Heterogeneous organization of a tandem repeat family in subtelomeric heterochromatin of rye

The presence of tandem repeat multicopy families in subtelomeric regions of all chromosomes is a characteristic feature of the rye karyotype, in contrast to the organization of these regions in chromosomes of extensively studied species, such as human, rice, and Arabidopsis. To study the molecular structure of these regions, we analyzed BAC clones from a library constructed from the genetic material of rye chromosome 1 short arm (1RS). Screening of the library detected numerous clones that contained copies of multicopy tandem families of DNA sequences pSc200, pSc250, and pSc119.2. An examination of the molecular organization of tandem arrays of the pSc200 family, which is the most common in the rye genome, showed that the subtelomeric 1RS region includes several such arrays, each of which contains characteristic blocks of multimers of various periodicity. Such pattern of heterogeneous organization of tandem repeat arrays differs from the view of the tandem arrays as monotonous sequence of identical monomers, which was generally accepted in recent past.     

The large-scale genomic organization of repetitive DNA families at the telomeres of rye chromosomes.

Repetitive DNA sequences in the terminal heterochromatin of rye (Secale cereale) chromosomes have consequences for the structural and functional organization of chromosomes. The large-scale genomic organization of these regions was studied using the telomeric repeat from Arabidopsis and clones of three nonhomologous, tandemly repeated, subtelomeric DNA families with complex but contrasting higher order structural organizations. Polymerase chain reaction analysis with a single primer showed a fraction of the repeat units of one family organized in a "head-to-head" orientation. Such structures suggest evolution of chromosomes by chromatid-type breakage-fusion-bridge cycles. In situ hybridization and pulse field gel electrophoresis showed the order of the repeats and the heterogeneity in the lengths of individual arrays. After Xbal digestion and pulse field gel electrophoresis, the telomeric and two subtelomeric clones showed strong hybridization signals from 40 to 100 kb, with a maximum at 50 to 60 kb. We suggest that these fragments define a basic higher order structure and DNA loop domains of regions of rye chromosomes consisting of arrays of tandemly organized sequences.     

Genomic Subtraction Recovers Rye-Specific DNA Elements Enriched in the Rye Genome

Repetitive DNA sequence families have been identified in methylated relic DNAs of rye. This study sought to isolate rye genome-specific repetitive elements regardless of the level of methylation, using a genomic subtraction method. The total genomic DNAs of rye-chromosome-addition-wheat lines were cleaved to short fragments with a methylation-insensitive 4-bp cutter, MboI, and then common DNA sequences between rye and wheat were subtracted by annealing with excess wheat genomic DNA. Four classes of rye-specific repetitive elements were successfully isolated from both the methylated and non-methylated regions of the genome. Annealing of the DNA mixture at a ratio of the enzyme-restricted fragments:the sonicated fragments (1:3–1:5) was key to this success. Two classes of repetitive elements identified here belong to representative repetitive families: the tandem 350-family and the dispersed R173 family. Southern blot hybridization patterns of the two repetitive elements showed distinct fragments in methylation-insensitive EcoO109I digests, but continuous smear signals in the methylation-sensitive PstI and SalI digests, indicating that both of the known families are contained in the methylated regions. The subtelomeric tandem 350-family is organized by multimers of a 380-bp-core unit defined by the restriction enzyme EcoO109I. The other two repetitive element classes had new DNA sequences (444, 89 bp) and different core-unit sizes, as defined by methylation-sensitive enzymes. The EcoO109I recognition sites consisting of PyCCNGGPu-multi sequences existed with high frequency in the four types of rye repetitive families and might be a useful tool for studying the genomic organization and differentiation of this species.     

Characterization of the constriction with neocentric activity of 5RL chromosome in wheat

In wheat-5RL monotelosomic and ditelosomic addition lines, a proximal constriction located on the long arm of rye chromosome 5R shows neocentric activity at metaphase I of meiosis. In some pollen mother cells this region is unusually stretched, acquires kinetic activity and co-orients with the true centromeres. In the work described here we characterized the putative neocentric constriction of 5RL using various approaches. Fluorescence in situ hybridization (FISH) revealed that the rye subtelomeric repetitive DNA sequence pSc119.2 is a constituent of the 5RL constriction. This FISH site corresponds with a heterochromatic C-band in normal rye. Other subtelomeric (pSc34, pSc74, pSc200), centromeric (CCS1, Bilby) and Arabidopsis-type telomeric sequences produce no detectable hybridization signal on the constriction. Immunolocalization with anti-alpha-tubulin antibodies showed that microtubules are bound to the constriction in a similar way to their binding to true centromeres. Silver staining demonstrated that proteins are accumulated at the constriction, the signal being more prominent than that observed at the centromere and telomeres of 5RL. The frequency of neocentric activity in different plants varied dramatically in different generations and in siblings grown in different years, suggesting that activation of the neocentric site is dependent on internal features and environmental conditions.     

Polyploidization as a retraction force in plant genome evolution: sequence rearrangements in triticale

Background

Polyploidization is a major evolutionary process in plants where hybridization and chromosome doubling induce enormous genomic stress and can generate genetic and epigenetic modifications. However, proper evaluation of DNA sequence restructuring events and the precise characterization of sequences involved are still sparse.

Methodology/Principal Findings

Inter Retrotransposons Amplified Polymorphism (IRAP), Retrotransposons Microsatellite Amplified Polymorphism (REMAP) and Inter Simple Sequence Repeat (ISSR) largely confirmed the absence of any intraspecific variation in wheat, rye and triticale. The comparative analysis of banding profiles between wheat and rye inbred lines revealed 34% of monomorphic (common to both parental species) bands for the ten different primer combinations used. The analysis of triticale plants uncovered nearly 51% of rearranged bands in the polyploid, being the majority of these modifications, due to the loss of rye bands (83%). Sequence analysis of rye fragments absent in triticale revealed for instance homology with hydroxyproline-rich glycoproteins (HRGP), a protein that belongs to a major family of inducible defence response proteins. Conversely, a wheat-specific band absent in triticale comprises a nested structure of copia-like retrotransposons elements, namely Claudia and Barbara. Sequencing of a polyploid-specific band (absent in both parents) revealed a microsatellite related sequence. Cytological studies using Fluorescent In Situ Hybridization (FISH) with REMAP products revealed a widespread distribution of retrotransposon and/or microsatellite flanking sequences on rye chromosomes, with a preferential accumulation in heterochromatic sub-telomeric domains.

Conclusions/Significance

Here, we used PCR-based molecular marker techniques involving retrotransposons and microsatellites to uncover polyploidization induced genetic restructuring in triticale. Sequence analysis of rearranged genomic fragments either from rye or wheat origin showed these to be retrotransposon-related as well as coding sequences. Further FISH analysis revealed possible chromosome hotspots for sequence rearrangements. The role of chromatin condensation on the origin of genomic rearrangements mediated by polyploidization in triticale is also discussed.     

The relationship between two tandem repeat families in rye heterochromatin

A bacterial artificial chromosome (BAC) library constructed from the short arm of rye (Secalecereale L.) chromosome 1R has been screened for clones containing copies of the pSc200 tandem repeat family, most abundant in rye subtelomeric heterochromatin. The molecular organization of the monomer array and adjacent sequences has been studied in BAC-126/C20. Digestion of the array with various restriction endonucleases reveals no higher-order organization. The DNA adjacent to the pSc200 array consists of different repeats, including retrotransposon derivatives and another tandemly repeated family, termed XbaI, with a monomer length of 576 bp, 475 of which show 82% similarity to the long terminal repeat of the known Cereba retrotransposon. Sequencing of the 13 kb long genomic region in BAC-126/C20 revealed a direct junction of the pSc200 and XbaI monomers. The arrays of both families terminate at the same AT-rich sequence CAAAAAT. Another recombination signal is the presence of palindromes in the close proximity to the junction site. The presence of microhomologies promotes the action of proteins involved in double-strand DNA break repair. To our knowledge, it is the first discovery of the direct junction of monomers that are longer than 100 bp and belong to different families of plant tandem repeats.     

Review: The cytogenetic and molecular architecture of chromosome 1R—one of the most widely utilized sources of alien chromatin in wheat varieties

Conclusions The evolution of chromosome 1R has resulted in a structure with genes that are similar enough, qualitatively and quantitatively, to those in wheat to allow substitution for wheat chromosomes. The sequences dispersed between the genes, and those arranged tandemly in large blocks, have however undergone major quantitative changes (and possibly qualitative changes as well). Amplification events since the time that wheat and rye have been separated in an evolutionary sense have generated arrays of repetitive sequence families that characterize the rye chromosomes (including 1R) and distinguish them from wheat chromosomes. The genetic mapping of chromosome 1R at the level of DNA has provided a range of probes for the study of 1R chromosome segments as they are manipulated in commercial wheat cultivars.The extensive utilization of chromosome 1R as a source of disease resistance genes in wheat implies that rye genes are normally expressed in a wheat background. This is, however, not always the case and a particularly well studied example is the suppression of rRNA gene expression (reviewed in Applels et al. 1986a). These isolated examples of modified expression of rye genes in a wheat background are presumably the result of evolutionary change in the rye promoter regions resulting in their reduced competitiveness when combined with wheat genes in a common cytoplasmic environment. The cytoplasm of wheat plants carrying rye chromosome fragments would be dominated by protein molecules adapted to wheat promoters.     

Fine Mapping of Satellite DNA Sequences along the Y Chromosome of Drosophila Melanogaster: Relationships between Satellite Sequences and Fertility Factors

The entirely heterochromatic Y chromosome of Drosophila melanogaster contains a series of simple sequence satellite DNAs which together account for about 80% of its length. Molecular cloning of the three simple sequence satellite DNAs of D. melanogaster (1.672, 1.686 and 1.705 g/ml) revealed that each satellite comprises several distinct repeat sequences. Together 11 related sequences were identified and 9 of them were shown to be located on the Y chromosome. In the present study we have finely mapped 8 of these sequences along the Y by in situ hybridization on mitotic chromosome preparations. The hybridization experiments were performed on a series of cytologically determined rearrangements involving the Y chromosome. The breakpoints of these rearrangements provided an array of landmarks along the Y which have been used to localize each sequence on the various heterochromatic blocks defined by Hoechst and N-banding techniques. The results of this analysis indicate a good correlation between the N-banded regions and 1.705 repeats and between the Hoechst-bright regions and the 1.672 repeats. However, the molecular basis for banding does not appear to depend exclusively on DNA content, since heterochromatic blocks showing identical banding patterns often contain different combinations of satellite repeats. The distribution of satellite repeats has also been analyzed with respect to the male fertility factors of the Y chromosome. Both loop-forming (kl-5, kl-3 and ks-1) and non-loop-forming (kl-2 and ks-2) fertility genes contain substantial amounts of satellite DNAs. Moreover, each fertility region is characterized by a specific combination of satellite sequences rather than by an homogeneous array of a single type of repeat.(ABSTRACT TRUNCATED AT 250 WORDS)     

＂Micro-deletions＂ of the human Y chromosome and their relationship with male infertility

The Y chromosome evolves from an autochromosome and accumulates male-related genes including sex-determining region of Y-chromosome (SRY) and several spermatogenesis-related genes.The human Y chromosome (60 Mb long) is largely composed of repeti-tive sequences that give it a heterochromatic appearance,and it consists of pseudoautosomal,euchromatic,and heterochromatic regions.Located on the two extremities of the Y chromosome,pseudoautosomal regions 1 and 2 (PAR1 and PAR2,2.6 Mb and 320 bp long,re-spectively) are homologs with the termini of the X chromosome.The euchromatic region and some of the repeat-rich heterochromatic parts of the Y chromosome are called "male-specific Y" (MSY),which occupy more than 95% of the whole Y chromosome.After evolu-tion,the Y chromosome becomes the smallest in size with the least number of genes but with the most number of copies of genes that are mostly spermatogenesis-related.The Y chromosome is characterized by highly repetitive sequences (including direct repeats,inverted repeats,and palindromes) and high polymorphism.Several gene rearrangements on the Y chromosome occur during evolution owing to its specific gene structure.The consequences of such rearrangements are not only loss but also gain of specific genes.One hundred and fifty three haplotypes have been discovered in the human Y chromosome.The structure of the Y chromosome in the GenBank belongs to haplotype R1.There are 220 genes (104 coding genes,111 pseudogenes,and 5 other uncategorized genes) according to the most recent count.The 104 coding genes encode a total of about 48 proteins/protein families (including putative proteins/protein families).Among them,16 gene products have been discovered in the azoospermia factor region (AZF) and are related to spermatogenesis.It has been dis-covered that one subset of gene rearrangements on the Y chromosome,"micro-deletions",is a major cause of male infertility in some populations.However,controversies exist about different Y chromosome haplotypes.Six AZFs of the Y chromosome have been discov-ered including AZFa,AZFb,AZFc,and their combinations AZFbc,AZFabc,and partial AZFc called AZFc/gr/gr.Different deletions in AZF lead to different content spermatogenesis loss from teratozoospermia to infertility in different populations depending on their Y hap-lotypes.This article describes the structure of the human Y chromosome and investigates the causes of micro-deletions and their relation-ship with male infertility from the view of chromosome evolution.After analysis of the relationship between AZFc and male infertility,we concluded that spermatogenesis is controlled by a network of genes,which may locate on the Y chromosome,the autochromosomes,or even on the X chromosome.Further investigation of the molecular mechanisms underlying male fertility/infertifity will facilitate our knowledge of functional genomics.     

Presence of various rye-specific repeated DNA sequences on the midget chromosome of rye.

The chromosome 1R of rye, or the midget chromosome, is necessary for plump, viable seed development and fertility restoration in the alloplasmic line with rye cytoplasm and a hexaploid wheat nucleus. The midget chromosome of rye represents 1/15th of the physical length of the chromosome 1R of rye. C-banding analysis indicated that the centromeric and pericentric region (approximately 30% physical length) of the midget chromosome is heterochromatic and the distant 70% physical length is euchromatic. These data suggest that the midget chromosome may represent the pericentric region of the long arm of chromosome 1R. In contrast with earlier reports, our results indicate that an array of rye-specific repeated sequences (both dispersed and tandem) are present on the midget chromosome. Various rye-specific repeated DNA sequences that are present on the midget chromosome will be useful in constructing a long-range map and studying the genomic organization of the midget chromosome. It is unclear if any of these repeated DNA sequences are involved in the origin of the midget chromosome.     

Molecular evolution of receptor-like kinase genes in hexaploid wheat. Independent evolution of orthologs after polyploidization and mechanisms of local rearrangements at paralogous loci

Hexaploid wheat is a young polyploid species and represents a good model to study mechanisms of gene evolution after polyploidization. Recent studies at the scale of the whole genome have suggested rapid genomic changes after polyploidization but so far the rearrangements that have occurred in terms of gene content and organization have not been analyzed at the microlevel in wheat. Here, we have isolated members of a receptor kinase (Lrk) gene family in hexaploid and diploid wheat, Aegilops tauschii, and barley (Hordeum vulgare). Phylogenetic analysis has allowed us to establish evolutionary relationships (orthology versus paralogy) between the different members of this gene family in wheat as well as with Lrk genes from barley. It also demonstrated that the sequences of the homoeologous Lrk genes evolved independently after polyploidization. In addition, we found evidence for gene loss during the evolution of wheat and barley. Analysis of large genomic fragments isolated from nonorthologous Lrk loci showed a high conservation of the gene content and gene organization at these loci on the homoeologous group 1 chromosomes of wheat and barley. Finally, sequence comparison of two paralogous fragments of chromosome 1B showed a large number of local events (sequence duplications, deletions, and insertions), which reveal rearrangements and mechanisms for genome enlargement at the microlevel.     

Genomic structure and paralogous regions of the inversion breakpoint occurring between human chromosome 3p12.3 and orangutan chromosome 2

Intrachromosomal duplications play a significant role in human genome pathology and evolution. To better understand the molecular basis of evolutionary chromosome rearrangements, we performed molecular cytogenetic and sequence analyses of the breakpoint region that distinguishes human chromosome 3p12.3 and orangutan chromosome 2. FISH with region-specific BAC clones demonstrated that the breakpoint-flanking sequences are duplicated intrachromosomally on orangutan 2 and human 3q21 as well as at many pericentromeric and subtelomeric sites throughout the genomes. Breakage and rearrangement of the human 3p12.3-homologous region in the orangutan lineage were associated with a partial loss of duplicated sequences in the breakpoint region. Consistent with our FISH mapping results, computational analysis of the human chromosome 3 genomic sequence revealed three 3p12.3-paralogous sequence blocks on human chromosome 3q21 and smaller blocks on the short arm end 3p26-->p25. This is consistent with the view that sequences from an ancestral site at 3q21 were duplicated at 3p12.3 in a common ancestor of orangutan and humans. Our results show that evolutionary chromosome rearrangements are associated with microduplications and microdeletions, contributing to the DNA differences between closely related species.     

Repeated sequence DNA relationships in four cereal genomes

The effect of DNA fragment size on the extent of hybridisation that occurs between repeated sequence DNAs from oats, barley, wheat and rye has been investigated. The extent of hybridisation is very dependent on fragment size, at least over the range of 200 to 1000 nucleotides. This is because only a fraction of each fragment forms duplex DNA during renaturation. From these results estimates of the proportions of repeated sequences of each of the cereal genomes that are homologous with repeated sequences in the other species have been determined and a phylogenetic tree of cereal evolution constructed on the basis of the repeated sequence DNA homologies. It is proposed that wheat and rye diverged after their common ancestor had diverged from the ancestor of barley. This was preceded by the divergence of the common ancestor of wheat, rye and barley and the ancestor of oats. Once introduced in Gramineae evolution most families of repeated sequences appear to have been maintained in all subsequently diverging species. — The repeated sequences of oats, barley, wheat and rye have been divided into Groups based upon their presence or absence in different species. Repeated sequences of related families are more closely related to one another within a species than between species. It is suggested that this is because repeated sequences have been involved in many rounds of amplification or quantitative change via unequal crossing over during species divergence in cereal evolution.     

New families of site-specific repetitive DNA sequences that comprise constitutive heterochromatin of the Syrian hamster (Mesocricetus auratus, Cricetinae, Rodentia)

We molecularly cloned new families of site-specific repetitive DNA sequences from BglII- and EcoRI-digested genomic DNA of the Syrian hamster (Mesocricetus auratus, Cricetrinae, Rodentia) and characterized them by chromosome in situ hybridization and filter hybridization. They were classified into six different types of repetitive DNA sequence families according to chromosomal distribution and genome organization. The hybridization patterns of the sequences were consistent with the distribution of C-positive bands and/or Hoechst-stained heterochromatin. The centromeric major satellite DNA and sex chromosome-specific and telomeric region-specific repetitive sequences were conserved in the same genus (Mesocricetus) but divergent in different genera. The chromosome-2-specific sequence was conserved in two genera, Mesocricetus and Cricetulus, and a low copy number of repetitive sequences on the heterochromatic chromosome arms were conserved in the subfamily Cricetinae but not in the subfamily Calomyscinae. By contrast, the other type of repetitive sequences on the heterochromatic chromosome arms, which had sequence similarities to a LINE sequence of rodents, was conserved through the three subfamilies, Cricetinae, Calomyscinae and Murinae. The nucleotide divergence of the repetitive sequences of heterochromatin was well correlated with the phylogenetic relationships of the Cricetinae species, and each sequence has been independently amplified and diverged in the same genome.     

Karyotype of Norway spruce by multicolor FISH

The chromosomes (2n = 2x = 24) of Norway spruce are very large since their size reflects the huge amount of genomic DNA (2C = 30 × 10⁹ bp). However, the identification of homologous pairs is hampered by their high degree of similarity at the morphological level. Data so far presented in the literature were not sufficient to solve all the ambiguities in chromosome identification. Several genomic Norway spruce DNA clones containing highly repetitive sequences have been identified and characterised in our laboratory. Three of them were selected for fluorescent in situ hybridization (FISH) experiments because of their strong signals and suitability for chromosome identification: PATR140 hybridized at the centromeric site of three chromosome pairs; PAF1 hybridized in six subtelomeric and two centromeric sites; 1PABCD6 co-localized with the subtelomeric sites identified by PAF1. The statistical analysis of microscopic measurements of chromosomes in combination with the FISH signals of these probes allowed the unambigous construction of Norway spruce karyotype. We also compared the karyotype of Norway spruce with that of other spruce species to infer the number and kind of rearrangements that have occurred during the evolution of these species.Communicated by D.B. Neale     

The mapping of highly-repeated DNA families and their relationship to C-bands in chromosomes of Secale cereale

The relationship between the chromosomal location of heterochromatin C-bands and of four non-homologous repeated sequence families constituting 8 to 12% of total rye DNA has been investigated in chromosomes of rye (Secale cereale) by in situ hybridisation. Three rye varieties, a set of rye disomic additions to wheat and a triticale were studied. Only centromeric and nucleolar organizer region (NOR) associated C-bands failed to display hybridisation to at least one of the sequences and many telomeric blocks of heterochromatin contained all four repeated sequence families. Both between-variety differences in the chromosomal distribution of repeated sequences, and intravarietal heterozygosities were frequently noted and are probably widespread. — Previously reported deletions of heterochromatin from King II rye chromosomes added to the Holdfast wheat complement were correlated with deletions of some, but not all, of the highly repeated sequence families. A previously unreported loss of some families from King II rye chromosome 4R/7R in a Holdfast wheat genetic background was detected. This loss was not associated with complete deletion of a C-band. A deletion has also probably occurred from the short arm telomere of 4R/7R in the triticale variety Rosner. It is suggested that the families of repeats in rye telomeric heterochromatin which are absent from wheat are selected against in the wheat genetic background.     

Organization and evolution of highly repeated satellite DNA sequences in plant chromosomes

A major component of the plant nuclear genome is constituted by different classes of repetitive DNA sequences. The structural, functional and evolutionary aspects of the satellite repetitive DNA families, and their organization in the chromosomes is reviewed. The tandem satellite DNA sequences exhibit characteristic chromosomal locations, usually at subtelomeric and centromeric regions. The repetitive DNA family(ies) may be widely distributed in a taxonomic family or a genus, or may be specific for a species, genome or even a chromosome. They may acquire large-scale variations in their sequence and copy number over an evolutionary time-scale. These features have formed the basis of extensive utilization of repetitive sequences for taxonomic and phylogenetic studies. Hybrid polyploids have especially proven to be excellent models for studying the evolution of repetitive DNA sequences. Recent studies explicitly show that some repetitive DNA families localized at the telomeres and centromeres have acquired important structural and functional significance. The repetitive elements are under different evolutionary constraints as compared to the genes. Satellite DNA families are thought to arise de novo as a consequence of molecular mechanisms such as unequal crossing over, rolling circle amplification, replication slippage and mutation that constitute "molecular drive".     

Molecular cytogenetic characterisation of the terminal heterochromatic segment of the B-chromosome of rye (Secale cereale)

The terminal heterochromatic segments of the long arms of 20 rye B-chromosomes were isolated by means of laser microdissection technology. Also the remaining portions of the long arms, along with the short arms of the same chromosomes were isolated. Each sample was used for degenerate oligonucleotide primer-polymerase chain reaction (DOP-PCR) amplification reactions. The resulting products were used as probes for chromosome in situ hybridisation experiments, and in Southern hybridisation to digests of 0B and +B DNA. Competition hybridisation of these probes with 0B DNA allowed the detection of B-specific sequences. The terminal heterochromatin of the rye B-chromosome contains both B-specific sequences and sequences also present on the A-chromosomes of rye. The B-specific D1100 family is the major repeat species located in the terminal heterochromatin. Primers designed to the cloned sequence (E1100) were used to search for related low copy sequences in 0B DNA. The sequences of the PCR products revealed no similarities to that of the clone E1100 except for the primer sequences. The possible origin of this sequence is discussed in the context of models for the evolution of the rye B-chromosome. EMBL and Genbank accession numbers: Z54196 (E1199): Z54278 (B1) Edited by: R. Appels