Jarmila Číhalíková

Development of chromosome-specific BAC resources for genomics of bread wheat.

The large bread wheat genome (1C ∼ 17 Gbp) contains a preponderance of repetitive DNA and the species is polyploid. These characteristics together serve to hamper the molecular analysis of the wheat genome. Its complexity can, however, be reduced by using flow cytometry to isolate individual chromosomes, and these can be exploited to construct chromosome-specific BAC libraries. Such libraries simplify the task of physical map construction, positional cloning and the targeted development of genetic markers. Rapid improvements in the efficiency and cost of DNA sequencing provide an opportunity to contemplate sequencing the wheat genome by preparing sequence-ready physical maps for each chromosome or chromosome arm in turn. The quality of the chromosome-specific libraries depends on their chromosome coverage and the mean insert size. First-generation libraries suffered from a relatively low mean insert size, but improvements to the protocol have generated a second wave of libraries with a significantly increased mean insert size and better chromosome coverage. Each chromosome (arm)-specific library is composed of a manageable number of clones, and so represents a practical tool in the area of wheat genomics.

Flow karyotyping and chromosome sorting in bread wheat ( Triticum aestivum L.).

Abstract.Previously, we reported on the development of procedures for chromosome analysis and sorting using flow cytometry (flow cytogenetics) in bread wheat. That study indicated the possibility of sorting large quantities of intact chromosomes, and their suitability for analysis at the molecular level. However, due to the lack of sufficient differences in size between individual chromosomes, only chromosome 3B could be sorted into a high-purity fraction. The present study aimed to identify wheat stocks that could be used to sort other chromosomes. An analysis of 58 varieties and landraces demonstrated a remarkable reproducibility and sensitivity of flow cytometry for the detection of numerical and structural chromosome changes. Changes in flow karyotype, diagnostic for the presence of the 1BL·1RS translocation, have been found and lines from which translocation chromosomes 5BL·7BL and 4AL·4AS-5BL could be sorted have been identified. Furthermore, wheat lines have been identified which can be used for sorting chromosomes 4B, 4D, 5D and 6D. The ability to sort any single arm of the hexaploid wheat karyotype, either in the form of a ditelosome or a isochromosome, has also been demonstrated. Thus, although originally considered recalcitrant, wheat seems to be suitable for the development of flow cytogenetics and the technology can be applied to the physical mapping of DNA sequences, the targeted isolation of molecular makers and the construction of chromosome- and arm-specific DNA libraries. These approaches should facilitate the analysis of the complex genome of hexaploid bread wheat.

Cell cycle synchronization in plant root meristems

The analysis of structure and metabolism of a cell at a defined phase of cell cycle is often difficult because cell cycle progression in somatic tissues is asynchronous and only a fraction of cells are cycling. An elegant solution to obtain populations of cells enriched for single stage of the cell cycle is to impose the synchrony artificially. Different systems have been used to obtain synchronized populations of plant cells, including suspension-cultured cells, leaf mesophyll protoplasts and root tip meristems. Root tips have been frequently used in a variety of studies ranging from chromosome analysis to cell cycle and its regulation. Seedlings with actively growing roots may be obtained in most plant species, they are easy to handle, the experimental system is well defined, reproducible and can be easily modified for different species. This paper describes a protocol for cell cycle synchronization in root tips of Vicia faba, which is based on the use of DNA synthesis inhibitor hydroxyurea [18]. Modifications of the protocol for Pisum sativum, Medicago sativa, Hordeum vulgare, Secale cereale, Triticum aestivum, and Zea mays are also given. Flow cytometric data indicate that about 90% of root tip cells are synchronized. On average, mitotic indices exceeding 50% are obtained with the method. Synchronized cells may be accumulated at metaphase using a mitotic spindle inhibitor to achieve metaphase indices exceeding 50%.

A novel resource for genomics of Triticeae: BAC library specific for the short arm of rye (Secale cereale L.) chromosome 1R (1RS)

BackgroundGenomics of rye (Secale cereale L.) is impeded by its large nuclear genome (1C~7,900 Mbp) with prevalence of DNA repeats (> 90%). An attractive possibility is to dissect the genome to small parts after flow sorting particular chromosomes and chromosome arms. To test this approach, we have chosen 1RS chromosome arm, which represents only 5.6% of the total rye genome. The 1RS arm is an attractive target as it carries many important genes and because it became part of the wheat gene pool as the 1BL.1RS translocation.ResultsWe demonstrate that it is possible to sort 1RS arm from wheat-rye ditelosomic addition line. Using this approach, we isolated over 10 million of 1RS arms using flow sorting and used their DNA to construct a 1RS-specific BAC library, which comprises 103,680 clones with average insert size of 73 kb. The library comprises two sublibraries constructed using Hin dIII and Eco RI and provides a deep coverage of about 14-fold of the 1RS arm (442 Mbp). We present preliminary results obtained during positional cloning of the stem rust resistance gene SrR, which confirm a potential of the library to speed up isolation of agronomically important genes by map-based cloning.ConclusionWe present a strategy that enables sorting short arms of several chromosomes of rye. Using flow-sorted chromosomes, we have constructed a deep coverage BAC library specific for the short arm of chromosome 1R (1RS). This is the first subgenomic BAC library available for rye and we demonstrate its potential for positional gene cloning. We expect that the library will facilitate development of a physical contig map of 1RS and comparative genomics of the homoeologous chromosome group 1 of wheat, barley and rye.

Development of flow cytogenetics and physical genome mapping in chickpea (Cicer arietinum L.)

Procedures for flow cytometric analysis and sorting of mitotic chromosomes (flow cytogenetics) have been developed for chickpea (Cicer arietinum). Suspensions of intact chromosomes were prepared from root tips treated to achieve a high degree of metaphase synchrony. The optimal protocol consisted of a treatment of roots with 2 mmol/L hydroxyurea for 18 h, a 4.5-h recovery in hydroxyurea-free medium, 2 h incubation with 10 µmol/L oryzalin, and ice-water treatment overnight. This procedure resulted in an average metaphase index of 47%. Synchronized root tips were fixed in 2% formaldehyde for 20 min, and chromosome suspensions prepared by mechanical homogenization of fixed root tips. More than 4×105 morphologically intact chromosomes could be isolated from 15 root tips. Flow cytometric analysis of DAPI-stained chromosomes resulted in histograms of relative fluorescence intensity (flow karyotypes) containing eight peaks, representing individual chromosomes and/or groups of chromosomes with a similar relative DNA content. Five peaks could be assigned to individual chromosomes (A, B, C, G, H). The purity of sorted chromosome fractions was high, and chromosomes B and H could be sorted with 100% purity. PCR on flow-sorted chromosome fractions with primers for sequence-tagged microsatellite site (STMS) markers permitted assignment of the genetic linkage group LG8 to the smallest chickpea chromosome H. This study extends the number of legume species for which flow cytogenetics is available, and demonstrates the potential of flow cytogenetics for genome mapping in chickpea.

BAC Libraries from Wheat Chromosome 7D: Efficient Tool for Positional Cloning of Aphid Resistance Genes

Positional cloning in bread wheat is a tedious task due to its huge genome size and hexaploid character. BAC libraries represent an essential tool for positional cloning. However, wheat BAC libraries comprise more than million clones, which makes their screening very laborious. Here, we present a targeted approach based on chromosome-specific BAC libraries. Such libraries were constructed from flow-sorted arms of wheat chromosome 7D. A library from the short arm (7DS) consisting of 49,152 clones with 113 kb insert size represented 12.1 arm equivalents whereas a library from the long arm (7DL) comprised 50,304 clones of 116 kb providing 14.9x arm coverage. The 7DS library was PCR screened with markers linked to Russian wheat aphid resistance gene DnCI2401, the 7DL library was screened by hybridization with a probe linked to greenbug resistance gene Gb3. The small number of clones combined with high coverage made the screening highly efficient and cost effective.

Flow cytometric chromosome sorting in plants: the next generation.

Genome analysis in many plant species is hampered by large genome size and by sequence redundancy due to the presence of repetitive DNA and polyploidy. One solution is to reduce the sample complexity by dissecting the genomes to single chromosomes. This can be realized by flow cytometric sorting, which enables purification of chromosomes in large numbers. Coupling the chromosome sorting technology with next generation sequencing provides a targeted and cost effective way to tackle complex genomes. The methods outlined in this article describe a procedure for preparation of chromosomal DNA suitable for next-generation sequencing.

Rapid identification and determination of purity of flow-sorted plant chromosomes using C-PRINS

BACKGROUND Flow-sorted plant chromosomes are being increasingly used in plant genome analysis and mapping. Consequently, there is a need for a rapid method for identification of sorted chromosomes and for determination of their purity. We report on optimization of procedures for primed in situ DNA labeling (PRINS) and cycling-PRINS (C-PRINS) for fluorescent labeling of repetitive DNA sequences on sorted plant chromosomes suitable for their identification. METHODS Chromosomes of barley, wheat, and field bean were sorted onto microscope slides, dried, and subjected to PRINS or C-PRINS with primers for GAA microsatellites (barley and wheat) or FokI repeat (field bean). The following parameters were optimized to achieve the highest specificity and intensity of fluorescent labeling: ratio of labeled versus unlabeled nucleotides, nucleotide concentration, and the number and concentration of primers. RESULTS Under optimal conditions, C-PRINS resulted in strong and specific labeling of GAA microsatellites on sorted barley and wheat chromosomes and FokI repeats on sorted field bean chromosomes. The labeling patterns were characteristic for each chromosome and permitted their unequivocal identification as well as determination of purity after sorting, which ranged from 96% to 99%. A standard polymerase chain reaction (PCR) with chromosome-specific primers was not sensitive enough to detect low-frequency contamination. CONCLUSIONS The results indicate that a single C-PRINS assay with primers that give chromosome-specific labeling pattern is sufficient not only to determine chromosome content of peaks on flow karyotype but also to determine the purity of sorted chromosome fractions. The whole procedure can be performed in less than 3 h on the next day after sorting. Numerous applications are expected in the area of plant flow cytogenetics.

Chromosome Genomics in the Triticeae

The Triticeae species are unique among the important agricultural crops in possessing massive genomes with a prevalence of dispersed DNA repeats. The highest level of complexity is observed in tetraploid and hexaploid wheat whose nuclear genomes comprise two and three homoeologous genomes, respectively. Polyploidy and the presence of repeats make gene cloning and genome sequencing in the Triticeae extremely difficult. Chromosome genomics simplifies these tasks by targeting single chromosomes and chromosome arms, which represent only a few percent of the nuclear genomes. The advantages of this strategy over a whole-genome approach include the avoidance of problems due to the presence of homoeologs in wheat, reduction of work to manageable portions, cost efficiency, and an opportunity to structure collaborative projects where individual laboratories work on particular chromosomes. In this chapter, we describe how chromosomes and chromosome arms can be isolated by flow cytometric sorting and we review development of flow cytogenetics in the Triticeae. We then discuss various applications of flow-sorted chromosomes and assess the potential of chromosome genomics in the Triticeae.

Localisation of DNA sequences on plant chromosomes using PRINS and C-PRINS

Localisation of DNA sequences to plant chromosomes in situ has traditionally been accomplished using fluorescence in situ hybridisation (FISH). Although the method is suitable for most applications it is time-consuming and requires labelled probes. Recently, primed in situ labelling (PRINS) has been developed as an alternative to FISH. PRINS is based on annealing of unlabelled oligonucleotide primer(s) to chromosome DNA and its elongation by DNA polymerase in the presence of labelled nucleotide(s). The method was found useful to detect high-copy tandem repeats on plant chromosomes. Low copy repeats were detected after a more sensitive variant of PRINS called cycling PRINS (C-PRINS), which involves a sequence of thermal cycles analogous to polymerase chain reaction. This paper describes protocols of PRINS and C-PRINS, which have been optimised for chromosome spreads and for chromosomes purified using gradient centrifugation and/or flow sorting. The methods result in clear signals with negligible non-specific labelling. Further work is needed to improve the sensitivity to allow for reliable detection of single- copy DNA sequences.