Your search keyword '"Perry, G."' showing total 3 results

1. Mitochondrial Genomic Analysis of Late Onset Alzheimer's Disease Reveals Protective Haplogroups H6A1A/H6A1B: The Cache County Study on Memory in Aging.

Author

Ridge, Perry G., Maxwell, Taylor J., Corcoran, Christopher D., Norton, Maria C., Tschanz, Joann T., O'Brien, Elizabeth, Kerber, Richard A., Cawthon, Richard M., Munger, Ronald G., Kauwe, John S. K., and Dermaut, Bart

Subjects

*ALZHEIMER'S disease research, *DEMENTIA research, *MITOCHONDRIAL DNA, *HUNTINGTON disease, *NUCLEOTIDE sequence

Abstract

Background: Alzheimer's disease (AD) is the most common cause of dementia and AD risk clusters within families. Part of the familial aggregation of AD is accounted for by excess maternal vs. paternal inheritance, a pattern consistent with mitochondrial inheritance. The role of specific mitochondrial DNA (mtDNA) variants and haplogroups in AD risk is uncertain. Methodology/Principal Findings: We determined the complete mitochondrial genome sequence of 1007 participants in the Cache County Study on Memory in Aging, a population-based prospective cohort study of dementia in northern Utah. AD diagnoses were made with a multi-stage protocol that included clinical examination and review by a panel of clinical experts. We used TreeScanning, a statistically robust approach based on haplotype networks, to analyze the mtDNA sequence data. Participants with major mitochondrial haplotypes H6A1A and H6A1B showed a reduced risk of AD (p = 0.017, corrected for multiple comparisons). The protective haplotypes were defined by three variants: m.3915G.A, m.4727A.G, and m.9380G.A. These three variants characterize two different major haplogroups. Together m.4727A.G and m.9380G.A define H6A1, and it has been suggested m.3915G.A defines H6A. Additional variants differentiate H6A1A and H6A1B; however, none of these variants had a significant relationship with AD case-control status. Conclusions/Significance: Our findings provide evidence of a reduced risk of AD for individuals with mtDNA haplotypes H6A1A and H6A1B. These findings are the results of the largest study to date with complete mtDNA genome sequence data, yet the functional significance of the associated haplotypes remains unknown and replication in others studies is necessary. [ABSTRACT FROM AUTHOR]

Published

2012

2. Population substructure in Cache County, Utah: the Cache County study.

Author

Sharp AR, Ridge PG, Bailey MH, Boehme KL, Norton MC, Tschanz JT, Munger RG, Corcoran CD, and Kauwe JS

Subjects

Ethnicity genetics, HapMap Project, Homozygote, Humans, Utah, White People genetics, Alzheimer Disease genetics, Genetics, Population

Abstract

Background: Population stratification is a key concern for genetic association analyses. In addition, extreme homogeneity of ethnic origins of a population can make it difficult to interpret how genetic associations in that population may translate into other populations. Here we have evaluated the genetic substructure of samples from the Cache County study relative to the HapMap Reference populations and data from the Alzheimer's Disease Neuroimaging Initiative (ADNI)., Results: Our findings show that the Cache County study is similar in ethnic diversity to the self-reported "Whites" in the ADNI sample and less homogenous than the HapMap CEU population., Conclusions: We conclude that the Cache County study is genetically representative of the general European American population in the USA and is an appropriate population for conducting broadly applicable genetic studies.

Published

2014

3. Strong evidence for a genetic contribution to late-onset Alzheimer's disease mortality: a population-based study.

Author

Kauwe JS, Ridge PG, Foster NL, and Cannon-Albright LA

Subjects

Adult, Aged, Alzheimer Disease epidemiology, Female, Genealogy and Heraldry, Genetic Predisposition to Disease, Genotype, Humans, Male, Middle Aged, Pedigree, Risk, Utah epidemiology, Alzheimer Disease genetics, Alzheimer Disease mortality

Abstract

Background: Alzheimer's disease (AD) is an international health concern that has a devastating effect on patients and families. While several genetic risk factors for AD have been identified much of the genetic variance in AD remains unexplained. There are limited published assessments of the familiality of Alzheimer's disease. Here we present the largest genealogy-based analysis of AD to date., Methods: We assessed the familiality of AD in The Utah Population Database (UPDB), a population-based resource linking electronic health data repositories for the state with the computerized genealogy of the Utah settlers and their descendants. We searched UPDB for significant familial clustering of AD to evaluate the genetic contribution to disease. We compared the Genealogical Index of Familiality (GIF) between AD individuals and randomly selected controls and estimated the Relative Risk (RR) for a range of family relationships. Finally, we identified pedigrees with a significant excess of AD deaths., Results: The GIF analysis showed that pairs of individuals dying from AD were significantly more related than expected. This excess of relatedness was observed for both close and distant relationships. RRs for death from AD among relatives of individuals dying from AD were significantly increased for both close and more distant relatives. Multiple pedigrees had a significant excess of AD deaths., Conclusions: These data strongly support a genetic contribution to the observed clustering of individuals dying from AD. This report is the first large population-based assessment of the familiality of AD mortality and provides the only reported estimates of relative risk of AD mortality in extended relatives to date. The high-risk pedigrees identified show a true excess of AD mortality (not just multiple cases) and are greater in depth and width than published AD pedigrees. The presence of these high-risk pedigrees strongly supports the possibility of rare predisposition variants not yet identified.

Published

2013