Genetic variation of bread wheat geneotypes for some important physiological traits under chiling stress

Asadi, Abouzar; Askary Kelestani, Ali Reza; Mirfakhraii, Rezagholi; Abasi, Alireza; Khodadadi, Mostafa

doi:10.22077/escs.2017.195.1049

Document Type : Original Article

Authors

¹ Ph.D. Student of Plant Breading, Razi University, Kermanshah, Iran.

² Ph.D. Student at Agricultural Nuclear Science, Gorgan University, Gorgan, Iran.

³ Assistant Professor of Plant Breeding and Agricultural Biotecnology, Tarbiat Modares University, Tehran, Iran.

⁴ Assistant Professor of Agronomy and Plant Breeding, Tehran University, Tehran, Iran.

⁵ Ph.D. Student at Plant Breading, Tarbiat Modares University, Tehran, Iran.

https://doi.org/10.22077/escs.2017.195.1049

Abstract

Introduction
Food productivity is declining due to the effect of different abiotic stresses. Stress is the result of abnormal physiological processes that influence by one or a combination of biological and environmental factors. Cold, salinity and drought are important among the other stresses. Three types of cold stress has been identified that include: Frost, Freezing and Chilling Stress. The relationship between plant growth and climate change is a seemingly contradictory event. In fact, warming increases danger of cold stress. In the spring, at the same time of started wheat growth, it is increase its sensitivity to low temperatures and it damaged. This model of cold stress called rapidly falling temperatures in the spring or in short term called "chilling". Chilling stress reduced leaf expansion, wilting, chlorosis (yellowing of leaves) and may lead to necrosis (death of tissue) and strongly disturbed the reproductive development of plants. Low temperature stress limit the grain production in cold and ultra-cold climates and makes high damages in some years. Therefore produce resistant cultivars is necessary. Management of genetic resources, and knowledge of the genetic diversity are tow important principles of breeding projects. This study examines the genetic diversity of some of bread wheat cultivars for some physiological characteristics associated with chiling stress using multivariate statistical methods and compare these methods.

Materials and methods
This survey performed in 2013 at the Faculty of agriculture, Tarbiat Modares University. In this study an experiment with 20 varieties of wheat with four treated cold levels of stress (8 (control), +2, 0, -2 Celsius) in factorial arrangement in randomized completely design implemented. In early of reproductive stages (Zydaky code 50 to 68), the plant transferred to growth chamber under 14/10 hours and 16/8 °C day/night photoperiod. To impose stress, temperature reduced 2°C per one hours from 8 °C then the pots were placed for 2 h under stress in each of stress temperature levels (2, 0 and -2 °C). After stress, temperature up to 8 °C with ramp 2 °C per hours. Sampling was done after 24 h and then electrolyte leakage, chlorophyll (a, b, ab and cartenoids), proline and fructan, were assessed.

Results and discussion
The results of this study showed that the effects of interaction between gentopyes and chiling stress were significant at 1% level. Based on results of the cluster analysis twenty genotypes were classified into four groups in -2 celsius temperature and two groups in control temperature. The principal component and principal coordinate ,confirmed grouping created based on of cluster analysis. The principal component analysis decrease all treats in to 3 components in control (with cumulative of variance 80) and sever stress (with cumulative of variance 85). Also the principal coordinate analysis decrease all component to 3 components with cumulative variance 94.11 (for control) and 96.59 (for sever stress). Based on cluster analysis Pishgam and Aflak genotypes in control condition and Alvand and Sivand in -2°C had the maximum genetic distance. The minimum genetic distance was observed between Mv17 and Navid genotypes (in control condition) and Kaskojen and Pishgam (sever stress).

Conclusions
(1) Chiling stress detects the diversity amoung studied gentopyes; (2) In order to grouping of genotypes, cluster analysis provided more accurate grouping than principal component analysis and principal coordinate analysis ; (3) Alvand and Sivand cultivars can be use as potential parents to provide the necessary population in classical breeding programs, in order to detect of QTLs for chiling tolerance and also for marker assisted selecion.

Keywords

References

Arzani, A., 2003. Crop Breeding.Isfahan University Publication Center. 666 pp. [In Persian].

Asadi, A., Mirfakhraii, R. Alireza, A., 2013. Genetic diversity of some of Bread wheat cultivars using SSR mlecular markers and some of physiological traits under chilling stress. MSc dissertation, Faculty of Agriculture, University of Tarbiat Modares, Iran. [In Persian with English Summary].

Ashraf, M., Foolad, M., 2007. Roles of glycine betaine and proline in improving plant abiotic stress resistance. Environmental and Experimental Botany. 59, 206-216.

Bates, L., Waldren, R., Teare, I., 1973. Rapid determination of free proline for water-stress studies. Plant and soil. 39, 205-207.

Bertin, P., Bouharmont, J., Kinet, J. M., 1996. Somaclonal variation and improvement in chilling tolerance in rice: changes in chilling‐induced electrolyte leakage. Plant Breeding. 115, 268-272.

Farahani, E., Arzani, A., 2009. Evaluation of genetic variation of durum wheat genotypes using multivariate analyses. Electronic Journal of Crop Production. 4, 51-64. [In Persian].

Farshadfar, E., Farshadfar, H., 2013. Biplot analysis for detection of heterotic crosses and estimation of additive and dominance components of genetic variation for drought tolerance in bread wheat (Triticum aestivum). Agriculture Communication. 1: 1-7.

Fowler, D. B., Breton, G., Limin, A. E., Mahfoozi, S., Sarhan, F., 2001. Photoperiod and temperature interactions regulate low-temperature-induced gene expression in barley. Plant Physiology. 127, 1676-1681.

Groppa, M., Benavides, M., 2008. Polyamines and abiotic stress: recent advances. Amino Acids. 34, 35-45.

Gusta, L., Fowler, D., 1976. Effects of temperature on dehardening and rehardening of winter cereals. Canadian Journal of Plant Science. 56, 673-678.

Hall, A.E., 2000. Crop Responses to Environment.CRC Press. 231p.

Han, B., Bischof, J.C., 2004. Direct cell injury associated with eutectic crystallization during freezing. Cryobiology. 48, 8-21.

Jermyn, M., 1956. A new method for determining ketohexoses in the presence of aldohexoses. Nature. 177, 38-39.

Jobson, J., 2012. Applied multivariate data analysis: volume II: Categorical and Multivariate Methods.Springer Science and Business Media. 129.

Joshi, S., Chandra, S., Palni, L., 2007. Differences in photosynthetic characteristics and accumulation of osmoprotectants in saplings of evergreen plants grown inside and outside a glasshouse during the winter season. Photosynthetica. 45, 594-600.

Kafi, M., Ganjali, A., Nezami, A. Shariatmadar, F., 2002. Weather and Yield.Ferdusi Mashad University Press. 311. [In Persian].

Khodadadi, M., Fotokian, M. H., Miransari, M., 2011. Genetic diversity of wheat (Triticum aestivum L.) genotypes based on cluster and principal component analyses for breeding strategies. Australian Journal of Crop Science. 5: 17.

Kimber, G., Feldman, M., 1987. Wild wheat. An introduction. Special Report, College of Agriculture, University of Missouri-Columbia.

Lichtenthaler, H. K., 1987. Chlorophylls and carotenoids: pigments of photosynthetic biomembranes. Methods in Enzymology. 148, 350-382.

Mahfoozi, S., Sasani, S., 2009. Vernalization requirement in some wheat and barely genotype and its relationship with expression of cold hardiness in field and controlled conditions. Journal of Crop Science of Iran. 39, 111-126. [In Persian with English Summary].

Meier, H., Reid, J., 1982. Reserve polysaccharides other than starch in higher plants. Plant Carbohydrates I, Springer, 418-471.

Mhajan, S., Tuteja, N., 2005. Cold, salinity and drought stresses. Arch Biochem Biophys. 444, 139-158.

Mirmohammadi Myboodi, A. M., 2006. Cold and Freezing Stresses: Breeding and Physiological Aspect of Crop Plant.Golban Isfahan Press. 336. [In Persian].

Mohamadi, M., Mirfakhraii, R. G., Abbasi, A. R., 2013. Study of genetic diversity of spring cold stress in Iranian bread wheat cultivars by using multivariate statistical methods. Electronic Journal of Crop Production. 6, 166-149. [In Persian with English Summary].

Mohammadi, S., Prasanna, B., 2003. Analysis of genetic diversity in crop plants salient statistical tools and considerations. Crop Science. 43, 1235-1248.

Perras, M. Sarhan, F., 1989. Synthesis of freezing tolerance proteins in leaves, crown, and roots during cold acclimation of wheat. Plant Physiology. 89, 577-585.

Pessarakli, M., 2014. Handbook of plant and crop Physiology.CRC press. 1031.

Sivakumar, P., Sharmila, P., Saradhi, P. P., 2000. Proline alleviates salt-stress-induced enhancement in ribulose-1, 5-bisphosphate oxygenase activity. Biochemical and biophysical research communications. 279, 512-515.

Skriver, K., Mundy, J., 1990. Gene expression in response to abscisic acid and osmotic stress. The Plant Cell. 2, 503.

Van Beuningen, L., Busch, R., 1997. Genetic diversity among North American spring wheat cultivars: I. Analysis of the coeffecient of parentage matrix. Crop Science. 37, 570-579.

Yuanyuan, M., Yali, Z., Jiang, L., Hongbo, S., 2009. Roles of plant soluble sugars and their responses to plant cold stress. African Journal of Biotechnology. 8, 2004-2010.

Zadocs, J.C., Changh, T.T., KKonzak, C.F., 1974. A decimal code for the growth stages of cereals. Weed Research. 14, 415-421.

Zhang, X., Li, C., Wang, L., Wang, H., You, G., Dong, Y., 2002. An estimation of the minimum number of SSR alleles needed to reveal genetic relationships in wheat varieties. I. Information from large-scale planted varieties and cornerstone breeding parents in Chinese wheat improvement and production. Theoretical and Applied Genetics. 106, 112-117.

Environmental Stresses in Crop Sciences

Genetic variation of bread wheat geneotypes for some important physiological traits under chiling stress

References

References

Volume 11, Issue 1 - Serial Number 24
Open Access Policy
April 2018
Pages 171-183

Genetic variation of bread wheat geneotypes for some important physiological traits under chiling stress

References

References

Volume 11, Issue 1 - Serial Number 24 Open Access PolicyApril 2018Pages 171-183

Volume 11, Issue 1 - Serial Number 24
Open Access Policy
April 2018
Pages 171-183