میزان تحمل انگور رقم عسکری به آسیب ناشی از نسل گل‌خوار کرم خوشه‌خوار، Lobesia botrana، با شبیه‌سازی میزان خسارت

نوع مقاله : مقاله پژوهشی

نویسندگان

گروه گیاهپزشکی، دانشکده کشاورزی، دانشگاه یاسوج، یاسوج، ایران

چکیده

شهرستان دنا، یکی از مناطق مهم تولید انگور در جنوب کشور می‌باشد. رقم غالب در این شهرستان، رقم عسکری و خوشه‌خوار انگور، Lobesia botrana (Denis & Schiffermüller, 1775)، مهم‌ترین آفت آن می‌باشد. جمعیت آفت در نسل اول بسیار بالا بوده و به گل‌ها آسیب می‌رساند. برای ارزیابی تحمل این رقم به خسارت نسل اول آفت، یک آزمایش شبیه‌سازی میزان خسارت طراحی و طی دو سال پیاپی انجام گرفت. در مرحله اول، میانگین‌ تعداد خوشه در درخت و گل در خوشه در هر سال به طور دقیق محاسبه شد. با داشتن این داده‌ها، آزمایش‌ها با هفت تیمار (0، 5، 10، 15، 20، 25 و 30 درصد حذف گل‌ بر مبنای میانگین تعداد گل در خوشه در آن سال) و چهار تکرار (هر درخت به عنوان یک تکرار) انجام پذیرفت. هنگام برداشت، محصول درختان تیمار شده به تفکیک، توزین و داده‌های به دست آمده برای هرسال به‌صورت جداگانه و برای دو سال تجزیه مرکب شدند. نتایج نشان داد رقم عسکری در منطقه از تحمل خوبی برخوردار بوده و توانست آسیب اعمال‌شده را بدون مشاهده کاهش عملکرد، به‌صورت کامل جبران کند. توانایی جبران خسارت با کاهش میزان ریزش طبیعی گل‌ها و افزایش وزن حبه‌ها حاصل می‌شود. با توجه به نتایج به‌دست آمده، تا 30 درصد آسیب به گل‌ها در رقم عسکری در منطقه دنا، نه تنها نیازی به مبارزه با نسل اول آفت نمی‌باشد، بلکه فعالیت آفت با تنک کردن گل‌ها، افزایش کیفی محصول را نیز به همراه دارد. با وجود این، لازم است سطوح بالاتر حذف گل بررسی و سپس، نسبت به آستانه خسارت نسل اول آفت در منطقه تصمیم‌گیری شود.

کلیدواژه‌ها

عنوان مقاله [English]

Tolerance of grapevine askari cultivar to injury caused by Lobesia botrana anthophagous generation using damage simulation

نویسندگان [English]

  • H. Mohammadi
  • S. Kazemzadeh Mansourabad
  • N. Sisakhti
Division of Plant Protection, Faculty of Agriculture, Yasouj University, Yasouj, Iran
چکیده [English]

Dena County is one of the most important grape-growing area in the southwest of Iran. The dominant cultivar in this area is Askari and grapevine moth, Lobesia botrana (Denis & Schiffermüller, 1775), is major pest on this cultivar. The first generation of this pest has a high population and seriously damages the flowers. To investigate this cultivar’s tolerance to first generation injuries on flowers, a damage simulation experiment designed and carried out for two consecutive years. In the first step, the average number of bunch/tree and flower/bunch for each year calculated, accurately. Having these data, the experiments performed with seven treatments (removal of 0, 5, 10, 15, 20, 25, and 30 percent of flowers based on the calculated average number of flowers/bunch in each year) and four replications (each tree considered as one replication). At vintage time, harvested grape product weighed separately and analyzed for simple and combined analyses of variance. The results showed that Askari cultivar in Dena region had a good tolerance and could compensate completely for anthophagus generation damage to the blossoms so that no yield loss observed in the treatments. The ability to compensate for damage is achieved by reducing the natural shedding of flowers and increasing the berry’s weight. According to the obtained results, up to 30% removal of flowers on Askari cultivar in Dena region, there is no need for controlling the first generation, thinning the flowers also increases the quality of berry. However, it is necessary to study the higher levels of flower removal and then make a final decision about the damage threshold of first generation in the region.

کلیدواژه‌ها [English]

  • Carpophagus generation
  • Damage compensation
  • Dena County
  • Resistance

مراجع

Agricultural Jihad Organization. 2016. Horticultural product report of Kohkiluyeh and Boyer-Ahmad in year 1395. Statistics and information technology of Kohkiluyeh and Boyer-Ahmad Agricultural Jihad Organization (In Farsi).
Aguiar, A., Aubyn, S. and Mexia, A. 2008. Decision making on the control of the European grape berry moth Lobesia botrana in the ‘vinhos verdes’ region, in the northwest of Portugal. International Congress Mountain Steep Slope Viticulture 2 March 2008, Galicia. Retrieved February 10, 2022. From https://www.repository.utl.pt/handle/10400.5/1054?locale=en.
Ahmadi, K., Ebadzadeh, H., Hatami, F., Mohammadnia Afrozi, S., Abbas Taghani, R., Yari, S. and Kalantari, M. 2021. Horticultural product report of year 1399. Iran Ministry of Agriculture, Deputy of Economy and Planning, Information and Communication Technology Center (In Farsi).
Buntin, G. D. 2000. Techniques for evaluating yield loss from insects. In Peterson, R. K. D., and Higley, L. G., (Eds.). Biotic stress and yield loss. (1st Eds.) CRC Press, USA. pp. 23-42.
Chan, K. Y., Fahey, D. J., Newell, M. and Barchia, I. 2010. Using composted mulch in vineyards-effects on grape yield and quality. International Journal of Fruit Science 10: 441-453.
Dhaliwal G. S. and Arora R. 2006. Integrated pest management, concepts and approaches. Kalyani publishers. 2nd edition. 369 pp.
Doulati Baneh, H., Nazemia, A., Mohammadi, S. A., Hassani, Gh. and Hanareh, M. 2010. Identification and evaluation of west Azarbaijan grape cultivars by ampelography and ampelometery. Plant Production Technology 2(1): 13-24 (In Farsi).
Gilligan, T. M., Epstein, M. E., Passoa, S. C., Powell, J. A., Sage, O. C. and Brown J. W. 2011. Discovery of Lobesia botrana (Denis & Schiffermuller) In California: An invasive species new to North America (Lepidoptera: Tortricidae). Proceedings of the Entomological Society of Washington 113(1), 14–30.
Gutierrez, A. P., Ponti, L., Gilioli, G. and Baumgärtner, J. 2018. Climate warming effects on grape and grapevine moth (Lobesia botrana) in the Palearctic region. Agricultural and Forest Entomology 20: 255–271.
Heit, G., Sione, W. and Cortese, P. 2015. Three years analysis of Lobesia botrana (Lepidoptera: Tortricidae) flight activity in a quarantined area. Journal of Crop Protection 4: 605-615.
Ioriati C., Anfora, G., Tasin, M., De Cristofaro, A., Witzgall, P. and Lucchi, A. 2011. Chemical ecology and management of Lobesia botrana. Journal of Economic Entomology 104(4): 1125-1137.
Karami, E., Mohammadi, H. and Haghani, M. 2017. Determination of generation numbers and adult Population fluctuation of Lobesia botrana (Lep.: Tortricidae) using pheromone trap in Sisakht, Kohgiluyeh and Boyer-Ahmad province. Journal of Plant Protection 35(1): 52-60. (In Farsi)
Kavousi, B., Saeedi, K. and Hasanpour, B. 2020. Principles and role of green pruning in vineyard management. Grapevine Extension Journal 2 (1): 1-6. (In Farsi)
Krasniqi, A. L., Blanke, M. M., Kunz, A., Damerow, L., Lakso, A. N. and Meland, M. 2017. Alternate bearing in fruit tree crops: past, present and future. Acta Horticulturae 1177: 241-248.
Lucchi, A., Scaramozzino, P. L., Michl, G., Loni, A. and Hoffmann, C. 2016. The first record in Italy of Trichogramma cordubense (Vargas & Cabello, 1985) emerging from the eggs of Lobesia botrana. Vitis 55: 161–164.
Maher, N. and Thiéry, D. 2003. Bunch extracts of Vitis vinifera at different development stages stimulate or deter oviposition in Lobesia botrana females. IOBC/WPRS Bulletin 26: 135-139.
Mitchell, C., Brennan, R. M., Graham, J. and Karley, A. J. 2016. Plant defense against herbivorous pests: exploiting resistance and tolerance traits for sustainable crop protection. Frontiers in Plant Science 7:1132.
Moreau, J., Villemant, C., Benrey, B. and Thiery D. 2010. Species diversity of larval parasitoids of the European grapevine moth (Lobesia botrana, Lep.: Tortricidae): The influence of region and cultivar. Biological Control 54: 300–306.
Moschos, T. 2005. Yield loss quantification and assessment of economic injury level for the anthophagous generation of the European grapevine moth, Lobesia botrana, (Lep.: Tortricidae). International Journal of Pest Management 51: 81–89.
Moschos, T. 2006. Yield loss quantification and economic injury level estimation for the carpophagous generations of the European grapevine moth, Lobesia botrana, (Lep.: Tortricidae). International Journal of Pest Management 52: 141–147.
Nejatian, M. and Rasouli, V. 2017. Pruning of green grapes. Qazvin agricultural and Natural resources research and training center, Agricultural Education Publishing, 20 pages. Retrieved February 10, 2022. From https://agrilib.areeo.ac.ir/book_3248.pdf (In Farsi).
OIV - International organization. 2017. Focus OIV 2017, Distribution of the world’s grapevine varieties. OIV - International organization of vine and wine. 1-54. Retrieved June 18, 2022. From http://www.oiv.int/public/medias/5888/en-distribution-of-the-worlds-grapevine-varieties.pdf.
Pavan, F., Stefanelli, G., Cargnus, E. and Villani, A. 2009. Assessing the influence of inflorescence traits on the susceptibility of grape to vine moths. Journal of Applied Entomology 133: 394–401.
Pelsy, F. 2010. Molecular and cellular mechanisms of diversity within grapevine varieties. Heredity 104: 331–340.
Peterson, R., Varella, A. and Higley, L. 2017. Tolerance: the forgotten child of plant resistance. PeerJ 5:e3934.
Quentin, A. G., Pinkard E. A., Beadle C. L., Wardlaw T. J., O’Grady A. P., Paterson S. and Mohammed, C. L. 2010. Do artificial and natural defoliation have similar effects on physiology of Eucalyptus globulus Labill. seedlings? Annals of Forest Science 67: 203.
Reji, G., Chander, S. and Aggarwal, P. K. 2008. Simulating rice stem borer, Scirpophaga incertulas Wlk., damage for developing decision support tools. Crop Protection 27(8): 1194-1199.
Roubos, C. R., Mason, K. S., Teixeira, L. A. F. and Isaacs, R. 2013. Yield-based economic thresholds for grape berry moth (Lepidoptera: Tortricidae) in juice grapes. Journal of Economic Entomology 106(2): 905-911.
Sciarretta A., Zinni A. and Trematerra P. 2011. Development of site-specific IPM against European grapevine moth Lobesia botrana in vineyards. Crop Protection 30: 1469-1477.
Sharon, R., Zahavi, T., Soroker, V. and Harari, A. R. 2009. The effect of grape vine cultivars on Lobesia botrana (Lepidoptera: Tortricidae) population levels. Journal of Pest Science 82: 187–193.
Simonella, M. A., Royo, O. M., Contreras, G. B., Mazza, S. and Montenegro, A. 2003. Simulation of damage caused by the Heliothis-Helicoverpa-Spodoptera spp. complex to cotton plant (Gossypium hirsutum L.) shoots. World Cotton Research Conference-3, Cape Town - South Africa, 1376-1382.
Smith C. 2005. Plant resistance to arthropods: molecular and conventional approaches. New York: Springer.
Thiery, D. and Moreau, J. 2005. Relative performance of European grapevine moth (Lobesia botrana) on grapes and other hosts. Oecologia 143: 548-557.
Thomas, G. D. 2022. Damage simulations as an approach to understanding economic losses to insects. Proceedings of World Soybean Research Conference III: (pp. 617-623). February. CRC Press.
Vassiliou, V. A. 2011. Effectiveness of insecticides in controlling the first and second generations of the lobesia botrana (lepidoptera: tortricidae) in table grapes. Journal of Economic Entomology 104(2): 580-585. 
Waterman, J., Cazzonelli, C., Hartley S. and Johnson, S. 2019. Simulated herbivory: The key to disentangling plant defence responses. Trends in Ecology and Evolution 34(5): 447-458.
Wilson, L., Sadras, V., Heimoana, S. and Gibb, D. 2003. How to succeed by doing nothing; Cotton compensation after simulated early season pest damage. Crop Science 43(6): 2125-2134.
تحقیقات آفات گیاهی
دوره 12، شماره 3
آذر 1401
صفحه 1-12

فایل ها

سابقه مقاله

  • تاریخ دریافت: 19 آذر 1401
  • تاریخ پذیرش: 19 آذر 1401

هم رسانی

ارجاع به این مقاله

آمار