Abstract
Williams–Beuren syndrome (WBS; OMIM no. 194050) is a multisystemic neurodevelopmental disorder caused by a hemizygous deletion of 1.55 Mb on chromosome 7q11.23 spanning 28 genes. Haploinsufficiency of the ELN gene was shown to be responsible for supravalvular aortic stenosis and generalized arteriopathy, whereas LIMK1, CLIP2, GTF2IRD1 and GTF2I genes were suggested to be linked to the specific cognitive profile and craniofacial features. These insights for genotype–phenotype correlations came from the molecular and clinical analysis of patients with atypical deletions and mice models. Here we report a patient showing mild WBS physical phenotype and normal IQ, who carries a shorter 1 Mb atypical deletion. This rearrangement does not include the GTF2IRD1 and GTF2I genes and only partially the BAZ1B gene. Our results are consistent with the hypothesis that hemizygosity of the GTF2IRD1 and GTF2I genes might be involved in the facial dysmorphisms and in the specific motor and cognitive deficits observed in WBS patients.
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Introduction
Williams–Beuren syndrome (WBS) is a multisystemic developmental disorder caused by a hemizygous deletion spanning 1.55 or 1.84 Mb on chromosome 7q11.23, a segment encoding 28 genes.1, 2, 3, 4 This region frequently undergoes genomic rearrangements due to the presence of low copy repeats flanking the commonly deleted region and results in meiotic nonallelic paralogous recombination.1 Consistently, along with the 7q11.23 deletion, recent papers reported the reciprocal duplication5, 6 and inversion7, 8 of the region. WBS has a prevalence estimated between 1/7500 and 1/20 000.9 The phenotype is widely heterogeneous in severity and manifestations (see Table 1), but generally entails distinctive facial dysmorphisms, cardiovascular abnormalities and mental retardation with a particular cognitive profile.10 The main cardiovascular abnormality is a generalized arteriopathy that is often accompanied by early hypertension.11 It is characterized by arteries stenoses, predominantly affecting the supravalvular aortic (SVAS) and peripheral pulmonary (PPS) regions. Nearly all WBS infants and young children exhibit developmental delay, which subsequently results in mild to moderate mental retardation. WBS is characterized by a specific cognitive profile with relative strengths in selected language domains alongside a prominent weakness in visuospatial construction.11 Similarly, WBS patients show a combination of high sociability and empathy for others with high anxiety. Patients demonstrate an adaptable behavior profile with relative strengths in socialization and communication skills and obvious weakness in daily living skills.10, 12 Endocrine abnormalities, including impaired glucose tolerance and diabetes mellitus are commonly observed in WBS patients and recently impairment of thyroid function and/or structure has been reported in about a third of patients.13
The majority of deletions span the same interval, however, a few individuals have smaller and/or larger deletions of the region. Their phenotypic features vary from isolated SVAS to classic WBS associated with infantile spasms or with autism spectrum behavior.5, 14, 15 Genotype–phenotype correlation studies of these patients suggested important insights in the genetic causes of some of the typical WBS symptoms. So far, the strongest correlations have been found for some of the facial features and cardiovascular problems linked to elastin haploinsufficiency.16, 17 In addition, clinical and molecular correlations in atypical patients and mouse models studies provided further genotype–phenotype correlations. These studies revealed that the most telomerically mapping genes such as GTF2I, GTF2IRD1 and CLIP2 (a.k.a. CYLN2) may contribute to the behavioral and cognitive manifestation of WBS.14, 18, 19, 20, 21, 22, 23, 24
Here we describe a male child (WBS207) with mild WBS physical features, average intelligence with normal IQ and only some features of the WBS neuropsychological profile. He carries a smaller atypical deletion of ∼1 Mb that does not include GTF2IRD1, GTF2I and only partially includes BAZ1B. Our results are consistent with the hypothesis that associates GTF2IRD1 and GTF2I hemizygosity to the WBS specific motor and cognitive deficits.
Materials and methods
Sample preparation
Genomic DNA from the proband and his parents were extracted from peripheral blood leukocyte using QIAamp DNA Mini Kit (Qiagen, Hilden, Germany). WBS and normal individuals' samples to be used as controls were selected from a previous study.21
Fluorescence in situ hybridization and quantitative real-time PCR
Fluorescence in situ hybridization was performed on metaphase cells following standard technique using the LSI ELN, D7S486 and D7S522 probes (Vysis). At least 30 metaphases were analyzed. All quantitative real-time PCR (QPCR) reactions were carried out as described.21 Amplicons and primer pairs are presented in Supplementary Table S1. The comparative Ct method reported in25 was used to measure relative quantities.
Results
Clinical findings
The proband, an 11–year-old boy, is the second child of healthy nonconsanguineous Italian parents aged 38 years (father) and 33 years (mother). The parents have both secondary educational levels, displaying normal professional and social interactions; their cognitive assessment has not been performed, due to lack of collaboration. Paternal and maternal heights are 180 cm and 172 cm respectively. Family history is unremarkable for mental retardation and/or congenital anomalies. He was born by spontaneous delivery without complications after 40 weeks of gestation. The pregnancy was complicated by uterine contractions from the 22nd week of gestation, controlled with rest and oral β-mimetic (Isoxsuprine). Birth weight, length and head circumference (OFC) were 2.830 kg (10th centile), 47.5 cm (3rd to 10th centile) and 34 cm (25–50th centile), respectively. Apgar scores were 9/9. He was breastfed, displaying a normal length and weight growth. During the first month of life an umbilical hernia was diagnosed, afterwards it spontaneously regressed. He was hospitalized for the persistence of a systolic heart murmur. A cardiology ultrasound examination unveiled a stenosis of the pulmonary valve with instantaneous pressure gradient (Δp) of 30 mm Hg, hemodynamically insignificant. Yearly echocardiography follow-up disclosed a mild SVAS (Δp 25 mm Hg) at 5 years of age. Hence the patient was referred to the pediatric-genetic clinic, where the association of the arterial abnormality with peculiar facial traits led to the clinical suspicion of WBS. The hypothesis was subsequently confirmed by cytogenetics analysis (see below). Spontaneous improvement of pulmonary valve stenosis and steadiness of SVAS have been documented by annual echocardiography follow-up.
Developmental milestones were reached at appropriate ages. He walked without support and spoke his first words at 13 and 15 months, respectively, showing a definitively normal motor development. The parents reported alteration of the normal 24 h sleep–wake cycle (sleep time 2000 hours to 0300 hours) and an outgoing personality consisting of increased approach to strangers and loquacity in early infancy. A cognitive assessment using the WPPSI test was performed at 6 years of age, revealing a normal full-scale IQ score of 105, although with an important difference between verbal IQ (117) and performance IQ (91). Particularly, he exhibited weaknesses on object assembly, geometric design and block design subtests, and strengths on vocabulary and similarities subtests (see Figure 1 for details). Remarkably, a mild impairment of ocular convergence and some hampering of fine motricity (the patient is left handed) were concurrently noted. The boy attended regular school with good results, without requiring specific teaching backup. An ophthalmologic assessment at 7 years of age revealed a hypermetropic astigmatism associated with convergent strabismus of the right eye. A concomitant evaluation by Developmental Test of Visual Perception (DTVP) disclosed an attention deficit and confirmed the light motricity impairment. A subsequent psychomotor evaluation, including DTVP, puzzles reproduction, block construction and drawing task, was performed after ocular anomalies correction. It revealed adequate results in ocular-motor integration, in hand-eye coordination and in visual perception. Moreover simple and complex ideomotor praxias resulted normal in movement programming and execution, but a slight weakness was observed in visual explorative and visual constructive performances (single scores not available). At the age of 11 years, the proband weight was 35 kg (50th centile), height 132 cm (5th centile), head circumference 51 cm (10th centile). Clinical evaluation disclosed bitemporal narrowing, broad forehead, short upturned nose with bulbous tip, long philtrum, full lips, bilateral clinodactyly of 5th fingers of the hands, hoarse voice, mild limitation of supination and pronation of the forearm, valgus flatfoot and knock knees. Echocardiography confirmed a hemodynamically insignificant mild SVAS (Δp 20 mm Hg). An elevation of serum TSH level (6.10 mUI/l, n.v. 0.4–4.4 mUI/l) with normal fT3 and fT4 levels was found; further analyses revealed antithyroid antibodies (antithyroid peroxidase, 342 kU/l, n.v. <40 kU/l), not associated with morphological abnormalities, leading to medical therapy with L-thyroxine. Screening for celiac disease was negative (quantitative serum IgA 163 mg/100 ml, antitissue transglutaminase IgA 0 IU/ml, antiendomysion IgA negative). Serum calcium (5.10 mEq/l), creatinine, cholesterol, triglyceride, liver enzymes, urinalysis, urinary calcium, 24-hour ambulatory blood pressure monitoring (mean daytime blood pressure 109/72 mm Hg, mean nighttime blood pressure 100/63 mm Hg) and abdominal ultrasound examination completed by echo color Doppler ultrasound of renal vessels were all normal.
Neurological examination did not show any abnormalities. An updated cognitive and psychological assessment by specific tests could not be performed because of parental refusal. Nevertheless the proband is attending regular schooling, and teachers, unaware of the genetic diagnosis, never pointed out any learning difficulties. Moreover, he plays soccer in a nondisabled age-matched team, showing a normal social life for his age, overall. We had the opportunity to observe the patient during the entire day on the occasion of clinical follow-up appointment and we noted that the outgoing personality traits referred by the parents since 5 years of age completely disappeared as he did not display increased sociability or anxiety with peers and/or strangers and an adequate interaction was observed at clinical examination.
Deletion mapping by FISH and genomic QPCR
FISH analysis revealed a single signal in cells from proband WBS207, whereas control probes detected two signals on chromosome 7 (data not shown). To map the deletion breakpoints we used QPCR as described.21 The first set of assays detected hemizygosity for the genes comprised between TBL2 and CLIP2 but not for BAZ1B and GTF2IRD1 (data not shown). To narrow down the centromeric and telomeric breakpoints, we designed new QPCR assays mapping to the BAZ1B and CLIP2 loci, respectively (Figure 2; Supplementary Table S1). The centromeric breakpoint maps between assay BAZ1B_17.002 (assay mapping in the third intron of BAZ1B) and assay BAZ1B_17.003 (fourth intron of BAZ1B) that are present in one and two copies, respectively. Thus BAZ1B is hemizygote for its transcription start site (TSS) and at least its first three exons. Note that both Ensembl release 50 (July 2008) and the UCSC Genome Browser do not report other more distal TSSs for that gene.
The telomeric breakpoint reaches the gene CLIP2 but preserves the two copies of the adjacent GTF2IRD1 and GTF2I genes. The boundary assays are 5_CYLN2 (intron 3 of CLIP2) and 4.13_CYLN2/GTF2IRD1 (intergenic region between CLIP2 and GTF2IRD1), which are present in a single and two copies, respectively (Supplementary Table S1 and Figure 1). These analyses indicate that the WBS207 proband carries a deletion of less than 1 Mb (0.84–0.94 Mb) that maps to the core of the WBS critical region and excludes the GTF2I, GTF2IRD1 and the 3′ portion of the BAZ1B gene. The absence of the deletion in both parents, assayed by QPCR, indicated that the deletion occurred de novo (Figure 2).
Discussion
We describe a patient with a ∼1 Mb deletion in the WBS genomic interval. This atypical rearrangement is shorter than the classical deletion both at the centromeric and telomeric sides. Cytogenetic and molecular analyses showed that the proband carries a deletion that does not include GTF2IRD1 and GTF2I at the telomeric end whereas the centromeric breakpoint lies between introns 3 and 4 of the BAZ1B gene (Figure 2). Even if not formally proven, because of lack of mRNA for WBS207, the expression of the BAZ1B is probably affected because the most distally mapped transcriptional start site for that gene is hemizygous in our patient. Although we were partially prohibited by the parents to pursue in-depth cognitive profiling, the comparison of the phenotype of proband WBS207 with those of typical WBS patients revealed some interesting clues. From a phenotypic perspective, he does not present a striking facial gestalt of WBS. For instance, he does not present periorbital fullness, stellate iris, dental abnormalities and the malocclusion commonly observed in WBS patients. Similarly, he does not present hypercalcemia, feeding difficulties or other gastrointestinal abnormalities (see Table 1). The most interesting feature of WBS207 is the peculiar cognitive profile, characterized by a normal full-scale IQ (105), with a difference between verbal IQ (117) and performance IQ (91). He displayed strengths on all verbal subtests except for arithmetic and weaknesses on object assembly, geometric designs and block design subtests. He attends regular school without any support and does not present overfriendly personality, even though parents reported an increased approach to strangers and loquacity in early infancy.
Our data are in keeping with previous partial deletion studies (Figure 3). Specifically, the mild clinical phenotype and the cognitive profile seen in WBS 207 and the mapping of the breakpoints suggest a role for CLIP2, GTF2IRD1 or GTF2I in some of the WBS facial features consistently with previous reports.14, 21, 24, 26 In the past years, the identification of an increasing number of WBS with smaller than usual deletions of 7q11.23 shed light on the genetic bases of some of associated clinical features (Figure 3). From these studies, it has been argued, for example, that CLIP2 hemizygosity contributes to motor coordination abnormalities.27 Other reports suggested that the GTF2I and GTF2IRD1 genes have dosage-dependent influences on craniofacial and neurological development and that hemizygosity for these genes appears to be associated with the general intellectual disability/mental retardation22 and/or visuospatial construction difficulties.19, 21, 24, 28, 29, 30 Finally, further insights into genotype–phenotype correlations come from an intriguing report of an individual without the abnormal motor behavior and the specific spatial and impaired visual–spatial capacities. Genetic analysis showed that this patient had a deletion that excluded the genes RFC2, CLIP2, GTF2IRD1 and GTF2I.27 Recently Korenberg's group described a child with an atypical WBS deletion.30 This female patient is hemizygote for GTF2IRD1, but the rearrangement does not include the more distal GTF2I gene. Her cognitive performance was overall remarkably above WBS typical range, but with striking deficits in visual–spatial construction (VSC). In addition, she did not show the typical overly social behavior seen in WBS individuals. These observations combine with previously published cases suggest that hemizygosity of the GTF2IRD1 gene is associated with the WBS facial features and VSC deficits, whilst that of the GTF2I gene plays a crucial role in the genesis of the WBS social behavior. Together these studies indicated that the telomeric end of the WBS critical region contains genes that emerge as the most promising candidates for the cognitive, behavioral and neural phenotype seen in WBS patients. The detection of a normal full-scale IQ in our patient supports the previous assumptions that GTF2IRD1 and GTF2I genes are crucial for WBS cognitive features.19, 22, 27, 28, 29, 30, 31 Nevertheless, we have to emphasize that our patient exhibits a peculiar discrepancy between verbal IQ and performance IQ, resembling the PIQ/VIQ ratio that has been reported in typical WBS patients.19, 32, 33 This finding seems contrary to previous reports of absent or minor visuospatial deficit in atypical WBS patients keeping GTF2IRD1 and GTF2I genes.19, 28, 31 Nonetheless, WBS207 scores on performance subtests were heterogeneous because he exhibited difficulties in geometric designs but not in picture completion, even if both investigate VSC, and in object assembly and in block design, but not in mazes, even if all investigate visual-motor integration. Therefore, the low result of PIQ could be related to the ocular anomalies (hypermetropic astigmatism associated with convergent strabismus) in association to some hampering of his fine motricity. Unfortunately, an updated and in-depth cognitive assessment by specific tests could not be performed because of parental refusal. Moreover, as parental IQs were unavailable, we can't exclude that the high VIQ score results from high biological potential derived from high-functioning parents. Alternatively, the visual–spatial impairment showed by WBS207 could be explained by a long-range position effect of the deletion that modifies the physiologic expression of GTF2IRD1 and/or GTF2I genes. Consistently, submicroscopic deletion and duplication were shown to modify the expression levels of some of their flanking genes.34, 35, 36, 37, 38 We could also not rule out the possibility that abnormally low levels of LIMK1 combined with reduced levels of other proteins involved in brain function (eg CLIP2) could affect spatial impairment, as suggested previously.35
GTF2I, GTF2IRD1 and GTF2IRD2 belong to the TFII-I gene family of transcription factors.36 They interact promiscuously with multiple proteins and DNA and could, therefore, influence a broad range of neural physiological and developmental processes. GTF2I acts as a basal transcription factor that binds to initiator elements of various promoters and also regulates transcription through E-box elements at enhancers in response to upstream signaling events.37 GTF2IRD1 can bind regulatory elements upstream of genes involved in tissue development and differentiation such as HOXC8, GOOSECOID and TROPONIN ISLOW.38, 39 The null mutants of the orthologous Gtf2ird1 and Gtf2i genes have been generated.24, 40, 41 The deletion of Gtf2ird1 by targeted insertion of a LacZ cassette in its second exon does not exhibit craniofacial dysmorphology or dental abnormalities.41 In contrast, a previous report, a mouse model with a deletion between Clip2 and the first exon of Gtf2ird1, presented craniofacial abnormalities involving a misaligned jaw, a twisted snout and dental abnormalities.24 The recently complete knockouts of the Gtf2ird1 and Gtf2i genes demonstrated that mice heterozygous for these genes are often growth retarded and exhibit hypoplasia of the mandible, as well as other craniofacial defects reminiscent of the characteristic facial appearance and dental problems seen in WBS individuals.40 Concomitantly a recent article showed that during mouse embryogenesis Baz1b is expressed strongly in the cranial neural crest-derived mesenchyme that drives facial morphogenesis. The reduction of the level of encoded protein was the source of an array of craniofacial features similar to those shown by typical WBS patients, such as a small upturned nose with flat nasal bridge, micrognathia (or mandibular hypoplasia), malocclusion, bitemporal narrowing and prominent forehead.42 These results suggest that genes mapping at the proximal and the distal end of the WBS deletion could be implicated in the genesis of the typical elfin facies. We should, therefore, not exclude the possibility that some of the mild facial features seen in the WBS207 patient could result from Baz1b haploinsufficiency.
Our study confirms the utility of atypical patients for WBS genotype–phenotype correlation. The identification of more of those subjects with a careful comparison of their genetic, clinical and neuropsychological profiles will be needed and useful to assess the contribution of each gene to the WBS phenotype. We also underline the utility of QPCR as a feasible and reliable method to precisely map deletion breakpoints. This technique represents a valid cost-effective alternative to FISH and MLPA or other more expensive, although with higher resolution, methods such as array CGH.
KEY POINTS
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Williams–Beuren syndrome is caused by a 1.55 Mb hemizygous deletion on chromosome 7q11.23, a segment encoding 28 genes
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Genotype–phenotype correlation studies of few individuals with smaller deletions are useful to assess the contribution of each gene to the WBS phenotype
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The phenotype of the WBS207 atypical patient suggests that GTF2IRD1 and/or GTF2I genes hemizygosity play(s) a role in the facial dysmorphisms and in the specific motor and cognitive deficits observed in WBS patients.
Conflict of interest
The authors declare no conflict of interest.
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Acknowledgements
We are grateful to the family who participated in the study. This work was supported by grants from the Jérôme Lejeune Foundation, the Telethon Action Suisse Foundation, the Novartis Foundation, the Swiss National Science Foundation and the European commission (anEUploidy grant 037627) to AR, by grants from the Italian Ministry of Health (Ricerca Corrente 2007–09), the Fondazione Banca del Monte di Foggia ‘Domenico Siniscalco Ceci’, the Italian Telethon Foundation (Grant N. GGP06122), the Jérôme Lejeune Foundation and Italian Foreign Office to GM, Compagnia di San Paolo and Fondazione CRT, Torino to GBF.
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Ferrero, G., Howald, C., Micale, L. et al. An atypical 7q11.23 deletion in a normal IQ Williams–Beuren syndrome patient. Eur J Hum Genet 18, 33–38 (2010). https://doi.org/10.1038/ejhg.2009.108
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DOI: https://doi.org/10.1038/ejhg.2009.108
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