Comparative analysis of the Brassica oleracea genetic map and the Arabidopsis thaliana genome

Genome ◽  
2009 ◽  
Vol 52 (7) ◽  
pp. 620-633 ◽  
Author(s):  
Malgorzata Kaczmarek ◽  
Grzegorz Koczyk ◽  
Piotr A. Ziolkowski ◽  
Danuta Babula-Skowronska ◽  
Jan Sadowski
Keyword(s):  
Arabidopsis Thaliana ◽  
Genetic Map ◽  
Physical Map ◽  
A Priori ◽  
Brassica Species ◽  
Cdna Clones ◽  
Map Construction ◽  
Gene Copies ◽  
In Silico Study ◽  
Comprehensive Comparison

We further investigated genome macrosynteny for Brassica species and Arabidopsis thaliana . This work aimed at comparative map construction for B. oleracea and A. thaliana chromosomes based on 160 known A. thaliana probes: 147 expressed sequence tags (ESTs) and 13 full-length cDNA clones. Based on an in silico study of the A. thaliana genome, most of the selected ESTs (83%) represented unique or low-copy genes. We identified conserved segments by the visual inspection of comparative data with a priori assumptions, and established their significance with the LineUp algorithm. Evaluation of the number of B. oleracea gene copies per A. thaliana EST revealed a fixed upward trend. We established a segregation distortion pattern for all genetic loci, with particular consideration of the type of selection (gametic or zygotic), and discuss its possible impact on genetic map construction. Consistent with previous reports, we found evidence for numerous chromosome rearrangements and the genome fragment replication of B. oleracea that have taken place since the divergence of the two species. Also, we found that over 54% of the B. oleracea genome is covered by 24 segments conserved with the A. thaliana genome. The average conserved segment is composed of 5 loci covering 19.3 cM in the B. oleracea genetic map and 2.42 Mb in the A. thaliana physical map. We have also attempted to use a unified system of conserved blocks (previously described) to verify our results and perform a comprehensive comparison with other Brassica species.

scholarly journals Meiotic recombination, noncoding DNA and genomic organization in Caenorhabditis elegans.

Genetics ◽  
1995 ◽  
Vol 141 (1) ◽  
pp. 159-179 ◽  
Author(s):  
T M Barnes ◽  
Y Kohara ◽  
A Coulson ◽  
S Hekimi
Keyword(s):  
Caenorhabditis Elegans ◽  
Genetic Map ◽  
Recombination Rate ◽  
Physical Map ◽  
Gene Density ◽  
Cdna Clones ◽  
Recombination Rates ◽  
Noncoding Dna ◽  
Physical Size ◽  
C Elegans

Abstract The genetic map of each Caenorhabditis elegans chromosome has a central gene cluster (less pronounced on the X chromosome) that contains most of the mutationally defined genes. Many linkage group termini also have clusters, though involving fewer loci. We examine the factors shaping the genetic map by analyzing the rate of recombination and gene density across the genome using the positions of cloned genes and random cDNA clones from the physical map. Each chromosome has a central gene-dense region (more diffuse on the X) with discrete boundaries, flanked by gene-poor regions. Only autosomes have reduced rates of recombination in these gene-dense regions. Cluster boundaries appear discrete also by recombination rate, and the boundaries defined by recombination rate and gene density mostly, but not always, coincide. Terminal clusters have greater gene densities than the adjoining arm but similar recombination rates. Thus, unlike in other species, most exchange in C. elegans occurs in gene-poor regions. The recombination rate across each cluster is constant and similar; and cluster size and gene number per chromosome are independent of the physical size of chromosomes. We propose a model of how this genome organization arose.

scholarly journals Identification and High-Density Mapping of Gene-Rich Regions in Chromosome Group 1 of Wheat

Genetics ◽  
1996 ◽  
Vol 144 (4) ◽  
pp. 1883-1891 ◽  
Author(s):  
Kulvinder S Gill ◽  
Bikram S Gill ◽  
Takashi R Endo ◽  
Teri Taylor
Keyword(s):  
Genetic Map ◽  
Physical Map ◽  
Average Distance ◽  
High Density ◽  
Genetic Maps ◽  
Cdna Clones ◽  
Density Mapping ◽  
Physical Maps ◽  
Group 1 Chromosomes ◽  
Group 1

We studied the distribution of genes and recombination in wheat (Triticum aestivum) group 1 chromosomes by comparing high-density physical and genetic maps. Physical maps of chromosomes 1A, 1B, and 1D were generated by mapping 50 DNA markers on 56 single-break deletion lines. A consensus physical map was compared with the 1D genetic map of Triticum tauschii (68 markers) and a Triticeae group 1 consensus map (288 markers) to generate a cytogenetic ladder map (CLM). Most group 1 markers (86%) were present in five clusters that encompassed only 10% of the group 1 chromosome. This distribution may reflect that of genes because more than half of the probes were cDNA clones and 30% were PstI genomic. All 14 agronomically important genes in group 1 chromosomes were present in these clusters. Most recombination occurred in gene-cluster regions. Markers fell at an average distance of 244 kb in these regions. The CLM involving the Triticeae consensus genetic map revealed that the above distribution of genes and recombination is the same in other Triticeae species. Because of a significant number of common markers, our CLM can be used for comparative mapping and to estimate physical distances among markers in many Poaceae species including rice and maize.

Collinearity between a 30-centimorgan segment of Arabidopsis thaliana chromosome 4 and duplicated regions within the Brassica napus genome

Genome ◽  
1998 ◽  
Vol 41 (1) ◽  
pp. 62-69 ◽  
Author(s):  
A C Cavell ◽  
D J Lydiate ◽  
IAP Parkin ◽  
C Dean ◽  
M Trick
Keyword(s):  
Arabidopsis Thaliana ◽  
Brassica Napus ◽  
Physical Map ◽  
Brassica Species ◽  
Single Copy ◽  
Genetic Maps ◽  
Haploid Genome ◽  
Chromosome 4 ◽  
Crop Species ◽  
Brassica Crop

Arabidopsis thaliana (the model dicotyledonous plant) is closely related to Brassica crop species. Genome collinearity, or conservation of marker order, between Brassica napus (oilseed rape) and A. thaliana was assessed over a 7.5-Mbp region of the long arm of A. thaliana chromosome 4, equivalent to 30 cM. Estimates of copy number indicated that sequences present in a single copy in the haploid genome of A. thaliana (n = 5) were present in 2-8 copies in the haploid genome of B. napus (n = 19), while sequences present in multiple copies in A. thaliana were present in over 10 copies in B. napus. Genetic mapping in B. napus of DNA markers derived from a segment of A. thaliana chromosome 4 revealed duplicated homologous segments in the B. napus genome. Physical mapping in A. thaliana of homologues of Brassica clones derived from these regions confirmed the identity of six duplicated segments with substantial homology to the 7.5-Mbp region of chromosome 4 in A. thaliana. These six duplicated Brassica regions (on average 22cM in length) are collinear, except that two of the six copies contain the same large internal inversion. These results have encouraging implications for the feasibility of shuttling between the physical map of A. thaliana and genetic maps of Brassica species, for identifying candidate genes and for map based gene cloning in Brassica crops.

scholarly journals Heterogeneity in Rates of Recombination Across the Mouse Genome

Genetics ◽  
1996 ◽  
Vol 142 (2) ◽  
pp. 537-548 ◽  
Author(s):  
Michael W Nachman ◽  
Gary A Churchill
Keyword(s):  
Linkage Map ◽  
Genetic Map ◽  
Large Scale ◽  
Physical Map ◽  
Genetic Maps ◽  
Recombination Rates ◽  
Physical Maps ◽  
Genomic Patterns ◽  
Mary Lyon ◽  
Microsatellite Linkage

Abstract If loci are randomly distributed on a physical map, the density of markers on a genetic map will be inversely proportional to recombination rate. First proposed by MARY LYON, we have used this idea to estimate recombination rates from the Drosophila melanogaster linkage map. These results were compared with results of two other studies that estimated regional recombination rates in D. melanogaster using both physical and genetic maps. The three methods were largely concordant in identifying large-scale genomic patterns of recombination. The marker density method was then applied to the Mus musculus microsatellite linkage map. The distribution of microsatellites provided evidence for heterogeneity in recombination rates. Centromeric regions for several mouse chromosomes had significantly greater numbers of markers than expected, suggesting that recombination rates were lower in these regions. In contrast, most telomeric regions contained significantly fewer markers than expected. This indicates that recombination rates are elevated at the telomeres of many mouse chromosomes and is consistent with a comparison of the genetic and cytogenetic maps in these regions. The density of markers on a genetic map may provide a generally useful way to estimate regional recombination rates in species for which genetic, but not physical, maps are available.

scholarly journals Development and validation of genome-wide InDel markers with high levels of polymorphism in bitter gourd (Momordica charantia)

BMC Genomics ◽  
2021 ◽  
Vol 22 (1) ◽  
Author(s):  
Junjie Cui ◽  
Jiazhu Peng ◽  
Jiaowen Cheng ◽  
Kailin Hu
Keyword(s):  
Genetic Map ◽  
Average Density ◽  
Momordica Charantia ◽  
Bitter Gourd ◽  
Map Construction ◽  
Indel Markers ◽  
Genome Wide ◽  
Indel Polymorphisms ◽  
Molecular Marker Development ◽  
Development And Validation

Abstract Background The preferred choice for molecular marker development is identifying existing variation in populations through DNA sequencing. With the genome resources currently available for bitter gourd (Momordica charantia), it is now possible to detect genome-wide insertion-deletion (InDel) polymorphisms among bitter gourd populations, which guides the efficient development of InDel markers. Results Here, using bioinformatics technology, we detected 389,487 InDels from 61 Chinese bitter gourd accessions with an average density of approximately 1298 InDels/Mb. Then we developed a total of 2502 unique InDel primer pairs with a polymorphism information content (PIC) ≥0.6 distributed across the whole genome. Amplification of InDels in two bitter gourd lines ‘47–2–1-1-3’ and ‘04–17,’ indicated that the InDel markers were reliable and accurate. To highlight their utilization, the InDel markers were employed to construct a genetic map using 113 ‘47–2–1-1-3’ × ‘04–17’ F2 individuals. This InDel genetic map of bitter gourd consisted of 164 new InDel markers distributed on 15 linkage groups with a coverage of approximately half of the genome. Conclusions This is the first report on the development of genome-wide InDel markers for bitter gourd. The validation of the amplification and genetic map construction suggests that these unique InDel markers may enhance the efficiency of genetic studies and marker-assisted selection for bitter gourd.

High Frequency Recombination During the Sexual Cycle of Dictyostelium discoideum

Genetics ◽  
1998 ◽  
Vol 148 (4) ◽  
pp. 1829-1832 ◽  
Author(s):  
David Francis
Keyword(s):  
Dictyostelium Discoideum ◽  
Genetic Map ◽  
High Frequency ◽  
Cell Biology ◽  
Physical Map ◽  
Genetic System ◽  
Sexual Cycle ◽  
Chromosome 2 ◽  
New Combinations ◽  
Restriction Sites

Abstract Analysis of Dictyostelium development and cell biology has suffered from the lack of an ordinary genetic system whereby genes can be arranged in new combinations. Genetic exchange between two long ignored strains, A2Cycr and WS205 is here reexamined. Alleles which differ in size or restriction sites between these two strains were found for seven genes. Six of these are in two clusters on chromosome 2. Frequencies of recombinant progeny indicate that the genetic map of the two mating strains is colinear with the physical map recently worked out for the standard nonsexual strain, NC4. The rate of recombination is high, about 0.1% per kilobase in three different regions of chromosome 2. This value is comparable to rates found in yeast, and will permit fine dissection of the genome.

scholarly journals Construction of the physical map for three loci in chromosome band 13q14: comparison to the genetic map.

1990 ◽  
Vol 87 (9) ◽  
pp. 3415-3419 ◽  
Author(s):  
M. J. Higgins ◽  
C. Turmel ◽  
J. Noolandi ◽  
P. E. Neumann ◽  
M. Lalande
Keyword(s):  
Genetic Map ◽  
Physical Map ◽  
Chromosome Band

A physical map with yeast artificial chromosome (YAC) clones covering 63% of the 12 rice chromosomes

Genome ◽  
2001 ◽  
Vol 44 (1) ◽  
pp. 32-37 ◽  
Author(s):  
Shoko Saji ◽  
Yosuke Umehara ◽  
Baltazar A Antonio ◽  
Hiroko Yamane ◽  
Hiroshi Tanoue ◽  
...  
Keyword(s):  
Genetic Map ◽  
Dna Markers ◽  
Yeast Artificial Chromosome ◽  
Physical Map ◽  
Genome Structure ◽  
Rice Genome ◽  
Artificial Chromosome ◽  
Physical Length ◽  
Rice Chromosomes ◽  
Yac Contig

A new YAC (yeast artificial chromosome) physical map of the 12 rice chromosomes was constructed utilizing the latest molecular linkage map. The 1439 DNA markers on the rice genetic map selected a total of 1892 YACs from a YAC library. A total of 675 distinct YACs were assigned to specific chromosomal locations. In all chromosomes, 297 YAC contigs and 142 YAC islands were formed. The total physical length of these contigs and islands was estimated to 270 Mb which corresponds to approximately 63% of the entire rice genome (430 Mb). Because the physical length of each YAC contig has been measured, we could then estimate the physical distance between genetic markers more precisely than previously. In the course of constructing the new physical map, the DNA markers mapped at 0.0-cM intervals were ordered accurately and the presence of potentially duplicated regions among the chromosomes was detected. The physical map combined with the genetic map will form the basis for elucidation of the rice genome structure, map-based cloning of agronomically important genes, and genome sequencing.Key words: physical mapping, YAC contig, rice genome, rice chromosomes.

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