Crops ›› 2018, Vol. 34 ›› Issue (6): 1-9.doi: 10.16035/j.issn.1001-7283.2018.06.001

    Next Articles

Preservation and Researches on Plant Germplasm Resources in the U.S.A.

Li Yu,Wang Tianyu   

  1. Institute of Crop Sciences, Chinese Academy of Agricultural Sciences, Beijing 100081, China
  • Received:2018-09-06 Online:2018-12-15 Published:2018-12-06

RichHTML

66

PDF (PC)

1433

Abstract:

USA is the country which preserves the most plant germplasm resources in the world although it is not a center of origin of crop plants. Generally, USA has a good National Plant Germplasm System (NPGS), with a stable and flexible system of laws and regulations, management policies, germplasm exchange and beneficial sharing and funding system. In recent years, plant germplasm preservation facilities and information network have steadily improved, and a great progress has been made in the fields of germplasm collecting, characterization and evaluation, gene discovery and germplasm enhancement, reflecting the characteristics of basic and non-profit activities. This paper reviews the current situation of preservation and researches on plant germplasm resources in USA and renders advice to germplasm preservation, research and management in China.

Key words: Plant germplasm resources, Conservation, USA

Table 1

Status of germplasm preservation in NPGS (up to Aug. 2018)"

基因库名称
Name of genebanks		 依托单位和地点
Supporting unit and location		 保存植物种类
Kind of plants preserved		 保存份数
Number of
accessions
遗传资源保护国家中心
National Center for Genetic Resources Preservation		 USDA-ARS,科罗拉多州Fort Collins 多种作物 11 741
植物品种保护库
Plant Variety Protection Voucher Collection		 USDA-ARS遗传资源保护国家中心,科罗拉多州Fort Collins 多种作物 7 980
植物种质资源检疫项目
Plant Germplasm Quarantine Program		 USDA-ARS,马里兰州Beltsville 多种作物 949
植物遗传资源保护部(原南部地区植物引种站)
Plant Genetic Resources Conservation Unit		 USDA-ARS,乔治亚州Griffin 高粱、甘薯、花生、豇豆、绿豆、甜瓜、辣椒、亚热带和热带食用豆作物、温季牧草等 101 182
中北部地区植物引种站
North Central Regional PI Station		 USDA-ARS,衣阿华州立大学Ames 玉米、油用芸薹属植物、瓜类作物、草木樨、籽粒苋、向日葵、粟类作物、胡萝卜、亚麻 54 785
东北部地区植物引种站
Northeast Regional PI Station		 USDA-ARS植物遗传资源部,纽约州Geneva 番茄、蔬菜类芸薹属作物、洋葱、苹果、葡萄、酸樱桃 12 695
西部地区植物引种站
Western Regional PI Station
 USDA-ARS,华盛顿州立大学Pullman,还在该州Prosser建立了国立温带豆科牧草遗传资源部 菜豆、豌豆、蚕豆、鹰嘴豆、洋葱、莴苣、
苜蓿、甜菜、红花,还包括冷季和温带牧草、园艺作物、药用作物等		 101 465
国家小粒禾谷类作物种质库
National Small Grains Collection		 USDA-ARS,爱达荷州Aberdeen 小麦、大麦、燕麦、水稻、黑麦、小黑麦地方品种及其野生近缘种,还包括小麦遗传材料、超过2000份的大麦非整倍体等遗传材料 146 409
玉米遗传材料中心Maize Genetic Stock Center USDA-ARS植物生理和遗传研究部,伊利诺伊大学University of Illinois,Urbana 玉米遗传材料 8 127
水稻遗传材料中心Rice Genetic Stock Center USDA-ARS Dale Bumpers国家水稻研究中心,阿肯色州Stuttgart 水稻遗传材料 37 809
大豆种质库Soybean Collection USDA-ARS,伊利诺伊州Urbana 大豆地方品种、野生种 22 498
马铃薯种质资源引种站
Potato Germplasm Introduction Station		 USDA-ARS,威斯康星州Sturgeon Bay 马铃薯 5 767
豌豆遗传材料库Pea Genetic Stock Collection USDA-ARS,华盛顿州立大学Pullman 豌豆、冷季食用豆 712
沙漠豆科植物项目Desert Legume Program 亚利桑那大学The University of Arizona,Tucson 沙漠豆科植物 2 608
C.M. Rick番茄遗传资源中心
Tomato Genetic Resources Center		 加州大学戴维斯分校University of California,Davis 番茄地方品种、野生种、突变体、导入系材料等 3 795
棉花种质库Cotton Collection USDA-ARS作物种质资源研究实验室,德克萨斯州College Station 棉花地方品种、野生种 9 798
烟草种质库
US Nicotiana Germplasm Collection		 北卡罗莱纳州立大学Raleigh 烟草地方品种、野生种,62个种 2 226
国家种质圃Brownwood分圃
National Germplasm Repository-Brownwood		 USDA-ARS,德克萨斯州Somerville 美洲山核桃、山胡桃、栗 4 066
国家种质圃Corvallis分圃
National Germplasm Repository-Corvallis		 USDA-ARS,俄勒冈州Corvallis 梨、草莓、木莓、黑莓、蓝莓等温带果树和坚果作物,以及啤酒花等专用作物 12 571
国家种质圃Davis分圃
National Germplasm Repository-Davis		 USDA-ARS,加州大学Davis分校University of California,Davis 葡萄、核果类作物、胡桃、杏、橄榄、阿月浑子、无花果、柿、桑、猕猴桃、石榴等 8 747
基因库名称
Name of genebanks		 依托单位和地点
Supporting unit and location		 保存植物种类
Kind of plants preserved		 保存份数
Number of
accessions
国家种质圃Geneva分圃
National Germplasm Repository-Geneva		 USDA-ARS,纽约州农业试验站Geneva 苹果、葡萄、酸樱桃 7 612
国家种质圃Hilo分圃
National Germplasm Repository-Hilo
 USDA-ARS,夏威夷州Hilo 昆士兰果、凤梨、番木瓜、荔枝、木菠萝、杨桃、番石榴、西番莲、红毛丹、面包树等热带果树和坚果作物 851
国家种质圃Mayaguez分圃
National Germplasm Repository-Mayaguez		 USDA-ARS热带农业研究站,波多黎各Mayaguez 香蕉、可可、热带果树 1 167
国家种质圃Miami分圃
National Germplasm Repository-Miami		 USDA-ARS,佛罗里达Miami 甘蔗、芒果和鳄梨等亚热带果树和坚果作物、观赏植物 3 327
国家种质圃Riverside分圃
National Germplasm Repository-Riverside		 USDA-ARS,加利福尼亚州Riverside 柑橘及其他芸香科植物、海枣及相关种 1 801
观赏植物种质资源中心
Ornamental Plant Germplasm Center		 俄亥俄州立大学Columbus 主要是秋海棠、金鸡菊、百合、草夹竹桃、金光菊、堇菜6个属的草本观赏植物,超过200个属 5 456
国立干旱陆地植物遗传资源部
National Arid Land Plant Genetic Resources Unit		 USDA-ARS,加利福尼亚州Parlier 不仅包括非冬季大麦和小麦、野生向日葵、红花、榛子等,还包括一些新型经济作物(如仙人掌果、泡泡白花草、银胶菊、希蒙得木等),在干旱贫瘠土壤上潜在经济作物(Hesperaloe),以及干旱地区土壤保持作物
(Atriplex,Bassia and Yucca),13个属126个种		 1 499
种子国家实验室(National Seed Laboratory)林木实验室 乔治亚州Dry Branch 林木 7 628
国家植物园National Arboretum 马里兰州Beltsville 木本景观植物 8 343
[1] Williams K A . An overview of the U.S. National Plant Germplasm System’s exploration program. HortScience, 2005,40:297-301.
[2] Brown A H D . The case for core collections//Brown A H D,Frankel O H, Marshall D R, et al. The use of plant genetic resources. Cambridge University Press, Cambridge,UK, 1989: 136-156.
[3] Sharma S, Upadhyaya H D, Varshney R K , et al. Pre-breeding for diversification of primary gene pool and genetic enhancement of grain legumes. Frontiers in Plant Science, 2013,4(1):309.
doi: 10.3389/fpls.2013.00309 pmid: 3747629
[4] Richards C M, Volk G M, Reeves P A , et al. Selection of stratified core sets representing wild apple (Malus sieversii). Journal of the American Society for Horticulturalence, 2009,134(2):228-235.
doi: 10.1051/fruits/2009006
[5] Potts S M, Han Y, Khan M A , et al. Genetic diversity and characterization of a core collection of Malus germplasm using simple sequence repeats (SSRs). Plant Molecular Biology Reporter, 2012,30(4):827-837.
doi: 10.1007/s11105-011-0399-x
[6] Quick J S, Nkongolo K K, Meyer W , et al. Russian wheat aphid reaction and agronomic and quality traits of a resistant wheat. Crop Science, 1991,31(1):50-53.
doi: 10.2135/cropsci1991.0011183X003100010012x
[7] Quick J S, Ellis G E, Normann R M , et al. Registration of ‘Halt’ wheat. Crop Science, 1996,36(1):210.
[8] Collins M B, Haley S D, Peairs F B , et al. Biotype 2 Russian wheat aphid resistance among wheat germplasm accessions. Crop Science, 2005,45(5):1877-1880.
doi: 10.2135/cropsci2004.0730
[9] Panthee D R, Gardner R G, Ibrahem R , et al. Molecular markers associated with Ph-3 gene conferring late blight resistance in tomato. American Journal of Plant Sciences, 2015,6(13):2144-2150.
doi: 10.4236/ajps.2015.613216
[10] Elshire R J, Glaubitz J C, Sun Q , et al. A robust,simple genotyping-by-sequencing (GBS) approach for high diversity species. PLoS ONE, 2011,6(5):e19379.
doi: 10.1371/journal.pone.0019379
[11] Buckler E S, Ilut D C, Wang X , et al. rAmpSeq:Using repetitive sequences for robust genotyping. bioRxiv, 2016. doi: 10.1101/096628.
[12] Yang S, Fresnedo-Ramírez J, Wang M , et al. A next-generation marker genotyping platform (AmpSeq) in heterozygous crops:a case study for marker-assisted selection in grapevine. Horticulture Research, 2016,3:16002.
doi: 10.1038/hortres.2016.2 pmid: 4879517
[13] Romay M C, Millard M J, Glaubitz J C , et al. Comprehensive genotyping of the USA national maize inbred seed bank. Genome Biology, 2013,14(6):R55.
doi: 10.1186/gb-2013-14-6-r55 pmid: 23759205
[14] Song Q, Hyten D L, Jia G , et al. Fingerprinting soybean germplasm and its utility in genomic research. G3:Genes, Genomes and Genetics, 2015,5(10):1999-2006.
doi: 10.1534/g3.115.019000 pmid: 4592982
[15] Crop Genebank Knowledge Base. Pre-breeding for effective use of plant genetic resources: E-learning course. Crop Genebank Knowledge Base,2018.[ 2018-09-10] .
[16] Falk D . Pre-domesticating wild relatives as new sources of novel genetic diversity// Maxted N,Dulloo M E,Ford-Lloyd B V. Enhancing crop genepool use:Capturing wild relative and landrace diversity for crop improvement. CAB Int., Boston, 2016.
[17] GEM. Germplasm enhancement of maize. Iowa State University,2018.[ 2018-09-10] .
[18] Maxted N, Dulloo M E, Ford-Lloyd B V . Enhancing crop genepool use:Capturing wild relative and landrace diversity for crop improvement. CAB Int., Boston, 2016.
[19] Ogbonnaya F C, Abdalla O, Mujeeb-Kazi A , et al. Synthetic hexaploids: Harnessing species of the primary gene pool for wheat improvement. Plant Breeding Reviews, 2013,37(1):35-122.
doi: 10.1002/9781118497869.ch2
[20] Byrne P F, Volk G M, Gardner C , et al. Sustaining the future of plant breeding:The critical role of the USDA-ARS National Plant Germplasm System. Crop Science, 2018,58:451-468.
doi: 10.2135/cropsci2017.05.0303
[21] Crop Trust. Conservation strategies. 2018. [2018-09-10] .
[1] Ying Chai,Yongqing Xu,Yao Fu,Xiuyu Li,Fumeng He,Yingqi Han,Zhe Feng,Fenglan Li. Characteristics of Cell Wall Degradation Enzyme Produced by Main Pathogenic Fusarium spp. in Potato Dry Rot [J]. Crops, 2018, 34(4): 154-160.
[2] Xuejiao Zhang,Jingjing Shi,Na Chang,Yaqin Zhang,Yongzhi Qi,Wenchao Zhen,Baozhong Yin. Isolation and Identification of Antagonistic Bacteria of Fusarium Head Blight of Winter Wheat in Hebei Province [J]. Crops, 2017, 33(2): 157-162.
[3] Meili Sun,Yongqing Xu,Lijuan Shi,Weiyu Shan,Ying Chai,Xiuyu Li,Lei Li,Fenglan Li. Cytological Observation in Fusarium culmorum-Infected Potato Tuber [J]. Crops, 2017, 33(1): 168-172.
Viewed
Full text


Abstract

Cited
  Shared   
  Discussed   
[1] Hongyan Li,Yonghong Wang,Rulang Zhao,Wenjie Zhang,Bo Ming,Ruizhi Xie,Keru Wang,Lulu Li,Shang Gao,Shaokun Li. The Construction and Application of Maize Grain Dehydration Model in Yellow River Irrigation and Pumping Irrigation District in Ningxia[J]. Crops, 2018, 34(4): 149 -153 .
[2] Huiqin Wen,Tianling Cheng,Ziyou Pei,Xue Li,Lisheng Zhang,Mei Zhu. Analysis of Comprehensive Characteristics of Wheat Varieties Registered in Shanxi Province in Recent Years[J]. Crops, 2018, 34(4): 32 -36 .
[3] Haiyan Liang, Hai Li, Fengxian Lin, Xiangyu Zhang, Zhi Zhang, Xiaoqiang Song. Field Identification of Different Broom Corn Millet Varieties Lodging Resistance and Evaluation Index Selection and Analysis[J]. Crops, 2018, 34(4): 37 -41 .
[4] Zhongguo He,Tongguo Zhu,Yufa Li,Baizhong Wang,Hailong Niu,Hongxin Liu,Weitang Li,Shujing Mu. Current Situation and Development Direction of Peanut Breeding in Jilin[J]. Crops, 2018, 34(4): 8 -12 .
[5] Yanli Fan,Hui Dong,Baishan Lu,Yaxing Shi,Ning Gao,Yamin Shi,Li Xu,Shengli Xi,Cuifen Zhang,Yanhui Liu. Effects of Sowing Date on Starch Gelatinization Characteristics of Different Waxy Maize Varieties[J]. Crops, 2018, 34(4): 79 -83 .
[6] Yan Zhang,Cui Yin,Yun’e Cao. Effects of Earthworm Fermentation Broth on Fruit and Vegetables Quality[J]. Crops, 2018, 34(1): 102 -106 .
[7] Shaohui Huang,Yunma Yang,Ketong Liu,Junfang Yang,Suli Xing,Yanming Sun,Liangliang Jia. Effects of Different Fertilization Method on Wheat Yield and Fertilizer Contribution Rate in Hebei Province[J]. Crops, 2018, 34(1): 113 -117 .
[8] Zhimin Du,Yuchen Yang,Yuanye Xia,Yanlong Gong,Zhiqiang Yan,Hai Xu. Effects of Harvest Time on Quality Traits of Hybrid Japonica Rice and Inbred Japonica Rice in Northern China[J]. Crops, 2018, 34(1): 147 -151 .
[9] Zhanning Gao,Hui Feng,Zhenggang Xue,Yongqian Yang,Shujie Wang,Zhengmao Pan. Analysis of Main Agronomic Traits of 28 Barley Varieties (Lines)[J]. Crops, 2018, 34(1): 77 -82 .
[10] Kai Zhu,Fei Zhang,Fulai Ke,Yanqiu Wang,Jianqiu Zou. Effects of Planting Density on Yield and Physiological Characteristics of Sorghum Hybrids Suitable for Mechenization[J]. Crops, 2018, 34(1): 83 -87 .