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Review Paper on Approaches in Developing Inbred Lines in Cross-Pollinated Crops

Received: 2 May 2017     Accepted: 17 May 2017     Published: 24 July 2017
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Abstract

Plant breeding aims to constantly develop crop cultivars with improved yields and quality and tolerant to droughts, diseases and pests. Use of genetically improved crop cultivars and better management practices are among the best strategies to increase food production and meet a projected doubling of food demand. Inbred lines are homozygous genotypes produced by repeated selfing with selection over several generations. It is developed and maintained by repeated selfing of selected plants. In cross-pollinated species with strongly expressed self-incompatibility, various techniques are used to overcome the incompatibility. The technique of doubled haploids may be used to produce complete homozygous diploid lines in just 1 year (versus more than 4 years in conventional breeding) by doubling the chromosome complement of haploid cells. Doubled haploidy is and will continue to be a very efficient tool for the production of completely homozygous lines from heterozygous donor plants in a single step. Haploids contain half the chromosome number of somatic cells. Anthers/stigma Contain immature microspores or pollen grains with the haploid (n) chromosome number. If successfully cultured (anther culture), the plantlets resulting will have a haploid genotype. To have maximum genetic variability in the plantlets, breeders usually use anthers from F1 or F2 plants. Usually, the haploid plant is not the goal of anther culture. Rather, the plantlets are diplodized (to produce diploid plants) by using colchicine for chromosome doubling. This strategy yields a highly inbred line that is homozygous at all loci, after just one generation.

Published in Biochemistry and Molecular Biology (Volume 2, Issue 4)
DOI 10.11648/j.bmb.20170204.12
Page(s) 40-45
Creative Commons

This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited.

Copyright

Copyright © The Author(s), 2017. Published by Science Publishing Group

Keywords

Doubled, Haploid, Homozygous, Loci, Inbreeding

References
[1] Sleper, D. A. and Poehlman, J. M. 2006. Breeding Field Crops. 5th Edition. Iowa State Press. Ames, USA.
[2] Acquaah, G. 2007. Principles of plant genetics and breeding. Blackwell Publishing Ltd., 350 Main Street, Malden, M. A., USA.
[3] Brown J., Caligari P. 2008. An introduction to plant breeding. Blackwell Publishing Ltd, Oxford, UK.
[4] Miller, J. K., Herman, E. M., Jahn, M. and Bradford, K. J. 2010. Strategic research, education and policy goals for seed science and crop improvement. Plant Sci. 179:645–652.
[5] Varshney, R. V., Hoisington, D. A. and Tyagi, A. K. 2006. Advances in cereal genomics and applications in crop breeding. Trends Biotechnol 24 490–499.
[6] Eathington, S. R., Crosbie, T. M., Edwards, M. D., Reiter, R. D., Bull, J. K. 2007. Molecular markers in a commercial breeding program. Crop Sci 47 S154–S163.
[7] Mumm, R.H. 2007. Backcross versus forward breeding in the development of transgenic maize hybrids: theory and practice. Crop Sci (Suppl 3) 47 S164–S171.
[8] Gepts, P. 2002. A comparison between crop domestication, classical plant breeding, and genetic engineering. Crop Sci 42: 1780–1790.
[9] Goodman, M. M. 2004. Plant breeding requirements for applied molecular biology. Crop Sci. 44:1913–1914.
[10] Thomas, W. T. B., B. P. Forster, and Gertsson, B. 2003. Doubled haploids in breeding. In: Doubled haploid production in crop plants (Maluszynski, M., K. Kasha, B.P. Forster, and I. Szarejko, eds), pp. 337–350. Kluwer Academic, Dordrecht.
[11] Eder, J. and Chalyk, S. 2002. In vivo haploid induction in maize. Theor. Appl. Genet. 104:703–708.
[12] Sprague, G. F. and Eberhart, S. A. 1977. Corn breeding. In: G. F. Sprague and J. W. Dudley (eds.).
[13] Hallauer, A. R., Carena, M. J. and Miranda, F. J. B. 2010. Quantitative Genetics in Maize Breeding. Springer Science and Business Media, New York.
[14] Nakanishi, T. and Hinata, K. 1973. Effective time for CO2 gas treatment in overcoming self incompatibility in Brassica. Plant and Cell Physiology, Vol. 14, No. 5, (October1973), pp. 873-879, ISSN 0032-0781.
[15] Choo, T. M., Reinbergs, E. and Kasha, K. J. 1985. Use of haploids in breeding barley. Plant Breed Rev. 3:219–252.
[16] O’Donoughue, L. S. and Bennet, M. D. 1994. Comparative responses of tetraploid wheat pollinated with Zea mays L. and HordeumbulbosumL. Theor Appl Genet. 87: 673–680.
[17] Steffenson, B. J., Jin, Y., Rossnagel, B. G., Kao, K. 1995. Genetics of multiple disease resistance in a doubled haploid population of barley. Plant Breed. 114: 50–54.
[18] Maluszynski, M. 2004. Doubled haploid production in crop plants: a manual. Kluwer Academic Publisher, Dordrecht, the Netherlands.
[19] Arzani, A. 2008. Improving salinity tolerance in crop plants: a biotechnological view. In Vitro Cell DevBiol Plant. 44:373–383.
[20] Asins, M. J., Bernet, G. P., Villalta, I. and Carbonell, E.A. 2010.Quality Analysis In Plant Breeding in Molecular Techniques in Crop Improvement In: eds. Jain S.M. and Brar D.S. Springer Science + Business Media B. V.
[21] Messmer, M., Wilboism, K. P., Baier, C., Schäfer, F., Arncken, Ch., Drexler, D. and Hildermann, I. 2012: Techniken Der Pflanzenzüchtung - EineEinschätzungfür den ökologischenLandbau. Rep. Dossier Nr. 2.
[22] Powell, W., Morgante, M., Andre, C., Hanafey, M., Vogel, J., Tingey, S. and Rafalski, A. 1996. The comparison of RFLP, RAPD, AFLP and SSR (microsatellite) markers for germplasm analysis. Mol Breed. 2:225–238.
[23] Horacek, J. Griga, M., Smykal, P. and Hybl, M. 2009. Effect of environmental and genetic factors on the stability of pea (PisumsativumL.) isozyme and DNA markers. Czech J Genet and Plant. 45:57–71.
[24] Lusser, M., Parisi, C., Plan, D. and Rodríguez-Cerezo, E. 2012. Deployment of new biotechnologies in plant breeding. Nat Biotechnol. 30:231–239.
[25] Podlich, D. W., Winkler, C. R. and Cooper, M. 2004. Mapping as you go: an effective approach for marker-assisted selection of complex traits. Crop Sci. 44:1560-1571.
[26] Knapp, S. J. 1998. Marker-assisted selection as a strategy for increasing the probability of selecting superior genotypes. Crop Sci. 38:1164–1174.
[27] Xiao, J. Li, J., Yuan, L., McCough, S. R. and Tanks, S. 1996. Genetic diversity.
[28] NTWG, 2011. Report of the Expert Working Group of the European Commission and the Member States on New Techniques.
[29] AGES, 2013. New plant breeding techniques. RNA-dependent DNA methylation, Reverse Breeding, Grafting. Federal Ministry of Health, Vienna. new plant breeding techniques.
[30] Schaart, J. G. and Visser, R. G. F. 2009. Novel Plant Breeding Techniques - Consequences of new genetic modification-based techniques in comparison to conventional plant breeding. COGEM Research Report number 2009-02. The Netherlands Commission on Genetic Modification.
[31] Wijnker, E., Van Dun, K., De Snoo, C. B., Lelivelt, C. L., Keurentjes, J. J., Naharudin, N. S., Ravi, M., Chan, S. W., De Jong, H. and Dirks, R. 2012. Reverse breeding in Arabidopsis generates homozygous parental lines from a heterozygous plant. Nature Genetics 44, 467-470.
[32] Vogel, B. 2012. Neue Pflanzenzuchtverfahren – Grundlagen für die Klärung offener Fragen bei der rechtlichen Regulierung neuer Pflanzenzuchtverfahren. Bundesamt für Umwelt, Bern.
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    Aliyi Robsa Shuro. (2017). Review Paper on Approaches in Developing Inbred Lines in Cross-Pollinated Crops. Biochemistry and Molecular Biology, 2(4), 40-45. https://doi.org/10.11648/j.bmb.20170204.12

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    ACS Style

    Aliyi Robsa Shuro. Review Paper on Approaches in Developing Inbred Lines in Cross-Pollinated Crops. Biochem. Mol. Biol. 2017, 2(4), 40-45. doi: 10.11648/j.bmb.20170204.12

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    AMA Style

    Aliyi Robsa Shuro. Review Paper on Approaches in Developing Inbred Lines in Cross-Pollinated Crops. Biochem Mol Biol. 2017;2(4):40-45. doi: 10.11648/j.bmb.20170204.12

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  • @article{10.11648/j.bmb.20170204.12,
      author = {Aliyi Robsa Shuro},
      title = {Review Paper on Approaches in Developing Inbred Lines in Cross-Pollinated Crops},
      journal = {Biochemistry and Molecular Biology},
      volume = {2},
      number = {4},
      pages = {40-45},
      doi = {10.11648/j.bmb.20170204.12},
      url = {https://doi.org/10.11648/j.bmb.20170204.12},
      eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.bmb.20170204.12},
      abstract = {Plant breeding aims to constantly develop crop cultivars with improved yields and quality and tolerant to droughts, diseases and pests. Use of genetically improved crop cultivars and better management practices are among the best strategies to increase food production and meet a projected doubling of food demand. Inbred lines are homozygous genotypes produced by repeated selfing with selection over several generations. It is developed and maintained by repeated selfing of selected plants. In cross-pollinated species with strongly expressed self-incompatibility, various techniques are used to overcome the incompatibility. The technique of doubled haploids may be used to produce complete homozygous diploid lines in just 1 year (versus more than 4 years in conventional breeding) by doubling the chromosome complement of haploid cells. Doubled haploidy is and will continue to be a very efficient tool for the production of completely homozygous lines from heterozygous donor plants in a single step. Haploids contain half the chromosome number of somatic cells. Anthers/stigma Contain immature microspores or pollen grains with the haploid (n) chromosome number. If successfully cultured (anther culture), the plantlets resulting will have a haploid genotype. To have maximum genetic variability in the plantlets, breeders usually use anthers from F1 or F2 plants. Usually, the haploid plant is not the goal of anther culture. Rather, the plantlets are diplodized (to produce diploid plants) by using colchicine for chromosome doubling. This strategy yields a highly inbred line that is homozygous at all loci, after just one generation.},
     year = {2017}
    }
    

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    AB  - Plant breeding aims to constantly develop crop cultivars with improved yields and quality and tolerant to droughts, diseases and pests. Use of genetically improved crop cultivars and better management practices are among the best strategies to increase food production and meet a projected doubling of food demand. Inbred lines are homozygous genotypes produced by repeated selfing with selection over several generations. It is developed and maintained by repeated selfing of selected plants. In cross-pollinated species with strongly expressed self-incompatibility, various techniques are used to overcome the incompatibility. The technique of doubled haploids may be used to produce complete homozygous diploid lines in just 1 year (versus more than 4 years in conventional breeding) by doubling the chromosome complement of haploid cells. Doubled haploidy is and will continue to be a very efficient tool for the production of completely homozygous lines from heterozygous donor plants in a single step. Haploids contain half the chromosome number of somatic cells. Anthers/stigma Contain immature microspores or pollen grains with the haploid (n) chromosome number. If successfully cultured (anther culture), the plantlets resulting will have a haploid genotype. To have maximum genetic variability in the plantlets, breeders usually use anthers from F1 or F2 plants. Usually, the haploid plant is not the goal of anther culture. Rather, the plantlets are diplodized (to produce diploid plants) by using colchicine for chromosome doubling. This strategy yields a highly inbred line that is homozygous at all loci, after just one generation.
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Author Information
  • Ethiopian Institute of Agricultural Research (EIAR), Assosa Agricultural Research Center (AsARC), Assosa, Ethiopia

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