Expansion of the phenotypic and mutational spectrum of Carpenter syndrome

Carpenter syndrome 1 (CRPT1) is an acrocephalopolysyndactyly (ACPS) disorder characterized by craniosynostosis, polysyndactyly, obesity, and other malformations. It is caused by mutations in the gene RAB23. We are reporting on two patients from two unrelated consanguineous Egyptian families. Patient 1 presented with an atypical clinical presentation of Carpenter syndrome including overgrowth with advanced bone age, epileptogenic changes on electroencephalogram and autistic features. Patient 2 presented with typical clinical features suggestive of Carpenter syndrome. Therefore, Patient 1 was subjected to whole exome sequencing (WES) to find an explanation for his unusual features and Patient 2 was subjected to Sanger sequencing of the coding exons of theRAB23 gene to confirm the diagnosis. We identified a novel homozygous missense RAB23 variant (NM_001278668:c.T416C:p.Leu139Pro) in Patient 1 and a novel homozygous splicing variant (NM_016277.5:c.398+1G > A) in Patient 2. We suggest that the overgrowth with advanced bone age, electroencephalogram epileptogenic changes, and autistic features seen in Patient 1 are an expansion of the Carpenter phenotype and could be due to the novel missense RAB23 variant. Additionally, the novel identified RAB23 variants in Patient 1 and 2 broaden the spectrum of variants associated with Carpenter syndrome.     

Carpenter syndrome: Marked variability of expression to include the summitt and Goodman syndromes

Here we report on two sibs with Carpenter syndrome showing marked intrafamilial variability. One patient had craniosynostosis of the sagittal suture, normal intelligence, and no abnormalities of hands and feet. The second patient had polysyndactyly of hands and feet, normal intelligence, and no craniosynostosis. The diagnosis of Carpenter syndrome was made after the second affected child in the family was born. This report emphasizes previous suggestions that acrocephalopolysyndactyly, type II, has variable clinical expression. It is suggested that polysyndactyly of feet is not an absolute requisite for the diagnosis of Carpenter syndrome. This allows the inclusion of Summitt and Goodman syndromes within the clinical spectrum of this disorder.     

Hypoparathyroidism,deafness, and renal dysplasia syndrome: 20 Years after the identification of the first GATA3 mutations

The hypoparathyroidism, deafness, and renal dysplasia (HDR) syndrome is an autosomal dominant disorder caused by heterozygous mutations of the GATA3 gene. In the last 20 years, since the identification of the genetic cause of the HDR syndrome, GATA3 mutations have been reported in 124 families (177 patients). The clinical aspects and molecular genetics of the HDR syndrome are reviewed here together with the reported mutations and phenotypes. Reported mutations consist of 40% frameshift deletions or insertions, 23% missense mutations, 14% nonsense mutations, 6% splice‐site mutations, 1% in‐frame deletions or insertions, 15% whole‐gene deletions, and 1% whole‐gene duplication. Missense mutations were found to cluster in the regions encoding the two GATA3 zinc‐finger domains. Patients showed great clinical variability and the penetrance of each HDR defect increased with age. The most frequently observed abnormality was deafness (93%), followed by hypoparathyroidism (87%) and renal defects (61%). The mean age of diagnosis of HDR was 15.3, 7.5, and 14.0 years, respectively. However, patients with whole‐gene deletions and protein‐truncating mutations were diagnosed earlier than patients with missense mutations.     

The Fibroblast Growth Factor Receptor 2 p.Ala172Phe Mutation in Pfeiffer Syndrome—History Repeating Itself

Pfeiffer syndrome is an autosomal dominant condition classically combining craniosynostosis with digital anomalies of the hands and feet. The majority of cases are caused by heterozygous mutations in the third immunoglobulin‐like domain (IgIII) of FGFR2, whilst a small number of cases can be attributed to mutations outside this region of the protein. A mild form of Pfeiffer syndrome can rarely be caused by a specific mutation in FGFR1. We report on the clinical and genetic findings in a three generation British family with Pfeiffer syndrome caused by a heterozygous missense mutation, p.Ala172Phe, located in the IgII domain of FGFR2. This is the first reported case of this particular mutation since Pfeiffer's index case, originally described in a German family in 1964, on which basis the syndrome was eponymously named. Genetic analysis demonstrated the two families to be unrelated. Similarities in phenotypes between the two families are discussed. Independent genetic origins, but phenotypic similarities in the two families add to the evidence supporting the theory of selfish spermatogonial selective advantage for this rare gain‐of‐function FGFR2 mutation. © 2013 Wiley Periodicals, Inc.     

Spectrum of HSPG2 (Perlecan) mutations in patients with Schwartz-Jampel syndrome

Schwartz-Jampel syndrome (SJS) is a rare autosomal recessive condition defined by the association of myotonia with chondrodysplasia. SJS results from mutations in the HSPG2 gene, which encodes perlecan, a major component of basement membranes. Only eight HSPG2 mutations have been reported in six SJS families. Here, we describe the molecular findings in 23 families (35 patients) with SJS, being one-third of the SJS cases reported in the medical literature. We identified 22 new HSPG2 mutations and unreported polymorphisms. Mutations included nine deletion or insertion (41%), six splice site (27%), five missense (23%), and two nonsense mutations (9%). All but four mutations were private, and we found no evidence for a founder effect. Analyses of HSPG2 messenger RNA (mRNA) and perlecan immunostaining on patients' cells revealed a hypomorphic effect of the studied mutations. They also demonstrated distinct consequences of truncating and missense mutations on perlecan expression as truncating mutations resulted in instability of HSPG2 mRNA through nonsense mRNA-mediated decay, whereas missense mutations involving cysteine residues led to intracellular retention of perlecan, probably due to quality control pathways. Our analyses strengthen the idea that SJS results from hypomorphic mutations of the HSPG2 gene. They also propose tools for its molecular diagnosis and provide new clues for the understanding of its pathophysiology.     

Two Swedish founder MSH6 mutations, one nonsense and one missense, conferring high cumulative risk of Lynch syndrome

Lynch syndrome, or hereditary non-polyposis colorectal cancer (HNPCC), is a cancer susceptibility syndrome caused by germline mutations in mismatch-repair genes, predominantly MLH1, MSH2 and MSH6. A majority of the mutations reported are truncating, but for MSH6, missense mutations constitute over one third. Few have been proven pathogenic in functional studies or shown to segregate in families. In this study, we show segregation of the putative pathogenic MSH6 missense mutation c.1346T>C p.Leu449Pro with microsatellite instability-high Lynch syndrome-related tumours lacking MSH6 expression in a large 17th century pedigree. Another large family with the MSH6 nonsense c.2931C>G, p.Tyr977X mutation is similar in tumour spectra, age of onset and cumulative risk. These MSH6 families, despite their late age of onset, have a high lifetime risk of all Lynch syndrome-related cancers, significantly higher in women (89% by age 80) than in men (69%). The gender differences are in part explained by high endometrial (70%) and ovarian (33%) cancer risks added upon the high colorectal cancer risk (60%). The several occurrences of breast cancer are not due to the MSH6 mutations. These findings are of great importance for counselling, management and surveillance of families with MSH6 mutations.     

Revisiting the craniosynostosis-radial ray hypoplasia association: Baller-Gerold syndrome caused by mutations in the RECQL4 gene

Baller‐Gerold syndrome (BGS) is a rare autosomal recessive condition with radial aplasia/hypoplasia and craniosynostosis (OMIM218600). Of >20 cases reported so far, a few appear atypical and have been reassigned to other nosologic entities, including Fanconi anaemia, Roberts SC phocomelia, and Pfeiffer syndromes after demonstration of corresponding cytogenetic or molecular abnormalities. Clinical overlap between BGS, Rothmund‐Thomson syndrome (RTS), and RAPADILINO syndrome is noticeable. Because patients with RAPADILINO syndrome and a subset of patients with RTS have RECQL4 mutations, we reassessed two previously reported BGS families and found causal mutations in RECQL4 in both. In the first family, four affected offspring had craniosynostosis and radial defect and one of them developed poikiloderma. In this family, compound heterozygosity for a R1021W missense mutation and a g.2886delT frameshift mutation of exon 9 was found. In the second family, the affected male had craniosynostosis, radial ray defect, poikiloderma, and short stature. He had a homozygous splice site mutation (IVS17‐2A>C). In both families, the affected offspring had craniosynostosis, radial defects, and growth retardation, and two developed poikiloderma. Our results confirm that BGS in a subgroup of patients is due to RECQL4 mutations and could be integrated into a clinical spectrum that encompasses RTS and RAPADILINO syndrome.     

Mutation analysis of Jagged1 (JAG1) in Alagille syndrome patients

Alagille syndrome (AGS) is an autosomal dominant disorder caused by mutations in Jagged1 (JAG1), a ligand in the evolutionarily conserved Notch signaling pathway. Previous studies have demonstrated that a wide spectrum of JAG1 mutations result in AGS. These include total gene deletions, protein truncating, splicing and missense mutations which are distributed across the coding region of the gene. Here we present results of JAG1 mutation screening by SSCP and FISH in 105 patients with AGS. For these studies, new primers were designed for 12 exons. Mutations were identified in 63/105 patients (60%). The spectrum of the JAG1 mutations presented here is consistent with previously reported results. Eighty three percent (52/63) of the mutations were protein truncating, 11% (7/63) were missense, 2% (1/63) were splice site, and 5% (3/63) were total gene deletions demonstrable by FISH. Six of the missense mutations are novel. As has been reported previously, there is no apparent relationship between genotype and clinical phenotype.     

No association between MUTYH and MSH6 germline mutations in 64 HNPCC patients

Hereditary non-polyposis colorectal cancer (HNPCC) is an autosomal dominant tumour predisposition syndrome caused by germline mutations in mismatch repair (MMR) genes. In contrast to MLH1 and MSH2, germline mutations in MSH6 are associated with a milder and particularly variable phenotype. Based on the reported interaction of the MMR complex and the base excision repair protein MUTYH, it was hypothesised that MUTYH mutations serve as phenotypical modifiers in HNPCC families. Recently, a significantly higher frequency of heterozygosity for MUTYH mutations among MSH6 mutation carriers was reported. We examined 64 MSH6 mutation carriers (42 truncating mutations, 19 missense mutations and 3 silent mutations) of the German HNPCC Consortium for MUTYH mutations by sequencing the whole coding region of the gene. Monoallelic MUTYH mutations were identified in 2 of the 64 patients (3.1%), no biallelic MUTYH mutation carrier was found. The frequency of MUTYH mutations was not significantly higher than that in healthy controls, neither in the whole patient group (P=0.30) nor in different subgroups regarding mutation type. Our results do not support the association between MSH6 mutations and heterozygosity for MUTYH mutations.     

Genotype/phenotype correlations in type 2 neurofibromatosis (NF2): evidence for more severe disease associated with truncating mutations.

Blood samples from 125 unrelated families with classical type 2 neurofibromatosis (NF2) with bilateral vestibular schwannomas have been analysed for mutations in the NF2 gene. A further 17 families fulfilling modified criteria for NF2 have also been analysed. Causative mutations have been identified in 54 (43%) classical families and six (35%) of those fulfilling modified criteria. Forty-two cases from 38 families with truncating mutations had an average age at onset of symptoms of 19 years and diagnosis at 22.4 years. Fifty-one cases from 16 families with splice site mutations (15 from six), missense mutations (18 from six), and large deletions (18 from five) had an average age of onset of 27.8 years and at diagnosis of 33.4 years. Subjects with truncating mutations were significantly more likely to have symptoms before 20 years of age (p<0.001) and to develop at least two symptomatic CNS tumours in addition to vestibular schwannoma before 30 years (p<0.001). There were also significantly fewer multigenerational families with truncating mutations. Four further truncating mutations were in mosaic form and were associated with milder disease than other similar mutations. This large study has confirmed the previous impression that truncating mutations are associated with severe disease, but caution has to be exercised in using mutation type to predict disease course.     

Legius syndrome in fourteen families

Legius syndrome presents as an autosomal dominant condition characterized by café-au-lait macules with or without freckling and sometimes a Noonan-like appearance and/or learning difficulties. It is caused by germline loss-of-function SPRED1 mutations and is a member of the RAS-MAPK pathway syndromes. Most mutations result in a truncated protein and only a few inactivating missense mutations have been reported. Since only a limited number of patients has been reported up until now, the full clinical and mutational spectrum is still unknown. We report mutation data and clinical details in fourteen new families with Legius syndrome. Six novel germline mutations are described. The Trp31Cys mutation is a new pathogenic SPRED1 missense mutation. Clinical details in the 14 families confirmed the absence of neurofibromas, and Lisch nodules, and the absence of a high prevalence of central nervous system tumors. We report white matter T2 hyperintensities on brain MRI scans in 2 patients and a potential association between postaxial polydactyly and Legius syndrome.     

The TWIST gene, although not disrupted in Saethre-Chotzen patients with apparently balanced translocations of 7p21, is mutated in familial and sporadic cases

The TWIST gene maps to 7p21 and mutations in the gene have been reported in the Saethre-Chotzen form of craniosynostosis. The position of the Saethre-Chotzen gene has previously been refined by FISH analysis of four patients carrying balanced translocations involving 7p21 which suggested that it was located between D7S488 and D7S503. We report here that the breakpoints in four translocation patients do not interrupt the coding sequence of the TWIST gene and thus most likely act through a positional effect. Twelve Saethre-Chotzen cases were found to have TWIST mutations. Four of these families had been used as part of the linkage study of the Saethre-Chotzen locus. The mutations detected included missense and nonsense mutations and three cases of a 21 bp duplication. Although phenotypically diagnosed as having Saethre- Chotzen syndrome, three families were found to have a pro250arg mutation of FGFR3.      

Mutations and molecular variants of the NBS1 gene in non-Hodgkin lymphoma

Non-Hodgkin lymphomas (NHLs) are characterized by chromosomal translocations that juxtapose loci encoding lymphoid antigen receptors with cellular proto-oncogenes. These translocations are thought to arise from inaccurate processing of DNA breaks created during physiologic recombination of the antigen receptor genes in lymphocytes. The inherited disorders ataxia-telangiectasia and Nijmegen breakage syndrome are caused by mutations in the ATM and NBS1 genes, respectively, and are characterized by generalized genomic instability and a high incidence of lymphoid cancers. Lymphoid cells from patients with either disorder frequently have chromosomal translocations involving T-cell-receptor or immunoglobulin loci. To investigate the potential role of the NBS1 gene in the pathogenesis of NHL, we screened tumor DNA samples from 91 sporadic cases of NHL and genomic DNA from 154 control individuals for mutations in all 16 exons of the NBS1 gene and in flanking intronic sequences. One NHL case with a truncating mutation in NBS1 and a second NHL case with a putative missense mutation were detected. Neither mutation was observed among controls. Three additional putative missense mutations were observed only in the normal control samples. A panel of six common polymorphisms spanning the NBS1 gene was genotyped and provided no evidence for loss of heterozygosity in the NHL cases with mutations or in the NHL population overall. These results suggest that mutations in NBS1 do not play a major role in the development of NHL in the United States.     

Familial CHARGE syndrome and the CHD7 gene: a recurrent missense mutation, intrafamilial recurrence and variability

CHARGE syndrome is an autosomal dominant condition that is caused by mutations in the CHD7 gene. Few familial cases of this syndrome have been reported and these were characterized by a wide clinical variability. We here report on five CHD7 mutation positive families and comment on their clinical features. We observed somatic and germline mosaicism as well as parent-to-child transmission of non-mosaic CHD7 mutations as causes of familial CHARGE syndrome. In one family with two affected sibs a somatic mutation was identified in lymphocytes of a clinically unaffected parent (2520G > A in exon 8). This is the second report of somatic CHD7 mosaicism in an unaffected parent. In two further families with affected siblings, we could not detect the mutation in parental lymphocytes suggesting germline mosaicism. The previously reported clinical variability was strikingly present in all five families. We find that alterations in CHD7 can result in a very mild phenotype, characterized by only a few minor symptoms of the CHARGE syndrome clinical spectrum. Such a mild phenotype was present in two families that shared the same 6322G > A missense mutation. These two families showed parent-to-child transmission. Phenotypically milder forms of CHARGE syndrome have a higher risk of transmission to multiple family members.     

Identification of WASP mutations in 10 Australian families with Wiskott-Aldrich syndrome and X-linked thrombocytopenia

Mutations of the gene encoding the Wiskott-Aldrich syndrome protein (WASP) have been previously shown to be responsible for classical Wiskott-Aldrich syndrome (WAS), isolated X-linked thrombocytopenia (XLT) and severe congenital X-linked neutropenia. AIMS: Identification of WASP mutations in 10 unrelated Australian families presenting with clinical features of WAS/XLT. METHODS: Mutation analysis was performed by PCR and sequence analysis. RESULTS AND CONCLUSIONS: Two novel mutations and seven mutations which have previously been reported were identified. The novel mutations consisted of a missense mutation in exon 2 (C290A) associated with the phenotype of XLT and a mutation in intron 10 (1372+1G>A) in the mother of two boys presenting with a classical WAS phenotype.     

Mutations in FOXL2 underlying BPES (types 1 and 2) in Colombian families

We report the genetic characterization of one family with blepharophimosis-ptosis-epicanthus inversus syndrome (BPES) type 1 and two families with BPES type 2 from a historically isolated population in northwest Colombia. Linkage and haplotype analyses indicate that BPES in these families is linked to 3q23. Mutation screening of FOXL2 in the family with BPES type 1 revealed a novel 394C --> T nonsense mutation which deletes the forkhead DNA binding domain. The two families with BPES type 2 both carry an in-frame 30 bp duplication that leads to the elongation of a polyalanine tract. This duplication has been previously reported in Europe, where recurrent mutation has been demonstrated in unrelated familial and sporadic BPES cases. The recurrent nature of this duplication seems to relate to the secondary structure of this DNA region. The genotype-phenotype correlation seen in the Colombian families is consistent with the recent proposal that BPES type 1 is caused by truncating mutations leading to haploinsufficiency, while BPES type 2 is due to mutations generating elongated protein products.     

Cancer risk in ATM heterozygotes: a model of phenotypic and mechanistic differences between missense and truncating mutations

The failure to find an increased frequency of ATM mutations in large cancer cohorts, especially breast cancer, is contrary to what was anticipated based on the increased cancer susceptibility of obligate ATM heterozygotes from families with ataxia-telangiectasia (A-T). We hypothesize that this paradox might be resolved if two types of ATM heterozygotes exist and the phenotypes differ, i.e., those with truncating types of mutations (ATM(trunc)), that make no protein, and those with missense types of mutations (ATM(mis)), that make reduced amounts of defective protein. The phenotype of ATM(trunc/trunc) mutations is the A-T syndrome; the phenotype of ATM(mis/mis) mutations, judging from the few homozygous patients that have been documented, appears to include some neurological features and cancer susceptibility but not the A-T syndrome. Evidence is reviewed which suggests that ATM(mis/wt) mutations are technically more difficult to detect than ATM(trunc/wt) mutations. Despite this, most large cancer cohort studies have identified mainly missense mutations and few truncating mutations. This model would require a paradigm shift for cancer risk analyses, to recognize the existence of different allele frequencies for the two types of A-T heterozygotes.     

Proven germline mosaicism in a father of two children with CHARGE syndrome

CHARGE syndrome is an autosomal dominant malformation syndrome caused by mutations in the CHD7 gene. The majority of cases are sporadic and only few familial cases have been reported. In these families, mosaicism in one parent, as well as parent- to-child transmission of a CHD7 mutation, has been described. In some further cases, germline mosaicism has been suggested. Here, we report the first case in which germline mosaicism could be demonstrated in a father of two affected children with CHARGE syndrome. The truncating mutation c.7302dupA in exon 34 of the CHD7 gene was found in both affected children but was not detected in parental lymphocytes. However, in DNA extracted from the father's spermatozoa, the c.7302dupA mutation could be identified. Furthermore, mutation analysis of DNA isolated from 59 single spermatozoa revealed that the c.7302dupA mutation occurs in 16 spermatozoa, confirming germline mosaicism in the father of the affected children. This result has a high impact for genetic counselling of the family and for their recurrence risk in further pregnancies.