Chromosomal localization of rDNA in the Brassicaceae.

A survey is given about the number and chromosomal position of rDNA loci in 45 Brassicaceae species. For 34 species, 5S and 45S rDNA loci have been localized by two-colour fluorescence in situ hybridization for the first time. These data show the variability of rDNA within karyotypes of the Brassicaceae, provide anchor points for (comparative) genetic maps, and might be important for studies on concerted evolution of internal transcribed sequence types of rDNA in cruciferous plants.     

Physical mapping of rDNA loci in Brassica species.

The number of major rDNA loci (the genes coding for 18S-5.8S-26S rRNA) was investigated in the economically important Brassica species and their wild relatives by in situ hybridization of an rDNA probe to metaphase chromosomes and interphase nuclei. The diploid species B. nigra (B genome) has two major pairs of rDNA loci, B. oleracea (C genome) has two major pairs and one minor pair of loci, while B. campestris (A genome) has five pairs of loci. Among the three tetraploid species arising from these three diploid ancestors, B. carinata (BBCC genomes) has four loci, B. juncea (AABB genomes) has five major pairs and one minor pair of loci, and B. napus (AACC genomes) has six pairs of loci, indicating that the number of loci has been reduced during evolution. The complexity of the known rDNA restriction fragment length polymorphism patterns gave little indication of number of rDNA loci. It is probable that chromosome rearrangements have occurred during evolution of the amphidiploid species. The data will be useful for physical mapping of genes relative to rDNA loci, micro- and macro-evolutionary studies and analysis of aneuploids including addition and substitution lines used in Brassica breeding programs.     

Molecular characterization of the flowering time gene FRIGIDA in Brassica genomes A and C

An important determinant of flowering time variation in Arabidopsis, the FRIGIDA (FRI) gene has not been until recently investigated in economically important Brassica species. In diploid Brassica species, this gene exists as two paralogous loci on chromosomes A3 and A4 (B. rapa; A genome), and C3 and C9 (B. oleracea; C genome). Each locus is represented by several genome-specific alleles, which are discerned primarily by polymorphisms in C- and especially N-terminal regions. Locus- and genome-specific sequences of two FRI paralogues are conserved almost completely in the subgenomes A and C of tetraploid B. napus. The phylogenetic analysis of available FRI sequences presumes that the duplication of FRI loci preceded speciation in the genus Brassica.     

Chromosomal localization of intergenomic RFLP loci in hexaploid wheat.

Hybridization of radiolabeled wheat DNA probes to genomic DNA digests of compensating nullisomic-tetrasomic lines and ditelosomic lines of hexaploid wheat (Triticum aestivum L. cv. Chinese Spring) can be used to identify intergenomic RFLPs. Sixty-three PstI/BamHI genomic DNA probes and eight cDNA probes were used to determine the chromosomal locations of 223 DNA fragments that define a minimum of 189 RFLP loci. Eighty-four percent of the genomic DNA clones hybridize to fragments located in homoeologous chromosomes and 16% hybridize to fragments located in one chromosome only or to fragments located in nonhomoeologous chromosomes. All of the cDNA probes hybridize to fragments located in homoeologous chromosomes.     

Alignment of the conserved C genomes of Brassica oleracea and Brassica napus

A population of 169 microspore-derived doubled-haploid lines was produced from a highly polymorphic Brassica oleracea cross. A dense genetic linkage map of B. oleracea was then developed based on the segregation of 303 RFLP-defined loci. It is hoped that these lines will be used by other geneticists to facilitate the construction of a unified genetic map of B. oleracea. When the B. oleracea map was compared to one ofB. napus (Parkin et al. 1995), based on the same RFLP probes (Sharpe et al. 1995), good collinearity between the C-genome linkage groups of the two species was observed.     

Quantitative karyotyping of three diploid Brassica species by imaging methods and localization of 45s rDNA loci on the identified chromosomes

 Chromosomes of the three diploid Brassica species, B. rapa (AA), B. nigra (BB) and B. oleracea (CC), were identified based on their morphological characteristics, especially on the condensation pattern appearing at the somatic pro-metaphase stage. The morphological features of the pro-metaphase chromosomes of the three Brassica spp. were quantified by imaging methods using chromosome image analyzing system II (CHIAS 2). As a result, quantitative chromosome maps or idiograms of the three diploid Brassica spp. were developed. The fluorescence in situ hybridization (FISH) method revealed the location of 45s rDNA (the 26s-5.8s-18s ribosomal RNA gene cluster) on the chromosomes involved. The number of 45s rDNA loci in the B. rapa, B. nigra and B. oleracea are five, three and two, respectively. The loci detected were systematically mapped on the idiograms of the three Brassica spp. Received: 5 September 1997 / Accepted: 6 October 1997     

Chromosomal localization of the loci responsible for dystrophic cardiac calcinosis in DBA/2 mice.

Dystrophic cardiac calcinosis (DCC) occurs in certain inbred strains of mice, including DBA/2 and C3H/He, and is generally found as an incidental lesion in adult animals at necropsy. Preliminary genetic studies into the cause of DCC have been performed in DBA/2 mice and suggest that DCC is inherited as an autosomal recessive trait involving three or four unlinked genes. To investigate the genetics of DCC further, we produced myocardial cell death by freeze-thaw injury to induce DCC. Experiments were conducted with three F1 hybrids made using three inbred strains of mice (DBA/2J and C3H/HeJ, DCC-susceptible strains; C57BL/6J, DCC-resistant strain) to compare the genetic factors in the development of DCC. We found that DBA/2 and C3H/He mice share the same gene pattern(s) that is responsible for DCC. We determined by backcross linkage analysis in DBA/2 and C57BL/6 mice that at least one recessive locus is responsible for DCC. A haplotype analysis of the backcross data demonstrated that the recessive locus, designated dyscalc1, is located on Chromosome 7, 20.5 cM distal to the centromere. The likely candidate genes for dyscalc1 are discussed. Further understanding of the structure and function of these mutant genes will be beneficial in explaining the molecular pathogenesis of DCC.     

Microsatellite markers for genome analysis in Brassica. II. Assignment of rapeseed microsatellites to the A and C genomes and genetic mapping in Brassica oleracea L.

Microsatellites are highly polymorphic and efficient markers for the analysis of plant genomes. Primer specificity, however, may restrict the applicability of these markers even between closely related species for comparative mapping studies. We have demonstrated that the majority of microsatellites identified in oilseed rape (Brassica napus L; AC genome) correspond to loci which can be easily assigned to the A and C progenitor genomes. A study with 63 primer pairs has shown that 54% detect two loci, one from each genome, while 25% and 21%, respectively, are either A or C genome-specific. The distribution of rapeseed microsatellites in the C genome was investigated by genetic mapping in Brassica oleracea L. Ninety two dinucleotide microsatellites were screened for polymorphism in an F₂ population derived from a cross between collard and cauliflower, for which an RFLP map has been constructed previously. Thirty three primer pairs (35.7%) have yielded either unspecific or no PCR products whereas the remaining primer pairs amplified one or more distinct loci. The level of polymorphism found in the mapping population was 49.2%. A total of 29 primer pairs disclosed 34 loci of which 31 are evenly distributed on 8 of the 9 B. oleracea linkage groups. For the remaining three markers linkage could not be established. Our results showed that microsatellite markers from the composite genome of B. napus can serve as a useful marker system in genetic studies and for plant-breeding objectives in B. oleracea. Received: 14 April 2000 / Accepted: 3 July 2000     

Chromosomal localization of microsatellite loci in Drosophila mediopunctata

Drosophila mediopunctata has been used as a model organism for genetics and evolutionary studies in the last three decades. A linkage map with 48 microsatellite loci recently published for this species showed five syntenic groups, which had their homology determined to Drosophila melanogaster chromosomes. Then, by inference, each of the groups was associated with one of the five major chromosomes of D. mediopunctata. Our objective was to carry out a genetic (chromosomal) analysis to increase the number of available loci with known chromosomal location. We made a simultaneous analysis of visible mutant phenotypes and microsatellite genotypes in a backcross of a standard strain and a mutant strain, which had each major autosome marked. Hence, we could establish the chromosomal location of seventeen loci; including one from each of the five major linkage groups previously published, and twelve new loci. Our results were congruent with the previous location and they open new possibilities to future work integrating microsatellites, chromosomal inversions, and genetic determinants of physiological and morphological variation.     

Identification of the A and C genomes of amphidiploid Brassica napus (oilseed rape).

A genetic linkage map consisting of 399 RFLP-defined loci was generated from a cross between resynthesized Brassica napus (an interspecific B. rapa x B. oleracea hybrid) and "natural" oilseed rape. The majority of loci exhibited disomic inheritance of parental alleles demonstrating that B. rapa chromosomes were each pairing exclusively with recognisable A-genome homologues in B. napus and that B. oleracea chromosomes were pairing similarly with C-genome homologues. This behaviour identified the 10 A genome and 9 C genome linkage groups of B. napus and demonstrated that the nuclear genomes of B. napus, B. rapa, and B. oleracea have remained essentially unaltered since the formation of the amphidiploid species, B. napus. A range of unusual marker patterns, which could be explained by aneuploidy and nonreciprocal translocations, were observed in the mapping population. These chromosome abnormalities were probably caused by associations between homoeologous chromosomes at meiosis in the resynthesized parent and the F1 plant leading to nondisjunction and homoeologous recombination.     

Characterization of seedling proteomes and development of markers to distinguish the Brassica A and C genomes

The diploid species Brassica rapa(genome AA)and B.oleracea(genome CC)were compared by fuU-seale proteome analyses of seedling.A total of 28.2% of the proteins was common to both species,indicating the existence of a basal or ubiquitous proteome.How-ever,a number of discriminating proteins(32.0%)and specific proteins(39.8%)of the Brassica A and C genomes,respectively,were identified,which could represent potentially species-specific functions.Based on these A or C genome-specific proteins,a number of PCR-based markers to distinguish B.rapa and B.oleracea species were also developed.     

Characterization of seedling proteomes and development of markers to distinguish the Brassica A and C genomes

The diploid species Brassica rapa(genome AA)and B.oleracea(genome CC)were compared by full-scale proteome analyses of seedling.A total of 28.2% of the proteins was common to both species,indicating the existence of a basal or ubiquitous proteome.However,a number of discriminating proteins(32.0%)and specific proteins(39.8%)of the Brassica A and C genomes,respectively,were identified,which could represent potentially species-specific functions.Based on these A or C genome-specific proteins,a number of PCR-bas...     

Chromosomal localization of three endogenous retrovirus loci associated with virus production in White Leghorn chickens.

Proposed mechanisms for the generation of endogenous retrovirus loci have been examined by determining the chromosomal distribution of these loci by means of in situ hybridization. Unlike the clustering on chromosome 1 of five endogenous retrovirus loci associated with the gs- chf- phenotype A. Tereba and S. M. Astrin, submitted for publication), three loci associated with endogenous retrovirus production (V+ phenotype) were located on three separate chromosomes. ev2, which codes for the prototype endogenous RAV-0 genome in line 7(2) chickens, was localized near the middle of the long arm of chromosome 2, ev7, coding for a noninfectious, inducible genome present in line 15B chickens, was located near the end of the long arm of the Z chromosome. A third V+ locus, designated ev14, was detected near the middle of chromosome 3. This arrangement of V+ loci is consistent with an integration mechanism employing randomly distributed integration sites in the chicken genome. In addition, these data provide evidence suggesting that the gs- chf- -associated loci may have been generated by a different mechanism.     

Repetitive sequence characterization and development of SSR and CMS-gene-specific markers in the Brassica mitochondrial genomes

Molecular Breeding - Kiwifruit plants are particularly sensitive to soil waterlogging. Enhancement of waterlogging tolerance in kiwifruit can potentially considerably increase its fruit production...     

Chromosomal localization and molecular characterization of 53 cosmid-derived bovine microsatellites

Gene mapping in cattle has progressed rapidly in recent years largely owing to the introduction of powerful genetic markers, such as the microsatellites, and through advances in physical mapping techniques such as synteny mapping and fluorescence in situ hybridization (FISH). Microsatellite markers are often not physically mapped because they are generally isolated from small insert plasmid libraries, which makes their chromosomal localization inefficient. In this report we describe the FISH mapping of a large group of cosmid-derived bovine microsatellite markers, as our contribution to the European mapping initiative, BovMap. One objective of BovMap is to develop a set of anchored loci for the cattle genome map.Two cosmid libraries were screened with probes corresponding to the (AC) _n microsatellite motif. Positive clones were mapped by FISH, and then a subset was further analyzed by sequencing the region flanking the microsatellite repeat. In total, 58 clones were hybridized with chromosomes and identified loci on 22 of the 31 different bovine chromosomes. Three clones contained satellite DNA. Two or more markers were placed on 12 chromosomes. Sequencing of the microsatellites and flanking regions was performed directly from 43 cosmids, as previously reported (Ferretti et al. Anim. Genet. 25, 209–214, 1994). Primers were developed for 39 markers and used to describe the polymorphism associated with the corresponding loci.     

Distribution of rDNA loci in the genus Glycine Willd.

The objective of this study was to examine the distribution of rDNA loci in the genus Glycine Willd. by fluorescent in situ hybridization (FISH) using the internal transcribed spacer (ITS) region of nuclear ribosomal DNA as a probe. The hybridized rDNA probe produced two distinct yellow signals on reddish chromosomes representing two NORs in 16 diploid (2n=40) species. Aneudiploid (2n=38) and aneutetraploid (2n=78) Glycine tomentella Hayata also exhibited two rDNA sites. However, the probe hybridized with four chromosomes as evidenced by four signals in two diploid species (Glycine curvata Tind. and Glycine cyrtoloba Tind.) and tetraploid (2n=80) G. tabacina (Labill.) Benth. and G. tomentella. Synthesized amphiploids (2n=80) of Glycine canescens F. J. Herm. (2n=40) and the 40-chromosome G. tomentella also showed four signals. This study demonstrates that the distribution of the rDNA gene in the 16 Glycine species studied is highly conserved and that silence of the rDNA locus may be attributed to amphiplasty during diploidization and speciation. Received: 10 October 2000 / Accepted: 6 December 2000     

Physical mapping by FISH and GISH of rDNA loci and discrimination of genomes A and B inScilla scilloides complex distributed in Korea

The chromosomal locations of the 18S-26S (45S) and 5S rDNA loci in cytotypes AA, BB, and AABB ofScilla scilloides Complex from Korea were physically mapped using multicolor fluorescencein situ hybridization (McFISH). Genomicin situ hybridization (GISH) was also performed to distinguish between the AA and BB genomes in allotetraploid AABB plants. One 18S-26S rDNA locus was detected in both AA (a2) and BB (b1 ); one locus also was found in the allopolyploid AABB (b1 ). This demon-strated the loss of that locus in genome A. GISH with biotin-labeled DNA from the BB genome and digoxigenin-labeled 18S-26S rDNA probes revealed that the 18S-26S rDNA in AABB plants was localized in the nucleolus organizer region (NOR) of genome B. One and two 5S rDNA loci were found in diploids AA and BB, respectively. As expected, all three 5S rDNA loci were detected in the AABB plants. The sequence identities of the 5S rDNA genes among cytotypes AA and BB, AA and AABB, and BB and AABB were 99%, 95%, and 95%, respectively. These authors contributed equally to this paper