Plant breeding, genetics, and genetic engineering all benefit from the use of doubled haploids technology. For genetic mapping of complicated phenotypes, the doubled haploid technique is a useful tool. To make doubled haploids, haploid cells (which are genetically unstable in the first place) can duplicate their genome at any point during their growth, resulting in diploid cells that don't require any additional therapies. The use of doubled haploidy in breeding is influenced by a variety of circumstances. Doubled haploids (DHs) are exploited in a variety of ways, depending on available technologies and species. In horticultural crops that are perennial in nature, outcrossing with inbreeding depression, or have high economic value where breeding time is critical, doubled haploids are gaining popularity as a powerful approach for enhancing genetic gain per cycle. For various reasons, the current methods for producing haploids and doubled haploids are primarily focused on the rapid generation of pure lines to speed hybrid seed production or CMS conversion, as well as the production of di-haploids to simplify breeding operations, such as in the case of potatoes. These approaches involve using methods based primarily on in vitro culture, in vivo induction of haploid development, or a combination of the two to make haploid embryos in vivo and then rescue them in vitro. Generally the aim of this review paper is to assess the technology of haploids, double haploids and their role in modern crop improvement program.
Published in | Journal of Plant Sciences (Volume 10, Issue 2) |
DOI | 10.11648/j.jps.20221002.14 |
Page(s) | 71-75 |
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), 2022. Published by Science Publishing Group |
Haploids, Double Haploids, Plant Breeding, Crop, Genetics
[1] | Badu, M., Tripathy, B., Sahu, G. S. and Jena, A. K., 2017. Role of doubled haploids in vegetable crop improvement. Journal of Pharmacognosy and Phytochemistry, 6 (6), pp. 384-389. |
[2] | Li, H., Singh, R. P., Braun, H. J., Pfeiffer, W. H. and Wang, J., 2013. Doubled haploids versus conventional breeding in CIMMYT wheat breeding programs. Crop Science, 53 (1), pp. 74-83. |
[3] | Seguí-Simarro, J. M., Jacquier, N. and Widiez, T., 2021. Overview of in vitro and in vivo doubled haploid technologies. In Doubled Haploid Technology (pp. 3-22). Humana, New York, NY. |
[4] | Forster, B. P., Heberle-Bors, E., Kasha, K. J. and Touraev, A., 2007. The resurgence of haploids in higher plants. Trends in plant science, 12 (8), pp. 368-375. |
[5] | Acquaah, G., 2009. Principles of plant genetics and breeding. John Wiley & Sons. |
[6] | Sala, K. and Kurczynska, E., 2015. Plant responses to a grafting process on the example of Arabidopsis thaliana hypocotyl during in vitro culture. BioTechnologia. Journal of Biotechnology Computational Biology and Bionanotechnology, 96 (1). |
[7] | Germana, M. A., 2011. Gametic embryogenesis and haploid technology as valuable support to plant breeding. Plant cell reports, 30 (5), pp. 839-857. |
[8] | Gupta, P. K., Kumar, J., Mir, R. R. and Kumar, A., 2010. 4 Marker-assisted selection as a component of conventional plant breeding. Plant breeding reviews, 33, p. 145. |
[9] | Karjee, S., Mahapatra, S., Singh, D., Saha, K. and Viswakarma, P. K., 2020. Production of double haploids in ornamental crops. Journal of Pharmacognosy and Phytochemistry, 9 (4), pp. 555-565. |
[10] | Murovec, J. and Bohanec, B., 2011. Haploids and doubled haploids in plant breeding. Plant Breeding, Dr. Ibrokhim Abdurakhmonov (Ed.). –2012. –Р, pp. 87-106. |
[11] | Grant, V., 1958, January. The regulation of recombination in plants. In Cold Spring Harbor Symposia on Quantitative Biology (Vol. 23, pp. 337-363). Cold Spring Harbor Laboratory Press. |
[12] | Tefera, A., 2017. Review on concept and impact of double haploid techniques in crop improvement. Jour. of Natural Sci. Research, 7, p. 23. |
[13] | Baenziger, P. S., 1996. Reflections on doubled haploids in plant breeding. In In vitro haploid production in higher plants (pp. 35-48). Springer, Dordrecht. |
[14] | Forster, B. P. and Thomas, W. T., 2005. Doubled haploids in genetics and plant breeding. Plant Breed Rev, 25 (57-88). |
[15] | Chaikam, V. and Prasanna, B. M., 2020. Doubled Haploid Technology for Rapid and Efficient Maize Breeding. In Accelerated Plant Breeding, Volume 1 (pp. 257-292). Springer, Cham. |
[16] | Slusarkiewicz-Jarzina, A., Ponitka, A., Pudelska, H. and Wozna, J., 2015. Comparison of the efficiency of haploid and doubled haploid induction in anther cultures of winter and spring forms of triticale (× Triticosecale Wittm.). BioTechnologia. Journal of Biotechnology Computational Biology and Bionanotechnology, 96 (1). |
[17] | Maluszynski, M., Kasha, K., Forster, B. P. and Szarejko, I. eds., 2003. Doubled haploid production in crop plants: a manual. Springer Science & Business Media. |
[18] | Matzk, F. and Mahn, A., 1994. Improved techniques for haploid production in wheat using chromosome elimination. Plant Breeding, 113 (2), pp. 125-129. |
[19] | Johri, B. M. ed., 2012. Experimental embryology of vascular plants. Springer Science & Business Media. |
[20] | Semagn, K., Bjørnstad, Å. and Xu, Y., 2010. The genetic dissection of quantitative traits in crops. Electronic Journal of Biotechnology, 13 (5), pp. 16-17. |
[21] | Chen, J. F., Cui, L., Malik, A. A. and Mbira, K. G., 2011. In vitro haploid and dihaploid production via unfertilized ovule culture. Plant Cell, Tissue and Organ Culture (PCTOC), 104 (3), pp. 311-319. |
[22] | Varshney, R. K., Graner, A. and Sorrells, M. E., 2005. Genomics-assisted breeding for crop improvement. Trends in plant science, 10 (12), pp. 621-630. |
[23] | Hasan, M. M., Rafii, M. Y., Ismail, M. R., Mahmood, M., Rahim, H. A., Alam, M. A., Ashkani, S., Malek, M. A. and Latif, M. A., 2015. Marker-assisted backcrossing: a useful method for rice improvement. Biotechnology & Biotechnological Equipment, 29 (2), pp. 237-254. |
[24] | Xu, Y. and Crouch, J. H., 2008. Marker-assisted selection in plant breeding: From publications to practice. Crop science, 4 8 (2), pp. 391-407. |
[25] | Quarrie, S. A., Lazić-Jančić, V., Kovačević, D., Steed, A. and Pekić, S., 1999. Bulk segregant analysis with molecular markers and its use for improving drought resistance in maize. Journal of experimental botany, 50 (337), pp. 1299-1306. |
[26] | Deschamps, S., Llaca, V. and May, G. D., 2012. Genotyping-by-sequencing in plants. Biology, 1 (3), pp. 460-483. |
[27] | Pink, D., Bailey, L., McClement, S., Hand, P., Mathas, E., Buchanan-Wollaston, V., Astley, D., King, G. and Teakle, G., 2008. Double haploids, markers and QTL analysis in vegetable brassicas. Euphytica, 164 (2), pp. 509-514. |
[28] | Deakin, J. E., Potter, S., O’Neill, R., Ruiz-Herrera, A., Cioffi, M. B., Eldridge, M. D., Fukui, K., Marshall Graves, J. A., Griffin, D., Grutzner, F. and Kratochvíl, L., 2019. Chromosomics: Bridging the gap between genomes and chromosomes. Genes, 10 (8), p. 627. |
[29] | Ellis, R. P., Forster, B. P., Gordon, D. C., Handley, L. L., Keith, R. P., Lawrence, P., Meyer, R., Powell, W., Robinson, D., Scrimgeour, C. M. and Young, G., 2002. Phenotype/genotype associations for yield and salt tolerance in a barley mapping population segregating for two dwarfing genes. Journal of Experimental Botany, 53 (371), pp. 1163-1176. |
[30] | Koumproglou, R., Wilkes, T. M., Townson, P., Wang, X. Y., Beynon, J., Pooni, H. S., Newbury, H. J. and Kearsey, M. J., 2002. STAIRS: a new genetic resource for functional genomic studies of Arabidopsis. The Plant Journal, 31 (3), pp. 355-364. |
[31] | Bohanec, B., 2002. Doubled-haploid onions. Allium Crop Science: Recent Advances. CABI Pub Wallingford Oxon New York, pp. 145-157. |
[32] | Hussain, B., Khan, M. A., Ali, Q. and Shaukat, S., 2012. Double haploid production is the best method for genetic improvement and genetic studies of wheat. Int J Agro Vet Med Sci, 6 (4), pp. 216-228. |
[33] | Dunwell, J. M., 2010. Haploids in flowering plants: origins and exploitation. Plant biotechnology journal, 8 (4), pp. 377-424. |
[34] | Morrison, R. A. and Evans, D. A., 1988. Haploid plants from tissue culture: new plant varieties in a shortened time frame. Bio/technology, 6 (6), pp. 684-690. |
[35] | Forster, B. P., Ellis, R. P., Thomas, W. T. B., Newton, A. C., Tuberosa, R., This, D., El-Enein, R. A., Bahri, M. H. and Ben Salem, M., 2000. The development and application of molecular markers for abiotic stress tolerance in barley. Journal of Experimental Botany, 51 (342), pp. 19-27. |
[36] | Snape, J. W., 1981, August. The use of doubled haploids in plant breeding. In Induced variability in plant breeding. International symposium of the section mutations and polyploidy of Eucarpia (pp. 52-58). |
[37] | Bolibok, H. and Rakoczy-Trojanowska, M., 2006. Genetic mapping of QTLs for tissue-culture response in plants. Euphytica, 149 (1), pp. 73-83. |
APA Style
Werkissa Yali. (2022). Haploids and Doubled Haploid Technology Application in Modern Plant Breeding. Journal of Plant Sciences, 10(2), 71-75. https://doi.org/10.11648/j.jps.20221002.14
ACS Style
Werkissa Yali. Haploids and Doubled Haploid Technology Application in Modern Plant Breeding. J. Plant Sci. 2022, 10(2), 71-75. doi: 10.11648/j.jps.20221002.14
AMA Style
Werkissa Yali. Haploids and Doubled Haploid Technology Application in Modern Plant Breeding. J Plant Sci. 2022;10(2):71-75. doi: 10.11648/j.jps.20221002.14
@article{10.11648/j.jps.20221002.14, author = {Werkissa Yali}, title = {Haploids and Doubled Haploid Technology Application in Modern Plant Breeding}, journal = {Journal of Plant Sciences}, volume = {10}, number = {2}, pages = {71-75}, doi = {10.11648/j.jps.20221002.14}, url = {https://doi.org/10.11648/j.jps.20221002.14}, eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.jps.20221002.14}, abstract = {Plant breeding, genetics, and genetic engineering all benefit from the use of doubled haploids technology. For genetic mapping of complicated phenotypes, the doubled haploid technique is a useful tool. To make doubled haploids, haploid cells (which are genetically unstable in the first place) can duplicate their genome at any point during their growth, resulting in diploid cells that don't require any additional therapies. The use of doubled haploidy in breeding is influenced by a variety of circumstances. Doubled haploids (DHs) are exploited in a variety of ways, depending on available technologies and species. In horticultural crops that are perennial in nature, outcrossing with inbreeding depression, or have high economic value where breeding time is critical, doubled haploids are gaining popularity as a powerful approach for enhancing genetic gain per cycle. For various reasons, the current methods for producing haploids and doubled haploids are primarily focused on the rapid generation of pure lines to speed hybrid seed production or CMS conversion, as well as the production of di-haploids to simplify breeding operations, such as in the case of potatoes. These approaches involve using methods based primarily on in vitro culture, in vivo induction of haploid development, or a combination of the two to make haploid embryos in vivo and then rescue them in vitro. Generally the aim of this review paper is to assess the technology of haploids, double haploids and their role in modern crop improvement program.}, year = {2022} }
TY - JOUR T1 - Haploids and Doubled Haploid Technology Application in Modern Plant Breeding AU - Werkissa Yali Y1 - 2022/03/23 PY - 2022 N1 - https://doi.org/10.11648/j.jps.20221002.14 DO - 10.11648/j.jps.20221002.14 T2 - Journal of Plant Sciences JF - Journal of Plant Sciences JO - Journal of Plant Sciences SP - 71 EP - 75 PB - Science Publishing Group SN - 2331-0731 UR - https://doi.org/10.11648/j.jps.20221002.14 AB - Plant breeding, genetics, and genetic engineering all benefit from the use of doubled haploids technology. For genetic mapping of complicated phenotypes, the doubled haploid technique is a useful tool. To make doubled haploids, haploid cells (which are genetically unstable in the first place) can duplicate their genome at any point during their growth, resulting in diploid cells that don't require any additional therapies. The use of doubled haploidy in breeding is influenced by a variety of circumstances. Doubled haploids (DHs) are exploited in a variety of ways, depending on available technologies and species. In horticultural crops that are perennial in nature, outcrossing with inbreeding depression, or have high economic value where breeding time is critical, doubled haploids are gaining popularity as a powerful approach for enhancing genetic gain per cycle. For various reasons, the current methods for producing haploids and doubled haploids are primarily focused on the rapid generation of pure lines to speed hybrid seed production or CMS conversion, as well as the production of di-haploids to simplify breeding operations, such as in the case of potatoes. These approaches involve using methods based primarily on in vitro culture, in vivo induction of haploid development, or a combination of the two to make haploid embryos in vivo and then rescue them in vitro. Generally the aim of this review paper is to assess the technology of haploids, double haploids and their role in modern crop improvement program. VL - 10 IS - 2 ER -