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The worldwide utilization of the Chinese soybean germplasm collection

Published online by Cambridge University Press:  17 January 2011

Li-Juan Qiu ,
Peng-Yin Chen ,
Zhang-Xiong Liu ,
Ying-Hui Li ,
Rong-Xia Guan ,
Li-Hui Wang  and
Ru-Zhen Chang
Li-Juan Qiu*
Affiliation:
The National Key Facility for Crop Gene Resources and Genetic Improvement, Key Lab of Germplasm Utilization, Institute of Crop Science, Chinese Academy of Agricultural Sciences, Beijing100081, PR China
Peng-Yin Chen
Affiliation:
Department of Crop, Soil, and Environmental Sciences, University of Arkansas, Fayetteville, AR72701, USA
Zhang-Xiong Liu
Affiliation:
The National Key Facility for Crop Gene Resources and Genetic Improvement, Key Lab of Germplasm Utilization, Institute of Crop Science, Chinese Academy of Agricultural Sciences, Beijing100081, PR China
Ying-Hui Li
Affiliation:
The National Key Facility for Crop Gene Resources and Genetic Improvement, Key Lab of Germplasm Utilization, Institute of Crop Science, Chinese Academy of Agricultural Sciences, Beijing100081, PR China
Rong-Xia Guan
Affiliation:
The National Key Facility for Crop Gene Resources and Genetic Improvement, Key Lab of Germplasm Utilization, Institute of Crop Science, Chinese Academy of Agricultural Sciences, Beijing100081, PR China
Li-Hui Wang
Affiliation:
The National Key Facility for Crop Gene Resources and Genetic Improvement, Key Lab of Germplasm Utilization, Institute of Crop Science, Chinese Academy of Agricultural Sciences, Beijing100081, PR China
Ru-Zhen Chang
Affiliation:
The National Key Facility for Crop Gene Resources and Genetic Improvement, Key Lab of Germplasm Utilization, Institute of Crop Science, Chinese Academy of Agricultural Sciences, Beijing100081, PR China
*
*Corresponding author. E-mail: [email protected]
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Abstract

This article focuses on advances in both basic and applied research on soybean germplasm resources collected from China and dispersed to the world. Many landraces developed over the course of the 4500 years since its domestication in the Huangdi period. Systematic germplasm collection was begun in the early 20th century by Professor Shou Wang, and since then over 170,000 accessions have been conserved worldwide. Evaluation with respect to key morphological characteristics, pest resistance, abiotic stress tolerance and nutritional quality attributes has been widely carried out. In addition, genetic diversity has been assessed at the DNA level, and used to establish core collections for both cultivated (Glycine max) and wild (Glycine soja) soybean. Some core sets have targeted the most used parental lines, and others have focused on specific traits, such as resistance to the soybean cyst nematode or to soybean mosaic virus, or enhanced phosphorus use efficiency. The recent acquisition of the soybean genome sequence should accelerate the utilization of not only the Chinese soybean germplasm collection, but also those maintained elsewhere in the world.

Keywords

Chinasoybean germplasmconservationevaluationutilization
Type
Research Article
Information
Plant Genetic Resources , Volume 9 , Issue 1 , April 2011 , pp. 109 - 122
Copyright
Copyright © NIAB 2011

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References

Abe, J, Ohara, Ma and Shimamoto, Y (1992) New electrophoretic mobility variations observed in wild soybean (G. soja) distributed in Japan and Korea. Soybean Genetic Newsletter 9: 6372.Google Scholar
Abe, J, Xu, DH, Suzuki, Y, Kanazawa, A and Shimamoto, Y (2003) Soybean germplasm pools in Asia revealed by nuclear SSRs. Theoretical and Applied Genetics 106: 445453.CrossRefGoogle ScholarPubMed
Ahrent, DK and Caviness, CE (1994) Natural cross-pollinaion of twelve soybean cultivars in Arkansas. Crop Science 34: 376378.CrossRefGoogle Scholar
Anand, SC (1991) Sources of resistance to Heterodera glycines in soybean cultivars. In: Colyer, PT (ed.) Proceedings of the Southern Soybean Disease Workers 18th Annual Meeting, March 20–21, 1991. Lexington, KY.Google Scholar
Anand, SC, Gallo, KM, Baker, IA and Hartwig, EE (1988) Soybean plant introductions with resistance to races 4 or 5 of soybean cyst nematode. Crop Science 28: 563564.Google Scholar
Arias, CAA, Dias, WP, Carneiro, GES, Oliveira, MF, Ferraz de – Toledo, JF, Carrão-Panizzi, MC, Pipolo, AE, Moreira, JUV, Kaster, M and Bertagnolli, P (2009) Resistance to soybean cyst nematode: genetics and breeding in Brazil. Proceedings of the World Soybean Research Conference VIII, August 9–16, 2009. Beijing.Google Scholar
Brown, AHD (1989) Core collections: a practical approach to genetic resources management. Genome 31: 818824.CrossRefGoogle Scholar
Brummer, EC, Graef, GL, Orf, J, Wilcox, JR and Shoemaker, RC (1997) Mapping QTL for seed protein and oil content in eight soybean populations. Crop Science 37: 370378.Google Scholar
Carter, TE Jr and Burton, JW (2007) Registration of NC114 and NC115 small-seeded soybean germplasm lines. Crop Science 47: 450451.CrossRefGoogle Scholar
Carter, TE, Nelson, RL, Sneller, CH and Cui, Z (2004) Genetic diversity in soybean. In: Spect, JE and Boerna, HR (eds) Soybeans: Improvement, Production and uses. Madison, WI: ASA/CSSA/SSSA, pp. 303416.Google Scholar
Chang, RZ (1989) Study on the origin of cultivated soybean. Oil Crops of China 1: 16.Google Scholar
Chang, RZ and Sun, JY (1991) Catalogues of Chinese Soybean Germplasm and Resources: Continuation I. Beijing: China Agricultural Press.Google Scholar
Chang, RZ, Sun, JY, Qiu, LJ and Chen, YW (1996) Catalogues of Chinese Soybean Germplasm and Resources: Continuation II. Beijing: China Agricultural Press.Google Scholar
Chiang, YC and Kiang, YT (1987) Geometric position of genotypes, honeybee foraging patterns and outcrossing in soybean. Botanical Bulletin of Academia Sinica 28: 111.Google Scholar
Chung, GH and Kim, JH (1990) Production of interspecific hybrids between Glycine max and G. tomentella through embryo culture. Euphytica 48: 97101.CrossRefGoogle Scholar
Coordinative Group of Evaluation of SCN (1993) Evaluation of soybean germplasm for resistance to race 1, 3 and 4 of the soybean cyst nematode. Soybean Science 12: 9199.Google Scholar
Ding, YL, Zhao, TJ and Gai, JY (2008) Genetic diversity and ecological differentiation of Chinese annual wild soybean (Glycine soja). Biodiversity Science 16: 133142.Google Scholar
Dong, YS, Zhuang, BC, Zhao, LM, Sun, H and He, MY (2001) The genetic diversity of annual wild soybeans grown in China. Theoretical and Applied Genetics 103: 98103.CrossRefGoogle Scholar
Dong, YS, Zhao, LM, Liu, B, Wang, ZW, Jin, ZQ and Sun, H (2004) The genetic diversity of cultivated soybean grown in China. Theoretical and Applied Genetics 108: 931936.CrossRefGoogle ScholarPubMed
Duan, YX, Zhou, B, Chen, LJ and Wu, HY (2008) Representative analysis of the establishment of a core collection focused on race 3 of soybean cyst nematode. Soybean Science 27: 366372.Google Scholar
Fan, YH (1988) Screening soybean varieties resistant to the soybean aphid. Soybean Science 7: 152154. English version available at http://www.ksu.edu/issa/aphids/reporthtml/trans63.htm verified 21 June 2005).Google Scholar
Fu, YS, Chen, WY, Jiang, CX, Jing, YL, Fu, CX and Lu, DC (2002) Understanding on the breeding and application of Suinong serial soybean varieties. Heilongjiang Agricultural Science 3: 4951.Google Scholar
Fujita, R, Ohara, M, Okazaki, O and Shimamoto, Y (1997) The extent of natural cross-pollination in wild soybean (Glycine soja). Journal of Heredity 88: 124128.Google Scholar
Gai, JY and Zhao, YJ (2001) The core ancestors of soybean cultivars in China. Journal of Nanjing Agricultural University 24: 2023.Google Scholar
Gai, JY, Zhao, TJ, Cui, ZL and Qiu, JX (1998) Nuclear and cytoplasmic contributions of germplasm from distinct areas to the soybean cultivars released during 1923–1995 in China. Scientia Agricultura Sinica 31: 3543.Google Scholar
Gai, JY, Xu, DH, Gao, Z, Yoshiya, S, Jun, A, Hirofumi, F and Shunji, K (2000) Studies on the evolutionary relationship among ecotypes of G. max and G. soja in China. Acta Agronomica Sinica 26: 513520.Google Scholar
Gao, X, Qian, J, Ma, YH and Zheng, SZ (2002) Research on chromosomes of perennial wild soybeans in China. Journal of Fudan University (Natural Science) 41: 717719.Google Scholar
Gizlice, Z, Carter, TE Jr and Burton, JW (1994) Genetic base for North America public soybean cultivars released between 1947 and 1988. Crop Science 34: 11431151.CrossRefGoogle Scholar
Guan, RX, Liu, XM, Chang, RZ, Ning, HX, Yuan, CP, Liu, ZX and Qiu, LJ (2006) Genetic diversity analysis of wild soybean (Glycine soja Sieb & Zucc.) from in-situ conserved population in Xinbin County of Liaoning Province. High Technology Letters 16: 6772.Google Scholar
Guan, RX, Qin, J, Hu, JS, Chen, WX, Chang, RZ, Liu, ZX and Qiu, LJ (2009) Genetic composition of elite soybean cultivar Hefeng 25. Acta Agronomica Sinica 35: 15901596.Google Scholar
Guo, JJ, Chang, RZ, Zhang, JX, Zhang, JS, Guan, RX and Qiu, LJ (2007) Contribution of Japanese soybean germplasm Tokachi Nagaha to Chinese soybean cultivars. Soybean Science 26: 807819.Google Scholar
Guo, J, Wang, YS, Song, C, Zhou, JF, Qiu, LJ, Huang, HW and Wang, Y (2010) A single origin and moderate bottleneck during domestication of soybean (Glycine max): implications from microsatellites and nucleotide sequences. Annals of Botany Available at www.aob.oxfordjournals.org.Google Scholar
Han, LD, Qiu, JX, Xu, HM, Hu, J and Gai, JY (2008) Construction of core selection of quality traits from genetic resources of summer-planted vegetable soybean. Soybean Science 27: 2125.Google Scholar
Harlan, JR and de Wet, JMJ (1971) Toward a rational classification of cultivated plants. Taxon 20: 509517.CrossRefGoogle Scholar
Hirata, T, Abe, J and Shimamoto, Y (1999) Genetic structure of the Japanese soybean population. Genetic Resources and Crop Evolution 46: 441453.Google Scholar
Hiromoto, DM and Vello, NA (1986) The genetic base of Brazilian soybean (Glycine max (L.) Merrill) cultivars. Brazil Journal of Genetics 9: 295306.Google Scholar
Hsieh, JS, Hsieh, KL, Tsai, YC and Hsing, YI (2001) Each species of Glycine collected in Taiwan has a unique seed protein Pattern. Euphytica 118: 6773.CrossRefGoogle Scholar
Huang, SQ (1989) Evaluation protein content of cultivated soybean in south China. Oil Crops of China 3: 5254.Google Scholar
Huo, YL, Zhu, ZD, Li, XH, Huang, JB and Wu, XF (2005) Preliminary screening for phytophthora root rot resistance in wild soybean. Journal of P1ant Genetic Resources 6: 182185.Google Scholar
Hwang, YH, Lee, JD, Jeong, YS, Dhakal, KH, Lee, CH and Seo, SM (2009) Development of soybean population with extremely high isofalvone content by an interspecific cross between Glycine max and Glycine soja. Proceedings of the World Soybean Research Conference VIII, August 9–16, 2009. Beijing.Google Scholar
Hymowitz, T (1984) Dorsett–Morse soybean collection trip to East Asia: 50 year retrospective. Economic Botany 38: 378388.Google Scholar
Hymowitz, T (2004) Speciation and cytogenetics. In: Boerma, HR and Specht, JE (eds) Soybeans: Improvement, Production and Uses. Madison, WI: American Society of Agronomy, Inc., pp. 97129.Google Scholar
Hymowitz, T and Newell, CA (1980) Toxonomy, speciation, domestication, dissemination, germplasm resources, and variation in the genus Glycine. In: Summerfeld, RJ and Bunting, AH (eds) Advances in Legume Science. Kew: Royal Botanic Gardens, pp. 251264.Google Scholar
Hymowitz, T, Sing, RJ and Kollipara, KP (1998) The genomes of the Glycine. Plant Breeding Review 16: 287319.Google Scholar
Hyten, DL, Song, QJ, Nelson, RL, Specht, JE, Shoemaker, RC and Cregan, PB (2008a) Creation of a 50,000 SNP infinium assay and two high resolution maps for soybean [abstract]. Proceedings of the World Soybean Research Conference VIII, August 9–16, 2009. Beijing.Google Scholar
Hyten, DL, Song, QJ, Zhu, Yl, Choi, IY, Nelson, RL, Costa, JM, Specht, JE, Shoemaker, RC and Cregan, PB (2008b) Impacts of genetic bottlenecks on soybean genome diversity. Proceedings of National Academy Sciences 103: 1666616671.Google Scholar
Hyten, DL, Cannon, SB, Song, QJ, Weeks, N, Fickus, EW, Shoemaker, RC, Specht, JE, Farmer, AD, May, GD and Cregan, PB (2010) High-throughput SNP discovery through deep resequencing of a reduced representation library to anchor and orient scaffolds in the soybean whole genome sequence. BMC Genomics 11: 38.Google Scholar
Institute of Crop Germplasm Resource, Chinese Academy of Agricultural Sciences (1990) Catalogues of Chinese Wild Soybean Germplasm and Resources. Beijing: China Agricultural Press.Google Scholar
Jin, LM, Xu, PF, Wu, JJ, Li, WB, Qiu, LJ, Chang, RZ, Chen, WY, Yu, AL, Wang, AL, Wang, JS, Nan, HY, Chen, C, Han, YP, Chen, YQ, Ding, GZ and Zhang, SZ (2007) Identification the resistance of wild soybean germplasm to phytophthorn sojae. Soybean Science 3: 300304.Google Scholar
Karmakar, PG and Bhatnagar, PS (1996) Genetic improvement of soybean varieties released in India from 1969 to 1993. Euphytica 90: 95103.CrossRefGoogle Scholar
Kiang, YT, Chiang, YC and Kaizuma, N (1992) Genetic diversity in natural populations of wild soybean in Iwate Prefecture, Japan. Journal of Heredity 83: 325329.CrossRefGoogle Scholar
Kin, MY, Lee, S, Van, K, Kim, TH, Jeong, SC, Choi, IY, Kim, DS, Lee, YS, Park, D, Ma, JX, Kim, WY, Kim, BC, Park, S, Lee, KA, Kim, DH, Kim, KH, Shin, JH, Jang, YE, Kin, KD, Liu, WX, Chaisan, T, Kang, YJ, Lee, YH, Kim, KH, Moon, JK, Schmutz, J, Jackson, SA, Bhak, J and Lee, SH (2010) Whole-genome sequencing and intensive analysis of the undomesticated soybean (Glycine soja Sieb. and Zucc.) genome. Proceedings of the National Academy of Sciences USA 107: 22032-22037.Google Scholar
Kurlovich, BS*, Rep'ev, SI, Petrova, MV, Buravtseva, TV, Kartuzova, LT and Voluzneva, TA (2000) The significance of Vavilov's scientific expeditions and ideas for development and use of legume genetic resources. Plant Genetic Resources 24: 2332.Google Scholar
Kuroda, Y, Kaga, A, Tomooka, N and Vaughan, DA (2006) Population genetic structure of Japanese wild soybean (Glycine soja) based on microsatellite variation. Molecular Ecology 15: 959974.Google Scholar
Ladizinsky, G, Newell, CA and Hymowitz, T (1979) Wide crosses in soybeans: prospects and limitations. Euphytica 28: 421423.CrossRefGoogle Scholar
Lee, JD, Yu, JK, Hwang, YH, Blake, S, So, YS, Lee, GJ, Nguyen, HT and Shannon, JG (2008) Genetic diversity of wild soybean (Glycine soja Sieb. and Zucc.) accessions from South Korea and other countries. Crop Science 48: 606616.Google Scholar
Li, SF and Shao, GH (1992) The methods for identifying drought tolerance in soybean. Crop Science 1: 3031.Google Scholar
Li, YJ, Zhao, YT, Chang, RZ, Liu, F, Liang, BW and Sun, JY (1991) The study on cold tolerance in soybean? Identify soybean germplasms tolerant to cold in Northeast China. Oil Crops in China 4: 8588.Google Scholar
Li, WX, Zhu, ZH, Liu, SC, Liu, F, Zhang, XF, Li, Y and Wang, SM (2004) Quality characters of Chinese soybean (Glycine max) varieties and germplasm resources. Journal of Plant Genetic Resources 5: 185192.Google Scholar
Li, YH, Guan, RX, Liu, ZX, Ma, YS, Wang, LX, Li, LH, Lin, FY, Luan, WJ, Chen, PY, Yan, Z, Guan, Y, Zhu, L, Ning, XC, Marinus, JM, Smulders, MJM, Li, W, Piao, RH, Cui, YH, Yu, ZM, Guan, M, Chang, RZ, Hou, AF, Shi, AN, Zhang, B, Zhu, SL and Qiu, LJ (2008a) Genetic structure and diversity of cultivated soybean (Glycine max (L.) Merr.) landraces in China. Theoretical and Applied Genetics 117: 857871.CrossRefGoogle ScholarPubMed
Li, HX, Li, ZG, Chang, WS and Zhang, CY (2008b) Identification and screening of vegetable soybean varieties based on yield traits. Soybean Science 27: 3741.Google Scholar
Li, WB, Zheng, YH and Han, YP (2008c) Analysis of fatty acid composition and other quality traits in soybean varieties developed in Heilongjiang Province. Soybean Science 27: 740745.Google Scholar
Li, YH, Zhang, C, Gao, ZS, Smulders, MJM, Ma, ZL, Liu, ZX, Nan, HY, Chang, RZ and Qiu, LJ (2009) Development of SNP markers and haplotype analysis of the candidate gene for rhg1, which confers resistance to soybean cyst nematode in soybean. Molecular Breeding 24: 6376.CrossRefGoogle Scholar
Li, YH, Li, W, Zhang, C, Yang, L, Chang, RZ, Gaut, BS and Qiu, LJ (2010) Genetic diversity in domesticated soybean (Glycine max) and its wild progenitor (Glycine soja) for SSR and SNP loci. New Phytologist Available at www.newphytologist.com.CrossRefGoogle Scholar
Lin, H (1996) Utilization and improvement of wild soybean germplasm resources. Chinese Journal of Oil Crop Sciences 18: 7072.Google Scholar
Liu, Y, Gai, JY and Lv, HN (2005) Identification of rhizosphere abiotic stress tolerance and related root traits in soybean [Glycine max (L.) Merr.]. Acta Agronomica Sinica 31: 11321137.Google Scholar
Liu, ZX, Lu, WG, Chang, RZ and Qiu, LJ (2008) Creation of new soybean SCN4-resistant lines. Soybean Science 27: 911914.Google Scholar
Lorenzen, LL, Lin, SF and Shoemaker, RC (1996) Soybean pedigree analysis using map-based molecular markers: recombination during cultivar development. Theoretical and Applied Genetics 93: 12511260.Google Scholar
Ma, SM, Li, BY and Ding, JJ (2001) Selections of soybean germplasms with resistance to peytophthora root rot and its use in rteeding for resistance. Soybean Science 3: 197199.Google Scholar
Ma, YS, Wang, WH, Wang, LX and Qiu, LJ (2006) Genetic diversity of soybean and establishment of a core collection focused on resistance to soybean cyst nematode. Journal of Integrative Plant Biology 48: 722731.CrossRefGoogle Scholar
Mi, SJ, Qiu, LJ, Chang, RZ, Hao, ZB and Guan, RX (2003) Genetic diversity analysis of varieties of Glycine max (L). Merr. resistant to soybean mosaic virus by SSR fingerprints. Acta Phytopathology Sinica 34: 244253.Google Scholar
Mikel, MA, Diers, BW, Nelson, RL and Smith, HH (2010) Genetic diversity and agronomic improvement of North American soybean germplasm. Crop Science 50: 12191229.Google Scholar
Nakayama, Y and Yamaguchi, H (2002) Natural hybridization in wild soybean (Glycine max ssp. soja) by pollen flow from cultivated soybean (Glycine max ssp. max) in a designed population. Weed Biology and Management 2: 2530.CrossRefGoogle Scholar
Nelson, RL (2009a) Collection, conservation, and evaluation of soybean germplasm [abstract]. Proceedings of the World Soybean Research Conference VIII, August 9–16, 2009. Beijing.Google Scholar
Nelson, RL (2009b) Expanding genetic diversity to increase soybean seed yield [abstract]. Proceedings of the World Soybean Research Conference VIII, August 9–16, 2009. Beijing.Google Scholar
Palmer, R, Pfeiffer, TW, Buss, GR and Kilen, TC (2004) Qualitative genetics. In: Boerma, HR and Specht, JE (eds) Soybeans: Improvement, Production and Uses. Madison, WI: American Society of Agronomy, Inc., pp. 137233.Google Scholar
Peng, YH (1988) Analysis of soybean cross type: I. Development of cross style in soybean breeding. Oil Crops of China 10: 1820.Google Scholar
Powell, W, Morgante, M, Andre, C, Hanafey, M, Vogel, J, Tingey, S and Rafalski, A (1996) The comparison of RFLP, RAPD, AFLP and SSR (microsatellite) markers for germplasm analysis. Molecular Breeding 2: 225238.Google Scholar
Qi, N, Lin, H, Wei, SH, Yang, XF and Liu, GY (2005) Using wild soybean resources to develop the new soybean germplasm of high quality and diseases resistance. Journal of Plant Genetic Resources 6: 200203.Google Scholar
Qiu, LJ and Chang, RZ (2006) Descriptors and data standard for soybean (Glycine spp.). Beijing: China Agriculture Press.Google Scholar
Qiu, LJ and Chang, RZ (2010) The origin and history of soybean. In: Singh, G (ed.) Soybean: Botany, Production and Uses. Wallingford: CAB International, pp. 123.Google Scholar
Qiu, LJ, Nelson, RL and Vodkin, LO (1997a) Evaluation of soybean germplasm with random amplification polymorphic DNA (RAPD) markers. Acta Agronomica Sinica 23: 408417.Google Scholar
Qiu, JX, Zhao, TJ and Gai, JY (1997b) The genetic contribution of the germplasm from Jiangsu and Shanghai to soybean cultivars released during 1923–1995 in China. Journal of Nanjing Agricultural University 20: 18.Google Scholar
Qiu, LJ, Chang, RZ, Chen, KM, Li, XH, Guan, RX and Sun, JY (2002) Analysis of conserving and renewal status for Chinese soybean germplasm. Journal of Plant Genetic Resources 3: 3439.Google Scholar
Qiu, LJ, Cao, YS, Chang, RZ, Zhou, XA, Wang, GX, Sun, JY, Xie, H, Zhang, B, Li, XH, Xu, ZY and Liu, LH (2003) Establishment of Chinese soybean (G. max) core collection: sampling strategy. Scientia Agricultura Sinica 36: 14421449.Google Scholar
Qiu, LJ, Wang, SM and Chang, RZ (2007a) Catalogues of Chinese Soybean Cultivar (1993–2004). Beijing: China Agricultural Press.Google Scholar
Qiu, LJ, Wang, CL, Zhou, GA, Chen, SY and Chang, RZ (2007b) Soybean molecular breeding. Scientia Agricultura Sinica 11: 24182436.Google Scholar
Qiu, LJ, Li, YH, Guan, RX, Liu, ZX, Wang, LX and Chang, RZ (2009) Establishment representative testing and research progress of soybean core collection and mini core collection. Acta Agronomica Sinica 35: 571579.Google Scholar
Qu, J, Liu, ZX, Li, KS, Qiu, LJ, Tang, N, Chang, RZ and Cao, YP (2008) Analysis of biological traits and daidzein and genistein content of perennial wild soybean (Glycine L. subgenus Glycine). Soybean Science 27: 949954.Google Scholar
Sakai, M, Kanazawa, A, Fujii, A, Thseng, FS, Abe, J and Shimamoto, Y (2003) Phylogenetic relationships of the chloroplast genomes in the genus Glycine inferred from four intergenic spacer sequences. Plant Sustematics and Evolution 239: 2954.Google Scholar
Schmutz, J, Cannon, SB, Schlueter, J, Ma, JX, Mitros, T, Nelson, W, Hyten, DL, Song, QJ, Thelen, JJ, Cheng, JL, Xu, D, Hellsten, U, May, GD, Yu, Y, Sakurai, T, Umezawa, T, Bhattacharyya, MK, Sandhu, D, Valliyodan, BD, Lindquist, E, Peto, M, Grant, D, Shu, SQ, Goodstein, D, Barry, K, Griggs, MF, Abernathy, B, Du, JC, Tian, ZX, Zhu, LC, Gill, N, Joshi, T, Libault, M, Sethuraman, M, Zhang, XC, Shinozaki, K, Nguyen, HT, Wing, RA, Cregan, G, Specht, J, Grimwood, J, Rokhsar, D, Stacey, G, Shoemaker, RC and Jackson, SA (2010) Genome sequence of the palaeopolyploid soybean. Nature 463: 178183.CrossRefGoogle ScholarPubMed
Sebolt, AM, Shoemaker, RC and Diers, BW (2000) Analysis of a quantitative trait locus allele from wild soybean that increases seed protein concentration in soybean. Crop Science. 40: 14381444.Google Scholar
Shan, ZH, Tan, YJ and Shen, MZ (2000) Screening and identification for rust resistant germplasm of soybean in China. Chinese Journal of Oil Crop Sciences 22: 6263.Google Scholar
Shan, ZH, Shan, LM, Qiu, RZ, Zhang, XJ, Cai, SP, Wu, XJ and Zhou, XA (2008) Evaluation of resistance to Phakopsora pachyrhizi in Glycine soja. Soybean Science 27: 888890.Google Scholar
Shao, GH, Chang, RZ and Chen, YW (1993) The development of salt tolerance in soybean. Soybean Science 3: 244248.Google Scholar
Shi, A, Chen, P, Zhang, B and Hou, A (2010) Genetic diversity and association analysis of protein and oil content in food-grade soybeans from Asia and the United States. Plant Breeding (online). Doi: 10.1111/j.1439-0523.2010.01766.x.Google Scholar
Shimamoto, Y, Fukushi, H, Abe, J, Kanazawa, A, Gai, JY, Gao, Z and Xu, DH (1998) RFLPs of chloroplast and mitochondrial DNA in wild soybean, Glycine soja, growing in China. Genetic Resources and Crop Evolution 45: 433439.CrossRefGoogle Scholar
Singh, RJ and Hymowitz, T (1998) The genomic relationship between Glycine max (L.) Merr. and G. soja Sieb. and Zucc. as revealed by pachytene chromosome analysis. Theoretical and Applied Genetics 76: 705711.Google Scholar
Singh, RJ and Nelson, RL (2009) Wide hybridization in soybean [abstract]. Proceedings of the World Soybean Research Conference VIII, August 9–16, 2009. Beijing.Google Scholar
Song, XE, Li, YH, Chang, RZ, Guo, PY and Qiu, LJ (2010) Population structure and genetic diversity of mini core collection of cultivated soybean (Glycine max (L.) Merr.) in China. Chinese Agricultura Sinica 43: 22092219.Google Scholar
Sun, YJ, Liu, YZ, Hu, JC and Xu, B (1991) Study on the resistance in wild soybean to soybean mosaic potyvirus. Soybean Science 10: 212216. English version available at http://www.ksu.edu/issa/aphids/reporthtml/trans64.htm verified 21 June 2005).Google Scholar
Sun, JY, Zhao, YT, Liu, F and Liang, BW (2001) Identification of cultivated soybean germplasm resources from china for acid rain tolerance. Soybean Science 4: 245248.Google Scholar
Tan, YJ, Shan, ZH, Shen, MZ, Yu, ZL, Chang, RZ, Sun, JY, Luo, Y and Xiao, SS (1997) Evaluation of soybean germplasm of china for resistance to soybean rust. Soybean Science 3: 205209.Google Scholar
Tian, Z, Zhou, CJ, Wu, YK, Yang, L, Li, JY and Gao, GJ (2007) Selection of soybean cultivar Kangxian 6. Crop Research 373.Google Scholar
Tian, Z, Wang, X, Lee, R, Li, Y, Specht, JE, Nelson, RL, McClean, PE, Qiu, LJ and Ma, JX (2010) Artificial selection for determinate growth habit in soybean. Proceedings of the National Academy of Sciences 107: 85638568.Google Scholar
Tozuka, A, Fukushi, H, Hirata, T, Ohara, M, Kanazawa, A, Mikami, T, Abe, J and Shimamoto, Y (1998) Composite and clinical distribution of Glycine soja in Japan revealed by RFLP analysis of mitochondrial DNA. Theoretical and Applied Genetics 96: 170176.CrossRefGoogle Scholar
Wang, GX (1982) Catalogues of Chinese Soybean Germplasm and Resources. Beijing: China Agricultural Press.Google Scholar
Wang, GX (1987) Classification of Chinese soybean cultivars. Chinese Journal of Oil Crops Science 1: 38.Google Scholar
Wang, KJ and Li, FS (2000) General situation of wild soybean (G. soja) germplasm resources and its utilization of introgression into cultivated soybean in China. Journal of Agricultural Science and Technology 2: 6972.Google Scholar
Wang, KJ and Takahata, Y (2007) A preliminary comparative evaluation of genetic diversity between Chinese and Japanese wild soybean (Glycine soja) germplasm pools using SSR markers. Genetic Resources and Crop Evolution 54: 157165.CrossRefGoogle Scholar
Wang, WZ, Liu, XY, Cao, YS and Zhang, M (1998) The study on protein content of Chinese soybean germplsams. Crops Cultivar Germplasms 1: 3536.Google Scholar
Wang, LX, Guan, Y, Guan, RX, Li, YH, Ma, YS, Dong, ZM, Liu, X, Zhang, HY, Zhang, YQ, Liu, ZX, Chang, RZ, Xu, HM, Li, LH, Lin, FY, Luan, WJ, Yan, Z, Ning, XC, Zhu, L, Cui, YH, Piao, RH and Liu, Y (2006a) Establishment of Chinese soybean (Glycine max) core collections with agronomic traits and SSR markers. Euphytica 151: 215223.Google Scholar
Wang, LX, Guan, RX, Liu, ZX, Chang, RZ and Qiu, LJ (2006b) Genetic diversity of Chinese cultivated soybean revealed by SSR markers. Crop Science 46: 10321038.CrossRefGoogle Scholar
Wang, LX, Lin, FY, Luan, WJ, Li, W, Guan, RX, Li, YH, Ma, YS, Liu, ZX, Chang, RZ and Qiu, LJ (2008a) Genetic diversity of Chinese spring soybean germplasm revealed by SSR markers. Plant Breeding 127: 5661.CrossRefGoogle Scholar
Wang, ZY, Wang, CL, Dong, LJ, Yu, FC and Meng, H (2008b) The situation of wild soybean populations in LiaoNing province. Rain Fed Crops 28: 241243.Google Scholar
Wen, ZX, Zhao, TJ, Zheng, YZ, Liu, SH, Wang, CE, Wang, F and Gai, JY (2008a) Association analysis of agronomic and quality traits with SSR markers in Glycine max and Glycine soja in China: exploration of elite alleles. Scientia Agricultura Sinica 34: 13391349.Google Scholar
Wen, ZX, Zhao, TJ, Zheng, YZ, Liu, SH, Wang, CE, Wang, F and Gai, JY (2008b) Association analysis of agronomic and quality traits with SSR markers in Glycine max and Glycine soja in China: exploration of elite alleles. Scientia Agricultura Sinica 34: 11691178.Google Scholar
Wen, ZX, Ding, YL, Zhao, TJ and Gai, JY (2009) Genetic diversity and peculiarity of annual wild soybean (G. soja Sieb. et Zucc.) from various eco-regions in China. Theoretical and Applied Genetics 119: 371381.CrossRefGoogle ScholarPubMed
Wu, XL, He, CY, Chen, SY, Zhuang, BC, Wang, KJ and Wang, XC (2001) Phylogenetic analysis of interspecies in genus Glycine through SSR markers. Acta Genetica Sinica 4: 359366.Google Scholar
Xie, H, Guan, RX, Chang, RZ and Qiu, LJ (2005) Genetic diversity of the summer soybean germplasm in China revealed by SSR markers. Chinese Science Bulletin 50: 526535.CrossRefGoogle Scholar
Xiong, DJ, Zhao, TJ and Gai, JY (2008) Parental analysis of soybean cultivars released in China. Scientia Agricultura Sinica 41: 25892598.Google Scholar
Xu, DH and Gai, JY (2003) Genetic diversity of wild and cultivated soybeans growing in China revealed by RAPD analysis. Plant Breeding 122: 503506.CrossRefGoogle Scholar
Xu, B, Lu, QH and Zhuang, BC (1987) Analysis of ecotypes of wild soybean (G. soja) in China. Scientia Agriculture Sinica 20: 2935.Google Scholar
Xu, DH, Gao, Z, Tian, QZ, Gai, JY, Fukushi, H, Kitajma, S, Abe, J and Shimamoto, Y (1999) Genetic diversity of the annual wild soybean (Glycine soja) in China. Chinese Journal of Applied and Environmental Biology 5: 439443.Google Scholar
Xu, DH, Abe, J, Gai, JY and Shimamoto, Y (2002) Diversity of chloroplast DNA SSRs in wild and cultivated soybeans: evidence for multiple origins of cultivated soybean. Theoretical and Applied Genetics 105: 645653.Google Scholar
Xu, YL, Wang, LF, Zhan, LL and Li, WB (2010) Progress on soybean SCN resistance. Soybean Science and Technology 2: 1317.Google Scholar
Yaklich, RW, Helm, RM, Cockrell, G and Herman, EM (1999) Analysis of the distribution of the major soybean seed allergens in a core collection of Glycine max accessions. Crop Science 39: 14441447.CrossRefGoogle Scholar
Yang, GY and Ji, F (1999) The study and utilization of wild soybean in China. Jilin Agricultural Sciences 24: 1217.Google Scholar
Yang, GY, Wang, Y, Ma, XP, Wang, L and Jiang, YL (2005) The evaluation and utilization of wild soybean germplasms. Jilin Agricultural Sciences 30: 6163.Google Scholar
Zhang, L and Dai, OH (1992) Study on indentification of soybean germplasm resistant to race 5 of soybean cyst nematode. Soybean Science 1: 7982.Google Scholar
Zhang, L, Dai, OH, Liu, JM and Li, JK (1998) Evaluation of resistance of soybean germplasms of China to race 5 of soybean cyst nematode. Soybean Science 2: 15.Google Scholar
Zhang, YQ, Guan, RX, Liu, ZX, Chang, RZ, Yao, YS and Qiu, LJ (2006) Identification of Gly m Bd 28K and Gly m Bd 30K lacking soybean by using random sampling of core collection in soybean. Acta Agronomica Sinica 32: 324329.Google Scholar
Zhang, SZ, Xu, PF, Wu, JJ, Li, WB, Qiu, LJ, Chang, RZ, Chen, WY, Yu, AL, Wang, JS, Jin, LM, Chen, C, Nan, HY, Chen, YQ and Ding, GZ (2007) Identification of resistance to phytophthora sojae in soybean germplasm. Soybean Science 6: 914917.Google Scholar
Zhang, Q, Li, H, Li, R, Hu, R, Fan, C, Chen, FL, Wang, ZH, Liu, X, Fu, YF and Lin, CT (2008) Association of the circadian rhythmic expression of GmCRY1a with a latitudinal cline in photoperiodic flowering of soybean. Proceedings of the National Academy of Sciences 105: 2102821033.Google Scholar
Zhang, J, Zhao, TJ and Gai, JY (2009) Inheritance of elite alleles of yield and quality traits in the pedigrees of major cultivar families released in Huanghuai Valleys and Southern China. Acta Agronomica Sinica 35: 191202.Google Scholar
Zhao, TJ, Cui, ZL and Gai, JY (1998) Nuclear and cytoplasmic contribution of 58–161 to their released soybean cultivars in China. Soybean Science 17: 120128.Google Scholar
Zhao, J, Fu, JB, Liao, H, He, Y, Nian, H, Hu, YM, Qiu, LJ, Dong, YS and Yan, XL (2004) Characterization of root architecture in an applied core collection for phosphorus efficiency of soybean germplasm. Chinese Science Bulletin 49: 16111620.Google Scholar
Zhao, L, Dong, Y, Liu, B, Hao, S, Wang, K and Li, X (2005) Establishment of a core collection for the Chinese annual wild soybean (Glycine Soja). Chinese Science Bulletin 50: 989996.CrossRefGoogle Scholar
Zhao, R, Cheng, ZH, Lu, WF and Lu, BR (2006) Sampling strategy for wild soybean populations based on their genetic diversity and fine scale spatial genetic structure. Chinese Science Bulletin 51: 10421048.Google Scholar
Zhao, QS, Nian, H and Yang, CY (2009) Genetic diversity of natural wild soybean populations in Xintian County, Hunan province. Acta Botanica Boreali-Occidentalia Sinica 29: 22212227.Google Scholar
Zheng, YZ, Gai, JY, Zhao, TJ, Zhou, RB and Tian, SJ (2008) A study on variability of fat-related traits in cultivated and wild soybean germplasm in China. Scientia Agricultura Sinica 41: 12831290.Google Scholar
Zhou, XA, Peng, Y, Wang, GX and Chang, RZ (1998) Preliminary studies on the centers of genetic diversity and origination of cultivated soybean in China. Acta Agronomica Sinica 31: 3743.Google Scholar
Zhu, WY, Zhou, TY, Zhong, M and Lu, BR (2006) Sampling strategy for wild soybean (Glycine soja) populations based on their genetic diversity and fine-scale spatial genetic structure. Journal of Fudan University (Natural Science Edition) 45: 321327.Google Scholar
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