding XF, Tong J, Li BY. Enhanced radiosensitivity in 1,25-dihydroxyvitamin D3 deficient mice. J. Radiat. Res. 2011;52(2):215–9.

* CAS

* Article

* Google Scholar

36. 36.

Ito I, Waku T, Aoki M, Abe R, Nagai Y, Watanabe T, et al. A nonclassical vitamin D receptor pathway suppresses renal fibrosis. J Clin Invest. 2013;123(11):4579–94.

* CAS

* Article

* Google Scholar

37. 37.

Zerr P, Vollath S, Palumbo-Zerr K, Tomcik M, Huang J, Distler A, et al. Vitamin D receptor regulates TGF-β signaling in systemic sclerosis. Ann Rheum Dis. 2015;74(3):e20.

* Article

* Google Scholar

38. 38.

Firrincieli D, Zúñiga S, Rey C, Wendum D, Lasnier E, Rainteau D, et al. Vitamin D nuclear receptor deficiency promotes cholestatic liver injury by disruption of biliary epithelial cell junctions in mice. Hepatology. 2013;58(4):1401–12.

* CAS

* Article

* Google Scholar

39. 39.

Ooi JH, Li Y, Rogers CJ, Cantorna MT. Vitamin D regulates the gut microbiome and protects mice from dextran sodium sulfate-induced colitis. J. Nutr. 2013;143(10):1679–86.

* CAS

* Article

* Google Scholar

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Acknowledgements

We give very special thanks to every teammate for their dedication to the experiment.

Funding

This project was supported by National Natural Science Foundation of China (81800062; 81630084).

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Author notes

1.

Se-Ruo Li and Zhu-Xia Tan contributed equally to this work.

Affiliations

1. Second Affiliated Hospital, Anhui Medical University, Hefei, 230032, China

* Se-Ruo Li

* , Zhu-Xia Tan

* , Biao Hu

* & Hui Zhao

2. Department of Toxicology, Anhui Medical University, 81 Meishan Road, Hefei, 230032, China

* Yuan-Hua Chen

* , Cheng Zhang

* , Hua Wang

* & De-Xiang Xu

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Contributions

DXX and HZ conceived and designed experiments. SRL, ZXT, BH, and CZ, conducted experiments. YHC contributed mice. SRL analyzed data. DXX and HW contributed reagents and materials. DXX and HZ contributed to writing of the manuscript. All authors read and approved the final manuscript.

Corresponding authors

Correspondence to Hui Zhao or De-Xiang Xu.

Ethics declarations

Ethics approval

The present investigation received permissions from the Institution of Laboratory Animals Center and Scientific Experimental Rodents in Anhui Medical University (AHMU). The entire practice for animals on the basis of the recommendation for humanitarian treatment enacted by the Committee of Ethics Laboratory Animals and Laboratory Animals Center in AHMU.

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The authors declare that they have no competing interests.

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Li, S., Tan, Z., Chen, Y. et al. Vitamin D deficiency exacerbates bleomycin-induced pulmonary fibrosis partially through aggravating TGF-β/Smad2/3-mediated epithelial-mesenchymal transition. Respir Res 20, 266 (2019) doi:10.1186/s12931-019-1232-6

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* Received

01 October 2019

* Accepted

05 November 2019

* Published

27 November 2019

* DOI

https://doi.org/10.1186/s12931-019-1232-6

Keywords

* Pulmonary fibrosis

* Vitamin D deficiency

* Epithelial-mesenchymal transition

* Bleomycin

* Mice