Prospects for combining the methods of haploid biotechnology and genome editing to improve spiked grains of the Triticeae family (review)

Grain Economy of Russia Pub Date : 2024-07-15 DOI:10.31367/2079-8725-2024-92-3-18-26

A. V. Zhiltsov, A. A. Chekalin, O. V. Popova, I. V. Duvanov, D. Miroshnichenko

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Abstract

Over the past few decades, haploid biotechnologies have become an integral part of breeding programs for many crops. Using the strategy of doubling haploids induced in the culture of gametic cells and tissues in vitro, through androgenesis, gynogenesis and distant hybridization, it became possible to significantly reduce the time for developing new varieties. Using the technology of doubled haploids, within one or two generations, it is possible to obtain aligned homozygous lines, which can both help speed up the breeding process and study several scientific and practical issues. Another promising tool for developing lines and samples with specified traits within several generations is genome editing (engineering) using various nuclease-based engineering complexes. The CRISPR/Cas9 genome editing technology, which came into use ten years ago, allows solving a wide variety of problems in plant functional genomics, including engineering resistance to biotic and abiotic stresses, improving productivity and product quality. The technology is better than the most known methods for improving varieties for the traits which have mono- or polygenic control, since it allows changing several genes simultaneously, which is important for polyploid species. An integral part of plant genome editing, as well as haploidogenesis technologies, is cell and tissue culture in vitro, which gives possibility for their combination. The combination of technologies allows producing homozygous plants with new gene-specific mutations, which improves genetic diversity and accelerates the selection of linear material with new economically valuable traits. The current review has summarized the experience of combining haploidy and genome editing methods in spiked grains of the Triticeae family. In addition to analyzing the current state, there have been considered the prospects for further development of technologies for obtaining haploids of wheat, barley, triticale, and rye with an edited genome.

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结合单倍体生物技术和基因组编辑方法改良三尖杉科谷物的前景（综述）

在过去几十年中，单倍体生物技术已成为许多作物育种计划中不可或缺的一部分。利用配子细胞和组织的体外培养，通过雄性发生、雌性发生和远缘杂交诱导加倍单倍体的策略，可以大大缩短培育新品种的时间。利用加倍单倍体技术，可以在一两代内获得排列整齐的同源品系，这既有助于加快育种进程，也有助于研究一些科学和实际问题。另一种有望在几代内培育出具有特定性状的品系和样本的工具是利用各种基于核酸酶的工程复合体进行基因组编辑（工程）。CRISPR/Cas9 基因组编辑技术在十年前投入使用，可以解决植物功能基因组学中的各种问题，包括工程抗生物和非生物胁迫、提高生产力和产品质量。在改良单基因或多基因控制性状的品种方面，该技术优于大多数已知方法，因为它可以同时改变多个基因，这对多倍体物种非常重要。植物基因组编辑和单倍体发生技术的一个组成部分是体外细胞和组织培养，这为两者的结合提供了可能。技术的结合可以培育出具有新基因特异性突变的同源植物，从而提高遗传多样性，加快筛选出具有新的经济价值性状的线性材料。本综述总结了结合单倍体和基因组编辑方法在三尖杉科谷物中应用的经验。除了分析现状之外，还考虑了进一步开发技术以获得具有编辑基因组的小麦、大麦、三棱麦和黑麦单倍体的前景。

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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Grain Economy of Russia

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