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Acta Agronomica Sinica ›› 2020, Vol. 46 ›› Issue (02): 179-193.doi: 10.3724/SP.J.1006.2020.91029

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

Development and validation of markers linked to genes resistant to Sitodiplosis mosellana in wheat

HAO Zhi-Ming1,GENG Miao-Miao1,WEN Shu-Min1,YAN Gui-Jun2,WANG Rui-Hui1,*(),LIU Gui-Ru1,*()   

  1. 1 Hebei Agricultural University / North China Key Laboratory for Crop Germplasm Resources of Education Ministry, Baoding 071000, Hebei, China
    2 School of Agriculture and Environment, the University of Western Australia, Nedlands 6009, Australia
  • Received:2019-04-08 Accepted:2019-09-26 Online:2020-02-12 Published:2019-10-16
  • Contact: Rui-Hui WANG,Gui-Ru LIU E-mail:wangrh@hebau.edu.cn;nxlgr@hebau.edu.cn
  • Supported by:
    This study was supported by the National Natural Science Foundation of China(31371617)

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Abstract:

Orange wheat blossom midge (OWBM) (Sitodiplosis mosellana Géhin) has seriously reduced wheat production and processing quality. Breeding midge-resistant wheat has been considered the most effective way to reduce kernel losses caused by OWBM, and marker-assisted selection (MAS) strategy in crop breeding using linked or functional markers of target trait of interest is of great importance in improving breeding efficiency. Based on the InDels and SNPs within the sequences of six midge resistance-related genes discovered from transcriptome data in the previously mapped major QTL (QSm.hbau-4A) region, we developed and validated two EST and six KASP markers in a panel of recombinant inbred lines (RILs) and a panel of wheat cultivars with different OWBM resistance levels. These markers were polymorphic between the resistant and susceptible wheat parents, and approximately 90% of RIL lines showed the corresponding marker-based genotypes with their phenotypes. Except for E10-10, the other seven markers had higher detection efficiency in highly resistant (56.3%-86.7%) and in highly susceptible (85.7%-100.0%) wheat cultivars, thus making them applicable for screening midge-resistant wheat germplasm with locus QSm.hbau-4A. Among the eleven midge-resistant wheat cultivars with all resistance alleles for the seven markers developed, most were historical wheat cultivars, and rarely used in the present production, which suggests how to use old cultivars in wheat germplasm identification and enhancement on midge-resistance through MAS is urgent.

Key words: bread wheat (Triticum aestivum L.), Sitodiplosis mosellana, resistance-related genes, functional markers, SNP, EST, KASP

Table 1

Phenotypes for wheat parents and selected RIL lines"

小麦亲本及株系
Wheat parent and line		 抗性指数(RI)
Resistance index		 抗虫等级
Classification		 小麦株系
Wheat line		 抗性指数(RI)
Resistance index		 抗虫等级
Classification
冀麦24 Jimai 24 0.0128-0.1233 1 RIL-264 0.1007-0.2659 2
6218 2.9543-7.2714 5 RIL-285 0.0064-0.2105 2
RIL-7 0.0575-0.0622 1 RIL-16 0.7300-1.3397 4
RIL-12 0.0133-0.0336 1 RIL-21 0.9122-1.4373 4
RIL-18 0.0745-0.0817 1 RIL-60 1.2009-1.2429 4
RIL-23 0.0029-0.0330 1 RIL-106 1.2142-1.2325 4
RIL-38 0.1441-0.1886 1 RIL-251 0.9603-1.4106 4
RIL-64 0.0188-0.0380 1 RIL-19 2.7085-2.8602 5
RIL-73 0.0784-0.1409 1 RIL-20 2.6327-3.1797 5
RIL-91 0.0205-0.0818 1 RIL-25 3.0783-4.3757 5
RIL-115 0.0503-0.1358 1 RIL-29 2.1227-2.5619 5
RIL-134 0.0104-0.0394 1 RIL-45 2.2811-2.7601 5
RIL-156 0.0244-0.0253 1 RIL-46 2.3158-6.3697 5
RIL-169 0.0434-0.0569 1 RIL-49 2.0398-2.6978 5
RIL-170 0.0539-0.1697 1 RIL-62 1.2193-2.6308 5
RIL-175 0.0123-0.0731 1 RIL-63 2.0683-2.5504 5
RIL-186 0.0231-0.0467 1 RIL-68 2.2674-4.9395 5
RIL-194 0.1535-0.1781 1 RIL-72 2.8236-3.1560 5
RIL-214 0.0778-0.1384 1 RIL-84 2.0781-2.8191 5
RIL-223 0.0460-0.1956 1 RIL-92 2.1872-4.3090 5
RIL-249 0.0403-0.0848 1 RIL-95 2.6088-2.6854 5
RIL-253 0.0037-0.0109 1 RIL-97 1.6879-2.1144 5
RIL-259 0.0406-0.0534 1 RIL-102 2.7594-2.9148 5
RIL-274 0.0293-0.0953 1 RIL-113 1.4552-2.8464 5
RIL-283 0.0091-0.0658 1 RIL-119 1.2420-3.1363 5
RIL-13 0.1109-0.2648 2 RIL-122 2.4698-2.6681 5
RIL-28 0.1087-0.4394 2 RIL-125 1.6834-2.1306 5
RIL-39 0.2354-0.2983 2 RIL-139 2.5142-3.2524 5
RIL-44 0.2961-0.3166 2 RIL-148 1.8636-5.5925 5
RIL-54 0.0331-0.2245 2 RIL-150 2.4328-3.1815 5
RIL-56 0.0064-0.3427 2 RIL-167 2.5747-2.9479 5
RIL-69 0.1050-0.2124 2 RIL-168 1.9348-3.3892 5
RIL-78 0.0586-0.2337 2 RIL-174 1.1562-2.6991 5
RIL-107 0.0039-0.3020 2 RIL-182 2.7128-3.3572 5
RIL-155 0.0188-0.2217 2 RIL-185 3.1085-4.9160 5
RIL-158 0.2659-0.4615 2 RIL-212 2.0868-2.6547 5
RIL-164 0.1272-0.3710 2 RIL-213 2.0094-3.0880 5
RIL-180 0.3315-0.3891 2 RIL-216 1.1651-1.7900 5
RIL-183 0.0392-0.3963 2 RIL-233 2.4937-2.6506 5
RIL-196 0.0518-0.2096 2 RIL-238 1.1102-3.0323 5
RIL-197 0.1203-0.2525 2 RIL-240 3.0399-6.1309 5
RIL-218 0.1467-0.2391 2 RIL-247 1.5939-2.1915 5
RIL-219 0.1613-0.2189 2 RIL-248 2.1621-4.1447 5
RIL-226 0.3513-0.4673 2 RIL-265 2.6932-2.9406 5
RIL-241 0.2658-0.3099 2 RIL-267 2.7879-4.7565 5
RIL-244 0.0933-0.2738 2 RIL-275 1.5796-2.3936 5
RIL-260 0.0977-0.2581 2 RIL-276 1.3032-2.7370 5

Fig. 1

Sequence alignments of the six differentially expressed genes from wheat parents, ‘6218’ (susceptible) and ‘Jimai 24’ (resistant) and the Chinese Spring reference genome Red or blue font letters represent non-synonymous SNPs and InDels present in the genes. Blue letters with arrowheads represent the SNPs with high confidence."

Fig. 2

Polyacrylamide gel electrophoresis profiles for EST markers E1-2 (A) and E10-10 (B) in susceptible, or resistant-wheat parent, and selected RIL lines M: Molecular marker (restriction fragments of plasmid pBR322 digested with Mst I endonuclease); 1: Susceptible wheat parent ‘6218’; 2: Resistant parent ‘Jimai 24’; 3-14: Susceptible lines (RIL-16, RIL-19, RIL-20, RIL-21, RIL-25, RIL-29, RIL-45, RIL-102, RIL-113, RIL-119, RIL-125, and RIL-139); 15-26: Resistant lines (RIL-7, RIL-12, RIL-18, RIL-23, RIL-64, RIL-73, RIL-91, RIL-115, RIL-134, RIL-156, RIL-169, and RIL-170)."

Fig. 3

KASP assays in wheat parents, 92 RIL lines, and 95 wheat cultivars Red dots represent the HEX-type allele; blue dots, the FAM-type allele; green dots, the heterozygous-type allele; pink dots, undetected; black dots, the NTC (non-template control); A to F refer to genotypes for K3-1-1, K3-7-1, K3-7-3, K3-16-1, K10-10-6, and K10-13-x, respectively."

Table 2

Proportion of marker-based genotypes for EST and KASP markers in selected wheat RIL lines"

标记
Marker		 物理位置a
Physical location a (bp)		 抗虫RILs各标记基因型及比例
Marker-based genotypes and their ratio
for resistant RIL lines (%)		 感虫RILs各标记基因型及比例
Marker-based genotypes and their ratio
for susceptible RIL lines (%)
A H B A H B
E1-2 707248439 40 (85.1) 0 (0.0) 7 (14.9) 2 (4.4) 0 (0.0) 43 (95.6)
E10-10 705763221 40 (85.1) 0 (0.0) 7 (14.9) 4 (8.9) 0 (0.0) 41 (91.1)
K3-7-1 705889579 39 (86.7) 0 (0.0) 6 (13.3) 2 (4.4) 0 (0.0) 43 (95.6)
K3-7-3 705890140 39 (86.7) 0 (0.0) 6 (13.3) 2 (4.4) 0 (0.0) 43 (95.6)
K10-10-6 705763509 39 (86.7) 0 (0.0) 6 (13.3) 2 (4.4) 0 (0.0) 43 (95.6)
K3-16-1 707251252 41 (87.2) 0 (0.0) 6 (12.8) 2 (4.4) 0 (0.0) 43 (95.6)
K3-1-1 707477512 0 (0.0) 39 (86.7) 6 (13.3) 0 (0.0) 2 (4.4) 43 (95.6)
K10-13-x 706095841 0 (0.0) 39 (88.6) 5 (11.4) 0 (0.0) 2 (4.6) 42 (95.5)

Table 3

Phenotypes for selected wheat cultivars"

小麦品种
Wheat cultivar		 抗性指数(RI)
Resistance index		 抗虫等级
Classification		 小麦品种
Wheat cultivar		 抗性指数(RI)
Resistance index		 抗虫等级
Classification
小偃81 Xiaoyan 81 0.0039-0.0073 1 邯麦12号 Hanmai 12 0.3599-0.8138 3
晋麦47 Jinmai 47 0.0026-0.0155 1 河农6425 Henong 6425 0.1632-0.8449 3
河农6049 Henong 6049 0.0000-0.0235 1 周黑麦1号 Zhouheimai 1 0.6180-0.8651 3
石麦12号 Shimai 12 0.0197-0.0468 1 中麦12 Zhongmai 12 0.3425-0.8812 3
衡优18 Hengyou 18 0.0442-0.0513 1 藁优9618 Gaoyou 9618 0.0978-0.9218 3
河农58-3 Henong 58-3 0.0300-0.0770 1 石麦14号 Shimai 14 0.9019-0.9743 3
石新828 Shixin 828 0.0013-0.0862 1 科农199 Kenong 199 0.8349-1.0414 4
河农4198 Henong 4198 0.0602-0.1087 1 良星99 Liangxing 99 0.3466-1.1006 4
西农6028 Xinong 6028 0.0015-0.1089 1 石家庄10号 Shijiazhuang 10 0.0074-1.1150 4
河农215 Henong 215 0.0900-0.1214 1 石4185 Shi 4185 0.3530-1.1329 4
PH82-2-2 0.0423-0.1223 1 邢麦7号 Xingmai 7 0.6757-1.1334 4
科农1093 Kenong 1093 0.0678-0.1338 1 观35 Guan 35 0.7848-1.1727 4
矮丰1号 Aifeng 1 0.0009-0.1345 1 长6878 Chang 6878 0.1776-1.1764 4
晋麦33 Jinmai 33 0.0632-0.1395 1 石家庄8号 Shijiazhuang 8 1.1628-1.2792 4
中农28 Zhongnong 28 0.1412-0.1509 1 藁优9908 Gaoyou 9908 0.1786-1.2974 4
丰产2号 Fengchan 2 0.0302-0.1567 1 济麦20 Jimai 20 0.6224-1.3508 4
南大2419 Nanda 2419 0.0012-0.1645 1 衡0628 Heng 0628 1.1138-1.3548 4
济麦22 Jimai 22 0.0636-0.1806 1 河农826 Henong 826 1.0058-1.3817 4
中麦155 Zhongmai 155 0.1302-0.2029 2 轮选061 Lunxuan 061 0.8530-1.5171 5
晋麦79 Jinmai 79 0.0115-0.2049 2 北京0045 Beijing 0045 0.7773-1.7354 5
河农822 Henong 822 0.0567-0.2088 2 农大399 Nongda 399 0.6830-1.7594 5
陕229 Shaan 299 0.1115-0.2167 2 衡95观26 Heng 95 guan 26 1.2248-1.7931 5
汶农14 Wennong 14 0.1723-0.2213 2 衡4444 Heng 4444 1.6026-1.8759 5
邯麦9号 Hanmai No.9 0.0259-0.2524 2 衡7228 Heng 7228 0.8897-1.8930 5
临汾3050 Linfen 3050 0.0146-0.2557 2 邢麦6号 Xingmai 6 1.6227-1.9706 5
白硬冬2号 Baiyingdong 2 0.2241-0.2673 2 周麦23 Zhoumai 23 1.1381-1.9960 5
良星66 Liangxing 66 0.1759-0.2731 2 石新618 Shixin 618 0.8939-1.9989 5
婴泊700 Yingbo 700 0.1775-0.2770 2 NC2 1.4307-2.0183 5
河农9206 Henong 9206 0.2792-0.2844 2 衡4399 Heng 4399 1.7993-2.1132 5
冀麦23 Jimai 23 0.0296-0.2923 2 衡4338 Heng 4338 2.0068-2.1404 5
师栾02-1 Shiluan 02-1 0.0307-0.3112 2 周麦22 Zhoumai 22 1.6367-2.2851 5
冀5579 Ji 5579 0.0469-0.3598 2 冀糯200 Jiru 200 0.0244-2.2972 5
陕225 Shaan 225 0.1824-0.3881 2 河农7106 Henong 7106 0.3960-2.4059 5
石麦21号 Shimai 21 0.3801-0.4025 2 邯麦14 Hanmai 14 2.4645-2.6210 5
中麦175 Zhongmai 175 0.0873-0.4178 2 沧麦6005 Cangmai 6005 0.5190-2.6750 5
冀5265 Ji 5265 0.2441-0.4259 2 郑麦9694 Zhengmai 9694 0.4956-2.7112 5
科农213 Kenong 213 0.2667-0.4381 2 沧麦119 Cangmai 119 1.0727-3.1996 5
石新539 Shixin 539 0.1862-0.4457 2 百农AK58 Bainong AK58 3.0456-3.2033 5
保麦10号 Baomai 10 0.1057-0.4679 2 沧麦028 Cangmai 028 2.5945-3.3725 5
烟农23 Yannong 23 0.0583-0.4747 2 周麦16 Zhoumai 16 1.5595-3.9194 5
石家庄11号 Shijiazhuang 11 0.3940-0.4798 2 烟优361 Yanyou 361 4.1998-4.7174 5
轮选987 Lunxuan 987 0.4651-0.4932 2 临汾6035 Linfen 6035 1.5158-4.9971 5
洛麦21 Luomai 21 0.5366-0.5377 3 冀6358 Ji 6358 2.8190-5.1615 5
农大3432 Nongda 3432 0.1076-0.5399 3 沧6003 Cang 6003 2.9203-5.2570 5
石麦16号 Shimai 16 0.5887-0.6046 3 周麦18 Zhoumai 18 5.9047-19.5165 5
晶白麦1号 Jingbaimai 1 0.3560-0.6230 3 中国春 Chinese Spring
河农827 Henong 827 0.1498-0.6978 3 咸农39 Xiannong 39
河农5290 Henong 5290 0.6108-0.7991 3

Table 4

Proportion of marker-based genotypes for EST and KASP markers in selected wheat cultivars (%)"

标记
Marker		 抗虫品种的标记基因型及比例
Marker-based genotypes and their ratios
for resistant wheat cultivars		 中间型品种的标记基因型及比例
Marker-based genotypes and their ratios
for lowly resistant wheat cultivars		 感虫品种的标记基因型及比例
Marker-based genotypes and their
ratios for susceptible wheat cultivars
A H B A H B A H B
E1-2 16 (37.2) 7 (16.3) 20 (46.5) 3 (25.0) 0 (0.0) 9 (75.0) 5 (12.5) 3 (7.5) 32 (80.0)
E10-10 37 (84.1) 0 (0.0) 7 (15.9) 9 (75.0) 1 (8.3) 2 (16.7) 30 (75.0) 1 (2.5) 9 (22.5)
K3-7-1 12 (30.8) 0 (0.0) 27 (69.2) 1 (8.3) 0 (0.0) 11 (91.7) 3 (7.7) 0 (0.0) 36 (92.3)
K3-7-3 12 (31.6) 0 (0.0) 26 (68.4) 1 (9.1) 0 (0.0) 10 (90.9) 3 (7.7) 0 (0.0) 36 (92.3)
K10-10-6 15 (37.5) 0 (0.0) 25 (62.5) 2 (16.7) 0 (0.0) 10 (83.3) 5 (12.8) 0 (0.0) 34 (87.2)
K3-16-1 20 (62.5) 1 (3.1) 11 (34.4) 3 (25.0) 0 (0.0) 9 (75.0) 8 (20.5) 1 (2.6) 30 (76.9)
K3-1-1 1 (2.5) 13 (32.5) 26 (65.0) 0 (0.0) 1 (8.3) 11 (91.7) 0 (0.0) 3 (7.7) 36 (92.3)
K10-13-x 0 (0.0) 15 (38.5) 24 (61.5) 0 (0.0) 1 (11.1) 8 (88.9) 0 (0.0) 5 (20.8) 19 (79.2)

Fig. 4

Marker-based genotypes and their proportions for resistant- (47) or susceptible- (45) RIL lines, highly resistant- (19), moderately resistant- (24), lowly resistant- (12), susceptible- (12), and highly susceptible- (28) wheat cultivars"

Table 5

Phenotypes and marker-based genotypes in eleven wheat cultivars with the same resistant allele sets at seven marker loci"

小麦品种名称
Wheat cultivar name		 抗性指数(RI)
Resistance index		 抗虫等级
Classification		 E1-2a K10-10-6 K3-7-1 K3-7-3 K10-13-x K3-16-1 K3-1-1
河农6049 Henong 6049 0.0000-0.0235 1 a G:G A:A T:T C:G T:T T:G
石麦12号 Shimai 12 0.0197-0.0468 1 a G:G A:A T:T C:G T:T T:G
河农4198 Henong 4198 0.0602-0.1087 1 a G:G A:A T:T C:G T:T T:G
西农6028 Xinong 6028 0.0015-0.1089 1 a G:G A:A T:T C:G T:T T:G
晋麦33 Jinmai 33 0.0632-0.1395 1 a G:G A:A T:T C:G T:T T:G
中农28 Zhongnong 28 0.1412-0.1509 1 a G:G A:A T:T C:G T:T T:G
丰产2号 Fengchan 2 0.0302-0.1567 1 a G:G A:A T:T C:G T:T T:T
河农215 Henong 215 0.0502-0.2069 2 a G:G A:A T:T C:G T:T T:G
邯麦9号 Hanmai 9 0.0259-0.2524 2 a G:G A:A T:T C:G T:T T:G
冀麦23 Jimai 23 0.0296-0.2923 2 a G:G A:A T:T C:G T:T T:G
石家庄11号 Shijiazhuang 11 0.3940-0.4798 2 a G:G A:A T:T C:G T:T T:G
[1] 屈振刚, 温树敏, 屈赟, 刘桂茹 . 小麦品种抗麦红吸浆虫鉴定与抗性分析. 植物遗传资源学报, 2011,12:121-124.
Qu Z G, Wen S M, Qu Y, Liu G R . Evaluation and identification of wheat varieties resistant to Sitodiplosis mosellana. J Plant Genet Resour, 2011,12:121-124 (in Chinese with English abstract).
[2] 温树敏, 赵玉新, 屈振刚, 刘桂茹, 王琳琳, 王金耀 . 小麦品种抗麦红吸浆虫鉴定及抗性评价. 河北农业大学学报, 2007,30(5):71-74.
Wen S M, Zhao Y X, Qu Z G, Liu G R, Wang L L, Wang J Y . The utilization and evaluation of resistance in wheat varieties to Sitadiplosis mosellana. J Agric Univ Hebei, 2007,30(5):71-74 (in Chinese with English abstract).
[3] Thomas J, Fineberg N, Penner G, McCartney C, Aung T, Wise I, McCallum B, . Chromosome location and markers ofSm1: a gene of wheat that conditions antibiotic resistance to orange wheat blossom midge. Mol Breed, 2005,15:183-192.
doi: 10.1007/s11032-004-5041-2
[4] Bruce T J, Hooper A M, Ireland L, Jones O T, Martin J L, Smart L E, Oakley J, Wadhams L J . Development of a pheromone trap monitoring system for orange wheat blossom midge,Sitodiplosis mosellana, in the UK. Pest Manag Sci, 2007,63:49-56.
doi: 10.1002/ps.1307 pmid: 17078014
[5] Flodrops Y, Taupin P . Soft wheat: combating the orange blossom midge. Perspect Agricol, 2010,365:46-50.
[6] Jacquemin G, Chavalle S, De P M . Forecasting the emergence of the adult orange wheat blossom midge,Sitodiplosis mosellana(Géhin), 2014,58:6-13.
[7] Gaafar N, Volkmar C, Cöster H, Spilke J . Susceptibility of winter wheat cultivars to wheat ear insects in central Germany. Gesunde Pflanzen, 2011,62:107-115.
doi: 10.1007/s10343-010-0227-5
[8] 赵中华, 王强, 朱晓明 . 2015年全国小麦病虫害发生新特点与防治新思路. 中国植保导刊, 2016,36(8):33-36.
Zhao Z H, Wang Q, Zhu X M . New patterns of wheat pest and disease infection in 2015 and new ideas for control in China. China Plant Prot, 2016,36(8):33-36 (in Chinese).
[9] 尹青云, 郑王义, 谢咸升, 李峰, 范绍强, 郑晓玲 . 小麦品种对麦红吸浆虫的抗性及抗性种质资源创新应用研究进展. 麦类作物学报, 2003,23(2):88-91.
doi: 10.7606/j.issn.1009-1041.2003.02.064
Yin Q Y, Zheng W Y, Xie X S, Li F, Fan S Q, Zheng X L . Advances in the study on wheat variety resistance to wheat midge and innovation and application of resistance germplasm resources. J Triticeae Crops, 2003,23(2):88-91 (in Chinese with English abstract).
doi: 10.7606/j.issn.1009-1041.2003.02.064
[10] 段云, 蒋月丽, 苗进, 巩中军, 李彤, 武予清, 罗礼智 . 麦红吸浆虫在我国的发生、危害及防治. 昆虫学报, 2013,56:1359-1366.
Duan Y, Jiang Y L, Miao J, Gong Z J, Li T, Wu Y Q, Luo L Z . Occurrence, damage and control of the wheat midge,Sitodiplosis mosellana(Diptera: Cecidomyiidae), in China. Acta Entomol Sin, 2013,56:1359-1366 (in Chinese with English abstract).
[11] Olfert O, Elliott R H, Hartley S . Non-native insects in agriculture: strategies to manage the economic and environmental impact of wheat midge,Sitodiplosis mosellana, in Saskatchewan. Biol Invasions, 2009,11:127-133.
doi: 10.1007/s10530-008-9324-0
[12] Gaafar N, El-Wakeil N, Volkmar C . Assessment of wheat ear insects in winter wheat varieties in central Germany. J Pest Sci, 2011,84:49-59.
doi: 10.1007/s10340-010-0325-2
[13] 屈振刚, 温树敏, 赵玉新, 路子云, 孙会 . 河北省麦红吸浆虫为害逐年加重的原因及防治对策. 河北农业科学, 2006,10(1):102-104.
Qu Z G, Wen S M, Zhao Y X, Lu Z Y, Sun H . Reason analysis and control strategies on the gradually increasedSitodiplosis mosellana Gehin damage in Hebei province. J Hebei Agric Sci, 2006,10(1):102-104 (in Chinese with English abstract).
[14] 郝燕冉, 温树敏, 王睿辉, 安雪娇, 刘桂茹 . 小麦品种冀麦24抗麦红吸浆虫QTL定位. 植物遗传资源学报, 2017,18:933-938.
Hao Y R, Wen S M, Wang R H, An X J, Liu G R . QTL analysis for midge resistance in wheat cultivar Jimai 24. J Plant Genet Resour, 2017,18:933-938 (in Chinese with English abstract).
[15] 黎丹 . 河北省麦红吸浆虫发生规律、成虫测报方法及品种抗虫性鉴定的研究. 河北农业大学研究生院硕士学位论文, 河北保定, 2012.
Li D . Study on Occurrence Regularity, the Method of Prediction of Adults, Analysis and Evaluation of Resistance of Wheat Midge, Sitodiplosis mosellana Géhin. MS Thesis of Agricultural University of Hebei, Baoding, Hebei, China, 2012 (in Chinese with English abstract).
[16] 仇松英, 史晓芳, 史忠良, 张松令, 谢福来, 高炜, 逯腊虎 . 小麦抗麦红吸浆虫品种遗传多样性的表型和SSR标记分析. 麦类作物学报, 2011,31:1050-1056.
doi: 10.7606/j.issn.1009-1041.2011.06.010
Qiu S Y, Shi X F, Shi Z L, Zhang S L, Xie F L, Gao W, Lu L H . Genetics diversity of wheat midge resistant varieties by phenotype and simple sequence repeat (SSR) markers analysis. J Triticeae Crops, 2011,31:1050-1056 (in Chinese with English abstract).
doi: 10.7606/j.issn.1009-1041.2011.06.010
[17] 瞿华香, 张玉烛, 张岳平, 曾翔, 屠乃美 . 分子标记辅助选择育种研究进展. 作物研究, 2008,22:355-358.
Qu H X, Zhang Y Z, Zhang Y P, Zeng X, Tu N M . Progress on marker-assisted selection. Crop Res, 2008,22:355-358 (in Chinese).
[18] 王昊龙, 韩俊杰, 李淼淼, 南富波, 李卫华 . 功能标记的开发及在禾谷类作物中的应用. 核农学报, 2014,28:1963-1971.
doi: 10.11869/j.issn.100-8551.2014.11.1963
Wang H L, Han J J, Li M M, Nan F B, Li W H . Development and application of functional markers in cereal crops. J Nuclear Agric Sci, 2014,28:1963-1971 (in Chinese with English abstract).
doi: 10.11869/j.issn.100-8551.2014.11.1963
[19] Li G, Quiros C F . Sequence-related amplified polymorphism (SRAP), a new marker system based on a simple PCR reaction: its application to mapping and gene tagging in Brassica. Theor Appl Genet, 2001,103:455-461.
doi: 10.1007/s001220100570
[20] 刘国圣, 张大乐 . 功能性分子标记在小麦育种中的应用. 生物技术通报, 2016,32(11):18-29.
doi: 10.13560/j.cnki.biotech.bull.1985.2016.11.003
Liu G S, Zhang D L . The application of the functional molecular marker in wheat breeding. Biotechnol Bull, 2016,32(11):18-29 (in Chinese with English abstract).
doi: 10.13560/j.cnki.biotech.bull.1985.2016.11.003
[21] Andersen J R, Lübberstedt T . Functional markers in plants. Trends Plant Sci, 2003,8:554-560.
doi: 10.1016/j.tplants.2003.09.010 pmid: 14607101
[22] 贺道华, 雷忠萍, 邢宏宜 . 功能标记的开发、特点和应用研究进展. 西北农林科技大学学报(自然科学版), 2009,37(1):110-116.
He D H, Lei Z P, Xing H Y . Development progress, characteristics and application of functional marker. J Northwest A&F Univ(Nat Sci Edn), 2009,37(1):110-116 (in Chinese with English abstract).
[23] 沈新莲, 张天真 . 作物分子标记辅助选择育种研究的进展与展望. 高技术通讯, 2003, ( 2):105-110.
Shen X L, Zhang T Z . Advances on molecular marker-assisted selection in crop. Chin High Technol Lett, 2003, ( 2):105-110 (in Chinese with English abstract).
[24] McKenzie R I H, Lamb R J, Aung T, Wise I L, Barker P, Olfert O O, McIntosh R I . Inheritance of resistance to wheat midge,Sitodiplosis mosellana, in spring wheat. Plant Breed, 2002,121:383-388.
doi: 10.1046/j.1439-0523.2002.745267.x
[25] Randhawa H S, Asif M, Pozniak C, Clarke J M, Graf R J, Fox S L, Humphreys D G, Knox R E, DePauw R M, Singh A K, Cuthbert R D, Hucl P, Spaner D, Gupta P . Application of molecular markers to wheat breeding in Canada. Plant Breed, 2013,132:458-471.
doi: 10.1094/PDIS-10-16-1421-RE pmid: 30682944
[26] Kassa M T, Haas S, Schliephake E, Lewis C, You F M, Pozniak C J, Krämer I, Perovic D, Sharpe A G, Fobert P R, Koch M, Wise I L, Fenwick P, Berry S, Simmonds J, Hourcade D, Senellart P, Duchalais L, Robert O, Förster J, Thomas J B, Friedt W, Ordon F, Uauy C, McCartney C A . A saturated SNP linkage map for the orange wheat blossom midge resistance gene Sm1. Theor Appl Genet, 2016,129:1507-1517.
doi: 10.1007/s00122-016-2720-4 pmid: 27160855
[27] Fox S L, Lamb R J, McKenzie R I H, Wise I L, Smith M A H, Humphreys D G, Brown P D, Townley-Smith T F, McCallum B D, Fetch T G, Menzies J G, Gilbert J A, Fernandez M R, Despins T, Lukow O, Niziol D . Registration of ‘Fieldstar’ hard red spring wheat. J Plant Regist, 2012,6:161-168.
doi: 10.3198/jpr2011.06.0329crc
[28] Blake N K, Stougaard R N, Weave D K, Sherman J D, Lanning S P, Naruoka Y, Xue Q, Martin J M, Talbert L,E . Identification of a quantitative trait locus for resistance to Sitodiplosis mosellana(Géhin), the orange wheat blossom midge, in spring wheat. Plant Breed, 2011,130:25-30.
doi: 10.1111/pbr.2011.130.issue-1
[29] 李建军, 李修炼, 成卫宁 . 小麦吸浆虫研究现状与展望. 麦类作物, 1999,19(3):52-55.
Li J J, Li X L, Cheng W N . Status and prospect on wheat blossom midge. Triticeae Crops, 1999,19(3):52-55 (in Chinese).
[30] 成卫宁, 李修炼, 李建军, 辛转霞 . 小麦品种抗麦红吸浆虫的研究现状与展望. 麦类作物学报, 2003,23(3):132-135.
doi: 10.7606/j.issn.1009-1041.2003.03.106
Cheng W N, Li X L, Li J J, Xin Z X . Status and prospect of studies on wheat blossom midge resistance of wheat varieties. J Triticeae Crops, 2003,23(3):132-135 (in Chinese with English abstract).
doi: 10.7606/j.issn.1009-1041.2003.03.106
[31] 赵菊香, 任芝英 . 小麦品种资源对麦红吸浆虫的抗性鉴定. 山西农业科学, 1990, ( 4):5-6.
Zhao J X, Ren Z Y . Evaluation of resistance in wheat cultivars and germplasms to Sitodiplosis mosellana(Géhin). J Shanxi Agric Sci, 1990, ( 4):5-6 (in Chinese).
[32] Zheng D S . Use of Italian wheat varieties in China. Genet Resour Crop Evol, 1993,40:137-142.
doi: 10.1007/BF00051118
[33] Lamb R J, McKenzie R I H, Wise I L, Barker P S, Smith M A H, Olfert O O . Resistance to Sitodiplosis mosellana(Diptera: Cecidomyiidae) in spring wheat (Graminae). Can Entomol, 2000,132:591-605.
doi: 10.4039/Ent132591-5
[34] Berzonsky W, Ding H, Haley S D, Harris M O, Lamb R J, McKenzie R I H, Ohm H W, Patterson F L, Peairs F B, Porter D R, Ratcliffe R H, Shanower T G . Breeding wheat for resistance to insects. Plant Breed Rev, 2003,22:221-297.
doi: 10.1007/s12298-019-00662-8 pmid: 31168238
[35] 张哲 . 小麦种质资源抗吸浆虫鉴定及分子标记筛选. 河北农业大学研究生院硕士学位论文, 河北保定, 2018.
Zhang Z . Screening for Midge-resistance Wheat Germplasm and Their Linked DNA-based Molecular Markers. MS Thesis of Agricultural University of Hebei, Baoding, Hebei, China, 2018 (in Chinese with English abstract).
[36] Ding H, Lamb R J, Ames N . Inducible production of phenolic acids in wheat and antibiotic resistance to Sitodiplosis mosellana. J Chem Ecol, 2000,26:969-985.
doi: 10.1023/A:1005412309735
[37] Abdel-Aal E S M, Hucl P, Sosulski F W, Graf R, Gillott C, Pietrzak L . Screening spring wheat for midge resistance in relation to ferulic acid content. J Agric Food Chem, 2001,49:3559-3566.
doi: 10.1021/jf010027h pmid: 11513628
[38] Wu X, Wu J, Luo Y, Bragg J, Anderson O, Vogel J, Gu Y Q . Phylogenetic, molecular, and biochemical characterization of caffeic acid O-methyltransferase gene family in Brachypodium distachyon. Int J Plant Genom, 2013,423189.
doi: 10.1155/2013/423189 pmid: 23431288
[39] 李小白, 向林, 罗洁, 胡标林, 田胜平, 谢鸣, 孙崇波 . 转录组测序(RNA-seq)策略及其数据在分子标记开发上的应用. 中国细胞生物学学报, 2013,35:720-726.
Li X B, Xiang L, Luo J, Hu B L, Tian S P, Xie M, Sun C B . The strategy of RNA-seq, application and development of molecular marker derived from RNA-seq. Chin J Cell Biol, 2013,35:720-726.
[40] 王智兰, 毛新国, 李昂, 昌小平, 刘惠民, 景蕊莲 . 小麦蛋白磷酸酶2A结构亚基基因TaPP2Aa的功能标记作图. 中国农业科学, 2011,44:2411-2421.
doi: 10.3864/j.issn.0578-1752.2011.12.001
Wang Z L, Mao X G, Li A, Chang X P, Liu H M, Jing R L . Functional marker mapping of protein phosphatase 2A structural subunit geneTaPP2Aa in common wheat. Sci Agric Sin, 2011,44:2411-2421 (in Chinese with English abstract).
doi: 10.3864/j.issn.0578-1752.2011.12.001
[41] Wu J H, Zeng Q D, Wang Q L, Liu S J, Yu S Z, Mu J M, Huang S, ·Sela H, Distelfeld A, Huang L L, Han D J, Kang Z S . SNP-based pool genotyping and haplotype analysis accelerate fine-mapping of the wheat genomic region containing stripe rust resistance gene Yr26. Theor Appl Genet, 2018,131:1481-1496.
doi: 10.1007/s00122-018-3092-8 pmid: 29666883
[42] 徐晓丹 . 5份小麦农家品种的抗白粉病基因分析及定位. 中国农业大学博士学位论文, 北京, 2017.
Xu X D . Identification and Mapping of Powdery Mildew Resistance Genes from Five Wheat Landraces. PhD Dissertation of China Agricultural University, Beijing, China, 2017 (in Chinese with English abstract).
[43] Liu S, Yeh C T, Tang H M, Nettleton D, Schnable P S . Gene mapping via bulked segregant RNA-seq (BSR-seq). PLoS One, 2012,7:e36406.
doi: 10.1371/journal.pone.0036406 pmid: 22586469
[44] Takagi H, Abe A, Yoshida K, Kosugi S, Natsume S, Mitsuoka C, Uemura A, Utsushi H, Tamiru M, Takuno S, Innan H, Cano L M, Kamoun S, Terauchi R . QTL-seq: rapid mapping of quantitative trait loci in rice by whole genome resequencing of DNA from two bulked populations. Plant J, 2013,74:174-83.
doi: 10.1111/tpj.12105
[45] Sutherland O R W, Russell G B, Biggs D R, Lane G A . Insect feeding deterrent activity of phytoalexin isoflavonoids. Biochem Syst Ecol, 1980,8:73-75.
doi: 10.1016/0305-1978(80)90029-0
[46] Caballero P, Smith C M, Franczek F R, Fischer N H . Isoflavones from an insect-resistant variety of soybeans and the molecular structure of afrormosin. J Nat Prod, 1986,49:1126-1129.
doi: 10.1021/np50048a030
[47] Saghai-Maroof M A, Soliman K M, Jorgensen R A, Allard R W . Ribosomal DNA spacer-length polymorphisms in barley: Mendelian inheritance, chromosomal location, and population dynamics. Proc Nat Acad Sci USA, 1984,81:8014-8018.
doi: 10.1073/pnas.81.24.8014 pmid: 6096873
[48] Lagudah E S, McFadden H, Singh R P, Huerta-Espino J, Bariana H S, Spielmeyer W . Molecular genetic characterization of the Lr34/Yr18 slow rusting resistance gene region in wheat. Theor Appl Genet, 2006,114:21-30.
doi: 10.1007/s00122-006-0406-z
[49] Lagudah E S, Krattinger S G, Herrera-Foessel S, Singh R P, Huerta-Espino J, Spielmeyer W, Brown-Guedira G, Selter L L, Keller B . Gene-specific markers for the wheat gene Lr34/Yr18/Pm38 which confers resistance to multiple fungal pathogens. Theor Appl Genet, 2009,119:889-898.
doi: 10.1007/s00122-009-1097-z
[50] 伍玲, 夏先春, 朱华忠, 李式昭, 郑有良, 何中虎 . CIMMYT 273个小麦品种抗病基因Lr34/Yr18/Pm38的分子标记检测. 中国农业科学, 2010,43:4553-4561.
Wu L, Xia X C, Zhu H Z, Li S Z, Zheng Y L, He Z H . Molecular characterization of Lr34/Yr18/Pm38 in 273 CIMMYT wheat cultivars and lines using functional markers. Sci Agric Sin, 2010,43:4553-4561 (in Chinese with English abstract).
[51] 张帆, 蒋雷, 鞠丽萍, 金秀锋, 王轩, 张晓科, 王宏礼, 付晓洁 . 一个普通小麦Trx 超家族新基因TaNRX的克隆与抗旱相关标记开发. 作物学报, 2014,40:29-36.
doi: 10.3724/SP.J.1006.2014.00029
Zhang F, Jiang L, Ju L P, Jin X F, Wang X, Zhang X K, Wang H L, Fu X J . Cloning a novel geneTaNRX of Trx superfamily and developing its molecular markers related to drought resistance in common wheat. Acta Agron Sin, 2014,40:29-36 (in Chinese with English abstract).
doi: 10.3724/SP.J.1006.2014.00029
[52] 肖永贵, 何心尧, 刘建军, 孙道杰, 夏先春, 何中虎 . 中国冬小麦品种多酚氧化酶活性基因等位变异检测及其分布规律研究. 中国农业科学, 2008,4:954-960.
Xiao Y G, He X Y, Liu J J, Sun D J, Xia X C, He Z H . Molecular identification and distribution of the polyphenol oxidase genes in Chinese winter wheat cultivars. Sci Agric Sin, 2008,4:954-960 (in Chinese with English abstract).
[53] He X Y, Zhang Y L, He Z H, Wu Y P, Xiao Y G, Ma C X, Xia X C . Characterization of phytoene synthase 1 gene (Psy1) located on common wheat chromosome 7A and development of a functional marker. Theor Appl Genet, 2008,116:213-221.
doi: 10.1007/s00122-007-0660-8
[54] 王亮, 穆培源, 徐红军, 庄丽, 桑伟, 聂迎彬, 韩新年, 邹波 . 新疆小麦品种黄色素含量基因(Psy-A1)等位变异的分子检测. 麦类作物学报, 2009,29:782-786.
doi: 10.7606/j.issn.1009-1041.2009.05.007
Wang L, Mu P Y, Xu H J, Zhuang L, Sang W, Nie Y B, Han X N, Zou B . Allelic variations ofPsy-A1 gene for yellow pigment content in Xinjiang wheat cultivars. J Triticeae Crops, 2009,29:782-786 (in Chinese with English abstract).
doi: 10.7606/j.issn.1009-1041.2009.05.007
[55] 胡凤灵, 何中虎, 葛建贵, 姜文武, 时萍, 夏先春 . 小麦品种黄色素含量和多酚氧化酶活性基因的分子标记检测. 麦类作物学报, 2011,31:47-53.
doi: 10.7606/j.issn.1009-1041.2011.01.009
Hu F L, He Z H, Ge J G, Jian W W, Shi P, Xia X C . Identification of genes for yellow pigment content and polyphenol oxidase activity in common wheat using molecular markers. J Triticeae Crops, 2011,31:47-53 (in Chinese with English abstract).
doi: 10.7606/j.issn.1009-1041.2011.01.009
[56] 张学林, 梅四伟, 郭天财, 王晨阳, 朱云集, 王永华 . 遗传和环境因素对不同冬小麦品种品质性状的影响. 麦类作物学报, 2010,30:249-253.
doi: 10.7606/j.issn.1009-1041.2010.02.012
Zhang X L, Mei S W, Guo T C, Wang C Y, Zhu Y J, Wang Y H . Effects of genotype and environment on winter wheat qualities. J Triticeae Crops, 2010,30:249-253 (in Chinese with English abstract).
doi: 10.7606/j.issn.1009-1041.2010.02.012
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