[Home ] [Archive]   [ فارسی ]  
:: About :: Main :: Current Issue :: Archive :: Search :: Submit :: Contact ::
Main Menu
Home::
Journal Information::
Articles archive::
For Authors::
For Reviewers::
Registration::
Contact us::
Site Facilities::
::
Search in website

Advanced Search
..
Receive site information
Enter your Email in the following box to receive the site news and information.
..



 
..
:: Volume 8, Issue 1 (2021) ::
pgr 2021, 8(1): 133-150 Back to browse issues page
Determination of haplotype variation and relationship between desirable agronomic traits and microsatellite alleles on chromosomes 4B and 7D in bread wheat
Esmaeil Dasturani , Khalil Zaynali Nezhad * , Masood Soltani Najafabadi , Mohammadhadi Pahlevani , Hassan Soltanlo , Saeed Bagherikia
Department of Plant Breeding and Biotechnology, Gorgan University of Agricultural Sciences and Natural Resources, Gorgan, Iran , zaynalinezhad@gau.ac.ir
Abstract:   (10281 Views)
The aim of this study was to determine the haplotype groups and identify the specific alleles associated with desirable agronomic characteristics in bread wheat. For this purpose, 42 local bread wheat genotypes belong to Iran region and nine commercial cultivars along with Chinese Spring variety (reference genotype) were cultivated in the format of augmented design and evaluated based on their 13 phenotypic traits. The results of descriptive statistics showed that awn length and day to flowering had the highest and lowest phenotypic coefficient of variation, respectively. Eight microsatellite markers were used to investigate the haplotype variation of QTLs associated with phenotypic traits located on wheat chromosomes 4B and 7D. The result showed that the genotypes were classified into 13 and 6 haplotype groups according to the allelic comparison with the reference genotype on chromosome 4B and 7D, respectively. In order to investigate the relationship between traits and markers, analysis of variance was performed based on completely randomized design with unequal numbers of replications for each marker. In general, of the 13 traits studied, there was a statistically significant linkage for eight traits and for the three traits, an allele-specific was introduced simultaneously. If the breeders are interested in genotype selection that simultaneously have three desirable characteristics such as early anthesis, semi-dwarfing and a greater number of grains per spike, they can use an allele-specific (153 bp) of Xgwm149-4B marker.
Keywords: Phenotypic traits, Marker-assisted selection, Landrace wheat, Allele-specific marker
Full-Text [PDF 721 kb]   (1466 Downloads)    
Type of Study: Research | Subject: Molecular genetics
References
1. Abri, A., Zaynali Nezhad, K., Alami, M. and Bagherikia S. (2020). Study of haplotype variation and association of microsatellite alleles on chromosome 4B of bread wheat with some agronomic traits. Journal of Crop Breeding, 12(34): 1-14 (In Persian).
2. Bennett, D., Izanloo, A., Reynolds, M., Kuchel, H., Langridge, P. and Schnurbusch, T. (2012a). Genetic dissection of grain yield and physical grain quality in bread wheat (Triticum aestivum L.) under wat-limited environments. Theoretical and Applied Genetics, 125: 255-271.
3. Bennett, D., Reynolds, M., Mullan, D., Izanloo, A., Kuchel, H., Langridge, P. and Schnurbusch, T. (2012b). Detection of two major grain yield QTL in bread wheat (Triticum aestivum L.) under heat, drought and high yield potential environments. Theoretical and Applied Genetics, 125: 1473-1485.
4. Börner, A., Schumann, E., Fürste, A., Cöster, H., Leithold, B., Röder, M. and Weber, W. (2002). Mapping of quantitative trait loci determining agronomic important characters in hexaploid wheat (Triticum aestivum L.). Theoretical and Applied Genetics, 105: 921-936.
5. Breseghello, F. and Sorrells, M.E. (2007). QTL analysis of kernel size and shape in two hexaploid wheat mapping populations. Field Crops Research, 101(2): 172-179.
6. Caviglia, O.P., Sadras, V.O. and Andrade, F.H. (2011). Yield and quality of wheat and soybean in sole-and double-cropping. Agronomy Journal, 103: 1081-1089.
7. Chen, C., Neill, K., Wichman, D. and Westcott, M. (2008). Hard red spring wheat response to row spacing, seeding rate, and nitrogen. Agronomy Journal, 100: 1296-1302.
8. Chen, Z., Cheng, X., Chai, L., Wang, Z., Bian, R., Li, J., Zhao, A., Xin, M., Guo, W., Hu, Z. and Peng, H. (2020). Dissection of genetic factors underlying grain size and fine mapping of QTgw. cau-7D in common wheat (Triticum aestivum L.). Theoretical and Applied Genetics, 133(1): 149-162.
9. Cook, J.P., Blake, N.K., Heo, H.Y., Martin, J.M., Weaver, D.K. and Talbert, L.E. (2017). Phenotypic and haplotype diversity among tetraploid and hexaploid wheat accessions with potentially novel insect resistance genes for wheat stem sawfly. The Plant Genome, 10(1): 1-10.
10. Creste, S., Neto, A.T. and Figueira, A. (2001). Detection of single sequence repeat polymorphisms in denaturing polyacrylamide sequencing gels by silver staining. Plant Molecular Biology Reporter, 19: 299-306.
11. Dakouri, A., McCallum, B.D. and Cloutier, S. (2013). Haplotype diversity and evolutionary history of the Lr34 locus of wheat. Molecular Breeding, 33: 639-655.
12. Denčić, S., Kastori, R., Kobiljski, B. and Duggan, B. (2000). Evaluation of grain yield and its components in wheat cultivars and landraces under near optimal and drought conditions. Euphytica, 113: 43-52.
13. Doyle, J. and Doyle, J. (1987). Genomic plant DNA preparation from fresh tissue-CTAB method. Phytochem Bull, 19: 11-15.
14. Duggan, B., Domitruk, D. and Fowler, D. (2000). Yield component variation in winter wheat grown under drought stress. Canadian Journal of Plant Science, 80: 739-745.
15. Fang, Q., Ma, L., Yu, Q., Ahuja, L., Malone, R. and Hoogenboom, G. (2010). Irrigation strategies to improve the water use efficiency of wheat-maize double cropping systems in North China Plain. Agricultural Water Management, 97: 1165-1174.
16. Farooq, M., Hussain, M. and Siddique, K.H. (2014). Drought stress in wheat during flowering and grain-filling periods. Critical Reviews in Plant Sciences, 33: 331-349.
17. FAO. (2020). Statistics: FAOSTAT - Food and Agriculture Organization. http://fao.org/crop/statistics. Accessed 1 April 2020.
18. Ganeva, G., Korzun, V., Landjeva, S., Tsenov, N. and Atanasova, M. (2005). Identification, distribution and effects on agronomic traits of the semi-dwarfing Rht alleles in Bulgarian common wheat cultivars. Euphytica, 145: 305-315.
19. Gebhardt, C., Ballvora, A., Walkemeier, B., Oberhagemann, P. and Schüler, K. (2004). Assessing genetic potential in germplasm collections of crop plants by marker-trait association: a case study for potatoes with quantitative variation of resistance to late blight and maturity type. Molecular Breeding, 13: 93-102.
20. Gent, M.P. (1995). Canopy light interception, gas exchange, and biomass in reduced height isolines of winter wheat. Crop Science, 35: 1636-1642.
21. Ghaffari, A. and Jalal Kamali, M. (2013). Wheat Productivity in Islamic Republic of Iran: Constraints and opportunities. In: Paroda, R., Dasgupta, S., Mal, B., Singh, S.S., Jat, M.L. and Singh, G., Eds., Proceedings of the Regional Consultation on Improving Wheat Productivity in Asia, PP. 98-111. Bangkok, Thailand.
22. Ghorbani, M.H., Harutyunyan, H., Soltani, A. and KamkarB. (2010). Tillers contribution on wheat yield in rainfed and saline soil in different row spacing and plant density. Journal of Crop Prouduction, 3(4): 125-142 (In Persian).
23. Guo, Y., Sun, J., Zhang, G., Wang, Y., Kong, F., Zhao, Y. and Li, S. (2013). Haplotype, molecular marker and phenotype effects associated with mineral nutrient and grain size traits of TaGS1a in wheat. Field Crops Research, 154: 119-125.
24. Gupta, P.K. and Varshney, R. (2000). The development and use of microsatellite markers for genetic analysis and plant breeding with emphasis on bread wheat. Euphytica, 113: 163-185.
25. Jagadish, K.S., Kishor, P.B.K., Bahuguna, R.N., von Wirén, N. and Sreenivasulu, N. (2015). Staying alive or going to die during terminal senescence-an enigma surrounding yield stability. Frontiers in Plant Science, 6: 1070
26. Jahangirzadeh Khiavi, S., Zamani, Z., Fatahi, M. and Ashourpour, M. (2018). Comparison of chloroplast DNA diversity in some Iranian apple genotypes, commercial cultivars and rootstocks. Plant Genetic Researches; 5(1): 77-86 (In Persian).
27. Kato, K., Miura, H. and Sawada, S. (2000). Mapping QTLs controlling grain yield and its components on chromosome 5A of wheat. Theoretical and Applied Genetics, 101: 1114-1121.
28. Kulwal, P.L., Mir, R.R., Kumar, S. and Gupta, P.K. (2010). QTL analysis and molecular breeding for seed dormancy and pre-harvest sprouting tolerance in bread wheat. Journal of Plant Biology, 37: 59-74.
29. Kumar, N., Kulwal, P., Balyan, H. and Gupta, P. (2007). QTL mapping for yield and yield contributing traits in two mapping populations of bread wheat. Molecular Breeding, 19: 163-177.
30. Lelley, T. and Stachel, M. (1998). Microsatellites can differentiate wheat varieties from different agroecological areas and of different quality. In Proceedings of the 9th International Wheat Genetics Symposium, University of Saskatchewan, Canada.
31. Manifesto, M.M., Schlatter, A.R., Hopp, H.E., Suárez, E.Y. and Dubcovsky, J. (2001). Quantitative evaluation of genetic diversity in wheat germplasm using molecular markers. Crop Science, 41(3): 682-690.
32. McCartney, C., Somers, D., Fedak, G. and Cao, W. (2004). Haplotype diversity at fusarium head blight resistance QTLs in wheat. Theoretical and Applied Genetics, 109: 261-271.
33. Miah, G., Rafii, M.Y., Ismail, M.R., Puteh, A.B., Rahim, H.A., Islam, K.N. and Latif, M.A. (2013). A review of microsatellite markers and their applications in rice breeding programs to improve blast disease resistance. International Journal of Molecular Sciences, 14: 22499-22528.
34. Mir Drikvand, R., Najafian, G., Bihamta, M.R. and Ebrahimi, A. (2015) Detection of QTLs associated to some grain traits in bread wheat (Triticum aestivum L.), using association mapping. Plant Genetic Researches, 1(2): 43-54 (In Persian).
35. Modarresi, M., Mohammadi, V., Zali, A. and Mardi, M. (2010). Response of wheat yield and yield related traits to high temperature. Cereal Research Communications, 38: 23-31.
36. Mohammadi-Nejad, G., Arzani, A., Rezai, A., Singh, R. and Gregorio, G. (2008). Assessment of rice genotypes for salt tolerance using microsatellite markers associated with the saltol QTL. African Journal of Biotechnology, 7(6): 730-736.
37. Moomaw, R., Lesoing, G. and Francis, C. (1991). Two Crops in One Year: Doublecropping. University of Nebraska-Lincoln, Nebraska, USA.
38. Naroui Rad, M.R., Farzanju, M., Fanay, H.R., Arjmandy Nejad, A.R., Ghasemy, A. and Polshekane Pahlevan, M.R. (2006). The study genetic variation and factor analysis for morphological characters of wheat native accessions of Sistan and Baluchistan. Pajouhesh and Sazandegi, 73: 50-57 (In Persian).
39. Nave, M., Avni, R., Ben-Zvi, B., Hale, I. and Distelfeld A. (2016). QTLs for uniform grain dimensions and germination selected during wheat domestication are co-located on chromosome 4B. Theoretical and Applied Genetics, 129(7): 1303-1315.
40. Poehlman, J.M. (2013). Breeding Field Crops. Springer Science & Business Media, New York, USA.
41. Ramya, P., Chaubal, A., Kulkarni, K., Gupta, L., Kadoo, N., Dhaliwal, H.S., Chhuneja, P., Lagu, M. and Gupt, V. (2010). QTL mapping of 1000-kernel weight, kernel length, and kernel width in bread wheat (Triticum aestivum L.). Journal of Applied Genetics, 51(4): 421-429.
42. Röder, M.S., Huang, X.Q. and Börner, A. (2008). Fine mapping of the region on wheat chromosome 7D controlling grain weight. Functional and Integrative Genomics, 8(1): 79-86.
43. Röder, M.S., Korzun, V., Wendehake, K., Plaschke, J., Tixier, M.H., Leroy, P. and Ganal, M.W. (1998). A microsatellite map of wheat. Genetics. 149: 2007-2023.
44. Sardouie-Nasab, S., Mohammadi-Nejad, G. and Zebarjadi, A. (2013). Haplotype analysis of QTLs attributed to salinity tolerance in wheat (Triticum aestivum). Molecular Biology Reports, 40: 4661-4671.
45. Sari, E., Berraies, S., Knox, R.E., Singh, A.K., Ruan, Y., Cuthbert, R.D. and Burt, A.J. (2018). High density genetic mapping of Fusarium head blight resistance QTL in tetraploid wheat. Plos One, 13(10): e0204362.
46. Sharma, R. (1993). Selection for biomass yield in wheat. Euphytica, 70: 35-42.
47. Somers, D.J., Isaac, P. and Edwards, K. (2004). A high-density microsatellite consensus map for bread wheat (Triticum aestivum L.). Theoretical and Applied Genetics, 109: 1105-1114.
48. Song, Q., Shi, J., Singh, S., Fickus, E., Costa, J., Lewis, J., Gill, B., Ward, R. and Cregan, P. (2005). Development and mapping of microsatellite (SSR) markers in wheat. Theoretical and Applied Genetics, 110: 550-560.
49. Spielmeyer, W., McIntosh, R.A., Kolmer, J. and Lagudah, E.S. (2005). Powdery mildew resistance and Lr34/Yr18 genes for durable resistance to leaf and stripe rust cosegregate at a locus on the short arm of chromosome 7D of wheat. Theoretical and Applied Genetics, 111(4): 731-735.
50. Tavala, R., Aalami, A., Sabouri. and Sabouri A. (2015). Evaluation of haplotype and allelic diversity of SSR markers linked to major effect QTL on chromosome 9 controlling drought tolerance in rice. Cereal Research, 5(2): 107-119 (In Persian).
51. Van Slageren, M. (1994). Wild Wheats: A Monograph of Aegilops L. and Amblypyrum (Jaub. & Spach) Eig (Poaceae), 1st. Agricultural University Wageningen, Wageningen, Netherland.
52. Wu, Q.H., Chen, Y.X., Zhou, S.H., Fu, L., Chen, J.J., Xiao, Y., Zhang, D., Ouyang, S.H., Zhao, X.J., Cui, Y. and Zhang, D.Y. (2015). High-density genetic linkage map construction and QTL mapping of grain shape and size in the wheat population Yanda1817× Beinong6. PloS One. 10(2): e0118144.
53. Würschum, T. (2012). Mapping QTL for agronomic traits in breeding populations. Theoretical and Applied Genetics, 125: 201-210.
54. Yao, H., Xie, Q., Xue, S., Luo, J., Lu, J., Kong, Z., Wang, Y., Zhai, W., Lu, N., Wei, R. and Yang, Y. (2019). HL2 on chromosome 7D of wheat (Triticum aestivum L.) regulates both head length and spikelet number. Theoretical and Applied Genetics, 132(6): 1789-1797.
55. Yao, J., Wang, L., Liu, L., Zhao, C. and Zheng, Y. (2009). Association mapping of agronomic traits on chromosome 2A of wheat. Genetica, 137: 67-75.
56. Yin, X., Stam, P., Kropff, M.J. and Schapendonk, A.H. (2003). Crop modeling, QTL mapping, and their complementary role in plant breeding. Agronomy Journal, 95: 90-98.
57. Yu, J.B., Bai, G.H., Cai, S.B. and Ban, T. (2006). Marker-assisted characterization of Asian wheat lines for resistance to Fusarium head blight. Theoretical and Applied Genetics, 113: 308-320.
58. Yu, L.X., Liu, S., Anderson, J.A., Singh, R.P., Jin, Y., Dubcovsky, J., Brown-Guidera, G., Bhavani, S., Morgounov, A. and He, Z. (2010). Haplotype diversity of stem rust resistance loci in uncharacterized wheat lines. Molecular Breeding, 26: 667-680.
59. Zaynali Nezhad, K., Weber, W., Röder, M., Sharma, S., Lohwasser, U., Meyer, R., Saal, B. and Börner, A. (2012). QTL analysis for thousand-grain weight under terminal drought stress in bread wheat (Triticum aestivum L.). Euphytica, 186: 127-138.
Send email to the article author



XML   Persian Abstract   Print


Download citation:
BibTeX | RIS | EndNote | Medlars | ProCite | Reference Manager | RefWorks
Send citation to:

Dasturani E, Zaynali Nezhad K, Soltani Najafabadi M, Pahlevani M, Soltanlo H, Bagherikia S. Determination of haplotype variation and relationship between desirable agronomic traits and microsatellite alleles on chromosomes 4B and 7D in bread wheat. pgr 2021; 8 (1) :133-150
URL: http://pgr.lu.ac.ir/article-1-214-en.html


Rights and permissions
Creative Commons License This work is licensed under a Creative Commons Attribution-NonCommercial 4.0 International License.
Volume 8, Issue 1 (2021) Back to browse issues page
پژوهش های ژنتیک گیاهی Plant Genetic Researches
Persian site map - English site map - Created in 0.08 seconds with 38 queries by YEKTAWEB 4657