7q11.23 Microduplication: a recognizable phenotype

Dixit A, McKee S, Mansour S, Mehta SG, Tanteles GA, Anastasiadou V, Patsalis PC, Martin K, McCullough S, Suri M, Sarkar A. 7q11.23 Microduplication: a recognizable phenotype. Williams‐Beuren syndrome is a well‐known microdeletion syndrome with a recognizable clinical phenotype. The subtle phenotype of the reciprocal microduplication of the Williams‐Beuren critical region has been described recently. We report seven further patients, and a transmitting parent, with 7q11.23 microduplication. All our patients had speech delay, autistic features and facial dysmorphism consistent with the published literature. We conclude that the presence of specific dysmorphic features, including straight, neat eyebrows, thin lips and a short philtrum, in our patients with speech delay and autistic features provides further evidence that the children with 7q11.23 microduplication have a recognizable phenotype.     

Parallel deletion and duplication at 7q11.23 in a silent carrier for two reciprocal syndromic disorders

Partial deletions at chromosome 7q11.23 are causative for the autosomal-dominant Williams–Beuren syndrome (WBS), whereas the partial duplication of this region leads to the 7q11.23 duplication syndrome. Both syndromes are highly penetrant and occur with a frequency of 1:7500–10,000 (WBS) and 1:13,000–20,000 (7q11.23 duplication syndrome). They are associated with multiple organ defects, intellectual disability, and typical facial dysmorphisms showing broad phenotypic variability. The 7q11.23 region is susceptible to chromosomal rearrangements due to flanking segmental duplications and regions of long repetitive DNA segments. Here, we report on a family with two children affected by WBS and clinically unaffected parents. Interestingly, metaphase fluorescence in situ hybridization (FISH) revealed a deletion on 7q11.23 in the father. Intensive genetic testing, using interphase FISH, whole genome sequencing and optical genome mapping led to the confirmation of a 1.5 Mb deletion at one 7q11.23 allele and the identification of a reciprocal 1.8 Mb duplication at the other allele. This finding is highly important regarding genetic counseling in this family. The father is a silent carrier for two syndromic disorders, thus his risk to transmit a disease-causing allele is 100%. To the best of our knowledge we, here, report on the first case in which the phenotype of a microdeletion/microduplication syndrome was compensated by its reciprocal counterpart.     

Autism, language delay and mental retardation in a patient with 7q11 duplication

Background

Chromosomal rearrangements, arising from unequal recombination between repeated sequences, are found in a subset of patients with autism. Duplications involving loci associated with behavioural disturbances constitute an especially good candidate mechanism. The Williams–Beuren critical region (WBCR), located at 7q11.23, is commonly deleted in Williams–Beuren microdeletion syndrome (WBS). However, only four patients with a duplication of the WBCR have been reported to date: one with severe language delay and the three others with variable developmental, psychomotor and language delay.

Objective and Methods

In this study, we screened 206 patients with autism spectrum disorders for the WBCR duplication by quantitative microsatellite analysis and multiple ligation‐dependent probe amplification.

Results

We identified one male patient with a de novo interstitial duplication of the entire WBCR of paternal origin. The patient had autistic disorder, severe language delay and mental retardation, with very mild dysmorphic features.

Conclusion

We report the first patient with autistic disorder and a WBCR duplication. This observation indicates that the 7q11.23 duplication could be involved in complex clinical phenotypes, ranging from developmental or language delay to mental retardation and autism, and extends the phenotype initially reported. These findings also support the existence of one or several genes in 7q11.23 sensitive to gene dosage and involved in the development of language and social interaction.     

Supravalvular aortic stenosis cosegregates with a familial 6;7 translocation which disrupts the elastin gene

Supravalvular aortic stenosis (SVAS) is an autosomal dominant disorder characterized by abnormalities of development of the great vessels. SVAS is also commonly part of Williams syndrome. Linkage to the elastin gene on chromosome 7q11 has recently been reported in two kindreds with SVAS. Previous reports of patients with 7q11 deletions have noted great vessel abnormalities in some. We report on a family in which SVAS is cosegregating with a balanced reciprocal translocation, t(6:7) (p21.1;q11.23), providing further evidence that SVAS is the result of mutation of elestin at 7q11.23 region. The propositus of the translocation family has some minor anomalies which occur in Williams syndrome, Suggesting that elestin abnormalities may cause some of the abnormalities found in Williams syndrome. © 1993 Wiley-Liss, Inc. © 1993 Wiley-Liss, Inc.     

Williams–Beuren syndrome: novel risk alleles in transmitting parents

Copy number variation at the 7q11.23 segmental duplications is a susceptibility factor for the Williams–Beuren syndrome deletion
Cuscó et al. (2008)
Genome Research 18 (5): 683–694. Epub 21 February 2008     

Molecular cytogenetic diagnosis of Williams syndrome

Williams syndrome (WS) is characterized by distinct facial changes, growth deficiency, mental retardation, and congenital heart defect (particularly supravalvular aortic stenosis), associated at times with infantile hypercalcemia. Molecular genetic studies have indicated that hemizygosity at the elastin locus (7q11.23) causes WS. The purpose of this study was to confirm that this regional deletion, involving the elastin locus, is the cause of WS in Japan, and to clarify the correlation between the phenotype and the elastin locus. Thirty-two patients with WS and thirty of their relatives were examined by fluorescent in situ hybridization (FISH), using the WS chromosome region (WSCR) probe. All patients had cardiovascular disease (100%), 30 had typical WS facial changes (94%), 31 had mental retardation or developmental delay (97%), 16 were small-for-date at birth (50%), 14 had short stature (44%), and 13 had dental anomalies (41%). No relatives showed any manifestation of WS. Hemizygosity for a region of 7q11.23, involving the elastin locus, was found in all WS patients, but was not found in the 30 relatives. © 1996 Wiley-Liss, Inc.     

TFII-I gene family during tooth development: candidate genes for tooth anomalies in Williams syndrome.

Williams syndrome is a rare congenital disorder involving the cardiovascular system, mental retardation, distinctive facial features, and tooth anomalies. It is caused by the heterozygous deletion of approximately 1.6 Mb encompassing 28 genes on human chromosome 7q11.23. It has been suggested that the genes responsible for craniofacial anomalies are located in the telomeric end region, which harbors three members of the TFII-I gene family (Tassabehji et al. [2005] Science 310:1184). To recognize potential candidate genes for the tooth anomalies in Williams syndrome, we carried out comparative in situ hybridization analysis of members of TFII-I gene family during murine odontogenesis. Gtf2i showed widespread expression in the developing head but was higher in the developing teeth than surrounding tissues throughout tooth development. At the bud stage, Gtf2ird1 and Gtf2ird2 were expressed in the epithelial buds. At the early bell stage, expression of Gtf2ird1 and Gtf2ird2 was observed in preameloblasts and preodontoblasts.     

Cohen syndrome and de novo reciprocal translocation t(5;7)(q33.1;p15.1)

Here we report on a de novo apparently balanced reciprocal 5q;7p translocation in a 15-year-old girl with apparent Cohen syndrome characterized by hypotonia, obesity, multiple congenital anomalies, and mental retardation. This case may indicate that the gene for Cohen syndrome is at 5q33.1 or 7p15.1.     

Cohen syndrome and de novo reciprocal translocation t(5;7) (q33.1;p15.1)

Here we report on a de novo apparently balanced reciprocal 5q;7p translocation in a 15-year-old girl with apparent Cohen syndrome characterized by hypotonia, obesity, multiple congenital anomalies, and mental retardation. This case may indicate that the gene for Cohen syndrome is at 5q33.1 or 7p15.1.     

Opitz trigonocephaly C syndrome in a boy with a de novo balanced reciprocal translocation t(3;18)(q13.13;q12.1)

Opitz trigonocephaly C syndrome (OTCS) is a multiple congenital anomaly syndrome characterized by trigonocephaly, mental retardation, a typical facial appearance, redundant skin, joint and limb abnormalities, and visceral anomalies. We describe a patient with the manifestations of OTCS who also had a de novo balanced reciprocal translocation t(3;18)(q13.13q12.1). His phenotype is a mild form with mild developmental delay and no severe visceral anomalies. Our findings suggest the possible existence of a new locus responsible for OTCS either on 3q13.13 or 18q12.1.     

Familial complex 3q;10q rearrangement unraveled by subtelomeric FISH analysis

In recent years, subtelomeric rearrangements have been identified as a major cause of multiple congenital anomalies/mental retardation syndromes. Currently, more than 2,500 individuals with mental retardation have been tested and reported in whom subtelomeric rearrangements were detected ranging from 2% to 29%. Therefore, subtelomeric FISH analysis is indicated as a second tier test after high-resolution G-banding analysis in patients with otherwise unexplained developmental delay/mental retardation and/or multiple congenital anomalies. We describe a patient and her three maternal female cousins, all showing an undiagnosed MCA/MR syndrome, associated with the same complex subtelomeric rearrangement. Subtelomeric FISH testing performed between 3(1/2) and 18 years after the initial karyotype showed, in all four patients, distal trisomy 3q and distal monosomy 10q as follows: 46,XX,ish der(10)t(3;10)(q29;q26.3)mat(D10S2488+,D10S2490-, D3S1272+,D10Z1+). Parental subtelomeric FISH analysis showed that the proposita's mother and three of four brothers and one of two sisters had a cryptic balanced 3:10 telomere translocation. The three brothers with the balanced translocation were father to one each of the three proband's cousins. All four affected girls showed a similar phenotype with pre/postnatal growth retardation, microcephaly, severe developmental delay/mental retardation, poor/absent speech, and a distinct pattern of malformation. On examination there were coarsening of facial features with low fronto-temporal hairline; thick eyebrows; bilateral epicanthal folds; hypertelorism; prominent nose with squared nasal root and narrow alar base; low-set posteriorly rotated large ears with a prominent anthelix; high arched palate; prominent chin; hands/feet brachydactyly; bilateral squint; hypotonia; and muscle hypotrophy. A slow overall improvement was seen in all patients over time. To our knowledge, this complex subtelomeric rearrangement in our patients has never been reported so far. Monosomy 10q has recently been described either isolated or as part of a complex rearrangement involving telomeres other than the 3q. Trisomy 3q29 has not yet been reported, but our patients resembled cases with 3q26 trisomy suggesting that the critical region of duplication for this phenotype is in 3q29.     

Williams syndrome: from genotype through to the cognitive phenotype

Williams syndrome, due to a contiguous gene deletion at 7q11.23, is associated with a distinctive facial appearance, cardiac abnormalities, infantile hypercalcemia, and growth and developmental retardation. The deletion is approximately 1.5Mb and includes approximately 17 genes. Large repeats containing genes and pseudogenes flank the deletion breakpoints, and the mutation mechanism commonly appears to be unequal meiotic recombination. Elastin hemizygosity is associated with supravalvular aortic stenosis and other vascular stenoses. LIM Kinase 1 hemizygosity may contribute to the characteristic cognitive profile. The relationship of the other deleted genes to phenotypic features is not known. People with Williams syndrome tend to be over friendly-though anxious-and lack social judgement skills. They exhibit an uneven cognitive-linguistic profile together with mild to severe mental retardation. Analysis of the cognitive phenotype based on analyses of the mental processes underlying overt behavior demonstrates major differences between normal and WS subjects although for some areas, such as face processing, WS subjects can achieve near normal scores. Cognitive analysis of patients with small deletions in 7q11.23 which include elastin and LIM Kinase 1 have revealed varying results and it is premature to draw genotype-phenotype correlations.     

De novo reciprocal 1p;2q translocation in a child with multiple congenital anomalies/mental retardation syndrome

A newborn male infant was found to have an unusual pattern of congenital anomalies associated with an apparently balanced de novo reciprocal translocation: 46,XY,t(1;2)(p22;q22). The infant had a previously apparently undescribed multiple congenital anomalies and mental retardation syndrome.     

Speech delay and autism spectrum behaviors are frequently associated with duplication of the 7q11.23 Williams-Beuren syndrome region.

PURPOSE: Williams-Beuren syndrome is among the most well-characterized microdeletion syndromes, caused by recurrent de novo microdeletions at 7q11.23 mediated by nonallelic homologous recombination between low copy repeats flanking this critical region. However, the clinical phenotype associated with reciprocal microduplication of this genomic region is less well described. We investigated the molecular, clinical, neurodevelopmental, and behavioral features of seven patients with dup(7)(q11.23), including two children who inherited the microduplication from one of their parents, to more fully characterize this emerging microduplication syndrome. METHODS: Patients were identified by array-based comparative genomic hybridization. Clinical examinations were performed on seven affected probands, and detailed cognitive and behavioral evaluations were carried out on four of the affected probands. RESULTS: Our findings confirm initial reports of speech delay seen in patients with dup(7)(q11.23) and further delineate and expand the phenotypic spectrum of this condition to include communication, social interactions, and repetitive interests that are often observed in individuals diagnosed with autism spectrum disorders. CONCLUSIONS: Array-based comparative genomic hybridization is a powerful means of detecting genomic imbalances and identifying molecular etiologies in the clinic setting, including genomic disorders such as Williams-Beuren syndrome and dup(7)(q11.23). We propose that dup(7)(q11.23) syndrome may be as frequent as Williams-Beuren syndrome and a previously unrecognized cause of language delay and behavioral abnormalities. Indeed, these individuals may first be referred for evaluation of autism, even if they do not ultimately meet diagnostic criteria for an autism spectrum disorder.     

Cortical dysplasia of the left temporal lobe might explain severe expressive-language delay in patients with duplication of the Williams-Beuren locus

We report on a new duplication case of 7q11.23, reciprocal of the Williams-Beuren (WB) deletion. The patient, a 13-year-old girl, was ascertained within an array-CGH screening of patients with epilepsy and neuronal migration defects. Similarly to the first reported patient, she showed serious difficulties in expressive language in the absence of severe mental retardation and marked dysmorphic features. Magnetic resonance imaging (MRI) of the brain revealed an abnormal development of the cerebral cortex in the left temporal lobe, which showed a simplified gyral pattern, and increased cortical thickness. This finding, which might explain poor language development, suggests that the WB critical region might harbour a dosage-sensitive gene controlling the molecular machinery of neuronal migration, with regional specificity and lateralization. It will be important to confirm our findings in newly diagnosed patients with dup(7)(q11.23). We expect to detect many more patients with the same duplication using widespread clinical implementation of high-resolution genome analysis.     

Familial reciprocal translocation, t(2;10)(p24;q26), resulting in duplication 2p and deletion 10q

We describe a familial reciprocal translocation between the distal part of the short arm of chromosome 2 and the long arm of chromosome 10. Five individuals in two generations had multiple congenital anomalies. Their karyotypes were 46, XX or XY,−10, + der(10), t(2;10)(p24;q26). Seven persons were balanced translocation carriers whose karyotypes were 46, XX or XY, t(2;10)(p24;q26). Common manifestations included mental retardation, strabismus, narrow high-arched palate, wide alveolar ridges, other facial abnormalities, genital abnormalities and mutism. The phenotype of the unbalanced individuals is compared to that of previously published cases of the syndrome of partial duplication 2p and to reported patients with partial deletion of 10q.     

Delineation of a duplication map of chromosome 3q: A new case confirms the exclusion of 3q25-q26.2 from the duplication 3q syndrome critical region

We report on the clinical, cytogenetic, and molecular characterization of a propositus and his mother with a duplication of 3q25–q26, minor anomalies, and mental retardation. The duplication, detected by cytogenetic analysis, was confirmed and delineated by comparative genomic hybridization and fluorescence in situ hybridization using probes previously mapped to the region. Comparison of the mapping data obtained in these patients and those obtained in patients that present with a typical dup(3q) syndrome phenotype shows that the segment duplicated in these patients lies proximally to the reported dup(3q) syndrome critical region, thus explaining the absence in our patients of the characteristic phenotype of dup(3q) syndrome patients. Accumulation of mapping data in patients with segmental duplications of 3q will eventually allow us to build a duplication map of the region and a genotype-phenotype correlation. Am. J. Med. Genet. 68:428–432, 1997. © 1997 Wiley-Liss, Inc.     

Free proximal trisomy 21 without the Down syndrome

Analysis of partial duplication of chromosome 21 suggests that band 21q22 contains determinants for the Down syndrome. We report two cases of free proximal trisomy 21 without manifestations of the Down syndrome. Phenotypic anomalies included marked microcephaly, short stature, hypoplastic nails, and mental retardation/developmental delay. Our cases are consistent with the assignment of band 21q22 as the causal duplicated segment in the Down syndrome.     

Microduplication of Xp11.23p11.3 with effects on cognition,behavior, and craniofacial development

El‐Hattab AW, Bournat J, Eng PA, Wu JBS, Walker BA, Stankiewicz P, Cheung SW, Brown CW. Microduplication of Xp11.23p11.3 with effects on cognition, behavior, and craniofacial development. We report an ～1.3 Mb tandem duplication at Xp11.23p11.3 in an 11‐year‐old boy with pleasant personality, hyperactivity, learning and visual‐spatial difficulties, relative microcephaly, long face, stellate iris pattern, and periorbital fullness. This clinical presentation is milder and distinct from that of patients with partially overlapping Xp11.22p11.23 duplications which have been described in males and females with intellectual disability, language delay, autistic behaviors, and seizures. The duplicated region harbors three known X‐linked mental retardation genes: FTSJ1, ZNF81, and SYN1. Quantitative polymerase chain reaction from whole blood total RNA showed increased expression of three genes located in the duplicated region: EBP, WDR13, and ZNF81. Thus, over‐expression of genes in the interval may contribute to the observed phenotype. Many of the features seen in this patient are present in individuals with Williams‐Beuren syndrome (WBS). Interestingly, the SYN1 gene within the duplicated interval, as well as the STX1A gene, within the WBS critical region, co‐localize to presynaptic active zones, and play important roles in neurotransmitter release.