Cytoplasmic incompatibility and sperm cyst infection in different Drosophila-Wolbachia associations

Wolbachia are a group of maternally transmitted obligatory intracellular alpha-proteobacteria that infect a wide range of arthropod and nematode species. Wolbachia infection in Drosophila in most cases is associated with the induction of cytoplasmic incompatibility (CI), manifested as embryonic lethality of offspring in a cross between infected males and uninfected females. While the molecular basis of CI is still unknown, it has been suggested that two bacterial functions are involved: mod (for modification) modifies the sperm during spermatogenesis and resc (for rescue) acts in the female germline and/or in early embryos, neutralizing the modification. There is considerable variation in the level of incompatibility in different Wolbachia/host interactions. We examine the relationship between the levels of CI in a number of naturally infected and transinfected Drosophila hosts and the percentage of Wolbachia-infected sperm cysts. Our results indicate the presence of two main groups of Drosophila-Wolbachia associations: group I, which exhibits a positive correlation between CI levels and the percentage of infected sperm cysts (mod(+) phenotype), and group II, which does not express CI (mod(-) phenotype) irrespective of the infection status of the sperm cysts. Group II can be further divided into two subgroups: The first one contains associations with high numbers of heavily Wolbachia-infected sperm cysts while in the second one, Wolbachia is rarely detected in sperm cysts, being mostly present in somatic cells. We conclude that there are three requirements for the expression of CI in a host-Wolbachia association: (a) Wolbachia has to be able to modify sperm (mod(+) genotype), (b) Wolbachia has to infect sperm cysts, and (c) Wolbachia has to be harbored by a permissive host.     

Offsetting effects of Wolbachia infection and heat shock on sperm production in Drosophila simulans: analyses of fecundity, fertility and accessory gland proteins

Infection in Drosophila simulans with the endocellular symbiont Wolbachia pipientis results in egg lethality caused by failure to properly initiate diploid development (cytoplasmic incompatibility, CI). The relationship between Wolbachia infection and reproductive factors influencing male fitness has not been well examined. Here we compare infected and uninfected strains of D. simulans for (1) sperm production, (2) male fertility, and (3) the transfer and processing of two accessory gland proteins, Acp26Aa or Acp36De. Infected males produced significantly fewer sperm cysts than uninfected males over the first 10 days of adult life, and infected males, under varied mating conditions, had lower fertility compared to uninfected males. This fertility effect was due to neither differences between infected and uninfected males in the transfer and subsequent processing of accessory gland proteins by females nor to the presence of Wolbachia in mature sperm. We found that heat shock, which is known to decrease CI expression, increases sperm production to a greater extent in infected compared to uninfected males, suggesting a possible link between sperm production and heat shock. Given these results, the roles Wolbachia and heat shock play in mediating male gamete production may be important parameters for understanding the dynamics of infection in natural populations.     

The distribution and proliferation of the intracellular bacteria Wolbachia during spermatogenesis in Drosophila.

Wolbachia is a cytoplasmically inherited alpha-proteobacterium found in a wide range of host arthropod and nematode taxa. Wolbachia infection in Drosophila is closely associated with the expression of a unique form of post-fertilization lethality termed cytoplasmic incompatibility (CI). This form of incompatibility is only expressed by infected males suggesting that Wolbachia exerts its effect during spermatogenesis. The growth and distribution of Wolbachia throughout sperm development in individual spermatocysts and elongating sperm bundles is described. Wolbachia growth within a developing cyst seems to begin during the pre-meiotic spermatocyte growth phase with the majority of bacteria accumulating during cyst elongation. Wolbachia are predominantly localized in the proximal end of the immature cyst, opposite the spermatid nuclei, and throughout development there appears little movement of Wolbachia between spermatids via the connecting cytoplasmic bridges. The overall number of new cysts infected as well as the number of spermatids/cysts infected seems to decrease with age and corresponds to the previously documented drop in CI with age. In contrast, in one CI expressing line of Drosophila melanogaster, fewer cysts are infected and a much greater degree of variation in numbers is observed between spermatids. Furthermore, the initiation and extent of the fastest period of Wolbachia growth in the D. melanogaster strain lags behind that of Drosophila simulans. The possible implications on the as yet unexplained mechanism of CI are discussed.     

黑腹果蝇Mst84Db敲降引起的父本缺陷类似Wolbachia诱导的细胞质不亲和

【目的】Wolbachia 是广泛存在于昆虫体内的一类通过母系传递的共生菌,能够通过多种方式影响宿主的生殖。细胞质不亲和（CI）是Wolbachia 引起的最普遍的一种表型,即感染Wolbachia的雄性和未感染的雌性宿主交配后,胚胎发育停滞于早期阶段。但目前有关CI的分子机理还不清楚。本研究组前期实验表明,Wolbachia感染引起黑腹果蝇Drosophila melanogaster 3龄幼虫精巢中Mst84Db基因的表达显著下调。本研究的目的是进一步研究Mst84Db与CI的关系。【方法】我们体外合成了Mst84Db的双链RNA（dsRNA）,注射雄性果蝇,将注射过的雄果蝇与野生雌果蝇交配,检测其繁殖力。基因表达采用定量RT-PCR方法进行检测。胚胎表型采用DAPI染色进行分析。【结果】注射dsRNA 24 h后,Mst84Db基因的表达水平发生显著下调。注射后72 h,基因表达下调幅度最大。与对照组相比,基因敲降后的雄蝇繁殖能力显著下降,与雌果蝇交配后胚胎孵化率显著低于对照组,这与Wolbachia诱导的CI现象类似。未孵化胚胎的表皮上没有体节出现,说明胚胎停滞于发育的早期。部分胚胎细胞核分裂不同步,且有染色质间桥出现,这也与CI胚胎中的细胞学表型一致。【结论】Wolbachia感染可能抑制果蝇精子发生过程中Mst84Db基因的表达,从而使精子失去正常功能,最终导致与雌性果蝇交配后,胚胎发育停滞,并最终死亡。Mst84Db基因在雄性果蝇中表达下调可能是产生CI的重要原因之一。     

Wolbachia infection lowers fertile sperm transfer in a moth

The endosymbiotic bacterium Wolbachia pipientis manipulates host reproduction by rendering infected males reproductively incompatible with uninfected females (cytoplasmic incompatibility; CI). CI is believed to occur as a result of Wolbachia-induced modifications to sperm during maturation, which prevent infected sperm from initiating successful zygote development when fertilizing uninfected females' eggs. However, the mechanism by which CI occurs has been little studied outside the genus Drosophila. Here, we show that in the sperm heteromorphic Mediterranean flour moth, Ephestia kuehniella, infected males transfer fewer fertile sperm at mating than uninfected males. In contrast, non-fertile apyrene sperm are not affected. This indicates that Wolbachia may only affect fertile sperm production and highlights the potential of the Lepidoptera as a model for examining the mechanism by which Wolbachia induces CI in insects.     

Sex-specific death in the Asian corn borer moth (Ostrinia furnacalis) infected with Wolbachia occurs across larval development.

Maternally inherited endosymbiotic bacteria of the genus Wolbachia induce various kinds of reproductive alterations in their arthropod hosts. In a Wolbachia-infected strain of the adzuki bean borer moth, Ostrinia scapulalis (Lepidoptera: Crambidae), males selectively die during larval development, while females selectively die when Wolbachia are eliminated by antibiotic treatment. We found that naturally occurring Wolbachia in the congener O. furnacalis caused sex-specific lethality similar to that in O. scapulalis. Cytogenetic analyses throughout the entire larval development clarified that the death of males (when infected) and females (when cured) took place mainly during early larval stages. However, some individuals also died after complete formation of larval bodies but before egg hatching, or at late larval stages, even in the penultimate instar. Although the specific timing was highly variable, death of males and females occurred before pupation without exception. The potential association of sex-specific lethality with the sex determination mechanism was also examined and is discussed.     

Wolbachia与昆虫精卵细胞质不亲和

Wolbachia是广泛分布在昆虫体内的一类共生菌,能通过多种机制调节宿主的生殖方式,包括诱导宿主精卵细胞质不亲和(CI)、孤雌生殖、雌性化、杀雄等,其中细胞质不亲和为最普遍的表型,即感染Wolbachia的雄性和未感染或感染不同品系Wolbachia的雌性宿主交配后,受精卵不能正常发育,在胚胎期死亡。多数CI胚胎在第1次分裂时,来自父本的染色质浓缩缺陷,导致父本遗传物质无法正常分配到子细胞中,因而引起胚胎死亡。守门员模型认为,产生CI可能需要有两种因子,其中之一使得精子发生修饰改变,导致受精后雄性原核发育滞后。第2种因子可能与Wolbachia的原噬菌体有关,在胚胎发育后期导致胚胎死亡。近期的研究已发现,在Wolbachia感染的宿主中,一些与生殖细胞发生和繁殖相关基因的表达发生了显著改变,Wolbachia可能因此对宿主的生殖产生重大影响,进而导致CI的产生。本文主要综述了CI的细胞学表型、解释CI的模型及其分子机理,向读者展示一个小小的细菌是如何通过精妙的策略影响昆虫宿主的繁殖,从而实现其自身的生存和传播的。     

Wolbachia plays no role in the one-way reproductive incompatibility between the hybridizing field crickets Gryllus firmus and G. pennsylvanicus

Wolbachia are cytoplasmically inherited alpha-proteobacteria that can cause cytoplasmic incompatibility (CI) in insects. This incompatibility between sperm and egg is evident when uninfected females mate with infected males. Wolbachia-driven reproductive incompatibilities are of special interest because they may play a role in speciation. However, the presence of Wolbachia does not always imply incompatibility. The field crickets Gryllus firmus and G. pennsylvanicus exhibit a very clear unidirectional incompatibility and have been cited as a possible example of Wolbachia-induced CI. Here, we conduct curing experiments, intra- and interspecific crosses, cytological examination of Wolbachia in testes and Wolbachia quantifications through real-time PCR. All of our data strongly suggest that Wolbachia are not involved in the reproductive incompatibility between G. firmus and G. pennsylvanicus.     

Effects of Wolbachia on sperm maturation and architecture in Drosophila simulans Riverside

Wolbachia is an intracellular obligate symbiont, that is relatively common in insects and also found in some nematodes. Cytoplasmic incompatibility (CI) is the most commonly expressed form, of several sex altering phenotypes caused by this rickettsial-like bacterium. CI is induced when infected males mate with uninfected females, and is likely the result of bacterial-induced modification of sperm grown in a Wolbachia-infected environment. Several studies have explored the dynamics of Wolbachia bacteria during sperm development in Drosophila. This study confirms and extends these earlier investigations of Wolbachia's distribution and proliferation in male germ cell lines. We examined Wolbachia population dynamics during testis development of Drosophila simulans (Riverside) by studying their distribution during the early mitotic divisions of secondary spermatogonial and subsequent meiotic cyst cells. Wolbachia are found in lower concentration in spermatogonial than in spermatocyte cells. Cytoplasmically incompatible crosses result in low levels of viable embryos despite the occurrence of fairly high levels of uninfected cysts. During meiotic divisions Wolbachia organize themselves at the poles during prophase and telophase but arrange themselves in equatorial bands during metaphase and anaphase. Moreover, during meiosis Wolbachia are asymmetrically divided between some daughter cells. There is no strong relationship between the fusome and Wolbachia and we have not found evidence that bacteria cross the ring canals. Wolbachia were observed at the distal and proximal sides of individualization complexes. Multiple altered sperm structures were observed during the process of individualization of infected sperm.     

Wolbachia distribution and cytoplasmic incompatibility during sperm development: the cyst as the basic cellular unit of CI expression

The growth and distribution of the intracellular microbe Wolbachia pipientis during spermatogenesis in several different host/symbiont genetic combinations in Drosophila melanogaster and Drosophila simulans is described. Considerable intra- and inter-strain variation in Wolbachia density and tissue distribution was observed. Wolbachia were found inside spermatocytes and spermatids or within the somatic cyst cells surrounding the germ cells. Some strains displayed both tissue distributions. High rates of cytoplasmic incompatibility (CI) are correlated with high levels of Wolbachia only when spermatocytes and/or spermatids harbor the microbe. Wolbachia infection of somatic cyst cells, although sometimes present at high levels, did not result in significant CI expression. CI-inducing Wolbachia strains within D. simulans showed no distinguishable differences in distribution or density within infected spermatids. To dissect the relative contribution of host and symbiont to the expression of CI, Wolbachia from various host strains known to exhibit varying levels of CI were introgressed into new uninfected host genetic backgrounds. These introgression experiments confirm that the mod(+)/mod(-) phenotype is an intrinsic Wolbachia trait and is not determined by host factors. The level of sperm modification in those lines harboring Wolbachia capable of modifying sperm, however, is influenced by host genetic background. These results form the basis of the Wolbachia Infected Spermatocyte/Spermatid Hypothesis (WISSH). According to WISSH, Wolbachia infection in spermatocytes and then spermatids during sperm development is required for CI expression.     

Within- and between-population variation for Wolbachia-induced reproductive incompatibility in a haplodiploid mite

Wolbachia pipientis is a bacterium that induces cytoplasmic incompatibility (CI), the phenomenon in which infected males are reproductively incompatible with uninfected females. CI spreads in a population of hosts because it reduces the fitness of uninfected females relative to infected females. CI encompasses two steps: modification (mod) of sperm of infected males and rescuing (resc) of these chromosomes by Wolbachia in the egg. Infections associated with CI have mod+ resa+ phenotypes. However, mod- resc+ phenotypes also exist; these do not result in CI. Assuming mod/resc phenotypes are properties of the symbiont, theory predicts that mod- resc+ infections can only spread in a host population where a mod+ resc+ infection already occurs. A mod- resc+ infection spreads if the cost it imposes on the infected females is lower than the cost inflicted by the resident (mod+ resc+) infection. Furthermore, introduction of a mod- Wolbachia eventually drives infection to extinction. The uninfected population that results can be recolonized by a CI-causing Wolbachia. Here, we investigated whether variability for induction of CI was present in two Tetranychus urticae populations. In one population all isofemale lines tested were mod-. In the other, mod+ resc+ and mod- resc+ isofemale lines coexisted. We found no evidence for a cost difference to females expressing either type (mod-/-). Infections in the two populations could not be distinguished based on sequences of two Wolbachia genes. We consider the possibility that mod- is a host effect through a population dynamics model. A mod- host allele leads to infection extinction in the absence of fecundity differences. Furthermore, the uninfected population that results is immune to reestablishment of the (same) CI-causing Wolbachia.     

Host genotype changes bidirectional to unidirectional cytoplasmic incompatibility in Nasonia longicornis

Wolbachia are the most abundant maternally inherited endosymbionts of insects and cause various reproductive alterations in their hosts. One such manipulation is cytoplasmic incompatibility (CI), which is a sperm-egg incompatibility typically resulting in zygotic death. Nasonia longicornis (Hymenoptera: Pteromalidae) has an A supergroup and two closely related B supergroup Wolbachia infections. The B supergroup bacteria co-diverged in this host genus. Both triple (wNlonAwNlonB1wNlonB2) and double infections (wNlonAwNlonB1, wNlonAwNlonB2) have been obtained from the field. In the present study, CI was determined among the three Wolbachia types in different host genetic backgrounds. Results show that host genetic background determines whether bidirectional CI or unidirectional CI occurs between the two closely related B group Wolbachia. Results show that the wNlonB1-infected males are bidirectionally incompatible with wNlonB2 in their 'native' nuclear genetic background, whereas wNlonB1 males are compatible with wNlonB2 in two other N. longicornis genetic backgrounds, resulting in unidirectional CI. In contrast, wNlonB2-infected males are incompatible with wNlonB1 females in all three host genetic backgrounds. These changes in incompatibility are not due to the loss of the bacteria. We hypothesize that a repressor gene for sperm modification by wNlonB1 is segregating in N. longicornis populations. The relevance of these findings to the potential role of Wolbachia in host-reproductive divergence and speciation is discussed.     

On the mod resc model and the evolution of Wolbachia compatibility types.

Cytoplasmic incompatibility (CI) is induced by the endocellular bacterium Wolbachia. It results in an embryonic mortality occurring when infected males mate with uninfected females. The mechanism involved is currently unknown, but the mod resc model allows interpretation of all observations made so far. It postulates the existence of two bacterial functions: modification (mod) and rescue (resc). The mod function acts in the males' germline, before Wolbachia are shed from maturing sperm. If sperm is affected by mod, zygote development will fail unless resc is expressed in the egg. Interestingly, CI is also observed in crosses between infected males and infected females when the two partners bear different Wolbachia strains, demonstrating that mod and resc interact in a specific manner: Two Wolbachia strains are compatible with each other only if they harbor the same compatibility type. Here we focus on the evolutionary process involved in the emergence of new compatibility types from ancestral ones. We argue that new compatibility types are likely to evolve under a wider range of conditions than previously thought, through a two-step process. First, new mod variants can arise by mutation and spread by drift. This is possible because mod is expressed in males and Wolbachia is transmitted by females. Second, once such a mod variant achieves a certain frequency, it can create the conditions for the deterministic invasion of a new resc variant, allowing the invasion of a new mod resc pair. Furthermore, we show that a stable polymorphism might be maintained in natural populations, allowing the long-term existence of "suicidal" Wolbachia strains.     

共生菌Wolbachia引起宿主细胞质不亲和的研究进展

Wolbachia 是一类广泛存在于节肢动物以及线虫体内细胞质中呈母系遗传的共生细菌,能够在宿主中产生细胞质不亲和、孤雌生殖、雌性化及杀雄等多种生殖调控作用,其中细胞质不亲和是指被 Wolbachia 感染的雄性个体与未感染的雌性个体（单向不亲和）,或者感染不同株系 Wolbachia 的雌性个体（双向不亲和）交配后不能或很少产生后代,或者后代偏雄性的现象。细胞质不亲和作用使感染的雌性个体在种群中具有很大的生殖优势,凭借这种生殖优势,Wolbachia 能够迅速在宿主种群中扩张。细胞质不亲和的机理探索主要集中在细胞学水平上,其中广为接受的精子“修饰”和“拯救”理论认为,精巢中的 Wolbachia 能够修饰宿主的精细胞,使其不能和卵细胞正常融合,但是当母本感染相同的 Wolbachia 时,就能够将“修饰”过的精子细胞“拯救”过来,使其恢复与卵细胞的正常融合。而分子机理上的探索也开始在转录组、基因组和miRNA水平上对部分昆虫展开了研究。影响细胞质不亲和的因素有很多,包括宿主遗传背景、 Wolbachia 株系、Wolbachia 基因型、共生菌密度（浓度、滴度）、雄虫年龄、环境因素以及共生菌在宿主生殖组织的分布等。近年来,人类也应用细胞质不亲和控制害虫（主要是蚊虫）和人类疾病,取得了较好的进展。     

A genetic test of the mechanism of Wolbachia-induced cytoplasmic incompatibility in Drosophila

Cytoplasmic bacteria of the genus Wolbachia are best known as the cause of cytoplasmic incompatibility (CI): many uninfected eggs fertilized by Wolbachia-modified sperm from infected males die as embryos. In contrast, eggs of infected females rescue modified sperm and develop normally. Although Wolbachia cause CI in at least five insect orders, the mechanism of CI remains poorly understood. Here I test whether the target of Wolbachia-induced sperm modification is the male pronucleus (e.g., DNA or pronuclear proteins) or some extranuclear factor from the sperm required for embryonic development (e.g., the paternal centrosome). I distinguish between these hypotheses by crossing gynogenetic Drosophila melanogaster females to infected males. Gynogenetic females produce diploid eggs whose normal development requires no male pronucleus but still depends on extranuclear paternal factors. I show that when gynogenetic females are crossed to infected males, uniparental progeny with maternally derived chromosomes result. This finding shows that Wolbachia impair the male pronucleus but no extranuclear component of the sperm.     

Stochastic spread of Wolbachia

Wolbachia are very common, maternally transmitted endosymbionts of insects. They often spread by a mechanism termed cytoplasmic incompatibility (CI) that involves reduced egg hatch when Wolbachia-free ova are fertilized by sperm from Wolbachia-infected males. Because the progeny of Wolbachia-infected females generally do not suffer CI-induced mortality, infected females are often at a reproductive advantage in polymorphic populations. Deterministic models show that Wolbachia that impose no costs on their hosts and have perfect maternal transmission will spread from arbitrarily low frequencies (though initially very slowly); otherwise, there will be a threshold frequency below which Wolbachia frequencies decline to extinction and above which they increase to fixation or a high stable equilibrium. Stochastic theory was used to calculate the probability of fixation in populations of different size for arbitrary current frequencies of Wolbachia, with special attention paid to the case of spread after the arrival of a single infected female. Exact results are given based on a Moran process that assumes a specific demographic model, and approximate results are obtained using the more general Wright-Fisher theory. A new analytical approximation for the probability of fixation is derived, which performs well for small population sizes. The significance of stochastic effects in the natural spread of Wolbachia and their relevance to the use of Wolbachia as a drive mechanism in vector and pest management are discussed.     

A genetic test of the role of the maternal pronucleus in Wolbachia-induced cytoplasmic incompatibility in Drosophila melanogaster

Cytoplasmic incompatibility (CI) is a reproductive sterility found in arthropods that is caused by the endoparasitic bacteria Wolbachia. In CI, host progeny fail to develop during early embryogenesis if Wolbachia-infected males fertilize uninfected females. It is widely accepted that this lethality is caused by some unknown Wolbachia-induced modification of the paternal nuclear material in the host testes. However, the direct means by which this modification leads to early embryonic death are currently unresolved. Results from previous studies suggested that CI lethality occurs as a result of asynchrony in cell cycle timing between the paternal and maternal pronuclei. This hypothesis can be tested experimentally by the prediction that the Wolbachia-modified paternal pronucleus should support androgenetic development (i.e., from the paternal pronucleus only). Using specific mutations in Drosophila melanogaster that produce androgenetic progeny, we demonstrate that the Wolbachia-induced modification inhibits this type of development. This result suggests that CI occurs independently of the maternal pronucleus and argues against pronuclear asynchrony as the primary cause of CI lethality. We propose that CI occurs instead as the result of either a developmentally incompetent paternal pronucleus or asynchrony between the paternal pronucleus and the cell cycle of the egg cytoplasm.     

The effect of Wolbachia on genetic divergence between populations: models with two-way migration

Wolbachia are intracellular bacteria that cause various reproduction alterations in their hosts, including cytoplasmic incompatibility (CI), an incompatibility between sperm and egg that typically results in embryonic death. We investigate theoretically the effects of Wolbachia-induced bidirectional CI on levels of divergence between two populations, where there is migration in both directions and differential selection at a single locus. The main findings are as follows: Wolbachia differences in the two populations are maintained up to a threshold migration rate, above which the system collapses to a single Wolbachia type; differential selection at a nuclear locus increases the threshold migration rate below which Wolbachia polymorphisms are maintained; Wolbachia differences between the populations enhance their genetic divergence at the selected locus by reducing the "effective migration rate," and even moderate levels of CI can cause large population differences in allele frequencies; and asymmetric CI can induce strong asymmetries in effective migration rate and dramatically alter the pattern of genetic divergence compared with the No Wolbachia situation. We derive an analytical approximation for the effective migration rate, which matches the simulation results for most parameter values. These results generally support the view that CI Wolbachia can contribute to genetic divergence between populations.     

Wolbachia affects oviposition and mating behaviour of its spider mite host

Wolbachia bacteria are transmitted from mother to offspring via the cytoplasm of the egg. When mated to males infected with Wolbachia bacteria, uninfected females produce unviable offspring, a phenomenon called cytoplasmic incompatibility (CI). Current theory predicts that ‘sterilization’ of uninfected females by infected males confers a fitness advantage to Wolbachia in infected females. When the infection is above a threshold frequency in a panmictic population, CI reduces the fitness of uninfected females below that of infected females and, consequently, the proportion of infected hosts increases. CI is a mechanism that benefits the bacteria but, apparently, not the host. The host could benefit from avoiding incompatible mates. Parasite load and disease resistance are known to be involved in mate choice. Can Wolbachia also be implicated in reproductive behaviour? We used the two‐spotted spider mite – Wolbachia symbiosis to address this question. Our results suggest that uninfected females preferably mate to uninfected males while infected females aggregate their offspring, thereby promoting sib mating. Our data agrees with other results that hosts of Wolbachia do not necessarily behave as innocent bystanders – host mechanisms that avoid CI can evolve.