Abstract
Background:
Lung cancer is the most life-threatening cancer type worldwide. Treatment options include surgery, radio- and chemotherapy, as well as the use of immunomodulatory antibodies. Interleukin (IL)-10 is an immunosuppressive cytokine involved in tumour immune escape.
Methods:
Immunohistochemistry (IHC) on human lung surgery tissue as well as human tumour cell line cultures, FACS analysis, real-time PCR and experimental lung cancer.
Results:
Here we discovered a positive correlation between IL-10 and IL-10 receptor (IL-10R) expression in the lung with tumour diameter in patients with lung cancer (non-small cell lung cancer), the most life-threatening cancer type worldwide. IL-10 and IL-10R were found induced in cells surrounding the lung tumour cells, and IL-10R was mainly expressed on the surface of Foxp-3+ T-regulatory lymphocytes infiltrating the tumour of these patients where its expression inversely correlated with programmed cell death 1. These findings were confirmed in translational studies. In a human lung adenocarcinoma cell line, IL-10R was found induced under metabolic restrictions present during tumour growth, whereby IL-10 inhibited PDL1 and tumour cell apoptosis.
Conclusions:
These new findings suggest that IL-10 counteracts IFN-γ effects on PD1/PDL1 pathway, resulting in possible resistance of the tumour to anti-PD1/PDL1 immunotherapy.
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Main
Lung cancer is the most common cancer type with the highest cancer-related mortality worldwide (Ferlay et al, 2015). Histologically, it is subgrouped into small cell lung cancer and non-small cell lung cancer (NSCLC), which can be further subgrouped into adenocarcinoma (ADC) and squamous cell carcinoma (SCC). Unfortunately, the frequently late clinical detection going along with high pathological stage and the absence of curative end-stage treatment options results in a low 5 years average survival rate (Naruke et al, 1988; Goldstraw et al, 2007). Current treatments are so far excision, radio- and chemotherapy, as well as the use of immune-modulating antibodies (Besse et al, 2014). For that reason, it is important to investigate key regulators of lung cancer development and progression.
In this context, interleukin (IL)-10, an acid-sensitive homodimeric cytokine, is regarded as a major immunosuppressive, pro-tumoural cytokine. It is a pleiotropic molecule with anti-inflammatory function, regulating autoimmunity, cell proliferation, survival, apoptosis and angiogenesis (Hatanaka et al, 2001), and is mainly secreted by M2-macrophages, Tregs and Th2-cells. In addition, bronchial epithelial cells, which are the initial source of NSCLC, are also capable of releasing IL-10 (Teng et al, 2011; Dennis et al, 2013).
The clinical relevance of IL-10 in NSCLC has been frequently proofed by presenting its pro-tumoural qualities. IL-10 is notably produced by tumour-associated macrophages (TAMs) (Montuenga and Pio, 2007), CD4+ Tregs or even infiltrating CD8+ T-cells and tumour cells themselves (Hatanaka et al, 2000), alhough it has been shown that not only the serum level of IL-10 (Petrovic et al, 2013), but especially the amount of IL-10 released by TAMs is correlating with non-response to anti-tumoural therapy (Zeni et al, 2007; Wang et al, 2011) and that Tregs in NSCLC overexpress IL-10 due to Foxp-3 promoter demethylation (Ke et al, 2016). Finally, incomplete surgery increases the level of IL-10 (Rybojad et al, 2013), which also has the potential to promote metastasis (Zeng et al, 2010). At the cellular basis, IL-10 impairs Th1-cells, antigen-presenting cells (APC) (Huang et al, 1998; Sharma et al, 1999; Coussens and Werb, 2002; Jarnicki et al, 2006) and M1-macrophages (Almatroodi et al, 2016), and in this context programmed death-1 (PD1) is regarded as an excellent marker of T-cell exhaustion (Wherry, 2011; Mandai et al, 2016). However, in addition to the knowledge on the immunosuppressive, pro-tumoural function of IL-10, its function depends on its application (Dennis et al, 2013; Almatroodi et al, 2016; Zhang et al, 2016; Naing et al, 2016a).
Thus, our present study aimed at understanding the role of IL-10-related immune molecular tumour escape regulation mechanisms in NSCLC, to gather new treatment ideas by multilateral investigations on a human cohort of patients.
Materials and methods
Human subjects and study population
This study is performed at the Friedrich-Alexander University Erlangen-Nürnberg, Germany, and was approved by the ethics review board of the University of Erlangen (Re-No: 56_12B; DRKS-ID: DRKS00005376). Patients, who suffered from NSCLC, gave their approval and were enroled in this study. The histological types of lung cancer are classified according to the World Health Organization (2010). The staging of lung cancer was based on the Cancer TNM Staging Manual, formulated by the International Association for the Study of Lung Cancer (2010). Tissue samples are divided into TU (solid tumour tissue) and CTR (tumour-free area, at least 5 cm away from the solid tumour).
IHC of paraffin-embedded tissue sections
Lung tissue samples were fixed in 10% formalin and processed for paraffin embedding. Blocks were sectioned and stained with antibodies for specific target antigens: αIL-10 (Acris, PM1121, Herford, Germany), αIL-10R (Abcam, ab197666, Cambridge, UK), αCD3 (Zytomed, RBK024, Berlin, Germany), αPD1 (Zytomed, 516-18632) and αTTF1 (Dako, M3575, Hamburg, Germany). Stained slides were scanned and digital hole slide images were performed using a digital slide scanner (Scan 150, 3D Histech Ltd, Budapest, Hungary) at the task group on digital pathology at the Institute of Pathology, Friedrich-Alexander-Universität Erlangen-Nürnberg (FAU), Erlangen, Germany. Hole slide images were visualised by the CaseViewer (Version 2.0, 3D Histech Ltd). The immune reactive score (IRS) or the area fraction quantification was analysed with ImageJ software Version 1.46 (Bethesda, MD, USA), open source by Wayne Rasband. The detailed quantification method is described in the supplements.
IHC quantification
The IRS by Remmele and Stegner respects the percentage of coloured cells and the intensity of the particular colour (0–12 points can be scored in total). To perform this quantification, five pictures with a × 20 objective of an Observer D.1 microscope (Zeiss Microscopy GmbH, Jena, Germany) were made of each patient using AxioCAM MR ZEN2 pro software (Zeiss Microscopy GmbH) and analysed as follows:
The area fraction is the quotient between the area (pixel) of coloured cells and all cells of an image (stained and unstained, but no interspace) calculated with ImageJ software (Version 1.46r) after receiving the scanned human arrays of lung tissue from patients suffering from NSCLC and importing the graphical material in case viewer software (Version 2.0, 3D Histech Ltd). These pictures were opened with ImageJ and area measurements were done by using its colour threshold function, customising a detection raster including hue, colour saturation and brightness, which allowed us to mark and measure the cells via analysis function quite accurate. The area fraction multiplied by 100 produces the percentage of stained cells.
Quantitative real-time PCR
Cultured cells were absorbed in peqGOLD RNA Pure (peqLab 30–1010, Erlangen, Germany). Human lung tissue samples were prepared with the help of Precellys (Bertin Technologies, REF KTO3961-1-009.2, Rockville, MD, USA) and Minilys Tissue Homogenizer (Bertin Technologies). RNA was isolated by a modified phenol-chloroform method described in Cold Spring Harbor Laboratory Press, Cold Spring Harbor, NY, USA, 2001 (Kirby, 1956). RNA was transcribed into cDNA by using the RevertAid First Strand cDNA Synthesis Kit (Thermo Scientific, K1621, Erlangen, Germany) according to the manufacturer’s protocol. The following specific genes were measured: HPRT, STAT3, PD1, PDL1, IL-10, IL-10RA and HIF-1A. Primer sequences are listed in Supplementary Table S1.
Experimental design of the A549 lung ADC cell line
A549 cells are human lung ADC alveolar basal epithelial cells, generated in 1972 by Donald Giard, originating primarily from a 58-year-old Caucasian male. In vitro, A549 grow in monolayer and are widely used in research. 3 × 105–106 A549 cells were cultured with 10% FCS containing medium (Gibco F-12 Nut Mix, Thermo Scientific, complemented with 1% penicillin and streptomycin and 1% L-glutamine) or 0.4% FCS (serum starvation) at 37 °C and 5% CO2. To analyse the effect IL-10, A549 cells were cultured for 24–48 h with rhIL-10 (Immunotools, 11340105, Friesoythe, Germany). Cells were collected and used for flow cytometric analysis or RNA extraction.
Flow cytometry
A549 were stained with the following specific antibodies: α-pSTAT3 (BD Bioscience, 550474, Alexa Fluor 647, San Diego, CA, USA) according to the manufacturer's protocol, α-IL-10R (Biolegend, 308804, PE, San Diego, USA), αPD1 (Biolegend, 329908, APC), αPDL1 (Biolegend, 329908), α-FAS (Miltenyi Biotec,130099738, APC, Bergisch Gladbach, Germany) and αFASL (Biolegend, 306407, PE). Apoptosis assay was performed with Annexin V (BD Pharmingen, 550474, APC, San Diego, CA, USA) and propidium iodide (BD Pharmingen, 5166211E) according to the manufacturer’s instructions. Measurements were done at the BD, FACS Calibur & Flow Supply (342975). Evaluation was performed with FlowJo-v10 software (Flowjo, LLC, Ashland, OR, USA).
Mice
Balb/c mice were purchased from Janvier (Charles River, Sulzfeld, Germany). Mice were kept in the animal care facility of the Kussmaul Campus, Hartmannstrasse 14, Erlangen-Nuremberg, under a 12 h light/dark cycle. Food and tap water were provided ad libitum. All animal procedures were approved by the respective governments in accordance to the German animal protection law and carried out by skilled experimenters. License Az. 54-2532.1-36/13.1
Murine model of lung ADC and tumour growth measurement
Female Balb/c mice (6–8 weeks) were intravenously injected with 106 LL/2-luc-M38 Bioware Cell line (Caliper LifeSciences, Hopkinton, MA, USA). At the described time points, mice were injected intraperitonally with luciferin (15 mg ml−1) and anaesthetised with isoflurane for the luciferase activity measurement. Luciferase activity was measured with the Caliper IVIS system.
Statistical evaluation
Statistical analysis excluding correlations were done with the Student’s/Gosset’s unpaired, two-tailed t-test (*P<0.05, **P<0.01 and ***P<0.001) and is presented with mean values±s.e.m.
Correlations were examined by importing data, which needed to be correlated, in XY-tables of GraphPad Prism 7 software (GraphPad Software, Inc., La Jolla, CA, USA), diagram it with linear regression curve and perform the two-tailed Pearson’s correlation analysis to get the R- and P-value (*P<0,05; **P<0,01; ***P<0,001).
Results
Increased IL-10 expression in the lung control region (CTR), surrounding the tumour, directly correlated with the tumour diameter in patients who suffered from ADC
In this study, we started analysing the micro-anatomical expression of the immunosuppressive cytokine IL-10 in the lung of patients that underwent surgery because of NSCLC. To this aim, we first did IHC on histological tissue arrays, which we generated by using lung tissues selected from the tumoural and control regions of our cohort of patients (n=48) who underwent surgery because of NSCLC. Lung samples were collected after surgery at the Thoracic Surgery Department of the FAU in Erlangen, directly processed at the adjacent Pathology Institute and transported immediately kept cold to our department. The characteristics of these patients are shown in Table 1.
To understand if IL-10 was co-localised with tumour cells expressing thyroid transcription factor-1 (TTF1), we first double immunostained the histological sections with an antibody directed to IL-10 followed by antibody to TTF1 (Figure 1A). The negative controls for IHC used in this study are shown in Supplementary Figure S1. In Figure 1B we then quantified the number of IL-10-positive cells in the tissue arrays and found that the number of IL-10-positive cells was upregulated in the control region of patients with ADC as compared with the respective tumour region, as well as to the SCC control and tumour region. Overall, this significance held true also when all patients of the cohort with NSCLC were analysed (Figure 1B, right panel). We then analysed IL-10 mRNA from a larger cohort of these patients with NSCLC and confirmed that the control region of patients with ADC had more IL-10 mRNA (Figure 1C) as compared with those bearing a SCC. Interestingly, we found that IL-10 mRNA was not downregulated in the tumour region of these ADC patients, indicating the presence of inhibitory mechanisms on IL-10 protein translation in the tumour region of patients with ADC. At the RNA level also, we found a downregulation of IL-10 mRNA in the tumoural region of patients with SCC as compared with their control region. In summary, we have found a downregulation of IL-10 in the tumoural region of patients with NSCLC (Figure 1B, right-hand-side panel). We next correlated IL-10 mRNA expression with the tumour diameter and found a direct positive correlation between these two parameters in the control region of patients with ADC and, in general, in NSCLC patients analysed in this study (Figure 1D), indicating a possible relationship between IL-10 mRNA expression in cells surrounding the tumour and the size of the tumour. To better characterise the cells expressing IL-10 in the lung tumour, we next immuno-double stained the tissue arrays with anti-IL-10 and anti-CD3 antibodies to understand whether IL-10 was produced by T-lymphocytes in NSCLC. As shown in Figure 1E and F, we could not see a significant co-localisation of these two markers in lung tissues. Moreover, CD3 was found elevated in the tumoural region of patients who suffered of ADC (Figure 1G), confirming that the main type of cells producing IL-10 in the lung of patients with ADC were not T-lymphocytes. Morphologically, we assume that these IL-10+ brown stained cells are mainly macrophages and leucocytes, and rarely even tumour cells.
Enhanced PD1 expression in the tumoural region of patients who suffered from NSCLC is directly correlated with CD3 and PDL1 levels
The peripheral tolerance has in health an important role on maintaining a homeostatic immune system. PD1 binds to PDL1 as an important component of this peripheral tolerance. However, PDL1 expressed on cancer cells or on myeloid cells infiltrating the tumour has an inhibitory role in the development of anti-tumour immune responses. PDL1 has been shown to be induced by IFN-γ, an inhibitor of IL-10 (Kuang et al, 2009; Zhang et al, 2009).
To start to investigate the relationship between IL-10 and the PD1/PDL1 expression we double stained our tissue arrays with PD1 and IL-10 (Figure 2). Here we found by double IHC that IL-10-positive cells, shown in brown in Figure 2A and B, were topographically located in proximity of PD1 positive cells shown in blue. By quantification, we found that PD1 elevated cells, similar to CD3, were induced in the tumoural region of patients with ADC and SCC (Figure 2C). Moreover, a direct positive correlation was found between PD1 and PDL1 in SCC specifically and in NSCLC, in general (Figure 2D and E, respectively) and between CD3 and PD1 in the tumoural region of patients with ADC (Figure 2F). We then concluded that cells other than T-cells, such as macrophages or other cells expressing IL-10, would be mapping in proximity of PD1-expressing cells.
In conclusion, here we discovered that the distribution of CD3+ and PD1+ stained cells is strongly correlated in lung tissues from NSCLC, showing a rise of them in the tumour region, especially in the tumour region of patients with ADC, compared to the control regions of each cancer type. Moreover, IL-10+ and PD1+ cells are seen to infiltrate the tumour tissue and are found next to each other.
Enhanced expression of IL-10R in the control region in patients who suffered from NSCLC
We next analysed the expression of the IL-10R. This cytokine receptor is known to be expressed on T-cells. Specifically, the IL-10/IL-10R system is believed to mediate immunosuppressive functions of T-regulatory (Treg) cells. We next asked about the localisation of IL-10R α-chain in the lung tissues of patients with NSCLC. The IHC on histological arrays are shown in the Figure 3A and B.
Here we detected a predominant localisation of IL-10R+ cells in the control region of patients with SCC (Figure 3C). IL-10R mRNA was upregulated in the tumoural region of lung tissue from patients affected by lung ADC as compared with the tumoural region bearing squamous carcinoma cells (Figure 3D). Moreover, we found that both, the control and the tumoural region of ADC expressed high levels of IL-10R as seen in SCC CTR. In conclusion, our findings suggest that IL-10 can directly or indirectly affect tumour surrounding or infiltrating cells as well as the tumour cells.
IL-10R expression directly correlated with the tumour diameter and PD1 levels and is upregulated in Foxp-3+ Treg cells infiltrating the tumoural region of patients with ADC
We next wanted to closer analyse the relationship of IL-10R mRNA expression in the tumour region and the tumour diameter in NSCLC. In patients with ADC, we found a direct correlation between IL-10R and the tumour diameter as defined by CT at the time of the surgery (Figure 3E). As IL-10R and PD1 directly correlated in the tumoural region of patients with SCC (Figure 3F), we next asked whether PD1, such as IL-10R, would correlate with the tumour diameter in the tumour (Figure 3G). However, we could not find a direct correlation, indicating that cells expressing IL-10R are distinct from PD1-expressing cells. Finally, we analysed IL-10R expression on CD4+ T-cells in freshly isolated lung cells from two patients with ADC. Here we found increased number of Foxp-3+ Treg cells expressing IL-10R in their tumoural region (Figure 3H). In conclusion, the data indicate that in the tumour region of patients with SCC, PD1 and IL-10R are co-localised whereas in ADC IL-10R maps with Foxp-3.
In SCC, but not in ADC, IL-10R directly correlated with PDL1 and HIF1-α expression
We next correlated IL-10 and IL-10R, and found a very good positive correlation between this cytokine and its receptor both in the control but especially in the tumoural region of the lung of patients with ADC (Figure 4A). As we described above, we think that the main cells producing IL-10 are macrophages type 2 in tumour, which then activate IL-10R+ T-cells, which are mainly Foxp-3+ T-cells. PDL1, which is expressed in macrophages and in tumour cells inversely correlated with IL-10R in the control region of ADC (Figure 4B), but directly correlated with SCC (Figure 4B, right-hand side). Upon cell activation, T-cells undergo under metabolic reprogramming, a process that require the activation of the glycolysis. We next found that HIF1-α correlated with IL-10R in the control region of SCC (Figure 4C), knowing that HIF1-α can cause metabolic cell reprogramming in cancer (DeBerardinis et al, 2008). It is possible that IL-10R on T-cells directly correlated with HIF1-α expression in the control region of patients with SCC. In conclusion, in SCC during tumour growth, PDL1 and HIF1-α directly correlated with IL-10R. By contrast, in ADC, IL-10R inversely correlated with PDL1 in ADC.
IL-10R and PD1 inversely correlated in the tumoural region of patients with ADC
We next asked about the relationship between PD1 and IL-10R, and confirmed that PD1 was induced in the tumour area, whereas IL-10R was induced in the control area of both ADC and SCC (Figure 5A). Moreover, in confirmation of this finding, we discovered a strong statistically significant inverse correlation between IL-10R and PD1 in the tumoural area of patients with ADC in particular and in patients with NSCLC in general (Figure 5B). These data suggest an inhibitory function of IL-10 on PD1 expression via the IL-10R.
Translational studies in a murine model of lung ADC confirmed the presence of IL-10R on Foxp-3+ Treg in the lungs of tumour-bearing mice
We next tried to recapitulate the results in humans, by using a murine model of lung cancer. Here we injected intravenously the lung ADC cells LL/2-luc-M38 containing the Firefly luciferase gene expressed from the PCI-luc promoter and analysed the tumour load by using an in vivo imaging based on luminometer (Figure 5C). We then analysed Foxp-3+ Treg cells for IL-10R expression. As in humans, lung tumour-infiltrating Foxp-3+ Treg cells carrying IL-10R were induced in the lung of mice bearing tumour (Figure 5C).
T-bet+CXCR3+ Th1-cells express PD1 in tumour-bearing mice
As PDL1 in tumour cells is known to be induced by IFN-γ and in patients with ADC we found that PD1 bearing lymphocytes are often not Foxp-3 positive, we next looked for T-cells bearing PD1. We found that, in the lung of mice bearing tumour, PD1 is induced in CD4+ T-cells expressing T-bet, the main transcription factor of IFN-γ, and in CD4+ Tbet+ CXCR3+ cells as analysed in the total cells isolated from tumour-bearing mice compared with naive mice (Figure 5D).
In conclusion, in developing lung tumour, Th1 bearing PD1 increase, thus allowing anti-PD1 treatment to limit this disease.
It is possible that PD1-bearing cells are on Th1 in lung tumour. As IL-10 is an inhibitor of IFN-γ, we concluded that the cells bearing IL-10R are distinct from Th1, in fact they are Foxp-3+ Treg cells and tumour cells. Under these immunosuppressive conditions, the tumour grows and the environment is deprived by metabolites; under these metabolic restrictions, IL-10R is induced on tumour cells. Finally, IL-10 terminates the PD1/PDL1 signalling induced by IFN-γ, by inhibiting PD1 and PDL1 in tumour, thus resulting in resistance to anti-PD1/PDL1 treatment in patients with NSCLC.
Metabolic deprivation induced IL-10R, IL-10 decreased FASL, FAS and apoptosis, and suppressed PDL1 and PD1 on lung A549 ADC cells
Taken together, the data above indicate that the presence of tumour cells of different origin might influence the balance between IL-10R and PDL1 in metabolic restriction present in the tumour milieu of ADC. Moreover, IL-10 has an inhibitory function on PD1 or vice versa.
Therefore, we next asked whether a lung ADC cell line would be responsive to IL-10, because it expresses IL-10R. To address this point we thought to reproduce conditions present during tumour growth and thus exposed the cells to normal nutrient conditions (10% FCS) or under limiting metabolic conditions present during tumour growth. Here we saw that, the human A549 ADC cell line cultured with 10% serum had lower levels of IL-10R as compared with the one cultured under low level of nutrients such as 0.4% FCS (Figure 6A). We thus concluded that limiting metabolic nutrients promotes IL-10 signal transduction in lung tumour. In fact, by adding IL-10 to the tumour ADC cell line, under metabolic restriction, we observed a significant upregulation of STAT3 as well as phosphorylated STAT3 (Figure 6B) intracellularly and a downregulation of the apoptosis marker Annexin V (Figure 6C). Even under normal conditions (no metabolic restriction Figure 6D–G), IL-10 inhibited the apoptotic pathway by inhibiting FASL (Figure 6D) and FAS (Figure 6E), consistent with the human data in ADC. In summary, IL-10 inhibited tumour cell apoptosis and cell apoptosis markers such as FAS, FASL and Annexin V in the human tumour A549 ADC cells, thus favouring lung tumour cell growth. Under normal growing conditions in 10% FCS, IL-10 inhibited PD1 (Figure 6F) and PDL1 (Figure 6G) on these human lung ADC cells. Thus IL-10 emerges as a possible marker to identify when anti-PD1 treatment would work.
Discussion
The demand on novel treatment options for the most life threatening cancer type, lung cancer, is obvious. Further research is inalienable to provide innovative therapy approaches and a powerful, pleiotropic signal transducer such as IL-10 might be a promising starting point for prospective investigations and therapy considerations, especially in the context with the presently, intensively investigated targets such as PDL1 and PD1 providing a plurality of new cancer treatments.
IL-10 is a frequently already examined cytokine; however, in the past, the focus was mainly placed on its immunosuppressive, pro-tumoural potential (Sharma et al, 1999), while presently more and more additional anti-tumoural properties, depending on its application, were revealed and it is even used as anti-tumoural medication (Teng et al, 2011).
However, its mode of functioning is obviously multisided. We have recognised noticeable differences in the accumulation patterns of IL-10-producing cells and its addressees among the human lung biopsy studies, which raises the question how this compartmentalisation is generated and what is their meaning. Our data show commonly by trend elevated levels of IL-10 and IL-10R in the NSCLC control region. Concerning the increase of IL-10, in NSCLC CTR region, especially in ADC, we found a positive correlation between IL-10 and the tumour diameter. Therefore, these results seem to highlight the impact of an IL-10-producing cell accumulation in the control region of the lung of patients carrying lung cancer, which should be examined carefully to understand IL-10 assisted tumour expansion. This thought is supported by the fact that the number of IL-10-producing TAMs, located in the CTR region, which can be morphologically retraced in our IHC pictures, correlates with poor prognosis (Zeni et al, 2007). On the subtended TU side of NSCLC, we see elevated levels of PD1 and CD3, typical for lung cancer stroma (Banat et al, 2015), being predominant especially in the lung tumoural region of patients with ADC. Among these cells, might be CD3 elevated PD1 elevated T-cells, likely a large amount of exhausted T-cells (Wherry, 2011). Thus, how do those two clusters arise and interact together (increased IL-10 and IL-10R in the CTR on the one hand and elevated CD3 and PD1 in the TU on the other hand)?
In our poly-phase model of the impact of IL-10 in lung ADC we hypothesise the following context: tumoural antigens trigger IFN-γ-mediated Th1 answer, which is meant to impair tumour development and maintain homeostasis (Hubackova et al, 2016), but via tumour escape mechanisms IFN-γ leads to tumoural PDL1 upregulation (Mandai et al, 2016). PDL1 promotes the accumulation and function of Tregs (Francisco et al, 2009; Chen et al, 2016b), as well as the accumulation of exhausted, PD1 expressing Th cells (Zun-Qiang Zhou et al, 2016), which is underlined by our transcription analysis showing positive correlation between PDL1 and PD1 in NSCLC TU, as well as the upregulation of the IL-10R in Foxp-3+ TU-infiltrating T-cells, shown in our flow cytometric analysis of human ADC biopsies. These anti-inflammatory cells support an IL-10 high, immunosuppressive tumour environment. An IL-10 high microenvironment supports further accumulation of immunosuppressive cells such as TAMs in the CTR region, exhausted Th cells and Tregs expressing IL-10R in the TU region correlating with increased tumour growth, as well as poor prognosis regarding IL-10R+ and Foxp-3+ Treg TU infiltration (Tao et al, 2012), and also hinders differentiation and accumulation of anti-tumoural cells such as M1 macrophages, fully functional Th1-cells, NK cells and APC (Sharma et al, 1999; Krneta et al, 2017).
After the establishment of a stable, IL-10 dominated, immunosuppressive environment and a resulting downregulation of tumoural PDL1, even medical anti-tumoural anti PDL1/PD1 treatment might be less useful. Those directly IL-10R/STAT3 mediated, tumoural surface characteristics modulating and antiapototical effects might be bigger, the faster the tumour is growing, when going along with a nutrient starvation and rise of HIF1-α, which was especially found in SCC CTR and is followed by an IL-10R sensitisation. Once, the IL-10 liberation is overbalanced the enforcement of an immunosuppressive environment seems unstoppable regarding the observed positive correlation between IL-10 and IL-10R, supported by other findings, that IL-10 can induce IL-10 in monocytes (Staples et al, 2007), maybe advantaged by a possible decrease of negative feedback via SOCS3 because of SOCS3 promoter hypermethylation (Lin et al, 2010). FASL is assumed to behave similarly and mediate similar effects in comparison with PDL1. This could be the subject of further studies.
Unfortunately, this model is not fully able to explain the more malignant (Fry et al, 1999) human situation in SCC regarding the differences in IL-10, IL-10R, PD1, CD3 expression and correlation analysis compared with ADC. A key reason for this difference could be that in SCC CTR and TU region we do not see a negative correlation between the IL-10R and PDL1 but a positive one. This leads to our suggestion that there might be no negative feedback concerning IL-10 and PDL1 like we found in ADC but the opposite. The absence of negative feedback means increased apoptosis of CD3 elevated Th1-cells via PD1 (Ji et al, 2016), leading to a poor prognosis (Kinoshita et al, 2016), which could explain the depressed levels of CD3 in SCC TU compared with ADC TU and implies more likely an assumed interaction and promotion of IL-10-producing Foxp-3+ CD4+ T-cells, than with exhausted Th1-cells such as in ADC. These Foxp3+ T-cells are frequently increased and often permanently activated in NSCLC (Ke et al, 2016) and usually express PD1 (Gao et al, 2012) as well as IL-10R (Chaudhry et al, 2011). This could be the reason why we see a positive correlation between PDL1 and PD1 in SCC TU, as well as between PD1 and IL-10R in SCC TU, between PDL1 and IL-10R in SCC TU and CTR, and finally why there are higher levels of PDL1 in general in SCC (Jiang et al, 2016) than in ADC. In SCC patients with high levels of PDL1 have a poor prognosis (Ferlay et al, 2015; Sundar et al, 2015), if untreated. We assume, as they are supposed to lack the IL-10-mediated downregulation mechanism of PDL1, meaning the absence of the anti-PDL1/PD1 treatment resistance functionality, these patients therefore may have a higher use of anti-PD1/PDL1 therapy (Reck et al, 2016). Anyway, we could not detect a positive correlation between PD1 and tumour diameter in NSCLC TU.
In summary, countering the overbalance of IL-10-producing cells in the CTR of NSCLC to stop IL-10-mediated tumour immune tolerance, which correlates with tumour growth, reaction to chemotherapeutics and prognosis may lead to a better outcome. There are already therapeutics in use such as the recommended PD1 inhibitors Nivolumab and Pembrolizumab (Ettinger et al, 2016), which achieve this goal by stopping T-cells from being impaired via tumoural PDL1, and leading to a higher level of IFN-γ, which also blocks IL-10 release. However, remarkably, also exogen liposomal PEG-IL-10, which is purposively flushed out in the TU because of fast growing, insufficient constructed vessels, leads to similar effects such as PD1-antagonists and rises CD8+ T-cell cytotoxity, promotes CD8+ T-cell accumulation, and IFN-γ and granzyme release in the tumoural region (Teng et al, 2011; Naing et al, 2016b). The mechanism seems unclear having all the immunosuppressive effects of IL-10 in mind.
Concerning immunotherapeutic intentions, we think a combination of PEG-IL-10 and PD1-antagonists could have a synergistic effect and might be a potent weapon against the devastating effect of tumoural PDL1 in NSCLC (Naing et al, 2016b), whereas PEG-IL-10 might be less useful in SCC, but especially useful in ADC. Besides those two, other antibody strategies would be thinkable according to our tumour model like the use of PDL1-AB (Antonia et al, 2016), IL10R-AB (Ni et al, 2015; Chen et al, 2016a) and IL-10-AB, whereupon current used IL-10-AB do not decrease but increase the level of IL-10 and are not used yet in NSCLC (Llorente et al, 2000). Furthermore, beside those primarily therapeutic intentions, IL-10 could possibly be used as a diagnostic parameter in ADC for anti-PD1/PDL1 treatment success forecast, whereas lower levels of IL-10 might go along with a lower anti-PD1/PDL1 resistance and better prognosis.
Change history
21 November 2017
This paper was modified 12 months after initial publication to switch to Creative Commons licence terms, as noted at publication
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Acknowledgements
We thank Bettina Klösch, Corinna Holzinger and Rebekka Springel for their excellent experimental help. This work was financially supported by an IZKF grant number A59 in Erlangen awarded to SF. JMV was supported by a fellowship on Cellular Immune-intervention in Erlangen, sponsored by the graduated school of the SFB-643 group in Erlangen. We thank the all supporting team in the Molecular Pneumology department, Thoracic Surgery and Institute of Pathology in Erlangen.
Author contributions
JMV did the histological and immune-histological analysis including correlations, did the A549 experiments and wrote the manuscript, and generated the figures. JF helped with the generation of the figures and with the patients sample collection. LB did the real-time PCR for IL-10 and IL-10R in patients. DIT and HS provided and indexing the human lung biopsies. RR, CG and NF did the pathological characterization and digitalisation of the human tissue arrays originated from those biopsies, as well as the quality control of slides, stains and scans. SM did the immunohistochemical staining. LH and KK contributed to the patient samples collection and did the FACS analysis on human and in murine lung cells. LH and NS supported JMV and ST in the planning and executing numerous experiments related to the cell line A549. SF designed and supervised this study, and contributed significantly to the manuscript and figures.
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Vahl, J., Friedrich, J., Mittler, S. et al. Interleukin-10-regulated tumour tolerance in non-small cell lung cancer. Br J Cancer 117, 1644–1655 (2017). https://doi.org/10.1038/bjc.2017.336
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DOI: https://doi.org/10.1038/bjc.2017.336
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