The effects of iron and zinc spraying in sulfate and nano forms on morphological and biochemical properties of peppermint (Mentha piperita L.) under salinity stress

Rostami, Ghader; Moghaddam, Mohammad; Ghasemi Pirbalouti, Abdollah; Tehranifar, Ali

doi:10.22077/escs.2018.870.1170

Document Type : Original Article

Authors

¹ MSc. Student, Department of Horticulture, Faculty of Agriculture, Ferdowsi University of Mashhad, Mashhad, Iran.

² Associate Professor, Department of Horticulture, Faculty of Agriculture, Ferdowsi University of Mashhad, Mashhad, Iran.

³ Professor, Department of Medicinal Plants, Shahrekord Branch, Islamic Azad University, Shahrekord, Iran.

⁴ Professor, Department of Horticulture, Faculty of Agriculture, Ferdowsi University of Mashhad, Mashhad, Iran.

https://doi.org/10.22077/escs.2018.870.1170

Abstract

Introduction
Salinity after drought stress is one of the important stress around world including Iran. Salinity causes interrupt in cell division and growth and affect all metabolic reactions in plant. Consuming micronutrient could increase the resistance of the plant against negative effects of salinity. The medicinal plant needs micronutrient enough for producing essential oil and among micronutrients, iron is more needed. Iron is one of essential nutrients, micro, and immobile. This nutrient is required a cofactor for many oxidant and reduction enzymes and the synthesis of chlorophylls. Zinc is also one of micronutrients that involves in tryptophan synthesis, auxin precursor, obsceneness of leaves, carbohydrate metabolism and protein synthesis.
One of the important applications of the non-technology is nano-fertilizers in agriculture. Nanoparticle inters into the plant through stomata. Peppermint (Mentha piperita L.) from family Lamiaceae grows in the sandy-acidic soil and medium light and high humidity conditions. Peppermint is a rich source of polyphenol that has the antioxidant effect. Regarding importance of peppermint, this research was aimed to investigate effects of nano-Fe and nano-Zn on some biochemical characteristics of peppermint.

Material and methods
This work conducted for evaluating the effects of iron and zinc application in two forms, nano and sulfate, on some morphological and biochemical characteristics of peppermint under salt stress, at research greenhouse of Ferdowsi University of Mashhad, Mashhad, Iran. The experiment arranged as factorial based on completely randomized design with three replications. The first factor was salinity in four levels (0, 40, 80, and 120 mM NaCl) and the second factor was foliar application Fe and Zn fertilizers in five levels (0, Fe-sulfate and Zn-sulfate at 1500 mg.l-1 and nano-particles of Fe and Zn at 300 mg.l-1). Rhizomes with 10 cm length were cultured within 5 cm depth in pots with 40 cm height and 30 cm diameter. The pots filled with an equal amount of soil, sand, and peat (1:1:1) in each pot. The physio-chemical characteristic of soil was as follows: 1.2 dS/m EC, 7.9 pH, 29% sand, 41% clay, 30% silt, and loam-clay tissue. The first spraying was applied one week before exerting salt stress and two spraying after three weeks exerting salt stress in two intervals. Traits measured were chlorophyll, SPAD, soluble carbohydrate, and some morphological traits.

Results
The results indicated that salt stress had significant effect on the growth and biochemical characteristics of peppermint including shoot length, number of branches, number of tiller, length and width of leaves, fresh and dry weight of aerial part, chlorophyll a and b, total chlorophyll, carotenoid, and SPAD. It decreased all of these traits. analysis of interaction effects of treatments indicated that the highest levels of growth and chlorophyll content were obtained in control treatment (without of salt stress) and plants grown under mild stress (40 mM NaCl) treated with nano-Fe and Zn. As the highest plant high (78 cm), number of branches (36 branches per plant), and leaf length (6 cm) were related to control treatment (without of salt stress) and foliar application with nano-Fe. While the highest width of leaf (2.16 cm) was obtained in plants treated with nano-Fe and grown under 40 mM NaCl which there was no significant difference with application of nano fertilizers in control treatment. The highest amount of soluble carbohydrates with the amount of 1.28 and 1.212 mg/g dry weight were obtained under 40 and 80 mM salinity conditions with the application of nano-Fe fertilizer, respectively.

Conclusion
The results of this study imply that application iron and zinc nanoparticles in comparison to its sulfate forms improves the growth characteristics, chlorophyll contents, and carbohydrate under control and mild salinity stress conditions (40 mM). Considering pivotal role of iron and zinc in the growth of the plant and expanding of nano-Fe and nano-Zn could have important role in supporting micronutrient for plants.

Keywords

References

Abd El-Aziz, N.G., Laila, B.K., 2007. Influence of tyrosine and zinc on growth, flowering and chemical constituents of Salvia farinacea plants. Journal of Applied Sciences Research. 3, 1479-1489.

Archangi, A., Khoddambashi, M., Mohammad Khani, A., 2012. Effect of salinity on morphological characteristics and the amount of sodium potassium and calcium inn fenugreek under hydroponic conditions. Science and Technology of Greenhouse Cultures. 10, 33-49 [In Persian with English Summary].

Abdmishani, S., Bushehri, A., 1992. Supplementary Plant Breeding Course. Department of Agronomy and Plant Breeding Publication, Tehran University. 322 p. [In Persian].

Alpaslan, M., Inal, A., Gunes, A., Cikili, Y., Oscan, H., 1999. Effect of zinc treatment on the alleviation of sodium and chloride injury in tomato (Lycopersicon esculentum L.) grown under salinity. Turkish Journal of Botany. 23, 1-6.

Cakmak, I., 2008. Enrichment of cereal grains with zinc: Agronomic or genetic biofortification. Plant and Soil. 302, 1-17.

Cornic, G., Massacci, A., 1996. Leaf photosynthesis under drought stress. In: Photosynthesis and the Environment: Springer. 347-366.

Cramer, G.R., Lynch, J., Läuchli, A., Epstein, E., 1987. Influx of Na⁺, K⁺, and Ca²⁺into roots of salt-stressed cotton seedlings effects of supplemental Ca²⁺. Plant Physiology. 833, 510-516.

Das, R., Kiley, P., Segal, M., Norville, J., Yu, A.A., Wang, L., Trammell, S.A., Reddick, L.E., Kumar, R., Stellacci, F., Lebedev, N., Schnur, J., Bruce, B.D., Zhang, S., Baldo, M., 2004. Integration of photosynthetic protein molecular complexes in solid-state electronic devices. Nano Letters. 4, 1053 -1033.

El-Fouly, M.M., Mobarak, Z.M., Salama, Z.A., 2011. Micronutrients (Fe, Mn, Zn) foliar spray for increasing salinity tolerance in wheat Triticum aestivum L. African Journal of Plant Science. 5, 314-322.

El-Tohamy, W., El-Greadly, N., 2007. Physiological responses, growth, yield and quality of snap beans in response to foliar application of yeast, vitamin E and zinc under sandy soil conditions. Australian Journal of Basic and Applied Sciences. 1, 294-299.

Eraslan, F., Inal, A. Gunes, A., Alpaslan, M., 2007. Impact of exogenous salicylic acid on the growth, antioxidant activity and physiology of carrot plants subjected to combined salinity and boron toxicity. Scientia Horticulturae. 113(2), 120-128.

Epstein, E., Rains, D.W., 1987. Advances in salt tolerance. Plant and Soil. 99, 17-29.

Fathi, A., Zahedi, M., 2014. Effect of foliar application of iron oxide nanoparticles on the growth and ionic content in two maize genotypes differing in soil salinity. Scientia Horticulturae. 121, 110-117.

Gardner, F., Piers, R., Michelle, L., 2011. Physiology of crop plants. Translation: Koocheki A, and Sarmadnia Gh: Mashhad SID Press. 327p.

Ginzberg, I., Stein, H., Kapulnik, Y., Szabados, L., Strizhov, N., Schell, J., Koncz, C., Zilberstein, A., 1998. Isolation and characterization of two different cDNAs of Δ1-pyrroline-5-carboxylate synthase in alfalfa, transcriptionally induced upon salt stress. Plant Molecular Biology. 38, 755-764.

Glyn, M., 2002. Mineral nutrition, production and artemisin content in Artemisia annua. Acta Horticulture. 426, 721-728.

Groppa, M., Rosales, E., Iannone, M., Benavides, M., 2008. Nitric oxide, polyamines and Cd-induced phytotoxicity in wheat roots. Phytochemistry. 69, 2609-2615.

Gurmani, A.R., Khan, S.U., Andaleep, R., Waseem, K., Khan, A., 2012. Soil application of zinc improves growth and yield of tomato. International Journal of Agriculture and Biology. 14, 91-96.

Gholami, R., Kashefi, B., Saeidi Sar, S., 2013. Effect salicylic acid on alleviation of salt stress on growth traits of Salvia limbata L. Journal of Plant Eco-Physiology. 15(5), 63-73 [In Persian with English Summary].

Ghahramani, A., 1993. Plant Systematics Cormophytes of Iran. Academic Publishing Center. 364pp. [In Persian].

Hemant Ranjan, A., 1996. Physiology and biochemical significance of zinc in plants. Advanct of Micro Research. 151-178.

Hendawy, S.F.K., Khalid, A., 2005. Response of sage Salvia officinalis L. plants to zinc application under different salinity levels. Journal of Applied Sciences Rrsearch. 1, 147-155.

Jiang, Y., Huang, B., 2001. Drought and heat stress injury to two cool-season turfgrasses in relation to antioxidant metabolism and lipid peroxidation. Crop Science Society of America. 41, 436-442.

Lahooti, M., 1989. Biochemistry and Physiology of Plant Hormones. University of Mashhad press. 360p. [In Persian].

Kaya, C., Higgs, D., Kirnak, H., 2001. The effects of high salinity (NaCl) and supplementary phosphorus and potassium on physiology and nutrition development of spinach. Bulgarian Journal of Plant Physiology. 27, 47-59.

Keles, Y., Öncel, I., 2004. Growth and solute composition in two wheat species experiencing combined influence of stress conditions. Russian Journal of Plant Physiology. 51, 203-209.

Koyro, H.W., 2006. Effect of salinity on growth, photosynthesis, water relations and solute composition of the potential cash crop halophyte Plantago coronopus (L.). Environmental and Experimental Botany. 56, 136-146.

Kubi, J., 2005. The effect of exogenous spermidine on superoxide dismutase activity, H₂O₂ and superoxide radical level in barley leaves under water deficit conditions. Acta Physiologiae Plantarum. 27, 289-295.

Kaffi, M., Lahootizand, M., Sharefi, H.R., Goldani, M., 1998. Plant Physiology. Vol, 1. Iranian Academic Center for Education, Culture and Research Publication, Mashhad. 664 p. [In Persian].

Misra, A., Srivastava, A., Srivastava, N., Khan, A., 2005. Zn-acquisition and its role in growth, photosynthesis, photosynthetic pigments, and biochemical changes in essential monoterpene oil (s) of Pelargonium graveolens. Photosynthetica. 43, 153-155.

Mortezainajad, F., Khavarinajad, R.A., Emami, M., 2005. Evaluation of some performance parameters and proline rice varieties under salt stress. New Agricultural Science. 2(4), 65-70 [In Persian with English Summary].

Malakuti, M.J., Homaei, M., 2004. Fertility of soils in arid and semi-arid regions, problems and solutions. University of Tarbiat Modares press 518p. [In Persian].

Naderi, M., Danesh-Shahraki, A., 2013. Nanofertilizers and their roles in sustainable agriculture. International Journal of Agriculture and Biology. 5, 22-29.

Nair, R., Varghese, S.H., Nair, B.G., Maekawa, T., Yoshida, Y., Kumar, D.S., 2010. Nanoparticulate material delivery to plants. Plant Science. 179, 154-163.

Nasiri, Y., Zehtab-Salmasi, S., Nasrullahzadeh, S., Najafi, N., Ghassemi-Golezani, K., 2010. Effects of foliar application of micronutrients (Fe and Zn) on flower yield and essential oil of chamomile (Matricaria chamomilla L.). Journal of Medicinal Plants Research. 4, 1733-1737.

Najafi, H., Mirmasumi, M., 1998. Evaluation the physiological reactions of soybean under salt stress. Journal of Agricultural Sciences and Technology. 1, 34-39.

Natran, M., Khalaj, H., Labbafi Hossinabadi, M., Shams Abadi, M., Razlazi, A., 2004. The effect of foliar application of nano-iron chelate on the quantity and quality of wheat. 15-16 Mhr, conference hall and Seed Improvement Institute, Abstract Second National Conference on Application of Nanotechnology in Agriculture [In Persian].

Omidbeigi, R., 2000. Approaches of Production and Process of Medicinal Plants. Volume 2. Tarahan Sabz Publishing, Tehran. 440p. [In Persian].

Pinheiro, C., Chaves, M.M., Ricardo, C.P., 2001. Alterations in carbon and nitrogen metabolism induced by water defficit in the stems and leaves of Lupinus albus L. Journal Experimental Bototany. 52, 1063–1070.

Peyvandi, M., Mirza, M., 2011. Comparison of the effect of iron nanoclay on growth parameters and activity of basaltic antioxidant enzymes (Ocimum basilicum). Journal of Cellular Biotechnology – Molecular. 1, 98-89.

Pidvandi, M., Mirza, M., Kamali Jamakani, Z., 2011. The effect of nano Fe chelate and Fe chelate on the growth and some antioxidant enzymes activity of summary survey (Satureja hortensis). New Cellular and Molecular Biotechnology Journal. 2, 25-32. [In Persian with English Summary]

Qi, D., Zhang, H., Tang, J., Deng, C., Zhang, X., 2010. Facile synthesis of mercaptophenylboronic acid-functionalized core-shell structure Fe3O4@C@Au magnetic microspheres for selective enrichment of glycopeptides and glycoproteins. Journal of Physologe Chemistry. 114, 9221-9226.

Rezaei, M., Hosseini S., Shaban Ali Fami, H., 2009. VassafaIdentifying and analyzing the barriers of nanotechnology development and technology in Iran's agricultural sector from the perspective of researchers. Journal of Research Science and Technology Policy. 2 (1), 17-26. [In Persian]

Radzimska, A.K., Jesionowski, T., 2014. Zinc oxide—from synthesis to application: A review. Journal of Materials. 7, 2833-2881.

Singh, R., Shushni, M. A., Belkheir, A., 2015. Antibacterial and antioxidant activities of Mentha piperita L. Arabian Journal of Chemistry. 8, 322-328.

Said-Al Ahl, H.A.H., Mahmoud, A.A., 2010. Effect of zinc and/or iron foliar application on growth and essential oil of sweet basil (Ocimum basilicum L.) under salt stress. Ozean Journal of Applied Sciences. 3(1), 97-111.

Şükran, D., GÜNEŞ, T., Sivaci, R., 1998. Spectrophotometric determination of chlorophyll-A, B and total carotenoid contents of some algae species using different solvents. Turkish Journal of Botany. 22, 13-18.

Sarani, S., Mostafa, M., Galoi, M., Syahsar, B.A., 2012. The effects of salinity and iron on the growth, photosynthetic pigments and electrophoretic bands of German chamomile (Marticaria chamomilla L.) and Roman chamomile (Anthemis nobilis L.). Journal of Medicinal and Aromatic Plants Research. 29(4), 732-746 [In Persian with English Summary].

Schaller, R.D., Klimov, V.I., 2004. High efficiency carrier multiplication in PbSe nanocrystals: implications for solar energy conversion. Physical Review Letters. 92(18): 186601-186604.

Sevengor, S., Yasar, F., Kusvuran, S., Ellialtioglu, S., 2011. The effect of salt stress on growth, chlorophyll content, lipid peroxidation and antioxidative enzymes of pumpkin seedling. African Journal of Agricultural Research. 6, 4920- 4924.

Torabiyan, S.H., Zahedi, M., 2013. The effect of foliar feeding iron and zinc sulfate to the usual two forms of nanoparticles on the growth of sunflower cultivars under salt stress. Iranian Journal of Field Crop Science. 44(1), 109-118 [In Persian with English Summary].

Yadlarlou, L., Majidi Heravan, E., 2008. Evaluation of salinity stress on morphophysiological traits of four salinity tolarant wheat cultivars. Iranian Journal of Field Crops Research. 1, 205-215 [In Persian with English Summary].

Yadghari, R., Nyakan, M., Mosavat, A., 2014. The effect of nano and non-nano forms chelate zinc on growth, chlorophyll content and soluble sugar pea plants (Cicer arietinum L.) in different levels of salinity. Iranian Journal of Plant Ecophysiology Research. 9,137-150 [In Persian with English Summary].

Environmental Stresses in Crop Sciences

The effects of iron and zinc spraying in sulfate and nano forms on morphological and biochemical properties of peppermint (Mentha piperita L.) under salinity stress

References

References

Volume 11, Issue 3
Open Access Policy
October 2018
Pages 707-720

The effects of iron and zinc spraying in sulfate and nano forms on morphological and biochemical properties of peppermint (Mentha piperita L.) under salinity stress

References

References

Volume 11, Issue 3 Open Access PolicyOctober 2018Pages 707-720

Volume 11, Issue 3
Open Access Policy
October 2018
Pages 707-720