Investigation of Growth Indices and Gas Exchanges in Two Cultivars of Sweet William (Dianthus barbatus) under Salinity Stress

Document Type : Research Article

Authors

1 Horticultural Sciences Department, Lorestan University, Khorramabad, Iran

2 Lorestan University

Abstract

Introduction
 Salinity stress impairs the absorption of elements such as potassium, leads to decrease in water and minerals, or due to an increase in Na+ effects the absorption of other elements. Salinity of water and soil is one of the obstacles to the expansion of agriculture in most part of the world. Salinity causes several physiological and morphological changes in plants and affects growth and photosynthesis. Salinity stress also affects the absorption of nutrients, and finally the plants sensitivity to stress increases. High concentrations of Nacl in rhizosphere reduce the water potential and cause physiological drought stress. In addition, salinity stress can cause ion toxicity and imbalance, which can damage the plant. Salinity stress has been shown to reduce plant biomass by decreasing photosynthetic capacity and chlorophyll content. As stress increases, stomatal conductance and CO2 assimilation decrease, which both negatively impact photosynthesis and lead to a decrease in plant growth. Dianthus is an annual or perennial plant that produces velvety flowers in various colors. Due to its resistance to cold and wide range of colors, it is commonly used in landscaping. However, limited research has been conducted on the response of Dianthus to environmental stress, making it important to investigate its behavior under such conditions.
Material and Method
 This research was conducted at greenhouse of municipality of Khomein, Iran. The statistical design was used in the factorial experiment based on CRD. Experimental factors included salinity stress (0, 10, 20, 30, 40, 50, 60, 70, 80, 90 mM) and cultivars (Barbarin and Diana). After preparing the seeds, it is first disinfected using sodium hypochlorite and then planted in plastic pots containing soil, sand and manure. At the end of the experiment, morphological traits, stomatal conductance, photosynthesis rate, Na+, K+ and Na+/K+ was also examined. Gas exchanges were measured using an exchange measuring device (LCA4, ADC Bioscientific,Ltd., Hoddesdon, England). At the time of measuring gas exchanges, the temperature under chamber was 26-29 C and relative humidity was 58-62%. (stomatal conductivity is based on mmol/m2/s and photosynthesis in µmol/m2/s). To measure the concentration of Na+ and K+, the leaf first turned to ash (at 550 C). Then 5 ml of hydrochlorid was added to dissolve the sample and the volume of the filtered solution was reduced to 50 ml with distilled water and the concentration of Na+ and K+ was measured with flame meter. In order to measure the fresh weight of leaves and roots, plant components were separated. Fresh weight was recorded with a scale and then samples were placed in the oven (for 48 h) and weighted again to measure dry weight. Leaf area was measured with a leaf guuge device (A30325) and plant height and root length using a ruler. Statistical analysis of data was performed using Mini Tab and Excel software.
Results and Discussion
 Results showed that salinity stress generally affected the growth of both carnation cultivars and reduced vegetative and reproductive growth. According to the results obtained from the study, fresh and dry weight of shoot, root and leaves, root length, plant height, stem diameter, diameter and number of flower, lateral shoot number, stomatal conductance, photosynthesis rate, K+ concentration in Diana and Barbarin cultivars decreased with increasing salinity level. Na+ concentration and Na+/K+ increased with increasing salinity and these two traits were higher in Diana than Barbarin cultivar, which indicates lower resistance of Diana cultivar. The plant's first response to stress is to reduce its leaf area, which reduces the supply of photosynthetic material to the growing parts and consequently hinders growth and flowering. Salinity stress and high osmotic potential in the rhizosphere greatly affect photosynthesis as they decrease pore conductivity. Moreover, excessive absorption of Na+ can interfere with the absorption of other elements, thereby restricting plant growth. Potassium (K+) is an essential inorganic molecule that plays a crucial role in increasing plant resistance to stress. It helps in maintaining turbidity, promoting cell development, and regulating stomatal function. In this study, salinity stress affected the growth and yield of both carnation cultivars, and with increasing stress, all morphological traits decreased. This stress also reduce photosynthesis by reducing stomatal conductance and subsequently reduce other growth characteristics. Growth reduction was observed at high salinity stress concentrations in both cultivars. However, barbarin cultivar showed higher resistance than Diana

Keywords

Main Subjects

References

  • Abdul, J., Gopisankar, R.B., Manivannan, P., Kishorekumar, A., Sridharan, R., & Panneerselvam, R. (2007). Studies on germination, seedling vigor, lipid peroxidation and proline metabolism in Catharanthus roseus seedling under salt stress. Journal of Botany 73: 190-195. https://doi.org/10.1016/j.sajb.2006.11.001.
  • Akram, N.A., & Ashraf, M. (2011). Improvement in growth, chlorophyll pigments and photosynthetic performance in salt-stressed plants of sunflower (Helianthus annuus) by foliar application of 5-aminolevulinic acid. Agrochimica 55: 94-104.
  • Aldesuquy, H.S., & Ibrahim, A.H. (2001). Interactive effect of seawater and growth bio-regulators on water relations, absicisic acid concentration, and yield of wheat plants. Journal of Agronomy and Crop Science 187: 185-193. https://doi.org/10.1046/j.1439-037x.2001.00522.x.
  • Alvarez, S., & SanchezBlanco, M.J. (2014). Longterm effect of salinity on plant quality, water relations, photosynthetic parameters and ion distribution in Callistemon citrus. Plant Biology 16(4): 757-764. https://doi.org/10.1111/plb.12106.
  • Azari, A., ModaresSanavi, S.A.M., Askari, H., Ghanati, F., Naji, A.M., & Alizadeh, B. (2012). Effect of salt stress on morphological and physiological traits of two species of rapeseed (Brassica napus and rapa). Iranian Journal of Crop Sciences 14: 121-135. (In Persian with English abstract). http://agrobreedjournal.ir/article-1-90-en.html.
  • Boursier, P., & Läuchli, A. (1990). Growth responses and mineral nutrient relations of salt-stressed sorghum. Crop Science 30: 1226-1233. https://doi.org/10.2135/cropsci1990.0011183X003000060014x.
  • Cai, X., Niu, G., Starman, T., & Hall, C. (2014). Response of six garden roses (Rosa × hybrida) to salt stress. ScientiaHorticulturae 16(8): 27-32. https://doi.org/10.1016/j.scienta.2013.12.032.
  • Cassaniti, C., Leonardi, C., & Flowers, T.J. (2009). The effects of sodium chloride on ornamental shrubs. ScientiaHorticulturae 122(4): 586-593. https://doi.org/10.1016/j.scienta.2009.06.032.
  • Centritto, M., Loreto, F., & Chartzoulakis, K. (2003). The use of low [CO2] to estimate diffusional and non-diffusional limitations of photosynthetic capacity of salt-stressed olive saplings. Plant, Cell and Environment 26: 585-594. http://dx.doi.org/10.1046/j.1365-3040.2003.00993.x.
  • Chinnusamy, V., Jagendorf, A., & Zhu, J.K.(2005). Understanding and improving salt tolerance in plants. Crop Science 45: 437-448. https://doi.org/10.2135/cropsci2005.0437.
  • Dulai, S., Molnár, I., Háló, B., & Molnár-Láng, M. (2010). Photosynthesis in the 7H AsakazeKomugi/Manas wheat/barley addition line during salt stress. Acta AgronomicaHungarica 58: 367-376. https://doi.org/10.1556/AAgr.58.2010.4.5.
  • Dulai, S., Molnár, I., & Molnár-Láng, M. (2011). Changes of photosynthetic parameters in wheat/barley introgression lines during salt stress. Acta Biologica Szegediensis 55: 73-75. http://www.sci.u-szeged.hu/ABS.
  • Dulai, S., Molnár, I., Szopkó, D., Darkó, É., Vojtkó, A., Sass-Gyarmati, A., & Molnár-Láng, M. (2014). Wheat Aegilops biuncialisamphiploids have efficient photosynthesis and biomass production during osmotic stress. Journal of Plant Physiology 171: 509-517. http://doi.org/10.1016/j.jplph.2013.11.015.
  • Ebrahim, M. (2005). Amelioration of sucrose metabolism and yield changes, in storage roots of NaCl-stressed sugar beet by ascorbic acid. Agrochimica 49: 93–103.
  • Flexas, J., Bota, J., Loreto, F., Cornic, G., & Sharkey, T.D. (2004). Diffusive and metabolic limitations to photosynthesis under drought and salinity in C3 plants. Plant Biology 6: 269-279. https://doi.org/10.1055/s-2004-820867.
  • Garcia-Caparros, P., & Lao, M.T. (2018). The effects of salt stress on ornamental plants and integrative cultivation practices. ScientiaHorticulturae 240: 430-439. https://doi.org/10.1016/j.scienta.2018.06.022.
  • Grattan, S.R., & Grieve, C.M. (1999). Salinity-mineral-nutrient relations in horticultural crops. Scientia Horticulture 78: 127-157. https://doi.org/10.1016/S0304-4238(98)00192-7.
  • HashemiEsfahani, A. (2000). Promotion of Modern Floriculture. Nasagh Publications. (In Persian)
  • Khorsandi, O., Hassani, A., Sefidkon, F., Shirzad, H., & Khorsandi. A. (2010). Effect of salinity (NaCl) on growth, yield, essential oil content and composition of Agastachefoeni culumkuntz. Iranian Journal of Medicinal and Aromatic Plants 26: 438-451. (In Persian with English abstract). https://doi.org/10.22092/ijmapr.2010.6807.
  • Heidari, Z., Asadi Gharneh, H., & Razmjo, J., (2018). The effect of salinity stress sodium chloride on some morphological aspect of sage plant (Salvia nemorosa). Jornal of Environmental Stress in Agricultural Science 13(4): 983-993. http://doi.org/10.22077/escs.2020.2211.1556.
  • Kingsbury, R.W., Epestin, E., & Pearcy, R.W. (1983). Physiological responses to salinity in selected lines of wheat. Journal Plant Physiology 74: 417-423. https://doi.org/10.1104/pp.74.2.417.
  • Koushafar, M., Khoshgoftarmanesh, A.H., Moezzi, A.A., & Mobli, M. (2011). Effect of dynamic unequal distribution of salts in the root environment on performance and crop per drop (CPD) of hydroponic-grown tomato. Science Horticulture 131: 1-5. https://doi.org/10.1016/j.scienta.2011.09.016.
  • Kwon, O.K., Mekapogu, M., &  Kim, K.S. (2019). Efect of salinity stress on photosynthesis and related physiological responses in carnation (Dianthus caryophyllus). Horticulture, Environment, and Biotechnology https://doi.org/10.1007/s13580-019-00189-7.
  • Mardani, H., & Azizi, M. (2010). Effect of salicylic acid on morphological and physiological parameter of cucumber (Cucumis sativus Super Dominus) in dry stress. Iranian Journal of Horticulture Science 3: 321-326. (In Persian). https://dorl.net/dor/20.1001.1.23222050.1390.18.3.5.8.
  • Misra, A., & Sricastatva, N.K. (2000). Influence of water stress on Japanese m int. Journal of Herbs, Spices & Medicinal Plants 7: 51-58. http://dx.doi.org/10.1300/J044v07n01_07.
  • Munns, R. (1993). Physiological process limiting plant growth in saline soils: some damages and hypothesis. Plant Cell Environment 16: 15-24. https://doi.org/10.1111/j.1365-3040.1993.tb00840.x.
  • Munns, R., James, R.A., & Lauchli, A. (2006). Approaches to increasing the salt tolerance of wheat and other cereals. Journal of Experimental Botany 57: 1025-1043. https://doi.org/10.1093/jxb/erj100.
  • Nabati, J., Kafi, M., Boromande Reza Zadeh, A., Masomi, A., &Zare Mehrjerdi, M. (2016). The effect of salinity stress on the photosynthetic apparatus Kochia (Bassias coparia) In field conditions. Iranian Agricultural Research Journal 16(4): 743-759. https://dorl.net/dor/20.1001.1.20081472.1397.16.4.4.1.
  • Nazir, N., Ashraf, M., & Ejaz, R. (2001). Genomic relationships in oilseed Brassicas with respect to salt tolerancephotosynthetic capacity and ion relations. Pakistan Journal of Botany 33: 483-501.
  • Noctor, G., Veljovic-Jovanovic, S.D., Driscoll, S., Novitskaya, L., & Foyer, C.H. (2002). Drought and oxidative load in wheat leaves. A predominant role for photorespiration. Annal Botonical 89: 841-850. https://doi.org/10.1093%2Faob%2Fmcf096.
  • Omidi, M., Khandan Mirkohi, A., Kafi, M., & Zamani, Z. (2018). The effect of salinity stress on some physiological and morphological indicators in damask rose Kashan genotype. Journal of Horticultural Science of Iran 51(1): 1-17. https://doi.org/10.22059/ijhs.2018.251968.1398.
  • Omoto, E., Taniguchi, M., and Miyake, H. 2010. Effects of salinity stress on the structure of bundle sheath and mesophyll chloroplasts in NAD-malic enzyme and PCK type C4 plants. Plant Production Science 13: 169-176. https://doi.org/10.1626/pps.13.169.
  • Rozbahani, F., Mosavi Fard, S., & Rezaiee Nejad, A. (2019). The effect of proline on some physiological and biochemical characteristics in two varieties lady flowers (Impatiens walleriana) under salinity stress. Journal of Horticultural Science of Iran 51 (3). 537-550. https://doi.org/10.22059/ijhs.2019.279774.1632.
  • Parida, A.K., & Das, A.B. (2005). Salt tolerance and salinity effects on plants: a review. Eco toxico. and Enviro. Safety 60: 324-349. https://doi.org/10.1016/j.ecoenv.2004.06.010.
  • Rahnama, A., Poustini, K., Tavakkol-Afshari, R., & Tavakoli, A. (2010). Growth and stomatal responses of bread wheat genotypes in tolerance to salt stress. World Academy of Science Engineering and Technology 71: 14-19.
  • Rostami, M., Mohammad Parast, B., & Golpham, R. (2013). Effect of different levels of salinity stress on leaf concentrations of saffron leaves (Crocus sativus L.). National Conference on Agricultural Science and Technology, Malayer, Malayer University. (In Persian). https://doi.org/10.22048/jsat.2015.10379.
  • Saravanavel, R., Ranganathan, R., & Anantharaman, P. (2011). Effect of sodium chloride on photosynthetic pigments and photosynthetic characteristics of Avicennia officinalis Recent Research in Science and Technology 3: 177-180.
  • Shirazi, M.U., Ashraf, M.Y., Khan, M.A., & Naqvi, M.H. (2005). Potassium induced salinity tolerance in wheat (Triticum aestivum). International Journal Environment Science Technology 2: 233-236. https://doi.org/10.1007/BF03325881.
  • Taize, L., & Zeiger, E. (1998). Plant Physiology. Sinauar Associates, Inc. Pub., Massachusetts.
  • Tester, M., & Venterport, R.D. (2003). Na+ tolerance and Na+ transport in higher plants. Botonical 93: 503- 537. https://doi.org/10.1093/aob/mcg058.
  • Veatch-Blohm, M.E., Chen, D., & Hassett, M. (2013). Narcissus cultivar differences in response to saline irrigation when application began either pre- or postemergence. Horticultureal Science 48(3): 322-329. https://doi.org/10.21273/HORTSCI.48.3.322.
  • William, H. (2000). Official methods of analysis of AOAC international. 17nd ed. USA: AOAC International. 100p.
  • Zhang, G., & Deng, C. (2012). Gas exchange and chlorophyll fluorescence of salinity-alkalinity stressed Phragmites australis Journal of Food, Agriculture & Environment 10: 880-884.

Zheng, J., Ma, X., Zhang, X., Hu, Q., & Qian, R. (2018). Salicylic acid promotes plant growth and salt-related gene expression in Dianthus superbus L. (Caryophyllaceae) grown under different salt stress conditions. Physiology and Molecular Biology of Plants 24(2): 231–238.  https://doi.org/10.1007%2Fs12298-017-0496-x

Send comment about this article
CAPTCHA Image

Files

History

  • Receive Date: 13 August 2021
  • Revise Date: 23 September 2021
  • Accept Date: 01 November 2021
  • First Publish Date: 01 November 2021

Share

How to cite

Statistics