Project description:Identification of genetic defects in families segregating rare eye disorders using next generation genomic tools

Project description:Identification of genetic defects in families segregating rare eye disorders using next generation genomic tools

Project description:Identification of genetic defects in families segregating rare inherited diseases using next generation genomic tools

Project description:Next generation rare variant discovery in multiplex AD families

Project description:Next generation rare variant discovery in multiplex AD families

Project description:Genetic Defects in familial renal disorders

Project description:Genetic Defects in familial renal disorders

Project description:Genetic causes of rare neurodegenerative disorders

Project description:Purpose: To identify the genetic basis of posterior polymorphous corneal dystrophy 1 (PPCD1). Methods: Next-generation sequencing was performed on DNA samples from 4 affected and 4 unaffected members of a previously reported family with PPCD1 linked to chromosome 20 between D20S182 and D20S195. Custom capture probes were utilized for targeted region capture of the linked interval. Single nucleotide variants (SNVs) and insertions/deletions (indels) were identified using two bioinformatics pipelines and two annotation databases. Candidate variants met the following criteria: quality score ≥20, read depth ≥5X, heterozygous, novel or rare (minor allele frequency (MAF) ≤ 0.05), present in each affected individual and absent in each unaffected individual. Structural variants were detected with two different microarray platforms to identify indels of varying sizes. Results: Sequencing reads aligned to the linked region on chromosome 20, and high coverage was obtained across the sequenced region. The majority of identified variants were detected with both pipelines and annotation databases, although unique variants were identified. Twelve SNVs in 10 genes (2 synonymous variants and 10 noncoding variants) and 9 indels in 7 genes met the filtering criteria and were considered candidate variants for PPCD1. Conclusions: Next-generation sequencing of the PPCD1 interval has identified 17 genes containing novel or rare SNVs and indels that segregate with the affected phenotype in an affected family previously mapped to the PPCD1 locus. We anticipate that screening of these candidate genes in other families previously mapped to the PPCD1 locus will result in the identification of the genetic basis of PPCD1. Four affected and 4 unaffected individuals from a single family were analyzed for copy number variation within the PPCD1 disease locus. Array design and analysis is based on genome build hg19.

Project description:In this study, we explored the possibility that rare variation in the genetic background may be an additional risk factor for Parkinson's Disease (PD) in families segregating pathogenic GBA gene variants. We performed whole-genome sequencing, rare variant filtering, segregation analysis and functional validation of PD cosegregating rare genetic variation in two families segregating PD associated GBA variants c.115+1G>A (ClinVar ID: 93445, ) and p.L444P (ClinVar ID: 4288) respectively. We found rare genetic variation in the HSP70 co-chaperone DnaJ homolog subfamily B member 6 (DNAJB6) and lysosomal protein prosaposin (PSAP) as additional factors possibly influencing PD risk in the two families.