ISSN 2410-776X (Online),
ISSN 2410-7751 (Print)
"Biotechnologia Acta" v. 6, no 6, 2013
https://doi.org/10.15407/biotech6.06.120
Р. 120-131, Bibliography 44, Ukrainian.
Universal Decimal classification: 582.284+57.083.132:532.61.08
Chaika A. V.1, Fedotov O. V.1, Fainerman V. B.2, Lylyk S. V.2
1Donetsk National University, Ukraine
2Donetsk National Medical University, Ukraine
The tensio-rheometric characteristics of 63 strains belonging to 19 basidiomycetes species submerged culture filtrate were investigated by the axisymmetric pendent drop profile analysis. The method showed required high sensitivity with mycological material. It was found that the interfacial tensiometric and rheometric parameters depend significantly on culture species, hence it is proposed to use ones complex for systematic identification of cultures and as a selection criterion for biosurfactantsproducing strains of basidiomycetes. Correlations of tensio-rheometric characteristics both among themselves and with the culture growth and lipid peroxidation rates were found. This provides an integrated indicator of the submerged culture metabolic state. By the results of the study several strains of basidiomycetes — potential producers of biosurfactants with a high growth rate and intensity of lipid peroxidation were selected for biotechnological manufacture.
Key words: xylotrophic basidiomycetes, submerged fermentation, interfacial tensiometry and rheometry, lipid peroxidation.
© Palladin Institute of Biochemistry of National Academy of Sciences of Ukraine, 2013
References
1. Feofilova E. P. New biotechnologies for production of biologically active substances of filamentous fungi. Usp. med. micol. 2007, V. 9, P. 195–196. (In Russian)
2. Villas-Boas S., Esposito G. E., Mitchell D. A., Villas-Boas S. G. Microbial conversion of lignocellulosic residues for production of animal feeds. Anim. Feed Sci. Technol. 2002, V. 98, Р. 1–12.
3. Wasser S. P., Sytnik K. M., Buchalo A. S., Solomko E. F. Medicinal mushrooms: past, present and future. Ukr. Botan. Journ. 2002, 59 (5), 499–524.
4. Antonenko L. O., Kuchma V. M., Krasiuk Yu. S. The impact of power supply on the growth of fungi of Coriolus Quel (Trametes Fr.) and their antioxidant activity. Nauk. Visti NTUU “KPI”. 2010, N 3, P. 10–15. (In Ukrainian).
5. Babitskaya V. G., Shcherba V. V., Gvozdkova T. S. New dietary supplements based on submerged mycelium of basidiomycetes. Usp. med. mikol. 2006, V. 7, P. 178–180. (In Russian).
6. Linovttska V. M., Bukhalo A. S., Dugan O. M. Selection of submerged conditions Grifola frondosa as a basis for the establishment of biotechnology obtain health care drugs. Nauk. Visti NTUU “KPI”. 2011, N 3, P. 56–60. (In Ukrainian).
7. Ufimtseva O. V., Mironov P. V. Obtaining of biomass oyster mushroom mycelium P 05/88 Pleurotus ostreatus and sulfur-yellow Polypore LS 1-06 Laetiporus sulphureus in deep conditions. Conifers of the boreal zone. 2009, 26 (2), 294–296. (In Russian).
8. Shcherba V. V., Babitskaya V. G. Carbohydrates submerged mycelium xylotrophic Basidiomycetes. Prikl. biokhim. mikrobiol. 2004, 41 (2), 194–199. (In Russian).
9. Vinayov A. Yu., Gordeev L. S., Kukharenko A. A., Panfilov V. I. The fermentation equipment for microbiological synthesis processes. Ed. V. A. Bykov. Мoskva. 2005, 278 p. (In Russian).
10. Garibova L. V., Antimonova, A. V., Zav’yalova L. A., Krasnopol’skaya L. M. Growth and Morphological Characteristics of the Reishi mushroom Ganoderma lucidum as Functions of Cultivation Conditions. Mikol. Fitopatol. 2003, 37 (3), 14–19.
11. Kim S. W., Hwang H. J., Park J. P. Mycelial growth and exo-biopolymer production by submerged culture of various edible mushrooms under different media. Lett. Appl. Microbiol. 2002, V. 34, Р. 56–61.
12. Campeanu G., Pele M., Cimpeanu M. Studies on the rheological properties of the fermentation broth in the production of pectolytic enzymes. Int. Agrophysics. 1999, V. 13, P. 421–424.
13. W?sten H. A. B., Willey J. M. Surface-active proteins enable microbial aerial hyphae to grow into the air. Microbiology. 2000, V. 146, Р. 767–773.
14. Linder M. B., Szilvay G. R., Nakari-Setala T., Penttila M. E. Hydrophobins: the protein-amphiphiles of filamentous fungi. FEMS Microbiol. Rev. 2005, V. 29, Р. 877–896.
15. W?sten H. A. B., Wessels J. G. H. Hydrophobins, from molecular structure to multiple functions in fungal development. Mycoscience. 1997, V. 38, Р. 363–374.
16. Kapich A. N., Karneichyk T. B. Determination of antioxidant activity in models of linoleic acid peroxidation initiated mushroom manganese peroxidase. Usp. med. mikol. 2007, V. 9, P. 162–164. (In Russian).
17. Kapich A. N. Pairing lipid peroxidation degradation of lignin from wood-Basidiomycetes. Mikrobn. biotekhnol.: fundament. prikl. asp.: Sb. nauchn. tr. 2011, N 3, P. 316–335. (In Russian).
18. Hammel K. E., Kapich A. N., Jensen K. A. Jr., Ryan Z. C. Reactive oxygen species as agents of wood decay by fungi. Enzyme and Microbial Technology. 2002, V. 30, Р. 445–453.
19. Pozdnyakova N. N., Nikiforova V. O., Turkovskaya O. V. Influence of PAHs on ligninolytic enzymes of the fungus Pleurotus ostreatus D1 S. Cent. Eur. J. Biol. 2010, 5 (1), 83–94.
20. Wasser S. P. Current findings, future trends, and unsolved problems in studies of medicinal mushrooms. Appl. Microbiol. Biotechnol. 2011, V. 89, Р. 1323–1332.
21. Bezalel L., Hadar Y., Fu P. P. Metabolism of phenanthrene by the white rot fungus Pleurotus ostreatus. Appl. Microbiol. Biotechnol. 1996, V. 62, P. 2547–2553.
22. Valentin L., Feijoo G., Moreira M. T., Lema J. M. Biodegradation of polycyclic aromatic hydrocarbons in forest and salt marsh soils by white-rot fungi. Int. Biodeterior. Biodegr. 2006, V. 58, P. 15–21.
23. Wesenberg D., Kyriakides I., Agathos S. N. White-rot fungi and their enzymes for the treatment of industrial dye effluents. Biotechnol. Adv. 2003, V. 22, Р. 161–187.
24. Winquist E., Moilanen U., Mettala A. Production of lignin modifying enzymes on industrial waste material by solid-state cultivation of fungi. Biochem. Eng. J. 2008, V. 42, Р. 128–132.
25. Ron E. Z., Rosenberg E. Biosurfactants and oil bioremediation. Curr. Opin. Biotechnol. 2002, V. 13, P. 249–252.
26. Rosenberg E., Navon-Venezia S., Ron E. Z. Rate-limiting steps in the microbial degradation of petroleum hydrocarbons. Soil and Aquifer Pollution. Ed. by Rubin H. Berlin-Heidelberg: Springer-Verlag. 1998, Р. 159–172.
27. Tugrul T., Cansunar E. Detecting surfactant-producing microorganisms by the drop-collapse test. World J. Microbiol. Biotechnol. 2005, V. 21, Р. 851–853.
28. Banat I. M., Makkar R. S., Cameotra S. S. Potential commercial applications of microbial surfactants. Appl. Microbiol. Biotechnol. 2000, V. 53, P. 495–508.
29. Makkar R. S., Cameotra S. S., Banat I. M. Advances in utilization of renewable substrates for biosurfactant production. AMB Exp. 2011, 1 (5), 1–19.
https://doi.org/10.1186/2191-0855-1-5
30. Gogotov I. M., Belonozhkin S. V., Khodakov R. S., Shkidchenko A. M. Biosurfactants: producers, properties and practical use. Mater. 3rd Int. Conf. "International cooperation in biotechnology: expectations and reality". Pushchino: ITs "Bioresources and Ecology". 2006, P. 104–111. (In Russian).
31. Desai J. D., M. Microbial production of surfactants and their commercial potential. Microbiol. Mol. Biol. Rev. 1997, 61 (1), 47–64.
32. Abramzon A. A., Zaichenko L. P., Raindgolts S. I. Surfactants. Synthesis, analysis and application. L.: Khimiya. 1988, 200 p. (In Russian).
33. Fedotov O. V., Chaika O. V., Voloshko T. E., Velogodska A. K. Culture Collection of mushrooms - the basis of mycological research and biodiversity conservation strategies basidiomycetes. Visn. Donetskogo nats. un-tu. Srr. A. Prirodn. nauky. Donetsk, DonNU. 2012, N 1, P. 209–213. (In Ukrainian).
34. Bukhalo A. S. Higher edible Basidiomycetes in pure culture. K.: Nauk. dumka. 1988, 144 p. (In Russian).
35. Dudka I. A., Vasser S. P., Ellanskaia I. A. Methods of experimental mycology. K.: Nauk. dumka. 1982, 550 p. (In Russian).
36. Kazakov V. N., Knyazevich V. M., Sinyachenko O. V. Interfacial Rheology of Biological Liquids: Application in Medical Diagnostics and Treatment Monitoring. Interfacial Rheology. V. 1. Progress in Colloid and Interface Science, R. Miller and L. Liggieri (Eds.). Brill Publ., Leiden. 2009, Р. 519–566.
37. Zaitsev S. Yu., Milaeva I. V., Zarudnaya E. N., Maximov V. I. Investigation of dynamic surface tension of biological liquids for animal blood diagnostics. Coll. Surf. 2011, V. 383, P. 109–113.
38. Kazakov V. N., Vozianov A. F., Sinyachenko O. V. Studies on the application of dynamic surface tensiometry of blood and cerebrospinal liquid for the diagnostics and?treatment control of rheumatic, neurological and oncological diseases. Adv. Coll. Interface Sci. 2000, V. 86, Р. 1–38.
39. Kazakov V. N., Barkalova E. L., Levchenko L. A. Dilation rheology as medical diagnostics of human biological liquids. Coll. Surf. 2011, V. 391, Р. 190–194.
40. Zholob S. A., Makievski A. V., Miller R., Fainerman V. B. Advances in calculation methods for the determination of surface tensions in drop profile analysis tensiometry. Bubble and Drop Interfaces. V. 2. Progress in Colloid and Interface Science, R. Miller and L. Liggieri (Eds.). Brill Publ., Leiden. 2011, Р. 49–74.
41. Fainerman V. B., Fainerman B. V., Umanskii V. Ya. On the control of organic compounds in drinking water and natural water by interfacial tensiometry. Vestn. gig. epidemiol. 2006, 10 (1), 181–185. (In Russian).
42. The decision to grant Ukraine a patent for utility model "Method of determining the intensity of lipid peroxidation basidiomycetes cultures" of 14.11.2012. Appl. № u201208872. (In Ukrainian).
43. Prysedskii Yu. G. Statistical analysis of the results of biological experiments. Donetsk: Kassiopeia. 1999, 210 p. (In Ukrainian).
44. Pat. 57945 Ukraine. Method for mikotesting of pollution by phenol. Fedotov O. V., Pertsevoy M. S. Appl. № u201009019 on 19.07.2010, MPK (2011.01), kl. А01G7/00, A01H15/00, Bul. № 6 on 25.03.2011. (In Ukrainian).