Scientia Agricultura Sinica ›› 2020, Vol. 53 ›› Issue (21): 4322-4332.doi: 10.3864/j.issn.0578-1752.2020.21.002

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

Breeding and Characteristics of a New Male Sterile Line of Maize, Jinyu1A

ZHANG HuanHuan1(),CUI GuiMei2(),WANG ChangBiao1,WANG XiaoQing1,HAO YaoShan1,DU JianZhong1,WANG YiXue1,SUN Yi1()   

  1. 1College of Life Sciences, Shanxi Agricultural University/Key Laboratory of Crop Gene Resources and Germplasm Enhancement on Loess Plateau, Ministry of Agriculture, Taiyuan 030031
    2The Seed Industry Limited Company of Shanxi Dafeng, Taiyuan 030031
  • Received:2019-12-14 Accepted:2020-03-07 Online:2020-11-01 Published:2020-11-11
  • Contact: Yi SUN E-mail:frank.red@163.com;guimeicui@126.com;sunyi692003@163.com

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Abstract:

【Objective】The study was aimed to determine the type of the male sterile line of maize, Jinyu1A, by molecular biology and cytology approaches, identify restoring and maintaining relationships of maize germplasm resources to the sterile line, and to test its general combining ability (GCA) and specific combining ability (SCA).【Method】The stability of sterility of Jinyu1A was investigated at 4 locations (Ledong, Jinzhong, Xinzhou and Yuncheng) for successive 3 years. Tassel, anther and pollen grains of Jinyu1A was observed and compared with Zheng58. F1 pollen grains of Jinyu1A×Chang7-2 were observed by I2-KI staining. The sterility type of Jinyu1A was identified by specific PCR. Jinyu1A was used as the female parent and test-crossed with 158 maize inbred lines. The fertility of F1 plants was investigated to screen for the suitable restorer and maintainer lines. The fertility of F2 and BC1 population plants was investigated. The grain yield general combining ability and specific combining ability of Jinyu1A were estimated by analyzing the data of its F1 hybrids.【Result】The sterility characters of Jinyu1A were stable in the 4 locations for the 3 years. The appearance of tassel of Jinyu1A was similar to that of Zheng58, but its glumes were closed, anthers were withered and could not exert out of the glumes, and I2-KI staining showed that the pollen of Jinyu1A was completely sterile. The microscopical observation on the pollen grains of F1 hybrid plants of Jinyu1A and Chang7-2 showed that 64.4% of the pollen grains could be stained dark by I2-KI and 35.6% pollen grains were aborted, which indicated that the sterile line belonged to S-type cytoplasmic sterile lines. The cytoplasm of Jinyu1A and Chang7-2 were identified as S-type male sterile type by specific PCR. The nuclear genome of Chang7-2 carries restorer genes, which concealed the phenotype of cytoplasmic male sterility. The specific primers suggested by ZHENG et al. were more applicable for categorizing maize cytoplasm sterile types. Among 158 inbred lines test-crossed with Jinyu1A as female parent, 96 maintainers, 47 restorers, and 15 semi-restorers were identified. There were 3.1%-8.7% sterile plants in F2 populations derived from fertile F1 plants of crosses between Jinyu1A and the restorer lines, which indicated that there were minor effect restorer genes in the restorer lines. There was no significant difference in the grain yields of the hybrids between each of Jinyu1A and Zheng58 as females and other 10 inbred lines as males, respectively. However, the F1 combining ability analysis of these hybrids showed that the general combining ability of Jinyu1A was slightly higher than that of Zheng58.【Conclusion】Jinyu1A was a S-type cytoplasmic male sterile line with stable male sterile characters and completely aborted pollen grains. There are a certain amount of restorer and maintainer type breeding stocks for Jinyu1A in the present maize germplasm resources. F1 plants of its hybrid with Chang7-2 could produce normal panicles and disperse fertile pollen. The existence of minor effect restorer gene(s) made the pollen dyeability shift to the direction of fertility, which led to the emergence of a few fertile plants in F2 populations. There was no significant difference in the grain yield between the hybrids with Jinyu1A and Zheng58 each as female parents test-crossed with the same male parents. The general combining ability of Jinyu1A was slightly higher than that of Zheng58, indicating that it could be used in the breeding programs for selecting new maize hybrids and male sterile lines.

Key words: maize, male sterility, restorer gene, combining ability

Table 1

Maize CMS specific primers"

引物名称
Primer name		 序列
Sequence (5’-3’)		 产物大小
Product size (bp)		 参考文献
Reference
CMST-F CATGAAATGGGTGAAGTCTCTTTC 440 [16]
CMST-R AAGAGAAAGGGAGACTTTGGTCCC
CMSC-F AGCATCATCCACATTCGCTAG 398
CMSC-R AGCATCATCCACATTCGCTAG
CMSS-F CAACTTATTACGAGGCTGATGC 799
CMSS-R AGTTCGTCCCATATACCCGTAC
CMST-1 GTCGTGTCCTGGTAGCCT 435 [17]
CMST-2 CCTCCTTCATTCCGTTGT
CMSC-1 TGAAAGGGTGGTGGAATA 698
CMSC-2 GAGCCAAAGTAATGAGAAAA
CMSS-1 GATGCTATGCTAAGCGAGAT 885
CMSS-2 CCGCTAACCCACTCTTCT

Fig. 1

Comparison of tassels and pollen between Jinyu1A and Zheng58 1: Tassels; 2: Anthers; 3: Pollen of Jinyu1A; 4: Pollen of Zheng58. A: Jinyu1A; B: Zheng58"

Fig. 2

F1 plants’ pollen of Jinyu1A×Chang7-2 and Zheng58×Chang7-2 stained with I2-KI A: F1 pollen of Jinyu1A×Chang7-2; B: F1 pollen of Zheng58×Chang7-2"

Fig. 3

PCR identification for specificity of Jinyu1A M: Marker 2000; 1-3: B73 (negative control); 4-6: JnA (positive control); 7-9: Jinyu1A; 10-12: Chang7-2 (cytoplasm source of Jinyu1A); 13-15: Zheng58 (maintainer of Jinyu1A)"

Table 2

Male sterile plants in the F2 and BC1 populations"

年份
Year		 群体
Population		 总株数
Total No.		 不育株
Sterile plant		 可育株
Normal plant		 不育率
Sterile rate (%)
2017 (昌7-2×郑58)×郑58 (Chang7-2×Zheng58)×Zheng58 48 25 23 52.1
2016 晋玉1A×昌7-2 F2群体 F2 population of Jinyu1A×Chang7-2 205 12 193 8.7
2016 晋玉1A×G155 F2群体 F2 population of Jinyu1A×G155 196 6 190 3.1
2016 晋玉1A×昌7-2无叶舌 F2群体
F2 population of Jinyu1A×Chang7-2 liguleless		 201 7 194 3.4
2017 晋玉1A×昌7-2 F2群体 F2 population of Jinyu1A×Chang7-2 343 24 319 7.0

Fig. 4

Yield of hybrids with Jinyu1A and Zheng 58 as female parents"

Table 3

Variance analysis of hybrid yields"

变异来源
Variation source		 自由度
df		 平方和
SS		 均方
Mean square		 F
F value		 F0.05 F0.01
区组Group 2 5428484.75 2714242.37 2.5438 2.9957 4.6052
父本一般配合力
Male general combining ability		 9 71335846.48 7926205.16 7.4285** 1.8799 2.4073
母本一般配合力
Female general combining ability		 1 786731.79 786731.79 0.7373 3.8415 6.6349
互作 Interaction 16 18321561.15 1145097.57 1.0732 1.6435 2.0000
误差 Error 31 62953214.52 1067003.64
总变异 Total variation 59 158825838.69

Table 4

General combining ability and effect value of inbred lines"

自交系
Inbred lines		 一般配合力
General combining
ability		 一般配合力效应值
General combining
ability effect (%)		 自交系
Inbred lines		 一般配合力
General combining
ability		 一般配合力效应值
General combining
ability effect (%)
PH4CV -741.31 -6.12 昌7-2 Chang7-2 705.11 5.82
PHB1M 932.83 7.70 G154 -500.23 -4.13
PH6WC 872.56 7.20 G30 -768.09 -6.34
B73 -747.99 -6.17 G31 1133.71 9.36
L269 1307.86 10.79 晋玉1A Jinyu1A 114.51 0.94
Mo17 -2194.45 -18.11 郑58 Zheng58 -114.51 -0.94

Table 5

Specific combining ability and effect value of hybrid combinations"

杂交组合
Hybrid combination		 特殊配合力
Specific combining ability		 特殊配合力效应值
Specific combining
ability effect (%)		 杂交组合
Hybrid combination		 特殊配合力
Specific combining ability		 特殊配合力效应值
Specific combining ability effect (%)
晋玉1A×PH4CV
Jinyu1A×PH4CV		 -188.14 -1.55 郑58×PH4CV
Zheng58×PH4CV		 188.14 1.55
晋玉1A×PHB1M
Jinyu1A×PHB1M		 -0.71 -0.01 郑58×PHB1M
Zheng58×PHB1M		 0.71 0.01
晋玉1A×PH6WC
Jinyu1A×PH6WC		 193.52 1.60 郑58×PH6WC
Zheng58×PH6WC		 -193.52 -1.60
晋玉1A×B73
Jinyu1A×B73		 622.10 5.13 郑58×B73
Zheng58×B73		 -622.10 -5.13
晋玉1A×L269
Jinyu1A×L269		 227.02 1.87 郑58×L269
Zheng58×L269		 -227.02 -1.87
晋玉1A×Mo17
Jinyu1A×Mo17		 -368.96 -3.04 郑58×Mo17
Zheng58×Mo17		 368.96 3.04
晋玉1A×昌7-2
Jinyu1A×Chang7-2		 -844.44 -6.97 郑58×昌7-2
Zheng58×Chang7-2		 844.44 6.97
晋玉1A×G154
Jinyu1A×G154		 561.85 4.64 郑58×G154
Zheng58×G154		 -561.85 -4.64
晋玉1A×G30
Jinyu1A×G30		 722.55 5.96 郑58×G30
Zheng58×G30		 -722.55 -5.96
晋玉1A×G31
Jinyu1A×G31		 -924.79 -7.63 郑58×G31
Zheng58×G31		 924.79 7.63
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