تأثیر دما و شوری بر ویژگی‌های جوانه‌زنی بذر دو اکوتیپ سس‌درختی (Cuscuta monogyna Vahl.)

نوع مقاله : مقالات پژوهشی

نویسندگان

1 دانشکده کشاورزی دانشگاه فردوسی مشهد

2 فردوسی

3 دانشکده کشاورزی

4 دانشکده کشاورزی، دانشگاه فردوسی مشهد

چکیده

سس­درختی از مهمترین گونه­های سس است که انگل درختان میوه و درختچه­های زینتی است. به منظور مطالعه تأثیر شوری و دما بر ویژگی­های جوانه­زنی دو اکوتیپ سس درختی آزمایشی به صورت فاکتوریل در قالب طرح کاملاً تصادفی با سه تکرار در سال 1394-95 در دانشکده کشاورزی دانشگاه فردوسی مشهد اجرا گردید. تیمارهای مورد بررسی شامل شوری در 8 سطح صفر (شاهد)، 0/1-، 0/2-، 0/4-، 0/6-، 0/8-، 1- و 1/2- مگاپاسکال و دما هم در 8 سطح 5، 10، 15، 20، 25، 30، 35 و 40 درجه سانتی­گراد بودند. نتایج نشان داد که با افزایش شوری در هر سطح دمایی درصد و سرعت جوانه­رنی در هر دو اکوتیپ کاهش یافت به طوری‌که در پتانسیل 1/2- مگاپاسکال جوانه­زنی هر دو اکوتیپ متوقف شد. در هر دو اکوتیپ در دماهای 5 ،10 و 40 درجه سانتی‌گراد در تمام سطوح مختلف شوری جوانه­زنی متوقف شد. بیشترین درصد و سرعت جوانه­زنی هر دو اکوتیپ در تیمار شوری شاهد و در دماهای 25 و 30 درجه به دست آمد. با توجه به نتایج به دست آمده جوانه­زنی اکوتیپ بردسکن هم در دماهای بالا و هم در سطوح بالای شوری نسبت به اکوتیپ قوچان برتری داشت. با توجه به نتایج آزمایش، شوری موثر برای 50 درصد کاهش جوانه­زنی در اکوتیپ قوچان در دماهای 15، 20، 25، 30 و 35 درجه سانتی­گراد به ترتیب 0/79-، 0/86-، 0/87-، 0/77- و 0/68- مگاپاسکال و در اکوتیپ بردسکن 0/93-، 0/93-، 0/95-، 0/90- و 75 /0- مگاپاسکال برآورد شد. اطلاعات این مطالعه برای پیش­بینی پتانسیل این گونه علف­هرز برای انتشار به مناطق جدید و برای بهبود برنامه­های مدیریتی این گونه علف­هرز انگلی مفید خواهد بود.

کلیدواژه‌ها

موضوعات

عنوان مقاله [English]

Effect of Temperature and Salinity on Two Eastern Dodder (Cuscuta monogyna Vahl) Ecotypes Seed Germination Characteristics

نویسندگان [English]

  • E. Ebrahimi 1
  • ebrahim izadi 2
  • Mohammad hasan rashed 3
  • R. tavakolafshari 4
1 Faculty of Agriculture, Department of Agrotechnology, Ferdowsi University of Mashhad, Mashhad, Iran
4 Faculty of Agriculture, Ferdowsi University of Mashhad, Mashhad, Iran
چکیده [English]

Introduction: Knowledge of weed biology helps to optimize weed management strategies and avoid unnecessary weed control input by for example accurate prediction of emergence timing of the weeds. According to the available references, 200 species of dodder have been reported in the world of which 18 species are in Iran. Among the 18 reported species in Iran, Cuscuta campestris and Cuscuta monogyna cause the greatest damage to crops and horticultural products in Iran. Cuscuta monogyna (Vahl), a member of the Cuscutaceae family, is a non-specific aboveground holoparasite, and as such is totally dependent on its host plant for assimilates, nutrients and water supply. Eastern dodder is one of the important dodder species that parasite fruit trees and ornamental shrubs. Each eastern dodder plant produces greater than 3000 seeds of which low percentage germinate in the first year. In the field, dodder started to germinate in March or April when daily average soil temperatures reached 10°C, and maximum germination was observed in May or June when daily average soil temperatures reached 20°C. After germination, seedlings of Cuscuta spp. Undergo a non-parasitic phase of growth, dependent on seed reserves, for 2–3 weeks. To improve management systems for specific weed species, it is critical to have good information on seed dormancy, persistence, production, seasonal germination, seedling emergence, and variations among populations. The objective of the present study was to effect of temperature and salinity on two eastern dodder (Cuscuta monogyna Vahl) ecotypes seed germination characteristics.
Materials and Methods: In order to study the effect of salinity and temperatures on seed germination chrachteristics of two eastern dodder ecotypes experiments were conducted based on factorial in a completely randomized design with three replications in the Research Laboratory of Ferdowsi University of Mashhad Faculty of Agriculture during 2015 and 2016. Treatments include salinity stress in 8 levels (0 (Control), -0.1, -0.2, -0.4, -0.6, -0.8, -1 and -1.2 Mpa) and temperature at 8 levels (5, 10, 15, 20, 25, 30, 35 and 40oC). After 14 days, seeds in treatment solutions were no longer germinating, so all germinated seedlings were removed and un-germinated seeds of the highest salinity treatment (-1.2 Mpa NaCl) were rinsed with distilled water and placed back in their dishes with 5 mL of distilled water for 14 more days.
Results and Discussion: Results showed that with increasing salinity at each level of temperature germination rate and percentage reduced in both ecotypes, so that in potential -1.2 Mpa germination was stopped in both ecotypes. In both ecotypes germination stamped at 5, 10 and 40 ̊C temperatures in all levels of salinity. In both ecotypes the highest percentage and rate of germination were indicated at control treatment salinity and 25 and 30 ̊C temperatures. It is believed that the effect of high concentration of NaCl at high temperatures can be attributed to the toxic sodium that causes irreversible damage. According to the results Bardaskan ecotype was better than Qouchan ecotype in view of germination at high levels of temperatures and salinity treatments. The three parameter logistic model provided a satisfactory fit for the response of seed germination to NaCl concentration. The effective salinity for reducing  of 50% seed germination in Qouchan ecotype at 15, 20, 25, 30 and 35 ̊C temperatures were -0.79, -0.86, -0.87, -0.77 and -0.68 Mpa and in Bardaskan ecotype were -0.93, -0.93, -0.95, -0.90 and -0.75 Mpa respectively. Recovering the ungerminated seeds from the salinity level of -1.2 Mpa and reincubating them with distilled water resulted in a germination of 70% in both ecotypes, indicating that enforced seed dormancy was mainly because of an osmotic effect, as opposed to toxicity owing to an ionic effect.
Conclusion: This study shows that eastern dodder has capacity to survive and reproduce even under a higher temperature and higher degree of salinity stress. The information of this study would be helpful for estimating the potential of this species to spread to new areas and for the improvement of this parasitic weed species management programs. As is evident from these experiments, the effective, long-term reduction of eastern dodder populations will require the use of an integrated weed management approach.

کلیدواژه‌ها [English]

  • Environmental factors
  • Parasitic plant
  • Salinity stress
  • Seedling establishment
  • Weed ecology

مراجع

  1. Benvenuti S., Dinelli G., Bonetti A., and Catizone P. 2005. Germination ecology’ emergence and host detection in Cuscuta campestris. Weed Research 45: 270-278.
  2. Bewley J.D., and Black M. 1982. Physiology and biochemistry of seeds in relation to germination. Vol. 2. Viability, dormancy and environmental control, Springer-Verlag. New York.
  3. Chauhan B.S., Gill G., and Preston C. 2006. Factors affecting seed germination of annual sowthistle (Sonchus oleraceus) in southern Australia. Weed Science 54: 854-860.
  4. Chauhan B.S., Gill G., and Preston C. 2006. Seed germination and seedling emergence of three horn bedstraw (Galium tricornutum). Weed Science 54: 867–872.
  5. Chauhan B.S., and Johnson D.E. 2008. Seed germination and seedling emergence of giant sensitiveplant (Mimosa invisa). Weed Science 56: 244-248.
  6. DiTommaso A. 2004. Germination behavior of common ragweed (Ambrosia artemisifolia) populations across a range of salinities. Weed Science 52: 1002-1009.
  7. Ebrahimi E., Eslami S.V., and Zand E. 2011. Effect of environmental factors on germination and emergence of Eastern dodder (Cuscuta monogyna). Journal of Plant Protection 25(1): 83-91. (In Persian with English abstract)
  8. Ebrahimi E., and Eslami S.V. 2012. Effect of different treatments on dormancy breaking and seed germination of Eastern dodder (Cuscuta monogyna Vahl) and African rocket (Malcolmia africana (R.BR.)). Journal of Plant Protection 26(2): 191-198. (In Persian with English abstract)
  9. Ebrahimi E., and Eslami S.V. 2013. Seed dormancy breaking and Effect of some environmental factors on germination of cutleaf mignonette (Reseda lutea ) seed. Journal of Plant Protection 27(2): 177-184. (In Persian with English abstract)
  10. Fathoulla C.N., and Mosleh M.S. 2008. Biological and anatomical study of different Cuscuta Kurdistan Conference Biological 11: 22-39.
  11. Fenando E.P., Boero C., Gallardo M., and Gonzalez J. 2000. Effect of NaCl on germination, growth, and soluble suger content in Chenopodium quinonaseeds. Botanical Bulletin of Academia Sinica 41: 27- 34.
  12. Fowler J.L., Hageman J.H., Moore K.J., Suzukida M., and Assadian H. 1988. Evalution of salinity tolerance of Russian-thistle, a potential forage crop. Agronomy Journal 80: 250-258.
  13. Goldwasser Y., Miryamchik H., Rubin B., and Eizenberg H. 2016. Field dodder (Cuscuta campestris) - a New Model describing temperature dependent seed germination. Weed Science 64: 53–60.
  14. Greenway H., and Munns R. 1980. Mechanisms of salt tolerance in nonhalophytes. Annal. Review. Plant. Physiology 31: 149-190.
  15. Guma I.R., Padron-Mederos M.A., Santos-Guerra A., and Reyes-Betancort J.A. 2010. Effect of temperature and salinity on germination of Salsola vermiculata (Chenopodiaceae) from Canary Islands. Journal of Arid Environment 74: 708–711.
  16. Holm L., Holm D.L.J., Pancho J.V., and Herberger J.P. 1997. World Weeds: Natural histories and distribution. John wiley and sons, Newyork. 1129 pp.
  17. Karimi H. 2001. Weeds of Iran. Tehran, 419pp. (In Persian)
  18. Keiffer C.W., and Ungar I.A. 1995. Germination responses of halophyte seeds exposed to prolonged hypersaline conditions. In: Khan M.A., Ungar I.A. (eds.) Biology of Salt Tolerant Plants. Karachi: Department of Botany, University of Karachi, 43-50.
  19. Khaleghi E., and Ramin A.A. 2005. Study of the effects of salinity on growth and development of lawns (Lolium perenne , Festuca arundinacea and Cynodon dactylon). Journal of Science and Technology of Agriculture and Natural Resources 9: 57-68.
  20. Khan M.A., and Ungar I.A. 1999. Seed germination and recovery of Triglochin maritima from salt stress under different thermo periods. Great Basin Naturalist 59: 144–150.
  21. Khan M.A., and Ungar I.A. 1997. Effects of light, salinity, and thermoperiod on the seed germination of halophytes. Canadian J of Botany 75: 835-841.
  22. Khan M.A., Gul B., and Weber D.J. 2001. Effect of salinity and temperature on the germination of Kochia scoparia. Wetlands Ecology and Management 9: 483-489.
  23. Khan M.A., and Gulzar S. 2002. Germination responses Of Sporobolus ioclados: a salin desert grass. Journal Arid Environment 53: 387-364.
  24. Khan M.A., Gul B., and Weber D.J. 2000. Germination responsesto Salicornia rubra to temperature and salinity. Journal Arid Environment 45: 207-214.
  25. Kiyani E., Siahmarguee A., and Soltani A. 2015. The effects of temperature, Salinity and seeding depth on seed germination and emergence of morning glory (Ipomoea spp.). Journal of Plant Protection 29(3): 437-448. (In Persian with English abstract)
  26. Koger C.H., Reddy K.N., and Poston D.H. 2004. Factors affecting seed germination, seedling emergence, and survival of texasweed (Caperonia palustris).Weed Science 52: 989-995.
  27. Koskela T., Salonen V., and Mutikainen P. 2001. Interaction of a host plant and its holoparasitie effects of previous selection by the parasite. Journal of Biology 6: 14-91.
  28. Krsmanovic M.S., Bozic D., Pavlovic M., Radivojevic L., and Vrbnicanin S. 2013. Temperature Effects on Cuscuta campestris Seed Germination. Journal of Pestic Phytomed 28(3): 187–193.
  29. Izadi-Darbandi E., Mohammadian M., Yanegh A., and Zarghani H. 2012. The Effects of Temperature and Salinity on Germination and Seedling Growth Characteristics of Sesame (Sesamum indicum) Landraces. Journal of Iranian Field Crop Research 10: 335-345. (In Persian with English abstract)
  30. Maguire J.D. 1962. Seed of germination–aid in selection and evaluation for seedling emergence and vigor. Crop Science 2: 176-177.
  31. Mennan H., and Ngouajio M. 2006. Seasonal cycles in germination and seedling emergence of summer and winter population of catch weed bedstraw and wild mustard. Weed Science 54: 114-120.
  32. Nazari S. 2014. Introducing Cuscuta monogyna as Oak Trees Parasite, its Biology, and Method to Fight in Lorestan province. Bull. Environment. Pharmacol. Life Science 3(2): 164-168.
  33. Radosevich S.R., Holt J.S., and Ghersa C.M. 2007. Ecology of Weeds and Invasive Plants Relationship to Agriculture and Natural Resource Management. John Wiley& Sons, 472pp.
  34. Smith S.E., and Dobrenz A.K. 1987. Seed age and salt tolerance at germination in alfalfa: Crop Science 27: 1053-1058.
  35. Stevens O.A. 1932. The number and weight of seeds produced by weeds. American Journal of Botany 19: 784-794.
  36. Tanji K.K., and Kielen N.C. 2002. Agricultural Drainge Water Management in Arid and Semi-Arid Areas. Fao Irrigation and Drainage Papper 61. Rome Italy. Food and Agriculture Organization of the United Nations, 202p.
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