Familial insertion (3;5)(q25.3;q22.1q31.3) with deletion or duplication of chromosome region 5q22.1-5q31.3 in ten unbalanced carriers.

We report on the clinical and cytogenetic data of a large family with an unbalanced insertion translocation (3;5)(q25.3;q22.1q31.3). Analysis of GTG-banded chromosomes demonstrated that unbalanced inheritance of a parental insertion translocation caused either a partial deletion or duplication 5q in this family. The derivative chromosomes were characterized further using microdissection and FISH with band-specific probes. The clinical picture of the proband with a partial deletion of chromosome 5 was characterized by moderate psychomotor retardation, mild facial dysmorphism, cleft palate, and single transverse crease. The family members with a partial duplication of chromosome 5 were borderline intelligent, had mild facial dysmorphism, a cardiac anomaly, and a high-pitched voice. The unbalanced carriers were compared with patients reported in the literature with a duplication or deletion of chromosome region 5q22.1 --> 5q31.3.

Deletion of chromosome region 18q21.1 --> 18q21.3 in a patient without clinical features of the 18q- phenotype.

In a 16-month-old boy referred because of developmental delay and asymmetric motor development, chromosome analysis showed an aberrant chromosome 18 in all 25 metaphases examined. The chromosome aberration was initially interpreted either as an interstitial deletion of chromosome region 18q21.1 --> 18q21.3 or an unbalanced translocation involving the distal part of the long arm of chromosome 18. Chromosome microdissection in combination with fluorescence in situ hybridization demonstrated that the aberrant chromosome 18 had an interstitial deletion, the karyotype being: 46,XY,del(18)(q21.1q21.3). At age 27 months, his development was moderately retarded. He showed craniofacial asymmetry but no other anomalies. The clinical and cytogenetic findings are compared with previously reported patients with a terminal or interstitial deletion in the long arm of chromosome 18.

Characterization of a chromosome 8-derived minute marker chromosome using microdissection and FISH in a boy with growth retardation.

In a 9-year-old boy referred because of growth retardation, chromosome analysis showed the presence of a minute marker chromosome in 75% of the metaphases examined. The application of microdissection in combination with fluorescence in situ hybridization demonstrated that the marker was derived from the centromere region of chromosome 8, the karyotype being: mos 47,XY,+mar.ish der(8)(D8Z1+)[75]/46,XY[25]. The clinical and cytogenetical findings are compared with cases previously reported in the literature.

Intrachromosomal insertion translocation resulting in duplication of chromosome band Yq11.2 in two fertile brothers.

Chromosome analysis in a couple referred because of two spontaneous abortions showed a normal 46,XX karyotype in the 28-year-old female and an aberrant Y chromosome with an enlarged short arm in the 30-year-old male. Subsequent chromosome analysis showed that his 33-year-old brother was carrier of the same Y chromosome aberration. Further characterization of the aberrant Y chromosome with FISH using probes specific for chromosome bands Yp11.32, Yq11.2, the centromere and the subtelomeric region of the p-arm of the Y chromosome showed that chromosome band Yq11.2 was duplicated and inserted in the p-arm of the Y chromosome. Combining the results of the analysis of GTG-banded chromosomes and of the FISH analysis we conclude that both patients have a 46,X,ins dup(Y)(pter --> p11.23::q12 --> q11.1::p11.23 -->) karyotype. The clinical and cytogenetical findings are reported and discussed.

Duplication of chromosome region (16)(p11.2 --> p12.1) in a mother and daughter with mild mental retardation.

We report a 40-year-old female with mild mental retardation and behavior problems and her 6-year-old daughter. Chromosome analysis showed that both patients had a proximal duplication in the short arm of chromosome 16. The aberration was characterized further with band-specific probes, resulting in a 46,XX,dir dup(16)(pter --> p11.2::p12.1 --> qter) karyotype. The clinical and cytogenetical findings are compared to other patients with partial trisomy 16p reported in the literature.

Holoprosencephaly: the Maastricht experience.

Holoprosencephaly (HPE) is a developmental field defect with impaired cleavage of the embryonic forebrain as the cardinal feature. The prevalence is about 1 in 11.000-20.000 in live births and 1 in 250 during embryogenesis. In most cases, craniofacial abnormalities are associated and reflect in 80% of cases the degree of severity. The severity is of marked variability and ranges from cyclopia to minimal craniofacial dysmorphism, such as mild microcephaly with a single central incisor. The etiology of HPE is very heterogeneous and comprises environmental factors (e.g. maternal diabetes) and genetic causes. Approximately 50% of HPE cases are associated with a cytogenetic abnormality (the most common of which is trisomy 13) or a monogenic syndrome. Based on recurrent cytogenetic abnormalities, there are at least 12 genetic loci that likely contain genes implicated in the pathogenesis of HPE. Currently, four human HPE genes are known: SHH at 7q36, ZIC2 at 13q32, SIX3 at 2p21 and TGIF at 18p11.3. Over the past 13 years, 16 patients with HPE have been observed at the Department of Clinical Genetics at Maastricht. Some of them are briefly presented in order to emphasize the spectral nature of HPE and the etiological heterogeneity. One patient appeared to have a partial 18p deletion due to a maternal cryptic translocation t(1:18) and, in addition, a SHH mutation. The mildest affected patient presented with microcephaly and a single maxillary incisor; she had a submicroscopic 7q deletion. Finally, we propose a protocol of etiological work-up of HPE cases.

De novo duplication (5)(q31.3q33.3): report of a patient and characterization of the duplicated region using microdissection and FISH.

We report on a 2-year-old boy presenting with growth and psychomotor retardation and facial anomalies, including a flat face with prominent forehead, a flat nasal bridge and flat occiput, unusually long curved eyelashes, and a thin upper lip with down-turned corners of the mouth. Analysis of GTG-banded chromosomes demonstrated that the patient had extra chromosomal material in the long arm of one chromosome 5. This chromosome aberration was characterized further using microdissection and FISH with band-specific probes and a de novo direct duplication (5)(q31.3q33.3) was shown to be present. We have compared this case with others known to be partially trisomic for chromosome 5q reported in the literature.

De novo "pure" partial trisomy (6)(p22.1-->pter) in a chromosome 15 with an enlarged satellite, identified by microdissection.

We report on a newborn boy with a congenital heart defect, severe pre- and postnatal growth retardation, feeding problems, facial anomalies and unilateral hydronephrosis. Cytogenetic analysis showed extra chromosomal material on the short arm of one chromosome 15 that at first sight could be mistaken for a chromosomal variant and could not be identified with conventional banding techniques. Chromosome analysis of the parents showed that both had a normal karyotype. Microdissection of five copies of the aberrant chromosome 15, amplification of the dissected chromosomal material by DOP-PCR and subsequent reverse painting was performed and disclosed that the patient had a de novo 46,XY,der(15)(6pter-->6p22.1::15p12-->15qter) karyotype with a "pure" trisomy of chromosome region 6p22.1-->6pter. The associated phenotypic anomalies are compared with other reported cases with a distal duplication of chromosome 6p.

De novo translocation (2;18)(q21;q22) in a child with severe epilepsy, developmental delay and mild dysmorphism.

De novo translocation (2;18)(q21;q22) in a patient with severe epilepsy developmental delay and mild dysmorphism: We report on a patient presenting with severe epilepsy, hypotonia, developmental delay, blepharophimosis, low-set ears, camptodactyly and tapering fingers, and cutaneous syndactyly of toes II and III of the right foot. The MRI showed some loss of volume of the white matter and delayed myelination, no other specific anomalies were present. Chromosome analysis revealed a translocation involving chromosomes 2 and 18, which was characterized further by FISH using band-specific probes. The possibility of a submicroscopic deletion is discussed and the patient is compared with patients reported in the literature with either 2q21 or 18q22 deletion.

Mosaic telomeric (2;14) association in a child with motor delay.

In a 6-year-old girl referred because of mild motor delay and hyperextensible joints, chromosome analysis disclosed a derivative chromosome consisting of end-to-end fusion of chromosomes 2 and 14. Two cell lines existed in which this telomere association was present, one with a 45,XX,tas(2;14)(q37;p11) karyotype and one with a 45,XX,tas(2;14) (q37;q32) karyotype. The cell line with the telomeric fusion of 2q and 14p was present in 90% of the cells; a telomeric fusion of 2q and 14q was seen in the remaining 10% of the cells. In both association complexes, only the centromere of chromosome 14 was active. Fluorescence in situ hybridization with telomere and subtelomere probes disclosed no deletion of chromosomal material. Microsatellite analysis showed that the patient had a normal biparental contribution of chromosomes 14.

Duplication of chromosome region 8p23.1-->p23.3: a benign variant?

Chromosome analysis was performed in a 34-year-old man who was phenotypically normal except for oligoasthenozoospermia. In this patient, analysis of GTG-banded chromosomes showed in one chromosome 8 additional chromosomal material of unknown origin. To characterize the aberrant chromosome more precisely, a paint specific for chromosome region 8pter-->8p23.1 was generated by microdissection and degenerated oligonucleotide primed-polymerase chain reaction (DOP-PCR) and used as fluorescence in situ hybridization (FISH) paint. After reverse painting, hybridization signals were only found on the short arm of the two chromosomes 8, with an enlarged signal on the derivative chromosome 8. The duplication was characterized further with band-specific FISH probes. We concluded that (part of) chromosome region 8p23.1-->p23.3 was duplicated. Chromosome analysis of the parents showed that the dup(8) was of maternal origin and that the fertile brother of the index patient also was a carrier of the chromosome aberration. There was no history of miscarriages. We suggest that duplication of region 8p23.1-->p23.3 can be regarded as euchromatic variant or duplication with no phenotypic effect.

Prenatally detected marker chromosome identified as an i(22)(p10) using (micro)FISH.

MicroFISH was used to elucidate the chromosomal origin of a prenatally detected marker chromosome. Five copies of the marker chromosome were collected from GTG-banded metaphases and amplified by means of DOP-PCR. The PCR product was labeled with blotine-14-dATP and used as a FISH probe for hybridization to metaphase chromosomes of the fetus (reverse painting). The marker appeared to be derived from the short arm of (an) acrocentric chromosome(s). After FISH with centromere-specific and band-specific probes complete characterization was possible and the marker chromosome appeared to consist of two short arms of chromosome 22. The pregnancy was continued and one year after birth the patient is developing normal.

Complex chromosome 9, 20, and 22 rearrangements in acute lymphoblastic leukemia with duplication of BCR and ABL sequences.

Cytogenetic analysis was performed on bone marrow cells from a 28-year-old woman who was diagnosed with acute lymphoblastic leukemia (ALL). Her karyotype was: 46,XX,t(9;22)(q34;q11)[6]/47, XX,+8,t(9;22)(q34;q11)[4]/47,XX,+8,t(9;22)(q34;q11),del(20)(q11)[2]/46, XX,t(9;22)(q34;q11),del[20](q11)[7]/45,XX,der(9)t(9;22)(q34;q11),-20,-22 , +mar1[8]/45,XX,der(9)t(9;22)(q34;q11),-20,-22,+mar2[3]. Both marker chromosomes are dicentric and have the same size and banding pattern but different primary constrictions. Fluorescence in situ hybridization (FISH) demonstrated that both markers were derived from chromosomes 9, 20, and 22. FISH with the bcr/abl probe showed fusion of the BCR gene with the ABL gene; however, this fusion signal was present in duplicate on both marker chromosomes. To our knowledge, duplication of the BCR/ABL fusion signal on a single chromosome arm has not been reported before, except for the extensive amplification of BCR/ABL fusion signals in the leukemic cell line K-562. These data demonstrate that the marker chromosomes are the result of complex genomic rearrangements. At the molecular level, the BCR/ABL fusion gene encodes the p190 fusion protein. Similar findings have never been observed in any case of ALL.

14q terminal deletion: prenatal diagnosis in a child with severe congenital anomalies.

A fetal patient presented at 27.3 weeks of gestation with polyhydramnion. Ultrasound examination showed enlarged cerebral ventricles, abnormal position of the fingers and abnormal external genitals. Chromosome studies in chorionic villus material were normal male: in cultured amniocytes a distal deletion 14q32 was demonstrated and confirmed by FISH analysis. The baby was born at 37 weeks and died spontaneously during labour. This is the first report of prenatal diagnosis of a terminal 14q deletion.

Trisomy 7p: report of 2 patients and literature review.

Two patients with a trisomy 7p are reported. Both were assessed by facial dysmorphism and congenital anomalies. In one of the patients trisomy 7p was a de novo event, in the other patient unbalanced inheritance of a parental translocation caused trisomy 7p. Developmental delay was severe in both. Our 2 cases are compared with patients reported in literature.

Characterization of a partial trisomy 16q with FISH. Report of a patient and review of the literature.

Characterization of a partial trisomy 16 q with FISH: Report of a patient and literature review: We report on a 28-year-old male patient with severe growth and mental retardation, severe behavioural problems, especially automutilation, and a spastic quadriplegia. He showed no specific dysmorphism. The karyotype was 46, XY, dir dup(16) (q11.2-q13). The clinical and cytogenetical findings are compared with 3 previously reported cases with proximal duplication 16q.

Duplication within chromosome region 15q11-q13 in a patient with similarities to Prader-Willi syndrome confirmed by region-specific and band-specific fish.

We report on a patient presenting with mental retardation and obesity and a proximal duplication of chromosome 15. The patient shared some clinical signs with Prader-Willi syndrome. With a region-specific paint, generated by microdissection, a duplication in region 15q11.2-q13 was shown to be present. Subsequently, FISH with probes localized to chromosome region 15q11.2-q12 and microsatellite analysis was used to characterize this chromosome aberration further and an insertion duplication within the region frequently deleted in Prader-Willi and Angelman syndrome was demonstrated.

Two cases of partial trisomy 8p and partial monosomy 21q in a family with a reciprocal translocation (8;21)(p21.1;q22.3).

We report on two mentally retarded adults with an unbalanced karyotype resulting from a familial balanced translocation between chromosomes 8 and 21, t(8;21)(p21.1;q22.3). This translocation has not been reported before. Both patients had partial trisomy 8p and partial monosomy 21q. Fluorescence in situ hybridisation (FISH) was used to determine the chromosomal breakpoints more precisely. The first patient showed mild mental retardation and facial dysmorphism, slightly resembling the earlier described trisomy 8p phenotype. He did not resemble his affected niece, who was more severely retarded, had serious epilepsy, but lacked the facial dysmorphism. Comparing the data of both patients with published reports of trisomy 8p, marked differences were found between patients with an inversion duplication (inv dup) 8p, patients with partial trisomy 8p caused by an unbalanced translocation, and our patients. Inv dup(8p) causes a recognisable phenotype, whereas the phenotype of trisomy 8p resulting from a translocation is much more variable, probably because of the accompanying monosomies. However, even the same abnormal karyotype can cause different phenotypes, as our patients show. Counselling carriers of the balanced translocation in this family, a 20-25% recurrence risk for unbalanced offspring and a 25% risk for miscarriages seem appropriate.

Disclosure of five breakpoints in a complex chromosome rearrangement by microdissection and FISH.

Microdissection and fluorescence in situ hybridisation (FISH) were used to elucidate the nature of a complex chromosome translocation, after GTG banding failed in the complete characterisation of the structural rearrangement between chromosomes 6 and 12. These chromosomes were painted with chromosome specific paints and one of the chromosome regions involved in the translocation was isolated by microdissection. Ten copies of the microdissected region were collected with microneedles from GTG banded metaphases, transferred to a collecting drop, and amplified by means of DOP-PCR. The PCR product was labelled with biotin-14-dATP and used as a FISH probe for hybridisation to normal metaphase chromosomes and metaphase chromosomes of the patients (microFISH). FISH with this chromosome region specific painting probe and with chromosome band specific probes enabled the characterisation of a complex chromosome rearrangement with five breakpoints in two chromosomes. This resulted in the following karyotype: 46,XY,t(6;12)(6pter--> 6q12::12q24.1-->12qter;12qter-->12q13.3:: 6q16.2-->6q26::12q13.3-->12q24.1::6q12--> 6q16.2::6q26-->6qter).

Application of micro-FISH to delineate deletions.

Microdissection combined with fluorescence in situ hybridization (micro-FISH) was used to visualize deletions in rearranged human chromosomes and in a de novo translocation. In each experiment five copies of a structurally aberrant chromosome or of the two chromosomes involved in the de novo translocation were isolated by microdissection and amplified using DOP-PCR. The PCR products were then used as probes for FISH to metaphase chromosomes of three patients. After reverse chromosome painting, the structurally aberrant chromosomes were completely painted, and the region deleted in the aberrant chromosomes was visible in the normal chromosomes. The smallest deletion that could be demonstrated this way was a microdeletion of approximately 6 x 10(6) bp, which is frequently reported in Angelman and Prader-Willi syndromes.