Efficient identification of marker chromosomes in 27 patients by stepwise hybridization with alpha-satellite DNA probes

Using a procedure involving stepwise hybridization of alpha-satellite DNA probes at various conditions of stringency, 33 marker chromosomes from 27 patients were identified. The markers were ascertained prenatally in fetal amniotic fluid and chorionic villi samples or postnatally in blood from liveborn children. The marker chromosomes first were characterized by cytogenetic techniques and later identified by fluorescence in situ hybridization. There were 14 bisatellited markers, 3 metacentric nonsatellited marker chromosomes, 2 nonsupernumerary sex-chromosomal rings, and 9 patients carrying markers that appeared to be small rings. Multiple stringency conditions were used for the identification of 14 supernumerary ringlike chromosomes detected in 8 patients. Ring-like markers were initially screened at low stringency and grouped into alpha-satellite families. Subsequent higher stringency hybridization led to marker identification. Ringlike chromosomes originated from chromosomes 1, 2, 8, 12, 13 or 21, 14 or 22, 15, 18, and X. Multiple ringlike markers ascertained in a single patient were determined to originate from different chromosomes.     

An unusual dicentric Y chromosome with a functional centromere with no detectable alpha-satellite

We describe an unusual marker chromosome Y. This marker is present in 5% of the lymphocytes of a dysgenetic woman showing a mosaic karyotype 45,X/46,XY/ 47,XY+mar. Q-banding revealed that the marker was morphologically identical to the Y chromosome of the patient but presented the primary constriction in the heterochromatic region. C-banding confirmed that the heterochromatic region was C-positive; furthermore, it showed two spots in the euchromatic region in a position corresponding to that of the centromere in the normal Y Fluorescence in situ hybridization with the centromere-specific probe pDP 97 and the pancentromeric alpha-satellite probe 2730 failed to detect any signal at the primary constriction site. To improve the characterization of the marker chromosome, hybridization was performed using pDP 105, a probe located on the short arm of the Y chromosome, together with chromosome-Y- specific paint-hybridizing to the single sequence spanning the Y short arm. In both cases, positive signals telomeric to the inactive centromere were observed. Possible mechanisms resulting in the formation of the marker chromosome are discussed.     

Evolution of alpha-satellite DNA on human acrocentric chromosomes

In situ hybridization of five new and one previously described alpha-satellite sequences isolated from chromosome 21 libraries gave the following chromosomal distribution patterns: (a) two sequences (pTRA-1 and -4) hybridizing to chromosomes 13, 14, 15, 21, and 22 (also 19 and 20); (b) one sequence (pTRA-7) hybridizing to chromosome 14; and (c) three sequences (pTRA-2, -11 and -15) hybridizing to chromosomes 13, 14, and 21, with significant but weaker signals on 15 and 22. These results suggested the sharing of alphoid domains between different acrocentric chromosomes and the coexistence of multiple domains on each chromosome. Analysis of somatic cell hybrids carrying a single human acrocentric chromosome using pTRA-2 demonstrated a higher-order repeating structure common to chromosomes 13, 14, and 21, but not to 15 and 22, providing direct evidence for sequence homogenization in this domain among the former three chromosomes. We present a model of evolution and genetic exchange of alpha sequences on the acrocentric chromosomes which can satisfactorily explain these and previous observations of (a) two different alphoid subfamilies, one common to chromosomes 13 and 21 and the other common to chromosomes 14 and 22, (b) a different alphoid subfamily on chromosome 22, and (c) nonrandom participation of chromosomes 13 and 14, and 14 and 21 in Robertsonian translocations.     

Integration of human alpha-satellite DNA into simian chromosomes: centromere protein binding and disruption of normal chromosome segregation.

Centromeres of mammalian and other complex eukaryotic chromosomes are dominated by one or more classes of satellite DNA. To test the hypothesis that alpha-satellite DNA, the major centromeric satellite of primate chromosomes, is involved in centromere structure and/or function, human alpha-satellite DNA was introduced into African green monkey (AGM) cells. Centromere protein binding was apparent at the sites of integrated human alpha-satellite DNA. In the presence of an AGM centromere on the same chromosome, human alpha-satellite was associated with bridges between the separating sets of chromatids at anaphase and an increased number of lagging chromosomes at metaphase, both features consistent with the integrated alpha-satellite disrupting normal chromosome segregation. These experiments suggest that alpha-satellite DNA provides the primary sequence information for centromere protein binding and for at least some functional aspect(s) of a mammalian centromere, playing a role either in kinetochore formation or in sister chromatid apposition.     

Discrimination between alpha-satellite DNA sequences from chromosomes 21 and 13 by using polymerase chain reaction.

alpha-Satellite subfamilies from chromosomes 21 and 13 are almost identical in sequence and cannot be distinguished from each other by hybridization techniques. A general method based on membrane-bound PCR is described here, allowing the discrimination of alpha-satellite DNA sequences from each of these two chromosomes, after detection by Southern blot hybridization. The PCR conditions were developed using somatic hybrid DNAs. The method was tested in membrane-bound PCR by using the alpha-satellite bands from a Southern blot of a CEPH family. The chromosomal origin of these bands, previously determined by linkage analysis, was confirmed by this method.     

No detectable misrejoining in double-minute chromosomes.

Pulsed-field gel electrophoresis combined with Southern hybridization and rare-cutting restriction endonuclease digestion has been used recently to quantify misrejoining of DNA double-strand breaks (DSBs) resulting from exposure to ionizing radiation. Measurements are made 24 h after a high dose of radiation. These studies have suggested that a large fraction of DSBs are misrejoined to result in gross rearrangements. In the experiments described here, we show that elimination of broken DNA also eliminates "misrejoined" DNA. Mouse cells resistant to high levels of methotrexate by virtue of 100-fold amplification of the dyhydrofolate reductase (Dhfr) gene were treated with 50 and 100 Gy of ionizing radiation. The cells were allowed to repair the damage for 24 h. After the repair period, the cells were immobilized in agarose. Aliquots of each sample were pre-electrophoresed to remove linear DNA molecules smaller than 6 Mbp resulting from apoptosis or necrosis. The samples repairing damage from 50 or 100 Gy that did not receive the pre-electrophoresis showed high levels of label in a region of the lane that could be due to misrejoining DNA molecules. However, when the DNA from cells undergoing apoptosis or necrosis was removed from these samples, the levels of "misrejoined" DNA were reduced to levels far below those of unirradiated controls. These results suggest that other radiation-induced effects present 24 h after irradiation with 50 or 100 Gy are more significant than misrejoining for altering hybridization to regions of the lane outside the specific bands. Measurements of misrejoining using PFGE, rare-cutting restriction endonucleases, and Southern hybridization are likely to be compromised by nonspecific hybridization to broken and difficult-to-digest DNA resulting from apoptosis or necrosis.     

Quinacrine fluorescence patterns in somatic chromosomes of a t(15q15q) carrier

Summary A sporadic translocation between two homologues of chromosome 15 was identified, by means of the quinacrine mustard fluorescence technique, in a phenotypically normal female infant with ventricular septal defect. Familial studies revealed certain individual variations regarding the intensely fluorescent centromeric regions in chromosomes 3 and 13, which appeared to be transmitted from the parents to offspring.

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Zusammenfassung Eine sporadische Translokation zwischen zwei homologen Chromosomen Nr. 15 wurde mit Hilfe der Quinacrine-Mustard-Fluorescenztechnik bei einem weiblichen Säugling mit Ventrikelseptumdefekt festgestellt, der sonst phänotypisch normal war. Familienuntersuchungen ergaben gewisse individuelle Varianten der Zentromerregion in den Chromosomen 3 und 13, und es wurde eine Vererbung von den Eltern auf ihre Kinder festgestellt.Familienberatungen ergaben gewisse individuelle Variationen der intensiv fluorescierenden Zentromerregion.

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Contributions from the Chromosome Research Unit, Faculty of Science, Hokkaido University, Sapporo, Japan. Supported by grants, No. 584099, and No. 92035, from the Scientific Research Fund of the Ministry of Education.     

Angelman syndrome: three molecular classes identified with chromosome 15q11q13-specific DNA markers

Angelman syndrome (AS) and Prader-Willi syndrome (PWS) share a cytogenetic deletion of chromosome 15q11q13. To determine the extent of deletion in AS we analyzed the DNA of 19 AS patients, including two sib pairs, with the following chromosome 15q11q13--specific DNA markers: D15S9-D15S13, D15S17, D15S18, and D15S24. Three molecular classes were identified. Class I showed a deletion of D15S9-D15S13 and D15S18; class II showed a deletion of D15S9-D15S13; and in class III, including both sib pairs, no deletion was detected. These molecular classes appear to be identical to those observed in PWS. High-resolution cytogenetic data were available on 16 of the patients, and complete concordance between the presence of a cytogenetic deletion and a molecular deletion was observed. No submicroscopic deletions were detected. DNA samples from the parents of 10 patients with either a class I or a class II deletion were available for study. In seven of the 10 families, RFLPs were informative as to the parental origin of the deletion. In all informative families, the deleted chromosome 15 was observed to be of maternal origin. This finding is in contrast to the paternal origin of the deletions in PWS and is currently the only molecular difference observed between the two syndromes.     

Ribosomal DNA is an effective marker of Brassica chromosomes

Simultaneous fluorescence in situ hybridisation with 5S and 25S rDNA probes enables the discrimination of a substantial number of chromosomes of the complement of all diploid and tetraploid Brassica species of the ”U-triangle”, and provides new chromosomal landmarks for the identification of some chromosomes of this genus which were hitherto indistinguishable. Twelve out of 20 chromosomes can be easily identified in diploid Brassica campestris (AA genome), eight out of 16 in Brassica nigra (BB genome), and six out of 18 in Brassica oleracea (CC genome). Furthermore, just two rDNA markers permit 20 out of 36 chromosomes to be distinguished and assigned to either the A or B genomes of the allotetraploid Brassica juncea, and 18 out of 38 chromosomes identified and assigned to the A or C genomes of the allotetraploid Brassica napus. The number of chromosomes bearing rDNA sites in the tetraploids is not in all cases simply the sum of the numbers of sites in their diploid ancestors. This observation is discussed in terms of the phylogeny and variability within the genomes of the species of this group. Received: 13 September 2000 / Accepted: 1 February 2001     

Colorectal cancer linkage on chromosomes 4q21, 8q13, 12q24, and 15q22

A substantial proportion of familial colorectal cancer (CRC) is not a consequence of known susceptibility loci, such as mismatch repair (MMR) genes, supporting the existence of additional loci. To identify novel CRC loci, we conducted a genome-wide linkage scan in 356 white families with no evidence of defective MMR (i.e., no loss of tumor expression of MMR proteins, no microsatellite instability (MSI)-high tumors, or no evidence of linkage to MMR genes). Families were ascertained via the Colon Cancer Family Registry multi-site NCI-supported consortium (Colon CFR), the City of Hope Comprehensive Cancer Center, and Memorial University of Newfoundland. A total of 1,612 individuals (average 5.0 per family including 2.2 affected) were genotyped using genome-wide single nucleotide polymorphism linkage arrays; parametric and non-parametric linkage analysis used MERLIN in a priori-defined family groups. Five lod scores greater than 3.0 were observed assuming heterogeneity. The greatest were among families with mean age of diagnosis less than 50 years at 4q21.1 (dominant HLOD?=?4.51, α?=?0.84, 145.40 cM, rs10518142) and among all families at 12q24.32 (dominant HLOD?=?3.60, α?=?0.48, 285.15 cM, rs952093). Among families with four or more affected individuals and among clinic-based families, a common peak was observed at 15q22.31 (101.40 cM, rs1477798; dominant HLOD?=?3.07, α?=?0.29; dominant HLOD?=?3.03, α?=?0.32, respectively). Analysis of families with only two affected individuals yielded a peak at 8q13.2 (recessive HLOD?=?3.02, α?=?0.51, 132.52 cM, rs1319036). These previously unreported linkage peaks demonstrate the continued utility of family-based data in complex traits and suggest that new CRC risk alleles remain to be elucidated.     

Small marker chromosomes in two patients with segmental aneusomy for proximal 17p

We report a nine-year-old girl (patient 1934) and a five-year-old boy (patient 2170) with small, de novo supernumerary marker chromosomes (SMCs) derived from proximal 17p. The clinical features of patient 1934 include developmental delay, triangular face, prominent forehead, low set ears, dental abnormalities, a high arched palate, long, flexible fingers, and joint laxity. Patient 2170 is affected with developmental delay, oral-motor dyspraxia/verbal apraxia, thick upper and lower lips, bilateral fifth finger clinodactyly, joint laxity and mild hypotonia. G-banded chromosome analysis of patient 1934 revealed mosaicism for a SMC in 72% of peripheral lymphocytes analyzed, whereas analysis of patient 2170 identified a smaller SMC present in 100% of cells analyzed. Fluorescence in situ hybridization (FISH) studies demonstrated that both of the SMCs derived from 17p10-p11.2. Using FISH and array-CGH analysis, the proximal breakpoints mapped within the centromere and the distal breakpoints were both located within the Smith-Magenis syndrome (SMS) common deletion region. We compare the clinical characteristics of our patients with those previously reported to have either SMC including 17p or duplications of proximal 17p in an effort to further delineate the phenotype of trisomy 17p10-p11.2 and to elucidate genotype-phenotype correlations.     

Primed in situ labeling: sensitivity and specificity for detection of alpha-satellite DNA in the centromere regions of chromosomes 13 and 21

The centromeric alpha-satellite DNA subfamilies from chromosomes 13 and 21 are almost identical in sequence. So far it has proven difficult to discriminate between sequence variations in the chromosome 13 and 21 alpha-satellite regions using in situ techniques. To analyze whether the method of modified single-color and double-color PRINS could be used to detect single nucleotide polymorphisms within this region, we used previously published primers D13Z and D21Z that differ in the terminal 3'-nucleotide and an additionally constructed primer "D13/21-test" lacking the final nucleotide at the 3' end. The results show that a one-base pair mismatch at the 3' end is sufficient to be detected by PRINS. Surprisingly, only about 35% of our samples exhibited the expected combination of two chromosomes 13 specifically labeled with only primer D13Z and two chromosomes 21 specifically labeled with only primer D21Z. The rest of the samples showed a polymorphic distribution of the target sequence for the primers, therefore these primers are not suited for routine detection of chromosomes 13 and 21 during interphase. Our data indicate that an interchromosomal exchange of alpha-satellite DNA takes place between chromosomes 13 and 21, possibly due to a concerted evolution process.     

Ordered-subsets linkage analysis detects novel Alzheimer disease loci on chromosomes 2q34 and 15q22

Alzheimer disease (AD) is a complex disorder characterized by a wide range, within and between families, of ages at onset of symptoms. Consideration of age at onset as a covariate in genetic-linkage studies may reduce genetic heterogeneity and increase statistical power. Ordered-subsets analysis includes continuous covariates in linkage analysis by rank ordering families by a covariate and summing LOD scores to find a subset giving a significantly increased LOD score relative to the overall sample. We have analyzed data from 336 markers in 437 multiplex (>/=2 sampled individuals with AD) families included in a recent genomic screen for AD loci. To identify genetic heterogeneity by age at onset, families were ordered by increasing and decreasing mean and minimum ages at onset. Chromosomewide significance of increases in the LOD score in subsets relative to the overall sample was assessed by permutation. A statistically significant increase in the nonparametric multipoint LOD score was observed on chromosome 2q34, with a peak LOD score of 3.2 at D2S2944 (P=.008) in 31 families with a minimum age at onset between 50 and 60 years. The LOD score in the chromosome 9p region previously linked to AD increased to 4.6 at D9S741 (P=.01) in 334 families with minimum age at onset between 60 and 75 years. LOD scores were also significantly increased on chromosome 15q22: a peak LOD score of 2.8 (P=.0004) was detected at D15S1507 (60 cM) in 38 families with minimum age at onset >/=79 years, and a peak LOD score of 3.1 (P=.0006) was obtained at D15S153 (62 cM) in 43 families with mean age at onset >80 years. Thirty-one families were contained in both 15q22 subsets, indicating that these results are likely detecting the same locus. There is little overlap in these subsets, underscoring the utility of age at onset as a marker of genetic heterogeneity. These results indicate that linkage to chromosome 9p is strongest in late-onset AD and that regions on chromosome 2q34 and 15q22 are linked to early-onset AD and very-late-onset AD, respectively.     

The role of unequal crossover in alpha-satellite DNA evolution: a computational analysis.

Human DNA consists of a large number of tandem repeat sequences. Such sequences are usually called satellites, with the primary example being the centromeric alpha-satellite DNA. The basic repeat unit of the alpha-satellite DNA is a 171 bp monomer. Arbitrary monomer pairs usually have considerable sequence divergence (20-40%). However, with the exception of peripheral alpha-satellite DNA, monomers can be grouped into blocks of k-monomers (4 < or = k < or = 20) between which the divergence rate is much smaller (e.g., 5%). Perhaps the simplest and best understood mechanism for tandem repeat array evolution is unequal crossover. Although it is possible that alpha-satellite sequences developed as a result of subsequent unequal crossovers only, no formal computational framework seems to have been developed to verify this possibility. In this paper, we develop such a framework and report on experiments which imply that pericentromeric alpha-satellite segments (which are devoid of higher order structure) are evolutionarily distinct from the higher order repeat segments. It is likely that the higher order repeats developed independently in distinct regions of the genome and were carried into their current locations through an unknown mechanism of transposition.     

Centromeric protein bodies on avian lampbrush chromosomes contain a protein detectable with an antibody against DNA topoisomerase II

In the oocyte nuclei (germinal vesicle or GV) of a variety of avian species, prominent spherical entities termed protein bodies (PBs) arise at the centromeric regions of the lampbrush chromosomes (LBCs). In spite of the obvious protein nature of PBs, nothing is known about their composition. We show that an antibody against DNA topoisomerase II (topo II), the DNA unwinding enzyme, recognizes PBs from chaffinch and pigeon oocytes. In later chaffinch oocytes, the PBs fuse to form a karyosphere, which is also labeled by the anti-topo II antibody. Furthermore, we show that proteins characteristic of Cajal bodies and B-snurposomes are not found in PBs, despite morphological similarities among these structures. Using immunoelectron microscopy and immunofluorescent laser scanning microscopy we demonstrated that topo II localizes predominantly in the dense material of PBs. Two antigens of 170 kDa (which corresponds to topo II) and 100 kDa were revealed with the antibody against topo II on immunoblots of avian GV proteins. We propose that the smaller protein results from oocyte specific topo II cleavage, since it was not detected in nuclei from testis cells. This represents the first report of a defined protein in the centromeric PBs on avian LBCs.