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.     

Quantitation of the male and female types of mitochondrial DNA in a blue mussel, Mytilus galloprovincialis, using real-time polymerase chain reaction assay

The system termed doubly uniparental inheritance (DUI) of mitochondrial transmission to progeny has been reported in Mytilus. Under DUI, it has been thought that males have both paternally (M type) and maternally (F type) transmitted mitochondrial DNA (mtDNA), and females have only F type. However, the presence of M type in females has been reported. To clarify the ratio of M type to F type mtDNA in female and male tissues to further our understanding of mitochondrial transmission, we developed a procedure to measure the copy numbers of the two types of mtDNA in Mytilus galloprovincialis using a real-time polymerase chain reaction assay. The following results were obtained by this method. In females, the copy numbers of M type mtDNA detected in adductor muscle, gonad and eggs were approximately 10 000-fold lower than those of F type. In males, F type dominated in adductor muscle, as in the female tissue. However, copy numbers of M type mtDNA were approximately 1000-fold higher than those of F type in gonad and 100 000-fold higher than those of F type in sperm. We examined the quantity relationship between the two types of mtDNA and the transmission mechanism of mtDNA in M. galloprovincialis.     

Sperm motility in Mytilus edulis in relation to mitochondrial DNA polymorphisms: implications for the evolution of doubly uniparental inheritance in bivalves

Bivalves of the families Mytilidae, Unionidae, and Veneridae have an unusual mode of mitochondrial DNA (mtDNA) transmission called doubly uniparental inheritance (DUI). A characteristic feature of DUI is the presence of two gender-associated mtDNA genomes that are transmitted through males (M-type mtDNA) and females (F-type mtDNA), respectively. Female mussels are predominantly homoplasmic with only the F-type expressed in both somatic and gonadal tissue; males are heteroplasmic with the M-type expressed in the gonad and F-type in somatic tissue for the most part. An unusual evolutionary feature of this system is that an mt genome with F-coding sequences occasionally invades the male route of inheritance (i.e., a "role reversal" event), and is thereafter transmitted as a new M-type. Phylogenetic studies have demonstrated that the new or "recently masculinized" M-types may eventually replace the older or "standard" M-types over time. To investigate whether this replacement process could be due to an advantage in sperm swimming behavior, we measured differences in motility parameters and found that sperm with the recently masculinized M-type had significantly faster curvilinear velocity and average path velocity when compared to sperm with standard M-type. This increase in sperm swimming speed could explain the multiple evolutionary replacements of standard M-types by masculinized M-types that have been hypothesized for the mytilid lineage. However, our observations do not support the hypothesis that DUI originated because it permits the evolution of mitochondrial adaptations specific to sperm performance, otherwise, the evolutionarily older, standard M genome should perform better.     

Highly divergent mitogenomes of Geukensia demissa (Bivalvia,Mytilidae) with extreme AT content

Complete sequences of two lineage-specific mitogenomes from mytilid bivalve Geukensia demissa are reported, confirming the existence of doubly uniparental inheritance system in this species. The reported mitogenomes show extreme sequence divergence; at protein level, it is in the range of 12%–55%, exceeding the highest values known from this family to date. Moreover, these mitogenomes are also extraordinarily AT-rich (~72%) making them the most compositionally biased mitogenomes from this family. The compositional bias is even more extreme at neutral sites, reaching 80% AT there. Despite high-sequence divergence, the mitogenomes are both compositionally and structurally similar, with only four trn genes relocated and overall gene order very similar to the phylogenetically close mitogenomes of Perumytilus purpuratus. Lineage-specific differences are limited to the non-coding regions and a short cox2 extension present in the paternally inherited M mitogenome. Phylogenetic analysis shows deeper separation of M and F lineages in Geukensia, than in Perumytilus consistent with higher protein divergence. It can be speculated that stronger mutational pressure in Geukensia is driving faster evolution of its mitogenomes.     

Sex ratio at mating does not modulate age fitness effects in Drosophila melanogaster

Understanding the effects of male and female age on reproductive success is vital to explain the evolution of life history traits and sex‐specific aging. A general prediction is that pre‐/postmeiotic aging processes will lead to a decline in the pre‐ and postcopulatory abilities of both males and females. However, in as much the sexes have different strategies to optimize their fitness, the decline of reproductive success late in life can be modulated by social context, such as sex ratio, in a sex‐specific manner. In this study, we used Drosophila melanogaster to investigate whether sex ratio at mating modulates age effects on male and female reproductive success. As expected, male and female age caused a decrease in reproductive success across male‐biased and female‐biased social contexts but, contrary to previous findings, social context did not modulate age‐related fitness decline in either of the two sexes. We discuss these results in the light of how sex ratio might modulate pre‐/postcopulatory abilities and the opportunity for inter‐ and intrasexual competition in D. melanogaster, and generally suggest that social context effects on these processes are likely to be species specific.     

去除Wolbachia 对丽蝇蛹集金小蜂繁殖适合度和成蜂寿命的影响

【目的】明确内共生菌 Wolbachia 对丽蝇蛹集金小蜂 Nasonia vitripennis 繁殖适合度和成蜂寿命的影响。【方法】通过给自然感染 Wolbachia 的丽蝇蛹集金小蜂成蜂喂食不同浓度的利福平来消除其体内的 Wolbachia,然后进行10个世代的连续饲养,探究不同浓度利福平对丽蝇蛹集金小蜂体内 Wolbachia 的去除效果和去除 Wolbachia 后对丽蝇蛹集金小蜂繁殖力、性比（雌蜂占子代数量的比值）和成蜂寿命的影响。【结果】低浓度利福平（0.1~0.5 mg/mL）对丽蝇蛹集金小蜂的毒害作用较小,而高浓度利福平（0.7~10.0 mg/mL）对丽蝇蛹集金小蜂的毒害作用较大,但二者均能去除丽蝇蛹集金小蜂体内的 Wolbachia;去除 Wolbachia 后丽蝇蛹集金小蜂的出蜂量显著下降（P <0.01）,子代中性比显著下降（P <0.01）,但寿命无明显差异。【结论】不同浓度利福平均能去除丽蝇蛹集金小蜂体内Wolbachia,但效果不一致;Wolbachia 对丽蝇蛹集金小蜂的出蜂量和子代性比均有显著影响,对成蜂寿命无显著影响。     

Extra‐mitochondrial localization and likely reproductive function of a female‐transmitted cytochrome c oxidase subunit II protein

Our previous study documented a reproductive function for the male‐transmitted mitochondrial DNA (mtDNA)‐encoded cytochrome c oxidase subunit II (MCOX2) protein in a unionoid bivalve. Here, immunoblotting, immunohistochemistry and immunoelectron microscopy analyses demonstrate that the female‐transmitted protein (FCOX2) is: (i) expressed in both male and female gonads; (ii) maximally expressed in ovaries just prior to the time of the annual fertilization event; (iii) displayed in the cytoplasm and more strongly in the plasma membrane (microvilli), vitelline matrix and vitelline envelope of mature ovarian eggs; and (iv) strongly localized to the vitelline matrix of some eggs just prior to fertilization. These findings represent evidence for the extra‐mitochondrial localization of an mtDNA‐encoded gene product and are consistent with multifunctionality for FCOX2 in eggs.     

Lower reproductive success in hybrid fur seal males indicates fitness costs to hybridization

Hybridization among organisms can potentially contribute to the processes of evolution, but this depends on the fitness of hybrids relative to parental species. A small, recently formed population of fur seals on subantarctic Macquarie Island contains a high proportion of hybrids (17-30%) derived from combinations of three parental species: Antarctic, subantarctic and New Zealand fur seals. Mitochondrial control-region data (restriction fragment length polymorphisms) and nine microsatellites were used to determine the species composition of breeding adults, and hybrid male fitness was measured by comparing reproductive success (number of genetically inferred paternities) of hybrid and pure-species territory males over 6 years. No correlations were found between male reproductive success and three genetic measures of outbreeding, but this may be due to a relatively small number of dominant males analysed. Territory males fathered 63% of pups, but hybrid males had lower reproductive success than pure-species males despite having the same ability to hold territories. A greater proportion of females in hybrid male territories conceived extra-territorially than those in territories of pure-species males, and most (70 of 82) mated with conspecifics. This suggests the presence of reproductive isolating mechanisms that promote positive assortative mating and reduce the production of hybrid offspring. Although we found no evidence for male sterility in the population, mechanisms that reduce lifetime reproductive success may act to decrease the frequency of hybrids. Our study has identified a disadvantage of hybridization - reduced reproductive success of hybrid sons - that may be contributing to the persistence of pure lineages at Macquarie Island and the temporal decline in hybridization observed there.     

Invasion fitness,inclusive fitness,and reproductive numbers in heterogeneous populations

How should fitness be measured to determine which phenotype or “strategy” is uninvadable when evolution occurs in a group‐structured population subject to local demographic and environmental heterogeneity? Several fitness measures, such as basic reproductive number, lifetime dispersal success of a local lineage, or inclusive fitness have been proposed to address this question, but the relationships between them and their generality remains unclear. Here, we ascertain uninvadability (all mutant strategies always go extinct) in terms of the asymptotic per capita number of mutant copies produced by a mutant lineage arising as a single copy in a resident population (“invasion fitness”). We show that from invasion fitness uninvadability is equivalently characterized by at least three conceptually distinct fitness measures: (i) lineage fitness, giving the average individual fitness of a randomly sampled mutant lineage member; (ii) inclusive fitness, giving a reproductive value weighted average of the direct fitness costs and relatedness weighted indirect fitness benefits accruing to a randomly sampled mutant lineage member; and (iii) basic reproductive number (and variations thereof) giving lifetime success of a lineage in a single group, and which is an invasion fitness proxy. Our analysis connects approaches that have been deemed different, generalizes the exact version of inclusive fitness to class‐structured populations, and provides a biological interpretation of natural selection on a mutant allele under arbitrary strength of selection.     

樟叶蜂两性生殖与孤雌生殖方式下雌虫生殖适合度及子代生活史特征的比较

【目的】樟叶蜂Mesoneura rufonota是危害樟树Cinnamonum campora的重要食叶性害虫,该虫的繁殖策略包括两性生殖和孤雌生殖两种模式。本研究旨在明确孤雌生殖在樟叶蜂生活史中的生物学意义。【方法】在室内25℃恒温条件下,测定并分析了樟叶蜂孤雌生殖和两性生殖两种生殖方式在亲代生殖适合度(雌虫寿命、产卵量和卵孵化率)和子代生活史(各虫态发育历期、死亡率、子代性比和产卵量等)特征上的差异。【结果】孤雌生殖的樟叶蜂雌虫寿命显著长于两性生殖的雌虫寿命,而雌虫产卵量和卵孵化率在两种生殖方式间均无差异。子代各虫态的发育历期和死亡率以及子代单雌产卵量在两种生殖方式间均无差异,但子代成虫性比在两种生殖方式间存在显著差异,表现为孤雌生殖大多产雄性子代,而两性生殖大多产雌性子代。【结论】樟叶蜂的孤雌生殖延长了亲代雌虫的寿命,且为产雄孤雌生殖。这些研究结果表明,樟叶蜂的孤雌生殖不但具有自身建群的能力,同时在种群繁衍中可以提供大量的雄虫以弥补两性生殖后代雄性个体的不足。     

Inheritance of progeny sex ratio in Urtica dioica

Seed samples collected from female Urtica dioica plants in the field showed considerable inter-family variation in the sex ratio (faction of males). To investigate the inheritance pattern of the sex ratio trait, crosses were performed between individual male and female plants from different sex ratio families. Our results suggest, at least for the families studied here, that maternal parents strongly contribute to the variation in the primary sex ratio. Furthermore, progeny sex ratios from reciprocal crosses were significantly different and resembled the sex ratios produced by their maternal parents. We discuss the possible mechanisms underlying maternal control.     

花冠对紫茉莉繁殖适合度的影响

以授粉后具花闭合特性的紫茉莉为研究材料,通过在不同天气状况下作去花冠和存留花冠处理,观察花冠对花粉活力、柱头可授性及结实率等繁殖特性的影响。结果表明:紫茉莉自然存留花冠比去花冠的花粉活力、柱头可授性、柱头上的花粉数及柱头上花粉萌发率各指标达最高值的时间重叠性更强,并以阴天存留花冠的最强。存留花冠通过这种时间的重叠性来保证花粉在柱头上的萌发,产生了有利的繁殖适合度。越晚去花冠结实率越高,结实率呈现花闭合自然存留花冠>花冠闭合期去花冠>散粉初期去花冠>花冠展开期去花冠的规律。因此,花冠对紫茉莉繁殖适合度具有利影响。紫茉莉花冠的存留提高了繁殖适合度,增强了对环境的适应能力。     

四川大头茶在不同群落中的遗传分化及适合度成分

研究了四川大头茶在 3个群落中的遗传分化和适合度成分。 12个引物的 RAPD分析表明 ,仅有 10 %左右的遗传多样性存在于种群间。四川大头茶纯林结实率 (31.86 % )显著高于针阔混交林 (2 2 .5 3% )和常绿阔叶林 (2 4 .5 2 % )。每果种子数和每果种子均重各种群间差异均显著 ,每果种子数和每果种子均重分别为常绿阔叶林 (2 9.5 0 ,0 .0 15 4 g) ,四川大头茶纯林 (2 8.39,0 .0 172 g) ,针阔混交林 (2 7.4 4 ,0 .0 195 g) ,表明二者间存在着负耦联关系 (trade off)。而以 R =∑lxbx表示的适合度却以常绿阔叶林最大     

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]     

Sex-specific sibling interactions and offspring fitness in vertebrates: patterns and implications for maternal sex ratios

Vertebrate sex ratios are notorious for their lack of fit to theoretical models, both with respect to the direction and the magnitude of the sex ratio adjustment. The reasons for this are likely to be linked to simplifying assumptions regarding vertebrate life histories. More specifically, if the sex ratio adjustment itself influences offspring fitness, due to sex-specific interactions among offspring, this could affect optimal sex ratios. A review of the literature suggests that sex-specific sibling interactions in vertebrates result from three major causes: (i) sex asymmetries in competitive ability, for example due to sexual dimorphism, (ii) sex-specific cooperation or helping, and (iii) sex asymmetries in non-competitive interactions, for example steroid leakage between fetuses. Incorporating sex-specific sibling interactions into a sex ratio model shows that they will affect maternal sex ratio strategies and, under some conditions, can repress other selection pressures for sex ratio adjustment. Furthermore, sex-specific interactions could also explain patterns of within-brood sex ratio (e.g. in relation to laying order). Failure to take sex-specific sibling interactions into account could partly explain the lack of sex ratio adjustment in accordance with theoretical expectations in vertebrates, and differences among taxa in sex-specific sibling interactions generate predictions for comparative and experimental studies.     

Mitochondrial DNA effects on fitness in Drosophila subobscura

We tested different fitness components on a series of conspecific mtDNA haplotypes, detected by RFLPs in Drosophila subobscura. Additionally, haplotype VIII, endemic to the Canary Islands, was tested upon its own native nuclear DNA background and upon that of the rest of mtDNAs tested herein. We found that both nuclear and mitochondrial DNA can have a significant effect upon their hosts' fitness, and that negative selection is one of the mechanisms that can intervene in this species' mtDNA haplotype pattern. We discuss the importance of this mechanism in relation to genetic drift, in the form of periodic population bottlenecks, and how the latter can enhance the former. We also detected a significant positive effect of haplotype VIII upon fitness that could explain in part the dominance of this endemic haplotype on some of the Canary Islands, and a mitochondrial heterosis involving this haplotype when on a foreign nuclear DNA background.     

Sex-specific associative learning cues and inclusive fitness benefits in the Seychelles warbler

In cooperative breeding vertebrates, indirect fitness benefits would be maximized by subordinates that accurately assess their relatedness to group offspring and preferentially help more closely related kin. In the Seychelles warbler (Acrocephalus sechellensis), we found a positive relationship between subordinate-nestling kinship (determined using microsatellite marker genotypes) and provisioning rates, but only for female subordinates. Female subordinates that helped were significantly more related to the nestlings than were nonhelpers, and the decision to help appears to be based on associative learning cues. High levels of female infidelity means that subordinates cannot trust their legitimacy through the male line, consequently they appear to use the continued presence of the primary female, but not the primary male, as a reliable cue to determine when to feed nestlings. By using effective discrimination, female subordinates are able to maximize the indirect benefits gained within a cooperative breeding system otherwise driven primarily by direct breeding benefits.     

Evidence for recombination of mtDNA in the marine mussel Mytilus trossulus from the Baltic

A number of studies have claimed that recombination occurs in animal mtDNA, although this evidence is controversial. Ladoukakis and Zouros (2001) provided strong evidence for mtDNA recombination in the COIII gene in gonadal tissue in the marine mussel Mytilus galloprovincialis from the Black Sea. The recombinant molecules they reported had not however become established in the population from which experimental animals were sampled. In the present study, we provide further evidence of the generality of mtDNA recombination in Mytilus by reporting recombinant mtDNA molecules in a related mussel species, Mytilus trossulus, from the Baltic. The mtDNA region studied begins in the 16S rRNA gene and terminates in the cytochrome b gene and includes a major noncoding region that may be analogous to the D-loop region observed in other animals. Many bivalve species, including some Mytilus species, are unusual in that they have two mtDNA genomes, one of which is inherited maternally (F genome) the other inherited paternally (M genome). Two recombinant variants reported in the present study have population frequencies of 5% and 36% and appear to be mosaic for F-like and M-like sequences. However, both variants have the noncoding region from the M genome, and both are transmitted to sperm like the M genome. We speculate that acquisition of the noncoding region by the recombinant molecules has conferred a paternal role on mtDNA genomes that otherwise resemble the F genome in sequence.