Research Article
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Year 2022, Volume: 27 Issue: 2, 256 - 264, 23.12.2022
https://doi.org/10.17557/tjfc.1177457

Abstract

Project Number

201906300105

References

  • Akaike, H. 1977. On entropy maximization principle. In: Krishnaiah P R, eds. Application of statistics, North-Holland, Amsterdam, the Netherlands.
  • Bi, X., X. Shi, S. Ma, F. Han, J. Qi, Q. Li, Z. Wang, G. Zhang and N. Niu. 2013 Genetic analysis of agronomic traits related to yield based on major gene plus polygene model in wheat. Journal of Triticeae Crops 33 (4): 630 – 634. (in Chinese with English abstract)
  • Chen, S.L. 2011. Genetic analysis and mapping of the mutant locus of a dwarf and compact spike mutant NAUH164 from wheat variety Sumai 3. Nanjing Agricultural University, Nanjing. (in Chinese with English abstract)
  • Cui, Y., J.N. Lu, Y.Z. Shi, X.G. Yin and Q.H. Zhang. 2019. Genetic analysis of plant height related traits in Ricinus communis L. with major gene plus polygenes mixed model. Zuo Wu Xue Bao 45 (7): 1111  1118. (in Chinese with English abstract)
  • Cui, C., Q. Lu, Z. Zhao, S. Lu, S. Duan, Y. Yang, Y. Qiao, L. Chen and Y.G. Hu. 2022. The fine mapping of dwarf gene Rht5 in bread wheat and its effects on plant height and main agronomic traits. Planta 255 (6): 1 – 19.
  • Dağüstü N (2008) Combining ability analysis in relation to heterosis for grain yield per spike and agronomic traits in bread wheat (Triticum aestivum L.) Turkish Journal of Field Crops 13(2):49-61.
  • Divashuk, M.G., A.V. Vasilyev, L.A. Bespalova and G.I. Karlov. 2012. Identity of the Rht-11 and Rht-B1e reduced plant height genes. Russ. J. Genet. 48: 761 – 763. (in Russian with English abstract)
  • Du, X., Y. Yan, W. Liu, A. Gao, J. Zhang, X. Li, X. Yang, Y. Che and X. Guo. 2011. Genetic analysis on several important agronomic traits in F2 generation of Mazhamai × Quality. Journal of Triticeae Crops 31 (4): 624 – 629. (in Chinese with English abstract)
  • Duan, S., Z. Zhao, Y. Qiao, C. Cui, A. Morgunov, A.G. Condon, L. Chen and Y.G. Hu. 2020. GAR dwarf gene Rht14 reduced plant height and affected agronomic traits in durum wheat (Triticum durum). Field Crops Res. 248: 1 – 10.
  • Gai, J.Y., Y.M. Zhang and J.K. Wang. 2003. Genetic system of quantitative traits in plants. Science Press, Beijing. (in Chinese)
  • Griffing, B. 1956. Concept of general and specific combining ability in relation to diallel crossing systems. Australian journal of biological sciences 9 (4): 463  493.
  • Gong, Y., S. Wei, Z. Peng, Z. Yang, M. Zhong and J. Zhang. 2021. Genetic study on plant height and its components, partial yield traits in durum wheat ‘ANW16F’. Southwest China Journal of Agricultural Sciences 34: 229  235. (in Chinese with English abstract)
  • Guo, S.Q., H Song, Q.H. Yang, J.F. Gao, X.L. Gao, B.L. Feng and P. Yang. 2021. Analyzing genetic effects for plant height and panicle traits by means of the mixed inheritance model of major genes plus polygenes in foxtail millet. Zhongguo Nong Ye Ke Xue 54 (24): 5177  5193. (in Chinese with English abstract)
  • Halloran, G.M. 1974. Genetic analysis of plant height in wheat. Theor. Appl. Genet. 45 (8): 368 – 375.
  • Istipliler, D., Ilker, E, Tonk, FA, Gizem, C., Tosun M. Line× tester analysis and estimating combining abilities for yield and some yield components in bread wheat. Turkish Journal of Field Crops, 2015. 20(1): 72-77
  • Karagöz, A. and N. Zencirci. 2005. Variation in wheat (Triticum spp.) landraces from different altitudes of three regions of Turkey. Genet. Resour. Crop Evol. 52 (6): 775 – 785.
  • Kaya, Y., Morgounov, A., Keser, M. 2015. Genotype by environment interaction effects on plant height of wheat genotypes carrying rht 8 dwarfing gene. Turkish Journal Of Field Crops. 20 (2), P. 252 -258.
  • Kefi, S., O. Kavuncu, E. Bıyıklı, A. Salantur, M.E. Alyamaç, A.K. Evlice and A. Pehlivan. 2021. Morpho-agronomical and nutritional evaluation of cultivated einkorn wheat (Triticum monococcum L. ssp. monococcum) lines sown in autumn and spring seasons. Asian J. Agric. Food. Sci. 9 (1): 1 – 11.
  • Li, F., X. Chang, Y. Wang, Q. Song, F. Tian and D. Sun. 2013. Genetic analysis of nine important agronomic traits in wheat population of recombinant inbred lines, Journal of Triticeae Crops 33 (1): 23 – 28. (in Chinese with English abstract)
  • Li, L.H., and X.Q. Li. 2006. Standard of Description and Data in Wheat Germplasm Resources. China Agriculture Press, Beijing. (in Chinese)
  • Li, Y.S., D. Hu, J. Nie, K.H. Huang, Y.K. Zhang, Y.L. Zhang, H.Z. She, X.M. Fang, R.W. Ruan and Z.L. Yi. 2018. Genetic analysis of plant height and stem diameter in common buckwheat. Zuo Wu Xue Bao 44 (8): 1185  1195. (in Chinese with English abstract)
  • Lyu, G., X. Jin, Y. Guo, Y. Zhao, Z. Qian, K. Wu and S. Li. 2021. Advances in molecular genetics of wheat plant height, Journal of Plant Genetic Resources, 22 (3): 571 –582. (in Chinese with English abstract)
  • Mo, Y., L.S. Vanzetti, I. Hale, E.J. Spagnolo, F. Guidobaldi, J. Al-Oboudi, N. Odle, S. Pearce, M. Helguera and J. Dubcovsky. 2018. Identification and characterization of Rht25, a locus on chromosome arm 6AS affecting wheat plant height, heading time, and spike development. Theor. Appl. Genet. 131(10): 2021 – 2035.
  • Öztürk, A.E., S.A. Ekinci, S. Kodaz and M. Aydin. 2021. Agronomic Performance of the alternative cereal species in the highest plain of Turkey. Tarim Bilim. Derg. 27 (2): 195 – 203.
  • Peng, Z.S., X. Li, Z.J. Yang and M.L. Liao. 2011. A new reduced height gene found in the tetraploid semi-dwarf wheat landrace Aiganfanmai. Genet. Mol. Res. 10 (4): 2349 – 2357.
  • Rebetzke, G.J., M.H. Ellis, D.G. Bonnett, B. Mickelson, A.G. Condon and R.A. Richards. 2012. Height reduction and agronomic performance for selected gibberellin-responsive dwarfing genes in bread wheat (Triticum aestivum L.). Field Crops Res. 126: 87 – 96.
  • Ren, Y., S. Wang, M. Shao, L. Sun, L. Huang, K. Zhao, X. Xu, J. Wang, W. Feng and L. Wang. 2016. QTL мapping аnalysis for plant height traits in wheat under different water environments. Shandong Agricultural Science 48 (9): 10 − 16. (in Chinese with English abstract)
  • Ripberger, E.I., N.A. Bome and D. Trautz. 2015. Variability of the height of plants of hybrid forms of spring common wheat (Triticum aestivum L.) under different ecological and geographical conditions. Vavilovskii Zhurnal Genetiki i Selektsii 19 (2): 185 – 190. (in Russian with English abstract)
  • Samofalov, A.P., S.V. Podgorny, O.V. Skripka and V.L. Chernova. 2020. The study of the trait “plant height” in winter bread wheat in the south of the Rostov region. Grain Economy of Russia 2 (68): 18 – 22. (in Russian with English abstract)
  • Seifolahpour, B., S. Bahraminejad and K. Cheghamirza. 2017. Genetic diversity of einkorn wheat (Triticum boeoticum Boiss.) accessions from the central Zagros Mountains. Zemdirbyste-Agriculture 104 (1): 23 – 30.
  • Sukhikh, I.S., V.J. Vavilova, A.G. Blinov and N.P. Goncharov. 2021. Diversity and phenotypical effect of the allele variants of dwarfing Rht genes in wheat. Russ. J. Genet. 57 (2): 127 – 139. (in Russian with English abstract)
  • Tian, X.L., W.E. Wen, L. Xie, L.P. Fu, D.A. Xu, C. Fu, D.S. Wang, X.M. Chen, X.C. Xia, Q.J. Chen, Z.H. He and S.H. Cao. 2017. Molecular mapping of reduced plant height gene Rht24 in bread wheat. Front. Plant Sci. 8: 1 – 9.
  • Volkova, L.V. 2016. Productivity of spring wheat and its relation to elements of yield structure in years differ by meteorological conditions. Agricultural Science Euro-North-East 6 (55): 9 – 15. (in Russian with English abstract)
  • Wang, J.T., Y.W. Zhang, Y.W. Du, W.L. Ren, H.F. Li, W.X. Sun, C. Ge and Y.M. Zhang. 2022. SEA v2.0: an R software package for mixed major genes plus polygenes inheritance analysis of quantitative traits. Zuo Wu Xue Bao 48 (6): 1416  1424. (in Chinese with English abstract)
  • Wen, M., D. Li, F. Hu, C. Chen and C. Qu. 2018. Genetic model analysis on yield-related traits in wheat F2 population of Ningmai 9 × Zhenmai 168, Journal of Triticeae Crops 38 (4): 386 – 394. (in Chinese with English abstract)
  • Wu, Y., L. Tang, G. Qiu, R Li, W. Wang, L. Zhao and Y. Zhang. 2022. Genetic pattern analysis of the height main gene and multigene of a dwarf maize. Journal of Sichuan Agricultural University 40 (3): 353  361. (in Chinese with English abstract)
  • Wu, X.S., Z.H. Wang, X.P. Chang and R.L. Jing. 2008. Dynamics of drought resistance based on drought stress coefficient derived from plant height in wheat development. Zuo Wu Xue Bao 34 (11): 2010 − 2018. (in Chinese with English abstract)
  • Xie, S.F., W.Q. Ji, Y.Y. Zhang, J.J. Zhang, W.G. Hu, J. Li, C.Y. Wang, H. Zhang and C.H. Chen. 2020. Genetic effects of important yield traits analyzed by mixture model of major gene plus polygene in wheat, Zuo Wu Xue Bao 46 (3): 365  384. (in Chinese with English abstract)
  • Xue, F., C. Li, Y. Chen, Y. Yan and Q. An. 2011. Genetics analysis of several quantitative characteristics of doubled haploid population in wheat. Acta Agriculturae Boreali-occidentalis Sinica 20 (6): 80 – 83. (in Chinese with English abstract)
  • Yan, J. and S. Zhang. 2017. Effects of dwarfing genes on water use efficiency of bread wheat. Front. Agr. Sci. Eng. 4 (2): 126 – 134.
  • Yang, Z.Y., C.Y. Liu, Y.Y. Du, L. Chen, Y.F. Chen and Y.G. Hu. 2007. Dwarfing gene Rht18 from tetraploid wheat responds to exogenous GA3 in hexaploid wheat. Cereal Res. Commun. 45: 23 – 34. Yao, J., L. Ren, P. Zhang, X. Yang, H. Ma, G. Yao, P. Zhang and M. Zhou. 2011. Genetic and correlation analysis of plant height and its components in wheat. Journal of Triticeae Crops 31 (4): 604 – 610. (in Chinese with English abstract)
  • Ye, Y., M. Li, Y. Liu, J. Chen, D. Yang, L. Hu, T. Lü, D. Jiao and S. Chai. 2015. QTL mapping and QTL × environmental interactions for plant height in wheat. Acta Agriculturae Boreali-Sinica 30 (5): 83 − 91. (in Chinese with English abstract)
  • Zakharova, N.N., N.G. Zakharov and М.N. Garanin. 2020. Plant height of winter soft wheat in connection with its crop yield and lodging resistance in forest steppe of middle Volga. Vestnik of Ulyanovsk state agricultural academy 1: 51 – 59. (in Russian with English abstract)
  • Zhang, G.H., D.L. Yang, M.F. Li, X.M. Li, S.L. Ni and H. Xing. 2012. Genetic analysis of QTL mapping for developmental behaviors of plant height and QTL × water regimes interactions in wheat (Triticum aestivum L.). Journal of Agricultural Biotechnology 20 (9): 996 − 1008. (in Chinese with English abstract)
  • Zhong, M., S. Wei, Y. Gong, J. Zhang, Z. Yang and Z. Peng. 2020. Genetic analysis of plant height and internode length of durum wheat ANW16G. Journal of China West Normal University (Natural Sciences). 41 (1): 35  41+ 64. (in Chinese)

INHERITANCE OF PLANT HEIGHT IN EINKORN WHEAT BY RESULTS OF SEGREGATION ANALYSIS

Year 2022, Volume: 27 Issue: 2, 256 - 264, 23.12.2022
https://doi.org/10.17557/tjfc.1177457

Abstract

The genetic control of plant height – important trait associated with yield – is practically not studied in diploid wheats. In this paper, using reciprocal crosses between two Triticum monococcum accessions – var. monococcum (UA0300311) and var. nigricultum (UA0300282) in autumn and spring sowing, inheritance of the plant height is studied. The sowing period significantly affects the expression of einkorn plant height. Data from the generations P1, P2, F1, F2 were used for segregation analysis. For a combination of UA0300311 × UA0300282, the optimal models for plant height inheritance are: at autumn sowing – one main gene with a negative complete dominant effect, its additive effect is –8.05; at spring sowing – one main gene with an additive-dominant effect, its additive effect is –24.51. For the reciprocal combination UA0300282 × UA0300311, at autumn sowing, the optimal model of plant height was one main gene with an equal additive-dominant effect, it additive effect is 10.94; at spring sowing – one main gene with a negative complete dominant effect, its additive effect is –18.37. The heritability was in all cases from 96.52% to 99.70%. The high dispersion of the trait in the second hybrid generation suggests that the studied parental forms differ not only in the main gene, as follows from the results of segregation analysis, but also in the system of modifier genes with a weak effect.

Supporting Institution

China Scholarship Council

Project Number

201906300105

Thanks

We express our deep gratitude to the Professor Zhang Yuan-Ming and PhD student Wang Jing-Tian of Huazhong Agricultural University for the invaluable help in using the SEA v2.0 software and data processing.

References

  • Akaike, H. 1977. On entropy maximization principle. In: Krishnaiah P R, eds. Application of statistics, North-Holland, Amsterdam, the Netherlands.
  • Bi, X., X. Shi, S. Ma, F. Han, J. Qi, Q. Li, Z. Wang, G. Zhang and N. Niu. 2013 Genetic analysis of agronomic traits related to yield based on major gene plus polygene model in wheat. Journal of Triticeae Crops 33 (4): 630 – 634. (in Chinese with English abstract)
  • Chen, S.L. 2011. Genetic analysis and mapping of the mutant locus of a dwarf and compact spike mutant NAUH164 from wheat variety Sumai 3. Nanjing Agricultural University, Nanjing. (in Chinese with English abstract)
  • Cui, Y., J.N. Lu, Y.Z. Shi, X.G. Yin and Q.H. Zhang. 2019. Genetic analysis of plant height related traits in Ricinus communis L. with major gene plus polygenes mixed model. Zuo Wu Xue Bao 45 (7): 1111  1118. (in Chinese with English abstract)
  • Cui, C., Q. Lu, Z. Zhao, S. Lu, S. Duan, Y. Yang, Y. Qiao, L. Chen and Y.G. Hu. 2022. The fine mapping of dwarf gene Rht5 in bread wheat and its effects on plant height and main agronomic traits. Planta 255 (6): 1 – 19.
  • Dağüstü N (2008) Combining ability analysis in relation to heterosis for grain yield per spike and agronomic traits in bread wheat (Triticum aestivum L.) Turkish Journal of Field Crops 13(2):49-61.
  • Divashuk, M.G., A.V. Vasilyev, L.A. Bespalova and G.I. Karlov. 2012. Identity of the Rht-11 and Rht-B1e reduced plant height genes. Russ. J. Genet. 48: 761 – 763. (in Russian with English abstract)
  • Du, X., Y. Yan, W. Liu, A. Gao, J. Zhang, X. Li, X. Yang, Y. Che and X. Guo. 2011. Genetic analysis on several important agronomic traits in F2 generation of Mazhamai × Quality. Journal of Triticeae Crops 31 (4): 624 – 629. (in Chinese with English abstract)
  • Duan, S., Z. Zhao, Y. Qiao, C. Cui, A. Morgunov, A.G. Condon, L. Chen and Y.G. Hu. 2020. GAR dwarf gene Rht14 reduced plant height and affected agronomic traits in durum wheat (Triticum durum). Field Crops Res. 248: 1 – 10.
  • Gai, J.Y., Y.M. Zhang and J.K. Wang. 2003. Genetic system of quantitative traits in plants. Science Press, Beijing. (in Chinese)
  • Griffing, B. 1956. Concept of general and specific combining ability in relation to diallel crossing systems. Australian journal of biological sciences 9 (4): 463  493.
  • Gong, Y., S. Wei, Z. Peng, Z. Yang, M. Zhong and J. Zhang. 2021. Genetic study on plant height and its components, partial yield traits in durum wheat ‘ANW16F’. Southwest China Journal of Agricultural Sciences 34: 229  235. (in Chinese with English abstract)
  • Guo, S.Q., H Song, Q.H. Yang, J.F. Gao, X.L. Gao, B.L. Feng and P. Yang. 2021. Analyzing genetic effects for plant height and panicle traits by means of the mixed inheritance model of major genes plus polygenes in foxtail millet. Zhongguo Nong Ye Ke Xue 54 (24): 5177  5193. (in Chinese with English abstract)
  • Halloran, G.M. 1974. Genetic analysis of plant height in wheat. Theor. Appl. Genet. 45 (8): 368 – 375.
  • Istipliler, D., Ilker, E, Tonk, FA, Gizem, C., Tosun M. Line× tester analysis and estimating combining abilities for yield and some yield components in bread wheat. Turkish Journal of Field Crops, 2015. 20(1): 72-77
  • Karagöz, A. and N. Zencirci. 2005. Variation in wheat (Triticum spp.) landraces from different altitudes of three regions of Turkey. Genet. Resour. Crop Evol. 52 (6): 775 – 785.
  • Kaya, Y., Morgounov, A., Keser, M. 2015. Genotype by environment interaction effects on plant height of wheat genotypes carrying rht 8 dwarfing gene. Turkish Journal Of Field Crops. 20 (2), P. 252 -258.
  • Kefi, S., O. Kavuncu, E. Bıyıklı, A. Salantur, M.E. Alyamaç, A.K. Evlice and A. Pehlivan. 2021. Morpho-agronomical and nutritional evaluation of cultivated einkorn wheat (Triticum monococcum L. ssp. monococcum) lines sown in autumn and spring seasons. Asian J. Agric. Food. Sci. 9 (1): 1 – 11.
  • Li, F., X. Chang, Y. Wang, Q. Song, F. Tian and D. Sun. 2013. Genetic analysis of nine important agronomic traits in wheat population of recombinant inbred lines, Journal of Triticeae Crops 33 (1): 23 – 28. (in Chinese with English abstract)
  • Li, L.H., and X.Q. Li. 2006. Standard of Description and Data in Wheat Germplasm Resources. China Agriculture Press, Beijing. (in Chinese)
  • Li, Y.S., D. Hu, J. Nie, K.H. Huang, Y.K. Zhang, Y.L. Zhang, H.Z. She, X.M. Fang, R.W. Ruan and Z.L. Yi. 2018. Genetic analysis of plant height and stem diameter in common buckwheat. Zuo Wu Xue Bao 44 (8): 1185  1195. (in Chinese with English abstract)
  • Lyu, G., X. Jin, Y. Guo, Y. Zhao, Z. Qian, K. Wu and S. Li. 2021. Advances in molecular genetics of wheat plant height, Journal of Plant Genetic Resources, 22 (3): 571 –582. (in Chinese with English abstract)
  • Mo, Y., L.S. Vanzetti, I. Hale, E.J. Spagnolo, F. Guidobaldi, J. Al-Oboudi, N. Odle, S. Pearce, M. Helguera and J. Dubcovsky. 2018. Identification and characterization of Rht25, a locus on chromosome arm 6AS affecting wheat plant height, heading time, and spike development. Theor. Appl. Genet. 131(10): 2021 – 2035.
  • Öztürk, A.E., S.A. Ekinci, S. Kodaz and M. Aydin. 2021. Agronomic Performance of the alternative cereal species in the highest plain of Turkey. Tarim Bilim. Derg. 27 (2): 195 – 203.
  • Peng, Z.S., X. Li, Z.J. Yang and M.L. Liao. 2011. A new reduced height gene found in the tetraploid semi-dwarf wheat landrace Aiganfanmai. Genet. Mol. Res. 10 (4): 2349 – 2357.
  • Rebetzke, G.J., M.H. Ellis, D.G. Bonnett, B. Mickelson, A.G. Condon and R.A. Richards. 2012. Height reduction and agronomic performance for selected gibberellin-responsive dwarfing genes in bread wheat (Triticum aestivum L.). Field Crops Res. 126: 87 – 96.
  • Ren, Y., S. Wang, M. Shao, L. Sun, L. Huang, K. Zhao, X. Xu, J. Wang, W. Feng and L. Wang. 2016. QTL мapping аnalysis for plant height traits in wheat under different water environments. Shandong Agricultural Science 48 (9): 10 − 16. (in Chinese with English abstract)
  • Ripberger, E.I., N.A. Bome and D. Trautz. 2015. Variability of the height of plants of hybrid forms of spring common wheat (Triticum aestivum L.) under different ecological and geographical conditions. Vavilovskii Zhurnal Genetiki i Selektsii 19 (2): 185 – 190. (in Russian with English abstract)
  • Samofalov, A.P., S.V. Podgorny, O.V. Skripka and V.L. Chernova. 2020. The study of the trait “plant height” in winter bread wheat in the south of the Rostov region. Grain Economy of Russia 2 (68): 18 – 22. (in Russian with English abstract)
  • Seifolahpour, B., S. Bahraminejad and K. Cheghamirza. 2017. Genetic diversity of einkorn wheat (Triticum boeoticum Boiss.) accessions from the central Zagros Mountains. Zemdirbyste-Agriculture 104 (1): 23 – 30.
  • Sukhikh, I.S., V.J. Vavilova, A.G. Blinov and N.P. Goncharov. 2021. Diversity and phenotypical effect of the allele variants of dwarfing Rht genes in wheat. Russ. J. Genet. 57 (2): 127 – 139. (in Russian with English abstract)
  • Tian, X.L., W.E. Wen, L. Xie, L.P. Fu, D.A. Xu, C. Fu, D.S. Wang, X.M. Chen, X.C. Xia, Q.J. Chen, Z.H. He and S.H. Cao. 2017. Molecular mapping of reduced plant height gene Rht24 in bread wheat. Front. Plant Sci. 8: 1 – 9.
  • Volkova, L.V. 2016. Productivity of spring wheat and its relation to elements of yield structure in years differ by meteorological conditions. Agricultural Science Euro-North-East 6 (55): 9 – 15. (in Russian with English abstract)
  • Wang, J.T., Y.W. Zhang, Y.W. Du, W.L. Ren, H.F. Li, W.X. Sun, C. Ge and Y.M. Zhang. 2022. SEA v2.0: an R software package for mixed major genes plus polygenes inheritance analysis of quantitative traits. Zuo Wu Xue Bao 48 (6): 1416  1424. (in Chinese with English abstract)
  • Wen, M., D. Li, F. Hu, C. Chen and C. Qu. 2018. Genetic model analysis on yield-related traits in wheat F2 population of Ningmai 9 × Zhenmai 168, Journal of Triticeae Crops 38 (4): 386 – 394. (in Chinese with English abstract)
  • Wu, Y., L. Tang, G. Qiu, R Li, W. Wang, L. Zhao and Y. Zhang. 2022. Genetic pattern analysis of the height main gene and multigene of a dwarf maize. Journal of Sichuan Agricultural University 40 (3): 353  361. (in Chinese with English abstract)
  • Wu, X.S., Z.H. Wang, X.P. Chang and R.L. Jing. 2008. Dynamics of drought resistance based on drought stress coefficient derived from plant height in wheat development. Zuo Wu Xue Bao 34 (11): 2010 − 2018. (in Chinese with English abstract)
  • Xie, S.F., W.Q. Ji, Y.Y. Zhang, J.J. Zhang, W.G. Hu, J. Li, C.Y. Wang, H. Zhang and C.H. Chen. 2020. Genetic effects of important yield traits analyzed by mixture model of major gene plus polygene in wheat, Zuo Wu Xue Bao 46 (3): 365  384. (in Chinese with English abstract)
  • Xue, F., C. Li, Y. Chen, Y. Yan and Q. An. 2011. Genetics analysis of several quantitative characteristics of doubled haploid population in wheat. Acta Agriculturae Boreali-occidentalis Sinica 20 (6): 80 – 83. (in Chinese with English abstract)
  • Yan, J. and S. Zhang. 2017. Effects of dwarfing genes on water use efficiency of bread wheat. Front. Agr. Sci. Eng. 4 (2): 126 – 134.
  • Yang, Z.Y., C.Y. Liu, Y.Y. Du, L. Chen, Y.F. Chen and Y.G. Hu. 2007. Dwarfing gene Rht18 from tetraploid wheat responds to exogenous GA3 in hexaploid wheat. Cereal Res. Commun. 45: 23 – 34. Yao, J., L. Ren, P. Zhang, X. Yang, H. Ma, G. Yao, P. Zhang and M. Zhou. 2011. Genetic and correlation analysis of plant height and its components in wheat. Journal of Triticeae Crops 31 (4): 604 – 610. (in Chinese with English abstract)
  • Ye, Y., M. Li, Y. Liu, J. Chen, D. Yang, L. Hu, T. Lü, D. Jiao and S. Chai. 2015. QTL mapping and QTL × environmental interactions for plant height in wheat. Acta Agriculturae Boreali-Sinica 30 (5): 83 − 91. (in Chinese with English abstract)
  • Zakharova, N.N., N.G. Zakharov and М.N. Garanin. 2020. Plant height of winter soft wheat in connection with its crop yield and lodging resistance in forest steppe of middle Volga. Vestnik of Ulyanovsk state agricultural academy 1: 51 – 59. (in Russian with English abstract)
  • Zhang, G.H., D.L. Yang, M.F. Li, X.M. Li, S.L. Ni and H. Xing. 2012. Genetic analysis of QTL mapping for developmental behaviors of plant height and QTL × water regimes interactions in wheat (Triticum aestivum L.). Journal of Agricultural Biotechnology 20 (9): 996 − 1008. (in Chinese with English abstract)
  • Zhong, M., S. Wei, Y. Gong, J. Zhang, Z. Yang and Z. Peng. 2020. Genetic analysis of plant height and internode length of durum wheat ANW16G. Journal of China West Normal University (Natural Sciences). 41 (1): 35  41+ 64. (in Chinese)
There are 45 citations in total.

Details

Primary Language English
Subjects Botany
Journal Section Articles
Authors

Hao Fu This is me 0000-0003-3791-7958

роман богуславський 0000-0003-3145-4788

Liubov Atramentova This is me 0000-0002-7143-9411

Project Number 201906300105
Publication Date December 23, 2022
Published in Issue Year 2022 Volume: 27 Issue: 2

Cite

APA Fu, H., богуславський, р., & Atramentova, L. (2022). INHERITANCE OF PLANT HEIGHT IN EINKORN WHEAT BY RESULTS OF SEGREGATION ANALYSIS. Turkish Journal Of Field Crops, 27(2), 256-264. https://doi.org/10.17557/tjfc.1177457
AMA Fu H, богуславський р, Atramentova L. INHERITANCE OF PLANT HEIGHT IN EINKORN WHEAT BY RESULTS OF SEGREGATION ANALYSIS. TJFC. December 2022;27(2):256-264. doi:10.17557/tjfc.1177457
Chicago Fu, Hao, роман богуславський, and Liubov Atramentova. “INHERITANCE OF PLANT HEIGHT IN EINKORN WHEAT BY RESULTS OF SEGREGATION ANALYSIS”. Turkish Journal Of Field Crops 27, no. 2 (December 2022): 256-64. https://doi.org/10.17557/tjfc.1177457.
EndNote Fu H, богуславський р, Atramentova L (December 1, 2022) INHERITANCE OF PLANT HEIGHT IN EINKORN WHEAT BY RESULTS OF SEGREGATION ANALYSIS. Turkish Journal Of Field Crops 27 2 256–264.
IEEE H. Fu, р. богуславський, and L. Atramentova, “INHERITANCE OF PLANT HEIGHT IN EINKORN WHEAT BY RESULTS OF SEGREGATION ANALYSIS”, TJFC, vol. 27, no. 2, pp. 256–264, 2022, doi: 10.17557/tjfc.1177457.
ISNAD Fu, Hao et al. “INHERITANCE OF PLANT HEIGHT IN EINKORN WHEAT BY RESULTS OF SEGREGATION ANALYSIS”. Turkish Journal Of Field Crops 27/2 (December 2022), 256-264. https://doi.org/10.17557/tjfc.1177457.
JAMA Fu H, богуславський р, Atramentova L. INHERITANCE OF PLANT HEIGHT IN EINKORN WHEAT BY RESULTS OF SEGREGATION ANALYSIS. TJFC. 2022;27:256–264.
MLA Fu, Hao et al. “INHERITANCE OF PLANT HEIGHT IN EINKORN WHEAT BY RESULTS OF SEGREGATION ANALYSIS”. Turkish Journal Of Field Crops, vol. 27, no. 2, 2022, pp. 256-64, doi:10.17557/tjfc.1177457.
Vancouver Fu H, богуславський р, Atramentova L. INHERITANCE OF PLANT HEIGHT IN EINKORN WHEAT BY RESULTS OF SEGREGATION ANALYSIS. TJFC. 2022;27(2):256-64.

Turkish Journal of Field Crops is published by the Society of Field Crops Science and issued twice a year.
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