Cytogenetic studies of familial Prader-Willi syndrome

Summary A family in which two first cousins were found to have the Prader-Willi syndrome was investigated cytogenetically. Although G-banding analysis of metaphase chromosomes failed to demonstrate abnormality, close analyses on the fine prometaphase bands by G-banding and the DA-DAPI bands by double stainings revealed a distinct chromosome abnormality in this family. A reciprocal translocation, rep(14:15)(q11.2;q13), was detected in three family members: the mother, the maternal grandmother, and a maternal uncle of the proband. And, the proband and one of the first cousins had an unbalanced translocation that was derived from their carrier parents. The karyotypes of the affected cousins were determined as 46,XY or XX,-15,+der(14),rcp(14;15)(q11.2;q13). Therefore, they were considered to have an identical cytogenetic abnormality: a partial trisomy of the 14pterq11.2 segment and a partial monosomy of the 15pterq13 segment. Detailed clinical features of the proband and his affected cousin are described, main features associated with the Prader-Willi syndrome having been observed in both cousins. These observations support a definite relationship between the Prader-Willi syndrome and chromosome 15.     

Senescence and human chromosome changes

Summary A girl with slight psychomotor retardation, microphthalmia, and colobomata of the left eye, a hypotrophy of the right arm and a surnumerary digit on the right hand is described. The routine chromsome analysis and a G-banding analysis revealed an elongated long arm of chromosome 10. An extra light and dark band was present proximally. Both parents had normal chromosomes. While the visual comparison of the abnormal with the normal chromosome 10, did not enable the extra bands of the normal bands q21 and q22 to be distinguished. However, measurements of length, surface area, and relative reflection of the different light and dark bands of the long arm on tracings or directly on the normal and abnormal chromosomes, enabled us to precisely locate the extra bands and to determine that the abnormal chromosome was a result of an insertional translocation. The value of such measurements is discussed.     

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.     

Interstitial deletion of 16(q13q22) in a newborn resulting from a paternal insertional translocation.

A dysmorphic newborn showed an interstitial deletion of the long arm of a chromosome 16 due to a balanced paternal insertional translocation 46,XY,ins(14;16)(q23;q13q22). The insertion was confirmed by chromosomal in situ suppression (CISS-) hybridization. Clinical features considered to be typical for a 16q- phenotype are demonstrated in this patient. Similar observations described in the literature are compared and discussed with reference to the phenocritical region.     

Inverted duplication of JH associated with chromosome 14 translocation and T-cell leukemia in ataxia-telangiectasia.

A specific 14q32 breakpoint is observed in a homologous chromosome 14 translocation [t(14;14)q12q32] occurring in the T-cells of about 10% of patients with ataxia-telangiectasia (AT). To investigate whether the 14q32 breakpoint in AT occurs within the immunoglobulin gene cluster as is frequently detected in B-cell lymphoma, immunoglobulin clones were hybridized to Southern blots of DNA isolated from the T-cells of two AT patients with this chromosome 14 translocation. The 14q32 translocation breakpoints in these patients are apparently not within JH, S mu, C mu, S alpha-1 or -2, or C alpha-1 or -2, but one of the patients has an inverted duplication of at least 26 kilobases (kb) of the C mu region, with an associated 5' flanking deletion. The point of origin of the inverted duplication is within JH near the recombination signal for the J4 gene. This suggests that normal JH recombination mechanisms may have played a role in the development of this 14q32 chromosomal aberration. The presence of AT chromosomal breakpoints near other rearranging genes suggests a role for exaggerated recombination in the pathogenesis of chromosomal instability in AT.     

T-lymphocytes with 7;14 translocations: frequency of occurrence, breakpoints, and clinical and biological significance.

Among 11,915 consecutive patients and 37 normal controls who had chromosome analysis at the Mayo Clinic between 1978 and 1984, 83 had a single sporadic metaphase with a 7;14 translocation. In 81 of the translocations, the breakpoints were at 14q11 and either 7q34 (type I) or 7p13 (type II): type I translocations occurred in 42 patients, and type II, in 39. The two other translocations had different breakpoints: one was t(7;14)(q11;q32), and the other was t(7;14)(p13;q32). All type I and type II translocations occurred in phytohemagglutinin-stimulated lymphocyte cultures; their combined incidence was 4.88 X 10(-4) per metaphase (81 of 165,991 metaphases) in such cultures. No type I or II translocation was found among 6,713 fibroblast metaphases, 33,463 amniocyte metaphases, or 68,972 bone marrow and unstimulated peripheral blood metaphases. One variant 7;14 translocation occurred in a phytohemagglutinin-stimulated culture, and the other occurred in a fibroblast culture. We did not find a correlation of sporadic 7;14 translocations with any month or season of the year or with patient age or sex. Of the 83 patients, 78 had various clinical disorders, three had ataxia-telangiectasia, one was a normal control, and one was an artificial insemination donor. Follow-up studies on 64 (77%) patients indicate that, to date, none have developed any malignant process subsequent to chromosome analysis. Except for ataxia-telangiectasia, the occurrence of types I and II translocations in lymphocyte cultures may have little, if any, clinical significance. The biological significance of these translocations may be the association of genes in chromosome bands 14q11, 7p13, and 7q34 with the normal physiology of lymphocytes such as the alpha- and beta-chains for T-cell antigen receptor.     

A complex chromosomal rearrangement with a translocation 4;10;14 in a fertile male carrier: ascertainment through an offspring with partial trisomy 14q13-->q24.1 and partial monosomy 4q27-->q28 [corrected

Complex chromosomal rearrangements (CCRs) are usually associated with infertility or subfertility in male carriers. If fertility is maintained, there is a high risk of abnormal pregnancy outcome. Few male carriers have been identified by children presenting with mental retardation/congenital malformations (MR/CM) or by spontaneous abortions of the spouses. We report a de novo CCR with five breakpoints involving chromosomes 4, 10 and 14 in a male carrier who was ascertained through a son presenting with MR/CM due to an unbalanced karyotype with partial trisomy 14 and partial monosomy 4. The child has a healthy elder brother. In the family history no abortions were reported. No fertility treatment was necessary. Cytogenetic analysis from the affected son showed a reciprocal translocation t(4;10) with additional chromosomal material inserted between the translocation junctions in the derivative chromosome 10. The father showed the same derivative chromosome 10 but had additionally one aberrant chromosome 14. Further molecular cytogenetic analyses determined the inserted material in the aberrant chromosome 10 as derived from chromosome 14 and revealed a small translocation with material of chromosome 4 inserted into the derivative chromosome 14. Thus the phenotype of the son is supposed to be associated with a partial duplication 14q13-->q24.1 and a partial monosomy 4q27-->q28. Including our case we are aware of eleven CCR cases with fertile male carriers. In eight of these families normal offspring have been reported. We propose that exceptional CCRs in fertile male carriers might form comparatively simple pachytene configurations increasing the chance of healthy offspring.     

A detailed analysis of chromosomal changes in heritable and non-heritable retinoblastoma

Summary Full cytogenetic analysis of 27 different retinoblastoma tumors is presented. Gross aneuploidy of chromosome arms 6p and 1q were very common, being observed in 15/27 and 21/27 tumors, respectively. However, we found that chromosome 13 was rarely missing: only 3/27 had a detectable monosomy affecting 13q14. Monosomy of chromosome 13 by small deletion or rearrangement was also not observed in any of 12 retinoblastoma tumor lines analyzed detail at the 300–400 chromosome band level. A novel observation in retinoblastoma was the discovery of non-random translocations at three specific breakpoints, 14q32 (4/12), 17p12 (5/12), and 10q25 (3/12). Genomic rearrangements similar to those described involving C-myc in Burkitt lymphoma 14q+ cells could not be demonstrated in the four 14q+ retinoblastoma lines using molecular techniques, and a probe mapping to the site implicated to have an activating role in lymphoma. These data suggest that there is a target for rearrangement at 14q32 but it is not the same sequence used in some Burkitt lymphomas. Two other breakpoints (2p24 and 8q24) coincided with the mapped position of cellular oncogenes, but also failed to show a molecular rearrangement with the oncogene probes. The breakpoints, 10q25 and 17p12, are constitutional fragile sites which may predispose these regions to act as acceptors of translocations in malignant cells. One line had double minute chromosomes, and was the only one of 16 (6%) tested with the N-myc probe which had an amplification. Different tumors from single patients with multifocal heritable retinoblastoma showed independent karyotype evolution. Unilateral non-heritable tumors exhibited a high level of karyotype stability throughout both in vivo and in vitro growth. The various common patterns of aneuploidy and translocations probably confer an early selective advantage to malignant cells, rather than induce malignant transformation.     

A case of insertional translocation resulting in partial trisomy 16p

This report concerns the case of a boy with partial trisomy 16p resulting from the insertional translocation of the short arm of chromosome 16 into the long arm of chromosome 1 in his father. He was referred for genetic testing because of mental retardation, short stature, microcephaly, seizures and multiple dysmorphic features. Chromosome analysis performed in the child demonstrated the presence of additional material in the long arm of chromosome 1. Paternal high resolution chromosome analysis and fluorescence in situ hybridisation revealed the following karyotype: 46,XY,ins(1;16)(q42;p13.1p13.3), while the karyotype of the boy is 46,XY,der(1),ins(1;16)(q42;p13.1p13.3)pat. This is the first reported case of partial trisomy 16p due to paternal insertional translocation.     

A rare insertional translocation of proximal segment with heterochromatic region of 1q into 7p in monozygotic twins and spontaneous abortions

Summary We present a family identified through a healthy 20-year-old female with a history of multiple successive spontaneous abortions. Her karyotype demonstrates a rare balanced insertional translocation between chromosomes 1 and 7, 46,XX,dir ins(7;1)(p15.3;q12q21.3). This is the first reported case of a 7;1 insertional translocation involving the proximal segment of chromosome 1 and may well be the cause of the multiple spontaneous abortions in our proband.     

Trisomy 3p syndrome. Report of a new case, due to a chromosomal insertion

A new case of the trisomy 3p syndrome is described. The propositus showed mental and growth retardation and many of the congenital anomalies typical of this syndrome. Chromosome analysis in the propositus revealed an enlarged short arm of chromosome 4. In the mother a similar chromosome 4 was found and, in addition, an abnormal chromosome 3 with a deleted short arm. The karyotype of the mother was interpreted as resulting from a balanced insertional translocation. GTG bands p21 and p22 of chromosome 3 were inserted into the short arm of chromosome 4.     

Trisomy 6q22 leads to 6qter due to maternal 6;21 translocation. Case report review of the literature

Partial trisomy for the long arm of chromosome 6, involving 6q22 leads to 6qter, was observed in a 2-month-old male infant. The mother was 6q;21p translocation carrier. A review of the previously published cases with trisomies of different 6q segments suggests that the critical segment responsible for the clinically recognizable phenotype of 6q trisomy seems to be limited to bands 6q26 and/or 6q27.     

Human T-cell tumours containing chromosome 14 inversion or translocation with breakpoints proximal to immunoglobulin joining regions at 14q32.

T-cell tumours are frequently found to carry an inversion of chromosome 14 (inv(14)) (q11;q32) or more rarely a chromosome 14 translocation t(14;14) with the same cytogenetic breakpoints (q11;q32). We have examined the molecular junctions of an inv(14) and a translocation t(14;14) using T-cell receptor (TCR) alpha joining (J) region probes. Both of these chromosomal abnormalities have breakpoints within the TCR J alpha locus at 14q11 and both have breakpoints which are proximal (i.e. on the centromeric side) to the immunoglobulin heavy chain JH region at 14q32. The cloned segments corresponding to the junctions at 14q32 are not associated with obvious immunoglobulin-like sequences. This contrasts to the previously described inv(14) in the cell line SUP-T1 and places a potential cluster of chromosome 14 breakpoints downstream of the Ig JH locus. The possible role of the varying breakpoints in the development of these tumours is discussed.     

Translocation t(1; 14) and rearrangement of the gene for the alpha chain of the T-cell receptor in acute T-lymphoblastic leukemia

A t(1; 14) (p32; q11) translocation has been found by the cytogenetic study of a T cell acute lymphoblastic leukemia patient. Molecular hybridization with a probe (D14S7) which recognizes a fragment of the alpha chain T receptor gene has shown a rearranged EcoRI 11.0 kb band in addition to the germline 3 and 8 kb bands. This translocation infrequently described until now is a new example of an alpha chain gene rearrangement in T cell malignancy. Moreover the breakpoint on chromosome 1 may also involve the newly isolated protooncogene, L-myc, normally localized on the chromosomal band 1 p32.     

Maternal uniparental disomy 22 has no impact on the phenotype.

A 25-year-old normal healthy male was karyotyped because five of his wife's pregnancies terminated in spontaneous abortions at 6-14 wk of gestation. Cytogenetic investigation disclosed a de novo balanced Robertsonian t(22q;22q) translocation. Molecular studies revealed maternal only inheritance for chromosome 22 markers. Reduction to homozygosity for all informative markers indicates that the rearranged chromosome is an isochromosome derived from one of the maternal chromosomes 22. Except for the possibility of homozygosity for recessive mutations, maternal uniparental disomy 22 does not seem to have an adverse impact on the phenotype, apart from causing reproductive failure. It can be concluded that no maternally imprinted genes with major effect map to chromosome 22.     

Detection of structural abnormalities in spermatozoa of a translocation carrier t(3;11)(q27.3;q24.3) by triple FISH

Structural chromosome abnormalities in spermatozoa represent an important category of paternally transmittable genetic damage. A couple was referred to our centre because of repetitive abortions and the man was found to be a carrier of a reciprocal translocation t(3;11)(q27.3;q24.3). A tailored fluorescence in situ hybridisation (FISH) approach was developed to study the meiotic segregation patterns in spermatozoa from this translocation carrier. A combination of three DNA probes was used, a centromeric probe for chromosome 11, a cosmid probe for chromosome 11q and a YAC probe for chromosome 3q. The frequency of spermatozoa carrying an abnormal chromosome constitution was compared with baseline frequencies in control semen specimens and it was found that a significantly higher percentage of spermatozoa carried an abnormal constitution for the chromosomes involved in the translocation. A normal or balanced chromosome constitution was found in 44.3% of the analysed spermatozoa, while the remainder exhibited an abnormal chromosome constitution reflecting different modes of segregation (15.9% adjacent I segregation, 6.5% adjacent II segregation, 28.9% 3 : 1 segregation, 0.8% 4 : 0 segregation, 3.6% aberrant segregation). The frequency of aneuploidy for chromosomes X, Y, 13 and 21 was assessed using specific probes but there was no evidence of interchromosomal effects or variations in the sex ratio in spermatozoa from the translocation carrier. In conclusion, structural aberrations can be reliably assessed in interphase spermatozoa using unique DNA probe cocktails, and this method provides insight into the genetic constitution of germ cells and enables evaluation of potential risks for the offspring. Received: 19 September 1997 / Accepted: 27 October 1997     

Precise localization of NF1 to 17q11.2 by balanced translocation.

A female patient is described with von Recklinghausen neurofibromatosis (NF1) in association with a balanced translocation between chromosome 17 and 22 [46,XX,t(17;22)(q11.2;q11.2)]. The breakpoint in chromosome 17 is cytogenetically identical to a previously reported case of NF1 associated with a 1;17 balanced translocation and suggests that the translocation events disrupt the NF1 gene. This precisely maps the NF1 gene to 17q11.2 and provides a physical reference point for strategies to clone the breakpoint and therefore the NF1 gene. A human-mouse somatic cell hybrid was constructed from patient lymphoblasts which retained the derivative chromosome 22 (22pter----22q11.2::17q11.2----17qter) but not the derivative 17q or normal 17. Southern blot analysis with genes and anonymous probes known to be in proximal 17q showed ErbA1, ErbB2, and granulocyte colony-stimulating factor (CSF3) to be present in the hybrid and therefore distal to the breakpoint, while pHHH202 (D17S33) and beta crystallin (CRYB1) were absent in the hybrid and therefore proximal to the breakpoint. The gene cluster including ErbA1 is known to be flanked by the constitutional 15;17 translocation breakpoint in hybrid SP3 and by the acute promyelocytic leukemia (APL) breakpoint, which provides the following gene and breakpoint order: cen-SP3-(D17S33,CRYB1)-NF1-(CSF3,ERBA1, ERBB2)-APL-tel. The flanking breakpoints of SP3 and API are therefore useful for rapidly localizing new markers to the neurofibromatosis critical region, while the breakpoints of the two translocation patients provide unique opportunities for reverse genetic strategies to clone the NF1 gene.     

Fine mapping of the gene for autosomal dominant juvenile-onset glaucoma with iridogoniodysgenesis in 6p25-tel

Glaucoma is a group of ocular disorders leading to reduced visual capabilities and sometimes blindness. The biochemical defect is unknown but it is shown that reduced drainage of the aqueous humour from the anterior chamber may lead to increased intraocular pressure and gradual atrophy of the optic neurons. Families with various forms of autosomal dominant (AD) glaucoma have been linked to 1q21-31, 2cen-q13, 4q25-27, and 13q14 and autosomal recessive congenital glaucoma have been localized to chromosome 1p36 and 2p21. Recently, a locus for AD iridogoniodysgenesis anomaly (IGDA) was mapped to chromosome 6p25. This study refines the localization of IGDA to an approximately 6–cM interval between D6S1600 and D6S1617/D6S1713 at 6p25-tel, based on recombinations in affected individuals with AD juvenile-onset glaucoma and concomitant iridogoniodysgenesis. Received: 5 May 1997 / Accepted: 15 June 1997     

Human chromosome hot points

Summary Peripheral lymphocytes from 16 healthy adults, 9 pregnant women, and 3 fragile X syndrome patients were cultured in Eagle's minimum essential medium without folic acid (MEM-FA). The addition of 2mM, 4mM, or 8mM uridine 24h or 72h prior to harvest resulted in increases of chromosome gaps or breaks, especially at hot points 3p14, 16q23-24, and at fragile site Xq27. Pregnant women showed higher frequencies of 3p14 breaks and total chromosome breaks than men and non-pregnant women. The other chromosome regions, such as 6q26, 7q23, 7q35, 6p25, Xp22, 14q23 and 11p13, also frequently showed gaps or breaks. The results indicated that the unbalance of nucleotide pools was one of the causes of chromosome breakages. The higher frequencies of chromosome gaps and breaks under the condition of thymidylate stress may be due to the misincorporation of uracil instead of thymine into DNA.     

Interchromosomal insertions

In five families with questionable chromosome rearrangements, we identified an interchromosomal insertion by fluorescent in situ hybridization (FISH). In case 1 with a dir ins (5;11)(p14;q14q24) in three generations, the mentally retarded and microcephalic proband showed a 5p14-->pter deletion. In case 2, a duplication (13)(q21.31--> q31.2) combined with a deletion (11)(q14-->q22) segregated from a reciprocal ins(11;13)(q14q122)(q21.32q31.2), causing a mixed phenotype with psychomotor retardation, caput quadratum, choanal atresia, and pes equinovarus. In case 3, a dir ins (18;5)(q21.3;p13.1p14) was associated with spontaneous abortions, in case 4, the proband with mental retardation, microcephaly, and a heart defect showed a pure trisomy of (12)(q13-->q15), which had segregated from a carrier of an ins (18;12)(p11.3;q13q15). In case 5, a duplication of (10)(q26.3-->q25.2) segregated from an inv ins(5;10)(q15;q26.3q25.2), which was passed on directly from a mother to her son,with mental retardation. In all families the elucidation of the insertional translocation (IT) considerably increased the associated genetic risks of carriers. For the review, we collected data from 81 articles on 87 IT probands on ascertainment, origin, familial transmittance, progeny, and genetic risks of IT carriers. We also discussed the recombinant chromosomes and complex rearrangements associated with ITs, and listed chromosome regions occurring solely as deletions, or solely as duplications, or as both to facilitate genotype/phenotype correlations. We conclude that ITs are rare chromosomal rearrangements with an 1:80,000 incidence, of which nearly 80% were referred because of congenital abnormalities and mental retardation. A maternal origin was seen in 59.5%, a paternal origin in 26.6%, and 13.9% were de novo. No notable difference in fertility between male and female IT carriers was noticed. Bias of ascertainment was excluded in 15 familial cases and led to an estimate of the genetic risks for IT carriers of 32.0-36.0%. The mean size of the inserted regions occurring solely as duplications (n=39) measures 0.96% of the haploid autosomal length (HAL), and of regions solely occurring as deletions (n=14) 0.47% HAL. In the families where both aneusomies occurred, the size of the insertions ranged between 0.22 and 1.21% HAL. Overall, the findings fit with the general idea that a surplus of genetic material is tolerated more easily than a deficiency.