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Wolbachia infection in the Chorthippus parallelus hybrid zone: evidence for its role as a reproductive barrier.

Introduction

The Pyrenean hybrid zone (HZ) of the orthopteroid Chorthippus parallelus (Acrididae: Gomphocerinae. Zetterstedt, 1821) is formed by Iberian endemism of C.p. erythropus (Cpe) with the continental European taxon C.p. parallelus (Cpp) (Reynolds 1980). The multiple morphological, cytogenetic, ecological, ethological and molecular studies done in recent years have contributed valuable information about this model for the study of the processes involved in genetic divergence and speciation (Butlin 1998, Shuker et al. 2005a).

The origin and establishment of this HZ is attributed to the isolation experienced by the ancestral populations of this grasshopper that, because of the Quaternary glaciations, formed refugia in the southernmost zones of the European continent: the Iberian, Italian and Balkan peninsulas. The retreat of the ice allowed these organisms to recolonize habitats from the south towards the north. auring this isolation and slow overall advance, allopatric genetic divergence between the Iberian populations and those of the rest of Europe took place, generating a panorama of "refugia into refugia" with a discontinuous distribution of Iberian populations (Bella et al. 2007). The barrier of the Pyrenees has prevented gene flow and maintained this separation between the two taxa, except in those regions where the topographic characteristics allow the formation of the aforementioned HZ: both ends of the mountainous barrier, and the areas and cross-sectional valleys that link Spain and France (Cooper et al. 1995, Hewitt 2004). The laboratory-produced F1 hybrids between the two pure subspecies strictly obey Haldane's rule, producing viable but sterile hybrid heterogametic X0 males (Hewitt et al. 1987, Bella et al. 1990). Current natural hybrids and populations are fit after the approximately 9,000 generations that have arisen since the origin of the HZ, during which recombination has broken down the gene complexes underlying the epistatic incompatibilities generated in allopatry (see also Shuker et al. 2005b).

The significance of an HZ (as a region where genetically different taxa hybridize and leave viable descendants) to this type of study is beyond dispute, but this example is especially relevant: we have recently noticed that Wolbachia (Rickettsiales) infects C. parallelus individuals inside and outside the HZ (Martinez et al. 2009, Zabal-Aguirre et al. 2010). A previous report had already detected this bacterium in the gut of C. parallelus (Dillon et al. 2008).

Wolbachia are gram-negative bacteria described as obligate endosymbionts of an enormous variety of invertebrates, such as insects, spiders, mites, crustaceans and nematodes. Transmission seems to be fundamentally maternal and it is accepted that up to 75% of invertebrate species can be infected (Hilgenboecker et al. 2008).

The interactions of this bacterium with the host are complex, potentially ranging from mutualism to pathogenesis. The "reproductive parasitism" that it often shows is remarkable, altering the reproduction of its host to facilitate its own transmission by the following mechanisms: i) Cytoplasmic Incompatibility (CI): crosses between infected males and uninfected females yield fewer or no descendants. This pattern is associated with the absence of fertilization or the death of the embryos. ii) Induction of Parthenogenesis: infected females are able to reproduce asexually from unfertilized ova. iii) Feminizing Effect: females carrying Wolbachia mainly yield females by selective death of male embryos, or infected male embryos develop like functional, morphologically normal females (Werren 1997, Moran et al. 2008, Serbus et al. 2008).

In this article we bring up to date our results concerning the distribution of Wolbachia in populations of C. parallelus inside and outside the HZ, as well as those about the phylogeny of the bacterium. We also present introductory results from experimental crosses set up to ascertain effects on the fecundity of infected individuals and on spermatogenesis.

Our findings are evidence of Wolbachia's capacity to induce or reinforce genetic divergence between organisms and contribute to the continuing debate about a model of "speciation by infection" (Wade 2001).

Distribution of Wolbachia in populations of Chorthippus parallelus

In a previous article (Zabal-Aguirre et al. 2010) we reported that populations of C. parallelus are infected to varying degrees by two strains of Wolbachia belonging to the B and F supergroups, as identified by Bayesian likelihood inference, based on their 16SrDNA genes (Giordano et al. 1995, Lo et al. 2002). Four categories of individuals and therefore of populations, are possible: infected by the B strain, by the F strain, co-infected (BF) and uninfected (0). The analysis of almost 5,000 individuals from 16 populations inside and outside the HZ enabled us to confirm that all the populations are infected by this bacterium, although to varying degrees. In general, we did not detect any statistically significant differences in patterns of infection between the sexes in these populations.

These differences in the proportions of the different types of infection (B, F, BF and O) from population to population, reveal three geographic patterns of distribution of the infection: northern, Iberian and hybrid. Northern-European locations show a low prevalence of infection and their individuals are mainly infected by the B strain. In Iberian populations, most grasshoppers carry Wolbachia, but have different proportions of B, F, BF and uninfected individuals. There is a north-south gradient between these two patterns along the HZ, from low to high frequencies of infection, but it is noticeable that in the hybrid population of Sallent de Gallego, which is geographically close to the middle of the HZ, a new pattern appears that is characterized by an extremely high degree of co-infection with the two Wolbachia types in its individuals. This co-infection peak in Sallent de Gallego was interpreted as existing through strong positive selection for individuals harboring both bacterial supergroup infections (Zabal-Aguirre et al. 2010); its cline coincides with a cytogenetic marker associated with the X-chromosome (Gosalvez et al. 1988, Serrano et al. 1996).

Our current results are consistent with those of the previous study. At present, we have data from approximately 7,000 individuals from 20 populations inside and outside the HZ. Updating our analyses confirms the existence of the aforementioned three biogeographical patterns, and provides further evidence for the presence of an infection area in the HZ for this north-south cline, between the two patterns generated by the frequencies of the types of the Wolbachia infection (Fig. 1, Table 1). This "hybrid zone pattern" also emerges from the phylogenetic analysis of these data (see below), highlighting the different, specific interaction between the bacterium and the hybrid grasshoppers.

Phylogeographic analysis of European populations of Wolbachia

A wide-ranging survey of Wolbachia-infected European populations of C. parallelus has been carried out in recent years. The bacteria from infected individuals from 14 populations from Spain, UK, Italy and France (Martinez-Rodriguez et al. in prep.; data not shown) have been characterized for their 16SrDNA, wsp gene, and a further five loci that make up a "Multi Locus Sequence Typing System" (MLST) specific to this bacterium (Baldo et al. 2006).

MLST genes (coxA, fbpA, hcpA, ftsZ and gatB) and wsp (Wolbachia surface protein) sequences in infected C. parallelus individuals were amplified and analyzed following the methods of Baldo et al. (2006). Identical nucleotide sequences at a given MLST gene of different samples were assigned the same arbitrary and unique allele number. A sequence type (ST) is characterized by the combination of the five MLST allele numbers: each ST corresponds to a different "strain". On the other hand, a ST complex is defined as a group of STs sharing at least three alleles, as defined above. This analysis allows us to discriminate the Wolbachia variability described in C. parallelus in two B- and 12 F- strains, and at least four ST- complexes.

The topology of the phylogenetic tree was constructed by Bayesian inference using the MrBayes 3.1 program (Ronquist & Huelsenbeck 2003) on the basis of concatenated MLST genes sequences. The GTR+G+I model of sequence evolution was selected using hierarchical likelihood ratio tests available in the jModeltest 3.7 program (Posada 2008). The two independent runs performed, each with four chains, reached convergence of the split frequencies after [10.sup.6] generations and a sample frequency of 100. The first 2,500 trees were discarded as burn-in, and the 50% majority rule was applied to the remaining set of trees.

[FIGURE 1 OMITTED]

The allelic profiles obtained are associated with the geographical distribution of the C. parallelus populations analyzed and concord with the northern, southern, and HZ patterns described above. However, we intend to extend this analysis with data from other European populations--from Norway, Germany, Italy and Slovenia; in doing so, we are open to the possibility that other ST complexes may appear.

The B supergroup (ST1 complex) homogenously infects both subspecies. The F supergroup is more variable than the B, with three ST complexes: ST2 infects pure Cpp populations and some hybrid populations on the other edge of the HZ; ST3 infects some populations in the center of the HZ; the ST4 complex infects pure and some hybrid populations on the edge of the HZ (Fig. 2a).

Wsp typing reveals a similar pattern (Fig. 2b). To date, six wsp types have been reported in pure (Cpe and Cpp) and hybrid populations. The Bayesian tree based on wsp sequences showed that the different lineages found in C. parallelus are clustered in three groups: wsp 1, 2 and 3 (F supergroup) in Cpe and hybrid populations; wsp 4 and 5 belong to the F supergroup, but they only appear in Cpp populations. However, wsp 6 clearly groups with the other Wolbachia that make up the B supergroup.

The analysis of allelic profiles in the ST3 complex reveals that some alleles of ftsZ, coxA and hcpA genes belong to the B supergroup, despite being characterized in F supergroup individuals by 16SrDNA, fbpA, gatB and wsp genes. These variant alleles constitute the ST3 complex and only appear in the center of the HZ.

[FIGURE 2 OMITTED]

[FIGURE 3 OMITTED]

The variations in the ST3 complex are interpreted as evidence of bacterial recombination between F and B supergroups (see also Werren & Bartos 2001). It is striking that they occur exclusively in the Pyrenean HZ between two subspecies of this grasshopper, and where their Iberian and northern infection patterns overlap (see above). Again, this is coincident with the hybrid area where we find the aforementioned HZ pattern for infection frequencies (the Sallent de Gallego hybrid population), supporting the idea of specific Wolbachia infection dynamics for the hybrids and the HZ (Zabal-Aguirre et al. 2010). No evidence for bacterial recombination has been found in populations outside the HZ.

Effects of Wolbachia on Chorthippus parallelus individuals and populations

Whole-cell hybridization (Amann et al. 1990, 1995; Garcia-Moyano et al. 2007) allows in situ localization of Wolbachia in squashed and even in paraffinized tissues of C. parallelus (Martinez et al. 2009). Short fluorescent monolabelled oligonucleotides target bacterial RNA for in situ hybridization in host cells and tissues. The large quantity of bacterial mRNA per cell produces an intense signal, which not only allows us to detect the bacteria, but also provides information about the distribution of the infection and its density.

In this study Martinez et al. (loc. cit.) showed that Wolbachia is widely distributed in different tissues of the infected individuals of C. parallelus, showing high bacterial density in male and female gonads. aifferences in bacterial density among tissues and individuals were also detected, but not quantified. Wolbachia is transmitted through the egg cytoplasm, which explains the high bacterial density in female gonads. However, high bacterial densities in male gonads may be related to the sperm modification by Wolbachia proposed by the "modification and rescue" model (Werren 1997, Charlat et al. 2001, Serbus et al. 2008). Wolbachia infection in the testes of C. parallelus seems to be homogeneous and all follicles are infected (Fig. 3). However, there is a notable cytoplasmic redistribution of bacteria during male meiosis: a progressive polarized organization occurs, with bacteria disappearing and aggregating at one of the poles of the prespermatic cell, finally disappearing in mature spermatic cells. The proposed sperm modifications by the "modification and rescue" model must therefore occur at the beginning of meiosis (Martinez et al. 2009).

The consequences of infection of male gametogenesis in C. parallelus have been quantified by analyzing the proportion of abnormal spermatids (morphology and size: aberrant, micro- and macro-spermatids) in pure populations of both subspecies and from infected and uninfected individuals from the hybrid Pyrenean population of Portalet (Fig. 4) (Bernal et al. in prep). Testicular follicles were squashed and stained with orcein and observed under light microscopy (Zeiss Standard, 40X). 1,500 spermatids were scored from each individual before their infection status was determined. The preliminary results obtained indicate an increasing frequency of abnormal spermatids, ranging from uninfected pure to infected hybrid individuals: more than 30,000 spermatids from 20 individuals from the corresponding categories (pure infected/uninfected individuals and infected/uninfected hybrids) were recorded and their abnormal spermatids scored. Pure uninfected individuals (independent of the subspecies) show 0.7% abnormal spermatids, which is comparable to the standard for other grasshoppers (Teruel et al. 2009). Uninfected hybrids display 2% abnormality, indicating some sort of genomic conflict and consistent with the idea of this HZ as a "tension zone", i.e., one maintained by a balance between the dispersal of individuals and selection operating against them (see Hewitt 1990, Shuker et al. 2005a, but also Shuker et al. 2005b). Wolbachia-infected pure individuals of Cpp and Cpe have more abnormal spermatids (3.2%), while this figure reaches 6% in hybrid-infected individuals. These differences are all statistically significant (data and analyses not shown).

[FIGURE 4 OMITTED]

This confirms that Wolbachia induces modifications in the male germinal cells of grasshoppers and reveals the existence of synergistic effects of the "hybrid" and "infected" traits: either of them separately induces irregular spermatids and, in conjunction, noticeably increase the frequency of irregularity. It is clearly difficult to judge the real effect of this production of aberrant spermatids on the fertility and fecundity of the affected individuals, since we cannot simply assume a direct relationship leading to a real reduction in the number of their descendants. Nevertheless, it should also be remembered that spermatogenesis is a complicated process and that the journey from spermatid to sperm is a long one. The percentage of cells not completing this process cannot be any lower than the numbers described here, but we cannot discount the possibility that the effects of Wolbachia on the sperm continue, even increasing this frequency of abnormal mature germ cells. There is other evidence of the effect of Wolbachia on cell division and sperm formation (Wade & Chang 1995, McGraw et al. 2001, Rances et al. 2008, Serbus et al. 2008).

In any case, this draws attention to a possibly important effect of Wolbachia on the dynamics of the HZ: the data presented below on the effect of the infection on the number of offspring arising from certain crosses support this idea, demonstrating the existence of uni- and bidirectional cytoplasmic incompatibility (CI) in the HZ. As stated above, Wolbachia infection in many organisms produces an alteration that reduces or impedes reproduction when the uninfected female is crossed with an infected male. This is called unidirectional CI. Similarly, interference through bidirectional CI has been described, wherein both the male and the female are infected by distinct bacterial strains (Moran et al. 2008, Serbus et al. 2008). Both reproductive alterations are present in our system (Table 2).

In order to ascertain the effects of Wolbachia in the HZ, we have analyzed the descendants of crosses between individuals from the Pyrenean hybrid population of Portalet. Regarding the Wolbachia infection, in this population all the possible types of individuals are represented (B- or F-infected, co-infected and uninfected) (Zabal-Aguirre et al. 2010). To ensure that the females were virgin, we initiated crosses with larvae. The crosses were blind, i.e., we did not know the infection status of the parents. This required us to establish a large number of crosses to ensure that all possibilities were sufficiently represented. As controls, we also made inter- and intrapopulational crosses with individuals from the pure populations of Escarrilla (Cpe) and Gabas (Cpp).

Finally, the descendants of 141 valid crosses between pure and hybrid individuals of Cp of the different types of infection were scored (close to 800 egg pods, more than 6,000 eggs) and the parents typed by the 16SrDNA and nested PCR analyses following Zabal-Aguirre et al. (2010) (Zabal-Aguirre et al. in prep.; data and analyses not shown).

To estimate possible Wolbachia-induced CI, the embryo proportions (number of embryos/number of eggs) from the crosses were compared. To check the potential effects of Wolbachia infection on female fecundity, we measured the number of eggs (quantity) and embryo proportions (quality) in females with different infection statuses from those crosses defined as compatible in Table 2.

The controls made with pure Cpp and Cpe individuals (collected in pure populations from both ends of the HZ) yielded no significant differences among intra- (Cpp x Cpp and Cpe x Cpe) or intersubspecific crosses (Cpp x Cpe and Cpe x Cpp). No significant differences between compatible pure and hybrid crosses were found. Nevertheless, in crosses susceptible to unidirectional CI (female uninfected x infected male. Table 2) there was a significant 32.5% reduction in the number of embryos obtained. A smaller reduction (16.4%) was found in the crosses susceptible to bidirectional CI. No significant differences in female fecundity were found with respect to infection status or pure/hybrid condition.

These results indicate the existence of cytoplasmic incompatibility in the HZ of C. parallelus. Other models show higher rates of incompatibility, but we should emphasize that these studies have usually been conducted under laboratory conditions. Studies performed in nature usually give rise to lower rates of incompatibility than those done in the laboratory (see Hoffmann et al. 1998). Our data come from experimental crosses set up in the field, a setting that more closely matches the natural conditions and mechanisms operating in these organisms within the HZ.

Wolbachia as a reproductive barrier in the Chorthippus parallelus hybrid zone

We now have distinct lines of evidence that Wolbachia markedly affects the dynamics of the C. parallelus HZ: the biogeographical distribution of bacterial strains and infected individuals and the phylogenetic data clearly indicate that the Pyrenean HZ is a "hot spot", with its own peculiar pattern of frequencies (the so-called "Sallent de Gallego pattern") and evidence of bacterial recombination events that appear to be exclusive to the contact zone (Martmez-Rodnguez, in prep.). Moreover, the analysis of spermatic cells clearly denotes that Wolbachia modifies the sperm of the infected individuals of C. parallelus. Considering the biogeographical distribution of the infection in these subspecies by itself, suggests the influence of the bacterium in the HZ. The remarkable observation that infected natural hybrid individuals have a significantly higher frequency of abnormal spermatids firmly supports this hypothesis. The demonstrated existence of the two types of cytoplasmic incompatibility operating in the HZ demonstrates Wolbachia to be an effective reproductive barrier in this case. Our current efforts attempt to model the influence of the distinct strains of the bacteria in the HZ, examining in greater depth the mechanisms that operate in Wolbachia and analyzing its maternal and horizontal transmission in our model.

The role of Wolbachia in inducing or reinforcing genetic divergence is a stimulating topic that has only recently attracted the attention of researchers. This bacterium has been proposed as a possible speciation agent (Werren 1998; Telschow et al. 2005, 2007), in the context of the "infectious speciation" model (Wade 2001). Some evidence for this exists in the wasp Nasonia (Werren 1997, Bordenstein et al. 2001, Bordenstein 2003) and the ant Acromyrmex (Van Borm et al. 2001). Our results contribute to the controversy in the form of data derived from natural populations of this well-known grasshopper.

The C. parallelus HZ is evidently the result of complex interactions involving genomic, genetic, cytogenetic, ethological and ecological factors, amongst others. We do not propose that the Wolbachia infection entirely explains the origin and maintenance of the HZ. However, we now know that we have to consider this new factor, since its influence is not negligible. These results raise other questions, a major one being whether the infection is recent or ancient. The answer is central to assessing the role of the bacterium in this HZ: in the case of Nasonia, for example, Wolbachia has a fundamental, but not unique, role in its reproductive isolation. However, the interactions between the nucleus, cytoplasm and bacteria are crucial and complex, establishing different cytotypes as a result of the relations between the nuclear, mitochondrial and bacterial DNAs (Bordenstein et al. 2001, 2003; Ellison et al. 2008). These cytotypes are those that interact, cooperate or compete, and ultimately explain the complicated circumstances in which we find Wolbachia.

The C. parallelus HZ joins the list of systems in which Wolbachia contributes to a reproductive barrier, in this case between the two subspecies Cpp and Cpe, and in a manner that we can quantify in nature. Other studies currently underway will allow us to assess the extent of this effect and its influence on the origin and maintenance of an HZ whose character is turning out to be even more fascinating than we had ever thought.

Acknowledgments

We are grateful to the Spanish Junta de Andalucfa, the Comunidad de Madrid, the Gobierno de Aragon, the Comunidad de Castilla y Leon, the Italian and French Alpes Maritime-Mercantour National Parc, and the French Parc National des Pyrenees for permission to collect grasshoppers. This work has been supported by the Spanish Grants CGL2009-08380/BOS and BFU2007-66340, and the collaboration of Chromacell S.L.

References

Amann R.I., Krumholz L., Stahl D.A. 1990. Fluorescent oligonucleotide probing of whole cells for determinative, phylogenetic, and environmental studies in microbiology. Journal of Bacteriology 172: 762-770.

Amann R.I., Ludwig W., Schleifer K.H. 1995. Phylogenetic identification and in situ detection of individual microbial cells without cultivation. Microbiology and Molecular Biology Reviews 59: 143-169.

Baldo L., Dunning Hotopp J.C., Jolley K.A., Bordenstein S.R., Biber S.A., Choudhury R.R.,Hayashi C., Maiden M.C.J., Tettelin H., Werren J.H., 2006. Multilocus sequence typing system for the endosymbiont Wolbachia pipientis. Applied Environmental Microbiology 72: 7098-7110.

Bella J.L., Hewitt G.M., Gosalvez J. 1990. Meiotic imbalance in laboratory produced hybrid males of Chorthippus parallelus parallelus and Chorthippus parallelus erythropus. Genetical Research 56: 43-48.

Bella J.L., Serrano L., Orellana J., Mason P.L., 2007. The origin of the Chorthippus parallelus hybrid zone: chromosomal evidence of multiple refugia for Iberian populations. Journal of Evolutionary Biology 20: 568-576.

Bordenstein S.R. 2003. Symbiosis and the origin of species, pp. 283-304. In: Bourtizs K., Miller T. (Eds). Insect Symbiosis. CRC Press, Boca Raton, Florida.

Bordenstein S.R., O'Hara F.P., Werren J.H. 2001. Wolbachia induced incompatibility precedes other hybrid incompatibilities in Nasonia. Nature 409: 707-710.

Bordenstein S.R., Uy J.J., Werren J.H. 2003. Host genotype determines cytoplasmic incompatibility type in the haplodiploid genus Nasonia. Genetics 163: 223-233.

Butlin R.K. 1998. What do hybrid zones in general, and the Chorthippus parallelus zone in particular, tell us about speciation? pp. 367-378. In: Howard D.J., Berlocher S.H. (Eds). Endless Forms: Species and Speciation. Oxford University Press. New York.

Charlat S., Calmet C., Mercot H., 2001. On the mod resc Model and the Evolution of Wolbachia Compatibility Types. Genetics 159: 1415-1422.

Cooper S.J., Ibrahim K.M., Hewitt G.M., 1995. Postglacial expansion and genome subdivision in the European grasshopper Chorthippus parallelus. Molecular Ecology 4: 49-60.

Dillon R.J., Webster G., Weightman A.J., Dillon V.M., Blanford S., Charnley A.K. 2008. Composition of Acridid gut bacterial communities as revealed by 16S rRNA gene analysis. Journal of Invertebrate Pathology 97: 265272.

Ellison C.K., Niehuis O., Gadau J. 2008. Hybrid breakdown and mitochondrial dysfunction in hybrids of Nasonia parasitoids wasps. Journal of Evolutionary Biology 21: 1844-1851.

Garcfa-Moyano A., Gonzalez-Toril E., Aguilera A., Amils R. 2007. Prokaryotic community composition and ecology offloating macroscopic filaments from an extreme acidic environment, Rio Tinto (SW, Spain). Systematic and Applied Microbiology 30: 601-614.

Giordano R., O'Neill S.L., Robertson H.M. 1995. Wolbachia infections and the expression of cytoplasmic incompatibility in Drosophila sechellia and D. Mauritania. Genetics 140: 1307-1317.

Gosalvez J., Lopez-Fernandez C., Bella J.L., Butlin R.K., Hewitt G.M. 1988. A hybrid zone between Chorthippus parallelus parallelus and Chorthippus parallelus erythropus (Orthoptera: Acrididae): chromosomal differentiation. Genome 30: 656-663.

Hewitt G.M. 1990. Divergence and speciation as viewed from an insect hybrid zone. Canadian Journal of Zoology 68: 1701-1715.

Hewitt G.M. 2004. Genetic consequences of climatic oscillations in the Quaternary. Philosophical Transactions Royal Society of London B 359: 183-195.

Hewitt G.M., Butlin R.K., East T.M. 1987. Testicular dysfunction in hybrids between parapatric subspecies of the grasshopper Chorthippus parallelus. Biological Journal of the Linnean Society 31: 25-34.

Hilgenboecker K. Hammerstein P. Schlattmann P. Telschow A. Werren J.H. 2008. How many species are infected with Wolbachia? A statistical analysis of current data. FEMS Microbiology Letters 281: 215-220.

Hoffmann A.A., Hercus M., Dagher H., 1998. Population dynamics of the Wolbachia infection causing cytoplasmic incompatibility in Drosophila melanogaster. Genetics 148: 221-231.

Lo N., Casiraghi M., Salati E., Bazzocchi C., Bandi C. 2002. How many Wolbachia supergroups exist? Molecular Biology Evolution 19: 341346.

McGraw E.A., Merritt D.J., Droller J.N., O'Neill S.L. 2001. Wolbachia-mediated sperm modification is dependent on the host genotype in Drosophila. Proceedings Royal Society of London B 268: 2565-2570.

Martinez P., Del Castillo P., Bella J.L. 2009. Cytological detection of Wolbachia in squashed and paraffin-embedded insect tissues. Biotechnic and Histochemistry 84: 347-353.

Moran N.A., McCutcheon J.P., Nakabachi A. 2008. Genomics and evolution of heritable bacterial symbionts. Annual Review of Genetics 42: 165-190.

Posada D. 2008. jModelTest: phylogenetic model averaging. Molecular Biology and Evolution 25: 1253-1256.

Rances E., Voronin D., Tran-Van V., Mavingui P. 2008. Genetic and functional characterization of the type IV secretion system in Wolbachia. Journal of Bacteriology 90: 5020-5030.

Reynolds W. J. 1980. A re-examination of the characters separating Chorthippus montanus and C. parallelus (Orthoptera: Acrididae). Journal of Natural History 14: 283-303.

Ronquist F., Huelsenbeck J.P. 2003. MrBayes 3: Bayesian phylogenetic inference under mixed models. Bioinformatic 19: 1572-1574.

Serbus L.R., Casper-Lindley C., Landmann F., Sullivan W. 2008. The genetics and cell biology of Wolbachia-host interactions. Annual Review of Genetics 42: 683-707.

Serrano L., Garcia de la Vega C., Bella J.L., Lopez-Fernandez C., Hewitt G.M., Gosalvez J. 1996. A hybrid zone between two subspecies of Chorthippus parallelus. X-chromosome variation through a contact zone. Journal of Evolutionary Biology 9: 173-184.

Shuker D.M., King T.M., Bella J.L., Butlin R.K. 2005a. The genetic basis of speciation in a grasshopper hybrid zone, pp. 427-454. In: Fellowes M., Holloway G., Rolff J. editors (Eds). Insect Evolutionary Ecology. CABI Publishing. Oxford University Press. Oxford.

Shuker D.M., Underwood K., King T.M., Butlin R.K. 2005b. Patterns of male sterility in a grasshopper hybrid zone imply accumulation of hybrid incompatibilities without selection. Proceedings Royal Society of London B 272: 2491-2497.

Telschow A., Hammerstein P., Werren J.H. 2005. The effects of Wolbachia versus genetic incompatibilities on reinforcement and speciation. Evolution 59: 1607-1619.

Telschow A., Flor M., Kobayashi Y., Hammerstein P., Werren J.H. 2007. Wolbachia induced unidirectional cytoplasmic incompatibility and speciation: mainland-island model. PLoS ONE Aug 8; 2(1):e701.

Teruel M., Cabrero J., Perfectti F., Alche J.D., Camacho J.P.M. 2009. Abnormal spermatid formation in the presence of the parasitic B24 chromosome in the grasshopper Eyprepocnemis plorans. Sex Development 3: 284-289.

Van Borm S., Wenseleers T., Billen J., Boomsma J.J. 2001. Wolbachia in leafcutter ants: a widespread symbiont that may induce male killing or incompatible matings. Journal of Evolutionary Biology 14: 805-814.

Wade M.J. 2001. Infectious speciation. Nature 409: 675-677.

Wade M.J., Chang N.W. 1995. Increased male fertility in Tribolium confusum beetles after infection with the intracellular parasite, Wolbachia. Nature 373: 72-74.

Werren J.H. 1997. Biology of Wolbachia. Annual Review of Entomology 42: 587-609.

Werren J.H. 1998. Wolbachia and speciation, pp. 245-260. In Berlocher S.H. Editor (Ed). Endless Forms: Species and Speciation. Oxford University Press, Oxford.

Werren J.H. Bartos J.D. 2001 Recombination in Wolbachia. Current 443 Biology 11: 431-435.

Zabal-Aguirre M., Arroyo F., Bella J.L. 2010. Distribution of Wolbachia infection of Chorthippus parallelus in populations within and beyond a Pyrenean hybrid zone. Heredity 104: 174-184.

Submitted May 5, 2010, accepted October 5, 2010

Jose L. Bella, Paloma Martinez-Rodriguez, Francisca Arroyo-Yebras, Aurora Bernal, JonAs Sarasa, Begona FernAndez-Calvin, Philip L. Mason and Mario Zabal-Aguirre

Departamento de Biologfa (Genetica), Facultad de Ciencias, Universidad Autonoma de Madrid, C/ Darwin 2, E-28049 Madrid, Spain. (PLM) Urban Studies, School of Social and Political Sciences, University of Glasgow, 28 Bute Gardens, Glasgow, G12 8RS, Scotland, United Kingdom.
Table 1. Infection frequencies in the C. parallelus populations
analyzed, with their location and altitude.

Population           B-infected   F-infected   Coinfected

Sabinanigo              0.05         0.91         0.05
Biescas                 0.00         0.56         0.41
Escarrilla              0.04         0.55         0.27
Sallent de Gallego      0.23         0.02         0.74
Corral de Mulas         0.12         0.15         0.32
Portalet                0.08         0.03         0.18
Cabana Antigua          0.10         0.01         0.20
Cabana Tourmont         0.18         0.08         0.01
L'Hermine               0.09         0.10         0.18
Soques                  0.16         0.04         0.21
Gabas                   0.19         0.00         0.03
Arudy                   0.24         0.09         0.05
Navafrfa                0.06         0.44         0.25
Becedas                 0.07         0.34         0.20
Bubion                  0.00         0.89         0.08
Epping Forest           0.40         0.00         0.00
Massif Centrale         0.30         0.10         0.00
Col de Larche           0.23         0.00         0.00
L'Argentera             0.34         0.06         0.03
Valdieri                0.21         0.00         0.00

                                   Number of
Population           Uninfected   individuals      Coordinates

Sabinanigo              0.00          22        42[degrees]31'06"N
Biescas                 0.03          34        42[degrees]37'31"N
Escarrilla              0.14          78        42[degrees]43'54"N
Sallent de Gallego      0.01          127       42[degrees]45'57"N
Corral de Mulas         0.41          123       42[degrees]47'09"N
Portalet                0.72          120       42[degrees]48'03"N
Cabana Antigua          0.69          99        42[degrees]48'51"N
Cabana Tourmont         0.73          84        42[degrees]49'11"N
L'Hermine               0.63          96        42[degrees]51'46"N
Soques                  0.60          82        42[degrees]50'07"N
Gabas                   0.78          91        42[degrees]53'60"N
Arudy                   0.62          66        43[degrees]07'00"N
Navafrfa                0.24          108       40[degrees]59'02"N
Becedas                 0.39          83        40[degrees]24'18"N
Bubion                  0.04          53        36[degrees]57'01"N
Epping Forest           0.60          15        51[degrees]39'36"N
Massif Centrale         0.60          10        44[degrees]28'43"N
Col de Larche           0.77          22        44[degrees]24'60"N
L'Argentera             0.57          35        44[degrees]14'00"N
Valdieri                0.79          33        44[degrees]12'00"N

Population              Coordinates      Altitude (m)

Sabinanigo           0[degrees]20'51"W       766
Biescas              0[degrees]19'39"W       848
Escarrilla           0[degrees]18'39"W      1,130
Sallent de Gallego   0[degrees]20'33"W      1,343
Corral de Mulas      0[degrees]23'34"W      1,569
Portalet             0[degrees]24'54"W      1,708
Cabana Antigua       0[degrees]25'05"W      1,695
Cabana Tourmont      0[degrees]24'21"W      1,625
L'Hermine            0[degrees]23'30"W      1,209
Soques               0[degrees]23'02"W      1,416
Gabas                0[degrees]25'60"W      1,020
Arudy                0[degrees]25'60"W       400
Navafrfa             3[degrees]49'00"W      1,710
Becedas              5[degrees]38'17"W      1,097
Bubion               3[degrees]21'22"W      1,300
Epping Forest        0[degrees]03'00"E       107
Massif Centrale      3[degrees]45'35"E      1,088
Col de Larche        6[degrees]52'60"E      1,942
L'Argentera          7[degrees]23'00"E       877
Valdieri             7[degrees]21'60"E      1,007

Table 2. Types of crosses and presumed cytoplasmic
incompatibilities (uni- and bidirectional) derived from the infection
status of the parental individuals. Key: c, compatible cross; UCI
and BCI, unidirectional and bidirectional cytoplasmic incompatibility,
respectively.

[male]
\[female]    O     B     F    BF

O            c    UCI   UCI   UCI
B            c     c    BCI   BCI
F            c    BCI    c    BCI
BF           c     c     c     c
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Author:Bella, Jose L.; Martinez-Rodriguez, Paloma; Arroyo-Yebras, Francisca; Bernal, Aurora; Sarasa, Jonas;
Publication:Journal of Orthoptera Research
Article Type:Report
Date:Jul 1, 2010
Words:5336
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