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Ukr. Bot. J. 2015, 72(4): 393–397
Plant Physiology, Biochemistry, Cell and Molecular Biology

The influence of metal citrates obtained by aquananotechnology on growth of the strains of medical macromycetes Ganoderma lucidum 1900 and Trametes versicolor 353

Al-Maali G.A.

The article presents results of the research on influence of different concentrations of metal citrate and sulfate (iron, copper, zinc and manganese) on the growth of medicinal macromycetes strains Ganoderma lucidum (Curtis) P. Karst 1900 and Trametes versicolor (L.) Lloyd 353. The strains are preserved in the Culture collection of mushrooms of M.G. Kholodny Institute of Botany, National Academy of Sciences of Ukraine. Concentrations of metal citrates, optimal for biomass accumulation, were determined for the studied strains. The highest biomass of T. versicolor 353 (8.6 g / L) was obtained in a medium with copper citrate, with a concentration of copper ions of 4 mg / L while the highest biomass of Ganoderma lucidum 1900 (9.9 g/L) was obtained in a medium with zinc citrate, with a concentration of zinc ions of 1 mg / L.

Keywords: Ganoderma lucidum, Trametes versicolor, metals citrate, biomass

Full text: PDF (Ukr) 587K

  1. Antonenko L.A. Biotechnology of biomass higher basidiomycetes of the genus Coriolus: Cand. Sci. Diss. Abstract, Kyiv, 2013, 22 p.
  2. Bandura I.I. Improvement of technological elements for industrial production of edible mushroom Pleurotus (Fr.) P. Kumm.: Cand. Sci. Diss. Abstract, Kyiv, 2014, 22 p.
  3. Chen X., Hu Z.P., Yang X.X., Huang M., Gao Y., et al. Int. immunopharmacol., 2006, 6, pp. 499–508.
  4. Klechak I.R., Bisko N.A., Mytropolska N.Iu., Antonenko L.O. Naukovi visti NTUU KPI, 2013, 3, pp. 59–64.
  5. Kosionov M.V., Kaplunenko V.H. Sposib otrymannia karboksylativ kharchovykh kyslot z vykorystanniam nanotekhnolohii. Patent VA № 39392, publ. 25.02.2009.
  6. Krupodorova T.A. Biological pecularity of Ganoderma applanatum (Pers.) Pat. and G. lucidum (Curtis) P. Karst in culture: Cand. Sci. Diss. Abstract, Kyiv, 2009, 21 p.
  7. Levasseur A., Piumi F., Coutinho P.M., Rancurel C., Asther M. et al. Fungal Genet. Biol., 2008, 45, pp. 638–645.
  8. Lui G.-T. Intern. J. Med. Mushr., 1999, 1(1): 63–67.
  9. Mizuno T., Sakamura S. Chem. Biol.,1995a, 23, pp. 797–802.
  10. Mizuno T., Sakamura S. Food Rev. Intern., 1995b, 60, pp. 151–166.
  11. Nanomaterialy v biologii. Osnovy nanoveterynarii. Eds V.B. Borysevych, V.H. Kaplunenko, Kyiv: Avitsena, 2010, 416 p.
  12. Patel S., Goyal A. Biotech., 2012, 2(1): 1–15.
  13. Paterson R.R. Phytochemistry, 2006, 67, pp. 1985–2001.
  14. Sanodiya B.S., Thakur G.S., Baghel R.K., Prasad G.B., Bisen P.S. Curr. Pharm. Biotechnol., 2009, 10, pp. 717–742.
  15. Serdiuk A.M., Gulich M.P., Kaplunenko V. G., Kosinov N. V. Materialy VI Mizhnarodnoi naukovo-praktichnoi konferentsii ‘Aktulni pytannia ta organizatsiyno-pravovi zasady spivrobitnytstva Ukrainy ta KNR u sferi visokykh tekhnologiy’, Kyiv, 2009, pp. 135–140.
  16. Wang H.X., Ng T.B. Appl. Microbiol. Biotechnol., 2006, 72, pp. 508–513.
  17. Wasser S.P. Biomed. J., 2014, 37(6): 345–356.
  18. Yashchenko O.V. Hygienic assessment of food and biological value of fungi, cultivated on the nutrient mediawith addition of biometal nanocitrates: Cand. Sci. Diss. Abstract, Kyiv, 2013, 21 p.
  19. Zong A., Cao H., Wang F. Carbohyd. Polym., 2012, 90, pp. 1395–1410.