Sexual and apomictic plant reproduction in the genomics era: exploring the mechanisms potentially useful in crop plants.

Sexual Plant Reproduction Pub Date : 2010-12-01 Epub Date: 2010-05-28 DOI:10.1007/s00497-010-0144-x
Sangam L Dwivedi, Enrico Perotti, Hari D Upadhyaya, Rodomiro Ortiz
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引用次数: 38

Abstract

Arabidopsis, Mimulus and tomato have emerged as model plants in researching genetic and molecular basis of differences in mating systems. Variations in floral traits and loss of self-incompatibility have been associated with mating system differences in crops. Genomics research has advanced considerably, both in model and crop plants, which may provide opportunities to modify breeding systems as evidenced in Arabidopsis and tomato. Mating system, however, not recombination per se, has greater effect on the level of polymorphism. Generating targeted recombination remains one of the most important factors for crop genetic enhancement. Asexual reproduction through seeds or apomixis, by producing maternal clones, presents a tremendous potential for agriculture. Although believed to be under simple genetic control, recent research has revealed that apomixis results as a consequence of the deregulation of the timing of sexual events rather than being the product of specific apomixis genes. Further, forward genetic studies in Arabidopsis have permitted the isolation of novel genes reported to control meiosis I and II entry. Mutations in these genes trigger the production of unreduced or apomeiotic megagametes and are an important step toward understanding and engineering apomixis.

基因组学时代的植物有性生殖和无融合生殖:探索在作物植物中潜在有用的机制。
拟南芥、拟南芥和番茄已成为研究交配系统差异遗传和分子基础的模式植物。花性状的变异和自交不亲和的丧失与作物交配系统的差异有关。基因组学研究在模式植物和作物植物方面都取得了相当大的进展,这可能为修改育种系统提供机会,正如拟南芥和番茄所证明的那样。然而,交配制度对多态性水平的影响更大,而不是重组本身。产生靶向重组仍然是作物遗传改良的重要因素之一。通过种子或无融合生殖的无性生殖,通过产生母系无性系,在农业上表现出巨大的潜力。尽管无融合性被认为是受简单的基因控制,但最近的研究表明,无融合性的结果是性行为时间失调的结果,而不是特定无融合性基因的产物。此外,在拟南芥中进行的遗传研究已经允许分离控制减数分裂I和II进入的新基因。这些基因的突变触发了未减数或无染色体分裂的巨配子的产生,这是理解和设计无染色体分裂的重要一步。
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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来源期刊
Sexual Plant Reproduction
Sexual Plant Reproduction 生物-生殖生物学
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