The Personal Genome Project Canada: findings from whole genome sequences of the inaugural 56 participants.

BACKGROUND: The Personal Genome Project Canada is a comprehensive public data resource that integrates whole genome sequencing data and health information. We describe genomic variation identified in the initial recruitment cohort of 56 volunteers. METHODS: Volunteers were screened for eligibility and provided informed consent for open data sharing. Using blood DNA, we performed whole genome sequencing and identified all possible classes of DNA variants. A genetic counsellor explained the implication of the results to each participant. RESULTS: Whole genome sequencing of the first 56 participants identified 207 662 805 sequence variants and 27 494 copy number variations. We analyzed a prioritized disease-associated data set (n = 1606 variants) according to standardized guidelines, and interpreted 19 variants in 14 participants (25%) as having obvious health implications. Six of these variants (e.g., in BRCA1 or mosaic loss of an X chromosome) were pathogenic or likely pathogenic. Seven were risk factors for cancer, cardiovascular or neurobehavioural conditions. Four other variants - associated with cancer, cardiac or neurodegenerative phenotypes - remained of uncertain significance because of discrepancies among databases. We also identified a large structural chromosome aberration and a likely pathogenic mitochondrial variant. There were 172 recessive disease alleles (e.g., 5 individuals carried mutations for cystic fibrosis). Pharmacogenomics analyses revealed another 3.9 potentially relevant genotypes per individual. INTERPRETATION: Our analyses identified a spectrum of genetic variants with potential health impact in 25% of participants. When also considering recessive alleles and variants with potential pharmacologic relevance, all 56 participants had medically relevant findings. Although access is mostly limited to research, whole genome sequencing can provide specific and novel information with the potential of major impact for health care.

Human sterile alpha motif domain 9, a novel gene identified as down-regulated in aggressive fibromatosis, is absent in the mouse.

BACKGROUND: Neoplasia can be driven by mutations resulting in dysregulation of transcription. In the mesenchymal neoplasm, aggressive fibromatosis, subtractive hybridization identified sterile alpha motif domain 9 (SAMD9) as a substantially down regulated gene in neoplasia. SAMD9 was recently found to be mutated in normophosphatemic familial tumoral calcinosis. In this study, we studied the gene structure and function of SAMD9, and its paralogous gene, SAMD9L, and examined these in a variety of species. RESULTS: SAMD9 is located on human chromosome 7q21.2 with a paralogous gene sterile alpha motif domain 9 like (SAMD9L) in the head-to-tail orientation. Although both genes are present in a variety of species, the orthologue for SAMD9 is lost in the mouse lineage due to a unique genomic rearrangement. Both SAMD9 and SAMD9L are ubiquitously expressed in human tissues. SAMD9 is expressed at a lower level in a variety of neoplasms associated with beta-catenin stabilization, such as aggressive fibromatosis, breast, and colon cancers. SAMD9 and SAMD9L contain an amino-terminal SAM domain, but the remainder of the predicted protein structure does not exhibit substantial homology to other known protein motifs. The putative protein product of SAMD9 localizes to the cytoplasm. In vitro data shows that SAMD9 negatively regulates cell proliferation. Over expression of SAMD9 in the colon cancer cell line, SW480, reduces the volume of tumors formed when transplanted into immune-deficient mice. CONCLUSION: SAMD9 and SAMD9L are a novel family of genes, which play a role regulating cell proliferation and suppressing the neoplastic phenotype. This is the first report as far as we know about a human gene that exists in rat, but is lost in mouse, due to a mouse specific rearrangement, resulting in the loss of the SAMD9 gene.

N-linked oligosaccharides play a role in disulphide-dependent dimerization of intestinal mucin Muc2.

Within the C-terminal domain of many secretory mucins is a 'cystine knot' (CK), which is needed for dimer formation in the endoplasmic reticulum. Previous studies indicate that in addition to an unpaired cysteine, the three intramolecular cystine bonds of the knot are important for stability of the dimers formed by rat intestinal mucin Muc2. The present study was undertaken to determine whether the two N-glycans N9 and N10, located near the first and second cysteines of the knot, also play a role in dimer formation. The C-terminal domain of rat Muc2 (RMC), a truncated RMC mutant containing the CK, and mutants lacking N9 and N10 sites, were expressed in COS-1 cells and the products monitored by radioactive [(35)S]Met/Cys metabolic pulse-chase and immunoprecipitation. Mutation of N9, but not N10, caused increased synthesis of dimers over a 2-h chase period. The N9 mutant remained associated with calreticulin for a prolonged period. About 34-38% of the total labelled products of RMC and its mutants was secreted into the media by 2 h, but the proportion in dimer form was dramatically reduced for the N9 mutant, suggesting lower dimer stability relative to RMC or its N10 mutant. We conclude that under normal conditions the presence of the N9 glycan functions to maintain a folding rate for mucin monomers that is sufficiently slow to allow structural maturation and stability of Muc2 dimers. To our knowledge this report is the first demonstration that a specific N-glycan plays a definitive role in mucin dimer formation.