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تاثیر کاربرد اسید سالیسیلیک بر برخی ویژگی های مورفولوژیکی و فیزیولوژیکی ارقام انگور (Vitis vinifera L.) تحت شرایط تنش خشکی

نوع مقاله : مقالات پژوهشی

نویسندگان

دانشگاه ارومیه

چکیده

به منظور بررسی اثرات تیمار اسید‌سالیسیلیک بر برخی ویژگی‌های مورفولوژیکی و فیزیولوژیکی دو رقم نهال انگور (رشه و بیدانه سفید)، تحت شرایط تنش خشکی، پژوهشی به صورت آزمایش فاکتوریل در قالب طرح بلوک‌های کامل تصادفی با سه تکرار انجام گرفت. دورهای آبیاری شامل آبیاری به فواصل هر 5 (شاهد)، 10 و 15روز یک بار و تیمارهای اسید‌سالیسیلیک شامل غلظت‌های صفر (شاهد)، 1 و 2 میلی مولار بود. نتایج نشان داد که با افزایش تنش خشکی،صفات ارتفاع نهال، قطرتنه، تعداد و سطح برگ و شاخص کلروفیل کاهش معنی‌داری نسبت به تیماردور آبیاری هر 5 روز یک بار (شاهد) پیدا کرد در حالی که میزان تجمع پرولین،قند‌های محلول، مالون دی آلدهید و پروتئین کل افزایش یافت. میزان ارتفاع نهال، قطرتنه، تعدادبرگ، میزان پرولین و پروتئین کل در رقم رشه بیشتر از رقم بیدانه سفید بود. محلول پاشی اسید‌سالیسیلیک با غلظت 2 میلی مولار موجب افزایش معنی‌دار صفات ارتفاع نهال، قطرتنه، تعداد و سطح برگ، شاخص کلروفیل، قندهای محلول و پروتئین کل و کاهش معنی دار میزان مالون دی آلدهید نسبت به تیمار اسید‌سالیسیلیک با غلظت صفر میلی مولار(شاهد)تحت شرایط تنش خشکی گردید. به طور کلی نتایج پژوهش حاضر نشان داد که کاربرد اسید‌سالیسیلیک با غلظت 2 میلی مولار می‌تواند اثرات تنش خشکی بر رشد انگور را تعدیل کند و رقم رشه در مقایسه با رقم بیدانه سفید از تحمل بالاتری نسبت به تنش خشکی برخوردار است.

کلیدواژه‌ها

عنوان مقاله [English]

TheEffect of Salicylic Acid Application on Some Morphological and Physiological Characteristics of Grape Cultivars (Vitisvinifera L.) Under Drought Stress Conditions

نویسندگان [English]

  • Naser Abbaspour
  • Lavin Babaei
  • Alireza Farrokhzad

Urmia University

چکیده [English]

Introduction: Water stress is considered as a main environmental factor limiting crop growth and yield, including grape in Mediterranean areas.Selection for drought-tolerantvarieties is possible through investigation of their performance under stress conditions. The estimation of physiological characteristics as reliable indices can be used as a tool to select tolerant plants. For this reason, varieties and genotypes of one plant species are usually investigated through physiological characteristics and its relation to drought tolerance. Investigation of the effects of water stress on some growth and physiological characteristics in grape plants has revealed that plant height, number of leaves and nodes, leaf area and the percentage of dry weightdecreased under increasing drought stress. Salicylic Acid is a naturally occurring plant hormone whichinfluences various morphological and physiological functions in plant. It can act as an important signaling molecule and has diverse effects on biotic and abiotic stresses tolerance capacity.
Materials and Methods: In this research, two-yearold grapesplanted in plastic pots containingingredients of humus, soil and sand (1:2:1) were used. The experiment was conducted using a factorial based on randomized complete block design with three factors including irrigation periods (every 5, 10 and 15 days), salicylic acid concentrations (0, 1 and 2 mM) and grape cultivars (Rasheh andBidanesefid) with 3 replications in thegreenhouse of faculty of agricultureinUrmia University. Plant height, stem diameter and leaf area and chlorophyll indicesweremeasuredby usingruler, digital caliper (Model22855 NO: Z), leaf Area Meter (ModelAM200) and SPAD-502 chlorophyll meter (Minolta Crop, Japan),respectively. In order to determine proline content, malondialdehyde (MDA), total protein and total soluble sugars, spectrophotometric methods [51,25,6and28] were utilized,respectively.
Results and Discussion: Based on comparing the averages related to the interaction of various levels of drought and salicylic acid, increasing watering intervals resulted in significant decrease in parameters of plant height, stem diameter, leaf area, leaf number and chlorophyll index,and increase inproline content, malondialdehyde, total protein and total soluble sugars.Furthermore, according to the obtained results, plant height, stem diameter, leaf number, chlorophyll index, accumulation of prolineandtotal protein in grape cv. Rashehwere higher than Bidanesefidone.Drought effected the mitotic division, andelongation and expansion of cells, leading to reduced growth and crop yield. It was concluded that plant height, stem diameter, and leaf area decreased noticeably byincreasing water stress. The reduction in plant height could be attributed to decline in the cell enlargement and higher rate ofleaf senescence in the plant under water stress. The reduction in leaf number under severe water deficit was partially due to leaf senescence. Reduction inthe number of leaves could be a response by plants to minimize the transpiration surface. Sorghum plants have also been reported to have a similarbehaviorthroughwhichthey conserve water by reducing the number of leaves. When exposed to chronic water deficit, they showed an initial decrease in the daily increment of leaf area and eventually a decrease due to accelerated senescence. Dropping of the leaves during severe stress markedly reduces the evaporative surface and allows the plant to conserve water.It is well known that proline contents in leaves of many plants are enhanced by several stresses including drought stress. The efficiency of exogenous SA depends on multiple causes such as the species, developmental stage of the plant, manner of application and concentration of SA.Plant height, stem diameter, leaf number, leaf area, leaf total soluble sugar and chlorophyll index increased by applying 2 mM salicylic acid comparedwith 0 and 1 mM doses. The findings of this study showed that salicylic ‌acid was able to enhance the tolerant capacity of the grape plant to the drought stress. According to theobtained results, Rashehcultivar showed a greater resistance to drought stress. Salicylic acid prohibits auxin and cytokinin loss in plants and thus enhances cell division and plant growth. Salicylic ‌acid maintainsphotosynthetic aspects like chlorophyll content at proper level and thus helps plants to grow and developwell. In this study, the drought stress increased the amount of MDA.MDA and other aldehydes in the dry conditions are the result ofactive oxygen species (ROS) such as super oxide radical, peroxide, hydrogen and radical hydroxide, whichareproduced underoxidative stress conditions. The species of active oxygen leads to lipids' per oxidation as a result of injury or damage to the cellular membrane, especially chloroplast membrane.Salicylic acid increases the activity of antioxidant enzymes such as CAT, POD and SOD which in turn protect plants against ROS generation and lipid peroxidation. Salicylic acid treatment also providesa considerable protection from the enzyme nitrate reductase, thereby maintaining the level of diverse proteins in leaves.Mohammadkhani and Heidari (48) found that the initial increase in total soluble proteins during drought stress was due to the expression of new stress proteins.

کلیدواژه‌ها [English]

  • Drought stress
  • Malondialdehyde
  • Proline
  • salicylic acid
  • Total proteins
  • Soluble sugars
مراجع
1- Abdel-Nasser L. E., and Abdel-Aali A. E. 2002. Effect of elevated CO2 and drought on proline metabolism and growth of safflower (Carthamus mareoticus L.) seedlings without improving water status. Pakistan Journal
2- of Biological Sciences, 5:523–528.
3- Al-Hakimi A.M.A. 2008. Effect of salicylic acid on biochemical changes in wheat plants under khat leaves residues. Plant Soil and Environment Journal, 54: 288–293.
4- Arji A., Arzani K., and Ebrahimzadeh H.2004. Quantitative study of proline and soluble sugarin5varieties of olive under drought stress. Iranian Journal of Biology, 16(4): 85-92. (in Persian)
5- Benjamin J. G., Nielsen D. C., 2006. Water deficit effects on root distribution of soybean, field pea and chickpea. Field Crops Research, 97:248-253.
6- Bertamini M., Zulini L., Muthuchelian K. and Nedunchezhian N. 2006. Effect of water deficit on photosynthetic and other physiological responses in grapevine (Vitis viniferaL. cv. Riesling) plants. Photosynthetica, 44(1): 151-154.
7- Bradford M. M. 1976. Arapid and sensitive method for the quantitation of micrograms quantities of protein utilizing the principle of protein dye bandung. The Annual Review of Biochemistry, 72: 248-254.
8- Christensen, L. P., 2000. Raisin Production Manual. University of California, Agriculture and Natural Resources.
9- Close T. J. 1996. Dehydrins: Emergence of a biochemical role of a family of plant dehydration proteins. Journal of Plant Physiology, 97: 795-803.
10- Cramer G. R., Lauchl A., and Epstein E. 1986. Effect of NaCl and CaCl2 on ion activities in complex nutrient solution and root growth of cotton. Journal of Plant Physiology, 81: 792-797.
11- Cuevas M. V., Torres-Ruiz J. M., Alvarez R., Jimenez M. D., Cuerva L., and Fernandez J. E. 2010. Assessment of trunk diameter variation derived indices as water stress indicators in mature olive trees. Agricultural Water Management, 97:1293–1302.
12- Devlin M. R. and Withman F. H. 2002. Journal of Plant Physiology. CBS Publishers & distributors, Chapter 12.
13- El-Tayeb M. A. 2005. Response of barley grains to the interactive effect of salinity and salicylic acid. Plant Growth Regulation, 45: 215-224.
14- Eraslan F., Inal A., Gunes A., and Alpaslan M. 2007. Impact of exogenous salicylic acid on growth, antioxidant activity and physiology of carrot plants subjected to combined salinity and boron toxicity. Scientia Horticulturae,113: 120–128.
15- Erdal S., Aydin M., Genisel M., Taspinar M. S., Dumlupinar R., Kaya O and Gorcek z. 2011. Effects of salicylic acid on wheat salt sensitivity. African Journal of Biotechnology, 10(30): 5713-5718.
16- Faragher J. D., and Brohier R. L. 1984. Anthocyanin accumulation in apple skin during ripening: Regulation by ethylene and phenylalanine ammonia-lyase. ScientiaHorticulturae, 22: 89-96.
17- Faridduddin Q., Hayat S., and Ahmad A. 2003. Salicylic acid influences net photosynthetic rate, carboxylation efficiency, nitrate reductase activity and seed yield in Brassica Juncea. Journal of Photosynthetica, 41: 281-284.
18- Fulton A., and Richard B. 2005. The effect of water stress on walnut tree growth, productivity and economics. ActaHorticalturae, 65: 125-132.
19- Garcia M.G., Busso C.A., Polci P., Garcia L.N., and EcheniqueV. 2002. Water relation and leaf growth rate of three Agropyron genotypes under water stress. Biology of Cell, 26:309-317.
20- Ghaderi N., Siosemardeh A., and Shahoei., S. 2005. The effect of water stress on some physiological characteristics in Rasheh and Khoshnave grape cultivars. Acta Horticulture, 754: 317-322.
21- Ghasemzadeh A. andJaafar H. Z. E., 2013. Interactive effect of salicylic acid on some physiological features and antioxidant enzymes activity in ginger (Zingiberofficinale Roscoe L.). Molecules, 18: 5965-5979.
22- Gomez del Campo M., Baeza P., Ruiz C., and Lissarrague J. R. 2004. Water Stress Induced Physiological Changes in Leaves of Four Container-grown Grapevine Cultivars (VitisviniferaL.). Vitis, 43: 99-105.
23- Hasani A., Omidbeygi R., andSharif Abad H. 2004. Evaluation of drought resistance indices in the basil plant. Journal of Agricultural Sciencesand Natural Resources, 10(4): 74-65. (in Persian with English abstract)
24- Hayat S., Fariduddin Q., Ali B., and Ahmad A., 2005. Effect of salicylic acid on growth and enzyme activities of wheat seedling. Agronomy Journal, 53: 433-437.
25- Hayat Q., Hayat S., Irfan M., and Ahmad A. 2010. Effect of exogenous salicylic acid under changing environment: A review. Environmental and Experimental Botany, 68: 14-25.
26- Heath R. L. and PacherL. 1969. Photo peroxidation in isolated chloroplast. I.Kinetics and stoichiometry of fatty acid peroxidation. Archives of Biochemistry and Biophysics, 125:189-198.
27- Horvath E., Szalai G., and Janda T. 2007. Induction of abiotic stress tolerance by salicylic acid signalling. Journal of Plant Growth Regulation, 26: 290 – 300.
28- Hsiao, T.C. (1973). Plant response to water stress. Journal of Plant Physiology, 24: 516-570.
29- Hussain, M., Malik, M. A., Farooq, M., Ashraf, M.Y., and Cheema, M. A. (2008). Improving drought tolerance by exogenous application of glycine-betaine and salicylic acid in sunflower. Journal of Agronomy and Crop Science, 194: 193-199.
30- Ingram J., and Bartels D. 1996. The molecular basis of dehydration tolerance in plants. Annual Review of Plant Physiology and Plant Molecular Biology, 47: 337-403.
31- Irigoyen J. J., Emerich D.W. and Sanchez-Diaz M. 1992. Water stress induced changes in concentrations of proline and total soluble sugars in nodulated alfalfa (Medicage sativa) plants. Journal of Plant Physiology, 84: 55-60.
32- JaliliMarandi R. 2010. Environmental stress physiology and resistance mechanisms in plants garden (fruit trees, vegetables, ornamental plants and medicinal plants). PressSID, West Azarbaijan. Iran.
33- JaliliMarandi R., Hasani A., DovlatiBaneh H., Azizi H., and Haji Taghiloo R. 2011. Effect of Different Levels of Soil Moisture on the Morphological and Physiological Characteristics of Three Grape Cultivars (Vitis vinifera L.). Iranian Journal of Horticaltural Sciences, 42 (1): 40-31. (in Persian)
34- Janda T., Horvath E., Szalai G., and Paldi E. 2007. Role of salicylic acid in the induction of abiotic stress tolerance. In: Salicylic acid: a plant hormone. Hayat S., and Ahmad A. (Eds). Springer. 410 p.
35- Jiang Y., and Huang B. 2002. Protein alternation in tall fescue in response to drought stress and ABA. Crop science, 42: 202-207.
36- Joseph B., Jini D., and Sujatha S. 2010. Insight into role ofexogenous salicylic acid on plants growth under salt environment. Asian Journal of Crop Science, 2(4): 226 – 235.
37- Kavikishore P. B., Sangam S., Amrotha R. N., Laxmi P., and Naidu S. 2005. Regulation of proline biosynthesis, degredation, uptake and transport in higher plants, crop science, 88: 424-438.
38- Khan M. B., Hussain N., and Iqbal M. 2001. Effect of water stress on growth and yield components of maize variety YHS 202. Science,12: 15-18.
39- Khodary A.S.E. 2004 . Effect of salicylic acid on the growth, photosynthesis and carbohydrate metabolism in salt stressed maize plants. International Journal of Agriculture & Biology, 226:1560–8530.
40- Lebon E., Pellegrino A., andLouarn G. 2006. Branch development controls leaf area dynamics in grapevine (Vitis vinifera L.) growing in drying soil. Journal of Botany, 98(1):175–185.
41- Li N., B.L. Parsons B. L., Liu D. R., and Mattoo A. K. 1992. Accumulation of wound-inducible ACC synthase transcript in tomato fruit is inhibited by salicylic acid and polyamines. Plant Molecular Biology, 18: 477-487.
42- Lurie S., Havdros A., Fallek E., and Shapira. 1996. Reversible inhibition of tomato fruit gene expression at light temperature. Journal of Plant Physiology, 110: 1207-1214.
43- Maestri M., Damatta F. M., Regazzi A. J., and Barros R. S. 1995. Accumulation of proline and quaternary ammonium compounds in mature leaves of water stressed coffee plants (Coffea Arabica L. Coffeacanephera L.). American Society for Horticultural Science, 72(2): 229-223.
44- Mandal S. 2010. Induction of phenolics, lignin and key defense enzymes in eggplant (SolanummelongenaL.) roots in response to elicitors. African Journal of Biotechnology, 9(47): 8038-8047.
45- Manivannan P., Jaleel CA., Kishorekumar A., Sankar B., Somasundaram R., Sridharan R., and Panneerselvam R. 2007. Changes in antioxidant metabolism of VignaunguiculataL. Walp. By propiconazole under water deficit stress. Colloids and Surfaces B: Biointerfaces, 57: 69-74.
46- Mardani H., Bayat H., and Azizi M. 2011. The effect offoliar application of salicylic acid on morphological and physiological characteristics of cucumber seedlings (Cucumissativus cv. Super Dominus) under drought stress. Journal ofHorticultural Science, 25(3): 326-320. (in Persian with English abstract)
47- McCree K.J. 1985. Whole plant carbon balance during osmotic adjustment to drought and salinity stress. Aust. Journal of Plant Physiology. 13, 33-43.
48- Meir S., Philosophhadas S., and Aharoni N. 1992. Ethylene increased accumulation of fluorescent lipid–peroxidation products detected during Parsley by a newly developed method. American Society for Horticultural Science, 117: 128- 132.
49- Mohammadkhani N., and Heidari R. 2008. Effects of drought stress on soluble proteins in two maize varieties. Journal of Biology, 32: 23-30.
50- Moradi MarjaneA., and Goldani M. 2012. The effect of drouth conflict and salisilicasid on som morphological features in (calendula officinalis L.) medical plant. Journal of environmental stress on cropscience, 4(1):6. (in Persian)
51- Nayyar H. and Walia D. P., 2003. Water stress induced proline accumulation in contrasting wheat genotypes as affected by calcium and abscisic acid. Journal of Plant Biology, 46: 275-279.
52- Paquin R., andLechasseur P. 1979. Observationssurunrmethod de dosage de la prolinelibredans les extraits de plantes. Canadian Journal of Botany, 57: 1851-1854.
53- Parida A., Das A. B., and Das P. 2002. NaCl stress causes changes in photosynthetic pigments, proteins and other metabolic components in the leaves of a true mangrove, Bruguieraparviflora, in hydroponic cultures. Journal of Plant Biology, 45:28–36.
54- Raskin I., 1992. Role of salicylic acid in plants. Annual Review of Plant Physiology and Plant Molecular Biology, 43: 439-46.
55- Rezaei T., GholamiM., Ershadi A., and MossadeghiM.2007.Effectsof water stress on growth and physiological characteristics of five grape varieties. Agricultural Research magazine: water, soil and plants in agriculture, 4(7): 199-210. (in Persian with English abstract)
56- Sairam R. K., Deshmukh P. S., and Saxena D. C. 1998. Role of antioxidant systemes in wheat genotype tolerance to water stress. Journal of Plant Biology, 41 (3): 387-394.
57- San-Miguel R., Gutierrez M., and Larque-saavedra A. 2003. Salicylic acid increases the biomass accumulation of Pinuspatula. Journal of Applied Forestry, 27(1): 52-54.
58- Senaratna T., Touchell D., Bunn E., and Dixon K. 1998. Method for inducing stress tolerance in plant material, Australia.
59- Senaratna T., Merrit D., Dixon K., Bunn E., Touchell D., and Sivasithamparam K. 2003. Benzoic acid may act as the functional group in salicylic acid and derivatives in the induction of multiple stress tolerance in plants. Plant Growth Regulator, 39: 77-81.
60- Singh B., and Usha K. 2003. Salicylic acid induced physiological and biochemical changes in weat seedlings under water stress. Plant Growth Regulator, 39: 137-14.
61- Smart D. R., Carlisle E., Goebel M., and Nunez A. 2005. Transverse hydraulic redistribution by a grapevine.Plant, Cell & Environment, 28: 157–166.
62- Ton Y., and Kopyt M. 2004. Grapevine trunk and shoot diameter micro variations and trends as indicators of water potential. ActaHorticulturae, 652: 220-226.
63- Vafabakhsh J., NasiriMahallati M., and koocheki A. 2008.Effects of drought stress on radiation use efficiency and yield of winter Canola (Brassica napusL.). Iranian Journal of Field Crops Research, 6: 193-208.
64- Wang L. j., Fan L., Leoscher W., Duan W., Liv G. J., and Cheng J. S. 2010. Salicylic acid allivates decreases in photosynthesis under heat and accelerates recovery in grapevine leaves. Journal of Plant Biology, 10: 34-37.
65- Winkel T., and Rambal S. 1993. Influence of water stress on grapevine growing in field: from leaf to whole- plant response. Australian Jounrnal of plant physiology, 20: 143-150.
66- Yadollahi A., Arzania K., Ebadib A., Wirthensohnc M., and Karimia S. 2011. The response of different almond genotypes to moderate and severe water stress. ScientiaHorticulturae, 129: 403–413.
67- Yildirim E., and Dursun A. 2003. Effect of foliar salicylic acid applications on plant growth and yield of tomato under greenhouse conditions. ActaHorticulturae, 807: 565- 571.
68- Zhu J. K. 2001. Cell signaling under salt, water and cold stresses. Current Opinion in Plant Biology, 4:401–406.
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علوم باغبانی
دوره 31، شماره 2 - شماره پیاپی 2
شهریور 1396
صفحه 269-280
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  • تاریخ دریافت: 26 مهر 1394
  • تاریخ پذیرش: 26 مهر 1394
  • تاریخ اولین انتشار: 01 شهریور 1396
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