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Bottleneck and selection in the germline and maternal age influence transmission of mitochondrial DNA in human pedigrees
- Source :
- Proceedings of the National Academy of Sciences of the United States of America, Proceedings of the National Academy of Sciences of the United States of America, vol 116, iss 50
- Publication Year :
- 2019
- Publisher :
- National Academy of Sciences, 2019.
-
Abstract
- Significance Mitochondria frequently carry different DNA—a state called heteroplasmy. Heteroplasmic mutations can cause mitochondrial diseases and are involved in cancer and aging, but they are also common in healthy people. Here, we study heteroplasmy in 96 multigenerational healthy families. We show that mothers effectively transmit very few mitochondrial DNA to their offspring. Because of this bottleneck, which intensifies with increasing maternal age at childbirth, mutation frequencies can change dramatically between a mother and her child. Thus, a child might inherit a disease-causing mutation at high frequency from an asymptomatic carrier mother and might develop a disease. We also demonstrate that natural selection acts against disease-causing mutations during germline development. Our study has important implications for genetic counseling of mitochondrial diseases.<br />Heteroplasmy—the presence of multiple mitochondrial DNA (mtDNA) haplotypes in an individual—can lead to numerous mitochondrial diseases. The presentation of such diseases depends on the frequency of the heteroplasmic variant in tissues, which, in turn, depends on the dynamics of mtDNA transmissions during germline and somatic development. Thus, understanding and predicting these dynamics between generations and within individuals is medically relevant. Here, we study patterns of heteroplasmy in 2 tissues from each of 345 humans in 96 multigenerational families, each with, at least, 2 siblings (a total of 249 mother–child transmissions). This experimental design has allowed us to estimate the timing of mtDNA mutations, drift, and selection with unprecedented precision. Our results are remarkably concordant between 2 complementary population-genetic approaches. We find evidence for a severe germline bottleneck (7–10 mtDNA segregating units) that occurs independently in different oocyte lineages from the same mother, while somatic bottlenecks are less severe. We demonstrate that divergence between mother and offspring increases with the mother’s age at childbirth, likely due to continued drift of heteroplasmy frequencies in oocytes under meiotic arrest. We show that this period is also accompanied by mutation accumulation leading to more de novo mutations in children born to older mothers. We show that heteroplasmic variants at intermediate frequencies can segregate for many generations in the human population, despite the strong germline bottleneck. We show that selection acts during germline development to keep the frequency of putatively deleterious variants from rising. Our findings have important applications for clinical genetics and genetic counseling.
- Subjects :
- bottleneck
Male
Mitochondrial Diseases
Somatic cell
Pedigree chart
Reproductive health and childbirth
Germline
0302 clinical medicine
80 and over
mitochondrion
heteroplasmy
Child
Pediatric
Genetics
Aged, 80 and over
0303 health sciences
education.field_of_study
Multidisciplinary
Biological Sciences
Middle Aged
Heteroplasmy
Mitochondrial
3. Good health
Mitochondria
Pedigree
Child, Preschool
Medical genetics
Female
Maternal Age
Adult
Mitochondrial DNA
medicine.medical_specialty
Adolescent
Evolution
1.1 Normal biological development and functioning
Population
Biology
DNA, Mitochondrial
03 medical and health sciences
Young Adult
medicine
Humans
Preschool
education
030304 developmental biology
Aged
Human Genome
Haplotype
Human Genetics
DNA
Genetics, Population
Germ Cells
Generic health relevance
030217 neurology & neurosurgery
Subjects
Details
- Language :
- English
- ISSN :
- 10916490 and 00278424
- Volume :
- 116
- Issue :
- 50
- Database :
- OpenAIRE
- Journal :
- Proceedings of the National Academy of Sciences of the United States of America
- Accession number :
- edsair.doi.dedup.....6ba1c07617bbcc72eca95bd76fd2842c