Skip to main navigation menu Skip to main content Skip to site footer

Vol. 18 No. 3 (2019)

Articles

THE INFLUENCE OF BIO-ALGEEN S90 ON THE GROWTHOF MULTIFLORA ROSE SEEDLINGS (Rosa multiflora Thunb.)

DOI: https://doi.org/10.24326/asphc.2019.3.4
Submitted: June 18, 2019
Published: 2019-06-18

Abstract

Striving to intensify horticultural production, new and more effective bio-preparations are being sought to stimulate plant growth and development. Bio-algeen S90 is a natural agent based on sea algae, the high bi- ological activity of which results from the high content of natural growth regulators. The aim of the study was to verify the influence of Bio-algeen S90 on the growth, morphological characteristics and chlorophyll fluorescence of Rosa multiflora seedlings. The bio-preparation was applied one, two and three times at con- centrations: 0.1, 0.2, 0.4 and 0.6 mg.dm−3. Following parameters were measured to evaluate the response of plants to the bio-preparation: F0 – initial fluorescence, Fm – maximal fluorescence in the dark-adapted state, Fv/Fm – maximum photochemical efficiency of PSII. All concentrations of the bio-preparation and frequency of its application stimulated the number of shoots in a bush, the length of shoots and the diameter of the root crown of plants intended for budding. The most beneficial was the two-fold bio-preparation application at a concentration of 0.4 mg.dm–3. Bio-algeen also positively influenced the chlorophyll fluorescence parame- ters. The highest mean F0 and Fm values were recorded with the two-fold preparation treatment. There was no significant effect of the bio-preparation on the Fv/Fm index, which was within the range of 0.75–0.66.

References

  1. Balej, N., Zogaj, R. (2011). Production seedlings of roses by grafting with bud for hybrid teas and climbing roses cultivars. Res. J. Agric. Sci., 43(2), 155–160.
  2. Cetner, M.D., Dombrowski, P., Samborska, I.A., Łukasik, I., Swoczyńska, T., Pietkiewicz, S., Bąba, W., Kalaji, H.M. (2016). Zastosowanie pomiarów fluorescencji chlorofilu w badaniach środowiskowych. Kosmos, 65(2), 197–205.
  3. Dąbrowska, J., Ropek, M., Kołton, A. (2011). Fluorescencja chlorofilu a i jej zastosowanie w ocenie stanu zdrowotności roślin. Materiały VI Krakowskiej Konferencji Młodych Uczonych, Kraków, 559–565.
  4. Dobromilska, R., Gubarewicz, K. (2008). Influence of Bio-algeen S90 on the yield and quality of small-sized tomato. In: Biostimulators in modern agriculture. Solanaceous crops, Dąbrowski, Z.T. (red.). Wieś Jutra, Warsaw, 7–12.
  5. Dobromilska, R., Mikiciuk, M., Gubarewicz, K. (2008). Evaluation of cherry tomato yielding and fruit mineral composition after using of Bio-algeen S-90 preparation. J. Elementol., 13(4), 491–499.
  6. Dudaš, S., Pohajda, I., Šegula, S., Varga, S., Andraković, J. (2014). Effect of cutting severance date on rooting success and Bio-algen S-90 application on further growth of cherry laurel Prunus laurocerasus L. 3rd Conference with International Participation. Conference VIVUS –14th and 15th November 2014, Naklo, Slovenia, 582–587.
  7. Efeoğlu, B., Ekmekçi. Y., Çiçek, N. (2009). Physiological responses of three maize cultivars to drought stress and recovery. S. Afr. J. Bot., 75, 34−42.
  8. Gruszczyk, M., Berbeć, S., (2004). The effect of foliar application of some preparations on yield and quality of feverfew (Chrysathemum parthenium L.) raw material. Ann. UMCS sec. E Agricultura, 59(2), 755–759.
  9. Grześkiewicz, H., Trawczyński, C. (1998). Dolistne stosowanie nawozów wieloskładnikowych w uprawie ziemniaka. Fol. Univ. Agric. Stetin., 72, 75–80.
  10. Hanzal, V., Janiszewski, P., Kubecek, J., Bergman, J., Gjurov, V., Tužinský, M., Baláš, M. (2015). Support of the growth and prosperity of the Norway spruce (Picea abies) seedlings in forest nursery by the Bio-algeen system – preliminary results. Pol. J. Nat. Sci., 30(3), 217–224.
  11. Hetman, J., Szmagara, M. (2013). Produkcja róż w tunelach foliowych. Ogrodnictwo ozdobne sektorem gospodarki narodowej. Wyd. SGGW, Warszawa, 73–80.
  12. Hetman, J., Maliborska, M., Iwanow, T. (2007). Wpływ Actisilu i sposobu uprawy na wzrost róży wielokwiatowej Rosa multiflora. XI Ogólnopolska Konferencja Szkółkarska „Problemy i perspektywy produkcji szkółkarskiej roślin ozdobnych”. Skierniewice, 20–21 lutego 2007, 53–64.
  13. Jamiołkowska, A. (2014). Effect of some biotechnical preparations on the growth of sweet pepper plants in the field production. Ann. UMCS sec. E Agricultura, 24(4), 61–70.
  14. Johnson, G.N., Yong, A.J., Scholes, J.D., Horton P. (1993). The dissipation of excess excitation energy in British plant species. Plant Cell Environ., 16, 673–679.
  15. Kalaji, M.H, Łoboda, T. (2010). Fluorescencja chlorofilu w badaniach stanu fizjologicznego roślin. 2 ed. Wyd. SGGW, Warszawa.
  16. Kałużewicz, A., Bączek-Kwinta, R., Krzesiński, W., Spiżewski, T., Zaworska, A. (2018). Effect of biostimulants on chlorophyll fluorescence parameters of broccoli (Brassica oleracea var. italica) under drought stress and rewatering. Acta Sci. Pol. Hortorum Cultus, 17(1), 97–106.
  17. Kiełtyka-Dadasiewicz, A., Król, B. (2012). Efekty dolistnego stosowania Bio-algeenu S90 i Biotrissolu T w uprawie serdecznika pospolitego (Leonurus cardiaca L.). Ann. UMCS, sec. E Agricultura, 67(2), 11–19.
  18. Lorenc, F., Pešková, V., Modlinger, R., Podrázský, V., Baláš, M., Kleinová, D. (2016). Effect of Bio-Algeen® preparation on growth and mycorrhizal characteristics of Norway spruce seedlings. J. For. Sci., 62(6), 285–291.
  19. Matysiak, K., Adamczewski, K. (2009). Regulatory wzrostu i rozwoju roślin – kierunki badań w Polsce i na świecie. Prog. Plant Prot., 49(4), 1810–1816.
  20. Maxwell, K., Johnson, G.N. (2000). Chlorophyll fluorescence – a practical guide. J. Exp. Bot., 51(345), 659–668.
  21. Michałek, W., Sawicka, B. (2005). Zawartość chlorofilu i aktywność fotosyntetyczna średnio późnych odmian ziemniaka w warunkach pola uprawnego w środkowo-wschodniej Polsce. Acta Agrophys., 6(1), 183–195.
  22. Mikiciuk, M., Dobromilska, R. (2014). Assessment of yield and physiological indices of small-sized tomato cv. ‘Bianka F1’ under the influence of biostimulators of marine algae origin. Acta Sci. Pol. Hortorum Cultus, 3(1), 31–41.
  23. Monder, M.J., Hetman, J. (2011). The influence of the thickness of rootstock and scions on the growth and quality of the obtained shrubs of two Rosa × hybrida cultivars. Part I. Growth parameter of the rose shrubs. Acta Sci. Pol. Hortorum Cultus, 10(1), 185–195.
  24. Niu, G., Rodriguez, D.S. (2009). Growth and physiological responses of four rose rootstocks to drought stress. J. Am. Soc. Hortic. Sci., 134(2), 202–209.
  25. Olszewska, M., Grzegorczyk, S., Olszewski, J., Bałuch-Małecka, A. (2010). A comparison of the response of selected grass species to water stress. Grassl. Sci. Pol., 13, 127–137.
  26. Orlikowski, L.B., Skrzypczak, Cz., Wojdyła, A., Jaworska-Marosz, A. (2002). Wyciągi roślinne i mikroorganizmy w ochronie roślin przed chorobami. Zesz. Nauk. AR Kraków, 82, 19–32.
  27. Polanco, L.R., Fabrício, Rodrigues A., Nascimento, K.J.T., Cruz, M.F.A., Curvelo, C.R.S., DaMatta, F.M., Vale, F.X.R. (2014). Photosynthetic gas exchange and antioxidative system in common bean plants infected by Colletotrichum lindemuthianum and supplied with silicon. Trop. Plant Paathol., 39(1), 35–42.
  28. Pudelska, K. (2003). Oddziaływanie podkładek na wzrost i kwitnienie odmian szlachetnych róż. Wyd. Nauk. AR Lublin, 269, 91 pp.
  29. Rios, V.S., Rios, J.A., Aucique-Pérez, C.E., Silveira, P.R., Barros, A.V., Rodrigues, F.Á. (2018). Leaf gas exchange and chlorophyll a fluorescence in soybean leaves infected by Phakopsora pachyrhizi. J. Phytopathol., 166, 75–85.
  30. Roháček, K., Barták, M. (1999). Technique of the modulated chlorophyll fluorescence: basic concepts, useful parameters, and some applications. Photosynthetica, 37, 339−363.
  31. Sultana, S., Baloch, G.N., Ara, J., Ehteshamul-Haque, S., Tariq, R.M., Athar, M. (2011). Seaweeds as an alternative to chemical pesticides for the management of root diseases of sunflower and tomato. J. Appl. Bot. Food Qual., 4, 162–168.
  32. Szabó, V., Magyar, L., Hratkó, K. (2016). Effect nof leaf spray treatments on rooting on Prunus machaleb (L.) cuttings. Acta Sci. Pol. Hortorum Cultus, 15(1), 77–87.
  33. Szmagara, M. (2007). Biotic and biotechnical factors inhibiting the growth and development of Topospora myrtilli (Feltg.) Boerema. Electron. J. Pol. Agric. Univ., 10(4), #14.
  34. Szmagara, M., Hetman, J., Pudelska, K., Kozak, D., Marcinek, B., Dudkiewicz, M., (2016). The effect of schoot bending and rootstock on quantity and quality of cut flower of rose cv. ‘Red House’ yield. Acta Sci. Pol. Hortorum Cultus, 15(2), 65–75.
  35. Tobiasz-Salach, R., Bobrecka-Jamro, D., Pyrek-Bajcar, E., Buczek, J. (2016). Response of hulled and naked oat to foliar fertilization. Acta Sci. Pol. Agricultura, 15(2), 77–88.
  36. Truba, M., Jankowski, K., Sosnowski, J. (2012). The plants reaction on biological preparations treatment. Ochr. Środ. Zasobów Nat., 53, 41–52.
  37. Włodarczyk, Z., Bryzek, Ł. (2008) Ocena plonowania i jakości pędów kwiatowych trzech odmian róż szklarniowych rozmnażanych z sadzonek i przez szczepienie na trzech różnych podkładkach. Zesz. Probl. Post. Nauk Roln., 525, 469–475.
  38. Zlatev, Z., Yordanov, I.T. (2004). Effects of soil drought on photosynthesis and chlorophyll fluorescence in bean plants. Bulg. J. Plant Physiol., 30, 3−18.

Downloads

Download data is not yet available.

Most read articles by the same author(s)

<< < 1 2 3 > >> 

Similar Articles

1 2 3 4 5 6 7 8 9 10 > >> 

You may also start an advanced similarity search for this article.