The sperm mitochondria-specific translocator has a key role in maternal mitochondrial inheritance

The mechanism of maternal mitochondrial inheritance in animals involves the selective elimination of sperm mitochondria by the elimination factor of the egg and the sperm mitochondria-specific factor. In vitro fertilization using sperm from isogenic mice incorporating heterospecific mitochondrial DNA (mtDNA) showed that the number of PCR positives of sperm mtDNA in two-cell embryos was significantly increased following sperm incubation with anti-tetratricopeptide repeat-containing protein involved in spermatogenesis (tpis) protein, anti-translocator of mitochondrial outer membrane (Tom) 22 and anti-Tom40 antibodies. The treatment of fertilized eggs with EGTA and other endonuclease inhibitors increased the sperm mtDNA levels. We conclude that the elimination factor, which is probably an endonuclease, is selectively received by the tpis protein of the sperm mitochondrial outer membrane within the egg. It is then transported into the sperm mitochondria by Tom22 and Tom40, where it destroys the sperm mtDNA, establishing the maternal inheritance of mtDNA.     

Hybrid male sterility is caused by mitochondrial DNA deletion

Although it is known that the hybrid male mouse is sterile just like any other animal’s heterogametic sex, the reason why only the male germ cells are impaired has yet to be discovered. TdT-mediated dUTP nick end labeling assay using a confocal fluorescence microscope and DNA fragmentation assay of hybrid testis indicated destruction of the mitochondrial DNA (mtDNA) rather than the nuclear DNA. Previously we reported that maternal mtDNA inheritance is through selective sperm mtDNA elimination based on the sperm factor and two egg factors, and expression of these three factors was recognized in the hybrid testis. It was thereby assumed that mtDNA destruction caused by the expression of maternal mtDNA inheritance system in male germ cells is implicated in the hybrid male sterility of mice.     

Doubly uniparental inheritance of mitochondrial DNA: Might it be simpler than we thought?

More than 100 species of bivalve mollusks are currently known to carry two highly diverged mitochondrial DNA (mtDNA) molecules, one of which is transmitted through the egg and the other through the sperm generation after generation, faithfully and uninterruptedly. This mtDNA system, which has become known as doubly uniparental inheritance (DUI), is most likely unique in eukaryotes and constitutes a striking deviation from the strictly maternal inheritance (SMI) of mtDNA that is the rule in the animal kingdom. Here, I present a model of how the paternal mtDNA may escape the mitochondrial destruction that occurs prior to sperm formation and enter the male germ line in the newly formed embryo. In essence, the model treats the sperm-transmitted mtDNA as a molecule that takes a ride with the sperm. The model can be easily tested and, if passed the tests, may open the way for the understanding of DUI at the molecular level and throw light on the mechanisms and evolution of mtDNA transmission in general. In addition, the model shifts attention from nuclear control of paternal mtDNA inheritance, whether systematic (as DUI) or leaky (as the cases reported in a wide variety of animal species), to the mtDNA itself as the protagonist of its own transmission. This possibility has been, so far, ignored in studies of paternal mtDNA transmission in other species including humans.     

Autophagy is not involved in the degradation of sperm mitochondria after fertilization in mice

In almost all animals, mitochondrial DNA (mtDNA) is transmitted only from the female, while the paternal mitochondria and mtDNA are thought to be eliminated during early embryogenesis. Autophagy is involved in the elimination of sperm mitochondria and mtDNA in early embryos in Caenorhabditis elegans; however, solid evidence is still lacking in mammals. Recently, we found that despite the fact that some autophagy-related proteins, such as SQSTM1 and LC3 could localize nearby sperm mitochondria before the 2-cell stage, autophagy did not participate in the elimination of sperm mitochondria and mtDNA. Instead, the pre-elimination of sperm mtDNA before fertilization and the restriction of sperm mitochondria in one blastomere before 4-cell stage embryos are the most important mechanisms of maternal mitochondrial inheritance in mice.     

Maternal inheritance of mitochondrial DNA

Maternal inheritance of mitochondrial DNA (mtDNA) is generally observed in many eukaryotes. Sperm-derived paternal mitochondria and their mtDNA enter the oocyte cytoplasm upon fertilization and then normally disappear during early embryogenesis. However, the mechanism underlying this clearance of paternal mitochondria has remained largely unknown. Recently, we showed that autophagy is required for the elimination of paternal mitochondria in Caenorhabditis elegans embryos. Shortly after fertilization, autophagosomes are induced locally around the penetrated sperm components. These autophagosomes engulf paternal mitochondria, resulting in their lysosomal degradation during early embryogenesis. In autophagy-defective zygotes, paternal mitochondria and their genomes remain even in the larval stage. Therefore, maternal inheritance of mtDNA is accomplished by autophagic degradation of paternal mitochondria. We also found that another kind of sperm-derived structure, called the membranous organelle, is degraded by zygotic autophagy as well. We thus propose to term this allogeneic (nonself) organelle autophagy as allophagy.     

Mitochondrial haplotype does not affect sperm velocity in the zebra finch Taeniopygia guttata

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.     

Mitochondrial DNA copy number is maintained during spermatogenesis and in the development of male larvae to sustain the doubly uniparental inheritance of mitochondrial DNA system in the blue mussel Mytilus galloprovincialis

Doubly uniparental inheritance (DUI) of mitochondrial (mt) DNA has been reported in the blue mussel Mytilus galloprovincialis. In DUI, males inherit both paternal (M type) and maternal (F type) mtDNA. Here we investigated changes in M type mtDNA copy numbers and mitochondrial mass in testicular cells by real‐time polymerase chain reaction and flow cytometry. The ratios of M type mtDNA copy numbers to nuclear DNA content were not different between haploid (1n), diploid (2n) and tetraploid (4n) spermatogenic cells. The mitochondrial mass decreased gradually during spermatogenesis. These results suggest that mtDNA and mitochondrial mass are maintained during spermatogenesis. We then traced M type mtDNA in larvae after fertilization. M type mtDNA was maintained up to 24 h after fertilization in the male‐biased crosses, but decreased significantly in female‐biased crosses (predicted by Mito Tracker staining pattern). These results are strikingly different from those reported for mammals and fish, where it is well known that the mitochondria and mtDNA are reduced during spermatogenesis and that sperm mitochondria and mtDNA are eliminated soon after fertilization. Thus, the M type mtDNA copy number is maintained during spermatogenesis and in the development of male larvae to sustain the DUI system in the blue mussel.     

Paternal mitochondrial DNA transmission during nonhuman primate nuclear transfer

Offspring produced by nuclear transfer (NT) have identical nuclear DNA (nDNA). However, mitochondrial DNA (mtDNA) inheritance could vary considerably. In sheep, homoplasmy is maintained since mtDNA is transmitted from the oocyte (recipient) only. In contrast, cattle are heteroplasmic, harboring a predominance of recipient mtDNA along with varying levels of donor mtDNA. We show that the two nonhuman primate Macaca mulatta offspring born by NT have mtDNA from three sources: (1) maternal mtDNA from the recipient egg, (2) maternal mtDNA from the egg contributing to the donor blastomere, and (3) paternal mtDNA from the sperm that fertilized the egg from which the donor blastomere was isolated. The introduction of foreign mtDNA into reconstructed recipient eggs has also been demonstrated in mice through pronuclear injection and in humans through cytoplasmic transfer. The mitochondrial triplasmy following M. mulatta NT reported here forces concerns regarding the parental origins of mtDNA in clinically reconstructed eggs. In addition, mtDNA heteroplasmy might result in the embryonic stem cell lines generated for experimental and therapeutic purposes ("therapeutic cloning").     

Embryo quality,and not chromosome nondiploidy,affects mitochondrial DNA content in mouse blastocysts

It has been shown recently that there is premature mitochondria biosynthesis in blastocysts from older women whose egg or embryo quality is poor and that aneuploid blastocysts also have a high number of mitochondrial DNA (mtDNA) copies. Whether nondiploidy/aneuploidy or reduced egg or embryo quality causes premature mitochondrial biosynthesis is not known. This study constructed haploid, diploid, triploid, and tetraploid blastocysts by parthenogenetic activation, intracytoplasmic sperm injection with one or two sperm heads, blastomere electrofusion, respectively, and generated reduced cytoplasm quality embryos from diabetic mouse and in vitro fertilization of aged oocytes, and examined whether nondiploidy or reduced cytoplasm quality causes premature mitochondrial biosynthesis. MtDNA numbers of each blastocyst from different models were tested by absolute quantitative real-time polymerase chain reaction. It was found that mtDNA content in preimplantation embryos was not associated with their chromosome ploidy, while mtDNA copy numbers in embryos with suboptimal quality were increased. Therefore, it might be the reduced cytoplasmic quality, and not chromosome nondiploidy, that causes premature mitochondria biosynthesis in blastocysts.     

Sperm Mitochondria in Reproduction： Good or Bad and Where Do They Go？

The mitochondrion is the major energy provider to power sperm motility. In mammals, aside from the nuclear genome, mitochondrial DNA （mtDNA） also contributes to oxidative phosphorylation to impact production of ATP by coding 13 polypeptides. However, the role of sperm mitochondria in fertilization and its final fate after fertilization are still controversial. The viewpoints that sperm bearing more mtDNA will have a better fertilizing capability and that sperm mtDNA is actively eliminated during early embryogenesis are widely accepted. However, this may be not true for several mammalian species, including mice and humans. Here, we review the sperm mitochondria and their mtDNA in sperm functions, and the mechanisms of maternal mitochondrial inheritance in mammals.     

Male-Dependent Doubly Uniparental Inheritance of Mitochondrial DNA and Female-Dependent Sex-Ratio in the Mussel Mytilus Galloprovincialis

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.     

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.     

Sperm mitochondrial DNA transmission to both male and female offspring in the blue mussel Mytilus galloprovincialis

In Mytilus mussels, paternal mitochondrial DNA (M type) from sperm is known to be transmitted to offspring. This phenomenon is called doubly uniparental inheritance (DUI). Under DUI, it has been reported that female mussels generally have only maternal mtDNA (F type). In this study, we examined the mode of mtDNA transmission in Mytilus galloprovincialis using M and F type-specific primer sets. The ratio of M and F types were measured in each sample by SNaPshot. The M type was detected in the adductor muscle and female gonad of all females. In unfertilized eggs spawned by 84.6% of females (22/26), M type was also detected. The F type was more abundant than the M type in all females. Although the ratio of M type in females was very low, all females contained the M type. From these results, we propose a new possibility about DUI inheritance. The presence of M type in unfertilized eggs indicates that the M type of eggs may also contribute to M type inheritance.     

Cytonuclear coadaptation in Drosophila: disruption of cytochrome c oxidase activity in backcross genotypes

Abstract The cytochrome c oxidase enzyme (COX) is comprised of 10 nuclear-encoded subunits and three mito-chondrial-encoded subunits in close physical association in the inner mitochondrial membrane. COX passes electrons from cytochrome c to molecular oxygen and pumps protons into the inner mitochondrial space for ATP production. Selection on nuclear-mitochondrial interactions within species should lead to coadaptation of the proteins comprising this important enzyme. Under this model, there should be relatively little disruption of COX activity when mitochondrial genomes are crossed among strains within species. A more pronounced disruption of activity is expected when the mitochondrial genome is expressed in the nuclear background of a different species. We test these hypotheses in Drosophila using hybridization and backcrossing among lines of D. simulans and D. mauritiana. Disrupted cytonuclear genotypes were constructed using backcrosses between two lines of D. simulans (siI and si II ) that introduced each divergent mitochondrial DNA (mtDNA) into each nuclear background due to maternal inheritance of mtDNA. Similar crosses were used to introduce eachD. simulans mtDNA into the D. mauritiana maI nuclear background. Reconstituted cytonuclear control genotypes were constructed by backcrossing the initial F1 females to males of the maternal genotype. COX enzyme activities were compared among these disrupted and reconstituted backcross genotypes within and between species. The disruption effect on COX activity was restricted to males of interspecific genotypes. These data support the coadaptation hypothesis and are consistent with predictions that the evolution of modifiers of male mitochondrial dysfunction is hindered by the maternal inheritance of mtDNA. New sequence data for nuclear encoded subunits of COX identified amino acids that may play a role in the disruption effect.     

Biparental mitochondrial DNA inheritance in the parasitic trematode Schistosoma mansoni

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.     

Mitochondrial DNA recombination in a free-ranging Australian lizard

Mitochondrial DNA (mtDNA) is the traditional workhorse for reconstructing evolutionary events. The frequent use of mtDNA in such analyses derives from the apparent simplicity of its inheritance: maternal and lacking bi-parental recombination. However, in hybrid zones, the reproductive barriers are often not completely developed, resulting in the breakdown of male mitochondrial elimination mechanisms, leading to leakage of paternal mitochondria and transient heteroplasmy, resulting in an increased possibility of recombination. Despite the widespread occurrence of heteroplasmy and the presence of the molecular machinery necessary for recombination, we know of no documented example of recombination of mtDNA in any terrestrial wild vertebrate population. By sequencing the entire mitochondrial genome (16761bp), we present evidence for mitochondrial recombination in the hybrid zone of two mitochondrial haplotypes in the Australian frillneck lizard (Chlamydosaurus kingii).     

The exceptional mitochondrial DNA system of the mussel family Mytilidae

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.     

What cost mitochondria? The maintenance of functional mitochondrial DNA within and across generations

The peculiar biology of mitochondrial DNA (mtDNA) potentially has detrimental consequences for organismal health and lifespan. Typically, eukaryotic cells contain multiple mitochondria, each with multiple mtDNA genomes. The high copy number of mtDNA implies that selection on mtDNA functionality is relaxed. Furthermore, because mtDNA replication is not strictly regulated, within-cell selection may favour mtDNA variants with a replication advantage, but a deleterious effect on cell fitness. The opportunities for selfish mtDNA mutations to spread are restricted by various organism-level adaptations, such as uniparental transmission, germline mtDNA bottlenecks, germline selection and, during somatic growth, regular alternation between fusion and fission of mitochondria. These mechanisms are all hypothesized to maintain functional mtDNA. However, the strength of selection for maintenance of functional mtDNA progressively declines with age, resulting in age-related diseases. Furthermore, organismal adaptations that most probably evolved to restrict the opportunities for selfish mtDNA create secondary problems. Owing to predominantly maternal mtDNA transmission, recombination among mtDNA from different individuals is highly restricted or absent, reducing the scope for repair. Moreover, maternal inheritance precludes selection against mtDNA variants with male-specific effects. We finish by discussing the consequences of life-history differences among taxa with respect to mtDNA evolution and make a case for the use of microorganisms to experimentally manipulate levels of selection.     

Elimination of paternal mitochondria through the lysosomal degradation pathway in C. elegans

In mammals, the inheritance of mitochondrion and its DNA (mtDNA) is strictly maternal, despite the fact that a sperm can inject up to 100 functional mitochondria into the oocyte during fertilization. The mechanisms responsible for the elimination of the paternal mitochondria remain largely unknown. We report here that this paternal mitochondrial elimination process is conserved in Caenorhabditis elegans, and that the lysosomal pathway actively participates in this process. Molecular and cell biological analyses indicate that in wild-type animals paternal mitochondria and mtDNA are destroyed within two hours after fertilization. In animals with compromised lysosomes, paternal mitochondria persist until late embryonic stages. Therefore, the lysosomal pathway plays an important role in degrading paternal mitochondria introduced into the oocyte during fertilization. Our study indicates that C. elegans is an excellent animal model for understanding and dissecting this conserved biological process critical for animal development and reproduction.     

Complete elimination of maternal mitochondrial DNA during meiosis resulting in the paternal inheritance of the mitochondrial genome in Chlamydomonas species

Summary. The non-Mendelian inheritance of organellar DNA is common in most plants and animals. In the isogamous green alga Chlamydomonas species, progeny inherit chloroplast genes from the maternal parent, as paternal chloroplast genes are selectively eliminated in young zygotes. Mitochondrial genes are inherited from the paternal parent. Analogically, maternal mitochondrial DNA (mtDNA) is thought to be selectively eliminated. Nevertheless, it is unclear when this selective elimination occurs. Here, we examined the behaviors of maternal and paternal mtDNAs by various methods during the period between the beginning of zygote formation and zoospore formation. First, we observed the behavior of the organelle nucleoids of living cells by specifically staining DNA with the fluorochrome SYBR Green I and staining mitochondria with 3,3′-dihexyloxacarbocyanine iodide. We also examined the fate of mtDNA of male and female parental origin by real-time PCR, nested PCR with single zygotes, and fluorescence in situ hybridization analysis. The mtDNA of maternal origin was completely eliminated before the first cell nuclear division, probably just before mtDNA synthesis, during meiosis. Therefore, the progeny inherit the remaining paternal mtDNA. We suggest that the complete elimination of maternal mtDNA during meiosis is the primary cause of paternal mitochondrial inheritance. Correspondence and reprints: Laboratory of Cell and Functional Biology, Faculty of Science, University of the Ryukyus, Nishihara, Okinawa 901-0213, Japan.