Liver fatty acids composition in the sterlet of different ages

Authors

DOI:

https://doi.org/10.15587/2519-8025.2018.141406

Keywords:

saturated fatty acids, monounsaturated fatty acids, polyunsaturated fatty acids, lipids, liver, sterlet

Abstract

Lipids are important factors in the response of organisms to exogenous action due to their role in energy metabolism and cellular signaling as a structural compound of biomembranes. To date, the features of the fatty acid composition of lipids, in particular in their various fractions, in the tissues of sterlet of different age have been studied to a lesser extent. This determines the topicality of deepening such research, which will be of great practical importance in the future, since it will be aimed at increasing adaptation potential and survival of sturgeon fish, especially given their high cost.

Here we present changes of fatty acid composition in different lipid fractions of the liver of sterlet of different age (namely two-, three- and nine-year-old) with masses 0.3 - 0.4, 0.5 - 0.6 and 5 - 6 kg for the age-groups of fish, respectively. Fatty acid (FA) composition was determined using gas chromatography on CarloErba (Italy) in Palladin Institute of Biochemistry of the National Academy of Sciences of Ukraine (NASU). The fatty acid composition of lipids of sterlet liver tissues is represented by saturated and unsaturated high-molecular carboxylic acids, the largest content of which belongs to palmitic, stearic, and oleic, linoleic acids, respectively.

With increasing sterlet age, fractions of triacylglycerols (TAG) of the liver tissues were found, mainly, reducing saturated and increasing unsaturated fatty acids. Depending on the increase in the unsaturation of high molecular weight carboxylic acids, a significant decrease in the amount of their monoenic (1.7 times), dienic (1.8 times) and, especially, polyenic (4 times) was observed. The amount of TAG unsaturated FA in the liver of 9-year-old sterlet was significantly lowered (~ 2 times) compared to 2- and 3-year-old individuals. Hence, the ratio of saturated and unsaturated FA was greater (~ 2 times) in the 9-year-old sterlet compared with the values of this indicator for two- and three-year-old fish.

In the phospholipids of sterlet liver tissues, with an increase of age, a slight increase in the saturated FA content and a decrease in the level of monounsaturated and polyunsaturated fatty acids were recorded.

Among the free fatty acids in the liver of sterlet, we identified 27 acids, of them 44%, 41 %, and 35 % were saturated in 2-, 3-year-old and mature fish, respectively. As for free fatty acids, we can conclude the age-dependent decreasing of saturated fatty acids. Monounsaturated FA content was 27 %, 31 % and 47 % in 2-, 3-year-old and adult sterlet fish, and polyunsaturated FA content –27 %, 25 % and 15 %, respectively.

All this can be used for the theoretical justification and development of appropriate corrective feed additives and premixes

Author Biographies

Roza Suleimanova, National University of Life and Environmental Sciences of Ukraine Heroiv Oborony str., 15, Kyiv, Ukraine, 03041

Postgraduate student

Department of Biochemistry and Physiology of Animals named after Academician M. F. Gulyi

Dmytro Melnichuk, Presidium of National Academy of Sciences of Ukraine Volodymyrska str., 54, Kyiv, Ukraine, 01601

Doctor of Biological Sciences, Professor, Academician of NAS and NAAS of Ukraine, Advisor to the Presidium of National Academy of Sciences of Ukraine

Liliia Kalachniuk, National University of Life and Environmental Sciences of Ukraine Heroiv Oborony str., 15, Kyiv, Ukraine, 03041

Doctor of Biological Sciences, Professor

Department of Biochemistry and Physiology of Animals named after Academician M.F. Gulyi

References

  1. Suleimanova, R. R., Hudz, E. А., Melnychuk, D. О., Kalachniuk, L. H. (2017). Age-related changes phospholipids of sterlet in liver and dorsal muscles. The Ukrainian Biochemical Journal, 89 (1), 71–75. doi: https://doi.org/10.15407/ubj89.01.071
  2. Suleimanova, R. R., Hudz, I. A., Melnychuk, D. O., Kalachniuk, L. H. (2017). Age peculiarities of the content of phospholipids in the blood of starlet. Reports of the National Academy of Sciences of Ukraine, 5, 98–101. doi: https://doi.org/10.15407/dopovidi2017.05
  3. Suleimanova, R., Melnychuk, D., Kalachniuk, L. (2018). Indices of fatty acids spectrum of lipids in the blood serum of sterlet of different age. EUREKA: Life Sciences, 2, 3–8. doi: https://doi.org/10.21303/2504-5695.2018.00578
  4. Suleimanova, R. R. (2018). Activity of some transferases in the blood serum of sterlet of different age. The Animal Biology, 20 (2), 77–81. doi: https://doi.org/10.15407/animbiol20.02.077
  5. Simon, M. (2016). Features oxidative processes in sturgeons fish (acipenseridae) (review). Fisheries science of Ukraine, 4 (38), 131–153. doi: https://doi.org/10.15407/fsu2016.04.131
  6. Osoba, I. A. (2013). Biologichna rol perekisnogo okisnennya lipidiv u zabezpechennі funktsіonuvannya organіzmu rib [The biological role of lipid peroxidation in the functioning of the organism of fish]. Fisheries science of Ukraine, 1, 87–96.
  7. Tsvetkova, M. V., Khirmanov, V. N., Zybina, N. N. (2010). Rol' nejesterificirovannyh zhirnyh kislot v patogeneze serdechno-sosudistyh zabolevanij [Significance of non–etherificated fatty acids in pathogenesis of cardiovascular diseases]. Arterial hypertension, 1, 93–103.
  8. Nelson, D. L., Cox, M. M. (2017). Lehninger Principle sof Biochemistry. NewYork: W.H. Freeman, 1328.
  9. Calder, P. C. (2012). Mechanisms of Action of (n-3) Fatty Acids. The Journal of Nutrition, 142 (3), 592S–599S. doi: https://doi.org/10.3945/jn.111.155259
  10. Liavrin, B. Z., Kurant, V. Z., Khomenchuk, V. O., Grubinko, V. V. (2014). Vydovi osoblyvosti lipidnoho skladu deiakykh tkanyn prisnovodnykh ryb Zakhidnoho Podillia [Specific features of lipid composition of some tissues of freshwater fish of West Podillya]. Reports of the National Academy of Sciences of Ukraine, 8, 123–127.
  11. Gritsyanak, І. І., Smolyaninov, K. B., Janovich, V. G. (2010). Obmin lipidiv u ryb [Exchange of lipids in fish]. Lviv: Triad plus, 335.
  12. Tarasiuk, S. I.., Dvoretskyi, A. I., Deren, O. V. (2015). Biologichni osnovi godivli rib [Biological basis of fish feeding]. Dnipro: Adverta, 180.
  13. Gula, N. M., Margitich, V. M. (2009). Zhyrni kysloty ta yikh pokhidni pry patolohichnykh stanakh [Fatty acids and their derivatives in pathologic states]. Kyiv: Scientific thought, 336.
  14. Sysolyatin, S. V., Khyzhnyak, S. V. (2017). Fatty acid composition of total lipids in liver of carp (Cyprinus carpio L.) under artificial hibernation. Reports of the National Academy of Sciences of Ukraine, 8, 102–105. doi: https://doi.org/10.15407/dopovidi2017.08.102
  15. Yli-Jama, P., Seljeflot, I., Meyer, H. E., Hjerkinn, E. M., Arnesen, H., Pedersen, J. I. (2002). Serum non-esterified very long-chain PUFA are associated with markers of endothelial dysfunction. Atherosclerosis, 164 (2), 275–281. doi: 10.1016/s0021-9150(02)00067-9
  16. Hrytsyniak, I. I., Rivis, Y. F., Maletych, M. B. (2015). Vmist ta zhyrnokyslotnyj sklad eteryfikovanogo holesterolu pechinky ta vidtvorna zdatnist' plidnykiv koropa (Cyprinus carpio) za riznogo rivnja vitaminu A v kombikormah [The content and fatty acid composition of the etherified cholesterol of the liver and reproductive ability of the carpal farmers (Cyprinus carpio) for different levels of vitamin A in mixed fodders]. Fisheries science of Ukraine, 3, 107–115.
  17. Khyzhniak, S. V., Midyk, S. V., Sysoliatin, S. V., Voitsitskyi, V. M. (2017). Vmist zhyrnyh kyslot u pechinci ta serci sterljadi (Acipenser ruthenus) za gipoksy-giperkapnichnogo vplyvu [The content of fatty acids in the liver and heart of the heart (Acipenser ruthenus) for hypoxic hypercapnic effects]. Hydrobiological journal, 53 (5), 88–95.
  18. Abedi, E., Sahari, M. A. (2014). Long-chain polyunsaturated fatty acid sources and evaluation of their nutritional and functional properties. Food Science & Nutrition, 2 (5), 443–463. doi: https://doi.org/10.1002/fsn3.121
  19. Passi, S., Ricci, R., Cataudella, S., Ferrante, I., De Simone, F., Rastrelli, L. (2004). Fatty Acid Pattern, Oxidation Product Development, and Antioxidant Loss in Muscle Tissue of Rainbow Trout andDicentrarchus labraxduring Growth. Journal of Agricultural and Food Chemistry, 52 (9), 2587–2592. doi: https://doi.org/10.1021/jf030559t
  20. Adloo, M. N., Matinfar, A., Sourinezhad, I. (2012). Effects of feeding enriched Artemia franciscana with HUFA, vitamin C and E on growth performance, survival and stress resistance of yellow fin sea bream larvae. J. Aquacult. Res., 3, 157–162.
  21. Bligh, E. G., Dyer, W. J. (1959). A rapid method of total lipid extraction and purification. Canadian Journal of Biochemistry and Physiology, 37 (8), 911–917. doi: https://doi.org/10.1139/o59-099
  22. Rivis, J. F., Fedoruk, R. S. (2010). Kil'kisni hromatografichni metody vyznachennja okremyh lipidiv i zhyrnyh kyslot u biologichnomu materiali: metodychnyj posibnyk [Quantitative and qualitative chromatographical methods of some lipids and fatty acids determination in biological material]. Lviv: Spolom, 109.
  23. Glanz, S. (1999). Medico-biological statistics. Moscow: Practice, 460.
  24. Baydalinova, L. S., Yarzhombek, A. A. (2011). Biohimiya syirya vodnogo proishozhdeniya. [Biochemistry of raw materials of aquatic origin]. Moscow: Morkniga, 504.
  25. Cap, M. M., Rivis, J. F. (2010). Obmin zhyrnyh kyslot v organizmi koropiv za zgodovuvannja zhyrovyh dobavok [Exchange of fatty acids in the body of carps for feeding fat supplements]. Bulletin of Agrarian Science, 5, 41–44.

Published

2018-08-31

How to Cite

Suleimanova, R., Melnichuk, D., & Kalachniuk, L. (2018). Liver fatty acids composition in the sterlet of different ages. ScienceRise: Biological Science, (4 (13), 50–57. https://doi.org/10.15587/2519-8025.2018.141406

Issue

Section

Biological Sciences