Apomixis and strategies to induce apomixis to preserve hybrid vigor for multiple generations.

IF 4.5 2区农林科学 Q1 BIOTECHNOLOGY & APPLIED MICROBIOLOGY

Gm Crops & Food-Biotechnology in Agriculture and the Food Chain Pub Date : 2021-01-01 DOI:10.1080/21645698.2020.1808423

Sajid Fiaz, Xiukang Wang, Afifa Younas, Badr Alharthi, Adeel Riaz, Habib Ali

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Abstract

Hybrid seeds of several important crops with supreme qualities including yield, biotic and abiotic stress tolerance have been cultivated for decades. Thus far, a major challenge with hybrid seeds is that they do not have the ability to produce plants with the same qualities over subsequent generations. Apomixis, an asexual mode of reproduction by avoiding meiosis, exists naturally in flowering plants, and ultimately leads to seed production. Apomixis has the potential to preserve hybrid vigor for multiple generations in economically important plant genotypes. The evolution and genetics of asexual seed production are unclear, and much more effort will be required to determine the genetic architecture of this phenomenon. To fix hybrid vigor, synthetic apomixis has been suggested. The development of MiMe (mitosis instead of meiosis) genotypes has been utilized for clonal gamete production. However, the identification and parental origin of genes responsible for synthetic apomixis are little known and need further clarification. Genome modifications utilizing genome editing technologies (GETs), such as clustered regularly interspaced short palindromic repeats (CRISPR)/CRISPR-associated protein (cas), a reverse genetics tool, have paved the way toward the utilization of emerging technologies in plant molecular biology. Over the last decade, several genes in important crops have been successfully edited. The vast availability of GETs has made functional genomics studies easy to conduct in crops important for food security. Disruption in the expression of genes specific to egg cell MATRILINEAL (MTL) through the CRISPR/Cas genome editing system promotes the induction of haploid seed, whereas triple knockout of the Baby Boom (BBM) genes BBM1, BBM2, and BBM3 cause embryo arrest and abortion, which can be fully rescued by male-transmitted BBM1. The establishment of synthetic apomixis by engineering the MiMe genotype by genome editing of BBM1 expression or disruption of MTL leads to clonal seed production and heritability for multiple generations. In the present review, we discuss current developments related to the use of CRISPR/Cas technology in plants and the possibility of promoting apomixis in crops to preserve hybrid vigor. In addition, genetics, evolution, epigenetic modifications, and strategies for MiMe genotype development are discussed in detail.

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Apomixis 和诱导 apomixis 以保持多代杂交活力的策略。

几十年来，人们一直在培育几种重要作物的杂交种子，它们具有最高的品质，包括产量、生物和非生物胁迫耐受性。迄今为止，杂交种子面临的一个主要挑战是，它们无法在后代中培育出具有相同品质的植物。Apomixis 是一种避免减数分裂的无性繁殖模式，在开花植物中自然存在，并最终产生种子。无性繁殖有可能使具有重要经济价值的植物基因型的杂种活力保持多代。无性生殖种子的进化和遗传学尚不清楚，要确定这一现象的遗传结构还需要更多努力。为了固定杂种活力，有人提出了合成无性繁殖。MiMe（有丝分裂代替减数分裂）基因型的开发已被用于克隆配子的生产。然而，对合成无性繁殖基因的鉴定和亲本来源知之甚少，需要进一步澄清。利用基因组编辑技术（GETs）进行基因组改造，如簇状规则间隔短回文重复序列（CRISPR）/CRISPR 相关蛋白（cas）（一种反向遗传学工具），为植物分子生物学新兴技术的应用铺平了道路。在过去十年中，一些重要作物的基因已被成功编辑。GETs 的广泛使用使得对粮食安全十分重要的作物的功能基因组学研究变得容易。通过 CRISPR/Cas 基因组编辑系统破坏卵细胞母细胞（MTL）特异性基因的表达可促进单倍体种子的诱导，而婴儿潮（BBM）基因 BBM1、BBM2 和 BBM3 的三重敲除会导致胚胎停育和流产，而雄性传递的 BBM1 可以完全挽救胚胎停育和流产。通过对 BBM1 表达的基因组编辑或 MTL 的破坏来设计 MiMe 基因型，从而建立人工合成的无性繁殖，这将导致多代的克隆种子生产和遗传性。在本综述中，我们讨论了与在植物中使用 CRISPR/Cas 技术有关的最新进展，以及在作物中促进无性繁殖以保持杂交活力的可能性。此外，还详细讨论了遗传学、进化、表观遗传修饰和 MiMe 基因型开发策略。

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来源期刊

Gm Crops & Food-Biotechnology in Agriculture and the Food Chain Biochemistry, Genetics and Molecular Biology-Biotechnology

CiteScore

8.10

自引率

10.30%

发文量

期刊介绍： GM Crops & Food - Biotechnology in Agriculture and the Food Chain aims to publish high quality research papers, reviews, and commentaries on a wide range of topics involving genetically modified (GM) crops in agriculture and genetically modified food. The journal provides a platform for research papers addressing fundamental questions in the development, testing, and application of transgenic crops. The journal further covers topics relating to socio-economic issues, commercialization, trade and societal issues. GM Crops & Food aims to provide an international forum on all issues related to GM crops, especially toward meaningful communication between scientists and policy-makers. GM Crops & Food will publish relevant and high-impact original research with a special focus on novelty-driven studies with the potential for application. The journal also publishes authoritative review articles on current research and policy initiatives, and commentary on broad perspectives regarding genetically modified crops. The journal serves a wide readership including scientists, breeders, and policy-makers, as well as a wider community of readers (educators, policy makers, scholars, science writers and students) interested in agriculture, medicine, biotechnology, investment, and technology transfer. Topics covered include, but are not limited to: • Production and analysis of transgenic crops • Gene insertion studies • Gene silencing • Factors affecting gene expression • Post-translational analysis • Molecular farming • Field trial analysis • Commercialization of modified crops • Safety and regulatory affairs BIOLOGICAL SCIENCE AND TECHNOLOGY • Biofuels • Data from field trials • Development of transformation technology • Elimination of pollutants (Bioremediation) • Gene silencing mechanisms • Genome Editing • Herbicide resistance • Molecular farming • Pest resistance • Plant reproduction (e.g., male sterility, hybrid breeding, apomixis) • Plants with altered composition • Tolerance to abiotic stress • Transgenesis in agriculture • Biofortification and nutrients improvement • Genomic, proteomic and bioinformatics methods used for developing GM cops ECONOMIC, POLITICAL AND SOCIAL ISSUES • Commercialization • Consumer attitudes • International bodies • National and local government policies • Public perception, intellectual property, education, (bio)ethical issues • Regulation, environmental impact and containment • Socio-economic impact • Food safety and security • Risk assessments