Genetic and physical mapping inBrassica diploid species of a gene cluster defined inArabidopsis thaliana

Sadowski, Jan; Gaubier, P.; Delseny, Michel; Quirós, Carlos F.

doi:10.1007/bf02172520

Cited by 39 publications

(26 citation statements)

References 31 publications

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“…However, a significant proportion (11 of 16 or 68%) of markers that were single-copy in Arabidopsis were also single-copy in Brassica. This result differs from previous Brassica and Arabidopsis comparative mapping studies in which single-copy Arabidopsis markers were found to be duplicated in the Brassica genome (Lagercrantz et al, 1996;Sadowski et al, 1996). …”

contrasting

confidence: 99%

“…All three markers also hybridized consistently with a 780-kb SfiI fragment that is, in all likelihood, a partially digested fragment (incomplete digestion is often observed upon treatment of Brassica DNA with SfiI; Sadowski et al, 1996). Marker y14 hybridized with the same 510-and 780-kb SfiI fragments as did the HV8 probe and with the same 97-kb BssHII and 115-kb SmaI fragments as did sp400.…”

Section: Comparative Mapping Of Molecular Markers In Arabidopsis and mentioning

confidence: 75%

“…This comparative approach was spurred by the fact that extensive homeologies and microcolinearity (microsynteny) of markers are often found between the genomes of related species in animal systems (Dietrich et al, 1995) as well as in plants (Tanksley et al, 1992;Ahn et al, 1993;Dunford et al, 1995;Kilian et al, 1995;Chen et al, 1997) and by recent successes in the use of comparative mapping to facilitate the isolation and analysis of loci of interest (e.g., see Darling and Abbott, 1992). In the case of Arabidopsis and Brassica spp, it has been shown that the two genomes do contain islands of conserved organization, despite the fact that the Brassica genome is highly duplicated and rearranged relative to Arabidopsis (Kowalski et al, 1994;Lagercrantz et al, 1996;Sadowski et al, 1996). The results of our comparative study revealed a high degree of microsynteny between the Brassica S locus region and its homeolog in Arabidopsis, with the notable exception that sequences related to the Brassica SI genes were missing from this interval of the Arabidopsis genome.…”

Section: Introductionmentioning

confidence: 99%

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Comparative Mapping of the Brassica S Locus Region and Its Homeolog in Arabidopsis: Implications for the Evolution of Mating Systems in the Brassicaceae

Conner

Nasrallah

et al. 1998

Plant Cell

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The crucifer family includes self-incompatible genera, such as Brassica , and self-fertile genera, such as Arabidopsis. To gain insight into mechanisms underlying the evolution of mating systems in this family, we used a selective comparative mapping approach between Brassica campestris plants homozygous for the S 8 haplotype and Arabidopsis. Starting with markers flanking the self-incompatibility genes in Brassica , we identified the homeologous region in Arabidopsis as a previously uncharacterized segment of chromosome 1 in the immediate vicinity of the ethylene response gene ETR1 . A total of 26 genomic and 21 cDNA markers derived from Arabidopsis yeast artificial and bacterial artificial chromosome clones were used to analyze this region in the two genomes. Approximately half of the cDNAs isolated from the region represent novel expressed sequence tags that do not match entries in the DNA and protein databases. The physical maps that we derived by using these markers as well as markers isolated from bacteriophage clones spanning the S 8 haplotype revealed a high degree of synteny at the submegabase scale between the two homeologous regions. However, no sequences similar to the Brassica S locus genes that are known to be required for the self-incompatibility response were detected within this interval or other regions of the Arabidopsis genome. This observation is consistent with deletion of self-recognition genes as a mechanism for the evolution of autogamy in the Arabidopsis lineage. INTRODUCTIONThe crucifer family (Brassicaceae) is well suited for the study of the evolution of plant mating systems. It includes self-fertilizing species, such as members of the genus Arabidopsis , as well as outcrossing species, such as members of the genus Brassica , in which self-pollination is prevented by a selfincompatibility (SI) system. In this family, SI is controlled genetically by haplotypes of a multifunctional gene complex, the S locus, which may span several hundred kilobases of DNA (Boyes et al., 1997). Among the genes contained at the locus are two highly polymorphic genes that encode proteins expressed specifically in the epidermal cells of the stigma, which is a structure at the tip of the female reproductive organ that is specialized for capturing and interacting with pollen. The two genes encode the cell wall-localized S locus glycoprotein (SLG) and the plasma membrane-spanning receptor protein kinase SRK ( S locus receptor kinase). The predicted extracellular domain of the SRK shares extensive sequence similarity with the SLG (reviewed in Nasrallah and Nasrallah, 1993;Nasrallah et al., 1994b).The SLG and SRK cell surface receptors fulfill an SI-specific function because plants carrying mutations that disrupt or downregulate the SLG and SRK genes are self-fertile (M.E. Nasrallah et al., 1992;Goring et al., 1993;J.B. Nasrallah et al., 1994a;Conner et al., 1997). In addition to the stigmatic SLG and SRK genes, the S locus complex is thought to encode at least one gene required for the SI phenotype in pollen. ...

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contrasting

confidence: 99%

Section: Comparative Mapping Of Molecular Markers In Arabidopsis and mentioning

confidence: 75%

Section: Introductionmentioning

confidence: 99%

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Comparative Mapping of the Brassica S Locus Region and Its Homeolog in Arabidopsis: Implications for the Evolution of Mating Systems in the Brassicaceae

Conner

Nasrallah

et al. 1998

Plant Cell

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“…Initial efforts at determining the relationships between the Brassica and Arabidopsis genomes involved using molecular probes for co-linear sets derived from the developing Arabidopsis genomic resources to map RFLP polymorphisms in Brassica species (Kowalski et al, 1994). These studies indicated that there is extensive co-linearity between the Brassica and Arabidopsis genomes, but that most single copy Arabidopsis regions exist as multiple, on average 3 copies in modern Brassica genomes (Lagercrantz et al, 1995;Sadowski et al, 1996;Cavell et al, 1998). This in turn, gave rise to the hypothesis that the modern diploid Brassica species are derived from a hexaploid ancestor whose genome was generated from a diploid, Arabidopsis-like genome through polyploidization events.…”

Section: Brassica Genomesmentioning

confidence: 99%

Positional Cloning in Brassica napus: Strategies for Circumventing Genome Complexity in a Polyploid Plant

Brown¹,

Gaborieau²

2011

Molecular Cloning - Selected Applications in Medicine and Biology

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“…oleracea and A. thaliana diverged 15-20 million years ago (Yang et al 1999). Earlier comparative mapping studies of Brassica and Arabidopsis using molecular markers revealed extensive synteny between these two species, suggesting that knowledge gained in one species can be productively applied to the other (Lan et al 2000;Babula et al 2003) although deviation from colinearity was also noted (Kowalski et al 1994;Sadowski et al 1996;Ryder et al 2001). Nucleotide sequence conservation between these two species has been reported to be in the range of 75%-90% in exons, whereas in introns and intergenic regions, it is Յ70% .…”

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confidence: 99%

Whole genome shotgun sequencing ofBrassica oleraceaand its application to gene discovery and annotation inArabidopsis

Ayele¹,

Haas²,

Kumar³

et al. 2005

Genome Res.

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Through comparative studies of the model organism Arabidopsis thaliana and its close relative Brassica oleracea, we have identified conserved regions that represent potentially functional sequences overlooked by previous Arabidopsis genome annotation methods. A total of 454,274 whole genome shotgun sequences covering 283 Mb (0.44×) of the estimated 650 Mb Brassica genome were searched against the Arabidopsis genome, and conserved Arabidopsis genome sequences (CAGSs) were identified. Of these 229,735 conserved regions, 167,357 fell within or intersected existing gene models, while 60,378 were located in previously unannotated regions. After removal of sequences matching known proteins, CAGSs that were close to one another were chained together as potentially comprising portions of the same functional unit. This resulted in 27,347 chains of which 15,686 were sufficiently distant from existing gene annotations to be considered a novel conserved unit. Of 192 conserved regions examined, 58 were found to be expressed in our cDNA populations. Rapid amplification of cDNA ends (RACE) was used to obtain potentially full-length transcripts from these 58 regions. The resulting sequences led to the creation of 21 gene models at 17 new Arabidopsis loci and the addition of splice variants or updates to another 19 gene structures. In addition, CAGSs overlapping already annotated genes in Arabidopsis can provide guidance for manual improvement of existing gene models. Published genome-wide expression data based on whole genome tiling arrays and massively parallel signature sequencing were overlaid on the Brassica-Arabidopsis conserved sequences, and 1399 regions of intersection were identified. Collectively our results and these data sets suggest that several thousand new Arabidopsis genes remain to be identified and annotated.

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Genetic and physical mapping inBrassica diploid species of a gene cluster defined inArabidopsis thaliana

Cited by 39 publications

References 31 publications

Comparative Mapping of the Brassica S Locus Region and Its Homeolog in Arabidopsis: Implications for the Evolution of Mating Systems in the Brassicaceae

Comparative Mapping of the Brassica S Locus Region and Its Homeolog in Arabidopsis: Implications for the Evolution of Mating Systems in the Brassicaceae

Positional Cloning in Brassica napus: Strategies for Circumventing Genome Complexity in a Polyploid Plant

Whole genome shotgun sequencing ofBrassica oleraceaand its application to gene discovery and annotation inArabidopsis

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