Scientific Issue Ternopil Volodymyr Hnatiuk National Pedagogical University. Series: Biology

Maximum content of lipid peroxidation end-products in the striated muscles of Legart geese was found at the end of embryonic ontogenesis. The content increased by 1.88 times compared to the input values. An antioxidant activity of the tissue reduced by 3.00 times during the ontogenesis. However, the increasing of antioxidant enzymes activity provided the maintenance of prooxidant-antioxidant balance in this period. There were no significant changes of the total unsaturated fatty acid content and the total tissue lipid unsaturation during the last week of embryogenesis in Legart breed. The content of lipid breakdown end-products in the original homogenate and after induction of peroxidation by Fe2+ ions in the skeletal muscles of Kharkiv breed had no weighty changes during the embryonic period. The highest values were on the 1st day of postnatal ontogenesis. There was a minimal value of antioxidant activity with its subsequent increase during the same period. Due to the activity of antioxidant protection enzymes, prooxidant-antioxidant balance in the skeletal muscles of Kharkiv breed was maintained. The activity is at a consistently high level during 22nd-28th days of embryogenesis. The average level of superoxide dismutase activity in the skeletal muscles of Kharkiv breed exceeded the value in Legart breed by 2.09 times, while glutathione peroxidase and catalase activity were at the same level. A prevalence of the superoxide dismutase in the antioxidant activity system indicated on higher adaptive breed potential – an average antioxidant activity was 1.5 times higher for the skeletal muscles of Kharkiv breed. Breed specificity is aimed to adapt goose organism to hyperoxia of atmospheric respiration in the skeletal muscles. Legart breed geese use the activation of antioxidant enzymes, whereas Kharkiv breed geese involve much more antioxidant enzymes – superoxide dismutase, probably, alternative mechanisms and low molecular weight antioxidants. It is established that the reduction of the total content of unsaturated fatty acids and unsaturation for this type of tissue and these breeds is not typical.

skeletal muscle; superoxide dismutase; glutathione peroxidase; catalase; fatty acids

Gavrilova A. R., Khmara N. V. Opredelenie aktivnosti glutationperoksidazy eritrotsitov pri nasyshchaiushchikh kontsentratsiiakh substrata. Laboratornoe delo. 1986. No 12. S. 721–724. [in Russian]

Danchenko O. O. Antyoksydantnyi status sviiskykh husepodibnykh za riznoho antropohennoho navantazhennia : dys. … d-ra s.-h. nauk : 03.00.04. Kyiv, 2010. 44 s. [in Ukrainian]

Dukh O. I., Vovk S. O. Aktyvnist katalazy ta superoksyddysmutazy i riven tseruloplazminu v pechintsi kurei ta ikh embrioniv zalezhno vid rivnia vitaminu a v ratsioni. Naukovyi visnyk Lvivs'koho natsional'noho universytetu veterynarnoi medytsyny ta biotekhnolohii imeni S.Z. Gzhytskoho. 2010. T. 12, No 2. S. 86–91. [in Ukrainian]

Zdorovtseva L. M. Prooksydantno-antyoksydantna systema v tkanynakh ptakhiv v umovakh hipo- ta hiperoksii : dys. … kand. biol. nauk : 03.00.04. Kyiv, 2011. 22 s. [in Ukrainian]

Zdorovtseva L. M., Pashchenko Yu. P., Danchenko O. O. Prooksydantno-antyoksydantna rivnovaha v tkanynakh mozku i sertsia husei v umovakh hipo- i hiperoksii. Naukovi dopovidi NUBiP Ukrainy. 2011. T. 26, No 4. URL: http://www.nbuv.gov.ua/e-journals/Nd/2011_4/11zlm.pdf [in Ukrainian]

Makarevich O. P., Golikov P. P. Opredelenie aktivnosti superoksiddismutazy. Laboratornoe delo. 1983. No 6. S. 24–28. [in Russian]

Metod opredeleniia aktivnosti katalazy / M. A. Koroliuk ta іn. Laboratornoe delo. 1988. No 1. S. 16–19. [in Russian]

Opredelenie malonovgo dialdegida v tkaniakh i organakh. Kriterii i metody kontrolia metabolizma zhivotnykh i ptits / red.: I. A. Ionov ta іn. 378-me vid. Kharkov, 2011. S. 224–225. [in Russian]

Osoblyvosti antyoksydantnoho vplyvu vitaminu E na okysni protsesy u miasi husei / H. V. Ruban ta in. The Animal Biology. 2017. T. 19, No 3. S. 82–87. URL: https://doi.org/10.15407/animbiol19.03.082 [in Ukrainian]

Osoblyvosti zmin zhyrnokyslotnoho skladu lipidiv miazovykh tkanyn husei v embrionalnomu i rannomu postnatalnomu ontohenezi / A. Fedorko ta in. Visnyk Lvivskoho universytetu. Seriia biolohichna. 2016. No 73. S. 221–225. [in Ukrainian]

Fedorko A. S., Danchenko O. O., Yakoviychuk O. V. Prooksydantno-antyoksydantna rivnovaha u tkanynakh sertsia i mozku husei za embrionalnoho ta rannoho postnatalnoho ontohenezu. Naukovi dopovidi NUBiP Ukrainy. 2020. T. 3, No 85. S. 1–11. URL: http://dx.doi.org/10.31548/dopovidi2020.03.001 [in Ukrainian]

Christensen R. Analysis of variance, design, and regression. Chapman and Hall/CRC, 2018. URL: https://doi.org/10.1201/9781315370095

Dietary selenomethionine increases antioxidant capacity of geese by improving glutathione and thioredoxin systems / X. L. Wan et al. Poultry Science. 2019. Vol. 98, no. 9. P. 3763–3769. URL: https://doi.org/10.3382/ps/pez066

Effects of dietary Enteromorpha powder supplementation on productive performance, egg quality, and antioxidant performance during the late laying period in Zi geese / W. Q. Ma et al. Poultry Science. 2020. Vol. 99, no. 2. P. 1062–1068. URL: https://doi.org/10.1016/j.psj.2019.10.003

Ichihara K., Fukubayashi Y. Preparation of fatty acid methyl esters for gas-liquid chromatography. Journal of lipid research. 2009. Vol. 51, no. 3. P. 635–640. URL: https://doi.org/10.1194/jlr.d001065

Lee B. W. L., Ghode P., Ong D. S. T. Redox regulation of cell state and fate. Redox Biology. 2019. Vol. 25. P. 101056. URL: https://doi.org/10.1016/j.redox.2018.11.014

Okuno T., Yokomizo T. Basic Techniques for Lipid Extraction from Tissues and Cells. Bioactive Lipid Mediators. Tokyo, 2015. P. 331–336. URL: https://doi.org/10.1007/978-4-431-55669-5_23

Ontogenetic features of redox reactions in the myocardium of geese / O. Yakoviichuk et al. Biologija. 2019. Vol. 64, no. 4. URL: https://doi.org/10.6001/biologija.v64i4.3898

Reactive Oxygen Species: A Key Constituent in Cancer Survival / S. Kumari et al. Biomarker Insights. 2018. Vol. 13. P. 117727191875539. URL: https://doi.org/10.1177/1177271918755391

Sündermann A., Eggers L. F., Schwudke D. Liquid Extraction: Bligh and Dyer. Encyclopedia of Lipidomics. Dordrecht, Springer, 2016. P. 1–4. URL: https://doi.org/10.1007/978-94-007-7864-1_88-1

Surai P. F., Kochish I. I. Nutritional modulation of the antioxidant capacities in poultry: the case of selenium. Poultry Science. 2019. Vol. 98, no. 10. P. 4231–4239. URL: https://doi.org/10.3382/ps/pey406