Variation of traits is a primary need of any plant breeding effort that involves the natural evolution and causes sustainable crop production under different environments. Fifty six bread wheat genotypes grown during the growing season of 2012/2013 were evaluated for variability characteristics for eighteen traits i.e., stem diameter, plant height, leaf number, leaf length, leaf width, tiller number, internode length, peduncle length, spike length, floret number, spikelet number, grain number, awn length, grain diameter, grain length, number of days to flowering, thousand seed weight and grain yield. Significant differences were observed for all the traits studied, indicating a considerable amount of variation among wheat genotypes for each trait. The estimates of the coefficient of variation (CV) were high for grain yield and number of tillers per plant. Spike length varied from 8.95 in G28 to 4.74 in G40, while genotype G20 had the maximum floret number (19). According to thousand seed weight, genotype G55 had the maximum thousand seed weight (45.57 g) and genotype G4 had the maximum grain yield performance (6936.3 kg ha-1). The information on diversity among the agro-morphological traits of the studied wheat genotypes will be helpful to plant breeders in constructing their breeding materials and implementing selection strategies.

Adhikary S.K., Alam M.Z., Paul N.K. (2009): Variation of grain growth of wheat cultivars. Bangladesh Journal of Agricultural Research, 34: 351–359.

Ali Y., Atta B.M., Akhter J., Monneveux P., Lateef Z. (2008): Genetic variability., association and diversity studies in wheat (Triticum aestivum L.) germplasm. Pakistan Journal of Botany, 40: 2087–2097.

Aliu S., Fetahu S. (2010): Determination on genetic variation for morphological traits and yield components of new winter wheat (Triticum aestivum L.) lines. Notulae Scientia Biologicae, 2: 121–124.

Annicchiarico P., Pecetti L. (1993): Contribution of some agronomic traits to durum wheat performance in a dry Mediterranean region of Northern Syria. Agronomie, 13: 25–34.

Atkinson M., Kettlewell P.S., Poulton P.R., Hollings P.D. (2008): Grain quality in the Broadbalk wheat experiment and the winter North Atlantic oscillation. Journal of Agricultural Science, 146: 541–549.

Austin R.B., Jones H.G. (1975): The physiology of wheat: In Plant Breeding Institute Annual Report-1974. Cambridge UK., Cambridge.

Boerner A., Schumann E., Fuerste A., Coester H., Leithold B., Roeder MS., Weber WE. (2002): Mapping of quantitative trait loci determining agronomic important characters in hexaploid wheat (Triticum aestivum L.). Theoretical and Applied Genetics, 105: 921–936.

Borras L., Slafer G.A., Otegui M.E. (2004): Seed dry weight response to source-sink manipulations in wheat, maize and soybean: a quantitative reappraisal. Field Crops Research, 86: 131–146.

Dwivedi A.N., Pawar I.S., Shashi M., Madan S. (2002): Studies on variability parameters and character association among yield and quality attributing traits in wheat. Haryana Agricultural University Journal of Research, 32: 77–80.

FAOSTAT (2012): FAOSTAT data of Food and Agriculture Organization of the United Nations. http://faostat.fao.org/. Fufa H., Baenziger P.S., Beecher B.S., Graybosch R.A., Eskridge K.M., Nelson L.A. (2005): Genetic improvement trends in agronomic performances and end-use quality characteristics among hard red winter wheat cultivars in Nebraska. Euphytica, 144: 187–198.Gegas V.C., Nazari A., Griffiths S., Simmonds J., Fish L., Orford S., Sayers L., Doonan H.J., Snape W.J. et al. (2010): A genetic framework for grain size and shape variation in wheat. Plant Cell, 22: 1046–1056.

Golabadi M., Arzani A., Maibody S.M.M. (2005): Evaluation of variation among durum wheat F3 families for grain yield and its components under normal and water-stress field conditions. Czech Journal of Genetics and Plant Breeding, 41: 263–267.

Keller M., Karats C.H., Schmid J.E. (1999): Quantitative trait loci for lodging resia segregation wheat×spert population. Theoretical and Applied Genetics, 98: 1171–1182.

Khamssi N.N., Najaphy A. (2012): Agro-morphological and phenological attributes under irrigated and rain-fed conditions in bread wheat genotypes. African Journal of Agricultural Research, 7: 51–57.

Korkut K.Z., Başer I., Bilgin O. (2001): Genotypic and phenotypic variability, heritability and phenotypic correlation for yield and yield components in bread wheat varieties. Acta Agronomica Hungarica, 49: 237–242.

Kumar S., Dwivedi V.K., Tyagi N.K., Kumar S. (2003): Genetic variability in some metric traits and its contribution to yield in wheat (Triticum aestivum L.). Progressive Agriculture, 3: 152–153.

Lammerts van Bueren E.T., van Soest L.J.M., de Groot E.C., Boukema I.W., Osman A.M. (2005): Broadening the genetic base of onion to develop better-adapted varieties for organic farming systems. Euphytica, 146: 125–132.

Mahmood Q., Lei W.D., Qureshi A.S., Khan M.R., Hayat Y., Jilani G., Shamsi I.H., Tajammal M.A., Khan M.D. (2006): Heterosis, correlation and path analysis of morphological and biochemical characters in wheat (Triticum aestivum L. Emp. Thell). Agriculture Journal, 1: 180–185.

Moghadam M., Ehdaie B., Waines J.G. (1997): Genetic variation and interrelationships of agronomic characters in landraces of bread wheat from southeastern Iran. Euphytica, 95: 361–369.

Moragues M., Garcia del Moral L.F., Moralejo M., Royo C. (2006): Yield formation strategies of durum wheat landraces with distinct pattern of dispersal within the Mediterranean basin. I: Yield components. Field Crops Research, 95: 194–205.

Nazem V., Arzani A. (2013): Evaluation of morphological traits diversity in synthetic hexaploid wheat. Journal of Applied Environmental and Biological Sciences, 3: 20–28.

Ortiz-Monasterio J.I., Sayre K.D., Rajaram S., McMahon M. (1997): Genetic progress in wheat yield and nitrogen use efficiency under four Nitrogen rates. Crop Science, 37: 898–904.

Parry M.L., Rosenzweig C., Iglesias A., Livermore M. Fischer G. (2004): Effects of climate change on global food production under SRES emissions and socio-economic scenarios. Global Environmental Change, 14: 53–67.

Pecetti L., Boggini G., Gorham J. (1994): Performance of durum wheat landraces in a Mediterranean environment (eastern Sicily). Euphytica, 80: 191–199.

Peltonen-Sainio P., Kangas A., Salo Y., Jauhiainen L. (2007): Grain number dominates grain weight in temperate cereal yield determination: Evidence based on 30 years of multi-location trials. Field Crops Research, 100: 179–188.

Peymaninia Y., Valizadeh M., Shahryari R. Ahmadizadeh M. (2012): Evaluation of morphophysiological responses of wheat genotypes against drought stress in presence of a Leonardite derived humic fertilizer under greenhouse condition. The Journal of Animal and Plant Sciences, 22: 1142–1149.

Reynolds M.P., Trethowan R., Crossa J., Vargas M., Sayre K.D. (2002): Physiological factors associated with genotype by environment interaction in wheat. Field Crops Research, 75: 139–160.

Sabo M., Bede M., Hardi Ž.U. (2002): Variability of grain yield components of some new winter wheat genotypes (Triticum aestivum L.). Rostilnná Výroba, 48: 230–235.

Subedi K.D., Gregory P.J., Summerfield R.J., Gooding M.J. (2000): Pattern of grain set in boron-deficient and cold-stressed wheat (Triticum aestivum L.). Journal of Agricultural Science, Cambridge, 134: 25–31.

Yang X., Chen X., Ge Q., Li B., Tong Y., Zhang A., Li Z., Kuang T., Lu C. (2006): Tolerance of photosynthesis to photoinhibition, high temperature and drought stress in flag leaves of wheat: A comparison between a hybridization line and its parents grown under field conditions. Plant Science, 171: 389–397.

Zarkti H., Ouabbou H., Udupa S.M.., Gaboun F., Hilali A. (2012): Agro-morphological variability in durum wheat landraces of Morocco. Australian Journal of Crop Science, 6: 1172– 1178.

Zečević V., Knežević V., Bošković D., Mićanović J., Dimitrijević D.B. (2009): Genetic and phenotypic variability of number of spikelets per spike in winter wheat. Kragujevac Journal of Science, 31: 85–90.