Effect of foliar application of ordinary and nano-zinc fertilizers on growth and essential oil profile of dragonhead

Shahabivand, Saleh; Aghaee, Ahmad; Athayi, Shamsi; Nasiri, Yusef

doi:https://doi.org/10.71551/ijpp.2025.1190283

Manuscript ID : 202411121190283 Visit : 14 Page: 5533 - 5543

https://doi.org/10.71551/ijpp.2025.1190283

Article Type: Original Research

Effect of foliar application of ordinary and nano-zinc fertilizers on growth and essential oil profile of dragonhead

Subject Areas : Plant Physiology

Saleh Shahabivand ^{1
*} , Ahmad Aghaee ² , Shamsi Athayi ³ , Yusef Nasiri ⁴

1 - Department of Biology, Faculty of Basic Sciences, University of Maragheh, Maragheh, Iran
2 - Department of Biology, Faculty of Basic Sciences, University of Maragheh, Maragheh, Iran
3 - Department of Biology, Faculty of Basic Sciences, University of Maragheh, Maragheh, Iran
4 - Department of Plant production and Genetics, Faculty of Agriculture, University of Maragheh, Maragheh, Iran

Received: 2024-11-12 Accepted : 2025-03-04 Published : 2025-05-11

Keywords: Dracocephalum moldavica L., essential oil, nano-fertilizer, zinc,

Abstract :

In this work, the effects of foliar zinc sprayings on some growth parameters and essential oil composition of dragonhead (Dracocephalum moldavica L.) were assessed. A greenhouse experiment was carried out with two sources of zinc including zinc oxide (ZnO, as ordinary fertilizer) and zinc oxide nanoparticles (ZnO-NP, as nano-fertilizer), each having four concentrations (0, 25, 50, and 100 mg/l). Results showed that sprayings with zinc had significant influence on the evaluated parameters. Treatments with ZnO and ZnO-NP significantly increased root length, shoot height, root and shoot dry weights, photosynthesis pigments contents, antioxidant enzymes activity, and essential oil percentage, and in the impact of ZnO-NP was more effective than ZnO. The highest growth parameters and pigment contents were observed at 100 mg/L ZnO-NP. Based on the results, 27 components were identified in the dragonhead essential oil in which the maximum values belonged to oxygenated monoterpenes with four main components as geranial (27.91-36.09%), geranyl acetate (18.36-25.48%), neral (19.18-21.7%), and geraniol (5.93-8.30%). The amounts of these monoterpenes under ZnO-NP (especially at 100 mg/L) were higher than ZnO treatment and control plants. The findings of this study showed that the effect of ZnO-NP in increasing the growth, the antioxidant enzymes, and bioactive ingredients of dragonhead was more than ZnO, and it may be possible to use ZnO-NP as a nano-fertilizer in the sustainable production of essential oil in medicinal plants.

References:

Abdal Dayem, A., M. K. Hossain, S. B. Lee, K. Kim, S. K. Saha, G.-M. Yang, H. Y. Choi and S.-G. Cho. 2017. The role of reactive oxygen species (ROS) in the biological activities of metallic nanoparticles. International journal of molecular sciences, 18, (1) 120.
Aćimović, M., O. Šovljanski, V. Šeregelj, L. Pezo, V. D. Zheljazkov, J. Ljujić, A. Tomić, G. Ćetković, J. Čanadanović-Brunet and A. Miljković. 2022. Chemical composition, antioxidant, and antimicrobial activity of Dracocephalum moldavica L. essential oil and hydrolate. Plants, 11, (7) 941.
Adrees, M., Z. S. Khan, M. Hafeez, M. Rizwan, K. Hussain, M. Asrar, M. N. Alyemeni, L. Wijaya and S. Ali. 2021. Foliar exposure of zinc oxide nanoparticles improved the growth of wheat (Triticum aestivum L.) and decreased cadmium concentration in grains under simultaneous Cd and water deficient stress. Ecotoxicology and Environmental Safety, 208, 111627.
Amini, R., A. Ebrahimi and A. D. M. Nasab. 2020. Moldavian balm (Dracocephalum moldavica L.) essential oil content and composition as affected by sustainable weed management treatments. Industrial crops and products, 150, 112416.
Aminzare, M., J. Aliakbarlu and H. Tajik.2015. The effect of Cinnamomum zeylanicum essential oil on chemical characteristics of Lyoner-type sausage during refrigerated storage. Proc. Veterinary Research Forum, 6(1): 31-39.
Arnon, A. 1967. Method of extraction of chlorophyll in the plants. Agronomy journal, 23, (1) 112-121.
Awan, S., K. Shahzadi, S. Javad, A. Tariq, A. Ahmad and S. Ilyas. 2021. A preliminary study of influence of zinc oxide nanoparticles on growth parameters of Brassica oleracea var italic. Journal of the Saudi Society of Agricultural Sciences, 20, (1) 18-24.
Azim, Z., N. Singh, S. Khare, A. Singh, N. Amist and R. K. Yadav. 2022. Green synthesis of zinc oxide nanoparticles using Vernonia cinerea leaf extract and evaluation as nano-nutrient on the growth and development of tomato seedling. Plant Nano Biology, 2, 100011.
Banerjee, S., J. Islam, S. Mondal, A. Saha, B. Saha and A. Sen. 2023. Proactive attenuation of arsenic-stress by nano-priming: Zinc Oxide Nanoparticles in Vigna mungo (L.) Hepper trigger antioxidant defense response and reduce root-shoot arsenic translocation. Journal of Hazardous Materials, 446, 130735.
Bonjoch, N. P. and P. R. Tamayo. 2001. Protein content quantification by Bradford method. In Handbook of plant ecophysiology techniques:283-295: Springer. Number of 283-295 pp.
Brahmi, F., M. Khodir, C. Mohamed and D. Pierre. 2017. Chemical composition and biological activities of Mentha species. In Aromatic and medicinal plants-Back to nature: IntechOpen.
Çakmak, İ. and U. Á. Kutman. 2018. Agronomic biofortification of cereals with zinc: a review. European journal of soil science, 69, (1) 172-180.
Chance Maehly, A. 1995. Assay of catalases and peroxidases. Methods Enzymol, 2, 764-775.
Cohen, G., M. Kim and V. Ogwu. 1996. A modified catalase assay suitable for a plate reader and for the analysis of brain cell cultures. Journal of neuroscience methods, 67, (1) 53-56.
Derks, A., K. Schaven and D. Bruce. 2015. Diverse mechanisms for photoprotection in photosynthesis. Dynamic regulation of photosystem II excitation in response to rapid environmental change. Biochimica et Biophysica Acta (BBA)-Bioenergetics, 1847, (4-5) 468-485.
Ehsani, A., O. Alizadeh, M. Hashemi, A. Afshari and M. Aminzare. 2017/ Phytochemical, antioxidant and antibacterial properties of Melissa officinalis and Dracocephalum moldavica essential oils. Proc. Veterinary Research Forum, 8(3): 223 – 229.
Elsheery, N. I., V. Sunoj, Y. Wen, J. Zhu, G. Muralidharan and K. Cao. 2020. Foliar application of nanoparticles mitigates the chilling effect on photosynthesis and photoprotection in sugarcane. Plant Physiology and Biochemistry, 149, 50-60.
Faizan, M., A. Faraz, M. Yusuf, S. Khan and S. Hayat. 2018. Zinc oxide nanoparticle-mediated changes in photosynthetic efficiency and antioxidant system of tomato plants. Photosynthetica, 56, 678-686.
Fallahi, A., A. Hassani and F. Sefidkon. 2016. Effect of foliar application of different zinc sources on yield and phytochemical characteristics of basil (Ocimum basilicum L.). Iranian Journal of Medicinal and Aromatic Plants Research, 32, (5) 743-757.
Ghosh, S. K. and T. Bera. 2021. Molecular mechanism of nano-fertilizer in plant growth and development: A recent account. In Advances in nano-fertilizers and nano-pesticides in agriculture:535-560: Elsevier. Number of 535-560 pp.
Gupta, N., H. Ram and B. Kumar. 2016. Mechanism of Zinc absorption in plants: uptake, transport, translocation and accumulation. Reviews in Environmental Science and Bio/Technology, 15, 89-109.
Hassan, M. U., H. A. Kareem, S. Hussain, Z. Guo, J. Niu, M. Roy, S. Saleem and Q. Wang. 2023. Enhanced salinity tolerance in Alfalfa through foliar nano-zinc oxide application: Mechanistic insights and potential agricultural applications. Rhizosphere, 28, 100792.
Hassanpouraghdam, M. B., G. R. Gohari, S. J. Tabatabaei, M. R. Dadpour and M. Shirdel. 2011. NaCl salinity and Zn foliar application influence essential oil composition of basil (Ocimum basilicum L.). Acta agriculturae Slovenica, 97, (2) 93-98.
Hernández-Fuentes, A. D., A. Montaño-Herrera, J. M. Pinedo-Espinoza, Z. H. Pinedo-Guerrero and C. U. López-Palestina. 2023. Changes of the antioxidant system in pear (Pyrus communis L.) fruits by foliar application of copper, selenium, iron, and zinc nanoparticles. Journal of Agriculture and Food Research, 14, 100885.
Hussain, A., S. Ali, M. Rizwan, M. Z. Ur Rehman, M. R. Javed, M. Imran, S. a. S. Chatha and R. Nazir. 2018. Zinc oxide nanoparticles alter the wheat physiological response and reduce the cadmium uptake by plants. Environmental Pollution, 242, 1518-1526.
Kah, M., R. S. Kookana, A. Gogos and T. D. Bucheli. 2018. A critical evaluation of nanopesticides and nanofertilizers against their conventional analogues. Nature nanotechnology, 13, (8) 677-684.
Kaur, H., H. Kaur, H. Kaur and S. Srivastava. 2023. The beneficial roles of trace and ultratrace elements in plants. Plant Growth Regulation, 100, (2) 219-236.
Khan, S. T., A. Malik, A. Alwarthan and M. R. Shaik. 2022. The enormity of the zinc deficiency problem and available solutions; an overview. Arabian Journal of Chemistry, 15, (3) 103668.
Kumar, S., S. Kumar and T. Mohapatra. 2021. Interaction between macro‐and micro-nutrients in plants. Frontiers in Plant Science, 12, 665583.
Li, C., P. Wang, E. Lombi, M. Cheng, C. Tang, D. L. Howard, N. W. Menzies and P. M. Kopittke. 2018. Absorption of foliar-applied Zn fertilizers by trichomes in soybean and tomato. Journal of Experimental Botany, 69, (10) 2717-2729.
Marslin, G., C. J. Sheeba and G. Franklin. 2017. Nanoparticles alter secondary metabolism in plants via ROS burst. Frontiers in plant science, 8, 832.
Miyake, C. and K. Asada. 1996. Inactivation mechanism of ascorbate peroxidase at low concentrations of ascorbate; hydrogen peroxide decomposes compound I of ascorbate peroxidase. Plant and cell physiology, 37, (4) 423-430.
Mohammadi, M. H. Z., S. Panahirad, A. Navai, M. K. Bahrami, M. Kulak and G. Gohari. 2021. Cerium oxide nanoparticles (CeO2-NPs) improve growth parameters and antioxidant defense system in Moldavian Balm (Dracocephalum moldavica L.) under salinity stress. Plant Stress, 1, 100006.
Moradbeygi, H., R. Jamei, R. Heidari and R. Darvishzadeh. 2020. Investigating the enzymatic and non-enzymatic antioxidant defense by applying iron oxide nanoparticles in Dracocephalum moldavica L. plant under salinity stress. Scientia Horticulturae, 272, 109537.
Moradi, S., S. Khaledian, M. Abdoli, M. Shahlaei and D. Kahrizi. 2018. Nano-biosensors in cellular and molecular biology. Cellular and Molecular Biology, 64, (5) 85-90.
Naseer, I., S. Javad, S. Iqbal, A. A. Shah, K. Alwutayd and H. Abdelgawad. 2023. Deciphering the role of zinc oxide nanoparticles on physiochemical attributes of exposed to saline conditions through modulation in antioxidant enzyme defensive system. South African Journal of Botany, 160, 469-482.
Nasiri, Y. 2021. Crop productivity and chemical compositions of dragonhead (Dracocephalum moldavica L.) essential oil under different cropping patterns and fertilization. Industrial Crops and Products, 171, 113920.
Nekoukhou, M., S. Fallah, A. Abbasi-Surki, L. R. Pokhrel and A. Rostamnejadi. 2022. Improved efficacy of foliar application of zinc oxide nanoparticles on zinc biofortification, primary productivity and secondary metabolite production in dragonhead. Journal of Cleaner Production, 379, 134803.
Pouresmaeil, M., M. Sabzi-Nojadeh, A. Movafeghi, B. N. Aghbash, M. Kosari-Nasab, G. Zengin and F. Maggi. 2022. Phytotoxic activity of Moldavian dragonhead (Dracocephalum moldavica L.) essential oil and its possible use as bio-herbicide. Process Biochemistry, 114, 86-92.
Prasad, T. N. V. K. V., A. N. Kumar, M. Swethasree, M. Saritha, G. Satisha, P. Sudhakar, B. R. Reddy, B. P. Girish, N. Sabitha and B. V. B. Reddy. 2022. Combined Effect of Nanoscale Nutrients (Zinc, Calcium, and Silica) on Growth and Yield of Groundnut (Arachis hypogaea L.).
Rizwan, M., S. Ali, M. Z. Ur Rehman, M. Adrees, M. Arshad, M. F. Qayyum, L. Ali, A. Hussain, S. a. S. Chatha and M. Imran. 2019. Alleviation of cadmium accumulation in maize (Zea mays L.) by foliar spray of zinc oxide nanoparticles and biochar to contaminated soil. Environmental Pollution, 248, 358-367.
Rossi, L., L. N. Fedenia, H. Sharifan, X. Ma and L. Lombardini. 2019. Effects of foliar application of zinc sulfate and zinc nanoparticles in coffee (Coffea arabica L.) plants. Plant Physiology and Biochemistry, 135, 160-166.
Rui, M., C. Ma, Y. Hao, J. Guo, Y. Rui, X. Tang, Q. Zhao, X. Fan, Z. Zhang and T. Hou. 2016. Iron oxide nanoparticles as a potential iron fertilizer for peanut (Arachis hypogaea). Frontiers in plant science, 7, 815.
Saleh, A. M., S. Selim, S. Al Jaouni and H. Abdelgawad. 2018. CO2 enrichment can enhance the nutritional and health benefits of parsley (Petroselinum crispum L.) and dill (Anethum graveolens L.). Food chemistry, 269, 519-526.
Umair Hassan, M., M. Aamer, M. Umer Chattha, T. Haiying, B. Shahzad, L. Barbanti, M. Nawaz, A. Rasheed, A. Afzal and Y. Liu. 2020. The critical role of zinc in plants facing the drought stress. Agriculture, 10, (9) 396.
Xu, M., M. Liu, F. Liu, N. Zheng, S. Tang, J. Zhou, Q. Ma and L. Wu. 2021. A safe, high fertilizer-efficiency and economical approach based on a low-volume spraying UAV loaded with chelated-zinc fertilizer to produce zinc-biofortified rice grains. Journal of Cleaner Production, 323, 129188.
Zhu, D., C. Wu, C. Niu, H. Li, F. Ge and W. Li. 2023. Biochemical and molecular characterization of a novel porphobilinogen synthase from Corynebacterium glutamicum. World Journal of Microbiology and Biotechnology, 39, (6) 165.

Full-Text:

Effect of foliar application of ordinary and nano-zinc fertilizers on growth and essential oil profile of dragonhead

Saleh Shahabivand1*, Ahmad Aghaee1, Shamsi Athayi1, Yousef Nasiri2

1. Department of Biology, Faculty of Basic Sciences, University of Maragheh, Maragheh, Iran

2. Department of Plant production and Genetics, Faculty of Agriculture, University of Maragheh, Maragheh, Iran

________________________________________________________________________________

Abstract

In this work, the effects of foliar zinc sprayings on some growth parameters and essential oil composition of dragonhead (Dracocephalum moldavica L.) were assessed. A greenhouse experiment was carried out with two sources of zinc including zinc oxide (ZnO, as ordinary fertilizer) and zinc oxide nanoparticles (ZnO-NP, as nano-fertilizer), each having four concentrations (0, 25, 50, and 100 mg/l). Results showed that sprayings with zinc had significant influence on the evaluated parameters. Treatments with ZnO and ZnO-NP significantly increased root length, shoot height, root and shoot dry weights, photosynthesis pigments contents, antioxidant enzymes activity, and essential oil percentage, and in the impact of ZnO-NP was more effective than ZnO. The highest growth parameters and pigment contents were observed at 100 mg/L ZnO-NP. Based on the results, 27 components were identified in the dragonhead essential oil in which the maximum values belonged to oxygenated monoterpenes with four main components as geranial (27.91-36.09%), geranyl acetate (18.36-25.48%), neral (19.18-21.7%), and geraniol (5.93-8.30%). The amounts of these monoterpenes under ZnO-NP (especially at 100 mg/L) were higher than ZnO treatment and control plants. The findings of this study showed that the effect of ZnO-NP in increasing the growth, the antioxidant enzymes, and bioactive ingredients of dragonhead was more than ZnO, and it may be possible to use ZnO-NP as a nano-fertilizer in the sustainable production of essential oil in medicinal plants.

Keywords: Dracocephalum moldavica L., essential oil, nano-fertilizer, zinc

Shahabivand, S., A. Aghaee, Sh. Athayi, Y. Nasiri. 2025. 'Effect of foliar application of ordinary- and nano-zinc fertilizers on growth and essential oil profile of dragonhead'. Iranian Journal of Plant Physiology 15 (2),5533- 5543.

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Introduction

The pharmaceutical herb dragonhead (Dracocephalum moldavica L.) is an annual plant from Lamiaceae family and Lamiales order. In traditional medicine, it is consumed in curing stomachache, liver disorders, headache, and flatulence. The secondary metabolites from this plant such as monoterpene glycosides, trypanocidal terpenoid, rosmarinic acid, and flavonoids have anti-bacterial, anti-rheumatic, anti-cancer, anti-mutagenic, antioxidant, and antiseptic properties (Mohammadi et al., 2021). Furthermore, the dragonhead essence is prevalently used in nutritional, cosmetics, and perfume industries (Nasiri, 2021).

Zinc is one of the essential micronutrients which is basic to plant growth and development (Çakmak and Kutman, 2018). Zinc deficiency in the soil will cause zinc insufficiency in plants and thus the food chain so that about 17.3% of the human beings are in danger of Zn deficiency (Khan et al., 2022). Due to lower bioavailability of Zn in the soil, the spraying of various forms of zinc on leaves is favored over soil application methods (Hussain et al., 2018). Foliar application has been shown to reduce micro-element deficiencies, prevent toxicity symptoms, and diminish fertilizer-related contamination (Kaur et al., 2023).

In recent years, nanotechnology has gained significant impetus in agriculture, including elevating crop productivity, reducing the use of fertilizers and pesticides, and helping to conserve natural resources (Rui et al., 2016). Against conventional methods (salt fertilizers and soil application of micronutrients), spraying nano-fertilizers can feed crops gradually and in a more controlled condition, resulting in reduced toxicity symptoms in soil (Kah et al., 2018). One of the advantages of nano-fertilizers is that they are used in small amounts compared to conventional fertilizers. Nano-fertilizers are absorbed faster by the plant due to their high solubility and small size (Moradbeygi et al., 2020). These nano-scale substances provide proper situation for plant growth and have a positive effect on the production of secondary metabolites (Moradi et al., 2018). It has been reported that nano-fertilizers improve crop yield and quality via enhancing growth parameters, chlorophyll contents, photosynthesis, and stress tolerance (Ghosh and Bera, 2021).

The objective of the present experiment was to investigate and compare the effect of zinc oxide and zinc nanoparticles on growth, photosynthesis pigments contents, antioxidant enzymes activities, and secondary metabolites of the medicinal plant dragonhead under greenhouse condition.

Materials and Methods

Preparation of materials and growth conditions

The experiment was arranged following a complete randomized design with four replicates per treatments. The experimental treatments were foliar spraying at four doses of ordinary zinc oxide (0, 25, 50, and 100 mg/L) and four doses of nano-zinc oxide (0, 25, 50, and 100 mg/L).

The dragonhead seeds obtained from the Horticulture Laboratory of University of Maraghehe, Iran, were disinfected for 5 min with sodium hypochlorite 5% with a few drops of Tween 20 and then were washed several times with sterile distilled water. For germination, 30 seeds were placed on wet filter paper in each Petri dish of 8 cm in diameters.

Sandy-loamy soil (0-25 cm) was taken from the soil surface of Maragheh University Campus. The sample was mixed with sand by 4:1 ratio. The physico-chemical characteristics of the soil used in our study were as follows: 68% sand, 20% silt, 12% clay, 1.2% organic matter, 0.05% total N, 7 mg/kg available P, 35 mg/kg available K, 1.98 mg/kg available Zn, pH 7.2 and 1.28 dS/m EC. Fresh soil was air-dried and then passed through a 5-mm sieve. Uniform and well-grown seedlings (three days after seed germination) were transplanted in the selected pots (with a diameter of the opening 25 cm and height 30 cm) filled with 7 kg of the soil. Eight seeds per each pot were planted and at two-leaf stage, 4 plants were kept. The experimental dragonheads were grown in the research greenhouse of Maragheh University under a photoperiod of 14 h per day at 30 ± 2/20 ± 2 ᵒC day/night cycle with 55-70% average relative humidity. In order to maintain soil moisture, irrigation was done every day to near field capacity using deionized water.

Ordinary zinc oxide (ZnO) and zinc oxide nanoparticle (ZnO-NP) were purchased from Pishgaman Danesh Company, Iran. The zinc nanoparticles had 99% purity as well as density of 5.606 g/cm3 and size of 20-30 nm. For foliar treatments, four levels of zinc oxide (0, 25, 50, and 100 mg/L) and four levels of zinc oxide nanoparticles (0, 25, 50, and 100 mg/L) were prepared with the deionized water. In order to elevate the dispersion of ZnO and ZnO-NP, the suspension was ultra-sonicated for 30 min. Foliar spray was done for 3 times at an interval of 15 days, 40 days after sowing. To prevent the leaves from burning, foliar application was done at sunset. The solutions of ZnO-NP and ZnO were freshly made in each application. For untreated plants, distilled water spray was used simultaneously with the treatments. The plant samples were harvested 15 days after the last foliar application. The dragonheads were separated into roots and shoots and washed with tap water. Then, plant height, root length, numbers of leaves per plant, and fresh weights were measured. To perform biochemical analyses, the samples were frozen in liquid nitrogen and stored at - 80 ᵒC until laboratory experiments. The shoot and root samples were dried at room temperature in the shade for one week to reach a constant weight, and dry weights were recorded using a weighing balance.

Photosynthesis pigments assay

For determination of pigment contents, 0.5 g fresh tissue of the youngest fully expanded leaves was homogenized in 80% acetone and centrifuged at 4000 rpm for 20 min. According to Arnon's method (Arnon, 1967), the absorbance of the supernatant was recorded at 663, 645, and 470 nm for Chl a, Chl b, and carotenoids, respectively, using a UV-visible spectrophotometer (BMS, UV-2600).

Antioxidant enzyme activities assay

Leaf tissue (0.5 g) was powdered by a pre-chilled mortar and pestle, and homogenized in 5 mL ice-cold extraction buffer (50 mM potassium phosphate, pH 7.0, 4% polyvinylpyrrolidone). The extract was centrifuged at 14.000 g for 30 min at 4 ᵒC. The supernatant was used for assays of the activities of antioxidant enzymes.

Total protein concentration in the leaf extracts was determined according to the Bradford method (Bonjoch and Tamayo, 2001) with bovine serum albumin as the standard. Catalase (CAT) activity was assayed at 240 nm by Cohen and coworkers method (Cohen et al., 1996). The hydrogen peroxide decomposition rate was monitored during 1 min at 25 ᵒC. The activity of ascorbate peroxidase (APX) was assayed following Miyake and Asada method (1996). The reaction of ascorbic acid oxidation was started by addition of H2O2, and the decrease in absorbance was read at 290 nm. The activity of guaiacol peroxidase (GPX) was assayed according to Chance and Maehly (1995). The reaction of guaiacol oxidation was initiated by addition of H2O2, and the increase in absorbance was read at 470 nm. The enzymes activities were expressed as U/min. mg protein.

Extraction of essential oil

To extract the essential oil, 50 g of dried shoot was hydro-distilled for 3 h by a Clevenger-type apparatus. The extracted essence was dried over anhydrous sodium sulphate and kept at −20 ᵒC until GC-MS analysis. The amount of essential oil content was recorded based on the oil volume per shoot dried sample (as % v/w, mL/100 g DW).

Analysis of essential oil

To identify the essential oil composition, GC-MS analysis was done on an Agilent 6890N gas chromatograph with a 5977 mass-selective detector (Agilent Technologies, USA). The separation was performed on an HP-5 MS capillary column (5% Phenyl Methylpolysiloxane, 30 m length, 0.25 mm diameter and 0.25 μm film thickness). Helium was used as the carrier gas with a flow rate of 1 mL/min. The system was programmed as follows: the injector temperature 250 ᵒC, initial temperature 50 ᵒC (for 5 min), raised to 240 ᵒC at 3 ᵒC/min (for 10 min), electron energy 70 eV, the transfer line temperature 270 ᵒC, split ratio 1:30, and the acquisition scan from 50 to 240 m/z. A mixture of aliphatic hydrocarbons (C8–C40; Sigma–Aldrich, USA) was injected into the device for calculation of the retention indices of peaks. The essential oil compounds were recognized using co-injection with available authentic standards (Sigma–Aldrich, USA) and by computer matching with MS libraries (WILEY275, NIST 05, ADAMS).

Statistical Analysis

This research was conducted in the form of a completely randomized design with four replicates. Statistical analysis of data was done using SPSS software ver. 19 (Chicago, IL, USA). To compare the means, Tukey's test was used at a probability level of 5% (p≤0.05), and the data was presented as means ± standard deviation (SD).

Table 1

Effect of ZnO and NP-ZnO treatments on the growth parameters of dragonhead

Treatment	Concentration (mg/L)	Shoot height (cm)	Root length (cm)	Shoot dry weight (g)	Root dry weight (g)
Control	0	47.23±3.71 e	15.70±1.93 d	1.89±0.28 b	0.91±0.11 c
ZnO	25	51.10±7.41 de	16.16±2.52 d	2.02±0.18 b	0.92±0.14 c
	50	55.56±2.16 cd	16.23±1.05 d	2.13±0.22 b	1.07±0.19 bc
	100	59.60±6.11 bc	22.00±4.58 bc	2.88±0.79 ab	1.50±0.18 b
NP-ZnO	25	59.50±1.70 bc	17.70±0.85 cd	2.22±0.18 b	1.18±0.15 bc
	50	65.33±4.01 ab	24.10±3.65 b	3.30±0.48 a	1.71±0.18 ab
	100	69.33±0.68 a	33.96±4.92 a	3.47±0.22 a	1.90±0.22 a

Values are Means ± SD. The same letter within each column indicates no significant difference among treatments using Tukey's Test at p≤0.05.

Table 2

Effect of ZnO and NP-ZnO treatments on the photosynthetic pigments and essential oil (%) of dragonhead

Treatments	Concentration (mg/L)	Chlorophyll a (mg/g FW)	Chlorophyll b (mg/g FW)	Chlorophyll a+b (mg/g FW)	Carotenoid (mg/g FW)	Essential oil (%)
Control	0	3.02±0.03 g	1.01±0.01 g	4.03±0.03 g	0.30±0.01 g	0.29±0.05 b
Zn O	25	3.32±0.03 f	1.07±0.06 f	4.39±0.05 f	0.31±0.06 f	0.29±0.05 b
	50	3.43±0.05 e	1.13±0.01 e	4.56±0.04 e	0.40±0.01 e	0.30±0.03 b
	100	3.80±0.06 c	1.23±0.03 c	5.03±0.04 c	0.53±0.03 c	0.31±0.03 b
NP-ZnO	25	3.66±0.03 d	1.21±0.02 d	4.87±0.03 d	0.41±0.02 d	0.30±0.04 b
	50	4.09±0.06 b	1.38±0.01 b	5.47±0.05 b	0.56±0.04 b	0.33±0.07 b
	100	4.27±0.03 a	1.41±0.01 a	5.68±0.03 a	0.66±0.07 a	0.53±0.07 a

Values are Means ± SD. The same letter within each column indicates no significant difference among treatments using Tukey's Test at p≤0.05.

Table 3

Effect of ZnO and NP-ZnO treatments on the antioxidant enzymes activity of dragonhead

Treatment	Concentration (mg/L)	Total soluble protein	CAT (U/min. mg prot.)	APX (U/min. mg prot.)	GPX (U/min. mg prot.)
Control	0	08.24±0.21 g	15.15±0.04 g	0.53±0.03 g	13.24±0.11 g
ZnO	25	10.06±0.10 f	17.20±0.05 f	0.73±0.02 f	16.78±0.09 f
	50	10.86±0.05 e	18.71±0.03 e	0.83±0.02 e	17.12±0.01 e
	100	14.32±0.02 c	21.63±0.05 c	1.79±0.04 c	20.32±0.04 c
NP-ZnO	25	12.55±0.02 d	20.33±0.09 d	1.00±0.01 d	19.51±0.04 d
	50	15.90±0.08 b	23.94±0.04 b	2.87±0.08 b	22.81±0.03 b
	100	17.79±0.13 a	26.19±0.06 a	4.31±0.04 a	24.62±0.04 a

Values are Means ± SD. The same letter within each column indicates no significant difference among treatments using Tukey's Test at p≤0.05.

Results

Results showed that both ZnO and ZnO-NPs, treatments at different concentrations affected growth traits in dragonhead (Table 1). By increasing levels of ZnO and ZnO-NPs, the growth parameters increased. In plants sprayed with ZnO, this increase was significant (p≤0.05) for shoot height at 50 and 100 mg/L and for root length and root dry weight at 100 mg/L, compared to control (Table 1). ZnO-NPs treatment significantly (p≤0.05) increased shoot height at all applied levels, and root length and shoot and root dry weights at 50 and 100 mg/L, when compared to control plants. Also, the improving effect of ZnO-NPs on growth traits at each experimental level was greater than that of ZnO at the respective level. The minimum and maximum amounts of all growth traits were observed in control plants and those treated with 100 mg/L ZnO-NPs, respectively (Table 1). Spraying the plants with 100 mg/L ZnO-NPs improved shoot height by 46%, root length by 116%, shoot dry weight by 83%, and root dry weight by 108% over the control.

Table 4

Effect of ZnO and NP-ZnO treatments on the essential oil components of dragonhead

As shown in Table 2, photosynthesis pigments were influenced by foliar spraying treatments. Application of ZnO and ZnO-NPs in all studied levels significantly (p≤0.05) improved the pigment contents including chlorophyll a and b, total chlorophyll, and carotenoids in comparison with control dragonheads. Improving the level of photosynthetic pigments had a similar trend with increasing the level of both ZnO and ZnO-NPs. Under each level of treatment, the plants treated with ZnO-NPs showed a higher level of the pigments than the plants treated with ZnO. The highest and lowest pigment contents were found under 100 mg/L of ZnO-NPs and 0 mg/L of ZnO NPs (or 0 mg/L ZnO), respectively (Table 2). Foliar treatment of ZnO-NPs at 100 mg/L enhanced the contents of chlorophyll a by 41%, chlorophyll b by 39%, total chlorophyll by 40%, and carotenoids by 120% over their respective controls.

Based on Table 2, the essential oil percent was significantly elevated by application of ZnO-NPs at 100 mg/L (82.7% compared to control) while other levels of ZnO-NP and ZnO did not have a significant effect on the percentage of essential oil.

The data presented in Table 3 illustrated that both treatments including ZnO and ZnO-NPs affected the total soluble protein and antioxidant enzymes so that with increasing levels of ZnO and ZnO-NPs, the soluble protein content and the activities of CAT, APX, and GPX were elevated. The maximum and minimum amount of leaf soluble protein and leaf enzymes activities were observed at 100 mg/L of ZnO-NPs and control plants, respectively (Table 3). The treatment of ZnO-NPs at 100 mg/L elevated the content of soluble protein by 115%, CAT activity by 73%, APX activity by 713%, and GPX activity by 86% over their respective controls (Table 3).

Twenty-seven (27) essential oil components were identified in different concentrations of ZnO and ZnO-NPs (Table 4). The major constituents of D. moldavica oil were found as geranial or E-citral (27.91-36.09%), geranyl acetate (18.36-25.48%), Z-Citral or neral (19.18-21.7%), and geraniol (5.93-8.30%) (Table 4). Treatments of the study caused an increase in the levels of the essential oil compounds. In the meantime, the effect of zinc oxide nanoparticles on the level of compounds was more than ordinary zinc oxide. The highest amount of these essential oil compounds was seen under nanoparticle treatment at 100 mg/L. Foliar application of ZnO-NPs at 100 mg/L elevated the amounts of geranial by 29.1%, geranyl acetate by 38.7%, Z-Citral by 13.1%, and geraniol by 39.9% in comparison with control plants. In this study, the level of oxygen-containing monoterpenes (76.07-96.82%) was the highest among essential oil compounds of D. moldavica under different levels of the treatments. The highest levels of oxygenated monoterpenes were observed in ZnO-NPs treatment at 100 mg/L, so that spraying D. moldavica plants with 100 mg/L ZnO-NPs increased the amounts of oxygenated monoterpenes by 28.6% in comparison to control plants (Table 4).

Discussion

Foliar application of micronutrients such as zinc is one of the easiest and fastest ways to eliminate or reduce the deficiency of these nutrients in plants. It is shown that spraying zinc is a highly efficient and practical method to improve the absorption and accumulation of this element, rather than soil application (Xu et al., 2021). In this way, zinc was rapidly translocated via phloem to different organs of the plant (Gupta et al., 2016). Zinc plays an important role in protein synthesis, indole acetic acid synthesis, cell elongation, regulating membrane stability and function, and enzyme activities (Umair Hassan et al., 2020). In our study, foliar spraying of ZnO and ZnO-NPs enhanced growth attributes in terms of plant height, root length, and shoot and root dry matter in dragonhead, and in this regard, the effectiveness of ZnO-NPs was higher than ordinary ZnO. Awan et al. (2021) reported more efficiency of ZnO-NPs for enhancing shoot and root lengths and leaf numbers compared to the macro size Zn salt in Brassica oleracea. Also, Rossi et al. (2019)showed a more positive role of ZnO-NPs on coffee growth and physiology than conventional Zn salts and argued that this positive impact may be due to increased ability of nanoparticle to penetrate the leaf. They stated that dissolution of zinc nanoparticles in water is relatively slow, so that about 2% of zinc from nanoparticles is dissolved in 1 day. However, after attaching Zn-NPs to leaf surfaces, zinc might be continuously released, providing a long-term source of Zn. The leaf cuticle permeability to water and lipophilic substances increases by mobility and solubility of these molecules, and in this regard, ZnO-NPs which are having more lipophilicity and mobility than non-NPs (Prasad et al., 2022), can penetrate via the lipophilic cuticle of leaf, and distribute via phloem in different parts of plants. The lower water solubility of ZnO-NPs can prevent fast falling off from leaf surface in compare to other supplements. The bioavailability of nanoparticles due to their small size and large surface area can also be higher than that of ZnO, resulting in a higher absorption of Zn to leaf.

Among the treatments used in this research, 100 mg/L ZnO-NPs was found optimum for foliar application as it produced the highest increase in the growth and dry biomass of dragonheads over all other treatments. In wheat plants and under foliar spray treatment with ZnO-NPs, increasing Zn-NPs concentration increased the growth, and maximum increase in growth attributes was achieved in the wheats treated with 100 mg/L ZnO-NPs (Adrees et al., 2021). Also, Rizwan et al. (2019) showed that foliar spray of 100 mg/L ZnO-NPs increased shoot dry biomass by 65%, root dry biomass by 86%, shoot length by 34%, and number of leaves per plant by 72% in maize plants compared to the control under cadmium stress. The apparent increase in the growth of the plants exposed to nano-fertilizers can be attributed to their homogeneous distribution in different parts of the plant (Awan et al., 2021). Furthermore, Li et al. (2018) argued that the slow release of ZnO-NPs in tomato and soybean plants prevents the toxicity of large amounts of zinc in plants by preventing its sudden uptake.

According to Table 2, maximum chlorophyll a and b, total chlorophyll, and carotenoid contents were observed in plants treated with 100 mg/L ZnO-NPs. Similar results were found in maize plants so that foliar application of 100 mg/L ZnO-NPs elevated the chlorophyll a and b concentrations by 64% and 67%, respectively (Rizwan et al., 2019). Foliar application of ZnO-NPs increased the amounts of light harvesting pigments, i.e., chlorophyll a, b, and carotenoids in sugarcane seedlings (Elsheery et al., 2020). A High carotenoid content in leaves of sugarcane plants treated with ZnO-NPs elevated the non-photochemical quenching (NPQ) of PSII (Elsheery et al., 2020).

Xanthophylls (as oxygen containing carotenoids) are involved in quenching of excess energy on PSII through the xanthophyll cycle, which is important to prevent photo-damage to the photosystems and maintain the photosynthesis rate (Derks et al., 2015). Zn affects the concentration of micro- or macro-nutrients involved in chlorophyll biosynthesis (such as Fe and Mn), which are part of chlorophyll structure such as N and Mg (Kumar et al., 2021). Amino levulinic acid dehydratase (an enzyme in the chlorophyll biosynthesis pathway) requires Mg2+ and Zn2+ for its activity (Zhu et al., 2023), so its activity is enhanced by Zn treatment. It could be hypothesized that an increase in the growth and photosynthesis pigment contents in dragonheads might be a result of physiological responses caused by zinc sufficiency under Zn fertilization.

The findings showed that a concentration of 100 mg/L ZnO-NP significantly increased the essential oil percentage in plant tissues.The increase in the content of essential oil under nano-zinc application have been observed by other researchers such as Nekoukhou et al. (2022) in dragonhead and Fallahi et al. (2016) in basil. Faizan et al. (2018) reported that zinc as a cofactor by increasing the activity of Rubisco enzyme and carbon metabolism promotes the synthesis of essential oils, especially monoterpenes. In other words, optimal supply of zinc allocates more assimilates (such as glucose) to the production of essential oils by improving the photosynthetic capacity (Nekoukhou et al., 2022; Saleh et al., 2018).

Nanoparticles cause calcium and reactive oxygen species signaling at the cell surface along with complex physiological changes at the organism level (Abdal Dayem et al., 2017). The results from Table 3 showed that by increasing levels of ZnO and ZnO-NPs, activities of CAT, APX, and GPX significantly increased. Application of nano-zinc and salt-zinc as priming treatment and foliar spray treatment significantly increased CAT and POD activities compared to control in corn plants (Naseer et al., 2023). Hernandez-Fuentes et al. (2023) reported that foliar application of zinc nanoparticles promoted greater CAT, APX, and POD activities, compared to the control in pear plants. Application of ZnO-NPs by 50-200 mg/L significantly boosted CAT, APX, and GPX activities under arsenic stress in both seedlings and plants before the reproductive stage in Vigna mungo (Banerjee et al., 2023). Increased antioxidant enzyme activities reflect the generation of ROS and then oxidative damage caused by the zinc treatment in dragonhead plants. The antioxidant enzymes of CAT, APX, and GPX play an important role in plant defense mechanisms against oxidative stress via converting H2O2 to water in plant cell organelles. Although zinc is an important element for many metabolic processes in the plant cell, its high concentration disrupts photosynthesis and creates oxidative stress. In this study, the effect of ZnO-NPs in each of the treatment levels on antioxidant enzymes activities was greater than the effect of ZnO at the same level. In alfalfa, the activities of CAT, APX, and POD (peroxidase) were noticeably higher in nano-ZnO treated plants than in bulk-ZnO under non-stress and salt-stress conditions (Hassan et al., 2023). CAT and APX activities increased by 88-106%, with 100 mg/L of in comparing to bulk Zn and control in tomato seedlings (Azim et al., 2022). The results of our experiment along with the results of previous studies confirm that the increase in the amount of antioxidant enzymes can be the plant's defense response to the increase in free radicals caused by the increase in zinc levels in the plant, although the dragonheads were able to compensate this negative effect by increasing the antioxidant enzymes, and thus improving their growth and biomass accumulation.

In the present study, the dominant compounds of the essential oils in the dragonhead plant, in the control and treated plants with different concentrations of zinc oxide and zinc nanoparticles, were oxygenated monoterpenes, and among them four dominant substances were geranial, geranyl acetate, Z-citral, and geraniol, respectively. Although their relative levels were different in the treatments. An increase in the levels of oxygenated monoterpenes, including geraniol, geranial, geranyl acetate, and neral, indicates an improvement in the quality of the synthesized essential oil in dragonhead, as most of the desirable physical, chemical, and biological properties of essential oils are attributed to these compounds (Brahmi et al., 2017). Review of the literature on chemical compositions of dragonhead suggests that the largest number of the compounds belongs to geranial + neral (Z-citral) + geranyl acetate chemotype (Aćimović et al., 2022). Some other researchers have reported the major compounds of dragonhead as follows: geranyl acetate + geranial + geraniol (Amini et al., 2020; Pouresmaeil et al., 2022). The chemotype of the essential oil extracted from D. moldavica harvested in Urmia, Iran included geranial, neral, geraniol, and geranyl acetate (Ehsani et al., 2017). The variation in essential oil composition can be caused by the factors such as regional climate, plant species and variety, distillation conditions, and maturation stage (Aminzare et al., 2015).

The results of Table 4 showed that the application of foliar zinc (zinc oxide and zinc nanoparticles) at different concentrations was effective on the composition of dragonhead’s essential oil. Monoterpenes such as geranyl acetate, geranial, geraniol and neral are synthesized via MEP (methylerythritol phosphate) pathway (Lukas et al., 2015). The key enzyme of MEP pathway (2-C-methyl-D-erytrithol 2, 4-cyclodiphosphate synthase) requires zinc as a cofactor for its activity (Steinbacher et al., 2003). It can be said that the optimal supply of zinc can increase the level of monoterpenes. Hassanpouraghdam et al. (2011) reported that methylchavicol as the main ingredient of essential oil of Ocimum basilicum increased with zinc sulfate treatment.

In our study, positive effects of ZnO-NP in increasing oxygenated monoterpenes were more pronounced in comparison with the same level of ZnO. In a previous work, the levels of the monoterpenes (neral, geraniol, and geranial) significantly increased with ZnO-NP (160 mg/L) compared to the equivalent level of ZnS or control (Nekoukhou et al., 2022). Nanoparticles may cause a slight increase in the production of reactive oxygen species (ROS) in cells, which can cause the changes in secondary metabolites and activate the antioxidant system (Marslin et al., 2017). Therefore, the use of nano-fertilizers as an elicitor, by changing the chemical composition of the essential oil, can be useful for increasing the production of the desired secondary metabolites.

The results of this research showed that foliar application of ordinary ZnO and ZnO-NPs at different levels had a significantly positive effect on growth, photosynthetic pigments, antioxidant enzymes, and the quantity and quality of dragonhead essential oil. The highest amount of growth indicators, contents of chlorophyll a, b, and carotenoids, antioxidant enzymes activities as well as the percentage of essential oils were observed in plants sprayed with 100 mg/L of ZnO-NP. The investigation of the main compositions of dragonhead essential oil revealed that oxygenated monoterpenes constitute an important percentage of the secondary compounds in the essential oil. The four compounds of geranial, geranyl acetate, Z-citral, and geraniol contain the highest levels of essential oil. Foliar application of zinc nanoparticles at 100 mg/L produced the highest amount of the above-mentioned essences. Therefore, foliar application of zinc, especially zinc nanoparticles, plays an important role in increasing the biomass and essential oil of the valuable dragonhead plant.

References

Abdal Dayem, A., M. K. Hossain, S. B. Lee, K. Kim, S. K. Saha, G.-M. Yang, H. Y. Choi and S.-G. Cho. 2017. The role of reactive oxygen species (ROS) in the biological activities of metallic nanoparticles. International journal of molecular sciences, 18, (1) 120.

Aćimović, M., O. Šovljanski, V. Šeregelj, L. Pezo, V. D. Zheljazkov, J. Ljujić, A. Tomić, G. Ćetković, J. Čanadanović-Brunet and A. Miljković. 2022. Chemical composition, antioxidant, and antimicrobial activity of Dracocephalum moldavica L. essential oil and hydrolate. Plants, 11, (7) 941.

Adrees, M., Z. S. Khan, M. Hafeez, M. Rizwan, K. Hussain, M. Asrar, M. N. Alyemeni, L. Wijaya and S. Ali. 2021. Foliar exposure of zinc oxide nanoparticles improved the growth of wheat (Triticum aestivum L.) and decreased cadmium concentration in grains under simultaneous Cd and water deficient stress. Ecotoxicology and Environmental Safety, 208, 111627.

Amini, R., A. Ebrahimi and A. D. M. Nasab. 2020. Moldavian balm (Dracocephalum moldavica L.) essential oil content and composition as affected by sustainable weed management treatments. Industrial crops and products, 150, 112416.

Aminzare, M., J. Aliakbarlu and H. Tajik.2015. The effect of Cinnamomum zeylanicum essential oil on chemical characteristics of Lyoner-type sausage during refrigerated storage. Proc. Veterinary Research Forum, 6(1): 31-39.

Arnon, A. 1967. Method of extraction of chlorophyll in the plants. Agronomy journal, 23, (1) 112-121.

Awan, S., K. Shahzadi, S. Javad, A. Tariq, A. Ahmad and S. Ilyas. 2021. A preliminary study of influence of zinc oxide nanoparticles on growth parameters of Brassica oleracea var italic. Journal of the Saudi Society of Agricultural Sciences, 20, (1) 18-24.

Azim, Z., N. Singh, S. Khare, A. Singh, N. Amist and R. K. Yadav. 2022. Green synthesis of zinc oxide nanoparticles using Vernonia cinerea leaf extract and evaluation as nano-nutrient on the growth and development of tomato seedling. Plant Nano Biology, 2, 100011.

Banerjee, S., J. Islam, S. Mondal, A. Saha, B. Saha and A. Sen. 2023. Proactive attenuation of arsenic-stress by nano-priming: Zinc Oxide Nanoparticles in Vigna mungo (L.) Hepper trigger antioxidant defense response and reduce root-shoot arsenic translocation. Journal of Hazardous Materials, 446, 130735.

Bonjoch, N. P. and P. R. Tamayo. 2001. Protein content quantification by Bradford method. In Handbook of plant ecophysiology techniques:283-295: Springer. Number of 283-295 pp.

Brahmi, F., M. Khodir, C. Mohamed and D. Pierre. 2017. Chemical composition and biological activities of Mentha species. In Aromatic and medicinal plants-Back to nature: IntechOpen.

Çakmak, İ. and U. Á. Kutman. 2018. Agronomic biofortification of cereals with zinc: a review. European journal of soil science, 69, (1) 172-180.

Chance Maehly, A. 1995. Assay of catalases and peroxidases. Methods Enzymol, 2, 764-775.

Cohen, G., M. Kim and V. Ogwu. 1996. A modified catalase assay suitable for a plate reader and for the analysis of brain cell cultures. Journal of neuroscience methods, 67, (1) 53-56.

Derks, A., K. Schaven and D. Bruce. 2015. Diverse mechanisms for photoprotection in photosynthesis. Dynamic regulation of photosystem II excitation in response to rapid environmental change. Biochimica et Biophysica Acta (BBA)-Bioenergetics, 1847, (4-5) 468-485.

Ehsani, A., O. Alizadeh, M. Hashemi, A. Afshari and M. Aminzare. 2017/ Phytochemical, antioxidant and antibacterial properties of Melissa officinalis and Dracocephalum moldavica essential oils. Proc. Veterinary Research Forum, 8(3): 223 – 229.

Elsheery, N. I., V. Sunoj, Y. Wen, J. Zhu, G. Muralidharan and K. Cao. 2020. Foliar application of nanoparticles mitigates the chilling effect on photosynthesis and photoprotection in sugarcane. Plant Physiology and Biochemistry, 149, 50-60.

Faizan, M., A. Faraz, M. Yusuf, S. Khan and S. Hayat. 2018. Zinc oxide nanoparticle-mediated changes in photosynthetic efficiency and antioxidant system of tomato plants. Photosynthetica, 56, 678-686.

Fallahi, A., A. Hassani and F. Sefidkon. 2016. Effect of foliar application of different zinc sources on yield and phytochemical characteristics of basil (Ocimum basilicum L.). Iranian Journal of Medicinal and Aromatic Plants Research, 32, (5) 743-757.

Ghosh, S. K. and T. Bera. 2021. Molecular mechanism of nano-fertilizer in plant growth and development: A recent account. In Advances in nano-fertilizers and nano-pesticides in agriculture:535-560: Elsevier. Number of 535-560 pp.

Gupta, N., H. Ram and B. Kumar. 2016. Mechanism of Zinc absorption in plants: uptake, transport, translocation and accumulation. Reviews in Environmental Science and Bio/Technology, 15, 89-109.

Hassan, M. U., H. A. Kareem, S. Hussain, Z. Guo, J. Niu, M. Roy, S. Saleem and Q. Wang. 2023. Enhanced salinity tolerance in Alfalfa through foliar nano-zinc oxide application: Mechanistic insights and potential agricultural applications. Rhizosphere, 28, 100792.

Hassanpouraghdam, M. B., G. R. Gohari, S. J. Tabatabaei, M. R. Dadpour and M. Shirdel. 2011. NaCl salinity and Zn foliar application influence essential oil composition of basil (Ocimum basilicum L.). Acta agriculturae Slovenica, 97, (2) 93-98.

Hernández-Fuentes, A. D., A. Montaño-Herrera, J. M. Pinedo-Espinoza, Z. H. Pinedo-Guerrero and C. U. López-Palestina. 2023. Changes of the antioxidant system in pear (Pyrus communis L.) fruits by foliar application of copper, selenium, iron, and zinc nanoparticles. Journal of Agriculture and Food Research, 14, 100885.

Hussain, A., S. Ali, M. Rizwan, M. Z. Ur Rehman, M. R. Javed, M. Imran, S. a. S. Chatha and R. Nazir. 2018. Zinc oxide nanoparticles alter the wheat physiological response and reduce the cadmium uptake by plants. Environmental Pollution, 242, 1518-1526.

Kah, M., R. S. Kookana, A. Gogos and T. D. Bucheli. 2018. A critical evaluation of nanopesticides and nanofertilizers against their conventional analogues. Nature nanotechnology, 13, (8) 677-684.

Kaur, H., H. Kaur, H. Kaur and S. Srivastava. 2023. The beneficial roles of trace and ultratrace elements in plants. Plant Growth Regulation, 100, (2) 219-236.

Khan, S. T., A. Malik, A. Alwarthan and M. R. Shaik. 2022. The enormity of the zinc deficiency problem and available solutions; an overview. Arabian Journal of Chemistry, 15, (3) 103668.

Kumar, S., S. Kumar and T. Mohapatra. 2021. Interaction between macro‐and micro-nutrients in plants. Frontiers in Plant Science, 12, 665583.

Li, C., P. Wang, E. Lombi, M. Cheng, C. Tang, D. L. Howard, N. W. Menzies and P. M. Kopittke. 2018. Absorption of foliar-applied Zn fertilizers by trichomes in soybean and tomato. Journal of Experimental Botany, 69, (10) 2717-2729.

Marslin, G., C. J. Sheeba and G. Franklin. 2017. Nanoparticles alter secondary metabolism in plants via ROS burst. Frontiers in plant science, 8, 832.

Miyake, C. and K. Asada. 1996. Inactivation mechanism of ascorbate peroxidase at low concentrations of ascorbate; hydrogen peroxide decomposes compound I of ascorbate peroxidase. Plant and cell physiology, 37, (4) 423-430.

Mohammadi, M. H. Z., S. Panahirad, A. Navai, M. K. Bahrami, M. Kulak and G. Gohari. 2021. Cerium oxide nanoparticles (CeO2-NPs) improve growth parameters and antioxidant defense system in Moldavian Balm (Dracocephalum moldavica L.) under salinity stress. Plant Stress, 1, 100006.

Moradbeygi, H., R. Jamei, R. Heidari and R. Darvishzadeh. 2020. Investigating the enzymatic and non-enzymatic antioxidant defense by applying iron oxide nanoparticles in Dracocephalum moldavica L. plant under salinity stress. Scientia Horticulturae, 272, 109537.

Moradi, S., S. Khaledian, M. Abdoli, M. Shahlaei and D. Kahrizi. 2018. Nano-biosensors in cellular and molecular biology. Cellular and Molecular Biology, 64, (5) 85-90.

Naseer, I., S. Javad, S. Iqbal, A. A. Shah, K. Alwutayd and H. Abdelgawad. 2023. Deciphering the role of zinc oxide nanoparticles on physiochemical attributes of exposed to saline conditions through modulation in antioxidant enzyme defensive system. South African Journal of Botany, 160, 469-482.

Nasiri, Y. 2021. Crop productivity and chemical compositions of dragonhead (Dracocephalum moldavica L.) essential oil under different cropping patterns and fertilization. Industrial Crops and Products, 171, 113920.

Nekoukhou, M., S. Fallah, A. Abbasi-Surki, L. R. Pokhrel and A. Rostamnejadi. 2022. Improved efficacy of foliar application of zinc oxide nanoparticles on zinc biofortification, primary productivity and secondary metabolite production in dragonhead. Journal of Cleaner Production, 379, 134803.

Pouresmaeil, M., M. Sabzi-Nojadeh, A. Movafeghi, B. N. Aghbash, M. Kosari-Nasab, G. Zengin and F. Maggi. 2022. Phytotoxic activity of Moldavian dragonhead (Dracocephalum moldavica L.) essential oil and its possible use as bio-herbicide. Process Biochemistry, 114, 86-92.

Prasad, T. N. V. K. V., A. N. Kumar, M. Swethasree, M. Saritha, G. Satisha, P. Sudhakar, B. R. Reddy, B. P. Girish, N. Sabitha and B. V. B. Reddy. 2022. Combined Effect of Nanoscale Nutrients (Zinc, Calcium, and Silica) on Growth and Yield of Groundnut (Arachis hypogaea L.).

Rizwan, M., S. Ali, M. Z. Ur Rehman, M. Adrees, M. Arshad, M. F. Qayyum, L. Ali, A. Hussain, S. a. S. Chatha and M. Imran. 2019. Alleviation of cadmium accumulation in maize (Zea mays L.) by foliar spray of zinc oxide nanoparticles and biochar to contaminated soil. Environmental Pollution, 248, 358-367.

Rossi, L., L. N. Fedenia, H. Sharifan, X. Ma and L. Lombardini. 2019. Effects of foliar application of zinc sulfate and zinc nanoparticles in coffee (Coffea arabica L.) plants. Plant Physiology and Biochemistry, 135, 160-166.

Rui, M., C. Ma, Y. Hao, J. Guo, Y. Rui, X. Tang, Q. Zhao, X. Fan, Z. Zhang and T. Hou. 2016. Iron oxide nanoparticles as a potential iron fertilizer for peanut (Arachis hypogaea). Frontiers in plant science, 7, 815.

Saleh, A. M., S. Selim, S. Al Jaouni and H. Abdelgawad. 2018. CO2 enrichment can enhance the nutritional and health benefits of parsley (Petroselinum crispum L.) and dill (Anethum graveolens L.). Food chemistry, 269, 519-526.

Umair Hassan, M., M. Aamer, M. Umer Chattha, T. Haiying, B. Shahzad, L. Barbanti, M. Nawaz, A. Rasheed, A. Afzal and Y. Liu. 2020. The critical role of zinc in plants facing the drought stress. Agriculture, 10, (9) 396.

Xu, M., M. Liu, F. Liu, N. Zheng, S. Tang, J. Zhou, Q. Ma and L. Wu. 2021. A safe, high fertilizer-efficiency and economical approach based on a low-volume spraying UAV loaded with chelated-zinc fertilizer to produce zinc-biofortified rice grains. Journal of Cleaner Production, 323, 129188.

Zhu, D., C. Wu, C. Niu, H. Li, F. Ge and W. Li. 2023. Biochemical and molecular characterization of a novel porphobilinogen synthase from Corynebacterium glutamicum. World Journal of Microbiology and Biotechnology, 39, (6) 165.

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Effect of foliar application of ordinary and nano-zinc fertilizers on growth and essential oil profile of dragonhead