Book contents
- Frontmatter
- Contents
- List of contributors
- Preface
- 1 Mitochondrial DNA in ancient and modern humans
- 2 Digital DNA typing of human paternal lineages
- 3 Minisatellites as tools for population genetic analysis
- 4 DNA fingerprinting: development of a technology and its application to the study of human populations
- 5 Kinship, inbreeding, and matching probabilities
- 6 Using the coalescent to interpret gene trees
- 7 Some attempts at measuring natural selection by malaria
- 8 AIDA: Geographical patterns of DNA diversity investigated by autocorrelation statistics
- 9 Mitochondrial DNA sequences in Europe: an insight into population history
- 10 Palaeolithic and neolithic contributions to the European mitochondrial gene pool
- 11 The molecular diversity of the Niokholo Mandenkalu from Eastern Senegal: an insight into West Africa genetic history
- 12 The peopling of Madagascar
- 13 Molecular perspectives on the colonisation of the Pacific
- 14 Population ancestry on Tristan da Cunha–the evidence of the individual
- 15 Linguistic divergence and genetic evolution: a molecular perspective from the New World
- 16 Allelic sequence diversity at the human β-globin locus
- 17 A nuclear perspective on human evolution
- 18 Contrasting gene trees and population trees of the evolution of modern humans
- 19 Methods and models for understanding human diversity
- Index
5 - Kinship, inbreeding, and matching probabilities
Published online by Cambridge University Press: 19 September 2009
- Frontmatter
- Contents
- List of contributors
- Preface
- 1 Mitochondrial DNA in ancient and modern humans
- 2 Digital DNA typing of human paternal lineages
- 3 Minisatellites as tools for population genetic analysis
- 4 DNA fingerprinting: development of a technology and its application to the study of human populations
- 5 Kinship, inbreeding, and matching probabilities
- 6 Using the coalescent to interpret gene trees
- 7 Some attempts at measuring natural selection by malaria
- 8 AIDA: Geographical patterns of DNA diversity investigated by autocorrelation statistics
- 9 Mitochondrial DNA sequences in Europe: an insight into population history
- 10 Palaeolithic and neolithic contributions to the European mitochondrial gene pool
- 11 The molecular diversity of the Niokholo Mandenkalu from Eastern Senegal: an insight into West Africa genetic history
- 12 The peopling of Madagascar
- 13 Molecular perspectives on the colonisation of the Pacific
- 14 Population ancestry on Tristan da Cunha–the evidence of the individual
- 15 Linguistic divergence and genetic evolution: a molecular perspective from the New World
- 16 Allelic sequence diversity at the human β-globin locus
- 17 A nuclear perspective on human evolution
- 18 Contrasting gene trees and population trees of the evolution of modern humans
- 19 Methods and models for understanding human diversity
- Index
Summary
To a geneticist, population structure signifies the relation between gene frequencies and genotype frequencies of individuals and pairs of individuals. The key concept is kinship, the probability that two alleles sampled in a specified way are identical by descent. If the alleles are in the same individual, kinship is called inbreeding, which is the same as kinship between the parents of that individual. Together with other coefficients that measure identity by descent in pairs of individuals, kinship and inbreeding determine the matching probability that two individuals sampled in a specified way have the same genotype. Kinship leads to inferences about the similarity and therefore (with less assurance) about the phylogeny of different populations and the optimal strategy for conserving variability in a species that may be endangered. Inbreeding leads to identifiable risks and inferences about the mutational load. Matching probabilities are the basis for DNA forensic science. The relationship of these concepts is the pons asinorum of population genetics. Much of the literature is marred by use of genetic distance and other surrogates for kinship, inefficient estimation, selection of extreme populations, and failure to allow for biases due to sample size and incompleteness of genealogies.
Kinship
It is possible to predict kinship from genealogies or migration, but the ultimate test is kinship bioassay.
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- Molecular Biology and Human Diversity , pp. 51 - 62Publisher: Cambridge University PressPrint publication year: 1996
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