The Effects of Natural Hybridization on the Regulation of Doubly Uniparental Mtdna Inheritance in Blue Mussels (Mytilus Spp.)

Blue mussels in the Mytilus edulis species complex have a doubly uniparental mode of mtDNA inheritance with separate maternal and paternal mtDNA lineages. Female mussels inherit their mtDNA solely from their mother, while males inherit mtDNA from both parents. In the male gonad the paternal mtDNA is preferentially replicated so that only paternal mtDNA is transmitted from fathers to sons. Hybridization is common among differentiated blue mussel taxa; whenever it involves M. trossulus, doubly uniparental mtDNA inheritance is disrupted. We have found high frequencies of males without and females with paternal mtDNA among hybrid mussels produced by interspecific matings between M. galloprovincialis and M. trossulus. In contrast, hybridization between M. galloprovincialis and M. edulis does not affect doubly uniparental inheritance, indicating a difference in the divergence of the mechanisms regulating mtDNA inheritance among the three blue mussel taxa. Our data indicate a high frequency of disrupted mtDNA transmission in F(1) hybrids and suggest that two separate mechanisms, one regulating the transmission of paternal mtDNA to males and another inhibiting the establishment of paternal mtDNA in females, act to regulate doubly uniparental inheritance. We propose a model for the regulation of doubly uniparental inheritance that is consistent with these observations.     

Transmission of human mitochondrial DNA along the paternal lineage in transmitochondrial mice

Previously we obtained heteroplasmic mice carrying murine and human mitochondrial DNA (mtDNA). Even the fourth generation of such mice had human mtDNA in their organs, hence, they were used to study the possibility of paternal mtDNA transmission. A lineage was obtained in which human mtDNA was transmitted by males to the progeny in four successive generations. This is the first observation of such a continuous paternal transmission of mtDNA. Persistence of paternal mtDNA in several successive generations of animals suggests that mechanisms aimed at elimination of paternally inherited mtDNA species are not as strict as has been postulated.     

Evolutionary relationships among the male and female mitochondrial DNA lineages in the Mytilus edulis species complex

A novel form of mitochondrial DNA (mtDNA) inheritance has previously been documented for the blue mussel (Mytilus edulis). Female mussels inherit their mtDNA solely from their mother while males inherit mtDNA from both their mother and their father. In males, the paternal mtDNA is preferentially amplified so that the male gonad is highly enriched for the paternal mtDNA that is then transmitted from fathers to sons. We demonstrate that this mode of mtDNA inheritance also operates in the closely related species M. galloprovincialis and M. trossulus. The evolutionary relationship between the male and female mtDNA lineages is estimated by phylogenetic analysis of 455 nucleotides from the large subunit ribosomal RNA gene. We have found that the male and female lineages are highly divergent; the divergence of these lineages began prior to the speciation of the three species of blue mussels. Further, the separation between the male and female lineages is estimated to have occurred between 5.3 and 5.7 MYA.      

Dynamics of Cytoplasmic Incompatibility and Mtdna Variation in Natural Drosophila Simulans Populations

In Drosophila simulans a cytoplasmically transmitted microorganism causes reduced egg hatch when infected males mate with uninfected females. The infection is rapidly spreading northward in California. Data on a specific mtDNA restriction site length polymorphism show that changes in the frequency of mtDNA variants are associated with this spread. All infected flies possess the same mtDNA allele, whereas the uninfected flies are polymorphic. Given that both paternal inheritance of the infection and imperfect maternal transmission have been demonstrated, one might expect instead that both infected and uninfected flies would possess both mtDNA variants. Our data suggest that imperfect female transmission of the infection (and/or the loss of the infection among progeny) is more common in nature than paternal transmission. A simple model of intrapopulation dynamics, with empirically supported parameter values, adequately describes the joint frequencies of the mtDNA variants and incompatibility types.     

Gene conversion in the mitochondrial genome on interspecific hybridization in voles of the <Emphasis Type="Italic">Clethrionomys</Emphasis> genus

The phenomenon of interspecific hybridization accompanied by transfer of the mitochondrial genome from the northern red-backed vole (Clethrionomys rutilus) to the bank vole (Cl. glareolus) in northeastern Europe is well known already for 25 years. However, the possibility of recombination between homologous segments of maternal and paternal mtDNAs of the voles during fertilization was not previously studied. Analysis of data on variability of nucleotide sequences of the mitochondrial gene for cytochrome b in populations of red-backed and bank voles in the area of their sympatry has shown that as a result of interspecific hybridization, the mitochondrial gene pool of bank voles contains not only mtDNA haplotypes of red-backed vole females, but also mtDNA haplotypes of bank voles bearing short nucleotide tracts of red-backed vole mtDNA. This finding supports the hypothesis that an incomplete elimination of red-backed vole paternal mtDNA during the interspecific hybridization between bank vole females and red-backed vole males leads to the gene conversion of bank vole maternal mtDNA tracts by homologous ones of mtDNA of red-backed vole males.     

Differential segregation patterns of sperm mitochondria in embryos of the blue mussel (Mytilus edulis)

In Mytilus, females carry predominantly maternal mitochondrial DNA (mtDNA) but males carry maternal mtDNA in their somatic tissues and paternal mtDNA in their gonads. This phenomenon, known as doubly uniparental inheritance (DUI) of mtDNA, presents a major departure from the uniparental transmission of organelle genomes. Eggs of Mytilus edulis from females that produce exclusively daughters and from females that produce mostly sons were fertilized with sperm stained with MitoTracker Green FM, allowing observation of sperm mitochondria in the embryo by epifluorescent and confocal microscopy. In embryos from females that produce only daughters, sperm mitochondria are randomly dispersed among blastomeres. In embryos from females that produce mostly sons, sperm mitochondria tend to aggregate and end up in one blastomere in the two- and four-cell stages. We postulate that the aggregate eventually ends up in the first germ cells, thus accounting for the presence of paternal mtDNA in the male gonad. This is the first evidence for different behaviors of sperm mitochondria in developing embryos that may explain the tight linkage between gender and inheritance of paternal mitochondrial DNA in species with DUI.     

Fate of maternal mtDNA following 60Co inactivation of maternal nuclear DNA in unfertilized salmonid eggs.

The effects of gamma irradiation on nuclear DNA and mitochondrial DNA (mtDNA) were examined by exposing unfertilized salmonid eggs to a 60Co source. Brown trout (Salmo trutta) eggs exposed to 60Co were fertilized with sperm from brook trout (Salvelinus fontinalis), and brook trout eggs exposed to 60Co were fertilized with sperm from splake males (S. namaycush x S. fontinalis). In both types of matings only paternal allozymes were found in embryos, confirming the inactivation of the nuclear genome in the eggs. Analysis of mtDNA in these same embryos showed exclusively maternal mtDNA. The absence of paternal mtDNA among any of the embryos supports the predominance of maternal inheritance of mtDNA in vertebrates and suggests that mtDNAs are more resistant to cobalt inactivation than nuclear DNAs based on structure or numerical superiority to maternal nuclear DNA. Inactivation of maternal nuclear DNA, fertilization, and an induced return to the diploid state provide a means for producing an inbred organism having the nuclear genome of the paternal parent (androgenetic) and the mitochondrial genome of the female.     

Mitochondrial DNA variation in a species with two mitochondrial genomes: the case of Mytilus galloprovincialis from the Atlantic, the Mediterranean and the Black Sea

We have examined mitochondrial DNA (mtDNA) variation in samples of the mussel Mytilus galloprovincialis from the Black Sea, the Mediterranean and the Spanish Atlantic coast by scoring for presence or absence of cleavage at 20 restriction sites of a fragment of the COIII gene and at four restriction sites of the 16S RNA gene. This species contains two types of mtDNA genomes, one that is transmitted maternally (the F type) and one that is transmitted paternally (the M type). The M genome evolves at a higher rate than the F genome. Normally, females are homoplasmic for an F type and males are heteroplasmic for an F and an M type. Occasionally molecules from the F lineage invade the paternal transmission route, resulting in males that carry two F-type mtDNA genomes. These features of the mussel mtDNA system give rise to a new set of questions when using mtDNA variation in population studies and phylogeny. We show here that the two mtDNA types provide different information with regard to amounts of variation and genetic distances among populations. The F genome exhibits higher degrees of diversity within populations, while the M genome produces higher degrees of differentiation among populations. There is a strong differentiation between the Atlantic and the Black Sea. The Mediterranean samples have intermediate haplotype frequencies, yet are much closer to the Black Sea than to the Atlantic. We conclude that in this species gene flow among the three Seas is restricted and not enough to erase the combined effect of mutation and random drift. In one sample, that from the Black Sea, the majority of males did not contain an M mtDNA type. This suggests that a molecule of the maternal lineage has recently invaded the paternal route and has increased its frequency in the population to the point that the present pool of paternally transmitted mtDNA molecules is highly heterogeneous and cannot be used to read the population's history. This liability of the paternal route means that in species with doubly uniparental inheritance, the maternal lineage provides more reliable information for population and phylogenetic studies.     

Maternal inheritance of mouse mtDNA in interspecific hybrids: segregation of the leaked paternal mtDNA followed by the prevention of subsequent paternal leakage.

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 10(8)-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.     

Sex-Limited Mitochondrial DNA Transmission in the Marine Mussel Mytilus Edulis

Mitochondrial DNA (mtDNA) was thought to be inherited maternally in animals, although paternal leakage has been reported in mice and Drosophila. Recently, direct evidence of extensive paternal inheritance of mtDNA has been found in the marine mussel Mytilus. We give evidence that whereas female mussels are homoplasmic for a genome that is transmitted to eggs, male mussels are heteroplasmic for this genome and for a second genome that is transmitted preferentially to sperm. The results provide support for the existence of separate male and female routes of mtDNA inheritance in mussels. The two genomes show a base sequence divergence exceeding 20% at three protein coding genes, consistent with long term maintenance of the heteroplasmic state. We propose that the two genomes differ in fitness in males and females, possibly as a result of interaction with nuclear genes.     

Paternal leakage of mitochondrial DNA in experimental crosses of populations of the potato cyst nematode Globodera pallida

Animal mtDNA is typically assumed to be maternally inherited. Paternal mtDNA has been shown to be excluded from entering the egg or eliminated post-fertilization in several animals. However, in the contact zones of hybridizing species and populations, the reproductive barriers between hybridizing organisms may not be as efficient at preventing paternal mtDNA inheritance, resulting in paternal leakage. We assessed paternal mtDNA leakage in experimental crosses of populations of a cyst-forming nematode, Globodera pallida. A UK population, Lindley, was crossed with two South American populations, P5A and P4A. Hybridization of these populations was supported by evidence of nuclear DNA from both the maternal and paternal populations in the progeny. To assess paternal mtDNA leakage, a ~3.4?kb non-coding mtDNA region was analyzed in the parental populations and in the progeny. Paternal mtDNA was evident in the progeny of both crosses involving populations P5A and P4A. Further, paternal mtDNA replaced the maternal mtDNA in 22 and 40?% of the hybrid cysts from these crosses, respectively. These results indicate that under appropriate conditions, paternal leakage occurs in the mtDNA of parasitic nematodes, and supports the hypothesis that hybrid zones facilitate paternal leakage. Thus, assumptions of strictly maternal mtDNA inheritance may be frequently violated, particularly when divergent populations interbreed.     

Lost in the zygote: the dilution of paternal mtDNA upon fertilization

The mechanisms by which paternal inheritance of mitochondrial DNA (mtDNA) (paternal leakage) and, subsequently, recombination of mtDNA are prevented vary in a species-specific manner with one mechanism in common: paternally derived mtDNA is assumed to be vastly outnumbered by maternal mtDNA in the zygote. To date, this dilution effect has only been described for two mammalian species, human and mouse. Here, we estimate the mtDNA content of chinook salmon oocytes to evaluate the dilution effect operating in another vertebrate; the first such study outside a mammalian system. Employing real-time PCR, we determined the mtDNA content of chinook salmon oocytes to be 3.2 x 10(9)+/-1.0 x 10(9), and recently, we determined the mtDNA content of chinook salmon sperm to be 5.73+/-2.28 per gamete. Accordingly, the ratio of paternal-to-maternal mtDNA if paternal leakage occurs is estimated to be 1:5.5 x 10(8). This contribution of paternal mtDNA to the overall mtDNA pool in salmon zygotes is three to five orders of magnitude smaller than those revealed for the mammalian system, strongly suggesting that paternal inheritance of mtDNA per offspring will be much less likely in this system than in mammals.     

Male Transmission of Linear Plasmids and Mitochondrial DNA in the Fungus Neurospora

One of the general rules of heredity is that in anisogamous matings genetic elements in organelles are inherited maternally. Nevertheless, there are cases of paternal transmission, both as rare exceptions, and as regular modes of inheritance. We report two new cases of paternal transmission in crosses of the model fungus Neurospora. First, we show leakage of a linear plasmid from males, the first case in fungi and the second in eukaryotes. Transmission frequencies ranged from 1% to 15% in different crosses, but some crosses showed no detectable male transmission. Second, we show leakage of male mitochondrial DNA (mtDNA), the second case in fungi. Some of the resulting progeny have only the male mtDNA type, but some are heteroplasmons. Heteroplasmons show novel restriction fragments attributable to recombination or rearrangement. Heteroplasmy of mtDNA through male transmission has not been reported previously in any eukaryote. In addition we have shown paternal leakage of circular mitochondrial plasmids, supporting another reported case. In a male bearing a linear and a circular plasmid, these plasmids and the mtDNA are transmitted in different combinations. These results show a potential for mitochondrial segregation and assortment during the sexual cycle in anisogamous fungi, pointing to more potential avenues for novel associations between genomic compartments, and between genomic and extragenomic elements.     

Extreme-Depth Re-sequencing of Mitochondrial DNA Finds No Evidence of Paternal Transmission in Humans

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.     

Different degree of paternal mtDNA leakage between male and female progeny in interspecific Drosophila crosses

Maternal transmission of mitochondrial DNA (mtDNA) in animals is thought to prevent the spread of selfish deleterious mtDNA mutations in the population. Various mechanisms have been evolved independently to prevent the entry of sperm mitochondria in the embryo. However, the increasing number of instances of paternal mtDNA leakage suggests that these mechanisms are not very effective. The destruction of sperm mitochondria in mammalian embryos is mediated by nuclear factors. Also, the destruction of paternal mitochondria in intraspecific crosses is more effective than in interspecific ones. These observations have led to the hypothesis that leakage of paternal mtDNA (and consequently mtDNA recombination owing to ensuing heteroplasmy) might be more common in inter‐ than in intraspecific crosses and that it should increase with phylogenetic distance of hybridizing species. We checked paternal leakage in inter‐ and intraspecific crosses in Drosophila and found little evidence for this hypothesis. In addition, we have observed a higher level of leakage among male than among female progeny from the same cross. This is the first report of sex‐specific leakage of paternal mtDNA. It suggests that paternal mtDNA leakage might not be a stochastic result of an error‐prone mechanism, but rather, it may be under complex genetic control.     

Extensive paternal mtDNA leakage in natural populations of Drosophila melanogaster

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.     

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

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.     

No evidence for presence of maternal mitochondrial DNA in the sperm of Mytilus galloprovincialis males

Species of the mussel family Mytilidae have a special mitochondrial DNA (mtDNA) transmission system, known as doubly uniparental inheritance (DUI), which consists of a maternally inherited (F) and a paternally inherited (M) mitochondrial genome. Females are normally homoplasmic for the F genome and males are heteroplasmic mosaics, with their somatic tissues dominated by the maternal and their gonads dominated by the paternal genome. Several studies have indicated that the maternal genome may often be present in the male germ line. Here we report the results from the examination of mtDNA in pure sperm from more than 30 males of Mytilus galloprovincialis. In all cases, except one, we detected only the M genome. In the sperm of one male, we detected a paternal genome with an F-like primary sequence that was different from the sequence of the maternal genome in the animal's somatic tissues. We conclude that the male germ line is protected against invasion by the maternal genome. This is important because fidelity of gamete-specific transmission of the two mitochondrial genomes is a basic requirement for the stability of DUI.     

Analysis of paternal transmission of mitochondrial DNA in Drosophila

It has previously been shown that paternal mitochondrial DNA (mtDNA) can be detected in later generations in Drosophila. To further analyze the paternal transmission of mtDNA, the progeny of two intraspecific and three interspecific crosses were examined in the frequency of the paternal transmission of mtDNA, using closely related species of the melanogaster species subgroup. Types of mtDNA in the progeny of the individual backcrosses of F(1) females were analyzed by selective amplification of paternal mtDNA. More than 100 F(1) females were examined for each backcross. The same type of mtDNA as that of the paternal mtDNA was detected in approximately 20-60% of the backcrosses. The present results indicate that paternal leakage occurs in the intraspecific crosses as well as in the interspecific crosses in Drosophila.     

New patterns of inheritance in mitochondrial disease

With the identification of a patient with mutated mitochondrial DNA (mtDNA) of paternal origin, it has been unequivocally proven that not only does paternal mtDNA survive in the zygote, but it can also contribute substantially to the mtDNA pool of adult, human skeletal muscle. The questions are: how often does paternal mtDNA inheritance occur and what mechanisms are involved? In this paper, we will review current knowledge on the fate of sperm mitochondria after fertilization and discuss the impact paternal inheritance may have on our understanding of mitochondrial biology.