Tissue-specific mosaicism in hereditary hemorrhagic telangiectasia: Implications for genetic testing in families.

Mosaicism in hemorrhagic telangiectasia (HHT) has been previously identified when testing blood samples of HHT patients. We report the first detection of mosaicism not involving blood of a family proband, and discuss implications for genetic testing algorithms in HHT families. Sanger sequencing and large deletion/duplication analysis in a patient with HHT identified no pathogenic variant in ENG, ACVRL1, or SMAD4. Exome sequencing was then performed on this proband, as well as her affected adult child. A pathogenic ENG variant was detected in the proband's affected child, but not in DNA extracted from peripheral blood of the affected parent/proband. Additional tissue samples (saliva and hair bulbs) were obtained from the proband. The variant was not detected in saliva, but was detected in the hair bulb sample (at 33%). This is the first report of an HHT patient with mosaicism in whom the disease-causing mutation was not detected in blood. The molecular findings in this family suggest that the possibility of mosaicism not present or detectable in blood should be considered if a proband with HHT tests "negative" for a mutation in known genes. This occurrence is particularly suspect for families in which the proband does not have a clearly affected parent. This mechanism may explain some patients with classic HHT in whom a pathogenic variant has not been identified in one of the known HHT genes.

EIF2AK4 Mutations in Patients Diagnosed With Pulmonary Arterial Hypertension.

BACKGROUND: Differentiating pulmonary venoocclusive disease (PVOD) and pulmonary capillary hemangiomatosis (PCH) from idiopathic pulmonary arterial hypertension (IPAH) or heritable pulmonary arterial hypertension (HPAH) is important clinically. Mutations in eukaryotic translation initiation factor 2 alpha kinase 4 (EIF2AK4) cause heritable PVOD and PCH, whereas mutations in other genes cause HPAH. The aim of this study was to describe the frequency of pathogenic EIF2AK4 mutations in patients diagnosed clinically with IPAH or HPAH. METHODS: Sanger sequencing and deletion/duplication analysis were performed to detect mutations in the bone morphogenetic protein receptor type II (BMPR2) gene in 81 patients diagnosed at 30 North American medical centers with IPAH (n = 72) or HPAH (n = 9). BMPR2 mutation-negative patients (n = 67) were sequenced for mutations in four other genes (ACVRL1, ENG, CAV1, and KCNK3) known to cause HPAH. Patients negative for mutations in all known PAH genes (n = 66) were then sequenced for mutations in EIF2AK4. We assessed the pathogenicity of EIF2AK4 mutations and reviewed clinical characteristics of patients with pathogenic EIF2AK4 mutations. RESULTS: Pathogenic BMPR2 mutations were identified in 8 of 72 (11.1%) patients with IPAH and 6 of 9 (66.7%) patients with HPAH. A novel homozygous EIF2AK4 mutation (c.257+4A>C) was identified in 1 of 9 (11.1%) patients diagnosed with HPAH. The novel EIF2AK4 mutation (c.257+4A>C) was homozygous in two sisters with severe pulmonary hypertension. None of the 72 patients with IPAH had biallelic EIF2AK4 mutations. CONCLUSIONS: Pathogenic biallelic EIF2AK4 mutations are rarely identified in patients diagnosed with HPAH. Identification of pathogenic biallelic EIF2AK4 mutations can aid clinicians in differentiating HPAH from heritable PVOD or PCH.

Noncontinuously binding loop-out primers for avoiding problematic DNA sequences in PCR and sanger sequencing.

We present a method in which noncontinuously binding (loop-out) primers are used to exclude regions of DNA that typically interfere with PCR amplification and/or analysis by Sanger sequencing. Several scenarios were tested using this design principle, including M13-tagged PCR primers, non-M13-tagged PCR primers, and sequencing primers. With this technique, a single oligonucleotide is designed in two segments that flank, but do not include, a short region of problematic DNA sequence. During PCR amplification or sequencing, the problematic region is looped-out from the primer binding site, where it does not interfere with the reaction. Using this method, we successfully excluded regions of up to 46 nucleotides. Loop-out primers were longer than traditional primers (27 to 40 nucleotides) and had higher melting temperatures. This method allows the use of a standardized PCR protocol throughout an assay, keeps the number of PCRs to a minimum, reduces the chance for laboratory error, and, above all, does not interrupt the clinical laboratory workflow.