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     

Fusion of two apparently intact human X chromosomes

Summary Cytological studies have been presented from a 15-year-old girl with short stature and failure of puberty. Buccal mucosa preparations revealed X-chromatin mass approximately double in size of that of a normal female. Leukocyte metaphases suggested a two cell line composition of the patient. One population of cells conformed with 45,X chromosome distribution. The chromosome complement of her other cell line had a modal number of 46. In this cell line a C chromosome was replaced by an exceptionally large submetacentric chromosome. This abnormal element exhibited late DNA replicating pattern. G-banding study revealed that the abnormal chromosome was produced as a result of fusion involving telomeric ends of long arms of 2 intact X chromosomes. This translocation X was bearing 2 C-banded areas; one around the centromere and the other at the distal end of the long arm. The distal C-band area did not show any evidence for centromeric function. It appears that a centromere becomes latent in the presence of another centromere in a translocation bearing 2 total chromosomes. Such a change of state in the additional centromere is vital for the stability of the translocation chromosome.     

Detection of aneuploid cells in fibroblast cultures from the father of two trisomy 21 patients.

Karyotype analysis was performed on successive cultures of fibroblasts from the parents of two trisomic 21 patients. Starting from the 7th passage in the father cultures an aneuploid clone showing an extra E-like chromosome was found, which eventually overgrew the cell population. The significance of this cytogenetic finding is discussed in relation to the recurrence of the trisomy in the family.     

Variation in S phase in synchronous human cell lines.

Growth parameters of diploid and trisomic human fibroblasts were determined. The rate of growth of both classes of cells was examined in asynchronous cultures, and diploid and trisomic cells had similar growth rates. Synchronous cultures were developed using simple mitotic selection. The patterns and length of the DNA synthetic period (S phase) were found to be altered in trisomy 21 cells when compared to diploid human or to heteroploid HeLa cells. Early S-phase synthesis was absent or reduced and the overall length of the S phase was extended. However, the trisomic cells have apparently normal rates of DNA chain elongation and normal replicon sizes.     

Structural analysis of a yeast centromere

The most striking region of structural differentiation of a eukaryotic chromosome is the kinetochore. This chromosomal domain plays an integral role in the stability and propagation of genetic material to the progeny cells during cell division. The DNA component of this structure, which we refer to as the centromere, has been localized to a small region of 220–250 base pairs within the chromosomes from the yeast Saccharomyces cerevisiae. The centromere DNA (CEN) is organized in a unique structure in the cell nucleus and is required for chromosome stability during both mitotic and meiotic cell cycles. The centromeres from one chromosome can stabilize small circular minichromosomes or other yeast chromosomes. The centromeres may therefore interact with the same components of the segregation apparatus regardless of the chromosome in which they reside. The CEN DNA does not encode any regulatory RNAs or proteins, but rather is a cis-acting element that provides genetic stability to adjacent DNA sequences.     

Variation in S phase in synchronous human cell lines

Summary Growth parameters of diploid and trisomic human fibroblasts were determined. The rate of growth of both classes of cells was examined in asynchronous cultures, and diploid and trisomic cells had similar growth rates. Synchronous cultures were developed using simple mitotic selection. The patterns and length of the DNA synthetic period (S phase) were found to be altered in trisomy 21 cells when compared to diploid human or to heteroploid HeLa cells. Early S-phase synthesis was absent or reduced and the overall length of the S phase was extended. However, the trisomic cells have apparently normal rates of DNA chain elongation and normal replicon sizes. This work was supported by the United States Department of Energy and the National Institutes of Health.     

Cytogenetic,FISH and DNA studies in 11 individuals from a family with two siblings with dup(21q) Down syndrome

A Spanish family has previously been described with two siblings with dup(21q) Down syndrome. The father has a normal karyotype. The mother has a microchromosome. Cytogenetic, fluorescence in situ hybridization and DNA studies have now been carried out on the family. Findings include that the mother has three different chromosome anomalies, viz. (1) a chromosome 22 with an unusual pericentromeric region that contains alphoid DNA from chromosomes 21/13 and chromosome 22, (2) an isochromosome 21p in the frequent cell line and (3) an isochromosome 21q in a rare second cell line. A possible explanation is that the mother developed from a zygote with trisomy 21 and that mitotic error in early development resulted in the formation of two cell lines with karyotypes of 47,XX,+i(21p) and 47,XX,+i(21q), respectively. The unusual chromosome 22 represents a hitherto undescribed chromosome anomaly and one possible explanation is a translocation of the short arms between chromosomes 21/13 and 22 in the ancestry of the family. The relationship between the unusual chromosome 22 and the isochromosome formation in the mother is not known. However, all three chromosome anomalies involve the alphoid DNA of chromosome 21/13, indicating that this is not a chance finding.     

The origin of mosaic Down syndrome: four cases with chromosome markers

Four children, a girl and three boys, with diploid/trisomic mosaic Down syndrome were studied for the mechanism of origin of mosaics, using Q- and R-banding heteromorphisms as markers. Three mosaic subjects started as a trisomic zygote followed by the loss of a chromosome 21 at an early mitotic division. Of these, one resulted from a maternal first-meiotic error, another resulted from a paternal first-meiotic event, and the third originated from a first-meiotic error in either parent. The remaining subject could have resulted from either a diploid or a trisomic zygote. These findings, together with a higher proportion of trisomic cells in skin fibroblasts than in peripheral blood lymphocytes in the two patients studied, suggest that the extra chromosome 21 in mosaic Down syndrome patients usually has a meiotic origin. At least two, possibly three, of the diploid cell lines in these mosaics consisted of "uniparental" chromosomes 21, namely, both the homologous members were derived from a parent.     

Cytological identification of an isotetrasomic in rice and its application to centromere mapping

The aneuploid with isochromosome or telochromosome is ideal material for exploring the position of centromere in lingkage map.For obtaining these aneuploids in rice,the primary trisomics from triplo-1 to triplo-12 and the aneuploids derived from a triploid of indica rice variety Zhongxiao 3037 were carefully investigated.From the offsprings of triplo-10,a primary trisomic of chromosome 10 of the variety,an isotetrasomic “triplo-10-1” was obtained.Cytological investigation revealed that a pair of extra isochromosomes of triplo-10-1 were come from the short arm of chromosome 10.In the offsprings of the isotetrasomic,a secondary trisomic “triplo-10-2”,in which the extra-chromosome was an isochromosome derived from the short arm of chromosome 10,was identified.With the isotetrasomic,secondary trisomic,primary trisomic and diploid of variety Zhongxiao 3037,different molecular markers were used for exploring the position of the centromere of chromosome 10.Based on the DNA dosage effect,it was verified that the molecular markers G1125,G333 and L169 were Located on the short arm,G1084 and other 16 available molecular markers were on the long arm of chromosome 10.So the centromere of chromosome 10 was located somewhere between G1125 and G1084 according to the RFLP linkage map given by Kurata et al[1].The distance from G1125 to G1084 was about 3.2cM.     

Balanced structural changes involving the human X: Effect on sexual phenotype

Summary A normal cell line arising from a translocation, t(12;21), possibly by dissociation, was observed in two brothers in early life. Each was conceived as trisomic 21 by their 45,XY,-12,-21,+t(12;21) father, who was phenotypically normal. Each brother showed morphologic manifestations of trisomy 21 syndrome, and each was mildly mentally retarded. Dermatoglyphic indices were not diagnostic of trisomy 21 syndrome. At 4 months the younger brother had a 50:50 proportion of trisomic:normal blood cells which became 25:75 of trisomic 21:normal at 36 months. The older brother had a 25:75 proportion of trisomic 21:normal when first studied at 41/2 years. A similar t(12;21) has not previously been reported. The occurrence of an apparently normal cell line arising spontaneously is unique.     

A telomere-mediated chromosome fragmentation approach to assess mitotic stability and ploidy alterations of Leishmania chromosomes

We have used a telomere-associated chromosome fragmentation strategy to induce internal chromosome-specific breakage of Leishmania chromosomes. The integration of telomeric repeats from the kinetoplastid Trypanosoma brucei into defined positions of the Leishmania genome by homologous recombination can induce chromosome breakage accompanied by the deletion of the chromosomal part that is distal to the site of the break. The cloned telomeric DNA at the end of the truncated chromosomes is functional and it can seed the formation of new telomeric repeats. We found that genome ploidy is often altered upon telomere-mediated chromosome fragmentation events resulting in large chromosomal deletions. In most cases diploidy is either preserved, or partial trisomic cells are observed, but interestingly we report here the generation of partial haploid mutants in this diploid organism. Partial haploid Leishmania mutants should facilitate studies on the function of chromosome-assigned genes. We also present several lines of evidence for the presence of sequences involved in chromosome mitotic stability and segregation during cell cycle in this parasitic protozoan. Telomere-directed chromosome fragmentation studies in Leishmania may constitute a useful tool to assay for centromere function.     

True vs. false inv(Y)(p11q11.2): a familial instance concurrent with trisomy 21

A boy with Down syndrome due to a free trisomy 21 also had a metacentric Y chromosome with an arm euchromatic and the other heterochromatic inherited from his phenotypically normal father. This chromosome was mitotically stable and hybridized with the DYZ3 probe precisely at its primary constriction; in addition, a subtelomeric Xp/Yp probe gave the expected signal near the end of the euchromatic arm. So, the proband's karyotype was 47,X,inv(Y)(p11q11.2),+21. Given the high frequency of both chromosome anomalies, we regard its concurrence as a mere coincidence. This observation, along with previous reports, allows us to classify the apparent pericentric inversions of the Y chromosome into two types: "true" inversions characterized by an alphoid single centromere and mitotic stability, and "false" inversions in which a nonalphoid centromere has taken over the usual alphoid centromere; indeed, these chromosomes are dicentric and mitotically unstable. Finally, the inv(Y) polymorphism in man compares with that documented in other mammal species, in which the rearranged Y chromosome neither impairs the fertility nor has other phenotypical consequences.     

Complex study of human cell strains with karyotype anomalies. II. Mitotic cycle parameters]

The object of this investigation were the parameters of the mitotic cycle in 14 fibroblasts-like cell strains with chromosome aberrations obtained from skin biopsies of patients and from spontaneous human abortuses. In two strains of embryonal origin (trisomic for chromosome and monosomic for chromosome 21) increased duration of stage G2 of the cell cycle accompanied by a shorter period of DNA synthesis was observed. In the other 5 strains of embryonal origin (two strains trisomic for chromosome 7, strains trisomic for chromosome 9, trisomic for chromosome 14 and triploid strains) no deviations from the normal duration of the stages of the cell cycle were observed. Two types of changes of the mitotic cycle parameters were observed in the cell strains obtained from patients with chromosome aberrations. A considerably prolonged G2 stage was observed in two strains obtained from patients affected by Down's syndrome. Three strains with the karyotypes 47, XXX, 47 XY+18 and 46, XX, 5p-were characterized by a complex of features typical of the strains of embryonal origin. A considerable decrease of the stage G2 duration was observed in these strains. In the strains obtained from a proband with Kleinfelter's syndrome and from a patient with the karyotype 46XX no deviations in the parameters of the cell cycle were observed.     

Phosphorylation of nonhistone proteins during premature chromosome condensation in a temperature-sensitive mutant, tsBN2

In tsBN2 cells, a temperature-sensitive (ts) mutant of the BHK21 cell line, with a ts-defect in its regulatory system for chromosome condensation, antigens that react with mitotic specific mouse monoclonal antibody MPM-2 were produced when premature chromosome condensation (PCC) was induced by a temperature shift. The polypeptides of antigens recognized by MPM-2 in tsBN2 cells with PCC were identical to those of antigens in mitotic cells. These antigens appeared concomitantly with chromosome condensation, which suggests that these mitotic-specific antigens may be related to chromosome condensation. As the production of mitotic-specific antigens was inhibited by W-7, a specific and potent antagonist of calmodulin, calmodulin may function in the mitotic phosphorylation of nonhistone protein.     

Centromere mitotic recombination in mammalian cells

Centromeres are special structures of eukaryotic chromosomes that hold sister chromatid together and ensure proper chromosome segregation during cell division. Centromeres consist of repeated sequences, which have hindered the study of centromere mitotic recombination and its consequences for centromeric function. We use a chromosome orientation fluorescence in situ hybridization technique to visualize and quantify recombination events at mouse centromeres. We show that centromere mitotic recombination occurs in normal cells to a higher frequency than telomere recombination and to a much higher frequency than chromosome-arm recombination. Furthermore, we show that centromere mitotic recombination is increased in cells lacking the Dnmt3a and Dnmt3b DNA methyltransferases, suggesting that the epigenetic state of centromeric heterochromatin controls recombination events at these regions. Increased centromere recombination in Dnmt3a,3b-deficient cells is accompanied by changes in the length of centromere repeats, suggesting that prevention of illicit centromere recombination is important to maintain centromere integrity in the mouse.     

The “happy puppet” syndrome in two siblings

Summary Disomic and trisomic cells of a patient with Down syndrome mosaic were used to study the effect of the additional chromosome 21 against an identical genetic background. The frequency of Ag staining and the participation in satellite associations were determined for each pair of acrocentric chromosomes. The additional chromosome 21 of the trisomic cells and its homologues proved to be regularly Ag positive. Therefore the trisomic cells showed more Ag positive chromosomes and more satellite associations per cell than the diploid cells. Thus, no compensation for the additional rRNA-gene dose could be found in the cells of the trisomic line.     

Identification of novel centromere/kinetochore-associated proteins using monoclonal antibodies generated against human mitotic chromosome scaffolds

We describe the generation of 11 monoclonal antibodies that bind to the centromere/kinetochore region of human mitotic chromosomes. These antibodies were raised against mitotic chromosome scaffolds and screened for centromere/kinetochore binding by indirect immunofluorescence against purified chromosomes. Immunoblot analyses with these antibodies revealed that all of the antigens are greater than 200 kD and are components of nuclei, chromosomes, and/or chromosome scaffolds. Comparison of the immunolocalization of the antigens with that observed for the centromere-associated protein CENP-B revealed that each of these centromere/kinetochore proteins lies more peripherally to the DNA than does CENP-B. In cells normally progressing through the cell cycle, these antigens displayed four distinct patterns of centromere/kinetochore association, corresponding to a minimum of four novel centromere/kinetochore-associated proteins.     

Molecular evidence for true isochromosome 21q

Summary In one family a duplicated 21q was shown to be a true isochromosome, which segregates from mosaic mother to non-mosaic child with full Down syndrome phenotype. Densitometric analysis of Southern blots, using probe pPW228C for the distal long arm of chromosome 21, indicated that the 21q duplication contains two copies of the allele detected by the probe. Maternal mosaic karyotype of 45,XX,-21/46,XX/46, XX,-21,+21i(21q) also suggested transverse mitotic centromere division as the origin of the 21q isochromosomes. Morphologic analysis of chromosome heteromorphisms strengthened this interpretation because the free 21 missing in the cell line with 45 chromosomes was also missing in cells with the isochromosome. In a second family the cytogenetic data also suggested transmission of an i(21q) from mosaic mother to nonmosaic Down syndrome child but molecular evidence did not prove identity of alleles in the duplicated chromosome 21.