Value of a café-au-lait macules screening clinic: Experience from The Hospital for Sick Children in Toronto.

BACKGROUND/OBJECTIVES: Café-au-lait macules (CALMs) are a characteristic feature of neurofibromatosis type 1 (NF1), but also occur in other genetic disorders. Differential diagnosis of CALMs remains challenging and can be stressful for families. We sought to examine the role of an established CALMs screening clinic in diagnosing CALMs-related disorders. METHOD: We retrospectively reviewed patients seen between July 2012 and January 2019 in a CALMs screening clinic at The Hospital for Sick Children, a tertiary pediatric hospital in Toronto, Canada. Pediatric patients were referred because of multiple CALMs or suspected NF1. Selection was based on a chronological referral sample with no exclusions. A pediatric dermatologist examined all patients for CALMs and NF1 manifestations. Genetic testing was offered to confirm a clinical diagnosis or when clinical findings were inconclusive. RESULTS: Three hundred patients, of which 152 (50.7%) were female and had a mean age of 5.6 ± 4.8 years were seen during the study period. NF1 was diagnosed in 76 (25.3%) patients, mosaic NF1 in 38 (12.7%) patients, and 8 (2.7%) patients received other genetic diagnoses. One hundred and twelve (37.3%) patients were diagnosed with isolated CALMs not associated with an underlying genetic disease. Furthermore, 36 (12%) of our patients did not have CALMs. CONCLUSIONS: The CALMs screening clinic aided in the early diagnosis of genetic disorders such as NF1 and distinguished CALMs from other hyperpigmented lesions. We encourage the adoption of this clinic model in referral centers to streamline and optimize care of patients with presumptive diagnosis of CALMs.

Student-Athletes' Views on APOE Genotyping for Increased Risk of Poor Recovery after a Traumatic Brain Injury.

Use of apolipoprotein E genotyping to personalize the risk of a poor recovery after traumatic brain injury is complicated by the potential for genetic discrimination and the potential to reveal an increased risk for late onset Alzheimer's disease. We developed a survey to gauge interest in testing among athletes participating in National Collegiate Athletic Association programs. Eight hundred and forty seven student-athletes were surveyed to determine their interest in genetic testing, their willingness to share the results of testing with parents, coaches and physicians, their concerns about privacy and/or discrimination, and their interest in genetic counseling. Nearly three quarters of respondents expressed some level of interest in testing, with the largest number describing themselves as 'possibly interested' (54.9 %, n = 463) and a smaller number describing themselves as 'very interested' (18.9 %, n = 159). Most student-athletes said that receiving secondary information about their risk for late-onset Alzheimer's disease made them more likely to test (50.6 %, n = 426) rather than less likely to test (12.4 %, n = 104). Student-athletes were open to apolipoprotein E genotyping and willing to share test results with their parents, coaches and physicians. They did not anticipate that test results would impact their behavior or ability to play. Testing programs may be welcome but should provide clear information as to risks and benefits.

Phenotypes and genotypes of mitochondrial aminoacyl-tRNA synthetase deficiencies from a single neurometabolic clinic.

Mitochondrial aminoacyl-tRNA synthetases play a major role in protein translation, synthesis, and oxidative phosphorylation. We reviewed all patients diagnosed with mitochondrial aminoacyl-tRNA synthetase deficiencies diagnosed in a single neurometabolic clinic. We report five patients with mitochondrial aminoacyl-tRNA synthetase deficiencies including DARS2, EARS2, PARS2, and RARS2 deficiencies. Siblings with DARS2 deficiency presented with global developmental delay within the first year of life. DARS2, EARS2, PARS2, and RARS2 deficiencies were identified by whole exome sequencing. We report coagulation factor abnormalities in PARS2 deficiency for the first time. We also report symmetric increased signal intensity in globus pallidi in FLAIR images in brain MRI in EARS2 deficiency for the first time. One patient with RARS2 deficiency had compound heterozygous variants in RARS2. One of those variants was an intronic variant. We confirmed the pathogenicity by mRNA studies. Mitochondrial aminoacyl-tRNA synthetase deficiencies are diagnosed by molecular genetic investigations. Clinically available non-invasive biochemical investigations are non-specific for the diagnosis of mitochondrial aminoacyl-tRNA synthetase deficiencies. A combination of brain MRI features and molecular genetic investigations should be undertaken to confirm the diagnosis of mitochondrial aminoacyl-tRNA synthetase deficiencies.

Clinical Application of Targeted Next-Generation Sequencing Panels and Whole Exome Sequencing in Childhood Epilepsy.

Genetic diagnosis of childhood epilepsy is crucial to provide disease-specific treatments. This report describes the genetic landscape of childhood epilepsy revealed by targeted next-generation sequencing panels for epilepsy (TNGSP-E) and whole exome sequencing (WES). In this retrospective cohort study, TNGSP-E and/or WES were applied to identify underlying genetic diagnoses in children seen in a single Pediatric Epilepsy Genetics Clinic. We reviewed electronic patient charts for phenotypes and biochemical, genetic, and neuroimaging investigations. Forty-four different genetic diagnoses were confirmed in 71 of 197 patients (36%; 95% CI 29.3%-43.2%). The diagnostic yield of WES (37%) was 1.9-fold greater than the diagnostic yield of TNGSP-E (19.0%; P=.0018). The number of genes included in TNGSP-E was not correlated with whether or not the test resulted in a diagnosis (Pearson's R=-0.02, P=.8). Inherited metabolic disorders accounted for 13% of the genetic diagnoses, despite abnormal metabolic investigations being an exclusion criteria. There was a direct treatment implication in 6% of patients with inherited metabolic disorders including pyridoxine dependent epilepsy, glucose transporter 1 deficiency and neuronal ceroid lipofuscinosis type 2. Additionally, there might be some treatment implications in 30% of patients with genetic diagnoses including SCN1A, SCN2A, SCN8A, and KCNQ2 associated epilepsies by application of effective anti-epileptic drugs or the ketogenic diet therapy. The high diagnostic yield of clinical molecular genetic investigations and their disease-specific treatment implications highlight the importance of genetic diagnosis in childhood epilepsy. We recommend a stepwise diagnostic algorithm including metabolic investigations for treatable disorders, chromosomal microarray analysis, TNGSP-E, and WES.

High diagnostic yield of direct Sanger sequencing in the diagnosis of neuronal ceroid lipofuscinoses.

BACKGROUND: Neuronal ceroid lipofuscinoses are neurodegenerative disorders. To investigate the diagnostic yield of direct Sanger sequencing of the CLN genes, we reviewed Molecular Genetics Laboratory Database for molecular genetic test results of the CLN genes from a single clinical molecular diagnostic laboratory. METHODS: We reviewed electronic patient charts. We used consent forms and Research Electronic Data Capture questionnaires for the patients from outside of our Institution. We reclassified all variants in the CLN genes. RESULTS: Six hundred and ninety three individuals underwent the direct Sanger sequencing of the CLN genes for the diagnosis of neuronal ceroid lipofuscinoses. There were 343 symptomatic patients and 350 family members. Ninety-one symptomatic patients had molecular genetic diagnosis of neuronal ceroid lipofuscinoses including CLN1 (PPT1) (n = 10), CLN2 (TPP1) (n = 33), CLN3 (n = 17), CLN5 (n = 7), CLN6 (n = 10), CLN7 (MFSD8) (n = 10), and CLN8 (n = 4) diseases. The diagnostic yield of direct Sanger sequencing of CLN genes was 27% in symptomatic patients. We report detailed clinical and investigation results of 33 NCL patients. Juvenile onset CLN1 (PPT1) and adult onset CLN6 diseases were nonclassical phenotypes. CONCLUSION: In our study, the diagnostic yield of direct Sanger sequencing was close to diagnostic yield of whole exome sequencing. Developmental regression, cognitive decline, visual impairment and cerebral and/or cerebellar atrophy in brain MRI are significant clinical and neuroimaging denominators to include NCL in the differential diagnosis.