Вплив вікасолу на активність дегідрогеназ циклу Кребса та стан системи антиоксидантного захисту м’язів шлунка гусей

O.V. Yakoviichuk; O.O. Danchenko; M.M. Danchenko; A.S. Fedorko; T.M. Haponenko

doi:10.31548/bio2019.05.002

Authors

O.V. Yakoviichuk Bogdan Khmelnitsky Melitopol State Pedagogical University
O.O. Danchenko Tavria State Agrotechnological University , Таврійський державний агротехнологічний університет
M.M. Danchenko Tavria State Agrotechnological University , Таврійський державний агротехнологічний університет
A.S. Fedorko Bogdan Khmelnitsky Melitopol State Pedagogical University
T.M. Haponenko Bogdan Khmelnitsky Melitopol State Pedagogical University

DOI:

https://doi.org/10.31548/bio2019.05.002

Keywords:

vicasol, dehydrogenases, antioxidant enzymes, product of lipids peroxidation

Abstract

The aim of work was to study the effect of vicasol on the Krebs cycle dehydrogenase activity and the state of the antioxidant defense system of geese muscle tissue of the stomach.

According to the results of the work, it was found in the smooth muscle tissue of the stomach of geese, vicasol increases the activity of glutathione peroxidase, catalase and superoxide dismutase on the 14th and 21st days of ontogenesis, in particular, on the 14th day glutathione peroxidase, catalase and superoxide dismutase activity increase by 181.1 % (p≤0.05), 153.2% (p≤0.05) i 103.3% (p≤0.05), after 7 days 168.0% (p≤0.05), 99.7% (p≤0.05) i 111.3% (p≤0.05) relative to the control group. The antioxidant system enzymes activity of the experimental group on the 28th day tends to decrease, however, a significant difference is observed only between groups of animals for superoxide dismutase, whose activity is reduced by 62.5 % under the influence of vicasol (p≤0.05). On the 35th day of ontogenesis, the activity of glutathione peroxidase and catalase in the experimental group increases by 43.2% (p≤0.05) and 54.1% (p≤0.05) compared to the control, at this time the activity of superoxide dismutase is lower by 23.9 % (p≤0.05).

A significant increase in the concentration of lipids hydrogen peroxides (28th day) by 27% (p≤0.05) relative to the control was established in the tissue, followed by a decrease on the 35th day of ontogenesis. Vicasol stabilizes the content of end products of lipid peroxidation in tissue homogenate, with the exception of a decrease of 8.6% (p≤0.05) at the end of experiment. Upon induction of peroxide processes with Fe²⁺ in cell, it is increased their content by 108 % (p≤0.05) (21st day), at the end of the experiment, a decrease in the content of secondary lipid decomposition products in the experimental group of animals by 27.5% (p≤0.05).

The antioxidant activity of the tissue at the beginning of the experiment under the influence of vicasol was higher by 30%, on the the 21st day decreased by 50% relative to the control group, and on the 35th day it increased by 21,6 %.

Vicasol increases the activity of the Krebs cycle dehydrogenase, in particular, succinate dehydrogenase, which activity is higher during the experiment by 14- (78.2%; p≤0.05), 21- (263.3%; p≤0.05), 28- (78, 8%; p≤0.05) and the 35th (92.3%; p≤0.05) day. 2-oxoglutarate dehydrogenase activity are more specific and significantly increases relative to the control group by 14- (122.2%; p≤0.05), 21- (84.4%; p≤0.05) and on the 28th (133.3%; p≤ 0.05) day relative to the control group.

In general, vicasol activates the system of antioxidant protection and energy metabolism, that is, it is a complex activator of the body’s metabolic functions.

References

Baran I., Ionescu D., Filippi A., Mocanu M., Iftime A., Babes R. Tofolean I.T., Irimia R., Goicea A., Popescu V., Dimancea A., Neagu A., Ganea C. (2014). Novel insights into the antiproliferative effects and synergism of quercetin and menadione in human leukemia Jurkat T cells. Leuk. Res, 38(7), : 836-849. (in English).

https://doi.org/10.1016/j.leukres.2014.04.010

Benedetti S., Nuvoli B., Catalani S., Galati R. (2015). Reactive oxygen species a double-edged sword for mesothelioma. Oncotarget, 6(19), : 16848-16865. (in English).

https://doi.org/10.18632/oncotarget.4253

Birjukova, D. Ju. (2000). Influence of biostimulating fodder additive and vikasol Z-naphthol on metabolism and productivity in broiler chickens. dis. сand. biol. sci. Novosibirsk,. 150. p. (in Russian).

Bolton J.L., Dunlap T. (2017). Formation and Biological Targets of Quinones: Cytotoxic versus Cytoprotective Effects. Chem Res Toxicol, 30(1) :, 13-37. (in English).

https://doi.org/10.1021/acs.chemrestox.6b00256

Carpentieri A., Marchionatti A., Areco V., Perez A., Centeno V., Tolosa de Talamoni N. (2014). Antioxidant and antiapoptotic properties of melatonin restore intestinal calcium absorption altered by menadione. Mol Cell Biochem, 387(1-2), : 197-205. (in English).

https://doi.org/10.1007/s11010-013-1885-2

Chen J., Hu X., Cui J. (2018). Shikonin, vitamin K3 and vitamin K5 inhibit multiple glycolytic enzymes in MCF-7 cells. Oncol Lett, 15(5), : 7423-7432. (in English).

https://doi.org/10.3892/ol.2018.8251

Danchenko O.O., Paschenko J.P., Danchenko N.M., Zdorovtseva L.M. (2012). Mechanisms of support prooxidant-antioxidant balance in the liver tissues of geese inhypo- and hyperoxia. Ukr.Biochem.J., 84(6), : 109-114.

Erjomin D.V., Petrov L. A. (2005). Phonometric determination of 2-methyl-1,4-naphthoquinone (vitamin K3) and 2-methylnaphthalene in reaction mixture. Analytics and control, 9(4), : 428-432.

Eshenko N.D., Volskii G.G. Determination of the amount of succinic acid and succinate dehydrogenase activity. In: Biochemical research methods, Leningrad. pp. 207-210. (in Russian).

Góth L. (1991). A simple method for determination of serum catalase activity and revision of reference range. Clin Chim Acta, 196(2-3) ,: 143-151. (in English).

https://doi.org/10.1016/0009-8981(91)90067-M

Haefeli R.H., Erb M., Gemperli A.C., Robay D., Courdier-Fruh I., Anklin C., Dallmann R., Gueven N. (2011). NQO1-dependent redox cycling of idebenone: effects on cellular redox potential and energy levels. PLoS One, 6(3). URL: https://www.intechopen.com/books/secondary-metabolites-sources-and-applications/physiology-and-pathology-of- mitochondrial-dehydrogenases.(in English).

https://doi.org/10.1371/journal.pone.0017963

Hassan G.S. (2013). Menadione. Profiles Drug Subst Excip Relat Methodol, 38, : 227-313. (in English).

https://doi.org/10.1016/B978-0-12-407691-4.00006-X

Havrilova A.R., Hmara N.V. (1986) Determination of erythrocyte glutathione peroxidase activity. Lab. Delo, 12, : 721-724. (in Russian).

Hein S., Steinbüchel A. (1996). Cloning and characterization of the Alcaligenes eutrophus 2-oxoglutarate dehydrogenase complex. FEMS Microbiol Lett, 136(3), : 231-238. (in English).

https://doi.org/10.1111/j.1574-6968.1996.tb08054.x

Ionov I.A., Shapovalov S.O., Rudenko E.V., Long M.N., Akhtyrsky A.V., Zozulya Yu.A., Komisova T.E., Kostyuk I.A. (2011). Criteria and methods of control. Institute of Animal Husbandry of the National Academy of Agrarian Sciences, Kharkov. (in Russian).

Ivanova, O. V. (2003). Effect of vicasol and probiotics on the productivity of broiler chickens. dis. cand. agrarian sci. Novosibirsk,. 112 p. (in Russian).

Jan Y.H., Richardson J.R., Baker A.A., Mishin V., Heck D.E., Laskin D.L., Laskin J.D. (2015). Vitamin K3 (menadione) redox cycling inhibits cytochrome P450-mediated metabolism and inhibits parathion intoxication. Toxicol Appl Pharmacol, 288(1), 114-120. (in English).

https://doi.org/10.1016/j.taap.2015.07.023

Kim E.H., Kim M.K., Yun H.Y., Baek K.J., Kwon N.S., Park K.C., Kim D.S. (2013). Menadione (Vitamin K3) decreases melanin synthesis through ERK activation in Mel-Ab cells. Eur J Pharmacol, 718(1-3), : 299-304. (in English).

https://doi.org/10.1016/j.ejphar.2013.08.018

Krylova N.G., Kulagova T.A., Semenkova G.N., Cherenkevich S.N. (2009). Vitamin K3-induced activation of molecular oxygen in glioma cells. Ukr Biokhim Zh (1999)., 81(6) ,: 85-93. (in Russian).

Krylova N.G., Kulahava T.A., Cheschevik V.T., Dremza I.K., Semenkova G.N., Zavodnik I.B. (2016). Redox regulation of mitochondrial functional activity by quinones. Physiol Int, 103(4), : 439-458. (in English).

https://doi.org/10.1556/2060.103.2016.4.4

Krylova N.G., Kylagova T.A., Semenkova G.N, Shadyro O.I., Cherenke S.N. (2014). Molecular mechanisms of quinone-mediated regulation of cellular signaling pathways. News of the National Academy of Sciences of Belarus. Series of Biological Sciences, 3, : 105-115. (in Russian).

Marchionatti A.M., Perez A.V., Diaz de Barboza G.E., Pereira B.M., Tolosa de Talamoni N.G. (2008). Mitochondrial dysfunction is responsible for the intestinal calcium absorption inhibition induced by menadione. Biochim Biophys Acta, 1780(2) ,: 101-107. (in English).

https://doi.org/10.1016/j.bbagen.2007.10.020

Method for determination of antioxidant activity of superoxide dismutase and chemical compounds: pat. 2144674. Russian Federation. № 99103192/14; st. 24.02.1999; pub. 20.01.2000. (in Russian).

Morgan M.J., Liu Z.G. (2011). Crosstalk of reactive oxygen species and NF-κB signaling. Cell Res, 21(1), : 103-115. (in English).

https://doi.org/10.1038/cr.2010.178

Moskalenko N.I., Komarovska-Porohniavets O.Z., Iskiv O.P., Stadnytska N.E. (2008). Biological and pharmacological aspects of quinones. Bulletin of Lviv Polytechnic National University. Chemistry, technology of substances and their application, 2008, 609, : 124-130. (in Ukrainian).

Oeckinghaus A., Ghosh S. (2009). The NF-kappa B family of transcription factors and its regulation. Cold Spring Harb Perspect Biol, 1(4). URL: https://cshperspectives.cshlp.org/content/1/4/a000034.long. (in English).

https://doi.org/10.1101/cshperspect.a000034

Oh S.J., Han H.K., Kang K.W., Lee Y.J., Lee M.Y. (2013). Menadione serves as a substrate for P-glycoprotein: implication in chemosensitizing activity. Arch Pharm Res, 36(4) ,: 509-516. (in English).

https://doi.org/10.1007/s12272-013-0052-3

Romani A.P. (2018). Physiology and Pathology of Mitochondrial Dehydrogenases. In: Secondary Metabolites, 125-138. (in English).

https://doi.org/10.5772/intechopen.76403

Saparova, E. I. (1999). The effectiveness of the use of various dosages of vicasol nicotinamide form in the diet of broiler chickens. dis. cand. agrarian sci. Kemerovo,. 112 p. (in Russian).

Vukomanovic D., Rahman M.N., Bilokin Y., Golub A.G., Brien J.F., Szarek W.A. et al. (2014). I2014.n vitro Activation of heme oxygenase-2 by menadione and its analogs. Med Gas Res., № 4(1). URL: https://www.ncbi.nlm.nih.gov/pmc/articles/PMC3942077/. (in English).

https://doi.org/10.1186/2045-9912-4-4

Wiraswati H.L., Hangen E., Sanz A.B., Lam N.V., Reinhardt C., Sauvat A., Mogha A., Ortiz A., Kroemer G., Modjtahedi N. (2016). Apoptosis inducing factor (AIF) mediates lethal redox stress induced by menadione. Oncotarget, 7(47) ,: 76496-76507.(in English).

https://doi.org/10.18632/oncotarget

Wróbel M., Jurkowska H. (2007). Menadione effect on l-cysteine desulfuration in U373 cells. Acta Biochim Pol, 54(2), : 407-411. (in Polish).

https://doi.org/10.18388/abp.2007_3263

Yakoviichuk O.V., Ruban G.V., Danchenko O.O. (2017). The effect of vikasol on the activity of Krebs and antioxidant system enzymes and the state of peroxide oxidation in geese muscles. Technology of production and processing of livestock products, 1(134), : 105-112. (in Ukrainian).

Yongbo C. (2017). Modified Bradford procedure for residual protein testing in enzyme catalysis synthesis products. URL: protocols.iodx.doi.org/ 10.17504/ protocols.io.k4kcyuw. (in English).

Influence of vicasol on the krebs cycle dehydrogenases activity and state of antioxidant defense system of the smooth muscle tissue of geese

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