Two novel cases expanding the phenotype of SETD2-related overgrowth syndrome.

The SETD2-related overgrowth syndrome is also called "Luscan-Lumish syndrome" (OMIM 616831) with the clinical characteristics of intellectual disability, speech delay, macrocephaly, facial dysmorphism, and autism spectrum disorders. We report on two novel patients a 4.5-year-old boy and a 23-year-old female adolescent with a speech and language developmental delay, autism spectrum disorder and macrocephaly, who were both diagnosed with SETD2-related overgrowth syndrome due to de novo frameshift mutations in the SETD2 gene. Features not previously described which were present in either one of our patients were nasal polyps, a large tongue with creases, a high pain threshold, constipation, and undescended testicles. These features may be related to the syndrome and may need special attention in future patients. Additionally, prevention of obesity should be an important point of attention for patients diagnosed with a SETD2-related overgrowth syndrome.

High Yield of Pathogenic Germline Mutations Causative or Likely Causative of the Cancer Phenotype in Selected Children with Cancer.

Purpose: In many children with cancer and characteristics suggestive of a genetic predisposition syndrome, the genetic cause is still unknown. We studied the yield of pathogenic mutations by applying whole-exome sequencing on a selected cohort of children with cancer.Experimental Design: To identify mutations in known and novel cancer-predisposing genes, we performed trio-based whole-exome sequencing on germline DNA of 40 selected children and their parents. These children were diagnosed with cancer and had at least one of the following features: (1) intellectual disability and/or congenital anomalies, (2) multiple malignancies, (3) family history of cancer, or (4) an adult type of cancer. We first analyzed the sequence data for germline mutations in 146 known cancer-predisposing genes. If no causative mutation was found, the analysis was extended to the whole exome.Results: Four patients carried causative mutations in a known cancer-predisposing gene: TP53 and DICER1 (n = 3). In another 4 patients, exome sequencing revealed mutations causing syndromes that might have contributed to the malignancy (EP300-based Rubinstein-Taybi syndrome, ARID1A-based Coffin-Siris syndrome, ACTB-based Baraitser-Winter syndrome, and EZH2-based Weaver syndrome). In addition, we identified two genes, KDM3B and TYK2, which are possibly involved in genetic cancer predisposition.Conclusions: In our selected cohort of patients, pathogenic germline mutations causative or likely causative of the cancer phenotype were found in 8 patients, and two possible novel cancer-predisposing genes were identified. Therewith, our study shows the added value of sequencing beyond a cancer gene panel in selected patients, to recognize childhood cancer predisposition. Clin Cancer Res; 24(7); 1594-603. ©2018 AACR.

Benign and malignant tumors in Rubinstein-Taybi syndrome.

Rubinstein-Taybi syndrome (RSTS) is a multiple congenital anomalies syndrome associated with mutations in CREBBP (70%) and EP300 (5-10%). Previous reports have suggested an increased incidence of specific benign and possibly also malignant tumors. We identified all known individuals diagnosed with RSTS in the Netherlands until 2015 (n = 87) and studied the incidence and character of neoplastic tumors in relation to their CREBBP/EP300 alterations. The population-based Dutch RSTS data are compared to similar data of the Dutch general population and to an overview of case reports and series of all RSTS individuals with tumors reported in the literature to date. Using the Nationwide Network and Registry of Histopathology and Cytopathology in the Netherlands (PALGA Foundation), 35 benign and malignant tumors were observed in 26/87 individuals. Meningiomas and pilomatricomas were the most frequent benign tumors and their incidence was significantly elevated in comparison to the general Dutch population. Five malignant tumors were observed in four persons with RSTS (medulloblastoma; diffuse large-cell B-cell lymphoma; breast cancer; non-small cell lung carcinoma; colon carcinoma). No clear genotype-phenotype correlation became evident. The Dutch population-based data and reported case studies underscore the increased incidence of meningiomas and pilomatricomas in individuals with RSTS. There is no supporting evidence for an increased risk for malignant tumors in individuals with RSTS, however, due to the small numbers this risk may not be fully dismissed.

Archetypal NOTCH3 mutations frequent in public exome: implications for CADASIL.

OBJECTIVE: To determine the frequency of distinctive EGFr cysteine altering NOTCH3 mutations in the 60,706 exomes of the exome aggregation consortium (ExAC) database. METHODS: ExAC was queried for mutations distinctive for cerebral autosomal dominant arteriopathy with subcortical infarcts and leukoencephalopathy (CADASIL), namely mutations leading to a cysteine amino acid change in one of the 34 EGFr domains of NOTCH3. The genotype-phenotype correlation predicted by the ExAC data was tested in an independent cohort of Dutch CADASIL patients using quantified MRI lesions. The Dutch CADASIL registry was probed for paucisymptomatic individuals older than 70 years. RESULTS: We identified 206 EGFr cysteine altering NOTCH3 mutations in ExAC, with a total prevalence of 3.4/1000. More than half of the distinct mutations have been previously reported in CADASIL patients. Despite the clear overlap, the mutation distribution in ExAC differs from that in reported CADASIL patients, as mutations in ExAC are predominantly located outside of EGFr domains 1-6. In an independent Dutch CADASIL cohort, we found that patients with a mutation in EGFr domains 7-34 have a significantly lower MRI lesion load than patients with a mutation in EGFr domains 1-6. INTERPRETATION: The frequency of EGFr cysteine altering NOTCH3 mutations is 100-fold higher than expected based on estimates of CADASIL prevalence. This challenges the current CADASIL disease paradigm, and suggests that certain mutations may more frequently cause a much milder phenotype, which may even go clinically unrecognized. Our data suggest that individuals with a mutation located in EGFr domains 1-6 are predisposed to the more severe "classical" CADASIL phenotype, whereas individuals with a mutation outside of EGFr domains 1-6 can remain paucisymptomatic well into their eighth decade.

EMQN/CMGS best practice guidelines for the molecular genetic testing of Huntington disease.

Huntington disease (HD) is caused by the expansion of an unstable polymorphic trinucleotide (CAG)n repeat in exon 1 of the HTT gene, which translates into an extended polyglutamine tract in the protein. Laboratory diagnosis of HD involves estimation of the number of CAG repeats. Molecular genetic testing for HD is offered in a wide range of laboratories both within and outside the European community. In order to measure the quality and raise the standard of molecular genetic testing in these laboratories, the European Molecular Genetics Quality Network has organized a yearly external quality assessment (EQA) scheme for molecular genetic testing of HD for over 10 years. EQA compares a laboratory's output with a fixed standard both for genotyping and reporting of the results to the referring physicians. In general, the standard of genotyping is very high but the clarity of interpretation and reporting of the test result varies more widely. This emphasizes the need for best practice guidelines for this disorder. We have therefore developed these best practice guidelines for genetic testing for HD to assist in testing and reporting of results. The analytical methods and the potential pitfalls of molecular genetic testing are highlighted and the implications of the different test outcomes for the consultand and his or her family members are discussed.

Myosin IXB variant increases the risk of celiac disease and points toward a primary intestinal barrier defect.

Celiac disease is probably the best-understood immune-related disorder. The disease presents in the small intestine and results from the interplay between multiple genes and gluten, the triggering environmental factor. Although HLA class II genes explain 40% of the heritable risk, non-HLA genes accounting for most of the familial clustering have not yet been identified. Here we report significant and replicable association (P = 2.1 x 10(-6)) to a common variant located in intron 28 of the gene myosin IXB (MYO9B), which encodes an unconventional myosin molecule that has a role in actin remodeling of epithelial enterocytes. Individuals homozygous with respect to the at-risk allele have a 2.3-times higher risk of celiac disease (P = 1.55 x 10(-5)). This result is suggestive of a primary impairment of the intestinal barrier in the etiology of celiac disease, which may explain why immunogenic gluten peptides are able to pass through the epithelial barrier.

CTLA4 +49 A/G and CT60 polymorphisms in Dutch coeliac disease patients.

Coeliac disease is an autoimmune disorder, characterised by villous atrophy of the small intestine, which results from a T-cell-mediated response to gluten-derived peptides. The cytotoxic T-lymphocyte-associated protein 4 (CTLA-4) is involved in the regulation of T-cell activation and the CTLA4 +49 A/G polymorphism in exon 1 has been implicated in several autoimmune disorders, including coeliac disease. However, this polymorphism was recently excluded as being the causal variant in Graves' disease, autoimmune hypothyroidism and type I diabetes mellitus. This causal variant was mapped to the 3' region of CTLA4, with the CT60 polymorphism showing the strongest association. The aim of this study was to determine the role of the CTLA4 gene in coeliac disease in the Dutch population. The +49 A/G and CT60 polymorphisms were genotyped in a case-control cohort of 215 patients and controls. The frequency of the +49 G-allele was increased in cases, although not significantly. However, the frequency of the CT60 G-allele was increased with borderline significance in coeliac disease patients (P = 0.048), although the genotype distributions did not show a significant difference between cases and controls. These results indicate the involvement of the CTLA4 gene in coeliac disease development. The haplotype carrying the CT60 G-allele was shown to be associated with lower mRNA levels of the soluble CTLA-4 isoform, providing a possible mechanism for the T-cell-mediated destruction of the small intestine.

A major non-HLA locus in celiac disease maps to chromosome 19.

BACKGROUND AND AIMS: The pathogenesis of celiac disease is still unknown despite its well-known association with human leukocyte antigen (HLA)-DQ2 and DQ8. It is clear that non-HLA genes contribute to celiac disease development as well, but none of the previous genome-wide screens in celiac disease have resulted in identification of these genes. METHODS: We, therefore, performed a 2-stage, genome-wide screen in 101 affected sibpairs from 82 Dutch families who met strict diagnostic criteria. The small intestinal biopsy samples, on which the original celiac disease diagnoses had been based, showed a Marsh III lesion in all patients on reevaluation by 1 pathologist. For association analysis of markers in regions linked to celiac disease, 216 independent MIII patients and 216 age- and sex-matched controls were available. RESULTS: As expected, highly significant linkage to the HLA-region was detected (multipoint maximum lod score [MMLS] = 8.14). More importantly, significant linkage was also present at 19p13.1 (MMLS = 4.31), with the peak at marker D19S899. Moreover, this marker was also significantly associated with celiac disease in the case-control study (corrected P = 0.016). Furthermore, we identified suggestive linkage to 6q21-22, which is approximately 70 cM downstream from the HLA region (MMLS = 3.10). CONCLUSIONS: Significant linkage of celiac disease to chromosome region 19p13.1 was detected in our genome-wide screen. These results were confirmed by the association of D19S899 to celiac disease in an independent case-control cohort. Furthermore, we identified a possible second celiac disease locus on chromosome region 6q21-22.