تاثیر مواد ضد یخ در شرایط باغی بر مواد بیوشیمیایی موثر در مقاومت به سرمای انگور

نوع مقاله : مقالات پژوهشی

نویسندگان

1 مرکز تحقیقات و آموزش کشاورزی و منابع طبیعی استان قزوین

2 وزارت جهاد کشاورزی

چکیده

به منظور بررسی امکان افزایش مقاومت به سرمای بهاره درخت انگور از طریق مواد ضد یخ در شرایط باغی، آزمایشی در ﻗﺎﻟﺐ ﻃﺮح بلوکهای ﮐﺎﻣل ﺗﺼﺎدﻓﯽ در مرکز تحقیقات شهرستان تاکستان در استان قزوین در دو سال 91 و92 اجرا شد. محلول پاشی با 4 ماده ضد یخ شامل سالیسیلیک اسید، تیوفر، کراپ اید، بایوبلوم و آب مقطر به عنوان تیمار شاهد در 4 مرحله فنولوژیکی از جمله پاییز پیش از به خواب رفتن گیاه، در زمان متورم شدن جوانه‌ها، مصادف با شروع خوشه‌دهی و در زمان خوشه‌دهی کامل روی سه درخت انگور بی دانه قرمز در هر کرت آزمایشی انجام شد. خصوصیات کمی و کیفی مانند وزن خوشه، عملکرد محصول و میزان مواد جامد محلول، خصوصیات بیوشیمیایی برگ انگور مانند میزان اسمولیت‌های پرولین و بتائین گلایسین و وضعیت آنزیم‌های شاخص مقاومت به سرما از جمله گایاکول پراکسیداز (GPX)، آسکوربات پراکسیداز (APX) و کاتالاز (CAT) اندازه‌گیری و مورد تجزیه و تحلیل آماری قرار گرفتند. نتایج نشان‌داد که استفاده از مواد ضد یخ نامبرده به طور متوسط میزان مواد جامد محلول، وزن خوشه و عملکرد درخت انگور را بطور متوسط به ترتیب تا 22، 17 و 26 درصد افزایش داد که از این نظر بایوبلوم تاثیر بیشتری داشت. کاهش به طور متوسط 2 درجه‌ دمای هوا طی مراحل ریزش برگ و رکود انگور (آبانماه تا دیماه) سال 92 نسبت به سال قبل از آن منجر به افزایش معنی‌دار میزان اسمولیت‌ها و فعالیت آنزیم‌های شاخص مقاومت به سرما شد. همچنین مواد ضد یخ موجب افزایش معنی‌دار میزان اسمولیت‌ها و فعالیت آنزیم‌های شاخص مقاومت به سرما نسبت به تیمار شاهد شدند. به طوریکه بیشترین میزان این اسمولیتها و میزان فعالیت این آنزیم ها به ترتیب مربوط به تیمارهای سالسیلیک اسید، تیوفر، کراپ آید و بایوبلوم بوده و کمترین آن در تیمار شاهد اندازه گیری شد. این نتایج نشان می دهد که ضد یخ های تجاری مورد بررسی می توانند نه تنها برای افزایش مقاومت گیاه به سرما در تاکستان مورد استفاده قرار بگیرند، بلکه اندازه خوشه و کیفیت انگور را نیز بهبود می‌دهند.

کلیدواژه‌ها


عنوان مقاله [English]

The Effects of Anti-freeze Compounds on the Effective Biological Materials in Freezing Tolerance of Grape under the Orchard Conditions

نویسندگان [English]

  • Shokrollah Hajivand 1
  • Mitra Rahmati 2
1 Agriculture and Natural Resources Research Center of Qazvin
2 Ministry of Jihad-e-Agriculture, Tehran
چکیده [English]

Introduction: Nowadays, horticultural products especially in our country are damaged by the climate change events (rising temperatures, water shortage associated by drought and extreme temperature fluctuations). The greatest economic damage to horticultural crops are caused by winter chilling and / or spring frosts, in which has been increased by seventimes during the last 10 years. Indeed, just during 9 months of 2016-2017 year, the chilling/frost damages were reached to 140 million euro of the total damage value of 240 million euro to agriculture (about 60%). According to the Agricultural Insurance Fund, maximum amount of compensation to farmers of the country was paid to apples, walnuts, grapes, almonds, pomegranates, oranges and pistachios orchardists, respectively. Grape (Vitisvinifera), a member of the Vitaceae family, is the most important horticultural crop in Takestan region, ranking top in producing raisins in Iran. Yearly, horticultural practices in order to reduce the severity of chilling damages to crops cost a lot under orchard conditions. Some of these practices are included burying vines under soil, winter ice-watering, flood irrigation, and turning the heaters on. Nowadays, cheap and fast alternative methods such as anti-freezes spraying havebeen considered to reduce the freeze injuries under orchards. These compounds as mechanical barriers either prevent the ice crystals formation on the sensitive plant tissues or activate the freezing tolerance mechanisms in the plants. Salicylic acid (SA), a type of phenolic acid, is one of the most secondary metabolites in the grape. SA not only plays an important role on the determination of the quality, color and taste of fruit, but also influences on the plant responses into environmental stresses such as drought, chilling, salinity and heavy metals. Natural osmolites such as soluble sugars, amino-acids and ammonium compounds are accumulated inside the plants under natural conditions. Commercial anti-freeze/anti-transpiration compounds on the basis of the mentioned natural osmolites are used to increase the freezing tolerance or postponing the bud break of horticultural crops. For example, Bio-bloom, Tiofer®, Cropaid® and Fosnutren® were used as anti-freeze compounds under almond, cherry, pistachio and apple orchards in Iran. The efficiency of this method to reduce the chilling injuries in vineyards is not well known. Therefore, to consider the effects of plant basis anti-freeze compounds on the freezing tolerance of red seedless grape under Takestan climate conditions, the current experimentation was conducted. In this regard, the important freezing tolerance determining osmolites as well as some of the qualitative and quantitative characters of vines in response to these compounds were evaluated.
Materials and Methods: In order to study the likely increase in grape spring freezing tolerance using the anti-freeze compounds under the orchard, an experiment was conducted as randomized completeblock design (RCBD) with anti-freeze compounds in Agriculture and Natural Resources Research Center of Qazvin during 2012-2013. Minimum monthly temperature during the autumn and winter months was -12.2 °C. The treatments including the spray of SA, Tiofer®, Cropaid®, Bio-Bloom® and water (control) were used on vines during fourphonological stages: before plant dormancy, during bud swelling, start of clustering and during the final clustering on the three red seedless vines per plot. Quantitative and qualitative characters such as cluster weight, yield and total soluble solids (TSS) were measured. Leaves osmolites contents such as proline (Bates et al.,1973) and glycin-betain (Grieve and Grattan.,1983) as well as the status of the freezing resistance index enzymes activities such as Glutathione peroxidase (GPX) (Updhyaya et al.,), Ascorbateperoxidase (APX) (Nakano and Asada,1981) and Catalase (CAT) (Aebi, 1984) were evaluated. All statistical analyses were made using SAS software. The comparison of mean values for the different treatments was made by ANOVA, followed by the Duncan’s test at the significant level of 0.05.
Results and Discussion: The results showed that the anti-freeze compounds resulted in an significant increase in the TSS, cluster weight and yield by 22%, 17% and 26%, respectively and the most effectswas observed in Bio-bloom. Our results regarding the effect of SA on the TSS was in accordance with other researchers (ShokrollahFaam, 2011; Sedighi et al., 2011; Champa et al., 2014;Marzouk and Kasm, 2011). However the effect of other anti-freeze compounds on the quantitative characteristics has not studied yet. Tiofer and Cropaid had no significant effect on the grape cluster weight. Proline content increased significantly using anti-freeze compounds compared to control during 2012-2013. But there was no significant difference between the different anti-freeze compounds for proline content. The most important content of betaine-glysine was observed in SA and Bio-bloom treatments. A decrease in air temperature during 2013 dormancy period resulted in higher amount of osmolytes contents (betaine glycine) and freezing resistance index enzymes activities compared to those of 2012. The most important contents of these enzymes activities were obtained in SA, Tiofer, Cropaid and Bio-Bloom treatments, respectively and the less important content was observed in control.
Conclusions: According to these results the commercial anti-freeze compounds could be useful not only for an increase in the grape spring freeze resistance but also for an improvement in the grape cluster weight, total soluble solids and yield. Osmolytes contents such as such as proline and betaine glycine and enzymes GPX, APX, CAT are significantly higher in anti-freeze treated plants compared to control. Since high levels of soluble solids, mentioned osmolytes and enzymes resulted in an increase in cold resistance in plant, the use of antifreeze as an easy and inexpensive way to increase the cold hardiness of grapes is recommended. These results were obtained with this antifreeze in 5 ppm concentration. Therefore more researches on the other varieties using different concentrations of anti-freeze compounds are recommended.

کلیدواژه‌ها [English]

  • Ascorbate peroxidase
  • Frost
  • Glycine-betaine
  • Proline
  • Red seedless
1- Aebi H. 1984. Catalase in vitro. Methods in Enzymology 105: 121–126.
2- Afshari H., Zahedi R., Parvaneh T., and Bagheri M. 2014. The effect of SA on the proline content, soluble solids and EC of two cultivar of apricot under frost stress. Agricultural Crop Management (16) 1: 127-138.
3- Agricultural Insurance Fund (2014). (In Persian with English abstract)
4-Aldesuquy H.S., Abbas M.A., Abo-Hamed S.A., and Elhakem A.H. 2013. Does glycine betaine and salicylic acid ameliorate the negative effect of drought on wheat by regulating osmotic adjustment through solutes accumulation? Journal of Stress Physiology & Biochemistry, 9 (3): 5-22.
5- Bamdadian A. and Kosari S. 2012. The importance of prevention the plants from frost during the winter months. Monthly cultivation and livestock industry, 154. (In Persian with English abstract)
6- Bates I.S., Waldern R.P., and Tear I.D. 1973. Rapid determination of free praline for water stress studies. Plant and Soil, 39: 205-207.
7- Cansev A., Gulen H., and Eris A. 2011. The Activities of Catalase and Ascorbate Peroxidase in Olive (Olea europaea L. cv. Gemlik) under Low Temperature Stress. Horticulture, Environment, and Biotechnology. 52 (2): 113-120.
8- Chamkha M., Cathala B., Cheynier V., and Douillard R. 2003. Phenolic composition of champagnes from Chardonnay and Pinot Noir vintages Journal of Agriculture and Food Chemistry. 51, 3179–3184.
9- Champa W.A., Gill M.I., Mahajan B.V.C., and Arora N.K. 2014. Preharvest salicylic acid treatments to improve quality and postharvest life of table grapes (Vitis vinifera L.) cv. Flame Seedless. Journal of Food and Science Technology. 52(6):3607-16.
10- Coughlan S., and Heber U. 1982. The role of glycine betaine in the protection of spinach thylakoids against freezing stress. Planta 156, 62-69.
11- Ecevit F.M. 2004. Bimas Team. Isparta / Türkiye, http: //www. bimastarim.com/dogal-bitki-antifrizi.html.
12- Eris A., Gulen E., Barut E., and Cansev A. 2007. Annual patterns of total soluble sugars and proteins related to cold hardiness in olive (Olea europaea L. cv. Gemlik). Journal of Horticultural Science and Biotechnology, 82:597-604.
13- Fischer C., and Holl W. 1991. Food reserves of scots pine (Pinus sylvestris L.) I. Seasonal changes in the carbohydrate and fat reserves of pine needles. Trees, 5: 187-195.
14- Grieve C.M., and Grattan R. 1983. Rapid assay for determination of water soluble quaternary-amino compounds. Plant and Soil 70: 303-307.
15- Haji vand S., Mohebi S. and Bakhshi Khanki Gh. 2015. The effects of amino acid and other anti-freeze compounds on the induction of resistance to cold in cherry. Proceedings of the second symposium on new issues in agriculture. Tehran. (In Persian with English abstract)
16- Haji vand S., Yazdipour F., and Bakhshi Khanki Gh. 2015. The effects of anti-freeze compounds on the induction of resistance to cold in pistachio var. ghazvin. Proceedings of the second symposium on new issues in agriculture. Tehran. (In Persian with English abstract)
17- Kang, H. M. and Saltiveit, M. E. 2002. Chilling tolerance of maize, cucumber and rice seedling (leaves and roots) and differentially affected by salicylic acid. Physiologia Plantarum, 115: 577-576.
18- Karami F., Siosemardeh A., Javadi T., and Vafaee Y. 2009. Evaluation of some physiological indices of cold resistance and fruiting characteristics in apricot cultivars. 6th Congress on Horticultural Sciences. Rasht, Gilan, Iran. (in Persian with English abstract)
19- Kazemi M. 2014. Effect of foliar application with salicylic acid and methyl jasmonate on growth, flowering, yield and fruit quality of tomato. Bulletin of Environment, Pharmacology and Life Sciences, 3 (2): 154-158.
20- Kosova K., Prasil I.T., Vitamvas P., Dobrev P., Motyka, V., and Flokova K. 2012. Complex phytohormone responses during the cold acclimation of two wheat cultivars differing in cold tolerance, winter Samanta and spring Sandra. Journal of Plant Physiology, 169, 567–576.
21- Mahmoudzade H., Faroughi D., and Imani A. 2012. The effect of some chemical compounds on the frost injury of apricot under West Azerbaijan conditions. Second National Conference on climate change and its impact on agriculture and the environment, Urmia, agricultural research center, West Azerbaijan. (In Persian with English abstract)
22- Mahmoudzadeh A. and Imani A. 2011. Effect of some of anti frost on morphology, anatomy and proline of selective almond cultivars flower buds. International Journal of Nuts and Related Sciences 2(3):35-40.
23- Mahmoudzadeh A., Imani A., and Masoumi H. 2011. Preliminary study of the reaction of some almond cultivars treated with anti-frost materials. Proceeding of 1th International Congress Applied Biology, Mashhad, Iran, 321-326. (In Persian with English abstract)
24- Mahmoudzadeh A., Imani A., and Piri H. 2013. Effects of some of nutritional materials on fruit set and its characteristics in apple. Journal of Basic and Applied Scientific Research, 3 (1): 281-285.
25- Marzouk H.A. and Kassem H.A. 2011. Improving yield, quality, and shelf life of Thompson seedless grapevine by preharvest foliar applications. Scientia Horticulturae, 130: 425–430.
26- Miura K. and Tad K. 2014. Regulation of water, salinity, and cold stress responses by salicylic acid. Frontiers in Plant Science, 5 (4) 1-12.
27- Nakano Y and Asada K. 1981. Hydrogen peroxide is scavenged by ascorbate-specific peroxidase in spinach choloroplast. Plant, Cell and Physiology, 22: 867-880.
28- Noreen S., and Ashraf M. 2010. Modulation of salt (NaCl)-induced effects on oil composition and fatty acid profile of sunflower (Helianthus annuus L.) by exogenous application of salicylic acid. Journal of Science of Food and Agriculture, 90, 2608:2616.
29- Popova L.P., Maslenkova L.T., Ivanova A. and Stoinova Z. 2012. Role of salicylic acid in alleviating heavy metal stress. Environmental Adaptations and Stress Tolerance of Plants in the Era of Climate Change, 447:466.
30- Safarpoor Taher MH. 2007. Half of the exploiters are covered by insurance. News Journal of Public Relations of Ministry of Jihad-e-Agriculture 87: 6-8. (In Persian with English abstract)
31- Scott I.M., Clarke S.M., Wood J.E., and Mur L.A. 2004. Salicylate accumulation inhibits growth at chilling temperature in Arabidopsis. Plant Physiology, 135, 1040:1049.
32- Senaratna T., Touchell D., Bunn E., and Dixon K. 2000. Acetyl salicylic acid (aspirin) and salicylic acid induce multiple stress tolerance in bean and tomato plants. Plant Growth Regulation. 30,157–161.
33- Sedighi A., Gholami M., Sarikhani H., and Ershadi A. 2011. The effect of GA and SA on the ripening time, anthocyanin and ethylene content of Sweet sherry var. Siah-e-Mashhad. Journal of Horticultural Sciences, FUM, Iran. 26 (2): 141-146. (In Persian with English abstract)
34- Shokrollah Fam S., Hajiloo J, Zare F. Taabatabaie J, and Naghshibandi Hasani R. 2011. The effect of cacl2 and SA on the quantitative characters and shelf life of plum var Ghatre Tala. Journal of Food Research 22 (1): 76-85. (In Persian with English abstract)
35- Statistics of chilling and hailstone injuries to horticulture products 2017. Executive committee on management of environmental stresses for horticultural products, Ministry of Jihad-e-Agriculture.
36- Taşgin E., Atici O., and Nalbantoğlu B. 2003. Effects of salicylic acid and cold on freezing tolerance in winter wheat leaves. Plant Growth Regulation 41(3): 231–236.
37- Task force for water scarcity, chilling and agriculture risks 2017. Office of risk and crisis management in agriculture. Ministry of Jihad-e-Agriculture. (In Persian with English abstract)
38- Updhyaya A., Sankhla D., Davis T.D., Sankhla N. and Smidth B.N. 1985. Effect of paclobutrazol on the activies of some enzymes of activated oxygen metabolism and lipid peroxidation in senescing soybean leaves. Plant Physiology 121: 453-461.
39- Valero D. 2010. The role of polyamines on fruit ripening and quality during storage: what is new. Acta Horticulture. 884, 199–205.
40- Verbruggen N., and Hermans C. 2008. Proline accumulation in plants: a review. Amino Acids, 35(4):753-9.
41- Wilson S 2001. Frost Management in Cool Climate Vineyards. Final report to grape and wine research and Development Corporation. University of Tasmania.
42- Wilson J.M. 1996. The Mechanism of chill and drought hardiness. New Physiologist, 97, 257-270.
43- Wan S.B., Tian L., Tian R., Pan Q.H., Zhan J.C., Wen P.F. 2009. Involvement of phospholipase D in the low temperature acclimation induced thermo tolerance in grape berry. Plant Physiology and Biochemistry. 47, 504–510.
CAPTCHA Image