Regulation of Immunity in Clear Cell Renal Carcinoma: Role of PD-1, PD-L1, and PD-L2
by
,
Liudmila Spirina
1,2,*
,
Zahar Yurmazov
1,
Evgeny Usynin
1,
Irina Kondakova
1,
Ekaterine Ladutko
2 and
Evgeny Choynzonov
1,2 1
Cancer Research Institute, Tomsk National Research Medical Center, 634050 Tomsk, Russia
2
Siberian State Medical University, 634050 Tomsk, Russia
*
Author to whom correspondence should be addressed.
Curr. Issues Mol. Biol. 2021, 43(2), 1072-1080; https://doi.org/10.3390/cimb43020076
Submission received: 19 August 2021
/
Revised: 31 August 2021
/
Accepted: 3 September 2021
/
Published: 6 September 2021
(This article belongs to the Section Molecular Medicine)
Abstract
:Regulation of immunity is a unique oncogenic mechanism that differs in different cancers. VHL deficient clear cell renal cell carcinomas (ccRCC) trigger the immune response resulting in cancer progression. This study aimed to investigate PD-1, PD-L1, and PD-L2 expression in ccRCC primary cancers and metastatic tissues associated with the p-VHL content, transcriptional, and growth factors expression. Methods: A total of 62 patients with RCC were enrolled in the study. Investigation of mRNA level was performed by PCR in real-time. Western blotting analysis was used for detecting the p-VHL protein content in tissues. Results: The PD-L2 prevalence in metastatic cancers is crucial in tumor progression. The VHL expression and p-VHL content determined the aggressive cancer behavior and elevated in disseminated tumors. The cancer dissemination was accompanied by an increase in both mRNA and VHL content. Conclusion: We present a new instrument targeting pathologies with p-VHL/HIF altered function that impact the PD-L2 expression through the change in transcriptional, growth factors, and AKT/mTOR modulation.
1. Introduction
Tumor immunogenicity is one of the urgent problems in modern oncology. Receptor PD-1 (Programmed cell death 1; CD279) plays a role in the cellular differentiation of immune cells [1]. Under physiological conditions, when PD-1 interacts with its ligands (PD-L1, PD-L2), an inhibitory signal is transmitted that prevents the development of an excessive immune response, triggering the processes of apoptosis of cytotoxic lymphocytes [2].
The recent analysis highlights the VHL impact on the biological processes, including metabolism, immune regulation, apoptosis, and cell movement. Its overexpression promotes immune system activation and sensitivity to interferon therapy [3]. The studies showed that PD-L1 expression levels positively correlate with VHL mutation and HIF-2α expression. VHL mutations positively correlate with PD-L1 expression in ccRCC and may influence ccRCC anti-PD-L1/PD-1 immunotherapy [4].
In the presented works, the relationship of the positive expression of PD-L1 with the sporadic and hereditary ccRCC aggressiveness is currently noted [5]. It was revealed that an association between the VHL biallelic inactivation and the PD-L1 increased expression [4]. In addition, there is evidence that if protein E3 of ubiquitin ligase is functional, an increase in the PD-L1/PD-1 will be observed [6]. Unlike PD-L1, PD-L2 has a less pronounced association with disease prognosis [7].
Currently, the prognostic role of the PD-L1 level with the cancer aggressiveness and the unfavorable outcome development is prominent [8]. Its function is currently not clearly defined. However, blocking antitumor immunity and inhibition of cytotoxic T cells and NK cells is possible, among other things, by increasing the expression of PD-L2 [9]. However, there is evidence of a greater affinity of this ligand for PD-1 receptors of immunocompetent cells [10]. It is known that the expression of PD-1, PD-L1, and PD-L2 differs in primary tumor tissues and metastases [11].
The changes in AKT/mTOR and MAPK signaling cascades in the ccRCC can influence tumorigenesis [12,13]. In addition, the expression of p-AKT is closely associated with the expression of ligands PD-L1 and PD-L2 in tumor cells [14]. The tumor withdrawal from immune surveillance occurs due to the PD-L1 and PD-L2 production by tumor cells is associated with the hypoxia initiation and the HIF-1 protein level [15,16]. In particular, for kidney cancer, a PD-L1 association with a HIF-2α high level in the presence of lymphocytic infiltration has been shown [17,18,19]. The study aimed to investigate PD-1, PD-L1, and PD-L2. Expression in ccRCC primary cancers and metastatic tissues associated with the p-VHL content, transcriptional, and growth factors expression.
2. Materials and Methods
A total of 62 patients with RCC were enrolled in the study. The retrospective study included patients with histopathologically verified RCC admitted to and nephrectomized at the Cancer Research Institute, Tomsk National Research Center, Russian Academy of Medical Sciences, Tomsk, Russian Federation. The patients underwent a physical examination, chest radiography, and computer tomography (CT) of the abdomen. Cavography or magnetic resonance imaging (MRI) was performed when vena cava tumor thrombus invasion was suspected. Patients with skeletal-associated pain or elevated serum alkaline phosphatase were assessed with bone scintigraphy. The patients were followed up according to a program, including regular clinical and radiological examinations. The median age of the patients was 57 years. The RCC therapy depends on the tumor size and its spreading to other parts of the body.
Localized RCC (T1-3N0M0) was diagnosed in 18 patients, metastatic RCC (T2-4N0-1M1) in 44 patients. All patients with localized RCC underwent surgery (partial nephrectomy or simple nephrectomy) and then followed up according to a program including regular clinical and radiological examinations. Patients with metastatic RCC received two cycles of preoperative targeted therapy with pazopanib at a dose of 800 mg daily for two months. Tumor response to targeted therapy was evaluated according to RECIST criteria. All patients underwent radical nephrectomy. The diagnosis was verified based on biopsy results.
The Local Committee approved the study for Medical Ethics, and all patients provided written informed consent (protocol code 4; 16 November 2018). Tumor tissue samples, histologically normal tissue samples adjacent to tumors, and metastatic tissues were used for investigation. Specimens were reviewed separately by two independent pathologists.
RNA extraction. The postoperative tumor samples were incubated in RNAlater solution (Ambion, 2130 Woodward St Ste 200, Austin (TX), 78744-1832, USA) for 24-h at +4 °C and then stored at −80 °C. Total RNA was extracted using the RNeasy Mini Kit (Qiagen, Bodenseeallee 20 78333 Stockach, Germany).
RT-qPCR. PCR was conducted in 25 μL reaction volumes containing 12.5 μL BioMaster HS-qPCR SYBR Blue (2X) (“Biolabmix”, 28, st. Ingenernaya, Novosibirsk, 630090, Russia) and 300 nanoM of each primers. VHL: F 5′-GGCAGGCGAATCTCTTGA-3′, R 5′-CTATTTCCTTTACTCAGCACCATT-3′; PD-L2: F 5′-GTTCCACATACCTCAAGTCCAA-3′, R 5′-ATAGCACTGTTCACTTCCCTCTT-3′; PD-L1: F 5′-AGGGAGAATGATGGATGTGAA-3′, R 5′-ATCATTCACAACCACACTCACAT-3′; PD-1-1: F 5′-CTGGGCGGTGCTACAACT-3′, R 5′-CTTCTGCCCTTCTCTCTGTCA-3′; CAIX: F 5′-GTTGCTGTCTCGCTTGGAA-3′, R 5′-CAGGGTGTCAGAGAGGGTGT-3′; HIF-1′: F 5′-CAAGAACCTACTGCTAATGCCA-3′, R 5′-TTTGGTGAGGCTGTCCGA-3′; EPAS1: F 5′-TGGAGTATGAAGAGCAAGCCT-3′, R 5′-GGGAACCTGCTCTTGCTGT-3′; NFKB1: F 5′-CGTGTAAACCAAAGCCCTAAA-3′, R 5′-AACCAAGAAAGGAAGCCAAGT-3′; RELA: F 5′-GGAGCACAGATACCACCAAGA-3′, R 5′-GGGTTGTTGTTGGTCTGGAT-3′; VEGFA: F 5′-AGGGCAGAATCATCACGAA-3′, R 5′-TCTTGCTCTATCTTTCTTTGGTCT-3′; KDR: F 5′-AACACAGCAGGAATCAGTCA-3′, R 5′-GTGGTGTCTGTGTCATCGGA-3′; 4E-BP1: F 5′-CAGCCCTTTCTCCCTCACT-3′, R 5′-TTCCCAAGCACATCAACCT-3′; AKT1: F 5′-CGAGGACGCCAAGGAGA-3′, R 5′-GTCATCTTGGTCAGGTGGTGT-3′; C-RAF: F 5′-TGGTGTGTCCTGCTCCCT-3′, R 5′-ACTGCCTGCTACCTTACTTCCT-3′; GSK3b: F 5′-AGACAAGGACGGCAGCAA-3′, R 5′-TGGAGTAGAAGAAATAACGCAAT-3′; 70S kinase alpha: F 5′-CAGCACAGCAAATCCTCAGA-3′, R 5′-ACACATCTCCCTCTCCACCTT-3′; m-TOR: F 5′-CCAAAGGCAACAAGCGAT-3′, R 5′-TTCACCAAACCGTCTCCAA-3′; PDK1: F 5′-TCACCAGGACAGCCAATACA-3′, R 5′-CTCCTCGGTCACTCATCTTCA-3′; GAPDH: F 5′-GGAAGTCAGGTGGAGCGA-3′, R 5′-GCAACAATATCCACTTTACCAGA-3′. At 95 °C for 10 min, a pre-incubation was to activate the Hot Start DNA polymerase and denature DNA and was followed by 45 amplification cycles of 95 °C denaturations at 95 °C for 10 s, 60 °C annealings at 60 °C for 20 s (iCycler iQ™, BioRad, 1000 Alfred Nobel Drive Hercules, CA 94547, USA).
The fold changes were calculated by ΔΔCt method (the total ΔΔCt = fold of cancerous/normal tissue gene level), using normal tissue. A ratio of specific mRNA/GADPH (GADPH as a respective control) amplification was then calculated.
Determination of p-VHL level in tissues. Electrophoresis SDS-PAGE (Laemmli) was used. The protein was transferred to a 0.2-/xm pore-sized PVDF membrane (GE Healthcare, Pollards Wood, Nightingales Ln, Chalfont Saint Giles HP8 4SP, UK), either at 150 mA or 100 V for one h by using a Bio-Rad Mini Trans-Blot electrophoresis cell. The membrane was incubated in a 1:2500 dilution of monoclonal mouse anti-p-VHL (Ser68) (Affinity Biosciences, 2928 Burnet Ave. Apt #6. Cincinnati, OH 45219, USA) at 4 °C overnight.
PVDF samples were incubated in Amersham ECL Western blotting detection analysis system (Amersham, Pollards Wood Nightingales Lane, Chalfont St Giles HP84SP, UK). The results were standardized using the beta-actin expression in a sample and were expressed in percentages to the protein content in non-transformed tissues. The analysis of the results was carried out using the ChemiDocTMTouch Imaging System, and their density was assessed using the ImageLab computer program (BioRad, 1000 Alfred Nobel Drive Hercules, CA 94547, USA). The level of protein in normal non-altered tissue was indicated as 100%.
Statistical analysis. Statistical analysis was performed using SPSS 19.0 software. Data were expressed as median and ranges. Mann–Whitney test was used for comparing differences in mean values. Nonparametric one-way ANOVA on ranks was carried out to test whether samples originate from the same distribution, which is used to compare two or more independent samples of equal or different sample sizes (Kruskal–Wallis test). Nonparametric correlation analysis was performed, and the Spearmen coefficient was calculated.
3. Results
3.1. PD-1, PD-L1, PD-L2 Expression in ccRCC Oncogenesis
The study revealed a relationship between PD-1 and PD-L1 ligand expression, increasing tumor size (Table 1). The mRNA level of the PD receptor decreased 5.17 and 10.1 times in patients with tumor size in patients with stage T3N0M0 and T2N0M0 compared with T1N0M0. There was also a decrease in the level of PD-L2 mRNA during tumor growth.
The presence of the disseminated form of the disease led to a decrease in PD expression by 4.75 times and an increase in PD-L2 expression by 5.3 times, respectively, compared with patients without distant metastases. A 2.69-fold decrease in the PD-L2 mRNA level in metastases was recorded compared to the primary tumor tissue.
The AKT/mTOR signaling cascade activation was found in the primary kidney tumor, both localized and disseminated cancers. PTEN loss results in the downstream activation of AKT/mTOR signaling in secondary cancer lesions and determines the survival of the overall ccRCC patients [19,20].
The associations (Figure 1) were revealed between the expression of the PD-1 gene was associated with the expression of NF-κB p50 (r = 0.30; p < 0.05), HIF-1 (r = 0.30; p < 0.05), 70S 6 kinase (r = 0.30; p < 0.05), mTOR (r = 0.30; p < 0.05), PDK (r = 0.50; p < 0.05). The PD-L1 mRNA level correlated with NF-κB p50 (r = 0.30; p < 0.05), VEGFR2 (r = 0.30; p < 0.05), VEGF (r = 0.37; p < 0.05). In turn, the expression of the PD-L2 gene was associated with the mRNA level of NF-κB p65 (r = 0.41; p < 0.05), HIF-1 (r = 0.30; p < 0.05), GSK-3β 70s 6 kinase (r = 0.30; p < 0.05). In turn, associations were noted between PD and the PD-L2 ligand (r = 0.30; p < 0.05). However, there are no correlations between the VHL expression and p-VHL with studied indicators.
3.2. VHL Expression and p-VHL Content in ccRCC Oncogenesis
The expression and content of VHL depended on the stage of the disease (criterion T) and the extent of the tumor process in ccRCC (Table 2). The VHL expression was increased by 12.5 times in patients with a T3-4N0-1M1 stage compared to T1-2N0M0. The found change was accompanied by a 5-fold decrease in the p-VHL content (Figure 2). The most significant changes were revealed when studying the prevalence of the tumor process. Substantial changes in the expression and protein level under study were observed in the metastatic tissue compared with the primary tumor. There was a decrease in the VHL expression in the metastases by 1.89 times and its content by 3.17 times compared with the primary tumor.
The expression and content of VHL depended on the stage of the disease (criterion T) and the extent of the tumor process in ccRCC (Table 3). The VHL expression was increased by 12.5 times in patients with a T3-4N0-1M1 stage than T1-2N0M0. The change was accompanied by a 5-fold decrease in the p-VHL in the patients with advanced cancers. The most significant changes were revealed when studying the prevalence of the tumor process. The expression and content of VHL are associated with the development of distant metastases. An increase in the VHL mRNA and its protein was recorded in patients with disseminated form by 32.0 and 2.68 times, respectively, of the disease, compared with patients with localized cancer.
3.3. AKT/mTOR Activation and Implementation of Transcriptional and Growth Factors in ccRCC Oncogenesis
A 2.8 times increase in mRNA level of HIF-2, NF-κB p50, respectively, was revealed in a primary tumor with stage T3-4N0-1M1 compared to T1-2N0M0. The reduction in CAIX mRNA level by 1.3 times was also found in these cancers. The distant metastases formation was accompanied by the increased nuclear factors NF-κBp50 and NF-κBp65 expression by 4.0 and 2.8 times, respectively, compared with patients with a localized form of the disease (Table 3). However, results in molecular markers in the transformed tissues in row primary localized, primary metastatic cancers and metastases show transcriptional factor NF-κB p50, HIF-1, CAIX, and VEGF overexpression.
Transcriptional and growth factors overexpression is the inducer of the molecular cascades and the most significant one—the AKT/mTOR signaling pathway. It is found the loss of PTEN mRNA in T3-4N0-1M0-1 in 3.23 times compared to the patients with T1-2N0M0 stage. The most pronounced changes were found in the metastatic kidneys and metastases. An 8.0 growth in PDK expression was detected in primary metastatic tissue compared to the localized one. The decreased mRNA level of c-RAF was accompanied by the cancer progression. A 1.76 times reduction in mRNA level was obtained in T3-4N0-1M0-1 stage patients compared to the patients with T1-2N0M0 stage. Additionally, the fall of gene expression indicated in primary metastatic cancers and affected distant organs. The exact change in mTOR expression (an 11.88 fall in gene expression) was also revealed in ccRCC, depending on the tumor size.
Thus, we indicate the transcriptional and growth factors induction, accompanied by the PD-L2 induction in ccRCC.
4. Discussion
The significance of immune system regulation has been verified in correlation analysis. The prevalence and distribution of PD-L2 are found to be correlated significantly with PD-L1 [5]. Previous studies have shown a relationship between the PD-L1 expression with a ccRCC poor prognosis [5,6,7,8,9]. The study revealed high levels of PD-L2 mRNA in patients with metastatic ccRCC. PD-L2 expression was observed in all tumor types and present in the stroma, tumor, and endothelial cells. However, PD-L2 was detected in the absence of PD-L1 in some tumor types [13]. The low rates in PD-1, PD-1, and PD-L2 were found in the tissue of metastases. The revealed data substantiate the contribution of heterogeneity and biological characteristics to the progression of the disease [11].
Multiple correlations between the PD-1, PD-L1, PD-L2, and transcriptional and growth factors are weak. However, taking into account their impact on oncogenesis, we suggest the summarized effect of molecular markers on the immune response modification.
We found the inner mechanism of immunity in ccRCC. The HIF-1, NF-κB p50, VEGF, CAIX overexpression trigger the immune response modulation, the key event in cancer progression and resistance induction.
VHL influences the progression of ccRCC tumors. ccRCC accounts for 2–3% of all tumors, the most frequent solid lesion in the kidney. The higher expression of VHL was correlated with the better disease-free survival in ccRCC patients using The Cancer Genome Atlas (TCGA) datasets [3].
Increased tumor immunogenicity during tumor progression is the foremost progression step associated with VHL inactivation [8,9,12,13,19]. Previous studies have revealed a relationship between VHL expression, the AKT/mTOR signaling cascade components, and transcriptional and growth factors [20,21,22,23], which possibly determines the response to targeted therapy [17,18,24,25,26]. In addition, the increase in gene expression and the content of transcriptional and growth factors have been shown in ccRCC. The expression and content of VHL depended on the stage of the disease (criterion T) and the extent of the tumor process in ccRCC.
5. Conclusions
The immune response is pivotal in oncogenesis in ccRCC. Growth in PD-L2 expression is associated with cancer progression. We found the prevalence of VHL expression in increased tumor growth and metastases development. The VHL expression and p-VHL content determine the aggressive cancer behavior and are elevated in disseminated tumors.
VHL mutation in kidney cancers is used to be a modulator of oncogenesis. Direct and indirect relationships in molecular factors determine the biological behavior and therapeutic effect. This work shows a novel mechanism for VHL tumor progression. It presents a new instrument and factor for targeting tumor-related pathologies with p-VHL/HIF altered function resulting in transcriptional, growth factors overexpression, and cancer immunity changes. We found the primary regulator among the programmed cell death receptors and their ligands. PD-L2 is revealed to be the potential marker of carcinogenesis and target anti-cancer therapy. This new insight in ccRCC progression may offer prominent opportunities for therapeutic intervention.
Author Contributions
Conceptualization, L.S.; methodology, E.U.; formal analysis, E.L.; investigation, L.S.; resources, E.C. and I.K.; data curation, Z.Y.; writing—original draft preparation, L.S.; writing—review and editing, L.S. All authors have read and agreed to the published version of the manuscript.
Funding
This research received no external funding.
Institutional Review Board Statement
The study was conducted according to the guidelines of the Declaration of Helsinki and approved by the Institutional Review Board of Cancer Research Institute, Tomsk National Research Medical Center (protocol code 4; 16 November 2018).
Informed Consent Statement
Written informed consent has been obtained from the patient(s) to publish this paper.
Conflicts of Interest
The authors declare no conflict of interest.
References
- Kushlinskii, N.E.; Fridman, M.V.; Morozov, A.A.; Gershtei, E.S.; Kadagidze, Z.G.; Matveev, V.B. Modern approaches to kidney cancer immunotherapy. Cancer Urol. 2018, 14, 54–67. [Google Scholar] [CrossRef] [Green Version]
- Yearley, J.H.; Gibson, C.; Yu, N.; Moon, C.; Murphy, E.; Juco, J.; Lunceford, J.; Cheng, J.; Chow, L.Q.M.; Seiwert, T.Y.; et al. PD-L2 Expression in Human Tumors: Relevance to Anti-PD-1 Therapy in Cancer. Clin. Cancer Res. 2017, 23, 3158–3167. [Google Scholar] [CrossRef] [Green Version]
- Zhu, S.; Ding, W.; Chen, Y.; Wang, W.; Xu, R.; Liu, C.; Liu, X.; Deng, H. High VHL Expression Reverses Warburg Phenotype and Enhances Immunogenicity in Kidney Tumor Cells. Genom. Proteom. Bioinform. 2021. [Google Scholar] [CrossRef]
- Messai, Y.; Gad, S.; Noman, M.Z.; Le Teuff, G.; Couve, S.; Janji, B.; Kammerer, S.F.; Rioux-Leclerc, N.; Hasmim, M.; Ferlicot, S.; et al. Renal Cell Carcinoma Programmed Death-ligand 1, a New Direct Target of Hypoxia-inducible Factor-2 Alpha, is Regulated by von Hippel-Lindau Gene Mutation Status. Eur. Urol. 2016, 70, 623–632. [Google Scholar] [CrossRef]
- Hong, B.; Cai, L.; Wang, J.; Liu, S.; Zhou, J.; Ma, K.; Zhang, J.; Zhou, B.; Peng, X.; Zhang, N.; et al. Differential Expression of PD-L1 Between Sporadic and VHL-Associated Hereditary Clear-Cell Renal Cell Carcinoma and Its Correlation With Clinicopathological Features. Clin. Genitourin. Cancer 2019, 17, 97–104. [Google Scholar] [CrossRef] [PubMed]
- Kammerer-Jacquet, S.F.; Crouzet, L.; Brunot, A.; Dagher, J.; Pladys, A.; Edeline, J.; Laguerre, B.; Peyronnet, B.; Mathieu, R.; Verhoest, G.; et al. Independent association of PD-L1 expression with noninactivated VHL clear cell renal cell carcinoma-A finding with therapeutic potential. Int. J. Cancer 2017, 140, 142–148. [Google Scholar] [CrossRef]
- Lu, Y.; Song, Y.; Xu, Y.; Ou, N.; Liang, Z.; Hu, R.; Zhang, W.; Kang, J.; Wang, X.; Liu, L.; et al. 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 3389 patients. Transl. Androl. Urol. 2020, 9, 367–381. [Google Scholar] [CrossRef]
- Ueda, K.; Suekane, S.; Kurose, H.; Chikui, K.; Nakiri, M.; Nishihara, K.; Matsuo, M.; Kawahara, A.; Yano, H.; Igawa, T. Prognostic value of PD-1 and PD-L1 expression in patients with metastatic clear cell renal cell carcinoma. Urol. Oncol. 2018, 36, 499.e9–499.e16. [Google Scholar] [CrossRef] [PubMed]
- Tanegashima, T.; Togashi, Y.; Azuma, K.; Kawahara, A.; Ideguchi, K.; Sugiyama, D.; Kinoshita, F.; Akiba, J.; Kashiwagi, E.; Takeuchi, A.; et al. Immune Suppression by PD-L2 against Spontaneous and Treatment-Related Antitumor Immunity. Clin. Cancer Res. 2019, 25, 4808–4819. [Google Scholar] [CrossRef] [Green Version]
- Philips, E.A.; Garcia-España, A.; Tocheva, A.S.; Ahearn, I.M.; Adam, K.R.; Pan, R.; Mor, A.; Kong, X.P. The structural features that distinguish PD-L2 from PD-L1 emerged in placental mammals. J. Biol. Chem. 2020, 295, 4372–4380. [Google Scholar] [CrossRef] [Green Version]
- Zhang, X.; Yin, X.; Zhang, H.; Sun, G.; Yang, Y.; Chen, J.; Zhu, X.; Zhao, P.; Zhao, J.; Liu, J.; et al. Differential expressions of PD-1, PD-L1 and PD-L2 between primary and metastatic sites in renal cell carcinoma. BMC Cancer 2019, 19, 360. [Google Scholar] [CrossRef]
- Lastwika, K.J.; Wilson, W., III; Li, Q.K.; Norris, J.; Xu, H.; Ghazarian, S.R.; Kitagawa, H.; Kawabata, S.; Taube, J.M.; Yao, S.; et al. Control of PD-L1 Expression by Oncogenic Activation of the AKT-mTOR Pathway in Non-Small Cell Lung Cancer. Cancer Res. 2016, 76, 227–238. [Google Scholar] [CrossRef] [PubMed] [Green Version]
- Tsai, T.F.; Lin, J.F.; Lin, Y.C.; Chou, K.Y.; Chen, H.E.; Ho, C.Y.; Chen, P.C.; Hwang, T.I. Cisplatin contributes to programmed death-ligand 1 expression in bladder cancer through ERK1/2-AP-1 signaling pathway. Biosci. Rep. 2019, 39, BSR20190362. [Google Scholar] [CrossRef] [PubMed] [Green Version]
- Dong, L.; Lv, H.; Li, W.; Song, Z.; Li, L.; Zhou, S.; Qiu, L.; Qian, Z.; Liu, X.; Feng, L.; et al. Co-expression of PD-L1 and p-AKT is associated with poor prognosis in diffuse large B-cell lymphoma via PD-1/PD-L1 axis activating intracellular AKT/mTOR pathway in tumor cells. Oncotarget 2016, 7, 33350–33362. [Google Scholar] [CrossRef] [PubMed]
- Noman, M.Z.; Desantis, G.; Janji, B.; Hasmim, M.; Karray, S.; Dessen, P.; Bronte, V.; Chouaib, S. PD-L1 is a novel direct target of HIF-1α, and its blockade under hypoxia enhanced MDSC-mediated T cell activation. J. Exp. Med. 2014, 211, 781–790. [Google Scholar] [CrossRef]
- Ruf, M.; Moch, H.; Schraml, P. PD-L1 expression is regulated by hypoxia-inducible factor in clear cell renal cell carcinoma. Int. J. Cancer 2016, 139, 396–403. [Google Scholar] [CrossRef] [PubMed] [Green Version]
- Tatli Dogan, H.; Kiran, M.; Bilgin, B.; Kiliçarslan, A.; Sender, M.A.N.; Yalçin, B.; Ardiçoglu, A.; Atmaca, A.F.; Gumuskaya, B. Prognostic significance of the programmed death-ligand 1 expression in clear cell renal cell carcinoma and correlation with the tumor microenvironment and hypoxia-inducible factor expression. Diagn. Pathol. 2018, 13, 60. [Google Scholar] [CrossRef]
- Wu, X.-F.; Cheng, T.; Li, J.; Ma, D.-Y.; Zhu, Q.-F.; Lian, X. Correlation analysis of VHL and Jade-1 gene expression in human renal cell carcinoma. Open Med. 2016, 11, 226–230. [Google Scholar] [CrossRef]
- Spirina, L.V.; Yurmazov, Z.A.; Gorbunov, A.K.; Usynin, E.A.; Lushnikova, N.A.; Kovaleva, I.V. Molecular Protein and Expression Profile in the Primary Tumors of Clear Cell Renal Carcinoma and Metastases. Cells 2020, 9, 1680. [Google Scholar] [CrossRef]
- Spirina, L.V.; Kondakova, I.V.; Yurmazov, Z.A.; Usynin, E.A.; Slonimskaya, E.M.; Lushnikova, N.A.; Podnebesnova, D.V. VHL Expression in Kidney Cancer: Relation to Metastasis Development, Transcription and Growth Factors and Component of Akt/m-TOR Signaling Pathway. Bull. Exp. Biol. Med. 2019, 167, 671–675. [Google Scholar] [CrossRef]
- Kim, B.J.; Kim, J.H.; Kim, H.S.; Zang, D.Y. Prognostic and predictive value of VHL gene alteration in renal cell carcinoma: A meta-analysis and review. Oncotarget 2017, 8, 13979–13985. [Google Scholar] [CrossRef] [PubMed] [Green Version]
- Less, F.; Mazzanti, C.M.; Tomei, S.; Di Cristofano, C.; Minervini, A.; Menicagli, M.; Apollo, A.; Masieri, L.; Collecchi, P.; Minervini, R.; et al. VHL and HIF-1α: Gene variations and prognosis in early-stage clear cell renal cell carcinoma. Med. Oncol. 2014, 31, 840. [Google Scholar] [CrossRef] [PubMed]
- Wang, J.; Ma, Y.; Jiang, H.; Zhu, H.; Liu, L.; Sun, B.; Pan, S.; Kristiansen, G.W.; Sun, X. Overexpression of von Hippel-Lindau protein synergizes with doxorubicin to suppress hepatocellular carcinoma in mice. J. Hepatol. 2011, 55, 359–368. [Google Scholar] [CrossRef] [PubMed]
- Walmsley, S.R.; McGovern, N.N.; Whyte, M.K.; Chilvers, E.R. The HIF/VHL pathway: From oxygen sensing to innate immunity. Am. J. Respir. Cell Mol. Biol. 2008, 38, 251–255. [Google Scholar] [CrossRef] [Green Version]
- Diez-Calzadilla, N.A.; Noguera Salvá, R.; Soriano Sarrió, P.; Martínez-Jabaloyas, J.M. Genetic profile and immunohistochemical study of clear cell renal carcinoma: Pathological-anatomical correlation and prognosis. Cancer Treat. Res. Commun. 2021, 27, 100374. [Google Scholar] [CrossRef]
- Yang, H.; Minamishima, Y.A.; Yan, Q.; Schlisio, S.; Ebert, B.L.; Zhang, X.; Zhang, L.; Kim, W.Y.; Olumi, A.F.; Kaelin, W.G., Jr. pVHL acts as an adaptor to promote the inhibitory phosphorylation of the NF-kappaB agonist Card9 by CK2. Mol. Cell 2007, 28, 15–27. [Google Scholar] [CrossRef] [Green Version]
Figure 1.
Association between the PD-1, PD-L1, PD-L2 with AKT/mTOR signaling pathway components, transcriptional and growth factors. Note: the correlation analysis revealed the interconnection between the PD receptors and their ligands in ccRCC. The found data indicates the complex associations between the molecular factors that trigger the immunity change.
Figure 1.
Association between the PD-1, PD-L1, PD-L2 with AKT/mTOR signaling pathway components, transcriptional and growth factors. Note: the correlation analysis revealed the interconnection between the PD receptors and their ligands in ccRCC. The found data indicates the complex associations between the molecular factors that trigger the immunity change.
Figure 2.
p-VHL content in ccRCC tissues and adjacent non-transformed ones. Note: 1, 3—cancers, 2, 4—non-transformed tissues; p-VHL content is a key oncogenic event in ccRCC development. It promotes and triggers the main biological processes resulting in metabolism modification, immune regulation, apoptosis, and cell movement.
Figure 2.
p-VHL content in ccRCC tissues and adjacent non-transformed ones. Note: 1, 3—cancers, 2, 4—non-transformed tissues; p-VHL content is a key oncogenic event in ccRCC development. It promotes and triggers the main biological processes resulting in metabolism modification, immune regulation, apoptosis, and cell movement.
Table 1.
PD, PD-L1, PD-L2 expression in ccRCC tissues depending on tumor size and disease spreading, Me (Q1; Q3).
Table 1.
PD, PD-L1, PD-L2 expression in ccRCC tissues depending on tumor size and disease spreading, Me (Q1; Q3).
| Indicator | Tumor Size | Cancer Dissemination | ||||
|---|---|---|---|---|---|---|
| T1N0M0 | T2N0M0-1 | T3N0M1 | Localized Cancers | Disseminated Cancers | Metastases | |
| PD-1 | 4.19 (3.45; 20.40) | 0.81 (0.11; 2.00) | 0.41 (0.20; 1.94) | 2.91 (1.44; 7.63) | 0.61 (0.12; 1.94) * | 0.57 (0.135; 1.82) |
| Kruskal–Wallis Test: H = 11.95785 p = 0.0025 | ||||||
| PD-L1 | 2.85 (0.40; 6.77) | 1.00 (0.19; 1.00) | 0.32 (0.28; 0.50) | 1.00 (0.25; 4.27) | 0.37 (0.24; 1.00) | 0.75 (0.375; 1.50) |
| Kruskal–Wallis Test: H = 3.792281 p = 0.1501 | ||||||
| PD-L2 | 11.8 (1.49; 21.10) | 1.14 (0.64; 2.00) | 1.77 (0.50; 10.54) | 1.28 (0.50; 2.17) | 6.81 (2.16; 17.8) * | 0.605 (0.435; 0.755) ** |
| Kruskal–Wallis Test: H = 4.837951 p = 0.0490 | ||||||
Note: *—the significance of the differences with the localized cancers, p < 0.05; **—the significance of the differences compared to the primary metastatic tumor, p < 0.05.
Table 2.
Expression and content of VHL in tumor tissue of patients depending on tumor size and disease spreading, Me (Q1; Q3).
Table 2.
Expression and content of VHL in tumor tissue of patients depending on tumor size and disease spreading, Me (Q1; Q3).
| Indicator | Tumor Size | Cancer Dissemination | |||
|---|---|---|---|---|---|
| T1-2N0M0 | T3-4N0-1M0-1 | Localized Cancer (T1-2N0M0) | Metastatic Cancers (T1-4N0-1M1) | Metastases | |
| VHL expression, Relative Units | 7.00 (2.00; 31.32) | 87.50 (4.22; 128.00) * | 2.00 (0.50;4.00) | 64.00 (8.46; 128.00) * | 1.09 (0.09; 5.44) ** |
| VHL content,% to unaltered tissue | 77.20 (42.25; 99.79) | 15.30 (11.30; 46.07) * | 55.00 (20.10; 93.61) | 147.54 (100.54; 156.78) * | 20.80 (10.60; 58.80) ** |
Note: *—the significance of the differences with the localized form, p < 0.05; **—the significance of the differences compared to the primary metastatic tumor, p < 0.05.
Table 3.
Expression of nuclear factors HIF-1, HIF-1, NF-κBp50 and NF-κBp65, growth factors and components of AKT/m-TOR signaling pathway in tumor tissue of patients depending on tumor size and disease prevalence, Me (Q1; Q3).
Table 3.
Expression of nuclear factors HIF-1, HIF-1, NF-κBp50 and NF-κBp65, growth factors and components of AKT/m-TOR signaling pathway in tumor tissue of patients depending on tumor size and disease prevalence, Me (Q1; Q3).
| Indicator | Tumor Size | Cancer Dissemination | |||
|---|---|---|---|---|---|
| T1-2N0M0 | T3-4N0-1M0-1 | Localized Cancer (T1-2N0M0) | Metastatic Cancers (T1-4N0-1M1) | Metastases | |
| Transcriptional and growth factors | |||||
| HIF-1 | 1.29 (0.11; 2.53) | 0.79 (0.09; 3.50) | 1.20 (0.11; 3.30) | 1.07 (0.01; 6.60) | 20.80 (9.60; 35.30) ** |
| Kruskal–Wallis Test: H = 3.845614; p = 0.0156 | |||||
| HIF-2 | 0.94 (0.13; 2.87) | 2.68 (0.13; 128.00) * | 1.00 (0.13; 4.00) | 1.13 (0.01; 3.50) | 2.95 (1.24; 12.27) |
| Kruskal–Wallis Test: H = 3.792281; p = 0.1501 | |||||
| NF-κB p50 | 1.07 (0.1; 12.72) | 3.00 (0.03; 9.13) * | 1.00 (0.08; 12.72) | 4.08 (0.10; 6.92) ** | 6.00 (2.05; 28.14) ** |
| Kruskal–Wallis Test: H = 5.845614 df = 1 p = 0.0156 | |||||
| NF-κB p65 | 1.39 (0.22; 4.60) | 1.64 (0.66; 12.73) | 1.00 (0.08; 12.72) | 2.83 (0.01; 6.60) ** | 4.11 (0.14; 16.24) |
| Kruskal–Wallis Test: H = 5.792281; p = 0.8501 | |||||
| VEGF | 1.39 (0.13; 25.00) | 1.00 (0.13; 16.00) | 1.35 (0.13; 25.00) | 1.03 (0.00; 3.43) | 21.75 (0.50; 31.31) |
| Kruskal–Wallis Test: H = 5.792281; p = 0.0501 | |||||
| CAIX | 1.97 (0.31; 2.00) | 2.56 (0.85; 5.00) * | 0.81 (0.02; 2.00) | 0.07 (0.01; 25.1) | 1.85 (1.14; 2.28) ** |
| Kruskal–Wallis Test: H = 4.845614; p = 0.0056 | |||||
| VEGFR2 | 0.74 (0.16; 8.57) | 0.75 (0.25; 16.00) | 1,00 (0.33; 16.00) | 0.32 (0.04; 12.5) | 0.91 (0.45; 1.82) |
| Kruskal–Wallis Test: H = 5.792281; p = 0.8501 | |||||
| AKT/mTOR signaling cascade components | |||||
| PTEN | 4.72 (1.00; 8.78) | 1.46 (0.50; 9.07) * | 0.81 (0.50; 7.80) | 2.23 (1.18; 8.11) | 0.50 (0.00; 48.00) |
| Kruskal–Wallis Test: H = 3.612530; p = 0.0490 | |||||
| AKT | 0.93 (0.63; 16.00) | 1.48 (0.34; 3.42) | 1.02 (0.54; 4.00) | 4.57 (0.70; 23.23) | 0.34 (0.28; 8.00) |
| Kruskal–Wallis Test: H = 3.792281; p = 0.1501 | |||||
| GSK-3β | 3.78 (1.24; 17.00) | 8.00 (4.00; 12.64) | 2.59 (0.64; 9.50) | 4.00 (0.54; 16.00) | 0.24 (0.13; 8.00) |
| Kruskal–Wallis Test: H = 3.792281; p = 0.1501 | |||||
| PDK | 3.65 (1.07; 15.60) | 3.00 (0.51; 14.06) | 5.48 (0.70; 17.30) | 0.68 (0.03; 6.35) ** | 0.29 (0.01; 2.00) |
| Kruskal–Wallis Test: H = 3.792281; p = 0.1501 | |||||
| c-RAF | 4.44 (1.96; 16.41) | 2.51 (2.00; 8.00) * | 1.90 (0.22; 4.88) | 2.59 (0.16; 12.20) | 0.25 (0.00; 10.00) |
| Kruskal–Wallis Test: H = 4.371429 df = 1 p = 0.0365 | |||||
| mTOR | 4.28 (2.80; 16.00) | 0.36 (0.16; 1.14) * | 3.39 (0.84; 13.28) | 1.15 (0.42; 7.47) | 0.31 (0.25; 2.00) |
| Kruskal–Wallis Test: H = 5.792281; p = 0.8501 | |||||
| 70S 6 kinase | 2.01 (0.50; 5.58) | 1.00 (0.20; 3.64) | 0.98 (0.49; 4.64) | 0.69 (0.55; 7.91) | 0.13 (0.10; 1.18) |
| Kruskal–Wallis Test: H = 4.792281; p = 0.1501 | |||||
| 4E-BP1 | 1.05 (0.35; 3.66) | 1.00 (0.33; 2.00) | 0.71 (0.28; 3.83) | 0.83 (0.21; 6.22) | 0.25 (0.00; 10.56) |
| Kruskal–Wallis Test: H = 2.792281; p = 0.5501 | |||||
Note: *—the significance of the differences with the T1-2N0M0 stage, p < 0.05; **—the significance of the differences compared to the localized tumor, p < 0.05.
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Spirina, L.; Yurmazov, Z.; Usynin, E.; Kondakova, I.; Ladutko, E.; Choynzonov, E. Regulation of Immunity in Clear Cell Renal Carcinoma: Role of PD-1, PD-L1, and PD-L2. Curr. Issues Mol. Biol. 2021, 43, 1072-1080. https://doi.org/10.3390/cimb43020076
AMA Style
Spirina L, Yurmazov Z, Usynin E, Kondakova I, Ladutko E, Choynzonov E. Regulation of Immunity in Clear Cell Renal Carcinoma: Role of PD-1, PD-L1, and PD-L2. Current Issues in Molecular Biology. 2021; 43(2):1072-1080. https://doi.org/10.3390/cimb43020076
Chicago/Turabian StyleSpirina, Liudmila, Zahar Yurmazov, Evgeny Usynin, Irina Kondakova, Ekaterine Ladutko, and Evgeny Choynzonov. 2021. "Regulation of Immunity in Clear Cell Renal Carcinoma: Role of PD-1, PD-L1, and PD-L2" Current Issues in Molecular Biology 43, no. 2: 1072-1080. https://doi.org/10.3390/cimb43020076
