The role of blood transport proteins in adaptation reactions to extremely uncomfortable conditions of the North and the Arctic

The purpose of this review is to integrate data on the role of blood transport proteins in adaptation reactions to extremely uncomforTable conditions of the North and Arctic of the Russian Federation. Regulation of shifts in homeostasis in humans under unfavorable Arctic conditions is carried out, among other things, by increasing the production of haptoglobin and transferrin, which perform antioxidant and immunomodulatory functions. An increase in the concentration of immunoglobulins in the blood ensures the efficiency of utilization of metabolic products, components of cellular destruction and damage. In the unfavorable conditions of the North and the Arctic, a shift and disruption of adaptive changes in lipid metabolism occurs.

1. Balanovskaya E.V., Balanovsky O.P. The Russian gene pool on the Russian plain. Moscow: Publishing House "Luch", 2007. 416 p.

2. Berova O.M. Immunological aspects of the body's response to hypoxia in different age periods // Penza State University. University proceedings. Medical sciences. 2007; 1: 83-91.

3. Galectin-3, haptoglobin and proangiogenic factors in gastric cancer / Kovaleva O.V. [et al.] // Molecular medicine. 2022; 20(4): 28-34.

4. Hypoxia-inducible factor (HIF): structure, function and genetic polymorphism / Zhukova A.G. [et al.] // Hygiene & Sanitation. 2019; 98(7): 723-728.

5. Golubeva M.G. Osmotic resistance of erythrocytes, methods of determination and correction, value at different pathologies // Uspehi sovremennoj biologii. 2019; 139(5): 446-456.

6. Golubeva M.G. The role of haptoglobin in protecting the body from the toxic effects of extracellular hemoglobin // Uspehi sovremennoj biologii. 2023; 143(2): 114-122.

7. Gromov A.A., Kruchinina M.V., Kruchinin V.N. Hemostasis and lipid profile features in the North // Atherosclerosis. 2019; 15(3): 62-77.

8. Gyrgolkau L.A., Shcherbakova L.V., Ivanova M.V. Blood lipid levels and frequency of dyslipidemia at the native people of Chukotka // The Siberian scientific medical journal. 2011; 31(5): 79-83.

9. Darenskaya M.A. Peculiarities of metabolic reactions in indigenous and migrant population of the North and Siberia // Acta Biomedica Scientifica. 2014;(2):97-103.

10. Dobrodeeva L.K., Lupachev V.V. The immune status of the crew of the Northern Shipping Company. In: Human immunological reactivity in the North. Arkhangelsk: Publishing House of the AGMA Center, 1993: 16-21.

11. Dobrodeeva L.K., Samodova A.V., Karyakina O.E. Interrelations in the immune system. Ekaterinburg: Publishing House Ural Branch of the Russian Academy of Sciences, 2014. 200 p.

12. Zaitseva N.V., Zemlyanova M.A. Disorders of serum proteomic profile in residents of area infl uenced by metallurgic industrial releases // Russian journal of Occupational health and industrial ecology. 2016; 12:1-5.

13. Kabbani M.S., Sergeeva T.B., Shchegoleva L.S. Cell-mediated cytotoxicity (phenotype of cd8 and cd16) in immune response // New studies. 2021:36-43.

14. Kim L.B. Oxygen transport during human adaptation to Arctic conditions and cardiorespiratory pathology. Novosibirsk: Science, 2015. 216 p.

15. Lipid and adipokine profile in oil refinery workers / Lebedeva E.N. [et al.] // Vestnik of the Orenburg state university. 2015; 9(184):92-95.

16. Mechanisms of hypoxia in Arctic zone of Russian Federation / Nagibovich O.A. [et al.] // Bulletin of the Russian Military Medical Academy. 2016; 2(54): 202-205.

17. Disorder of iron metabolism as a universal pathogenetic factor in damage to organs and systems in Covid-19 /shikalova I.A. [et al.] // Russian Sklifosovsky Journal of Emergency Medical Care. 2021; 10 (2): 259-267.

18. Naryzny S.N., Legina O.K. Haptoglobin as a biomarker // Biomedical Chemistry. 2021; 67(2): 105-118.

19. Features of the physiology of erythrocytes. Hemolysis and eryptosis / Chumakova S.P. [et al.] // Russian journal of hematology and transfusiology. 2018; 63(4): 343-351.

20. Evaluation of the influence of production factors on lipid metabolism in industrial workers / Demina I.D. [et al.] // Laboratory Service. 2012;(2):26 29.

21. An assessment of lipid metabolism indicators in working exposed to electromagnetic field of industrial frequency / Kuzmina L.P. [et al.] // International Scientific Research Journal. 2021; 11: 167-171.

22. Patrakeeva V.P., Dobrodeeva L.K., Geshavec N.P. Relationship of changes in hematological indicators of peripheral blood with transferrin concentration and CD71+ lymphocyte count //siberian Journal of Life Science and Agriculture. 2022; 14(1): 419-434.

23. Post-translation oxidation modifications of blood plasma proteins of cosmonauts after a long-term flight. Part II / Larina I.M. [et al.] // Human Physiology. 2021; 47(4): 91-102.

24. Rakitskii V.N., Iudina T.V., Saarkoppel L.M. Development of the problem of integral estimation of the functional state of working people // Laboratory Service. 2013; 3: 6-9.

25. Early diagnostic and prognostic criteria for health disorders in chemical workers / Timasheva G.V. [et al.] // Russian Clinical Laboratory Diagnostics. 2020;65(12): 750-756.

26. Soburov K.A. Peculiarities of immune reactivity of permanent residents of mountain region // Ulyanovsk Medico-biological Journal. 2011; 4: 69-76.

27. The combined effect of industrial chemical factors and labor intensity on the lipid spectrum of blood in different categories of workers at an oil refinery / Ivanov A.A. [et al.] // Bulletin of the Russian military medical academy. 2005;1(14):286-289.

28. Method for identifying increased cell-mediated cytotoxicity of lymphocytes in people in Arctic conditions: patent 2753693 Russian Federation No. 2020124876 /shashkova E.Yu. [et al.]; application date 17.07.2020; published 19.08.2021, Bulletin No. 23. 13 p.

29. Method for assessing the adaptedness of the immune system by the level of human lyphoproliferation in the Arctic conditions: patent 2757754 Russian Federation /sergeeva T.B. [et al.]; application date 17.07.2020; published: 21.10.2021, Bulletin No. 30. 17 p.

30. The frequency of lipid metabolism disorder among the indigenous population of the Arctic zone of Yakutia / Olesova L.D. [et al.]// Yakut medical journal. 2018; 2: 30-34.

31. Comparative analysis of biochemical blood parameters in residents of the Yamalo-Nenets Autonomous Okrug living in various territories / Buyak M.A. [et al.] // Public Health and Life Environment. 2009; 4: 17-19.

32. Stavinskaya O.A., Dobrodeeva L.K., Patrakeeva V.P. Association between blood concentrations of cytotoxic CD8+ cells and lymphocyte apoptosis in healthy humans // Human Ecology. 2021; 9:4-10.

33. Startseva O.N. Features of laboratory parameters of lipid, protein, and carbohydrate metabolism in visiting residents of the Far North: abstract for the degree of Candidate of Biological Sciences: 14.00.46 clinical laboratory diagnostics. St. Petersburg, 2008. 23 p.

34. Titova O.N., Kuzubova N.A., Lebedeva E.S. The role of the hypoxia signaling pathway in cellular adaptation to hypoxia // Russian medical inquiry. 2020; 4: 207-213.

35. Alterations of human plasma proteome profile on adaptation to high-altitude hypobaric hypoxia / Du X. [et al.] // J Proteome Res. 2019; 18(5):2021-2031. doi: 10.1021/acs.jproteome.8b00911

36. Haptoglobin expression in human colorectal cancer / Mariño-Crespo Ó. [et al.] // Histol Histopathol. 2019; 34(8): 953-963. doi: 10.14670/HH-18-100.

37. Haptoglobin genotype and its relation to asymptomatic cerebral small-vessel disease in type 1 diabetes / Eriksson M.I. [et al.] // Acta Diabetol. 2023; 60(6): 749-756. doi: 10.1007/s00592-023-02059-2.

38. Haptoglobin genotype does not confer a risk of stroke in type 1 diabetes /syreeni A. [et al.] // Diabetes. 2022; 71(12): 2728-2738. doi: 10.2337/db22-0327.

39. Haptoglobin induces a specific proteomic profile and a mature-associated phenotype on primary human monocyte-derived dendritic cells / Torres A. [et al.] // Int J Mol Sci. 2022; 23(13):6882. doi: 10.3390/ijms23136882.

40. Hypoxia and low temperature upregulate transferrin to induce hypercoagulability at high altitude / Li M. [et al.] // Blood. 2022; 140 (19): 2063-2075.

41. Hypoxia-inducible factors and the regulation of lipid metabolism / Mylonis I. [et al.] // Cells. 2019; 8(3): 214-230. doi: 10.3390/cells8030214.

42. Influence of haptoglobin polymorphism on stroke in sickle cell disease patients / Edwards O. [et al.] // Genes. 2022; 13(1): 144-159. doi: 10.3390/genes13010144.

43. Intercellular interactions in peripheral venous blood in practically healthy residents of high latitudes / Dobrodeeva L.K. [et al.] // BioMed Research International. 2021; 2021: 11 p.

44. Iron-loaded transferrin potentiates erythropoietin effects on erythroblast proliferation and survival: a novel role through transferrin receptors / Fouquet G. [et al.] // Experimental Hematology. 2021; 99: 12-20. doi: 10.1016/j.exphem.2021.05.005.

45. Kierans S.J., Taylor C.T. Regulation of glycolysis by the hypoxia-inducible factor (HIF): implications for cellular physiology // Journal of Physiology. 2021; 599(1): 23-27. doi: 10.1113/JP280572.

46. Mingxiao L., Haiquan S. The role of hypoxia-inducible factor 1α in hepatic lipid metabolism // Journal of Molecular Medicine. 2023; 101: 487-500.

47. The role of haptoglobin and hemopexin in the prevention of delayed cerebral ischaemia after aneurysmal subarachnoid hemorrhage / Griffiths S. [et al.] // Neurosurgical Review. 2020; 43(5): 1273-1288. doi: 10.1007/s10143-019-01169-2.