Your search keyword '"Wright, Margaret"' showing total 4 results

1. Is there a genetic correlation between general factors of intelligence and personality?

Author

Loehlin, John C, Bartels, Meike, Boomsma, Dorret I, Bratko, Denis, Martin, Nicholas G, Nichols, Robert C, and Wright, Margaret J

Subjects

GENETIC correlations, INTELLIGENCE levels, PERSONALITY, HUMAN evolution, TWINS, PSYCHOLOGY

Published

2015

2. Heritability of head size in Dutch and Australian twin families at ages 0-50 years.

Author

Smit, Dirk J. A., Luciano, Michelle, Bartels, Meike, Van Beijsterveldt, Catharine E. M., Wright, Margaret J., Hansell, Narelle K., Brunner, Han G., Estourgie-van Burk, G. Frederiek, De Geus, Eco J. C., Martin, Nicholas G., and Boomsma, Dorret I.

Subjects

HEAD, TWINS, SEX differences (Biology), BIOMETRY, BRAIN, COMPARATIVE studies, GENETICS, RESEARCH methodology, MEDICAL cooperation, RESEARCH, EVALUATION research, ANATOMY

Abstract

We assessed the heritability of head circumference, an approximation of brain size, in twin-sib families of different ages. Data from the youngest participants were collected a few weeks after birth and from the oldest participants around age 50 years. In nearly all age groups the largest part of the variation in head circumference was explained by genetic differences. Heritability estimates were 90% in young infants (4 to 5 months), 85-88% in early childhood, 83-87% in adolescence, 75% in young and mid adulthood. In infants younger than 3 months, heritability was very low or absent. Quantitative sex differences in heritability were observed in 15- and 18-year-olds, but there was no evidence for qualitative sex differences, that is, the same genes were expressed in both males and females. Longitudinal analysis of the data between 5, 7, and 18 years of age showed high genetic stability (.78 > R(G) > .98). These results indicate that head circumference is a highly heritable biometric trait and a valid target for future GWA studies. [ABSTRACT FROM AUTHOR]

Published

2010

3. Sequence variants in three loci influence monocyte counts and erythrocyte volume.

Author

Ferreira MA, Hottenga JJ, Warrington NM, Medland SE, Willemsen G, Lawrence RW, Gordon S, de Geus EJ, Henders AK, Smit JH, Campbell MJ, Wallace L, Evans DM, Wright MJ, Nyholt DR, James AL, Beilby JP, Penninx BW, Palmer LJ, Frazer IH, Montgomery GW, Martin NG, and Boomsma DI

Subjects

Age Factors, Alleles, Australia, Chromosome Mapping, Chromosomes, Human, Pair 6, Chromosomes, Human, Pair 9, Cohort Studies, Computer Simulation, Female, Gene Frequency, Genetics, Population, Genome-Wide Association Study, Genotype, Haplotypes, Humans, Leukocyte Count, Linkage Disequilibrium, Male, Netherlands, Phenotype, Platelet Count, Polymorphism, Single Nucleotide, Base Sequence genetics, Erythrocyte Indices genetics, Genome, Human, Monocytes, Quantitative Trait Loci

Abstract

Blood cells participate in vital physiological processes, and their numbers are tightly regulated so that homeostasis is maintained. Disruption of key regulatory mechanisms underlies many blood-related Mendelian diseases but also contributes to more common disorders, including atherosclerosis. We searched for quantitative trait loci (QTL) for hematology traits through a whole-genome association study, because these could provide new insights into both hemopoeitic and disease mechanisms. We tested 1.8 million variants for association with 13 hematology traits measured in 6015 individuals from the Australian and Dutch populations. These traits included hemoglobin composition, platelet counts, and red blood cell and white blood cell indices. We identified three regions of strong association that, to our knowledge, have not been previously reported in the literature. The first was located in an intergenic region of chromosome 9q31 near LPAR1, explaining 1.5% of the variation in monocyte counts (best SNP rs7023923, p=8.9x10(-14)). The second locus was located on chromosome 6p21 and associated with mean cell erythrocyte volume (rs12661667, p=1.2x10(-9), 0.7% variance explained) in a region that spanned five genes, including CCND3, a member of the D-cyclin gene family that is involved in hematopoietic stem cell expansion. The third region was also associated with erythrocyte volume and was located in an intergenic region on chromosome 6q24 (rs592423, p=5.3x10(-9), 0.6% variance explained). All three loci replicated in an independent panel of 1543 individuals (p values=0.001, 9.9x10(-5), and 7x10(-5), respectively). The identification of these QTL provides new opportunities for furthering our understanding of the mechanisms regulating hemopoietic cell fate.

Published

2009

4. Genetic influences on handedness: data from 25,732 Australian and Dutch twin families.

Author

Medland SE, Duffy DL, Wright MJ, Geffen GM, Hay DA, Levy F, van-Beijsterveldt CE, Willemsen G, Townsend GC, White V, Hewitt AW, Mackey DA, Bailey JM, Slutske WS, Nyholt DR, Treloar SA, Martin NG, and Boomsma DI

Subjects

Adolescent, Adult, Aged, Aged, 80 and over, Algorithms, Australia epidemiology, Birth Weight physiology, Child, Cohort Studies, Female, Humans, Male, Middle Aged, Models, Statistical, Netherlands epidemiology, Reproducibility of Results, Twins, Twins, Dizygotic, Twins, Monozygotic, Functional Laterality genetics

Abstract

Handedness refers to a consistent asymmetry in skill or preferential use between the hands and is related to lateralization within the brain of other functions such as language. Previous twin studies of handedness have yielded inconsistent results resulting from a general lack of statistical power to find significant effects. Here we present analyses from a large international collaborative study of handedness (assessed by writing/drawing or self report) in Australian and Dutch twins and their siblings (54,270 individuals from 25,732 families). Maximum likelihood analyses incorporating the effects of known covariates (sex, year of birth and birth weight) revealed no evidence of hormonal transfer, mirror imaging or twin specific effects. There were also no differences in prevalence between zygosity groups or between twins and their singleton siblings. Consistent with previous meta-analyses, additive genetic effects accounted for about a quarter (23.64%) of the variance (95%CI 20.17, 27.09%) with the remainder accounted for by non-shared environmental influences. The implications of these findings for handedness both as a primary phenotype and as a covariate in linkage and association analyses are discussed.

Published

2009