植物45S rDNA的染色体位置的CPD染色和FISH分析

采用PI和DAPI组合(CPD)染色结合45SrDNA探针的荧光原位杂交(FISH)对分属6个科的16种植物的45S rDNA的染色体位置进行了分析。在所有供试植物中,共检测到53个45S rDNA位点。大多数45S rDNA位点分布在染色体的短臂;位于染色体臂内和染色体末端的位点的比例大体相当;多数位于染色体臂内的45S rDNA位点有次缢痕形成,但rDNA重复单位簇所处的位置存在差异。根据45S rDNA所处的染色体臂的不同、距着丝粒远近的差异、形成次缢痕与否以及rDNA重复单位簇相对于次缢痕的位置等特征,将植物的45S rDNA位点划分为12种染色体分布类型。基于我们的结果和其他的报道对45S rDNA位点、核仁组织区(NOR)、次缢痕和随体相互之间的关系进行了分析。     

Telomeric signals in robertsonian fusion and fission chromosomes: implications for the origin of pseudoaneuploidy.

In situ hybridization with synthetic plant telomeric sequences resulted in labeling of all broad bean (Vicia faba) chromosomes at their ends only. Telocentric chromosomes derived by fission of the metacentric satellite chromosome of V. faba also showed signals at both of their ends, whereas the ancestral metacentric did not display signals at its primary constriction, the point of fission. As in V. faba, all acrocentric mouse chromosomes were labeled by in situ hybridization with a vertebrate telomeric probe at both ends of each chromatid exclusively. However, different metacentric Robertsonian chromosomes derived by fusion of defined acrocentrics did not show signals at their primary constrictions. The mechanism of Robertsonian rearrangement leading to a pseudoaneuploid increase or decrease in chromosome number therefore cannot consist solely of a simple fission or fusion of chromosomes without a concomitant gain or loss of chromatin material. The additional assumption of a subdetectable deletion of telomeric sequences after fusion and amplification of these sequences following fission is necessary to explain the present observations.     

47,X,idic(Y),inv dup(Y): a non-mosaic case of a phenotypically normal boy with two different Y isochromosomes and neocentromere formation

A de novo aberrant karyotype with 47 chromosomes including 2 different-sized markers was identified during prenatal diagnosis. Fluorescence in situ hybridization (FISH) with a Y painting probe tagged both marker chromosomes which were supposed to be isochromosomes of the short and the long arm, respectively. A normal boy was born in time who shows normal physical and mental development. To characterize both Y markers in detail, we postnatally FISH-mapped a panel of Y chromosomal probes including SHOX (PAR1), TSPY, DYZ3 (Y centromere), UTY, XKRY, CDY, RBMY, DAZ, DYZ1 (Yq12 heterochromatin), SYBL1 (PAR2), and the human telomeric sequence (TTAGGG)(n). The smaller Y marker turned out to be an isochromosome containing an inverted duplication of the entire short arm, the original Y centromere, and parts of the proximal long arm, including AZFa. The bigger Y marker was an isochromosome of the rest of the Y long arm. Despite a clearly visible primary constriction within one of the DAPI- and DYZ1-positive heterochromatic regions, hybridization of DYZ3 detected no Y-specific alphoid sequences in that constriction. Because of its stable mitotic distribution, a de novo formation of a neocentromere has to be assumed.     

Human telomeric 6; 19 translocation chromosome with a tendency to break at the fusion point

The behavior of a translocation chromosome t(6; 19) in the lymphocytes of a mentally retarded woman with other anomalies has been analyzed. The two chromosomes were attached at the telomeres of their short arms without any apparent deletion. The centromere of chromosome 19 was marked by a primary constriction and the site of the centromere of chromosome 6 by a C-band, but no constriction. The translocation chromosome showed two primary constrictions once in 8,800 metaphases, probably resulting from mitotic crossing-over. One or both chromatids of the translocation chromosome were broken at the attachment point with a frequency of 1/733 cells. In addition, the chromosome was often bent at this point and the translocated chromosomes 19 and 6 showed a differential spiralization. In this characteristic as well as the weakness of the fusion point, this chromosome differed from other translocations; the fusion obviously was not as firm as in translocations in general. The broken-off chromosome 6 did not regain a primary constriction, but had the appearance of a large acentric fragment. The segregation of the translocation chromosome and the fragment gave rise to a complicated mosaicism with various levels of ploidy for the fragment lacking a functional centromere. The data are in quantitative agreement with the equilibrium expectations under the assumption that each fragment goes to either pole at random in mitosis and that cells divide at the same rate regardless of ploidy. The high rate of nondisjunction of the fragment showed that the inactivated centromere of the translocation chromosome did not regain its activity when chromosome 19 with the functional centromere became separated from it. — The fragility and the behavior of the translocation chromosome and the production of telomeric associations are briefly discussed.     

Ribosomal, telomeric and heterochromatin sequences localization in the karyotype of Anemone hortensis

The karyotype of the Mediterranean species Anemone hortensis L. (Ranunculaceae) was characterized with emphasis on heterochromatin distribution and localization of ribosomal (18S−5.8S−26S and 5S rDNA) and telomeric repeats (TTTAGGG). Diploid chromosome complement, 2 n  = 2 x  = 16, common to all investigated populations, consisted of three acrocentric, one meta-submetacentric and four metacentric chromosomes ranging in size from 6.34 to 10.47 µm. Fluorescence in situ hybridization (FISH) with 18S and 5S rDNA probes revealed two 18S−5.8S−26S rDNA loci on a satellite and secondary constriction of acrocentric chromosome pair 2 and terminally on acrocentric chromosome pair 3, and two 5S rDNA loci in the pericentromeric region of meta-submetacentric chromosome pair 4 and in the proximity of the 18S−5.8S−26S rDNA locus on chromosome pair 2. The only GC-rich heterochromatin, as revealed by fluorochrome Chromomycin A3 staining, was that associated with nucleolar organizer regions, whereas AT-rich heterochromatin, stained with 4,6-diamino-2-phenylindole (DAPI), was distributed intercalarly and terminally on the long arm of all three acrocentric chromosomes, and terminally on chromosomes 4 and 5. FISH with Arabidopsis -type telomeric repeats (TTTAGGG) as a probe revealed two classes of signals, small dot-like and large bands, at chromosome termini exclusively, where they corresponded to terminal DAPI-stained heterochromatin. Heteromorphism of chromosome pair 4, which refers to terminal DAPI bands and FISH signals, was observed in populations of Anemone hortensis . Chromosome pairing during meiosis was regular with formation of localized chiasmata proximal to the centromere.  © 2006 The Linnean Society of London, Botanical Journal of the Linnean Society , 2006, 150 , 177–186.     

On telomere replication and fusion in eukaryotes: apropos of a case of 45,X/46,X,ter rea(X;X)(p22.3;p22.3)

A Mexican 181/2-year-old girl with short stature, primary amenorrhea, and mild Turner stigmata was found to have a 45,X/46,X,ter rea(X;X)(p22.3;p22.3) karyotype in her lymphocytes. The rearranged chromosome was twice the size of a normal X, appeared to be attached head-to-head, had no detectable chromatin loss, only one primary constriction, constitutive heterochromatin at both the centromere and pseudocentromere regions, was mitotically stable, and always showed late replication. From the analysis of this and other X;X terminal rearrangements we draw four conclusions: (1) Terminal rearrangements may arise either by telomeric fusion (tel fus) without loss of genetic material or from a conventional telomeric translocation. (2) Telomeric fusions between homologous chromosomes (the commonest type) can be secondary to impaired telomeric replication. (3) Phenotypically, patients with an X;X terminal rearrangement show great variability which depends mainly on whether or not chromatin has been lost in the rejoining process and a 45,X clone. (4) Patients with an X;X telomeric fusion without mosaicism are likely to have an XXX phenotype, whereas turneroid features are expected in mixoploidies that include an X monosomic clone and in cases of translocations involving the short arms.     

A mitotically stable marker chromosome negative for whole chromosome libraries, centromere probes and chromosome specific telomere regions: a novel class of supernumerary marker chromosome?

A two year-old child presented with mild developmental delay. On karyotype analysis, a supernumerary small marker chromosome (SMC) was found in all cells examined. This SMC was approximately the size of an isochromosome 18p, being symmetrical with a central constriction. C-banding and silver staining were negative and FISH with all chromosome-specific paints, centromere probes and telomere probes showed no hybridization to the SMC; telomere repeat sequences were however present on both arms. Comparative genomic hybridization showed no amplification of any chromosome region. Flow sorting of the SMC and reverse painting onto normal metaphase spreads showed no hybridization to any chromosome, whereas reverse painting onto the patient's own metaphases showed hybridization to the SMC only. This SMC may thus represent either a complex amplicon of different genomic regions, or a multifold amplification of a very small region, with a neocentromere comprising an active kinetochore but no alphoid DNA. Prognostic implications for the proband were difficult to assess due to the absence of reports of similar marker chromosomes in the literature.     

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.     

The structure of a subterminal repeated sequence present on many human chromosomes.

All telomeres which have been studied consist of an array of simple G/C rich repeats. Human telomeres were shown to share sequence similarity with those of lower eukaryotes by cross-hybridization and human telomeric sequences have been cloned by complementation of telomere function in yeast. Analysis of human telomeric sequences cloned in this way is described here. The terminal part of the cloned human telomeric DNA consists of an array of simple repeats, principally of the sequence TTAGGG and derivatives. The very terminal part consists of yeast-type telomeric repeats which suggests that the human telomeric sequences have acted as a primer for the addition of additional telomeric repeats in the yeast. Subterminal sequences are shared between a number of clones and in situ data shows that these subterminal sequences are present at several different chromosomal ends. Related sequences are present at internal as well as telomeric positions. Differences in the hybridization patterns of subterminal sequences in somatic compared to germ-line tissues are described which indicate differential modification of these sequences during development.     

A functional marker centromere with no detectable alpha-satellite,satellite III,or CENP-B protein: activation of a latent centromere?

We report the investigation of an unusual human supernumerary marker chromosome 10 designated "mar del(10)." This marker is present together with two other marker chromosomes in the karyotype of a boy with mild developmental delay. It has a functional centromere at a primary constriction and is mitotically stable. Fluorescence in situ hybridization (FISH) using alpha-satellite and satellite III DNA as probes failed to detect any signal at the primary constriction site. CENP-B protein could not be demonstrated, although the presence of at least some centromeric proteins was confirmed using a CREST antiserum. Consideration of these and other cytogenetic and FISH results supports a mechanism of formation of the mar del(10) chromosome involving the activation of a latent intercalary centromere at 10q25.     

Characterization of a maize isochromosome 8S*8S.

An isochromosome was found in the maize HiII Parent B line during somatic karyotyping with a multiprobe fluorescence in situ hybridization (FISH) system. Cytological analyses showed that it pairs with the short arm of chromosome 8 during the pachytene stage of meiosis. The chromosome 8 short arm origin of this isochromosome was also confirmed by FISH at mitotic metaphase. Knob heterochromatin signals were present at the short arms of chromosome 8 when subjected to prolonged exposure and also observed at both ends of the isochromosome. This isochromosome can be a univalent or a trivalent by pairing with the normal chromosome 8 short arms during meiosis. At anaphase and telophase, the isochromosome lagged behind other chromosomes. It had a transmission rate of 17%-20% from both male and female gametes. One plant homozygous for the isochromosome contained 2 isochromosomes that differed in the quantity of their CentC centromere repeat sequence. Both variations of the isochromosome were transmitted to the next generation. Because the 2 isochromosomes should be identical by descent, these observations document a radical change in copy number of the centromere repeat array within 1 generation. Plants with 1 isochromosome were not normal as compared with the original HiII Parent B plants. Those that contained a pair of this isochromosome (6 total copies of 8S) were even more abnormal and had reduced fertility. The results indicate the ability of the somatic karyotyping system to recognize and characterize chromosomal aberrations.     

The clustering of telomeres and colocalization with Rap1, Sir3, and Sir4 proteins in wild-type Saccharomyces cerevisiae

We have developed a novel technique for combined immunofluorescence/in situ hybridization on fixed budding yeast cells that maintains the three-dimensional structure of the nucleus as monitored by focal sections of cells labeled with fluorescent probes and by staining with a nuclear pore antibody. Within the resolution of these immunodetection techniques, we show that proteins encoded by the SIR3, SIR4, and RAP1 genes colocalize in a statistically significant manner with Y' telomere- associated DNA sequences. In wild-type cells the Y' in situ hybridization signals can be resolved by light microscopy into fewer than ten foci per diploid nucleus. This suggests that telomeres are clustered in vegetatively growing cells, and that proteins essential for telomeric silencing are concentrated at their sites of action, i.e., at telomeres and/or subtelomeric regions. As observed for Rap1, the Sir4p staining is diffuse in a sir3- strain, and similarly, Sir3p staining is no longer punctate in a sir4- strain, although the derivatized Y' probe continues to label discrete sites in these strains. Nonetheless, the Y' FISH is altered in a qualitative manner in sir3 and sir4 mutant strains, consistent with the previously reported phenotypes of shortened telomeric repeats and loss of telomeric silencing.     

Tetrasomy 18p de novo: Identification by FISH with conventional and microdissection probes and analysis of parental origin and formation by short sequence repeat typing

We report a de novo supernumerary isochromosome 18p in a child with tetrasomy 18p, analyzed by a straightforward combination of cytogenetic and molecular cytogenetic methods. The diagnostic procedure consisted of standard banding techniques and fluorescence in situ hybridization (FISH) with centromere and library DNA probes for chromosome 18, and 18p-specific FISH probes prepared by chromosome microdissection and in vitro amplification. The maternal origin as well as the most probable cell stages of formation of the supernumerary isochromosome were determined by typing of short sequence repeats (SSRs). The pattern of allelic distribution suggests a nondisjunction during meiosis followed by a centromeric misdivision in an early postzygotic mitosis as the most probable mode of isochromosome 18p formation. The combination of the applied methods represents a powerful tool to investigate the nature and the origin of de novo marker chromosomes. Received: 28 August 1995 / Revised: 3 November 1995; 20 December 1995     

Origin of an apparent B chromosome by mutation,chromosome fragmentation and specific DNA sequence amplification

The present study documents the de novo origin of an apparent B chromosome in Plantago lagopus. The origin was associated with mutation (aneuploidy), chromosome fragmentation, specific DNA sequence amplification, addition of telomeric repeats, and centromeric misdivision. It originated in the progeny of trisome 2, from the excision of 5S rDNA and 18S, 5.8S, 25S rDNA sequences located on chromosome 2, and within a few generations acquired many characteristics of an apparent B chromosome. The B chromosome has preferential transmission through the male (41%, P<0.025) and female gametes (42%, P<0.01) but does not affect plant phenotype. The B chromosome is completely heterochromatic, has a functional centromere and does not pair at meiosis with any A chromosomes of the standard complement. Fluorescence in situ hybridization analysis showed that it arose from massive amplification of 5S rDNA sequences, has 18S, 5.8S, 25S rDNA sequences at the ends of both arms and telomeric repeats at both termini. Ag-NOR-banding and determination of the maximum number of nucleoli in interphase cells indicate that the nucleolar organizer regions at the ends of both arms of the B chromosome are active in organizing nucleoli. RNA blot analysis showed that the 5S rDNA sequences are not transcribed. To our knowledge, this is the first report that fully documents one of the mechanisms by which B chromosomes may arise in nature.     

Satellite DNA III and alkaline Geimsa staining.

Satellite DNA III visualized by staining chromosomes with Giemsa at pH 10-12. Evidence is presented that besides the secondary constriction of chromosome 9, satellite III contained in considerable amount in the long arms of chromosome 20, giving rise to a clearly visible secondary constriction just below the centromere. The latter finding confirms that reported by Bobrow et al. (1972). The long arms of the Y chromosome also show strong staining with alkaline Giemsa, the region of staining corresponding exactly with the intensely flourescing area. This is interpreted as possible evidence for the presence of satellite DNA III in the distal long arms of the human Y chromosome.     

Centromeric inactivation in a dicentric human Y;21 translocation chromosome

A de novo dicentric Y;21 (q11.23;p11) translocation chromosome with one of its two centromeres inactive has provided the opportunity to study the relationship between centromeric inactivation, the organization of alphoid satellite DNA and the distribution of CENP-C. The proband, a male with minor features of Down’s syndrome, had a major cell line with 45 chromosomes including a single copy of the translocation chromosome, and a minor one with 46 chromosomes including two copies of the translocation chromosome and hence effectively trisomic for the long arm of chromosome 21. Centromeric activity as defined by the primary constriction was variable: in most cells with a single copy of the Y;21 chromosome, the Y centromere was inactive. In the cells with two copies, one copy had an active Y centromere (chromosome 21 centromere inactive) and the other had an inactive Y centromere (chromosome 21 centromere active). Three different partial deletions of the Y alphoid array were found in skin fibroblasts and one of these was also present in blood. Clones of single cell origin from fibroblast cultures were analysed both for their primary constriction and to characterise their alphoid array. The results indicate that (1) each clone showed a fixed pattern of centromeric activity; (2) the alphoid array size was stable within a clone; and (3) inactivation of the Y centromere was associated with both full-sized and deleted alphoid arrays. Selected clones were analysed with antibodies to CENP-C, and staining was undetectable at both intact and deleted arrays of the inactive Y centromeres. Thus centromeric inactivation appears to be largely an epigenetic event. Received: 30 January 1997; in revised form: 3 April 1997 / Accepted: 8 May 1997     

Telomeric DNA damage by topoisomerase I. A possible mechanism for cell killing by camptothecin

Topoisomerase I adjusts torsional stress in the genome by breaking and resealing one strand of the helix through a transient covalent coupling between enzyme and DNA. Camptothecin, a specific topoisomerase I poison, traps this covalent intermediate, thereby damaging the genome. Here we examined the activity of topoisomerase I at telomeric repeats to determine whether telomere structures are targets for DNA damage. We show that topoisomerase I is catalytically active in cleaving the G-rich telomeric strand in vitro in the presence of camptothecin but not in cleaving the C-rich strand. The topoisomerase I cleavage site is 5'-TT (downward arrow) AGGG-3' (cleavage site marked by the downward arrow). We also show that endogenous topoisomerase I can access telomeric DNA in vivo and form camptothecin-dependent covalent complexes. Therefore, each telomeric repeat represents a potential topoisomerase I cleavage site in vivo. Because telomere structures are comprised of a large number of repeats, telomeres in fact represent a high concentration of nested topoisomerase I sites. Therefore, more telomeric DNA damage by camptothecin could occur in cells with longer telomeres when cells possess equivalent levels of topoisomerase I. The evidence presented here suggests that DNA damage at telomeric repeats by topoisomerase I is a prominent feature of cell killing by camptothecin and triggers camptothecin-induced apoptosis.     

Rad51 suppresses gross chromosomal rearrangement at centromere in Schizosaccharomyces pombe

Centromere that plays a pivotal role in chromosome segregation is composed of repetitive elements in many eukaryotes. Although chromosomal regions containing repeats are the hotspots of rearrangements, little is known about the stability of centromere repeats. Here, by using a minichromosome that has a complete set of centromere sequences, we have developed a fission yeast system to detect gross chromosomal rearrangements (GCRs) that occur spontaneously. Southern and comprehensive genome hybridization analyses of rearranged chromosomes show two types of GCRs: translocation between homologous chromosomes and formation of isochromosomes in which a chromosome arm is replaced by a copy of the other. Remarkably, all the examined isochromosomes contain the breakpoint in centromere repeats, showing that isochromosomes are produced by centromere rearrangement. Mutations in the Rad3 checkpoint kinase increase both types of GCRs. In contrast, the deletion of Rad51 recombinase preferentially elevates isochromosome formation. Chromatin immunoprecipitation analysis shows that Rad51 localizes at centromere around S phase. These data suggest that Rad51 suppresses rearrangements of centromere repeats that result in isochromosome formation.     

Tandem insertions of Alu elements

The technique of chromosomal orientation and direction fluorescence in situ hybridization (COD-FISH) was adapted for plant chromosomes in order to study long-range organization of two families of satellite repeats, VicTR-B of Vicia sativa and PisTR-B of Pisum sativum. The technique allowed FISH to be performed on mitotic chromosomes in a strand-specific manner, resulting in visualization of the repeat orientation along the chromosomes and with respect to the direction of telomeric repeats. The VicTR-B probe applied to V. sativa chromosomes produced signals on a single chromatid at most regions containing corresponding sequences, thus confirming a presence of long arrays of head-to-tail arranged repeat monomers which is typical for satellite DNA. However, hybridization signals of different or equal intensities on both chromatids were also detected at some loci, suggesting a more complex arrangement of the repeats. Similar observations were made for PisTR-B repeats on P. sativum chromosomes, although the proportion of loci displaying signals on both chromatids was lower. In contrast to VicTR-B, orientation of the PisTR-B clusters with respect to telomeric sequences appeared to be conserved among subtelomeric regions of metacentric chromosomes and of the short arms of acrocentric chromosomes.     

An evolutionary change in telomere sequence motif within the plant section Asparagales had significance for telomere nucleoprotein complexes

In association with a phylogenetic tree of Asparagales, our previous results showed that a distinct clade included plant species where the ancestral, Arabidopsis-type of telomeric repeats (TTTAGGG)n had been partially, or fully, replaced by the human-type telomeric sequence (TTAGGG)n. Telomerases of these species synthesize human repeats with a high error rate in vitro. Here we further characterize the structure of telomeres in these plants by analyzing the overall arrangement of major and minor variants of telomeric repeats using fluorescence in situ hybridization on extended DNA strand(s). Whilst the telomeric array is predominantly composed of the human variant of the repeat, the ancestral, Arabidopsis-type of telomeric repeats was ubiquitously observed at one of the ends and/or at intercalary positions of extended telomeric DNAs. Another variant of the repeat typical of Tetrahymena was observed interspersed in about 20% of telomerics. Micrococcal nuclease digestions indicated that Asparagales plants with a human-type of telomere have telomeric DNA organised into nucleosomes. However, unexpectedly, the periodicity of the nucleosomes is not significantly shorter than bulk chromatin as is typical of telomeric chromatin. Using electrophoretic mobility shift assays we detected in Asparagales plants with a human type of telomere a 40-kDa protein that forms complexes with both Arabidopsis- and human-type G-rich telomeric strands. However, the protein shows a higher affinity to the ancestral Arabidopsis-type sequence. Two further proteins were found, a 25-kDa protein that binds specifically to the ancestral sequence and a 15-kDa protein that binds to the human-type telomeric repeat. We discuss how the organisation of the telomere repeats in Asparagales may have arisen and stabilised the new telomere at the point of mutation.