نوع مقاله : مقالات پژوهشی

نویسندگان

دانشگاه صنعتی اصفهان

چکیده

از آن‌جایی که شوری یکی از مهم‌ترین تنش‌های غیر زیستی و عوامل محدود کننده رشد گیاهان در سرتاسر جهان می‌باشد لازم است که به دنبال راهکارهایی برای کاهش اثرات مخرب این تنش بر روی گیاهان باشیم. گوجه فرنگی یکی از پر مصرف‌ترین محصولات مزرعه‌ای و گلخانه‌ای می‌باشد که بسته به شرایط پرورش ممکن است با تنش شوری مواجه شود. سالیسیلیک اسید از جمله سیگنال‌های القا مقاومت در شرایط تنش می‌باشد. آزالئیک اسید ترکیبی آلی است که می‌تواند سبب افزایش تجمع سالیسیلیک اسید در گیاه شود. از این رو پژوهش حاضر به منظور بررسی خصوصیات رویشی و فتوسنتزی گیاه گوجه فرنگی در شرایط استفاده توام از آزالئیک اسید و آبیاری با آب شور به صورت فاکتوریل با فاکتورهای سطوح مختلف شوری (0، 100، 150 و 200 میلی‌مولار) و سطوح مختلف آزالئیک اسید (0، 8، 10 و 24 میلی‌گرم در لیتر) در قالب طرح کاملا تصادفی با 3 تکرار طرح ریزی شد. نتایج نشان داد با افزایش سطوح شوری اعمال شده کاهش توانایی تولید بیومس بوجود می‌آید. کاربرد آزالئیک اسید به ویژه در تیمار آزالئیک اسید 8 میلی گرم در لیتر با کمک به بهبود کارایی مصرف آب فتوسنتزی، هدایت روزنه‌ای و هدایت مزوفیلی تاثیر مثبتی را بر خصوصیات فتوسنتزی بر جای گذاشته است به طوری که در سطح شوری 100 میلی مولار و کاربرد آزالئیک اسید چهار میلی گرم در لیتر هدایت روزنه‌ای را تا 20 درصد نسبت به شاهد افزایش داد. در سطوح پایین شوری کاربرد آزالئیک اسید در بهبود شرایط فتوسنتزی موثر واقع شد اما زمانی که سطح شوری به بیش از 100 میلی‌مولار رسید شاخص‌های فتوسنتزی حتی با کاربرد آزالئیک اسید نیز به طور معنی‌داری کاهش یافت به طوری که با در سطوح شوری اعمال شده کاهش 15-10 درصدی را در سرعت فتوسنتز نسبت به حال شاهد مشاهده گردید. با کاربرد آزالئیک اسید تا حدودی تعادل اسمزی درون گیاه ایجاد شده است و به دنبال آن از غلظت پرولین این تیمارهای فاقد آزالئیک اسید کاسته شد. بطورکلی کاربرد آزالیئک اسید در شرایطی که شوری در محدود 100 میلی مولار باشد با حفظ تبادلات گازی در حد مطلوب و ایجاد تعادل اسمزی در کاهش اثرات مخرب تنش موثر واقع شده است.

کلیدواژه‌ها

عنوان مقاله [English]

Evaluating of Azealic Acid on Tomato Vegetative and Photosynthetic Parameters under Salinity Stress

نویسندگان [English]

  • Maryam Haghighi
  • Atena Sheibanirad

Isfahan University of Technology

چکیده [English]

Introduction: Soil salinity is a global problem that affects approx. 20 % of irrigated land and reduces crop yields significantly. Since, salinity is one of the most important abiotic stress and limiting factor for plant growth all around the world. It is necessary to find some way to ameliorate these damages. The physiological responses of a plant to salinity are often complex and multi-faceted, which makes experiments difficult to design and interpret. At basic level, the response of plants to salinity can be described in two main phases: the shoot ion-independent response occurs first, within minutes to days, and is thought to be related to Na+sensing and signaling. Tomato is one the most popular crop in open door and greenhouse cultivation which could face with salinity stresses. Salinity with inducing osmotic stress could have irreversible damages on plant growth and function. Three main salinity tolerance mechanisms have been proposed: on exclusion – the net exclusion of toxic ions from the shoot; tissue tolerance – the compartmentalization of toxic ions into specific tissues, cells and subcellular organelles; and shoot ion-independent tolerance – the maintenance of growth and water uptake independent of the extent of Na+ accumulation in the shoot. In order to face with stresses plant make some internal signals which cause producing different compound and inducing stress resistance. Salicylic acid is one these resistances induced agent. Azealic acid is an organic compound which could increase salicylic acid accumulation in plants.
Materials and Methods: So that, the present experiment was conducted to evaluate the effect of azealic acid and saline irrigation on tomato vegetative and photosynthetic parameters in factorial design based on CRD with three replications. The treatments were salinity level (0, 100, 150 and 200 mM) and azealic acid (0, 8, 10, and 24 mg l-1). The experiment was conducted in pot and in the greenhouse. Gradually in a week salinity treatments applied for plants after that each week once azelaic treatments also applied in each plant. Two weeks later each gas exchange parameters and all parameters needed fresh plant were measured and at the end all parameters with dry matter measured. The photosynthesis traits like transpiration, photosynthesis rate, mesophyll conductance, stomata conductance some stress indices like proline and antioxidant phenol were measured.
Results and Discussion: Results indicated that with increasing salinity level biomass production reduced. It seems that with azealic supplement especially in AZ2 treatment with improving photosynthetic water use efficiency, stomatal and mesophyll conductance has positive effect on photosynthesis. Under low salinity level azealic acid was an effective treatment in photosynthetic parameters although when salinity exceeds more than 100 mM photosynthetic parameters even with azealic acid application reduced. Azealic acid causes a kind of osmotic balance following that the proline content of these treatment reduced. In all salinity levels when azaleic acid applied the phenolic compound increased significantly and the highest was in AZ3. Azaleic acid reduced the Na concentration of leaves it causing the most tolerate reason against salinity when the azaleic acid applied. Although the photosynthetic rate increased with azaleic acid it is not because of chlorophyll content, because the chlorophyll content decreased with azaleic acid. The increase of photosynthesis could be due to decreasing Na concentration of leaves and increasing defense system of plants. Chlorophyll florescence decreased even with azaleic acid in salinity, it means that azaleic acid cannot completely compensate the stress harmful effect. The growth was improved with azaleic acid in salinity; the improvement was greater in root weight compare with shoot weight. Azaleic acid not only prevent decreasing the weight but also improved them in salinity. In defense system of tomato it seems that antioxidant and phenol content were more effective than proline because they are increased with azaleic acid in saline condition effectively compare with proline.
Conclusions: Finally, it seems that until 100mM salinity level azealic acid with maintaining gas exchange capacity in optimum level and inducing osmotic balance could reduce salinity damages. Conclusively, when azaleic acid was applied in 8mg/l that it improved photosynthetic traits like stomata conductance, mesophyll conductance, and photosynthetic water use efficiency compare with control. Azaleic acid can improve the photosynthetic traits when salinity was in low level like 100mM. Proline which is amino acid role as a defense system of plants increased the osmotic adjustment in plant in response to azaleic acid

کلیدواژه‌ها [English]

  • Azealic acid
  • Organic Acid
  • salicylic acid
  • Saline water
1- Arfan M., Athar H.R. and Ashraf M. 2007. Does exogenous application of salicylic acid through the rooting medium modulate growth and photosynthetic capacity in two differently adapted spring wheat cultivars under salt stress?, Plant Physiology, 164:685–94.
2- Haghighi M., Sheibanirad A. and Pessarakli M. 2015. Plant Responses under Environmental Stress Conditions, Advances in Plants & Agriculture Research, Advances in Plants and Agriculture Research, 2(6):1-12.
3- Haghighi M. and Pessarakli M. 2013. Influence of silicon and nano-silicon on salinity tolerance of cherry tomatoes (Solanum lycopersicum L.) at early growth stage, Scientia Horticulturae, 161: 111–117.
4- Halim V.A., Vess A., Scheel D. and Rosahl S. 2006. The role of salicylic acid and jasmonic acid in pathogen defence, Plant Biology, 8(3):307–13.
5- Howladar S.M. 2014. A novel Moringa oleifera leaf extract can mitigate the stress effects of salinity and cadmium in bean (Phaseolus vulgaris L.), Ecotoxicology and Environmental Safety, 100: 69–75.
6- Kafi M., Borzooei A., Salehi M., Kamandi A., Masumi A. and Nabati J. 2012. Environmental stress in plant physiology, Publications University of Mashhad. ( In Persian).
7- Kafi M. and Rahimi Z. 2011. Effect of salinity and silicon on root characteristics, growth, water status, proline content and ion accumulation of purslane (Portulaca oleracea L.), Soil Science and Plant Nutrition, 57: 341–347.
8- Kahrizi S., Sedghi M. and Sofalian O. 2012. Effect of salt stress on proline and activity of antioxidant enzymes intend rum wheat cultivars, Annal of Bioloical Research, 3: 3870–3874.
9- Misra N. and Saxena P. 2009. Effect of salicylic acid on proline metabolism in lentil grown under salinity stress, Plant Science, 177: 181–189.
10- Miteva E., Hristova A.D., Nenova B.V. and Maneva S. 2005. Arsenic as a factor affecting virus infection in tomato plants: changes in plant growth, peroxidase activity and chloroplast pigments, Horticultural science, 105: 343–58.
11- Munns R. 2002. Comparative physiology of salt and water stress, Plant, Cell & Environment, 20: 239–250.
12- Nakashima K., Ito Y. and Yamaguchi-Shinozaki K. 2009. transcriptional regulatory networks in response to abiotic stresses in arabidopsis and grasses, Plant Physiology, 149: 88-95.
13- Shannon M.C. 1998. Adaptation of plants to salinity, Advances in Agronomy, 60: 75–119.
14- Parida A.K. and Das A.B. 2005. Salt tolerance and salinity effects on plants, Ecotoxicology and Environmental Safety, 60: 324–349.
15- Puniran-Hartley N., Hartley J., Shabala L. and Shabala S. 2014. Salinity-induced accumulation of organic osmolytes in barley and wheat leaves correlates with increased oxidative stress tolerance: In planta evidence for cross-tolerance, Plant Physiology and Biochemistry, 83:32-39.
16- Rady M.M. 2011. Effect of 24-epibrassinolide on growth, yield, antioxidant system and cadmium content of bean (Phaseolus vulgaris L.) plants under salinity and cadmium stress, Scientia Horticulturae, 129: 232–237.
17- Uta V.R., Martin J. and Mueller J.D. 2005. Evaluation of natural and synthetic stimulants of plant immunity by microarray technology, New Phytologist, 165:191–202.
18- Yurtseven E., Kesme G.D. and Ünlükara. F.A. 2005. The effects of water salinity and potassium levels on yield, fruit quality and water consumption of a native central Anatolian tomato species (Lycopersicon esculentum), Agricultural Water Management, 78: 128–135.
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