#PAGE_PARAMS# #ADS_HEAD_SCRIPTS# #MICRODATA#

Extreme Divergence of Tropism for the Stem-Cell-Niche in the Testis


Microbes evolve to infect structures favoring their transmission in host populations. A large fraction of insects are infected with Wolbachia bacteria. Usually Wolbachia are transmitted the same way we inherit our mitochondria, via the eggs from the mother. In fruit flies, to favor maternal transmission, Wolbachia infect the microenvironment containing the egg producing stem cells, called the “stem cell niche”. Targeting of the stem cell niche is evolutionary conserved in female fruit flies, observed in all Wolbachia strains analyzed to date. Remarkably, in males, we find many Wolbachia strains not infecting the stem cell niche present in the testis. We report a surprising diversity in stem cell niche infection in males, contrasting with extreme conservation in females. We further show that even closely related Wolbachia strains in D. melanogaster display rapidly evolving patterns of stem cell niche targeting in males. Understanding the molecular mechanisms driving these differences will identify sex specific features of stem cell niche biology. Because Wolbachia promote insect resistance against human diseases transmitted by mosquitos, Wolbachia are becoming a valuable tool in the control of several diseases, including Dengue and malaria. Knowledge emerging from this research will also provide novel tools towards Wolbachia based strategies of disease control.


Published in the journal: . PLoS Pathog 10(12): e32767. doi:10.1371/journal.ppat.1004577
Category: Research Article
doi: https://doi.org/10.1371/journal.ppat.1004577

Summary

Microbes evolve to infect structures favoring their transmission in host populations. A large fraction of insects are infected with Wolbachia bacteria. Usually Wolbachia are transmitted the same way we inherit our mitochondria, via the eggs from the mother. In fruit flies, to favor maternal transmission, Wolbachia infect the microenvironment containing the egg producing stem cells, called the “stem cell niche”. Targeting of the stem cell niche is evolutionary conserved in female fruit flies, observed in all Wolbachia strains analyzed to date. Remarkably, in males, we find many Wolbachia strains not infecting the stem cell niche present in the testis. We report a surprising diversity in stem cell niche infection in males, contrasting with extreme conservation in females. We further show that even closely related Wolbachia strains in D. melanogaster display rapidly evolving patterns of stem cell niche targeting in males. Understanding the molecular mechanisms driving these differences will identify sex specific features of stem cell niche biology. Because Wolbachia promote insect resistance against human diseases transmitted by mosquitos, Wolbachia are becoming a valuable tool in the control of several diseases, including Dengue and malaria. Knowledge emerging from this research will also provide novel tools towards Wolbachia based strategies of disease control.

Introduction

The evolutionary interests of males and females are frequently divergent. Sexual conflict arises when phenotypes that enhance the reproductive success of one sex reduces the fitness of the other sex [1]. A well-characterized example in Drosophila is sperm competition between males. Sperm competition results in rapid evolution of sperm proteins which up-regulate females' egg-laying rate and reduces her desire to re-mate with another male. However, these proteins also shorten the female's lifespan reducing her fitness [reviewed by 2].

Vertically transmitted reproductive parasites, such as Wolbachia, can also cause sexually divergent phenotypes in males and females. Wolbachia are obligate intracellular bacteria present in a large fraction of insects, as well as spiders, mites, crustaceans, and filarial worms. They are primarily vertically transmitted from mother to offspring in a manner analogous to mitochondrial inheritance, although there is extensive evidence of horizontal transmission in nature [3], [4]. For intracellular bacteria, vertical transmission often favors infected female hosts, which is also the case for Wolbachia [5]. There are several Wolbachia-induced phenotypes favoring the infected female, including parthenogenesis, feminization, male killing, and cytoplasmic incompatibility [6]. Each of these phenotypes ultimately results in the spread of more infected female hosts. In such cases, maternally transmitted bacteria can act as selfish genetic elements driving sexual conflict [5].

For successful vertical transmission, Wolbachia need to be present in the eggs laid by infected females. It has been shown in Drosophila that Wolbachia display a strong tropism for the germline, in particular, the oocyte, to ensure a high percentage of vertical transmission [7][10]. Although vertical transmission is prevalent, Wolbachia also can spread horizontally across individuals and species [3], [11], [12]. Colonization of the germline is a prerequisite for the infection to become successfully established into a population. We have previously shown that upon recent infection, Wolbachia colonize the stem cell niches in the Drosophila ovary, favoring vertical transmission after horizontal transfer [13]. Furthermore, stem cell niche tropism in the ovary is a highly evolutionarily conserved phenotype across the Drosophila genus, present in 100% of ovaries analyzed [14]. Wolbachia also infect the putative stem cell niches in the ovaries of other species, such as the bedbug and leafhopper [15], [16] indicating that the selective pressure for Wolbachia targeting of ovarian stem cell niches to favor transmission extends beyond the Drosophila genus.

Wolbachia have also been shown to display tropism to the stem cell niche present in the testis in Drosophila mauritiana [17]. However, the conservation of this phenotype across the Drosophila genus is unknown. Here we show that the evolutionary conservation of stem cell niche tropism present in females is not maintained in the male lineage. In fact, Wolbachia niche tropism in the testis, compared to the female results, represents a pronounced sexual dimorphism in the evolutionary history of Wolbachia stem cell niche tropism. Furthermore, we′ve identified that both Wolbachia and host factors modulate hub tropism in this system. Finally, we show that very closely related Wolbachia strains infecting the same host differ significantly in the densities at which they colonize the hub, indicating that hub tropism is a rapidly diverging phenotype in males.

Results

Wolbachia targeting of the hub in the Drosophila testis is not pervasive

In the testis, the germline stem cells (GSCs) and cyst stem cells (CySCs) reside at the “hub”, a structure at the apical tip of the testis (Fig. 1A). The hub is a group of 10 to 16 somatically derived cells forming the microenvironment supporting the stem cells, referred to as the niche [18]. It has been shown that the GSCs receive maintenance signals from both the hub and the CySCs, hence both are considered to be part of the stem cell niche for the GSCs. However for the context of this study, niche tropism in the testis refers to Wolbachia infection of the hub only. To investigate whether Wolbachia niche tropism is as pervasive in the hub, as previously shown in the ovary [14], we surveyed various Drosophila species infected with different strains of Wolbachia (Fig. 1; S1 Dataset; see S1 Table for the sources for the stocks used in this analysis).

Fig. 1. Diverse Wolbachia strains infect the hub of various Drosophila species at different frequencies and densities.
Diverse <i>Wolbachia</i> strains infect the hub of various <i>Drosophila</i> species at different frequencies and densities.
(A) Diagram of the testis apical tip, with cell nuclei in blue. The germline stem cells (GSCs, grey) and cyst stem cells (CySCs, yellow) reside at the hub (red). (B-J) Representative images of Wolbachia (green) hub tropism in 9 Drosophila species (hub marker, red; DNA, blue). (K) Quantification of the frequency of Wolbachia hub tropism in each Drosophila species (Error bars represent 95% confidence intervals). Letters indicate statistically significant groups (two-sample test for proportions). (L) Quantification of Wolbachia density in the hub, normalized to the surrounding tissue (Error bars represent SEM for average density across all samples). Letters indicate statistically significant groups (pairwise T-tests). [For each host/Wolbachia pair, abbreviations are as follows: D. ana wAna, Drosophila ananassae infected with Wolbachia ananassae. See S1 Table for details.]

Using confocal imaging and immunohistochemistry, we analyzed the density of Wolbachia infection in the hub cells as compared to the density of Wolbachia in the surrounding tissue (see Materials and Methods). We found that Wolbachia target the hub at varying frequencies and densities across the Drosophila genus (Fig. 1, S2 Table, S1 Dataset). 3 out of 9 species showed very little to no Wolbachia infection in the hub (Fig. 1 H–J, quantification in K), indicating that hub tropism is not pervasive across the Drosophila genus. 6 out of 9 species analyzed, however, did have Wolbachia tropism to the hub, ranging from 17% of niches infected to 95% of niches infected (Fig. 1 B–G, K, see also Materials and Methods). The 6 Drosophila species- Wolbachia strain pairs with hub tropism fall into two groups with significantly different frequencies and densities of tropism: 3 had very high frequencies and densities of hub infection: D. ananassae wAna, D. melanogaster wMel, and D. mauritiana wMau; and 3 had moderate frequencies of Wolbachia tropism to the hub: D. yakuba, wYak, D. tropicalis wWil, and D. simulans wRi. In the ovary, tropism to the somatic stem cell niche is found at high frequencies in every individual of all Drosophila species analyzed [14]. In contrast, tropism for the hub is found in only a fraction of the species analyzed.

Hub targeting does not correlate with germline stem cell niche tropism in the ovary

Similar to the results for hub tropism, the frequency of tropism to the germline stem cell niche (GSCN) in the ovary was shown to be variable across the Drosophila genus (Fig. 2A and [14]). We reasoned that Wolbachia tropism to the hub in the testis could simply be a byproduct of GSCN targeting in the ovaries. Interestingly, however, the presence of hub tropism does not correlate with the presence GSCN tropism (S3 Table, Correlation Test, p = 0.773). Although tropism in males and females is correlated in some strains (5 out of 9, e.g. wMau displays high frequencies of both hub tropism and GSCN tropism and wSh does not have tropism to either the hub or the GSCN), there are also others that do not (4 out of 9). The Wolbachia strain displaying one of the highest frequencies of GSCN tropism in the ovary (wNo, 99% [14]), displays no tropism to the hub (0%, Fig. 1 I and K). Conversely, a Wolbachia strain displaying a high frequency of tropism to the hub (wMel, 71%, Fig. 1 C and K) does not target the GSCN in the ovary (1%, [14]). These data reveal that Wolbachia stem cell niche tropism does not correlate with GSCN tropism in the female.

Fig. 2. Comparison of evolutionary conservation of niche tropism in males and females.
Comparison of evolutionary conservation of niche tropism in males and females.
Diagrams of ovary and testis displaying Wolbachia tropism (green) to the GSCN and hub, respectively, are shown at the top. Ovary data adapted from [14]. Color key at top right: Green  =  High hub/GSCN tropism, Blue  =  moderate hub/GSCN tropism, Red  =  low/no hub/GSCN tropism (see S3 Table for details). Pattern of Wolbachia tropism is evolutionarily conserved in the female ovaries (A), but not in the testis (B). There is no clear correlation of tropism pattern with the Wolbachia phylogeny in the testis as was seen in the ovaries (P = 0.773).

Hub tropism phenotype is independent of host and bacterial phylogenies

Previously, we have shown that the pattern of GSCN tropism is evolutionarily conserved across the Wolbachia lineage ([14] and Fig. 2). To assess whether hub tropism was also conserved across the Wolbachia lineage, we aligned the frequencies of hub tropism on the Wolbachia phylogenetic tree (Fig. 2). We quantified the correlation of hub tropism pattern with the Wolbachia phylogeny using a computer simulated model of randomized character distributions to compare with the distribution of niche tropism pattern on each of the phylogenies, as previously described [14]. We found that it is highly probable that the distribution of hub tropism is completely independent of the Wolbachia phylogeny (S2 Fig.). Similarly, when we compared hub tropism to the Drosophila phylogeny, we found no clear correlation between the two (S3 Fig.). Quantification of the relationship revealed that frequency of hub tropism bears no correlation with the Drosophila phylogeny (S4 Fig.).

Hub tropism does not correlate with cytoplasmic incompatibility

An important Wolbachia related phenotype that also bears no correlation with host or microbial phylogenies is cytoplasmic incompatibility (CI). CI is a reproductive phenotype resulting in reduced embryo hatching when a Wolbachia infected male mates with an uninfected female. We examined the possibility of a correlation between tropism to the hub and CI by comparing our tropism data to previously published reports on the levels of CI across the Drosophila genus (S4 Table) [19][23]. This analysis shows that some species with high levels of CI have different levels of tropism (i.e. wSh and wRi have 0% and 17% hub tropism, respectively). Conversely, some species with low levels of CI also have a wide range of hub tropism phenotypes (i.e. wTei and wMau have 2.3% and 71% hub tropism frequencies, respectively). Although hub tropism is highly divergent even amongst closely related strains of Wolbachia, similar to CI, there does not seem to be a correlation between these two phenotypes (S4 Table, Correlation test, p = 0.267).

Both host and bacterial factors can influence hub tropism

We next aimed to elucidate if host or bacterial factors influence the highly dynamic nature of the hub tropism phenotype. To investigate this question, Wolbachia strains backcrossed into a different host were used to assess Wolbachia strain versus host background influence on hub tropism, as previously described [14]. D. mauritiana wMau, which displays hub tropism (Fig. 1D and Fig. 3) and D. sechellia wSh, which does not display hub tropism (Fig. 1J and Fig. 3) and their hybrid offspring were utilized in this study (See Material and Methods).

Fig. 3. Both host and Wolbachia factors influence hub tropism.
Both host and <i>Wolbachia</i> factors influence hub tropism.
(A) Representative images of Wolbachia tropism to the hub in parental D. mauritiana and D. sechellia testis (top row) and F5 hybrid testis (bottom row) [Wolbachia, green; hub marker, red; DNA, blue]. Red and green arrows represent direction of Wolbachia transfer. (B) Quantification of frequency of hub tropism. Solid and hatched bars represent the parental and hybrid host species, respectively. Error bars represent 95% confidence intervals. Fisher Exact tests indicate that both the host genetic background and the Wolbachia strain have a significant effect on hub tropism (p = 8.309×10−5 and p = 2.267×10−10, respectively). (C) Quantification of Wolbachia density in the hub, normalized to the surrounding germline and soma. Linear regression analysis indicates that the Wolbachia strain, rather than the host genetic background, modulates Wolbachia density in the hub (P = 0.045 and P = 0.56, respectively).

Wolbachia strain wSh, infecting its native host, D. sechellia, and its non-native host, D. mauritiana, displays no hub localization, regardless of host genetic background (Fig. 3, S5 Table). This result suggests that Wolbachia wSh is incapable of hub tropism in either species. However it does not rule out the possibility that the hosts share a mechanism for excluding wSh from the hub. Therefore, a lack of tropism in both hosts cannot provide insight into whether the host or microbe is providing factors contributing to hub tropism.

The analysis of wMau hub tropism allows further probing into this question. Wolbachia strain wMau infecting its native host, D. mauritiana, and its non-native host, D. sechellia, displays tropism for the hub, suggesting that the Wolbachia strain is driving this phenotype. However, the frequency of targeting in the hybrid host is 3-fold lower than in the native host (Fig. 3C, green bars). Statistical analysis of frequency data indicates that both host genetic background and Wolbachia strain can significantly affect the frequency of hub tropism (Fisher's exact test, p = 8.309×10−5 and p = 2.267×10−10, respectively). These results are in contrast to previous data in the ovaries where only the Wolbachia strain drives tropism. wMau can efficiently target the GSCN in the ovary of both its native and hybrid host, greater than 80% of niches infected, regardless of the host genetic background [14]. The wMau frequency data in the male support the hypothesis that the Wolbachia strain is directing hub tropism. However, because the frequency of targeting is not as robust in the hybrid host compared to its native host, a role for the host is also implicated.

In relation to Wolbachia density in the hub, the data indicate that the Wolbachia encoded factors play a major role in both native and hybrid hosts. The overall density at which wMau infect the hub is conserved (Fig. 3 B and C, native host solid green bar, hybrid host hatched green bar, S4 Table). Similarly, wSh hub titers, compared to the surrounding tissue, are less than 1 in both native and hybrid hosts (Fig. 3 B and C, native host solid red bar and hybrid host hatched red bar, S4 Table). Linear regression analysis of density data indicates that the Wolbachia strain, rather than the host genetic background, modulates Wolbachia density in the hub (P = 0.045 and P = 0.56, respectively). With respect to both frequency and density, the overall data reveal that factors encoded by both the host species and the Wolbachia strain influence hub tropism in the Drosophila testis.

Wolbachia strain specific factors are sufficient for differences in hub tropism

To further investigate the role of Wolbachia on hub tropism, we then analyzed different Wolbachia strains in the same host species. We took advantage of D. simulans, which is a host to many different Wolbachia strains. We investigated two strains of D. simulans flies differentially infected with wRi and wNo and their backcrossed offspring. Flies were backcrossed to account for any genomic divergence between host strains, as previously described [14]. D. simulans flies infected with Wolbachia wRi display hub tropism in about 33% and 43% of hubs analyzed for the parental and backcrossed hosts, respectively (Fig. 4, S6 Table). D. simulans wNo displays hub tropism infrequently (2% and 15% of hubs highly infected for the parental and backcrossed hosts, respectively, Fig. 4, S6 Table). Although the frequencies of hub tropism for each Wolbachia strain increase in the backcrossed hosts, the general trend remains, where wRi targets the hub at a higher frequency than wNo. To quantify the relative contributions of host and bacterial factors towards hub tropism, logistical regression was performed. Wolbachia factors have a significant effect on hub tropism as compared to no significance of the host genetic background in the D. simulans hybrid flies (p = 0.0000552 and p = 0.927 respectively). These results indicate that when host factors are kept constant, Wolbachia strain factors are sufficient to significantly modulate the frequency of hub tropism.

Fig. 4. Wolbachia strain directs niche targeting in closely related Drosophila strains.
<i>Wolbachia</i> strain directs niche targeting in closely related <i>Drosophila</i> strains.
(A) Representative images of Wolbachia tropism to the hub in parental D. simulans strains 198 and 169 testis (top row) and F5 hybrid testis (bottom row) [Wolbachia, green; hub marker, red; DNA, blue]. Red and green arrows represent direction of Wolbachia transfer. (B) Quantification of frequency of hub tropism. Solid and hatched bars represent the parental and hybrid host species, respectively. Error bars represent 95% confidence intervals. Logistical regression confirms Wolbachia factors have a significant effect on hub tropism as compared to the host genetic background (p = 0.0000552 and p = 0.927 respectively).

Hub tropism is a rapidly diverging phenotype

In the previous analyses of hybrid crosses, hub tropism of distantly related Wolbachia strains were compared, first with different host species (Fig. 3), then within the same host species (Fig. 4). These results indicate that although the fly host can play a role in hub tropism, Wolbachia can significantly affect tropism on its own. In both cases, we were comparing Wolbachia strains from the A and B supergroups. We next investigated if the observed diversity of niche tropism is still present between more closely related Wolbachia strains. To address this question, we analyzed hub tropism of several Wolbachia strain variants infecting Drosophila melanogaster that diverged from a single ancestor within the last 8,000 years [24], [25].

Hub tropism of wMel-like (wMel, wMel2, and wMel3) and wMelCS-like (wMelCS, wMelCS2, and wMelPop) Wolbachia strains were analyzed. These Wolbachia strains were introgressed into the same D. melanogaster genetic background with the same microbiota [25]. The data reveal that the three wMel-like Wolbachia strains have significantly different tropism phenotypes from the wMelCS-like strains (Fig. 5, S7 Table). The wMel-like strains target the hub at similar frequencies, between 25% and 50%, and at similar densities, about 1.5-fold higher than the surrounding tissue. The wMelCS-like strains target the hub at significantly higher frequencies (P<0.05) and densities (P<0.001) than the wMel-like strains. Within the wMelCS-like group, wMelPop targets the hub at a significantly higher frequency (100%) than wMelCS2 (77%; P = 0.005), but not wMelCS (90%). However, wMelPop targets at a significantly higher density than both wMelCS and wMelCS2 (P<0.0001; S1 Movie). Interestingly, wMelPop densities increase to the point where the hub cells burst open in approximately 20% of hubs (S5 Fig. and S2 Movie). The finding that the wMel-like and wMelCS-like Wolbachia variants, all derived from a single ancestor only 8,000 years ago, have significantly different frequencies and densities of targeting indicates that hub tropism is a rapidly diverging phenotype.

Fig. 5. Closely related Wolbachia strains display rapidly divergent hub tropism phenotypes in Drosophila melanogaster.
Closely related <i>Wolbachia</i> strains display rapidly divergent hub tropism phenotypes in <i>Drosophila melanogaster</i>.
(A-F) Representative images of wMel-like strains: wMel, wMel2, wMel3; and wMelCS-like strains: wMelCS2, wMelCS and wMelPop infecting D. melanogaster hubs [Wolbachia, green; hub marker, red; DNA, blue]. (G) Quantification of frequency of hub tropism. The three wMel-like Wolbachia strains target the hub at similar frequencies, significantly different from the wMelCS-like strains. Frequencies with different letters are significantly different (two-sample test for proportions, error bars represent 95% confidence intervals). (H) Quantification of density of Wolbachia infecting the hub. The three wMel-like Wolbachia strains target the hub at similar densities, and are significantly different from the wMelCS-like strains. Means with different letters are significantly different from one another as determined by a t-test, error bars represent SEM.

Discussion

A fundamental aspect of Wolbachia-host interactions is the type of tissue preferentially infected by the bacteria. We have previously shown that Wolbachia tropism to the stem cell niches in the female Drosophila ovaries is important for vertical transmission, and that this tropism is ubiquitous across the Drosophila genus. Furthermore, closely related Wolbachia strains tend to display the same patterns of tropism in the ovary, indicating the importance of maintaining this phenotype for vertical transmission [14].

If the major role of niche tropism is related to Wolbachia transmission, evolutionary theory predicts that there should be reduced selective pressure to maintain niche tropism in males, since Wolbachia is not transmitted through the sperm. Patterns of Wolbachia niche tropism in the filarial nematode (B. malayi, D. immitis, L. sigmondontis, M. unguiculatus, and O. dewittei japonica) support this concept, where Wolbachia colonization of the distal tip cell (the nematode equivalent of the stem cell niche) and subsequent germline invasion occurs only in females [26]. In agreement, the results shown here indicate a reduced level of conservation of hub tropism phenotype, contrasting with previous observation in females [14]. The stem cell niches in the ovary and testis are well characterized and have several signaling pathways in common [27]. The robust sexual dimorphism in the evolutionary conservation of niche tropism, indicates that Wolbachia could be recognizing novel sex specific differences in these cells [28].

Wolbachia-induced host phenotypes related to stem cell biology and testis physiology have been previously described [17], [23]. We investigated whether hub tropism correlates with those known Wolbachia-related reproductive phenotypes. Because GSCN tropism in the ovary was shown to not be ubiquitous across the Drosophila genus, we reasoned that hub tropism could simply be a byproduct of GSCN tropism in the female. However, the frequencies of GSCN and hub tropism only correlate in 5 out of the 10 species and are not statistically significant.

On the cellular level, another phenotype we have previously shown was a Wolbachia-dependent increase in the rate of germline stem cell division (GSCD) in the ovaries of D. mauritiana. Although a similar trend exists in the D. mauritiana testis, the up-regulation of GSCD was not shown to be significant, showing a lack of conservation of a phenotype derived in the females to boost their spread [17].

A third important Wolbachia mediated phenotype, cytoplasmic incompatibility (CI), is a consequence of Wolbachia modification of sperm during spermatogenesis, causing embryonic lethality of uninfected eggs fertilized by sperm from infected males [reviewed by 29]. Although the precise mechanism is not well understood, the sperm from infected males is modified (mod+) and an infected egg with the appropriate rescue factor (resc+) is required for embryo viability [30], [31]. Several lines of evidence suggest that the modification of the sperm occurs at the chromatin level [32][34]. Extensive analyses of Wolbachia population dynamics and localization during spermatogenesis have demonstrated that CI is a non-cell autonomous effect caused by a diffusible Wolbachia factor during spermatogenesis [35]. Interestingly, local factors secreted by the hub can act on the germline stem cell. Since niche factors are extrinsic to the stem cell, they can affect the testis germline stem cell and consequently their sperm-forming progeny in a non-cell autonomous fashion. Niche factors have also been shown to cooperate with chromatin remodeling complexes towards control of germline stem cell maintenance and differentiation [36]. Therefore, we attempted to correlate our tropism data with published data regarding CI levels of several Wolbachia strains across the Drosophila genus. However, we found no correlation between Wolbachia hub tropism and CI, suggesting that Wolbachia's presence in the hub is not required for the CI effect. This suggests that either Wolbachia factors modify the sperm later in spermatogenesis or if Wolbachia-derived factors are affecting early spermatogenesis events towards CI, it is independent of Wolbachia infection of the niche.

Literature shows that both the host species and Wolbachia strains have rapidly evolving aspects that could contribute to the dynamic evolutionary changes in Wolbachia hub targeting shown here. Regarding the host, several testis specific genes, male seminal fluid proteins, and spermatogenesis genes have been shown to be rapidly evolving [37]. Furthermore, proteins related to GSC biology are also undergoing recurrent positive selection [38]. From the perspective of the bacteria, Wolbachia genomic analyses suggest that these bacteria have one of the most highly recombining intracellular bacterial genomes, with many genomic differences between closely related strains [39][42].

We investigated the relative contribution of both host and bacterial factors towards hub tropism phenotype. Unlike in the ovary where host derived factors did not play a role [14], in the testis, host factors could not be ruled out. When comparing distantly related Wolbachia strains and host species (D. mauritiana and D. sechellia hybrid lines), the data indicate that both host and Wolbachia derived factors contribute to the differences in hub tropism. One possibility is that there is selective pressure on the host driving rapid evolution of the hub intracellular environment to counteract negative effects of Wolbachia colonization of the testis niche. Although there is no evidence in the literature for positive selection of hub proteins, genes in the neighboring germline stem cell have been shown to be undergoing positive selection [38], [43]. Independent of differential host factors, we were able to confirm Wolbachia's role in hub tropism. By comparing distantly related Wolbachia strains in the same host species (D. simulans lines), we were able to confirm that Wolbachia derived factors significantly modulate hub tropism.

To assess how quickly this modulation of hub tropism can evolve, we investigated if very closely related Wolbachia strains that have recently diverged could display diverse hub tropism phenotypes. Several variants of the wMel strain of Wolbachia naturally infecting D. melanogaster exist [44], [45]. Due to strict maternal transmission, congruent Wolbachia and mitochondrial lineages made it possible to trace these lineages back to a single common D. melanogaster ancestor existing around 8,000 years ago [24], [25]. We investigated hub tropism of wMel-like (wMel, wMel2, and wMel3) and wMelCS-like (wMelCS, wMelCS2 and wMelPop) Wolbachia strains which have been shown to induce differential protection against viruses [25]. The wMel-like and wMelCS-like subgroups can be separated into three statistically distinct groups based on their density of hub infection (1: wMel, wMel2, and wMel3; 2: wMelCS and wMelCS2; 3: wMelPop), indicating that they have evolved distinct cellular tropisms. These data demonstrate that hub tropism is a rapidly diverging phenotype.

The fast paced changes in the hub tropism phenotype during the evolution of these different Wolbachia strains raises the questions of what mechanisms are driving these rapid changes and is adaptive evolution occurring. If Wolbachia tropism for the hub is causing an unfavorable phenotype in the host, a molecular arms race will result where both the host and microbe will rapidly evolve [46], [47]. We did not find any correlation of hub tropism with CI, germline stem cell division, or with other obvious testis related phenotypes. It is possible that hub tropism may have a phenotypic effect on the host, but at the moment these are unknown and we have no evidence supporting adaptive evolution in response to a host-microbe arms race driving rapid changes in hub tropism in wMel strains.

Another possibility is that genetic drift is driving the extreme divergence in hub tropism that we report here. At every generation, from embryonic development through the mature egg, Wolbachia undergoes several bottlenecks: only the Wolbachia present in the germplasm of the embryo will colonize the primordial germ cells [8], [10]. Within the germline, only the Wolbachia present in the oocyte is transmitted to the progeny [7], [9], [10]. This effectively reduces the genetic effective population sizes and increases the rate of fixation of mutations by drift. There are several studies highlighting the role of genetic drift driving high rates of genome sequence evolution in vertically transmitted endosymbionts [reviewed by 48]. The data presented here suggest that mutations that are neutral regarding niche targeting in the female may affect niche tropism in the male. If these mutations do not affect Wolbachia overall fitness in the females and do not interfere with transmission, they can be fixed by drift and result in significant niche tropism evolution in males.

At the moment it is difficult to identify the specific molecular underpinnings resulting in the differences in niche tropism phenotypes between these strains. A possible molecular player involved in hub tropism could be encoded by the gene region known as ‘octomom’. This region was found to be amplified several times in wMelPop, and contains genes predicted to be involved in DNA replication. It has been proposed to be responsible for the wMelPop over-replication phenotype [25], although there are conflicting reports [49]. This could explain the highest titers present in wMelPop-infected hubs. However, there are other unknown factors contributing to the range of hub tropism phenotypes observed in the other wMelCS-like and wMel-like strains, since they have only once copy of the octomom region. The wMel variants are defined by several polymorphic genetic markers [25], [44], [45], [49]. There are 108 single nucleotide polymorphisms (SNPs), a tandem duplication, and seven insertion-deletion polymorphisms between the wMel and wMelCS-like (wMelPop) strains [25]. Further characterization of niche tropism of different strains in the same host genetic background, together with additional sequencing of diverse strains, will allow the correlation of Wolbachia genomic features with patterns of niche tropism. Future identification of Wolbachia proteins modulating the different levels of hub tropism will provide insights into the evolutionary mechanism driving this rapid divergence in males and the robust sexual dimorphism of stem cell niche targeting.

Here we presented tropism differences in Wolbachia strains well characterized at the genomic level in a Drosophila species with a large repertoire of transgenic and genetic tools. These findings provide the foundation to dissect the molecular mechanisms involved in Wolbachia hub tropism. Furthermore, the differences in stem cell niche tropism between males and females may reveal sex specific differences in the biology of stem cell niche being recognized by Wolbachia. Identification of the Wolbachia factors involved in tissue tropism is fundamental in understanding how bacteria spread and infect their hosts in nature and will provide additional tools towards vector and disease control.

Materials and Methods

Fly stocks used for analysis

Fly stocks used in this analysis and their sources are listed in S1 Table. Drosophila species naturally infected with Wolbachia comprising the melanogaster subgroup were selected, along with two additional species outside the melanogaster subgroup: D. tropicalis and D. ananassae, belonging to the willistoni and ananassae subgroups, respectively. Introgression crosses for hybrid analysis experiments were performed as previously described [14]. D. melanogaster flies infected with the several wMel Wolbachia variants were introduced into the same genetic background as described elsewhere [25].

Fly husbandry

Flies were raised at room temperature and fed a typical molasses, yeast, cornmeal, agar food, with the exception of D. sechellia flies which were supplemented with reconstituted Noni Fruit (Hawaiian Health Ohana, LLC) [50].

Immunohistochemistry

For consistency and proper comparison to previous analysis of niche tropism in the female, males in this study were aged to seven days at room temperature (with the exception of the D. simulans hybrids for Fig. 4, which were dissected upon eclosion, see Toomey et al, 2013 for details). At least 20 flies were dissected for each sample, and total N's of hubs analyzed are listed in the Supplemental tables for each experiment. Testis were fixed using a 4% paraformaldehyde solution and subjected to immunostaining as previously described [13]. The mouse anti-hsp60 (Sigma, 1∶100) antibody was used to visualize Wolbachia. Hub markers were either rat anti-α-catenin (DSHB, DCAT1, 1∶40) or rat anti-DE-Cadherin (DSHB, DCAD2, 1∶20). Nuclei were counterstained with Hoechst (1 µg/ml, Molecular Probes).

Image analysis of Wolbachia niche tropism

Images of the hub were acquired using a FV1000 confocal microscope. Wolbachia signal intensity in the hub and surrounding area were measured in Z-stacks of images using MatLab software for image quantification. Manual masks were drawn around the hub structure as well as the surrounding soma and germline using only the hub marker and DNA. Wolbachia density was measured within each mask and Wolbachia infection of the hub was considered tropism if the density relative to the surrounding soma and germline was at least 1.5-fold increased. A 1.5-fold threshold for tropism was previously determined to best represent what visually appears to be a higher density of Wolbachia in the niche versus the surrounding tissue [14]. Raw data showing density ratios is provided in S1 Dataset.

Phylogenetic analyses

We utilized a computer simulation model of randomized character distributions to compare with the distribution of niche tropism pattern on each of the phylogenies to quantify the correlation of niche tropism pattern to the Wolbachia and Drosophila phylogenies (S1 and S3 Figs.) [51]. We used tree length as a measurement for goodness of fit for the distribution of a character, such as the tropism pattern, as aligned with the phylogeny. Tree length is defined as the total number of steps required to map a data set onto a phylogenetic tree.

Statistical analysis of data

To determine the three significant groups for tropism in Fig. 1, a two-sample test for proportions was used on frequency data (Fig. 1K) and T-tests were used for density data (Fig. 1L). A Bonferroni correction was applied to account for multiple comparisons.

To determine the significance of host genetic background versus Wolbachia strain (Fig. 4) on the frequency of hub tropism a logistical regression was performed on frequency data as previously described (Fig. 4B) [14]. When “zero” frequencies are present, logistic regression analysis was replaced by a Fisher Exact Test (Fig. 3B). For density data, a linear regression was performed (Fig. 3C).

To determine if the frequencies of targeting between Wolbachia strains were significantly different (Fig. 5B), a two-sample test for proportions was used. If there were more than two strains being compared a Chi-square test was performed. To determine if the differences in densities were significant, pair-wise t-tests were performed (Fig. 5C).

Supporting Information

Attachment 1

Attachment 2

Attachment 3

Attachment 4

Attachment 5

Attachment 6

Attachment 7

Attachment 8

Attachment 9

Attachment 10

Attachment 11

Attachment 12

Attachment 13

Attachment 14

Attachment 15


Zdroje

1. ChapmanT, ArnqvistG, BanghamJ, RoweL (2003) Sexual conflict. Trends in Ecology & Evolution 18: 41–47.

2. AvilaFW, SirotLK, LaFlammeBA, RubinsteinCD, WolfnerMF (2011) Insect seminal fluid proteins: identification and function. Annu Rev Entomol 56: 21–40.

3. BaldoL, AyoubNA, HayashiCY, RussellJA, StahlhutJK, et al. (2008) Insight into the routes of Wolbachia invasion: high levels of horizontal transfer in the spider genus Agelenopsis revealed by Wolbachia strain and mitochondrial DNA diversity. Molecular ecology 17: 557–569.

4. SchilthuizenM, StouthamerR (1997) Horizontal transmission of parthenogenesis-inducing microbes in Trichogramma wasps. Proc R Soc Lond B Biol Sci 264: 361–366.

5. WerrenJH (2011) Selfish genetic elements, genetic conflict, and evolutionary innovation. Proceedings of the National Academy of Sciences of the United States of America 108 Suppl 2: 10863–10870.

6. WerrenJH, BaldoL, ClarkME (2008) Wolbachia: master manipulators of invertebrate biology. Nat Rev Microbiol 6: 741–751.

7. FerreePM, Frydman, HM, LiJM, CaoJ, WieschausE, SullivanW (2005) Wolbachia Utilizes Host Microtubules and Dynein for Anterior Localization in the Drosophila Oocyte. PLoS Pathog 1: 111–124 (e114)..

8. HadfieldSJ, AxtonJM (1999) Germ cells colonized by endosymbiotic bacteria. Nature 402: 482.

9. SerbusLR, SullivanW (2007) A cellular basis for Wolbachia recruitment to the host germline. PLoS Pathog 3: e190.

10. VenetiZ, ClarkME, KarrTL, SavakisC, BourtzisK (2004) Heads or tails: host-parasite interactions in the Drosophila-Wolbachia system. Appl Environ Microbiol 70: 5366–5372.

11. BoyleL, OneillSL, RobertsonHM, KarrTL (1993) Interspecific and Intraspecific Horizontal Transfer of Wolbachia in Drosophila. Science 260: 1796–1799.

12. VavreF, FleuryF, LepetitD, FouilletP, BouletreauM (1999) Phylogenetic evidence for horizontal transmission of Wolbachia in host- parasitoid associations. Mol Biol Evol 16: 1711–1723.

13. FrydmanHM, LiJM, RobsonDN, WieschausE (2006) Somatic stem cell niche tropism in Wolbachia. Nature 441: 509–512.

14. ToomeyME, PanaramK, FastEM, BeattyC, FrydmanHM (2013) Evolutionarily conserved Wolbachia-encoded factors control pattern of stem-cell niche tropism in Drosophila ovaries and favor infection. Proc Natl Acad Sci U S A 110: 10788–10793.

15. HosokawaT, KogaR, KikuchiY, MengXY, FukatsuT (2010) Wolbachia as a bacteriocyte-associated nutritional mutualist. Proc Natl Acad Sci U S A 107: 769–774.

16. SacchiL, GenchiM, ClementiE, NegriI, AlmaA, et al. (2010) Bacteriocyte-like cells harbour Wolbachia in the ovary of Drosophila melanogaster (Insecta, Diptera) and Zyginidia pullula (Insecta, Hemiptera). Tissue Cell 42: 328–333.

17. FastEM, ToomeyME, PanaramK, DesjardinsD, KolaczykED, et al. (2011) Wolbachia enhance Drosophila stem cell proliferation and target the germline stem cell niche. Science 334: 990–992.

18. HardyRW, TokuyasuKT, LindsleyDL, GaravitoM (1979) The germinal proliferation center in the testis of Drosophila melanogaster. J Ultrastruct Res 69: 180–190.

19. CharlatS, NirgianakiA, BourtzisK, MercotH (2002) Evolution of Wolbachia-induced cytoplasmic incompatibility in Drosophila simulans and D. sechellia. Evolution Int J Org Evolution 56: 1735–1742.

20. ZabalouS, CharlatS, NirgianakiA, LachaiseD, MercotH, et al. (2004) Natural Wolbachia infections in the Drosophila yakuba species complex do not induce cytoplasmic incompatibility but fully rescue the wRi modification. Genetics 167: 827–834.

21. van MeerMMM, WitteveldtJ, StouthamerR (1999) Phylogeny of the arthropod endosymbiont Wolbachia based on the wsp gene. Insect Molecular Biology 8: 399–408.

22. VenetiZ, ClarkME, ZabalouS, KarrTL, SavakisC, et al. (2003) Cytoplasmic incompatibility and sperm cyst infection in different Drosophila-Wolbachia associations. Genetics 164: 545–552.

23. BourtzisK, NirgianakiA, MarkakisG, SavakisC (1996) Wolbachia infection and cytoplasmic incompatibility in Drosophila species. Genetics 144: 1063–1073.

24. RichardsonMF, WeinertLA, WelchJJ, LinheiroRS, MagwireMM, et al. (2012) Population genomics of the Wolbachia endosymbiont in Drosophila melanogaster. PLoS Genet 8: e1003129.

25. ChrostekE, MarialvaMS, EstevesSS, WeinertLA, MartinezJ, et al. (2013) Wolbachia variants induce differential protection to viruses in Drosophila melanogaster: a phenotypic and phylogenomic analysis. PLoS Genet 9: e1003896.

26. LandmannF, BainO, MartinC, UniS, TaylorMJ, et al. (2012) Both asymmetric mitotic segregation and cell-to-cell invasion are required for stable germline transmission of Wolbachia in filarial nematodes. Biol Open 1: 536–547.

27. DecottoE, SpradlingAC (2005) The Drosophila ovarian and testis stem cell niches: similar somatic stem cells and signals. Dev Cell 9: 501–510.

28. GilboaL, LehmannR (2004) How different is Venus from Mars? The genetics of germ-line stem cells in Drosophila females and males. Development 131: 4895–4905.

29. WerrenJH (1997) Biology of Wolbachia. Annu Rev Entomol 42: 587–609.

30. TramU, SullivanW (2002) Role of delayed nuclear envelope breakdown and mitosis in Wolbachia-induced cytoplasmic incompatibility. Science 296: 1124–1126.

31. PintoSB, StaintonK, HarrisS, KambrisZ, SuttonER, et al. (2013) Transcriptional regulation of Culex pipiens mosquitoes by Wolbachia influences cytoplasmic incompatibility. PLoS Pathog 9: e1003647.

32. O'NeillSL, KarrTL (1990) Bidirectional incompatibility between conspecific populations of Drosophila simulans. Nature 348: 178–180.

33. BreeuwerJA, WerrenJH (1990) Microorganisms associated with chromosome destruction and reproductive isolation between two insect species. Nature 346: 558–560.

34. BrennanLJ, HaukedalJA, EarleJC, KeddieB, HarrisHL (2012) Disruption of redox homeostasis leads to oxidative DNA damage in spermatocytes of Wolbachia-infected Drosophila simulans. Insect Mol Biol 21: 510–520.

35. RiparbelliMG, GiordanoR, CallainiG (2007) Effects of Wolbachia on sperm maturation and architecture in Drosophila simulans Riverside. Mech Dev 124: 699–714.

36. CherryCM, MatunisEL (2010) Epigenetic regulation of stem cell maintenance in the Drosophila testis via the nucleosome-remodeling factor NURF. Cell Stem Cell 6: 557–567.

37. HaertyW, JagadeeshanS, KulathinalRJ, WongA, Ravi RamK, et al. (2007) Evolution in the fast lane: rapidly evolving sex-related genes in Drosophila. Genetics 177: 1321–1335.

38. Bauer DuMontVL, FloresHA, WrightMH, AquadroCF (2007) Recurrent positive selection at bgcn, a key determinant of germ line differentiation, does not appear to be driven by simple coevolution with its partner protein bam. Mol Biol Evol 24: 182–191.

39. BaldoL, BordensteinS, WernegreenJJ, WerrenJH (2006) Widespread recombination throughout Wolbachia genomes. Mol Biol Evol 23: 437–449.

40. KlassonL, WestbergJ, SapountzisP, NaslundK, LutnaesY, et al. (2009) The mosaic genome structure of the Wolbachia wRi strain infecting Drosophila simulans. Proceedings of the National Academy of Sciences of the United States of America 106: 5725–5730.

41. BaldoL, DesjardinsCA, RussellJA, StahlhutJK, WerrenJH (2010) Accelerated microevolution in an outer membrane protein (OMP) of the intracellular bacteria Wolbachia. BMC Evol Biol 10: 48.

42. SioziosS, IoannidisP, KlassonL, AnderssonSG, BraigHR, et al. (2013) The diversity and evolution of Wolbachia ankyrin repeat domain genes. PLoS One 8: e55390.

43. ChoiJY, AquadroCF (2014) The coevolutionary period of Wolbachia pipientis infecting Drosophila ananassae and its impact on the evolution of the host germline stem cell regulating genes. Mol Biol Evol 31: 2457–2471.

44. RieglerM, SidhuM, MillerWJ, O'NeillSL (2005) Evidence for a global Wolbachia replacement in Drosophila melanogaster. Curr Biol 15: 1428–1433.

45. IlinskyY (2013) Coevolution of Drosophila melanogaster mtDNA and Wolbachia genotypes. PLoS One 8: e54373.

46. JigginsFM, HurstGD, YangZ (2002) Host-symbiont conflicts: positive selection on an outer membrane protein of parasitic but not mutualistic Rickettsiaceae. Mol Biol Evol 19: 1341–1349.

47. BrownlieJC, AdamskiM, SlatkoB, McGrawEA (2007) Diversifying selection and host adaptation in two endosymbiont genomes. BMC Evol Biol 7: 68.

48. MoranNA, McCutcheonJP, NakabachiA (2008) Genomics and evolution of heritable bacterial symbionts. Annu Rev Genet 42: 165–190.

49. WoolfitM, Iturbe-OrmaetxeI, BrownlieJC, WalkerT, RieglerM, et al. (2013) Genomic evolution of the pathogenic Wolbachia strain, wMelPop. Genome Biol Evol 5: 2189–2204.

50. AmlouM, MoreteauB, DavidJR (1998) Genetic analysis of Drosophila sechellia specialization: oviposition behavior toward the major aliphatic acids of its host plant. Behavior genetics 28: 455–464.

51. Maddison WP, Maddison DR (2005) MacClade; Analysis of phylogeny and character evolution. 4.08a ed. Sunderland, Massachussettz: Sinauer Associates. Pp.

52. ParaskevopoulosC, BordensteinSR, WernegreenJJ, WerrenJH, BourtzisK (2006) Toward a Wolbachia multilocus sequence typing system: discrimination of Wolbachia strains present in Drosophila species. Curr Microbiol 53: 388–395.

53. Maddison WP, Maddison DR (2005) MacClade: Analysis of phylogeny and character evolution. 4.08a ed. Sunderland, Massachusetts: Sinauer Associates.

54. JeffsPS, HolmesEC, AshburnerM (1994) The molecular evolution of the alcohol dehydrogenase and alcohol dehydrogenase-related genes in the Drosophila melanogaster species subgroup. Mol Biol Evol 11: 287–304.

Štítky
Hygiena a epidemiologie Infekční lékařství Laboratoř

Článek vyšel v časopise

PLOS Pathogens


2014 Číslo 12
Nejčtenější tento týden
Nejčtenější v tomto čísle
Kurzy

Zvyšte si kvalifikaci online z pohodlí domova

Svět praktické medicíny 3/2024 (znalostní test z časopisu)
nový kurz

Kardiologické projevy hypereozinofilií
Autoři: prof. MUDr. Petr Němec, Ph.D.

Střevní příprava před kolonoskopií
Autoři: MUDr. Klára Kmochová, Ph.D.

Aktuální možnosti diagnostiky a léčby litiáz
Autoři: MUDr. Tomáš Ürge, PhD.

Závislosti moderní doby – digitální závislosti a hypnotika
Autoři: MUDr. Vladimír Kmoch

Všechny kurzy
Kurzy Podcasty Doporučená témata Časopisy
Přihlášení
Zapomenuté heslo

Zadejte e-mailovou adresu, se kterou jste vytvářel(a) účet, budou Vám na ni zaslány informace k nastavení nového hesla.

Přihlášení

Nemáte účet?  Registrujte se

#ADS_BOTTOM_SCRIPTS#