Assessment of effect of drought stress on inhibitory properties of Peganum harmala L.

Document Type : Research Paper

Authors

1 Graduated Student of Arid Land Management, Yazd University

2 Associate Professor of Natural Recourses Faculty, Yazd University

3 Assistant Professor of Natural Recourses Faculty, Yazd University

10.29252/aridbiom.2019.10340.1697

Abstract

The herbicidal properties of some plants species can be exploited successfully as a tool to reduce the herbicide application. Wild plant species, including medicinal herbs, usually contain much higher levels of chemicals compounds than the cultivated crops; therefore in the present study, the effects of drought stress on inhibitory properties of Esfand on purple weed in both laboratory and greenhouse conditions were investigated. Factorial design experiment in a completely randomized design with four replications was used. In laboratory conditions, the factors studied included the concentration of extract in four levels (0, 0.4, 0.8 and 1.2%), irrigation treatment on the mother's base of the plant manufacturer in Esfand was irrigated at two levels (native rootstock and Irrigation was not done) and the type of extracted organ was considered in two levels (shoot and root). In greenhouse conditions, instead of extract of Esfand plant residual (0, 4, 8 and 12 g) in 1000 g of soil was used. The results showed that in both greenhouse and laboratory conditions, with increasing concentrations  and amounts of shoot and root powder, the inhibitory effect was significantly increased on the most traits measured in the purple species (p

Keywords

References

[1]. Abasi Khalaki, M., Moammari, M., Tavily, A., Zare Chahkohee, M. A. (2012). Allelopathic effect of Haloxylon ammodenderon extract on germination and some characteristics of Agropyron desertorum. Journal of Seed Science and Technology, 1(2), 173-183. (in Farsi).
[2]. Aramesh, M., Sodaeizadeh. H., Mirmohammadi Maibody, A. M. (2015). Assessment of allelopathic potential of capparis spinosa L. on weeds control under laboratory and greenhouse conditions. Journal of Desert Management.  6, 1-12. (in Farsi). 
[3]. Atal, C. k., Kapur, M. N. (1998). Cultivation and utilization of medicinal plant. India: Jammu-Tawi.
[4]. Azizi, M., Ghorbani, R., Rashed Mohasel, M. H., Khazaee, H. R., Orojee, K. (2009). Investigating the effects of allelopathy (Helianthus annuus) on germination and growth of Amaranthus retroflexus weed and Chenopodium album. Journal of Plant Protection (Science and Technology of Agriculture), 22 (2), 119-128 (in Farsi).
[5]. Bagheri, R., Hamze-Nejad, N. (2011). Effect of Allelopathy of Peganum harmala on two species of Agropyron desertorum and Agroperon elongatum. Biome Journal. 1 (4), 1-14. (in Farsi).
[6]. Deef, H. E., El-Fattah, R. I. (2008). Allelopathic effects of water extract Artemisia princeps var. orientalis on wheat under two type of soils. Academic Journal of Plant Sciences, 1(1), 12-17.
[7]. El-Khatib, A. A., Hegazy, A. K., Gala, A. K. (2004). Does allelopathy have a role in the ecology of Chenopodium. Annals Botani Fennici, 41, 37-45.
[8]. Fakhrtabatabaee, S.M. (1998). About Biology of Nature, Iran, Majed Publications (in Farsi).
[9]. Javiad, A., Shafique, S., Bajwa, R., Shafique, S. (2006). Effect of aqueous extracts of allelopathic crops on germination and growth of Parthenium hysterophorus L. South African Journal of Botany, 72(4), 609-612.
 
[10]. Hakimi Maybodi, M. H., Sodaeizadeh, H., Shakeri, M. (2004). Preliminary investigation on allelopathic and nematode extract effect of Haloxilon ammodenderon extract. Journal of Pajouhesh & Sazandegi, (62), 75-80. (in Farsi).
[11]. Hekmat shoar, H. (1994). Plant physiology in difficult conditions, Tabriz, Hekmat Shoar Publisher, (in Farsi).
[12]. Itani, T., Nakahata, Y., Kato-Nogouchi, H. (2013). Allelopathic activity of some herb plant species. International Journal of Agriculture and Biology, 15, 1359-1362.
[13]. Jones, E., Jessop, R. S., Sindel, B. M., Hoult, A. (2004). Utilizing crop residues to control weeds. Australia, University of Tasmania.
[14]. Rashed, M. H., Akbar zadeh. M. D., Najafi, H. (2009). Weed biology and control. Iran, Mashhad University Press. (in Farsi).
[15]. Makkizadeh Tafti, M., Farhoudi, R. (2010).The effect of allelopathy of (Cynodon dactylon L.) on wheat (Triticum aestivum L.). Journal of Agricultural Science and Sustainable Production, 27-40. (in farsi).
[16]. Maguire, J.D. (1962). Speed of germination-aid selection and evaluation for seedling emergence and vigour. Crop Science, 2, 176 – 177.
[17]. Meril, A., Rass Karol, A., Limbi. A. (1993). Investigation of Allelopathic Effect of Peganum harmala L. on Germination and Growth of Amaranth and Wild Oat. Second National Conference on Agriculture and Sustainable Development, Future Opportunities and Challenges, Shiraz Islamic Azad University. (in farsi).
[18]. Mozaffarian, v. (1998). Dictionary of Iranian plant names. Tehran, Farhang Moaser, (in Farsi).
[19]. Nabeel, M. M., Fawzia, M. R., Gharchafchi, A. (2006). Allelopathic effects of Artemisia herba alba on germinatin and seedling growth of Anabasis setifera. Pakistan Journal of Biotecnology Sciences, 9(9), 1795-1798.
[20]. Omidpanah, N., Moradshahi, A., Asrar, Z. (2012). Investigating the allelopathic potential of Zhumeria majdae Rech. On two wheat cultivars (Triticum sativum Lam.). Journal of Research in Iranian Herbs and Medicinal Herbs, 28(3), 209-198. (in Farsi).
[21]. Omidbaigy, R. (1996). Production and processing of medicinal plants. Mashhad, Astan Quds Razavi, (in Farsi).
[22]. Omidbaigy, R. (2009). Approaches to the production and processing of medicinal plants. Mashhad, Astan Quds Razavi, (in Farsi).
[23]. Pedrol, N., Gonzalez, L., Reigosa, M. L. (2006). Allelopathy and abiotic stress. In:Reigosa, M. J.,
Pedrol, N., Gonzalez, L. (Eds). Allelopathy: a Physiological process with ecological implications. The Netherlands: Springer
[24]. Petrova, S. T., Valcheva, E. G., Valcheva, I. G. (2015). A case study of allelopathic effects of weeds in wheat. Ecologia Balkanica, 7(1), 121-129.
[25]. Sayyednejad, S. M., Koochak, H., Pourabdollah najafabade, F., Kolahi, M. (2010). Allelopathic effect of aquatic hull extract of rice (Oryza sativa L.) on grouth of Silybum marianum and Echoinochloacrus-galli. African Journal of Agriculture Research, 5, 2222-2226.
[26]. Singh, H.P., Batish, D.R., Kaur, S., Kohli, R.K. (2003). Phytotoxic interference of Ageratum with Wheat (Triticum aestivum). Jurnal of Agronomy and Crop Science, 18, 341-346.
[27]. Sodaiezadeh, H., Van Damme, P. (2009).  Phytotoxicity of a medicinal plant, Peganum harmala L., against germination and seedling growth of Wild Oat (Avena fatua L.). Scientia Pharmaceutica, 77 (7), 251
[28]. Sodaiezadeh, H., Hakimi Maybodi, M. H. (2010). Allelopatic effects of Capparis spinosa, Herttia angustifolia and Peganumharmala on germination and seedling growth of wheat and alfalfa.  Journal of Agricultural Science and Sustainable Production, 2(1), 181-189. (in Farsi).
[29]. Harborne, J.B. (1999). Classes and functions of secondary products. In: Walton NJ., Brown DE. (Eds) Chemicals from Plant, London, Imprical College Press.
[30]. Yarnia, m. (2012). Allelopatic effect of bermudagrass (Cynodon dactylon L.) extract and residues on wheat (Triticumaestivum L.).  Journal of Agricultural Science and Sustainable Production, 22(3), 181-189 (in Farsi).
[31]. Yazdani, A. S., Naderi, R., Bijan Zadeh, A., Imam, Yahya. (2014).  Allelopathic effects of  Rubia tinctorum extract on seed germination and seedling growth characteristics of maize (Zea mays), sorghum (Sourghum bicolor), Convolvolus arvensand Sourghum halepense, Journal of Plant Protection, 6(4), 390-377.
Journal of Arid Biome
Volume 9, Issue 1
September 2019
Pages 125-138

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