Jitka Kopecká scite author profile

Crossing over-based recombination is a powerful tool for generating new allelic combinations during sexual reproduction. It usually occurs between homologous chromosomes. However, under some conditions, homoeologues may also be capable of crossing over. Whether homologous and homoeologous crossovers are equivalent and governed by the same rules has never been established. Here we report on chromosome distribution of homoeologous crossovers in a unique system of Festuca × Lolium hybrids. Unlike in most other hybrids, in these intergeneric hybrids, homoeologous chromosomes are capable of pairing and crossing over with frequencies approaching that of homologues. At the same time, genome divergence makes cytological detection of chromosome recombination feasible. We analyzed the distribution of homoeologous recombination along individual chromosomes in a complete set of intergeneric single chromosome substitutions fromF. pratensisinto tetraploid L. multiflorum. Homoeologous recombination sites were not evenly distributed along the chromosomes, being concentrated in intercalary regions of the arms and reduced in proximal and distal regions. Several recombination hotspots and cold spots were found along individual chromosomes and the recombination was not affected by the presence of a secondary constriction. Our results indicate that despite the uneven distribution of homoeologous recombination, introgression of any part of the F. pratensis genome into L. multiflorum is feasible.

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Flow Sorting and Sequencing Meadow Fescue Chromosome 4F

Kopecký

Martis

Číhalíková

et al. 2013

Plant Physiol.

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The analysis of large genomes is hampered by a high proportion of repetitive DNA, which makes the assembly of short sequence reads difficult. This is also the case in meadow fescue (Festuca pratensis), which is known for good abiotic stress resistance and has been used in intergeneric hybridization with ryegrasses (Lolium spp.) to produce Festulolium cultivars. In this work, we describe a new approach to analyze the large genome of meadow fescue, which involves the reduction of sample complexity without compromising information content. This is achieved by dissecting the genome to smaller parts: individual chromosomes and groups of chromosomes. As the first step, we flow sorted chromosome 4F and sequenced it by Illumina with approximately 503 coverage. This provided, to our knowledge, the first insight into the composition of the fescue genome, enabled the construction of the virtual gene order of the chromosome, and facilitated detailed comparative analysis with the sequenced genomes of rice (Oryza sativa), Brachypodium distachyon, sorghum (Sorghum bicolor), and barley (Hordeum vulgare). Using GenomeZipper, we were able to confirm the collinearity of chromosome 4F with barley chromosome 4H and the long arm of chromosome 5H. Several new tandem repeats were identified and physically mapped using fluorescence in situ hybridization. They were found as robust cytogenetic markers for karyotyping of meadow fescue and ryegrass species and their hybrids. The ability to purify chromosome 4F opens the way for more efficient analysis of genomic loci on this chromosome underlying important traits, including freezing tolerance. Our results confirm that next-generation sequencing of flow-sorted chromosomes enables an overview of chromosome structure and evolution at a resolution never achieved before.

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Establishing Chromosome Genomics in Forage and Turf Grasses

Kopecký

Číhalíková

Kopecká

et al. 2012

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Analyses of large genomes are hampered by high proportions of repetitive DNA, that make the assembly of short sequence reads difficult. This is also the case for meadow fescue (Festuca pratensis Huds.), one of predominant grass species in temperate and Northern regions with the genome size estimated at 1C = 3,175 Mbp. This species is known for its ability to survive under freezing conditions and it has been used widely in intergeneric hybridization with various ryegrass species to produce superior Festulolium cultivars. Here we describe attempts to dissect the meadow fescue's genome into smaller fractions-individual chromosomes and groups of chromosomes. Following the methods of flow cytogenetics developed for legumes and cereals, we have developed a chromosome sorting protocol for grasses and currently we are able to sort F. pratensis chromosome 4 (the largest in the genome) and two groups of three chromosomes each: 2, 3, 7 and 1, 5, 6. As the first step we sequenced chromosome 4 by Illumina with 50x coverage and assembled low copy and genic regions. This facilitated detailed comparative analysis with sequenced genomes of rice, Brachypodium and sorghum and provided the first insight into the genome composition of this species. The possibility to purify chromosome 4 opens the way for a more efficient analysis of genetic loci on this chromosome that control important agronomic traits, such as freezing tolerance. Moreover, purified chromosomes are excellent templates for PCR screening as well as cytogenetic and physical mapping.

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Jitka Kopecká

Physical Distribution of Homoeologous Recombination in Individual Chromosomes of <i>Festuca pratensis </i>in <i>Lolium multiflorum</i>

Flow Sorting and Sequencing Meadow Fescue Chromosome 4F

Establishing Chromosome Genomics in Forage and Turf Grasses

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