Physiological-biotechnological aspects of drought resistance of narrow-leaved lavender (Lavandula angustifolia mill.)

O. Klyachenko, I. Shliakhtun


National Nature Park “Pyryatynsky”  is a valuable reserve of flora and vegetation of the Left-Bank Dnipro. The extensive hydrological network of the Udai River and the wide representation within this nature reserve of floodplain reservoirs are the reason for the high diversity of plant communities of higher aquatic vegetation. In this article we classified the communities of order  Callitricho-Batrachietalia  in National nature park "Pyryatynskyi" and identify the features of their syntaxonomic and ecological differentiation. Fragmentary and non-comlete information about this type of vegetation are existed in literature, however, without geobotanical releves and detailed characteristics of the structure of phytoceonoses, synecology and synchorology. All obtained results based on original field data. In total, 22 geobotanical releves were performed during the period 2010–2017. The description of communities was carried out within their natural boundaries. Treatment of fitosociological data was performed with the JUICE software package. The nomenclature of syntaxons was consistent with the International Code of Phytosociological Nomenclature (ICFN).The order of Callitricho-Batrachietalia on the territory of NPP "Pyriatynsky" is represented by alliance Batrachion aquatilis Gehu 1961 and 4 associations (Batrachietum aquatilis Gehu 1961, Potameto perfoliati–Batrachietum circinati Sauer 1937, Hottonietum palustris Sauer 1947, Veronico beccabungae–Callitrichetum stagnalis (Oberdorfer 1957) Th. Müller 1962). This is first prodrome of order  Callitricho-Batrachietalia  for territory of National Nature Park “Pyryatynskyi”. The communities of this syntaxon occupy small areas and have a limited distribution in the region. Most of them are rare and vulnerable to changes in environmental conditions. Monitoring of their structure, chorology and dynamics is an important task to maintain and preserve the species and coenotic diversity of NPP "Pyryatynsky".

Повний текст:

PDF (English)


López, V., Nielsen, B., Solas, M., Ramírez, M. J., & Jäger, A. K. (2017). Exploring pharmacological mechanisms of lavender (Lavandula angustifolia) essential oil on central nervous system targets. Frontiers in pharmacology, 8, 280.

Kunicka‐Styczyńska, A., Sikora, M., & Kalemba, D. (2009). Antimicrobial activity of lavender, tea tree and lemon oils in cosmetic preservative systems. Journal of applied microbiology, 107(6), 1903-1911.

Erland, L. A., & Mahmoud, S. S. (2016). Lavender (Lavandula angustifolia) oils. Essential oils in food preservation, flavor and safety, 501-508.

Prusinowska, R., & Śmigielski, K. (2014). Composition, biological properties and therapeutic effects of lavender (Lavandula angustifolia L). A review. Herba Polonica. 60.

Kwon, M. Y., & Woo, S. Y. (2016). Plants responses to drought and shade environments. African Journal of Biotechnology. 15. 29-31.

Giray, F. (2018). An analysis of world lavender oil markets and lessons for Turkey. Journal of Essential Oil Bearing Plants, 21, 1612-1623.

Manushkina, Т. М. (2019). Growth, development and formation of productivity of narrow-leaved lavender in the conditions of the Southern Steppe of Ukraine. Scientific horizons, 7, 48-54.

Rudnyk-Ivashchenko, O. I., & Kremenchuk, R. I. (2019). Methods of creating new varieties of lavender (Lavandula Angustifolia Mill.), Sadivnytstvo, 74. 65-72.

Mitrofanova, I., Chirkov, S., Lesnikova-Sedoshenko, N., Chelombit, S., Zakubanskiy, A., Rabotyagov, V., & Mitrofanova, O. (2017). Micropropagation of Lavandula angustifolia Mill. "Record" and "Belyanka". Acta Horticulturae, 37-42.

Murashige, T., & Skoog, F. (1962). A revised medium for rapid growth and bio assays with tobacco tissue cultures. Physiologia Plantarum, 15(3), 473-497.

Bona, C. M., Santos, G. D., & Biasi, L. (2012). Calogênese, curva de crescimento de calos e formação de suspensões celulares de Lavandula. Revista Brasileira de Ciências Agrárias, 7, 17-23.

Szekely-Varga, Z., González-Orenga, S., Cantor, M., Jucan, D., Boscaiu, M., & Vicente, O. (2020). Effects of drought and salinity on two commercial varieties of Lavandula angustifolia Mill. Plants (Basel), 9(5), 637.

Lamacque, L., Charrier, G., dos Santos Farnese, F., Lemaire, B., Améglio, T., & Herbette, S. (2019). Drought-induced mortality: stem diameter variation reveals a point of no return in lavender species. bioRxiv, 848879.

Marulanda, A., Porcel, R., Barea, J. M., & Azcón, R. (2007). Drought tolerance and antioxidant activities in lavender plants colonized by native drought-tolerant or drought-sensitive Glomus species. Microbial ecology, 54(3), 543.

Burnett, S., Van Iersel, M., & Thomas, P. (2006). Medium-incorporated PEG8000 reduces elongation, growth, and whole-canopy carbon dioxide exchange of Marigold. HortScience: a publication of the American Society for Horticultural Science, 41, 124-130.

Bulavin, I., Brailko, V., & Zhdanova, I. (2020). In vitro rhizogenesis of the Lavandula angustifolia cultivars. In BIO Web of Conferences (Vol. 24, p. 00017). EDP Sciences.

Метрики статей

Завантаження метрик ...

Metrics powered by PLOS ALM


  • Поки немає зовнішніх посилань.