Flow cytometric analysis and sorting of plant mitotic chromosomes has been mastered by only a few laboratories worldwide. Yet, it has been contributing significantly to progress in plant genetics, including the production of genome assemblies and the cloning of important genes. The dissection of complex genomes by flow sorting into the individual chromosomes that represent small parts of the genome reduces DNA sample complexity and streamlines projects relying on molecular and genomic techniques. Whereas flow cytometric analysis, that is, chromosome classification according to fluorescence and light scatter properties, is an integral part of any chromosome sorting project, it has rarely been used on its own due to lower resolution and sensitivity as compared to other cytogenetic methods. To perform chromosome analysis and sorting, commercially available electrostatic droplet sorters are suitable. However, in order to resolve and purify chromosomes of interest the instrument must offer high resolution of optical signals as well as stability during long runs. The challenge is thus not the instrumentation, but the adequate sample preparation. The sample must be a suspension of intact mitotic metaphase chromosomes and the protocol, which includes the induction of cell cycle synchrony, accumulation of dividing cells at metaphase, and release of undamaged chromosomes, is time consuming and laborious and needs to be performed very carefully. Moreover, in addition to fluorescent staining chromosomal DNA, the protocol may include specific labelling of DNA repeats to facilitate discrimination of particular chromosomes. This review introduces the applications of chromosome sorting in plants, and discusses in detail sample preparation, chromosome analysis and sorting to achieve the highest purity in flow-sorted fractions, and their suitability for downstream applications.

• Keywords
• DNA amplification, DNA isolation, cell cycle synchronization, gene mapping and cloning, genome sequencing, liquid chromosome suspension, marker development, mitotic metaphase chromosomes, repetitive DNA labelling,
• MeSH
• Cell Cycle MeSH
• Chromosomes, Plant * genetics   MeSH
• Metaphase MeSH
• Flow Cytometry MeSH
• Plants * genetics   MeSH
• Publication type
• Journal Article MeSH
• Research Support, Non-U.S. Gov't MeSH
• Review MeSH

Nuclear genomes of human, animals, and plants are organized into subunits called chromosomes. When isolated into aqueous suspension, mitotic chromosomes can be classified using flow cytometry according to light scatter and fluorescence parameters. Chromosomes of interest can be purified by flow sorting if they can be resolved from other chromosomes in a karyotype. The analysis and sorting are carried out at rates of 10(2)-10(4) chromosomes per second, and for complex genomes such as wheat the flow sorting technology has been ground-breaking in reducing genome complexity for genome sequencing. The high sample rate provides an attractive approach for karyotype analysis (flow karyotyping) and the purification of chromosomes in large numbers. In characterizing the chromosome complement of an organism, the high number that can be studied using flow cytometry allows for a statistically accurate analysis. Chromosome sorting plays a particularly important role in the analysis of nuclear genome structure and the analysis of particular and aberrant chromosomes. Other attractive but not well-explored features include the analysis of chromosomal proteins, chromosome ultrastructure, and high-resolution mapping using FISH. Recent results demonstrate that chromosome flow sorting can be coupled seamlessly with DNA array and next-generation sequencing technologies for high-throughput analyses. The main advantages are targeting the analysis to a genome region of interest and a significant reduction in sample complexity. As flow sorters can also sort single copies of chromosomes, shotgun sequencing DNA amplified from them enables the production of haplotype-resolved genome sequences. This review explains the principles of flow cytometric chromosome analysis and sorting (flow cytogenetics), discusses the major uses of this technology in genome analysis, and outlines future directions.

• MeSH
• Chromosomes chemistry   genetics   MeSH
• Physical Chromosome Mapping methods   MeSH
• Genome, Human MeSH
• Genomics methods   MeSH
• Gene Library MeSH
• Karyotype MeSH
• Humans MeSH
• Chromosome Painting methods   MeSH
• Mitosis MeSH
• Flow Cytometry methods   MeSH
• Plants chemistry   genetics   MeSH
• Oligonucleotide Array Sequence Analysis methods   MeSH
• Chromosome Structures chemistry   genetics   MeSH
• Animals MeSH
• Check Tag
• Humans MeSH
• Animals MeSH
• Publication type
• Journal Article MeSH
• Research Support, Non-U.S. Gov't MeSH
• Review MeSH

Cultivated chickpea is the third most important legume after field bean and garden pea worldwide. Despite considerable breeding towards improved yield and resistance to biotic and abiotic stresses, the production of chickpea remained stagnant, but molecular tools are expected to increase the impact of current improvement programs. As a first step towards this goal, various genetic linkage maps have been established and markers linked to resistance genes been identified. However, until now, only one linkage group (LG) has been assigned to a specific chromosome. In the present work, mitotic chromosomes were sorted using flow cytometry and used as template for PCR with primers designed for genomic regions flanking microsatellites. These primers amplify sequence-tagged microsatellite site markers. This approach confirmed the assignment of LG8 to the smallest chromosome H. For the first time, LG5 was linked to the largest chromosome A, LG4 to a medium-sized chromosome E, while LG3 was anchored to the second largest chromosome B. Chromosomes C and D could not be flow-sorted separately and were jointly associated to LG6 and LG7. By the same token, chromosomes F and G were anchored to LG1 and LG2. To establish a set of preferably diagnostic cytogenetic markers, the genomic distribution of various probes was verified using FISH. Moreover, a partial genomic bacterial artificial chromosome (BAC) library was constructed and putative single/low-copy BAC clones were mapped cytogenetically. As a result, two clones were identified localizing specifically to chromosomes E and H, for which no cytogenetic markers were yet available.

• MeSH
• Chromosomes, Plant genetics   MeSH
• Cicer genetics   MeSH
• Cytogenetics methods   MeSH
• DNA, Plant genetics   MeSH
• Genetic Linkage MeSH
• Genetic Markers MeSH
• Genome, Plant MeSH
• In Situ Hybridization, Fluorescence MeSH
• Chromosome Mapping methods   MeSH
• Polymerase Chain Reaction MeSH
• Flow Cytometry MeSH
• Chromosomes, Artificial, Bacterial MeSH
• Publication type
• Journal Article MeSH
• Research Support, Non-U.S. Gov't MeSH
• Names of Substances
• DNA, Plant MeSH
• Genetic Markers MeSH

BACKGROUND: Rye (Secale cereale L.) belongs to tribe Triticeae and is an important temperate cereal. It is one of the parents of man-made species Triticale and has been used as a source of agronomically important genes for wheat improvement. The short arm of rye chromosome 1 (1RS), in particular is rich in useful genes, and as it may increase yield, protein content and resistance to biotic and abiotic stress, it has been introgressed into wheat as the 1BL.1RS translocation. A better knowledge of the rye genome could facilitate rye improvement and increase the efficiency of utilizing rye genes in wheat breeding. RESULTS: Here, we report on BAC end sequencing of 1,536 clones from two 1RS-specific BAC libraries. We obtained 2,778 (90.4%) useful sequences with a cumulative length of 2,032,538 bp and an average read length of 732 bp. These sequences represent 0.5% of 1RS arm. The GC content of the sequenced fraction of 1RS is 45.9%, and at least 84% of the 1RS arm consists of repetitive DNA. We identified transposable element junctions in BESs and developed insertion site based polymorphism markers (ISBP). Out of the 64 primer pairs tested, 17 (26.6%) were specific for 1RS. We also identified BESs carrying microsatellites suitable for development of 1RS-specific SSR markers. CONCLUSION: This work demonstrates the utility of chromosome arm-specific BAC libraries for targeted analysis of large Triticeae genomes and provides new sequence data from the rye genome and molecular markers for the short arm of rye chromosome 1.

• MeSH
• Chromosomes, Plant genetics   MeSH
• DNA, Plant genetics   MeSH
• Physical Chromosome Mapping MeSH
• Genetic Markers MeSH
• Genome, Plant * MeSH
• Gene Library MeSH
• In Situ Hybridization, Fluorescence MeSH
• Molecular Sequence Data MeSH
• Repetitive Sequences, Nucleic Acid MeSH
• Genes, Plant MeSH
• Base Sequence MeSH
• Sequence Homology, Nucleic Acid MeSH
• Chromosomes, Artificial, Bacterial MeSH
• Computational Biology MeSH
• Secale genetics   MeSH
• Publication type
• Journal Article MeSH
• Research Support, Non-U.S. Gov't MeSH
• Names of Substances
• DNA, Plant MeSH
• Genetic Markers MeSH

BACKGROUND: Flow cytometry facilitates sorting of single chromosomes and chromosome arms which can be used for targeted genome analysis. However, the recovery of microgram amounts of DNA needed for some assays requires sorting of millions of chromosomes which is laborious and time consuming. Yet, many genomic applications such as development of genetic maps or physical mapping do not require large DNA fragments. In such cases time-consuming de novo sorting can be minimized by utilizing whole-genome amplification. RESULTS: Here we report a protocol optimized in barley including amplification of DNA from only ten thousand chromosomes, which can be isolated in less than one hour. Flow-sorted chromosomes were treated with proteinase K and amplified using Phi29 multiple displacement amplification (MDA). Overnight amplification in a 20-microlitre reaction produced 3.7 - 5.7 micrograms DNA with a majority of products between 5 and 30 kb. To determine the purity of sorted fractions and potential amplification bias we used quantitative PCR for specific genes on each chromosome. To extend the analysis to a whole genome level we performed an oligonucleotide pool assay (OPA) for interrogation of 1524 loci, of which 1153 loci had known genetic map positions. Analysis of unamplified genomic DNA of barley cv. Akcent using this OPA resulted in 1426 markers with present calls. Comparison with three replicates of amplified genomic DNA revealed >99% concordance. DNA samples from amplified chromosome 1H and a fraction containing chromosomes 2H - 7H were examined. In addition to loci with known map positions, 349 loci with unknown map positions were included. Based on this analysis 40 new loci were mapped to 1H. CONCLUSION: The results indicate a significant potential of using this approach for physical mapping. Moreover, the study showed that multiple displacement amplification of flow-sorted chromosomes is highly efficient and representative which considerably expands the potential of chromosome flow sorting in plant genomics.

• MeSH
• Chromosomes, Plant genetics   MeSH
• DNA, Plant genetics   MeSH
• Physical Chromosome Mapping methods   MeSH
• Genetic Markers MeSH
• Hordeum genetics   MeSH
• Polymorphism, Single Nucleotide * MeSH
• Polymerase Chain Reaction MeSH
• Flow Cytometry MeSH
• Nucleic Acid Amplification Techniques methods   MeSH
• Publication type
• Journal Article MeSH
• Research Support, Non-U.S. Gov't MeSH
• Names of Substances
• DNA, Plant MeSH
• Genetic Markers MeSH

BACKGROUND: Genomics of rye (Secale cereale L.) is impeded by its large nuclear genome (1C approximately 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. RESULTS: We 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 HindIII and EcoRI 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. CONCLUSION: We 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.

• MeSH
• Chromosomes, Plant genetics   MeSH
• DNA, Plant genetics   isolation & purification   MeSH
• Genome, Plant MeSH
• Genomic Library MeSH
• In Situ Hybridization, Fluorescence MeSH
• Karyotyping MeSH
• Plant Diseases genetics   MeSH
• Flow Cytometry MeSH
• Triticum genetics   MeSH
• Translocation, Genetic MeSH
• Chromosomes, Artificial, Bacterial genetics   MeSH
• Secale genetics   MeSH
• Publication type
• Journal Article MeSH
• Research Support, Non-U.S. Gov't MeSH
• Names of Substances
• DNA, Plant MeSH

The cereals are of enormous importance to mankind. Many of the major cereal species - specifically, wheat, barley, oat, rye, and maize - have large genomes. Early cytogenetics, genome analysis and genetic mapping in the cereals benefited greatly from their large chromosomes, and the allopolyploidy of wheat and oats that has allowed for the development of many precise cytogenetic stocks. In the genomics era, however, large genomes are disadvantageous. Sequencing large and complex genomes is expensive, and the assembly of genome sequence is hampered by a significant content of repetitive DNA and, in allopolyploids, by the presence of homoeologous genomes. Dissection of the genome into its component chromosomes and chromosome arms provides an elegant solution to these problems. In this review we illustrate how this can be achieved by flow cytometric sorting. We describe the development of methods for the preparation of intact chromosome suspensions from the major cereals, and their analysis and sorting using flow cytometry. We explain how difficulties in the discrimination of specific chromosomes and their arms can be overcome by exploiting extant cytogenetic stocks of polyploid wheat and oats, in particular chromosome deletion and alien addition lines. Finally, we discuss some of the applications of flow-sorted chromosomes, and present some examples demonstrating that a chromosome-based approach is advantageous for the analysis of the complex genomes of cereals, and that it can offer significant potential for the delivery of genome sequencing and gene cloning in these crops.

• MeSH
• Chromosomes, Plant genetics   MeSH
• Cytogenetics MeSH
• Genomics methods   MeSH
• Gene Library MeSH
• Edible Grain cytology   genetics   MeSH
• Flow Cytometry methods   MeSH
• Sequence Analysis, DNA MeSH
• Chromosomes, Artificial, Bacterial genetics   MeSH
• Publication type
• Journal Article MeSH
• Research Support, Non-U.S. Gov't MeSH
• Review MeSH

This study evaluates the potential of flow cytometry for chromosome sorting in durum wheat (Triticum turgidum Desf. var. durum, 2n = 4x = 28). Histograms of fluorescence intensity (flow karyotypes) obtained after the analysis of DAPI-stained chromosomes consisted of three peaks. Of these, one represented chromosome 3B, a small peak corresponded to chromosomes 1A and 6A, and a large peak represented the remaining 11 chromosomes. Chromosomes sorted onto microscope slides were identified after fluorescence in situ hybridization (FISH) with probes for GAA microsatellite, pSc119.2, and Afa repeats. Genomic distribution of these sequences was determined for the first time in durum wheat and a molecular karyotype has been developed for this crop. Flow karyotyping in double-ditelosomic lines of durum wheat revealed that the lines facilitated sorting of any arm of the wheat A- and B-genome chromosomes. Compared to hexaploid wheat, flow karyotype of durum wheat is less complex. This property results in better discrimination of telosomes and high purities in sorted fractions, ranging from 90 to 98%. We have demonstrated that large insert libraries can be created from DNA purified using flow cytometry. This study considerably expands the potential of flow cytogenetics for use in wheat genomics and opens the possibility of sequencing the genome of this important crop one chromosome arm at a time.

• MeSH
• Cell Cycle MeSH
• Chromosomes, Plant MeSH
• Chromosomes ultrastructure   MeSH
• DNA, Plant MeSH
• DNA genetics   MeSH
• Physical Chromosome Mapping MeSH
• Genetic Techniques MeSH
• Genome, Plant * MeSH
• Genome MeSH
• In Situ Hybridization, Fluorescence MeSH
• Karyotyping MeSH
• Chromosome Mapping MeSH
• Metaphase MeSH
• Microsatellite Repeats MeSH
• Models, Genetic MeSH
• Ploidies MeSH
• Flow Cytometry MeSH
• Triticum genetics   MeSH
• Cell Separation MeSH
• Publication type
• Journal Article MeSH
• Research Support, Non-U.S. Gov't MeSH
• Names of Substances
• DNA, Plant MeSH
• DNA MeSH

The analysis of the hexaploid wheat genome (Triticum aestivum L., 2 n=6 x=42) is hampered by its large size (16,974 Mb/1C) and presence of three homoeologous genomes (A, B and D). One of the possible strategies is a targeted approach based on subgenomic libraries of large DNA inserts. In this work, we purified by flow cytometry a total of 10(7) of three wheat D-genome chromosomes: 1D, 4D and 6D. Chromosomal DNA was partially digested with HindIII and used to prepare a specific bacterial artificial chromosome (BAC) library. The library (designated as TA-subD) consists of 87,168 clones, with an average insert size of 85 kb. Among these clones, 53% had inserts larger than 100 kb, only 29% of inserts being shorter than 75 kb. The coverage was estimated to be 3.4-fold, giving a 96.5% probability of identifying a clone corresponding to any sequence on the three chromosomes. Specificity for chromosomes 1D, 4D and 6D was confirmed after screening the library pools with single-locus microsatellite markers. The screening indicated that the library was not biased and gave an estimated coverage of sixfold. This is the second report on BAC library construction from flow-sorted plant chromosomes, which confirms that dissecting of the complex wheat genome and preparation of subgenomic BAC libraries is possible. Their availability should facilitate the analysis of wheat genome structure and evolution, development of cytogenetic maps, construction of local physical maps and map-based cloning of agronomically important genes.

• MeSH
• Chromosomes, Plant genetics   MeSH
• Genome, Plant MeSH
• Genomic Library * MeSH
• Chromosome Mapping MeSH
• Polyploidy MeSH
• Triticum genetics   MeSH
• Chromosomes, Artificial, Bacterial MeSH
• Publication type
• Journal Article MeSH
• Research Support, Non-U.S. Gov't MeSH