Origin of a paternal (13q; 15q) translocation leading to dup(13q) in two half sibs

We report on two half-sibs, a male and a female with dup(13)(q1405 → qter) that resulted from a der(15),t(13;15)(15qter → 15q25::13q1405 → 13qter), h +, pat. Their manifestations were similar to those with duplication of the distal half 13q. The father was a balanced de novo translocation carrier. Since the der(15) had a long secondary constriction, it was possible to trace the site of the mutation to the germ cell of the patients paternal grandmother who had this distinctive long secondary constriction in one of her normal 15 chromosomes.     

15q duplication associated with autism in a multiplex family with a familial cryptic translocation t(14;15)(q11.2;q13.3) detected using array-CGH

Autism spectrum disorders (ASDs) are a group of neurodevelopmental disorders with a strong genetic aetiology. In approximately 1% of cases, duplication of the 15q11-13 region has been reported. We report the clinical, array-comparative genomic hybridization (CGH) and cytogenetic evaluation of two individuals from a multiplex family demonstrating autism due to a maternally inherited gain of 15q11-13. Our findings indicate that unlike most 15q11-13 gains, which are caused by interstitial duplication of this region or supernumerary marker chromosomes deriving from proximal 15q, the 15q gain in this family is the result of abnormal segregation of a cryptic familial translocation with breakpoints at 14q11.2 and 15q13.3. The affected members of this family were found to have a normal karyotype at >550 band resolution. This translocation was identified using the 1-Mb resolution whole genome array (Spectral Genomics). The affected individuals have a gain of seven clones from proximal 15q, a loss of two clones from proximal 14q and a gain of two clones from 6q. Fluorescent in situ hybridization (FISH) analysis with clones from chromosomes 14 and 15, combined with DAPI reverse banding, showed an abnormal karyotype with one normal chromosome 15 and the der(15) t(14;15)(q11.2.;q13.3), resulting in the gain of proximal 15q and the loss of proximal 14q in affected individuals. The duplication of two clones from 6q in the affected subjects was also found in unaffected members of the family. Our findings suggest that the gain of 15q in autism may in some cases be due to cryptic translocations with breakpoints in the pericentromic regions of chromosome 15 and a different acrocentric chromosome. Variation in the size of pericentromic regions of any acrocentric chromosome may justify karyotype and FISH studies of autistic probands and their parents using probes from the 15q proximal region to determine recurrence risk for autism in some families.     

Unbalanced translocation 46,xy,−15,+der(22)t(15;22)(q13;q11)pat: Case report and review of the literature

We present a boy with a rare unbalanced translocation 46,XY,?15,+der(22),t(15;22)(q13;q11) pat. Previous reports of similar chromosome findings mention only the Prader-Willi phenotype. At birth, his manifestations included severe hypotonia and lethargy, (typical of deletion of 15pter→q13); hypertelorism, down-slanting small palpebral fissures, preauricular tags, long philtrum (typical of duplication of 22pter→q11); severe laryngotracheo-malacia, and proximal implantation of the thumb. In a review of the literature on chromosome abnormalities involving duplication of 22q11 the associated clinical phenotype consists of mild mental retardation, microcephaly, hypotonia, hypertelorism, down-slanting palpebral fissures, a long philtrum, cleft or highly arched palate, and ear abnormalities. Preauricular pits or tags are common. Cardiovascular defects, renal and genital problems and dislocated hips are frequently present. Anal atresia and colobomata are mainly seen in cat-eye syndrome, the phenotype associated with idic 22q11. Our findings indicate that patients with unbalanced t(15;22) can have manifestations of the dup 22q11, in addition to the previously reported Prader-Willi phenotype, even if the duplicated segment is small. © 1992 Wiley-Liss, Inc.     

Neuroblastoma in a boy with MCA/MR syndrome,deletion 11q,and duplication 12q

Deletion 11q23→qter and duplication 12q23→qter are described in a boy with neuroblastoma, multiple congenital anomalies, and mental retardation. The patient has clinical manifestations of 11q deletion and 12q duplication syndromes. The possible involvement of the segment 11q23→24 in the cause of the neuroblastoma is discussed. © 1995 Wiley-Liss, Inc.     

Partial duplication 8q12→q21.2 in two sibs with maternally derived insertional and reciprocal translocations

We report on two sibs with duplication of the segment 8ql2→8q21.2 resulting from malsegregation of a maternal insertional translocation: [inv ins (5;8)(pl3;ql2q2l.2)]. The mother also carries a reciprocal translocation [t (l;6)(q31;q5)], which was transmitted in the balanced state to the propositi and to a phenotypically normal son and daughter. The literature on two translocations occurring in one individual and on insertional rearrangements is reviewed in terms of reproductive risks to balanced carriers. The two affected infants have a previously undescribed partial duplication of an interstitial segment of 8q and a pattern of abnormalities distinct from those seen in other partial duplications of 8. These infants are reviewed with 78 other cases of partial duplication of chromosome 8 with regard to phenotype-karyotype correlations.     

Duplication of distal 22q

We report on three patients with duplication of distal 22q. One patient is a de novo carrier of the translocation t(21;22) (p13;q11), the other two are offspring of a translocation carrier t(10;22) (q26;q12). The clinical manifestations of these patients demonstrate the variability of the dup(22q) syndrome.     

De novo inverted interstitial (“mirror”) duplication of chromosome 8(q13→q24.1) in a liveborn male

We report on a newborn boy with a de novo inverted interstitial duplication of chromosome 8(q13→q24.1). This form of cytogenetic abnormality, in which a mirror image interstitial duplication has occurred, is exceedingly rare. Review of the literature and mechanisms to explain the origin of this type of chromosome aberration are presented. A review of the findings from individuals with partial dup(8q) demonstrate remarkable similarity to the infant we describe.     

The 11q23 breakpoint in acute leukemia with t(11;19)(q23;p13) is distal to those of t(4;11), t(6;11) and t(9;11).

Thirteen cosmid probes were mapped on the long arm of chromosome 11 between 11q22 and 11q24 by nonradioactive in situ hybridization. Starting with these localizations and those of other probes mapped to 11q23, four acute leukemias with translocations involving 11q23 were studied with the same method. The translocation breakpoints of the t(4;11)(q21;q23), t(6;11)(q27;q23), t(9;11)(p21-p22;q23), and t(11;19)(q23;p13) were confirmed to be distal to CD3D. The probe cC111-304 was proximal to the t(11;19) breakpoint while distal to the breakpoints of the other rearrangements. In view of the diversity of chromosomal abnormalities involving band 11q23, our finding extends the molecular heterogeneity of the breakpoint localization in leukemias with rearrangements involving 11q23.     

Segregation of a familial balanced (12;10) insertion resulting in dup(10)(q21.2q22.1) and del(10)(q21.2q22.1) in first cousins

An interchromosomal insertion in 3 generations of a family was ascertained through two developmentally delayed first cousins. Cytogenetic analysis using G-banding and chromosome painting showed an apparently balanced direct insertion of chromosome 10 material into chromosome 12, ins(12;10)(q15;q21.2q22.1), in the mothers and grandfather of these children. The proposita inherited only the derivative 10 chromosome, resulting in deletion of 10q21.2 → 22.1 while her cousin inherited only the derivative 12, resulting in duplication of 10q21.2 → 22.1. A comparison of the proposita with published deletion cases suggests a pattern of anomalies attributable to deletion of the 10q21 → q22 region: developmental delay, hypotonia, a heart murmur, telecanthus, broad nasal root and ear abnormalities. This is the first report of a nontandem duplication of the 10q21 → q22 region. The phenotype of the cousin with the duplication does not overlap greatly with published tandem 10q duplications. Finally, this report reaffirms the importance of obtaining family studies of patients with interstitial chromosomal abnormalities. Am J. Med. Genet. 69:188–193, 1997. © 1997 Wiley-Liss, Inc.     

Interstitial duplications of chromosome region 15q11q13: Clinical and molecular characterization

Duplications of chromosome region 15q11q13 often occur as a supernumerary chromosome 15. Less frequently they occur as interstitial duplications [dup(15)]. We describe the clinical and molecular characteristics of three patients with de novo dup(15). The patients, two males and one female (ages 3–21 years), had nonspecific findings that included autistic behavior, hypotonia, and variable degrees of mental retardation. The extent, orientation, and parental origin of the duplications were assessed by fluorescent in situ hybridization, microsatellite analyses, and methylation status at D15S63. Two patients had large direct duplications of 15q11q13 [dir dup(15)(q11q13)] that extended through the entire Angelman syndrome/Prader-Willi syndrome (AS/PWS) chromosomal region. Their proximal and distal breaks, at D15S541 or D15S9 and between D15S12 and D15S24, respectively, were comparable to those found in the common AS/PWS deletions. This suggests that duplications and deletions may be the reciprocal product of an unequal recombination event. These two duplications were maternally derived, but the origin of the chromatids involved in the unequal crossing over in meiosis differs. In one patient, the duplication originated from two different maternal chromosomes, while in the other patient it arose from the same maternal chromosome. The third patient had a much smaller duplication that involved only D15S11 and parental origin could not be determined. There was no obvious correlation between phenotype and extent of the duplication in these patients. Am. J. Med. Genet. 79:82–89, 1998. © 1998 Wiley-Liss, Inc.     

Malformation syndrome of duplication 12q24.1→qter

While duplication and deletion of the short arm of chromosome 12 cause well-recognized syndromes, duplication of the long arm of chromosome 12 is rarely observed. We are reporting a duplication of chromosome 12 distal to band q24.1 in a five-month-old child. His chromosome constitution is 46,XY,-4, + der(4),t(4:12)(p16;q24.1)mat. The balanced translocation is also carried by his maternal grandmother and two of the mother's brothers. The malformation syndrome consisted of unusual facial appearance and anomalies of the musculoskeletal, cardiovascular, genitourinary, and central nervous systems. Four previously reported patients had similar break points on chromosome 12 with similar malformations; therefore, phenotype-karyotype correlation suggests a definitive malformation syndrome associated with duplication of chromosome region 12q24.1→qter.     

Cryptic duplication of the distal segment of 22q due to a translocation (21;22): three case reports and a review of the literature

Duplications of the proximal segment of chromosome 22q are not uncommon, like Cat-eye syndrome and duplications due to familial (11;22) translocations. However, duplications of the distal long arm of chromosome 22 (22qter) seem to be exceedingly rare. So far, duplications of 22q12 or 22q13 to 22qter have been described in 21 patients, of whom 13 had a pure duplication 22qter. Here we report on three new cases with a pure duplication of the distal part of 22q. The first patient carries a duplication of terminal 22q due to a de novo unbalanced translocation, 46,XX,der(21)t(21;22) (p13;q13.2), detected by NOR-staining, while the other patients have a familial cryptic duplication of terminal 22q due to an unbalanced translocation, 46,XY,der(21)t(21;22)(p10;q13.3). The last two patients were initially thought to have a polymorphic variant of 21p, but additional subtelomeric screening using FISH showed the extra material was derived from chromosome 22. Terminal duplications of 22qter may be more common than generally assumed, but due to its small size, especially when located on an acrocentric chromosome and/or possibly relatively mild phenotype remain undetected thus far.     

Unbalanced translocation 46,XY,-15,+der(22)t(15;22)(q13;q11)pat: case report and review of the literature.

We present a boy with a rare unbalanced translocation 46,XY,-15,+der(22),t(15;22)(q13;q11) pat. Previous reports of similar chromosome findings mention only the Prader-Willi phenotype. At birth, his manifestations included severe hypotonia and lethargy, (typical of deletion of 15pter----q13); hypertelorism, down-slanting small palpebral fissures, preauricular tags, long philtrum (typical of duplication of 22pter----q11); severe laryngotracheomalacia, and proximal implantation of the thumb. In a review of the literature on chromosome abnormalities involving duplication of 22q11 the associated clinical phenotype consists of mild mental retardation, microcephaly, hypotonia, hypertelorism, down-slanting palpebral fissures, a long philtrum, cleft or highly arched palate, and ear abnormalities. Preauricular pits or tags are common. Cardiovascular defects, renal and genital problems and dislocated hips are frequently present. Anal atresia and colobomata are mainly seen in cat-eye syndrome, the phenotype associated with idic 22q11. Our findings indicate that patients with unbalanced t(15;22) can have manifestations of the dup 22q11, in addition to the previously reported Prader-Willi phenotype, even if the duplicated segment is small.     

Partial duplication of 3q (q25.1→q26.1) without the Brachmann-de Lange phenotype

Partial duplications of chromosome 3 have previously been reported to have phenotypic characteristics similar to Brachmann-de Lange syndrome (BDLS). We present the case of a 13-Year-old girl with an apparent duplication in the 3q25.1→q26.1 region but none of the manifestations commonly seen in BDLS. The chromosome 3 duplication was confirmed with a FISH painting probe of the involved region. These results suggest that the region critical for Brachmann-de Lange syndrome is not within the duplicated region of 3q25.1→q26.1. © 1993 Wiley-Liss, Inc.     

INTERPHASE FLUORESCENCE IN SITU HYBRIDIZATION DETECTION OF t(2;13)(q35;q14) IN ALVEOLAR RHABDOMYOSARCOMA—A DIAGNOSTIC TOOL IN MINIMALLY INVASIVE BIOPSIES

The identification of t(2;13)(q35;q14) is a useful aid in the accurate diagnosis of rhabdomyosarcoma, distinguishing it from other small round cell tumours and supporting the distinction between alveolar and embryonal forms. Cytogenetic analysis is difficult and with the increased use of minimally invasive biopsy methods and primary chemotherapy, adequate tumour material is not always available. To overcome these difficulties, two-colour interphase fluorescence in situ hybridization (FISH) to detect t(2;13)(q35;q14) was developed and its utility in assessing minimally invasive biopsies was investigated. Two cosmid clones which mapped proximal or distal to the breakpoint region 13q14 and one yeast artificial chromosome clone that mapped distal to the 2q35 breakpoint were identified. In interphase cells containing t(2;13)(q35;q14), the configuration of cosmid and yeast artificial chromosome signals demonstrated the presence of the translocation. Five cases of rhabdomyosarcoma were analysed by interphase FISH. The t(2;13)(q35;q14) was detected in all four alveolar tumours and was confirmed by cytogenetics in two cases, but was absent in one embryonal tumour. This sensitive detection method is applicable to minimal amounts of fresh or frozen tumour.     

A new case of dup(3q) syndrome due to a pure duplication of 3qter

The characteristic clinical features of the dup(3q) syndrome include typical facial features, mental and growth retardation, and (often) congenital heart anomalies. However, pure duplication of 3qter is rare because most of the reported cases are patients who carry an unbalanced translocation and, in addition to the duplication for 3qter, have a deletion for another chromosomal segment. A new case with a pure duplication of 3q detected in a 2-month-old boy is presented here. Extensive cytogenetic analysis revealed an inverted duplication of the distal part of 3q (chromosomal band 3q26.3 up to the telomere), with no (detectable) loss of the original telomeric sequences. Clinical evaluation revealed several phenotypic hallmarks characteristic for the dup(3q) syndrome. By comparing the duplicated region of this patient with the duplicated regions of the other patients with a pure duplication of 3q, we were able to localize the critical region for the dup(3q) phenotype to band 3q26.3. Alongside this new case with a pure duplication of 3q, an overview of six previous cases is given.     

Duplication of distal 22q

We report on three patients with duplication of distal 22q. One patient is a de novo carrier of the translocation t(21;22) (p13;q11), the other two are offspring of a translocation carrier t(10;22) (q26;q12). The clinical manifestations of these patients demonstrate the variability of the dup(22q) syndrome.     

A maternal de novo non-reciprocal translocation results in a 6q13-q16 deletion in one offspring and a 6q13-q16 duplication in another

Here we report a case of two siblings with reciprocal aberrations, one presenting with a deletion and the other carrying two novel duplications at 6q13q16.1. Interestingly, both alterations were inherited from a healthy mother carrying a non-reciprocal translocation of 6q13q16 to 15q11. Deletions at 6q13q16.1 have been previously described; however this is the first characterisation of a 6q13q16.1 duplication. In this report we provide a comprehensive molecular and phenotypical characterisation of the affected siblings and discuss the profiles of previously identified patients carrying 6q deletions.     

Cryptic subtelomeric translocations in the 22q13 deletion syndrome

Cryptic subtelomeric rearrangements are suspected to underlie a substantial portion of terminal chromosomal deletions. We have previously described two children, one with an unbalanced subtelomeric rearrangement resulting in deletion of 22q13→qter and duplication of 1qter, and a second with an apparently simple 22q13→qter deletion. We have examined two additional patients with deletions of 22q13→qter. In one of the new patients presented here, clinical findings were suggestive of the 22q13 deletion syndrome and FISH for 22qter was requested. Chromosome studies suggested an abnormality involving the telomere of one 22q (46,XX,?add(22)(q13.3)). FISH using Oncor D22S39 and Vysis ARSA probes confirmed a terminal deletion. A multi-telomere FISH assay showed a signal from 19qter on the deleted chromosome 22. Results were confirmed with 19qtel and 22qtel specific probes. The patient is therefore trisomic for 19qter and monosomic for 22qter. The patient''s mother was found to have a translocation (19;22)(q13.42;q13.31). We also re-examined chromosomes from two patients previously diagnosed with 22q deletions who were not known to have a rearrangement using the multi-telomere assay. One of these patients was found to have a derivative chromosome 22 (der(22)t(6;22)(p25;q13)). No evidence of rearrangement was detected in the other patient. Thus we have found the 22q13 deletion to be associated with a translocation in three of four patients. This report illustrates the usefulness of examining patients with hypotonia, severe language delay, and mild facial dysmorphism for this syndrome and suggests that most of these deletions may be unbalanced subtelomeric rearrangements.     

A 15 → 1 translocation in a patient mosaic for presence or absence of an isodic(15p)(q11)

We report a patient with a 15 → 1 translocation who was mosaic for presence or absence of an isodic(15p)(q11). Her phenotype is similar to that of patients with deletions of proximal 15q or isodic(15p). Several phenotypes, including the Prader-Labhart-Willi syndrome, have been described with abnormalities of proximal 15q and have in common severe hypotonia, developmental delay, and lack of major congenital anomalies. Our patient is the first to be described with an isodic (15p)(q11) associated with a nonreciprocal translocation. We think her isodic(15p)(q11) arose as a result of a sister chromatid fusion rather than nonsister chromatid exchange as has been proposed in most other cases. Because of the various phenotypes described with proximal 15q abnormalities, we recommend caution in the assignment of specific phenotypes to small chromosome changes in this area.