Scientia Agricultura Sinica ›› 2020, Vol. 53 ›› Issue (7): 1287-1308.doi: 10.3864/j.issn.0578-1752.2020.07.001

• CROP GENETICS & BREEDING·GERMPLASM RESOURCES·MOLECULAR GENETICS • Previous Articles     Next Articles

Research Progress of Wheat Wild Hybridization, Disease Resistance Genes Transfer and Utilization

Cheng LIU,Ran HAN,XiaoLu WANG,WenPing GONG,DunGong CHENG,XinYou CAO,AiFeng LIU,HaoSheng LI,JianJun LIU   

  1. Crop Research Institute, Shandong Academy of Agricultural Sciences/Key Laboratory of Wheat Biology and Genetic Improvement in the North Huang-Huai River Valley, Ministry of Agriculture/National Engineering Laboratory for Wheat and Maize, Jinan 250100
  • Received:2019-07-31 Accepted:2019-11-14 Online:2020-04-01 Published:2020-04-14

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Abstract:

Wheat alien species are vast reservoir of diversity for disease and pest resistance as well as stress tolerance, which are excellent gene sources for wheat breeding. Through wide hybridization, the genes of alien species could be transferred to wheat to create wheat-alien chromosome lines such as amphiploids or partial amphiploids, additions, substitutions and translocation lines. These genetic stocks could be utilized to study chromosome behavior and genome evolution, mapping genes, and diversifying the genetic basis of wheat for diseases and pest resistance, as well as yield and quality improvement. In order to understand the progress of wheat wide hybridization and useful gene transfer from alien species to wheat, in this paper, the classification of the tribe Triticeae, the definition and significance of wheat wide hybridization, alien transfers progress from species belonging to genera Aegilops, Secale, Thinopyrum, Dasypyrum, Agropyron, Hordeum, Elymus, Leymus, Psathyrostachys and Eremopyrum to wheat have been summarized and discussed. To date, the official designated genes originated from wheat alien species include 17 stripe rust resistance genes, 35 leaf rust resistance gens, 30 stem rust resistance genes, 41 powdery mildew resistance genes, 3 Fusarium head blight-resistance genes, one wheat blast resistance gene, one Septoria tritici blotch resistance genes, one Septoria nodorum blotch resistance gene, 4 tan spot resistance genes, 2 eyespot resistance genes, one wheat spindle streak mosaic virus resistance gene, 2 wheat streak mosaic virus resistance genes and 2 cereal yellow dwarf resistance genes. Names and the chromosomal locations of these disease resistance genes were inducted. Moreover, the utilization of these genes in wheat breeding has also been reviewed and summarized. In the history of world wheat breeding, disease resistant germplasms such as wheat-rye 1RS·1BL translocation, 1RS·1AL translocation and wheat-Aegilops ventricosa 2NS/2AS translocation have made outstanding contributions. However, this only benefited from the utilization of a few disease resistant genes. Compared to the number of the designated genes, relatively few disease-resistant genes have been used in wheat breeding. In this paper, the limiting factors for the underutilization are discussed. Suggestions on how to use these disease-resistant genes in the future are put forward. Meanwhile, the cloned disease-resistant genes from wheat alien species are listed. The methods of cloning these genes and the possible research hotspots in the future are also analyzed. It is believed that the development and application of wheat-wild species translocation lines without genetic drag may be an important driving force for material innovation and variety breeding in the future.

Key words: wheat, wild hybridization, chromosome line, disease resistance gene, derived varieties

Table 1

Stripe rust resistance genes transferred from wild relatives to wheat"

序号
No.		 基因
Gene		 来源
Source		 染色体位置
Chromosomal location		 参考文献
Reference		 序号
No.		 基因
Gene		 来源
Source		 染色体位置
Chromosomal location		 参考文献
Reference
1 Yr8 顶芒山羊草Ae. comsa 2D [25] 10 Yr9 栽培黑麦S. cereale 1BL [91]
2 Yr17 偏凸山羊草Ae. ventricosa 2AS [83] 11 Yr50 中间偃麦草Th. intermedium 4BL [92]
3 Yr19 拟斯卑尔脱山羊草Ae. speltoides 5B [84] 12 Yr7 硬粒小麦T. durum 2BL [93]
4 Yr28 粗山羊草Ae. tauschii 4DS [85] 13 Yr24 硬粒小麦T. durum 1BS [94]
5 Yr37 粘果山羊草Ae. kotschy 2DL [86] 14 Yr53 硬粒小麦T. durum 2BL [95]
6 Yr38 沙融山羊草Ae. sharonensis 6A [87] 15 Yr15 野生二粒小麦T. dicoccoides 1BL [96]
7 Yr40 卵穗山羊草Ae. geniculata 5DS [88] 16 Yr35 野生二粒小麦T. dicoccoides 6BS [97]
8 Yr42 三芒山羊草Ae. neglecta 6A [89] 17 Yr36 野生二粒小麦T. dicoccoides 6BS [98]
9 Yr70 小伞山羊草Ae. umbellulata 5DS [90]

Table 2

Leaf rust resistance genes transferred from wild relatives to wheat"

序号
No.		 基因
Gene		 来源
Source		 染色体位置
Chromosomal location		 参考文献
Reference		 序号
No.		 基因
Gene		 来源
Source		 染色体位置
Chromosomal location		 参考文献
Reference
1 Lr9 小伞山羊草Ae. umbellulata 6BL [99] 19 Lr58 钩刺山羊草Ae. triuncialis 2BL [111]
2 Lr76 小伞山羊草Ae. umbellulata 5DS [90] 20 Lr59 柱穗山羊草Ae. peregrina 1AL [112]
3 Lr21 粗山羊草Ae. tauschii 1DL [100] 21 Lr62 短穗山羊草Ae. neglecta 6A [89]
4 Lr22a 粗山羊草Ae. tauschii 2DS [101] 22 Lr25 栽培黑麦S. cereale 4BS [113]
5 Lr22b 粗山羊草Ae. tauschii 2DS [101] 23 Lr26 栽培黑麦S. cereale 1BL [114]
6 Lr32 粗山羊草Ae. tauschii 3D [102] 24 Lr45 栽培黑麦S. cereale 2AS [115]
7 Lr39 粗山羊草Ae. tauschii 2DS [103] 25 Lr19 长穗偃麦草Th. elongatum 7DL [116]
8 Lr42 粗山羊草Ae. tauschii 1D [104] 26 Lr24 彭提卡偃麦草Th. ponticum 3DL [117]
9 Lr28 拟斯卑尔脱山羊草Ae. speltoides 4AL [25] 27 Lr38 中间偃麦草Th. intermedium 2AL [118]
10 Lr35 拟斯卑尔脱山羊草Ae. speltoides 2B [105] 28 Lr29 长穗偃麦草Th. elongatum 7DS [119]
11 Lr36 拟斯卑尔脱山羊草Ae. speltoides 6BS [106] 29 Lr55 粗穗披碱草E. trachycaulis 1BS [120]
12 Lr47 拟斯卑尔脱山羊草Ae. speltoides 7AS [107] 30 Lr14a 栽培二粒小麦T. dicoccum 7BL [121]
13 Lr51 拟斯卑尔脱山羊草Ae. speltoides 1BL [108] 31 Lr53 野生二粒小麦T. dicoccoides 6BS [97]
14 Lr66 拟斯卑尔脱山羊草Ae. speltoides 3A [109] 32 Lr64 野生二粒小麦T. dicoccoides 6AL [122]
15 Lr37 偏凸山羊草Ae. ventricosa 2AS [83] 33 Lr23 硬粒小麦T. durum 2BS [123]
16 Lr54 粘果山羊草Ae. kotschyi 2DL [110] 34 Lr63 一粒小麦T. monococcum 3AS [124]
17 Lr56 沙融山羊草Ae. sharonensis 6A [87] 35 Lr50 提莫非维小麦T. timopheevi 2BL [125]
18 Lr57 卵穗山羊草Ae. geniculata 5DS [88]

Table 3

Stem rust resistance genes transferred from wild relatives to wheat"

序号
No.		 基因
Gene		 来源
Source		 染色体位置
Chromosomal location		 参考文献
Reference		 序号
No.		 基因
Gene		 来源
Source		 染色体位置
Chromosomal location		 参考文献
Reference
1 Sr34 顶芒山羊草Ae. comosa 2A, 2B [25] 16 Sr43 长穗偃麦草Th. elongatum 7D [136]
2 Sr38 偏凸山羊草Ae. ventricosa 2AS [83] 17 Sr44 中间偃麦草Th. intermedium 7DS [137]
3 Sr32 拟斯卑尔脱山羊草Ae. speltoides 2A, 2B [126] 18 Sr2 野生二粒小麦T. dicoccoides 3BS [138]
4 Sr39 拟斯卑尔脱山羊草Ae. speltoides 2B [105] 19 Sr9d 野生二粒小麦T. dicoccoides 2BL [139]
5 Sr47 拟斯卑尔脱山羊草Ae. speltoides 2B [127] 20 Sr9e 野生二粒小麦T. dicoccoides 2BL [140]
6 Sr51 希尔斯山羊草Ae. searsii 3AS, 3BS, 3DS [128] 21 Sr13 野生二粒小麦T. dicoccoides 6AL [141]
7 Sr53 卵穗山羊草Ae. geniculata 5DL [129] 22 Sr14 野生二粒小麦T. dicoccoides 1BL [141]
8 Sr27 栽培黑麦S. cereale 3A [130] 23 Sr17 野生二粒小麦T. dicoccoides 7BL [142]
9 Sr31 栽培黑麦S. cereale 1BL [131] 24 Sr21 一粒小麦T. monococcum 2AL [143]
10 Sr50 栽培黑麦S. cereale 1BS [132] 25 Sr22 一粒小麦T. monococcum 7AL [143]
11 Sr59 栽培黑麦S. cereale 2DL [133] 26 Sr35 一粒小麦T. monococcum 3AL [144]
12 Sr52 簇毛麦D. villosum 6AL [134] 27 Sr60 一粒小麦T. monococcum 5AS [145]
13 Sr24 彭提卡偃麦草Th. ponticum 3DL [117] 28 Sr12 硬粒小麦T. durum 3BS [146]
14 Sr25 彭提卡偃麦草Th. ponticum 7DL [117] 29 Sr36 提莫非维小麦T. timopheevi 2BS [147]
15 Sr26 长穗偃麦草Th. elongatum 6AL [135] 30 Sr37 提莫非维小麦T. timopheevi 4BL [147]

Table 4

Powdery mildew resistance genes transferred from wild relatives to wheat"

序号
No.		 基因
Gene		 来源
Source		 染色体位置
Chromosomal location		 参考文献
Reference		 序号
No.		 基因
Gene		 来源
Source		 染色体位置
Chromosomal location		 参考文献
Reference
1 Pm12 拟斯卑尔脱山羊草Ae. speltoides 6B [148] 22 Pm1b 一粒小麦T. monococcum 7AL [168]
2 Pm32 拟斯卑尔脱山羊草Ae. speltoides 1BS [149] 23 Pm4d 一粒小麦T. monococcum 2AL [169]
3 Pm53 拟斯卑尔脱山羊草Ae. speltoides 5BL [150] 24 Pm25 野生一粒小麦T. boeoticum 1A [170]
4 Pm19 粗山羊草Ae. tauschii 7D [151] 25 Pm4b 波斯小麦T. carthlicum 2AL [171]
5 Pm34 粗山羊草Ae. tauschii 5DL [152] 26 Pm4a 栽培二粒小麦T. dicoccum 2AL [171]
6 Pm35 粗山羊草Ae. tauschii 5DL [153] 27 Pm5a 栽培二粒小麦T. dicoccum 7BL [172]
7 Pm58 粗山羊草Ae. tauschii 2DS [154] 28 Pm49 栽培二粒小麦T. dicoccum 2BS [173]
8 Pm13 高大山羊草Ae. longissima 3B, 3D [155] 29 Pm50 栽培二粒小麦T. dicoccum 2AL [174]
9 Pm57 希尔斯山羊草Ae. searsii 2BL [156] 30 Pm16 野生二粒小麦T. dicoccoides 4A [175]
10 Pm29 卵穗山羊草Ae. geniculata 7DL [157] 31 Pm26 野生二粒小麦T. dicoccoides 2BS [176]
11 Pm7 栽培黑麦S. cereale 4BL [158] 32 Pm30 野生二粒小麦T. dicoccoides 5BS [177]
12 Pm8 栽培黑麦S. cereale 1BS [91] 33 Pm36 野生二粒小麦T. dicoccoides 5BL [178]
13 Pm17 栽培黑麦S. cereale 1AS [159] 34 Pm41 野生二粒小麦T. dicoccoides 3BL [179]
14 Pm20 栽培黑麦S. cereale 6BL [160] 35 Pm42 野生二粒小麦T. dicoccoides 2BS [180]
15 Pm56 栽培黑麦S. cereale 6AS [161] 36 Pm64 野生二粒小麦T. dicoccoides 2BL [181]
16 Pm21 簇毛麦D. villosum 6AS [162] 37 Pm3h 硬粒小麦T. durum 1AS [182]
17 Pm55 簇毛麦D. villosum 5AS, 5DS [163] 38 Pm60 乌拉尔图小麦T. urartu 7A [183]
18 Pm62 簇毛麦D. villosum 2BL [164] 39 Pm6 提莫非维小麦T. timopheevii 2BL [184]
19 Pm40 中间偃麦草Th. intermedium 7BS [165] 40 Pm27 提莫非维小麦T. timopheevii 6B [185]
20 Pm43 中间偃麦草Th. intermedium 2DL [166] 41 Pm37 提莫非维小麦T. timopheevii 7AL [186]
21 Pm51 彭提卡偃麦草Th. ponticum 2BL [167]

Table 5

Fusarium head blight resistance genes transferred from wild relatives to wheat"

序号
No.		 基因
Gene		 来源
Source		 染色体位置
Chromosomal location		 参考文献
Reference
1 Fhb3 大赖草 L. racemosus 7AS [187]
2 Fhb6 柯孟披碱草/鹅观草 E. tsukushiensis/R. kamoji 1AS [188]
3 Fhb7 彭提卡偃麦草Th. ponticum 7D [189]

Table 6

Wheat blast resistance gene and other disease resistance genes transferred from wild relatives to wheat"

序号
No.		 基因
Gene		 来源
Source		 染色体位置
Chromosomal location		 参考文献
Reference		 序号
No.		 基因
Gene		 来源
Source		 染色体位置
Chromosomal location		 参考文献
Reference
1 Rmg7 栽培二粒小麦T. dicoccum 2A [190] 8 Pch1 偏凸山羊草Ae. ventricosa 7DL [196]
2 Stb5 粗山羊草Ae. tauschii 7DS [191] 9 Pch3 簇毛麦D. villosum 4V [197]
3 Snb3 粗山羊草Ae. tauschii 5DL 10 Wss1 簇毛麦D. villosum 4DS [198]
4 Tsr2 野生二粒小麦T. dicoccoides 3BL [192] 11 Wsm1 中间偃麦草Th. intermedium 4DS [199]
5 Tsr3 粗山羊草Ae. tauschii 3DS [193] 12 Wsm3 中间偃麦草Th. intermedium 7B [200]
6 Tsr5 圆锥小麦T. turgidum 3BL [194] 13 Bdv2 中间偃麦草Th. intermedium 7DS [201]
7 Tsr7 野生二粒小麦T. dicoccoides 3BL [195] 14 Bdv3 中间偃麦草Th. intermedium 7DL [202]
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