Acessibilidade / Reportar erro

Genetic relationships between Chinese, Japanese, and Brazilian soybean gene pools revealed by simple sequence repeat (SSR) markers

Abstract

An understanding of the relationship of geographically different soybean gene pools, based on selectively neutral DNA markers would be useful for the selection of divergent parental cultivars for use in breeding. We assessed the relationships of 194 Chinese, 59 Japanese, and 19 Brazilian soybean cultivars (n = 272) using 12 simple sequence repeat (SSR) markers. Quantification Theory III and clustering analyses showed that the Chinese and Japanese cultivars were genetically quite distant to each other but not independent, while Brazilian cultivars were distantly related to the cultivars from the other two countries and formed a cluster that was distant from the other two gene pool clusters. Our results indicated that the Brazilian soybean gene pool is different from the Chinese and Japanese pool. Exchanges of these gene pools might be useful to increase the genetic variability in soybean breeding.

DNA marker; genetic relationship; genetic resources; Glycine max


PLANT GENETICS

SHORT COMMUNICATION

Genetic relationships between Chinese, Japanese, and Brazilian soybean gene pools revealed by simple sequence repeat (SSR) markers

Naoki YamanakaI, II; Hiroyuki SatoI, III; Zhenyu YangIV; Dong He XuI; Lizandra Lucy CatelliII, V; Eliseu BinneckII; Carlos Alberto Arrabal AriasII; Ricardo Vilela AbdelnoorII; Alexandre Lima NepomucenoII

IJapan International Research Center for Agricultural Sciences, Tsukuba, Ibaraki, Japan

IIEMBRAPA-Soja, Londrina, PR, Brazil

IIIFaculty of Horticulture, Chiba University, Matsudo, Chiba, Japan

IVSoybean Research Center, Jilin Academy of Agricultural Sciences, Gongzhuling, Jilin, China

VUniversidade Estadual de Londrina, Londrina, PR, Brazil

Send correspondence to Send correspondence to: Naoki Yamanaka Japan International Research Center for Agricultural Sciences 1-1 Ohwashi, Tsukuba, Ibaraki 305-8686 Japan E-mail: naokiy@jircas.affrc.go.jp

ABSTRACT

An understanding of the relationship of geographically different soybean gene pools, based on selectively neutral DNA markers would be useful for the selection of divergent parental cultivars for use in breeding. We assessed the relationships of 194 Chinese, 59 Japanese, and 19 Brazilian soybean cultivars (n = 272) using 12 simple sequence repeat (SSR) markers. Quantification Theory III and clustering analyses showed that the Chinese and Japanese cultivars were genetically quite distant to each other but not independent, while Brazilian cultivars were distantly related to the cultivars from the other two countries and formed a cluster that was distant from the other two gene pool clusters. Our results indicated that the Brazilian soybean gene pool is different from the Chinese and Japanese pool. Exchanges of these gene pools might be useful to increase the genetic variability in soybean breeding.

Key words: DNA marker, genetic relationship, genetic resources, Glycine max.

Morphological differences are usually determined by a small number of genes and may not be representative of genetic divergence in the entire genome. Regarding soybeans, an understanding of the relationships between geographically different soybean gene pools, based on selectively neutral DNA markers, would be useful for selection of divergent parental cultivars for use in soybean breeding programs. Additionally, information on soybean diversity revealed by DNA markers may help in understanding the limitations inherent in the genetic base of our breeding materials. In order to overcome restriction of the genetic base of cultivars within the regions, we utilize the genetic resources of these regions efficiently in soybean breeding programs by considering the genetic relationship as well as the agronomic value.

There have been several DNA marker studies on the genetic relationships and diversity between Japanese, Chinese, and North American soybean cultivars (Abe et al., 2003; Ude et al., 2003). Although these United States, China and Japan are important for soybean production and consumption and as a source of soybean genetic variation, Brazil, is a very large-scale soybean producer (either the largest or second largest) and indispensable to meeting the increasing world soybean demand. Brazilian soybean varieties are derived from a limited number of North American ancestors (Hiromoto and Vello, 1986) and since North American cultivars have a narrow genetic base (Gizlice et al., 1994), it can be assumed that, compared with the Chinese and Japanese soybean gene pools, the Brazilian soybean gene pool is similar to that of North American cultivars and shares its low diversity. A study using simple sequence repeat (SSR) markers showed that 437 Brazilian commercial varieties released from 1968 to 2001 might be derived from a very limited number of soybean varieties (Catelli et al., unpublished data) but the genetic relationships between Chinese, Japanese and Brazilian soybean cultivars have not been addressed yet. The objective of the research described in the present paper was to assess the relationship of these three soybean gene pools.

We investigated 194 Chinese, 59 Japanese, and 19 Brazilian soybean cultivars (n = 272) belonging to three genetic pools (Table 1). The Chinese cultivars were randomly selected from the Northeast China soybean genetic resources database and included soybean landraces and developed varieties which have been well characterized in relation to their main traits (Yamanaka and Okabe, 2005). The Japanese cultivars were selected from the Ministry of Agriculture, Forestry and Fisheries of Japan (MAFF) Genebank according to the geographic regions where the developed varieties and landraces originated. The Brazilian cultivars were selected from an unweighted pair group method using arithmetic averages (UPGMA) dendrogram previously constructed with 22 SSR markers and 437 Brazilian cultibars released from 1968 to 2001 (Catelli et al. unpublished data). To reflect the genetic diversity of this gene pool, the Brazilian soybean cultivars used in the present study were chosen by randomly selecting one cultivar from each of 19 clusters (coefficient of similarity = 0.44 for cluster assessment) in the UPGMA dendrogram. For analysis we selected 12 SSR markers (Table 2) developed by Cregan et al. (1999) and carried out SSR amplification and the gel electrophoresis according to the methods of Hossain et al. (2000). The sizes of the amplified bands were calculated for every ten base-pairs and the alleles for each SSR marker were then decided according to the band sizes in all the cultivars and then used for analysis. Two types of analyses were used to evaluate the genetic relationships between the three gene pools. The data was analyzed by Hayashi's Quantification Theory III (QT III; Hayashi, 1956), which quantified the category data (e.g. haplotype data) based on the allelic patterns obtained with the 12 SSR markers to schematically represent the relationships among the cultivars and classify them. This type of analysis corresponds to principal component analysis (PCA) using the values of interval or ratio scales and similar results can be obtained by the Correspondence analysis (CA) or Dual scaling (DS). QT III analysis was carried out by the Japanese web-based Black-Box statistics service (http://aoki2.si.gunma-u.ac.jp/ BlackBox/BlackBox.html. as of 11/04/2005). In addition, UPGMA cluster analysis was performed with the PHYLIP computer program (Felsenstein, 1989). For cluster analysis, the genetic distance was calculated using the MSAT2 computer (Minch et al., 1997) and the 1 - P distance measurement (where P is the proportion of shared alleles for the 12 SSR markers) and 1,000 bootstrap re-samplings before subjecting the genetic matrix to UPGMA cluster analysis.

All 12 SSR markers produced amplified bands in all 272 cultivars, with the number of alleles ranging from 3 to11 (Table 2). The diversity index (H) of the SSR markers ranged from 0.222 to 0.836, indicating that these markers present large differences in information for characterization of the cultivars studied. As a result, these SSR markers could distinguish 261 cultivars, i.e. more than 95% of the cultivars could be identified.

In both QT III and cluster analyses, the Chinese and Japanese cultivars were not classified as independent but these two groups were quite distant from each other. However, Brazilian cultivars were distantly related to the Chinese and Japanese cultivars and formed a cluster that was distant from the gene pools from Japan and China (Figures 1 and 2). Cluster analysis showed seven clusters, with the first cluster containing only Japanese and Chinese cultivars, the second to the sixth cluster Chinese and two Japanese cultivars, and seventh cluster all the Brazilian cultivars (Figure 2). In the cluster analysis the distances between cultivars belonging to the three gene pools was 0 to 0.691 for both Chinese and Japanese cultivars but only 0 to 0.520 for Brazilian cultivars. Abe et al. (2003) have shown that the genetic relationship revealed by SSR markers corresponds well to the geographical separation between Japanese and Chinese soybean gene pools and classified these gene pools as independent, which was not the case in our study _ possibly because of the different materials used. However, we also showed that the Brazilian varieties were distantly related and classified in a completely different group from the Japanese and Chinese gene pools and, furthermore, the genetic diversity within each gene pool was lower than that observed among different gene pools. A similar phenomenon was reported by Ude et al. (2003) who showed that for Japanese, Chinese, North American soybean cultivars and North American ancestral lines, the genetic distances between different regional gene pools was greater than the variation within gene pools. Thus, geographically different genetic resources of soybean are quite different genetically even though they are not completely different. A DNA marker study by Thompson and Nelson (1998) revealed that introgression of genetic diversity from exotic genetic resources can contribute to increasing the yield of current USA cultivars. Therefore it can also be expected that exchanging soybean genetic resources between Japan, China and Brazil would expand their genetic base and increase variability especially when Brazilian varieties are used for soybean breeding in Japan and China or when Chinese cultivars are used in breeding programs in Brazil. These findings are useful as selection criteria to determine parental cultivars in addition to considering only the agronomic characteristics of the cultivar. Furthermore, the data presented in this paper are useful for the identification of cultivars and for checking the introduction of gene segments into breeding lines when the cultivars described in this paper are used in breeding programs.



Acknowledgments

This study was supported by JIRCAS international projects, "Comprehensive Studies on Soybean Improvement, Production and Utilization in South America" and "Development of Stable Production and Utilization of Major Food Resources in China".

Internet Resources

Minch E, Ruiz-Linares A, Goldstein D, Feldman M and Cavalli-Sforza LL (1997) Microsat: A computer program for calculating various statistics on microsatellite allele data. http://hpgl.stanford.edu/projects/microsat/ (20/04/2006).

Ministry of Agriculture, Forestry and Fisheries of Japan (MAFF) Genebank, http://www.gene.affrc.go.jp/index.html (25/4/2002).

The database of soybean genetic resources in Northeast China, http://www.jircas.affrc.go.jp/DB/guide-eng.html (19/11/2004).

Received: October 31, 2005; Accepted: July 17, 2006.

Associate Editor: Everaldo Gonçalves de Barros

  • Abe J, Xu DH, Suzuki Y, Kanazawa A and Shimamoto Y (2003) Soybean germplasm pools in Asia revealed by nuclear SSRs. Theor Appl Genet 106:445-453.
  • Cregan PB, Jarvik T, Bush AL, Shoemaker RC, Lark KG, Kahler AL, Kaya N, VanToai TT, Lohnes DG, Chung J and Specht JE (1999) An integrated genetic linkage map of the soybean. Crop Sci 39:1464-1490.
  • Felsenstein J (1989) PHYLIP - Phylogeny Inference Package (Version 3.2). Cladistics 5:164-166.
  • Gizlice Z, Carter Jr. TE and Burton JW (1994) Genetic base for North American public soybean cultivars released between 1947 and 1988. Crop Sci 34:1143-1151.
  • Hayashi C (1956) Theory and examples of quantification III. Proc Institute Statistical Math 4:19-30.
  • Hiromoto DM and Vello NA (1986) The genetic base of Brazilian soybean (Glycine max (L.) Merrill) cultivars. Brazil J Genetics 9:295-306.
  • Hossain KG, Kawai H, Hayashi M, Hoshi M, Yamanaka N and Harada K (2000) Characterization and identification of (CT)n microsatellites in soybean using sheared genomic libraries. DNA Res 7:103-110.
  • Thompson JA and Nelson RL (1998) Utilization of diverse germplasm for soybean yield improvement. Crop Sci 38:1362-1368.
  • Ude GN, Kenweorthy WJ, Costa JM, Cregan PB and Alvernaz J (2003) Genetic diversity of soybean cultivars from China, Japan, North America, and North American ancestral lines determined by amplified fragment length polymorphism. Crop Sci 43:1858-1867.
  • Yamanaka N and Okabe A (2005) Evaluation and utilization of soybean genetic resources in Northeast China and development of novel soybean breeding materials using new technology. JIRCAS Working Report N. 42:77-87.
  • Send correspondence to:

    Naoki Yamanaka
    Japan International Research Center for Agricultural Sciences
    1-1 Ohwashi, Tsukuba, Ibaraki 305-8686 Japan
    E-mail:
  • Publication Dates

    • Publication in this collection
      27 Mar 2007
    • Date of issue
      2007

    History

    • Accepted
      17 July 2006
    • Received
      31 Oct 2005
    Sociedade Brasileira de Genética Rua Cap. Adelmio Norberto da Silva, 736, 14025-670 Ribeirão Preto SP Brazil, Tel.: (55 16) 3911-4130 / Fax.: (55 16) 3621-3552 - Ribeirão Preto - SP - Brazil
    E-mail: editor@gmb.org.br