Роль подопланина в опухоль-ассоциированных тромбозах

Онкологические больные подвержены повышенному риску венозных тромбоэмболических осложнений (ВТЭО), которые являются второй по значимости причиной смерти у данных пациентов. В литературе описано несколько механизмов, приводящих   к подобным осложнениям. Одним из таких является взаимодействие гликопротеина   подопланина, которому посвящена данная статья, со своим рецептором на тромбоцитах семейства лектиноподобных типа С (CLEC-2). Данное взаимодействие приводит   к активации тромбоцитов и способствует гематогенному метастазированию и тромбозу, связанному с раком. Подопланин экспрессируется при глиомах, плоскоклеточном   раке, остеосаркоме раковыми клетками, а также в норме в подоцитах и лимфатических   эндотелиальных клетках, но не в эндотелии сосудов. Тромбовоспаление инициирует   эктопическую экспрессию подопланина в эндотелиальных клетках сосудов, что способствует тромбозу. Показано, что экспрессия подопланина коррелирует с частотой   ВТЭО, а также с метастазированием рака. Нарушение взаимодействия PDPN-CLEC-2   может стать новым направлением в разработке препаратов для профилактики тромбозов у пациентов с онкологическими заболеваниями 

1. Low S, et al. Isocitrate dehydrogenase mutation and risk of venous thromboembolism in glioma: A systematic review and meta-analysis. Thrombosis Research. 2022; 45: 175–198.

2. Horsted F, West J, Grainge M. Risk of venous thromboembolism in patients with cancer: a systematic review and meta-analysis. PLoS Med. 2012. 9: 1–19.

3. Davila M, et al. Tissue factor-bearing microparticles derived from tumor cells: impact on coagulation activation. Journal of thrombosis and haemostasis. 2008; 9: 1517–1524.

4. Geddings J, Mackman M. Tumor-derived tissue factor-positive microparticles and venous thrombosis in cancer patients. Blood. 2013; 122: 1873–1880.

5. Hisada Y, et al. Human pancreatic tumors grown in mice release tissue factor-positive microvesicles that increase venous clot size. Journal of Thrombosis and Haemostasis. 2017; 11: 208–2217.

6. Astarita J, Acton E, Turley J. Podoplanin: emerging functions in development, the immune system, and cancer. Frontiers in immunology. 2012; 3: 283–287.

7. Ugorski M, Dziegiel P, Suchanski J. Podoplanin-a small glycoprotein with many faces. American journal of cancer research. 2016; 2: 370.

8. Renart J, et al. New insights into the role of podoplanin in epithelial–mesenchymal transition.International review of cell and molecular biology. 2015; 317: 185–239.

9. Suzuki-Inoue K. Platelets and cancer-associated thrombosis: focusing on the platelet activation receptor CLEC-2 and podoplanin. the American Society of Hematology Education Program Book. 2019; 1: 175–181.

10. Navarro-Núñez L, et al. The physiological and pathophysiological roles of platelet CLEC-2. Thrombosis and haemostasis. 2013; 109: 991–998.

11. Astarita J, et al. The CLEC-2–podoplanin axis controls the contractility of fibroblastic reticular cells and lymph node microarchitecture. Nature immunology. 2015; 16: 75–84.

12. Martín-Villar E, et al. Podoplanin mediates ECM degradation by squamous carcinoma cells through control of invadopodia stability. Oncogene. 2015; 34: 4531–4544.

13. Kato Y, et al. Molecular analysis of the pathophysiological binding of the platelet aggregation- inducing factor podoplanin to the C-type lectin-like receptor CLEC-2. Cancer science. 2008; 99: 54–61.

14. Nagae M, et al. A platform of C-type lectin-like receptor CLEC-2 for binding O-glycosylated podoplanin and nonglycosylated rhodocytin. Structure. 2014; 22: 1711–1721.

15. Suzuki-Inoue K, Osada M, Ozaki Y. Physiologic and pathophysiologic roles of interaction between C- type lectin-like receptor 2 and podoplanin: partners from in utero to adulthood. Journal of Thrombosis and Haemostasis. 2017; 15: 219–229.

16. Tammela T, Alitalo K. Lymphangiogenesis: molecular mechanisms and future promise. Cell. 2010; 140: 460–476.

17. Peterziel H, et al. Expression of podoplanin in human astrocytic brain tumors is controlled by the PI3K-AKT-AP-1 signaling pathway and promoter methylation. Neuro-oncology. 2012; 14: 426–439.

18. Durchdewald M, et al. Podoplanin is a novel fos target gene in skin carcinogenesis. Cancer Research. 2008; 68: 6877–6883.

19. Kunita A, et al. Podoplanin is regulated by AP-1 and promotes platelet aggregation and cell migration in osteosarcoma. The American journal of pathology. 2011; 179: 1041–1049.

20. Kato Y, Kaneko M. A cancer-specific monoclonal antibody recognizes the aberrantly glycosylated podoplanin. Sci. Rep. 2014.; 4:5924.

21. Shirai T, et al. C-type lectin-like receptor 2 promotes hematogenous tumor metastasis and prothrombotic state in tumor-bearing mice. Journal of Thrombosis and Haemostasis. 2017; 15: 513–525.

22. Lee H, et al. Podoplanin promotes cancer-associated thrombosis and contributes to the unfavorable overall survival in an ectopic xenograft mouse model of oral cancer. Biomedical journal. 2020; 43: 146–162.

23. Wang X, et al. Blocking podoplanin inhibits platelet activation and decreases cancer-associated venous thrombosis. Thrombosis Research. 2021; 200: 72–80.

24. Payne H, et al. Mice with a deficiency in CLEC-2 are protected against deep vein thrombosis. Blood, The Journal of the American Society of Hematology. 2017; 129: 2013–2020.

25. Hitchcock J, et al. Inflammation drives thrombosis after Salmonella infection via CLEC-2 on platelets. The Journal of clinical investigation. 2015; 125: 4429–4446.

26. Riedl J, et al. Podoplanin expression in primary brain tumors induces platelet aggregation and increases risk of venous thromboembolism. Blood, The Journal of the American Society of Hematology. 2017; 129: 1831– 1839.

27. Khorana A, et al. Cancer-associated venous thromboembolism. Nature Reviews Disease Primers. 2022; 8: 1337–1347.

28. Seyed N, et al. Combination of isocitrate dehydrogenase 1 (IDH 1) mutation and podoplanin expression in brain tumors identifies patients at high or low risk of venous thromboembolism. Journal of Thrombosis and Haemostasis. 2008; 6: 1121–1127.

29. Gharahkhani R, Pourhadi M, Mirdamadi N, et al. Effect of Anti-Podoplanin on Malignant Glioma Cell Viability, Invasion and Tumor Cell-Induced Platelet Aggregation. Arch Med Res. 2022; 53: 461–468.

30. Gi T, et al. Histopathological features of cancer-associated venous thromboembolism: presence of intrathrombus cancer cells and prothrombotic factors. Arteriosclerosis, Thrombosis, and Vascular Biology. 2023; 43: 146–159.

31. Schacht V, et al. Up-regulation of the lymphatic marker podoplanin, a mucin-type transmembrane glycoprotein, in human squamous cell carcinomas and germ cell tumors. The American journal of pathology. 2005; 166: 913–921.

32. Takagi S, et al. Expression of Aggrus/podoplanin in bladder cancer and its role in pulmonary metastasis. International journal of cancer. 2014; 134: 2605–2614.

33. Hisakane K, et al. Unique intravascular tumor microenvironment predicting recurrence of lung squamous cell carcinoma.Journal of cancer research and clinical oncology. 2016; 142: 593–600.

34. Mishima K, et al. Podoplanin expression in primary central nervous system germ cell tumors: a useful histological marker for the diagnosis of germinoma. Acta neuropathologica. 2006; 111: 563–568.

35. Sankiewicz A, et al. Podoplanin serum and urine concentration in transitional bladder cancer. Cancer Biomarkers. 2016; 16: 343–350.

36. Zhao X, et al. Plasma soluble podoplanin is a novel marker for the diagnosis of tumor occurrence and metastasis. Cancer science. 2018; 109: 403–411.

37. Pan Y, et al. Podoplanin requires sialylated O-glycans for stable expression on lymphatic endothelial cells and for interaction with platelets. Blood, The Journal of the American Society of Hematology. 2014; 124: 3656–3665.

38. Carrasco-Ramírez P, et al. Podoplanin is a component of extracellular vesicles that reprograms cell-derived exosomal proteins and modulates lymphatic vessel formation. Oncotarget. 2016; 7: 16070.

39. Falanga A, et al. Mechanisms and risk factors of thrombosis in cancer. Critical reviews in oncology/ hematology. 2017; 118: 79–83.

40. Mege D, et al. The origin and concentration of circulating microparticles differ according to cancer type and evolution: A prospective single-center study. International journal of cancer. 2016; 138: 939–948.

41. Melnichnikova O, et al. Circulating Small Extracellular Vesicles Profiling and Thrombin Generation as Potential Markers of Thrombotic Risk in Glioma Patients. Frontiers in Cardiovascular Medicine. 2022; 9.