Association between PD-L1 expression combined with tumor-infiltrating lymphocytes and the prognosis of patients with advanced hypopharyngeal squamous cell carcinoma.

Limited information is available regarding the immune-related prognostic factors of patients with advanced hypopharyngeal squamous cell carcinoma (HPSCC). The expression of programmed cell death-ligand 1 (PD-L1) in tumor cells contributes to a mechanism that allows cancer cells to escape immune surveillance. We investigated whether PD-L1 or human leukocyte antigen (HLA) class I expression in tumor cells and the tumor-infiltrating lymphocyte (TIL) density were associated with the tumor response to neoadjuvant chemotherapy (NAC) and survival in patients with advanced HPSCC. We retrospectively reviewed 83 consecutive patients with stage III or IV HPSCC who received NAC. We evaluated PD-L1 and HLA class I expression and TIL density using immunohistochemistry. Univariate and multivariate analyses demonstrated that CD8+ TIL density was an independent and significant predictive factor for the response to NAC, progression-free survival (PFS) and overall survival (OS), whereas PD-L1 or HLA class I expression did not significantly correlate. The subgroup analysis revealed that a higher CD8+ TIL density without detectable PD-L1 expression tended to be associated with longer patient survival. These results suggest that PD-L1 expression levels combined with CD8+ TIL density may serve as a predictive biomarker for patients with stage III or IV HPSCC receiving NAC.

INTRODUCTION

Hypopharyngeal squamous cell carcinoma (HPSCC) accounts for 3%–5% of all head and neck squamous cell carcinoma (HNSCC) [1]. Most patients with HPSCC present with advanced disease and have the worst prognosis among those with HNSCCs arising from different anatomical sites, despite the development of treatments comprised of surgery and chemotherapy with or without radiotherapy [2].

Although neoadjuvant chemotherapy (NAC) has no clear evidence of survival benefits [3], it has been used as a treatment option for larynx-preservation in locally advanced laryngeal and hypopharyngeal cancer [4, 5]. Despite the correlation between tumor responses to NAC and patient prognosis [6, 7], few reports describing the predictive biomarkers for tumor responses to NAC are available in the context of HNSCC [8, 9].

The CD28 protein family member, programmed cell death 1 (PD-1), is a receptor expressed on the surface of T cells, which suppresses their activation and proliferation. The binding of PD-1 to its ligand, programmed cell death-ligand 1, induces apoptosis or exhaustion in activated T cells, and inhibition of this interaction enhances the antitumor activity of T cells [10]. Therefore, PD1 and PD-L1 are considered immune checkpoint molecules. PD-L1 is frequently overexpressed in many types of human cancers [10], and therefore, the PD-1/PD-L1 axis is considered to contribute to a mechanism that allows cancers to escape immune surveillance. Specific antibodies, which act as immune checkpoint blockers to inhibit the interactions between PD-1 and its ligands, PD-L1 and PD-L2, exhibit promising clinical efficacy against certain malignancies [11-13].

Currently, there is limited information available regarding the prognostic values of PD-L1 or HLA class I expression and TILs in patients with HPSCC receiving NAC. Therefore, this study aimed to evaluate the predictive relevance of these factors in patients with advanced HPSCC who received NAC.

RESULTS

Patient characteristics

The clinical characteristics of the 83 patients included in this study are presented in Table 1. The median age of the patients at diagnosis was 65 years (range: 40–80 years). A total of 79 patients (95%) were men, and 75 (90%), 6 (7%), and 2 (2%) patients had PS (0), PS (1), and PS (2), respectively. Mild (< 40 packs of cigarettes per year) and heavy (≥ 40 packs of cigarettes per year) smokers consisted of 33 (40%) and 45 (54%) patients, respectively. Moderate (10-30 g/day) and heavy (≥ 30 g/day) alcohol consumers consisted of 38 (46%) and 40 (48%) patients, respectively. Tumor histology was classified as well differentiated (30 patients), moderately differentiated (42 patients), or poorly differentiated (11 patients). The anatomical subsites were classified as pyriform sinus (70 patients), post-cricoid (6 patients), and posterior wall (7 patients). In accordance with the system adopted by the Union for International Cancer Control (UICC) TNM Classification of Malignant Tumors 7th edition [14], 16 (19%), 55 (66%), and 12 (15%) patients, respectively exhibited stage III, IVA, or IVB disease at the time of diagnosis.

Table 1

Patients’ characteristics

Characteristics		N (%)
Age (years) (n = 83)
	Median	65
	Range	40–80
Performance status
	0	75 (90)
	1	6 (7)
	2	2 (2)
Sex
	Male	79 (95)
	Female	4 (5)
Follow up (month)
	Median	32
	Range	2–127
Progression-free survival(month)
	Median	24
	Range	1–127
Overall survival (month)
	Median	32
	Range	2–127
Current status
	Dead	48 (58)
	Alive	35 (42)
Smoking status
	Never	5 (6)
	Mild	33 (40)
	Heavy	45 (54)
Alcohol status
	Never	5 (6)
	Moderate	38 (46)
	Heavy	40 (48)
Differentiation
	Well differentiated	30 (36)
	Moderately differentiated	42 (51)
	Poorly differentiated	11 (13)
Subsite
	Pyriform sinus	70 (84)
	Post cricoid	6 (7)
	Posterior wall	7 (8)
T stage
	T1	0
	T2	15 (18)
	T3	38 (46)
	T4	30 (36)
N Stage
	N0	10 (12)
	N1	13 (16)
	N2	49 (59)
	N3	11 (13)
Stage
	III	16 (19)
	IVA	55 (66)
	IVB	12 (15)
NAC categories
	PF	45 (54)
	TPF	38 (46)
Response to NAC
	Complete response	0
	Partial response	39 (47)
	Stable disease	34 (41)
	Progressive disease	10 (12)
Definitive treatment
	Surgery	48 (58)
	CCRT	29 (35)
	Palliation	6 (7)
Postoperative treatment
	None	20 (24)
	RT	20 (24)
	CCRT	8 (10)
HLA class I expression
	< 25%	35 (42)
	25–74	34 (41)
	≥ 75%	14 (17)
PD-L1 TPS
	< 1%	57 (68)
	1%–49%	13 (16)
	≥ 50%	13 (16)

NAC, neoadjuvant chemotherapy; PF, cisplatin and 5-fluorouracil; TPF, docetaxel, cisplatin, and 5-fluorouracil; TPS, tumor proportion score; CCRT, concurrent chemoradiotherapy.

Treatment protocol

The various treatments and associated tumor responses are shown in Table 1. All patients received platinum and fluorouracil-based agents as NAC as for the initial treatment. A total of 45 patients received intravenous PF (20 mg/m2 cisplatin on days 1-5 and 1000 mg/m2 5-fluorouracil on days 1-5 in one cycle) and 38 patients received TPF (60 mg/m2 docetaxel on day1, 60 mg/m2 cisplatin on day 1, and 700 mg/m2 5-fluorouracil on days 1-4 in one cycle). An evaluation of the tumor response to NAC based on the response evaluation criteria in solid tumors, was performed using computed tomography and magnetic resonance imaging. Partial responses (PR), stable disease (SD), and progressive disease (PD) were observed in 39 (47%), 34 (41%), and 10 (12%) patients, respectively. Six patients (7%) received palliative treatment because of rapid locoregional progression or the appearance of distant metastasis, 29 patients (35%) received concurrent chemoradiotherapy (CCRT) containing platinum and 5-fluorouracil-based agents, and 48 patients (58%) received surgical treatment (e.g., transoral resection or total pharyngolaryngectomy) combined with a neck dissection. Twenty (24%) and eight (10%) patients received RT and CCRT, respectively, as a post-operative treatment. Post-operative RT for primary and regional sites consisting of a single daily irradiation administered at 1.8 Gy per fraction (total: 60-61Gy), was initiated 3–4 weeks after surgery. Definitive or post-operative CCRT containing cisplatin (5 mg/m2 on days 1-15) and 5-fluorouracil (250 mg/m2 on days 115) was performed with a daily irradiation administered at 1.8 Gy per fraction (total: 61-71Gy).

PD-L1 or HLA class I expression and CD3+, CD4+, or CD8+ TIL density

We restricted our immunohistochemical analysis to PD-L1 or HLA class I expression and CD3+, CD4+, or CD8+ TIL density due to limited tissue availability. Figure 1 shows the representative staining patterns of PD-L1, HLA class I, CD3, CD4, and CD8 in the tumor specimens. PD-L1 expression was observed in the membrane, cytoplasm, or both in tumor cells and/or stromal lymphocytes. PD-L1 expression in the tumors [tumor proportion score (TPS) ≥1%] was detected in 26 (31%) patients. Regarding the expression of HLA class I in tumor cells, positive (expression level ≥ 75%), heterogeneous (expression level: 25%-74 %), and negative (expression level < 25%) staining was detected in 14 (17%), 34 (41%), and 35 (42%) of patients, respectively (Table 1). The median number of CD3+, CD4+, and CD8+ TILs were 50 (range: 0–383), 21 (range: 0–186), and 36 (range: 0–347), respectively; these values were used to discriminate patients with high or low TIL density. Although we examined the expression of P16, which was associated with HPV infection, using immunohistochemistry, the CD8+ TIL density was not correlated with the level of P16 expression (data not shown).

Figure 1

Immunohistochemical (IHC) staining patterns of PD-L1, HLA class I, CD3, CD4, and CD8 of patients with advanced hypopharyngeal squamous cell carcinoma

Representative examples of patients whose tumor proportion scores (TPS) were classified as < 1%, 1%–49%, and ≥ 50% for the membrane expression of PD-L1 are shown (A). The level of HLA class I expression was classified as < 25%, 25%–74%, and ≥ 75% (B). High or low IHC staining patterns for CD3+, CD4+, and CD8+ TILs are shown (C).

Correlation between PD-L1 or HLA class I expression and patient characteristics

The relationships between PD-L1 or HLA class I expression and patient demographics are presented in Table 2. No significant correlations were not detected between PD-L1 expression and age (p = 0.479), smoking status (p = 1.000), alcohol consumption (p = 0.488), performance status (p = 0.710), tumor differentiation (p = 0.139), T classification (p = 1.000), or N classification (p = 0.605). The correlation between PD-L1 and HLA class I expression was significant (p = 0.030); however, PD-L1 expression was not significantly associated with the CD3+ TIL density (p = 1.000). In addition, PD-L1 expression tended to be positively correlated with CD4+ (p = 0.061) and CD8+ (p = 0.061) TIL density, albeit this was not statistically significant. Of note, significant correlations were found between PD-L1 expression and CD4+ (p = 0.010) or CD8+ (p = 0.022) TIL density when these TIL densities were analyzed as continuous variables (Supplementary Figure 1).

Table 2

Relationship between PD-L1 or HLA class I expression and patients’ characteristics

Characteristic	N	PD-L1			HLA class I
		Negative	Positive	P valuea	Low	High	P valuea
	83	57	26		69	14
Age (years)
≤ 65	42	27	15	0.479	36	6	0.570
> 65	41	30	11		33	8
Smoking status
Never or Mild	38	26	12	1.000	29	9	0.151
Heavy	45	31	14		40	5
Alcohol status
Never or Moderate	43	28	15	0.488	35	8	0.773
Heavy	40	29	11		34	6
Performance status
0	75	52	23	0.710	63	12	0.617
1 or 2	8	5	3		6	2
Differentiation
Well	30	24	6	0.139	25	5	1.000
Moderately or Poorly	53	33	20		44	9
T classification
T2	15	10	5	1.000	12	3	0.711
T3–4	68	47	21		57	11
N classification
N0–1	23	17	6	0.605	18	5	0.518
N2–3	60	40	20		51	9
HLA class I
High	14	6	8	0.030	-	-	-
Low	69	51	18		-	-
CD3
High	41	28	13	1.000	30	11	0.020
Low	42	29	13		39	3
CD4
High	41	24	17	0.061	32	9	0.245
Low	42	33	9		37	5
CD8
High	41	24	17	0.061	30	11	0.020
Low	42	33	9		39	3

aFisher's exact test.

Regarding the correlation with HLA class I expression, significant differences were not detected for age (p = 0.570), smoking status (p = 0.151), alcohol consumption (p = 0.773), performance status (p = 0.617), tumor differentiation (p = 1.000), T classification (p = 0.711), N classification (p = 0.518), or CD4+ TIL density (p = 0.245). In contrast, CD3+ or CD8+ TIL density was significantly correlated with HLA class I expression (p = 0.020 and p = 0.020, respectively).

Correlation between the tumor response to NAC and patient characteristics

Patients who exhibited a partial response (PR) to NAC were defined as responders, whereas those with stable disease (SD) or progressive disease (PD) were defined as non-responders. As shown in Supplementary Figure 2, the responders to NAC were associated with a significantly better prognosis than the non-responders. The relationships between the response rate (RR) to NAC and patient demographics are presented in Table 3. In the univariate analysis, N classification (RR: N0-N1vs. N2-3, 65.2% vs. 40%; p = 0.043), CD3+ TIL density (RR: high vs. low, 58.5% vs. 35.7%; p = 0.039), and CD8+ TIL density (RR: high vs. low, 63.4% vs. 31.0%; p = 0.004) were significantly correlated with the tumor response to NAC. HLA class I expression was not included in the multivariate analysis because it was significantly correlated with PD-L1 expression, CD3+ TIL density, or CD8+ TIL density (p = 0.030, 0.020, and 0.020, respectively). The multivariate analysis demonstrated that N classification (odds ratio [OR]: 0.29; 95% confidence interval [CI]: 0.09–0.89; p = 0.031) and CD8+ TILs density (OR: 0.32; 95%CI: 0.11–0.95; p = 0.039) were significant factors for the tumor response to NAC.

Table 3

Univariate and multivariate analyses of clinicopathologic factors associated with response to NAC

Factor	N	Response rate (%)	Univariate	Multivariate
			P valueaOR (95% CI)	P valueaOR (95% CI)
Age (years)
≤ 65	42	56.1	0.102	0.154
> 65	41	38.1	2.07 (0.86–4.99)	2.02 (0.77–5.33)
Smoking status
Never or Mild	38	39.5	0.209
Heavy	45	53.3	1.75 (0.73–4.20)
Alcohol status
Never or Moderate	43	48.8	0.726
Heavy	40	45.0	0.86 (0.36–2.03)
Performance status
0	75	48.0	0.574
1 or 2	8	37.5	0.65 (0.15–2.92)
Differentiation
Well	30	50.0	0.679
Moderately or poorly	53	45.3	1.21 (0.49–2.96)
T classification
T2	15	46.7	0.978	0.628
T3-4	68	47.1	1.02 (0.33–3.11)	0.73 (0.20–2.60)
N classification
N0-1	23	65.2	0.043	0.031
N2-3	60	40.0	0.36 (0.13–0.98)	0.29 (0.09–0.89)
NAC categories
PF	45	48.9	0.706
TPF	38	44.7	0.84 (0.36–2.01)
HLA class I
High	14	57.1	0.407
Low	69	44.9	0.61 (0.19–1.95)
PD-L1
Positive	26	53.8	0.399	0.591
Negative	57	43.9	0.67 (0.26–1.70)	0.73 (0.24–2.26)
CD3
High	41	58.5	0.039	0.378
Low	42	35.7	0.39 (0.16–0.95)	0.61 (0.20–1.82)
CD4
High	41	51.2	0.446	0.711
Low	42	42.8	0.71 (0.30–1.70)	0.81 (0.28–2.39)
CD8
High	41	63.4	0.004	0.039
Low	42	31.0	0.26 (0.10–0.64)	0.32 (0.11–0.95)

aLogistic regression analysis; OR, odds ratio; CI, confidence interval; NAC, neoadjuvant chemotherapy; PF, cisplatin and 5-fluorouracil; TPF, docetaxel, cisplatin, and 5-fluorouracil.

Survival analysis

At the time of analysis, the median follow-up time for all patients was 32 months, and 35 patients (42%) were alive at the time of the last follow-up (Table 1). The median progression-free survival (PFS) and overall survival (OS) were 24 and 32 months, respectively, and PFS and OS rates at 60 months were 41.9% and 42.5%, respectively. A Kaplan-Meier analysis was performed to evaluate whether PD-L1 or HLA class I expression and CD3+, CD4+, or CD8+ TIL density were associated with PFS or OS (Figure 2). The expression of PD-L1 or HLA class I was not significantly correlated with PFS (positive vs negative: median 21.9 vs. 31.9 months, p = 0.316; high vs. low: median not reached [NR] vs. 20.5 months; p = 0.149; respectively] or OS (positive vs. negative: median 28.4 vs. 35.1 months, p = 0.397; high vs. low: median NR vs. 31.9 months, p = 0.233; respectively). Although the differences were not significant, patients with higher numbers of CD3+ TILs tended to have a longer PFS (high vs. low: median NR vs. 10.4 months; p = 0.062), but not OS (high vs. low: median NR vs. 28.4 months; p = 0.181). CD4+ TIL density did not exhibit a significant correlation with PFS (high vs. low: median 23.5 vs. 24.1 months, p = 0.382) or OS (high vs. low: median NR vs. 31.9 months, p = 0.261). In contrast, patients with higher numbers of CD8+ TILs experienced significantly longer PFS (high vs. low: median NR vs. 9.5 months; p < 0.001) and OS (high vs. low: median NR vs. 18.6 months; p = 0.001). Furthermore, the univariate analysis indicated that N classification was a significant predictive factor of OS (hazard ratio [HR]: 0.47; 95%CI: 0.21–0.93; p = 0.029) (Table 4).

Figure 2

Kaplan-Meier analysis of the progression-free survival (PFS) (A) and overall survival (OS) (B) of patients with advanced hypopharyngeal squamous cell carcinoma exhibiting positive or negative expression of PD-L1, HLA class I, and high or low CD3+, CD4+, and CD8+ TIL density. Significant differences were evaluated using a log-rank test.

Table 4

Univariate and multivariate analyses of clinicopathologic factors associated with PFS and OS

Factor	N	PFS		OS
		Univariate	Multivariate	Univariate	Multivariate
		P valueaHR (95% CI)	P valueaHR (95% CI)	P valueaHR (95% CI)	P valueaHR (95% CI)
Age (years)
≤ 65	42	0.521		0.743
> 65	41	1.20 (0.68–2.12)		1.10 (0.62–1.95)
Smoking status
Never or Mild	38	0.666		0.345
Heavy	45	1.13 (0.64–1.99)		1.31 (0.74–2.32)
Alcohol status
Never or Moderate	43	0.461		0.679
Heavy	40	0.81 (0.46–1.42)		0.89 (0.50–1.56)
Performance status
0	75	0.276		0.188	0.298
1 or 2	8	0.60 (0.28–1.58)		0.53 (0.25–1.41)	0.60 (0.26–1.65)
Differentiation
Well	30	0.672		0.943
Moderately or poorly	53	1.13 (0.62–2.01)		1.02 (0.56–1.82)
T classification
T2	15	0.464	0.581	0.437	0.602
T3–4	68	1.29 (0.63–2.45)	1.21 (0.58–2.34)	1.31 (0.64–2.50)	1.21 (0.57–2.40)
N classification
N0–1	23	0.060	0.102	0.029	0.048
N2–3	60	0.53 (0.25–1.02)	0.56 (0.26–1.11)	0.47 (0.21–0.93)	0.49 (0.22–0.99)
NAC categories
PF	45	0.263		0.417
TPF	38	0.72 (0.41–1.28)		0.78 (0.44–1.41)
HLA class I
High	14	0.127		0.209
Low	69	0.54 (0.20–1.17)		0.60 (0.22–1.30)
PD-L1
Positive	26	0.326	0.070	0.405	0.073
Negative	57	1.35 (0.73–2.43)	1.85 (0.95–3.48)	1.30 (0.42–1.45)	1.86 (0.94–3.57)
CD3
High	41	0.063	0.437	0.181	0.596
Low	42	0.59 (0.33–1.03)	0.78 (0.41–1.46)	0.67 (0.38–1.20)	0.84 (0.44–1.58)
CD4
High	41	0.385	0.517	0.260	0.301
Low	42	0.78 (0.44–1.37)	0.78 (0.42–1.44)	0.72 (0.40–1.27)	0.72 (0.38–1.34)
CD8
High	41	< 0.001	0.001	0.001	0.005
Low	42	0.34 (0.18–0.61)	0.33 (0.16–0.62)	0.38 (0.20–0.70)	0.38 (0.19–0.75)

aCox proportional hazards model. PFS, progression-free survival; OS, overall survival; CI, confidence interval; NAC, neoadjuvant chemotherapy; PF, cisplatin and 5-fluorouracil; TPF; docetaxel, cisplatin, and 5-fluorouracil.

The multivariate analyses revealed that the density of CD8+ TILs was an independent and significant predictive factor of PFS (HR: 0.33; 95%CI: 0.16–0.62; p = 0.001) and OS (HR: 0.38; 95%CI: 0.19–0.75; p = 0.005) (Table 4). In addition, the multivariate analysis revealed that N classification was a significant factor associated with OS (HR: 0.49; 95%CI: 0.22–0.99; p = 0.048 (Table 4).

Correlation between survival and PD-L1 expression combined with CD8+ TIL density

We performed subanalyses to determine whether the combination of PD-L1 expression and CD8+ TIL density could predict patient prognosis. For this purpose, patients were divided into four subgroups, which were defined by PD-L1 expression and CD8+ TIL density [15, 16]. A Kaplan-Meier analyses of PFS and OS in the four subgroups (PD-L1−/CD8high, PD-L1+/CD8high, PD-L1−/CD8low, and PDL1+/CD8low) are presented in Figure 3. The median PFS values were NR in the PD-L1−/CD8high group, 25.6 months in the PD-L1+/CD8high group, 10.8 months in the PD-L1−/CD8low group, and 7.9 months in the PD-L1+/CD8low group (p = 0.006) (Figure 3A). The univariate analysis revealed that the PFS of the CD8high group was longer than that of the CD8low group in patients negative or positive for PD-L1 expression (PD-L1+/CD8high vs PD-L1+/CD8low, p = 0.044; PD-L1−/CD8high vs PD-L1−/CD8low groups, p = 0.001, respectively). In addition, although not statistically significant, the PFS of the PD-L1−/CD8high group also tended to be longer than that of the PD-L1+/CD8high group (p = 0.072).

Figure 3

Kaplan-Meier analysis of PFS (A) and OS (B) of patients with positive or negative PD-L1 expression combined with high or low CD8+ TIL density. Significant differences were evaluated using a log-rank test.

The median OS was NR in the PD-L1−/CD8high group, 34.0 months in the PD-L1+/CD8high group, 25.1 months in the PD-L1−/CD8low group, and 14.3 months in the PD-L1+/CD8low group (p = 0.011) (Figure 3B). The univariate analysis revealed that the OS of the CD8high group was longer than that of the CD8low group in patients with negative or positive PD-L1 expression (PD-L1+/CD8high vs. PD-L1+/CD8low, p = 0.132 and PD-L1−/CD8high vs. PD-L1−/CD8low groups, p = 0.004, respectively). In addition, although not statistically significant, the OS of the PD-L1−/CD8high group also tended to be longer than that of the PD-L1+/CD8high group (p = 0.076).

DISCUSSION

CD8+ cytotoxic T cells are a crucial component of the cellular immune system and play a pivotal role in cell-mediated antitumor immune responses [17, 18]. For example, patients with HNSCC who exhibit a greater number of tumor-infiltrating CD8+ TILs are reported to survive longer [9, 19–21]. Consistent with these studies, we this study demonstrated that a higher CD8+ TIL density was significantly associated with long-term survival, indicating that CD8+ T cells may play an important role in antitumor immunity in HPSCC patients who received NAC [22]. In addition, the subgroup analysis suggested that further stratification based on PD-L1 expression could be useful for predicting the prognosis of patients with a higher CD8+ TIL density. This suggests that a co-assessment of CD8+ TIL density and PD-L1 expression may be a predictive biomarker for patients with HPSCC receiving NAC.

Several immune-related biomarkers used to predict chemotherapeutic responses have been identified for various types of cancers [23]. For example, a higher CD3+ TIL density and fewer intraepithelial macrophages in tumors have been found to exhibit a better response to NAC in patients with head and neck cancer [9]. In the present study, the multivariate analysis revealed that CD8+ TIL density was significantly associated with tumor response to NAC. To our knowledge, there have been no published reports demonstrating that CD8+ TIL density may be a useful biomarker for predicting tumor responses to NAC in patients with advanced HPSCC. Because chemotherapy has been reported to change the tumor microenvironment via high antigen exposure and the accumulation of dendritic cells, which stimulate CD8+ T cells and the type I IFN pathway [24], pre-existing CD8+ TILs may be one of the key components for efficient responses to NAC.

Negative regulatory mechanisms (e.g., increased PD-1 expression) may impact the prognostic importance of CD8+ TILs. For example, previous reports have demonstrated that patients with high PD-1+/CD8+ TILs were associated with a significantly worse prognosis compared to those with low PD-1+/CD8+ TILs [25, 26]. These findings suggest that increased PD-1 expression on CD8+ TILs may represent an exhausted state of effector cells, thus resulting in a reduced anti-tumor effect. Therefore, it may be important to investigate the level of PD-1 expression on CD8+ TILs to distinguish between functional and exhausted CD8+ TILs. However, unfortunately, we were unable to examine the PD-1 expression in TILs using immunohistochemistry in this study due to the limited number of available tumor tissues for immunohistochemistry. We would like to investigate the significance of the PD-1 expression on CD8+ TILs in patients with advanced HPSCC in future studies and to report the results in detail in future publications.

Although blockade of the PD-1/PD-L1 pathway using monoclonal antibodies is a novel therapeutic strategy for treating patients with recurrent HNSCC [27], the association between PD-L1 expression and the prognosis of patients with HNSCC has not been well described. Recent studies have demonstrated that higher levels of PD-L1 expression are associated with a poor prognosis in various types of cancers [28-32], whereas other studies have presented controversial results [33-35]. For example, PD-L1 expression was reportedly not associated with patient prognosis in laryngeal and pharyngeal squamous cell carcinoma [9, 36]. Consistent with these results, the present study did not find a significant correlation between PD-L1 expression and the prognosis of patients with stage III or IV HPSCC who received NAC.

It has been reported that IFN-γ produced by tumor-specific TILs could induce PD-L1 expression in tumor cells and/or immune cells as an adaptive immune response. Nevertheless, because CD8+ TIL density does not strictly correlate positively with PD-L1 expression, the PD-1/PD-L1 axis may function as an immune escape mechanism only in some (but not all) patients; albeit the precise mechanism remains unclear. Therefore, we considered that an evaluation of CD8+ TIL density could become more meaningful when interpreted in conjunction with PD-L1 expression on tumor cells. The Kaplan-Meier analysis demonstrated that the four subgroups defined by PD-L1 expression and CD8+ TIL density demonstrated prognostic relevance. Of note, the PD-L1+/CD8high group tended to exhibit a worse prognosis than the PD-L1−/CD8high group. In the PD-L1+/CD8high group, PD-L1 expression may be intrinsically expressed or efficiently induced as an adaptive immune escape response, possibly resulting in a worse prognosis. In contrast, in the PD-L1−/CD8high group, immune suppressive mechanisms other than the PD-1/PD-L1 axis [e.g., regulatory T cells, tumor-associated macrophages, or myeloid-derived suppressor cells (MDSCs)], may be activated for the purpose of immune escape [37, 38]; however, the specific details remain unclear. Based on our finding that the PD-L1−/CD8high group tended to have a better prognosis than the PD-L1+/CD8high group, it may be possible that PD-L1 expression could induce more efficient immune suppression than other immune escape mechanisms. Consistent with the current study, previous studies have demonstrated similar results in other tumor types (e.g., lung and gastric cancer) [16, 37].

The anti-PD-L1 antibody MPDL3280A has been reported to elicit improved clinical responses in patients with tumors that express high levels of PD-L1 and contain higher numbers of tumor-infiltrating immune cells [39]. Similarly, it has been suggested that patients with tumor cells expressing PD-L1, as well as a high density of CD8+ TILs may achieve better outcomes via an anti-PD-1 blocking antibody [38]. Further studies are required to determine the predictive relevance of a co-assessment of PD-L1 expression and CD8+ TIL density for selecting patients with HPSCC who are most likely to respond to the PD-1/PD-L1 blocking treatments.

The current retrospective study has several limitations. First, the definitive treatments of the patients following NAC were heterogeneous. Second, the tissue samples obtained using nasal endoscopy were small, and may not reflect the entire tumor. Because the expression of PD-L1 on tumor cells, as well as the TIL density are often heterogeneous even within the same tumors, an accurate evaluation of PD-L1 expression and TIL density in small biopsy samples may occasionally be difficult in this study. Third, the threshold for positive immunohistochemistry results was not formally defined, and reproducibility was not formally assessed. Therefore, future investigations and validations are warranted to harmonize and standardize testing for PD-L1 expression using an immunohistochemical analysis of larger sample sizes.

In conclusion, the current study demonstrated that a higher CD8+ TIL density was significantly associated with the tumor responses to NAC and long-term survival in patients with advanced HPSCC who received NAC. In addition, our subanalysis suggested that patients who exhibited a higher CD8+ TIL density without detectable levels of PD-L1 in tumor cells survived longer. We propose that a co-assessment of CD8+ TIL density and PD-L1 expression would have greater predictive potential compared with an evaluation of each factor alone in patients with advanced HPSCC.

MATERIALS AND METHODS

Patients

We retrospectively screened consecutive patients diagnosed with stage III or IV HPSCC at Kurume University Hospital between 2000 and 2013. The inclusion criteria were as follows: pathological diagnosis of HPSCC; NAC treatment followed by surgery, definitive concurrent chemoradiotherapy (CCRT) with combined platinum-containing chemotherapy, or palliation; and the availability of adequate histological specimens containing tumor cells. The present study was conducted in accordance with the provisions of the Declaration of Helsinki and was approved by the Institutional Review Boards of Kurume University Hospital.

Immunohistochemical analysis

We used 4-μm-thick sections of formalin-fixed, paraffin-embedded tissues. The sections were mounted on glass slides and then incubated with an anti-rabbit monoclonal antibody against PD-L1 (clone D3; Cell Signaling Technology, Danvers, MA) using a BenchMark ULTRA (Ventana Automated Systems, Inc., Tucson, AZ). Briefly, each slide was heated using the Ventana CC1 retrieval solution for 30 min and incubated with the PD-L1 antibody for 30 min. This automated system used the ultraVIEW DAB detection kit with 3, 3′ diaminobenzidine (DAB) as the chromogen (Ventana Automated Systems).

Immunohistochemical analysis of HLA class I (EMR8-5; ab70328; Abcam, Cambridge, England), CD3, CD4, and CD8 expression (Leica Microsystems, Newcastle-upon-Tyne, UK) was performed using a fully automated Bond-III system (Leica Microsystems). Briefly, each slide was treated using onboard heat-induced antigen retrieval with an epitope retrieval solution 2 for 10 min at 99°C, incubated with the antibody for 30 min at room temperature, and then incubated with a secondary antibody for 30 min at room temperature. This automated system used a Refine polymer detection kit with HRP (horseradish peroxidase)-polymer as the secondary antibody in conjunction with DAB.

All immunohistochemical analyses were evaluated by two observers (A.K. and J.A.) who were unaware of the patients’ condition. Disagreements in data interpretation were reviewed jointly, and a single consensus category was established. All patient samples for PD-L1 expression were divided into groups based on the TPS of < 1%, 1%–49%, and ≥ 50%, as detailed previously [40, 41]. Patients with PD-L1 TPS of ≥ 1% were considered positive, as described previously [42]. Regarding the expression of HLA class I, we divided the expression levels into three criteria as previously described: 1) positive, expressed on more than 75% of tumor cells; 2) heterogeneous, expressed between 25% and 74%; and 3) negative, expressed on less than 25% of tumor cells [43, 44]. Patients with positive HLA class I expression (≥75%) were defined as the high group. Furthermore, the TIL numbers were counted, and scoring was performed using a four-tier scale. We determined the median values of CD3+, CD4+, and CD8+ TILs to define the cut-off value for TIL density.

Statistical analyses

Correlations between PD-L1 or HLA class I expression and the patient characteristics were analyzed using Fisher's exact test for categorical variables. We evaluated whether variables, including PD-L1 expression, were associated with the survival of patients with stage III or IV HPSCC who received NAC, followed by definitive treatment or best supportive care. To examine the predictive factors for the NAC response, univariate and multivariate logistic regression analyses were performed. The progression-free survival (PFS) and overall survival (OS) were calculated from the date of initiating NAC to tumor relapse (locoregional recurrence, distant metastasis, or both) or death, respectively. Kaplan–Meier analysis was used to assess patient's survival, and a log-rank test was used to evaluate the significant differences between and among two or four groups, respectively. Multivariate regression analysis was performed using a Cox proportional hazards model. All tests were two-sided, and p < 0.05 indicates a statistically significant difference. The statistical analyses were conducted using JMP version 11 (SAS Institute Inc., Cary, NC).