1,694 research outputs found

    The genetics of cardiovascular disease

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    Recent advances in genotyping technology and insights into disease mechanisms have increased interest in the genetics of cardiovascular disease. Several candidate genes involved in cardiovascular diseases were identified from studies using animal models, and the translation of these findings to human disease is an exciting challenge. There is a trend towards large-scale genome-wide association studies that are subject to strict quality criteria with regard to both genotyping and phenotyping. Here, we review some of the strategies that have been developed to translate findings from experimental models to human disease and outline the need for optimizing global approaches to analyze such results. Findings from ongoing studies are interpreted in the context of disease pathways instead of the more traditional focus on single genetic variants

    Differential gene expression in anatomical compartments of the human eye

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    BACKGROUND: The human eye is composed of multiple compartments, diverse in form, function, and embryologic origin, that work in concert to provide us with our sense of sight. We set out to systematically characterize the global gene expression patterns that specify the distinctive characteristics of the various eye compartments. RESULTS: We used DNA microarrays representing approximately 30,000 human genes to analyze gene expression in the cornea, lens, iris, ciliary body, retina, and optic nerve. The distinctive patterns of expression in each compartment could be interpreted in relation to the physiology and cellular composition of each tissue. Notably, the sets of genes selectively expressed in the retina and in the lens were particularly large and diverse. Genes with roles in immune defense, particularly complement components, were expressed at especially high levels in the anterior segment tissues. We also found consistent differences between the gene expression patterns of the macula and peripheral retina, paralleling the differences in cell layer densities between these regions. Based on the hypothesis that genes responsible for diseases that affect a particular eye compartment are likely to be selectively expressed in that compartment, we compared our gene expression signatures with genetic mapping studies to identify candidate genes for diseases affecting the cornea, lens, and retina. CONCLUSION: Through genome-scale gene expression profiling, we were able to discover distinct gene expression 'signatures' for each eye compartment and identified candidate disease genes that can serve as a reference database for investigating the physiology and pathophysiology of the eye

    Genetics of age-related macular degeneration and Stargardt disease in South African populations

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    Background: The Retinal Degenerative Diseases (RDD) Research Group in the Division of Human Genetics at UCT has for the past 25 years been intensively investigating a range of RDD phenotypes. Two points of particular note have emerged regarding Macular Degenerations (MD) : (i) that more than 58% of juvenile MD, notably Stargardt Disease (STGD) , in Caucasian populations may have the underlying causative genetic defect identified , while only 1 1 % of the similar phenotype in indigenous African populations is resolved, and (ii) that the 'elderly' form of MD, i.e. age - related macular degeneration (AMD) has a remarkably lower incidence in the indigenous African population when compared to any other population group, and most notably the Caucasian (or European - derived) population /s . This study investigates the genetic factors underlying macular degeneration (MD) in our study cohort comprising various South African ethnolinguistic groups with particular focus on disease in juvenile and elderly indigenous Africans. Materials and Methods: For the STGD part of the study, sequencing of the entire ABCA4 coding and splice region (comprising 50 amplicons) was performed in three African STGD patients who were representative of three common haplotypes identified within the larger cohort of 36 patients . Pathogenicity predictive software, PON - P and Human Splice Finder (HSF), were used for in silico data analysis. For the AMD subset: Available local indigenous southern African population - based genome - wide S ingle Nucleotide Polymorphism (SNP) chip (Affymetrix SNP6) data was used to identify SNPs within known AMD candidate genes in which allele frequencies were significantly different (i.e. 10 fold) between Caucasians and indigenous southern Africans. Nine SNPs occurring at higher frequencies within Africans compared to Caucasian controls were genotyped by SNaPshot PCR within a multi - ethnic AMD SA cohort. Minor allele frequencies (MAF) were compared using SHEsis. Results: Sequencing of ABCA 4 in three African STGD patients produced 39 unique variants, out of which only one, (V643M), was deemed pathogenic. HSF predicted 22 of these non - exonic variants to be 'possibly pathogenic', confounding analysis. No variants segregated with the common haplotypes. Regarding the AMD cohort, eight SNPs in candidate AMD genes showed a decreased MAF in African AMD cases compared to controls, two of which (rs9621622 in TIMP3 and rs17110714 in ABCA4 ), were statistically significant ( p values of 9.95 x 10 - 4 and 1.04 x 10 - 2 , respectively). Discussion and Conclusion: Although a number of variants were identified in the coding region of three haplotype - representative STGD subjects, only one variant proved pathogenic but did not co - segregate with the haplotype in the rest of the samples. It is possible that variants in regulatory regions not captured by the exonic screening might be involved, or that another gene may be imp licated in the 'STGD - like' phenotype in the indigenous African subjects. In the second part of the study, the investigation of the African AMD cohort suggested that SNPs in TIMP3 and ABCA4 are associated with a decreased susceptibility, and may therefore plausibly be protective for AMD in indigenous Africans. Overall, however, this should be considered only a pilot study of macular degeneration in the indigenous African population, providing leads to larger scale studies of this group of disorders in this population group

    The molecular basis of human retinal and vitreoretinal diseases

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    During the last two to three decades, a large body of work has revealed the molecular basis of many human disorders, including retinal and vitreoretinal degenerations and dysfunctions. Although belonging to the group of orphan diseases, they affect probably more than two million people worldwide. Most excitingly, treatment of a particular form of congenital retinal degeneration is now possible. A major advantage for treatment is the unique structure and accessibility of the eye and its different components, including the vitreous and retina. Knowledge of the many different eye diseases affecting retinal structure and function (night and color blindness, retinitis pigmentosa, cone and cone rod dystrophies, photoreceptor dysfunctions, as well as vitreoretinal traits) is critical for future therapeutic development. We have attempted to present a comprehensive picture of these disorders, including clinical, genetic and molecular information. The structural organization of the review leads the reader through non-syndromic and syndromic forms of (i) rod dominated diseases, (ii) cone dominated diseases, (iii) generalized retinal degenerations and (iv) vitreoretinal disorders, caused by mutations in more than 165 genes. Clinical variability and genetic heterogeneity have an important impact on genetic testing and counselling of affected families. As phenotypes do not always correlate with the respective genotypes, it is of utmost importance that clinicians, geneticists, counsellors, diagnostic laboratories and basic researchers understand the relationships between phenotypic manifestations and specific genes, as well as mutations and pathophysiologic mechanisms. We discuss future perspectives

    Development and application of a next-generation-sequencing (NGS) approach to detect known and novel gene defects underlying retinal diseases

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    <p>Abstract</p> <p>Background</p> <p>Inherited retinal disorders are clinically and genetically heterogeneous with more than 150 gene defects accounting for the diversity of disease phenotypes. So far, mutation detection was mainly performed by APEX technology and direct Sanger sequencing of known genes. However, these methods are time consuming, expensive and unable to provide a result if the patient carries a new gene mutation. In addition, multiplicity of phenotypes associated with the same gene defect may be overlooked.</p> <p>Methods</p> <p>To overcome these challenges, we designed an exon sequencing array to target 254 known and candidate genes using Agilent capture. Subsequently, 20 DNA samples from 17 different families, including four patients with known mutations were sequenced using Illumina Genome Analyzer IIx next-generation-sequencing (NGS) platform. Different filtering approaches were applied to identify the genetic defect. The most likely disease causing variants were analyzed by Sanger sequencing. Co-segregation and sequencing analysis of control samples validated the pathogenicity of the observed variants.</p> <p>Results</p> <p>The phenotype of the patients included retinitis pigmentosa, congenital stationary night blindness, Best disease, early-onset cone dystrophy and Stargardt disease. In three of four control samples with known genotypes NGS detected the expected mutations. Three known and five novel mutations were identified in <it>NR2E3, PRPF3, EYS, PRPF8, CRB1, TRPM1 </it>and <it>CACNA1F</it>. One of the control samples with a known genotype belongs to a family with two clinical phenotypes (Best and CSNB), where a novel mutation was identified for CSNB. In six families the disease associated mutations were not found, indicating that novel gene defects remain to be identified.</p> <p>Conclusions</p> <p>In summary, this unbiased and time-efficient NGS approach allowed mutation detection in 75% of control cases and in 57% of test cases. Furthermore, it has the possibility of associating known gene defects with novel phenotypes and mode of inheritance.</p

    Candidate Genes for Chromosomes 6 and 10: Quantitative Trait Loci for Age-Related Retinal Degeneration in Mice

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    Purpose: In a previous study, several quantitative trait loci (QTL) that influence age-related degeneration (ageRD) were identified in a cross between the albino strains B6(Cg)-Tyr(c-2J)/J (B6a) and BALB/cByJ (C). The Chromosome (Chr) 6 and Chr 10 QTL were the strongest and most highly significant loci and both involved B6a protective alleles. The QTL were responsible for 21% and 9% of the variance in phenotypes, respectively. We focused on these two QTL to identify candidate genes. Methods: DNA microarrays were used for the two mouse strains at four and eight months of age to identify genes that are differentially regulated and map to either QTL. Gene Ontology (GO) analysis of the differentially expressed genes was performed to identify possible processes and pathways associated with ageRD. To identify additional candidates, database analyses (Positional Medline or PosMed) were used. Based on differential expression, PosMed, and the presence of reported polymorphisms, five genes per QTL were selected for further study by sequencing analysis and qRT-PCR. Tumor necrosis factor, alpha-induced protein 3 (Tnfaip3; on a C57BL/6J (B6) background) was phenotypically tested. Single nucleotide polymorphisms (SNPs) flanking this gene were correlated with outer nuclear layer thickness (ONL), and eight-month-old Tnfaip3(+/-) mice were tested for ageRD. Results: Polymorphisms were found in the coding regions of eight genes. Changes in gene expression were identified by qRT-PCR for Hexokinase 2 (Hk2) and Docking protein 1 (Dok1) at four months and for Dok1 and Tnfaip3 at eight months. Tnfaip3 was selected for phenotypic testing due to differential expression and the presence of two nonsynonymous mutations. However, when ONL thickness was compared in eight-month-old congenic Tnfaip3(+/-) and Tnfaip3(+/+) mice, no differences were found, suggesting that Tnfaip3 is not the quantitative trait gene (QTG) for the Chr 10 QTL. The GO analysis revealed that GO terms associated with stress and cell remodeling are overrepresented in the ageRD-sensitive C strain compared with the B6a strain with age (eight months). In the ageRD-resistant B6a strain, compared with the C strain, GO terms associated with antioxidant response and the regulation of blood vessel size are overrepresented with age. Conclusions: The analyses of differentially expressed genes and the PosMed database yielded candidate genes for the Chr 6 and Chr 10 QTL. HtrA serine peptidase 2 (Htra2), Dok1, and Tnfaip3 were deemed most promising because of their known roles in apoptosis and our finding of nonsynonymous substitutions between B6a and C strains. While Tnfaip3 was excluded as the QTG for the Chr 10 QTL, Dok1 and Htra2 remain good candidates for the Chr 6 QTL. Finally, the GO term analysis further supports the general hypothesis that oxidative stress is involved in ageRD

    De Novo Occurrence of a Variant in ARL3 and Apparent Autosomal Dominant Transmission of Retinitis Pigmentosa.

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    BackgroundRetinitis pigmentosa is a phenotype with diverse genetic causes. Due to this genetic heterogeneity, genome-wide identification and analysis of protein-altering DNA variants by exome sequencing is a powerful tool for novel variant and disease gene discovery. In this study, exome sequencing analysis was used to search for potentially causal DNA variants in a two-generation pedigree with apparent dominant retinitis pigmentosa.MethodsVariant identification and analysis of three affected members (mother and two affected offspring) was performed via exome sequencing. Parental samples of the index case were used to establish inheritance. Follow-up testing of 94 additional retinitis pigmentosa pedigrees was performed via retrospective analysis or Sanger sequencing.Results and conclusionsA total of 136 high quality coding variants in 123 genes were identified which are consistent with autosomal dominant disease. Of these, one of the strongest genetic and functional candidates is a c.269A&gt;G (p.Tyr90Cys) variant in ARL3. Follow-up testing established that this variant occurred de novo in the index case. No additional putative causal variants in ARL3 were identified in the follow-up cohort, suggesting that if ARL3 variants can cause adRP it is an extremely rare phenomenon
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