Digital mapping of bacterial artificial chromosomes by fluorescence in situ hybridization

Extended DNA Fibers for High-Resolution Mapping

DNA fiber-FISH is an easy and simple light microscopic method to map unique and repeat sequences relative to each other at the molecular scale. A standard fluorescence microscope and a DNA labeling kit are sufficient to visualize DNA sequences from any tissue or organ. Despite the enormous progress of high-throughput sequencing technologies, DNA fiber-FISH remains a unique and indispensable tool to detect chromosomal rearrangements and to demonstrate differences between related species at high resolution. We discuss standard and alternative steps to easily prepare extended DNA fibers for high-resolution FISH mapping.

Fluorescence in situ hybridization in plants: recent developments and future applications

Fluorescence in situ hybridization (FISH) was developed more than 30 years ago and has been the most paradigm-changing technique in cytogenetic research. FISH has been used to answer questions related to structure, mutation, and evolution of not only individual chromosomes but also entire genomes. FISH has served as an important tool for chromosome identification in many plant species. This review intends to summarize and discuss key technical development and applications of FISH in plants since 2006. The most significant recent advance of FISH is the development and application of probes based on synthetic oligonucleotides (oligos). Oligos specific to a repetitive DNA sequence, to a specific chromosomal region, or to an entire chromosome can be computationally identified, synthesized in parallel, and fluorescently labeled. Oligo probes designed from conserved DNA sequences from one species can be used among genetically related species, allowing comparative cytogenetic mapping of these species. The advances with synthetic oligo probes will significantly expand the applications of FISH especially in non-model plant species. Recent achievements and future applications of FISH and oligo-FISH are discussed.

Single molecule mtDNA fiber FISH for analyzing numtogenesis

Somatic human cells contain thousands of copies of mitochondrial DNA (mtDNA). In eukaryotes, natural transfer of mtDNA into the nucleus generates nuclear mitochondrial DNA (NUMT) copies. We name this phenomenon as "numtogenesis". Numtogenesis is a well-established evolutionary process reported in various sequenced eukaryotic genomes. We have established a molecular tool to rapidly detect and analyze NUMT insertions in whole genomes. To date, NUMT analyses depend on deep genome sequencing combined with comprehensive computational analyses of the whole genome. This is time consuming, cumbersome and cost prohibitive. Further, most laboratories cannot accomplish such analyses due to limited skills. We report the development of single-molecule mtFIBER FISH (fluorescence in situ hybridization) to study numtogenesis. The development of mtFIBER FISH should aid in establishing a role for numtogenesis in cancers and other human diseases. This novel technique should help distinguish and monitor cancer stages and progression, aid in elucidation of basic mechanisms underlying tumorigenesis and facilitate analyses of processes related to early detection of cancer, screening and/or cancer risk assessment.

In Situ Hybridization in Rice (Oryza sativa)

Fluorescence in situ hybridization (FISH) is widely used in cytogenetics to determine the localization of DNA sequences on target chromosomes, to provide visible information regarding the physical position of DNA sequences, to determine the abundance and distribution of repetitive sequences that comprise a large proportion of genomes, and to determine the relative chromosome positions of multiple sequences in physical mapping. By mapping on extended chromatin fibers, fiber-FISH can be used to determine the structure and organization of genes or DNA sequences with a high resolution (to a few kilobases). The protocols described here will provide procedures of FISH on metaphase chromosomes and extended chromatin fibers of rice (Oryza sativa). © 2016 by John Wiley & Sons, Inc.

Systematic application of DNA fiber-FISH technique in cotton

Fluorescence in situ hybridization on extended DNA (fiber-FISH) is a powerful tool in high-resolution physical mapping. To introduce this technique into cotton, we developed the technique and tested it by deliberately mapping of telomere and 5S rDNA. Results showed that telomere-length ranged from 0.80 kb to 37.86 kb in three species, G. hirsutum, G. herbaceum and G. arboreum. However, most of the telomeres (>91.0%) were below 10 kb. The length of 5S rDNA was revealed as 964 kb in G. herbaceum whereas, in G. arboreum, it was approximately three times longer (3.1 Mb). A fiber-FISH based immunofluorescence method was also described to assay the DNA methylation. Using this technique, we revealed that both telomere and 5S rDNA were methylated at different levels. In addition, we developed a BAC molecule-based fiber-FISH technique. Using this technique, we can precisely map BAC clones on each other and evaluated the size and location of overlapped regions. The development and application of fiber-FISH technique will facilitate high-resolution physical mapping and further directed sequencing projects for cotton.

Preparations of meiotic pachytene chromosomes and extended DNA fibers from cotton suitable for fluorescence in situ hybridization

Fluorescence in situ hybridization (FISH) has become one of the most important techniques applied in plant molecular cytogenetics. However, the application of this technique in cotton has lagged behind because of difficulties in chromosome preparation. The focus of this article was FISH performed not only on cotton pachytene chromosomes, but also on cotton extended DNA fibers. The cotton pollen mother cells (PMCs) instead of buds or anthers were directly digested in enzyme to completely breakdown the cell wall. Before the routine acetic acid treatment, PMCs were incubated in acetic acid and enzyme mixture to remove the cytoplasm and clear the background. The method of ice-cold Carnoy's solution spreading chromosome was adopted instead of nitrogen removed method to avoid chromosomes losing and fully stretch chromosome. With the above-improved steps, the high-quality well-differentiated pachytene chromosomes with clear background were obtained. FISH results demonstrated that a mature protocol of cotton pachytene chromosomes preparation was presented. Intact and no debris cotton nuclei were obtained by chopping from etiolation cotyledons instead of the conventional liquid nitrogen grinding method. After incubating the nuclei with nucleus lysis buffer on slide, the parallel and clear background DNA fibers were acquired along the slide. This method overcomes the twist, accumulation and fracture of DNA fibers compared with other methods. The entire process of DNA fibers preparation requires only 30 min, in contrast, it takes 3 h with routine nitrogen grinding method. The poisonous mercaptoethanol in nucleus lysis buffer is replaced by nonpoisonous dithiothreitol. PVP40 in nucleus isolation buffer is used to prevent oxidation. The probability of success in isolating nuclei for DNA fiber preparation is almost 100% tested with this method in cotton. So a rapid, safe, and efficient method for the preparation of cotton extended DNA fibers suitable for FISH was established.

De novo assembly of potential linear artificial chromosome constructs capped with expansive telomeric repeats

BACKGROUND

Artificial chromosomes (ACs) are a promising next-generation vector for genetic engineering. The most common methods for developing AC constructs are to clone and combine centromeric DNA and telomeric DNA fragments into a single large DNA construct. The AC constructs developed from such methods will contain very short telomeric DNA fragments because telomeric repeats can not be stably maintained in Escherichia coli.

RESULTS

We report a novel approach to assemble AC constructs that are capped with long telomeric DNA. We designed a plasmid vector that can be combined with a bacterial artificial chromosome (BAC) clone containing centromeric DNA sequences from a target plant species. The recombined clone can be used as the centromeric DNA backbone of the AC constructs. We also developed two plasmid vectors containing short arrays of plant telomeric DNA. These vectors can be used to generate expanded arrays of telomeric DNA up to several kilobases. The centromeric DNA backbone can be ligated with the telomeric DNA fragments to generate AC constructs consisting of a large centromeric DNA fragment capped with expansive telomeric DNA at both ends.

CONCLUSIONS

We successfully developed a procedure that circumvents the problem of cloning and maintaining long arrays of telomeric DNA sequences that are not stable in E. coli. Our procedure allows development of AC constructs in different eukaryotic species that are capped with long and designed sizes of telomeric DNA fragments.

Divergence in centromere structure distinguishes related genomes in Coix lacryma-jobi and its wild relative

Knowledge about the composition and structure of centromeres is critical for understanding how centromeres perform their functional roles. Here, we report the sequences of one centromere-associated bacterial artificial chromosome clone from a Coix lacryma-jobi library. Two Ty3/gypsy-class retrotransposons, centromeric retrotransposon of C. lacryma-jobi (CRC) and peri-centromeric retrotransposon of C. lacryma-jobi, and a (peri)centromere-specific tandem repeat with a unit length of 153 bp were identified. The CRC is highly homologous to centromere-specific retrotransposons reported in grass species. An 80-bp DNA region in the 153-bp satellite repeat was found to be conserved to centromeric satellite repeats from maize, rice, and pearl millet. Fluorescence in situ hybridization showed that the three repetitive sequences were located in (peri-)centromeric regions of both C. lacryma-jobi and Coix aquatica. However, the 153-bp satellite repeat was only detected on 20 out of the 30 chromosomes in C. aquatica. Immunostaining with an antibody against rice CENH3 indicates that the 153-bp satellite repeat and CRC might be both the major components for functional centromeres, but not all the 153-bp satellite repeats or CRC sequences are associated with CENH3. The evolution of centromeric repeats of C. lacryma-jobi during the polyploidization was discussed.

Current status and the future of fluorescence in situ hybridization (FISH) in plant genome research

Fluorescence in situ hybridization (FISH), which allows direct mapping of DNA sequences on chromosomes, has become the most important technique in plant molecular cytogenetics research. Repetitive DNA sequence can generate unique FISH patterns on individual chromosomes for karyotyping and phylogenetic analysis. FISH on meiotic pachytene chromosomes coupled with digital imaging systems has become an efficient method to develop physical maps in plant species. FISH on extended DNA fibers provides a high-resolution mapping approach to analyze large DNA molecules and to characterize large genomic loci. FISH-based physical mapping provides a valuable complementary approach in genome sequencing and map-based cloning research. We expect that FISH will continue to play an important role in relating DNA sequence information to chromosome biology. FISH coupled with immunoassays will be increasingly used to study features of chromatin at the cytological level that control expression and regulation of genes.

High-resolution physical mapping of the secalin-1 locus of rye on extended DNA fibers

High-resolution mapping of secalin-1 (Sec-1) locus has been performed by fluorescence in situ hybridization to extended DNA fibers of rye (Secale cereale, 2n = 14), employing DNA probes of lambda phage clones containing the omega-secalin gene. The fluorescent signals to rye extended DNA fibers revealed continuous strings of 45 microm, corresponding to the size of 147 kb DNA. To determine the copy number of Sec-1 locus on DNA fibers, a 1.2-kb fragment including the entire coding region of the omega-secalin gene and a 1.0-kb fragment of the promoter region were amplified by PCR as probes for another fiber FISH. The physical position of these sequences was visualized as alternating fluorescent spots by multicolor in situ hybridization. Alternating signals of two DNA probes reflected the tandem repeated organization of the Sec-1 locus having 15 copies of the gene. The present findings based on fiber FISH analysis support the contention that the omega-secalin genes are arranged in a head-to-tail fashion separated by 8 kb of spacer sequences with a total length of 145 kb.

Pericentromeric regions of soybean (Glycine max L. Merr.) chromosomes consist of retroelements and tandemly repeated DNA and are structurally and evolutionarily labile

Little is known about the physical makeup of heterochromatin in the soybean (Glycine max L. Merr.) genome. Using DNA sequencing and molecular cytogenetics, an initial analysis of the repetitive fraction of the soybean genome is presented. BAC 076J21, derived from linkage group L, has sequences conserved in the pericentromeric heterochromatin of all 20 chromosomes. FISH analysis of this BAC and three subclones on pachytene chromosomes revealed relatively strict partitioning of the heterochromatic and euchromatic regions. Sequence analysis showed that this BAC consists primarily of repetitive sequences such as a 102-bp tandem repeat with sequence identity to a previously characterized approximately 120-bp repeat (STR120). Fragments of Calypso-like retroelements, a recently inserted SIRE1 element, and a SIRE1 solo LTR were present within this BAC. Some of these sequences are methylated and are not conserved outside of G. max and G. soja, a close relative of soybean, except for STR102, which hybridized to a restriction fragment from G. latifolia. These data present a picture of the repetitive fraction of the soybean genome that is highly concentrated in the pericentromeric regions, consisting of rapidly evolving tandem repeats with interspersed retroelements.

Cytogenetic tools for Arabidopsis thaliana

Although the first description of chromosomes of Arabidopsis dates as far back as 1907, little attention was paid to its cytogenetics for a long time. The spectacular interest in chromosome research for this species that now is the model plant species by excellence came with the introduction of molecular cytogenetical research including FISH technology, genome sequence data and immunodetection of chromatin proteins. In this paper, we present an overview of the most important cytogenetic tools that were developed for Arabidopsis in recent decades. It shows the power of meiosis for studying synaptic mutants and FISH technology, and the development of numerical and structural chromosome mutant series like trisomics, telotrisomics and translocations for assigning linkage groups to chromosomes. Its small genome and chromosome size and relatively simple organization of heterochromatin have been the key to a successful characterization of the molecular organization of repetitive and single copy sequences on the chromosomes, both in metaphase and pachytene complements, but also in interphase nuclei and extended DNA fibres. Finally, Arabidopsis is the first plant species in which a heterochromatin knob could be analysed in full detail and in which chromosome painting with BAC clones covering whole chromosome arms could be established. All these achievements are probably only the very first steps in a promising new era in plant cytogenetics and chromatin research yet to come.

Resolution of fluorescence in-situ hybridization mapping on rice mitotic prometaphase chromosomes, meiotic pachytene chromosomes and extended DNA fibers

Fluorescence in-situ hybridization (FISH) is a quick and affordable approach to map DNA sequences to specific chromosomal regions. Although FISH is one of the most important physical mapping techniques, research on the resolution of FISH on different cytological targets is scarce in plants. In this study, we report the resolution of FISH mapping on mitotic prometaphase chromosomes, meiotic pachytene chromosomes and extended DNA fibers in rice. A majority of the FISH signals derived from bacterial artificial chromosome (BAC) clones separated by approximately 1 Mb of DNA cannot be resolved on mitotic prometaphase chromosomes. In contrast, the relative positions of closely linked or even partially overlapping BAC clones can be resolved on a euchromatic region of rice chromosome 10 at the early pachytene stage. The resolution of pachytene FISH is dependent on early or late pachytene stages and also on the location of the DNA probes in the euchromatic or heterochromatic regions. We calibrated the fiber-FISH technique in rice using seven sequenced BAC clones. The average DNA extension was 3.21 kb/microm among the seven BAC clones. Fiber-FISH results derived from a BAC contig that spanned 1 Mb DNA matched remarkably to the sequencing data, demonstrating the high resolution of this technique in cytological mapping.

Molecular and cytological analyses of large tracks of centromeric DNA reveal the structure and evolutionary dynamics of maize centromeres

We sequenced two maize bacterial artificial chromosome (BAC) clones anchored by the centromere-specific satellite repeat CentC. The two BACs, consisting of approximately 200 kb of cytologically defined centromeric DNA, are composed exclusively of satellite sequences and retrotransposons that can be classified as centromere specific or noncentromere specific on the basis of their distribution in the maize genome. Sequence analysis suggests that the original maize sequences were composed of CentC arrays that were expanded by retrotransposon invasions. Seven centromere-specific retrotransposons of maize (CRM) were found in BAC 16H10. The CRM elements inserted randomly into either CentC monomers or other retrotransposons. Sequence comparisons of the long terminal repeats (LTRs) of individual CRM elements indicated that these elements transposed within the last 1.22 million years. We observed that all of the previously reported centromere-specific retrotransposons in rice and barley, which belong to the same family as the CRM elements, also recently transposed with the oldest element having transposed approximately 3.8 million years ago. Highly conserved sequence motifs were found in the LTRs of the centromere-specific retrotransposons in the grass species, suggesting that the LTRs may be important for the centromere specificity of this retrotransposon family.

Physical mapping of plasmid and cosmid clones in filamentous fungi by fiber-FISH

Fluorescence in situ hybridization to extended DNA fibers (fiber-FISH) serves as a powerful tool for direct physical mapping in plants and animals. Here, we show that fiber-FISH is useful for contig mapping as well as for estimating the physical distance between genetic markers in fungi. A five-cosmid contig from a chromosome of Nectria haematococca and four cloned genetic markers from a linkage map of Cochliobolus heterostrophus were chosen as models for the application of this technology. In N. haematococca, overlapping and non-overlapping clones were visually mapped on individual DNA fibers, confirming the results from conventional physical mapping perfectly. Fiber-FISH concomitantly indicated the gap size or the extent of overlap between two clones. In C. heterostrophus, the physical distance between the two pairs of genetic markers could be estimated from the microscopic measurements of the intervals. Chromosomal DNA isolated from a pulsed field gel was suitable for preparing the DNA fibers.

BAC FISH analysis in Allium cepa

Onion (Allium cepa L.; 1C=15,000 Mb) is an agriculturally important plant. The genome of onion has been extensively studied at the conventional cytogenetic level, but molecular analyses have lagged behind due to its large genome size. To overcome this bottleneck, a partial bacterial artificial chromosome (BAC) library of onion was constructed. The average insert size of the BAC library was about 100 kb. A total of 48,000 clones, corresponding to 0.32 genome equivalent, were obtained. Fluorescent in situ hybridization (FISH) screening resulted in identification of BAC clones localized on centromeric, telomeric, or several limited interstitial chromosomal regions, although most of the clones hybridized with entire chromosomes. The partial BAC library proved to be a useful resource for molecular cytogenetic studies of onion, and should be useful for further mapping and sequencing studies of important genes of this plant. BAC FISH screening is a powerful method for identification of molecular cytogenetic markers in large-genome plants.

DNA fiber mapping techniques for the assembly of high-resolution physical maps

High-resolution physical maps are indispensable for directed sequencing projects or the finishing stages of shotgun sequencing projects. These maps are also critical for the positional cloning of disease genes and genetic elements that regulate gene expression. Typically, physical maps are based on ordered sets of large insert DNA clones from cosmid, P1/PAC/BAC, or yeast artificial chromosome (YAC) libraries. Recent technical developments provide detailed information about overlaps or gaps between clones and precisely locate the position of sequence tagged sites or expressed sequences, and thus support efforts to determine the complete sequence of the human genome and model organisms. Assembly of physical maps is greatly facilitated by hybridization of non-isotopically labeled DNA probes onto DNA molecules that were released from interphase cell nuclei or recombinant DNA clones, stretched to some extent and then immobilized on a solid support. The bound DNA, collectively called "DNA fibers," may consist of single DNA molecules in some experiments or bundles of chromatin fibers in others. Once released from the interphase nuclei, the DNA fibers become more accessible to probes and detection reagents. Hybridization efficiency is therefore increased, allowing the detection of DNA targets as small as a few hundred base pairs. This review summarizes different approaches to DNA fiber mapping and discusses the detection sensitivity and mapping accuracy as well as recent achievements in mapping expressed sequence tags and DNA replication sites.

Instability of bacterial artificial chromosome (BAC) clones containing tandemly repeated DNA sequences

The cloning and propagation of large DNA fragments as bacterial artificial chromosomes (BACs) has become a valuable technique in genome research. BAC clones are highly stable in the host, Escherichia coli, a major advantage over yeast artificial chromosomes (YACs) in which recombination-induced instability is a major drawback. Here we report that BAC clones containing tandemly repeated DNA elements are not stable and can undergo drastic deletions during routine library maintenance and DNA preparation. Instability was observed in three BAC clones from sorghum, rice, and potato, each containing distinct tandem repeats. As many as 46% and 74% of the single colonies derived from a rice BAC clone containing 5S ribosomal RNA genes had insert deletions after 24 and 120 h of growth, respectively. We also demonstrated that BAC insert rearrangement can occur in the early stage of library construction and duplication. Thus, a minimum growth approach may not avoid the instability problem of such clones. The impact of BAC instability on genome research is discussed.Key words: repetitive DNA, large insert DNA library, genome research.

Complex mtDNA constitutes an approximate 620-kb insertion on Arabidopsis thaliana chromosome 2: implication of potential sequencing errors caused by large-unit repeats

Previously conducted sequence analysis of Arabidopsis thaliana (ecotype Columbia-0) reported an insertion of 270-kb mtDNA into the pericentric region on the short arm of chromosome 2. DNA fiber-based fluorescence in situ hybridization analyses reveal that the mtDNA insert is 618 +/- 42 kb, approximately 2.3 times greater than that determined by contig assembly and sequencing analysis. Portions of the mitochondrial genome previously believed to be absent were identified within the insert. Sections of the mtDNA are repeated throughout the insert. The cytological data illustrate that DNA contig assembly by using bacterial artificial chromosomes tends to produce a minimal clone path by skipping over duplicated regions, thereby resulting in sequencing errors. We demonstrate that fiber-fluorescence in situ hybridization is a powerful technique to analyze large repetitive regions in the higher eukaryotic genomes and is a valuable complement to ongoing large genome sequencing projects.

High-resolution pachytene chromosome mapping of bacterial artificial chromosomes anchored by genetic markers reveals the centromere location and the distribution of genetic recombination along chromosome 10 of rice

Large-scale physical mapping has been a major challenge for plant geneticists due to the lack of techniques that are widely affordable and can be applied to different species. Here we present a physical map of rice chromosome 10 developed by fluorescence in situ hybridization (FISH) mapping of bacterial artificial chromosome (BAC) clones on meiotic pachytene chromosomes. This physical map is fully integrated with a genetic linkage map of rice chromosome 10 because each BAC clone is anchored by a genetically mapped restriction fragment length polymorphism marker. The pachytene chromosome-based FISH mapping shows a superior resolving power compared to the somatic metaphase chromosome-based methods. The telomere-centromere orientation of DNA clones separated by 40 kb can be resolved on early pachytene chromosomes. Genetic recombination is generally evenly distributed along rice chromosome 10. However, the highly heterochromatic short arm shows a lower recombination frequency than the largely euchromatic long arm. Suppression of recombination was found in the centromeric region, but the affected region is far smaller than those reported in wheat and barley. Our FISH mapping effort also revealed the precise genetic position of the centromere on chromosome 10.

Comparative fluorescence in situ hybridization mapping of a 431-kb Arabidopsis thaliana bacterial artificial chromosome contig reveals the role of chromosomal duplications in the expansion of the Brassica rapa genome

Comparative genome studies are important contributors to our understanding of genome evolution. Most comparative genome studies in plants have been based on genetic mapping of homologous DNA loci in different genomes. Large-scale comparative physical mapping has been hindered by the lack of efficient and affordable techniques. We report here the adaptation of fluorescence in situ hybridization (FISH) techniques for comparative physical mapping between Arabidopsis thaliana and Brassica rapa. A set of six bacterial artificial chromosomes (BACs) representing a 431-kb contiguous region of chromosome 2 of A. thaliana was mapped on both chromosomes and DNA fibers of B. rapa. This DNA fragment has a single location in the A. thaliana genome, but hybridized to four to six B. rapa chromosomes, indicating multiple duplications in the B. rapa genome. The sizes of the fiber-FISH signals from the same BACs were not longer in B. rapa than those in A. thaliana, suggesting that this genomic region is duplicated but not expanded in the B. rapa genome. The comparative fiber-FISH mapping results support that chromosomal duplications, rather than regional expansion due to accumulation of repetitive sequences in the intergenic regions, played the major role in the evolution of the B. rapa genome.