مقدار عناصر غذایی پر مصرف و کم مصرف در دمبرگ چند رقم انگور ایرانی و خارجی

دولتی بانه, حامد; طاهری, مهدی; مجیدی, عزیز; طاهری, محسن

doi:10.22067/jhorts4.v0i0.28029

مقدار عناصر غذایی پر مصرف و کم مصرف در دمبرگ چند رقم انگور ایرانی و خارجی

نوع مقاله : مقالات پژوهشی

نویسندگان

¹ مرکز تحقیقات کشاورزی ارومیه

² مرکز تحقیقات کشاورزی زنجان

³ مرکزتحقیقات کشاورزی ارومیه

⁴ مدیریت جهاد کشاورزی تکاب

10.22067/jhorts4.v0i0.28029

چکیده

به منظور ارزیابی و مقایسه غلظت تعدادی از عناصر کم مصرف (بور، روی، منگنز، آهن و مس) و عناصر پر مصرف (نیتروژن، فسفر، پتاسیم،منیزیوم وکلسیم) در دمبرگ چند رقم تجارتی انگور ایرانی شامل بیدانه سفید قزوین، پیکانی کاشمر، خلیلی شیراز، رشه و ارقام خارجی تامسون سیدلس، فلیم سیدلس، پرلت و بلک سیدلس این تحقیق در قالب طرح بلوک‎های کامل تصادفی در سه تکرار در ایستگاه تحقیقات باغبانی کهریز ارومیه اجرا گردید. نتایج تجزیه واریانس نشان داد که بین ارقام مورد بررسی تفاوت معنی‌داری در غلظت اغلب عناصر جذب شده در دمبرگ وجود داشت. در بین هشت رقم مورد مطالعه بیشترین مقدار نیتروژن در دمبرگ‎های رقم فلیم سیدلس و کمترین مقدار در ارقام پیکانی کاشمر و رشه وجود داشت. از لحاظ جذب پتاسیم رقم بیدانه قزوین در رتبه اول و رقم پیکانی کاشمر و پرلت در رتبه آخر قرار گرفتند. کمترین مقدار منیزیم برگ‎ در رقم بیدانه قزوین و بیشترین آن در رقم پیکانی کاشمر اندازه‎گیری گردید. مقدار بور در اغلب ارقام در حد مسمومیت بود اما رقم رشه کمترین مقدار این عنصر را در بافت دمبرگ‎ها داشت. از لحاظ جذب روی ارقام ایرانی توانایی کمتری نسبت به ارقام خارجی داشتند به طوری‌که بیشترین و کمترین غلظت روی به ترتیب در ارقام تامسون سیدلس و پیکانی کاشمر اندازه‌گیری شد.

کلیدواژه‌ها

20.1001.1.20084730.1394.29.3.9.1

عنوان مقاله [English]

Amount of Macronutrients and Micronutrients in Petiole of Some Iranian and Imported Grape Cultivars

نویسندگان [English]

H. Doulati Baneh ¹
M. Taheri ²
A. Majidi ³
M. Taheri ⁴

¹ West Azarbaijan Agriculture and Natural Resources Research Center, AREEO, Urmia

² Zanjan Agriculture and Natural Resources Research Center, AREEO, Zanjan

³ West Azarbaijan Agriculture and Natural Resources Research Center, AREEO, Urmia

⁴ Jehade Agriculture Management Tekab

چکیده [English]

Introduction: Grapevine (Vitis vinifera L.) is one of the oldest and most important perennial crops in the world. Several native grapevine genotypes, highly appreciated for their organoleptic characteristics and commercial potential are still cultivated in Iran. Developing viticulture requires the conservation of autochthonous varieties that have evolved several mechanisms enabling them to cope with the local bioclimatic and edaphic conditions. Nutrition is a key component of vineyard management that has the potential to influence various factors in vine production that includes fruit set and quality. To develop suitable nutrient plant growers need to have an understanding of the factors such as cultivars, rootstocks, soil type, irrigation type and nutrients that they are applying in the vineyard. The uptake of nutrients from the soil depends on different factors namely; their soluble content in it, soil pH, plant growth stage, plant genetics and types of soil and fertilizers. Plant species have a variety of capacities in removing and accumulating elements. Vigorous genotypes are more capable of finding the necessary nutrients from the surrounding soil environment. This indicates that it does not require as much nutrient as poor vigor genotypes. So, for sustainable viticulture, it is important to know the interactive influences of cultivars, soil characters, climatic conditions, and irrigation type on vine productivity.
Materials and Methods: To evaluate and compare the amount of macronutrient elements (N, P, K, Mg and Ca) and micronutrient elements (B, Zn and Mn) in petiole of some Iranian grapevine cultivars including Bidanesefid Qazvin- Peikany Kashmar- Khalili Shiraz-Rasha and four foreign cultivars Thompson seedless, Flame seedless, Perlette and Black seedless,This study was carried out as –randomized complete blocks design -with-four replications in the Kahriz Horticulture Research station -.A total of 30 adult leaves per cultivar were taken from lower, middle and upper regions of the vines bulked together and transported directly to the laboratory. They were oven-dried for 48 h at 70 °C and grounded to pass through a 1 mm diameter sieve. The concentrations of the -mineral elements were determined using an atomic absorption and spectrophotometer.
Results and Discussion: The results showed there was significant difference among study cultivars in respect of elements concentration in petiole-. Among 8 cultivars, the highest and the lowest petiole N concentration were recorded in Flame seedless-and Peikany and Rasha cultivars respectively. P -concentration in Bidane sefid Qazvin was significantly higher than all tested cultivars. The highest and the lowest Mg amounts were measured in Peikany and Bidanesefid Qazvin, respectively. In petiole of cultivars B concentration was in the range of toxicity except Rasha that had the concentration less than -other cultivars. Iranian cultivars had lesscap ability to absorb Zn than abroad cultivars. The highest and lowest Zn were recorded in petioles of Thompson seedless and Peikany cultivars, respectively. It was reported that the mineral content of a grapevine is a combined result of the root systems ability to absorb, trans locate and accumulate the different nutrients. Previous investigations had clearly stated the differences in nutrients uptake and content of many grape cultivars. Furthermore, grape cultivars have shown differences in their nutrients uptake and distribution. These differences may be explained in different ways. First, cultivar may have different absorption capability or tendency for some specific minerals. Second, differences exist in translocation and distribution of nutrients and third, hormone synthesis of cultivar roots and their translocation is done. Finally, some nutrients might be assimilated mostly by roots; thus reducing the amount translocated to the shoots. In addition, some grape varieties may alter soil chemical characters and play a role in improving nutrients uptake. The rootstocks of V. labruscaand scions grafted on them achieve a higher ability in uptaking iron, even in markedly alkaline soils. Such tolerant varieties can mobilize iron by reducing soil pH at root level, thanks to their ability to emit H+ and/or organic acids.In the latter case, iron is absorbed and transferred as a complex. Roots of some cultivars can also reduce Fe3+ to Fe2 + encouraging its migration from roots to leaves.
Conclusion: The studied grapevine cultivars displayed a considerable level of variability based on mineral content analysis. The results suggested that significant differences existed in the leaf petioles elemental concentrations among the grapevine cultivars analysis that might be in due part to the ability of the cultivar to accumulate metals. This study could be also used as a reference for grape growers to help them decide the best varieties that might grow under their soil conditions giving the best growth and yield productivity.

کلیدواژه‌ها [English]

Iron
Boron
Potassium
Leaf
Toxicity

مراجع

Agev N. A. 1985. Effects of boron on grapevines yield and quality. Horticultural Abstracts, No. 54. 2

2- Al-Obeed R.S., kassem H.A and Ahmed M.A. 2011. Leaf petiole mineral and fruit heavy metals content of different grape cultivars grown under arid environments and irrigated with treated domestic waste water. AAB Bioflux, 3(1): 5-14.

3- Antonio Ibacache G and Carlos Sierra B. 2009. Influence of rootstock on nitrogen, phosphorus and potassium content in petioles of four table grape varieties. Chilean Journal of Agricultural Research, 69(4):503-508.

4- Bavaresco L., Fregoni M. and Frachini P. 1991.Investigations on iron uptake and reduction by excised roots of different grapevine rootstocks and a V .vinifera cultivar. Journal of Plant Soil, 130: 109-113.

5- Bavaresco L., Lovisolo C. 2000. Effect of grafting on grapevine chlorosis and hydraulic conductivity. Vitis, 39:89-92.

6- Cinelli F. 1995. Physiological responses of clonal quince root-stocks to iron-deficiency induced by addition of bicarbonate to nutrient solution. Journal of Plant Nutrition, 18:77-89.

7- Doulati H and Taheri M. 2009. Effects of foliar application of nutrient elements on fruit set and quantitative and qualitative traits of Keshmeshi grape cultivar. Seed and Plant Production Journal. 25-2 (1): 103-115.(In Persian)

8- Emami A. 1997. Plant Analysis Methods. Agricultural Research, Education and Extension Organization Publication, Iran. 128 pp. (in Persian).

9- Fisarakis J., Nikolaou N., Tsikalas P., Therios I and Stavrakas D. 2004. Effect of salinity and rootstock on concentration of potassium, calcium, magnesium, phosphorus, and nitrate-nitrogen in Thompson Seedless grapevine. Journal of Plant Nutrition, 27:2117-2134.

10- Ghaffari S. and Ferchichi A. 2011. Characterization of Tunisian grapevine (Vitis vinifera L.) cultivars using leaves morphological traits and mineral composition. Romanian Biotechnological Letters, 16(5): 6556-6563.

11- Keller M., Kummer M and Vasconcelos M.C. 2001. Reproductive growth of grapevines in response to nitrogen supply and rootstock. Australian Journal of Grape and Wine Research, 7: 12-18.

12- Montazeri A., Jalili Marandi R., Doulati Baneh H and Ghani Shaieste F. 2011. Response of three different grape cultivar to iron chelate application in alkaline soil. 12th Iranian soil science congress. Tabriz, Iran. 1-4. (In Persian)

13- Nikolaou N., Koukourikou M.A. and Karagiannidis N.2000. Effects of various rootstocks on xylem exudates cytokinin content, nutrient uptake and growth patterns of grapevine Vitis vinifera L. cv. Thompson Seedless. Agronomie, 20: 363-373.

14- Papric Dj and Kuljancic I. 1994. Influence of grapevine cultivar on adsorption of mineral elements in vineyard. Savremena poljoprivreda, 42(3):11-16.

15- Paranychianakis V. N., Chartzoulakis K. S., Angelakis A. N. 2004. Influence of rootstock, irrigation level and recycled water on water relations and leaf gas exchange of Soultanina grapevines. Environmental and Experimental Botany, 52(2):185-198.

16- Pe´rez-Castro R., Kasai K., Gainza-Corte´s F., Ruiz-Lara S., Casaretto J.A., Pen˜a-Corte´s H., Tapia J., Fujiwara T and Gonza´lez E. 2012. VvBOR1, the grapevine ortholog of AtBOR1, encodes an efflux boron transporter that is differentially expressed throughout reproductive development of Vitis vinifera L. Plant Cell Physiology, 53(2): 485–494

17- Provenzano M.R., El Bilali H., Simeone V., Baser N., Mondelli D and Cesari G. 2010. Copper contents in grapes and wines from a Mediterranean organic vineyard. Food Chemistry, 122: 1338–1343.

18- Ruhl E. H. 2000. Effect of rootstocks and K+ supply on pH and acidity of grape juice. Acta Horticulturea, 512:31-37.

19- Singh SH. 2006. Grapevine Nutrition Literature Review. Cooperative Research Centre for Viticulture (CRCV), Pp. 50.

20- Taheri M., Doulati Baneh J and Malakouti M.J. 2003. Nutrient level of grapes in West Azarbaijan vineyards in Iran. Proceedings of the first national symposium on dried fruit/nut. Tabriz, Iran. 411-422.

21- Vercesi A. 1987. Gli assorbimenti radicali della vite: meccanismi e fattori influenti. Vignevini, 4:47-55.

22- Wolpert J. A., Smart D. R and Anderson M. 2005. Lower petiole potassium concentration at bloom in rootstocks with Vitis berlandieri genetic backgrounds. American Journal of Enology and Viticulture, 2:163-169.