谷子近缘野生种的亲缘关系及其利用研究

doi:10.3724/SP.J.1006.2022.14047

作物学报 ›› 2022, Vol. 48 ›› Issue (2): 267-279.doi: 10.3724/SP.J.1006.2022.14047

• 综述 • 下一篇

谷子近缘野生种的亲缘关系及其利用研究

赵美丞¹^,²(), 刁现民²^,^*()

¹中国科学院遗传与发育生物学研究所农业资源研究中心/河北省节水农业重点实验室, 河北石家庄 050021
²中国农业科学院作物科学研究所, 北京 100081

收稿日期:2021-02-02 接受日期:2021-05-17 出版日期:2022-02-12 网络出版日期:2021-05-24
通讯作者: 刁现民
作者简介:E-mail: mczhao@sjziam.ac.cn
基金资助:
本研究由国家重点研发计划项目(2019YFD1000700);本研究由国家重点研发计划项目(2019YFD1000701);本研究由国家重点研发计划项目(2018YFD1000706);本研究由国家重点研发计划项目(2018YFD1000700);国家现代农业产业技术体系建设专项(CARS-06-13.5-A4);国家自然科学基金项目(31871634);河北省自然科学基金项目资助(C2020503004)

Phylogeny of wild Setaria species and their utilization in foxtail millet breeding

ZHAO Mei-Cheng¹^,²(), DIAO Xian-Min²^,^*()

¹Center for Agricultural Resources Research, Institute of Genetics and Developmental Biology, Chinese Academy of Sciences/Hebei Province Key Laboratory for Water-Saving Agriculture, Shijiazhuang 050021, Heibei, China
²Institute of Crop Sciences, Chinese Academy of Agricultural Sciences, Beijing 100081, China

Received:2021-02-02 Accepted:2021-05-17 Published:2022-02-12 Published online:2021-05-24
Contact: DIAO Xian-Min
Supported by:
This study was supported by the National Key Research and Development Program of China(2019YFD1000700);This study was supported by the National Key Research and Development Program of China(2019YFD1000701);This study was supported by the National Key Research and Development Program of China(2018YFD1000706);This study was supported by the National Key Research and Development Program of China(2018YFD1000700);the China Agricultural Research System(CARS-06-13.5-A4);the National Natural Science Foundation of China(31871634);the Natural Science Foundation of Hebei Province(C2020503004)

摘要/Abstract

摘要：

谷子在约1万年前由青狗尾草驯化而来, 我国是谷子的起源中心。谷子所属的狗尾草属在全世界约有125个种, 其中中国有15个种, 从二倍体到八倍体均有。目前利用染色体原位杂交技术鉴定出狗尾草属6个基因组, 利用分子标记分析发现狗尾草属是多起源的, 与其多样性的基因组一致。系统演化分析发现, 青狗尾草和谷子亲缘关系最近, 其次是法式狗尾草和轮生狗尾草; 基因组比较分析发现, S. adhaerans的B基因组和S. grisebachii的C基因组与谷子和青狗尾草的A基因具有相对近的亲缘关系, 而其他基因组和谷子亲缘较远。在野生资源的利用方面, 谷子育种工作者已成功将近缘野生种自然发生的抗除草剂基因转育到谷子中, 培育成功了可化学除草的新品种并在生产上利用。本文对谷子野生种的分类、基因组构成、系统进化关系和遗传育种的研究进展进行了综述, 重点讨论了谷子近缘野生种在谷子起源与驯化、遗传育种中起到的作用, 并对谷子近缘野生种在谷子驯化及育种中的进一步利用做了展望。

关键词: 谷子, 近缘野生种, 系统进化分析, 遗传育种

Abstract:

Foxtail millet (Setaria italica) was domesticated from the wild ancestor, green foxtail (S. viridis), about ten thousand years ago in China. Foxtail millet belongs to Setaria genus, which includes about 125 species of panicoid grasses worldwide, and 15 species of them in China varied from diploid to octoploid. Currently, six genomes in the Setaria genus have been identified by GISH (genomic in situ hybridization). Molecular phylogenetic analyses show that the Setaria genus is polyphyletic, in line with the characteristic of diversified genomes. Phylogeny of Setaria genus reveal that foxtail millet is most closely related with green foxtail, and then S. fabrei and S. verticillata, and that A genome of S. italica/S. viridis appears to be closer to B genome of S. adhaeran and C genome of S. grisebachii than the other known genomes. For utilization of wild species resources, foxtail millet breeders have successfully introduced the naturally mutated herbicide-resistant genes from green foxtail into cultivars, resulting in the herbicide-resistant foxtail millet variety. Here, we review the recent advances of wild species of foxtail millet in species classification, genome constitution and phylogenetic relationships, and highlight the utility of the wild species resources for breeding and domestication of foxtail millet. We also discuss the potentials of the wild Setaria species in discovery of domestication genes and breeding in foxtail millet in the future.

Key words: foxtail millet, wild species, phylogenetic analysis, breeding

赵美丞, 刁现民. 谷子近缘野生种的亲缘关系及其利用研究[J]. 作物学报, 2022, 48(2): 267-279.

ZHAO Mei-Cheng, DIAO Xian-Min. Phylogeny of wild Setaria species and their utilization in foxtail millet breeding[J]. Acta Agronomica Sinica, 2022, 48(2): 267-279.

图/表 4

表1

表2

图1

表3

已鉴定的自然突变抗除草剂狗尾草"

狗尾草种类 Species	发现年份 Year of the first identification	发现地点 Country	种植作物环境 Situation	抗除草剂种类 Active ingredients	除草剂作用位点 Site of action
S. viridis	1988	加拿大(曼尼托巴) Canada (Manitoba)	大麦 Barley 小麦 Wheat	乙丁烯氟灵 Ethalfluralin 氟乐灵 Trifluralin	微管抑制剂 Microtubule assembly inhibitors
S. viridis	1991	加拿大(曼尼托巴) Canada (Manitoba)	大麦 Barley 小麦 Wheat	禾草灵 Diclofop-methyl 拿扑净 Sethoxydim 肟草酮 Tralkoxydim	乙酰辅酶羧化酶抑制剂 Acetyl CoA carboxylase
S. viridis	1992	加拿大(曼尼托巴) Canada (Manitoba)	大麦 Barley 油菜 Canola	禾草灵 Diclofop-methyl 拿扑净 Sethoxydim 肟草酮 Tralkoxydim 氟乐灵 Trifluralin	微管和乙酰辅酶羧化酶抑制剂 Microtubule assembly and acetyl CoA carboxylase inhibitor
S. viridis	2001	加拿大(安大略省) Canada (Ontario)	玉米 Maize 大豆 Soybean	氟酮磺隆 Flucarbazone 咪唑乙烟酸 Imazethapyr 烟嘧磺隆 Nicosulfuron 嘧草硫醚 Pyrithiobac	乙酰乳酸合成酶抑制剂 Acetolactate synthase inhibitor
S. viridis	1982	法国 France	玉米 Maize	阿特拉津 Atrazine	光合作用光系统II抑制剂 Photosystem II inhibitor
S. viridis	1987	西班牙 Spain	玉米 Maize	阿特拉津 Atrazine	光合作用光系统II抑制剂 Photosystem II inhibitor
S. viridis	1989	美国(北达科他州) USA (North Dakota)	向日葵 Sunflower 小麦 Wheat	氟乐灵 Trifluralin	微管抑制剂 Microtubule assembly inhibitors
S. viridis	1999	美国(威斯康星州) USA (Wisconsin)	玉米 Maize 大豆 Soybean	甲氧咪草烟 Imazamox	乙酰乳酸合成酶抑制剂 Acetolactate synthase inhibitor
S. verticillata	1992	西班牙 Spain	玉米 Maize	阿特拉津 Atrazine	光合作用光系统II抑制剂 Photosystem II inhibitor
S. faberi	2003	加拿大(安大略省) Canada (Ontario)	大豆 Soybean	咪唑乙烟酸 Imazethapyr	乙酰乳酸合成酶抑制剂 Acetolactate synthase inhibitor
S. faberi	1987	西班牙 Spain	玉米 Maize	阿特拉津 Atrazine	光合作用光系统II抑制剂 Photosystem II inhibitor
S. faberi	1984	美国(马里兰州) USA (Maryland)	玉米 Maize	阿特拉津 Atrazine	光合作用光系统II抑制剂 Photosystem II inhibitor
S. faberi	1991	美国(威斯康星州) USA (Wisconsin)	胡萝卜 Carrot 玉米 Maize 洋葱 Onion	氟禾草灵 Fluazifop-butyl 拿扑净 Sethoxydim	乙酰辅酶羧化酶抑制剂 Acetyl CoA carboxylase
S. faberi	1999	美国(威斯康星州) USA (Wisconsin)	玉米 Maize 大豆 Soybean	咪唑乙烟酸 Imazethapyr 烟嘧磺隆 Nicosulfuron	乙酰乳酸合成酶抑制剂 Acetolactate synthase inhibitor
S. glauca	1997	美国(明尼苏达州) USA (Minnesota)	大豆 Soybean	咪唑乙烟酸 Imazethapyr	乙酰乳酸合成酶抑制剂 Acetolactate synthase inhibitor
S. glauca	1981	法国 France	玉米 Maize	阿特拉津 Atrazine	光合作用光系统II抑制剂 Photosystem II inhibitor

表3

参考文献 48

[1]	Diao X M, Jia G Q. Origin and domestication of foxtail millet. In: Doust A, Diao X, eds. Genetics and Genomics of Setaria. Berlin: Springer, 2017. pp 61-72.
[2]	刁现民. 禾谷类杂粮作物耐逆和栽培技术研究新进展. 中国农业科学, 2019,52:3943-3949.
	Diao X M. Progresses in stress tolerance and field cultivation studies of orphan cereals in China. Sci Agric Sin, 2019,52:3943-3949 (in Chinese with English abstract).
[3]	Diao X M, Schnable J, Bennetzen J L, Li J Y. Initiation of Setaria as a model plant. Front Agric Sci Eng, 2014,1:16-20.
[4]	Brutnell T P, Wang L, Swartwood K, Goldschmidt A, Jackson D, Zhu X G, Kellogg E, Eck J V. Setaria viridis: a model for C₄ photosynthesis. Plant Cell, 2010,22:2537-2544.
[5]	Diao X M, Jia G Q. Foxtail millet germplasm and inheritance of morphological characteristics. In: Doust A, Diao X, eds. Genetics and Genomics of Setaria. Berlin: Springer, 2017. pp 73-92.
[6]	Li C H, Pao W K, Li H W. Interspecific crosses in Setaria: II. Cytological studies of interspecific hybrids involving: 1, S. faberii and S. italica, and 2, a three way cross, F₂ of S. italica × S. viridis and S. faberii. J Heredity, 1942,33:351-355.
[7]	高俊华, 毛丽萍, 王润奇. 谷子四体的细胞学和形态学研究. 作物学报, 2000,26:801-805.
	Gao J H, Mao L P, Wang R Q. A study on the cytology and morphology of the tetrasomics in foxtail millet. Acta Agron Sin, 2000,26:801-805 (in Chinese with English abstract).
[8]	Wang Y Q, Zhi H, Li W, Li H Q, Wang Y F, Huang Z J, Diao X M. A novel genome of C and the first autotetraploid species in the Setaria genus identified by genomic in situ hybridization. Genet Resour Crop Evol, 2009,56:843-850.
[9]	Zhao M C, Zhi H, Doust A N, Li W, Wang Y F, Li H Q, Jia G Q, Wang Y Q, Zhang N, Diao X M. Novel genomes and genome constitutions identified by GISH and 5S rDNA and knotted1 genomic sequences in the genus Setaria. BMC Genomics, 2013,14:244.
[10]	Benabdelmouna A, Shi Y, Abirached-Darmency M, Darmency H. Genomic in situ hybridization (GISH) discriminates between the A and the B genomes in diploid and tetraploid Setaria species. Genome, 2001,44:685-690.
[11]	Benabdelmouna A, Abirached-Darmency M, Darmency H. Phylogenetic and genomic relationships in Setaria italica and its close relatives based on the molecular diversity and chromosomal organization of 5S and 18S-5.8S-25S rDNA genes. Theor Appl Genet, 2001,103:668-677.
[12]	Hubbard F T. A taxonomic study of Setaria and its immediate allies. Am J Bot, 1915,2:169-198.
[13]	Dekker J. The evolutionary biology of the foxtail (Setaria) species-group. In: Inderjit, ed. Weed Biology and Management. Dordrecht: Kluwer Academic, 2004. pp 65-113.
[14]	Rominger J M. Taxonomy of Setaria(Gramineae) in North America. Bull Torrey Bot Club, 1962,29:1-132.
[15]	Pensiero J F. Las especies sudamericanas del género Setaria(Poaceae, Paniceae). Darwiniana, 1999,37:37-151 (in Spanish with English abstract).
[16]	Morrone O, Aliscioni S A, Veldkamp J F, Pensiero J, Zuloaga F O, Kellogg E A. A revision of the old world species of Setaria. Syst Bot Monographs, 2014,96:1-160.
[17]	Kellogg E A, Aliscioni S S, Morrone O, Pensiero J, Zuloaga F. A phylogeny of Setaria(Poaceae, Panicoideae, Paniceae) and related genera, based on the chloroplast gene ndhF. Int J Plant Sci, 2009,170:117-131.
[18]	郑殿升. 中国粮食作物的野生近缘植物及其保存概况. 中国野生植物资源, 2006,25(5):5-7.
	Zheng D S. General situation of wild relatives of food crop and their conservation in China. Chin Wild Plant Resour, 2006,25(5):5-7 (in Chinese with English abstract).
[19]	Kellogg E A. Evolution of Setaria. In: Doust A, Diao X, eds. Genetics and Genomics of Setaria. Berlin: Springer, 2017. pp 3-27.
[20]	Dekker J. The foxtail (Setaria) species-group. Weed Sci, 2003,51:641-656.
[21]	Doust A N, Penly A M, Jacobs S W L, Kellogg E A. Congruence, conflict, and polyploidization shown by nuclear and chloroplast markers in the monophyletic “bristle clade” (Paniceae, Panicoideae, Poaceae). Syst Bot, 2007,32:531-544.
[22]	Jia G Q, Shi S K, Wang C F, Niu Z G, Chai Y, Zhi H, Diao X M. Molecular diversity and population structure of Chinese green foxtail [Setaria viridis(L.) Beauv.] revealed by microsatellite analysis. J Exp Bot, 2013,64:3645-3656.
[23]	王永强, 智慧, 李伟, 李海权, 王永芳, 刁现民. 狗尾草属野生近缘种的染色体鉴定. 植物遗传资源学报, 2007,8:159-164.
	Wang Y Q, Zhi H, Li W, Li H Q, Wang Y F, Diao X M. Chromosome number identification of some wild Setaria species. J Plant Genet Resour, 2007,8:159-164 (in Chinese with English abstract).
[24]	Kim S, Kim C S, Lee J, Lee I Y, Chung Y J, Cho M S, Kim S C. Phylogenetic relationships among species of Setaria(Paniceae; Panicoideae; Poaceae) in Korea: insights from nuclear, 2015,301:725-736.
[25]	Layton D J, Kellogg E A. Morphological, phylogenetic, and ecological diversity of the new model species Setaria viridis(Poaceae: Paniceae) and its close relatives. Am J Bot, 2014,101:539-557.
[26]	吴权明, 白君礼. 谷子与轮生狗尾草(2x、4x)种间的亲缘关系分析. 西北植物学报, 2000,20:954-959.
	Wu Q M, Bai J L. Cytogenetic and isoenzymic studies on Setaria millet and S. verticillata(2x) and S. verticiformis, 2000,20:954-959 (in Chinese with English abstract).
[27]	黎裕, 王雅儒. 谷子及其近缘种的蛋白质变异. 作物品种资源, 1998, (2):3-5.
	Li Y, Wang Y R. Protein variation analysis of foxtail millet and related wild species. China Seed Ind, 1998, (2):3-5 (in Chinese with English abstract).
[28]	吴权明, 陈雪婷, 朱静林. 谷子及其近缘野生种酯酶同工酶分析(I). 西北农业学报, 2000,9(3):106-109.
	Wu Q M, Chen X T, Zhu J L. A isozyme study on foxtail millet and some related species (I). Acta Agric Boreali-Occident Sin, 2000,9(3):106-109 (in Chinese with English abstract).
[29]	吴权明. 谷子及其近缘野生种酯酶同工酶分析(II). 西北农业学报, 2001,10(2):39-44.
	Wu Q M. A isozyme study on foxtail millet and some related species (II). Acta Agric Boreali-Occident Sin, 2001,10(2):39-44 (in Chinese with English abstract).
[30]	阎洪波, 黎裕, 王天宇, 石云素, 宋燕春, 马峙英, 周世良. 中国谷子主产区谷子近缘种狗尾草的遗传多样性. 西北植物学报, 2003,23:926-932.
	Yan H B, Li Y, Wang T Y, Shi Y S, Song Y C, Ma Z Y, Zhou S L. Genetic diversity of wild relatives of foxtail millet distributed in the major foxtail millet production regions of China. Acta Bot Boreali-Occident Sin, 2003,23:926-932 (in Chinese with English abstract).
[31]	Jusuf M, Pernes J. Genetic variability of foxtail millet (Setaria italica P. Beauv.). Theor Appl Genet, 1985,71:385-391.
[32]	Le Thierry d’Ennequin M, Panaud O, Toupance B, Sarr A. Assessment of genetic relationships between Setaria italica and its wild relative S. viridis using AFLP markers. Theor Appl Genet, 2000,100:1061-1066.
[33]	Li Y, Jia J, Wang Y, Wu S. Intraspecific and interspecific variation in Setaria revealed by RAPD analysis. Genet Resour Crop Evol, 1998,45:279-285.
[34]	Li W, Zhi H, Wang Y F, Li H Q, Diao X M. Assessment of genetic relationship of foxtail millet with its wild ancestor and close relatives by ISSR markers. J Integr Agric, 2012,11:556-566.
[35]	Hirano R, Naito K, Fukunaga K, Watanabe K N, Ohsawa R, Kawase M. Genetic structure of landraces in foxtail millet (Setaria italica(L.) P. Beauv.) revealed with transposon display and interpretation to crop evolution of foxtail millet. Genome, 2011,54:498-506.
[36]	Jia G Q, Huang X H, Zhi H, Zhao Y, Zhao Q, Li W J, Chai Y, Yang L F, Liu K Y, Lu H Y, Zhu C R, Lu Y Q, Zhou C C, Fan D L, Weng Q J, Guo Y L, Huang T, Zhang L, Lu T T, Feng Q, Hao, H F, Liu H K, Lu P, Zhang N, Li Y H, Guo E H, Wang S J, Wang S Y, Liu J R, Zhang W F, Chen G Q, Zhang B J, Li W, Wang Y F, Li H Q, Zhao B H, Li J Y, Diao X M, Han B. A haplotype map of genomic variations and genome-wide association studies of agronomic traits in foxtail millet (Setaria italica). Nat Genet, 2013,45:957-961.
[37]	Mamidi S, Healey A, Huang P, Grimwood J, Jenkins J, Barry K, Sreedasyam A, Shu S, Lovell J T, Feldman M, Wu J, Yu Y, Chen C, Johnson J, Sakakibara H, Kiba T, Sakurai T, Tavares R, Nusinow D A, Baxter I, Schmutz J, Brutnell T P, Kellogg E A. A genome resource for green millet Setaria viridis enables discovery of agronomically valuable loci. Nat Biotechnol, 2020,38:1203-1210.
[38]	Doust A N, Devos K M, Gadberry M D, Gale M D, Kellogg E A. Genetic control of branching in foxtail millet. Proc Natl Acad Sci USA, 2004,101:9045-9050.
[39]	Yu Y, Hu H, Doust A N, Kellogg E A. Divergent gene expression networks underlie morphological diversity of abscission zones in grasses. New Phytol, 2002,225:1799-1815.
[40]	智慧, 王永强, 李伟, 王永芳, 李海权, 陆平, 刁现民. 利用野生青狗尾草的细胞质培育谷子质核互作雄性不育材料. 植物遗传资源学报, 2007,8:261-264.
	Zhi H, Wang Y Q, Li W, Wang Y F, Li H Q, Lu P, Dian X M. Development of CMS material from intra-species hybridization between green foxtail and foxtail millet. J Plant Genet Resour, 2007,8:261-264 (in Chinese with English abstract).
[41]	朱光琴, 李续中, 师公贤, 李亚文. 谷子不育系同源四倍体秋水仙碱引变试验. 陕西农业科学, 1987, ( 6):33.
	Zhu G Q, Li J Z, Shi G X, Li Y W. Development of autotetraploid sterile line in foxtail millet by colchicine induction. Shaanxi J Agric Sci, 1987, ( 6):33 (in Chinese with English abstract).
[42]	朱光琴, 吴权明, 马云彤. 谷子Ve型不育系的选育. 陕西农业科学, 1991, (1):7.
	Zhu G Q, Wu Q M, Ma Y T. Development of Ve type of sterile line in foxtail millet. Shaanxi J Agric Sci, 1991, ( 1):7 (in Chinese with English abstract).
[43]	Darmency H, Pernes J. Use of wild Setaria viridis(L.) Beauv. to improve triazine resistance in cultivated S. italica, 2006,25:175-179.
[44]	李志江. 谷子抗除草剂基因的发现及其应用. 基因组学与应用生物学, 2010,29:768-774.
	Li Z J. Discovery and application of herbicide resistant gene in foxtail millet. Genomics Appl Biol, 2010,29:768-774 (in Chinese with English abstract).
[45]	Zhao H J, Wang J H, Gao P, Gu R L, Zhang J Q, Wang T Y. Cloning of plastid AcetylCoA carboxylase cDNA from Setaria italica and sequence analysis of graminicide target site. Acta Bot Sin, 2004,46:751-756.
[46]	Darmency H, Picard J C, Wang T. Fitness costs linked to dinitroaniline resistance mutation in Setaria. Heredity, 2011,107:80-86.
[47]	王天宇, 石云素, 辛志勇, Darmency H. 抗除草剂谷子新种质的创制、鉴定与利用. 中国农业科技导报, 2000, ( 5):62-66.
	Wang T Y, Shi Y S, Xin Z Y, Darmency H. Development and utilization of herbicide-resistant foxtail millet variety. J Agric Sci Technol, 2000, ( 5):62-66 (in Chinese with English abstract).
[48]	Tian J G, Wang C L, Xia J L, Wu L S, Xu G H, Wu W H, Li D, Qin W C, Han X, Chen Q Y, Jin W W, Tian F. Teosinte ligule allele narrows plant architecture and enhances high-density maize yields. Science, 2019,365:658-664.

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物种名称 Species name	起源地 Origin	染色体数目 Chromosome number (2n)
S. adhaerens	亚洲 Asia	18
S. apiculata	澳大利亚 Australia	36
S. barbata	非洲 Africa	54, 56
S. faberi	南美洲 South America	36
S. flavida	澳大利亚 Australia	44, 54
S. geminata	非洲 Africa	ND
S. grisebachii	北美洲和南美洲 North and South America	18
S. homonyma	非洲 Africa	ND
S. italica	亚洲 Asia	18, 36
S. kagerensis	非洲 Africa	18
S. lachnea	南美洲 South America	36
S. leucopila	美国, 墨西哥, 南美洲 USA, Mexico, and South America	54, 68, 72
S. longiseta	非洲 Africa	36
S. macrostachya	北美洲和南美洲 North and South America	54, 72
S. magna	北美洲和南美洲 North and South America	36
S. nigrirostris	非洲 Africa	18, 36, 54
S. oblongata	阿根廷和玻利维亚 Argentina and Bolivia	ND
S. palmifolia	亚洲和非洲 Asia and Africa	54, 36
S. pampeana	阿根廷 Argentina	50
S. pflanzii	南美洲 South America	36
S. plicata	亚洲 Asia	ND
S. pumila	非洲和亚洲 Africa and Asia	36, 54
S. restioidea	非洲 Africa	ND
S. rosengurtii	南美洲 South America	ND
S. scabrifolia	南美洲 South America	ND
S. sphacelata	非洲 Africa	18, 36, 54
S. sulcata	北美洲和南美洲 North and South America	18, 32, 36
S. tenacissima	北美洲和南美洲 North and South America	54, 36
S. vaginata	南美洲 South America	18
S. verticillata	欧亚大陆 Eurasia	36, 54
S. viridis	亚洲 Asia	18
S. vulpiseta	北美洲和南美洲 North and South America	36, 54

种名 Species name	起源地 Origin	搜集号 Accession number	染色体倍数 Chromosome number	基因组构成 Genome constitutions
S. viridis	中国河北 Hebei, China	N033	2n = 2x = 18	AA
S. viridis	俄罗斯 Russia	09005	2n = 2x = 18	AA
青9 Qing 9	中国河北 Hebei, China	N011	2n = 2x = 18	BB
S. adhaerans	西班牙 Spain	02448	2n = 2x = 18	BB
S. adhaerans	美国夏威夷 Hawaii, USA	25001	2n = 2x = 18	BB
S. grisebachii	墨西哥 Mexico	03001	2n = 2x = 18	CC
S. queenslandica	澳大利亚 Australia	PI316342	2n = 4x = 36	AAAA
S. lachnea	澳大利亚 Australia	11001	2n = 4x = 36	CCC’C’
S. verticillata	法国 France	08006	2n = 4x = 36	AABB
S. faberi	俄罗斯 Russia	02005	2n = 4x = 36	AABB
S. glauca	美国 USA	04004	2n = 4x = 36	X (DD)
S. glauca	日本 Japan	04002	2n = 8x = 72	X (DD)
S. plicata	中国昆明 Kunming, China	25001	2n = 4x = 36	X (EE)
S. palmifolia	中国昆明 Kunming, China	26001	2n = 6x = 54	X (EE)
S. arenaria	中国昆明 Kunming, China	27001	2n = 6x = 54	X (FF)

谷子近缘野生种的亲缘关系及其利用研究

Phylogeny of wild Setaria species and their utilization in foxtail millet breeding

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