Marker-Assisted Breeding in Wheat

Next Generation Plant Breeding Pub Date : 2018-09-26 DOI:10.5772/INTECHOPEN.74724

Nana Vagndorf, P. Kristensen, J. R. Andersen, A. Jahoor, J. Orabi

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引用次数: 3

Abstract

Selection is an integral component in plant breeding, which ensures the progressive values of the breeding material, in terms of yield and quality. However, selection is influenced by the environment in any given growing season. The observed phenotype is a product of the genotype (G), the environment (E), and/or genotype × environment (G×E). Therefore, phenotypic selection is not always the best predirector of the genotype. Therefore, an environment-independent method is preferred by the breeder. The development of molecular markers in plants has facilitated marker-assisted selection (MAS). MAS requires the establishment of correlation between a desired trait such as disease resistance and molecular marker(s). This can be obtained, e.g., by phenotyping a genetic mapping population followed by QTL analysis. Initially, this process was slow due to the laborious nature of the first DNA molecular marker system, such as restriction fragment length polymorphism (RFLP). Later, with the discovery of various marker systems amenable to automation and the development of genotyping techniques and instruments, MAS has become a standard procedure in plant breeding. In wheat breeding, MAS helped to accelerate the introgression of many genes that contribute to improve quality and resistance.

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小麦的标记辅助育种

选择是植物育种的一个组成部分，它确保了育种材料在产量和质量方面的进步价值。然而，在任何给定的生长季节，选择受到环境的影响。观察到的表型是基因型(G)、环境(E)和/或基因型x环境(G×E)的产物。因此，表型选择并不总是基因型的最佳预导。因此，一种与环境无关的方法是育种者的首选。植物分子标记的发展促进了标记辅助选择的发展。MAS需要建立所需性状(如抗病性)与分子标记之间的相关性。这可以通过对遗传作图群体进行表型分析，然后进行QTL分析来获得。最初，由于第一个DNA分子标记系统(如限制性片段长度多态性(RFLP))的费力性质，这个过程很慢。后来，随着各种可自动化的标记系统的发现以及基因分型技术和仪器的发展，MAS已成为植物育种的标准程序。在小麦育种中，MAS有助于加速许多有助于提高品质和抗性的基因的渗入。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Next Generation Plant Breeding

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