Your search keyword '"Paternal mtDNA transmission"' showing total 49 results

1. Heredity and segregation of mtDNA

Author

Stephen Peter Burr and Patrick F. Chinnery

Subjects

Genetics, Mitochondrial DNA, Non-Mendelian inheritance, Somatic cell, Inheritance (genetic algorithm), Biology, medicine.disease_cause, Germline, symbols.namesake, Paternal mtDNA transmission, Heredity, Mendelian inheritance, symbols, medicine

Abstract

It is generally accepted that human mtDNA is transmitted uniparentally, exclusively down the maternal line, in contrast to the biparental pattern of inheritance seen in the nucleus. This unusual mode of transmission means that normal Mendelian laws of inheritance cannot be applied when discussing mtDNA. To explore the heredity and segregation of mtDNA further, in this chapter we will consider the following questions: • How is strict maternal inheritance of mtDNA maintained in humans? • Is there evidence for paternal mtDNA inheritance in humans? • How do mtDNA mutations segregate during germline transmission? • How do mtDNA mutations segregate in somatic tissues?

Published

2020

2. Mitochondrial DNA inheritance in the human fungal pathogen Cryptococcus gattii

Author

Zixuan Wang, Jianping Xu, and Amanda J. Wilson

Subjects

Cryptococcus neoformans, Genetics, Canada, Mitochondrial DNA, Non-Mendelian inheritance, Mitochondrial DNA inheritance, Ubiquitination, Uniparental inheritance, Cryptococcus gattii, Biology, Decitabine, biology.organism_classification, DNA, Mitochondrial, Microbiology, Ammonium Chloride, Genes, Mitochondrial, Paternal mtDNA transmission, Azacitidine, Humans, Inheritance Patterns, DNA, Fungal

Abstract

The inheritance of mitochondrial DNA (mtDNA) is predominantly uniparental in most sexual eukaryotes. In this study, we examined the mitochondrial inheritance pattern of Cryptococcus gattii, a basidiomycetous yeast responsible for the recent and ongoing outbreak of cryptococcal infections in the US Pacific Northwest and British Columbia (especially Vancouver Island) in Canada. Using molecular markers, we analyzed the inheritance of mtDNA in 14 crosses between strains within and between divergent lineages in C. gattii. Consistent with results from recent studies, our analyses identified significant variations in mtDNA inheritance patterns among strains and crosses, ranging from strictly uniparental to biparental. For two of the crosses that showed uniparental mitochondrial inheritance in standard laboratory conditions, we further investigated the effects of the following environmental variables on mtDNA inheritance: UV exposure, temperature, and treatments with the methylation inhibitor 5-aza-2'-deoxycytidine and with the ubiquitination inhibitor ammonium chloride. Interestingly, one of these crosses showed no response to these environmental variables while the other exhibited diverse patterns ranging from complete uniparental inheritance of the MATa parent mtDNA, to biparental inheritance, and to a significant bias toward inheritance of the MATα parental mtDNA. Our results indicate that mtDNA inheritance in C. gattii differs from that in its closely related species Cryptococcus neoformans.

Published

2015

3. Multiple ways to prevent transmission of paternal mitochondrial DNA for maternal inheritance in animals

Author

Miyuki Sato and Ken Sato

Subjects

0301 basic medicine, Genetics, Non-Mendelian inheritance, Mitochondrial DNA, biology, Offspring, Autophagy, Inheritance (genetic algorithm), General Medicine, Mitochondrion, biology.organism_classification, DNA, Mitochondrial, Biochemistry, 03 medical and health sciences, Drosophila melanogaster, 030104 developmental biology, Paternal mtDNA transmission, Paternal Inheritance, Animals, Maternal Inheritance, Caenorhabditis elegans, Molecular Biology

Abstract

Mitochondria contain their own DNA (mtDNA). In most sexually reproducing organisms, mtDNA is inherited maternally (uniparentally); this type of inheritance is thus referred to as 'maternal (uniparental) inheritance'. Recent studies have revealed various mechanisms to prevent the transmission of sperm-derived paternal mtDNA to the offspring, thereby ensuring maternal inheritance of mtDNA. In the nematode Caenorhabditis elegans, paternal mitochondria and their mtDNA degenerate almost immediately after fertilization and are selectively degraded by autophagy, which is referred to as 'allophagy' (allogeneic [non-self] organelle autophagy). In the fruit fly Drosophila melanogaster, paternal mtDNA is largely eliminated by an endonuclease G-mediated mechanism. Paternal mitochondria are subsequently removed by endocytic and autophagic pathways after fertilization. In many mammals, including humans, paternal mitochondria enter fertilized eggs. However, the fate of paternal mitochondria and their mtDNA in mammals is still a matter of debate. In this review, we will summarize recent knowledge on the molecular mechanisms underlying the prevention of paternal mtDNA transmission, which ensures maternal mtDNA inheritance in animals.

Published

2017

4. Maternal inheritance of mitochondrial DNA by diverse mechanisms to eliminate paternal mitochondrial DNA

Author

Miyuki Sato and Ken Sato

Subjects

Genetics, Non-Mendelian inheritance, Mitochondrial DNA, Maternal Transmission, Zygote, Maternal inheritance, Ubiquitin, Autophagy, Cell Biology, Mitochondrion, Biology, Human mitochondrial genetics, DNA, Mitochondrial, Mitochondria, Paternal mtDNA transmission, Fertilization, Ubiquitin–proteasome system, Animals, Humans, Molecular Biology

Abstract

The mitochondrion is an organelle that has its own DNA (mtDNA). Mitochondria play essential roles in energy production and in various cellular processes such as metabolism and signal transduction. In most animals, including humans, although the sperm-derived paternal mitochondria enter the oocyte cytoplasm after fertilization, their mtDNA is never transmitted to the offspring. This pattern of mtDNA inheritance is well known as “maternal inheritance.” However, how the paternal mitochondria and mtDNA are eliminated from the cytoplasm of gametes or zygotes remains an enigma. Recently, a variety of mechanisms, including specific nuclease-dependent systems, ubiquitin–proteasome system, and autophagy have been shown to degrade the paternal mtDNA or the paternal mitochondria themselves in order to prevent paternal mtDNA transmission. In this review, we will address the current state of knowledge of the molecular mechanisms underlying the elimination of paternal mtDNA or mitochondrial structures for ensuring the maternal transmission of mtDNA.

Published

2013

5. Selective sweeps of mitochondrial DNA can drive the evolution of uniparental inheritance

Author

Joshua R. Christie and Madeleine Beekman

Subjects

0301 basic medicine, Genetics, education.field_of_study, Non-Mendelian inheritance, Mitochondrial DNA, Heredity, Population, Inheritance Patterns, Uniparental inheritance, Biology, DNA, Mitochondrial, Heteroplasmy, Mitochondria, 03 medical and health sciences, Fixation (population genetics), 030104 developmental biology, Paternal mtDNA transmission, Haplotypes, Mutation, Trait, Animals, General Agricultural and Biological Sciences, education, Ecology, Evolution, Behavior and Systematics

Abstract

Although the uniparental (or maternal) inheritance of mitochondrial DNA (mtDNA) is widespread, the reasons for its evolution remain unclear. Two main hypotheses have been proposed: selection against individuals containing different mtDNAs (heteroplasmy) and selection against "selfish" mtDNA mutations. Recently, uniparental inheritance was shown to promote adaptive evolution in mtDNA, potentially providing a third hypothesis for its evolution. Here, we explore this hypothesis theoretically and ask if the accumulation of beneficial mutations provides a sufficient fitness advantage for uniparental inheritance to invade a population in which mtDNA is inherited biparentally. In a deterministic model, uniparental inheritance increases in frequency but cannot replace biparental inheritance if only a single beneficial mtDNA mutation sweeps through the population. When we allow successive selective sweeps of mtDNA, however, uniparental inheritance can replace biparental inheritance. Using a stochastic model, we show that a combination of selection and drift facilitates the fixation of uniparental inheritance (compared to a neutral trait) when there is only a single selective mtDNA sweep. When we consider multiple mtDNA sweeps in a stochastic model, uniparental inheritance becomes even more likely to replace biparental inheritance. Our findings thus suggest that selective sweeps of beneficial mtDNA haplotypes can drive the evolution of uniparental inheritance.

Published

2016

6. Early replication dynamics of sex-linked mitochondrial DNAs in the doubly uniparental inheritance species Ruditapes philippinarum (Bivalvia Veneridae)

Author

Marco Passamonti, Davide Guerra, Liliana Milani, Fabrizio Ghiselli, Sophie Breton, Guerra, D., Ghiselli, F., Milani, L., Breton, S., and Passamonti, M

Subjects

DNA Replication, Male, 0301 basic medicine, Mitochondrial DNA, Non-Mendelian inheritance, Inheritance Patterns, Embryonic Development, Uniparental inheritance, Ruditapes, Real-Time Polymerase Chain Reaction, DNA, Mitochondrial, 03 medical and health sciences, Paternal mtDNA transmission, Human population genetics, Genetics, Animals, Cluster Analysis, Genetics (clinical), Homoplasmy, Models, Genetic, biology, Doubly Uniparental Inheritance, Ruditapes philippinarum, Mitochondria, Development, biology.organism_classification, Bivalvia, 030104 developmental biology, Genome, Mitochondrial, Linear Models, Female, Original Article

Abstract

Mitochondrial homoplasmy, which is maintained by strictly maternal inheritance and a series of bottlenecks, is thought to be an adaptive condition for metazoans. Doubly uniparental inheritance (DUI) is a unique mode of mitochondrial transmission found in bivalve species, in which two distinct mitochondrial genome (mtDNA) lines are present, one inherited through eggs (F) and one through sperm (M). During development, the two lines segregate in a sex- and tissue-specific manner: females lose M during embryogenesis, whereas males actively segregate it in the germ line. These two pivotal events are still poorly characterized. Here we investigated mtDNA replication dynamics during embryogenesis and pre-adulthood of the venerid Ruditapes philippinarum using real-time quantitative PCR. We found that both mtDNAs do not detectably replicate during early embryogenesis, and that the M line might be lost from females around 24 h of age. A rise in mtDNA copy number was observed before the first reproductive season in both sexes, with the M mitochondrial genome replicating more than the F in males, and we associate these boosts to the early phase of gonad production. As evidence indicates that DUI relies on the same molecular machine of mitochondrial maternal inheritance that is common in most animals, our data are relevant not only to DUI but also to shed light on how differential segregations of mtDNA variants, in the same nuclear background, may be controlled during development.

Published

2016

7. Heteroplasmy in a deep-sea protobranch bivalve suggests an ancient origin of doubly uniparental inheritance of mitochondria in Bivalvia

Author

Ron J. Etter and Elizabeth E. Boyle

Subjects

Genetics, Non-Mendelian inheritance, Mitochondrial DNA, Ecology, biology, Cytochrome b, Inheritance (genetic algorithm), Uniparental inheritance, Aquatic Science, Bivalvia, biology.organism_classification, Heteroplasmy, Paternal mtDNA transmission, Ecology, Evolution, Behavior and Systematics

Abstract

Most metazoan species have strict maternal inheritance of the mitochondrial genome. In bivalves, a unique inheritance pattern called doubly uniparental inheritance (DUI) occurs in at least seven bivalve families. In this system of mitochondrial inheritance, males inherit and carry mtDNA from both parents, while females only carry mtDNA from the mother. Here, we present evidence of mitochondrial heteroplasmy in deep-sea protobranch bivalves. Divergent 16S rRNA and cytochrome b sequences were obtained within individuals of Ledella ultima. Ledella sublevis also exhibited divergent 16S sequences. Levels of divergence between 16S sequences within individuals were 27 and 15 % for each species, respectively. Ratios of homoplasmic to heteroplasmic individuals were not significantly different from 1:1, in agreement with sex ratios in protobranchs. The results provide the first evidence for mitochondrial heteroplasmy in the protobranchs and suggest DUI might have evolved much earlier in the evolution of the Bivalvia than previously thought.

Published

2012

8. Mitochondrial haplotype does not affect sperm velocity in the zebra finchTaeniopygia guttata

Author

Jon Slate, Tim R. Birkhead, and Jim A. Mossman

Subjects

Male, Genetics, Non-Mendelian inheritance, Mitochondrial DNA, Biology, Mitochondrion, biology.organism_classification, DNA, Mitochondrial, Spermatozoa, Sperm, Haplotypes, Paternal mtDNA transmission, Genetic variation, Sperm Motility, Animals, Female, Finches, Genetic Fitness, Zebra finch, Ecology, Evolution, Behavior and Systematics, Taeniopygia

Abstract

Mitochondrial DNA (mtDNA) variation has been suggested as a possible cause of variation in male fertility because sperm activity is tightly coupled to mitochondrial oxidative phosphorylation and ATP production, both of which are sensitive to mtDNA mutations. Since male-specific phenotypes such as sperm have no fitness consequences for mitochondria due to maternal mitochondrial (and mtDNA) inheritance, mtDNA mutations that are deleterious in males but which have negligible or no fitness effect in females can persist in populations. How often such mutations arise and persist is virtually unknown. To test whether there were associations between mtDNA variation and sperm performance, we haplotyped 250 zebra finches Taeniopygia guttata from a large pedigreed-population and measured sperm velocity using computer-assisted sperm analysis. Using quantitative genetic 'animal' models, we found no effect of mtDNA haplotype on sperm velocity. Therefore, there is no evidence that in this system mitochondrial mutations have asymmetric fitness effects on males and females, leading to genetic variation in male fertility that is blind to natural selection.

Published

2010

9. Maternal Inheritance of Mitochondrial DNA (mtDNA) in the Pacific oyster (Crassostrea gigas): a Preliminary Study Using mtDNA Sequence Analysis with Evidence of Random Distribution of MitoTracker-Stained Sperm Mitochondria in Fertilized Eggs

Author

Akira Komaru, Michiyo Shimizu, Mayu Obata, and Natsumi Sano

Subjects

Male, endocrine system, Mitochondrial DNA, Non-Mendelian inheritance, Somatic cell, Uniparental inheritance, Biology, DNA, Mitochondrial, Andrology, Paternal mtDNA transmission, medicine, Animals, Crassostrea, Ovum, Genetics, Base Sequence, Staining and Labeling, urogenital system, Blastomere, Spermatozoa, Sperm, Mitochondria, Meiosis, medicine.anatomical_structure, Fertilization, Female, Animal Science and Zoology, Germ cell

Abstract

In many bivalve species, paternal and maternal mitochondrial DNA (mtDNA) from sperm and eggs is transmitted to the offspring. This phenomenon is known as doubly uniparental inheritance (DUI). In these species, sperm mtDNA (M type) is inherited by the male gonad of the offspring. Egg mtDNA (F type) is inherited by both male and female somatic cells and female gonadal cells. In Mytilidae, sperm mitochondria are distributed in the cytoplasm of differentiating male germ cells because they are transmitted to the male gonad. In the present study, we investigated maternal inheritance of mtDNA in the Pacific oyster, Crassostrea gigas. Sequence analysis of two mitochondrial non-coding regions revealed an identical sequence pattern in the gametes and adductor muscle samples taken from six males and five females. To observe whether sperm mitochondria were specifically located in the cytoplasm of differentiating germ cells, their distribution was recorded in C. gigas fertilized eggs by vital staining with MitoTracker Green. Although the 1D blastomere was identified in the cytoplasm of differentiating germ cells, sperm mitochondria were located at the 1D blastomere in only 32% of eggs during the 8-cell stage. Thus, in C. gigas, sperm mitochondria do not specifically locate in the germ cell region at the 1D blastomere. We suggest that the distribution of sperm mitochondria is not associated with germ cell formation in C. gigas. Furthermore, as evidenced by the mtDNA sequences of two non-coding regions, we conclude that mitochondrial DNA is maternally inherited in this species.

Published

2008

10. The unusual system of doubly uniparental inheritance of mtDNA: isn’t one enough?

Author

Walter R. Hoeh, Sophie Breton, Hélène Doucet Beaupré, Donald T. Stewart, and Pierre U. Blier

Subjects

Male, Genetics, Non-Mendelian inheritance, Mitochondrial DNA, Genome, Models, Genetic, Adaptation, Biological, Uniparental inheritance, Mitochondrion, Biology, Models, Biological, Human mitochondrial genetics, Bivalvia, Evolution, Molecular, Genes, Mitochondrial, Sex Factors, Paternal mtDNA transmission, Animals, Female, Gene, Phylogeny

Abstract

Mitochondria possess their own genetic material (mitochondrial DNA or mtDNA), whose gene products are involved in mitochondrial respiration and oxidative phosphorylation, transcription, and translation. In animals, mitochondrial DNA is typically transmitted to offspring by the mother alone. The discovery of 'doubly uniparental inheritance' (DUI) of mtDNA in some bivalves has challenged the paradigm of strict maternal inheritance (SMI). In this review, we survey recent advances in our understanding of DUI, which is a peculiar system of cytoplasmic DNA inheritance that involves distinct maternal and paternal routes of mtDNA transmission, a novel extension of a mitochondrial gene (cox2), recombination, and periodic 'role-reversals' of the normally male and female-transmitted mitochondrial genomes. DUI provides a unique opportunity for studying nuclear-cytoplasmic genome interactions and the evolutionary significance of different modes of mitochondrial inheritance.

Published

2007

11. Context-dependent effects of Y chromosome and mitochondrial haplotype on male locomotive activity in Drosophila melanogaster

Author

Rebecca Dean, Damian K. Dowling, and Bernardo Lemos

Subjects

0106 biological sciences, Genetics, Male, 0303 health sciences, Mitochondrial DNA, Non-Mendelian inheritance, Haplotype, Biology, Y chromosome, biology.organism_classification, 010603 evolutionary biology, 01 natural sciences, DNA, Mitochondrial, 03 medical and health sciences, Drosophila melanogaster, Paternal mtDNA transmission, Haplotypes, Y Chromosome, Genetic variation, Animals, Gene, Ecology, Evolution, Behavior and Systematics, Locomotion, 030304 developmental biology

Abstract

Some regions of the genome exhibit sexual asymmetries in inheritance and are thus subjected to sex-biased evolutionary forces. Maternal inheritance of mitochondrial DNA (mtDNA) enables mtDNA mutations harmful to males, but not females, to accumulate. In the face of male-harmful mtDNA mutation accumulation, selection will favour the evolution of compensatory modifiers in the nuclear genome that offset fitness losses to males. The Y chromosome is a candidate to host these modifiers, because it is paternally inherited, known to harbour an abundance of genetic variation for male fertility, and therefore likely to be under strong selection to uphold male viability. Here, we test for intergenomic interactions involving mtDNA and Y chromosomes in male Drosophila melanogaster. Specifically, we examine effects of each of these genomic regions, and their interaction, on locomotive activity, across different environmental contexts – both dietary and social. We found that both the mtDNA haplotype and Y chromosome haplotype affected activity in males assayed in an environment perceived as social. These effects, however, were not evident in males assayed in perceived solitary environments, and neither social nor solitary treatments revealed evidence for intergenomic interactions. Finally, the magnitude and direction of these genetic effects was further contingent on the diet treatment of the males. Thus, genes within the mtDNA and Y chromosome are involved in genotype-by-environment interactions. These interactions might contribute to the maintenance of genetic variation within these asymmetrically inherited gene regions and complicate the dynamics of genetic interactions between the mtDNA and the Y chromosome.

Published

2015

12. Keeping in shape the dogma of mitochondrial DNA maternal inheritance

Author

Valerio Carelli and Carelli, Valerio

Subjects

Male, Cancer Research, Non-Mendelian inheritance, Mitochondrial DNA, lcsh:QH426-470, Inheritance Patterns, Uniparental inheritance, Biology, Mitochondrion, DNA, Mitochondrial, Genetic, Paternal mtDNA transmission, Genetics, Humans, Molecular Biology, Genetics (clinical), Ecology, Evolution, Behavior and Systematics, Haplotype, Embryo, Sequence Analysis, DNA, Ecology, Evolution, Behavior and Systematic, lcsh:Genetics, Female, Research Article

Abstract

Recent reports have questioned the accepted dogma that mammalian mitochondrial DNA (mtDNA) is strictly maternally inherited. In humans, the argument hinges on detecting a signature of inter-molecular recombination in mtDNA sequences sampled at the population level, inferring a paternal source for the mixed haplotypes. However, interpreting these data is fraught with difficulty, and direct experimental evidence is lacking. Using extreme-high depth mtDNA re-sequencing up to ~1.2 million-fold coverage, we find no evidence that paternal mtDNA haplotypes are transmitted to offspring in humans, thus excluding a simple dilution mechanism for uniparental transmission of mtDNA present in all healthy individuals. Our findings indicate that an active mechanism eliminates paternal mtDNA which likely acts at the molecular level., Author Summary Emerging evidence raises the possibility that human mitochondrial DNA (mtDNA) is not strictly maternally inherited, but it has not been technically possible to test this hypothesis directly. We identified trios with discordant mtDNA haplotypes, parent-offspring trios were validated using polymorphic microsatellites, and then used extreme-high depth mtDNA re-sequencing to look for paternally transmitted mtDNA. Despite having up to ~1.2 million-fold coverage of mtDNA, we find no evidence that paternal mtDNA haplotypes are transmitted to offspring in humans. Our findings exclude a simple dilution mechanism for uniparental transmission of mtDNA present in all healthy individuals.

Published

2015

13. Genotypes from patients indicate no paternal mitochondrial DNA contribution

Author

Franco Carrara, Martina T. McDonnell, Geoffrey A. Taylor, Patrick F. Chinnery, Egill Briem, Emma L. Blakely, Robert W. Taylor, Douglass M. Turnbull, Neil Howell, and Massimo Zeviani

Subjects

Male, Mitochondrial DNA, Non-Mendelian inheritance, Genotype, DNA Mutational Analysis, Molecular Sequence Data, Extrachromosomal Inheritance, Mitochondrion, Biology, medicine.disease_cause, DNA, Mitochondrial, Human mitochondrial genetics, Fathers, Paternal mtDNA transmission, Mitochondrial myopathy, Reference Values, medicine, Humans, Female, Genetic Variation, Mitochondria, Muscle, Mitochondrial Myopathies, Mutation, Genetics, DNA, medicine.disease, Mitochondrial, Mitochondria, Neurology, Muscle, Neurology (clinical)

Abstract

A cornerstone of mitochondrial genetics, strict maternal inheritance, has been challenged recently by the study of a patient with mitochondrial myopathy due to a sporadic 2bp deletion. The mitochondrial DNA (mtDNA) harboring the mutation was paternal in origin, whereas the patient's blood was identical to the maternal genotype. To determine whether this is a common phenomenon, we studied mtDNA sequence variation between muscle and blood from 35 patients with sporadic mitochondrial myopathies, but detected no evidence of paternal mtDNA transmission. Our findings suggest that paternal transmission of mtDNA is rare and should not alter our genetic advice to families.

Published

2003

14. The costs of being male: are there sex-specific effects of uniparental mitochondrial inheritance?

Author

Madeleine Beekman, Duur K. Aanen, and Damian K. Dowling

Subjects

Male, Non-Mendelian inheritance, Mitochondrial DNA, Uniparental inheritance, haldanes rule, Biology, Laboratorium voor Erfelijkheidsleer, DNA, Mitochondrial, Genome, Oxidative Phosphorylation, General Biochemistry, Genetics and Molecular Biology, Paternal mtDNA transmission, Gene Duplication, Genetic variation, evolution, Animals, Humans, Selection, Genetic, Allele, cytoplasmic male-sterility, Alleles, unisexual sterility, Genetics, life-span, mussel mytilus, mothers curse, Genetic Variation, maternal inheritance, dna mutations, Articles, PE&RC, Biological Evolution, Mitochondria, seed beetle, Genome, Mitochondrial, Haldane's rule, Female, Laboratory of Genetics, General Agricultural and Biological Sciences

Abstract

Eukaryotic cells typically contain numerous mitochondria, each with multiple copies of their own genome, the mtDNA. Uniparental transmission of mitochondria, usually via the mother, prevents the mixing of mtDNA from different individuals. While on the one hand, this should resolve the potential for selection for fast-replicating mtDNA variants that reduce organismal fitness, maternal inheritance will, in theory, come with another set of problems that are specifically relevant to males. Maternal inheritance implies that the mitochondrial genome is never transmitted through males, and thus selection can target only the mtDNA sequence when carried by females. A consequence is that mtDNA mutations that confer male-biased phenotypic expression will be prone to evade selection, and accumulate. Here, we review the evidence from the ecological, evolutionary and medical literature for male specificity of mtDNA mutations affecting fertility, health and ageing. While such effects have been discovered experimentally in the laboratory, their relevance to natural populations—including the human population—remains unclear. We suggest that the existence of male expression-biased mtDNA mutations is likely to be a broad phenomenon, but that these mutations remain cryptic owing to the presence of counter-adapted nuclear compensatory modifier mutations, which offset their deleterious effects.

Published

2014

15. The Units of Selection on Mitochondrial DNA

Author

David M. Rand

Subjects

Genetics, mtDNA control region, Non-Mendelian inheritance, Mitochondrial DNA, education.field_of_study, Ecology, Population, Population genetics, Biology, Heteroplasmy, Paternal mtDNA transmission, Molecular evolution, Evolutionary biology, education

Abstract

▪ Abstract Mitochondrial DNA (mtDNA) exists in a nested hierarchy of populations. There are multiple mtDNAs within each mitochondrion, a population of mitochondria in each cell, multiple oocytes within each reproductive female, multiple females in each population, and so on up through species and higher clades. The metabolic properties of mitochondria make them highly mutagenic environments for the naked, circular mtDNAs that lie within them. This mutational pressure introduces mtDNA variation (i.e., heteroplasmy) into the cytoplasmic population of cell lineages that are particularly prone to mutational decay and Muller's ratchet owing to the asexual, maternal inheritance of mtDNA. Neutrality tests show that deleterious mutations are common in mtDNA evolution. Population cage experiments further show that mtDNA fitnesses are influenced by nuclear-mitochondrial interactions. These selective processes are pervasive despite the long-standing use of mtDNA as a neutral marker in population and evolutionary biology. These evolutionary dynamics are also unique in the nested hierarchy of mtDNA populations because mutation, selection, and drift can act—and interact—at multiple levels. Multi-level selection can facilitate the escape from Muller's ratchet and help resolve intragenomic conflicts. This review addresses recent advances in the transmission genetics, population genetics, and evolution of mtDNA. A primary goal of the review is to motivate additional empirical studies that might clarify the many units of selection acting on mtDNA.

Published

2001

16. BIPARENTAL MITOCHONDRIAL DNA INHERITANCE IN THE PARASITIC TREMATODESCHISTOSOMA MANSONI

Author

Liana K. Jannotti-Passos, C. P. Souza, J. C. Parra, and Andrew J. G. Simpson

Subjects

Male, Non-Mendelian inheritance, Mitochondrial DNA, Snails, Extrachromosomal Inheritance, Population genetics, Minisatellite Repeats, DNA, Mitochondrial, Polymerase Chain Reaction, Mice, Paternal mtDNA transmission, Animals, Crosses, Genetic, Ecology, Evolution, Behavior and Systematics, Genetics, Mitochondrial DNA inheritance, Zygote, biology, Schistosoma mansoni, DNA, Helminth, biology.organism_classification, Schistosomiasis mansoni, Minisatellite, Female, Parasitology

Abstract

The maternal inheritance of mitochondrial DNA (mtDNA) in eukaryotic organisms occurs because of the selective destruction of paternal mtDNA molecules that may be present in the zygote. The elimination of sperm mtDNA is less efficient in interspecific crosses, and biparental inheritance of mtDNA has been observed in a variety of species. Because interspecific crosses are likely to be extremely rare in nature, parental inheritance of mtDNA has been deemed of little relevance to population genetics. The mtDNA of the parasitic trematode Schistosoma mansoni was examined for its utility in addressing epidemiological questions related to the transmission and spread of schistosomiasis. Prior to embarking on such experiments, we sought to confirm the mode of inheritance of this molecule using the highly polymorphic mtDNA minisatellite as a marker. In 3 separate crosses, mtDNA apparently identical to paternal DNA was observed in some individuals of the F2 and F3 generations. These observations thus suggest the intraspecific paternal inheritance of mtDNA across multiple generations in Schistosoma mansoni.

Published

2001

17. A hypothesis for transmission of paternal mitochondrial DNA

Author

Justin C. St. John and Christopher J De Jonge

Subjects

Genetics, Mitochondrial DNA, Non-Mendelian inheritance, Offspring, medicine.medical_treatment, fungi, food and beverages, Obstetrics and Gynecology, Karyotype, Reproductive technology, Biology, Human mitochondrial genetics, Intracytoplasmic sperm injection, Paternal mtDNA transmission, medicine

Abstract

Since the introduction of more complex and invasive forms of assisted reproductive technologies (ART), there has been much speculation as to whether the genetic integrity of the offspring can be maintained. For example, Y microdeletions and cystic fibrosis mutations can be transmitted to the offspring following intracytoplasmic sperm injection (ICSI), as can karyotype disorders. Furthermore, speculation has arisen over the transmission of mitochondrial DNA (mtDNA) to offspring and whether maternal inheritance patterns are maintained.

Published

2000

18. The exceptional mitochondrial DNA system of the mussel family Mytilidae

Author

Eleftherios Zouros

Subjects

Male, Sex Determination Analysis, Non-Mendelian inheritance, Mitochondrial DNA, Extrachromosomal Inheritance, Uniparental inheritance, DNA, Mitochondrial, Paternal mtDNA transmission, Genotype, Genetics, Animals, Sex Ratio, Allele, Molecular Biology, Phylogeny, biology, General Medicine, Sex Determination Processes, Unionidae, biology.organism_classification, Bivalvia, Mitochondria, Pedigree, Mytilidae, Female

Abstract

Species of the families Mytilidae (sea mussels) and Unionidae (fresh water mussels) contain two types of mitochondrial DNA (mtDNA), the F that behaves as the standard animal mtDNA and the M that is transmitted through the sperm and establishes itself only in the male gonad. The two molecules have, therefore, separate transmission routes, one through the female and the other through the male lineage. The system has been named doubly uniparental inheritance (DUI). Another important feature of sea mussels is that the sex ratio among offspring of a pair mating is determined by the female parent only. The mechanism of DUI remains unknown. One hypothesis that is consistent with all observations is that the standard maternal inheritance was modified in mussels via the evolution of a suppressor gene that is expressed during oogenesis and has two alleles, the inactive and the active allele. In the presence of the active allele in the mother's genotype the egg is supplied with a substance that interferes and the normal mechanism of elimination of sperm mitochondria. This will explain why half of mussels have the father's mtDNA and half do not, but would not explain why presence/absence of paternal mtDNA is linked with the male and female gender, respectively. To provide an explanation for this linkage, one would have to assume that there is a causal relationship between retention of paternal mtDNA and sex determination.

Published

2000

19. Maternal Inheritance of Mouse mtDNA in Interspecific Hybrids: Segregation of the Leaked Paternal mtDNA Followed by the Prevention of Subsequent Paternal Leakage

Author

Sumiyo Takahama, Jun-Ichi Hayashi, Hiroshi Shitara, Hideki Kaneda, and Hiromichi Yonekawa

Subjects

Male, Genetics, Mitochondrial DNA, Non-Mendelian inheritance, Zygote, Chimera, Extrachromosomal Inheritance, Mice, Inbred Strains, Embryo, Biology, DNA, Mitochondrial, Polymerase Chain Reaction, Spermatozoa, Sperm, Germline, Mice, Chimera (genetics), Paternal mtDNA transmission, Fertilization, Animals, Female, Crosses, Genetic, Research Article

Abstract

The transmission profiles of sperm mtDNA introduced into fertilized eggs were examined in detail in F1 hybrids of mouse interspecific crosses by addressing three aspects. The first is whether the leaked paternal mtDNA in fertilized eggs produced by interspecific crosses was distributed stably to all tissues after the eggs' development to adults. The second is whether the leaked paternal mtDNA was transmitted to the subsequent generations. The third is whether paternal mtDNA continuously leaks in subsequent backcrosses. For identification of the leaked paternal mtDNA, we prepared total DNA samples directly from tissues or embryos and used PCR techniques that can detect a few molecules of paternal mtDNA even in the presence of 108-fold excess of maternal mtDNA. The results showed that the leaked paternal mtDNA was not distributed to all tissues in the F1 hybrids or transmitted to the following generations through the female germ line. Moreover, the paternal mtDNA leakage was limited to the first generation of an interspecific cross and did not occur in progeny from subsequent backcrosses. These observations suggest that species-specific exclusion of sperm mtDNA in mammalian fertilized eggs is extremely stringent, ensuring strictly maternal inheritance of mtDNA.

Published

1998

20. No recombination of mtDNA after heteroplasmy for 50 generations in the mouse maternal germline

Author

James B. Stewart, Christoph Freyer, Nils-Göran Larsson, Brendan J. Battersby, Erik Hagström, Research Programs Unit, and Research Programme for Molecular Neurology

Subjects

Mitochondrial DNA, Non-Mendelian inheritance, TRANSMISSION, Population, education, GENOMES, Biology, INHERITANCE, DNA, Mitochondrial, Polymerase Chain Reaction, Human mitochondrial genetics, Germline, Mice, 03 medical and health sciences, 0302 clinical medicine, Paternal mtDNA transmission, REVEALS, Genetics, Animals, PHYLOGENETIC ANALYSIS, Cloning, Molecular, Molecular Biology, 030304 developmental biology, Recombination, Genetic, mtDNA control region, Mice, Inbred BALB C, 0303 health sciences, education.field_of_study, LINEAGE, Bacteriophage lambda, Heteroplasmy, HUMAN MITOCHONDRIAL-DNA, EXPLAINS, ALLOPHAGY, 3111 Biomedicine, Artifacts, 030217 neurology & neurosurgery

Abstract

Variants of mitochondrial DNA (mtDNA) are commonly used as markers to track human evolution because of the high sequence divergence and exclusive maternal inheritance. It is assumed that the inheritance is clonal, i.e. that mtDNA is transmitted between generations without germline recombination. In contrast to this assumption, a number of studies have reported the presence of recombinant mtDNA molecules in cell lines and animal tissues, including humans. If germline recombination of mtDNA is frequent, it would strongly impact phylogenetic and population studies by altering estimates of coalescent time and branch lengths in phylogenetic trees. Unfortunately, this whole area is controversial and the experimental approaches have been widely criticized as they often depend on polymerase chain reaction (PCR) amplification of mtDNA and/or involve studies of transformed cell lines. In this study, we used an in vivo mouse model that has had germline heteroplasmy for a defined set of mtDNA mutations for more than 50 generations. To assess recombination, we adapted and validated a method based on cloning of single mtDNA molecules in the lambda phage, without prior PCR amplification, followed by subsequent mutation analysis. We screened 2922 mtDNA molecules and found no germline recombination after transmission of mtDNA under genetically and evolutionary relevant conditions in mammals.

Published

2013

21. Mitochondria, maternal inheritance, and asymmetric fitness: why males die younger

Author

Neil J. Gemmell and Jonci N. Wolff

Subjects

Male, Non-Mendelian inheritance, Mitochondrial DNA, Aging, Offspring, Longevity, Inheritance Patterns, Uniparental inheritance, Mitochondrion, Biology, DNA, Mitochondrial, General Biochemistry, Genetics and Molecular Biology, Epigenesis, Genetic, Sex Factors, Paternal mtDNA transmission, Animals, Humans, Genetics, Sex Characteristics, Natural selection, Mitochondria, Sexual dimorphism, Drosophila melanogaster, Haplotypes, Genome, Mitochondrial, Mutation, Female, Reactive Oxygen Species

Abstract

Mitochondrial function is achieved through the cooperative interaction of two genomes: one nuclear (nuDNA) and the other mitochondrial (mtDNA). The unusual transmission of mtDNA, predominantly maternal without recombination is predicted to affect the fitness of male offspring. Recent research suggests the strong sexual dimorphism in aging is one such fitness consequence. The uniparental inheritance of mtDNA results in a selection asymmetry; mutations that affect only males will not respond to natural selection, imposing a male-specific mitochondrial mutation load. Prior work has implicated this male-specific mutation load in disease and infertility, but new data from fruit flies suggests a prominent role for mtDNA in aging; across many taxa males almost invariably live shorter lives than females. Here we discuss this new work and identify some areas of future research that might now be encouraged to explore what may be the underpinning cause of the strong sexual dimorphism in aging. Editor's suggested further reading in BioEssays: Mitonuclear match: Optimizing fitness and fertility over generations drives ageing within generations Abstract Mitochondrial manoeuvres: Latest insights and hypotheses on mitochondrial partitioning during mitosis in Saccharomyces cerevisiae Abstract Mitochondria and the culture of the Borg Abstract

Published

2013

22. Misconceptions about mitochondria and mammalian fertilization: Implications for theories on human evolution

Author

James M. Cummins and Friderun Ankel-Simons

Subjects

Male, Mitochondrial DNA, Non-Mendelian inheritance, Mitochondrion, Biology, DNA, Mitochondrial, Genomic Imprinting, Human fertilization, Paternal mtDNA transmission, Animals, Humans, Mammals, Organelles, Sperm-Ovum Interactions, Genetics, Multidisciplinary, Models, Genetic, Embryo, Biological Sciences, Biological Evolution, Spermatozoa, Mitochondria, Human evolution, Homo sapiens, Fertilization, Oocytes, Female

Abstract

In vertebrates, inheritance of mitochondria is thought to be predominantly maternal, and mitochondrial DNA analysis has become a standard taxonomic tool. In accordance with the prevailing view of strict maternal inheritance, many sources assert that during fertilization, the sperm tail, with its mitochondria, gets excluded from the embryo. This is incorrect. In the majority of mammals—including humans—the midpiece mitochondria can be identified in the embryo even though their ultimate fate is unknown. The “missing mitochondria” story seems to have survived—and proliferated—unchallenged in a time of contention between hypotheses of human origins, because it supports the “African Eve” model of recent radiation of Homo sapiens out of Africa. We will discuss the infiltration of this mistake into concepts of mitochondrial inheritance and human evolution.

Published

1996

23. DNA analysis of sex chromosomal aberration: curious mutation found in Turner syndrome

Author

Einosuke Tanaka, Katsuya Honda, Z. Tun, Shogo Misawa, Takako Nakamura, and Kentaro Yamazaki

Subjects

Genetics, Non-Mendelian inheritance, Mitochondrial DNA, Paternal mtDNA transmission, Turner syndrome, medicine, Karyotype, General Medicine, Klinefelter syndrome, Biology, medicine.disease, Heteroplasmy, Hypervariable region

Abstract

The clear evidence that curious fashion of mitochondrial DNA (mtDNA) inheritance was reported in sex chromosomal aberration. Human mtDNA is located outside the nucleus of the cell producing energy for the cell. In the recent years, mtDNA is being used in forensic DNA identification because each cell has many copies of mitochondria, and is easy to be amplified by PCR. Human mtDNA has polymorphic sites in hypervariable regions (HVR) I, II and III. However, human mtDNA evokes some problems, such as heteroplasmic point mutations and questionable maternal inheritance. To investigate this phenomenon, we had a chance to perform a mtDNA testing on 1-month-old infant, diagnosed as Turner Syndrome which was confirmed to be 45XO karyotype by X-STR testing. As a result, two remarkable evidences were obtained. The first, an intermarriage, is seemed to be related in the genesis of the sex chromosomal aberration. The second, the exact maternal inheritance of mtDNA was not maintained in Turner syndrome, as well as in Klinefelter syndrome reported by us previously. In these cases, although paternal influence of mtDNA inheritance was deniable, mutations of mother's mtDNA were excluded or repaired to the usual type in child's mtDNA.

Published

2004

24. No evidence for paternal inheritance of mtDNA in patients with sporadic mtDNA mutations

Author

Marianne Schwartz and John Vissing

Subjects

Male, Genetics, Non-Mendelian inheritance, Mitochondrial DNA, Muscles, Genetic counseling, Mitochondrial disease, Molecular Sequence Data, Haplotype, Mitochondrial Myopathies, Biology, medicine.disease, DNA, Mitochondrial, Polymerase Chain Reaction, Neurology, Paternal mtDNA transmission, Mitochondrial myopathy, Mutation, medicine, Humans, Female, Neurology (clinical), Paternal Inheritance

Abstract

With the publication of a patient with severe exercise intolerance, in whom the mutated mtDNA in muscle was shown to be paternally inherited, the strict maternal inheritance of mtDNA was challenged. Paternal mtDNA inheritance may have gone unrecognized in cases of mitochondrial disease with no clear maternal pattern of inheritance because mitochondrial haplotypes are rarely investigated in diagnostic analyses. To find further evidence for a paternal inheritance of mtDNA, we reinvestigated 12 patients with mitochondrial myopathy, in whom the pathogenic mutation was known to be sporadic. We compared the mtDNA haplotypes from the patient's muscle with that of the mtDNA haplotypes in blood from either the mother or the patient. No evidence of paternal inheritance of mtDNA was found in this small study. Although these findings indicate that the paternal inheritance of mtDNA is rare, they do not rule out that the phenomenon may occur at a rate that could still affect genetic counselling and anthropological research.

Published

2004

25. Uniparental inheritance of mitochondrial and chloroplast genes: mechanisms and evolution

Author

C W Birky

Subjects

Genetics, Non-Mendelian inheritance, Chloroplasts, Multidisciplinary, Nuclear gene, Extranuclear inheritance, Models, Genetic, Extrachromosomal Inheritance, Fungi, Inheritance (genetic algorithm), Eukaryota, Uniparental inheritance, Plants, Biology, Biological Evolution, Mitochondria, Eukaryotic Cells, Plastid inheritance, Paternal mtDNA transmission, Animals, Gene, Research Article

Abstract

In nearly all eukaryotes, at least some individuals inherit mitochondrial and chloroplast genes from only one parent. There is no single mechanism of uniparental inheritance: organelle gene inheritance is blocked by a variety of mechanisms and at different stages of reproduction in different species. Frequent changes in the pattern of organelle gene inheritance during evolution suggest that it is subject to varying selective pressures. Organelle genes often fail to recombine even when inherited biparentally; consequently, their inheritance is asexual. Sexual reproduction is apparently less important for genes in organelles than for nuclear genes, probably because there are fewer of them. As a result organelle sex can be lost because of selection for special reproductive features such as oogamy or because uniparental inheritance reduces the spread of cytoplasmic parasites and selfish organelle DNA.

Published

1995

26. Paternal transmission of mitochondrial DNA as an integral part of mitochondrial inheritance in metapopulations of Drosophila simulans

Author

J. W. O. Ballard, Peter Sutovsky, Jonci N. Wolff, and Mohammad Michael Nafisinia

Subjects

mtDNA control region, Genetics, Male, Mitochondrial DNA, Non-Mendelian inheritance, Offspring, Molecular Sequence Data, Biology, Human mitochondrial genetics, DNA, Mitochondrial, Polymerase Chain Reaction, Polymorphism, Single Nucleotide, Heteroplasmy, chemistry.chemical_compound, Genes, Mitochondrial, Genetics, Population, chemistry, Paternal mtDNA transmission, Molecular marker, Animals, Original Article, Drosophila, Female, Genetics (clinical)

Abstract

Maternal inheritance is one of the hallmarks of animal mitochondrial DNA (mtDNA) and central to its success as a molecular marker. This mode of inheritance and subsequent lack of heterologous recombination allows us to retrace evolutionary relationships unambiguously down the matriline and without the confounding effects of recombinant genetic information. Accumulating evidence of biparental inheritance of mtDNA (paternal leakage), however, challenges our current understanding of how this molecule is inherited. Here, using Drosophila simulans collected from an East African metapopulation exhibiting recurring mitochondrial heteroplasmy, we conducted single fly matings and screened F1 offspring for the presence of paternal mtDNA using allele-specific PCR assays (AS–PCR). In all, 27 out of 4092 offspring were identified as harboring paternal mtDNA, suggesting a frequency of 0.66% paternal leakage in this species. Our findings strongly suggest that recurring mtDNA heteroplasmy as observed in natural populations of Drosophila simulans is most likely caused by repeated paternal leakage. Our findings further suggest that this phenomenon to potentially be an integral part of mtDNA inheritance in these populations and consequently of significance for mtDNA as a molecular marker.

Published

2012

27. Evidence of animal mtDNA recombination between divergent populations of the potato cyst nematode Globodera pallida

Author

Angelique H. Hoolahan, Mark Dowton, Vivian C. Blok, and Tracey Gibson

Subjects

Male, Mitochondrial DNA, Non-Mendelian inheritance, Molecular Sequence Data, Population genetics, Plant Science, Biology, DNA, Mitochondrial, Paternal mtDNA transmission, Sequence Homology, Nucleic Acid, Genetic variation, Genetics, Animals, Tylenchoidea, Globodera pallida, Crosses, Genetic, Phylogeny, Solanum tuberosum, Recombination, Genetic, Base Sequence, Genetic Variation, General Medicine, Biodiversity, South America, biology.organism_classification, Heteroplasmy, United Kingdom, Genetics, Population, Insect Science, Genome, Mitochondrial, Animal Science and Zoology, Female, Recombination

Abstract

Recombination is typically assumed to be absent in animal mitochondrial genomes (mtDNA). However, the maternal mode of inheritance means that recombinant products are indistinguishable from their progenitor molecules. The majority of studies of mtDNA recombination assess past recombination events, where patterns of recombination are inferred by comparing the mtDNA of different individuals. Few studies assess contemporary mtDNA recombination, where recombinant molecules are observed as direct mosaics of known progenitor molecules. Here we use the potato cyst nematode, Globodera pallida, to investigate past and contemporary recombination. Past recombination was assessed within and between populations of G. pallida, and contemporary recombination was assessed in the progeny of experimental crosses of these populations. Breeding of genetically divergent organisms may cause paternal mtDNA leakage, resulting in heteroplasmy and facilitating the detection of recombination. To assess contemporary recombination we looked for evidence of recombination between the mtDNA of the parental populations within the mtDNA of progeny. Past recombination was detected between a South American population and several UK populations of G. pallida, as well as between two South American populations. This suggests that these populations may have interbred, paternal mtDNA leakage occurred, and the mtDNA of these populations subsequently recombined. This evidence challenges two dogmas of animal mtDNA evolution; no recombination and maternal inheritance. No contemporary recombination between the parental populations was detected in the progeny of the experimental crosses. This supports current arguments that mtDNA recombination events are rare. More sensitive detection methods may be required to adequately assess contemporary mtDNA recombination in animals.

Published

2011

28. Thermal habit, metabolic rate and the evolution of mitochondrial DNA

Author

David M. Rand

Subjects

Genetics, Mitochondrial DNA, Non-Mendelian inheritance, Paternal mtDNA transmission, Phylogenetics, Inheritance (genetic algorithm), Biology, Genome, Ecology, Evolution, Behavior and Systematics, Organism, Sequence (medicine)

Abstract

The hallmarks of animal mitochondrial DNA (mtDNA) are a rapid rate of sequence evolution, a small genome carrying the same set of homologous genes, maternal inheritance and lack of recombination. Over the past few years, a variety of different observations has challenged these accepted notions of mitochondrial biology. Notable examples include evidence for variable rates of mtDNA sequence evolution among taxa, evidence for large and variable mitochondrial genome sizes in certain groups, and a growing number of cases in metazoans of 'paternal leakage' in the inheritance of mtDNA. Several recent studies have uncovered different lines of evidence suggesting that an organism's thermal habit, or metabolic rate, can influence the evolution of mtDNA.

Published

2011

29. Segregation of mtDNA throughout human embryofetal development: m.3243AG as a model system

Author

David C. Samuels, Nelly Frydman, Jelena Martinovic, Philippe Burlet, Jean-Paul Bonnefont, Laetitia Hesters, René Frydman, Arnold Munnich, Julie Steffann, Nadine Gigarel, Sophie Monnot, V. Kerbrat, Alexandra Benachi, Benoît Funalot, Josué Feingold, Université Paris Descartes - Paris 5 ( UPD5 ), Génétique et épigénétique des maladies métaboliques, neurosensorielles et du développement ( Inserm U781 ), Université Paris Descartes - Paris 5 ( UPD5 ) -Institut National de la Santé et de la Recherche Médicale ( INSERM ), Service de Génétique Médicale [CHU Necker], Assistance publique - Hôpitaux de Paris (AP-HP)-CHU Necker - Enfants Malades [AP-HP], Molecular Physiology and Biophysics, Vanderbilt University Medical Center, Service de gynécologie-obstétrique, médecine de la reproduction [Béclère], Université Paris-Sud - Paris 11 ( UP11 ) -Assistance publique - Hôpitaux de Paris (AP-HP)-Hôpital Antoine Béclère, Genetics, Assistance publique - Hôpitaux de Paris (AP-HP), Service d'obstétrique, Université Paris Descartes - Paris 5 (UPD5), Génétique et épigénétique des maladies métaboliques, neurosensorielles et du développement (Inserm U781), Université Paris Descartes - Paris 5 (UPD5)-Institut National de la Santé et de la Recherche Médicale (INSERM), Assistance publique - Hôpitaux de Paris (AP-HP) (AP-HP)-CHU Necker - Enfants Malades [AP-HP], Assistance publique - Hôpitaux de Paris (AP-HP) (AP-HP), Vanderbilt University Medical Center [Nashville], Vanderbilt University [Nashville]-Vanderbilt University [Nashville], AP-HP - Hôpital Antoine Béclère [Clamart], Assistance publique - Hôpitaux de Paris (AP-HP) (AP-HP)-Assistance publique - Hôpitaux de Paris (AP-HP) (AP-HP)-Université Paris-Sud - Paris 11 (UP11), Université Paris-Sud - Paris 11 (UP11)-Assistance publique - Hôpitaux de Paris (AP-HP) (AP-HP)-AP-HP - Hôpital Antoine Béclère [Clamart], Assistance publique - Hôpitaux de Paris (AP-HP) (APHP)-CHU Necker - Enfants Malades [AP-HP], Université Paris-Sud - Paris 11 (UP11)-Assistance publique - Hôpitaux de Paris (AP-HP) (APHP)-Hôpital Antoine Béclère, and Assistance publique - Hôpitaux de Paris (AP-HP) (APHP)

Subjects

Mitochondrial DNA, Non-Mendelian inheritance, Gene Dosage, embryo, Embryonic Development, mitochondrial DNA, respiratory chain deficiency, Biology, NARP, Preimplantation genetic diagnosis, medicine.disease_cause, MELAS syndrome, Gene dosage, DNA, Mitochondrial, Fetal Development, 03 medical and health sciences, 0302 clinical medicine, Paternal mtDNA transmission, Pregnancy, Prenatal Diagnosis, Genetics, medicine, MELAS Syndrome, Humans, preimplantation genetic diagnosis, Genetics (clinical), 030304 developmental biology, 0303 health sciences, Mutation, Models, Genetic, Life Sciences, medicine.disease, Heteroplasmy, mitochondria, MELAS, Female, 030217 neurology & neurosurgery, Research Article

Abstract

Mitochondrial DNA (mtDNA) mutations cause a wide range of serious diseases with high transmission risk and maternal inheritance. Tissue heterogeneity of the heteroplasmy rate (“mutant load”) accounts for the wide phenotypic spectrum observed in carriers. Owing to the absence of therapy, couples at risk to transmit such disorders commonly ask for prenatal (PND) or preimplantation diagnosis (PGD). The lack of data regarding heteroplasmy distribution throughout intrauterine development, however, hampers the implementation of such procedures. We tracked the segregation of the m.3243A > G mutation (MT-TL1 gene) responsible for the MELAS syndrome in the developing embryo/fetus, using tissues and cells from eight carrier females, their 38 embryos and 12 fetuses. Mutant mtDNA segregation was found to be governed by random genetic drift, during oogenesis and somatic tissue development. The size of the bottleneck operating for m.3243A > G during oogenesis was shown to be individual-dependent. Comparison with data we achieved for the m.8993T > G mutation (MT-ATP6 gene), responsible for the NARP/Leigh syndrome, indicates that these mutations differentially influence mtDNA segregation during oogenesis, while their impact is similar in developing somatic tissues. These data have major consequences for PND and PGD procedures in mtDNA inherited disorders. Hum Mutat 32:116–125, 2011. © 2010 Wiley-Liss, Inc.

Published

2010

30. Paternal inheritance of mitochondria in Chlamydomonas

Author

Soichi Nakamura

Subjects

Genetics, Non-Mendelian inheritance, Mitochondrial DNA, Zygote, biology, Chlamydomonas, Uniparental inheritance, Plant Science, biology.organism_classification, DNA, Mitochondrial, Diploidy, Genes, Mitochondrial, Paternal mtDNA transmission, Genome, Mitochondrial, Paternal Inheritance, Gene

Abstract

To analyze mitochondrial DNA (mtDNA) inheritance, differences in mtDNA between Chlamydomonas reinhardtii and Chlamydomonas smithii, respiration deficiency and antibiotic resistance were used to distinguish mtDNA origins. The analyses indicated paternal inheritance. However, these experiments raised questions regarding whether paternal inheritance occurred normally. Mitochondrial nucleoids were observed in living zygotes from mating until 3 days after mating and then until progeny formation. However, selective disappearance of nucleoids was not observed. Subsequently, experimental serial backcrosses between the two strains demonstrated strict paternal inheritance. The fate of mt+ and mt− mtDNA was followed using the differences in mtDNA between the two strains. The slow elimination of mt+ mtDNA through zygote maturation in darkness was observed, and later the disappearance of mt+ mtDNA was observed at the beginning of meiosis. To explain the different fates of mtDNA, methylation status was investigated; however, no methylation was detected. Variously constructed diploid cells showed biparental inheritance. Thus, when the mating process occurs normally, paternal inheritance occurs. Mutations disrupting mtDNA inheritance have not yet been isolated. Mutations that disrupt maternal inheritance of chloroplast DNA (cpDNA) do not disrupt inheritance of mtDNA. The genes responsible for mtDNA inheritance are different from those of chloroplasts.

Published

2009

31. Mitochondrial Non‐Mendelian Inheritance: Evolutionary Origin and Consequences

Author

C. William Birky

Subjects

Genetics, Mitochondrial DNA, Non-Mendelian inheritance, Paternal mtDNA transmission, Evolutionary biology, Inheritance (genetic algorithm), Uniparental inheritance, Biology, Mitochondrion, Genome, Heteroplasmy

Abstract

Alleles of mitochondrial genes segregate during vegetative (mitotic) divisions as a consequence of the random manner in which mitochondrial genomes are replicated and partitioned at cell division. This is probably an evolutionary relic of their endosymbiotic origin. Uniparental inheritance of mitochondrial genes in humans is a result of oogamy and degradation of paternal mitochondria in the egg, but different mechanisms have evolved in other organisms. Keywords: uniparental inheritance; maternal inheritance; vegetative segregation; inheritance of mitochondrial genes; heteroplasmy

Published

2006

32. Assaying the probabilities of obtaining maternally inherited heteroplasmy as the basis for modeling OXPHOS diseases in animals

Author

Vadim B. Vasilyev, Oksana V. Kidgotko, Elena V. Grachyova, Vassilina A. Sokolova, Mikhail G. Bass, Maria E. Kustova, and Alexander V. Sorokin

Subjects

Genetically modified mouse, Non-Mendelian inheritance, Mitochondrial DNA, Mitochondrial Diseases, Maternal inheritance, Zygote, Biophysics, OXPHOS diseases modeling, Mice, Transgenic, Mitochondrion, Biology, Biochemistry, DNA, Mitochondrial, Oxidative Phosphorylation, Mice, Paternal mtDNA transmission, Transgenic mice, Animals, Humans, Probability, Genetics, Embryo, Cell Biology, Energy metabolism, Embryo, Mammalian, Heteroplasmy, mtDNA transfer, Mitochondria, Disease Models, Animal, Genes, Mitochondrial, Animals, Newborn, Organ Specificity, Human mtDNA

Abstract

Gross alterations in cell energy metabolism underlie manifestations of hereditary OXPHOS (oxidative phosphorylation) diseases, many of which depend on proportion of mutant mitochondrial DNA (mtDNA) in tissues. An animal model of OXPHOS disease with maternal inheritance of mitochondrial heteroplasmy might help understanding the peculiarities of abnormal mtDNA distribution and its effect on pre- and postnatal development. Previously we obtained mice that carry human mtDNA in some tissues. It co-existed with murine mtDNA (heteroplasmy) and was transmitted maternally to the progeny of animals developed from zygotes injected with human mitochondria. To analyze the probability of obtaining heteroplasmic mice we increased the number of experiments with early embryos and obtained more specimens from F1. About 33% of zygotes injected with human mtDNA developed into post-implantation embryos (7th–13th days). Lower amount of such developed into neonate mice (ca. 21%). Among post-implantation embryos and in generations F0 and F1 percentages of human mtDNA-carriers were ca. 14–16%. Such percentages are sufficient for modeling maternally inherited heteroplasmy in small animal groups. More data are needed to understand the regularities of anomalous mtDNA distribution among cells and tissues and whether heart and muscles frequently carrying human mtDNA in our experiments are particularly susceptible to heteroplasmy.

Published

2005

33. The mitochondrial genome

Author

Douglas C. Wallace

Subjects

Genetics, Non-Mendelian inheritance, Mutation, Mitochondrial DNA, Somatic cell, Biology, medicine.disease_cause, Human mitochondrial genetics, symbols.namesake, Paternal mtDNA transmission, Mendelian inheritance, symbols, medicine, Gene

Abstract

The human mitochondrial genome consists of approximately 1500 genes, 37 encoded by the maternally inherited mitochondrial DNA (mtDNA) and the remainder encoded by the nuclear chromosomes. Mutation in the nDNA genes result in Mendelian diseases that affect mitochondrial function or mtDNA replication and stability. Mutations in the mtDNA include ancient adaptive polymorphisms, maternally inherited diseases, and somatic mutations that contribute to age-related diseases, aging, and cancer. Keywords: mitochondrial; mtDNA; maternal inheritance; degenerative diseases; cancer; aging

Published

2005

34. Degradation of paternal mitochondria after fertilization: implications for heteroplasmy, assisted reproductive technologies and mtDNA inheritance

Author

Tod C. McCauley, Klaus van Leyen, Miriam Sutovsky, Billy N. Day, and Peter Sutovsky

Subjects

Genetics, Male, Non-Mendelian inheritance, Mitochondrial DNA, Mitochondrial Degradation, Inheritance Patterns, Obstetrics and Gynecology, Reproductive technology, Mitochondrion, Biology, DNA, Mitochondrial, Spermatozoa, Heteroplasmy, Mitochondria, Reproductive Techniques, Reproductive Medicine, Paternal mtDNA transmission, Fertilization, Humans, Paternal Inheritance, Developmental Biology

Abstract

Maternal inheritance of mitochondrial DNA has long been regarded as a major paradox in developmental biology. While some confusion may still persist in popular science, research data clearly document that the paternal sperm-borne mitochondria of most mammalian species enter the ooplasm at fertilization and are specifically targeted for degradation by the resident ubiquitin system. Ubiquitin is a proteolytic chaperone that forms covalently linked polyubiquitin chains on the targeted proteinaceous substrates. The polyubiquitin tag redirects the substrate proteins to a 26-S proteasome, a multi-subunit proteolytic organelle. Thus, specific proteasomal inhibitors reversibly block sperm mitochondrial degradation in ooplasm. Lysosomal degradation and the activity of membrane-lipoperoxidating enzyme 15-lipoxygenase (15-LOX) may also contribute to sperm mitochondrial degradation in the ooplasm, but probably is not crucial. Prohibitin, the major protein of the inner mitochondrial membrane, appears to be ubiquitinated in the sperm mitochondria. Occasional occurrence of paternal inheritance of mtDNA has been suggested in mammals including humans. While most such evidence has been widely disputed, it warrants further examination. Of particular concern is the documented heteroplasmy, i.e. mixed mtDNA inheritance after ooplasmic transplantation. Intracytoplasmic sperm injection (ICSI) has inherent potential for delaying the degradation of sperm mitochondria. However, paternal mtDNA inheritance after ICSI has not been documented so far.

Published

2004

35. Mitochondrial DNA and the Y chromosome: parallels and paradoxes

Author

James M. Cummins

Subjects

Genetic Markers, Male, Non-Mendelian inheritance, Mitochondrial DNA, Reproductive technology, Biology, Y chromosome, Genome, DNA, Mitochondrial, Endocrinology, Paternal mtDNA transmission, Y Chromosome, Genetics, Animals, Humans, Selection, Genetic, Spermatogenesis, Molecular Biology, X chromosome, Infertility, Male, Recombination, Genetic, Human evolutionary genetics, Biological Evolution, Fertility, Reproductive Medicine, Animal Science and Zoology, Female, Developmental Biology, Biotechnology

Abstract

Both mitochondrial DNA (mtDNA) and the Y chromosome have been used extensively by molecular paleoanthropologists in attempts to reconstruct human lineages. Both are inherited in a haploid manner: mtDNA through the female and the Y through the male. For mtDNA, maternal inheritance is ensured by a species-specific mechanism of proteolysis of the sperm midpiece in early embryogenesis, based on ubiquitination of the mitochondria during spermiogenesis. Both genomes are thought to lack recombination and are thus liable to high rates of neutral mutation. For the human Y chromosome, it is now clear that there has been selection on genes controlling spermatogenesis, resulting in differential long-term reproductive success. This is corroborated from studies of genealogies and hunting–gathering societies, although these lack the rigour provided by the modern molecular markers of inheritance. Selection is made more complicated by a concentration of genes controlling secondary sexual characteristics on the X chromosome. Likewise, mtDNA affects the bioenergetics of gametogenesis and embryo development, as well as longevity, disease and the aging process. Both Y chromosome and mitochondrial haplotypes show significant associations with patterns of male infertility that could distort their use for phylogenetic reconstruction. Moreover, the molecular analysis of mtDNA is complicated by the presence of numerous nuclear mitochondrial pseudogenes (Numts) that can be erroneously amplified by molecular techniques such as PCR. This review examines some of these complex interactions and suggests that some of the more contentious issues in understanding human evolution may be resolved by considering the biology of these genetic markers.

Published

2002

36. Evaluation of parental mitochondrial inheritance in neonates born after intracytoplasmic sperm injection

Author

Willy Lissens, Philippe Duquesnoy, Serge Amselem, Claude Besmond, Claude Danan, Andre Van Steirteghem, Cécile Cazeneuve, Michel Goossens, Damien Sternberg, Department of Embryology and Genetics, and Vrije Universiteit Brussel

Subjects

Male, Infertility, Non-Mendelian inheritance, Mitochondrial DNA, Mitochondrial inheritance, medicine.medical_treatment, Extrachromosomal Inheritance, Mothers, Fertilization in Vitro, Regulatory Sequences, Nucleic Acid, Biology, DNA, Mitochondrial, Polymerase Chain Reaction, Sensitivity and Specificity, Intracytoplasmic sperm injection, law.invention, Male infertility, Fathers, Paternal mtDNA transmission, law, Prohibitins, Genetics, medicine, Humans, Genetics(clinical), Infertility, Male, Genetics (clinical), Polymerase chain reaction, Polymorphism, Genetic, Base Sequence, mtDNA, Infant, Newborn, Genetic Variation, DNA Restriction Enzymes, medicine.disease, Heteroplasmy, Electrophoresis, Polyacrylamide Gel, Female, Research Article

Abstract

SummaryIntracytoplasmic sperm injection (ICSI) is now used when severe male-factor infertility has been documented. Since defective mitochondrial functions may result in male hypofertility, it is of prime importance to evaluate the risk of paternal transmission of an mtDNA defect to neonates. DNA samples from the blood of 21 infertile couples and their 27 neonates born after ICSI were studied. The highly polymorphic mtDNA D-loop region was analyzed by four PCR-based approaches. With denaturing gradient gel electrophoresis (DGGE), which allows 2% of a minor mtDNA species to be detected, the 27 newborns had a DGGE pattern identical to that of their mother but different from that of their father. Heteroplasmy documented in several parents and children supported an exclusive maternal inheritance of mtDNA. The parental origin of the children's mtDNA molecules also was studied by more-sensitive assays: restriction-endonuclease analysis (REA) of α[32P]-radiolabeled PCR products; paternal-specific PCR assay; and depletion of maternal mtDNA, followed by REA. We did not detect paternal mtDNA in nine neonates, with a sensitivity level of 0.01% in five children, 0.1% in two children, and 1% in two children. The estimated ratio of sperm-to-oocyte mtDNA molecules in humans is 0.1%–1.5%. Thus, we conclude that, in these families, the ICSI procedure performed with mature spermatozoa did not alter the uniparental pattern of inheritance of mtDNA.

Published

1999

37. Mammalian mitochondrial genetics: heredity, heteroplasmy and disease

Author

Patrick F. Chinnery, Robert N. Lightowlers, Neil Howell, and Douglass M. Turnbull

Subjects

Genetics, Recombination, Genetic, Non-Mendelian inheritance, Homoplasmy, Mitochondrial DNA, Models, Genetic, Mitochondrial Myopathies, Biology, medicine.disease, Genome, Human mitochondrial genetics, DNA, Mitochondrial, Heteroplasmy, Mitochondrial myopathy, Paternal mtDNA transmission, Mutation, medicine, Animals, Humans, Female

Abstract

Mammalian mitochondrial DNA (mtDNA) is present at high copy number (10(3)-10(4) copies) in virtually all cells of the body. The mitochondrial genome shows strict maternal inheritance and the vast majority of copies are identical at birth (homoplasmy). Occasionally, a subpopulation of mtDNA molecules carry a pathogenic mutation. When this heteroplasmic mtDNA is present during embryogenesis, it can lead to a variety of clinical symptoms predominantly affecting muscle and nerve, but also affecting other tissues. While the importance of mitochodrial heteroplasmy in human disease is unquestioned, we remain largely ignorant of many fundamental aspects of mitochondrial genetics. How do mutations arise and can they be repaired, what influences the segregation and fixation of heteroplasmic mtDNA, do levels of heteroplasmy fluctuate during life, is it possible to modulate these levels by external intervention and, finally, can we predict the segregation and transmission of a mutant genome? The aim of this article is to summarize and discuss recent observations that have addressed several of these fundamental issues and to reiterate how much we still have to learn about mitochondrial genetics.

Published

1998

38. Mitochondrial DNA Genetics and the Heteroplasmy Conundrum in Evolution and Disease

Author

Dimitra Chalkia and Douglas C. Wallace

Subjects

Male, Non-Mendelian inheritance, Mutation rate, Mitochondrial DNA, Mitochondrial Diseases, Mitochondrial replacement therapy, Population, Inheritance Patterns, Biology, DNA, Mitochondrial, Oxidative Phosphorylation, General Biochemistry, Genetics and Molecular Biology, Germline, Mice, Paternal mtDNA transmission, Animals, Humans, education, Phylogeny, Genetics, education.field_of_study, Polymorphism, Genetic, Models, Genetic, food and beverages, Biological Evolution, Heteroplasmy, Mitochondria, Genetics, Population, Phenotype, Evolutionary biology, Genome, Mitochondrial, Mutation, Macaca, Cattle, Female, Perspectives

Abstract

The unorthodox genetics of the mtDNA is providing new perspectives on the etiology of the common "complex" diseases. The maternally inherited mtDNA codes for essential energy genes, is present in thousands of copies per cell, and has a very high mutation rate. New mtDNA mutations arise among thousands of other mtDNAs. The mechanisms by which these "heteroplasmic" mtDNA mutations come to predominate in the female germline and somatic tissues is poorly understood, but essential for understanding the clinical variability of a range of diseases. Maternal inheritance and heteroplasmy also pose major challengers for the diagnosis and prevention of mtDNA disease.

Published

2013

39. MITOCHONDRIAL DNA FROM MOM AND DAD

Author

Celia M. Henry

Subjects

Genetics, Mitochondrial DNA, Mutation rate, chemistry.chemical_compound, Non-Mendelian inheritance, Nuclear gene, chemistry, Paternal mtDNA transmission, General Medicine, Biology, Human mitochondrial genetics, DNA sequencing, DNA

Abstract

MITOCHONDRIAL DNA (MTDNA) is a circular DNA molecule that is essential for mitochondrial function and, unlike the nuclear genome, is present in multiple copies in most cells. MtDNA has been thought to be inherited only from the mother and therefore not subject to the process known as recombination, which is the exchange of homologous segments between two DNA molecules that results in the formation of new DNA sequences. Armed with maternal inheritance and known mutation rates, scientists have used mtDNA as a clock in studies of human origins and evolution. Recent work, however, shows that the assumptions about maternal inheritance and recombination may not be as ironclad as previously thought. In 2002, Marianne Schwartz and John Vissing at Copenhagen University Hospital (Rigshospitalet), in Denmark, revealed that they had a patient with a mitochondrial disorder who had inherited mtDNA from his father { N. Engl. J. Med. , 347 , 576 (2002)}. Paternal mtDNA accounted ...

Published

2004

40. Paternal Inheritance of Mitochondrial DNA

Author

Paul S. Heckerling

Subjects

Genetics, Mitochondrial DNA, Non-Mendelian inheritance, medicine.diagnostic_test, business.industry, General Medicine, Extrachromosomal inheritance, Human mitochondrial genetics, chemistry.chemical_compound, chemistry, Paternal mtDNA transmission, medicine, Paternal Inheritance, business, DNA, Genetic testing

Published

2002

41. Transfer of paternal mitochondrial DNA during fertilization of honeybee (Apis mellifera L.) eggs

Author

Michael S. Meusel and Robin F. A. Moritz

Subjects

Genetics, Male, Mitochondrial DNA, Non-Mendelian inheritance, Extranuclear inheritance, Genetic transfer, Restriction Mapping, General Medicine, Biology, Bees, DNA, Mitochondrial, Spermatozoa, Human fertilization, Paternal mtDNA transmission, Fertilization, Animals, Female, Restriction fragment length polymorphism, Paternal Inheritance, Ovum

Abstract

Strict maternal inheritance of mitochondrial (mt) DNA is believed to be the rule in most eukaryotic organisms because of exclusion of paternal mitochondria from the egg cytoplasm during fertilization. In honeybees, polyspermic fertilization occurs, and many spermatozoa, including their mitochondria-rich flagellum, can completely penetrate the egg, thus allowing for a possibly high paternal leakage. In order to identify paternal mtDNA in honeybee eggs, restriction fragment length polymorphisms (RFLP) of different subspecies were used. Total DNA extracts of different developmental stages of an Apis mellifera carnica x Apis mellifera capensis hybrid brood were tested with a radioactively-labelled diagnostic mtDNA probe. Densitograms of autoradiographs indicated that the male contribution represents up to 27% of the total mitochondrial DNA in the fertilized eggs 12 h after oviposition. In subsequent developmental stages the portion of paternal mtDNA slowly decreased until hatching of the larvae when only traces were found. Although rapid disintegration of paternal mtDNA does not occur, the initially high paternal mitochondrial contribution is not maintained in the adult animal.

Published

1993

42. Strictly maternal inheritance of rat mitochondrial DNA

Author

Osamu Gotoh, Hiromichi Yonekawa, Yusaku Tagashira, Junko Watanabe, and Jun-Ichi Hayashi

Subjects

Male, Genetics, Mitochondrial DNA, Non-Mendelian inheritance, Genotype, Biophysics, EcoRI, Mitochondria, Liver, DNA Restriction Enzymes, Cell Biology, Biology, DNA, Mitochondrial, Biochemistry, Molecular biology, Rats, Paternal mtDNA transmission, Agarose gel electrophoresis, biology.protein, Animals, Female, Molecular Biology, Crosses, Genetic

Abstract

Maternal inheritance of rat mitochondrial DNA (mtDNA) was demonstrated in Sprague-Dawley rats, which have two types of mtDNAs with respect to their Eco RI cleavage patterns on agarose gel electrophoresis. Use of litters of rats with the two types of mtDNAs for interbreeding showed that the mtDNA type of the progeny was the same as that of the dam. Furthermore, examination using the electrophoresis system that can detect as little as 0.02 μg mtDNA showed that 237 progeny in at least 40 generations in the closed breeding colony had one or other type of mtDNA, but that no individual had both types. Thus it is concluded that maternal inheritance of rat mtDNA is strict.

Published

1978

43. Maternal inheritance of human mitochondrial DNA

Author

Hugues Blanc, Howard M. Cann, Douglas C. Wallace, and Richard E. Giles

Subjects

Blood Platelets, Genetics, Mitochondrial DNA, Non-Mendelian inheritance, Polymorphism, Genetic, Multidisciplinary, Genetics, Medical, Nucleic acid sequence, DNA Restriction Enzymes, Biology, DNA, Mitochondrial, Molecular biology, Human mitochondrial genetics, Pedigree, Restriction enzyme, chemistry.chemical_compound, Paternal mtDNA transmission, chemistry, Humans, Cambridge Reference Sequence, DNA, Research Article

Abstract

Human mitochondrial DNA was obtained from peripheral blood platelets donated by the members of several independent families. The samples were screened for nucleotide sequence polymorphisms between individuals within these families. In each family in which we were able to detect a distinctly different restriction endonuclease cleavage pattern between the parents, the progeny exhibited the maternal cleavage pattern. Informative polymorphisms were detected for Hae II (PuGCGCPy) in a three-generation family composed of 33 members, for HincII (GTPyPuAC) in a two-generation family composed of four members, and for Hae III(GGCC) in a two-generation family composed of four members. The Hae II polymorphism was analyzed through all three generations in both the maternal and paternal lines. The results of this study demonstrate that human mitochondrial DNA is maternally inherited. The techniques described for using peripheral blood platelets as a source of human mitochondrial DNA represent a convenient way to obtain data on mitochondrial DNA variation in both individuals and populations.

Published

1980

44. Critical experimental test of the possibility of 'paternal leakage' of mitochondrial DNA

Author

Milton D. Huettel, John C. Avise, and Robert A. Lansman

Subjects

Male, Genetics, Non-Mendelian inheritance, Mitochondrial DNA, Multidisciplinary, biology, Chromosome Mapping, DNA Restriction Enzymes, Biological evolution, biology.organism_classification, Biological Evolution, DNA, Mitochondrial, Lepidoptera, Lepidoptera genitalia, Paternal mtDNA transmission, Heliothis, Backcrossing, Animals, Hybridization, Genetic, Noctuidae, Female, Research Article

Abstract

Most previous data suggesting maternal inheritance of mtDNA have come from single-generation mating experiments, and most of the analytical techniques utilized would not have detected paternal mtDNA molecules in progeny at levels less than about 5%. Long-term mating experiments, in which a fertile female lineage derived from hybridization of two species with distinguishable mtDNAs is backcrossed recurrently to the male parental species, provide an ideal opportunity to assess possible low-level paternal leakage. We have analyzed the 45- and 91-generation backcross progeny of such matings between two species of lepidopteran insects [Heliothis (Noctuidae)], using autoradiographic techniques that can detect rare mtDNA molecules in less than 1 part per 500. The analysis failed to detect any paternal mtDNA and sets an upper limit of paternal leakage at about 1 molecule per 25,000 per generation in this system.

Published

1983

45. Maternal inheritance of mitochondrial DNA during backcrossing of two species of mice

Author

Allan C. Wilson, Dan Wharton, and Ulf Gyllensten

Subjects

Male, Mitochondrial DNA, Non-Mendelian inheritance, Mus spretus, animal diseases, Biology, medicine.disease_cause, Genome, DNA, Mitochondrial, chemistry.chemical_compound, Mice, Sex Factors, Paternal mtDNA transmission, Genetics, medicine, Animals, Molecular Biology, Genetics (clinical), Crosses, Genetic, Ovum, Cell Nucleus, Mutation, DNA, DNA Restriction Enzymes, biology.organism_classification, Spermatozoa, Mice, Inbred C57BL, Molecular Weight, Muridae, chemistry, Backcrossing, Female, Biotechnology

Abstract

As judged by restriction analysis, mitochondrial DNA shows strictly maternal inheritance during 6-8 generations of backcrossing in both directions between Mus domesticus and Mus spretus. The average number of paternal mitochondrial genomes contributed to the next generation is estimated to be no more than one per thousand maternal mitochondrial genomes contributed. Despite the estimated accumulation of over 2000 mutational differences between M. spretus and M. domesticus mtDNAs since their divergence from a common ancestor, each of these mitochondrial DNAs, whether on a M. spretus or a M. domesticus nuclear background, allows mice to develop with seemingly normal viability and fertility.

Published

1985

46. Male-dependent doubly uniparental inheritance of mitochondrial DNA and female-dependent sex-ratio in the mussel Mytilus galloprovincialis

Author

Carlos Saavedra, Eleftherios Zouros, and María-Isabel Reyero

Subjects

Male, Mitochondrial DNA, Non-Mendelian inheritance, Sex Determination Analysis, Disorders of Sex Development, Extrachromosomal Inheritance, Uniparental inheritance, Biology, Investigations, DNA, Mitochondrial, Paternal mtDNA transmission, Hermaphrodite, Species Specificity, Testis, Genetics, medicine, Animals, Disorders of sex development, Sex Ratio, Mitochondrial DNA inheritance, Models, Genetic, Ovary, medicine.disease, Spermatozoa, Bivalvia, Female, Sex ratio

Abstract

We have investigated sex ratio and mitochondrial DNA inheritance in pair-matings involving five female and five male individuals of the Mediterranean mussel Mytilus galloprovincialis. The percentage of male progeny varied widely among families and was found to be a characteristic of the female parent and independent of the male to which it was mated. Thus sex-ratio in Mytilus appears to be independent of the nuclear genotype of the sperm. With a few exceptions, doubly uniparental inheritance (DUI) of mtDNA was observed in all families fathered by four of the five males: female and male progeny contained the mother's mtDNA (the F genome), but males contained also the father's paternal mtDNA (the M genome). Two hermaphrodite individuals found among the progeny of these crosses contained the F mitochondrial genome in the female gonad and both the F and M genomes in the male gonad. All four families fathered by the fifth male showed the standard maternal inheritance (SMI) of animal mtDNA: both female and male progeny contained only the maternal mtDNA. These observations illustrate the intimate linkage between sex and mtDNA inheritance in species with DUI and suggest different major roles for each gender. We propose a model according to which development of a male gonad requires the presence in the early germ cells of an agent associated with sperm-derived mitochondria, these mitochondria are endowed with a paternally encoded replicative advantage through which they overcome their original minority in the fertilized egg and this advantage (and, therefore, the chance of an early entrance into the germ line) is countered by a maternally encoded egg factor.

47. [Untitled]

Subjects

Genetics, Mitochondrial DNA, Non-Mendelian inheritance, education.field_of_study, Haplotype, Population, Biology, Heteroplasmy, Natural population growth, Paternal mtDNA transmission, Genetic variation, education, Ecology, Evolution, Behavior and Systematics

Abstract

Strict maternal inheritance is considered a hallmark of animal mtDNA. Although recent reports suggest that paternal leakage occurs in a broad range of species, it is still considered an exceptionally rare event. To evaluate the impact of paternal leakage on the evolution of mtDNA, it is essential to reliably estimate the frequency of paternal leakage in natural populations. Using allele-specific real-time quantitative PCR (RT-qPCR), we show that heteroplasmy is common in natural populations with at least 14% of the individuals carrying multiple mitochondrial haplotypes. However, the average frequency of the minor mtDNA haplotype is low (0.8%), which suggests that this pervasive heteroplasmy has not been noticed before due to a lack of power in sequencing surveys. Based on the distribution of mtDNA haplotypes in the offspring of heteroplasmic mothers, we found no evidence for strong selection against one of the haplotypes. We estimated that the rate of paternal leakage is 6% and that at least 100 generations are required for complete sorting of mtDNA haplotypes. Despite the high proportion of heteroplasmic individuals in natural populations, we found no evidence for recombination between mtDNA molecules, suggesting that either recombination is rare or recombinant haplotypes are counter-selected. Our results indicate that evolutionary studies using mtDNA as a marker might be biased by paternal leakage in this species.

48. Maternal inheritance of mitochondrial DNA in sexual crosses of Pythium sylvaticumm

Author

Frank N. Martin

Subjects

Genetics, Mating type, Non-Mendelian inheritance, Mitochondrial DNA, education.field_of_study, Extranuclear inheritance, Population, General Medicine, Biology, biology.organism_classification, Paternal mtDNA transmission, Restriction fragment length polymorphism, Pythium sylvaticum, education

Abstract

Fifty single oospore progeny from crosses between opposite mating types of Pythium sylvaticum that contained polymorphisms in mitochondrial DNA (mtDNA) for HindIII restriction sites were analyzed for patterns of mitochondrial inheritance. All progeny retained the morphological form of the oogonial parental type; the antheridial form or recombinant forms of parental mtDNA were not detected. With the techniques used, other forms of mtDNA would have been detected it they had comprised 8% or more of the mitochondrial population.

Published

1989

49. Co-expressed mitochondrial genomes: recently masculinized, recombinant mitochondrial genome is co-expressed with the female – transmitted mtDNA genome in a male Mytilus trossulus mussel from the Baltic Sea

Author

Tomasz J. Sanko and Artur Burzyński

Subjects

Male, Non-Mendelian inheritance, Mitochondrial DNA, mtDNA inheritance, Population, DNA, Recombinant, Inheritance Patterns, Mitochondrion, Biology, DUI, Genome, DNA, Mitochondrial, Paternal mtDNA transmission, Genetics, Animals, Genomic library, EST, Genetics(clinical), Paternal Inheritance, education, Transcriptomics, Genetics (clinical), Gene Library, Doubly uniparental inheritance, Mytilus, education.field_of_study, Sequence Analysis, DNA, Genome, Mitochondrial, Female, Masculinization, Paternally inherited mtDNA, Research Article

Abstract

Background Few exceptions have been described from strict maternal inheritance of mitochondrial DNA in animals, including sea mussels (Mytilidae), clams (Donacidae, Veneridae and Solenidae) and freshwater mussels (Unionoidae) order. In these bivalves mitochondria and their DNA are transferred through two separate routes. The females inherit only the maternal mitochondrial DNA whereas the males inherit maternal as well as paternal mitochondrial DNA, which is usually present only in gonads and sperm. The mechanism controlling this phenomenon is unclear but leads to the existence of two separate mitochondrial DNA lineages in a single species. The lineages are usually well differentiated: up to 20-50% divergence in nucleotide sequence. Occasionally, a maternal mitochondrial DNA can invade the paternal transmission route, eventually replacing the diverged M-type and lowering the divergence. Such role reversal (masculinization) event has happened recently in the Mytilus population of the Baltic Sea which consists of M. edulis × M. trossulus hybrids, but the functional status of the resulting mitochondrial genome was unknown. Results In this paper we sequenced transcripts from one specimen that was identified as male carrying both the female mitochondrial genome and a recently masculinized mitochondrial genome. Additionally, the analysis of the control region has showed that the recently masculinized, recombinant genome, not only has an M-type control region and all coding regions derived from the F-type, but also is transcriptionally active along side the maternally inherited F-type genome. In the comparative analysis, the two genomes exhibit different substitution patterns, typical for the M vs. F genome comparisons. The genetic distances and ratios of non-synonymous substitutions also suggest that one of the genomes is transitioning from the maternal to the paternal inheritance mode, consistent with its recent masculinization. Conclusion We have shown, for the first time, that the recently masculinized mitochondrial genome is active and that it accumulates excess of non-synonymous substitutions across its coding sequence. This suggests, that, under certain cytonuclear incompatibility conditions, masculinization may serve to restore the endangered functionality of the paternally inherited genome. This is also another example of a mitochondrial genome in which the recombination in the control region predated its transition from paternal to maternal transmission route.