Inducible Co-Stimulator ICOS Expression Correlates with Immune Cell Infiltration and Can Predict Prognosis in Lung Adenocarcinoma.

Background: Inducible co-stimulator (ICOS) is a cell-enhanced co-stimulatory receptor that has shown great potential in the regulation of innate and adaptive immunity. However, the role of ICOS in lung adenocarcinoma (LUAD) remains unclear.
Methods: We used data from the Cancer Genome Atlas(TCGA) database to identify the expression and prognostic role of ICOS in LUAD. The results were validated using Gene Expression Omnibus(GEO) and Kaplan-Meier plotter databases. A model with predictive performance for overall survival of LUAD patients was constructed using fitted ICOS expression and other clinical parameters. We explored the biological function of ICOS. Subsequently, we further analysed and validated the effect of ICOS expression on tumour immune microenvironment (TIME) and survival. Finally, the CellMiner database was used to determine the relationship between ICOS expression and drug sensitivity.
Results: ICOS expression is significantly associated with poor prognosis in multiple cancers, especially LUAD, and is a good predictor of overall survival in LUAD patients. The biological function is to promote autoimmunity and inhibit cell proliferation. ICOS-related survival prediction model developed to more accurately predict 1-, 3- and 5-year survival probabilities for LUAD patients. In addition, we can use the expression of ICOS to effectively assess patient malignancy, prognosis, TIME status and clinical combination of drugs.
Conclusion: Our results suggest that ICOS is correlated with prognosis and immune infiltrating levels in LUAD. Higher ICOS expression predicts better TIME. This study provides a novel strategy for the development of immunotherapeutic and prognostic markers in LUAD.

Introduction

Lung cancer is one of the most common malignancies, of which more than 80% is non-small cell lung cancer (NSCLC). Lung adenocarcinoma (LUAD), the most recurrent of these NSCLC subtypes, accounts for more than 40% of all lung cancer cases.1,2 Over the past few years, although targeted therapies and immunotherapy have improved the prognosis of LUAD patients have improved clinical outcomes, the 5-year survival rate is still below 20%.3–5 Therefore, finding more accurate markers and therapeutic targets for LUAD is urgently needed, which is the key to improving the survival rate of LUAD patients.

Inducible T cell costimulator (ICOS) is a CD28 superfamily receptor induced in activated T lymphocytes that regulates T cell activation and participates in adaptive immune responses.6 It has been demonstrated that they are aberrantly expressed in a variety of tumors and are associated with cancer development, metastasis and disease.7–10 It has been reported that modulation of ICOS expression may improve anti-tumor immunity, and ICOS co-stimulation at tumor sites combined with anti-CTLA-4 and Treg depletion may also exhibit higher anti-tumor effects.11,12 Although immunotherapy with ICOS is promising, there are still too few studies to date and the mechanism of action is still not well understood. Therefore, the assessment of ICOS as an immune-related biomarker in LUAD and its potential use remains to be further explored.

In this study, we analysed the expression and prognosis of ICOS in pan-cancer and found that ICOS was significantly associated with poor prognosis and poorer clinical factors in several cancers, particularly LUAD. The mechanism of ICOS in the development of LUAD was revealed and analysed in relation to the level of immune cell infiltration and the tumour immune microenvironment. The findings in this study elucidate the critical role of ICOS as a prognostic biomarker in the diagnosis and development of LUAD and reveal potential mechanisms between ICOS and tumour immunity, which provide a basis for clinical research and immune-targeted therapy.

Materials and Methods

Data Collection

The expression profiles and clinical information of TCGA were downloaded from the TCGA database ().

The expression profiles and clinical information of GSE72094 were downloaded from the GEO database ().

Oncomine Database

Oncomine is a database that aggregates multiple cancer types and multiple datasets ().13 Using data from this database, we validated the mRNA expression of ICOS in LUAD.

Kaplan-Meier Plotter Database Analysis

The Kaplan-Meier Plotter can evaluate the impact of 54,675 genes on survival using 10,461 cancer samples. We validated the correlation between ICOS expression and survival in LUAD using data from the Kaplan-Meier Plotter.

Linkedomics Database

LinkedOmics is a database for GO, KEGG and Reactome functional analysis online based on a large number of tumour samples ().

TISIDB Database

TISIDB () is a strong website that provides a huge number of tumor immune-related data and allows for a more in-depth analysis of tumor-immune interactions. The site has 988 genes associated to anti-tumor immunity after grouping 4176 entries from 2530 publications. For each of the 30 TCGA cancer types, associations between genes and immunological activities (eg, lymphocytes, immunomodulators, and chemokines) were pre-calculated. We investigate the immune system connection between ICOS and various tumors in this study.

Statistical Analysis

The statistical significance of differential ICOS expression was determined using the Wilcoxon test. Survival curves with HR and P or Cox P values were plotted, and the correlation and statistical significance of ICOS expression with the degree of immune infiltration of the associated cancer was assessed using the Spearman correlation method. The median was taken as the cutoff point. p ≤ 0.05 was considered statistically significant.

Results

The mRNA Expression Levels of ICOS in Different Types of Human Cancers

To assess the relevance of ICOS in tumour development, we analyzed the differences of ICOS expression levels between tumor and adjacent normal tissues in pan-cancer (Figure 1A). We found that ICOS mRNA expression was significantly higher in Breast invasive carcinoma (BRCA), Cervical squamous cell carcinoma and endocervical adenocarcinoma (CESC), Esophageal carcinoma (ESCA), Head and Neck squamous cell carcinoma (HNSC), Kidney renal clear cell carcinoma (KIRC), Kidney renal papillary cell carcinoma (KIRP), Liver hepatocellular carcinoma (LIHC), Stomach adenocarcinoma (STAD) and Uterine Corpus Endometrial Carcinoma (UCEC). However, ICOS expression was significantly lower in Lung adenocarcinoma (LUAD), Lung squamous cell carcinoma (LUSC) and Thyroid carcinoma (THCA) compared to adjacent normal tissues. Analysis based on 103 tumour samples and 113 paraneoplastic samples from the Oncomine database in Figure 1B and C and 535 tumour samples and 59 paraneoplastic samples from the TCGA database in Figure 1D, E showed that ICOS expression was lower in LUAD than in non-cancerous tissues. In addition, immunohistochemical results provided by the HPA database confirmed similar results (Figure 1F and G). Given its prognostic value in LUAD, we used TCGA normal and LUAD data to generate ROC curves to further analyze the diagnostic value of ICOS in LUAD. Figure 1H shows that the area under the curve (AUC) area was 0.726, indicating that ICOS has the diagnostic ability to distinguish LUAD from normal controls. The results of our analysis suggest that ICOS expression in LUAD is significantly weaker than in normal tissue and may play an important regulatory role in the progression of LUAD, promising to be a diagnostic biomarker for LUAD.

Figure 1

The expression level of ICOS in different types of tumor tissues and normal tissues (A) the expression level of ICOS in different types of tumor tissues and normal tissues in TIMER database. (B and C) Box plot showing ICOS mRNA expression in the Oncomine datasets. (D and E) Results of comparison of normal and LUAD tissues in the TCGA. (F and G) Comparison of ICOS expression between immunohistochemical images of normal and tumor tissues in HPA. (H) A ROC curve to test the value of ICOS to identify LUAD tissues was created. (*P < 0.05, **P < 0.01, ***P < 0.001).

Prognostic Value of ICOS in Cancers Prognosis

Our analysis of clinical data showed that high ICOS expression was associated with better survival in several cancer types (Figure 2A), including LUAD, HNSC, Ovarian serous cystadenocarcinoma (OV), Rectum adenocarcinoma (READ), Sarcoma (SARC), Skin Cutaneous Melanoma (SKCM), and UCEC. In contrast, high ICOS expression resulted in poor prognosis in some cancers such as Lower Grade Glioma (LGG) and Uveal Melanoma (UVM). To avoid noncancer events leading to bias, we also performed an analysis of disease-specific survival (DSS) and progression-free interval (PFI), as shown in Figure 2B and C, respectively. The results showed, as did the OS analysis, that higher ICOS expression was significantly associated with better DSS in LUAD, HNSC, OV, SKCM, UCEC, and UCS. In LUAD, Bladder Urothelial Carcinoma (BLCA), CESC, HNSC, and UCEC, higher ICOS expression was significantly associated with better PFI. To further confirm the importance of ICOS in the survival of patients with LUAD, we analyzed the LUAD data using the Kaplan-Meier Plotter database. Figure 2D shows the OS, FPS (first progression survival), and PPS (post progression survival) of patients with LUAD. This analysis is consistent with the TCGA analysis and confirms that ICOS expression affects the prognosis of patients with LUAD.

Figure 2

Relation between ICOS expression and patient prognosis of different cancers in TCGA database and Kaplan-Meier plotter database (A) survival curves of OS with significance in TCGA cancer types. (B) Survival curves of DSS with significance in TCGA cancer types. (C) Survival curves of PFI with significance in TCGA cancer types. (D) Relationship between ICOS and survival of LUAD patients in Kaplan-Meier plotter database. (*P < 0.05, **P < 0.01, ***P < 0.001).

Correlations Between ICOS Expression and Clinicopathological Parameters in LUAD Patients

We then analyzed the correlation between expression levels and clinical features of ICOS. Our data were derived from gene expression and clinical data of 535 LUAD patients from TCGA (Table 1). We divided LUAD patients into two groups of high and low expression based on median values and then performed the Wilcoxon test to assess the significance of ICOS expression in different clinical features (Figure 3A–J). ICOS overexpression correlated significantly with T-phase, TNM-phase, response to immunotherapy, gender, and age. Following univariate and multivariate analyses of clinical features, we found that ICOS expression (HR=0.657, P=0.016), T stage (HR=1.764, P=0.017) and N stage (HR=2.138, P<0.001) were independently associated with overall survival in patients with LUAD (Figure 3K and L). These results suggest that ICOS expression, T stage and N stage may play a role in determining clinical treatment.

Table 1

Grouping of Clinicopathological Features According to ICOS Expression Levels

Characteristic	Levels	Low Expression of ICOS	High Expression of ICOS
n		267	268
Gender	Female	126 (23.6%)	160 (29.9%)
	Male	141 (26.4%)	108 (20.2%)
Race	Asian	5 (1.1%)	2 (0.4%)
	Black or African American	28 (6%)	27 (5.8%)
	White	202 (43.2%)	204 (43.6%)
Age	≤65	140 (27.1%)	115 (22.3%)
	>65	118 (22.9%)	143 (27.7%)
T	T1	68 (12.8%)	107 (20.1%)
	T2	155 (29.1%)	134 (25.2%)
	T3	31 (5.8%)	18 (3.4%)
	T4	12 (2.3%)	7 (1.3%)
N	N0	166 (32%)	182 (35.1%)
	N1	50 (9.6%)	45 (8.7%)
	N2	45 (8.7%)	29 (5.6%)
	N3	1 (0.2%)	1 (0.2%)
M	M0	180 (46.6%)	181 (46.9%)
	M1	13 (3.4%)	12 (3.1%)
Stage	Stage I	132 (25%)	162 (30.7%)
	Stage II	65 (12.3%)	58 (11%)
	Stage III	52 (9.9%)	32 (6.1%)
	Stage IV	13 (2.5%)	13 (2.5%)
Primary therapy outcome	PD	46 (10.3%)	25 (5.6%)
	SD	19 (4.3%)	18 (4%)
	PR	4 (0.9%)	2 (0.4%)
	CR	151 (33.9%)	181 (40.6%)
Residual tumor	R0	181 (48.7%)	174 (46.8%)
	R1	8 (2.2%)	5 (1.3%)
	R2	1 (0.3%)	3 (0.8%)
Years of smoking	<40	93 (25.2%)	95 (25.7%)
	≥40	90 (24.4%)	91 (24.7%)
Smoker	No	35 (6.7%)	40 (7.7%)
	Yes	226 (43.4%)	220 (42.2%)

Figure 3

Association of ICOS expression with clinical parameters. (A) Gender; (B) age; (C) race; (D) smoking years. (E) History of smoking (F) T stage; (G) N stage; (H) M stage; (I) TNM stage; (J) immunotherapy response; (K) the Univariate Cox analysis regarding prognosis. (L) The Multivariate Cox analysis regarding prognosis.

Development of a Prognostic Model Based on ICOS and Clinical Factors

An overall survival prediction model was constructed using ICOS and independent clinical risk factors to predict the prognosis of ICOS patients (Figure 4A). In this prediction model, we evaluated these variables and used the summed score of the values of these variables to predict the 1-, 3-, and 5-year survival probabilities of LUAD patients (Figure 4B). The analysis of 1000 bootstrap samples showed that the C-index of ICOS was 0.660 (0.638–0.683). This indicates that the model is highly accurate in terms of predictive performance. Poorer T-stage, N-stage and ICOS expression predicted higher risk scores and poorer prognosis for patients. Thus, the results of our analysis found that the nomogram was a model that was better than individual prognostic factors in predicting short- or long-term survival in LUAD patients.

Figure 4

A model regarding ICOS for predicting the probability of OS in patients at 1, 3, and 5 years. (A) Nomogram regarding ICOS to predict prognosis in patients with LUAD. (B) Calibration plots of a nomogram regarding ICOS to predict prognosis in LUAD patients.

ICOS Co‐expression Network in LUAD

To understand the biological function of ICOS in LUAD, we used LinkedOmics database analysis to find 10,765 genes (dark red dots) positively linked to ICOS and 9222 genes (dark green dots) negatively linked in TCGA-LUAD (Figure 5A, ). Figure 5B and C shows heat maps for the top 50 genes positively and negatively linked to ICOS.GO term annotation showed that co‐expressed genes of ICOS co-expressed genes mainly promote immune processes such as interleukin production, adaptive immune response, interferon-gamma production, T cell activation, leukocyte proliferation, lymphocyte activation involved in immune response, and inhibit cell proliferation processes such as mitochondrial respiratory chain complex assembly and NADH dehydrogenase complex assembly (Figure 5D). Analysis of the KEGG pathway has shown that it promotes autoimmune and inflammatory responses and inhibits oncogenic-related pathways (Figure 5E). Reactome analysis similarly confirmed that ICOS expression promotes autoimmune responses and suppresses tumor cell proliferation during cancer development, we also found that ICOS expression was positively correlated with some immunity-related signalling, such as PD-1 signalling and TCR signalling (Figure 5F). These results suggest that the expression network of ICOS could influence prognosis in LUAD by regulating tumor cell proliferation and autoimmunity.

Figure 5

Functional analysis of genes co-expressed with ICOS in LUAD. (A) Volcano map of genes significantly associated with ICOS in LUAD. (B and C) Top 50 genes positively and negatively associated with ICOS in LUAD (D–F) GO, KEGG and Reactome enrichment analysis of ICOS in LUAD.

Immune Infiltration Analysis of ICOS in LUAD

Tumor infiltrating lymphocytes (TILs) have been shown to be an independent predictor of sentinel lymph node (SLN) status and survival.14 To investigate the role of ICOS in the tumor immune microenvironment, we performed correlation analysis using the ESTIMATE R package. We found that ICOS correlated positively with stromal score, ESTIMATE score, and immune score and correlated negatively with tumor clearance in LUAD, and not only that, increased ICOS expression enhances immune cell infiltration and immune function (Figure 6A and B). We next analyzed the relationship between ICOS and 24 types of immune cell infiltration in LUAD (Figure 6C). The results revealed that there was a significant positive correlation between ICOS and almost all immune cell infiltrates, including T cell expression (R=0.810, P<0.001) (Figure 6D). With these results we found that differences in ICOS expression affect the degree of infiltration of different immune cells in LUAD. Finally, to determine the correlation between ICOS expression, TIME and survival of LUAD patients, we performed analysis and validation using data from TCGA and GSE72094, as shown in Figure 6E, in the TCGA (R=0.82, P<2.2e-16) and GSE72094 (R=0.8, P<2.2e-16) datasets. There was a significant positive correlation between ICOS expression and immune score, and patients with high immune score had better overall survival than those with low immune score (Figure 6F). These results suggest that high ICOS expression may contribute to immune cell infiltration and improve the TIME in patients with lung adenocarcinoma, resulting in a better prognosis for patients with LUAD.

Figure 6

Relationship between ICOS and tumor microenvironment in LUAD. (A and B) Analysis of the relationship between ICOS and tumor microenvironment in LUAD. (C) Correlation analysis of ICOS with related 24 immune cells in LUAD. (D) Correlation between ICOS and T cells in LUAD. (E) Correlation analysis of ICOS expression with immune scores in LUAD samples in TCGA-LUAD and GSE72094 datasets.(F) Correlation of ICOS0 expression levels with overall patient survival time in TCGA-LUAD and GSE72094 datasets.

Relation Between ICOS with Immune Molecules

We expanded our understanding of the relationship between ICOS and the immune microenvironment by analyzing data from the TISIDB database. We found a particularly strong correlation between ICOS expression and several immunological traits. In most cancers, high ICOS expression can lead to a significant increase in tumor-infiltrating lymphocytes (TILs), and Figure 7A shows the six TILs with the highest correlation, including Tem_CD8 (R=0.788, P<2.2e-16). Figure 7B shows a strong positive correlation between ICOS and immunoinhibitors. Figure 7C shows a correlation between ICOS expression and immunostimulants, with higher ICOS expression stimulating a stronger immune response. Figure 7D shows the correlation between ICOS expression and MHC molecules and demonstrates that high ICOS expression induced a strong immune response to MHC in various tumors. Figure 7E shows the correlation between ICOS expression and chemokines, with the highest correlation between ICOS and CCL5 (R=0.731). Figure 7F shows the correlation between ICOS expression and receptors, with ICOS not only correlating with CXCR6 and CCR5 above 0.80, but also showing strong facilitation with other receptors.

Figure 7

The relationship between ICOS and different immune characteristics. (A) Relationship analysis of ICOS expression with TILs (B–D) relationship analysis of ICOS expression with immunomodulators, (E and F) relationship analysis of ICOS expression with chemokines (or receptors).

Thus, our study suggests that ICOS as a novel prognostic marker is actively involved in the regulation of various immune molecules in LUAD and influences immune infiltration in the tumor microenvironment.

Gene Mutation Between High and Low-ICOS Groups in LUAD

Gene mutations can promote cancer development and drive malignant cancer proliferation. Investigating mutations at the genomic level is important for the development of tumour-targeted drugs and novel oncology therapies. We divided LUAD patients into two groups according to their median expression of ICOS and compared the differences of gene mutations between the two groups. The results indicated that patients with low ICOS expression possess higher gene mutation frequency than those with high ICOS expression in LUAD (Figure 8). This suggested that low ICOS expression could result in a worse tumour microenvironment and progression in LUAD patients.

Figure 8

Gene mutation between high and low-ICOS groups in LUAD. Top 20 genes with the highest mutation differences between the high-low ICOS groups in LUAD.

Correlation Between ICOS and Drug Sensitivity

Finally, we investigated the antitumor drugs sensitive to ICOS expression using the CellMiner database. Of these, the sensitivity of 32 drugs was significantly correlated with ICOS expression and the results are shown in Figure 9 and Table 2. ICOS expression was significantly positively correlated with the sensitivity of Pipobroman, Bendamustine, Sapacitabine, Nelarabine and Dabrafenib, and negatively correlated with the sensitivity of Cordycepin and Saracatinib.

Figure 9

Correlation of ICOS expression with the sensitivity of anticancer drugs.

Table 2

Correlation of ICOS Expression with the Sensitivity of Anticancer Drugs

Gene	Drug	cor	pvalue
ICOS	Pipobroman	0.372544979	0.003663909
ICOS	Bendamustine	0.323509267	0.012441672
ICOS	Cordycepin	-0.313281453	0.015690545
ICOS	Sapacitabine	0.309591334	0.01702897
ICOS	SHP-099	-0.306141711	0.018367165
ICOS	P-529	-0.304499527	0.01903505
ICOS	SB-590885	0.298346244	0.021724476
ICOS	XAV-939	-0.296601339	0.022543297
ICOS	OTS-964	-0.294253954	0.023685906
ICOS	TAK-632	0.291108405	0.025293382
ICOS	Nelarabine	0.284892642	0.028740915
ICOS	Dabrafenib	0.284156666	0.029174036
ICOS	XK-469	0.281656463	0.030686443
ICOS	Saracatinib	-0.281410218	0.030838882
ICOS	CNDAC	0.278304877	0.03281617
ICOS	Poziotinib	-0.275655749	0.034585445
ICOS	BMS-690514	-0.274576508	0.035328627
ICOS	Quisinostat	0.273913699	0.035791587
ICOS	Temsirolimus	-0.271980274	0.037170905
ICOS	AT-13148	-0.270206147	0.038475051
ICOS	Momelotinib	-0.270052186	0.03858999
ICOS	PKM2 (9)	-0.270025498	0.038609943
ICOS	IDH-C227	-0.267095389	0.040853047
ICOS	LY-2228820	-0.266573555	0.04126359
ICOS	entosplenitib	-0.263627441	0.043645675
ICOS	Vemurafenib	0.26055171	0.046252013
ICOS	Thiotepa	0.259296982	0.047351255
ICOS	PLX-8394	0.258690809	0.047889921
ICOS	Panobinostat	0.258204654	0.048325547
ICOS	XL-147	-0.257346028	0.049102843
ICOS	Deforolimius	-0.257157203	0.049275146
ICOS	TAS-6417	-0.256512157	0.049867475

Discussion

LUAD is one of the most common types of cancer and a worldwide killer of health.15 In the absence of early symptoms, patients often miss the opportunity to receive the most appropriate treatment.16 Due to the poor prognosis of advanced LUAD, there is an urgent need to find more accurate potential biomarkers to predict the prognosis of patients with LUAD and to personalize their treatment.

ICOS belongs to a family of co-stimulatory factors that are closely associated with tumor development and play an important role in the activation and proliferation of T cells.17,18 Elevated ICOS has been shown to induce its own anti-tumor response not only by regulating immune cell homeostasis but also by regulating the production of inflammatory cytokines,19–21 such as TNF-α and IFN-γ, which contribute to T cell immune function.22–24 In primary breast cancer, ICOS mediates the interaction between tumor-infiltrating CD4+ T cells and plasmacytoid dendritic cells (pDCs), leading to the proliferation of regulatory T cells (Tregs) and the secretion of interleukin 10, which alters the immune microenvironment of the tumor and thus affects patient survival.25,26 In addition, ICOS expression in cholangiocarcinoma and metastatic melanoma has been shown to significantly improve survival by modulating autoimmunity.17,27 Not only can ICOS inhibit tumor progression and enhance immune cell activity, but the combination of anti-PD-L1 and anti-CTLA-4 therapy can further improve the immune environment of tumors and significantly enhance the anti-tumor immune response.28–30 Therefore, ICOS can be used as a potential prognostic biomarker and target for immunotherapy in the diagnosis and treatment of patients with LUAD.

In this study, in order to investigate the role of ICOS in the prognosis and immunological aspects of LUAD, we collected data from a large number of LUAD patients. Our analysis showed that ICOS expression is not only involved in the pathological tissue progression of LUAD but is also an independent prognostic factor for patients with LUAD. The ICOS prognostic model showed good agreement between actual and predicted survival at 1, 3, and 5 years in LUAD patients and may be a valuable new prognostic approach for future clinicians. ICOS improves the prognosis of LUAD primarily by inhibiting tumor progression and modulating autoimmune-related signaling pathways. To investigate the Immunological mechanisms, we found that high expression of ICOS induces increased infiltration of most immune cells, especially T cells. In addition, ICOS is also actively involved in the regulation of various immune molecules. Our results suggest that ICOS can be involved in regulating the immune microenvironment and improving the prognosis of LUAD. Finally, we obtained antitumor agents sensitive to ICOS expression.

In conclusion, our research shows that ICOS is a potential biomarker and therapeutic target associated with immunity and prognosis in patients with LUAD. Low expression of ICOS predicts worse clinical characteristics, TIME and prognosis in patients with LUAD. This study provides new insights into the clinical management of patients with LUAD.