Maternal complex chromosome rearrangement ascertained through a del (13)(q12.1q14.1) detected in her mildly affected daughter.

A maternal complex chromosome rearrangement (CCR) involving chromosomes 2, 13, and 20 was ascertained in a normal female through the diagnosis of a deletion of 13q in her daughter. The child has mild clinical features and developmental delay consistent with proximal deletions of 13q that do not extend into band q32 and a del(13)(q12q14.1) that does not involve the retinoblastoma locus by FISH. Maternal studies by GTG banding and FISH showed a complex karyotype with bands 13q12.3-->13q12.1::20p13 translocated to 2p13 and bands 2pter-->2p13::13q12.3-->13q14.1 translocated into band 20p13. This would be the first report of an interstitial deletion of 13q inherited from a parental complex chromosome rearrangement.     

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 complex,five breakpoint intrachromosomal rearrangement ascertained through two recombinant offspring

Intrachromosomal rearrangements usually result from three or fewer breaks. We report a complex intrachromosomal rearrangement resulting from five breaks in one chromosome 10 of a phenotypically normal father of two developmentally delayed children. GTG-banding analysis of the father's rearranged chromosome 10 suggested an initial pericentric inversion followed by an insertion from the short arm into the terminal band of the long arm [der(10)(pter→p13::q21.2→p12.2::q22.1→q26.3::q22.1→q21.2::p12.2→p13::q26.3→qter)]. To our knowledge, this rearrangement is the most complex ever reported in a single chromosome. Both children inherited a recombinant chromosome 10 with loss of the insertion and the segment distal to it [rec(10)der(pter→p13::q21.2→p12.2::q22.1→q26.3:)]. Mechanisms for both rearrangements are proposed. © 1996 Wiley-Liss, Inc.     

A father and son with mental retardation, a characteristic face, inv(12), and insertion trisomy 12p12.3-p11.2

A male patient with mental retardation (MR) and mild facial features was shown by high-resolution G-banding to have pericentric inversion of chromosome 12 with an unknown segment inserted into the long arm of the inverted chromosome [46,XY,inv(12)(pter-->p11.2::q14.1-->p11.2::?::q14.1-->qter)]. Both the inverted chromosome 12 and clinical manifestations were transmitted to his son. Karyotypes of the propositus' parents were normal. Studies with fluorescence in situ hybridization (FISH) in both the propositus and his son revealed that the extra segment was derived from 12p. Further FISH mapping and the genome-wide copy number detection by GeneChip Mapping 100K Array showed that an 11-Mb segment of 12p between two BAC clones, RP11-22H10 and RP11-977P2, was inserted at one of the reunion points in the long arm of the inv(12) chromosome. Analysis of parent-child transmissions of duplicated alleles using microsatellite markers defined the maternal origin of the chromosomal anomaly in the propositus and suggested a mechanism of its formation through a sister-chromatid rearrangement (SCR), that is, mismatched pairing and unequal crossover between sister chromatids as well as three break rearrangements including a U type rearrangement. Karyotypes of the propositus and his son were thus inv(12)(pter-->p11.22::q14.1-->p12.3::q14.1-->qter). This is the first report of "pure" proximal 12p-trisomy including p12.3-p11.22 region.     

Different mechanisms lead to a karyotypically identical t(20;21) in myelodysplastic syndrome and in acute myelocytic leukemia

A new t(20;21)(q11;q11), associated with a deletion on the long arm of chromosome 20, was found in one patient with an acute myelocytic leukemia (AML) and in one with myelodysplastic syndrome (MDS). In both cases deletion was interstitial, extending from band q11 to band q13, as shown by comparative genomic hybridization (CGH) and fluorescence in situ hybridization (FISH). FISH analysis with whole arm paints, subtelomeric probes, and locus-specific probes for the long arms of chromosomes 20 and 21 revealed in patient 1 a reciprocal translocation between the deleted 20q and the long arm of chromosome 21, that is, del(20)(q11q13)t(20;21)(q11;q11), and in patient 2, material from 21q was inserted into the deleted 20q, that is, del(20)(q11q13)ins(20;21)(q11;q11q22). This is the first identification of a complex 20;21 rearrangement in MDS/AML. Deletion at 20q and juxtaposition between 20q11 and 21q11 appear to be the critical genomic events.     

Fluorescence in situ hybridization detection of two telomeres on the short arm of a derived chromosome 16 in an infant with thrombocytopenia

We report a case of severe thrombocytopenia with an abnormal bone marrow karyotype described by G-banding analysis as t(16;21)(p?13;q11). Using fluorescence in situ hybridization (FISH) analysis with whole chromosome paints, the chromosome rearrangement was shown to be more complex, with the additional cryptic involvement of the long arm of chromosome 3. The chromosome rearrangement involved the breakpoints 3q26, 16p13.3, and 21q11; this rearrangement has not been previously described. The size of genomic material translocated from the chromosome 16 homologue was too small to be detected by chromosome paint. A 16p-specific telomeric probe was hybridized to locate the translocated 16p material. The 16p telomeric unique sequence DNA was retained on the der(16) chromosome, indicating a more distal breakpoint. This study demonstrates that telomeric translocations can occur that would be undetected by telomeric-specific FISH probes.     

Fluorescence in situ hybridization confirmation of 5q deletions in patients with hematological malignancies

Fluorescence in situ hybridization (FISH) using specific probes for the 5q31-32 region and a whole chromosomal painting (WCP) probe for chromosome 5 were used to corroborate the results of classical cytogenetic examinations performed on G-banded chromosomes of 77 patients with hematological malignancies. Using classical cytogenetic methods, we suspected the presence of clones with a deletion 5q in 63 patients, and complex rearrangements with involvement of chromosome 5 in 14 other cases. Fluorescence in situ hybridization proved the occurrence of deletion 5q31 in 23 patients and ascertained translocations of part of the long arms of deleted chromosome 5 with missing region 5q31 in 12 patients. In 2 cases, the 5q31 region was translocated to other chromosomes as a part of complex rearrangements. The combination of classical cytogenetics and FISH with specific probes for the 5q31 band yielded cytogenetic results in 35 cases. Routine FISH detection of deleted regions was possible by commercially available cosmid probes for the 5q31 chromosomal band. The interpretation of small deletions and frequent involvement of the deleted chromosomes 5 in complex translocations were ascertained by WCP probes.     

Polysomy 13 with concomitant deletion of 13q13-14 involving the retinoblastoma gene and the D13S25 locus in a case of acute myeloid leukemia

We herein describe a case of acute myeloblastic leukemia (AML), FAB subtype M4, with an unfavorable clinical course and a complex karyotype, including 4-9 copies of chromosome 13. Polysomy 13 was a result of clonal evolution. Fluorescence in situ hybridization (FISH) revealed a cytogenetically unrecognizable deletion within 13q13-14 that included the retinoblastoma gene (RB) and the D13S25 locus in all but one copy of chromosome 13. The only chromosome 13 that did not show a deletion affecting the q13-14 region was translocated to chromosome 7, resulting in a dic(7;13)(q21;p11). In this case, the coexistence of polysomy and a partial deletion within the same chromosome point toward a possible formation of a fusion product with oncogenic potential and its consecutive amplification as a critical alteration in this case.     

Characterization of a de novo unbalanced translocation t(14q18q) using microdissection and fluorescence in situ hybridization

We report on a patient with a de novo translocation between the long arms of chromosomes 14 and 18. The translocation was studied using microdissection in combination with fluorescence in situ hybridization (micro-FISH). Five copies of the chromosomes involved in the translocation were isolated by microdissection and amplified by means of degenerate oligonucleotide primed-polymerase chain reaction (DOP-PCR). Reverse chromosome painting with the biotin-labeled PCR product showed that part of the q-arm of chromosome 18 had no signal. The deletion was characterized further by FISH with band-specific probes and it was concluded that the rearrangement was unbalanced: 46,XY,t(14;18)(14pter→4q22::18q21.1→18qter)(18pter→18q12.2::14q22→14qter). The patient, who presented with psychomotor retardation, mild obesity, pes equinovarus, strabismus, and facial anomalies, is compared with previously reported patients with an interstitial deletion of band 18q12. Am. J. Med. Genet. 75:409-413, 1998. © 1998 Wiley-Liss, Inc.     

Delineation of a critical region on chromosome 18 for the del(18)(q12.2q21.1) syndrome

Deletions involving the long arm of chromosome 18 have been reported in many patients. Most of these deletions are localized in the distal half of the long arm (18q21.1 --> qter) and are detectable by standard cytogenetic analysis. However, smaller interstitial deletions leading to a recognizable phenotype and residing in the region around chromosome band 18q12.3 (bands q12-q21) are less common. Here we report on an interstitial deletion of less than 1.8 Mb within chromosomal band 18q12.3. The phenotypic features of the propositus correspond well with those observed in patients with larger cytogenetically detectable deletions encompassing chromosome band 18q12.3. The deletion enabled us to define a critical region for the following features of the del(18)(q12.2q21.1) syndrome: hypotonia, expressive language delay, short stature, and behavioral problems.     

易位点在随体的2q37缺失综合征患儿的临床及遗传学分析

目的对1例儿童多动症患儿进行细胞以及分子遗传学检测以明确诊断。方法常规进行外周血细胞培养制片及核型分析,荧光原位杂交(fluorescence in situ hybridization,FISH);常规提取外周血DNA,进行单核苷酸多态性微阵列(single nucleotide polymorphism array,SNP-array)检测。结果患儿具有典型的面部畸形,包括耳位低、耳廓卷曲、眉弓高突、鼻孔凹口、人中短平、上唇薄等。SNP-arry检测显示患儿染色体2q37区存在4.883 Mb的缺失,综合各项检测结果,患儿染色体核型最终被确定为45,XY,der(2;21)(2pter→2q37.3∷21p13→21p10∷20p10→20pter),der(20)(21qter→21q10∷20q10→20qter)。结论报道了1例涉及3条染色体的易位点发生在随体的2q37缺失综合征,综合运用各种细胞及分子遗传学技术对复杂结构染色体异常的诊断十分重要。     

Maternal balanced translocation leading to partial duplication of 4q and partial deletion of 1p in a son: Cytogenetic and FISH studies using band-specific painting probes generated by chromosome microdissection

A 9-month-old boy with pre- and post-natal growth retardation, microcephaly, plagiocephaly, and several minor anomalies had the initial karyotype: 46,XY,der(1)t(1;?)(p36.1;?). Further analysis showed that the der(1) was derived from an unfavorable segregation of a maternal complex chromosome rearrangement, i.e., 46,XX,der(1)t(1;?)(p36.1;?), der(4)t(4;?)(q?;?). Whole chromosome fluorescence in situ hybridization (FISH) and chromosome microdissection were used to clarify the maternal karyotype as: 46,XX,der(1)t(1;4)(4qter→4q33::1p36.13→1qter),der(4)t(1;4)inv(4)(4pter→ 4q31.3::1p36.33→1p36.13::4q33→4q31.3::1p36.33→1pter). Therefore, the karyotype of the boy actually was 46,XY,der(1)t(1;4)(p36.13;q33). Clinical comparison of the patient's clinical findings showed similarities to individuals with partial del(1p) and dup(4q). To our knowledge the above cytogenetic abnormalities have not been described previously. This case further demonstrates the advantages of chromosome microdissection and FISH in the identification of anomalous chromosome regions and breakpoints. Am. J. Med. Genet. 71:160–166, 1997. © 1997 Wiley-Liss, Inc.     

Molecular cytogenetic studies of duplication 9q32→q34.3 inserted into 9q13

Fluorescence in situ hybridization (FISH) studies using whole chromosome 9 painting probe, classical satellite (9q12-specific) probe and abl cosmid probe (locus: 9q34) were performed on a female infant who was born with multiple congenital anomalies and the karyotype 46,XX, 9q+. The results of FISH confirm the euchromatic nature of the extra material on the long arm of chromosome 9, and provide evidence that it is of chromosome 9 origin. The structural rearrangement has probably resulted from an insertion of a duplicated segment 9q32→q34.3 into band q13, as shown by the abl cosmid probe. The clinical features in this patient are similar to the previously reported cases of partial trisomy 9q3.     

Deletions of 2q14 that include the homeobox engrailed 1 (EN1) transcription factor are compatible with a normal phenotype

A novel transmitted 2-3 Mb deletion of 2q14.1-q14.2 was found in an affected boy from a consanguineous family with a possible diagnosis of PEHO syndrome (OMIM 260565). BAC FISH showed that the deletion included a minimum of 20 genes including the homeobox engrailed 1 gene (EN1). However, the same deletion was also found in his phenotypically normal father and brother (family 1). The phenotype of the proband may, therefore, have been coincidental to the deletion, a result of a recessive condition within or outside the deleted segment or possibly due to variable dosage compensation of EN1 by the paralogous EN2 gene at 7q36. BAC FISH also showed that this deletion overlapped with a previously reported transmitted deletion of 2q13-q14.1 that had no phenotypic consequences (family 2). The deleted regions contained a total of 32 genes and comprise the final 5.25 Mb of the ancestral chromosome 2B from which chromosome 2 was formed in man. These families provide further evidence that heterozygous deletions of regions of low gene density are compatible with a normal phenotype.     

A de novo complex chromosomal rearrangement with a translocation 7;9 and 8q insertion in a male carrier with no infertility

A de novo complex chromosomal rearrangement (CCR) involving chromosomes 7, 8 and 9 in a male carrier was ascertained through his healthy wife's recurrent spontaneous abortions. Six pregnancies over eight years resulted in four spontaneous abortions and two livebirths who died perinatally due to abnormal vital signs. Cytogenetic analyses utilizing high resolution chromosome banding technique showed a deletion of band in a der(7) chromosome and an extra band inserting at 8q21.2. Another extra band was also observed at the band 9p24, but it could not be karyotypically determined. Fluorescent in-situ hybridization using chromosome 7 and 8 specific microdissected library as probes confirmed the insertion of a segment from the translocated chromosome 7 into a chromosome 8, and additionally revealed a translocation between chromosomes 7 and 9. The karyotype of the CCR carrier was determined as 46,XY,t(7;9)(q22;p24),ins(8;7)(q21.2;q22q32).ish der(9)(wcp7+);ins(8;7)(wcp8+,wcp7+). Comparing with previously reported male CCR carriers with our case, we conclude that male CCR carriers may not always present with infertility or subfertility phenotypes. This may suggest that rare transmission of male carriers could result from abnormal chromosomal rearrangements during meiosis and gametogenesis in addition to frequent infertility.     

Neocentromere at 13q32 in one of two stable markers derived from a 13q21 break

A 10-month-old girl with psychomotor retardation, microcephaly, bilateral microphthalmia, and postaxial polydactyly of the feet was karyotyped using banding techniques and (single or dual color) fluorescent in situ hybridization (FISH) with four probes: D13Z1/D21Z1, pancentromeric, pantelomeric, and a mix of 13q subtelomeric and 13/21 alphoid repeats. She was found to have a 47-chromosome karyotype in which a normal 13 was replaced by two stable markers derived from a breakpoint at 13q21.1, namely a del(13)(q21.1) and an isofragment(13) (qter→q21.1::q21.1→qter). The latter had a single C-negative but Cd-positive primary constriction at 13q32 which, however, was not obvious in about 12% of the cells. FISH studies showed that the small 13q- had the 13-centromere and a 13q telomere (as shown for a specific 13q subtelomeric signal) onto the broken end whereas the isofragment lacked alphoid signals but had 13q subtelomeric sequences on both ends. Parental karyotypes were normal. The patient's rearrangement represents the eighth chromosome-13–derived marker with a nonalphoid neocentromere located at 13q. All in all, such neocentromeres have been described in 29 markers derived from chromosomes 2, 3, 8–11, 13–15, 20, and Y, and plausibly result from the epigenetic activation of a latent centromere, which may even be a telomere with neocentric activity. The 13q telomere found in the del(13q) was probably captured from the homologous chromosome. Am. J. Med. Genet. 85:385–388, 1999. © 1999 Wiley-Liss, Inc.     

Deletions at chromosome regions 7q11.23 and 7q36 in a patient with Williams syndrome

We report on a patient with Williams syndrome and a complex de novo chromosome rearrangement, including microdeletions at 7q11.23 and 7q36 and additional chromosomal material at 7q36. The nature of this additional material was elucidated by spectral karyotyping and first assigned to chromosome 22. Subsequent fluorescence in situ hybridization (FISH) experiments showed that it consisted of satellite material only. Refinement of the 7q36 breakpoint was performed with several FISH probes, showing a deletion distal to the triphalangeal thumb (TPT) region. The phenotype of the patient principally results from the microdeletion of the 7q11.23; the small deletion at 7qter and the extra satellite material may not be of clinical significance.     

A complex chromosome rearrangement with at least five breakpoints studied by fluorescence in situ hybridization

A newborn infant with multiple congenital anomalies was diagnosed with an unbalanced translocation of chromosomes 1 and 5. Studies of parental chromosomes revealed a complex rearrangement in the patient's mother involving the exchange of terminal long arms between chromosomes 1 and 5 and the insertion of an interstitial segment from the same chromosome 5q into chromosome 2q by high-resolution G-banding. Further study of the mother's chromosomes by fluorescent in situ hybridization (FISH) detected an additional insertion between the rearranged chromosomes 2 and 5, which was not revealed by G-banding. This led to the identification of a complex translocation-insertion between 3 chromosomes with at least 5 breaks [t(1;5;2)(1pter→1q42.3::5q23.2→5qter;5pter→5q21.2::2q33→2q35::1q42.3→1qter;2pter→2q33::5q21.2→5q23.2::2q35→2qter)] and illustrates the value of FISH as an adjunct to standard cytogenetics, particularly in cases of complex rearrangements. Am. J. Med. Genet. 68:417–420, 1997. © 1997 Wiley-Liss, Inc.     

Molecular characterization of partial trisomy 16q24.1-qter: clinical report and review of the literature

We describe a 3(1/2)-year-old girl with psychomotor and mental retardation; dysmorphic features, including a high forehead with bitemporal narrowing; a broad nasal bridge and a broadened nose; downslanting palpebral fissures; abnormal ears; vertebral abnormalities; cardiac defect; genital hypoplasia; and anal abnormalities. The karyotype of our patient (550 bands) was normal. Molecular cytogenetic techniques, including comparative genomic hybridization (CGH) and fluorescence in situ hybridization (FISH), revealed that this girl was a carrier of a de novo derivative chromosome 7 arising from a cryptic t(7;16)(p22.3;q24.1) translocation generating a trisomy 16q24.1-qter and a 7p22.3-pter deletion. FISH with a series of specific chromosome 7p and 16q probes allowed us to delineate the chromosome 7 breakpoint between YAC660G6 (WD7S517) and YAC848A12 (D7S521, D7S31, and WI-4829) and the chromosome 16 breakpoint between BAC457K7 (D42053) and BAC44201 (SGC30711). The comparison of the clinical features of our patient with those of 2 cases of pure terminal 7p deletion and 28 cases of trisomy 16q reported in the literature allowed us to establish the following phenotype-genotype correlation for trisomy of the long arm of chromosome 16: distinctive facies (high/prominent forehead, bitemporal narrowing, periorbital edema in the neonatal period); severe mental retardation; vertebral, genital, and anal abnormalities to 16q24; distal joint contractures and camptodactyly to 16q23; cleft palate and renal anomalies to 16q22; beaked nose and gall bladder agenesis to 16q21; gut malrotation; lung and liver anomalies to 16q13; and behavior abnormalities to band 16q11-q13.