Your search keyword '"Christine Macgillivray"' showing total 5 results

1. Mutations in origin recognition complex gene ORC4 cause Meier-Gorlin syndrome

Author

Christopher R. McMaster, Makoto Matsuoka, Lysanne Patry, Cheri Deal, Jean Paquette, Sandhya Parkash, Christine Macgillivray, Jacques L. Michaud, Mark Ludman, Mathew Nightingale, Susan C. Evans, Haiyan Jiang, Duane L. Guernsey, Marissa A. LeBlanc, Duane W Superneau, David Skidmore, Mark E. Samuels, Aidan Thomas, Sylvie Langlois, Andrew C. Orr, Scott Perry, Andrea L. Rideout, and Meghan Ferguson

Subjects

Male, Adolescent, Micrognathism, Molecular Sequence Data, Origin Recognition Complex, Cell Cycle Proteins, Biology, medicine.disease_cause, Polymorphism, Single Nucleotide, Conserved sequence, Consanguinity, ORC6, Germline mutation, Genetics, medicine, Humans, Missense mutation, Amino Acid Sequence, Child, ORC1, Gene, Conserved Sequence, Growth Disorders, Exome sequencing, Congenital Microtia, Mutation, Base Sequence, Sequence Homology, Amino Acid, Ear, DNA, Patella, Founder Effect, Pedigree, Haplotypes, Child, Preschool, Female

Abstract

Meier-Gorlin syndrome is a rare autosomal recessive genetic condition whose primary clinical hallmarks include small stature, small external ears and small or absent patellae. Using marker-assisted mapping in multiple families from a founder population and traditional coding exon sequencing of positional candidate genes, we identified three different mutations in the gene encoding ORC4, a component of the eukaryotic origin recognition complex, in five individuals with Meier-Gorlin syndrome. In two such individuals that were negative for mutations in ORC4, we found potential mutations in ORC1 and CDT1, two other genes involved in origin recognition. ORC4 is well conserved in eukaryotes, and the yeast equivalent of the human ORC4 missense mutation was shown to be pathogenic in functional assays of cell growth. This is the first report, to our knowledge, of a germline mutation in any gene of the origin recognition complex in a vertebrate organism.

Published

2011

2. Phenotypic overlap between familial exudative vitreoretinopathy and microcephaly, lymphedema, and chorioretinal dysplasia caused by KIF11 mutations

Author

Conrad V. Fernandez, Somayyeh Fahiminiya, Sandhya Parkash, Mathew Nightingale, Jacek Majewski, Johane M Robitaille, Christopher R. McMaster, Aidan Thomas, Stavit A. Shalev, Marissa A. LeBlanc, Karin Wallace, Daniel Gaston, Mélanie Roy, Christine Macgillivray, Karen Bedard, Elise Héon, Julie Hathaway, Roxanne M. Gillett, Michael P. Mackley, Anna L. Ells, and Elias I. Traboulsi

Subjects

Proband, Male, Microcephaly, Pathology, medicine.medical_specialty, Familial Exudative Vitreoretinopathies, DNA Mutational Analysis, Molecular Sequence Data, Kinesins, Gene mutation, Polymerase Chain Reaction, Retinal Diseases, Ophthalmology, medicine, Humans, Lymphedema, Fluorescein Angiography, Child, Chorioretinal dysplasia, Base Sequence, business.industry, Retinal detachment, Facies, Eye Diseases, Hereditary, Exons, medicine.disease, Phenotype, Pedigree, Electrophysiology, Child, Preschool, Mutation, Familial exudative vitreoretinopathy, Female, Retinal Dysplasia, business

Abstract

Retinal detachment with avascularity of the peripheral retina, typically associated with familial exudative vitreoretinopathy (FEVR), can result from mutations in KIF11, a gene recently identified to cause microcephaly, lymphedema, and chorioretinal dysplasia (MLCRD) as well as chorioretinal dysplasia, microcephaly, and mental retardation (CDMMR). Ophthalmologists should be aware of the range of presentations for mutations in KIF11 because the phenotypic distinction between FEVR and MLCRD/CDMMR portends management implications in patients with these conditions.To identify gene mutations in patients who present with a FEVR phenotype and explore the spectrum of ocular and systemic abnormalities caused by KIF11 mutations in a cohort of patients with FEVR or microcephaly in conjunction with chorioretinopathy or FEVR.Clinical data and DNA were collected from each participant between 1998 and 2013 from the clinical practices of ophthalmologists and clinical geneticists internationally. Twenty-eight FEVR probands with diagnoses made by the referring physician and without a known FEVR gene mutation, and 3 with microcephaly and chorioretinopathy, were included. At least 1 patient in each pedigree manifested 1 or more of the following: macular dragging, partial retinal detachment, falciform folds, or total retinal detachment.Whole-exome sequencing was conducted on affected members in multiplex pedigrees, and Sanger sequencing of the 22 exons of the KIF11 gene was performed on singletons. Clinical data and history were collected and reviewed.Identification of mutations in KIF11.Four novel heterozygous KIF11 mutations and 1 previously published mutation were identified in probands with FEVR: p.A218Gfs*15, p.E470X, p.R221G, c.790-1GT, and the previously described heterozygous p.R47X. Documentation of peripheral avascular areas on intravenous fluorescein angiography was possible in 2 probands with fibrovascular proliferation demonstrating phenotypic overlap with FEVR.Mutations in KIF11 cause a broader spectrum of ocular disease than previously reported, including retinal detachment. The KIF11 gene likely plays a role in retinal vascular development and mutations in this gene can lead to clinical overlap with FEVR. Cases of FEVR should be carefully inspected for the presence of microcephaly as a marker for KIF11-related disease to enhance the accuracy of the prognosis and genetic counseling.

Published

2014

3. Mutations in a novel serine protease PRSS56 in families with nanophthalmos

Author

Andrew, Orr, Marie-Pierre, Dubé, Juan C, Zenteno, Haiyan, Jiang, Geraldine, Asselin, Susan C, Evans, Aurore, Caqueret, Hesham, Lakosha, Louis, Letourneau, Julien, Marcadier, Makoto, Matsuoka, Christine, Macgillivray, Mathew, Nightingale, Simon, Papillon-Cavanagh, Scott, Perry, Sylvie, Provost, Mark, Ludman, Duane L, Guernsey, and Mark E, Samuels

Subjects

Canada, Heterozygote, Base Sequence, Genotype, Genotyping Techniques, Genetic Linkage, DNA Mutational Analysis, Homozygote, Molecular Sequence Data, Membrane Proteins, Exons, Eye, Pedigree, Cohort Studies, Mice, Hyperopia, Mutation, Animals, Humans, Microphthalmos, Cloning, Molecular, Lod Score, Serine Proteases, Mexico, Research Article

Abstract

Purpose Nanophthalmos is a rare genetic ocular disorder in which the eyes of affected individuals are abnormally small. Patients suffer from severe hyperopia as a result of their markedly reduced axial lengths, but otherwise are capable of seeing well unlike other more general forms of microphthalmia. To date one gene for nanophthalmos has been identified, encoding the membrane-type frizzled related protein MFRP. Identification of additional genes for nanophthalmos will improve our understanding of normal developmental regulation of eye growth. Methods We ascertained a cohort of families from eastern Canada and Mexico with familial nanophthalmos. We performed high density microsatellite and high density single nucleotide polymorphism (SNP) genotyping to identify potential chromosomal regions of linkage. We sequenced coding regions of genes in the linked interval by traditional PCR-based Sanger capillary electrophoresis methods. We cloned and sequenced a novel cDNA from a putative causal gene to verify gene structure. Results We identified a linked locus on chromosome 2q37 with a peak logarithm (base 10) of odds (LOD) score of 4.7. Sequencing of coding exons of all genes in the region identified multiple segregating variants in one gene, recently annotated as serine protease gene (PRSS56), coding for a predicted trypsin serine protease-like protein. One of our families was homozygous for a predicted pathogenic missense mutation, one family was compound heterozygous for two predicted pathogenic missense mutations, and one family was compound heterozygous for a predicted pathogenic missense mutation plus a frameshift leading to obligatory truncation of the predicted protein. The PRSS56 gene structure in public databases is based on a virtual transcript assembled from overlapping incomplete cDNA clones; we have now validated the structure of a full-length transcript from embryonic mouse brain RNA. Conclusions PRSS56 is a good candidate for the causal gene for nanophthalmos in our families.

Published

2011

4. Mutation in the gene encoding ubiquitin ligase LRSAM1 in patients with Charcot-Marie-Tooth disease

Author

Mark E. Samuels, Mark Ludman, David Skidmore, Scott Perry, Christine Macgillivray, Andrew C. Orr, Susan C. Evans, Andrea L. Rideout, Meghan Ferguson, Haiyan Jiang, Mathew Nightingale, Makoto Matsuoka, Timothy Benstead, Karen Bedard, and Duane L. Guernsey

Subjects

Male, Cancer Research, Canada, Neurological Disorders/Peripheral Neuropathies, lcsh:QH426-470, RNA Splicing, Ubiquitin-Protein Ligases, Molecular Sequence Data, Chromosome 9, medicine.disease_cause, Polymorphism, Single Nucleotide, Frameshift mutation, Exon, Charcot-Marie-Tooth Disease, Genetics, medicine, Humans, Molecular Biology, Gene, Genetics (clinical), Ecology, Evolution, Behavior and Systematics, Genetics and Genomics/Medical Genetics, Mutation, biology, Base Sequence, Disease gene identification, Molecular biology, Ubiquitin ligase, Pedigree, Developmental Biology/Neurodevelopment, lcsh:Genetics, Mutagenesis, Insertional, RNA splicing, biology.protein, Female, Genetics and Genomics/Gene Discovery, RNA Splice Sites, Research Article

Abstract

Charcot-Marie-Tooth disease (CMT) represents a family of related sensorimotor neuropathies. We studied a large family from a rural eastern Canadian community, with multiple individuals suffering from a condition clinically most similar to autosomal recessive axonal CMT, or AR-CMT2. Homozygosity mapping with high-density SNP genotyping of six affected individuals from the family excluded 23 known genes for various subtypes of CMT and instead identified a single homozygous region on chromosome 9, at 122,423,730–129,841,977 Mbp, shared identical by state in all six affected individuals. A homozygous pathogenic variant was identified in the gene encoding leucine rich repeat and sterile alpha motif 1 (LRSAM1) by direct DNA sequencing of genes within the region in affected DNA samples. The single nucleotide change mutates an intronic consensus acceptor splicing site from AG to AA. Direct analysis of RNA from patient blood demonstrated aberrant splicing of the affected exon, causing an obligatory frameshift and premature truncation of the protein. Western blotting of immortalized cells from a homozygous patient showed complete absence of detectable protein, consistent with the splice site defect. LRSAM1 plays a role in membrane vesicle fusion during viral maturation and for proper adhesion of neuronal cells in culture. Other ubiquitin ligases play documented roles in neurodegenerative diseases. LRSAM1 is a strong candidate for the causal gene for the genetic disorder in our kindred., Author Summary Sensory motor neuropathies are diseases of the peripheral nervous system, involving primarily the nerves which control our muscles. These can result from either genetic or non-genetic causes, with genetic causes usually referred to as Charcot-Marie-Tooth (CMT) disease after the three clinicians who first described the key diagnostic markers. CMT patients lose muscle function, mainly in their arms and legs, with increasing severity during their lives. There are almost two dozen known genes that can mutate to cause CMT, and these fall into a wide variety of biochemical cellular pathways. We identified a group of patients with CMT from a small rural community, with good reason to suspect a genetic basis for their disease. Using high-throughput mapping and DNA sequencing technologies developed as part of the Human Genome Project, we were able to find the likely mutated gene, which was not any of the previously known CMT genes. Based on its sequence, the gene, called LRSAM1, probably plays a role in the correct metabolism of other proteins in the cell. Among the known CMT genes, some are also involved in protein metabolism, suggesting that this is a generally important pathway in the neurons that control muscle activity.

Published

2010

5. Mutations in Centrosomal Protein CEP152 in Primary Microcephaly Families Linked to MCPH4

Author

Makoto Matsuoka, Andrew C. Orr, Philip Awadalla, Ingrid Hoffmann, Khalil Bouyakdan, Nadine Dumas, Julie Hussin, Jill Beis, Haiyan Jiang, Christine Macgillivray, Mark E. Samuels, Mathew Nightingale, Aidan Thomas, Marc Arnold, Duane L. Guernsey, Susan C. Evans, Andrea L. Rideout, Lysanne Patry, Meghan Ferguson, David Meek, Jacques L. Michaud, Tina Babineau-Sturk, Scott Perry, and Mark Ludman

Subjects

Candidate gene, Microcephaly, Molecular Sequence Data, Cell Cycle Proteins, Locus (genetics), Biology, Compound heterozygosity, Article, Mice, 03 medical and health sciences, Exon, 0302 clinical medicine, Genetics, medicine, Animals, Humans, Missense mutation, Genetics(clinical), Amino Acid Sequence, Gene, Genetic Association Studies, Genetics (clinical), 030304 developmental biology, 0303 health sciences, Base Sequence, Computational Biology, medicine.disease, Pedigree, Genetic Loci, Centrosome, Mutation, Female, 030217 neurology & neurosurgery

Abstract

Primary microcephaly is a rare condition in which brain size is substantially diminished without other syndromic abnormalities. Seven autosomal loci have been genetically mapped, and the underlying causal genes have been identified for MCPH1, MCPH3, MCPH5, MCPH6, and MCPH7 but not for MCPH2 or MCPH4. The known genes play roles in mitosis and cell division. We ascertained three families from an Eastern Canadian subpopulation, each with one microcephalic child. Homozygosity analysis in two families using genome-wide dense SNP genotyping supported linkage to the published MCPH4 locus on chromosome 15q21.1. Sequencing of coding exons of candidate genes in the interval identified a nonconservative amino acid change in a highly conserved residue of the centrosomal protein CEP152. The affected children in these two families were both homozygous for this missense variant. The third affected child was compound heterozygous for the missense mutation plus a second, premature-termination mutation truncating a third of the protein and preventing its localization to centrosomes in transfected cells. CEP152 is the putative mammalian ortholog of Drosphila asterless, mutations in which affect mitosis in the fly. Published data from zebrafish are also consistent with a role of CEP152 in centrosome function. By RT-PCR, CEP152 is expressed in the embryonic mouse brain, similar to other MCPH genes. Like some other MCPH genes, CEP152 shows signatures of positive selection in the human lineage. CEP152 is a strong candidate for the causal gene underlying MCPH4 and may be an important gene in the evolution of human brain size.