Abstract
Activation of the Hedgehog (Hh) signaling pathway by mutations within its components drives the growth of several cancers. However, the role of Hh pathway activation in lung cancers has been controversial. Here, we demonstrate that the canonical Hh signaling pathway is activated in lung stroma by Hh ligands secreted from transformed lung epithelia. Genetic deletion of Shh, the primary Hh ligand expressed in the lung, in KrasG12D/+;Trp53fl/fl autochthonous murine lung adenocarcinoma had no effect on survival. Early abrogation of the pathway by an anti-SHH/IHH antibody 5E1 led to significantly worse survival with increased tumor and metastatic burden. Loss of IHH, another Hh ligand, by in vivo CRISPR led to more aggressive tumor growth suggesting that IHH, rather than SHH, activates the pathway in stroma to drive its tumor suppressive effects—a novel role for IHH in the lung. Tumors from mice treated with 5E1 had decreased blood vessel density and increased DNA damage suggestive of reactive oxygen species (ROS) activity. Treatment of KrasG12D/+;Trp53fl/fl mice with 5E1 and N-acetylcysteine, as a ROS scavenger, decreased tumor DNA damage, inhibited tumor growth and prolonged mouse survival. Thus, IHH induces stromal activation of the canonical Hh signaling pathway to suppress tumor growth and metastases, in part, by limiting ROS activity.
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Introduction
Lung cancer is the leading cause of cancer-related mortality in the U.S. and the world [1] with 5-year survival of <5% for patients with metastatic disease [2]. Non-small cell lung cancer (NSCLC) accounts for ~85% of lung cancers, of which, adenocarcinoma is the most common subtype of NSCLC (http://seer.cancer.gov/csr/1975_2007/results_merged/sect_15_lung_bronchus.pdf). KRAS mutations are the most common oncogenic driver mutations and occur in ~30% of lung adenocarcinoma (LAD) [3]. Currently, specific targeted therapies for mutant KRAS LAD are not available in the clinic.
The Hedgehog (Hh) signaling pathway is critical for embryonic development, tissue homeostasis, and cancer [4]. The pathway primarily operates in a paracrine manner in which a secreted Hh ligand (Sonic Hh (SHH), Indian Hh (IHH), and Desert Hh (DHH) in mammals) binds to Patched (PTCH), a 12-pass transmembrane protein, to relieve its basal inhibition of Smoothened (SMO), a seven-pass transmembrane protein. SMO activation leads to activation and nuclear localization of the glioma-associated oncogene 2 (GLI2) transcription factor to initiate the transcription of target genes, including PTCH, glioma-associated oncogene 1 (GLI1), and Hh interacting protein (HHIP) [4].
Aberrant activation of the Hh signaling pathway by mutations in pathway components such as PTCH, SUFU, SMO, and amplifications of GLI1 and GLI2 drive tumor growth in basal cell carcinoma (BCC) [5], medulloblastoma [6], keratocystic odontogenic tumors [7, 8], meningioma [9,10,11], and ameloblastoma [12]. Vismodegib [13], sonidgeib [14], and glasdegib [15], potent SMO antagonists, have been approved by the FDA for clinical use [16,17,18].
Mutations of Hh pathway components are rare in sporadic epithelial tumors of endodermal origin such as lung, pancreas, gut and prostate cancers. It was proposed that these cancers recapitulated development by secreting Hh ligands from the tumor epithelia to activate the pathway in stromal cells that, in turn, secreted factors instrumental for tumor initiation and growth [19]. However, recent data suggest that paracrine activation of stroma by Hh ligands promotes fibroblast expansion and restrains tumor growth early in the tumorigenic process. Inhibition of stromal pathway activation led to accelerated tumor growth with more aggressive, higher grade tumors [20,21,22,23,24,25].
In lung cancers, a variety of roles for the Hh signaling pathway has been reported. In autochthonous mouse models of small cell lung cancer (SCLC), overexpression of SHH or SMOM2, a constitutively active mutant, in Rb−/−;Trp53−/− cancer cells promoted tumor proliferation [26, 27], loss of SMO led to significantly decreased tumor formation, and treatment with sonidegib inhibited tumor growth of chemotherapy-resistant SCLC in vivo [26]. However, a phase III clinical trial showed no benefit of adding vismodegib to standard chemotherapy in treatment-naïve SCLC patients [28]. For NSCLC, distinct modes of action have been reported for the Hh signaling pathway. In lung squamous cell carcinoma (LSCC) tumor-spheres [29], SOX2 activation induced upregulation of Hh acyltransferase (HHAT) [30], a critical component that palmitoylates Hh ligands, and induced autocrine pathway activation to drive growth of LSCC tumor-spheres but not bulk LSCC cells nor LAD tumor-spheres [29]. Alternatively, in PIK3CA-amplified LSCC, PI3K-mTOR pathway activation led to non-canonical GLI1 expression independent of the Hh pathway [31]. GLI1 activation drove LSCC growth and treatment with combinatorial PI3K and GLI1 antagonists induced tumor regression in vivo [31]. In LAD tumor-spheres and cell lines, paracrine SHH from LAD epithelia activated the pathway in stroma to express VEGF that in turn, bound to NRP2 receptor to activate the MAPK pathway and express GLI1 in a non-canonical manner [32]. Given these varied results of the pathway’s role and modes of action in lung cancers and other solid tumors, we tested the role of paracrine Hh pathway activation in LAD tumorigenesis and growth in autochthonous mutant KrasG12D/+;Trp53fl/fl mouse model of LAD.
Results
SHH ligand is expressed in lung adenocarcinoma and activates stromal Hh pathway by a paracrine mechanism
We evaluated the impact of SHH expression on LAD patients as SHH is the primary Hh ligand critical for lung development [33] and adult lung airway homeostasis [34]. SHH expression and activity has also been reported in lung cancers [26, 27, 30, 32, 35]. We assessed the impact of high SHH mRNA expression in LAD patients in the Kaplan–Meier Plotter (KM-Plotter; [36]) database that aggregates Affymetrix microarray mRNA expression data with clinical annotation. From 720 LAD patients and using median expression as the cutoff, a univariate Cox regression analysis of high SHH mRNA expression significantly correlated with worse overall survival (P = 0.0006; Fig. 1a) and progression-free survival (P = 0.044; Fig. 1b). These results were corroborated when stage, gender, and smoking history were accounted for in multivariate analyses for overall survival (Supplementary Fig. 1a) but not in progression-free survival (Supplementary Fig. 1b). We then surveyed 34 human LAD cell lines for Hh ligand expression by qPCR (Fig. 1c). Mutant KRAS cell lines were sought as mutant KRAS has been reported to upregulate SHH expression [37]. The majority of high Hh ligand expressing cell lines, defined as >4× expression of normal bronchial epithelial HBEC7-KT cells, also expressed mutant KRAS (Fig. 1c). H23, H2887, HCC44, and H2258 LAD cells expressed high levels of SHH protein, whereas H441 and H3122 expressed low levels of SHH protein as measured by immunoblot (Fig. 1d), consistent with qPCR results (Fig. 1c).
To test if SHH protein was secreted from LAD cells and could activate the Hh signaling pathway, we co-cultured three cell lines with the highest level of SHH (from Fig. 1c, d) with Hh-pathway responsive Shh-Light2 mouse embryonic fibroblasts that contain an 8×-GLI binding site-firefly luciferase reporter [38]. Treatment of Shh-Light2 cells alone with SHHN conditioned medium (CM) [39] induced high levels of Hh pathway activity that was suppressed by KAAD-cyclopamine 200 nM [40], a potent SMO antagonist, and 5E1 10 μg/ml, a blocking monoclonal antibody that binds to SHH and IHH [41, 42] (Fig. 1e). Co-culture of high SHH-expressing cells (H2887, H23, and HCC44) with Shh-Light2 cells, but without addition of exogenous SHH, resulted in potent activation of the pathway in Shh-Light2 cells, compared with normal airway epithelial HBEC7-KT cells (Fig. 1e). Treatment of these co-cultured cells with KAAD-cyclopamine and 5E1 inhibited Hh pathway activation in Shh-Light2 cells (Fig. 1e). In contrast, low SHH-expressing H3122 cells did not significantly induce Hh pathway activation in Shh-Light2 cells. To test for autocrine activation of the Hh signaling pathway in tumor cells, we treated high SHH-expressing H2887 and HCC44 cells (Fig. 1c, d) with recombinant SHH (rSHH) 1 μg/ml, 5E1 10 μg/ml or KAAD-cyclopamine 300 nM and monitored the mRNA transcription of reported pathway target genes GLI1, PTCH1, HHIP, BMP4, BMP7, MYCN, CCND1, SOX9, and BMI1 by qPCR after treatment. In both H2887 (Fig. 1f–h, Supplementary Fig. 2) and HCC44 (Supplementary Fig. 3), addition of rSHH did not increase mRNA transcription of target genes nor did treatment with 5E1 or KAAD-cyclopamine substantially decrease mRNA transcription, defined as >50% decrease, across the panel of the tested target genes compared with DMSO control. These results are in contrast with Hh-responsive MLg murine lung fibroblasts [35] (Supplementary Fig. 4) suggesting that the tumor cells did not respond to secreted SHH in an autocrine manner. Interestingly, H2887 and HCC44 cells expressed higher GLI1 mRNA and other pathway target genes than the normal bronchial epithelial HBEC7-KT cells (Fig. 1f–h, Supplementary Fig. 2) suggesting that the genes may be upregulated by a Hh-independent mechanism. Taken together, the results of the co-culture (Fig. 1e) and autocrine (Fig. 1f–h, Supplementary Figs. 2 and 3) experiments suggested that SHH from LAD cells activate the pathway in stromal cells in a paracrine manner without autocrine activation in tumor cells.
SHH does not affect lung adenocarcinoma growth in vivo
We next sought to test the role of stromal Hh pathway in lung tumor development. As reliable anti-SHH antibodies for immunohistochemistry (IHC) were not commercially available, we tested for Shh mRNA expression by in situ hybridization. We validated Shh mRNA probes in the neural tube of E11.5 mouse embryos, where SHH is highly expressed in the notochord [43, 44] and floor plate [45, 46] (Supplementary Fig. 5a). Ten weeks after infection of KrasLox-Stop-Lox-G12D/+;Trp53fl/fl (KP) mice [47] with adenovirus-expressing cre recombinase (adeno-cre) by intranasal inhalation, LAD expressed Shh mRNA as shown by in situ hybridization (Fig. 2a, Supplementary Fig. 5b). We further verified the expression of Shh mRNA specifically in primary KP transformed lung epithelia. Lungs from uninfected KP mice and KP;Rosa26Loxp-mtdTomato-Stop-Loxp-mGFP/+ (KPmTmG) mice [48], a strain that conditionally switches from constitutive tdTomato expression to GFP expression and initiates LAD when exposed to cre recombinase (Supplementary Fig. 6a), infected with adeno-cre were enzymatically dissociated into single cells. Lung epithelial cells were isolated using FACS–EpCAM+, GFP+ (adeno-cre infected cells) for KPmTmG epithelia (Supplementary Fig. 6b), and CD31− (endothelial cell antigen), CD45− (leukocyte antigen), EpCAM+ (epithelial cell antigen) for uninfected KP epithelia (Supplementary Fig. 6c)—and Shh mRNA measured by qPCR. Infected KPmTmG lung epithelia expressed higher levels of Shh mRNA than wild-type lung epithelia of uninfected KP mice (Fig. 2b). After identifying the optimal dose of 5E1 for in vivo studies using a Hh-dependent hair regrowth study [49, 50] (Supplementary Fig. 7), KPmTmG mice were treated with IgG1 control or 5E1 10 mg/kg by intraperitoneal (i.p.) injection twice per week for four weeks starting 2 weeks after adeno-cre infection and transformed epithelial cells and stromal cells were isolated by FACS (Supplementary Fig. 8). Shh mRNA expression was ~4 orders of magnitude higher in transformed lung epithelial cells than in stromal cells, as measured by qPCR (Fig. 2c). Gli1 mRNA levels, as a measure of response to SHH ligand, were ~4 orders of magnitude higher in stromal cells than in transformed epithelial cells (Fig. 2d). Furthermore, stromal cells from KPmTmG mice treated with 5E1 showed ~90% decrease in Gli1 mRNA transcription compared with stromal cells treated with IgG1 control in contrast to FACS-sorted epithelial cells (Fig. 2d), suggesting that the Hh signaling pathway is activated primarily in stroma by a paracrine mechanism with no autocrine activation in tumor epithelia. mRNA expression of Hh pathway target genes in 808-T3 cells, a murine KP LAD cell line that expresses SHH (Supplementary Fig. 9), were not significantly increased when treated with rSHH or significantly diminished when treated with pathway inhibitors, 5E1 or KAAD-cyclopamine (Fig. 2e–g, Supplementary Fig. 10). To identify the pathway-responsive stromal cells, we crossed KP mice with the Gli1Lacz/+ reporter strain [51] that contains the LacZ gene with a nuclear localization signal sequence knocked into the Gli1 locus to generate the KP;Gli1Lacz/+ strain. Nuclear expression of β-galactosidase was diminished in KP;Gli1Lacz/+ murine lungs treated with 5E1 10 μg/ml twice per week for 2 weeks starting 2 weeks after adeno-cre infection compared with those treated with IgG1 control (Fig. 2h, Supplementary Fig. 11). Nuclear β-galactosidase co-localized with fibroblast (PDGRα) and myobfibroblast (αSMA) markers but not with perivascular smooth muscle (αSMA+, PDGRα−), lung epithelial cells (E-Cadherin+), nor endothelial cells (CD31+) (Fig. 2i, Supplementary Fig. 12) suggesting that fibroblasts and myofibroblasts are the primary cells that respond to Hh ligands. We next tested the requirement of stromal Hh pathway activity for LAD tumorigenesis by crossbreeding KP with Shhfl/fl [52] mice to generate KP, KP;Shhfl/+, and KP;Shhfl/fl strains to induce LAD with wild-type (wt), heterozygous, and homozygous loss of SHH expression. Surprisingly, KP, KP;Shhfl/+, and KP;Shhfl/fl mice did not show any differences in survival after LAD induction with adeno-cre (Fig. 2j). To verify that Shh was indeed deleted in KP;Shhfl/fl mice, we isolated EpCAM+;GFP+ infected lung epithelial cells by FACS from KPmTmG and KPmTmG;Shhfl/fl mice 3 weeks after adeno-cre infection, analogous to Supplementary Fig. 6b, and tested for Shh mRNA expression by qPCR. Indeed, KP;Shhfl/fl infected epithelial cells expressed Shh mRNA ~6 orders of magnitude less than KP epithelial cells (Fig. 2k), suggesting that Shh was indeed knocked out. Furthermore, no significant differences in tumor size were seen in the lungs of KP, KP;Shhfl/+, and KP;Shhfl/fl 10 weeks after infection (Fig. 2l, m). Taken together, these results suggest that SHH may not play a role in mutant Kras LAD tumorigenesis and progression.
Activation of the Hh pathway in stroma prolongs survival by restraining tumor growth and metastasis in vivo
To further examine the effect of paracrine Hh pathway activity in lung tumorigenesis, KP mice were treated with 5E1 10 mg/kg i.p. twice per week or IgG1 control starting 2 or 6 weeks after tumor initiation by adeno-cre infection (Fig. 3a) such that the pathway was inhibited early in the tumorigenic process (2 weeks) or once adenomas with nuclear atypia had been established (6 weeks) [47]. KP mice treated with 5E1 starting 2 weeks after tumor initiation had significantly worse survival compared with IgG1 treated control mice (Fig. 3b) in contrast to mice treated with 5E1 starting 6 weeks after adeno-cre infection (Fig. 3c). Furthermore, KP mice treated with 5E1 at the 2 week time point exhibited significantly higher rates of metastases (Fig. 3d), primarily to mediastinal lymph nodes and pleura (Fig. 3e, f). Examination of LAD tumors after 8 weeks of 5E1 treatment (10 weeks after adeno-cre infection) demonstrated significantly larger size of tumors (Fig. 3g–i) with a greater proportion of poorly differentiated tumors and less well-differentiated tumors (Fig. 3j, k) compared with mice treated with IgG1 control. Thus, pharmacologic inhibition of stromal Hh pathway induced greater tumor burden with greater metastases and worse survival, suggesting that stromal Hh pathway activity restrains LAD growth and metastasis.
IHH is the predominant Hh ligand in murine mutant Kras lung adenocarcinoma
With the disparate outcomes of genetic SHH loss (Fig. 2j, l, m) and pharmacologic blockade by 5E1 (Fig. 3b, d–k), we hypothesized that IHH may play a role in LAD tumorigenesis as 5E1 binds both SHH and IHH. We verified that 5E1 can inhibit stromal pathway activation by IHH using Shh-Light2 cells stimulated with either recombinant IHH (rIHH) or rSHH (Fig. 4a). Of note, there was almost no induction of pathway activity with recombinant DHH treatment (results are not shown). As reliable antibodies for IHH IHC and immunoblots were not commercially available, we turned to RNA in situ hybridization. KP LAD 10 weeks after adeno-cre infection expressed Ihh mRNA (Fig. 4b). To further verify that IHH is expressed by transformed lung epithelial cells, EpCAM+,GFP+ epithelial cells were isolated by FACS (analogous to Supplementary Fig. 6b) from KPmTmG mice 6 weeks after adeno-cre infection. The sorted epithelial cells show a striking increase in Ihh mRNA expression compared with Shh mRNA as measured by qPCR (Fig. 4c). In FACS-sorted lung epithelial and stromal cells (analogous to Supplementary Fig. 8), Ihh mRNA was expressed primarily in lung epithelial cells (Fig. 4d) with stromal cells responding to Hh ligands (Fig. 2d). Ihh mRNA was also expressed significantly higher than Shh mRNA in 808-T3 murine KP LAD cell line (Fig. 4e). Addition of more rIHH to 808-T3 cells did not modulate transcription of pathway target genes (Fig. 4f, Supplementary Fig. 13) in contrast to MLg lung fibroblasts (Supplementary Fig. 14), further suggesting that there is no autocrine activation of the Hh signaling pathway in tumor cells. To genetically test the requirement of IHH to suppress LAD tumorigenesis and growth, we used the pSECC lentiviral in vivo CRISPR/Cas9 system [53] that encodes for Cre recombinase to initiate tumorigenesis, Cas9 for gene editing, and sgRNA against the gene of interest. Several candidate sgRNA against Ihh (sgIhh) were tested with SURVEYOR assay (Supplementary Fig. 15a) and the sgRNA sequence (#2, hereafter just sgIhh) with the greatest percentage of digested bands was chosen for further study. We tested pSECC-Ihh for loss of Ihh mRNA expression by qPCR in 808-T3 cells with high Ihh mRNA expression (Fig. 4e). Approximately half of the clones from 808-T3 cell lines transfected with the pSECC-Ihh showed substantial decreases in Ihh mRNA expression compared with pSECC-GFP control (Supplementary Fig. 15b). Subsequently, KP;Rosa26LSL-fLuc/+ (KPL) mice were infected with lentiviral particles containing pSECC-Ihh or pSECC-GFP via intratracheal administration and tumor growth monitored by bioluminescence imaging (BLI) (Fig. 4g). Infection with pSECC-Ihh induced significant tumor growth compared with pSECC-GFP control 18 weeks after infection (Fig. 4h, i). KPL mice infected with pSECC-GFP eventually developed tumors that were detected by BLI at 22–26 weeks after infection (Fig. 4h). Examination of tumors at 18 weeks after pSECC-Ihh or pSECC-GFP infection from a separate experiment demonstrated greater tumor burden with loss of IHH (Fig. 4j, k).
IHH in human lung adenocarcinoma
We next tested for IHH mRNA by in situ hybridization in human LAD samples in mutant and wild-type KRAS and TP53 samples. Two of the three mutant KRAS;TP53 samples expressed IHH mRNA in malignant cells (Fig. 5a, Supplementary Fig. 16), whereas only one of the six wild-type samples expressed IHH mRNA (Fig. 5b, Supplementary Fig. 16). All of the IHH mRNA positive tumors had a predominance of lepidic histology with mucinous features (Supplementary Fig. 16). Lepidic histology has been correlated with less aggressive biology. The prognosis of mucinous histology in LAD is uncertain currently [54]. Re-examination of the 34 human LAD cell lines (Fig. 1c) revealed only 4 lines with IHH mRNA elevated beyond four times the normal lung epithelial line HBEC7-KT (Fig. 5c). As most of the cell lines were generated from patients with late stage or metastatic adenocarcinomas, the dearth of cancer lines with upregulated IHH mRNA corroborates the in situ results of IHH mRNA in more indolent lepidic histologies (Fig. 5a, Supplementary Fig. 16). In high IHH mRNA expressing H650 cells (Fig. 5c), treatment with rIHH or pathway inhibitors, 5E1 and KAAD-cyclopamine, did not show increase nor substantial decrease (>50%) in mRNA transcription compared with DMSO control across the panel of tested pathway target genes, respectively (Supplementary Fig. 17). These data, along with those of high SHH/IHH expressing H2887 cells (Fig. 1f–h, Supplementary Fig. 2) suggest that there is no autocrine activation of the pathway by IHH in human LAD cells. Univariate Cox regression analysis of a clinically annotated microarray database of human LAD (KM Plotter; [36]) revealed that patients with high expression of Ihh mRNA had better overall (P = 0.0001; Fig. 5d) and progression-free (P = 0.0069; Fig. 5e) survival compared with those with low expression. These results remained consistent after multivariate analyses when stage, gender, and smoking history were considered (Fig. 5f, g), in agreement with our murine LAD data (Figs. 3b and 4g–k). The data here suggest that IHH is sufficient to suppress tumor initiation and growth and that SHH is dispensable for LAD tumorigenesis.
Loss of stromal Hh pathway inhibits angiogenesis and increases the activity of reactive oxygen species
The Hh signaling pathway has been implicated in the regulation of angiogenesis in normal tissues [55, 56] and cancer [57, 58] through induction of angiogenic factors including VEGFs and ANG1, 2. Examination of CD31 expression, a marker of endothelial cells, showed decreased blood vessel density in LAD tumors treated with anti-SHH/IHH 5E1 antibody compared with IgG1 treated tumors (Fig. 6a, b). As the effects of stromal Hh pathway inhibition were seen with mice when treatment was initiated 2 weeks after adeno-cre infection (Fig. 3b, d–k), we hypothesized that the inability of growing tumors to generate new vessels would lead to early hypoxia and production of reactive oxygen species (ROS) [59, 60], that in turn, would promote tumor proliferation and growth [61,62,63]. We developed two macros (“ROI_Draw” and “Nuclear_Fraction_Calculator”) for ImageJ [64] or Fiji [65] to quantify DAB stained nuclei of phospho-histone 2AX (γH2AX), a protein that responds to double stranded DNA breaks and a marker of oxidative stress [66, 67]. Nuclear_Fraction_Calculator counts DAB stained nuclei and total nuclei in digital images of tissue sections and calculates the fraction of IHC positive nuclei within regions of interest (ROI; tumors in our studies) that have been drawn interactively with ROI_Draw. With these macros, LAD from mice treated with 5E1 showed significantly higher fraction of nuclei stained with γH2AX than tumors from IgG1 treated mice (Fig. 6c, d), suggesting increased DNA damage from ROS. To assess whether ROS from stromal Hh pathway inhibition induced accelerated tumor growth, KP mice were treated with 5E1 and N-acetyl cysteine (NAC), as a scavenger of ROS and precursor to the antioxidant, glutathione (GSH) (Fig. 6e). Treatment with NAC and 5E1 prolonged survival compared with 5E1 and vehicle control (Fig. 6f), whereas treatment with NAC and IgG1 did not affect survival (Fig. 6g). Furthermore, the median survival of 5E1 with NAC approximated that of IgG1 with vehicle control (Supplementary Fig. 18). Interestingly, the rate of metastases did not decrease when mice were treated with 5E1 and NAC compared with 5E1 and vehicle control (Fig. 6h). The tumor size in mice treated with 5E1 and NAC were significantly decreased compared with mice treated with 5E1 and vehicle control 10 weeks after adeno-cre infection (Fig. 6i, j) and corresponded to decreased DNA damage as measured by γH2AX stained nuclei as a marker of ROS activity (Fig. 6k, l). These data suggest that IHH restrains tumor growth through support of angiogenesis and limiting ROS activity early in the tumorigenic process.
Discussion
In accordance with previous studies [20,21,22,23,24,25], paracrine Hh activation of stroma, particularly early in the tumorigenic process, suppresses lung tumor growth, formation of aggressive histologies and metastases. A surprising result of our studies was the central role of IHH, instead of SHH, to suppress tumor growth. SHH is the dominant ligand that regulates lung development [33], adult lung airway homeostasis [34], and lung cancers [26, 27, 30, 32, 35]. IHH is expressed in the adult colon and prostate and restrains the growth of colon [24, 68] and prostate [25] cancers. However, to our knowledge, IHH activity has not been reported in the lung. Further studies are needed to test if IHH has a role in the homeostasis of the adult lung epithelia or if it is unique to lung cancers.
In our studies, loss of stromal pathway activation in KP LAD decreased blood vessel density (Fig. 6a, b) suggesting that the Hh signaling pathway induces angiogenesis in the lungs consistent with reports in other organs [55, 56, 69]. However, loss of stromal Hh pathway activation in KP pancreas ductal adenocarcinoma (PDAC) increased tumor blood vessel density and inhibition of angiogenesis through VEGFR2 antagonism in KP;Shhfl/fl PDACs prolonged mouse survival [20]. Another study reported that loss of Hh ligand co-receptors, GAS1 and BOC, in mouse embryonic and pancreas cancer-associated fibroblasts (CAFs) led to partial suppression of pathway response to SHH and increased angiogenesis [70]. Loss of co-receptors GAS1, BOC, and CDO in fibroblasts caused a more severe suppression of the pathway and inhibited angiogenesis through modulation of angiogenic ligands VEGFA, ANGPT1, 2 [70]. If stromal cells respond distinctly to SHH and IHH ligands, then IHH may play a more prominent role in angiogenesis in LAD than SHH due to the lower potency of IHH (Fig. 4a) analogous to the diminished pathway response of Gas1−/−;Boc−/− fibroblasts in pancreatic cancer [70]. Previous studies also have noted differences in genomic and transcriptomic heterogeneity [71] and effectors downstream of mutant Kras [72] between murine KP LADs and PDACs. Such differences may also play a role in the tumor microenvironment where responses to Hh ligands may differ significantly between pancreas and lung stroma. The distinct phenotypic outcomes of stromal Hh pathway activation in LAD and PDAC suggest that tumor-stromal interactions of various cancer types will need to be studied individually and caution against broad generalizations.
ROS exhibit seemingly paradoxical effects of tumor growth enhancement and tumor cytotoxicity depending on their levels [73]. Oncoproteins, such as mutant KRAS and MYC, and hypoxic states can increase cellular ROS levels [63, 74] that enhance tumor growth [63, 75,76,77]. But high levels of ROS can be cytotoxic and cancer cells upregulate antioxidant proteins including glutathione peroxidases, peroxiredoxins, and NRF2 to maintain ROS at optimal levels [74]. Here, we have shown that loss of stromal pathway activity early in the tumorigenic process increased DNA damage as marker of ROS activity in tumor cells (Fig. 6c, d). Reduction of ROS activity with NAC combined with stromal pathway inhibition prolonged survival with retardation of tumor growth in KP LAD (Fig. 6f, i–l). A recent study [78] demonstrated increased metastases when KP mice were treated with NAC. In our study, addition of NAC to 5E1 treatment did not change the rate of metastases in KP mice compared with 5E1 treatment (Fig. 6h) while 5E1 treatment of KP mice increased the rate of metastases compared with control treatment (Fig. 3d–f). These results suggest that KP mice treated with 5E1 and NAC may have increased metastases compared with KP control mice and are in general agreement with the observations of Wiel et al. [78]. Further studies will be needed for direct comparisons of adding NAC to control or 5E1 treatment in KP mice.
In bladder [23] and colon [24] cancers, BMPs secreted from Hh-dependent stroma limit the histologic progression of cancers. Similarly, loss of stromal Hh pathway activation in the lung leads to higher grade tumors (Fig. 3j, k) and murine lung fibroblasts express BMPs in response SHH (Supplementary Fig. 4) and IHH (Supplementary Fig. 14). Thus, loss of BMPs from lung fibroblasts may also contribute to the increased growth and aggressiveness of KP LAD with pathway inhibition.
Our studies here highlight the tumor suppressive roles of stromal Hh pathway activation by IHH via limiting hypoxia and ROS activity through angiogenesis and reinforce the anti-oncogenic role of stroma early in the tumorigenic process. Identification of factors that negatively regulate IHH production in LAD may serve as targets of small molecule or antibody therapeutics to enhance IHH expression and restrain tumor growth and metastases. Such therapeutic strategies may be employed in early stage or locally advanced disease prior to surgery/high dose radiation or concurrent chemoradiation, respectively, where treatment failure often occurs due to distant metastases. Also, identification of such factors may serve as biomarkers to determine the early stage patients that might benefit from more aggressive therapy.
Materials and methods
Cell culture
All human LAD cell lines were obtained from the Hamon Cancer Center Collection (UT Southwestern Medical Center, UTSW), were DNA fingerprinted with a PowerPlex 1.2 kit (Promega) and tested for mycoplasma using e-Myco kit (Boca Scientific). The cell lines were generated between 1979 and 2007. Cells were maintained in RPMI-1640 (Life Technologies) with 5% fetal bovine serum (FBS). 808-T3 and Green-Go [53] cell lines were kind gifts from Dr David McFadden (UTSW) and Dr Tyler Jacks (MIT), respectively, and were maintained in DMEM (Life Technologies) with 10% FBS. All cells were maintained at 37 °C, with 5% CO2, and under humidified conditions.
Drugs and reagents
5E1 antibody was expanded in our laboratory (see Supplementary material and methods) and prepared in PBS. IgG1 (InVivoMab, BE0083) was diluted in PBS. KAAD-cyclopamine (Millipore) was prepared in DMSO. Recombinant SHH (C25II) (R&D Systems) and IHH (C28II) (Genscript) were prepared in PBS containing 0.1% bovine serum albumin (BSA). N-Acetyl-L-cysteine (NAC) was purchased from Sigma-Aldrich and prepared in PBS for i.p. injection or sterile tap water for supplemented drinking water. For NAC solution, pH was adjusted to 7.4.
GLI-reporter assay
Shh-Light2 cells [38], a clonal NIH-3T3 cell line that stably expresses 8xGLI-binding site-firefly and TK-Renilla luciferase reporters, were co-cultured with LAD cell lines in 24-well plates until confluent and then treated with KAAD-cyclopamine (Millipore) 200 nM, 5E1 antibody 10 µg/ml or recombinant SHHN protein 1 µg/ml in DMEM containing 0.5% (vol/vol) bovine calf serum. Luciferase activity was measured by Fluostar Optima (BMG Labtech) using Dual Luciferase Assay Reporter System (Promega).
Quantitative real-time PCR
Total RNA was extracted using TriZol (Invitrogen) and purified with PureLink RNA Mini Kit (Invitrogen). cDNA was generated using iScript cDNA synthesis kit (Bio-Rad) or Superscript III First Strand Synthesis System (Invitrogen). qPCR was performed using Bio-Rad CFX real-time cycler and SYBR Green Master Mix (Bio-Rad). Data are presented as fold change relative to control samples using the ΔΔCt (2−ΔΔCt) method with HPRT1 or GAPDH as an internal control gene. Primers for qPCR are listed in Supplementary Table 1.
Western blot
Cell lysates were generated and analyzed as previously described [31]. Briefly, cells were lysed in ice-cold lysis buffer (M-PER Mammalian Protein Extraction Reagent (Thermo Scientific) with protease inhibitors (Roche) and PhosSTOP phosphatase inhibitors (Roche). Cell lysates were centrifuged at 14,000 rpm for 5 min at 4 °C and then supernatants were collected. Protein concentration was measured using BCA protein assay kit (Pierce) following the manufacturer’s instructions. The following primary antibodies were used: SHHN (1:1000, Cell Signaling Technology, C9C5), HSP90 (1:2000, Santa Cruz biotechnology, sc-13119), and Tubulin (1:5000, abcam, ab7291).
sg-RNA design and cloning
All sg-RNA against Ihh were designed using GE Dharmacon web tool. The sg-RNA sequences targeting GFP were published previously [79]. sg-RNA oligo candidates (listed on Supplementary Table 2) were inserted into pSECC vector (a kind gift from Dr Tyler Jacks, Addgene, 60820) by following the protocol available at this website: https://tinyurl.com/y29utjk8.
Co-transfection of 808-T3 cells
Cells were grown to 70% confluency on six-well plates and then co transfected with pCMV:DsRed(FRT)GFP plasmid expressing DsRed (Addgene, 31128) and pSECC-Ihh or pSECC-GFP using Lipofectamine 3000 (Thermo Fisher Scientific) following manufacturer instructions. DsRed+ transfected cells were FACS sorted and plated at limiting dilutions to isolate clonal lines.
Animals
All animal related experiments and procedures were performed with prior approval of the Institutional Animal Care and Use Committee at UTSW. FVB, KrasLox-Stop-Lox-G12D/+ [80], Trp53fl/fl [81], Shhfl/fl [52], and Rosa26Lox-mtdTomato-Stop-Lox-mGFP/+ [48] mouse strains were purchased from Jackson Laboratory (Bar Harbor, ME). Gli1LacZ/+ [51] mouse strain was a kind gift from Dr Philip Beachy (Stanford University). Compound strains were generated through cross-breeding. For all animal experiments, mice were randomly selected to the experimental groups. Sample size for time point and survival studies included at least five mice per treatment arm except where noted in the figure legends. Numbers of mice used in the studies are given in the corresponding figure legends. Investigators were not blinded to the treatment groups.
Infection and treatment of mice
Adenovirus-expressing cre recombinase (Ad5-CMV-Cre) was purchased from Vector Development Laboratory (Baylor College of Medicine, Houston). Six-to-ten-week-old mice were infected by intranasal instillation with 3 × 108 pfu per mouse as described previously [82] to initiate lung tumorigenesis. For the in vivo CRISPR experiments, 10–14-week-old KrasLox-Stop-Lox-G12D/+; Trp53fl/fl;Rosa26LSL-fLuc/+ (KPLuc) mice were infected with 5 × 104 ifu of lentivirus containing pSECC-Ihh or pSECC-GFP via intratracheal administration as described previously [82]. KP or KP;Rosa26Lox-mtdTomato-Stop-Lox-mGFP/+ (KPmTmG) mice were treated with 5E1 or IgG1 10 mg/kg intraperitoneally (i.p.) twice per week starting 2 or 6 weeks after adeno-cre infection. For NAC study, KP mice were infected with adeno-cre then treated with NAC 200 mg/kg i.p. on days 12 and 13 after adeno-cre infection. Afterward, NAC 1 g/L (pH = 7.4) was provided in the drinking water. Supplemented drinking water was changed every 2–3 days for the duration of study.
Lung tissue extraction and processing
Mice were anesthetized with Avertin 25 mg/kg i.p., lungs perfused with ice-cold PBS, inflated with ice-cold 4% Paraformaldehyde (PFA) in PBS by intra-tracheal instillation, then fixed in 4% PFA at 4 °C for 24 h. Tissue processing and paraffin embedding were performed by Tissue Management Core Facility or Histo-Pathology Core Facility at UTSW. Frozen lung tissue blocks were made by inflating lungs with 50% (v/v) OCT (Tissue-Tek) in PBS and embedded in cryomold with 100% OCT on dry ice, and stored in −80 °C. Five and fifteen micron thick sections were made from each PFA fixed paraffin-embedded and frozen tissue blocks, respectively, and subjected to hematoxylin and eosin (H&E) or IHC staining. Brightfield images were taken using a Nikon Eclipse E800 or Hamamatsu Nanozoomer in Whole Brain Microscopy Facility (UTSW). Tumor area on H&E stained images were measured using NIS Elements (Nikon) or Fiji imaging software. The fraction of IHC positive nuclei in each tumor was estimated using ImageJ or Fiji as described in Supplemental material and methods. Images of Immunofluorescence stained sections were taken by Nikon Eclipse TE2000-U.
Immunohistochemistry (IHC)
Heat-mediated antigen retrieval (citrate buffer, pH 6) was used for tissue sections from paraffin-embedded blocks. Samples were blocked with goat (Sigma) or donkey serum (Sigma) for 1 h and diluted primary antibodies were applied overnight at 4 oC. Vectastain ABC (Vector Labs) with DAB substrate (Vector Labs) was used for staining according to the manufacturer’s instructions. The following primary antibodies were used: Ser139-p-Histone H2A.X (1:1,000; Cell Signaling Technology, 9718), CD31 (1:500, Cell Signaling Technology, 77,699), β-Galactosidase (1:20,000, abcam, ab9361), PDGFRα (Cell Signaling Technology, 3174), αSMA (1:500, Bio Care Medical, CM001A), and E-Cadherin (1:400, Cell Signaling Technology, 3195).
RNA in situ hybridization method (RNAScope)
Murine samples
Five micrometer sections from paraffin embedded lungs were deparaffinaized, fixed in 10% formalin solution at room temperature for 24 h and then subjected to RNAscope assay using RNAscope 2.0 HD Reagent Kit-Red (Advanced Cell Diagnostics (ACD, 310034) and following manufacturer instructions. Mm-Ihh-noXHs (413091) and Mm-Shh (314361) probes were used for murine Ihh and Shh mRNA detection, respectively. Dapb (negative control, 310043) and PPIB (positive control, 313911) were used for quality control (data not shown).
Human Samples
Use of human samples for research purposes was approved by the Institutional Review Board at M.D. Anderson Cancer Center. Consent was obtained from patients for use of their samples for research purposes. Please see Supplementary methods for full details of methods. Briefly, in situ hydbridization was performed on an automated Leica Bond RX autostainer (Leica Biosystems, Nussloch, GmbH). LS 2.5 Probe- Hs-IHH probe (472388, ACD) was used. RNA expression of IHH was scored using a semi-quantitative scoring system as follows: 0: no staining or <1 dot/10 cells; 1+: 1–3 dots/cell; 2+: 4–9 dots per cell, None or very few dot clusters; 3+: 10–15 dots/ cell and <10% dots are in clusters; 4+: >15 dots/cell and >10% dots are in clusters. Positive (PPIB, Hs-PPIB, 313908) and negative (Dapb, Hs-PPIB, 312038) control probes were also evaluated, dapB score of <1 and PPIB score ≥2 with relatively uniform PPIB signals throughout the sample were considered adequate for analysis (data not shown).
Histology analysis
H&E stained lungs with tumors from KP mice were examined. The pathologist was blinded to the conditions of the experiment. As nearly all tumors <0.5 mm were well-differentiated histology, only tumors ≥0.5 mm were examined. Tumors were graded as poor, moderate or well differentiated cancers.
Digestion of lung tissue and FACS-sort of lung epithelial cells
Single cell suspensions of whole lungs were prepared as described previously [83]. For FACS, single cell suspensions were incubated with eBioscience Fixable Viability Dye eFluor™ 780 (Invitrogen) and the following antibodies (0.6 μg per 107 cells): PerCP-Cy5.5 Rat Anti-Mouse CD45 (BD Pharmingen, 550994), PE-Cy7 Rat Anti-Mouse CD31 (BD Pharmingen, 561410), and Brilliant Violet 421 anti-mouse CD326 (Ep-CAM) (BioLegend, 118225) on ice for 45 min, and then subjected to FACS-sorting using FACS Aria II (BD Biosciences) at the Moody Foundation Flow Cytometry Core Facility at the Children’s Research Institute at UTSW. Flow cytometry data were analyzed with FlowJo v10.
Statistical analysis
GraphPad Prism 7 software was used to generate the graphs and for statistical analysis. Unpaired, two-sided Student’s t-test was used for comparison of 2 groups. Mantel-Cox log-rank test was used for statistical significance of murine survival curves. Univariate Cox regression analysis was performed to calculate hazard ratio and log-rank P values per KM-Plotter [36] (http://kmplot.com/analysis/) for the human LAD Kaplan–Meier curves.
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Acknowledgements
We thank Dr John D. Minna for valuable discussions, Drs Rolf Brekken and David Wang for their helpful comments on the manuscript, Nicolas Loof, Kim Nguyen, and Terry Shih of the Moody Foundation Flow Cytometry Core Facility for assistance with FACS, and Denise Ramirez of the Whole Brain Microscopy Facility. We also thank John Shelton at UTSW HistoPathology Core and Dr Cheryl Lewis at UTSW Tissue Management Core for assistance with tissue processing and embedding. This work was supported in part by the National Cancer Institute (P50CA70907: JK; R01CA196851: JK; R21 CA208746: J-WK), National Heart, Lung, and Blood Institute (5T32HL098040 to SK), American Cancer Society (RSG-16-090-01-TBG: JK), American Lung Association (LCD-400239: J-WK), Sidney Kimmel Foundation for Cancer Research (SKF-14-057: JK), Lung Cancer Research Foundation (JK) and Bonnie J. Addario Lung Cancer Foundation (J.K.).
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Kasiri, S., Chen, B., Wilson, A.N. et al. Stromal Hedgehog pathway activation by IHH suppresses lung adenocarcinoma growth and metastasis by limiting reactive oxygen species. Oncogene 39, 3258–3275 (2020). https://doi.org/10.1038/s41388-020-1224-5
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DOI: https://doi.org/10.1038/s41388-020-1224-5
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