BAC-FISH in wheat identifies chromosome landmarks consisting of different types of transposable elements

Fluorescence in situ hybridization (FISH) has been widely used in the physical mapping of genes and chromosome landmarks in plants and animals. Bacterial artificial chromosomes (BACs) contain large inserts making them amenable for FISH mapping. We used BAC-FISH to study genome organization and evolution in hexaploid wheat and its relatives. We selected 56 restriction fragment length polymorphism (RFLP) locus-specific BAC clones from libraries of Aegilops tauschii (the D-genome donor of hexaploid wheat) and A-genome diploid Triticum monococcum. Different types of repetitive sequences were identified using BAC-FISH. Two BAC clones gave FISH patterns similar to the repetitive DNA family pSc119; one BAC clone gave a FISH pattern similar to the repetitive DNA family pAs1. In addition, we identified several novel classes of repetitive sequences: one BAC clone hybridized to the centromeric regions of wheat and other cereal species, except rice; one BAC clone hybridized to all subtelomeric chromosome regions in wheat, rye, barley and oat; one BAC clone contained a localized tandem repeat and hybridized to five D-genome chromosome pairs in wheat; and four BAC clones hybridized only to a proximal region in the long arm of chromosome 4A of hexaploid wheat. These repeats are valuable markers for defined chromosome regions and can also be used for chromosome identification. Sequencing results revealed that all these repeats are transposable elements (TEs), indicating the important role of TEs, especially retrotransposons, in genome evolution of wheat.Communicated by P.B. Moens     

A Ty3/gypsy retrotransposon-like sequence localizes to the centromeric regions of cereal chromosomes

A 745 bp sequence (pSau3A9) located at the centromeres of several cereal species was isolated from a sorghum BAC library by Jiang et al. (1996, Proc. Natl Acad. Sci. USA, 93, 14210-14213). We have amplified a partially homologous 809 bp sequence from barely genomic DNA by PCR and localized it to the centromeres of barley, wheat and rye chromosomes by fluorescent in situ hybridization (FISH). Sequence analysis showed this barley homolog of pSau3A9 to have high similarity to the integrase region of the polyprotein gene of Ty3/gypsy group retrotransposons. Using this integrase sequence as a probe, several clones were isolated from a lambda library constructed of genomic barley DNA. One of the lambda clones contained coding regions for all five catalytic sites characteristic of the retrotransposon polyprotein. Two direct repeats flanking the polyprotein gene are homologous to the cereal centromeric sequence described by Aragón-Alcaide et al. (1996, Chromosoma, 105, 261-268) and may represent all or part of the long-terminal repeats (LTRs). Different plasmid subclones containing various regions of the lambda clone were used in FISH to show that the entire polyprotein gene and upstream flanking sequences, including the presumed LTR, are present at barley centromeres. The preferential (or exclusive) localization of an apparently complete retroelement within the centromeric regions of several cereal species raises interesting questions about its role in karyotype evolution and centromere function.     

Simultaneous painting of three genomes in hexaploid wheat by BAC-FISH.

Fluorescence in situ hybridization (FISH) is widely used in the physical mapping of genes and chromosome landmarks in plants and animals. Bacterial artificial chromosomes (BACs) contain large inserts, making them amenable for FISH mapping. In our BAC-FISH experiments, we selected 56 restriction fragment length polymorphism (RFLP)-locus-specific BAC clones from the libraries of Triticum monococcum and Aegilops tauschii, which are the A- and D-genome donors of wheat (Triticum aestivum, 2n = 6x = 42), respectively. The BAC clone 676D4 from the T. monococcum library contains a dispersed repeat that preferentially hybridizes to A-genome chromosomes, and two BAC clones, 9I10 and 9M13, from the Ae. tauschii library contain a dispersed repeat that preferentially hybridizes to the D-genome chromosomes. These repeats are useful in simultaneously discriminating the three different genomes in hexaploid wheat, and in identifying intergenomic translocations in wheat or between wheat and alien chromosomes. Sequencing results show that both of these repeats are transposable elements, indicating the importance of transposable elements, especially retrotransposons, in the genome evolution of wheat.     

Inter- and intra-genomic transfer of small chromosomal segments in wheat-rye allopolyploids

Newly synthesized wheat-rye allopolyploids, derived from Triticum aestivum Mianyang11 × S. cereale Kustro, were investigated by sequential fluorescent in situ hybridization (FISH) and genomic in situ hybridization (GISH) using rye tandem repeat pSc200 and rye genomic DNA as probes, respectively, over the first, second and third allopolyploid generations. FISH signals of pSc200 could be observed at both telomeres/subtelomeres of all 14 chromosomes of the parental rye. In the first allopolyploid generation, there were ten rye chromosomes bearing FISH signals at both telomeres/subtelomeres and four rye chromosomes bearing FISH signals at only one telomere/subtelomere. However, in the second and the third allopolyploid generations, there were 12 rye chromosomes bearing FISH signals at both telomeres/subtelomeres and 2 rye chromosomes bearing FISH signals at only one telomere/subtelomere. Rye telomeric segments were transferred to the centromeric region of wheat chromosomes in some cells and small segments derived from non-telomeric regions of rye chromosome were transferred to the telomeric region of wheat chromosomes in some other cells. These observations indicated that the rye telomeric/subtelomeric region was unstable in newly synthesized wheat-rye allopolyploids and allopolyploidization was accompanied by rapid inter/intra-genomic exchange. The inter-genomic exchange may have occurred in somatic cells.     

Identification of Bilby, a diverged centromeric Ty1-copia retrotransposon family from cereal rye (Secale cereale L.).

A diminutive rye chromosome (midget) in wheat was used as a model system to isolate a highly reiterated centromeric sequence from a rye chromosome. Fluorescence in situ hybridization (FISH) shows this sequence localized within all rye centromeres and no signal was detected on wheat chromosomes. DNA sequencing of the repetitive element has revealed the presence of some catalytic domains and signature motifs typical of retrotransposon genes and has been called the Bilby family, representing a diverged family of retrotransposon-like elements. Extensive DNA database searching revealed some sequence similarity to centromeric retrotransposons from wheat, barley, and centromeric repetitive sequences from rice. Very low levels of signal were observed when Bilby was used as a probe against barley, and no signal was detected with rice DNA during Southern hybridization. The abundance of Bilby in rye indicates that this family may have diverged from other distantly related centromeric retrotransposons or incorporated in the centromere but rapidly evolved in rye during speciation. The isolation of a rye retrotransposon also allowed the analysis of centromeric breakpoints in wheat-rye translocation lines. A quantitative analysis shows that the breakpoint in IDS.1RL and 1DL.1RS and recombinant lines containing proximal rye chromatin have a portion of the rye centromere that may contribute to the normal function of the centromeric region.     

Identification and Preliminary Analysis of Several Centromere-associated Bacterial Artificial Chromosome Clones from a Diploid Wheat Library

Although the centromeres of some plants have been investlgated prevlously, our knowledge of the wheat centromere Is still very llmlted. To understand the structure and functlon of the wheat centromere, we used two centromeric repeats （RCS1 and CCS1-5ab） to obtain some centromere-assoclated bacterial artificial chromosome （BAC） clones in 32 RCS1-related BAC clones that had been screened out from a diploid wheat （Triticum boeoticum Boiss.; 2n=2x=14） BAC library. Southern hybridization results indicated that, of the 32 candidates, there were 28 RCS1-positive clones. Based on gel blot patterns, the frequency of RCS1 was approximately one copy every 69.4 kb in these 28 RCS1-positive BAC clones. More bands were detected when the same filter was probed with CCS1-5ab. Furthermore, the CCS1 bands covered all the bands detected by RCS1, which suggests that some CCS1 repeats were distributed together with RCS1. The frequency of CCS1 families was once every 35.8 kb, nearly twice that of RCS1. Fluorescence in situ hybridization （FISH） analysis Indicated that the five BAC clones containing RCS1 and CCS1 sequences all detected signals at the centromerlc regions in hexaplold wheat, but the signal intensities on the A-genome chromosomes were stronger than those on the B- and/or Dgenome chromosomes. The FISH analysis among nine Triticeae cereals indicated that there were A-genomespecific （or rich） sequences dispersing on chromosome arms in the BAC clone TbBACS. In addition, at the interphase cells, the centromeres of diploid species usually clustered at one pole and formed a ring-like allocation In the period before metaphase.     

FISH landmarks for barley chromosomes (Hordeum vulgare L.).

Barley metaphase chromosomes (2n = 14) can be identified by fluorescence in situ hybridization (FISH) and digital imaging microscopy using heterologous 18S rDNA and 5S rDNA probe sequences. When these sequences are used together, FISH landmark signals were seen so that all 7 chromosomes were uniquely identified and unambiguously oriented. The chromosomal location of the landmark signals was determined by FISH to a barley trisomic series using the 18S and 5S probes labeled with different fluorophores. The utility of these FISH landmarks for barley physical mapping was also demonstrated when an Amy-2 cDNA clone and a BAC clone were hybridized with the FISH landmark probes.     

Random BAC FISH of monocot plants reveals differential distribution of repetitive DNA elements in small and large chromosome species

BAC FISH (fluorescence in situ hybridization using bacterial artificial chromosome probes) is a useful cytogenetic technique for physical mapping, chromosome marker screening, and comparative genomics. As a large genomic fragment with repetitive sequences is inserted in each BAC clone, random BAC FISH without adding competitive DNA can unveil complex chromosome organization of the repetitive elements in plants. Here we performed the comparative analysis of the random BAC FISH in monocot plants including species having small chromosomes (rice and asparagus) and those having large chromosomes (hexaploid wheat, onion, and spider lily) in order to understand a whole view of the repetitive element organization in Poales and Asparagales monocots. More unique and less dense dispersed signals of BAC FISH were observed in species with smaller chromosomes in both the Poales and Asparagales species. In the case of large-chromosome species, 75-85% of the BAC clones were detected as dispersed repetitive FISH signals along entire chromosomes. The BAC FISH of Lycoris did not even show localized repetitive patterns (e.g., centromeric localization) of signals.     

Origin and molecular structure of a midget chromosome in a common wheat carrying rye cytoplasm

The origin and molecular structure of the midget chromosome that is retained in a common wheat with rye cytoplasm, were studied by using fluorescent in situ hybridization (FISH). FISH with biotinylated rye genomic DNA as a probe clearly showed that the midget chromosome had originated from certain part(s) of rye chromosome(s). The midget chromosome did not possess sequences similar to wheat rDNA nor to a rye telomeric sequence with a 350 bp repeat unit. However, another repetitive sequence (120 bp family) of rye was found to occur at one end of the midget chromosome. The telomeric repeat sequences from Arabidopsis thaliana cross-hybridized to both ends of the midget chromosome as well as to wheat chromosomes. From the results obtained in this and previous studies, it is assumed that the midget chromosome originated from part of a rye chromosome, most likely the centromeric region of chromosome 1R, and that the telomeric sequences were synthesized de novo.by R. Appels     

The genomic composition of Tricepiro, a synthetic forage crop.

Chromosome in situ hybridization (FISH and GISH) is a powerful tool for determining the chromosomal location of specific sequences and for analysing genome organization and evolution. Tricepiro (2n = 6x = 42) is a synthetic cereal obtained by G. Covas in Argentina (1972), which crosses hexaploid triticale (2n = 6x = 42) and octoploid Trigopiro (2n = 8x = 56). Several years of breeding produced a forage crop with valuable characteristics from Secale, Triticum, and Thinopyrum. The aim of this work is to analyse the real genomic constitution of this important synthetic crop. In situ hybridization using total DNA of Secale, Triticum, and Thinopyrum as a probe (GISH) labelled with biotin and (or) digoxigenin showed that tricepiro is composed of 14 rye chromosomes and 28 wheat chromosomes. Small zones of introgression of Thinopyrum on wheat chromosomes were detected. The FISH using the rye repetitive DNA probe pSc 119.2 labelled with biotin let us characterize the seven pairs of rye chromosomes. Moreover, several wheat chromosomes belonging to A and B genomes were distinguished. Therefore, tricepiro is a synthetic hexaploid (2n = 6x = 42) being AABBRR in its genomic composition, with zones of introgression of Thinopyrum in the A genome of wheat.     

Identification of Alien Chromatin and Ribosomal DNA in Wheat by in Situ Hybridization

In situ hybridization was carried out to somatic cells of hexaploid Triticale “Badger”, lB/IR translocation line “Ning 8026” and IR(ID) substitution line “84056-1-36-1” using biotin-labelled total rye genomic DNA and wheat rDNA as probes, the results were as follows: 1. The probe containing the total genomic DNA from rye hybridized to the entire length of all rye chromosomes, as a result of the formation of a brown precipitate over the sites of hybridization, the rye chromosomes could be distinguished from wheat chromosomes counterstained by Wright’s solution, the distinguishable appearance of the wheat and rye chromosomes resulted in an efficient method of detecting rye chromosome or segments in wheat. 2. When the probe PTA 71 containing wheat ribosomal DNA was used to hybridize to somatic chromosomes of "Badger" and “84056-1-36-1”, six signals in “Badger” and eight in “84056-1-36-1” were observed on lB, 6B, 1R and SD, among which lB and 6B showed large in situ signals corresponding to many copies of the genes. 3. The expression behavior of wheat rDNA was found in interphase cells by in situ hybridization.     

Painting the rye genome with genome-specific sequences

We used rye-specific repetitive DNA sequences in fluorescence in situ hybridization (FISH) to paint the rye genome and to identify rye DNA in a wheat background. A 592 bp fragment from the rye-specific dispersed repetitive family R173 (named UCM600) was cloned and used as a FISH probe. UCM600 is dispersed over the seven rye chromosomes, being absent from the pericentromeric and subtelomeric regions. A similar pattern of distribution was also observed on the rye B chromosomes, but with weaker signals. The FISH hybridization patterns using UCM600 as probe were comparable with those obtained with the genomic in situ hybridization (GISH) procedure. There were, however, sharper signals and less background with FISH. UCM600 was combined with the rye-specific sequences Bilby and pSc200 to obtain a more complete painting. With these probes, the rye chromosomes were labeled with distinctive patterns; thus, allowing the rye cultivar 'Imperial' to be karyotyped. It was also possible to distinguish rye chromosomes in triticale and alien rye chromatin in wheat-rye addition and translocation lines. The distribution of UCM600 was similar in cultivated rye and in the wild Secale species Secale vavilovii Grossh., Secale sylvestre Host, and Secale africanum Stapf. Thus, UCM600 can be used to detect Secale DNA introgressed from wild species in a wheat background.     

Fluorescent labeling of plant chromosomes in suspension by FISH

By optimizing the concentration and time of treatment with hydroxyurea (HU), a DNA synthesis inhibitor, and trifluralin, a microtubule inhibitor, a highly effective (over 60%) cell cycle synchronization method for rye and barley meristem cells was developed. Chromosome suspensions containing highly purified and morphologically intact rye and barley chromosomes were prepared from the meristems of their root tips by homogenization. Digoxigenin-labeled 5S rDNA was used as a probe in FISH for the rye chromosomes in the suspension, and biotin-labeled 17S rDNA and centromeric DNA were used in FISH for the rye and barley chromosome suspensions, respectively. Bright signals were detected at the specific regions of interest on the chromosomes. The results indicate that the method developed in this study is useful for selection and sorting of chromosomes that are not distinguishable by other means, using specific fluorescent labeling by FISH of the chromosomes in suspension.     

Molecular Cytogenetic Identification of Triticum aestivum-Secale cereale Substitution and Addition Lines

Two substitution lines, designated as 930498 and 930483, and one addition line, designated as 930029, via Fo immature embryo culture of Triticum aestivum x octoploid triticale ( x Triti-cosecale Wittmack) were identified. Fluorescence in situ hybridization (FISH) using total genomic DNA of rye ( Secale cereale L. ) as probe corroborated the existence of rye chromosomes, further confirmed through chromosome paring at meiotic metaphase 1, C-banding and glutenin SDS- PAGE. The results demonstrated that the two substitution lines are ID/IR, and the addition line is also IR addition. Rye chromosomes that are distinct to the red-colored wheat chromosomes appear yellow-green at mitotic metaphase after FISH.     

Conversion of a RAPD-generated PCR product,containing a novel dispersed repetitive element,into a fast and robust assay for the presence of rye chromatin in wheat

Bulk segregant analysis was used to obtain a random amplified polymorphic DNA (RAPD) marker specific for the rye chromosome arm of the 1BL.1RS translocation, which is common in many high-yielding bread wheat varieties. The RAPD-generated band was cloned and end-sequenced to allow the construction of a pair of oligonucleotide primers that PCR-amplify a DNA sequence only in the presence of rye chromatin. The amplified sequence shares a low level of homology to wheat and barley, as judged by the low strength of hybridization of the sequence to restriction digests of genomic DNA. Genetic analysis showed that the amplified sequence was present on every rye chromosome and not restricted to either the proximal or distal part of the 1RS arm. In situ hybridization studies using the amplified product as probe also showed that the sequence was dispersed throughout the rye genome, but that the copy number was greatly reduced, or the sequence was absent at both the centromere and the major sites of heterochromatin (telomere and nucleolar organizing region). The probe, using both Southern blot and in situ hybridization analyses, hybridized at a low level to wheat chromosomes, and no hybridizing restriction fragments could be located to individual wheat chromosomes from the restriction fragment length polymorphism (RFLP) profiles of wheat aneuploids. The disomic addition lines of rye chromosomes to wheat shared a similar RFLP profile to one another. The amplified sequence does not contain the RIS 1 sequence and therefore represents an as yet undescribed dispersed repetitive sequence. The specificity of the amplification primers is such that they will provide a useful tool for the rapid detection of rye chromatin in a wheat background. Additionally, the relatively low level of cross-hybridization to wheat chromatin should allow the sequence to be used to analyse the organization of rye euchromatin in interphase nuclei of wheat lines carrying chromosomes, chromosome segments or whole genomes derived from rye.     

St基因组中的CRW同源序列在偃麦草中的FISH分析

为了确定十倍体长穗偃麦草(Thinopyrum ponticum, Liu & Wang)和六倍体中间偃麦草(Th. intermedium, [Host] Barkworth & Dewey )的基因组组成, 根据野生一粒小麦(Triticum boeoticum)着丝粒自主型反转录转座子(CRW)序列设计特异引物, 以二倍体拟鹅观草(Pseudoroegneria spicata, Á Löve )基因组 DNA为模板进行PCR扩增, 筛选到一条St基因组着丝粒区相对特异反转录转座子的部分序列pStC1, 长度为1.755 kb (GenBank登录号: FJ952565), 其中有800 bp与小麦着丝粒反转录转座子(CRW)的LTR区高度同源, 另有小部分片段与其外壳蛋白编码基因(gag)部分同源, 并且包含一段富含AGCAAC碱基的重复序列。以pStC1为探针, 对十倍体长穗偃麦草的FISH检测结果显示其基因组组成为两个St组3个E组(St₁St₂E^eE^bE^x); pStC1与中间偃麦草杂交时, 不仅St基因组上有强烈的荧光信号, 而且E基因组一些染色体的近着丝粒区域也有杂交信号, 说明偃麦草属异源多倍体物种在其形成及进化过程中St与E基因组之间在着丝粒及近着丝粒相关区域可能存在协同进化。     

FISH physical mapping with barley BAC clones

Fluorescence in situ hybridization (FISH) is a useful technique for physical mapping of genes, markers, and other single- or low-copy sequences. Since clones containing less than 10 kb of single-copy DNA do not reliably produce detectable signals with current FISH techniques in plants, a bacterial artificial chromosome (BAC) partial library of barley was constructed and a FISH protocol for detecting unique sequences in barley BAC clones was developed. The library has a 95 kb average barley insert, representing about 20% of a barley genome. Two BAC clones containing hordein gene sequences were identified and partially characterized. FISH using these two BAC clones as probes showed specific hybridization signals near the end of the short arm of one pair of chromosomes. Restriction digests of these two BAC clones were compared with restriction patterns of genomic DNA; all fragments contained in the BAC clones corresponded to bands present in the genomic DNA, and the two BAC clones were not identical. The barley inserts contained in these two BAC clones were faithful copies of the genomic DNA. FISH with four BAC clones with inserts varying from 20 to 150 kb, showed distinct signals on paired chromatids. Physical mapping of single- or low-copy sequences in BAC clones by FISH will help to correlate the genetic and physical maps. FISH with BAC clones also provide an additional approach for saturating regions of interest with markers and for constructing contigs spanning those regions.     

Cloning of DNA sequences localized on proximal fluorescent chromosome bands by microdissection in Pinus densiflora Sieb. & Zucc.

Japanese red pine, Pinus densiflora, has 2n=24 chromosomes, of which most carry chromomycin A3 (CMA) and 4',6-diamidino-2-phenylindole (DAPI) bands at their centromere-proximal regions. It was proposed that these regions contain highly repetitive DNA. The DNA localized in the proximal fluorescent bands was isolated and characterized. In P. densiflora, centromeric and neighboring segments of the somatic chromosomes were dissected with a manual micromanipulator. The centromeric DNA was amplified from the DNA contained in dissected centromeric segments by degenerate oligonucleotide primed-polymerase chain reaction (DOP-PCR) and a cloned DNA library was constructed. Thirty-one clones carrying highly repetitive DNA were selected by colony hybridization using Cot-1 DNA from this species as a probe, and their chromosomal localization was determined by fluorescent in situ hybridization (FISH). Clone PDCD501 was localized to the proximal CMA band of 20 chromosomes. This clone contained tandem repeats, comprising a 27 bp repeat unit, which was sufficient to provide the proximal FISH signal, with a 52.3% GC content. The repetitive sequence was named PCSR (proximal CMA band-specific repeat). Clone PDCD159 was 1700 bp in length, with a 61.7% AT content, and produced FISH signals at the proximal DAPI band of the remaining four chromosomes. Four clones hybridized strongly to the secondary constriction and gave weak signals at the centromeric region of several chromosomes. Clone PDCD537, one of the four clones, was homologous to the 26S rRNA gene. A PCR experiment using microdissected centromeric regions suggested that the centromeric region contains 18S and 26S rDNA. Another 24 clones hybridized to whole chromosome arms, with varying intensities and might represent dispersed repetitive DNA.     

Development and molecular cytogenetic identification of new winter wheat--winter barley ('Martonvásári 9 kr1' - 'Igri') disomic addition lines.

This paper describes a series of winter wheat - winter barley disomic addition lines developed from hybrids between winter wheat line Triticum aestivum L. 'Martonvásári 9 kr1' and the German 2-rowed winter barley cultivar Hordeum vulgare L. 'Igri'. The barley chromosomes in a wheat background were identified from the fluorescent in situ hybridization (FISH) patterns obtained with various combinations of repetitive DNA probes: GAA-HvT01 and pTa71-HvT01. The disomic addition lines 2H, 3H, and 4H and the 1HS isochromosome were identified on the basis of a 2-colour FISH with the DNA probe pairs GAA-pAs1, GAA-HvT01, and pTa71-HvT01. Genomic in situ hybridization was used to confirm the presence of the barley chromosomes in the wheat genome. The identification of the barley chromosomes in the addition lines was further confirmed with simple-sequence repeat markers. The addition lines were also characterized morphologically.     

A chromosome bin map of 2148 expressed sequence tag loci of wheat homoeologous group 7

The objectives of this study were to develop a high-density chromosome bin map of homoeologous group 7 in hexaploid wheat (Triticum aestivum L.), to identify gene distribution in these chromosomes, and to perform comparative studies of wheat with rice and barley. We mapped 2148 loci from 919 EST clones onto group 7 chromosomes of wheat. In the majority of cases the numbers of loci were significantly lower in the centromeric regions and tended to increase in the distal regions. The level of duplicated loci in this group was 24% with most of these loci being localized toward the distal regions. One hundred nineteen EST probes that hybridized to three fragments and mapped to the three group 7 chromosomes were designated landmark probes and were used to construct a consensus homoeologous group 7 map. An additional 49 probes that mapped to 7AS, 7DS, and the ancestral translocated segment involving 7BS also were designated landmarks. Landmark probe orders and comparative maps of wheat, rice, and barley were produced on the basis of corresponding rice BAC/PAC and genetic markers that mapped on chromosomes 6 and 8 of rice. Identification of landmark ESTs and development of consensus maps may provide a framework of conserved coding regions predating the evolution of wheat genomes.