Two patients with overlapping de novo duplications of the long arm of chromosome 9, including one case with Di George sequence

11q13.3q13.4 deletion plus 9q21.13q21.33 duplication in an affected girl arising from a familial four-way balanced chromosomal translocation

BACKGROUND

We describe a 13-year-old girl with a 11q13.3q13.4 deletion encompassing the SHANK2 gene and a 9q21.13q21.33 duplication. She presented with pre- and postnatal growth retardation, global developmental delay, severe language delay, cardiac abnormalities, and dysmorphisms. Her maternal family members all had histories of reproductive problems.

METHODS

Maternal family members with histories of reproductive problems were studied using G-banded karyotyping and optical genome mapping (OGM). Long-range PCR (LR-PCR) and Sanger sequencing were used to confirm the precise break point sequences obtained by OGM.

RESULTS

G-banded karyotyping characterized the cytogenetic results as 46,XX,der(9)?del(9)(q21q22)t(9;14)(q22;q24),der(11)ins(11;?9)(q13;?q21q22),der(14)t(9;14). Using OGM, we determined that asymptomatic female family members with reproductive problems were carriers of a four-way balanced chromosome translocation. Their karyotype results were further refined as 46,XX,der(9)del(9)(q21.13q21.33)t(9;14)(q21.33;q22.31),der(11)del(11)(q13.3q13.4)ins(11;9)(q13.3;q21.33q21.13),der(14)t(9:14)ins(14;11)(q23.1;q13.4q13.3). Thus, we confirmed that the affected girl inherited the maternally derived chromosome 11. Furthermore, using LR-PCR, we showed that three disease-related genes (TMC1, NTRK2, and KIAA0586) were disrupted by the breakpoints.

CONCLUSIONS

Our case highlights the importance of timely parental origin testing for patients with rare copy number variations, as well as the accurate characterization of balanced chromosomal rearrangements in families with reproductive problems. In addition, our case demonstrates that OGM is a useful clinical application for analyzing complex structural variations within the human genome.

A rare occurrence of two large de novo duplications on 1q42-q44 and 9q21.12-q21.33

De novo partial distal 1q trisomy is uncommon and mostly occurs in combination with monosomy of another chromosome due to a parental translocation. Distal 1q trisomy co-occurring with another de novo duplication on a separate chromosome is extremely rare. Here, we reported a patient carrying two large de novo interstitial duplications including a 20Mb duplication at 1q42-q44 and a 14.2Mb duplication at 9q21.12-q21.33. The patient presented with features of pre- and postnatal growth retardation, low birth weight, failure to thrive, developmental delay and frequent infection. Her dysmorphic features included macrocephaly, prominent forehead, triangular face, wide fontanelle, hypertelorism, flat nasal bridge, tented mouth, micrognathia, protruding and low-set ears, slender limbs with toe-walking appearance. In addition, she presented with subdural hematoma. The clinical presentations of this patient are mostly consistent with those of distal 1q trisomy syndrome or 9q interstitial duplication. The interstitial 1q trisomy may have contributed to the macrocephaly, prominent forehead and limb abnormalities of our patient. Either or both de novo duplications could have contributed to the features of growth retardation, developmental delay and dysmorphic features including hypertelorism, low-set ears and abnormal nose/nasal bridge.

Detection of single clone deletions using array CGH: identification of submicroscopic deletions in the 22q11.2 deletion syndrome as a model system

Constitutional submicroscopic DNA copy number alterations have been shown to cause numerous medical genetic syndromes, and are suspected to occur in a portion of cases for which the causal events remain undiscovered. Array comparative genomic hybridization (array CGH) allows high-throughput, high-resolution genome scanning for DNA dosage aberrations and thus offers an attractive approach for both clinical diagnosis and discovery efforts. Here we assess this capability by applying array CGH to the analysis of copy number alterations in 44 patients with a phenotype of the 22q11.2 deletion syndrome. Twenty-five patients had the deletion on chromosome 22 characteristic of this syndrome as determined by fluorescence in situ hybridization (FISH). The array measurements were in complete concordance with the FISH analysis, supporting their diagnostic utility. These data show that a genome-scanning microarray has the level of sensitivity and specificity required to prospectively interrogate and identify single copy number aberrations in a clinical setting. We demonstrate that such technology is ideally suited for microdeletion syndromes such as 22q11.2.

Tetrasomy 9q in an infant with cleft palate and multiple anomalies

We report a patient with partial tetrasomy 9q resulting from a de novo triplication of 9q13q22.1. The clinical features, including microcephaly, beaked nose, short palpebral fissures, camptodactyly, joint contractures, and moderate developmental delay were similar to trisomy 9q, although our patient also had unique features including cleft palate and several unexplained fractures. The latter could be secondary to abnormal tone and contractures. Although tetrasomy 9p is a well-known entity, our patient, to our knowledge, is the first and only individual reported to have tetrasomy 9q.

DiGeorge anomaly in a patient with isochromosome 18p born to a diabetic mother

The DiGeorge anomaly (DGA) is an etiologically heterogeneous developmental field defect in which cardiovascular malformations, hypocalcemia, thymic hypoplasia, and characteristic dysmorphisms are major clinical features. The 22q11.2 deletion is the most common single etiology of DGA, although a number of other chromosomal abnormalities and teratogens, including maternal diabetes, have been implicated as well. We present a patient, born to a diabetic mother, with interrupted aortic arch type B (IAA-B), neonatal hypocalcemia, thymic hypoplasia, and dysmorphic features including microcephaly, thick, overfolded helices, and anteriorly-placed anus. Cytogenetic studies showed the presence of a marker chromosome, identified by fluorescence in-situ hybridization (FISH) as an isochromosome 18p [i(18p)]. We did not detect a 22q11.2 deletion by FISH using a cosmid probe corresponding to locus D22S75. The patient is the first example of either DGA or IAA-B in a patient with i(18p). We review the genetic abnormalities associated with DGA, and discuss the potential contributions of maternal diabetes and i(18p) in our patient.

Identification of 14 rare marker chromosomes and derivatives by spectral karyotyping in prenatal and postnatal diagnosis

Extra structurally abnormal chromosomes (ESACs) and cryptic rearrangements are often associated with mental retardation and phenotypic abnormalities. In some cases their characterisation, using standard cytogenetic techniques and fluorescence in situ hybridization (FISH), is difficult and time consuming, where a fast and accurate identification is essential, especially when such chromosomal aberrations are found in prenatal diagnosis. A recent molecular technique, spectral karyotyping (SKY), based on the spectral signature of 24 chromosome-specific painting probes labelled with different combinations of five fluorochromes, allows the simultaneous visualisation of all human chromosomes in different colours. We used SKY analysis on 14 cases with rare ESACs or cryptic unbalanced rearrangements found at pre- or postnatal diagnosis. SKY analysis permitted the classification of chromosome rearrangements in all 14 cases analysed in combination with FISH analysis.

Newborn with malformations and a combined duplication of 9pter-q22 and 16q22-qter resulting from unbalanced segregation of a complex maternal translocation

We report a patient with duplication of 9pter-q22 combined with duplication of 16q22-qter. The chromosome anomaly was the result of a 3:1 segregation of a maternal translocation (46,XX,t[9;16;21]). This newborn had intrauterine growth retardation and microcephaly, the characteristic recognizable pattern of trisomy 9p, cerebellar hypoplasia, a porencephalic cyst in the parieto-occipital region, and rocker-bottom feet. We compare the clinical features with another previously described case of duplication of an identical 9p segment combined with distal 16q duplication of a similar, but not identical segment, as well as with cases with duplication of either one of the two segments.

Molecular cytogenetic characterization of a 10p14 deletion that includes the DGS2 region in a patient with multiple anomalies

We report on a prenatally diagnosed four-month-old boy with DiGeorge-like phenotype and a deletion of chromosome 10pter --> 14. Fluorescence in situ hybridization (FISH) experiments using phage artificial chromosome (PAC) and yeast artificial chromosome (YAC) clones indicated that the chromosomal breakpoint was located at the proximal boundary of the DiGeorge syndrome 2 (DGS2) critical region. The patient demonstrated a high forehead, high arched eyebrows, short palpebral fissures, sparse eyelashes, prominent nose with bulbous tip, small mouth, receding chin, round ears with deficient helices, cardiac defects atrial septal defect (ASD), ventricular septal defect (VSD), mild brachytelephalangy, mild syndactyly, hypoplastic left kidney, undescended testes, muscular hypertonia, dorsally flexed big toes, and developmental delay. The phenotype corresponded well with the clinical signs of 10p deletion of this region that were described previously. The facial features appeared different from the typical face with the 22q11 deletion.

Brachydactyly type B: linkage to chromosome 9q22 and evidence for genetic heterogeneity

Brachydactyly type B (BDB), an autosomal dominant disorder, is the most severe of the brachydactylies and is characterized by hypoplasia or absence of the terminal portions of the index to little fingers, usually with absence of the nails. The thumbs may be of normal length but are often flattened and occasionally are bifid. The feet are similarly but less severely affected. We have performed a genomewide linkage analysis of three families with BDB, two English and one Portugese. The two English families show linkage to the same region on chromosome 9 (combined multipoint maximum LOD score 8.69 with marker D9S257). The 16-cM disease interval is defined by recombinations with markers D9S1680 and D9S1786. These two families share an identical disease haplotype over 18 markers, inclusive of D9S278-D9S280. This provides strong evidence that the English families have the same ancestral mutation, which reduces the disease interval to <12.7 cM between markers D9S257 and D9S1851 in chromosome band 9q22. In the Portuguese family, we excluded linkage to this region, a result indicating that BDB is genetically heterogeneous. Reflecting this, there were atypical clinical features in this family, with shortening of the thumbs and absence or hypoplasia of the nails of the thumb and hallux. These results enable a refined classification of BDB and identify a novel locus for digit morphogenesis in 9q22.

Velo-cardio-facial and partial DiGeorge phenotype in a child with interstitial deletion at 10p13--implications for cytogenetics and molecular biology

We report on a female with a interstitial deletion of 10p13 and a phenotype similar to that seen with the 22q deletion syndromes (DiGeorge/velo-cardio-facial). She had a posterior cleft palate, perimembranous ventricular septal defect, dyscoordinate swallowing, T-cell subset abnormalities, small ears, maxillary and mandibular hypoplasia, broad nasal bridge, deficient alae nasi, contractures of fingers and developmental delay. This could indicate homology of some developmental genes at 22q and 10p so that patients with the velocardiofacial phenotype who do not prove to be deleted on 22q are candidates for a 10p deletion.

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.