ارزیابی زراعی ژنوتیپ‌های نخود (Cicer arietinum L.) متحمل به سرما در شرایط کاشت پاییزه در مشهد

نوع مقاله : مقالات پژوهشی

نویسندگان

1 دانشگاه فردوسی مشهد/پژوهشکدة علوم گیاهی

2 دانشگاه فردوسی مشهد

چکیده

به‌منظور بررسی خصوصیات زراعی و عملکردی ژنوتیپ‌های نخود متحمل به سرما در شرایط کاشت پاییزه، آزمایشی طی سه سال زراعی 82-1381، 83-1382 و 1384-1383 در مزرعه تحقیقاتی دانشکده کشاورزی دانشگاه فردوسی مشهد به‌صورت دیم، به اجرا درآمد. در هر سه سال به‌منظور اطمینان از سبز‌شدن نمونه‌ها، تنها دو نوبت آبیاری (یکی در هنگام کاشت و دیگری 20روز پس از آن) انجام شد. در سال زراعی اول (82-1381)، 46ژنوتیپ نخود شامل30نمونه متحمل به سرما حاصل مطالعات قبلی در مشهد و چند نمونه متحمل به سرما از ایکاردا و کانادا در قالب طرح بلوک‌های کامل تصادفی با سه تکرار به‌صورت پاییزه (اواسط مهرماه) کشت شدند. با توجه به ازبین‌رفتن تمام نمونه‌ها در اثر سرما در این سال، در دو سال زراعی بعد، با اضافه‌نمودن 106نمونه نخود متحمل به سرمای دیگر، در مجموع 152ژنوتیپ نخود به‌همراه چهار شاهد در قالب آزمون مقدماتی ارزیابی عملکرد (آگمنت) در هر یک از دو سال در کاشت مهرماه مورد ارزیابی قرار گرفتند. در هر سال، تمامی ژنوتیپ‌های نخود بر اساس عملکرد دانه، در گروه‌های عملکردی دسته‌بندی شدند و بر اساس آن، شاخص‌های آماری شامل میانگین، انحراف‌معیار و دامنة‌‌ تغییر برای صفات مختلف (اجزای عملکرد، عملکرد و ارتفاع بوته) در مورد هر گروه عملکردی محاسبه گردید. بر اساس نتایج حاصل از اندازه‌گیری صفات در شاهدها و ژنوتیپ‌ها، تفاوت‌های آماری معنی‌داری در میان ژنوتیپ‌ها و نیز در مقایسه با شاهدهای آزمایش مشاهده شد. بر این اساس، در سال دوم، در ژنوتیپ‌های اولین گروه عملکردی که بالاترین مقادیر عملکرد دانه (بیشتر از 250گرم در مترمربع) را دارا بوده و شامل 5/39درصد از تعداد کل ژنوتیپ‌های مورد بررسی بودند، میزان عملکرد دانه از 251 تا 622گرم در مترمربع متغیر بود؛ درحالی‌که در سال سوم، مقادیر مربوط به این گروه عملکردی که شامل20درصد از تعداد کل ژنوتیپ‌های مورد بررسی بودند، از 254 تا 442گرم در مترمربع مشاهده شد. در انتها، تعداد20ژنوتیپ برتر از هر کدام از دو سال آزمایش (در مجموع 39ژنوتیپ)، انتخاب و همراه با سایر صفات اندازه‌گیری‌شده مربوط به آن‌ها به‌منظور استفاده در ادامة آزمایشات معرفی شدند.

کلیدواژه‌ها

عنوان مقاله [English]

Agronomic assessment of cold tolerant chickpea (Cicer arietinum L.) genotypes in fall sowing at Mashhad conditions

نویسندگان [English]

  • hassan porsa 1
  • Ahmad Nezami 2
  • Abdolreza Bagheri 2
  • Samaneh Najibnia 2
1 Research Center for Plant Sciences, Ferdowsi University of Mashhad
2 Ferdowsi University of Mashhad
چکیده [English]

Introduction
Studies on the fall-winter sowing of chickpea were commenced in 1974-75 at Mediterranean regions. For example, Singh et al, (1997) studied some chickpea cold and ascochyta blight tolerant genotypes in fall-winter sowing for 10 years (1983-1993) on three regions in Syria and Lebanon under rain-fed conditions. The mean of seed yield for 10 years in the fall-winter sowing was 1686 kg.ha-1 that showed 70% of increase comparing to seed yield in spring sowing with 994 kg.ha-1. Biological yield in fall-winter sowing had the same increase record comparing with spring sowing, too. They declared that the extended vegetative period in fall-winter sowing than spring sowing was the cause of this result. Also, studies on fall sowing of chickpea in Iran have shown that significant enhancement of seed yield compared to spring sowing has arisen from exploiting of sufficient water and extending of a growth period in fall sowing. Regarding to the results of previous studies on fall-winter sowing of chickpea that demonstrated possibility of this type of sowing in cold areas, this experiment was performed in order to evaluate yield and yield components of 152 other chickpea genotypes in fall sowing.

Materials and Methods
This study was carried out in three years of 2002-2003, 2003-2004 and 2004-2005 at the Experimental Field of College of Agriculture, Ferdowsi University of Mashhad, north-eastern Khorassan state of Iran. This study was performed in rainfed conditions with only two times irrigation at planting stage and 20 days after that. In the first year (2002-2003), 46 chickpea genotypes (30 cold tolerant accessions resulted from previous studies at Mashhad and some genotypes from ICARDA and Canada) were planted based on Randomized Complete Block Design with three replications. During this year, cold injury caused complete loss so, in the next two years by adding of 106 other accessions, totally, 152 chickpea genotypes with 4 checks were evaluated based on the Augmented Preliminarily Design. The seeds of genotypes were attained from Mashhad Chickpea Collection (MCC), Research Center for Plant Sciences, Ferdowsi University of Mashhad. The seeds of each genotype in all trials were sown in plots containing one row with a length of 2.5 meter. The distance between seeds on the row was 0.1 meter and rows were placed 0.5 meter apart. In the second and third trials, genotypes were categorized according to their seed yield amounts to several groups and some statistical indices such as mean, standard deviation and range were calculated on their measured quantitative traits (such as seed yield, biological yield, and yield components). Based on data analysis, existing of significant differences among genotypes and controls were studied between them. Finally, superior genotypes were selected and introduced for continuing of investigations at future.

Results and Discussion
In the first year, the hard, cold and freezing temperatures occurred after emerging of seedlings, repeatedly and then all plants were lost. There were 69 days with freezing temperatures through the period of planting to late winter. The lowest temperature through this period was -12.8°C that occurred in November and December. Based the on results, in the next two years, there were significant differences (P≤0.05) among genotypes with each other and with checks in yield, yield components and plant height. In the second year (2003-2004), the range of seed yield among the first yield group (39.5% of all genotypes) was from 251 to 622 g.m-2, while in the third year (2004-2005) this range among the first yield group (20% of all genotypes) was from 254 to 442 g.m-2. In the second and third years, the highest survival percent, meaning among all five groups was observed in the first groups. Totally, 20 chickpea genotypes with the most yields for each year were selected and introduced for the next studies.

Conclusion
Regarding to rainfed conditions, the higher seed yields in the second year comparing to the third year can be related to greater precipitations in this trial (271 mm) compared to the third (202 mm), as well as better distribution of rainfall in the second year coinciding with the vegetative growth period. Occurrence of higher temperatures at the end of the growing season in the third year also could be a limiting factor for reproductive growth of chickpeas. It seems that the existing of only one genotype (MCC798), communally in two years among 20 superior genotypes, revealed this fact that these genotypes respond to various environmental circumstances, differently. Regarding to mean of seed yield of chickpea in Iran (410 kg.ha-1), achieving of seed yield records of 3800 to 6220 kg.ha-1 at the second trial and 2740 to 4420 kg.ha-1 at the third trial in this study that were obtained from next to 40 chickpea genotypes, reveals a promising potential for a fall sowing of chickpea in Mashhad. However, concerning about this fact that the temperature in the two years of this study did not drop less than -13.2°C on the second trial and -9.2°C on the third, it is suggested to investigate of phenological and morpho-phisiological aspects of these genotypes more, especially in colder areas in order to be sure of their cold tolerance, sustainably. Finally, 20 chickpea genotypes with the most yields for each year (totally 39 genotypes) were selected and introduced for the next studies. Considering the importance of field investigations, these results can be completely efficient for continuing research and development programs on the subject of chickpea cold tolerance in the present and the future.

کلیدواژه‌ها [English]

  • Augmented preliminarily design
  • Plant height
  • Rainfed
  • Yield and yield components

مراجع

1. Bagheri, A. 1998. Pulse breeding for tolerating biotic and abiotic stresses. In: Proc. of the 5th Iranian Crop Production and Breeding Congress, 31Aug-4Sep, 1998. Seed and Plant Improvement Institute, Karaj, Iran, p. 12-13. (In Persian).
2. Calcagno, F., and Gallo, G. 1993. Physiological and morphological basis of abiotic stress resistance in chickpea. In: K.B. Singh and M.C. Saxena (Eds.). Breeding for Stress Tolerance in Cool-Season Food Legumes. John Wiley and Sons, Chichester, UK. P. 293-309.
3. Fraiedi, Y. 2007. Study of agronomic characteristic and cold hardiness in chickpea (Cicer arietinum L.) genotypes in autumn rainfed sowing conditions. Seed and Plant 23: 489-503. (In Persian).
4. Hadjichristodoulou, A. 1990. Winter sowing: a major breakthrough in chickpea production in Cyprus. In: Chickpea in the Nineties, Proc. of the Second International Workshop on Chickpea Improvement, 4-8Dec. 1989, ICRISAT. Patancheru, India: ICRISAT, p. 297-298.
5. http://faostat.fao.org/site/567/default.aspx#ancor (verified 14 February 2015).
6. http://www.irimo.ir/farsi/
7. Islam, R. 1981. Responses of winter and spring planted chickpea to inoculation with Rhizobium in Syria. ICN 4: 24-25.
8. Kanooni, H. 2005. Evaluation of chickpea genotypes for cold tolerance in fall sowing. Seed & Plant Journal 20: 89-99. (In Persian with English Summary).
9. Kanouni, H., Khalily, M., and Malhotra, R.S. 2009. Assessment of cold tolerance of chickpea at rainfed highlands of Iran. American-Eurasian Journal Agriculture & Environment Science 5: 250-254.
10. Kanouni, H., Taleei, A., and Okhovat, M. 2011. Ascochyta blight (Ascochyta rabiei (Pass.) Lab.) of chickpea (Cicer arietinum L.): Breeding strategies for resistance. International Journal of Plant Breeding and Genetics 5: 1-22.
11. Keating, J.D.H., and Cooper, P.J.M. 1983. Kabuli chickpea as a winter-sown crop in northern Syria: moisture relations and crop productivity. Journal of Agricultural Science Cambridge 100: 667 -680.
12. Keating, J.D.H., and Cooper, P.J.M. 1984. Physiological and moisture-use studies on growth and development of winter-sown chickpeas. In: M.C. Saxena and K.B. Singh (Eds.). Ascochyta Blight and Winter Sowing of Chickpeas. Martinus Nijhoff/Dr. W. Junk Publishers, The Hague, the Netherlands, p. 141-157.
13. Khanna-Chopra, R., and Sinha, S.K. 1987. Chickpea: physiological aspects of growth and yield. In: M.C. Saxena and K.B. Singh (Eds.). The Chickpea. C.A.B. International, UK, p. 163-189.
14. Millan, T., Clark, H.J., Siddique, K.H.M., Buhariwalla, H.K., Gaur, P.M., Kumar, J., Gill, J., Kahl, G., and Winter, P. 2006. Chickpea molecular breeding: New tools and concepts. Euphytica 147: 81-103.
15. Naderi, H., Shokrpoor, M., Asghari, A., Kanooni, H., and Esfandiari, A. 2013. Evaluation of cold tolerance in winter sowing of chickpea (Cicer arietinum L.) using morphological and phonological traits in Kurdistan region. Iranian Journal of Pulses Research 4(1): 69-80. (In Persian with English Summary).
16. Nezami, A. 2003. Evaluation of chickpea genotypes (Cicer arietinum L.) for cold tolerance in fall sowing on highland regions. PhD. Dissertation. Faculty of Agriculture, Ferdowsi University of Mashhad. (In Persian).
17. Nezami, A., and Bagheri, A. 2005a. Responsiveness of cold tolerant chickpea characteristics in fall and spring planting: 1- Phenology and morphology. Iranian Journal of Field Crops Research 3(1): 143-155. (In Persian with English Summary).
18. Nezami, A., and Bagheri, A. 2005b. Responsiveness of cold tolerant chickpea characteristics in fall and spring planting: 2- yield and yield components. Iranian Journal of Field Crops Research 3(1): 156-170. (In Persian with English Summary).
19. Nezami, A., and Bagheri, A. 2001. Screening of Mashhad chickpea (Cicer arietinum L.) collection for cold tolerance under field conditions. Journal of Agricultural Science and Technology 15(2): 156-162. (In Persian with English Summary).
20. Nezami, A., and Bagheri, A. 2006. Preliminary evaluation of phenology, yield components and yield of fall chickpea genotypes in the Mashhad conditions. Agricultural Sciences & Technology Journal 20(3): 71-80. (In Persian with English Summary).
21. Nezami, A., Sedaghat-Khahi, H., Porsa, H., Parsa, M., and Bagheri, A. 2010. Evaluating of the fall sowing cold tolerant chickpea (Cicer arietinum L.) genotypes at supplementary irrigation in Mashhad conditions. Iranian Journal of Field Crops Research 8(3): 415-423. (In Persian with English Summary).
22. Ozdemir, S., and Karadavut, U. 2003. Comparison of the performance of autumn and spring sowing of chickpeas in a temperature region. Turkish Journal of Agriculture and Forestry 27: 345-352.
23. Peterson, R.G. 1986. Augmented Preliminarily Design (Translated to Farsi by Ghaffari, A.). Organization of Agricultural Research & Natural Resources, Seed and Plant Improvement Institute. pp. 25.
24. Porsa, H., Bagheri, A., Nezami, A., Mohammadabadi, A.A., and Langari, M. 2002. Investigation on fall-winter sowing possibility of chickpea (Cicer arietinum L.) under rainfed conditions in Northern Khorassan. Journal of Agricultural Science & Technology 16(1): 143-152. (In Persian with English Summary).
25. Sedaghat-Khahi, H., Parsa, M., Nezami, A., Bagheri, A. and Porsa, H. 2012. Evaluating of the morphological and phenological characteristics of cold tolerant chickpea (Cicer arietinum L.) genotypes at Entezary sowing in Mashhad conditions. Iranian Journal of Pulses Research 3(1): 41-52. (In Persian with English Summary).
26. Silim, S.N., Hebblethwait, P.D., and Heath, M.C. 1985. Comparison of the effects of autumn and spring sowing date on growth and yield of combining peas (Pisum sativum L.). Journal of Agricultural Science Cambridge 104: 35-46.
27. Singh, K.B., and Saxena, M.C. 1996. Winter Chickpea in Mediterranean Type Environments. ICARDA, Aleppo, Syria.
28. Singh, K.B., Malhotra, R.S., Halia, M.H., Knights, E.J., and Werma, M. 1994. Current status and future strategy in breeding chickpea for resistance to biotic and abiotic stresses. Euphytica 73: 137-149.
29. Singh, K.B., Malhotra, R.S., Saxena, M.C., and Bejia, G. 1997. Superiority of winter sowing over traditional spring sowing of chickpea in the Mediterranean region. Agronomy Journal 89: 112-118.
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