Literature DB >> 28086852

PD-L1 expression in papillary renal cell carcinoma.

Takanobu Motoshima^1,2, Yoshihiro Komohara³, Chaoya Ma¹, Arni Kusuma Dewi^1,4, Hirotsugu Noguchi⁵, Sohsuke Yamada⁵, Toshiyuki Nakayama⁵, Shohei Kitada⁶, Yoshiaki Kawano², Wataru Takahashi², Masaaki Sugimoto^7,8, Motohiro Takeya², Naohiro Fujimoto⁶, Yoshinao Oda⁷, Masatoshi Eto^2,8.

Abstract

BACKGROUND: The immune escape or tolerance of cancer cells is considered to be closely involved in cancer progression. Programmed death-1 (PD-1) is an inhibitory receptor expressed on activating T cells, and several types of cancer cells were found to express PD-1 ligand 1 (PD-L1) and ligand 2 (PD-L2).
METHODS: In the present study, we investigated PD-L1/2 expression in papillary renal cell carcinoma (pRCC). RESULT: We found PD-L1 expression in 29 of 102 cases, but no PD-L2 expression was seen. PD-L1 expression was not significantly correlated with any clinicopathological factor, including progression-free survival and overall survival. The frequency of PD-L1-positive cases was higher in type 2 (36%) than in type 1 (22%) pRCC; however, there was no significant difference in the percentages of score 0 cases (p value = 0.084 in Chi-square test). The frequency of high PD-L1 expression cases was higher in type 2 (23%) than in type 1 (11%), and the frequency of high PD-L1 expression cases was higher in grade 3/4 (21%) than in grade 1/2 (13%). However, no significant association was found between PD-L1 expression and all clinicopathological factors in pRCC.
CONCLUSION: High expression of PD-L1 in cancer cells was potentially associated to highly histological grade of malignancy in pRCC. The evaluation of the PD-L1 protein might still be useful for predicting the efficacy of anti-cancer immunotherapy using immuno-checkpoint inhibitors, however, not be useful for predicting the clinical prognosis.

Entities: CellLine Chemical Disease Gene Species

Mesh：

Substances：
B7-H1 Antigen

Year: 2017 PMID： 28086852 PMCID： PMC5237189 DOI： 10.1186/s12894-016-0195-x

Source DB: PubMed Journal: BMC Urol ISSN： 1471-2490 Impact factor: 2.264

Background

Renal cell carcinoma (RCC) is a common cancer of the kidney, and the three most frequent histological subtypes are clear cell RCC (ccRCC, 70 to 80%), papillary RCC (pRCCc, 10 to 20%), and chromophobe RCC (5%) [1]. Although patients with sporadic RCC of any histological subtype usually show a good clinical outcome, patients with metastatic pRCC show a significantly worse clinical course than patients with ccRCC or chromophobe RCC [2-4]. Recent findings have indicated that MET gene　activation, which is known to promote proliferative activity and cell survival, is frequently observed in pRCC, and MET inhibitors have become a new type of therapeutic agent for patients with advanced pRCC [5, 6]. Anti-cancer immune responses were considered to play important roles in preventing cancer progression in RCC [7]; however, immunotherapy against advanced RCC such as interferon therapy and vaccine therapy has shown limited anti-cancer effects over the past fewdecades [8]. In recent years, immuno-checkpoint inhibitors have attracted much attention. Anti-CTLA-4 antibodies, which are used to treat advanced melanoma patients, have been reported to have an excellent therapeutic effect [9]. Subsequently, anti-PD-1 antibody was discovered and used to treat kidney cancer, non-small cell lung cancer and malignant melanoma patients, and superior therapeutic effects have been reported [10]. Some clinical trials demonstrated that combination therapy using anti-CTLA-4 antibody and anti-PD-1 antibody produced significant anti-cancer effects [11]. However, although the antibodies produced excellent therapeutic effects in most patients, no therapeutic effect was observed in some patients. PD-1 ligand 1 (PD-L1) expression in cancer tissues is considered to be a biomarker for predicting the therapeutic effect of immuno-checkpoint inhibitors [12]. Although some studies have demonstrated that a high expression of PD-L1 was associated with poor clinical outcomes [13-17], few studies have investigated PD-L1 expression in pRCC. Therefore, we analyzed the correlation between PD-L1 expression and clinicopathological factors in pRCC.

Methods

Patients and Samples

We reviewed 102 cases of pRCC that were excised at Kumamoto University, the University of Occupational and Environmental Health, and Kyushu University between 2001 and 2014. All samples were obtained with informed consent from patients in accordance with the study protocols that were approved by the review board of each university (Kumamoto University Hospital Review Board, Kyushu University Review Board, Review Board of University of Occupational and Environmental Health). Tissue samples of primary site were fixed in 10% neutral buffered formalin and were embedded in paraffin as per a routine method. Nuclear grade and T classification were assessed according to the World Health Organization classification. Patient characteristics, such as age, gender, Fuhrman grade, pathological TNM stage and follow-up data were retrospectively collected.

Immunohistochemistry

Rabbit monoclonal antibodies against PD-L1 (clone E1L3N) and PD-L2 (clone D7U8C) were purchased from Cell Signaling Technology (Danvers, MA, USA). Briefly, after samples were reacted with primary antibodies, they were incubated with horseradish peroxidase (HRP)-labeled goat anti-rabbit secondary antibodies (Nichirei, Tokyo, Japan). Can Get Signal Solution (TOYOBO, Tokyo, Japan) was used to dilute the antibodies for enhancing the immunoreaction. Reactions were visualized using the diaminobenzidine substrate system (Nichirei). Two pathologists (TM and YK), who were blinded to information about the samples, evaluated the immunostaining of PD-L1/2.

Cell lines

Two lymphoma cell lines (PD-L1/2-positive cell line; ATL-T, PD-L1/2-negative cell line; DAUDI) were obtained from RIKEN Cell Bank (Tsukuba, Japan), and cell block specimens were used for confirmation of specificities of anti-PD-L1/2 antibodies. Cells were fixed in 10% neutral buffered formalin and cell block samples were embedded in paraffin.

Statistics

Statistical analysis was carried out with StatMate III (Atoms, Tokyo, Japan). The simultaneous relationships between multiple prognostic factors for survival were assessed using the Cox proportional hazards model with a stepwise backwards reduction. A value of p < 0.05 was considered to be statistically significant.

Results

PD-L1/B7-H1 expression in pRCC and correlations with clinicopathological factors

At first, we confirmed the specificities of anti-PD-L1 and PD-L2 monoclonal antibodies used for immunostaining using cell block samples of two cell lines (Fig. 1a). In total, 102 resected specimens of pRCC were used for immunostaining of PD-L1/B7-H1; the characteristics of the patients are shown in Table 1. PD-L1-positive cancer cells were detected in 29 of the 102 cases, and the positive signals were detected on the cell surface membrane and cytoplasm of the cancer cells (Fig. 1b). Macrophages stained positive for PD-L1 in 4 cases (Fig. 1c), but no infiltrated lymphocytes were positive for PD-L1. Notably, neurons were strongly positive for PD-L1 in all cases (Fig. 1d). In contrast, no expression of PD-L2 was observed on any of the cancer cells or infiltrating macrophages and lymphocytes (Fig. 1e).

Fig. 1

Table 1

Characteristic of pRCC patients

Gender/Male		80
Female		22
Age (Years)
<70		60
≧70		42
Median (Years) 66		66
T classification
T1/2		82
T3/4		20
Fuhrman grade
G1/G2		72
G3/G4		30
Histological subtype
Type 1		52
Type 2		50
Clinical course
Reccurence		16
Cancer specific death 14		14

PD-L1/2 expression in pRCC a Pictures of immunostaining of PD-L1/2 in two cell lines (PD-L1/2-positive cell line; ATL-T, PD-L1/2-negative cell line; DAUDI) b Pictures of H.E. staining and immunostaining of PD-L1 in 2 cases of pRCC. Positive signals are detected most strongly in cancer cells c Positive signals for PD-L1 are also detected in macrophages d Positive signals for PD-L1 are also detected in neuronal fibers e PD-L2 is detected in dendritic cells in the lymph node, whereas no PD-L2 is observed in the cancer cells of any of the pRCC cases Characteristic of pRCC patients Next, we classified the PD-L1 staining patterns into three scores according to the percentage of PD-L1-positive cancer cells: score 0, negative or less than 2%; score 1, 2 to 30%; and score 2, more than 30% (Fig. 2a, Additional file 1 table S1). Overall, the most frequent pattern was score 0 (71%), while score 1 and score 2 comprised 11 and 18%, respectively, of the cases. Since there are two histological subtypes of pRCC (types 1 and 2), the frequencies of scores 0 1 and 2 were compared between the subtypes. The frequency of score 1/2 (PD-L1-positive) was higher in type 2 (36%) than in type 1 (22%) pRCC; however, there was no significant difference in the percentages of score 0 cases (p value = 0.084 in Chi-square test, Fig. 2). Next, the frequencies of scores 0, 1 and 2 were compared between the nuclear grades. The frequency of score 1/2 (PD-L1-positive) was slightly higher in grade 3/4 (32%) than in grade 1/2 (25%); however, there was no significant difference between grade 1/2 and grade 3/4 (p value = 0.47 in Chi-square test, Fig. 2). The percentage of score 2 seemed to be higher in Type 2 (23%) or grade 3/4 (21%) than that in Type 1 (11%) or grade 1/2 (13%); however, however, there was no significant difference (p value = 0.42 or 0.36 in Chi-square test respectively, Fig. 2). Although score 0 cases seemed to have shorter progression-free survival and longer cancer specific overall survival, there was no significant correlation between PD-L1 scores and clinical course (Fig. 3).

Fig. 2

The frequencies of scores 0, 1, and 2 in pRCC. Cases were divided into two groups by histological subtype (a) or nuclear grade (b), and the frequencies of scores 0, 1, and 2 are shown

Fig. 3

Kaplan-Meier analysis of cancer-specific overall survival and progression-free survival

The frequencies of scores 0, 1, and 2 in pRCC. Cases were divided into two groups by histological subtype (a) or nuclear grade (b), and the frequencies of scores 0, 1, and 2 are shown Kaplan-Meier analysis of cancer-specific overall survival and progression-free survival

Discussion

Expression of PD-L1 is associated with a poor clinical course in colorectal cancer, lung cancer, ovarian cancer, and ccRCC [17-22]. In this study, we demonstrated that PD-L1 expression on cancer cells is not useful as a biomarker in pRCC. PD-L1 expression is positive in approximately 50% of ccRCC cases [13, 17, 18], which is much higher than in the pRCC cases of the present study. PD-L1 expression is known to be induced by infiltrating T cell-derived interferon γ. It is well known that ccRCC is an immunogenic cancer and many T-cell infiltrations are detected in ccRCC [23]. However, T-cell infiltration was lower in pRCC than in ccRCC in our preliminary observations (data not shown). PD-L1 expression and the density of infiltrating CD8-positive T cells have been shown to be well correlated in ccRCC [24]. The differences in the frequencies of PD-L1-positive cells between ccRCC and pRCC might be due to the immunogenicity of the cancer cells. PD-L1 expression is also known to be detected in infiltrating leukocytes, including macrophages [25]; however, PD-L1 expression was observed only in macrophages in 4 of the 102 cases. PD-L1 expression in macrophages is induced by cancer-derived factors, and macrophage-derived interleukin 10 is involved in the induction of PD-L1 expression [26], suggesting that cell-cell interaction with cancer cells is necessary for PD-L1 expression in macrophages. The density of macrophages is closely associated with poor clinical prognosis in ccRCC [27], but no report has yet described the relationship between macrophages and clinical course in pRCC. The discrepancy in PD-L1 expression in macrophages between ccRCC and pRCC might be due to the induction of cell-cell interactions between cancer cells and macrophages. Although PD-L2 expression in cancer cells has been reported in ovarian cancer [16], there are much fewer studies on PD-L2 than on PD-L1 in cancer tissues. This might be due to the fact that no monoclonal antibody suitable for use on paraffin sections had been commercially available. However, a new monoclonal antibody against PD-L2 has recently been made commercially available [28], and as a result, some research articles related to PD-L2 expression have just been published. One such article stated that PD-L2 expression was seen in 49% of pRCC cases; however, no pictures were published [29]. The staining density of PD-L2 expression seemed to be lower than that of PD-L1 expression (Fig. 1a), therefore, appropriate positive or negative controls are required and should be presented in research articles to indicate whether the immunostaining procedure was correctly performed.

Conclusion

In the present study, PD-L1 expression was observed in 28% of the pRCC cases. The frequency of score 2 was high in type 2 or higher nuclear grade cases. Although PD-L1 expression appeared to be related to worse overall survival, there was no significant correlation between PD-L1 expression and clinical prognosis. Further studies are necessary to evaluate if PD-L1 expression might be useful for predicting the efficacy of anti-cancer immunotherapy using immuno-checkpoint inhibitors.

29 in total

1. PD-L1 expression as a potential predictive biomarker.

Authors: Alberto Fusi; Lucia Festino; Gerado Botti; Giuseppe Masucci; Ignacio Melero; Paul Lorigan; Paolo A Ascierto
Journal: Lancet Oncol Date: 2015-10 Impact factor: 41.316

Review 2. Renal-cell carcinoma.

Authors: Herbert T Cohen; Francis J McGovern
Journal: N Engl J Med Date: 2005-12-08 Impact factor: 91.245

3. Clinicopathologic Analysis of PD-L1 and PD-L2 Expression in Renal Cell Carcinoma: Association with Oncogenic Proteins Status.

Authors: Su-Jin Shin; Yoon Kyung Jeon; Pil-Jong Kim; Yong Mee Cho; Jaemoon Koh; Doo Hyun Chung; Heounjeong Go
Journal: Ann Surg Oncol Date: 2016-02 Impact factor: 5.344

Review 4. Prognostic Role of PD-L1 Expression in Renal Cell Carcinoma. A Systematic Review and Meta-Analysis.

Authors: Roberto Iacovelli; Franco Nolè; Elena Verri; Giuseppe Renne; Chiara Paglino; Matteo Santoni; Maria Cossu Rocca; Palma Giglione; Gaetano Aurilio; Daniela Cullurà; Stefano Cascinu; Camillo Porta
Journal: Target Oncol Date: 2016-04 Impact factor: 4.493

5. Significance of programmed cell death-ligand 1 expression and its association with survival in patients with small cell lung cancer.

Authors: Hidenobu Ishii; Koichi Azuma; Akihiko Kawahara; Kazuhiko Yamada; Yohei Imamura; Takaaki Tokito; Takashi Kinoshita; Masayoshi Kage; Tomoaki Hoshino
Journal: J Thorac Oncol Date: 2015-03 Impact factor: 15.609

6. Resistance to Antiangiogenic Therapy Is Associated with an Immunosuppressive Tumor Microenvironment in Metastatic Renal Cell Carcinoma.

Authors: Xian-De Liu; Anh Hoang; Lijun Zhou; Sarathi Kalra; Alper Yetil; Mianen Sun; Zhiyong Ding; Xuesong Zhang; Shanshan Bai; Peter German; Pheroze Tamboli; Priya Rao; Jose A Karam; Christopher Wood; Surena Matin; Amado Zurita; Axel Bex; Arjan W Griffioen; Jianjun Gao; Padmanee Sharma; Nizar Tannir; Kanishka Sircar; Eric Jonasch
Journal: Cancer Immunol Res Date: 2015-05-26 Impact factor: 11.151

7. Tumor B7-H1 is associated with poor prognosis in renal cell carcinoma patients with long-term follow-up.

Authors: R Houston Thompson; Susan M Kuntz; Bradley C Leibovich; Haidong Dong; Christine M Lohse; W Scott Webster; Shomik Sengupta; Igor Frank; Alexander S Parker; Horst Zincke; Michael L Blute; Thomas J Sebo; John C Cheville; Eugene D Kwon
Journal: Cancer Res Date: 2006-04-01 Impact factor: 12.701

8. Association of PD-L1 overexpression with activating EGFR mutations in surgically resected nonsmall-cell lung cancer.

Authors: K Azuma; K Ota; A Kawahara; S Hattori; E Iwama; T Harada; K Matsumoto; K Takayama; S Takamori; M Kage; T Hoshino; Y Nakanishi; I Okamoto
Journal: Ann Oncol Date: 2014-07-09 Impact factor: 32.976

9. Effect of papillary and chromophobe cell type on disease-free survival after nephrectomy for renal cell carcinoma.

Authors: Stephen D W Beck; Manish I Patel; Mark E Snyder; Michael W Kattan; Robert J Motzer; Victor E Reuter; Paul Russo
Journal: Ann Surg Oncol Date: 2004-01 Impact factor: 5.344

Review 10. Adjuvant therapy in renal cell carcinoma-past, present, and future.

Authors: Tobias Janowitz; Sarah J Welsh; Kamarul Zaki; Peter Mulders; Tim Eisen
Journal: Semin Oncol Date: 2013-08 Impact factor: 4.929

12 in total

1. Prognostic and clinicopathological significance of PD-L1 in patients with renal cell carcinoma: a meta-analysis based on 1863 individuals.

Authors: Zhun Wang; Shuanghe Peng; Hui Xie; Linpei Guo; Qiliang Cai; Zhiqun Shang; Ning Jiang; Yuanjie Niu
Journal: Clin Exp Med Date: 2018-01-23 Impact factor: 3.984

Review 2. Prognostic impact of PD-1 and its ligands in renal cell carcinoma.

Authors: Franziska Erlmeier; Wilko Weichert; Andres Jan Schrader; Michael Autenrieth; Arndt Hartmann; Sandra Steffens; Philipp Ivanyi
Journal: Med Oncol Date: 2017-04-21 Impact factor: 3.064

3. Accurate expression of PD-L1/L2 in lung adenocarcinoma cells: A retrospective study by double immunohistochemistry.

Authors: Yusuke Shinchi; Yoshihiro Komohara; Kimihiro Yonemitsu; Kensaku Sato; Koji Ohnishi; Yoichi Saito; Yukio Fujiwara; Takeshi Mori; Kenji Shiraishi; Koei Ikeda; Makoto Suzuki
Journal: Cancer Sci Date: 2019-07-31 Impact factor: 6.716

4. A pooled analysis of the prognostic value of PD-L1 in melanoma: evidence from 1062 patients.

Authors: Jing Yang; Meilian Dong; Yifang Shui; Yue Zhang; Zhigang Zhang; Yin Mi; Xiaoxiao Zuo; Li Jiang; Ke Liu; Zheyan Liu; Xiaobin Gu; Yonggang Shi
Journal: Cancer Cell Int Date: 2020-03-30 Impact factor: 5.722

5. The prevalence and prognostic and clinicopathological value of PD-L1 and PD-L2 in renal cell carcinoma patients: a systematic review and meta-analysis involving 3,389 patients.

Authors: Yi Lu; Yuxuan Song; Yawei Xu; Ningjing Ou; Zhen Liang; Rui Hu; Wei Zhang; Jiaqi Kang; Xianhao Wang; Li Liu; Yongjiao Yang; Xiaoqiang Liu
Journal: Transl Androl Urol Date: 2020-04

6. Open-Label, Single-Arm, Phase II Study of Pembrolizumab Monotherapy as First-Line Therapy in Patients With Advanced Non-Clear Cell Renal Cell Carcinoma.

Authors: David F McDermott; Jae-Lyun Lee; Marek Ziobro; Cristina Suarez; Przemyslaw Langiewicz; Vsevolod Borisovich Matveev; Pawel Wiechno; Rustem Airatovich Gafanov; Piotr Tomczak; Frederic Pouliot; Frede Donskov; Boris Yakovlevich Alekseev; Sang Joon Shin; Georg A Bjarnason; Daniel Castellano; Rachel Kloss Silverman; Rodolfo F Perini; Charles Schloss; Michael B Atkins
Journal: J Clin Oncol Date: 2021-02-02 Impact factor: 44.544

7. Programmed Death-Ligand 1 Expression and Its Correlation with Lymph Node Metastasis in Papillary Thyroid Carcinoma.

Authors: Hyo Jung An; Gyung Hyuck Ko; Jeong-Hee Lee; Jong Sil Lee; Dong Chul Kim; Jung Wook Yang; Min Hye Kim; Jin Pyeong Kim; Eun Jung Jung; Dae Hyun Song
Journal: J Pathol Transl Med Date: 2017-10-03

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

Authors: Takeharu Ono; Koichi Azuma; Akihiko Kawahara; Tetsuro Sasada; Satoshi Hattori; Fumihiko Sato; Buichiro Shin; Shun-Ich Chitose; Jun Akiba; Umeno Hirohito
Journal: Oncotarget Date: 2017-10-06

Review 9. Genetic, transcriptional and post-translational regulation of the programmed death protein ligand 1 in cancer: biology and clinical correlations.

Authors: Ioannis Zerdes; Alexios Matikas; Jonas Bergh; George Z Rassidakis; Theodoros Foukakis
Journal: Oncogene Date: 2018-05-16 Impact factor: 9.867

Review 10. PD-1 immunobiology in glomerulonephritis and renal cell carcinoma.

Authors: Colleen S Curran; Jeffrey B Kopp
Journal: BMC Nephrol Date: 2021-03-06 Impact factor: 2.388