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Particular Mutation (particular + mutation)

Distribution by Scientific Domains

Life Sciences	85%

Selected Abstracts

Molecular basis of perinatal hypophosphatasia with tissue-nonspecific alkaline phosphatase bearing a conservative replacement of valine by alanine at position 406

FEBS JOURNAL, Issue 11 2008
Structural importance of the crown domain
Hypophosphatasia, a congenital metabolic disease related to the tissue-nonspecific alkaline phosphatase gene (TNSALP), is characterized by reduced serum alkaline phosphatase levels and defective mineralization of hard tissues. A replacement of valine with alanine at position 406, located in the crown domain of TNSALP, was reported in a perinatal form of hypophosphatasia. To understand the molecular defect of the TNSALP (V406A) molecule, we examined this missense mutant protein in transiently transfected COS-1 cells and in stable CHO-K1 Tet-On cells. Compared with the wild-type enzyme, the mutant protein showed a markedly reduced alkaline phosphatase activity. This was not the result of defective transport and resultant degradation of TNSALP (V406A) in the endoplasmic reticulum, as the majority of newly synthesized TNSALP (V406A) was conveyed to the Golgi apparatus and incorporated into a cold detergent insoluble fraction (raft) at a rate similar to that of the wild-type TNSALP. TNSALP (V406A) consisted of a dimer, as judged by sucrose gradient centrifugation, suggestive of its proper folding and correct assembly, although this mutant showed increased susceptibility to digestion by trypsin or proteinase K. When purified as a glycosylphosphatidylinositol-anchorless soluble form, the mutant protein exhibited a remarkably lower Kcat/Km value compared with that of the wild-type TNSALP. Interestingly, leucine and isoleucine, but not phenylalanine, were able to substitute for valine, pointing to the indispensable role of residues with a longer aliphatic side chain at position 406 of TNSALP. Taken together, this particular mutation highlights the structural importance of the crown domain with respect to the catalytic function of TNSALP. [source]

Myocilin allele-specific glaucoma phenotype database,

HUMAN MUTATION, Issue 2 2008
Alex W. Hewitt
Abstract Glaucoma, a complex heterogenous disease, is the leading cause for optic nerve,related blindness worldwide. Since 1997, when mutations in the myocilin (MYOC) gene were identified as causing juvenile onset as well as a proportion of primary open-angle glaucoma (POAG), more than 180 variants have been documented. Approximately one in 30 unselected patients with POAG have a disease-causing myocilin mutation and it has been shown that firm genotype,phenotype correlations exist. We have compiled an online catalog of myocilin variants and their associated phenotypes. This locus-specific resource, to which future submissions can be made, is available online (www.myocilin.com; last accessed 28 August 2007). The database, constructed using MySQL, contains three related sheets that contain data pertaining to the information source, variant identified, and relevant study data, respectively. The website contains a list of all identified variants and summary statistics as well as background genomic information, such as the annotated sequence and cross-protein/species homology. Phenotypic data such as the mean±standard deviation (SD) age at POAG diagnosis, mean±SD maximum recorded intraocular pressure, proportion of patients requiring surgical intervention, and age-related penetrance can be viewed by selecting a particular mutation. Approximately 40% of the identified sequence variants have been characterized as disease causing, with the majority (,85%) of these being missense mutations. Preliminary data generated from this online resource highlight the strong genotype,phenotype correlations associated with specific myocilin mutations. The large-scale assimilation of relevant data allows for accurate comprehensive genetic counseling and the translation of genomic information into the clinic. Hum Mutat 29(2), 207,211, 2008. © 2007 Wiley-Liss, Inc. [source]

Using linked markers to infer the age of a mutation

HUMAN MUTATION, Issue 2 2001
Bruce Rannala
Abstract Advances in sequencing and genotyping technologies over the last decade have enabled geneticists to easily characterize genetic variation at the nucleotide level. Hundreds of genes harboring mutations associated with genetic disease have now been identified by positional cloning. Using variation at closely linked genetic markers, it is possible to predict the times in the past at which particular mutations arose. Such studies suggest that many of the rare mutations underlying human genetic disorders are relatively young. Studies of variation at genetic markers linked to particular mutations can provide insights into human geographic history, and historical patterns of natural selection and disease, that are not available from other sources. We review two approaches for estimating allele age using variation at linked genetic markers. A phylogenetic approach aims to reconstruct the gene tree underlying a sample of chromosomes carrying a particular mutation, obtaining a "direct" estimate of allele age from the age of the root of this tree. A population genetic approach relies on models of demography, mutation, and/or recombination to estimate allele age without explicitly reconstructing the gene tree. Phylogenetic methods are best suited for studies of ancient mutations, while population genetic methods are better suited for studies of recent mutations. Methods that rely on recombination to infer the ages of alleles can be fine-tuned by choosing linked markers at optimal map distances to maximize the information available about allele age. A limitation of methods that rely on recombination is the frequent lack of a fine-scale linkage map. Maximum likelihood and Bayesian methods for estimating allele age that rely on intensive numerical computation are described, as well as "composite" likelihood and moment-based methods that lead to simple estimators. The former provide more accurate estimates (particularly for large samples of chromosomes) and should be employed if computationally practical. Hum Mutat 18:87,100, 2001. © 2001 Wiley-Liss, Inc. [source]

Expanding the phenotypic spectrum of Caffey disease

CLINICAL GENETICS, Issue 3 2007
K Suphapeetiporn
Infantile cortical hyperostosis (ICH) is an inherited disorder characterized by hyperirritability, acute inflammation of soft tissues, and massive subperiosteal new bone formation. It typically appears in early infancy and is considered a benign self-limiting disease. We report a three-generation Thai family with ICH, the oldest being a 75-year-old man. A heterozygous mutation for a 3040C,T in exon 41 of COL1A1 was found in affected individuals, further confirming the autosomal dominance of Caffey disease that is caused by this particular mutation. The novel findings in our studies include short stature and persistent bony deformities in the elderly. The height mean Z-score of the five affected individuals was ,1.75, compared to 0.53 of the other seven unaffected individuals giving a p-value of 0.008. Short stature may be partly due to progressive height loss from scoliosis, compression fractures of the spine and genu varus. These features, which have not previously been described, expand the phenotypic spectrum of the Caffey disease. [source]

A novel nonsense mutation in the EYA1 gene associated with branchio-oto-renal/branchiootic syndrome in an Afrikaner kindred

CLINICAL GENETICS, Issue 1 2006
JC Clarke
Branchio-oto-renal (BOR) syndrome is an autosomal dominant disorder characterized by the associations of hearing loss, branchial arch defects and renal anomalies. Branchiootic (BO) syndrome is a related disorder that presents without the highly variable characteristic renal anomalies of BOR syndrome. Dominant mutations in the human homologue of the Drosophila eyes absent gene (EYA1) are frequently the cause of both BOR and BO syndromes. We report a South African family of Afrikaner descent with affected individuals presenting with pre-auricular abnormalities and either hearing loss or bilateral absence of the kidneys. Genetic analysis of the pedigree detected a novel EYA1 heterozygous nonsense mutation in affected family members but not in unaffected family members or a random DNA panel. Through mutational analysis, we conclude that this particular mutation is the cause of BOR/BO syndrome in this family as a result of a truncation of the EYA1 protein that ablates the critical EYA homologous region. To the best of our knowledge, this is the first case of BOR/BO syndrome reported in Africa or in those of the Afrikaner descent. [source]

Using linked markers to infer the age of a mutation

Mutation analysis of Wilson disease in the Spanish population , identification of a prevalent substitution and eight novel mutations in the ATP7B gene

CLINICAL GENETICS, Issue 1 2005
E Margarit
Wilson disease (WD) is a copper metabolism disorder characterized by hepatic and/or neurological damage. More than 200 mutations in the ATP7B gene causing this autosomal recessive defect have been reported. In certain populations, a high prevalence of particular mutations allows rapid screening and diagnosis of the disease. We identified the ATP7B alterations in Spanish patients with WD. Mutations in the ATP7B gene were analysed in a total of 64 individuals from 40 different WD families by PCR amplification, single-strand conformation polymorphism (SSCP) analysis and sequencing. Twenty-one different ATP7B gene mutations were identified, eight of which were novel. 74% of the disease alleles were characterized among the 40 unrelated probands. We identified a prevalent mutation in our population (Met645Arg), present in 55% of this 40 patients. The frequency of the remaining ATP7B alterations was low. In addition, 17 different polymorphic variants were found. There is remarkable allele heterogeneity in WD in the Spanish population. Nevertheless, SSCP screening for the most frequent mutations in our population is feasible and leads to the detection of about 74% of the mutated chromosomes. Molecular diagnosis of WD is very useful in clinical practice to confirm or support clinical suspicion. [source]