Investigation of Correlation and Board Sense Heritability in Tritipyrum Lines under Normal and Drought Stress Conditions

American-Eurasian J. Agric. & Environ. Sci., 3 (): 07-, 03 ISSN 88-6769 IDOSI Publications, 03 DOI: 0.589/idosi.aejaes.03.3.0.333 Investigation of Correlation and Board Sense Heritability in Tritipyrum Lines under Normal and Drought Stress Conditions Maryam Allahdou, Barat Ali Fakheri and Hossein Shahsevand Hassani Department of Plant Breeding and Biotechnology, University of Zabol, Agriculture Faculty, Zabol City, Iran Department of Agronomy and Plant Breeding, University of Kerman, Agriculture Faculty, Kerman City, Iran Abstract: In order to correlation and board sense inheritance was performed experimentally under randomized completely blocked design (RCBD) with two replication in the institute of agriculture and natural resources. Results exhibited that height of flag leaf had positive and significant correlation to height of peduncle, height of stem, height of spike, day to flowering and day to seed beginning. Height of peduncle also had positive and significant correlation to height of stem, height of spike, day to flowering and day to seed beginning under normal conditions. Height of flag leaf to height of out stem from flag leaf, width of flag leaf to width of spike, height of peduncle to height of spike and day to seed beginning had positive and significant correlation under drought stress conditions. Traits such as: width of flag leaf, length of flag leaf, length of stem, day to flowering, number seed per spike and weight of thousand seed had the most heritability and height of peduncle, height of out stem from flag leaf and number of tillering had the lowest heritability under normal conditions. Traits such as: height of spike, day to stem elongation, day to flowering, day to seed beginning, day to maturity, number seed per spike and weight of thousand seed had the most heritability and traits such as: length of flag leaf, height of peduncle, height of plant, height of out stem from flag leaf had the lowest inheritance under stress conditions. Traits such as day to flowering, number seed per spike and weight of thousand seed had the highest board sense inheritance under normal and stress conditions. Therefore these traits that had high inheritance and were stable under both normal and stress conditions should be given more attention for selecting genotypes in breeding program. Key words: Tritipyrum eneral inheritance Phenotypic correlation INTRODUCTION between Triticum durum and Thinopyrum bessarabicum, have been produced which can set seed in at least 50 Wheat (Triticum aestivum L.) as the most important mm NaCl [3]. Shahsevand Hassani et al. [4] studied crop as well as it has specific situation in Iranian food agronomy and morphological traits in tritipyrum lines to and diets. It is reasonable to assume that wheat is compare wheat and triticale. They resulted that tritipyrum predominantly considered as the most important aspects. reaches morphological maturity far later than wheat and Wheat is cultivating about in 8 million hectare around triticale. The late maturity of tritipyrum, which can be the world []. In the last four decades, the incorporation handicap, is compensated by a better adaptation to the of alien genetic material from Thinopyrum into common high temperature in spring and summer in Iran. wheat (Triticum aestivum L. em Thell., AABBDD olestani et al. [5] investigated inheritance of controlling genomes) through wide crosses has increased the genes for some important quantitative traits in crossing genetic diversity in wheat for improvement of disease of Omid bread wheat and la/b tritipyrum primary lines and resistance, drought and salinity tolerance and other traits observed only additive effects and dominant effects in the []. Primary hexaploid tritipyrum lines, amphiploids model for flag leaf length, ear number and own length Corresponding Author: Maryam Allahdou, Department of Plant Breeding and Biotechnology, University of Zabol, Agriculture Faculty, Zabol City, Iran. 07

Am-Euras. J. Agric. & Environ. Sci., 3 (): 07-, 03 traits. Therefore, dominant-additive simple model is The objective of this study was estimation of board sufficient for describing the effects. They also resulted sense heritability in tritipyrum lines under normal and the amount of dominant variance is more than the drought stress conditions and identification traits that additive variance for all reviewed traits so breeding had high inheritance to use in breeding program. methods base on hybridization should be used for the investigated traits. Allahdou [6] studied drought MATERIALS AND METHODS resistance of tritipyrum lines using stress indices and resulted that St/b line which had the highest MP, STI Materials: Plant material used in this study was and MP, had high yield under stress and non-stress tritipyrum lines and one wheat cultivar which named conditions. Shahryari et al. [7] investigated drought Hamoun and was Sistan local and relatively tolerant to resistance and Mitotic instability of tritipyrum compared drought (Table ). Hamoun cultivar was used as control. with triticale and bread wheat. Evaluation of leaf Experiment was conducted based on randomized osmotic and water potentials and drought susceptibility completed block design (RCBD) with replications index showed that drought resistance of tritipyrum and F (because seed deficit could not be have more than genotypes was significantly higher than that of bread replication) under both normal and stress conditions. wheat and triticale. Cytological investigations showed The experiment was carried out in 009-00 at Institute that tritipyrum-derived genotypes aneuploidy was of Natural Resource and Agriculture Researches located significantly higher than Triticale and bread wheat. in Zabol city. Irrigated plots were watered at tillering, The breeders are faced with an array of environments joining, flowering and grain filing stage but non-irrigated in which their breeding program is to achieve results. were watered at tillering and joining. Irrigation was Thus, heritability estimate should be determined for stopped at flowering in non-irrigated plots. optimum breeding program [8]. Estimation of the number of controlling gene of traits, identification of the Parameters Evaluated: During the growing season, inheritance method and the amount of heritability for seven plants were randomly chosen from each plot to every one of the traits can be useful in selecting suitable measure height of flag leaf ( ), width of flag leaf ( ), breeding methods [5]. Pistorale et al. [9], studied enetic height of peduncle ( 3), height of plant ( 4), height of diversity and broad sense heritability in tall wheatgrass (Thinopyrum ponticum). They showed that seed weight Table : Plant materilas used in this study. had a high heritability and was positively correlated with No. Line No. Line seed production (r=0.85). The wide variability observed CistanHamoun wheat 7 Ma/b (St/b) (Cr/b)F3 8 (Ka/b) (Cr/b)F4 between populations for almost all the studied characters 3 (Ka/b) (Cr/b)F 9 La (4B/4D)/b will allow them to be integrated into a single germoplasm 4 (Ka/b) (Cr/b)F3 0 Ka/b or into a genetic pool that could be used in programs 5 (St/b) (Cr/b)F4 La/b aimed at the genetic improvement of tall wheatgrass. 6 Cr/b St/b Table : Correlation coefficient of traits in tritipyrum lines under stress condition. Traits 0 3 4 0.05 0.57-0.66-0.68 0.045-0.585 0.7-0.79 0.495-0.653 0.9-0.776 0.844-0.3 0.30 0.74 0.803-0.76 0.094-0.04-0.9 0.477-0.099 0.59-0.73 0.5 0.9-0.0 0.0974-0.435 0.664-0.459 0.07 0.548-0.654 0.785 0-0.38-0.574 0.3 0.483-0. 0.53-0.79-0.7 0.5-0.4-0.8 0.78-0.05 0.06 0.8-0.95 0.3 0.639 0.806-0.575-0.3 0.69 0.6-0. 0.5-0.73-0. 0.34 0.73 0.667 3 0.0407-0.066 0.8-0.63 0.039 0.043-0.4 0.87 0.693-0.359 0. 0.04 4 0.358-0.045 0.454-0.6 0.03 0.357-0.83-0.48 0.099 0.075 0.05-0.05-0.379 08

Am-Euras. J. Agric. & Environ. Sci., 3 (): 07-, 03 Table 3: Correlation coefficient of traits in tritipyrum lines under normal condition. Traits 0 3 4-0.55 0.86-0.70 0.79 0.408 0.85-0.53 0.057-0.4 0.08 0.785-0.608 0.803 0.588-0.9 0.769 0.445-0.80-0.58 0.4-0.89 0.49-0.506 0.6-0.5-0.67 0.56-0.49 0.58-0.80 0.86-0.4-0.07 0.40-0.33 0.758 0 0.849-0.397 0.783 0.834-0.47 0.536-0.59 0.063-0.094 0.93-0.48 0.87 0.905-0.34 0.76-0.74 0. -0.05 0.96 0.394-0.56 0.43 0.44-0.8 0.46-0.34-0.03-0.85 0.487 0.545 3-0.57 0.33-0.55-0.784-0.474-0.467 0.333 0.436 0.79-0.387-0.568-0.43 4-0.464 0.079-0.07-0.9 0.55-0.43 0.055-0.07 0.9-0.406-0.45-0.44 0.0 Table 4: Variation parameters and board sense inheritance related to investigated traits in tritipyrum lines under normal condition. Trait/ paramters A(0) A(5) hb MST MSE 6669 7847 78.08 48.65 38 86.65 0.65 04.377 476.09 99.84.99 4 0.085 8.485 97.05.43 3.78 0.47 4.4 3.3 960.9 3076.7 70. 59.46.8 7.6 47.66 8.4.68.04 0.09 0.05 0. 9.99 567.74 668.07 47.74 6.77.35 0.0 3.54..4 48.4 0.04 0.006 0.0 0.007 480.87 565.8 6.47 6.63.74 9.37 3.89 0.47 30.30 63.6 0.99 0.63.63 0.368 0 6993.67 39.05 76.59 5.03 39.85 9.88.8 594.53 305.38 64.35.96 4.78 37.75 8.8 3.89 478.9 49.39 4.38.04 36.43.34 3 3.09 330.89 79.03 8.5 6.44 4.6.7 4 0633.7 5.04 98.9 6.4 60.59.84 0.658 p Table 5: Variation parameters and board sense inheritance related to investigated traits in tritipyrum lines under stress condition. Trait/ paramters A(0) A(5) hb MST MSE 6.4 7.7.9 8.5 0.35 8.5 7.8.97.3 7.4 0.05 0.0 0.07 0.004 965.5 35.75 30.98 7.75 5.5 3.5.5 68.9 375.39.5 44. 6.66 448.8 435.48 365.04 49.5 0.436 476.9.08 479 474.84 036.3 9.38 89.3 6.6 5.9.53 0.7 3.47 4.08 93.83 0.0 0.09 0.04 0.003 569.49 670.09.55 8.08 3.4 3.33 4.84 459.8 54.03 77.74 3.37.6 5.99 0.75 0 506.9 5956.49 88.33 3.65 8.84 6.5 3.8 406.7 483. 86.4 7.08 3.4 50.48 3.68 095.47 465.6 9.7.94.94 4.88 3 53.3 80.8 96.79 9.0 8.7 7.74 0.89 4 895.58 9643.4 95.55 48.87 46.69 95.57.7 p stem out of the flag leaf ( 5), height of spike ( 6), width Statistical Analysis: enetic parameters were calculated of spike ( 7), number of tillers per plant ( 8), days to for analysis of variance (ANOVA) based on randomized stem elongation ( 9), days to flowering ( 0), days to completely block design (RCBD). Coefficient of seed beginning ( ), days to maturity ( ), number of correlation and analysis of variance were calculated seed per spike ( 3), weight of thousand seed ( 4). using SAS software version 9. [0]. The genetic, 09

Am-Euras. J. Agric. & Environ. Sci., 3 (): 07-, 03 environmental and genotypic variances were determined, Number of tillering was the most to control through an analysis of variance according to the cultivar and in Ka/b was high. These results shown equations indicated below. two traits late maturity and high tillering from Thinopyrum bessarabicum came into tritipyrum. MSP MSe Shahsevand Hassani et al. [] and King et al. [] g = p= + E E =MS E r indefinitely traits such as late maturity and high tillering reported in tritipyrum. Between single plant per line were The variability coefficients phenotypic, genotypic variation a lot and some lines (Ka/b) did not produce and environmental, board sense heritability and seeds. Ma/b line was similar than control cultivar genetic efficiently w ith content of selection 5 and (Hamoun wheat) the day to maturity. Siahsar et al. [3] 0% were obtained through equations indicated below investigated intra and inter variation in tritipyrum lines [9]. using molecular markers and results of molecular variance analysis shown inter variation is more than intra variation e and due to intra variation pointed chromosome instability CVe = 00 and meiotic unbalanced. Cytological investigation by Shahryari et al. [7] also showed that Tritipyrum-derived P CVP = 00 genotypes aneuploidy was significantly higher than Triticale and bread wheat. Mitotic instability in light grains (000-grains weight < 30 gr) was significantly CV = 00 higher than heavy grains (000-grains weight > 30 gr) in parental and F genotypes. They also resulted that h = aneuploidy had a significant negative correlation with P fertility, grain yield and 000-grains weight in tritipyrum A = Kh p genotypes. Height of flag leaf had positive and significant In these equations CV e, CV P and CV are correlation to height of peduncle, height of plant, height environmental variability coefficient, phenotypic of spike, day to flowering and day to seed beginning and variability coefficient and genetic variability also height of peduncle had positive and significant coefficient respectively. H and A are board correlation to height of plant, height of spike, day to sense heritability and genetic efficiency respectively. flowering and day to seed beginning under normal condition. height of flag leaf to height of out stem from RESULTS AND DISCUSSION flag leaf, width of flag leaf to width of spike, height of peduncle to height of spike and day to seed beginning Analysis of variance under normal condition had positive and significant correlation under stress showed significant different at % level in traits such as conditions. Traits such as: width of flag leaf, height of leaf width, day to flowering, seed number per spike and flag leaf, height of plant, day to flowering, number seed weight of seed thousand and significant different at 5% per spike and weight of thousand seed had the highest level in traits such as stem length, day to stem elongation heritability respectively and height of peduncle, height of and day to seed beginning. Analysis of variance under out stem from flag leaf and number of tillering had the stress condition also showed significant different at % lowest heritability under normal condition. Traits such as: level in traits such as leaf width, spike length, spike width, height of spike, day to stem elongation, day to flowering, day to stem elongation, day to flowering, day to seed day to seed beginning, day to maturity, number seed per beginning, day to maturity, number of seed per spike and spike and weight of thousand seed had the highest weight of seed thousand. Test of mean comparison heritability and traits such as: height of flag leaf, height exhibited significant difference for tritipyrum lines to of peduncle, height of plant, height of out stem from flag control cultivar (Hamoun wheat). Tritipyrum lines had the leaf had the lowest inheritance under stress condition. most different to control cultivar (Hamoun wheat) the day Nevzat et al. [8] estimated the highest heritability in to maturity. protein content and test weight and the lowest 0

Am-Euras. J. Agric. & Environ. Sci., 3 (): 07-, 03 heritability for the grain yield and plant height that 4. Shahsevand Hassani, H., SM. Reader and T. Miler, corresponded to this study. Traits such as day to 005. Agronomical and adaptation characters of flowering, number seed per spike and weight of seed tritipyrum lines in comparison with Triticale and thousand had the highest board sense inheritance under Iranian Wheat. Asian Journal of Plant Sciences, 40: normal and stress conditions. Adaption genes are very -6. important to obtain the stable grain yield across the 5. olestani, M., H. Shahsevand Hassani, environments [8]. Therefore those traits that had high A. Baghizadeh, M. alavi and A. Kazemipour, 0. inheritance and were stable under both normal and stress Estimating the number and inheritance of controlling conditions should be given more attention for selecting genes for some important quantitative traits in genotypes in breeding program. crossing of Omid bread wheat and la/b tritipyrum primary line. African Journal of Agricultural CONCLUSIONS Research, 7(): 38-386. 6. Allahdou, M., 0. Evaluation of resistance to Tritipyrum lines had the most different to control drought in tritipyrum lines using drought tolerance cultivar (Hamoun wheat) the day to maturity. Number of indices. International Research Journal of Applied tillering was the most to control cultivar and in Ka/b was and Basic Sciences, 3(3): 46-465. high. These results shown two traits late maturity and 7. Shahryari, Z., M.T. Assad and H. Shahsavand high tillering from Thinopyrum bessarabicum came Hassani, 0. Drought resistance and Mitotic into tritipyrum. Between single plant per line were iinstability of tritipyrum compared with triticale and variation a lot and some lines (Ka/b) did not produce bread wheat. Not Bot Horti Agrobo, 40(): 70-76. seed. Ma/b line was similar than control cultivar 8. Nevzat, A., M. Zeki and O. Hasan, 00. Estimation of (Hamoun wheat) the day to maturity. Traits such as broad-sense heritability for grain yield and some day to flowering, number seed per spike and weight of agronomic and quality traits of bread wheat thousand seed had the highest board sense inheritance (Triticum aestivum L.). Journal of Food, Agriculture under normal and stress conditions. Therefore the traits and Environment, 8(): 49-4. that had high inheritance and were stable under both 9. Pistorale, S.M., L.A. Abbott and A. Adriana, 008. normal and stress conditions, should be given more enetic diversity and broad sense heritability in tall attention for selecting genotypes in breeding program. wheatgrass (Thinopyrum ponticum). Ciencia e Investigación Agraria, 35(3): 3-8. REFERENCES 0. SAS, Institute, 005. SAS Users uide; SAS/STAT, Version 9.. SAS Inst. Inc., Cary (NC, USA).. holipouri, A., M. Sedghi, S.S. Rauf and. Shahsevand Hassani, H., P.D. Caligari and T.E. Miller, N.M. Nazari, 009. Evaluation of drought tolerance 003. The chromosomal assessment of salt tolerance indices and their relationship with grain yield with substituted Tritipyrum using genomic Flurescent in grain yield in wheat cultivars. Recent Research in situ hybridization (FISH). Iranian J. Biot, : 69-78. Science and Technology, (4): 95-98.. King, I.P., C.N. Law, K.A. Cant, S.E. Orford,. Chen, Q., 005. Detection of alien chromatin S.M. Reader and T.E. Miller, 997. Tritipyrum, a introgression from Thinopyrum into wheat using potential new salt-tolerant cereal. Plant Breeding, S genomic DNA as a probe-a landmark approach for 6: 7-3. Thinopyrum genomic research. Cytog. enome Res. 3. Siahsar, B.A., M. Allahdoo and H. Shahsevand 09: 350-359. Hassani, 0. enetic variation among and within 3. King, I., S.E. Orford, S.M. Reader and T.E. Miler, tritipyrum (Thinopyrum bessarabicum Triticum 996. An assessment of the salt tolerance of wheat / durum) lines using PCR-based molecular markers. Thinopyrum bessarabicum 5Eb addition and Cien. Inv. Agr, 38(): 7-35. substitution lines. Plant Breed, 5: 77-78.