A common region of loss of heterozygosity in Wilms' tumor and embryonal rhabdomyosarcoma distal to the D11S988 locus on chromosome 11p15.5

The development of Wilms' tumor has been associated with two genetic loci on chromosome 11: WTI in 11p13 and WT2 in 11p15.5. Here, we have used loss of heterozygosity (LOH) in Wilms' tumors to narrow the WT2 locus distal to the D11S988 locus. A similar region was apparent for the clinically associated tumor, embryonal rhabdomyosarcoma. We have also demonstrated that a constitutional chromosome translocation breakpoint associated with Beckwith-Wiedemann syndrome and an acquired somatic chromosome translocation breakpoint in a rhabdoid tumor each occur in the same chromosomal interval as the smallest region of LOH in Wilms' tumors and embryonal rhabdomyosarcoma. Finally, we report the first Wilms' tumor without a cytogenetic deletion that shows targeted LOH for 11p15 and 11p13 while maintaining germline status for 11p14.     

A tumor chromosome rearrangement further defines the 11p13 Wilms tumor locus.

A sporadic Wilms tumor, WT-21, with an (11;14)-(p13;q23) reciprocal translocation has been identified. The translocation is found in tumor cells, but not in the patients' circulating lymphocytes. Molecular analysis of somatic cell hybrids segregating the derivative translocation chromosomes reveals a submicroscopic interstitial deletion at the translocation breakpoint, as well as a cytologically undetectable interstitial deletion in the nontranslocation chromosome 11, resulting in a homozygous deletion in 11p13. Pulsed-field gel analysis of tumor DNA indicates that the two deletions are indistinguishable, and the homozygously deleted region is less than 875 kb. The homozygously deleted regions of three other sporadic Wilms tumors overlap with the deleted region in WT-21, and the candidate cDNA clone for the 11p13 Wilms tumor gene described by Call et al. (Cell 60, 509-520, 1990) is included in the deleted region. These findings strengthen previous conclusions regarding the obligate location for the 11p13 WT locus and support the suggestion that the Wilms tumor gene has been cloned.     

Familial aniridia and translocation t(4;11)(q22;p13) without Wilms' tumor

A family with dominantly inherited aniridia in three generations is presented. All three patients had an apparently balanced chromosome translocation t(4;11)(q22;p13). The patients were otherwise clinically normal and without signs of Wilms' tumor; their erythrocyte catalase activities were within the normal range. We suggest that in this family aniridia is caused either by a submicroscopic deletion at the translocation breakpoint 11p13 or by a position effect on the same chromosome segment. Furthermore, the loci for aniridia and Wilms' tumor susceptibility are separate. It follows that the WAGR complex is caused by a mutation of more than one gene located at 11p13. The theoretical implications of a presumably defective allele causing a mendelian dominant phenotype are discussed.     

Aniridia-Wilms' tumor association: evidence for specific deletion of 11p13.

A 7-year-old boy with aniridia, Wilms' tumor, and mental retardation, previously reported as having an interstitial deletion of the short arm of chromosome 8 resulting from a t(8p+;11q-) translocation (Ladda et al., 1974), has been restudied using high-resolution trypsin-Giemsa banding of prometaphase chromsomes. The results revealed a complex rearrangement with four break points in 8p, 11p, and 11q, leading to a net loss of an interstitial segment of 11p (region p1407 yields p1304) but not of 8p. His red blood cells contained normal activities of glutathione reductase (gene on 8p) and lactate dehydrogeanse A (gene on 11p12), indicating a gene dosage consistent with the chromosomal findings. The revised interpretation of this case agrees with seven others reported as having aniridia and interstitial 11p deletions in establishing the distal half of band 11p13 as the site of gene(s) which lead to aniridia and predispose to Wilms' tumor if present in a hemizygous state. Possible relationships between heterozygous deletion of specific chromosomal bands 11p13 and 13q14 and the autosomal dominant disorders aniridia, Wilms' tumor, and retinoblastoma, respectively, are discussed.     

Localization of the rhabdomyosarcoma t(2;13) breakpoint on a physical map of chromosome 13.

Previous investigations of the pediatric soft tissue tumor alveolar rhabdomyosarcoma have identified a characteristic translocation t(2;13)(q35;q14). We have employed a physical mapping strategy to localize the site of this translocation breakpoint on chromosome 13. Using a panel of somatic cell hybrid and lymphoblast cell lines with deletions and unbalanced translocations involving chromosome 13, we have mapped numerous probes from the 13q12-q14 region and demonstrate that this region is divisible into five physical intervals. These probes were then mapped with respect to the t(2;13) rhabdomyosarcoma breakpoint by quantitative Southern blot analysis of an alveolar rhabdomyosarcoma cell line with two copies of the derivative chromosome 13 and one copy of the derivative chromosome 2. Our findings demonstrate that the t(2;13) breakpoint is localized within a map interval delimited by the proximal deletion breakpoints in lymphoblast lines GM01484 and GM07312. Furthermore, the breakpoint is most closely flanked by loci D13S29 and TUBBP2 within this map interval. These findings will facilitate chromosomal walking strategies for cloning the regions disrupted by the alveolar rhabdomyosarcoma translocation. In addition, this physical map will permit rapid determination of the proximity of new cloned sequences to the translocation breakpoint.     

Frequent chromosome aberrations revealed by molecular cytogenetic studies in patients with aniridia

Seventy-seven patients with aniridia, referred for cytogenetic analysis predominantly to assess Wilms tumor risk, were studied by fluorescence in situ hybridization (FISH), through use of a panel of cosmids encompassing the aniridia-associated PAX6 gene, the Wilms tumor predisposition gene WT1, and flanking markers, in distal chromosome 11p13. Thirty patients were found to be chromosomally abnormal. Cytogenetically visible interstitial deletions involving 11p13 were found in 13 patients, 11 of which included WT1. A further 13 patients had cryptic deletions detectable only by FISH, 3 of which included WT1. Six of these, with deletions <500 kb, share a similar proximal breakpoint within a cosmid containing the last 10 exons of PAX6 and part of the neighboring gene, ELP4. Two of these six patients were mosaic for the deletion. The remaining four had chromosomal rearrangements: an unbalanced translocation, t(11;13), with a deletion including the WAGR (Wilms' tumor, aniridia, genitourinary abnormalities, and mental retardation) region, and three balanced rearrangements with what appear to be position effect breakpoints 3' of PAX6: (a) a t(7;11) with the 11p13 breakpoint approximately 30 kb downstream of PAX6, (b) a dir ins(12;11) with a breakpoint >50 kb from PAX6, and (c) an inv(11)(p13q13) with a breakpoint >75 kb downstream of PAX6. The proportion and spectrum of chromosome anomalies in familial (4/14, or 28.5%) and sporadic (26/63, or 41%) cases are not significantly different. An unexpectedly high frequency of chromosomal rearrangements is associated with both sporadic and familial aniridia in this cohort.     

Choroideremia associated with an X-autosomal translocation

Summary A patient with mild choroideremia has been shown to carry a balanced translocation between chromosome X and 13 – 46,X,t(X;13)(q21.2;p12). Loci (DXY21, DX232, DX233) shown to map to this region on the X chromosome and in some cases to be deleted in other patients with choroideremia are intact in the DNA from this patient. To our knowledge this is the first report of a translocation associated with choroideremia. One of the translocation chromosomes, derivative 13, free of the derivative X and normal X, has been isolated in a somatic cell hybrid. Because of the clinical association of the eye findings with chromosome interchange, we suggest that the breakpoint on the X is at or near the choroideremia locus. Further analysis of this translocation may be useful in cloning the choroideremia gene.     

Unbalanced translocation t(15;22) in "severe" Prader-Willi syndrome

A 13-year-old girl with an unbalanced karyotype 45,XX,-15,der(22)t(15;22)(q13;q13.3) de novo had Prader-Willi syndrome (PWS), (score 13.5), but with features of mental and physical retardation more severe than usually seen in PWS. The clinical diagnosis of PWS was confirmed by methylation analysis that showed absence of the paternal band. With GTG banding, the cytogenetic breakpoint on chromosome 15q13, with 15q14 intact, encompassed the PWS region, while the breakpoint on 22q was terminal. Investigations with FISH utilised ten different probes/combinations, namely SNRPN/PML, TUPLE1/22q13.3, TUPLE/ARSA, GABRB3, three YAC clones and one cosmid for specific regions within chromosome 15q, painting probes for the long arm of chromosomes 15 and 22 and a pantelomere probe. Deletion of SNRPN,TYAC 9 (at 15q11-12), TYAC19 (at 15q13) and GABRB3 (within the PWS locus), was evident on the derivative (22) chromosome, while TYAC10 (at 15q22), cos15-5 (at 15q22) and PML (15q22) were not deleted. On the der(22), 22q13.3 and ARSA were not deleted, but the most distal non specific pantelomeric probe was deleted. Thus, the severe phenotype could be attributable to deletion on chromosome 15q extending beyond q13 to q14, (further than the usual chromosome 15q deletion (q11-13) in PWS), or be related to loss of the very terminal 22q region (from ARSA to the pantelomere) or be due to genetic factors elsewhere in the genome.     

C-abl and bcr are rearranged in a Ph1-negative CML patient.

Chromosomal analysis of a patient with chronic myelocytic leukemia (CML) revealed a translocation (9;12) (q34;q21) without a detectable Philadelphia chromosome (Ph1). Using molecular approaches we demonstrate (i) a rearrangement within the CML breakpoint cluster region (bcr) on chromosome 22, and (ii) a joint translocation of bcr and c-abl oncogene sequences to the derivative chromosome 12. These observations support the view that sequences residing on both chromosome 9 (c-abl) and 22 (bcr) are involved in the generation of CML and suggest that a subset of Ph1-negative patients may in fact belong to the clinical entity of Ph1-positive CML.     

The QM gene is X-linked and therefore not involved in suppression of tumorigenesis in Wilms' tumor

Summary Inactivation of one or more tumor-suppressor genes on the short arm of chromosome 11 is thought to play a role in the etiology of Wilms' tumor. A candidate gene, QM, was recently isolated by subtractive hybridization between a tumorigenic cell line (deleted for part of 11p) and a non-tumorigenic cell line (the tumorigenic cell line carrying an extra t(X;11)copy). We show here with an exon-specific polymerase chain reaction that the genomic homolog of the QM cDNA is located in the G6PD-color vision genes region in Xq28. No homologous sequences could be detected on 11p. Our experiments indicate that the QM gene is not involved in the suppression of Wilms' tumor.     

Characterization of a translocation within the von Recklinghausen neurofibromatosis region of chromosome 17

The genetic defect causing von Recklinghausen neurofibromatosis (NF1) has been mapped to the proximal long arm of chromosome 17 by linkage analysis. Flanking markers have been identified, bracketing NF1 in 17q11.2 and laying the foundation for isolating the disease gene. Recently, a family in which a mother and her two children show both the symptoms of NF1 and the presence of a balanced translocation, t(1;17)(p34.3;q11.2), has been identified. We have examined the possibility that the translocation has occurred in or near the NF1 gene by constructing a somatic cell hybrid line containing the derivative chromosome 1 (1qter-p34.3::17q11-qter). On chromosome 1, the breakpoint occurred between SRC2 and D1S57, which are separated by 14 cM. The translocation breakpoint was localized on chromosome 17 between D17S33 and D17S57, markers that also flank NF1 within a region of 4 cM. These data are consistent with the possibility that the translocation event is the cause of NF1 in this pedigree. Consequently, the isolation of the translocation breakpoint, by approach from either the chromosome 1 or the chromosome 17 side, may facilitate the identification of the NF1 gene.     

Translocation of oncogene c-sis from chromosome 22 to chromosome 11 in a Ewing sarcoma-derived cell line.

Somatic cell hybrids, obtained after fusion of translocation (11;22)-positive Ewing sarcoma cells and Chinese hamster fibroblasts, were assayed for the presence of immunoglobulin C lambda, Philadelphia chromosome breakpoint cluster region, and c-sis oncogene sequences. It was found that c-sis was translocated from chromosome 22 to chromosome 11 in the Ewing sarcoma cells used, indicating that the breakpoint must be proximal to this locus. Moreover, we found that the chromosome 22-linked C lambda and breakpoint cluster region sequences are not translocated. This result confirms an earlier cytogenetic observation that the Ewing sarcoma-associated breakpoint in chromosome 22 is distal to those observed in translocation (8;22)-positive Burkitt lymphoma and in Philadelphia chromosome-positive chronic myeloid leukemia.     

Cytologically balanced t(2;20) in a two-generation family with alagille syndrome: cytogenetic and molecular studies.

Alagille syndrome is a clinically defined, dominantly inherited disorder affecting the liver, heart, face, eye, and vertebrae. Alagille syndrome has previously been localized to the short arm of chromosome 20, on the basis of reports of a small number of patients with chromosomal deletions of 20p. We undertook a cytogenetic study of patients with Alagille syndrome and identified a family in which a cytologically balanced translocation between chromosomes 2 and 20, 46,XX/XY, t(2;20)(q21.3;p12), is segregating concordantly with the disease. The breakpoint on chromosome 20p in this t(2;20) is consistent with the shortest region of overlap demonstrated in the reported deletion patients. This is the first report of a translocation associated with 20p and Alagille syndrome, and this rearrangement confirms the location of the Alagille disease gene at 20p12. We have established a somatic cell hybrid from a lymphoblastoid cell line from one of the affected individuals that contains the derivative chromosome 20 (20qter-->p12::2q21.3-->qter) but not the derivative chromosome 2, the normal chromosome 2, or the normal chromosome 20. Southern blot and PCR analysis of probes and sequences from 20p have been studied to define the location of the translocation breakpoint. Our results show that the breakpoint lies distal to D20S61 and D20S56 within band 20p12.     

Closely linked loci on the long arm of chromosome 13 flank a specific 2;13 translocation breakpoint in childhood rhabdomyosarcoma

A specific chromosomal translocation, t(2;13)(q35;q14), is present in tumor cells from about one-half of children with alveolar rhabdomyosarcoma, who generally have widely disseminated disease at diagnosis. Using a series of six DNA probes from five loci previously assigned to bands 13q12----q14, we have localized the translocation breakpoint on chromosome 13 by in situ hybridization. Each probe was used to examine metaphase spreads from two or more rhabdomyosarcoma cell lines that have the t(2;13), as well as from control lymphoblastoid cell metaphases. All six probes bound to chromosome 13q12----q14 in the control cell line, but showed no appreciable hybridization to other sites. With rhabdomyosarcoma metaphases, cDNA clones of the retinoblastoma susceptibility gene (RB1) and the esterase D gene (ESD), as well as the arbitrary genomic fragment 7D2 (D13S10), showed specific hybridization to the normal chromosome 13 and the der(2) marker, but not to the der(13). By contrast, the genomic fragments HU10 (D13S6) and 7F12 (D13S1) hybridized specifically to the normal chromosome 13 and the der(13), but not to the der(2). Thus, the breakpoint of this translocation lies distal to D13S6 and D13S1 and proximal to ESD, RB1, and D13S10. Our data indicate that the locus affected by the translocation breakpoint on chromosome 13, which we have termed RMS, is physically distinct from the RB1 locus and is, in fact, proximal to ESD, which others have placed at least 10(6) bp proximal to RB1. The consistent presence of the der(2) marker chromosome, coupled with occasional loss of the der(13), suggests that the RMS gene, or at least a critical component, moves to chromosome 2 in tumors with this translocation.     

Investigations with fluorescence in situ hybridization (FISH) demonstrate loss of the telomeres on the reciprocal chromosome in three unbalanced translocations involving chromosome 15 in the Prader-Willi and Angelman syndromes

Two patients with classical features of Angelman syndrome (AS) and one with Prader-Willi syndrome (PWS) had unbalanced reciprocal translocations involving the chromosome 15 proximal long arm and the telomeric region of chromosomes 7, 8 and 10. Fluorescence isitu hybridization (FISH) was used for the detection of chromosome 15(q11-13) deletions (with probes from the PWS/AS region) and to define the involvement of the telomere in the derivative chromosomes (with library probes and telomere-specific probes). The 15(q11-13) region was not deleted in one patient but was deleted in the other two. The telomere on the derivative chromosomes 7, 8 and 10 was deleted in all three cases. Thus, these are true reciprocal translocations in which there has been loss of the small satellited reciprocal chromosome (15) fragment.     

Molecular analysis of a reciprocal translocation t(5;11)(q11;p13) in a WAGR patient

Summary Most patients with the complex association aniridia — predisposition to Wilms' tumor (WAGR syndrome) present with a de novo constitutional deletion of band 11p13. We report a patient with WAGR syndrome and a reciprocal translocation between chromosomes 5 and 11 t(5;11)(q11;p13). High resolution banding cytogenetic analysis and molecular characterization using 11p13 DNA markers showed a tiny deletion encompassing the gene for CAT but sparing the gene for FSHB. This suggests that syndromes associated with apparently balanced translocations may be due to undetectable loss of material at the breakpoint(s) rather than to breakage in the gene itself.     

Localization of the t(2;13) breakpoint of alveolar rhabdomyosarcoma on a physical map of chromosome 2.

A characteristic translocation t(2;13)(q35;q14) has been previously identified in the pediatric soft tissue tumor alveolar rhabdomyosarcoma. We have assembled a panel of lymphoblast, fibroblast, and somatic cell hybrid cell lines with deletions and unbalanced translocations involving chromosome 2 to develop a physical map of the distal 2q region. Twenty-two probes were localized on this physical map by Southern blot analysis of the mapping panel. The position of these probes with respect to the t(2;13) rhabdomyosarcoma breakpoint was then determined by quantitative Southern blot analysis of an alveolar rhabdomyosarcoma cell line with two copies of the derivative chromosome 13 and one copy of the derivative chromosome 2 and by analysis of somatic cell hybrid clones derived from an alveolar rhabdomyosarcoma cell line. We demonstrate that the t(2;13) breakpoint is situated within a map interval delimited by the distal deletion breakpoint in fibroblast line GM09892 and the t(X;2) breakpoint in somatic cell hybrid GM11022. Furthermore, from a comparison of our data with the linkage map of the syntenic region on mouse chromosome 1, we conclude that the t(2;13) breakpoint is most closely flanked by loci INHA and ALPI within this map interval.     

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.     

Evidence for involvement of TRE-2 (USP6) oncogene, low-copy repeat and acrocentric heterochromatin in two families with chromosomal translocations

We report clinical findings and molecular cytogenetic analyses for two patients with translocations [t(14;17)(p12;p12) and t(15;17)(p12;p13.2)], in which the chromosome 17 breakpoints map at a large low-copy repeat (LCR) and a breakage-prone TRE-2 (USP6) oncogene, respectively. In family 1, a 6-year-old girl and her 5-year-old brother were diagnosed with mental retardation, short stature, dysmorphic features, and Charcot-Marie-Tooth disease type 1A (CMT1A). G-banding chromosome analysis showed a der(14)t(14;17)(p12;p12) in both siblings, inherited from their father, a carrier of the balanced translocation. Chromosome microarray and FISH analyses revealed that the PMP22 gene was duplicated. The chromosome 17 breakpoint was mapped within an ∼383 kb LCR17pA that is known to also be the site of several breakpoints of different chromosome aberrations including the evolutionary translocation t(4;19) in Gorilla gorilla. In family two, a patient with developmental delay, subtle dysmorphic features, ventricular enlargement with decreased periventricular white matter, mild findings of bilateral perisylvian polymicrogyria and a very small anterior commissure, a cryptic duplication including the Miller–Dieker syndrome region was identified by chromosome microarray analysis. The chromosome 17 breakpoint was mapped by FISH at the TRE-2 oncogene. Both partner chromosome breakpoints were mapped on the short arm acrocentric heterochromatin within or distal to the rRNA cluster, distal to the region commonly rearranged in Robertsonian translocations. We propose that TRE-2 together with LCR17pA, located ∼10 Mb apart, also generated the evolutionary gorilla translocation t(4;19). Our results support previous observations that the USP6 oncogene, LCRs, and repetitive DNA sequences play a significant role in the origin of constitutional chromosome aberrations and primate genome evolution.     

Mapping of thec-sis oncogene on human chromosome 22 with respect to the breakpoint associated with chronic myeloid leukaemia

Chronic myeloid leukaemia (CML) cells are often characterized by the presence of a small chromosome 22, in which most of the q arm has been translocated to chromosome 9. Using cell hybrids containing different parts of chromosome 22 I have mapped the c-sis oncogene, which is known to be situated on chromosome 22, to a region distal to the CML breakpoint (22q112) and proximal to 22q13. This demonstrates that c-sis is translocated to chromosome 9 in CML cells.