Prognostic Significance of Tumor-Associated Macrophages in Chondroblastoma and Their Association with Response to Adjuvant Radiotherapy.

OBJECTIVE: Chondroblastoma (CB) is a rare and locally growing cartilage-derived tumor. Currently, clinical implications of tumor-associated macrophages (TAMs) in CB remain unclear. In this study, we sought to analyze the relationship between TAM parameters (including densities of CD68+ and CD163+ cells as well as the CD163+/CD68+ ratio) and clinicopathological characteristics and survival of patients.
METHODS: Immunohistochemistry was used to assess TAM subtypes for CD68 and CD163, as well as the expression levels of p53, CD34, and Ki-67 on tumor cells in 132 tissue specimens retrieved between July 2002 and April 2020. Then, TAM parameters were retrospectively analyzed for their associations with patient outcomes (local recurrence-free survival [LRFS] and overall survival [OS]) and clinicopathological features.
RESULTS: TAM densities were significantly higher in axial chondroblastoma tissue than in extra-axial chondroblastoma tissue. Moreover, the number of CD163+ TAMs was positively correlated with tumor invasion of surrounding tissues and high expression of CD34 and Ki-67 on tumor cells, whereas CD163+ cell density and the CD163/CD68 ratio were negatively associated with patient response to adjuvant radiotherapy. Univariate Kaplan-Meier analysis revealed that the number of CD68+ and CD163+ lymphocytes was significantly associated with both LRFS and OS. Multivariate Cox regression analysis showed that CD163+ and CD68+ cell levels were independent prognostic factors of LRFS, while TAM data independently predicted OS. More importantly, in subgroup analysis based on three significant factors in univariate survival analysis (including tumor location, adjuvant radiotherapy, and surrounding tissue invasion by tumors), the TAM parameters still displayed good prognostic performance.
CONCLUSION: These data suggest that TAM may significantly affect the biological behavior of CB. We hypothesize that modulating the TAM level or polarization status in the microenvironment may be an effective approach for CB treatment.

Introduction

Chondroblastoma (CB) is a rare cartilage-derived tumor with locally aggressive growth characteristics. CB commonly involves the long bone epiphysis and accounts for less than 1% of all bone tumors.1 Due to resistance to traditional chemotherapy, the current treatment of choice for CB mainly includes surgery and radiotherapy.2 Although surgery is indicated for patients with neurological deficits, spinal instability and/or worsening symptoms caused by tumors, complete resection of CB lesion may be difficult due to its locally aggressive nature and proximity to important neurovascular structures. It has also been reported that radiotherapy can be administered for patients with postoperative recurrence and those who cannot be treated surgically.3 However, radiotherapy may even cause malignant changes in this disease.4 Therefore, the therapeutic options for CB patients are limited at present and the recurrence risk of this disease is high after surgery (approximately 10–35% of patients experience relapse),5 which exerts a significant adverse effect on the long-term quality of life and survival of patients.

Tumor-associated macrophages (TAMs) constitute an important component of the tumor microenvironment. Studies have shown that TAMs can interact with cancer cells to promote neovascularization and increase radiotherapy resistance, thus accelerating the invasion and metastasis of tumors.6 Moreover, it has been suggested that TAM infiltration in the microenvironment is closely associated with the survival of patients with various human malignancies.7 Specifically, the number of CD163+ TAMs was shown to be negatively correlated with better survival in patients with gastric cancer, breast cancer, and glioma,8–10 while the density of CD68+ cells was related to poor prognosis in non-small cell lung cancer and renal clear cell carcinoma.11,12 Furthermore, for patients with colon cancer and non-small cell lung cancer, the inclusion of the CD163+/CD68+ ratio was found to significantly improve the accuracy of traditional tumor-node metastasis staging in predicting patient outcomes.13,14

Previous studies have demonstrated that many factors can affect CB prognosis. For example, it has been reported that CB lesions located in the pelvis and proximal humerus have a poor prognosis.15,16 Similarly, studies have found that patient age and secondary cyst formation within the lesion are significantly associated with postoperative CB recurrence.16–18 However, there is currently a lack of studies analyzing the clinical implications of TAMs in CB. Considering the locally aggressive feature and potentially malignant transformation of CB, we consider similarities in the functional role of TAM among CB and cancers. Moreover, assessing the effect of microenvironmental TAMs on the biological behavior of CB may help optimize preoperative risk stratification and provide direction for the development of new therapeutic approaches. In this study, we aimed to analyze the relationship between TAM parameters (including the densities of CD68+ and CD163+ cells as well as the CD163+/CD68+ ratio) and the clinicopathological characteristics and survival of patients.

Methods and Materials

Patients and Tissue Samples

A total of 132 CB patients who underwent surgical resection at the Second Xiangya Hospital from July 1, 2002, to April 30, 2020, were retrospectively included in this study. Patients’ characteristics are detailed in Table 1. Demographic information (age and sex), clinical features (including tumor location, tumor size, duration of symptoms, preoperative and postoperative neurological status) and treatment (including type of surgery, radiotherapy and chemotherapy) were directly obtained from medical records. Surrounding tissue invasion by tumors was recorded when the tumor lesion had an extraosseous invasion into surrounding tissues, which was evaluated by preoperative magnetic resonance imaging (MRI).19 Tumors were recorded as axial chondroblastoma (ACB) or extra-axial chondroblastoma (EACB), according to the site involved. The pathological diagnosis was independently confirmed by two neuropathologists based on hematoxylin and eosin (HE)-stained sections, and the presence of aneurysmal bone cyst (ABC) and chicken-wire calcification in the tumor tissue was also assessed. Analyzing the expression levels of several key proteins (including CD34, Ki-67 and p53) in CB tissues was also performed, which was detailed below. The type of surgical resection was classified as Enneking appropriate (EA) or Enneking inappropriate (EI) based on the pathological analysis of the postoperative specimens.20 The revised response evaluation criteria for solid tumors were used to evaluate the efficacy of radiotherapy21 and patients were divided into ineffective group (tumor had progression in images) or effective group (tumor had complete remission, partial remission, or was stable) according to this method. In this study, we included patients harboring histopathologically confirmed CB, irrespective of whether tumors invaded the axial or extra-axial skeleton. In addition, we restricted our cohort to patients who had only received surgery with or without adjuvant radiotherapy. Patients who had previously received other tumor-specific treatments (such as chemotherapy) and those who had any other comorbidities (such as immunocompromised state) were excluded from this study, considering that both situations could likely distort the true TAM profile within the CB microenvironment.19

Table 1

Association Between TAMs Parameters and Clinicopathological Features of Chondroblastoma Patients

Factors	Categories	Number of Patients	CD68+ Cells Density		CD163+ Cells Density		CD163/CD68 Ratio
			Mean Level	P-value	Mean Level	P-value	Mean Level	P-value
Age (years)	Young (≤ cutoffa)	105	527.2± 199.9	0.067	257.6 ± 100.8	0.429	0.52 ± 0.20	0.298
	Old (> cutoffa)	27	606.7 ± 197.3		275.0 ± 103.7		0.48 ± 0.18
Gender	Female	46	544.0 ± 215.7	0.982	254.0 ± 96.4	0.550	0.50 ± 0.18	0.646
	Male	86	543.2 ± 194.3		265.0 ± 104.1		0.52 ± 0.20
Duration of symptoms (months)	Short (≤ cutoffa)	118	536.8 ± 199.4	0.274	260.0 ± 99.6	0.710	0.52 ± 0.19	0.458
	Long (> cutoffa)	14	599.3 ± 210.7		270.7 ± 117.4		0.49 ± 0.19
Tumor size (in diameter, cm)	Small (≤ cutoffa)	28	486.1 ± 166.0	0.057	233.9 ± 84.2	0.073	0.51 ± 0.16	0.270
	Large (> cutoffa)	104	558.9 ± 1207.7		268.5 ± 104.5		0.52 ± 0.20
Type of resection	EA	65	517.4 ± 206.5	0.144	254.3 ± 99.0	0.446	0.52 ± 0.17	0.635
	EI	67	568.7 ± 194.2		267.8 ± 103.6		0.51 ± 0.21
Surrounding tissue invasion	No	65	512.4 ± 187.0	0.081	231.7 ± 85.4	0.001	0.48 ± 0.16	0.053
	Yes	67	573.5 ± 211.1		289.7 ± 107.6		0.54 ± 0.22
Adjuvant radiotherapy	No	98	539.4 ± 200.3	0.746	262.2 ± 102.3	0.040	0.52 ± 0.20	0.021
	Ineffective	26	542.3 ± 208.1		282.3 ± 102.0		0.55 ± 0.17
	Effective	8	596.4 ± 208.5		179.3 ± 16.4		0.34 ± 0.12
Preoperative neurological dysfunction	No	97	544.2 ± 205.5	0.290	254.1 ± 100.6	0.181	0.49 ± 0.18	0.027
	Yes	35	513.6 ± 188.2		280.1 ± 101.9		0.58 ± 0.22
Postoperative neurological dysfunction	No	53	547.5 ± 197.9	0.851	242.0 ± 94.6	0.070	0.48 ± 0.19	0.081
	Yes	79	540.7 ± 204.6		274.0 ± 104.0		0.54 ± 0.19
Secondary ABC	No	74	548.4 ± 205.9	0.753	255.4 ± 95.9	0.472	0.50 ± 0.19	0.510
	Yes	58	537.2 ± 196.7		268.5 ± 108.0		0.53 ± 0.20
Chicken-wire calcification	No	63	532.5 ± 197.7	0.553	253.5 ± 100.7	0.407	0.50 ± 0.18	0.589
	Yes	69	533.4 ± 205.3		268.2 ± 102.0		0.52 ± 0.21
Tumor location	Axial	61	602.4 ± 212.8	0.002	322.5 ± 103.8	< 0.001	0.58 ± 0.23	< 0.001
	Extra-axial	71	492.8 ± 176.9		208.4 ± 61.9		0.46 ± 0.13
Tumoral p53 expression	Low (≤ cutoffa)	101	544.9 ± 203.6	0.882	260.3 ± 102.3	0.861	0.51 ± 0.20	0.819
	High (> cutoffa)	31	538.7 ± 196.4		264.0 ± 99.2		0.52 ± 0.18
Tumoral CD34 expression	Low (≤ cutoffa)	77	551.4 ± 202.0	0.704	239.4 ± 90.5	0.004	0.48 ± 0.19	0.036
	High (> cutoffa)	55	574.0 ± 205.9		291.7 ± 108.2		0.56 ± 0.19
Tumoral Ki-67 expression	Low	88	522.4 ± 195.6	0.090	242.8 ± 94.1	0.005	0.50 ± 0.18	0.156
	High	44	585.5 ± 208.0		297.9 ± 106.0		0.55 ± 0.22

Notes: Bold values indicate P < 0.05; ABC, aneurysmal bone cyst; p53, protein 53; TAMs, tumor-associated macrophages; aCutoff points were obtained by the “surv_cutpoint” function in the “survminer” package of R software. Cutoff points for patient age, duration of symptoms, tumor size, tumoral p53 expression, and tumoral CD34 expression in the survival analysis of OS were 38, 16, 2.0, 194, and 115 respectively.

Formalin-fixed paraffin-embedded blocks from 132 CB patients were retrieved from the Department of Pathology and sectioned into 4-μm-thick tissue sections for subsequent assays. This study was approved by our hospital ethics committee, and informed consent was obtained from all patients before commencing of the study.

Follow-Up of Patients

All patients received regular clinical and radiological follow-ups after surgery, and the last follow-up was performed in September 2020. As 24 patients died before the final follow-up date and 2 patients were lost during the follow-up period, only 106 patients were visited in hospital for the final follow-up. The primary outcome parameters of interest were local recurrence-free survival (LRFS) and overall survival (OS). LRFS was defined as the time interval between tumor resection and the first local recurrence, which was assessed by MRI findings and/or pathological results of surgically resected specimens,22 and OS was determined as the time interval between surgical resection of the tumors and patient death from all causes. The event was recorded as censored if no tumor relapse was observed (for LRFS analysis) or the patient was still alive (for OS analysis).

Immunohistochemistry

Immunohistochemical staining was performed as we previously described.23 Briefly, paraffin-embedded sections (4 μm) of 132 CB specimens from our institute were deparaffinized in xylene, rehydrated with a graded series of ethanol solutions and then rinsed in distilled water. The tissue sections were then treated with primary antibodies () at 4°C overnight following antigen retrieval and blocking. After incubation with secondary biotinylated goat anti-rabbit or anti-mouse immunoglobulin, immunodetection was conducted with a streptavidin–peroxidase conjugate (Auragene, Changsha, Hunan, China), followed by visualization with the 3,3ʹ-diaminobenzidine solution and counterstaining with hematoxylin. A negative control was produced by replacing the primary antibody with a phosphate buffer solution, and a positive control was generated using human testis tissues according to a previous report.14

Evaluation of Immunohistochemistry

Semiquantitative Analysis

Immunohistochemical results were evaluated as we have previously documented.24 Briefly, using a light microscope, immunostained tissue sections were independently scored by two experienced neuropathologists who were blinded to patient data and had profound expertise in neuro-oncology. All discrepancies were resolved by consensus. Brown cytoplasmic or nuclear staining of tumor cells was recorded as positive for protein 53 (p53) and CD34 expression. Tissue sections were first scanned at low power, and five high-power fields were then randomly selected, with at least 1000 cells counted for each field. After this, the staining intensity of tumor cells in tissue sections was graded by neuropathologists as 0 (negative), 1 (weak), 2 (moderate), and 3 (strong) according to a previously described method.19,25 The staining percentage was counted as the ratio of positively stained cells to the total number of cells assessed. For each case, the staining intensity (0–3) and staining percentage (0–100%) scores were multiplied to generate the final data. Noticeably, the Ki-67-staining index score was determined as the percentage of cells with nuclear staining, and these data were separated into low (< 10%) or high (≥ 10%) Ki-67 expression as previously suggested.26

Automated Image Analysis

Automated quantitative analysis of CD68+ and CD163+ cells was performed as previously described.19,27 Briefly, sections were viewed in regions where TAM was focally rich using Nikon’s inverted Eclipse Ti microscope, and images representative of regions of interest were taken by a Nikon DS-Ri 1-U3 digital camera (Tokyo, Japan) with NIS-Elements image analysis software AR 3.0. The number of TAMs was then counted in 5 areas (20x) using a computer-assisted image analysis method (Image-Pro Plus 6.0, Media Cybernetics Inc., Rockville, Maryland). Finally, measurements were determined as the mean number of positively stained cells per tissue surface unit in square millimeters (mm2).

Statistical Analysis

All statistical analyses were performed using SPSS 17.0 (IBM Inc., Armonk, New York). Categorical data are presented as frequencies and were analyzed by the chi-square test. Quantitative data are presented as the mean ± standard deviation and were analyzed by Student’s t-test or one-way ANOVA. The “surv_cutpoint” function in the “survminer” package of R software (version 3.6.2, R Foundation for Statistical Computing, Vienna, Austria) was used to determine cutoff values for continuous variables in survival analysis, with OS as the outcome parameter ( and ).28 Patients were divided into two subgroups (≤ cutoff or > cutoff) according to these cutoff points. Specifically, this threshold value was defined as the point with the lowest P value from the Log rank test, which was corrected accordingly.29 Univariate analysis using the Kaplan–Meier method was applied to analyze the survival difference between groups. Multivariate Cox proportional hazard models were used to identify independent predictors for LRFS and OS after controlling for other covariates that were significant in univariate analysis. All tests were two-sided, and a P ≤ 0.05 was considered statistically significant.

Results

Patient and Tumor Characteristics

A total of 132 patients with CB were included in this study. Among them, 61 patients had ACB, and 71 patients had EACB (Figure 1). Sixty-five patients underwent EA resection, and 67 patients underwent EI resection. The average values for age, duration of symptoms and tumor size are 29.2 ± 13.4 years, 8.3 ± 7.4 months, and 3.9 ± 1.8 cm, respectively. Thirty-four patients received adjuvant photon radiotherapy after surgery. The average dose was 39.6 Gy/22 F, and the number of radiations ranged from 5 to 20. The mean levels of CD68+ and CD163+ cells and the CD163/CD68 ratio were 543.4 ± 201.2 (cells/mm2), 261.2 ± 101.2 (cells/mm2) and 0.51 ± 0.19, respectively. Similarly, the average immunostaining scores for p53, CD34 and Ki-67 in tumor tissues were 165.2 ± 48.5, 144.1 ± 62.9, and 10.1 ± 11.2, respectively. The mean follow-up time was 76.0 months. The median LRFS was 192.0 months, and the 1-, 3- and 5-year LRFS rates were 86%, 78%, and 75%, respectively. The median OS was 180.0 months, and the OS rates at 3 years, 5 years, and 10 years were 90%, 84%, and 70%, respectively. Based on the cutoff values obtained by R software, we divided TAM data as well as p53 and CD34 data into two groups (low or high expression) for subsequent survival analysis. Representative images of TAMs and immunohistochemical markers are shown in Figure 2.

Figure 1

Distribution of the tumor site for 132 chondroblastoma patients.

Figure 2

Representative images of tumor-associated macrophages parameters and immunohistochemical markers in chondroblastoma tissues.

Association Between TAM Levels and Clinicopathological Features

The results of the association between TAM parameters and patient features are shown in Table 1. We found that the number of macrophages was significantly higher in ACB tissue than in EACB tissue. The density of CD163+ TAMs was positively correlated with tumor invasion of surrounding tissues and high Ki-67 and CD34 expression on tumor cells. In contrast, CD163+ cell density and the CD163/CD68 ratio were negatively associated with the patient response to radiotherapy (Figure 3).

Table 2

Univariate Analysis of the Prognostic Factors of Local Recurrence-Free Survival in Patients with Chondroblastoma

Factors	Categories	Number of Patients	Univariate Analysis
			χ2	P-value
Age (years)	Young (≤ cutoffa)	105	2.366	0.124b
	Old (> cutoffa)	27
Gender	Female	46	3.555	0.059
	Male	86
Duration of symptoms (months)	Short (≤ cutoffa)	118	0.483	0.487b
	Long (> cutoffa)	14
Tumor size (in diameter, cm)	Small (≤ cutoffa)	28	0.204	0.652b
	Large (> cutoffa)	104
Type of resection	EA	65	16.492	< 0.001
	EI	67
Surrounding tissue invasion	No	65	12.131	< 0.001
	Yes	67
Adjuvant radiotherapy	No	98	12.977	0.002
	Ineffective	26
	Effective	8
Preoperative neurological dysfunction	No	97	0.456	0.499
	Yes	35
Postoperative neurological dysfunction	No	53	2.860	0.091
	Yes	79
Secondary ABC	No	74	1.073	0.300
	Yes	58
Chicken-wire calcification	No	63	1.209	0.272
	Yes	69
Tumor location	Axial	61	3.388	0.066
	Extra-axial	71
Tumoral p53 expression	Low (≤ cutoffa)	101	0.594	0.441b
	High (> cutoffa)	31
CD163+ cells density	Low (≤ cutoffa)	103	24.834	< 0.001b
	High (> cutoffa)	29
CD68+ cells density	Low (≤ cutoffa)	91	14.683	< 0.001b
	High (> cutoffa)	41
CD163/CD68 ratio	Low (≤ cutoffa)	22	2.286	0.131b
	High (> cutoffa)	110
Tumoral CD34 expression	Low (≤ cutoffa)	77	3.333	0.068b
	High (> cutoffa)	55
Tumoral Ki-67 expression	Low	88	1.661	0.197
	High	44

Notes: Bold values indicate P < 0.05; ABC, aneurysmal bone cyst; p53, protein 53; aCutoff points were obtained by the “surv_cutpoint” function in the “survminer” package of R software; Cutoff points for patient age, duration of symptoms, tumor size, tumoral p53 expression, tumoral CD34 expression, CD163+ cells density, CD68+ cells density, and CD163/CD68 ratio in the survival analysis of OS were 38, 16, 2.0, 194, 115, 392, 698, and 0.3, respectively. bP value from the Log rank test was corrected as previously suggested.

Figure 3

The relationship between tumor-associated macrophages parameters and response to radiotherapy in patients with chondroblastoma.

Influence of TAM on Survival of CB Patients

LRFS

Univariate Kaplan-Meier analysis showed that the number of CD68+ and CD163+ lymphocytes significantly affected patient survival (Table 2 and Figure 4). In addition, our analysis also revealed that type of resection, presence of surrounding tissue invasion by tumors and adjuvant radiotherapy were significantly associated with LRFS (Table 2). A multivariate Cox regression model showed that the resection modality and microenvironmental CD163+ and CD68+ cell levels could independently predict LRFS (Figure 5).

Figure 4

Kaplan–Meier curves of local recurrence-free survival of chondroblastoma patients stratified by CD68+ cell density and CD163+ cell density.

Figure 5

Multivariate Cox proportional hazard analyses of prognostic factors for local recurrence-free survival in patients with chondroblastoma. The results showed that type of surgery, densities of CD163+ and CD68+ cells were significant predictors of patients’ local recurrence-free survival (bold values used in the Figure indicate P < 0.05). Patients with Enneking inappropriate tumor resection and high number of CD163+ and CD68+ cells had a 4.124-, 2.929- and 2.236-times higher risk of chondroblastoma recurrence after surgery than their counterparts, respectively.

OS

Univariate Kaplan-Meier analysis showed that CD68+ and CD163+ cell counts and the CD163/CD68 ratio significantly influenced OS (Table 3 and Figure 6). Moreover, our results also indicated that type of surgery, presence of tumor infiltration into surrounding tissues, adjuvant radiotherapy, and postoperative neurological status were closely related to survival (Table 3). Further, multivariate Cox regression analysis identified TAM data and modality of tumor resection as independent predictors of patient OS (Figure 7).

Table 3

Univariate Analysis of the Prognostic Factors of Overall Survival in Patients with Chondroblastoma

Factors	Categories	Number of Patients	Univariate Analysis
			χ2	P-value
Age (years)	Young (≤ cutoffa)	105	2.707	0.100b
	Old (> cutoffa)	27
Gender	Female	46	3.281	0.070
	Male	86
Duration of symptoms (months)	Short (≤ cutoffa)	118	1.071	0.313b
	Long (> cutoffa)	14
Tumor size (in diameter, cm)	Small (≤ cutoffa)	28	3.102	0.078b
	Large (> cutoffa)	104
Type of resection	EA	65	9.855	0.002
	EI	67
Surrounding tissue invasion	No	65	7.554	0.006
	Yes	67
Adjuvant radiotherapy	No	98	9.865	0.007
	Ineffective	26
	Effective	8
Preoperative neurological dysfunction	No	97	0.397	0.529
	Yes	35
Postoperative neurological dysfunction	No	53	8.002	0.005
	Yes	79
Secondary ABC	No	74	0.119	0.730
	Yes	58
Chicken-wire calcification	No	63	0.556	0.456
	Yes	69
Tumor location	Axial	61	0.018	0.893
	Extra-axial	71
Tumoral p53 expression	Low (≤ cutoffa)	101	2.195	0.138b
	High (> cutoffa)	31
CD68+ cells density	Low (≤ cutoffa)	91	15.310	< 0.001b
	High (> cutoffa)	41
CD163+ cells density	Low (≤ cutoffa)	103	13.614	< 0.001b
	High (> cutoffa)	29
CD163/CD68 ratio	Low (≤ cutoffa)	22	7.267	0.007b
	High (> cutoffa)	110
Tumoral CD34 expression	Low (≤ cutoffa)	77	1.705	0.192b
	High (> cutoffa)	55
Tumoral Ki-67 expression	Low	88	0.582	0.445
	High	44

Notes: Bold values indicate P < 0.05; ABC, aneurysmal bone cyst; p53, protein 53; aCutoff points were obtained by the “surv_cutpoint” function in the “survminer” package of R software; Cutoff points for patient age, duration of symptoms, tumor size, tumoral p53 expression, tumoral CD34 expression, CD163+ cells density, CD68+ cells density, and CD163/CD68 ratio in the survival analysis of OS were 38, 16, 2.0, 194, 115, 392, 698, and 0.3, respectively. bP value from the Log rank test was corrected as previously suggested.

Figure 6

Kaplan–Meier curves of overall survival of chondroblastoma patients stratified by CD68+ cell density, CD163+ cell density and CD163/CD68 ratio.

Figure 7

Multivariate Cox proportional hazard analyses of prognostic factors for overall survival in patients with chondroblastoma. The results showed that type of surgery, density of CD163+ cells and CD163/CD68 ratio were significant predictors of patients’ overall survival (bold values used in the Figure indicate P < 0.05). Patients with Enneking inappropriate tumor resection and high number of CD163+ cells had a 3.286- and 6.354-times higher risk of death after surgery than their counterparts, respectively. However, patients with low CD163/CD68 ratio within the chondroblastoma microenvironment were 0.194 times less likely to have death following surgery than those harboring high CD163/CD68 ratio.

Subgroup Analysis for the Prognostic Performance of TAMs Stratified by Significant Clinical Predictors in Univariate Analysis

Subgroup analysis based on tumor location revealed that the number of CD163+ TAMs was significantly associated with LRFS and OS in ACB patients (). In the EACB group, however, the results showed that TAM parameters significantly affected patient outcomes ().

Similarly, in patients who did not receive radiotherapy, we found that the number of CD163+ and CD68+ cells was associated with LRFS, while CD163+ and CD68+ cell densities as well as the CD163/CD68 ratio were correlated with OS (). In contrast, regarding patients who had ineffective adjuvant radiotherapy, this analysis showed that CD68+ cell density significantly affected OS (). However, due to the small sample size (n = 8), subgroup analysis was not performed in patients with good response to radiotherapy.

In patients without surrounding tissue invasion of tumors, we found that the level of CD68+ cells and the CD163/CD68 ratio was associated with OS (). However, for patients whose tumors invaded into surrounding tissues, our results revealed that CD68+ and CD163+ cell densities were closely related to patient survival ().

Discussion

In this study, we analyzed the TAM profile in the CB microenvironment and their association with the clinicopathological characteristics and survival of patients. We found that TAM parameters had a significant positive correlation with preoperative neurological deficits, surrounding tissue infiltration by tumors and high expression levels of Ki-67 and CD34 on tumor cells. Moreover, our results revealed a significant increase in TAM density for tumors located in the axial skeleton and among patients who received ineffective radiotherapy. More importantly, a multivariate Cox analysis identified CD68+ and CD163+ cell levels as independent predictors of LRFS, while CD163+ cell density and the CD163/CD68 ratio independently affected OS. These data suggest that TAMs may significantly influence the biological behavior of CB. We hypothesize that modulating TAM densities or polarization status in the microenvironment may open up a new opportunity for CB therapy.

Due to the different forms of activation and polarization,30 the prognostic value of TAMs in several cancer types is still controversial. However, a large body of evidence suggests that the levels of TAM could independently predict poor patient survival in various human malignancies.31 In line with these findings, our study showed that the number of CD68- and CD163-positive cells as well as the CD163/CD68 ratio were significantly associated with poor LRFS and/or OS of CB patients. Additionally, this study also found that TAM density was positively correlated with preoperative neurological dysfunction, tumor invasion into surrounding tissues, and a high Ki-67 index in tumor cells (the large variation in our Ki-67 data possibly indicates a different biological behavior between tumors), consistent with previous reports indicating that high TAM levels were associated with an aggressive phenotype of many cancers.32,33 Moreover, recent results from preclinical studies and clinical trials suggest that cancer patients may benefit from the use of drugs targeting the TAM.33 These data strongly imply that TAMs may influence CB development.

Currently, the specific mechanism underlying TAM affecting the clinical outcome of CB patients remains unknown. Previous studies have shown that TAMs may promote tumor initiation through the induction of angiogenesis and thus exert an effect on prognosis.33,34 Supporting this idea, we found that CD163+ cell density significantly correlated with CD34 expression in tumor tissues. These results suggest that TAMs may affect patient outcome in part by inducing CD34 expression in CB tissues. Moreover, it should be noted that CD163+ cell levels and/or the CD163/CD68 ratio were significantly associated with an aggressive CB phenotype and patient survival. It is well known that CD163 and CD163/CD68 ratios are commonly used to assess the degree of M2-type polarization of macrophages.35 Prior data found that the PI3Kγ/NF-κB pathway could regulate the polarization status of TAMs in cancer tissues.36 Further, it has been demonstrated that RANKL (as the ligand of NF-κB) expression is linked to CB progression.37 These data suggest the possibility that TAMs may influence CB outcome by regulating macrophage polarization status through the PI3Kγ/RANKL/NF-κB signaling pathway. To corroborate this speculation, our future studies will analyze the expression levels of RANKL and key proteins in PI3Kγ pathways and their association with TAM parameters. In addition, recent reports have indicated that CD47 is highly expressed in many sarcoma tissues,38 and SIRPα on TAMs can mediate immune escape by binding to CD47 to promote tumor development.39,40 Whether TAMs affect tumor progression through similar mechanisms deserves further exploration in CB.

Another major finding of this study was that the number of CD163+ macrophages and the CD163/CD68 ratio had a significantly negative association with the effectiveness of radiotherapy in CB patients. Further subgroup analysis showed that tumors with high TAM levels portended the worst survival for patients who were not treated with adjuvant radiotherapy. In agreement with this finding, it has been reported that TAMs (especially CD163+ macrophages) can increase the resistance of tumor cells to radiotherapy.41,42 In addition, studies have found that TAM parameters are correlated with the effectiveness of radiotherapy in patients with colon and head and neck cancers.43–45 Apart from this, researchers have proven that a high CD163+ cell count could predict poor response to radiotherapy and affect cause-specific survival in patients with cervical cancer.43 Altogether, these data indicate that TAMs may influence patient outcomes by increasing the resistance of CB cells to radiotherapy.

Interestingly, we also found that TAM parameters (including the number of CD68+ and CD163+ cells as well as the CD163/CD68 ratio) were significantly higher in ACB tissues than in EACB tissues. Furthermore, this analysis revealed that ACB harbored higher tumoral Ki-67 expression and an increased risk of surrounding tissue infiltration by tumors than EACB. This was also the case for patient age, tumor size, and postoperative neurological status in ACB compared to EACB, whereas other variables, including the type of surgical resection, were not significantly different between the two groups. Further subgroup analysis showed that prognostic factors were not consistent between ACB and EACB (data not shown). Taken together, these results suggest that ACB displays more aggressive behavior than EACB, similar to preceding observations showing that ACB progresses more rapidly and that patients are more likely to experience disease recurrence after surgery.3,46,47 One possible explanation could be that TAMs in the microenvironment induce an aggressive phenotype for ACB through the production of various factors or proteases,48 thereby leading to poor patient survival. This information may be useful in improving prognostic risk stratification and guiding treatment optimization for patients.

Limitations

Our study had a retrospective design. Further prospective studies with a large sample size are still needed to confirm our findings. Additionally, this study is exploratory in nature. Future studies are required to uncover the precise molecular mechanisms of how TAM affects the clinical outcome of CB patients. For example, whether TAM influences CB progression via PI3Kγ/RANKL/NF-κB or SIRPα/CD47 signaling pathways deserves further exploration. Further studies involving TAM quantification and transcriptome sequencing using pre- and postradiotherapy CB tissue samples are also needed to help confirm the exact molecular mechanisms by which TAMs promote resistance to radiotherapy. Nevertheless, despite lack of experimental data, our findings may still provide useful information for prognostic risk stratification and therapeutic optimization of patients.

Conclusion

Our data suggest that TAM may significantly affect the biological behavior of CB. We hypothesize that modulating the TAM level or polarization status in the microenvironment may be an effective therapeutic approach for patients.