Induced Paternal Effects Mimic Cytoplasmic Incompatibility in Drosophila

doi:10.1534/genetics.105.052431

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Induced Paternal Effects Mimic Cytoplasmic Incompatibility in Drosophila

Michael E. Clark¹, Benjamin D. Heath¹, Cort L. Anderson² and Timothy L. Karr³

University of Chicago, Department of Organismal Biology and Anatomy, Chicago, Illinois 60637

^³ Corresponding author: University of Bath, Department of Biology and Biochemistry, 4 South Claverton Down, Bath BA2 7AY, United Kingdom.
E-mail: t.l.karr{at}bath.ac.uk

Manuscript received October 14, 2005. Accepted for publication February 4, 2006.

ABSTRACT

TOP
ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGEMENTS
LITERATURE CITED

Wolbachia is an intracellular microbe found in a wide diversityof arthropod and filarial nematode hosts. In arthropods thesecommon bacteria are reproductive parasites that manipulate centralelements of their host's reproduction to increase their ownmaternal transmission in one of several ways. Cytoplasmic incompatibility(CI) is one such manipulation where sperm are somehow modifiedin infected males and this modification must be rescued by thepresence of the same bacterial strain in the egg for normaldevelopment to proceed. The molecular mechanisms involved inthe expression of CI are unknown. Here we show that Wolbachiainfection results in increased mRNA and protein expression ofthe Drosophila simulans nonmuscle myosin II gene zipper. Inducedoverexpression of zipper in Wolbachia-free transgenic D. melanogastermales results in paternal-effect lethality that mimics the fertilizationdefects associated with CI. Likewise, overexpression of thetumor suppressor gene, lethal giant larvae [l(2)gl], resultsin egg lethality and a CI phenotype. Stoichiometric levels ofzipper and l(2)gl are required for proper segregation of cellulardeterminants during neuroblast stem cell division. Taken togetherthese results form the basis of a working hypothesis wherebyWolbachia induces paternal effects in sperm by manipulatingthe expression of key regulators of cytoskeletal activity duringspermatogenesis.

WOLBACHIA'S manipulation of central elements of reproductionhas long intrigued evolutionary biologists because of its potentialimportance as a driving force in directing the evolutionarytrajectories of populations (TURELLI and HOFFMANN 1995), asa possible mechanism of speciation (O'NEILL and KARR 1990; STOUTHAMER et al. 1999;BORDENSTEIN et al. 2001), as a potential tool for the biocontrolof insect pests (KARR 1994; ZABALOU et al. 2004; XI et al. 2005),and as a potential vehicle for the introduction of foreign DNAinto natural populations (TURELLI and HOFFMANN 1999). Estimatesof infection rates in arthropods range from 25–75%, makingWolbachia the most widely spread eubacterium known (WERREN et al. 1995;JEYAPRAKASH and HOY 2000). Maternally inherited, these reproductiveparasites have evolved a number of different strategies formanipulating host reproduction that result in their increasedtransmission through a population. Wolbachia-mediated manipulationof host reproduction includes feminization, male killing, inducedparthenogenesis, and cytoplasmic incompatibility (CI), a formof postfertilization reproductive failure in crosses of infectedmales to uninfected females (O'NEILL et al. 1997; STOUTHAMER et al. 1999).

Because Wolbachia is not present in sperm from infected malesand its presence has no effect on the processing of two majormale accessory gland proteins (BRESSAC and ROUSSET 1993; SNOOK et al. 2000),it most probably exerts its effect during earlier stages ofspermatogenesis. How and where this effect takes place is notknown.

Elucidation of the cellular and molecular mechanisms of CI wouldsignificantly advance our understanding of how Wolbachia manipulateshost reproduction and provide new insights into the mechanismsand dynamics of symbiosis. Wolbachia are obligate endocellularmicrobes that cannot be cultured outside the host; consequently,little is known about their molecular biology. Because of thepresumed effect of Wolbachia in the testis and the lack of specificinformation on Wolbachia genetics, we chose to focus on thehost's response to infection by looking for alterations in hostgene activity in infected testes. Here we describe a seriesof experiments in which we measured differential levels of geneexpression to obtain information on the mechanistic basis ofCI in male Drosophila. By manipulating gene expression in uninfectedmales we observed a reduction in egg hatch and a phenotype indistinguishablefrom CI. Our findings support the general hypothesis that Wolbachiaalter the expression of genes essential for normal sperm developmentin male Drosophila and thereby induce the male component ofCI.

MATERIALS AND METHODS

TOP
ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGEMENTS
LITERATURE CITED

Fly strains used:
Drosophila simulans:
The DSR strain from Riverside, California, (HOFFMANN et al. 1986)known to be infected by Wolbachia was obtained from M. Turelli(UC Davis). An uninfected strain (DSRT) was prepared by tetracyclinetreatment of the DSR strain as described (O'NEILL and KARR 1990).Prior to and following all experiments, the infection statusof these and the Drosophila melanogaster lines (see below) wasdetermined using the polymerase chain reaction and primers specificfor the Wolbachia 16S rDNA gene (O'NEILL et al. 1992). D. melanogasterTempe, a D. melanogaster line collected near Tempe, Arizona,in the spring of 1998, was used as a source of females. Thesefemales were found to be infected by Wolbachia and subsequentlycleared of infection using tetracycline. hs-zip (long), a hybridcDNA construct consisting of the hsp70 promoter attached 5'to a cDNA clone of the zipper gene, was a kind gift of D. Kiehart(YOUNG et al. 1993). hs-l(2)gl, a hybrid cDNA construct consistingof the hsp 70 promoter attached 5' to a cDNA clone of the l(2)glgene, was a kind gift of Chris Q. Doe.

cDNA subtraction library preparation and screening:
Testes from DSR and DSRT flies were dissected in sterile InsectRinger, and RNA and resident mRNA were isolated by binding tostreptavidin beads followed by magnetic separation (PolyATractmRNA Isolation System, Promega). First strand cDNA was synthesizedfrom the message isolated from infected testes as per manufacturer'sinstructions (Universal Riboclone cDNA Synthesis System, Promega).Single-stranded cDNA was hybridized to an excess of similarlyprepared mRNA from DSRT testes. Hybridized double-stranded DNA–RNAsequences common to both were separated by hydroxylapatite chromatographyand the remaining single-stranded cDNA was used as templatefor second strand synthesis (Universal Riboclone cDNA SynthesisSystem, Promega). The resultant double-stranded cDNA was clonedinto a lambda gt-11 phage vector and packaged in a commercialpackaging extract following manufacturer's protocol (Packagene,Promega). The resultant cDNA library was then screened for thosesequences unique to the testes of DSR. cDNA from testes of DSRand DSRT males was radiolabeled, and duplicate filter liftsof the plated library were probed with the respective populationsof mRNA. Clones that showed signal when probed with DSR-derivedcDNA, but lacked signal when probed with DSRT-derived DNA, werethen further investigated. Inserts from candidate clones weresubcloned into a plasmid vector and sequenced. Sequencing wascarried out using the ABI Prism Cycle Sequencing Dye TerminatorKit and an ABI 3777 automated sequencer. Identification of candidategenes was accomplished by submitting the sequences for a BLASTsearch (GenBank).

Immunoblotting of testes proteins:
zipper:
Testes from newly eclosed DSR and DSRT males (12–24 hr)were dissected in a drop of Ringer, rinsed once in Ringer, andground in 50 µl PBS in a 1.5-ml Kontes tube at 40°.After tissue disruption, samples were heated for 2 min at 95°to lyse cells. Protein concentrations were measured using Bio-Radprotein assay kit (Bio-Rad) using BSA as standard. Followingsolubilization in SDS, samples were boiled in the presence ofDTT and equal concentrations loaded onto 4–12% precastTris-Glycine gels (Novex). Proteins were electrophoresed at136 V for 2 hr and transferred onto PVDF-Plus transfer membrane(Micron Separations) using a semidry blotting apparatus (Pharmacia).Transfer was carried out over 2 hr at 60 mA constant current.Membranes were blocked for 1 hr in TBST (50 mM Tris–HCl,100 mM NaCl, 0.1% Triton X-100) containing 5% w/v nonfat drymilk (Carnation), washed three times for 5 min in TBST and incubatedwith an anti-zipper antibody (KIEHART and FEGHALI 1986) diluted1:2500 in TBST for 1 hr. The membrane was then washed threetimes for 5 min in TBST, followed by incubation for 1 hr inan alkaline phosphatase-conjugated goat anti-rabbit IgG (Jackson)diluted 1:2500. Anti-zipper immunoreactive bands were visualizedusing BCIP/Tetrazolium solution.

l(2)gl:
Testes of 3-day-old male DSR and DSRT reared at controlled densitywere dissected into PBS and their testes prepared for Westernimmunoblotting analysis using the Invitrogen NuPage system (Invitrogen,Paisley, UK). Samples were quantified using the EZQ proteinquantitation kit (Molecular Probes, Eugene, OR) and a Fujifilmphosphorimager. Equal amounts of protein were loaded with molecularweight markers and probed with a rat anti-l(2)gl (1:200) antibodyand with a mouse anti ${alpha}$ -tubulin antibody (Sigma) used as a loadingcontrol. Alkaline phosphatase-conjugated secondary antibodieswere used in conjunction with ECF Western blotting reagent (AmershamBioscieces, Little Chalfont, UK). A Fujifilm phosphorimagerwas used to acquire 14-bit data images (used to quantify therelative amount of the protein of interest on the blot and ensurethe loading controls are equal). For both immunoassays bandintensity was quantified using AIDA software (Raytest, Straubenhardt,Germany); indicated values are normalized using ${alpha}$ -tubulin asan internal control for equal loading.

CI measurement in hs-zip and hs-l(2)gl:
We used a sublethal heat treatment of 36° for 1 hr/day duringlarval development sufficient to induce zipper overexpression.The heat-shock regime was optimized for zip overexpression andlarval viability. The protocol relied on the minimal heat-shockregimen needed to elevate Zipper levels to near those observedin DSR, while minimizing effects on viability. We found thata 1-hr heat treatment of third instar larvae at 36° resultedin sufficient Zipper increases while resulting in <25% pupallethality. The same regimeregimen was used for the hs-l(2)glflies. All experiments used males or females that were grownunder standard conditions as described (SNOOK et al. 2000) exceptas follows: first instar crawling larvae were transferred tofresh cornmeal/agar food vials (50 larvae/vial), treated at36° for 1 hr, and returned to 25°. Daily 1-hr heat treatmentscontinued until eclosion when males were separated into freshfood vials and maintained for 24 hr. Males received a finalheat treatment 6–12 hr prior to mating, were allowed torecover for 6 hr, and were mated to uninfected wild-type females(females were aged for 1 week prior to mating). Control experimentswere performed using the same cohort of first instar larvaewithout heat treatment or heat-treated wild-type first instarlarvae. Additional heat-treatment controls, using both wild-typeD. melanogaster and D. simulans males, were also performed (notshown). In all cases male viability was the same in all controlsamples as determined by Mann-Whitney statistical tests. Measurementof CI was carried out as described (SNOOK et al. 2000). CI isreported as the fraction of unhatched eggs, calculated as thenumber of unhatched eggs/total number of eggs (Table 1). NonparametricMann–Whitney statistical analyses were performed usingStatview (Abacus).

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TABLE 1 Effect of Zipper and Lgl on CI expression

Test for rescue of incompatibility:
The CI measurement assay using the hs-zip flies was repeated,except this time larvae heat treated from the third instar wereused to test whether the developmental stage at which zipperexpression is increased affected the proportion of unhatchedeggs. We additionally tested whether this incompatibility couldbe rescued by the presence of Wolbachia in the egg by crossingheat-treated hs-zip males with Wolbachia-infected females andmeasuring CI as previously described.

Tissue fixation, staining, and confocal microscopy:
Embryos were fixed and stained using the DROP 1.1 anti-spermtail antibody as described (KARR 1991) and nuclei stained withPropidium Iodide (Molecular Probes) following treatment with2 mg/ml RNAase (Promega). Confocal optical sections were obtainedusing either a Zeiss LSM 510 or a Leica DM IRB microscope. Imageswere projected along the z-axis and displayed using associatedZeiss image analysis software. Images were annotated and printedusing Photoshop 7.0 (Adobe).

RESULTS

TOP
ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGEMENTS
LITERATURE CITED

Identification of host genes with altered expression due to Wolbachia infection:
The screening of a subtraction cDNA library prepared from mRNAof infected and uninfected D. simulans Riverside males (DSRand DSRT, respectively) (HOFFMANN et al. 1986; O'NEILL and KARR 1990)identified seven candidate DSR cDNA clones of which one wasrepresented twice and the others were either very short unidentifiedsequences or vector sequences. Subsequent DNA sequencing anddatabase searches identified the two positive clones as theDrosophila nonmuscle myosin II gene zipper. Alignment of 660nucleotides shows only two changes resulting in two substitutionsin the inferred amino acid sequence. Thus, Wolbachia-infectedtestes overexpress zipper mRNA relative to genetically identicaluninfected flies. In concert with the mRNA results we foundincreased levels of zipper protein on immunoblots of testisextracts (Figure 1A).

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FIGURE 1.— Western blot analysis of expression of zipper and l(2)gl in testes of 3-day-old Drosphila. (A) l(2)gl and zipper expression in D. simulans (Riverside) infected (DSR) and uninfected with Wolbachia (DSRT). (B) Effect of heat treatment (indicated +/–) on expression of l(2)gl and zipper in transgenic D. melanogaster carrying a construct with the indicated gene linked to a heat-shock promoter. Band intensity was quantified using AIDA software (Raytest). Values were normalized using ${alpha}$ -tubulin as an internal control for equal loading (not shown). Bars show normalized mean band intensity values (± 1 SE). Sample size (n) is shown below each bar. The bands shown represent typical results.

Phenotypic analysis of zipper overexpression in D. melanogaster:
Increased levels of zipper mRNA and protein in infected D. simulansled us to examine the effect of zipper overexpression in uninfectedD. melanogaster lines. Heat-shock treatment of an hs-zip line(see MATERIALS AND METHODS) resulted in increased levels ofZipper in the testes (Figure 1B) with little overall effecton viability and sperm production (not shown). However, whenheat-treated hs-zip males were crossed to wild-type femalesthe proportion of unhatched eggs was significantly higher thanin crosses with non-heat-treated hs-zip males or heat-treatedwild-type males (Figure 2A, Table 1). We conclude that, withregard to egg-hatch rates, increasing Zipper levels in malesresulted in a CI-like phenotype.

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FIGURE 2.— Proportion of eggs unhatched in crosses between wild-type D. melanogaster females and heat-treated Wolbachia-free transgenic D. melanogaster males. + or – sign indicates presence or absence of heat-shock regime during development. (A) Overexpression of zipper. (B) Overexpression of l(2)gl.

CI in D. simulans has a well-characterized early lethal embryonicphase (LASSY and KARR 1996). We therefore examined early developmentin fertilized eggs from these crosses (Figure 3). Normal zygotedevelopment is characterized by synchronized and evenly spacednuclear divisions (FOE and ALBERTS 1983; ZALOKAR and ERK 1976)clearly observed in eggs fertilized by control and non-heat-treatedhs-zip males (Figure 3, A and B). Conversely, heat-treated transgenichs-zip males displayed numerous chromosomal abnormalities (Figure 3, C–F).These early postfertilization anomalies are very similar tothose observed in incompatible CI crosses previously describedin D. simulans (LASSY and KARR 1996) and D. melanogaster (CLARK et al. 2005).An unambiguous assay for fertilization is visualization of thesperm tail localized in the anterior region of the egg (KARR 1991)(Figure 3, A and G, arrow) eliminating the trivial possibilitythat heat treatment rendered males sterile or otherwise incapableof producing fertilization-competent sperm. We therefore concludethat increasing Zipper levels in males leads to fertilizationdefects similar to those observed in CI crosses.

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FIGURE 3.— Expression of CI in hs-zip flies and hs-l(2)gl flies. Confocal images of fertilized eggs visualized by indirect immunofluorescence using an anti-sperm tail primary antibody (A, C, G), a DNA-specific green dye (A–C), propidium iodide (D–F and H), and an anti- ${alpha}$ -tubulin antibody (green) (E and H). (A and B) Control crosses displaying normal egg development when fertilized by (A) non-heat-treated males (arrow, sperm tail) or (B) wild-type males. (C–F) Fertilization defects observed in crosses using heat-treated hs-zip males. (G and H) Typical examples of the early lethal phenotype observed in an incompatible cross between a heat-treated hs-lgl male and a wild-type female (H).

Late overexpression of zipper reduces penetrance of the CI-like phenotype:
Overexpression of zipper from the third larval instar resultedin weaker CI effect compared to when zipper was overexpressedfrom the first instar onward (Figure 2A, Figure 4). This indicatesthat the strength of the effect may increase with earlier overexpressionand/or depends on total time over which zipper is overexpressedin the testes.

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FIGURE 4.— Proportion of eggs hatching in crosses between wild-type D. melanogaster females, infected (T) and uninfected (TT) with Wolbachia and hs-zip males, heat treated during development from the third larval instar, or not heated (nohs).

The CI phenotype cannot be rescued by Wolbachia in the egg:
In contrast to expectations, the presence of Wolbachia in theegg did not rescue the CI-like phenotype (Figure 4); the crossbetween hs-zip males and Wolbachia-infected wild-type femalesresulted in even stronger incompatibility than crosses withuninfected females (Figure 4). This result was consistentlyobserved in repeat experiments and clearly indicates additiveor synergistic interactions of unknown character.

Overexpression of zipper results in a spermatogenesis phenotype:
In addition to causing a CI phenotype in fertilized eggs, overexpressionof zipper during spermatogenesis resulted in minor defects indeveloping spermatid bundles. This defect was most easily seenin elongating bundles where the normally apically localizedsperm nuclei were found scattered along the length of the cyst(Figure 5). Although not obvious in this particular projectionof the data stack, cyst cell nuclei are easily distinguishableby their unique morphology and their location at the peripheryof the spermatid bundle. Therefore, the other elongated nucleiobserved (Figure 5, arrows) are presumed sperm nuclei that havebecome displaced from the apical region during elongation. Thesedefects are present prior to spermatid individualization andwere not observed in non-heat-treated hs-zip males or in heat-treatedwild-type males (data not shown).

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FIGURE 5.— Aberrant sperm cyst from a heat-treated hs-zip male. Two ends of the same elongated, pre-individualized sperm cyst. (A) Spermatid nuclei are normally all apically located in a bundle of nuclei (arrowhead). Abnormal spermatid nuclei are also seen scattered along the length of the cyst (A, arrows). Abnormal spermatid nuclei are less needle-like farther from the apical nuclei bundle (B, arrows). ccn, cyst cell nuclei. Bar, 10 µm.

Overexpression of l(2)gl also results in a CI-like phenotype:
The product of l(2)gl, Lgl (also known as P127), is known tophysically interact with Zipper in the specification of cellpolarity during germ-line stem cell divisions and mutationsin zip strongly suppress the l(2)gl mutant phenotype (STRAND et al. 1994a;PENG et al. 2000). We therefore examined the effect of overexpressingl(2)gl in males from a transgenic line carrying a wild-typecopy of l(2)gl driven by an hsp70 promoter. First, we examinedthe endogenous level of l(2)gl in the testes of DSR and DSRTmales and found them to be indistinguishable (Figure 1A). Wethen determined that a heat-shock regime similar to that usedfor hs-zip resulted in increased Lgl in the testes (Figure 1B).We then measured egg viability in crosses between heat-shockedmales and control (uninfected) wild-type females (Figure 2B,Table 1). Again, highly significant reduction in egg hatch wasobserved, suggesting that overexpression of l(2)gl in malessimilarly resulted in a CI phenotype. Finally, fertilizationdefects were also observed similar to those observed in bothDSR-incompatible and heat-treated hs-zip crosses (Figure 3, G and H).

DISCUSSION

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ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGEMENTS
LITERATURE CITED

Zipper overexpression results in a paternal effect:
Under the conditions used, transient zipper overexpression isnot lethal and results in mature and motile sperm capable offertilization. These sperm, although able to penetrate the eggand activate development, are, like sperm from DSR males, incapableof supporting zygote formation and subsequent nuclear divisions.This phenotype is similar to both a paternal effect gene, ms(3)K81(YASUDA et al. 1995; LOPPIN et al. 2005), and Wolbachia-inducedCI (LASSY and KARR 1996). These results suggest that increasedzipper expression during spermatogenesis is causally linkedto the expression of CI in D. simulans. How does increased zipperexpression in the testes result in defects in fertilizationand early egg development? zipper has been extensively studiedover the past decade where its action in important morphologicalevents during early embryogenesis is well known (KIEHART and FEGHALI 1986;KIEHART 2003), although the role of cytoplasmic myosin in spermatogenesisand fertilization is not known and has yet to be specificallyexamined (D. KIEHART, personal communication). However, heterozygouszip¹/+ males generate fully mature, fertilization-competentsperm that do not exhibit either a CI phenotype or reductionin egg viability (M. CLARK and T. L. KARR, unpublished observations),suggesting, as expected for a recessive gene, that reductionin Zipper is not detrimental to sperm function and zygote viability.Therefore the effect appears specific to overexpression of Zipper.Further studies on the mechanism by which increased Zipper resultsin a paternal effect that mimics CI is currently under studyin our laboratory. As discussed below, one avenue of explorationinvolves interactions with the tumor suppressor gene l(2)gl,a gene intimately associated with zipper function (STRAND et al. 1994b;BARROS et al. 2003).

Males overexpressing zipper were also shown to have weakly penetranteffects on spermatid development (Figure 5). Although the roleof zipper in this process is yet to be determined, another closelyrelated myosin, myosin IV (jaguar), does have an essential function(TUXWORTH and CHIA 2003) during spermatid individualization,and zipper is present in individualization cones (data not shown).It therefore remains to be determined if zipper function duringthese stages of development is the site of action that elicitsCI.

Wolbachia does not rescue Zipper-induced paternal effect.
Curiously, the presence of Wolbachia did not rescue egg lethalityin our experiments. In fact, Wolbachia resulted in measurablyhigher levels of egg lethality suggesting synergistic effects.There are two possible explanations for these findings. First,although counterintuitive, the result may indicate negativeinteractions not previously observed that reflect inherent differencesin the CI modification/rescue systems used by these two species.Second, the heat-treatment regimens used to elevate Zipper inD. melanogaster could only approximate Zipper levels in theDSR lines. Additionally, inherent differences in endogenousZipper levels and any differential effects of elevated Zipperin these two species may further confound interpretation ofthe results. The more straightforward approach to measure CIusing hs-zip D. simulans transgenic flies, although technicallymore challenging, is currently planned.

A working model for CI in D. melanogaster:
Zipper and Lgl perform crucial functions during embryonic developmentthat may provide clues to their role in sperm dysfunction wehave described. They both clearly have a central role in theasymmetric neuroblast divisions in the embryo. Neuroblasts divideasymmetrically to generate a series of smaller, more differentiatedganglion mother cells (GMCs). During each asymmetric division,several proteins/mRNAs are specifically partitioned into theGMC, and this process of protein localization requires the activityof l(2)gl (PENG et al. 2000). The products of l(2)gl and zipperphysically interact (STRAND et al. 1994b), and mutations inzipper strongly suppress the l(2)gl phenotype, suggesting thatthe l(2)gl phenotype is due to an imbalance in levels of Zipperprotein (OHSHIRO et al. 2000; PENG et al. 2000). By analogy,the imbalance in the levels of Zipper in Wolbachia-infectedmales observed may disrupt protein localization during the asymmetricdivisions of the spermatogonial stem cells, leading to similarmislocalization in important determinative factors and ultimatelyto defective sperm. Our finding that l(2)gl overexpression alsoresults in a CI phenotype is consistent with the hypothesisthat balanced expression of zipper and l(2)gl are required fornormal sperm development and an imbalance results in modifiedsperm leading to CI (Figure 6). We note that perturbations inthe levels of Zipper and Lgl result in subtle cellular phenotypesas in both instances the affected stem cells go on to produceeither neurons (pathfinding defects) or motile sperm (fertilizationdefect) that fail to function later in development.

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FIGURE 6.— Hypothesis that zipper overexpression causes developmental abnormalities in sperm leading to CI in males.

One major deficiency in this model is that it fails to explainwhy the modification cannot be rescued by the presence of Wolbachiain the egg. In fact, contrary to expectations, the presenceof Wolbachia in D. melanogaster females results in a significantreduction in egg viability (Figure 4). These experiments werehighly repeatable and indicate a more complex scenario for therole of these genes in the mechanism of CI; they do, however,demonstrate an interaction of Wolbachia with this system. Thissurprising result may be related to the well-known differencesin the levels of CI expression between D. simulans and D. melanogaster(HOFFMANN et al. 1986; HOFFMANN and TURELLI 1988) making comparisonsof the zipper effect problematical. Further studies aimed atoverexpressing zipper in D. simulans are currently underwayin which a more direct test of rescue can be performed.

Wolbachia-induced overexpression of host gene expression maybe an effective strategy used by Wolbachia to affect sperm functionduring fertilization. Two mechanisms not necessarily mutuallyexclusive, induced or enhanced transcription and/or mRNA stabilization,could result in the overexpression observed. As such, Wolbachia-inducedhost gene expression represents a unique form of neomorphicmutation and raises many important questions about the natureof incompatibility and host/symbiosis. For example, does zipper-inducedreproductive failure suggest a model for multiple incompatibilitytypes like those previously observed in D. simulans (O'NEILL and KARR 1990)and Nasonia (BREEUWER and WERREN 1990)? Perhaps different strainsof Wolbachia will likewise be associated with overexpressionof different specific host genes in the testis.

ACKNOWLEDGEMENTS

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ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGEMENTS
LITERATURE CITED

The hs-l(2)gl line was a generous gift of Chris Q. Doe (Universityof Oregon); the hs-zip line was generously provided by Dan Kiehart(Duke University). This work was generously funded by the NationalScience Foundation USA (MCB-0135166), the Royal Society, andthe Biotechnology and Biological Sciences Research Council UK.

FOOTNOTES

¹ These authors contributed equally to this work.

² Present address: College of Natural Resources, University ofIdaho, P.O. Box 1136, Moscow, ID 83844-1136.

LITERATURE CITED

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MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGEMENTS
LITERATURE CITED

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Communicating editor: D. M. RAND

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