Evaluation of Growth Characteristics of Four Clover Species (Trifoliums pp.) Affected by Freezing Stress under Controlled Conditions

Document Type : Research Article

Authors

1 Department of Agrotechnology, Faculty of Agriculture, Ferdowsi University of Mashhad

2 PhD in Agronomy, Department of Agrotechnology, Faculty of Agriculture, Ferdowsi University of Mashhad

Abstract

Introduction: In Iran, clover is the second most important forage crop after alfalfa (Medicago sativa) and is cultivated on a surface of about 70,000 hectares. Yield improvement of this plant could be achieved through autumn cultivation. Iran is still one of the main centers for the diversity of clover species, there is not much information about freezing tolerance of native species of this important plant. Since freezing stress is one of the most important winter stresses which causes severe damage to the plant cells and tissues and ultimately plant death, evaluation of freezing tolerance of this crop could help to determination of the best planting date in order to achieve the highest yield. The aim of this study was to evaluate the freezing tolerance of four clover species through assessment of plant survival and re-growth after freezing stress.
Materials and Methods: In order to study growth criteria of four clover species after freezing stress in controlled conditions, an experiment was conducted in 2012-13 in Faculty of agriculture, Ferdowsi University of Mashhad. Treatments were arranged as factorial based on Completely Randomized Design with four replications. Factors were included of planting dates (late September and late October), clover species (red clover T. pratense, white clover T. repense, Persian clover T. resupinatum (autumn species) and crimson clover T. incarnatum (spring species) and freezing temperatures (0 (control), -3, -6, -9, -12, -15, -18, -21ºC). Survival percentage, LT50 according to Survival (LT50su), leaf area, Reduced 50% Leaf Area Temperature (RLAT50), dry weight and Reduced Dry Matter Temperature 50 (RDMT50) were measured after three weeks re-growth.
Results and Discussion: Results indicated that survival percentage was significantly affected by interaction of planting date, species and freezing temperatures. In both planting dates, crimson and white species showed a good survival till -15°C while they were killed as temperature was more decreased to -18°C. In first planting date, two species of red and Persian clover had 50 and 42% survival, but were killed in this temperature in the second planting date. The lowest LT50su in autumn (red, white and Persian) and spring (crimson) species was found in first and second planting dates, respectively indicating higher freezing tolerance in crimson species at second planting date and a better acclimation of autumn species at first planting date which led to a higher survival compared to spring species. Leaf area was significantly affected by planting date, species and freezing temperatures at the end of the recovery period. In first planting date, decreasing temperature from zero to -18°C caused reduction of 98 and 48% of leaf area in red and Persian species while no plant of white and crimson species was survived in this condition. In second planting date, leaf area was decreased about 6, 33 and 2% as temperature decreased from zero to -15°C while leaf area of Persian species, not only was not decreased, but also increased by about 12%. The lowest and highest RLAT50 were observed in Persian and red species. Interaction of planting date and species on RDMT50 was significant in a way that in delayed planting date, RDMT50 was increased in red, Persian and crimson species while it was decreased in white species.
Conclusion: Red and Persian species showed higher freezing tolerance according to indices of survival percentage and LT50su. The highest recovery ability of plants based on leaf area per plant, RLAT50, plant dry matter and RDMT50 was found for second planting date. Also annual species of Persian and crimson had lower RLAT50 and RDMT50 and higher freezing tolerance compared to perennial species of red and white clover.

Keywords


  1. Anderson, J. A., and Taliaferro, C. M. 1995. Laboratory freeze tolerance of field grown forage Bermuda grass cultivars. Agronomy Journal87: 1017-1020.
  2. Azizi, H., Nezami, A., Nassiri Mahallati, M., and Khazaie, H. 2007. Evaluation of cold tolerance in wheat (Triticum aestivum L.) cultivars under controlled conditions. Iranian Journal of Field Crops Research 5 (1): 107-120. (in Persian with English abstract).
  3. Bridger, G. M., Falk, D. E., Mckersie, B. D., and Smith, D. L. 1996. Crown freezing tolerance and field winter survival of winter cereals in eastern Canada. Crop Science 36: 150-157.
  4. Cardona, C. A., Duncan, R. R., and Lindstrom, O. 1997. Low temperature tolerance assessment in paspalum. Crop Science 37: 1283-1291.
  5. Chabok, Kh., and Espahbodi, K. 2011. Seeding dates effects on seed and forage production of Berseem clover (Trifolium alexandrinum L.) in Mazandaran. Agronomy Journal (Pajouhesh & Sazandegi). No: 93. pp: 1-7. (in Persian with English abstract).
  6. Gusta, L. V., O’Connor, B. J., Gao, Y. P., and Jana, S. 2001. A re-evaluation of controlled freeze-tests and controlled environment hardening conditions to estimate the winter survival potential of hardy winter wheat. Canadian Journal of Plant Science 80: 241-246.
  7. Henkeby, M., Antolin, M. C., and Sanchez-Diaz, M. 2006. Frost resistance and biochemical changes during cold acclimation in different annual legumes. Environmental and Experimental Botany 55: 305-314.
  8. Huner, N. P. A, Bode, R., and Dahal, K. 2013. Shedding some light on cold acclimation, cold adaptation, and phenotypic plasticity. Botany 91 (3): 127-136.
  9. Jeffrey, A. A., and Charles, M. T. 1995. Laboratory freeze tolerance of field-grown forage Bermuda grass cultivars. Agronomy Journal 87: 1017-1020.
  10. Lindow, S. E., Arny, D. C., and Upper, C. D. 1982. Bacterial ice nucleation: A factor in frost injury to plants. Plant Physiology 70: 1084-1089.
  11. Mirmohammadi Maibodi, A. M., and Tarkesh Esfahani, S. 2004. Physiological and Breeding Aspects of Cold and Freezing Stress in Crops. Golbon Press. 223 pp. (in Persian).
  12. Murray, G. A., Eser, D., Gusta, L. V., and Eteve, G. 1988. Winter hardiness in pea, lentil, faba bean and chickpea. p. 831-843. In the R.J. Summerfield (Ed.) World crops: cool season food legumes. Kluwer Academic Publishers A. the Netherlands.
  13. Nezami, A., Bagheri, A., Rahimian, H., Kafi, M., and Nassiri Mahallati, M. 2007. Evaluation of Freezing Tolerance of Chickpea (Cicer arietinum L.) Genotypes under Controlled Conditions. Journal of Water and Soil Sciences 10 (4): 257-269. (in Persian with English abstract).
  14. Nezami, A., Hajmohammadnia Ghalibaf, K., and Kamandi, A. 2010a. Evaluation of freezing tolerance of sugar beet (Beta vulgaris L.) cultivars under controlled conditions. Environmental Stresses in Crop Sciences 3 (2): 177-187. (in Persian with English abstract).
  15. Nezami, A., Soleimani, M. R., Ziaee, M., Ghodsi, M., and Bannayan Aval, M. 2010b. Evaluation of freezing tolerance of hexaploid triticale genotypes under controlled conditions. Notulae Scientia Biologicae 2: 114-120.
  16. Ouellet, F., and Charron, J. B. 2013. Cold Acclimation and Freezing Tolerance in Plants. In: eLS. John Wiley & Sons, Ltd: Chichester. DOI: 10.1002/9780470015902.a0020093. pub2
  17. Rife, C. L., and Zeinali, H. 2003. Cold tolerance in oilseed rape over varying acclimation durations. Crop Science 43: 96-100.
  18. Swensen, J. B. 1980. Development of freezing tolerance and changes in tissue moisture during hardening of Pisumsativum L. and Pisumsativum subsp. Arvense L. MSc thesis, University of Idaho, USA.
  19. Thomashow, M. F. 2001. So what’s new in the field of plant cold acclimation? Lots! Plant Physiology. 125: 89-93.
  20. Zamanian, M., and Asadi, H. 2004. Effects of seed rate, planting date and planting method on morphological traits and forage yield of Persian clover. Iranian Journal of Crop Sciences 7 (3): 241-251. (in Persian with English abstract).
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