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A Sequence-Tagged Linkage Map of Brassica rapa

Jung Sun Kim^*, Tae Young Chung, Graham J. King, Mina Jin^*, Tae-Jin Yang^*, Yong-Moon Jin^*, Ho-Il Kim^* and Beom-Seok Park^*,1

^* National Institute of Agricultural Biotechnology (NIAB), Rural Development Administration, Suwon, 441-707, Korea, Department of Genetic Engineering, SungKyunKwan University, Suwon, 440-746, Korea and Rothamsted Research, Harpenden, AL5 2QJ, United Kingdom

¹ Corresponding author: National Institute of Agricultural Biotechnology (NIAB), Rural Development Administration, Suwon, 441-707, Korea.
E-mail: pbeom{at}rda.go.kr

	ABSTRACT

TOP ABSTRACT MATERIALS AND METHODS RESULTS DISCUSSION ACKNOWLEDGEMENTS LITERATURE CITED

 
A detailed genetic linkage map of Brassica rapa has been constructed containing 545 sequence-tagged loci covering 1287 cM, with an average mapping interval of 2.4 cM. The loci were identified using a combination of 520 RFLP and 25 PCR-based markers. RFLP probes were derived from 359 B. rapa EST clones and amplification products of 11 B. rapa and 26 Arabidopsis. Including 21 SSR markers provided anchors to previously published linkage maps for B. rapa and B. napus and is followed as the referenced mapping of R1–R10. The sequence-tagged markers allowed interpretation of the pattern of chromosome duplications within the B. rapa genome and comparison with Arabidopsis. A total of 62 EST markers showing a single RFLP band were mapped through 10 linkage groups, indicating that these can be valuable anchoring markers for chromosome-based genome sequencing of B. rapa. Other RFLP probes gave rise to 2–5 loci, inferring that B. rapa genome duplication is a general phenomenon through 10 chromosomes. The map includes five loci of FLC paralogues, which represent the previously reported BrFLC-1, -2, -3, and -5 and additionally identified BrFLC3 paralogues derived from local segmental duplication on R3.

The high degree of neutral DNA polymorphisms of most Brassica species (FIGDORE et al. 1988) has facilitated the development of molecular linkage maps, with at least 15 described to date for B. oleracea (SLOCUM et al. 1990; KIANIAN and QUIROS 1992; LAN et al. 2000), B. rapa (SONG et al. 1991; CHYI et al. 1992; TEUTENICO and OSBORN 1994), B. nigra (LAGERCRANTZ and LYDIATE 1996), B. Juncea (CHEUNG et al. 1997; PRADHAN et al. 2003), and B. napus (LANDRY et al. 1991; UZUNOVA et al. 1995). Where common sets of DNA markers and/or parental genotypes have been used, it has been possible to designate linkage groups according to a common nomenclature (PARKIN et al. 1995, 2005; BUTRUILLE et al. 1999; SEBASTIAN et al. 2000). Thus for B. napus linkage groups N1–N10 representing the A genome correspond to B. rapa R1–R10, and linkage groups N11–N19 representing the C genome correspond to B. oleracea O1–O9. BOHUON et al. (1996) demonstrated that marker order and linkage group structure had been conserved between the diploid (B. oleracea) and amphidiploid (B. napus) C genomes. In this study, we generated a detailed linkage map using sequenced EST clones derived from tissue-specific libraries of B. rapa. To establish the identity of linkage groups corresponding to R1–R10, we used SSR markers from SUWABE et al. (2002) and LOWE et al. (2004).

The Brassica genomes are closely related to the model plant Arabidopsis thaliana, diverging 20 MYA (KOCH et al. 2001), and remain collinear. Comparative mapping of RFLP probes among the three diploid species B. rapa (n = 10), B. oleracea (n = 9), and B. nigra (n = 8) has suggested that genomes of the Brassica species are composed of three rearranged variants of an ancestral genome and descended from a common hexaploid ancestor (LAGERCRANTZ and LYDIATE 1996). All comparative studies of Arabidopsis and Brassica to date have revealed extensive duplications, with Arabidopsis segments being conserved an average of three times within the diploid Brassica genomes (TRUCO et al. 1996; LAN et al. 2000; LUKENS et al. 2003; PARKIN et al. 2005). Fiber–FISH mapping has been used to compare a 431-kb Arabidopsis BAC contig with B. rapa mitotic chromosomes (JACKSON et al. 2000). Cytogenetic study using 21 Brassicaceae species revealed that the tribe Brassiceae comprising 240 species descended from a common hexaploid ancestor that has a similar genome to Arabidopsis (LYSAK et al. 2005). Comparative genome analysis revealed that genes are reduced by deletion in the triplication blocks in the Brassica genome (O'NEILL and BANCROFT 2000; RANA et al. 2004; PARK et al. 2005). Recently, we showed the sequence-level indel in four BAC clones that represent a triplicated and segmentally duplicated FLC region of B. rapa and are homologous with 125 kb of Arabidopsis chromosome 5 (YANG et al. 2006).

In this study we demonstrate the conservation of genome segments within and between chromosomes, on the basis of sequence-tagged markers.

	MATERIALS AND METHODS

TOP ABSTRACT MATERIALS AND METHODS RESULTS DISCUSSION ACKNOWLEDGEMENTS LITERATURE CITED

 
Population development and DNA extraction:
F_2:3 families (40 F₃ seedling) of 134 F₂ lines ("JWF3p") were developed from Chinese cabbage F₁ cultivar Jangwon (B. rapa ssp. pekinensis). These two biennial inbred parent lines were made available courtesy of the former "Seoul Seed" company (Korea). To induce flowering, all seedling plants were vernalized for 35 days in a cold room at 5° with a 16-hr photoperiod. Tissues were collected from F_2:3 families after 15 days of growing in greenhouses. Genomic DNA was extracted from the lyophilized tissue following the method of CHO et al. (1994), using 1 ml saturated phenol (BM Co.) for every 1-g sample.

Gel electrophoresis and Southern blot analysis:
To screen for polymorphisms, an average of 10 µg genomic DNA from the inbred parent lines was digested with seven restriction enzymes (BamHI, DraI, EcoRI, HindIII, EcoRV, XbaI, and ScaI) and fractionated on 0.9% agarose gels. Electrophoresis and Southern blotting were conducted as described by CHO et al. (1994). BamHI, EcoRI, EcoRV, and ScaI enzymes were used for digestion of the segregating progeny populations.

EST clones used as RFLP probes:
Four different tissue-specific libraries were used as a source of RFLP probe. These were prepared from mRNA isolated from immature flowers (BIF), anthers (BAN), roots (BR), and dark-grown seedlings (BDS) of B. rapa line Jangwon (KIM et al. 1996; LIM et al. 2000). Plasmid DNA preparation and nucleotide sequencing were conducted as described by LIM et al. (2000). We have used less redundant cDNA clones on the basis of their sequence and BLASTN search in GenBank (National Center for Biotechnology Information). Insert DNA was amplified by PCR using T7 and T3 primers and eluted by QIAGEN (Valencia, CA) gel extraction kits. Probe labeling was conducted by random hexamer labeled with ³²P-dCTP (FEINBERG and VOGELSTEIN 1983). Hybridization followed the method described by CHO et al. (1994). Hybridized filters were washed with three stringency steps (2x, 1x, and 0.5x SSC with 0.5, 0.1, and 0.1% SDS), respectively, and exposed to X-ray film (Fuji, Stamford, CT) for 2–3 days.

Genome sequence tag markers used as RFLP probes:
Genome sequence tags (GSTs) representing 24 genes from Arabidopsis chromosomes 4 and 5 were generated by PCR amplication using Arabidopsis ecotype Columbia genomic DNA. The DNA were cloned and sequenced prior to use as RFLP probes. The 10 GSTs derived from Arabidopsis chromosome (chr)4 were At4RPP5 (At4g16860), At4ML1 (At4g21750), At4TR1 (At4g24520), At4CBF2a (At4g25480), At4PRHA (At4g29940), At4CPK5 (At4g35310), At4FAH1 (At4g36220), AtAP2 (At4g36920), At4HLS1 (At4g37580), and At4CESA2 (At4g39350). The other 14 GSTs derived from Arabidopsis chr5, At5HAT2 (At5g4730), At5COR78 (At5g52310), At5PDC2 (At5g54960), At5ILL1 (At5g56650), At5MSI1 (At5g58230), At5NPH3 (At5g64330), AtMYB68 (At5g6579), At5LCY (U50738), and 6 R-EST genes containing a cluster of NBS-LRR resistance recognition motif were used. Two flowering-time genes, AtFCA (At4g16280) and AtLFY (At5g61850) of Arabidopsis, were developed as probes. As for B. rapa genes, 6 flowering-time genes of B. rapa BrFLC (AY273164), BrAGL20 (AY345237), BrCO (AY356370), BrGI (AY356369), BrSVP (AY356366), and BrFLC5 gene-specific PCR product (forward primer, 5'-TTACCGCCTCTTTTATCCTTCTC-3'; reverse primer, 5'-CATATAACAACAAAAACCCCAATC-3') were used in this genetic map. The 5 function genes of B. rapa, BrGST, BrMyrosinase, BrSAM, BrSLP, and BrDFRI, were surveyed. Characteristics of genetic markers are summarized in Table 1.

Linkage analysis:
Linkage analysis and map construction were carried out using JoinMap 3.0 (VAN OOIJEN and VOORRIPS 2001). Segregating data were sorted according to locus order for each linkage group using MSExcel. This facilitated detection of errors associated with putative "double-recombinant" events and guided visual checking of original autoradiographs and revision of data points where these had been misscored or typed. All editing operations were recorded and are traceable. Linked loci were grouped on the basis of pairwise LOD values between 5 and 8, and centimorgan distances were estimated with the Kosambi mapping function (KOSAMBI 1944). Locus order within the LOD grouping was decided through an optimized algorithm using three rounds of linked markers. Multiple segregating loci detected by a probe were indicated by the addition of a suffix (-a, -b, -c, -d) to the locus names. Linkage maps were visualized using MapChart (VOORRIPS 2002) and PowerPoint.

	RESULTS

TOP ABSTRACT MATERIALS AND METHODS RESULTS DISCUSSION ACKNOWLEDGEMENTS LITERATURE CITED

 
EST marker characteristics:
A total of 551 cDNA clones from four B. rapa tissue-specific EST libraries were screened to obtain informative RFLP markers. Of these 440 were polymorphic between the parents. A high degree of polymorphism with such markers has previously been reported within Brassica subspecies (SONG et al. 1988). To obtain segregating genotypes among the progeny, four restriction enzymes were used, with EcoRV found to detect the highest level of polymorphism (Table 2).

View larger version (68K): [in this window] [in a new window] [Download PPT slide]   FIGURE 1.— Composite detailed genetic linkage map of Brassica rapa.

Sequence homology:
B. rapa probe sequences used to establish marker loci were compared against all sequences in GenBank release using BLASTn. The supplemental table (http://www.genetics.org/supplemental/) lists the B. rapa loci for which nucleotide sequence homology was determined with a cutoff of 1E-12, together with the matching GenBank database accession. The similarity data indicated that 422 (77%) of all loci corresponded to genes of known sequence, of which 89 aligned with Arabidopsis expressed, putative, or hypothetical protein-coding sequences. A study of the hit sequence based on their organisms showed that 317 of 422 (75%) had highest sequence homology to the Arabidopsis genome and 97 of 422 (23%) were matched on four species of Brassica, which were B. rapa (39/97), B. napus (32/97), B. oleracea (19/97), and B. juncea (7/97). Only 2% (8 of 422) showed the sequence homology on other organisms, including on rice. The probe sequences used to generate the marker loci appeared to represent a wide range of gene classes, including regulatory factors and structural genes involved in membrane transport, signal transduction, cell cycle regulation, carbon metabolism, stress response, DNA synthesis, and fatty acid metabolism.

Single-locus genes:
From the screening of RFLP probes against parental lines using seven restriction enzymes, 12% of clones gave single hybridization fragments, and 62 of these were incorporated into the linkage map. Probe BAN235 (Figure 2A) mapped to a single locus on R9, and this was confirmed by screening the probe to an 11x genome coverage HindIII BAC library (PARK et al. 2005). Positive hybridization signals were detected for 14 BAC clones, and the isolated DNA was digested with HindIII enzyme. The resultant fingerprints were consistent with the BACs forming a single contig by Southern analysis using the same probe, BAN235 (Figure 2B).

View larger version (55K): [in this window] [in a new window] [Download PPT slide]   FIGURE 2.— Examples of single-locus genes of a parent survey, colony hybridization, and confirmation by Southern blotting to positive BAC fingerprints using BAN235 that it is located on R9 (61 cM). (A) RFLP autoradiography of parent genomic DNA digested with seven restriction enzymes using a BAN 235 single-locus probe. (B) Autoradiography of HindIII fingerprint of positive BAC clones using a BAN235 probe.

Duplicated marker and homologous linkage groups:
The remainder of the RFLP probes detected more than one segregating locus, with an average of 1.31 loci per probe (520/396). A total of 102 of the 396 mapped probes gave rise to multiple loci (229), with an average of 2.25 loci per probe. Eighty-one detected 2 loci, 18 detected 3, 2 detected 4, and a single probe detected 5 loci. Of these, 72 probes revealed locus duplication (164 loci) of two or three copies on different linkage groups. The pattern of duplications within the B. rapa genome was revealed by comparing ordered clusters of loci derived from common gene probes. At the top of the largest linkage group R3 with five loci duplicated R1 and the middle region of R3 corresponds to sections of R4 and R5, whereas the lower region corresponds to sections represented by 10 loci on R2 and 7 loci on R10. Four marker loci, spanning 19 cM at the top of R4, are also duplicated within R7 and R9 where the four duplicated loci span 17 and 11 cM, respectively. Most chromosomal parts show two or three duplication blocks (Figure 3). These relationships between homeologous chromosome segments provide good evidence for a series of historical segmental duplication events in this genome. However, since all genetic mapping experiments are based on polymorphism of genetic markers, the fine detailed pattern of duplications or triplication is incomplete due to the presence of monomorphic or dimorphic markers.

View larger version (35K): [in this window] [in a new window] [Download PPT slide]   FIGURE 3.— Interchromosomal duplication of Brassica rapa. Circles show duplicated loci of the same markers. Each linkage group is assigned 10 different colors.

	DISCUSSION

TOP ABSTRACT MATERIALS AND METHODS RESULTS DISCUSSION ACKNOWLEDGEMENTS LITERATURE CITED

 
Genetic linkage map:
A detailed genetic linkage map of the Brassica A genome has been constructed, on the basis of 134 B. rapa F_2:3 families. It contains 545 loci and most of them were detected by RFLP analysis using sequenced EST probes from four different tissue-specific libraries (474 loci/359 probes). Additional gene-specific probes were derived from Arabidopsis chromosome 4 (10 loci/10 probes) and chromosome 5 (17 loci/14 probes). Several flowering-time genes from Arabidopsis (2 loci/2 probes), B. rapa (7 loci/6 probes), and BrMyrosinase, BrDFRI, BrGST, BrSAM, and BrSLP (10 loci/5 probes) functional genes were mapped on this linkage map. The detection of 1.31 loci per RFLP probe (520/396) closely matches that reported (1.27 and 1.34 from 220 and 269 probes, respectively) for previous B. rapa maps (SONG et al. 1991; CHYI et al. 1992). In contrast, UDALL et al. (2005) observed a higher level of polymorphism with codominant and dominant segregation in the amphidiploid B. napus, where there are twice as many potential loci.

The accumulated set of sequence-tagged genetic markers provides a valuable source of information for study and navigation of the Brassica A genome, not only in B. rapa but also in the context of B. napus and B. juncea. Since the model dicotyledonous plant, A. thaliana, is closely related to Brassica the genus and share, on average, 87% sequence identity (CAVELL et al. 1998), there is an expectation that understanding the genetic control of basic biological processes in Arabidopsis can be transferable to other species (LAGERCRANTZ 1998). However, Brassica EST markers that do not correspond to genes derived from other species are of additional value, as they provide insight into the identity and location of novel gene functions, which may be related to the well-characterized adaptability and plasticity of this crop genus.

We have obtained an average marker density of 2.4 cM. B. rapa has the smallest diploid Brassica genome, estimated at 529 Mb (JOHNSTON et al. 2005). Thus we calculate that the current map provides a genetic marker on average at least every 1 Mb. This information may be exploited in at least two ways. First, within the ongoing B. rapa genome-sequencing project (YANG et al. 2005) 62 single-locus gene markers are now available that will assist in the isolation and confirmation of "seed" BACs, as well as provide anchored markers to span between adjacent BAC contigs to integrate the physical map. Second, there is the prospect of benefiting from the rich source of biological information and genetic resources from Arabidopsis functional genomics research to benefit Brassica crop plants.

Multiple duplicated FLC genes of B.rapa:
The MADS-box flowering-time regulator FLC, located at the top of chromosome 5 of Arabidopsis, has a repressive function role on flowering time (MICHAELS and AMASINO 1999). There are some differences on the number of orthologous or paralogous BrFLC loci with that of SCHRANZ et al. (2002). Using the BrFLC gene as an RFLP probe, we obtained two polymorphic and three monomorphic bands. These two loci were located at the telomere of the long arm of R3, whereas Schranz et al. were able to assign only one locus to R3. This difference appears to result from the use of a backcross population by Schranz et al., where heterozygote genotypes are not detected. In contrast, the JWF3 is an F₃ pooled population (40 seedlings per line) that is able to represent F₂ segregation. We were able to detect eight recombinant genotypes in the population between two alleles of BrFLC3-a and -b, where one was homozygous for one parent line (genotype A), and the other represented the heterozygote (H), resulting in a map interval of 5 cM on R3. Other monomorphic BrFLC fragments were detected using SSR markers derived from B. rapa BACs that contain BrFLC genes. Sequences of four BACs, KBrH080A08, KBrH004D11, KBrH117M18, and KBrH52O08 containing BrFLC1, -2, -3a, and -3b, respectively, are collinear to the FLC region at 3.0–3.35 Mb of Arabidopsis chromosome 5 with indels (YANG et al. 2006). This genetic map surrounding BrFLC1, -2, -3a, and -3b shows synteny between each linkage group and with the 3-Mb region of Arabidopsis chromosome 5 (Figure 4). Meanwhile BrFLC5 is identified in a BAC clone KBrH038M21 (not submitted yet) that is collinear with 12.7–12.91 Mb of Arabidopsis chromosome 2 and the genetic position was determined 33 cM away from BrFLC3a on the long arm of R3. From this we infer that this genomic segment was replicated by an insertion within the homeologous region of R3 and this region and mostly shows the homeologous blocks to R4 and R5. Another BAC clone KrH80C09 corresponds to the MAF gene locus (At565050) within the 25.8- to 26.2-Mb region of Arabidopsis chromosome 5 (YANG et al. 2006).

View larger version (22K): [in this window] [in a new window] [Download PPT slide]   FIGURE 4.— Comparative mapping of B. rapa linkage groups containing replicated FLC genes to the Arabidopsis genome. Vertical lines represent homeologous linkage groups in B. rapa, two loci of BrFLC3a and FLC3b are the polymorphic segregating RFLP genotype data using the BrFLC gene (AY273164), and the other three, BrFLC1, BrFLC2, and BrMAF, are the segregated genotype data using developed SSR markers from BACs containing FLC and MAF genes. R2, R3, and R10 show the sequenced homology to Arabidopsis chr5 (0.5–7 Mb and 20.5–26.2 Mb, respectively). Originated FLC of Arabidopsis is triplicated at the top of R10 and R2 and at the bottom of R3, and a local duplication event has happened at the bottom of R3. The BrFLC5 gene mapped region shows R4 and -5 homeologues and corresponds to Arabidopsis chr3 (0–1 Mb and 12.3–18.9 Mb, respectively).

The genomes of Brassica species have triplicated counterparts to corresponding homeologous segments of Arabidopsis (O'NEILL and BANCROFT 2000; RANA et al. 2004; LYSAK et al. 2005). Almost 88% of triplicated genes near the FLC regions returned to a single-copy or a two-copy state by deletion (YANG et al. 2006). Because of this reason, hybridization data using a single EST probe might have limitations for inferring genome duplication. But, overall distributions of duplicate or triplicate regions are detected from the hybridization data of multiloci EST markers (Figure 3), suggesting that the genome-level triplication might have happened in the ancestor of Brassica.

The KBGP is currently underway and is aiming to generate the first complete Brassica chromosome sequence of R9 (cytogenetic chromosome 1) (www.brassic.rapa.org). We have selected nine seed BACs through BAC library screening using single-locus EST markers. FISH and sequence information generally coincided with our expectations. The complete set of 62 locus-specific single-copy EST markers will be valuable markers for the primary anchoring of "seed" BACs for each linkage group.

	ACKNOWLEDGEMENTS

TOP ABSTRACT MATERIALS AND METHODS RESULTS DISCUSSION ACKNOWLEDGEMENTS LITERATURE CITED

 
This work was supported by a grant from the BioGreen 21 Program and by the National Institute of Agricultural Biotechnology, Rural Development Administration. G.J.K. is supported by the United Kingdom Biotechnology & Biological Sciences Research Council.

	LITERATURE CITED

TOP ABSTRACT MATERIALS AND METHODS RESULTS DISCUSSION ACKNOWLEDGEMENTS LITERATURE CITED

 

BOHUON, E. J., D. J. KEITH, I. A. P. PARKIN, A. G. SHARPE and D. J. LYDIATE, 1996 Alignment of the conserved C genomes of Brassica oleracea and Brassica napus. Theor. Appl. Genet. 93: 833–839.

BUTRUILLE, D. V., R. P. GURIES and T. C. OSBORN, 1999 Linkage analysis of molecular markers and quantitative trait loci in populations of inbred backcross lines of Brassica napus L. Genetics 153: 949–964.[Abstract/Free Full Text]

CAVELL, A. C., D. LYDIATE, I. A. P. PARKIN, C. DEAN and M. TRICK, 1998 Collinearity between a 30-centimorgan segment in Arabidopsis thaliana chromosome 4 and duplicated regions within the Brassica napus genome. Genome 41: 62–69.[Medline]

CHEUNG, W. Y., G. CHAMPANGE, N. HUBERT and B. S. LANDRY, 1997 Comparison of the genetic map of Brassica napus and Brassica oleracea. Theor. Appl. Genet. 94: 569–582.[CrossRef]

CHO, Y. G., M. Y. EUN, S. R. MCCOUCH and Y. A. CHAE, 1994 The semidwarf gene, sd-1, of rice (Oryza sativa L.). II. Molecular mapping and marker-assisted selection. Theor. Appl. Genet. 89: 54–59.

CHYI, Y. S., M. E. HONECK and J. L. SERNYK, 1992 A genetic linkage map of restriction fragment length polymorphism loci for Brassica rapa (syn. campestris). Genome 35: 746–757.

FAHEY, J. W., and P. TALALAY, 1995 The role of Crucifers in cancer chemoprotection, pp. 87–93 in Phytochemicals and Health, edited by D. L. GUSTINE and H. E. FLORES. American Society of Plant Physiologists, Rockville, MD.

FEINBERG, A. P., and B. VOGELSTEIN, 1983 A technique for radiolabeling DNA restriction fragments to a high specific activity. Ann. Biochem. 132: 6–13.[CrossRef]

FIGDORE, S. S., W. C. KENARD, K. M. SONG, M. K. SLOCUM and T. C. OSBORN, 1988 Assessment of the degree of restriction fragment length polymorphism in Brassica. Theor. Appl. Genet. 75: 833–840.

GOMEZ-CAMPO, C., 1999 Biology of Brassica Coenospecies. Elsevier, Amsterdam/New York.

JACKSON, S. A., Z. CHENG, M. L. WANG, H. M. GOODMAN and J. JIANG, 2000 Comparative fluorescence in situ hybridization mapping of a 431-kb Arabidopsis thaliana bacterial artificial chromosome contig reveals the role of chromosomal duplications in the expansion of the Brassica rapa genome. Genetics 156: 833–838.[Abstract/Free Full Text]

JOHNSTON, J. S., A. E. PEPPER, A. E. HALL, Z. J. CHEN, G. HODNETT et al., 2005 Evolution of genome size in Brassicaceae. Ann. Bot. 95: 229–235.[Abstract/Free Full Text]

KIANIAN, S. F., and C. F. QUIROS, 1992 Generation of a Brassica oleracea composite RFLP map: linkage arrangements among various populations and evolutionary implications. Theor. Appl. Genet. 84: 544–554.

KIM, H. U., B. S. PARK, T. Y. CHUNG and S. K. KANG, 1996 Isolation of anther-preferentially expressed genes from Chinese cabbage. Mol. Cells 6: 666–672.

KOCH, M., B. HAUBOLD and T MITCHELL-OLDS, 2001 Molecular systematics of the Brassicaceae: evidence from coding plastidic MATK and nuclear CHS sequences. Am. J. Bot. 88: 534–544.[Abstract/Free Full Text]

KOLE, C., P. QUIJADA, S. D. MICHAELS, R. M. AMASINO and T. C. OSBORN, 2001 Evidence for homology of flowering-time genes VFR2 from Brassica rapa and FLC from Arabidopsis thaliana. Theor. Appl. Genet. 102: 425–430.[CrossRef]

KOSAMBI, D. D., 1944 The estimation of map distance from recombination values. Ann. Eugen. 12: 172–175.

LABANA, K. S., and M. L. GUPTA, 1993 Importance and origin, pp. 1–20 in Breeding Oilseed Brassica, edited by K. S. LABANA, S. S. BANGA and S. K. BANGA. Springer-Verlag, Berlin.

LAGERCRANTZ, U., 1998 Comparative mapping between Arabidopsis thaliana and Brassica nigra indicates that Brassica genomes have evolved through extensive genome replication accompanied by chromosome fusions and frequent rearrangements. Genetics 150: 1217–1228.[Abstract/Free Full Text]

LAGERCRANTZ, U, and D. LYDIATE, 1996 Comparative genome mapping in Brassica. Genetics 144: 1903–1910.[Abstract]

LAN, T. H., T. A. DELMONTE, K. P. REISCHAMANN, J. HYMAN, S. KOWALSKI et al., 2000 EST-enriched comparative map of Brassica oleracea and Arabidopsis thaliana. Genome Res. 10: 776–788.[Abstract/Free Full Text]

LANDRY, B. S., N. HUBERT, T. ETOH, J. J. HARADA and S. E. LINCOLN, 1991 A genetic map for Brassica napus based on restriction fragment length polymorphisms detected with expressed DNA sequences. Genome 34: 543–552.

LIM, J. Y., C. S. SHIN, E. CHUNG, J. S. KIM, H. U. KIM et al., 2000 Analysis of expressed sequence tags form Brassica rapa L. ssp. pekinensis. Mol. Cells 10: 399–404.[Medline]

LIM, K. B., H. DE JONG, T. J. YANG, J. Y. PARK, S. J. KWON et al., 2005 Characterization of rDNAs and tandem repeats in heterochromatin of Brassica rapa. Mol. Cells 19: 436–444.[Medline]

LOWE, A. J., C. MOULE, M. TRICK and K. J. EDWARDS, 2004 Efficient large-scale development of microsatellites for marker and mapping applications in Brassica crop species. Theor. Appl. Genet. 108: 1103–1112.[CrossRef][Medline]

LUKENS, L., F. ZOU, D. LYDIATE, I. A. PARKIN and T. OSBORN, 2003 Comparison of a Brassica oleracea genetic map with the genome of Arabidopsis thaliana. Genetics 164: 359–372.[Abstract/Free Full Text]

LYSAK, M. A., M. A. KOCH, A. PECINKA and I. SCHUBERT, 2005 Chromosome triplication found across the tribe Brassiceae. Genome Res. 15: 516–525.[Abstract/Free Full Text]

MICHAELS, S. D., and R. M. AMASINO, 1999 FLOWERING LOCUS C encodes a novel MADS domain protein that acts as a repressor of flowering. Plant Cell 11: 949–956.[Abstract/Free Full Text]

O'NEILL, C. M., and I. BANCROFT, 2000 Comparative physical mapping of segments of the genome of Brassica oleracea var. alboglabra that are homoeologous to sequenced regions of chromosomes 4 and 5 of Arabidopsis thaliana. Plant J. 23: 233–243.[CrossRef][Medline]

PARK, J. Y., D. H. KOO, C. P. HONG, S. J. LEE, J. W. JEON et al., 2005 Physical mapping and microsynteny of Brassica rapa ssp. pekinensis genome corresponding to a 222 kb gene-rich region of Arabidopsis chromosome 4 and partially duplicated on chromosome 5. Mol. Gen. Genet. 274: 579–588.

PARKIN, I. A. P., A. G. SHARPRE, D. J. KEITH and D. J. LYDIATE, 1995 Identification of the A and C genomes of amphidiploid Brassica napus (oilseed rape). Genome 38: 1122–1131.

PARKIN, I. A. P., J. M. GULDEN, A. G. SHARPE, L. LUKENS, M. TRICK et al., 2005 Segmental structure of the Brassica napus genome based on comparative analysis with Arabidopsis thaliana. Genetics 171: 765–781.[Abstract/Free Full Text]

PRADHAN, A. K., V. GUPTA, A. MUKHOPADHYAY, N. ARUMUGAM, Y. S. SODHI et al., 2003 A high-density linkage map in Brassica juncea (Indian mustard) using AFLP and RFLP markers. Theor. Appl. Genet. 106: 607–614.[Medline]

RANA, D., T. VAN DEN BOOGAART, C. M. O'NEILL, L. HYNES, E. BENT et al., 2004 Conservation of the microstructure of genome segments in Brassica napus and its diploid relatives. Plant J. 40: 725–733.[CrossRef][Medline]

SEBASTIAN, R. L., E. C. HOWELL, G. J. KING, D. F. MARSHALL and M. J. KEARSEY, 2000 An integrated AFLP and RFLP Brassica oleracea linkage map from two morphologically distinct doubled-haploid mapping populations. Theor. Appl. Genet. 100: 75–81.[CrossRef]

SCHRANZ, M. E., P. QUIJADA, S. B. SUNG, L. LUKENS, R. AMASINO et al., 2002 Characterization and effects of the replicated flowering time gene FLC in Brassica rapa. Genetics 162: 1457–1468.[Abstract/Free Full Text]

SLOCUM, M. K., S. S. FIGDORE, W. C. KENNARD, J. Y. SUZURI and T. C. OSBORN, 1990 Linkage arrangements of restriction fragment length polymorphism loci in Brassica oleracea. Theor. Appl. Genet. 80: 57–64.

SONG, K. M., T. C. OSBORN and P. H. WILLIAMS, 1988 Brassica taxonomy based on nuclear restriction fragment length polymorphism (RFLPs). A genome evolution of diploid and amphidiploid species. Theor. Appl. Genet. 75: 784–794.

SONG, K. M., J. Y. SUSUKI and M. K. SLOCUM, 1991 A linkage map of Brassica rapa (syn. B. campestris) based on restriction fragment length polymorphism loci. Theor. Appl. Genet. 82: 296–304.[CrossRef]

SUWABE, K., H. IKETANI, T. NUNOME, T. KAGE and M. HIRAI, 2002 Isolation and characterization of microsatellites in Brassica rapa L. Theor. Appl. Genet. 104: 1092–1098.[CrossRef][Medline]

TEUTENICO, R. A., and T. C. OSBORN, 1994 Mapping of RFLP and qualitative trait loci in Brassica rapa, and comparison to linkage maps of B. napus, B. oleracea, and Arabidopsis thaliana. Theor. Appl. Genet. 89: 885–894.[CrossRef]

TRUCO, M. J., J. HU, J. SADOWSKI and C. F. QUIROS, 1996 Inter- and intra-genomic homology of the Brassica genomes: implications for their origin and evolution. Theor. Appl. Genet. 93: 1225–1233.[CrossRef]

UDALL, J. A., P. A. QUIJADA and T. C. OSBORN, 2005 Detection of chromosomal rearrangements derived from homeologous recombination in four mapping populations of Brassica napus L. Genetics 169: 967–979.[Abstract/Free Full Text]

UZUNOVA, M., W. ECKE, K. WEISSLEDER and G. ROBBELEN, 1995 Mapping the genome of rapeseed (Brassica napus L.) I. Construction of an RFLP linkage map and localization of QTLs for seed glucosinate content. Theor. Appl. Genet. 90: 194–204.

VAN OOIJEN, J. W., and R. E. VOORRIPS, 2001 JoinMap Version 3.0: Software for the Calculation of Genetic Linkage Maps. Plant Research International, Wageningen, The Netherlands.

VOORRIPS, R. E., 2002 MapChart: software for the graphical presentation of linkage maps and QTLs. J. Hered. 93: 77–78.[Free Full Text]

YANG, T. J., J. S. KIM, K. B. LIM, S. J. KWON, J. A. KIM et al., 2005 The Korea Brassica Genome Project: a glimpse of the Brassica genome based on comparative genome analysis with Arabidopsis. Comp. Funct. Genomics 6: 138–146.[CrossRef]

YANG, T. J., J. S. KIM, S. J. KWON, K. B. LIM, B. S. CHOI et al., 2006 Sequence-level analysis of the diploidization process in the triplicated FLC region of Brassica rapa. Plant Cell 18: 1339–1347.[Abstract/Free Full Text]

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