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Introduction

Tumor-infiltrating immune cells, such as lymphocytes and macrophages, are associated with tumor aggressiveness, prognosis, and treatment response in several cancers, including colorectal cancer (CRC) (1–4). Several factors influence the infiltration of immune cells within the tumor, and shape both pro- and anti-tumoral immune properties (5–10). Aggressive cancer phenotypes, such as epithelial–mesenchymal transition (EMT), have been linked to the degree of immune cell infiltration (11–14). The significant correlation between vascular density and the deposition of tumor-infiltrating lymphocytes has been extensively discussed (15,16). In addition, tumor-infiltrating lymphocytes are associated with good prognosis and sensitivity to anticancer drugs in lung and ovarian cancers (17,18), whereas tumor-infiltrating macrophages are associated with treatment resistance in glioblastoma (19). However, the impact of tumor-infiltrating immune cells on sensitivity to anticancer drugs in CRC, with the frequent use of anticancer therapy for the treatment and prevention of recurrence, has not been thoroughly investigated. Therefore, it is essential to develop an immune scoring system for accurately predicting the treatment response of patients with CRC at a high risk of requiring adjuvant chemotherapy.

Several researchers have used diverse immune cell markers, such as CD3 (pan-T cell marker), CD8 (cytotoxic T cell marker), CD68 (pan-macrophage marker), and CD163 (anti-inflammatory macrophage marker), to analyze the interaction between tumor cells and immune cells in tumor microenvironments (20–24). Immunoscore (IS), an immune scoring system based on the tumor-infiltrating levels of CD8+ and CD3+ T cells in stage I–III CRC, has been established and has indicated a substantial prognostic value for overcoming existing clinical parameters (25). Moreover, Mezheyeuski et al (26) proposed an alternative immune scoring system that reflects the balance between anti- and pro-tumor immune components called the signature of immune activation (SIA). Using multicolor fluorescence staining, the SIA system combines infiltrating anti-tumor CD8+ T cells with tumor-supportive CD68+CD163+ macrophages in CRC samples. However, whether IS, based on stages I–III CRC samples using dedicated image analysis software, can help predict survival in patients with locally advanced pathological T4 (pT4) CRC, including stage IV CRC, has not been thoroughly investigated. Furthermore, multicolor fluorescence staining was used to assess CD68+CD163+ tumor-supportive macrophages with respect to SIA, which cannot be assessed by the generally available bright-field observations.

Based on previous reports regarding IS and SIA as promising prognostic immune markers in CRC, we aimed to evaluate the prognostic value of modified IS (mIS) and modified SIA (mSIA) in pT4 stage II–IV CRC using bright-field immunohistochemical immune cell observation, which is commonly used in clinical practice. Therefore, we performed immunohistochemical staining for immune cell markers such as CD3, CD8, and CD163 in surgically resected specimens from patients with pT4 CRC.

Materials and methods

Clinical samples

This study conformed to the Declaration of Helsinki and was approved by the Institutional Review Board for Clinical Research at the Gunma University Hospital (approval number: HS2023-056). Informed consent was obtained for this retrospective study using the opt-out method. This study included 78 patients with primary pT4 CRC who underwent radical surgery at the Gunma University Hospital from July 2013 to February 2020. Patients who received neoadjuvant chemotherapy or radiation therapy and those who did not undergo radical resection for distant metastases were excluded. Clinical data, including patient characteristics (age, sex, body mass index, tumor location, postoperative complications, pathological T stage, tumor size, tumor differentiation, pathological lymph node metastasis, adjuvant chemotherapy, and radical resection margins), were retrieved from medical and surgical records. Histological sections derived from the surgical specimens were employed for immune cell quantification through immunohistochemical staining. For each patient, immune cells were assessed in both the central tumor and the invasive margin from the same section. Follow-up was conducted until May 2023. The time from surgery to death from any cause was defined as overall survival (OS), and cancer-related mortality was defined as cancer-specific survival (CSS). Disease-free survival was defined as the time from surgery to the first documented disease progression, including local recurrence, distant metastasis, or death due to any reason.

Immunohistochemical staining

Paraffin-embedded CRC specimens were cut into 4-µm-thick sections. All sections were incubated at 60°C for 60 min and deparaffinized using ClearPlus (FALMA, Tokyo, Japan). The sections were rehydrated using a graded series of ethanol and subjected to antigen retrieval using Immunosaver (Nishin EM, Tokyo, Japan) at 98–100°C for 45 min. To block endogenous peroxidase activity, the sections were incubated with fresh 0.3% hydrogen peroxide in 100% methanol for 30 min at room temperature. After 30 min of blocking with Protein Block Serum-Free Reagent (Agilent, Santa Clara, USA), the specimens were incubated with primary antibodies in REAL Antibody Diluent (Agilent) at 4°C for 24 h. The following antibodies were used in this study: CD3 antibody (1:1; Ventana, Tucson, USA; 790-4341), CD8 antibody (1:400; Abcam, Cambridge, UK; ab-4055), CD163 antibody (1:500; Cell Signaling Technology, Danvers, USA; CST-93498S), E-cadherin antibody (1:400; Cell Signaling Technology; CST-3195S), and CD31 antibody (1:50; Agilent; M0823). Primary antibody staining was visualized using the Histofine Simple Stain MAX-PO (Multi) Kit (Nichirei, Tokyo, Japan) according to the manufacturer's instructions. The chromogen 3,3-diaminobenzidine tetrahydrochloride (DAB) was applied as a 0.02% solution in 50 mM ammonium acetate-citrate buffer (pH 6.0) containing 0.005% hydrogen peroxide. Finally, the sections were lightly counterstained with Mayer's hematoxylin. Negative controls were incubated without the primary antibody, and no detectable staining was evident.

Image acquisition and semi-quantitative cell counting

For the quantification of tumor-infiltrating CD3+, CD8+, and CD163+ immune cell density, 41 images covering 11.04 mm2 tissue area were obtained from each CRC slide using an All-in-One Microscope (BZ-X700, KEYENCE; Fig. 1). Four representative region images consisting of 36 views (4 regions × 9 views, total area 9.07 mm2) of the central tumor area were captured, and five representative region images (total area 1.97 mm2) of the invasive margin were captured (Fig. 1B). Tumor-infiltrating CD3+, CD8+, and CD163+ immune cell densities in the central tumor and invasive margins were determined using the Hybrid Cell Count Module (KEYENCE) as a semi-automatic image analysis software. The number of tumor-infiltrating immune cells was divided by the total area (mm2) to calculate the cell density per mm2.

Figure 1. Immune marker staining and illustration of image acquisition and analysis. (A) Representative images of high and low immune cell infiltration of CD8+, CD3+ and CD163+ cells at the central tumor and invasive margin. All images were obtained at a magnification of ×200; scale bar, 100 µm. (B) A methodological illustration of image acquisition of CD8+, CD3+ and CD163+ immune cells. The panoramic image was acquired by stitching multiple images captured at ×4 magnification, images showing the hybrid cell counting process were obtained at a magnification of ×200; scale bar, 100 µm.

Analysis procedure of mIS and mSIA based on the tumor-infiltrating immune cell density

The evaluation processes of the mIS and mSIA in this study are shown in Fig. S1. Briefly, tumor-infiltrating CD3+ and CD8+ immune cell densities derived from the central tumor and invasive margins were converted into percentiles, followed by the average calculation of four percentiles: the CD8 CT percentile, CD8 IM percentile, CD3 CT percentile, and CD3 IM percentile (Fig. S1A). The cut-off value of the average mIS was determined to be 25%, according to the original IS report (25). An average mIS percentile of less than 25% was scored as low mIS and a density between 25 and 100% was scored as high mIS (Fig. S1A).

For mSIA evaluation, the formula for the mSIA ratio was as previously described (26); however, tumor-infiltrating CD163+ immune cells were recognized as tumor-supportive macrophages in this study (Fig. S1B). The density of CD8+ immune cells was divided by the sum of the densities of CD8+ and CD163+ immune cells in the central tumor region, which was further converted into percentiles. The cut-off value of the average mIS was determined to be 51.9% according to the receiver operating characteristic (ROC) curve for cancer recurrence. An average mIS percentile of less than 51.9% was scored as low mSIA, and a density between 51.9 and 100% was scored as high mSIA (Fig. S1B).

Evaluation of E-cadherin expression and CD31-positive microvessel density

To evaluate E-cadherin expression and CD31-positive microvessel density in the CRC tissues, we captured digital images at a magnification of ×200 from five representative areas. The number of cells expressing membrane E-cadherin was manually quantified by counting 100 cancer cells in each field, resulting in a total count of 500 cells per slide. The average positive cell count from five fields was used to represent the expression levels of E-cadherin in individual tumors. For microvessel density, we counted the number of CD31-positive vascular structures using five fields using ImageJ software (National Institutes of Health, USA) and calculated the average number of CD31-positive vascular structures. E-cadherin expression and microvessel density were categorized into low and high groups, respectively. The cut-off values of E-cadherin expression and microvessel density were determined according to the ROC curve for cancer recurrence. Among the 78 patients with CRC in this study, 32 (41.0%) were classified into the high E-cadherin expression group and 46 (59.0%) into the low E-cadherin expression group. Regarding the microvessel density, 44 CRC samples (56.4%) were classified into the high microvessel density group and 34 (43.6%) into the low microvessel density group.

Statistical analysis

Chi-square and Fisher's exact tests were used to determine the association between categorical variables, and the Wilcoxon signed-rank test was used to compare the means of continuous variables between the two groups. Survival rates were analyzed using the Kaplan-Meier method with the log-rank test. Univariate Cox regression analyses were performed to identify the hazard ratio (HR), confidence interval (CI), and P-value for each predictor variable. Factors with P<0.05 in the univariate analyses were included in the multivariate Cox proportional hazards model. The ROC curve was used to determine the cut-off values of mSIA, E-cadherin, and microvessel density that optimally predict cancer recurrence. Statistical analyses were performed using JMP Pro 15 (SAS Institute, Cary, NC, USA). A P-value of <0.05 was considered statistically significant.

Results

Evaluation of mIS and mSIA based on the immunohistochemical staining of tumor-infiltrating CD3+, CD8+, and CD163+ immune cells in pT4 CRC tissues

Fig. 1A shows representative images of immune cell markers, such as CD3, CD8, and CD163, in the central tumor and invasive margin of the surgically resected specimens from patients with pT4 CRC (Fig. 1A). Fig. 1B shows a methodological illustration of the image acquisition and semi-automatic cell counting process from 41 fields of view (Fig. 1B). Based on the counted immune cell density, mIS and mSIA were evaluated according to the analytical procedures (Fig. S1). CD8+ T cell density was significantly higher in the central tumor than in the invasive margin, however no significant difference was observed for the CD3+ cells. In contrast, CD163+ cell densities were significantly higher in the invasive margin than in the central tumor (Fig. S2).

Association of mIS and mSIA with clinicopathological features of patients with pT4 CRC

According to the mIS cut-off value (Fig. S1A), 64 CRC samples (82.1%) were classified into the high mIS group and 14 (17.9%) into the low mIS group (Table I). Information about mIS concerning the clinicopathological characteristics of the patients are summarized in Table I. A low mIS in the total CRC cohort (n=78) was significantly associated with low E-cadherin expression (P=0.0056), microvessel density (P=0.0061), and mSIA (P=0.0066; Table I). The low mIS group with adjuvant chemotherapy was associated with low E-cadherin expression (P=0.0588) and mSIA (P=0.0622), whereas the low mIS group without adjuvant chemotherapy was associated with positive lymph node metastasis (P=0.0390), low E-cadherin expression (P=0.0980), and low microvessel density (P=0.1032; Table I).

Table I. Relationship between clinicopathological factors and mIS in patients with pT4 colorectal cancer with and without adjuvant chemotherapy.

Table I.

Relationship between clinicopathological factors and mIS in patients with pT4 colorectal cancer with and without adjuvant chemotherapy.

	Total patients (n=78)			Adjuvant chemotherapy patients (n=50)			Non-adjuvant chemotherapy patients (n=28)
Factors	mIS high, n (%) (n=64)	mIS low, n (%) (n=14)	P-value	mIS high, n (%) (n=45)	mIS low, n (%) (n=5)	P-value	mIS high, n (%) (n=19)	mIS low, n (%) (n=9)	P-value
Age, years
<65	20 (31.2)	5 (35.7)	0.7475a	17 (37.8)	3 (60.0)	0.3772b	3 (15.8)	2 (22.2)	>0.9999b
≥65	44 (68.8)	9 (64.3)		28 (62.2)	2 (40.0)		16 (84.2)	7 (77.8)
Sex
Female	29 (45.3)	6 (42.9)	0.8670a	22 (48.9)	2 (40.0)	>0.9999b	7 (36.8)	3 (33.3)	>0.9999b
Male	35 (54.7)	8 (57.1)		23 (51.1)	3 (60.0)		12 (63.2)	6 (66.7)
Body mass index, kg/m2
≥22	24 (37.5)	7 (50.0)	0.3905a	17 (37.8)	1 (20.0)	0.6418b	7 (36.8)	6 (66.7)	0.2275b
<22	40 (62.5)	7 (50.0)		28 (62.2)	4 (80.0)		12 (63.2)	3 (33.3)
Tumor location
Colon	46 (71.9)	8 (57.1)	0.2900a	33 (73.3)	3 (60.0)	0.6108b	13 (68.4)	5 (55.6)	0.6775b
Rectum	18 (28.1)	6 (42.9)		12 (26.7)	2 (40.0)		6 (31.6)	4 (44.4)
Post-operative complications
(Clavien-Dindo; grade ≥III)
Absence	57 (89.1)	12 (85.7)	0.6602b	41 (91.1)	4 (80.0)	0.4234b	16 (84.2)	8 (88.9)	>0.9999b
Presence	7 (10.9)	2 (14.3)		4 (8.9)	1 (20.0)		3 (15.8)	1 (11.1)
Pathological T stage
pT4a	31 (48.4)	10 (71.4)	0.1471b	25 (55.6)	4 (80.0)	0.3830b	6 (31.6)	6 (66.7)	0.1139b
pT4b	33 (51.6)	4 (28.6)		20 (44.4)	1 (20.0)		13 (68.4)	3 (33.3)
Tumor size, mm
≥50	41 (64.1)	6 (42.9)	0.1461a	31 (68.9)	3 (60.0)	0.6498b	10 (52.6)	3 (33.3)	0.4348b
<50	23 (35.9)	8 (57.1)		14 (31.1)	2 (40.0)		9 (47.4)	6 (66.7)
Tumor differentiation
Well or moderately differentiated	31 (48.4)	4 (28.6)	0.2394b	22 (48.9)	2 (40.0)	>0.9999b	9 (47.4)	2 (22.2)	0.2495b
Poorly differentiated	33 (51.6)	10 (71.4)		23 (51.1)	3 (60.0)		10 (52.6)	7 (77.8)
Pathological lymph node metastasis
Absence	19 (29.7)	3 (21.4)	0.7456b	8 (17.8)	2 (40.0)	0.2581b	11 (57.9)	1 (11.1)	0.0390b,c
Presence	45 (70.3)	11 (78.6)		37 (82.2)	3 (60.0)		8 (42.1)	8 (88.9)
Distant metastasis
Absence	54 (84.4)	10 (71.4)	0.2640b	37 (82.2)	4 (80.0)	>0.9999b	17 (89.5)	6 (66.7)	0.290b
Presence	10 (15.6)	4 (28.6)		8 (17.8)	1 (20.0)		2 (10.5)	3 (33.3)
Radical resection margin
Negative	55 (85.9)	10 (71.4)	0.2345b	37 (82.2)	4 (80.0)	>0.9999b	18 (94.7)	6 (66.7)	0.0841b
Positive	9 (14.1)	4 (28.6)		8 (17.8)	1 (20.0)		1 (5.3)	3 (33.3)
E-cadherin expression
High	31 (48.4)	1 (7.1)	0.0056b,c	22 (48.9)	0 (0.0)	0.0588b	9 (47.4)	1 (11.1)	0.0980b
Low	33 (51.6)	13 (92.9)		23 (51.1)	5 (100.0)		10 (52.6)	8 (88.9)
Micro-vessel density
High	41 (64.1)	3 (21.4)	0.0061b,c	29 (64.4)	1 (20.0)	0.1432b	12 (63.2)	2 (22.2)	0.1032b
Low	23 (35.9)	11 (78.6)		16 (35.6)	4 (80.0)		7 (36.8)	7 (77.8)
mSIA
High	36 (56.3)	2 (14.3)	0.0066b,c	30 (66.7)	1 (20.0)	0.0622b	6 (31.6)	1 (11.1)	0.3715b
Low	28 (43.7)	12 (85.7)		15 (33.3)	4 (80.0)		13 (68.4)	8 (88.9)

a χ² test;

b Fisher's exact test.

c P<0.05. mIS, modified Immunoscore; mSIA, modified signature of immune activation.

According to the cut-off value of mSIA (Fig. S1), 38 CRC samples (48.7%) were classified into the high mSIA group and 40 (51.3%) into the low mSIA group (Table II). Information on mSIA concerning the clinicopathological characteristics of patients is summarized in Table II. Low mSIA was not significantly associated with any existing clinicopathological factors other than mIS (Table II).

Table II. Relationship between clinicopathological factors and mSIA in patients with pT4 colorectal cancer with and without adjuvant chemotherapy.

Table II.

Relationship between clinicopathological factors and mSIA in patients with pT4 colorectal cancer with and without adjuvant chemotherapy.

	Total patients (n=78)			Adjuvant chemotherapy patients (n=50)			Non-adjuvant chemotherapy patients (n=28)
Factors	mSIA high, n (%) (n=38)	mSIA low, n (%) (n=40)	P-value	mSIA high, n (%) (n=31)	mSIA low, n (%) (n=19)	P-value	mSIA high, n (%) (n=7)	mSIA low, n (%) (n=21)	P-value
Age, years
<65	13 (34.2)	12 (30.0)	0.6904a	12 (38.7)	8 (42.1)	0.8121a	1 (14.3)	4 (19.0)	>0.9999b
≥65	25 (65.8)	28 (70.0)		19 (61.3)	11 (57.9)		6 (85.7)	17 (81.0)
Sex
Female	15 (39.5)	20 (50.0)	0.3496a	13 (41.9)	12 (63.2)	0.1434a	2 (28.6)	8 (38.1)	>0.9999b
Male	23 (60.5)	20 (50.0)		18 (58.1)	7 (36.8)		5 (71.4)	13 (61.9)
Body mass index, kg/m2
≥22	16 (42.1)	15 (37.5)	0.6778a	13 (41.9)	5 (26.3)	0.2586a	3 (42.9)	10 (47.6)	>0.9999b
<22	22 (57.9)	25 (62.5)		18 (58.1)	14 (73.7)		4 (57.1)	11 (52.4)
Tumor location
Colon	28 (73.7)	26 (65.0)	0.4053a	24 (77.4)	12 (63.2)	0.2796a	4 (57.1)	14 (66.7)	0.6744b
Rectum	10 (26.3)	14 (35.0)		7 (22.6)	7 (36.8)		3 (42.9)	7 (33.3)
Post-operative complications
(Clavien-Dindo; grade ≥III)
Absence	34 (89.5)	35 (87.5)	>0.9999b	29 (93.6)	16 (84.2)	0.3551b	5 (71.4)	19 (90.5)	0.2530b
Presence	4 (10.5)	5 (12.5)		2 (6.4)	3 (15.8)		2 (28.6)	2 (9.5)
Pathological T stage
pT4a	19 (50.0)	22 (55.0)	0.6584a	17 (54.8)	12 (63.2)	0.5618a	2 (28.6)	10 (47.6)	0.6618b
pT4b	19 (50.0)	18 (45.0)		14 (45.2)	7 (36.8)		5 (71.4)	11 (52.4)
Tumor size, mm
≥50	25 (65.8)	22 (55.0)	0.3296a	21 (67.7)	13 (68.4)	0.9601a	4 (57.1)	9 (42.9)	0.6703b
<50	13 (34.2)	18 (45.0)		10 (32.3)	6 (31.6)		3 (42.9)	12 (57.1)
Tumor differentiation
Well or moderately differentiated	17 (44.7)	18 (45.0)	0.9814a	14 (45.2)	10 (52.6)	0.6078a	3 (42.9)	8 (38.1)	>0.9999b
Poorly differentiated	21 (55.3)	22 (55.0)		17 (54.8)	9 (47.4)		4 (57.1)	13 (61.9)
Pathological lymph node metastasis
Absence	10 (26.3)	12 (30.0)	0.7176a	6 (19.3)	4 (21.0)	>0.9999b	4 (57.1)	8 (38.1)	0.4184b
Presence	28 (73.7)	28 (70.0)		25 (80.7)	15 (79.0)		3 (42.9)	13 (61.9)
Distant metastasis
Absence	33 (86.8)	31 (77.5)	0.2794a	26 (83.9)	15 (79.0)	0.7152b	7 (100.0)	16 (76.2)	0.2895b
Presence	5 (13.2)	9 (22.5)		5 (16.1)	4 (21.0)		0 (0.0)	5 (23.8)
Radical resection margin
Negative	34 (89.5)	31 (77.5)	0.2259b	27 (87.1)	14 (73.7)	0.2729b	7 (100.0)	17 (81.0)	0.5453b
Positive	4 (10.5)	9 (22.5)		4 (12.9)	5 (26.3)		0 (0.0)	4 (19.0)
E-cadherin expression
High	18 (47.4)	14 (35.0)	0.2665a	14 (45.2)	8 (42.1)	0.8325a	4 (57.1)	6 (28.6)	0.2075b
Low	20 (52.6)	26 (65.0)		17 (54.8)	11 (57.9)		3 (42.9)	15 (71.4)
Micro-vessel density
High	22 (57.9)	22 (55.0)	0.7966a	18 (58.1)	12 (63.2)	0.7207a	4 (57.1)	10 (47.6)	>0.9999b
Low	16 (42.1)	18 (45.0)		13 (41.9)	7 (36.8)		3 (42.9)	11 (52.4)
mIS
High	36 (94.7)	28 (70.0)	0.0066b,c	30 (96.8)	15 (79.0)	0.0622b	6 (85.7)	13 (61.9)	0.3715b
Low	2 (5.3)	12 (30.0)		1 (3.2)	4 (21.0)		1 (14.3)	8 (38.1)

a χ² test;

b Fisher's exact test.

c P<0.05. mIS, modified Immunoscore; mSIA, modified signature of immune activation.

Prognostic impact of the mIS and mSIA in patients with pT4 CRC

We evaluated the prognostic value of mIS using survival analysis. Unexpectedly, we did not find a statistically significant difference in overall, cancer-specific, or disease-free survival between patients with high and low mIS scores (Fig. 2, top panel). The significance of mIS as a prognostic factor was analyzed with a focus on the presence or absence of adjuvant chemotherapy. However, similar to the results of the overall case analysis, no significant association was detected between the mIS and survival (Fig. 2, middle and bottom panels).

Figure 2. Kaplan-Meier survival curves stratified according to high and low mIS. The top panel shows the overall (left), cancer-specific (middle) and disease-free (right) survival of all patients with pT4 CRC (n=78), according to mIS. The middle panel shows the overall (left), cancer-specific (middle) and disease-free (right) survival of patients with pT4 CRC with postoperative adjuvant chemotherapy (n=50), according to mIS. Patients who underwent adjuvant treatment exhibited indistinguishable overall and cancer-specific survival rates. Within this specific subgroup, all deceased patients succumbed to causes directly linked to cancer. The bottom panel shows the overall (left), cancer-specific (middle) and disease-free (right) survival of patients with pT4 CRC without postoperative adjuvant chemotherapy (n=28), according to mIS. mIS, modified Immunoscore; CRC, colorectal cancer.

The same prognostic analyses were performed for the mSIA and mIS. The low mSIA group had significantly poorer overall, cancer-specific, and disease-free survival rates compared to those of the high mSIA group (Fig. 3, top panel). In patients with pT4 CRC who received adjuvant chemotherapy (n=50), low mSIA was not a significant prognostic factor (Fig. 3, middle panel). However, notably, among the patients who did not receive adjuvant chemotherapy (n=20), the low mSIA group had significantly shorter cancer-specific and disease-free survival compared to those of the high mSIA group, and the low mSIA group tended to have poorer OS than the high mSIA group (Fig. 3, bottom panel).

Figure 3. Kaplan-Meier survival curves stratified according to high and low mSIA. The top panel shows the overall (left), cancer-specific (middle) and disease-free (right) survival of all patients with pT4 CRC (n=78), according to mSIA. The middle panel shows the overall (left), cancer-specific (middle) and disease-free (right) survival of patients with pT4 CRC with postoperative adjuvant chemotherapy (n=50), according to mSIA. Patients who underwent adjuvant treatment exhibited indistinguishable overall and cancer-specific survival rates. Within this specific subgroup, all deceased patients succumbed to causes directly linked to cancer. The bottom panel shows the overall (left), cancer-specific (middle) and disease-free (right) survival of patients with pT4 CRC without postoperative adjuvant chemotherapy (n=28), according to mSIA. mSIA, modified signature of immune activation; CRC, colorectal cancer.

Table III shows the univariate and multivariate analyses of risk factors for different survival rates using the Cox regression model. Univariate analysis revealed that the mSIA was associated with OS (HR=3.6195, 95% CI: 1.2787-10.245; P=0.0154), CSS (HR=3.3266, 95% CI: 1.0118–10.936; P=0.0478), and disease-free survival (HR=2.7883, 95% CI: 1.3938-5.5783; P=0.0037). The multivariate analysis determined that the mSIA was an independent prognostic biomarker for disease-free survival (HR=2.1633, 95% CI, 1.0313-4.5376; P=0.0412; Table III). In contrast, the mIS was not identified as a significant prognostic factor in the same analyses (data not shown).

Table III. Univariate and multivariate analyses of clinicopathological factors affecting survival following surgery in patients with pT4 colorectal cancer.

Table III.

Univariate and multivariate analyses of clinicopathological factors affecting survival following surgery in patients with pT4 colorectal cancer.

	Overall survival						Cancer-specific survival						Disease-free survival
	Univariate analysis			Multivariate analysis			Univariate analysis			Multivariate analysis			Univariate analysis			Multivariate analysis
Factors	HR	95% CI	P-value	HR	95% CI	P-value	HR	95% CI	P-value	HR	95% CI	P-value	HR	95% CI	P-value	HR	95% CI	P-value
Age, years
<65	1		0.7592				1		0.9705				1		0.2888
≥65	1.1665	0.4355-					0.9790	0.3180-					1.5077	0.7060-
		3.1247						3.0140						3.2198
Sex
Female	1		0.4168				1		0.8075				1		0.6988
Male	1.4818	0.5734-					1.1453	0.3843-					1.1427	0.5813-
		3.8294						3.4135						2.2463
Body mass index, kg/m2
≥22	1		0.2725				1		0.2311				1		0.4456
<22	1.7346	0.6486-					2.0578	0.6315-					1.3041	0.6592-
		4.6391						6.7053						2.5798
Tumor location
Colon	1		0.0822				1		0.0822				1		0.2294
Rectum	2.6407	0.8835-					2.6407	0.8835-					1.5263	0.7659-
		7.8926						7.8926						3.0416
Post-operative complications
(Clavien-Dindo; grade ≥III)
Absence	1		0.7315				1		0.4824				1		0.8340
Presence	0.7720	0.1760-					0.4801	0.0619-					1.1179	0.3941-
		3.3851						3.7196						3.1711
Pathological T stage
pT4a	1		0.9876				1		0.9021				1		0.4940
pT4b	0.9923	0.3768-					1.0747	0.3406-					0.7851	0.3925-
		2.6131						3.3909						1.5703
Tumor size, mm
≥50	1		0.0147a	1		0.0817	1		0.0710				1		0.0041a	1		0.0312a
<50	3.3915	1.2711-		2.4931	0.8913-		2.8030	0.9156-					2.7130	1.3721-		2.1633	1.0723-
		9.0505			6.9731			8.5811						5.3641			4.3644
Tumor differentiation
Well or moderately differentiated	1		0.2261				1		0.1927				1		0.0470
Poorly differentiated	1.8429	0.6847-4.9599					2.2050	0.6710-7.2461					2.1064	1.0099-4.3936
Pathological lymph node metastasis
Absence	1		0.6506				1		0.7365				1		0.0648
Presence	1.3356	0.3817-					1.2989	0.2830-					2.4500	0.9465-
		4.6731						5.9610						6.3420
Distant metastasis
Absence	1		0.0218a	1		0.1006	1		0.0497a	1		0.1055	1		0.0011a	1		0.0040a
Presence	3.0515	1.1766-		2.3333	0.8486-		3.0867	1.0014-		2.5927	0.8180-		3.4543	1.6390-		3.0750	1.4314-
		7.9141			6.4157			9.5148			8.2178			7.2799			6.6058
Adjuvant chemotherapy
Presence	1		0.0015a	1		0.0229a	1		0.0909				1		0.0078a	1		0.0645
Absence	5.4394	1.9150-		3.7504	1.2009-		2.8722	0.8453-					2.6138	1.2881-		2.0519	0.9576-
		15.450			11.712			9.7587						5.3036			4.3968
Radical resection margin
Negative	1		0.4011				1		0.7294				1		0.4849
Positive	1.5295	0.5671-					1.2337	0.3753-					1.3290	0.5982-
		4.1253						4.0548						2.9528
E-cadherin expression
High	1		0.1490				1		0.2608				1		0.1010
Low	2.2695	0.7455-6.9087					2.0993	0.5763-7.6466					1.8479	0.8871-3.8495
Micro-vessel density
High	1		0.3024				1		0.5731				1		0.5825
Low	1.6379	0.6412-4.1839					1.3822	0.4483-4.2613					1.2157	0.6058-2.4394
mIS
High	1		0.0877				1		0.3958				1		0.1573
Low	2.6898	0.8640-8.3740					1.9427	0.4194-8.9969					1.9045	0.7798-4.6511
mSIA
High	1		0.0154a	1		0.2966	1		0.0478a	1		0.0807	1		0.0037a	1		0.0412a
Low	3.6195	1.2787-10.245		1.8865	0.5727-6.2138		3.3266	1.0118-10.936		2.9588	0.8760-9.9937		2.7883	1.3938-5.5783		2.1633	1.0313-4.5376

a P<0.05. mIS, modified Immunoscore; mSIA, modified signature of immune activation; HR, hazard ratio.

Discussion

In summary, we evaluated mIS and mSIA using bright-field immunohistochemical staining for CD3, CD8, and CD163 in pathological T4 CRC samples. Contrary to previously reported IS data based on tumor-infiltrating CD3 and CD8 lymphocytes in patients with stage I–III CRC, mIS levels in our T4 CRC cohort were not associated with prognosis. In contrast, in this study, low mSIA levels based on tumor-infiltrating CD8 and CD163 were significantly associated with shorter overall, cancer-specific, and disease-free survival. Moreover, a low mSIA was an independent predictor of recurrence in patients with radically resected pT4 CRC. In patients with CRC who did not receive postoperative adjuvant chemotherapy, a low mSIA was a significantly poor prognostic factor; however, this was not observed in patients receiving adjuvant chemotherapy, suggesting a meaningful relationship between adjuvant chemosensitivity and tumor immune status in CRC.

In this study, we focused on IS (assessing tumor-infiltrating lymphocytes) and SIA (assessing tumor-infiltrating lymphocytes and macrophages), which have previously been reported as promising prognostic markers in stages I–III CRC. In a previous study, a specially developed module was integrated into a commercial image analysis system for the analysis and quantitative evaluation of an IS (25). This study validated the prognostic value of the mIS assessed only using commercial-based image analysis software without a specially developed module and a few technical differences regarding the staining procedure (antigen retrieval and incubation time). We believe that our mIS resembles the IS evaluation system; however, contrary to our expectations, mIS was not a significant prognostic biomarker in our radically resected pT4 CRC cohort. This might be because our cohort only consisted of patients with stage II–IV CRC with pT4, which differs from those in previous research, which included patients with stage I–III CRC.

In contrast, a previous study on SIA utilized fluorescence multiplex staining to identify and determine CD68+ CD163+ anti-inflammatory M2-like macrophages quantitatively and performed a predictive analysis of SIA in patients with stage I–III CRC (26). This study assessed tumor-infiltrating CD163+ cells as anti-inflammatory macrophages using bright-field immunohistochemical observation. Compared to the original SIA, our mSIA has some differences, such as the single-color DAB staining detection of immune cells in a sequential section. We also did not stain the CD68 marker, as it is considered a global macrophage marker (27,28). We believe that single staining of CD163+ cells can potentially represent M2-like phenotypic populations. Many investigators have already used CD163 as a marker of M2-like macrophages, showing its prognostic significance in several cancers (29–32). Thus, we believe that our mSIA, based on CD8+ and CD163+ immune cells, could have the same efficiency as the original SIA. Consistent with our understanding, we found that the mSIA remarkably predicted poor prognosis and recurrence in patients with pT4 CRC. Although we expect that mIS and mSIA may be promising biomarkers that sensitively reflect the local tumor immune status of advanced CRC, including stage IV CRC, this was a retrospective observational study with a limited number of patients. Future studies are needed to prospectively investigate the prognostic and predictive potential of the mSIA and mIS in a larger number of advanced CRC specimens.

Our findings showed that the mSIA, a composite assessment of cytotoxic T cells and macrophages, was not significantly associated with existing clinical factors. In contrast, cases with low mIS, based on low T cell infiltration levels, showed low E-cadherin expression. T cells are recognized as target cells activated by immune checkpoint inhibitors, and the inactivation (exhaustion) of T cells is reportedly triggered by transforming growth factor-beta (TGF-β) signaling (33,34). Moreover, TGF-β signaling activation in tumor microenvironments can cause epithelial-mesenchymal transition (EMT), characterized by the loss of epithelial marker expression, increased migration and invasive ability, therapeutic resistance on the cancer cell side, and suppression of anti-tumor T cell immunity on the immune cell side (35–37). These findings suggest that EMT induction by activating TGF-β signaling in the tumor microenvironment might be one of the reasons underlying low E-cadherin expression in patients with low mIS.

Endothelial cells are crucial in controlling oxygen delivery to and circulating cell infiltration in the tissues (9,10). Furthermore, endothelial cells actively participate in immune responses by regulating immune cell trafficking and activation (8,10,38,39). Microvessel density, evaluated using CD31 staining, was lower in patients with low mIS than in those with high mIS. Our findings coincide with those of previous reports demonstrating that a high microvessel density is correlated with an increased number of tumor-infiltrating lymphocytes in various types of solid cancers (15,16). These reports propose an explanation for the association between mIS levels and the abundance of tumor-infiltrating lymphocytes.

Previous reports on melanoma have described that cases with low SIA, based on single-cell RNA sequencing data, are more resistant to immune checkpoint inhibitors (26). The current mechanism of action of immune checkpoint inhibitors includes the activation of cytotoxic T lymphocytes by antibody drugs targeting immune checkpoint proteins. Many investigators have reported low levels of tumor-infiltrating cytotoxic T cells being associated with low sensitivity to immune checkpoint inhibitors such as anti-PD-1 and anti-PD-L1 antibodies (40–43). However, the impact of tumor-infiltrating immune cells on the sensitivity to cytotoxic anticancer drugs has not been thoroughly investigated in patients with CRC. In the present study, we analyzed whether mIS and mSIA are associated with sensitivity to cytotoxic anticancer drugs in patients with radically resected pT4 CRC, with and without postoperative adjuvant chemotherapy. Our findings in the total pT4 CRC cohort, including stage IV cases (n=78), showed that patients with CRC and high mSIA had a better prognosis than those with low mSIA, consistent with the results of a previous report in a stage I–III CRC cohort. Thus, high mSIA predicted better survival because high mSIA might reflect a tumor microenvironment with high anti-tumor (CD8+ cells) components and low pro-tumoral (CD163+ cells) components. The mSIA was not associated with prognosis in patients receiving adjuvant chemotherapy (n=50). Notably, among patients with pT4 CRC who received non-adjuvant chemotherapy (n=28), the low mSIA group had significantly shorter survival than the high mSIA group. Among patients with low mSIA (n=40), the median disease-free survival time in patients undergoing adjuvant chemotherapy (n=19, 24.17 months) was higher than that in patients who did not receive adjuvant chemotherapy (n=21, 8.87 months; Fig. 3), suggesting that the tumor-infiltrating immune cells might be sensitive to adjuvant chemotherapy with cytotoxic anticancer drugs. Therefore, based on our findings, we suggest that active consideration of postoperative adjuvant chemotherapy for low mSIA cases with a high recurrence risk may improve the prognosis of advanced CRC.

This study has some limitations. First, this was a retrospective, single-institution study, and only patients with radically resected pT4 CRC were recruited. These subjects may have underestimated the significance of the mSIA and mIS in CRC. However, focusing only on stage II–IV pT4 CRCs was a unique feature of this study because the importance of tumor-infiltrating immune cells in stages I–III has already been investigated and reported in many cases. Second, in the present study we did not evaluate the microsatellite instability (MSI) and mismatch repair (MMR) status. Several studies demonstrated that MSI and MMR status are known to be associated with the presence of tumor infiltrated immune cells, treatment response, and overall prognosis in CRC (44,45). Third, this study focused on the prognostic significance of immune cells in advanced CRC; however, we only analyzed cases whose surgical specimens were available following radical resection, which might have caused a sampling bias. In the future, it is necessary to further investigate whether mSIA and mIS are associated with drug sensitivity and prognosis in stage I–IV CRC using both pretreatment biopsy and resected tumor samples. Finally, the mSIA and mIS evaluations conducted in this study differed from those in previous reports.

In conclusion, we showed a remarkably good prognostic value of high mSIA based on high CD8+ T cell and low CD163+ macrophage infiltration in patients with radically resected pT4 CRC. Evaluation of tumor-infiltrating immune cells may be a useful predictive marker of recurrence and poor prognosis in patients with locally advanced CRC. Moreover, a low mSIA was associated with poor survival and recurrence in patients with pT4 CRC who did not receive adjuvant therapy, unlike in those who received chemotherapy. Pretreatment mSIA assessment following radical CRC resection shows potential in identifying high-risk patients with pT4 CRC who require adjuvant chemotherapy.

Supplementary Material

Supporting Data

Acknowledgements

The authors would like to thank Ms. Mariko Nakamura and Ms. Kao Abe (Department of General Surgical Science, Graduate School of Medicine, Gunma University, Maebashi, Japan), and Ms. Yukiko Suto (Laboratory for Analytical Instruments, Gunma University, Maebashi, Japan) for their assistance in immunohistochemical staining. The authors would also like to thank Ms. Kyoko Miyoshi, Ms. Miyoko Suzuki, Ms. Chiho Noguchi and Ms. Saori Suto (Division of Integrated Oncology Research, Gunma University Initiative for Advanced Research, Maebashi, Japan), and Ms. Sayaka Okada and Ms. Harumi Kanai (Department of General Surgical Science, Graduate School of Medicine, Gunma University, Maebashi, Japan) for their administrative support.

Funding

The present study was supported by the Grants-in-Aid for Scientific Research from the Japan Society for the Promotion of Science (JSPS; grant nos. 23K14610, 22H02912, 22K08766 and 21K08749).

Availability of data and materials

The datasets used and/or analyzed during the current study are available from the corresponding author on reasonable request.

Authors' contributions

GD and HO collected and analyzed the image data. GD, BEO, TS and TY analyzed and interpreted the data. TS, MSo and TY confirm the authenticity of all the raw data. GD, BEO, TS and TY drafted the manuscript. MSo, TS, BEO, TY, KS and HS conceptualized the study. TS, AY, IS, CK, NN, NO, YS, TO, KO, AS, MSa, HO and MSo contributed to sample collection and data analysis. All authors read and approved the final manuscript.

Ethics approval and consent to participate

The present study conformed to the Declaration of Helsinki and was approved by the Institutional Review Board for Clinical Research at the Gunma University Hospital (approval no. HS2023-056; Maebashi, Japan). Informed consent was obtained for this retrospective study using the opt-out method.

Patient consent for publication

Not applicable.

Competing interests

The authors declare that they have no competing interests.

References