Sequence analysis of the breakpoint regions of an X;5 translocation in a female with Duchenne muscular dystrophy.

X;autosome translocations in females with Duchenne muscular dystrophy (DMD) provide an opportunity to study the mechanisms responsible for chromosomal rearrangements that occur in the germ line. We describe here a detailed molecular analysis of the translocation breakpoints of an X;autosome reciprocal translocation, t(X;5)(p21;q31.1), in a female with DMD. Cosmid clones that contained the X-chromosome breakpoint region were identified, and subclones that hybridized to the translocation junction fragment in restriction digests of the patient's DNA were isolated and sequenced. Primers designed from the X-chromosomal sequence were used to obtain the junction fragments on the der(X) and the der(5) by inverse PCR. The resultant clones were also cloned and sequenced, and this information used to isolate the chromosome 5 breakpoint region. Comparison of the DNA sequences of the junction fragments with those of the breakpoint regions on chromosomes X and 5 revealed that the translocation arose by nonhomologous recombination with an imprecise reciprocal exchange. Four and six base pairs of unknown origin are inserted at the exchange points of the der(X) and der(5), respectively, and three nucleotides are deleted from the X-chromosome sequence. Two features were found that may have played a role in the generation of the translocation. These were (1) a repeat motif with an internal homopyrimidine stretch 10 bp upstream from the X-chromosome breakpoint and (2) a 9-bp sequence of 78% homology located near the breakpoints on chromosomes 5 and X.     

Mapping of four translocation breakpoints within the Duchenne muscular dystrophy gene

There are over 20 females with Duchenne or Becker muscular dystrophy (DMD or BMD) who have X-autosome translocations that break the X chromosome within band Xp21. Several of these translocations have been mapped with genomic probes to regions throughout the large (approximately 2000 kb) DMD gene. In this report, a cDNA clone from the 5' end of the gene was used to further map the breakpoints in four X-autosome translocations. A t(X;21) translocation in a patient with BMD and a t(X;1) translocation in a patient with DMD were found to break within a large 110-kb intron between exons 7 and 8. Two other DMD translocations, t(X;5) and t(X;11), were found to break between the first and the second exon of the gene within a presumably large intron (greater than 100 kb). These results demonstrate that all four translocations have disrupted the DMD gene and make it possible to clone and sequence the breakpoints. This will in turn determine whether these translocations occur by chance in these large introns or whether there are sequences that predispose to translocations.     

Mapping of 12 translocation breakpoints in the Xp21 region with respect to the locus for Duchenne muscular dystrophy

Over 20 females have been reported to carry reciprocal X; autosome translocations with breakpoints in Xp21 and to suffer from Duchenne muscular dystrophy (DMD). We have positioned nine of these breakpoints with respect to the Duchenne gene by mapping probes from the DMD region against a panel of somatic cell hybrids, each containing one of the translocation chromosomes from a different female patient; further information has also been obtained by in situ hybridization, including the breakpoint location in a tenth DMD patient. We have also characterized two translocation breakpoints that lie in the same chromosomal region but which are not associated with the expression of DMD. All the DMD-associated translocation breakpoints examined lie at several sites within the DMD locus and between the two non-DMD breakpoints.     

Localisation of the endpoints of deletions in the 5'' region of the Duchenne gene using a sequence isolated by chromosome jumping.

We have used chromosome jumping technology to move from within a large intron sequence in the Duchenne muscular dystrophy (DMD) gene to a region adjacent to exons of the gene. The single copy jump clone, HH1, was used to characterise deletions in patients previously shown to be deleted for DNA markers in the 5' end of the gene. 12 out of 15 such patients have breakpoints which lie between HH1 and the genomic locus J-47. Thus the vast majority of the deletions in these patients have proximal breakpoints in a similar region distal to the 5' end of the gene. HH1 was mapped with respect to the X;1 translocation in a DMD female and was shown to lie at least 80 kb from the starting point of the chromosome jump, HIP25.     

Genomic rearrangements resulting in PLP1 deletion occur by nonhomologous end joining and cause different dysmyelinating phenotypes in males and females

In the majority of patients with Pelizaeus-Merzbacher disease, duplication of the proteolipid protein gene PLP1 is responsible, whereas deletion of PLP1 is infrequent. Genomic mechanisms for these submicroscopic chromosomal rearrangements remain unknown. We identified three families with PLP1 deletions (including one family described elsewhere) that arose by three distinct processes. In one family, PLP1 deletion resulted from a maternal balanced submicroscopic insertional translocation of the entire PLP1 gene to the telomere of chromosome 19. PLP1 on the 19qtel is probably inactive by virtue of a position effect, because a healthy male sibling carries the same der(19) chromosome along with a normal X chromosome. Genomic mapping of the deleted segments revealed that the deletions are smaller than most of the PLP1 duplications and involve only two other genes. We hypothesize that the deletion is infrequent, because only the smaller deletions can avoid causing either infertility or lethality. Analyses of the DNA sequence flanking the deletion breakpoints revealed Alu-Alu recombination in the family with translocation. In the other two families, no homologous sequence flanking the breakpoints was found, but the distal breakpoints were embedded in novel low-copy repeats, suggesting the potential involvement of genome architecture in stimulating these rearrangements. In one family, junction sequences revealed a complex recombination event. Our data suggest that PLP1 deletions are likely caused by nonhomologous end joining.     

Molecular cytogenetic characterization of 17 rob(13q14q) Robertsonian translocations by FISH, narrowing the region containing the breakpoints.

We have characterized 17 rob(13q14q) Robertsonian translocations, using six molecular probes that hybridize to the repetitive sequences of the centromeric and shortarm regions of the five acrocentric chromosomes by FISH. The rearrangements include six de novo rearrangements and the chromosomally normal parents, five maternally and three paternally inherited translocations, and three translocations of unknown origin. The D21Z1/D13Z1 and D14Z1/D22Z1 centromeric alpha-satellite DNA probes showed all rob(13q14q) chromosomes to be dicentric. The rDNA probes did not show hybridization on any of the 17 cases studied. The pTRS-47 satellite III DNA probe specific for chromosomes 14 and 22 was retained around the breakpoints in all cases. However, the pTRS-63 satellite III DNA probe specific for chromosome 14 did not show any signals on the translocation chromosomes examined. In 16 of 17 translocations studied, strong hybridization signals on the translocations were detected with the pTRI-6 satellite I DNA probe specific for chromosome 13. All parents of the six de novo rob(13q14q), including one whose pTRI-6 sequence was lost, showed strong positive hybridization signals on each pair of chromosomes 14 and 13, with pTRS-47, pTRS-63, and pTRI-6. Therefore, the translocation breakpoints in the majority of rob(13q14q) are between the pTRS-47 and pTRS-63 sequences in the p11 region of chromosome 14 and between the pTRI-6 and rDNA sequences within the p11 region of chromosome 13.     

Jumping translocations in spontaneous abortions

Chromosome translocations involving one donor chromosome and multiple recipient chromosomes have been referred to as jumping translocations (JTs). Acquired JTs are commonly observed in cancer patients, mainly involving chromosome 1. Constitutional forms of JTs mostly involve the acrocentric chromosomes and their satellites and have been reported in patients with clinical abnormalities. Recognizable phenotypes resulting from these events have included Down, Prader-Willi, and DiGeorge syndromes. The presence of JTs in spontaneous abortions has not been previously described. The breakpoints of all JTs occur in areas rich in repetitive DNA (telomeric, centromeric, and nucleolus organizing regions). We report two different unstable chromosome rearrangements in samples derived from spontaneous abortions. The first case involved a chromosome 15 donor. The recipient chromosomes were 1, 9, 15, and 21, and the respective breakpoints were in either the heterochromatic regions or the centromeres. FISH studies confirmed that the breakpoints of the jumping 15 rearrangement did not involve the Prader-Willi region but originated at the centromere or in the proximal short arm. A second case of instability was observed with a rearrangement resulting from a presumed de novo 8;21 translocation. Three JT cell lines were observed. They consisted of a deleted 8p chromosome, a dicentric 8;21 translocation, and an 8q isochromosome. The instability regions appeared to be at the pericentromeric region of chromosome 8 and the satellite region of chromosome 21. Both cases proved to be de novo events. The unstable nature of the JT resulting in chromosomal imbalance most likely contributed to the fetal loss. It appears that JT events may predispose to chromosomal imbalance via nondisjunction and chromosomal rearrangement and, therefore, may be an unrecognized cause of fetal loss.     

Translocation breakpoint mapping and sequence analysis in three monosomy 1p36 subjects with der(1)t(1;1)(p36;q44) suggest mechanisms for telomere capture in stabilizing de novo terminal rearrangements

Monosomy 1p36 results from a variety of chromosome rearrangements, including terminal deletions, interstitial deletions, derivative chromosomes, and complex rearrangements. Our previous molecular studies on a large cohort of monosomy 1p36 subjects suggest that a significant percentage of terminal deletions of 1p36 are stabilized by the acquisition of telomeric sequences from other chromosome ends, forming derivative chromosomes (i.e., telomere capture). However, the molecular mechanism(s) that results in and/or stabilizes terminal deletions of 1p36 by telomere capture is poorly understood. In this report, we have mapped the translocation breakpoints in three subjects with der(1)t(1;1)(p36;q44) chromosomes by fluorescence in situ hybridization (FISH). These results indicate that the breakpoint locations are variable in all three subjects, with no common 1p deletion or 1q translocation breakpoints. In addition, sequence analysis of the 1p and 1q breakpoint-containing clones did not identify homologous sequences or low-copy repeats in the breakpoint regions, suggesting that nonallelic homologous recombination did not play a role in mediating these rearrangements. Microsatellite marker analysis indicates that two of the three derivative chromosomes were formed by intra-chromosomal rearrangements. These data are consistent with a number of recent reports in other model organisms that suggest break-induced replication at the site of a double-strand break may act as a mechanism of telomere capture by generating nonreciprocal translocations from terminally deleted chromosomes. Alternative models are also discussed.     

Prenatal and postnatal characterization of a de novo Xq22.1 terminal deletion

We present a case of a de novo Xq22.1 chromosomal terminal deletion discovered prenatally by conventional cytogenetics. The pregnancy resulted in the birth of a normal girl. Preferential inactivation of the abnormal X was demonstrated postnatally. Fluorescence in situ hybridization (FISH) demonstrated a terminal Xq deletion spanning Xq22.1 -->qter. An X painting probe ruled out a translocation. The deleted X chromosome was determined to be of paternal origin. The girl is now 4 years old with normal physical and psychomotor development. X chromosomal deletions are infrequent findings in prenatal diagnosis and present a difficult counseling challenge when they occur. Prenatal X-inactivation studies provide an opportunity for more informative genetic counseling when a de novo X chromosome deletion is detected.     

Isolation of a conserved sequence deleted in Duchenne muscular dystrophy patients.

We have isolated a DNA sequence (HIP25) by subtraction- hybridisation which is deleted in a number of Duchenne muscular dystrophy (DMD) patients. HIP25 is conserved in evolution and hybridises to human fetal and adult muscle mRNA. HIP25 is absent in human fetal fibroblast mRNA. Physical mapping data localise this sequence within Xp21 between the breakpoints of X;autosome translocations found in two females suffering from the disease. HIP25 is a candidate exon sequence for the basic defect in DMD boys deleted at this locus.     

Unbalanced 1q whole-arm translocation resulting in der(14)t(1;14)(q11-12;p11) in myelodysplastic syndrome

Unbalanced whole-arm translocations (WATs) of the long arm of chromosome 1, resulting in complete trisomy 1q, are chromosomal abnormalities detectable in both solid tumors and hematologic neoplasms. Among the WATs of 1q to acrocentric chromosomes, a few patients with der(1;15) described as a dicentric chromosome have been reported so far, whereas cases of der(1;14) are much rarer. We report on a case of der(1;14) detected as single anomaly in a patient with myelodysplastic syndrome. The aim of our work was to investigate the breakpoints of the (1;14) translocation leading to the der(1;14). Fluorescence in situ hybridization (FISH) experiments have been performed on chromosome preparations from bone marrow aspirate, using specific centromeric probes of both chromosomes, as well as a probe mapping to 1q11 band. FISH results showed that in our patient the derivative chromosome was monocentric with a unique centromere derived from chromosome 14. The breakpoints of the translocation were located in the short arm of chromosome 14 and in the long arm of chromosome 1, between the alphoid D1Z5 and the satellite II domains. The 1q breakpoint was within the pericentromeric region of chromosome 1, which is notoriously an unstable chromosomal region, involved in different chromosomal rearrangements.     

A highly complex chromosomal rearrangement between five chromosomes in a healthy female diagnosed in preparation for intracytoplasmatic sperm injection.

We report a case of a de novo complex chromosomal rearrangement among five chromosomes found in a clinically healthy woman. The only indication for chromosome analysis was a planned intracytoplasmatic sperm injection. Physical examination, including internal and external genitals, and ovaries and hormone status were normal. Banding cytogenetics showed a rearrangement among chromosomes #3, #4, #7, #9, and #17. Twenty-four-color fluorescence in situ hybridization and multicolor banding were applied to characterize the translocations and breakpoints more precisely. This confirmed the involved chromosomes and revealed two breakpoints in chromosome #4. This six-breakpoint rearrangement [der(3)t(3;4), der(4)t(17;4;7), der(7)t(3;7), der(9)t(4;9), and der(17)t(9;17)] seemed to be balanced on a molecular cytogenetic level, although submicroscopic deletions or duplications close to the breakpoints cannot be excluded.     

Duchenne muscular dystrophy due to familial Xp21 deletion detectable by DNA analysis and flow cytometry

Summary We report two male cousins with Duchenne muscular dystrophy (DMD) in whom cytogenetic studies have shown a small interstitial deletion at Xp21. The lesion is readily detectable in patients and carriers by flow cytometry which indicates that approximately 6000 kb of DNA are deleted in each case. The DNA markers OTC, C7, and B24 are present in the deleted X chromosome but 87-8, 87-1, and 754 are absent. Despite apparently identical deletions one affected boy has profound mental handicap while the other is only mildly retarded. The results confirm the assignment of familial DMD to Xp21 and illustrate the value of flow cytometry in improving the precision of chromosome analysis. We have also undertaken flow cytometry in a cell line from a previously reported DMD patient with a de novo Xp21 deletion who had, in addition, chronic granulomatous disease, retinitis pigmentosa, and the McLeod syndrome. The results indicate that the amount of DNA deleted from the X is similar in both families despite the striking differences in phenotype.     

Molecular and cytogenetic characterization of a de novo t(5p;21q) in a patient previously diagnosed as monosomy 21.

Genomic single-copy DNA fragments were used to characterize an undetected chromosome translocation in an individual whose metaphase chromosome analysis revealed apparent monosomy 21. Eight RFLPs detected by six probes were used to identify homologous sequences from chromosome 21 in DNA digests from the proband and her parents. These family studies showed that the proband was disomic for the distal region of 21q. Reverse banding and in situ hybridization of chromosome 21-specific probes to metaphase chromosomes from the proband revealed a de novo translocation with breakpoints at 5p13 or 14 and 21q11 or 21. In situ hybridization permitted orientation of the translocated portion of chromosome 21 on the derivative chromosome 5 and, in conjunction with molecular analysis and previous mapping studies, refined the physical map for the long arm of chromosome 21.     

De novo balanced complex chromosome rearrangement (CCR) involving chromosome 8, 11 and 16 in a boy with mild developmental delay and psychotic disorder

Congenital Complex Chromosome rearrangements (CCRs) compatible with life are rare in humans. We report a de novo CCR involving chromosomes 8, 11 and 16 with 4 breakpoints in a patient with mild dysmorphic features, acquisition delay and psychotic disorder. Conventional cytogenetic analysis revealed an apparently balanced 8;16 translocation. Further FISH analysis with WCP 8 and WCP 16 probes revealed the presence of a third chromosome involved in the translocation. The multicolour karyotype confirmed the complexity of the rearrangement and showed that the derivative chromosome 8 was composed of 3 distinct segments derived from chromosomes 8, 16 and 11. The breakpoints of this complex rearrangement were located at 8q21, 11q14, 11q23 and 16q12. Comparative genomic hybridization (CGH) and array-CGH were performed to investigate the possibility of any genomic imbalance as a result of the complex rearrangement. No imbalance was detected by these two techniques. Our study showed: i) the necessity to confirm reciprocal translocations with FISH using painting probes, particularly when the karyotype resolution is weak; ii) the usefulness of multicolour karyotype for the characterization of structural chromosomal rearrangements, particularly when they are complex; iii) the usefulness of CGH and array-CGH in cases of abnormal phenotype and apparently balanced rearrangement in order to explore the breakpoints and to detect additional imbalances.     

The generation of DNA probes to chromosome 11q23 by Alu PCR on small numbers of flow-sorted 22q- derivative chromosomes

A strategy for the isolation of DNA probes from small numbers of flow-sorted human chromosomes has been developed. A lymphoblastoid cell line carrying the 22q- derivative chromosome product of the constitutional t(11;22) translocation was used as the source of chromosomes. Synthetic oligonucleotide primers, based on the consensus Alu sequence, were used to amplify inter-Alu sequence from 500 flow-sorted 22q- derivative chromosomes. The amplified sequences were cloned into a plasmid vector by blunt-end ligation, yielding clones with inserts in the range of 400 to 1000 bp. Approximately 70% of these clones hybridized to human DNA as single-copy probes. To identify clones derived from chromosome 11, the library was screened with a heterogeneous probe prepared by Alu-PCR amplification from the DNA of a somatic cell hybrid containing one homology of chromosome 11. All the positive clones found were mapped to within the q23-q25 region of chromosome 11 known to be translocated onto the 22q- derivative chromosome. Further mapping studies showed that most of these probes (7/8) lay between the breakpoints for the t(4;11) translocation of acute lymphocytic leukemia and the t(11;22) of Ewing sarcoma. Thus, the use of Alu-PCR on the small derivative chromosome 22q- has provided a greatly enriched source of probes to region 11q23, a part of the genome that is currently of great interest. This approach will be particularly appropriate to small numbers of chromosomes when high specificity rather than total representation is required.     

Physical mapping of nine Xq translocation breakpoints and identification of XPNPEP2 as a premature ovarian failure candidate gene

Women with balanced translocations between the long arm of the X chromosome (Xq) and an autosome frequently suffer premature ovarian failure (POF). Two "critical regions" for POF which extend from Xq13-->q22 and from Xq22-->q26 have been identified using cytogenetics. To gain insight into the mechanism(s) responsible for ovarian failure in women with X;autosome translocations, we have molecularly characterized the translocation breakpoints of nine X chromosomes. We mapped the breakpoints using somatic cell hybrids retaining the derivative autosome and densely spaced markers from the X-chromosome physical map. One of the POF-associated breakpoints in a critical region (Xq25) mapped to a sequenced PAC clone. The translocation disrupts XPNPEP2, which encodes an Xaa-Pro aminopeptidase that hydrolyzes N-terminal Xaa-Pro bonds. XPNPEP2 mRNA was detected in fibroblasts that carry the translocation, suggesting that this gene at least partially escapes X inactivation. Although the physiologic substrates for the enzyme are not known, XPNPEP2 is a candidate gene for POF. Our breakpoint mapping data will help to identify additional candidate POF genes and to delineate the Xq POF critical region(s).     

Localization of DNA sequences to a region within Xp11.21 between incontinentia pigmenti (IP1) X-chromosomal translocation breakpoints.

Incontinentia pigmenti (IP) is an X-linked dominant disorder characterized by developmental anomalies of the tissues and organs derived from embryonic ectoderm and neuroectoderm. An IP locus, designated IP1, probably resides in Xp11.21, since five unrelated patients with nonfamilial IP have been identified who possess constitutional de novo reciprocal X;autosome translocations involving Xp11.21. We have used a series of somatic cell hybrids containing the rearranged chromosomes derived from three of the five IP1 patients, along with other hybrid cell lines, to map probes in the vicinity of the IP1 locus. Five anonymous DNA loci--DXS422, DXS14, DXS343, DXS429, and DXS370--have been mapped to a region within Xp11.21, between two IP1 X-chromosomal translocation breakpoints; the IP1 t(X;17) breakpoint is proximal (centromeric) to this region, and the IP1 t(X;13) and t(X;9) X-chromosomal breakpoints lie distal to it. While no IP1 translocation breakpoint has yet been identified by pulsed-field gel electrophoretic (PFGE) analysis, an overlap between three probes--p58-1, 7PSH3.5, and cpX210--has been detected, placing these probes within 125 kb. Four probes--p58-1, 7PSH3.5, cpX210, and 30CE2.8--have been helpful in constructing a 1,250-kb PFGE map of the region between the breakpoints; these results suggest that the IP1 X-chromosomal translocation breakpoints are separated by at least this distance. The combined somatic cell hybrid and PFGE analyses we report here favor the probe order DXS323-(IP1 t(X;13), IP1, t(X;9]-(DXS422, DXS14, DXS343, DXS429, DXS370)-(IP1 t(X;17), DXZ1). These sequences provide a starting point for identifying overlapping genomic sequences that span the IP1 translocation breakpoints; the availability of IP1 translocation breakpoints should now assist the cloning of this locus.