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从全球优质春小麦种质中鉴定适合非洲南部和东部的杂种优势群种子。

Identifying the seeds of heterotic pools for Southern and Eastern Africa from global elite spring wheat germplasm.

作者信息

John-Bejai Carus, Trethowan Richard, Revell Isobella, de Groot Stephan, Shezi Lindani, Koekemoer Francois, Diffey Simon, Lage Jacob

机构信息

Wheat Breeding, KWS UK Ltd, Thriplow, United Kingdom.

The Plant Breeding Institute, School of Life and Environmental Sciences, The University of Sydney, Narrabri, NSW, Australia.

出版信息

Front Plant Sci. 2024 Jun 27;15:1398715. doi: 10.3389/fpls.2024.1398715. eCollection 2024.

DOI:10.3389/fpls.2024.1398715
PMID:38993941
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11236601/
Abstract

Hybrid breeding can increase the competitiveness of wheat ( L.) in Sub-Saharan Africa by fostering more public-private partnerships and promoting investment by the private sector. The benefit of hybrid wheat cultivars in South Africa has previously been demonstrated but due to the high cost of hybrid seed production, hybrid breeding has not received significant attention in the past decade. Considering the renewed commitment of the private sector to establish wheat as a hybrid crop globally, coupled with significant research investment into enhancement of outcrossing of wheat, hybrid wheat breeding in Southern and Eastern Africa should be revisited. Our study aimed to identify genetically distinct germplasm groups in spring wheat that would be useful in the establishment of heterotic pools targeting this region. Multi-environment yield testing of a large panel of F1 test hybrids, generated using global elite germplasm, was carried out between 2019 and 2020 in Argentina, Africa, Europe, and Australia. We observed significant genotype by environment interactions within our testing network, confirming the distinctiveness of African trial sites. Relatively high additive genetic variance was observed highlighting the contribution of parental genotypes to the grain yield of test hybrids. We explored the genetic architecture of these parents and the genetic factors underlying the value of parents appear to be associated with their genetic subgroup, with positive marker effects distributed throughout the genome. In testcrosses, elite germplasm from the International Maize and Wheat Improvement Center (CIMMYT) appear to be complementary to the genetically distinct germplasm bred in South Africa. The feasibility of achieving genetic gain via heterotic pool establishment and divergence, and by extension the viability of hybrid cultivars in Sub-Saharan Africa, is supported by the results of our study.

摘要

杂交育种可以通过促进更多公私合作伙伴关系和推动私营部门投资来提高撒哈拉以南非洲地区小麦的竞争力。杂交小麦品种在南非的益处此前已得到证明,但由于杂交种子生产成本高昂,在过去十年中杂交育种并未受到显著关注。鉴于私营部门重新承诺在全球将小麦打造成杂交作物,再加上对提高小麦异交率的大量研究投资,应该重新审视非洲南部和东部的杂交小麦育种。我们的研究旨在确定春小麦中遗传上不同的种质组,这将有助于建立针对该地区的杂种优势群。2019年至2020年期间,在阿根廷、非洲、欧洲和澳大利亚对使用全球精英种质培育的大量F1测试杂交种进行了多环境产量测试。我们在测试网络中观察到显著的基因型与环境互作,证实了非洲试验地点的独特性。观察到相对较高的加性遗传方差,突出了亲本基因型对测试杂交种籽粒产量的贡献。我们探索了这些亲本的遗传结构,亲本价值背后的遗传因素似乎与其遗传亚组相关,正向标记效应分布在整个基因组中。在测交中,国际玉米和小麦改良中心(CIMMYT)的精英种质似乎与南非培育的遗传上不同的种质互补。我们的研究结果支持了通过建立和分化杂种优势群实现遗传增益的可行性,进而支持了杂交品种在撒哈拉以南非洲地区的生存能力。

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