Evidence of doubly uniparental inheritance of the mitochondrial DNA in Polititapes rhomboides (Bivalvia,Veneridae): Evolutionary and population genetic analysis of F and M mitotypes

Doubly uniparental inheritance (DUI) is a particular mitochondrial DNA inheritance mode reported in a number of bivalves. DUI species show two types of mtDNA, one transmitted from females to daughters and sons (F mitotype) and another one from males to sons (M mitotype). In Veneridae, the existence of DUI has been investigated in several species but it was found in only two of them. In this study, we obtained partial sequences of rrnL, cytb and cox1 genes of males and females of Polititapes rhomboides from NW Spain and we demonstrated the existence of heteroplasmy in males, as expected under DUI. F and M mitotypes showed a taxon-specific phylogenetic pattern and similar evolutionary rates. We focused on cox1 for population genetic analysis, examining separately F and M mitotypes, but also F mitotypes from females (F_♀) and males (F_♂). In all cases, cox1 bears signs of strong purifying selection, with no apparent evidence of relaxed selection in the M genome, while the divergence between F and M genomes is in agreement with the neutral model of evolution. The cox1 polymorphism, higher at the M than at the F genome, also shows clear footprints of genetic hitchhiking with favourable mutations at other mtDNA loci, except for F_♂. In terms of population structure, results suggest that the pattern depends on the examined mitotype (F, F_♀, F_♂ or M).     

MULTIPLE ORIGINS OF GENDER-ASSOCIATED MITOCHONDRIAL DNA LINEAGES IN BIVALVES (MOLLUSCA: BIVALVIA)

Previous studies have shown that marine mussels (genus Mytilus) and a freshwater mussel (Pyganodon grandis) contain two distinct gender-associated mitotypes, which is a characteristic feature of the phenomenon of doubly uniparental inheritance (DUI) of mitochondrial DNA (mtDNA). Here we present evidence for the presence of distinct male (M) and female (F) mitotypes in three other bivalve species, the mytilid Geukensia demissa, and the unionid species P. fragilis and Fusconaia flava. Nucleotide sequences of a segment of the COI gene from the M and F mitotypes from each of the three mytilid species (M. edulis, M. trossulus, G. demissa) and three unionid species (P. grandis, P. fragilis, F. flava) were used for phylogenetic analysis. The analysis suggests three independent origins of M and F mitotypes for the six species examined; one for the three unionid species, one for the two Mytilus species, and one for Geukensia. The first of these F/M divergence events, while of uncertain age, predates the divergence of the two unionid genera and is likely older than either of the two F/M divergence events in the mytilid taxa. The most parsimonious explanation of multiple F/M divergence events is that they represent independent origins of DUI. Another possibility is that, in a given taxon, an F or M mitotype assumes the role of the opposite mitotype (by virtue of a mechanism that remains to be clarified) and subsequently was fixed within its new gender. The fixation of a mtDNA lineage derived from a mitotype of switched function would reset the divergence of the gender-associated lineages to zero, thereby mimicking a de novo split of F and M lineages from a preexisting mtDNA genome that was not gender specific. Further broad-scale taxonomic studies of the occurrence of distinct M and F mitotypes may allow for the evaluation of the latter hypothesis.     

High fidelity of mitochondrial genome transmission under the doubly uniparental mode of inheritance in freshwater mussels (Bivalvia: Unionoidea)

Abstract.— Doubly uniparental inheritance (DUI) of mitochondrial DNA (mtDNA) has been demonstrated in both mytilid and unionid bivalves. Under DUI, females pass on their mtDNA to both sons and daughters, whereas males pass on their mtDNA to only sons. In mytilids, the loss of an original male (or M) mitotype, with its subsequent replacement by that lineage's female (or F) mitotype, has been called a role-reversal or, more specifically, a masculinization event. Multiple masculinization events have been inferred during the evolutionary history of mytilids but not unionids. The perceived lack of role-reversal events in unionids may represent a significant difference in the evolutionary dynamics of DUI between the two bivalve taxa or simply a lack of sufficient taxon sampling in unionids. To evaluate these alternative hypotheses, six additional unionoidean bivalve genera were sampled for DUI including one genus from the sister taxon of the Unionidae, the Hyriidae. Phylogenetic analyses of 619 base pairs of cytochrome c oxidase I (COI) from eight genera (nine species) of unionoidean bivalves, plus the sister taxon to the Unionoida, Neotrigonia , revealed that the M and F unionoidean mitotypes were contained in gender-specific, topologically congruent clades. This supports the hypothesis that either role-reversal events do not occur in unionoideans or, if they do occur, their products are ephemeral in an evolutionary sense. Furthermore, the fact that the mantle-tissue-derived Neotrigonia mitotype is the sister mitotype to the unionoidean F mitotype clade suggests that DUI has been operating with high fidelity in unionoids for at least 200 million years. A relatively low incidence of interspecific hybridization in unionoideans and a possibly obligate role for the M mitotype in unionoidean gender determination are offered as potential explanations for the disparate evolutionary dynamics of DUI observed between mytilid and unionoidean bivalves.     

Phylogenetic evidence for role-reversals of gender-associated mitochondrial DNA in Mytilus (Bivalvia: Mytilidae)

Distinct gender-associated mitochondrial DNA (mtDNA) lineages (i.e., lineages which are transmitted either through males or through females) have been demonstrated in two families of bivalves, the Mytilidae (marine mussels) and the Unionidae (freshwater mussels), which have been separated for more than 400 Myr. The mode of transmission of these M (for male-transmitted) and F (for female-transmitted) molecules has been referred to as doubly uniparental inheritance (DUI), in contrast to standard maternal inheritance (SMI), which is the norm in animals. A previous study suggested that at least three origins of DUI are required to explain the phylogenetic pattern of M and F lineages in freshwater and marine mussels. Here we present phylogenetic evidence based on partial sequences of the cytochrome c oxidase subunit I gene and the 16S RNA gene that indicates the DUI is a dynamic phenomenon. Specifically, we demonstrate that F lineages in three species of Mytilus mussels, M. edulis, M. trossulus, and M. californianus, have spawned separate lineages which are now associated only with males. This process is referred to as "masculinization" of F mtDNA. By extension, we propose that DUI may be a primitive bivalve character and that periodic masculinization events combined with extinction of previously existing M types effectively reset the time of divergence between conspecific gender-associated mtDNA lineages.      

The Complete Female- and Male-Transmitted Mitochondrial Genome of Meretrix lamarckii

Bivalve mitochondrial genomes show many uncommon features, like additional genes, high rates of gene rearrangement, high A-T content. Moreover, Doubly Uniparental Inheritance (DUI) is a distinctive inheritance mechanism allowing some bivalves to maintain and transmit two separate sex-linked mitochondrial genomes. Many bivalve mitochondrial features, such as gene extensions or additional ORFs, have been proposed to be related to DUI but, up to now, this topic is far from being understood. Several species are known to show this unusual organelle inheritance but, being widespread only among Unionidae and Mytilidae, DUI distribution is unclear. We sequenced and characterized the complete female- (F) and male-transmitted (M) mitochondrial genomes of Meretrix lamarckii, which, in fact, is the second species of the family Veneridae where DUI has been demonstrated so far. The two mitochondrial genomes are comparable in length and show roughly the same gene content and order, except for three additional tRNAs found in the M one. The two sex-linked genomes show an average nucleotide divergence of 16%. A 100-aminoacid insertion in M. lamarckii M-cox2 gene was found; moreover, additional ORFs have been found in both F and M Long Unassigned Regions of M. lamarckii. Even if no direct involvement in DUI process has been demonstrated so far, the finding of cox2 insertions and supernumerary ORFs in M. lamarckii both strengthens this hypothesis and widens the taxonomical distribution of such unusual features. Finally, the analysis of inter-sex genetic variability shows that DUI species form two separate clusters, namely Unionidae and Mytilidae+Veneridae; this dichotomy is probably due to different DUI regimes acting on separate taxa.     

Additional taxonomic coverage of the doubly uniparental inheritance in bivalves: Evidence of sex-linked heteroplasmy in the razor clam Solen marginatus Pulteney, 1799, but not in the lagoon cockle Cerastoderma glaucum (Bruguière, 1789)

In animals, doubly uniparental inheritance (DUI) is a major exception to the common strict maternal inheritance of mitochondria. To date, DUI has only been found in many bivalve species, but its distribution is still unclear. Given the great species richness of the class, much effort is needed to further investigate the occurrence of DUI in unsampled species. A compelling evidence of DUI is generally the presence of a sex-linked heteroplasmy, where two divergent mitochondrial lineages are found: One is isolated from the male germline, and the other one is isolated from the female germline and, normally, from the soma of both sexes. In the present study, we investigated the sex-linked heteroplasmy in the razor clam Solen marginatus Pulteney, 1799 and in the lagoon cockle Cerastoderma glaucum (Bruguière, 1789) using two mitochondrial markers (cox1 and rrnL). We found evidence of DUI in the species S. marginatus, with a divergence up to 21% for the rrnL gene, but not in C. glaucum. Moreover, our phylogenetic reconstruction includes all the available data for heterodont species with sex-linked heteroplasmy and suggests multiple origins of DUI in this subclass, as well as the presence of DUI in other species of the genus Solen.     

Comparative analysis of gender-associated complete mitochondrial genomes in marine mussels (Mytilus spp.)

Marine mussels of the genus Mytilus have an unusual mode of mitochondrial DNA (mtDNA) transmission termed doubly uniparental inheritance (DUI). Female mussels are homoplasmic for the F mitotype, which is inherited maternally, while males are usually heteroplasmic, carrying a mixture of the maternal F mitotype and the paternally inherited M genome. Two classes of M genomes have been observed: "standard" M genomes and "recently masculinized" M genomes. The latter are more similar to F genomes at the sequence level but are transmitted paternally like standard M genomes. In this study we report the complete sequences of two standard male M. edulis and one recently masculinized male M. trossulus mitochondrial genome. A comparative analysis, including the previously sequenced M. edulis F and M. galloprovincialis F and M mtDNAs, reveals that these genomes are identical in gene order, but highly divergent in nucleotide and amino acid sequence. The large amount (>20%) of nucleotide substitutions that fall in coding regions implies that there are several amino acid replacements between the F and M genomes, which likely have an impact on the structural and functional properties of the mitochondrial proteome. Correlation of the divergence rate of different protein-coding genes indicates that mtDNA-encoded proteins of the M genome are still under selective constraints, although less highly than genes of the F genome. The mosaic F/M control region of the masculinized F genome provides evidence for lineage-specific sequences that may be responsible for the different mode of transmission genetics. This analysis shows the value of comparative genomics to better understand the mechanisms of maintenance and segregation of mtDNA sequence variants in mytilid mussels.     

An unusual case of gender-associated mitochondrial DNA heteroplasmy: the mytilid <Emphasis Type="Italic">Musculista senhousia</Emphasis> (Mollusca Bivalvia)

Background

Doubly Uniparental Inheritance (DUI) represents the most outstanding exception to matrilinear inheritance of mitochondrial DNA (mtDNA), typical of Metazoa. In a few bivalve mollusks, two sex-linked mtDNAs (the so-called M and F) are inherited in a peculiar way: both daughters and sons receive their F from the mother, whereas sons inherit M from the father (males do not transmit F to their progeny). This realizes a double mechanism of transmission, in which M and F mtDNAs are inherited uniparentally.DUI systems represent a unique experimental model for testing the evolutionary mechanisms that apply to mitochondrial genomes and their transmission patterns as well as to mtDNA recombination.

Results

A new case of DUI is described in Musculista senhousia (Mollusca: Bivalvia: Mytilidae). Its heteroplasmy pattern is in line with standard DUI. Sequence variability analysis evidenced two main results: F haplotypes sequence variability is higher than that of M haplotypes, and F mitochondrial haplotypes experience a higher mutation rate in males' somatic tissues than in females' ones. Phylogenetic analysis revealed also that M. senhousia M and F haplotypes cluster separately from that of the other mytilids.

Conclusion

Sequence variability analysis evidenced some unexpected traits. The inverted variability pattern (the F being more variable than M) was new and it challenges most of the rationales proposed to account for sex-linked mtDNA evolution. We tentatively related this to the history of the Northern Adriatic populations analyzed. Moreover, F sequences evidenced a higher mutation level in male's soma, this variability being produced de novo each generation. This suggests that mechanisms evolved to protect mtDNA in females (f.i. antioxidant gene complexes) might be under relaxed selection in males. Phylogenetic analysis of sex-linked haplotypes confirmed that they have switched their roles during the evolutionary history of mytilids, at variance to what has been observed in unionids. Consequently, reciprocal monophyly of M and F lineages got easily lost because of role-reversals and consequent losses of M lineages, as already observed in Mytilus.

     

Footprints of unconventional mitochondrial inheritance in bivalve phylogeny: Signatures of positive selection on clades with doubly uniparental inheritance

The doubly uniparental inheritance (DUI) of some bivalve mollusks is the major exception to the common maternal inheritance of mitochondria in animals. DUI involves two mitochondrial lineages with paternal and maternal transmission routes, and it appears as a complex phenomenon requiring both nuclear and mitochondrial adaptations. DUI distribution seems to be scattered among the Bivalvia, and there are several clues for its multiple origins. In this paper, we investigate whether the incipient DUI systems had left possible selective signatures on mitochondrial genomes. Alongside the outstanding divergence of amino acid sequences, we confirmed strong purifying selection to act on mitochondrial genes. However, we found evidence that distinct episodes of intense directional pressure are associated with the origins of different DUI systems: We interpret these signals as footprints of the coevolution with the nuclear genome that ought to take place at the base of a DUI clade. Six genes (atp6, cox1, cox2, cox3, nad4L, and nad6) seem to be more commonly linked to the appearance of DUI. We also identified few putative DUI‐specific mutations, thus extending support to the hypothesis of multiple independent origins of this complex phenomenon.     

Biparental Inheritance Through Uniparental Transmission: The Doubly Uniparental Inheritance (DUI) of Mitochondrial DNA

Many bivalvian mollusks have a sperm-transmitted mitochondrial genome (M), along with the standard egg-transmitted one (F). The phenomenon, known as doubly uniparental inheritance (DUI) of mtDNA, is the only known case in which biparental inheritance of a cytoplasmic genome is the rule rather than the exception. In the mussel Mytilus sperm mitochondria disperse randomly among blastomeres in female embryos, but form an aggregate and stay in the same blastomere in male embryos. In adults, somatic tissues of both sexes are dominated by the F genome. Sperm contains only the M genome and eggs the F (and perhaps traces of M). A female produces mostly daughters, mostly sons, or both sexes in about equal numbers, irrespective of its mate. Thus maleness and M mtDNA fate are tightly linked and under maternal control. Hybridization and triploidization affect the former but not the latter, which suggests that the two are not causally linked. Gene content and arrangement are the same in conspecific F and M genomes, but primary sequence has diverged from 20 % to 40 %, depending on species. The two genomes differ at the control region (CR). Synonymous substitutions accumulate faster in the M than the F genome and non-synonymous even faster. Expression studies indicate that the M genome is active only at spermatogenesis. These observations suggest that the M genome is under a more relaxed selective constraint than the F. Some mytilid species carry, in low frequencies, sperm-transmitted mtDNAs whose primary sequence is of the F type and the CR is an F/M mosaic (“masculinized” genomes). In venerids sperm mitochondria behavior, M genome fate and sex determination are as in mytilids. In unionids the M genome also evolves faster than the F and F/M sequence divergence reaches 50 %. The identification of F-specific and M-specific open reading frames in non-coding regions of unionids and mytilids, in conjunction with the CR’s mosaic structure of masculinized genomes, suggest that the mitochondrial genomes of species with DUI carry sequences that affect their transmission route. A model that incorporates these findings is presented in this review.     

Disruption of doubly uniparental inheritance of mitochondrial DNA in hybrid mussels (Mytilus edulis x M. galloprovincialis)

Blue mussels of the genus Mytilus have an unusual mode of mitochondrial DNA inheritance termed doubly uniparental inheritance (DUI). Females are homoplasmic for the F mitotype which is inherited maternally, whereas males are heteroplasmic for this and the paternally inherited M mitotype. In areas where species distributions overlap a varying degree of hybridization occurs; yet genetic differences between allopatric populations are maintained. Observations from natural populations and previous laboratory experiments suggest that DUI may be disrupted by hybridization, giving rise to heteroplasmic females and homoplasmic males. We carried out controlled laboratory crosses between Mytilus edulis and M. galloprovincialis to produce pure species and hybrid larvae of known parentage. DNA markers were used to follow the fate of the F and M mitotypes through larval development. Disruption of the mechanism which determines whether the M mitotype is retained or eliminated occurred in an estimated 38% of M. edulis x M. galloprovincialis hybrid larvae, a level double that previously observed in adult mussels from a natural M. edulis x M. galloprovincialis hybrid population. Furthermore, reciprocal hybrid crosses exhibited contrasting types of DUI disruption. The results indicate that disruption of DUI in hybrid mussels may be associated with increased mortality and hence could be a factor in the maintenance of genetic integrity for each species.     

Doubly uniparental inheritance of mitochondrial DNA in freshwater mussels: History and status of the European species

Doubly uniparental inheritance (DUI) is a mode of inheriting mitochondrial DNA that is distinct from strictly maternal inheritance. It has been described in nine and three families of marine and freshwater mussels, respectively, including the European margaritiferids and unionids. Among the 16 freshwater species of Unionida inhabiting Europe, DUI has been described in 9 species of dioecious mussels and was absent from a single hermaphroditic species and from secondary hermaphroditic specimens. The DUI freshwater mussels include two vastly genetically different mitochondrial genomes: maternal (F genome) and paternal (M genome), which coexist within the same specimen but in different tissues. The F genome is present in all female tissues and somatic male tissues. It is inherited in the typical, maternal, manner. Conversely, the M genome is located primarily in the male gonads and generative cells, and is inherited paternally. Dioecious Unionidae display unique characteristics that have been interrelated for over 200 million years: a high fidelity of the transmission of the F and M genomes in DUI and two paths of spermatogenesis–the typical path that produces sperm cells containing mitochondria with the F genome and the atypical path that produces sperm cells with the M genome. The mitogenomes of freshwater mussels display unique features that are not present in any other animal, that is, an additional, gender-specific gene and an elongated cox2 gene occurring exclusively in the M genome. These features mean that the mitochondria, in addition to their basic function of producing energy, also may take part in determining sex in these dioecious organisms.     

Mitochondrial phylogenomics of the Bivalvia (Mollusca): searching for the origin and mitogenomic correlates of doubly uniparental inheritance of mtDNA

Background  

Doubly uniparental inheritance (DUI) is an atypical system of animal mtDNA inheritance found only in some bivalves. Under DUI, maternally (F genome) and paternally (M genome) transmitted mtDNAs yield two distinct gender-associated mtDNA lineages. The oldest distinct M and F genomes are found in freshwater mussels (order Unionoida). Comparative analyses of unionoid mitochondrial genomes and a robust phylogenetic framework are necessary to elucidate the origin, function and molecular evolutionary consequences of DUI. Herein, F and M genomes from three unionoid species, Venustaconcha ellipsiformis, Pyganodon grandis and Quadrula quadrula have been sequenced. Comparative genomic analyses were carried out on these six genomes along with two F and one M unionoid genomes from GenBank (F and M genomes of Inversidens japanensis and F genome of Lampsilis ornata).     

Sex-specific effects of hybridization on reproductive fitness in Mytilus

Blue mussels of the genus Mytilus form extensive hybrid zones in the North Atlantic and elsewhere where the distributions of different species overlap. Mytilus species transmit both maternal and paternal mtDNA through egg and sperm, respectively, a process known as doubly uniparental inheritance (DUI), and some females produce offspring with extremely biased sex ratios. These two traits have been shown to be linked and maternally controlled, with sex determination involving nuclear–cytoplasmic interactions. Hybridization has been shown to disrupt DUI mitochondrial inheritance and sex ratio bias; however, the effect of hybridization on reproductive fitness has not previously been examined. We investigated this effect in M. edulis × M. trossulus crosses through histological examination of mature F1 progeny, and spawning of F1 hybrids to monitor survival of their progeny through to the D stage of larval development. For progeny produced from mothers with a strong bias toward female offspring (often 100%) in pure-bred crosses, there was a clear breakdown in female dominance of progeny and significantly more hermaphrodites in the hybrid crosses produced from sperm with the M-tr1 mitotype. We also found significant sex-specific differences among hybrid progeny, with females producing normal eggs while males and hermaphrodites evidenced impaired gonadal development with significantly greater numbers of Sertoli cells, phagocytic hemocytes, and degenerating germ cells, all associated with gonad resorption. Males from crosses where DUI was disrupted and where male progeny were homoplasmic for the female mtDNA were the most severely compromised. Allelic incongruity between maternal and paternal mitotypes in hybrid crosses was associated with significant disruption of male gonadal development.     

Nonhomologous Recombination Between the Large Unassigned Region of the Male and Female Mitochondrial Genomes in the Mussel, Mytilus trossulus

Doubly uniparental inheritance of mtDNA (DUI) is commonly observed in several genera of bivalves. Under DUI, female offspring inherit mtDNA from their mothers, while male offspring inherit mtDNA from both parents but preferentially transmit the paternally inherited mtDNA to their sons. Several studies have shown that the female- and male-specific mtDNA lineages in blue mussels, Mytilus spp., vary by upward of 20% at the nucleotide level. In addition to high levels of nucleotide substitution, the present study observed substantial gender-based length polymorphism in the presumptive mitochondrial control region (=large unassigned region; LUR) of North American M. trossulus. In this species, female lineage LUR haplotypes are over 2 kb larger than male lineage LUR haplotypes. Analysis of sequence data for these length variants indicates that the F LUR haplotypes of North American M. trossulus contain sequences similar to the F lineage control region in the congeners M. edulis and M. galloprovincialis. Relative to the F LUR in the latter two species, however, the F lineage LUR haplotypes in M. trossulus contain two large sequence insertions, each nearly 1 kb in size. One of these insertions has high sequence similarity to the male lineage LUR of M. trossulus. The tandem arrangement of F and M control region sequences in the F lineage LUR of M. trossulus is most likely the result of nonhomologous recombination between the male and the female mitochondrial genomes in M. trossulus, a finding that has important implications regarding the transmission and evolution of blue mussel mitochondrial genomes. [Reviewing Editor: Dr. Martin Kreitman]     

Building the Coleoptera tree‐of‐life for >8000 species: composition of public DNA data and fit with Linnaean classification

The species representation of public databases is growing rapidly and permits increasingly detailed phylogenetic inferences. We present a supermatrix based on all gene sequences of Coleoptera available in Genbank for two nuclear (18S and 28S rRNA) and two mitochondrial (rrnL and cox1) genes. After filtering for unique species names and the addition of ?2000 unpublished sequences for cox1 and 18S rRNA, the resulting data matrix included 8441 species‐level terminals and 6600 aligned nucleotide positions. The concatenated matrix represents the equivalent of 2.17% of the 390 000 described species of Coleoptera and includes 152 beetle families. The remaining 29 families constitute small lineages with ?250 known species in total. Taxonomic coverage remains low for several major lineages, including Buprestidae (0.16% of described species), Staphylinidae (1.03%), Tenebrionidae (0.90%) and Cerambycidae (0.58%). The current taxon sampling was strongly biased towards the Northern Hemisphere. Phylogenetic trees obtained from the supermatrix were in very good agreement with the Linnaean classification, in particular at the family level, but lower for the subfamily and lowest for the genus level. The topology supports the basal split of Derodontidae and Scirtoidea from the remaining Polyphaga, and the broad paraphyly of Cucujoidea. The data extraction pipeline and detailed tree provide a framework for placement of any new sequences, including environmental samples, into a DNA‐based classification system of Coleoptera.     

The postglacial history of Scots pine (Pinus sylvestris L.) in western Europe: evidence from mitochondrial DNA variation

The geographical structure of mitochondrial (mt)DNA variants (mitotypes) was investigated in 38 western European populations of Scots pine Pinus sylvestris using restriction fragment length polymorphism (RFLP) analysis of total DNA and a homologous cox1 probe. Three major mitotypes (designated a, b and d ) were detected. Within Spain all three major mitotypes were found, gene diversity was high, H_T = 0.586, and this diversity was distributed predominantly among rather than within populations (F_ST(M) = 0.813 for the seven Spanish populations). Mitotype d was present only in the most southerly population from the Sierra Nevada . Elsewhere in Europe, populations showed little or no mtDNA diversity within regions, but there were marked differences between regions. Italian populations were fixed for mitotype b ; populations from northern France, Germany, Poland, Russia and southern Sweden were fixed for mitotype a ; while populations in northern Fennoscandia were fixed for mitotype b . The isolated Scottish populations were predominantly of mitotype a , but mitotype b was present in three of the 20 populations scored. In Scotland, UK gene diversity (H_T = 0.120) and genetic differentiation among populations (F_ST(M) = 0.37) was much lower than in Spain. When interpreted in the light of complementary data from pollen analysis and nuclear genetic markers, the results suggest that present-day populations of P. sylvestris in western Europe have been derived from at least three different sources after glaciation.     

Polymorphism of mitochondrial DNA and infection with symbiotic cytoplasmic bacterium <Emphasis Type="Italic">Wolbachia pipientis</Emphasis> in mosquitoes of the <Emphasis Type="Italic">Culex pipiens</Emphasis> (Diptera,Culicidae) complex from Russia

A total of 208 mosquitoes of the Culex pipiens complex from 15 basement and terrestrial populations collected in different regions of the European part of Russia and Siberia were examined by genetic methods. Among these, two major mitotypes, M and P, were identified. These mitotypes differed by six substitutions in the 246-bp mitochondrial DNA cytochrome oxidase I gene fragment examined. Urban basement mosquitoes C. pipiens (form molestus) were characterized by the presence of mitotype M and infection with the endosymbiotic bacteria of the genus Wolbachia. Mosquitoes of the C. pipiens complex inhabiting opened biotopes harbored mitotype P, or its variety, mitotype P1, and were not infected with Wolbachia. Thus, in natural conditions marked linkage disequilibrium between cytoplasmic elements, mitochondrial DNA and Wolbachia, can be observed. Similarity of mitotypes in form molestus mosquito from different geographical localities favors the hypothesis on the common ancestry of urban mosquitoes.Translated from Genetika, Vol. 41, No. 3, 2005, pp. 320–325.Original Russian Text Copyright © 2005 by Shaikevich, Vinogradova, Platonov, Karan, Zakharov.     

Inferring the history of speciation in house mice from autosomal,X‐linked,Y‐linked and mitochondrial genes

Patterns of genetic differentiation among taxa at early stages of divergence provide an opportunity to make inferences about the history of speciation. Here, we conduct a survey of DNA‐sequence polymorphism and divergence at loci on the autosomes, X chromosome, Y chromosome and mitochondrial DNA in samples of Mus domesticus, M. musculus and M. castaneus. We analyzed our data under a divergence with gene flow model and estimate that the effective population size of M. castaneus is 200 000–400 000, of M. domesticus is 100 000–200 000 and of M. musculus is 60 000–120 000. These data also suggest that these species started to diverge approximately 500 000 years ago. Consistent with this recent divergence, we observed considerable variation in the genealogical patterns among loci. For some loci, all alleles within each species formed a monophyletic group, while at other loci, species were intermingled on the phylogeny of alleles. This intermingling probably reflects both incomplete lineage sorting and gene flow after divergence. Likelihood ratio tests rejected a strict allopatric model with no gene flow in comparisons between each pair of species. Gene flow was asymmetric: no gene flow was detected into M. domesticus, while significant gene flow was detected into both M. castaneus and M. musculus. Finally, most of the gene flow occurred at autosomal loci, resulting in a significantly higher ratio of fixed differences to polymorphisms at the X and Y chromosomes relative to autosomes in some comparisons, or just the X chromosome in others, emphasizing the important role of the sex chromosomes in general and the X chromosome in particular in speciation.     

The largest unassigned regions of the male- and female-transmitted mitochondrial DNAs in Musculista senhousia (Bivalvia Mytilidae)

Musculista senhousia is a marine mussel with doubly uniparental inheritance (DUI) of mitochondria. In this study we analyzed the largest unassigned region (LUR) of its female- and male-transmitted mitochondrial genomes, described their fine characteristics and searched for shared features. Our results suggest that both LURs contain the control region of their respective mitochondrial genomes. The female-transmitted control region is duplicated in tandem, with the two copies evolving in concert. This makes the F-mtDNA of M. senhousia the first Bivalve mitochondrial genome with this feature. We also compared M. senhousia control regions to that of other Mytilidae, and demonstrated that signals for basic mtDNA functions are retained over evolutionary times even among the fast-evolving mitochondrial genomes of DUI species. Finally, we discussed how similarities between female and male LURs may be explained in the context of DUI evolution and if the duplicated female control region might have influenced the DUI system in this species.