普通小麦及其祖先种的基因比较分析

K. Tsunewaki, H. Kihara
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However, the B1 and F2 data from the cross T. macha subletshchumicum ×T. aestivum Chinese Spring indicated that a recessive gene in addition to the above-mentioned genes must be considered regarding the expression of necrosis.2) Relationships among various varieties of common wheat concerning necrosis are represented in the diagram of Fig. 2.3) Distribution of the three major genes in common wheat and its ancestors, Emmer wheat and Ae. squarrosa, was investigated using T. aestivum Prelude (Ne1ne2Ne3), T. aestivum Kharkov (ne1Ne2Ne3) and T. macha subletshchumicum (Ne1Ne2ne3) as test varieties.In Emmer wheat a majority of varieties were found to have the genotype Ne1ne2, while minor fractions were either ne1ne2 or Ne1Ne2.All strains of Ae. squarrosa so far tested had Ne3.In common wheat, most varieties were either ne1ne2Ne3 or ne1Ne2Ne3, while a small fraction were Ne1ne2Ne3. One variety only was found to be Ne1ne2ne3 and another only one to be Ne1Ne2ne3, both belonging to T. macha.4) From these results, the genotypes of Emmer wheat, that supplied the AB genomes to common wheat, are assumed to be Ne1ne2 or ne1ne2. T. dicoccoides spontaneo-nigrum, some forms of T. dicoccum, T. turgidum, T. persicum and T. orientale, and many varieties of T. durum have these genotypes.The donor of the D genome to common wheat must have possessed Ne3. All strains of Ae. squarrosa so far tested had this allele.5) The presumable hexaploid progenitor must have had either Ne1ne2Ne3 or ne1ne2Ne3. In common wheat, some forms of T. spelta, T. sphaerococcum, T. compactum and T. aestivum have these genotypes. 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引用次数: 19

摘要

1)已知普通小麦的补体坏死主要由3个基因控制,即位于5B染色体的Ne1 (V)、位于2A染色体的Ne2 (XIII)和位于3D染色体的Ne3 (XVI)。然而,来自杂交T. macha subletshchumicum ×T的B1和F2数据。aestivum Chinese Spring表明,坏死的表达除上述基因外,还必须考虑一个隐性基因。2)图2.3所示为普通小麦各品种间与坏死有关的关系。以T. aestivum Prelude (Ne1ne2Ne3)、T. aestivum Kharkov (Ne1ne2Ne3)和T. macha subletshchumicum (Ne1ne2Ne3)为试验品种。在二粒小麦中,大多数品种为Ne1ne2基因型,少数品种为Ne1ne2或Ne1ne2基因型。所有菌株Ae。到目前为止检测到的squarrosa含有Ne3。在普通小麦品种中,ne1ne2Ne3或ne1ne2Ne3品种居多,ne1ne2Ne3品种占少数。其中一个品种为Ne1ne2ne3,另一个品种为Ne1ne2ne3,这两个品种都属于T. macha。4)根据这些结果,可以假设为普通小麦提供AB基因组的Emmer小麦的基因型为Ne1ne2或Ne1ne2。硬粒绦虫(T. dicoccoides spontanenigrum)、某些形式的硬粒绦虫(T. dicoccuum)、膨胀绦虫(T. turgidum)、桃粉绦虫(T. persicum)和东方绦虫(T. orientale)以及许多硬粒绦虫变种都有这些基因型。普通小麦的D基因组供体必须拥有Ne3。所有菌株Ae。5)假定的六倍体祖先一定有Ne1ne2Ne3或Ne1ne2Ne3。在普通小麦中,某些形式的粗粒T.,球形T.,紧实T.和aestivum有这些基因型。具有ne3等位基因的T. macha被认为是六倍体中一个孤立的物种,似乎对普通小麦的起源没有贡献。6)普通小麦中的Ne2起源于六倍体水平,而不是来自二粒小麦。在六倍体水平上,Ne2可能具有选择性优势,而Ne1具有选择性劣势。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Comparative Gene Analysis of Common Wheat and its Ancestral Species, I. Necrosis
1) It has been known that complementary necrosis in common wheat is mainly controlled by three genes, Ne1 located in chromosome 5B (V), Ne2 in 2A (XIII)and Ne3 in 3D (XVI). However, the B1 and F2 data from the cross T. macha subletshchumicum ×T. aestivum Chinese Spring indicated that a recessive gene in addition to the above-mentioned genes must be considered regarding the expression of necrosis.2) Relationships among various varieties of common wheat concerning necrosis are represented in the diagram of Fig. 2.3) Distribution of the three major genes in common wheat and its ancestors, Emmer wheat and Ae. squarrosa, was investigated using T. aestivum Prelude (Ne1ne2Ne3), T. aestivum Kharkov (ne1Ne2Ne3) and T. macha subletshchumicum (Ne1Ne2ne3) as test varieties.In Emmer wheat a majority of varieties were found to have the genotype Ne1ne2, while minor fractions were either ne1ne2 or Ne1Ne2.All strains of Ae. squarrosa so far tested had Ne3.In common wheat, most varieties were either ne1ne2Ne3 or ne1Ne2Ne3, while a small fraction were Ne1ne2Ne3. One variety only was found to be Ne1ne2ne3 and another only one to be Ne1Ne2ne3, both belonging to T. macha.4) From these results, the genotypes of Emmer wheat, that supplied the AB genomes to common wheat, are assumed to be Ne1ne2 or ne1ne2. T. dicoccoides spontaneo-nigrum, some forms of T. dicoccum, T. turgidum, T. persicum and T. orientale, and many varieties of T. durum have these genotypes.The donor of the D genome to common wheat must have possessed Ne3. All strains of Ae. squarrosa so far tested had this allele.5) The presumable hexaploid progenitor must have had either Ne1ne2Ne3 or ne1ne2Ne3. In common wheat, some forms of T. spelta, T. sphaerococcum, T. compactum and T. aestivum have these genotypes. T. macha, that is an exception in possessing the ne3 allele, is considered to be an isolated species among the hexaploids and seems not to have contributed to the origin of common wheat.6) It is suggested that Ne2 in common wheat originated at the hexaploid level rather than to have been derived from Emmer wheat. Possibility of selective advantage of Ne2 and disadvantage of Ne1 at the hexaploid level is suggested.
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