Abstract
Given the long-term ineffectiveness of current therapies and late-stage diagnoses, lung cancer is a leading cause of malignant diseases. Tumor progression is influenced by cancer cell interactions with the tumor microenvironment (TME). Insulin-like growth factor 1 receptor (IGF1R) was reported to affect the TME; however, the role of IGF1R in lung TME has not been investigated. First, we assessed IGF1R genomic alterations and expression in NSCLC patient tissue samples, as well as IGF1R serum levels. Next, we performed tumor heterotopic transplantation and pulmonary metastases in IGF1R-deficient mice using melanoma and Lewis lung carcinoma (LLC) cells. Herein we report increased amplification and mRNA expression, as well as increased protein expression (IGF1R/p-IGF1R) and IGF1R levels in tumor samples and serum from NSCLC patients, respectively. Moreover, IGF1R deficiency in mice reduced tumor growth, proliferation, inflammation and vascularization, and increased apoptosis after tumor heterotopic transplantation. Following induction of lung metastasis, IGF1R-deficient lungs also demonstrated a reduced tumor burden, and decreased expression of tumor progression markers, p-IGF1R and p-ERK1/2. Additionally, IGF1R-deficient lungs showed increased apoptosis and diminished proliferation, vascularization, EMT and fibrosis, along with attenuated inflammation and immunosuppression. Accordingly, IGF1R deficiency decreased expression of p-IGF1R in blood vessels, fibroblasts, tumor-associated macrophages and FOXP3+ tumor-infiltrating lymphocytes. Our results demonstrate that IGF1R promotes metastatic tumor initiation and progression in lung TME. Furthermore, our research indicates that IGF1R could be a potential biomarker for early prediction of drug response and clinical evolution in NSCLC patients.
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Introduction
Lung cancer is a leading cause of malignant diseases and the most common cause of cancer-related death worldwide with a 5-year survival rate of about 21% [1, 2]. The predominant lung cancer subtype, non-small-cell lung cancer (NSCLC), accounts for 80% of lung cancer-associated deaths, and about 70% of patients have locally advanced or metastatic disease at the time of diagnosis. Moreover, the lung is one of the most common sites for cancer metastases. Distant tumor metastasis to the lung changes staging, clinical prognosis and treatment options of the original tumor and severely decreases survival rate [3,4,5].
Tumor masses consist of a heterogeneous population of cancer cells and a variety of resident and infiltrating host cells, secreted factors, and extracellular matrix proteins, collectively known as the tumor microenvironment (TME). Among others, tissue-resident and peripherally recruited immune cells, fibroblasts, and endothelial cells are key elements within the TME. Tumor progression is profoundly influenced by cancer cells interactions with the TME, which ultimately determine whether the primary tumor is eradicated, metastasizes, or establishes dormant micrometastases. Moreover, tumor metastasis requires the development of a pre-metastatic niche suitable for a subpopulation of tumor cells to colonize and develop into metastases with their own TME. Since the TME can also shape therapeutic responses and resistance, a deeper understanding of TME characteristics and function is required for developing new strategies for targeting its components in patients with primary and metastatic tumors [6,7,8].
The insulin-like growth factor 1 receptor (IGF1R) is a ubiquitously expressed membrane-bound tyrosine kinase receptor that recognizes its two major ligands IGF1 and IGF2, and controls multiple essential cellular functions [9]. IGF activity is highly relevant in several chronic lung pathologies, including lung cancer [10,11,12]. IGF1R signaling has been profusely implicated as a critical contributor to cancer cell proliferation, survival, migration, and resistance to anticancer therapies, thus targeting IGF signaling is an attractive therapeutic strategy. In this regard, IGF1R is currently being evaluated as a pharmacological target in clinical trials for oncologic patients, including NSCLC [13, 14]. However, the role IGF1R plays in implantation and progression of lung metastases in the TME has not been evaluated in the context of NSCLC. The Lewis lung carcinoma (LLC) model is the only reproducible syngeneic model for NSCLC [15]. Here, we studied the implication of IGF1R as a cancer-promoting factor in the TME by analyzing tumor samples from NSCLC patients, and generating LLC models by performing heterotopic transplantation or pulmonary metastasis in the context of IGF1R deficiency.
Results
Increased IGF1R amplification and mRNA expression, as well as upregulation of IGF1R protein expression in tumor samples and serum in NSCLC patients
To explore genomic alterations and mRNA expression of IGF1R in patients with NSCLC, we used the cBio Cancer Genomics Portal (cBioPortal). Overall, data obtained from different studies included in the cBioPortal cancer database, showed an increased IGF1R amplification frequency with an average of 1.385%. In addition, copy number values and mRNA expression were significantly increased in tissue samples from NSCLC patients in which IGF1R was found amplified with respect to diploid tissue. We also observed that the increase of IGF1R mRNA expression correlated with copy number values (Pearson´s correlation coefficient, r = 0.4603, p = 0.0157) (Fig. 1A and Supplementary Table 1). To complement this data IGF1R was assessed in tissue samples and serum from our own NSCLC patient cohort. We show that the increase of p-IGF1R expression in tumoral lung tissues correlated with proliferation (Ki67), macrophage (Iba1) and tumor-associated macrophage, TAMs (CD68) presence (Pearson´s correlation coefficient, r = 0.5906, p = 0.0013; r = 0.4012, p = 0.015; and r = 0.6257, p = 0.0341, respectively) (Fig. 1B). We also report overexpression of both IGF1R and p-IGF1R, although this increase was more evident in the case of p-IGF1R in peritumoral lung tissue from NSCLC patients, corresponding to accumulations of infiltrated immune cells (Fig. 1C). Finally, serum IGF1R protein levels evaluated by ELISA revealed a significant increase in NSCLC patients compared to healthy controls (Fig. 1D).
IGF1R deficiency reduces tumor growth, proliferation, inflammation and vascularization, and increases apoptosis after tumor heterotopic transplantation
Since IGF1R has been implicated in the pathogenesis of lung cancer by facilitating metastasis, tumor-associated inflammation and immune checkpoint regulation [12, 16], we decided to assess whether IGF1R deficiency in the TME delays implantation and progression in a heterotopic LLC mouse model. For that purpose, UBC-CreERT2;Igf1rfl/fl and Igf1rfl/fl female mice were treated with TMX to induce Igf1r gene deletion. Then, mice were subcutaneously injected with LLC cells, and follow-up of LLC engraftments was performed for 14 days to assess the tumor volume as detailed in Fig. 2A. LLC cell tumorigenic capacity was evaluated by measuring the heterotopic tumor volume, which was lower in IGF1R deficient (CreERT2) vs. Igf1rfl/fl mice (Fig. 2B). Next, we assessed p-IGF1R by immunofluoresce and ELISA in sections and homogenates of heterotopic tumors. Notably, the apparent reduction of p-IGF1R in heterotopic tumors from IGF1R deficient mice was reflected in reduced p-IGF1R protein levels measured by ELISA (Fig. 2C, D). On the other hand, delayed tumor growth observed in CreERT2 mice is supported by reduced proliferation (Ki67+ cells) and vascularization (CD31+ area), as well as increased apoptosis (C3+ cells) (Fig. 2E). In addition, heterotopic tumors from CreERT2 mice showed diminished inflammation demonstrated by reduced presence of total leukocytes (CD45+ area), TAMs (CD68+ area), neutrophils (MPO+ cells), tumor-infiltrating lymphocytes, TILs (FOXP3+), as well as T regulatory cells, Tregs (FOXP3+CD4+ cells). Conversely, CD4+ TILs were found increased in heterotopic tumors from CreERT2 mice (Fig. 2F). Overall, these results indicate that IGF1R deficiency has an antitumoral effect on the lung TME.
IGF1R deficiency depletes peripheral monocytes, bone marrow neutrophils and leukocyte counts in BALF, and attenuates the increase of serum IL6 and TNFα levels after experimental pulmonary metastasis
To determine the effect of IGF1R deficiency on key components of the lung TME, we performed an experimental pulmonary metastasis model. UBC-CreERT2;Igf1rfl/fl and Igf1rfl/fl female mice were treated with TMX to induce Igf1r gene deletion (CreERT2 mice). Then, mice were intravenously injected with LLC cells in PBS or equal volume of PBS (Fig. 3A). IL6 and TNFα serum levels demonstrated a clear induction in LLC-challenged Igf1rfl/fl mice, while both remained unaltered in CreERT2 mice (Fig. 3B). The proportion of circulating neutrophils and monocytes exhibited a marked increase in LLC-challenged Igf1rfl/fl mice, and while the proportion of neutrophils remained high, monocyte counts did not change in CreERT2 mice after LLC challenge. In contrast, we observed a significant reduction in the proportion of lymphocytes in LLC-challenged mice, and this reduction was lower in CreERT2 mice. Circulating levels of eosinophils did not change between experimental groups (Fig. 3C, D). On the other hand, a significant increase in total cell numbers and neutrophil counts was observed in bone marrow of Igf1rfl/fl mice after LLC challenge, an increase that was not significant in LLC-challenged IGF1R-deficient mice (Fig. 3C, E). Moreover, total and differential BALF cell counts for neutrophils, macrophages and lymphocytes were found elevated in LLC-challenged Igf1rfl/fl mice, while this increase was less pronounced in CreERT2 mice. Total protein concentration in BALF was significantly increased in LLC-challenged Igf1rfl/fl mice but remained unaltered in CreERT2 mice upon LLC challenge (Fig. 3C, F).
As a complement to the LLC experimental pulmonary metastasis model, we generated an additional mouse model: B16-F10 (melanoma) cells were intravenously injected in IGF1R-deficient (CreERT2) and Igf1rfl/fl mice to induce lung metastasis (Supplementary Fig. 1A). As noted in the LLC model, TNFα levels in both serum and lung homogenates also demonstrated a clear induction in B16-F10-challenged Igf1rfl/fl mice, remaining unaltered in CreERT2 mice (Supplementary Fig. 1B). Accordingly, total and differential BALF cell counts for macrophages and lymphocytes, as well as total protein concentration in BALF were found elevated in B16-F10-challenged Igf1rfl/fl mice, but not in CreERT2 mice as shown in the LLC model. Neutrophil counts in BALF did not show any significant changes between groups, unlike in the LLC model (Supplementary Fig. 1C, D).
Reduced tumor burden and decreased expression of metastasis markers, p-IGF1R and p-ERK1/2, as well as changes in IGF system gene expression in lungs of IGF1R-deficient mice
To evaluate the effect of IGF1R depletion on LLC metastasis, tumor burden, metastasis markers, p-IGF1R, p-ERK1/2 and IGF system gene expression were assessed in lungs of IGF1R-deficient (CreERT2) mice vs. controls. After LLC experimental pulmonary metastasis, CreERT2 mice exhibited decreased lung tumor foci and area with respect to Igf1rfl/fl mice (Fig. 4A). A similar result was found in mice challenged with B16-F10 cells (Supplementary Fig. 1E). mRNA expression of Mmp9, Egfr and Hmox1 (tumor progression), Timp1 and Timp2 (inhibitors of metalloproteinases) and Hif1α (hypoxia) evaluated in lung homogenates was significantly augmented in LLC-challenged Igf1rfl/fl mice, remaining unaltered in CreERT2 mice. Conversely, Mmp2 (tumor progression) and Timp3 (inhibitor of metalloproteinases) mRNA expression was significantly repressed after LLC challenge in Igf1rfl/fl mice, while this repression was milder in CreERT2 mice (Fig. 4B). Accordingly, MMP9 levels quantified by ELISA in lung homogenates mirrored its mRNA expression profile (Fig. 4C). Regarding IGF system gene expression, Igf1r mRNA expression increased significantly in Igf1rfl/fl mice upon experimental pulmonary metastasis, showing an efficient depletion in PBS- and LLC-challenged CreERT2 mice, as expected due to tamoxifen-mediated Igr1r gene depletion. Insulin receptor (Insr) mRNA levels did not change between experimental groups. In contrast, Igf1 mRNA levels showed significantly increased levels in both CreERT2 experimental groups indicating IGF1 resistance to the IGF1R-defiency condition. Surprisingly, a significant reduction in Igf1 mRNA levels was noticed in Igf1rfl/fl mice upon experimental pulmonary metastasis. Notably, mRNA expression of Igfbp genes Igfbp2, Igfbp3 and Igfbp5 was found significantly depleted, and Igfbp4 levels significantly increased upon LLC challenge only in Igf1rfl/fl mice. Specifically, Igfbp6 expression was slightly increased within LLC experimental groups (Fig. 4D). p-IGF1R levels assessed by ELISA in lung homogenates showed a significant increase in Igf1rfl/fl mice after experimental pulmonary metastasis, but were reduced in IGF1R-deficient PBS- and LLC-challenged mice. On the other hand, p-IGF1R and p-ERK1/2, assessed by immunohistochemistry in metastatic tumors, demonstrated smaller stained areas in LLC-challenged CreERT2 mice (Fig. 4E).
IGF1R deficiency decreases proliferation, DNA damage, senescence, and vascularization, attenuates tumor invasion by reduced EMT and fibrosis, and induces apoptosis upon pulmonary metastasis
To determine the effect of IGF1R deficiency in the metastatic TME, we immunostained lung tumors of LLC-challenged mice for the following markers: Ki67 (proliferation), 53BP1 (DNA damage), p21 (senescence), C3 (apoptosis), CD31 and CD34 (vascularization), SOX9 (epithelial-mesenchymal transition, EMT), as well as Vimentin, Fibronectin, SMA and Masson (fibrosis). All markers showed decreased expression in LLC-challenged IGF1R-deficient CreERT2 mice, except for C3 whose expression was found to be significantly increased (Fig. 5A, B, D). In accordance, quantification of immunostains for Ki67, CD31, Vimentin and SMA were also found decreased in B16-F10-challenged CreERT2 mice with respect to Igf1rfl/fl (Supplementary Fig. 1F). Moreover, to determine how the lack of IGF1R in the lung TME is mechanistically affecting tumor growth and metastasis, we performed double fluorescence immunostainings of p-IGF1R with CD31 (vascularization), Vimentin (fibroblast presence) and SMA (fibroblast activation) in lung sections from LLC-challenged mice. In this regard, representative immunostainings indicated a reduction of p-IGF1R expression in blood vessels and fibroblasts (Fig. 5C, E, F). To complement these data, we also assessed mRNA expression of Ccl12 (recruitment of fibrocytes), Tgfβ and E-cadherin (EMT) markers in lung homogenates. Concerning EMT and fibrosis, lung mRNA levels of Ccl12 and Tgfβ were found significantly increased in LLC-challenged Igf1rfl/fl mice, remaining unaltered in CreERT2 mice. In contrast, E-cadherin mRNA expression was highly attenuated in Igf1rfl/fl mice upon experimental pulmonary metastasis, while this reduction was milder in CreERT2 mice (Fig. 6A).
IGF1R depletion diminishes inflammation and attenuates lung tumor immunosuppression
To evaluate the impact of IGF1R deficiency on lung inflammation and immunosuppression, total mRNA expression and protein levels of related markers were assessed on lung homogenates by qPCR and ELISA, as well as by immunostaining (Fig. 6B, C). Interestingly, mRNA levels of Il1β, Ifnγ, Cxcl1, Mpo, Ccl2, Cd68, Cd163, Cd80, Cd86, Pdcd1 and Il10 were strongly induced after experimental pulmonary metastasis in Igf1rfl/fl mice, remaining unaltered in IGF1R-deficient mice (Fig. 6B). Exceptionally, Tnfα and Foxp3 markers were found slightly augmented, and Cd4 and Cd8a strongly reduced in Igf1rfl/fl mice upon LLC challenge. Accordingly, TNFα, PDCD1 (PD-1) and IL10 protein levels were significantly increased in Igf1rfl/fl mice upon LLC challenge, while this increase was milder in CreERT2 mice (Fig. 6C).
To reinforce these data, we also performed immunostainings for Iba1 (macrophages), CD68 (TAMs), FOXP3, CD4 and CD8 (TILs), as well as double immunostainings for FOXP3 and CD4 (Tregs) in lung sections from LLC-challenged mice. We observed a decreased presence of Iba1, CD68, FOXP3 and double FOXP3-CD4 positive cells, along with an increased number of CD4 and CD8 positive cells in LLC-challenged CreERT2 mice (Fig. 7A). Similarly, we also consistently found a decreased presence of Iba1+ macrophages in B16-F10 metastatic tumors from CreERT2 mice (Supplementary Fig. 1G). In addition, to determine how the lack of IGF1R in the lung TME is conditioning tumor growth and metastasis, we performed double fluorescence immunostainings of p-IGF1R with CD68 (TAMs) and FOXP3 (FOXP3+ TILs) in lung sections from LLC-challenged mice. In this regard, representative immunostainings indicated an apparent reduction of p-IGF1R expression in TAMs and FOXP3+ TILs (Fig. 7B, C). Altogether, our findings suggest that IGF1R depletion in the lung TME of IGF1R-deficient mice delays lung metastasis implantation and progression by reducing the presence of blood vessels, fibroblasts, TAMs and FOXP3+ TILs, as well as by increasing the amount of infiltrating CD4+ and CD8+ T cells (Fig. 7D).
Discussion
We aimed to determine how IGF1R deficiency acts in the lung tumor microenvironment (TME) conditioning metastatic tumor implantation and progression, by generating LLC models using heterotopic transplantation or pulmonary metastasis in the context of IGF1R deficiency. We also explored genomic alterations of IGF1R in patients with NSCLC, as well as IGF1R protein expression and levels in tissue samples and serum from NSCLC patients.
We found increased serum IGF1R levels in our NSCLC patient cohort. IGF1R was previously found in serum and plasma exosomes [17, 18], and recently identified as a novel plasma biomarker to predict mortality in COVID-19 patients [19]. Thus, IGF-1R could be a candidate serum biomarker for the NSCLC diagnosis. We also report IGF1R overexpression in NSCLC patient lung tissues, in accordance with previous reports where its upregulation was associated with reduced disease-free survival [12, 16]. Accordingly, data obtained from cBioPortal cancer database showed increased gene amplification frequency, mRNA expression and copy number values of IGF1R in NSCLC patient tissue samples.
Since the Lewis lung carcinoma (LLC) model is the only reproducible syngeneic model for NSCLC [15], we deemed it is appropriate for determining the effect of IGF1R deficiency on key components of the TME, not only using an experimental pulmonary metastasis model but also upon heterotopic syngeneic transplantation. LLC primary tumors generated in IGF1R-deficient mice showed delayed tumor implantation and progression. Overall, these results indicate that IGF1R deficiency could have an antitumoral effect on the lung TME. After experimental pulmonary metastasis, IGF1R-deficient mice exhibited reduced tumor implantation in both LLC and melanoma models, as similarly observed upon heterotopic syngeneic transplantation. CreERT2 mice also showed decreased total protein concentration in BALF, an indicator of reduced vascular permeability, as reported in an additional IGF1R-deficient mouse line [20], which supports diminished presence of inflammatory cells in the lung. In this regard, CreERT2 mice were reported to confer resistance to initiation of the inflammatory response [21,22,23]. In addition, IGF1/IGF1R signaling in the TME was found to be critical for medulloblastoma growth [24]. Furthermore, peripheral IL6 and TNFα levels were found reduced in CreERT2 mice upon induction of LLC metastasis. Thus, elevated serum IL6 and TNFα levels were found associated with tumor recurrence in NSCLC patients [25].
LLC-challenged IGF1R-deficient mice exhibited unchanged lung mRNA expression of Mmp9, Egfr, Hmox1, Hif1-α, Timp1, Timp2 and Timp3. MMP-9 was reported to promote LLC cell invasiveness and pulmonary metastasis, and was found overexpressed NSCLC patients [26, 27]. Of relevance, EGFR increased in NSCLC patients, and MMP9 and EGFR co-expression was associated with a poor prognosis [28, 29]. Moreover, HMOX1/HO-1 (heme oxygenase 1) was reported to promote lung metastasis in mice, and its high expression was correlated with tumor invasiveness in NSCLC, as similarly reported for HIF-1α [30,31,32]. In addition, TIMP1 overexpression or TIMP3 silencing have been linked to cancer progression and poor prognosis in NSCLC [33]. The unexpected reduction of Mmp2 mRNA expression observed in LLC-challenged Igf1rfl/fl mice does not correlate with MMP2 overexpression reported in NSCLC patients [34]. It should be noted that differences in mRNA expression patterns between Mmp9 and Mmp2 upon LLC challenge observed in IGF1R-deficient mice could be related to their distinct functional implication in this context, since MMP9 but not MMP2 was reported to promote LLC tumorigenesis [26].
As expected, LLC-challenged IGF1R-deficient mice exhibited counteracted IGF1R phosphorylation (p-IGF1R) and diminished p-ERK1/2 levels. Accordingly, IGF1R has been reported to contribute to the pathogenesis of lung cancer, as it is commonly overexpressed in NSCLC patients [12, 16]. On the other hand, p-ERK1/2 is a major IGF1R MAP kinase signaling mediator that was extensively reported to be activated in NSCLC and associated with tumor cell proliferation [35, 36]. Intriguingly, we found unchanged lung mRNA expression of Insr in all experimental groups, as well as reduced Igf1 expression in Igf1rfl/fl LLC-challenged mice. Of note, Insr expression was found upregulated in mouse lungs with compromised IGF1R signaling [21,22,23, 37], and IGF1 expression by the TME was reported to have a supportive role in tumor initiation and progression [16, 24]. These discrepancies could be due to differential transcriptional and post-transcriptional regulation of Insr and Igf1 between different mouse models or consequence of the complex interactions and regulation between the insulin and IGF system components. Noteworthy, Igf1 expression was found increased in PBS and LLC-challenge IGF1R deficient mice with respect to Igf1rfl/fl mice. These results indicate that IGF1R deficiency itself confers IGF1 resistance. Accordingly, we have previously reported a similar Igf1 mRNA expression profile in IGF1R deficient mice [22], and Moody et al. have reported increased circulating levels of IGF1 after IGF1R blockade [38]. We think that discrepancies between increased Igf1 expression and resistance to devolvement of LLC in IGF1R-deficient mice could also be due to differential transcriptional regulation of Igf1. Specifically, in pancreatic and breast cancer models, macrophages and fibroblasts were shown to be the main producers of IGF1, supporting drug resistance and metastasis of cancer cells [39, 40]. Here we show that IGF1R deficiency in mice reduced p-IGF1R expression in blood vessels, fibroblasts, TAMs and Tregs, supporting reduced metastasis observed in IGF1R deficient mice. Our results demonstrate that p-IGF1R expression is apparently reduced in the lung TME of IGF1R-deficient mice, suggestive of a functionally “weak” TME, contributing to a reduced lung metastasis implantation and progression. Accordingly, inactivation of IGF1R was recently reported to delay tumor progression [24]. Even though Igfbp2, Igfbp3 and Igfbp5 expression was reduced, and in the case of Igfbp4 increased upon LLC challenge, IGF1R deficiency maintained its levels unchanged. Moreover, Igfbp6 expression was found slightly incremented upon LLC challenge in both genotypes. Concerning IGFBPs, we have previously reported that IGFBP2-6 are highly expressed at the transcriptional level in lungs of young mice [37]. Specifically, we previously reported similar expression profiles showing transcriptional repression of Igfbp3 and Igfbp5 after different challenges in IGF1R-deficient lungs [21,22,23, 37]. It should be noted that due to its complex regulation at different levels, IGFBPs were described to promote or suppress tumor growth in various tissues and contexts [41]. Specifically, IGFBP3 was reported to inhibit tumorigenesis and cell growth, and IGFBP5 was suggested to function as a tumor suppressor [42,43,44,45]. Conversely, IGFBP4 overexpression was found adversely associated with the prognosis of lung cancer patients [46]. On the other hand, the role of both IGFBP2 and IGFBP6 in cancer remains less clearly understood [41].
Interestingly, after LLC-challenge, IGF1R deficient mice showed increased apoptosis. Accordingly, IGF1R signaling was reported to protect tumor cells from apoptosis [47]. Moreover, IGF1R deficiency also reduced proliferation, DNA damage, senescence, vascularization, EMT and fibrosis in the lung TME, most of which are considered cancer hallmarks [6]. Remarkably, increased DNA damage was found associated with NSCLC development. Assessment of undifferentiated (CD31+) and differentiated (CD34+) blood vessels are important prognostic factors in advanced NSCLC [48,49,50]. EMT, a key indicator of early stage NSCLC, was reported to promote tumor growth and invasion, and was associated with increased IGF1R expression [51]. EMT is manifested by the loss of E-cadherin and increased expression of Vimentin and SOX9, thus promoting tumor invasion [52, 53]. Accordingly, these markers were found counteracted in CreERT2 mice after LCC challenge. Furthermore, IGF1R deficiency also attenuated TGFβ, an EMT promoter favoring tumor invasion, metastasis, and transdifferentiation of cancer-associated fibroblasts (CAFs). SMA, a classical marker of CAFs, was found reduced in CreERT2 mice, as well as fibronectin that was shown to stimulate NSCLC growth [54,55,56,57].
As expected, LLC-challenged Igf1rfl/fl lungs showed augmented levels of the Il1β, Ifnγ, CD80, CD86, TNFα and IL10 inflammation markers that were consistently counteracted in IGF1R-deficient mice. TNF-α, IL1B, IFN-γ and IL10 were reported to have immunoevasive and T cell exhaustion functions, and to promote tumorigenesis, drug resistance and poor survival in NSCLC [25, 58,59,60]. Moreover, CD80+ and CD86+ dendritic cells present in peritumoral tissues of NSCLC patients were associated with an immature phenotype that favors tumor immune escape [61]. Within the lung TME many cells modulate the antitumor response including CD68+ TAMs, FOXP3+ Tregs, CD4+ helper T cells and CD8+ cytotoxic T cells [62]. Here we demonstrate that IGF1R deficiency decreased the presence of macrophages, TAMs, Tregs and neutrophils, and their respective chemotactic chemokines, as well as increased the presence of CD4+ and CD8+ cells upon LLC induction. The TME of NSCLC contains a large number of TAMs which influence tumor progression and patient prognosis, and specifically, M2 TAMs were shown to induce tumor aggressiveness and proliferation in NSCLC [63, 64]. In this respect, ablation of IGF1R to reduce M2 marker expression in the murine myeloid lineage was reported [65]. Moreover, accumulation of M2 TAMs in solid tumors was associated with hypoxia (HIF1α), IL-10 and TGFβ production [66, 67], as well as cytokines that were found counteracted in the TME of IGF1R- deficient mice. Of note, FOXP3 was reported to promote tumor growth and metastasis by inducing EMT in NSCLC [68]. Moreover, accumulation of CD4+FOXP3+ Tregs was reported to correlate with increasing incidence of lung cancer [69]. Interestingly, expression of Igf1r was found upregulated in Treg cells and IGF1R-deficient Treg cells were reported to express lower levels of FOXP3 [70, 71]. On the other hand, the presence of infiltrating CD8+ and CD4+ T cells is a favorable prognostic factor in NSCLC, since their activation correlates with a stronger antitumor immune response [72, 73]. Specifically, we report counteracted TNFα levels in IGF1R-deficient mice upon LLC challenge. In this regard, blocking of TNFα was shown to enhance CD8 T-cell-dependent immunity, thus favoring accumulation of CD8+ TILs [74, 75]. In addition, CD4 and CD8 immunity in NSCLC patients was reported to be required for clinical responses to PD-1 [76, 77]. PD-1 is a key element within the TME and therefore an important mechanism of tumor-immune resistance, thus PD-1 blockade was proposed as an attractive therapy in NSCLC [62, 78]. Herein we show that LLC-challenged CreERT2 mice exhibited reduced inflammation and attenuated tumor immunosuppression by depleted PD-1 levels. Accordingly, Ajona et al. have recently demonstrated that both genetic and pharmacological inhibition of the IGF-1/IGF-1R axis enhance the antitumor activity of anti-PD-1–PD-L1 antibodies against lung cancer [16]. Of note, this is the first report showing that IGF1R acts in the lung TME sustaining inflammation and tumor-associated immunosuppression.
In summary, our results demonstrate that IGF1R deficiency in the lung TME impairs tumor initiation and progression (proposed mechanism in Fig. 7D). Our research indicates that IGF1R could be a potential biomarker for early prediction of drug response and clinical evolution of NSCLC patients.
Materials and methods
Clinical samples
Genomic data on amplification frequency, mRNA expression and copy number values of IGF1R in tissue samples from NSCLC patients were obtained from the cBio Cancer Genomics Portal (cBioPortal) (http://www.cbioportal.org). Formalin-fixed paraffin-embedded lung cancer tissues from 14 NSCLC patients were obtained from the San Pedro Hospital (Logroño, Spain). Serum samples from 24 NSCLC patients and matched controls were obtained from the Fundación Jimenez Díaz Hospital (Madrid, Spain). All patients provided written informed consent for participation in the study. Serum IGF1R levels were measured using human IGF1R ELISA kit. For additional details, see supplementary information.
Cell lines and culture conditions
LLC/1 (Lewis Lung Carcinoma) and B16-F10 (Melanoma) cell lines were cultured following the American Type Culture Collection (http://www.atcc.org) recommendations and standard methods. For additional details, see supplementary information.
Mice and ethical statement
For experimental purposes, UBC-Cre-ERT2;Igf1rfl/fl mice were crossed with Igf1rfl/fl mice to directly generate descendants in equal proportions in the same litter. Tamoxifen (TMX) was administered daily for five consecutive days to four-week-old mice of both genotypes to induce a postnatal Igf1r gene conditional deletion [79].
All experiments and animal procedures were carried out in accordance with the European Communities Council Directive guidelines (86/609/EEC) and were revised and approved by the CEAA/CIBIR (Gobierno de La Rioja) Bioethics Committee (refs. JGP02_1, JGP02_7 and JGP02_9). For additional details, see supplementary information.
Heterotopic syngeneic transplantation
Nine- to 10 week-old (W9-10) female mice of both genotypes (Igf1rfl/fl and UBC-Cre-ERT2; Igf1rfl/fl (CreERT2)) were subcutaneously injected in shaved flanks with 1 × 106 Lewis Lung Carcinoma (LLC) cells in PBS (100 µl) or equal volume PBS at day (D) 0, under light isoflurane anesthesia. LLC engraftments were allowed to grow for 14 days (D14). Tumor size was measured with a caliper on alternate days. Tumor volumes were determined using the formula: volume = (width2 × length) × 0.50 [80], and their weight assessed at D14. Mice were euthanized by intraperitoneal injection of 10 μL/g of a ketamine-xylazine anesthetic combination in saline (300:30 mg/kg, respectively). Resected tumors were fixed by inflation with 4% formaldehyde for 8–10 h and embedded in paraffin for immunohistochemistry.
Experimental pulmonary metastasis
Ten- to 12 week-old (W10-12) female mice of both genotypes (Igf1rfl/fl and UBC-Cre-ERT2;Igf1rfl/fl (CreERT2)) were injected through the lateral tail vein with 1 ×106 LLC or B16-F10 cells in PBS (100 µL) or equal volume PBS at D0 under light isoflurane anesthesia.
Sample collection and preparation
Animals were euthanized using 10 μL/g ketamine-xylazine. Blood was then collected, and lungs were lavaged with PBS. Right lung lobes were dissected and snap frozen for quantitative PCR (qPCR) and ELISA analyses, and left lung lobes were harvested for histopathological evaluation or immunohistochemistry. Femurs were dissected to isolate bone marrow. For additional details, see supplementary information.
Quantification of blood, BALF and bone marrow cells
Total cell number was counted and expressed as cells/mL in BALF and BM, and as a percentage in peripheral blood. Cells were determined to be macrophages, lymphocytes and neutrophils using standard morphology criteria [81]. For additional details, see supplementary information.
Histopathological and immunostaining analysis
Hematoxylin and eosin (H&E) staining was performed to quantify the number of surface metastases and to evaluate lung tumor area. Masson´s trichrome staining was for quantifying collagen deposition. IGF1R, CD45, p-IGF1R, p-ERK1/2 (p-42/44), Ki67, CD31, CD34, Vimentin, Fibronectin, SMA and CD68 antibodies were used to evaluate IGF1R+, CD45+, p-IGF1R+, p-ERK1/2+ (p-42/44), Ki67+, CD31+, CD34+, Vimentin+, Fibronectin+, SMA+ and CD68+ areas. 53BP1, C3, p21, SOX9, Iba1, FOXP3 and CD4 antibodies were used to determine the number of 53BP1+, C3+, p21+, SOX9+, Iba1+, FOXP3+ and CD4+ cells. For additional details, see supplementary information.
RNA isolation, reverse transcription, and qPCR
Inferior right lung lobes were homogenized in TRIzol, and RNA was isolated and reverse-transcribed to cDNA. cDNA samples were amplified by qPCR for each primer pair assayed (Supplementary Table 2). Results were normalized using the 18 S rRNA gene (Rn18s). For additional details, see supplementary information.
Mouse ELISAS
Total serum IL6 and TNFα levels were assessed with mouse ELISA kits. Superior right lung lobes were homogenized in RIPA Buffer. Phospho(p)-IGF1R, MMP9, IL10, TNFα and PD-1 levels were evaluated in homogenized lung tissue lysates using mouse ELISA kits, and normalized to total protein levels. For additional details, see supplementary information.
Statistics
Statistical analyses were carried out using SPSS Statistics Software v21 for Windows (IBM, Armonk, NY). Following a Shapiro-Wilk normality test, the statistical significance was determined using the Mann-Whitney U test or Student´s t-test for comparing two groups. According to the sample distribution, either a one-way ANOVA test or a Kruskal–Wallis test were used and then, the post hoc Dunn–Sidak test was carried out for multiple comparisons. For all analysis, a p value <0.05 was considered statistically significant.
Data availability
Data available on request from the authors.
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Acknowledgements
We are grateful to Drs J. Brüning (University of Cologne, Germany) and E. Brown (U Penn School of Medicine, PA) for providing Igf1rfl/fl and UBC- CreERT2 mouse lines, respectively. We are also grateful to Carmen Guerrero for her experimental advice. EA-A also thanks the Spanish Association Against Cancer (AECC) for the PhD fellowship. This work was supported by grants from the Fundación Rioja Salud (Gobierno de La Rioja, Spain) to JGP and co-funded by the ERDF (European Regional Development Fund), the ESF (European Social Fund), and a donation from Muebles Guerra (La Rioja, Spain; R.I.P.).
Funding
This work was supported by the Spanish MCIN/AEI/https://doi.org/10.13039/501100011033 (Project PGC2018-097397-B-I00), the Fundación Rioja Salud (Gobierno de La Rioja, Spain) (Project 6.FRS-ABC.006), and the European Regional Development and European Social Funds (ERDF/ESF by the European Union) to JGP.
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EA-A, IPL and JGP designed the experiments, GPB, CG, AR, CR-M and IS provided patient tissue samples and serum, SP-H contributed with experimental support, EA-A, IPL and MC performed the experiments, EA-A and JGP analyzed the data and EA-A, SP-H and JGP wrote the manuscript, with input from the rest of authors.
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A written informed consent was received from participants prior to inclusion in the study. The research protocol was approved by the Ethics Committee of Clinical Research of La Rioja (CEICLAR, ref. PI-205), and Fundación Jiménez Díaz Hospital (Madrid, Spain) (CEImJGD, ref. ER_EO180-19_FJD-HGV).
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Alfaro-Arnedo, E., López, I.P., Piñeiro-Hermida, S. et al. IGF1R acts as a cancer-promoting factor in the tumor microenvironment facilitating lung metastasis implantation and progression. Oncogene 41, 3625–3639 (2022). https://doi.org/10.1038/s41388-022-02376-w
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DOI: https://doi.org/10.1038/s41388-022-02376-w
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