An APC Mutation in a Large Chinese Kindred With Familial Adenomatous Polyposis Was Identified Using Both Next Generation Sequencing and Simple STR Marker Haplotypes.

BACKGROUND: Familial adenomatous polyposis (FAP) is an autosomal dominant disorder characterized primarily by the development of numerous adenomatous polyps in the colon and a high risk for colorectal cancer. FAP is caused by germline mutations of the adenomatous polyposis coli (APC) gene. The proband in this family was a 39-year-old female patient with the pathologic diagnosis of adenomatous polyps, and then a five-generation kindred with FAP was characterized in the following years. This article identified an APC mutation, and demonstrated the practical use of APC-linked STR markers, which could be used to reduce misdiagnosis of prenatal diagnosis or preimplantation genetic diagnosis resulted from contamination or allele drop-out. METHODS: Next-generation sequencing (NGS) was used to identify the possible APC mutations in an affected individual from a family with autosomal dominant colon cancer. Targeted sequencing then used to identify additional related individuals with the mutation. Three short tandem repeat (STR) loci, D5S299, D5S134, and D5S346, were used for PCR-based microsatellite analysis of the APC gene in the extended family. RESULTS: We identified an APC: p.W553X mutation. The STR haplotype at the APC locus, A1B4C1, was shared by all clinically affected individuals with the APC: p.W553X mutation. In addition, the APC: p.D1822V variant was observed in 40% affected individuals and in two unaffected individuals. CONCLUSION: We described a protein truncation mutation, APC: p.W553X; demonstrated the value of APC-linked STR markers (D5S299, D5S134, and D5S346) haplotypes; and suggested the potential role of these haplotypes in detecting loss of heterozygosity of the APC gene.

Next-generation sequencing detection and characterization of a heterozygous novel splice junction mutation in the 2B domain of KRT1 in a family with diffuse palmoplantar keratoderma.

Diffuse palmoplantar keratoderma (DPPK) is an autosomal-dominant genodermatosis characterized by restricted, uniform hyperkeratosis on the palm and sole epidermis. DPPK is normally associated with dominant-negative mutations in the keratin-encoding gene, KRT1. We report a heterozygous novel point mutation in the exon 6 splice donor site of KRT1 (c.1254G>C) by next-generation sequencing, resulting in the formation of two alternative transcripts, which segregates with DPPK in a four-generation Chinese family. This results in both the complete loss of exon 6 and the simultaneous utilization of a novel in-frame splice site 54 bases downstream of the mutation with the subsequent deletion of 42 amino acids and the insertion of 18 amino acids into the protein's 2B domain. This is the first report of a novel splice donor site mutation with aberrant splicing and the formation of two alternative transcripts causing DPPK. This study also demonstrates the value of next-generation sequencing in the identification of novel disease-causing mutations.

High resolution melting analysis of the MMAB gene in cblB patients and in those with undiagnosed methylmalonic aciduria.

Isolated methylmalonic aciduria (MMA) results either from a defect in the mitochondrial enzyme methylmalonylCoA mutase (MCM), or in the intracellular conversion of vitamin B12 (cobalamin) into its active coenzyme adenosylcobalamin (AdoCbl). Mutations in the MMAB gene affect the function of the enzyme ATP:cob(I)alamin adenosyltransferase (ATR) and the production of AdoCbl. Measurement of MCM function in cultured patient fibroblasts, followed by somatic cell complementation analysis in cases where MCM function is decreased, has classically been used to diagnose the cblB cobalamin disorder. A patient with persistent MMA, who could not be diagnosed using traditional somatic cell studies, was subsequently shown by sequencing in a clinical laboratory to contain two variants in the MMAB gene. This observation brings into question whether somatic cell studies have failed to diagnose other cblB patients with mild cellular phenotypes. A high resolution melting analysis (HRMA) assay was developed for the MMAB gene. It was used to scan 96 reference samples and two cohorts of patients: 42 patients diagnosed with cblB by complementation studies; and 181 patients with undiagnosed MMA. MMAB mutations, including one novel nonsense mutation (c.12 C>A [p.C4X]), were identified in all members of the cblB cohort. Four patients with undiagnosed MMA, including the index case described above, were found to contain variants in the MMAB gene: c.185C>T (p.T62M), c.394T>C (p.C132R), c.398C>T (p.S133F), c.521C>T (p.S174L), c.572G>A (p.R191Q). Only the index case was found to have two variants, suggesting that somatic cell studies diagnose almost all cblB patients.

Unexpected structural complexity of supernumerary marker chromosomes characterized by microarray comparative genomic hybridization.

BACKGROUND: Supernumerary marker chromosomes (SMCs) are structurally abnormal extra chromosomes that cannot be unambiguously identified by conventional banding techniques. In the past, SMCs have been characterized using a variety of different molecular cytogenetic techniques. Although these techniques can sometimes identify the chromosome of origin of SMCs, they are cumbersome to perform and are not available in many clinical cytogenetic laboratories. Furthermore, they cannot precisely determine the region or breakpoints of the chromosome(s) involved. In this study, we describe four patients who possess one or more SMCs (a total of eight SMCs in all four patients) that were characterized by microarray comparative genomic hybridization (array CGH). RESULTS: In at least one SMC from all four patients, array CGH uncovered unexpected complexity, in the form of complex rearrangements, that could have gone undetected using other molecular cytogenetic techniques. Although array CGH accurately defined the chromosome content of all but two minute SMCs, fluorescence in situ hybridization was necessary to determine the structure of the markers. CONCLUSION: The increasing use of array CGH in clinical cytogenetic laboratories will provide an efficient method for more comprehensive characterization of SMCs. Improved SMC characterization, facilitated by array CGH, will allow for more accurate SMC/phenotype correlation.

Androgenetic/biparental mosaicism in an infant with hepatic mesenchymal hamartoma and placental mesenchymal dysplasia.

Androgenetic/biparental mosaicism, in which a subset of cells has complete paternal uniparental disomy, is associated with placental mesenchymal dysplasia (PMD), which is compatible with fetal development, indicating that fetal organs could also have androgenetic/biparental mosaicism, but few cases of somatic mosaicism have been described. A hepatic mesenchymal hamartoma (HMH) was resected from an otherwise healthy, nondysmorphic, 11-month-old girl, whose prenatal development was complicated by PMD. Placenta, HMH, histologically normal liver, and other tissues were examined for androgenetic/biparental mosaicism by analysis of (1) polymorphic DNA microsatellite markers, (2) the methylation status of an imprinted gene, SNRPN, and (3) immunohistochemically detectable protein products of the imprinted genes p57KIP2 and PHLDA2. The patient's liver, HMH, and 1 placental sample demonstrated an increased ratio of paternal to maternal alleles, indicating androgenetic/biparental mosaicism. The androgenetic component comprised 26% to 60% of the cells. Other tissues, including a 2nd placental sample, white blood cells, umbilical cord, and abdominal fascia, had no detectable androgenetic component. Methylation analysis confirmed a relative excess of the paternally imprinted SNRPN homolog in the normal liver, HMH, and placenta. Placental p57KIP2 immunoreactivity was consistent with androgenetic/biparental mosaicism, but neither p57KIP2 nor PHLDA2 immunohistochemistry were informative for HMH, because neither antigen was detected in control liver samples. We report androgenetic/biparental mosaicism in nonplacental tissues of an infant with PMD and provide the 1st description of genome-wide paternal uniparental disomy in HMH. Androgenetic/biparental mosaicism appears to play a role in the pathogenesis of HMH and other somatic lesions, particularly those associated with PMD.

Spondylometaphyseal dysplasia with cone-rod dystrophy.

The co-occurrence of ophthalmologic abnormality and intrinsic skeletal dysplasia is uncommon. We describe eight instances of a unique form of spondylometaphyseal dysplasia (SMD) associated with cone-rod dystrophy (although documentation is insufficient to be certain of that diagnosis in some). This is a new, syndromic form of SMD for which there is evidence for autosomal recessive transmission. Recognition of the specific bony features described here should precipitate comprehensive ophthalmologic assessment, since vision impairment becomes significantly disabling with age.

Novel mutations in CPT 1A define molecular heterogeneity of hepatic carnitine palmitoyltransferase I deficiency.

Liver carnitine palmitoyltransferase I (CPT I) deficiency is a rare disorder of hepatic mitochondrial long-chain fatty acid oxidation. It characteristically presents with symptoms associated with failure of ketogenesis (hypoketotic hypoglycemia). The disorder is due to mutations in the CPT 1A gene for which few patients have been characterized. We present here four novel mutations in five patients from four families with severe enzyme deficiency. Three of these are missense mutations (G465W, R316G, and F343V) and the fourth a nonsense mutation (R160X). Other than small Inuit and Hutterite populations in Canada and the Northern plains, there is complete heterogeneity of disease-causing mutations within CPT I deficient families with each demonstrating unique mutations. Because there are no easily recognizable disease-specific metabolite markers, diagnostic confirmation of this disorder requires a combination of enzymatic analysis and whole gene sequencing.

Novel missense mutations in the TRPS1 transcription factor define the nuclear localization signal.

Deletion or mutation of the TRPS1 gene leads to the tricho-rhino-phalangeal syndromes (TRPS). The gene encodes a zinc-finger transcription factor, which contains two regions with basic amino acids LRRRRG (NLS1) and RRRTRKR (NLS2) that resemble potential nuclear localization signals (NLSs). Here, we describe the identification of novel TRPS1 mutations in patients with TRPS type I (TRPS I) and provide, by reconstructing the mutant TRPS1 proteins and subcellular localization studies, evidence that only the RRRTRKR motif functions as a NLS. Two different mutations affect the last arginine residue of this motif. The exchanges of arginine to histidine, found in two unrelated patients with TRPS I, as well as the exchange of arginine to cysteine, found in another unrelated patient, prevent the translocation of the mutant TRPS1 to the nucleus when ectopically expressed in COS 7 cells. In contrast, a mutant that lacks the conserved GATA-type zinc-finger domain and most of the LRRRRG motif is able to enter the nucleus.