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Drosophila Sperm Swim Backwards in the Female Reproductive Tract and Are Activated via TRPP2 Ion Channels

  • Michael Köttgen ,

    Contributed equally to this work with: Michael Köttgen, Alexis Hofherr, Weizhe Li

    michael.koettgen@uniklinik-freiburg.de (MK); twatnick@jhmi.edu (TW)

    Current address: Division of Nephrology and Spemann Graduate School, University Medical Center Freiburg, Freiburg Germany

    Affiliations Division of Nephrology, Department of Medicine, Johns Hopkins University School of Medicine, Baltimore, Maryland, United States of America, Departments of Biological Chemistry and Neuroscience, Center for Sensory Biology, Johns Hopkins University School of Medicine, Baltimore, Maryland, United States of America

  • Alexis Hofherr ,

    Contributed equally to this work with: Michael Köttgen, Alexis Hofherr, Weizhe Li

    Current address: Division of Nephrology and Spemann Graduate School, University Medical Center Freiburg, Freiburg Germany

  • Weizhe Li ,

    Contributed equally to this work with: Michael Köttgen, Alexis Hofherr, Weizhe Li

    Affiliation Division of Nephrology, Department of Medicine, Johns Hopkins University School of Medicine, Baltimore, Maryland, United States of America

  • Kristy Chu,

    Affiliation Division of Nephrology, Department of Medicine, Johns Hopkins University School of Medicine, Baltimore, Maryland, United States of America

  • Stacey Cook,

    Affiliation Division of Nephrology, Department of Medicine, Johns Hopkins University School of Medicine, Baltimore, Maryland, United States of America

  • Craig Montell,

    Affiliation Departments of Biological Chemistry and Neuroscience, Center for Sensory Biology, Johns Hopkins University School of Medicine, Baltimore, Maryland, United States of America

  • Terry Watnick

    michael.koettgen@uniklinik-freiburg.de (MK); twatnick@jhmi.edu (TW)

    Affiliation Division of Nephrology, Department of Medicine, Johns Hopkins University School of Medicine, Baltimore, Maryland, United States of America

Abstract

Background

Sperm have but one purpose, to fertilize an egg. In various species including Drosophila melanogaster female sperm storage is a necessary step in the reproductive process. Amo is a homolog of the human transient receptor potential channel TRPP2 (also known as PKD2), which is mutated in autosomal dominant polycystic kidney disease. In flies Amo is required for sperm storage. Drosophila males with Amo mutations produce motile sperm that are transferred to the uterus but they do not reach the female storage organs. Therefore Amo appears to be a mediator of directed sperm motility in the female reproductive tract but the underlying mechanism is unknown.

Methodology/Principal Findings

Amo exhibits a unique expression pattern during spermatogenesis. In spermatocytes, Amo is restricted to the endoplasmic reticulum (ER) whereas in mature sperm, Amo clusters at the distal tip of the sperm tail. Here we show that flagellar localization of Amo is required for sperm storage. This raised the question of how Amo at the rear end of sperm regulates forward movement into the storage organs. In order to address this question, we used in vivo imaging of dual labelled sperm to demonstrate that Drosophila sperm navigate backwards in the female reproductive tract. In addition, we show that sperm exhibit hyperactivation upon transfer to the uterus. Amo mutant sperm remain capable of reverse motility but fail to display hyperactivation and directed movement, suggesting that these functions are required for sperm storage in flies.

Conclusions/Significance

Amo is part of a signalling complex at the leading edge of the sperm tail that modulates flagellar beating and that guides a backwards path into the storage organs. Our data support an evolutionarily conserved role for TRPP2 channels in cilia.

Introduction

The evolutionary success of sexual reproduction depends on the ability of motile sperm cells to find an egg and fertilize it. Different animals have evolved distinct and elaborate mechanisms to accomplish this essential task but female sperm storage is a commonly used strategy in species ranging from insects to mammals. In Drosophila melanogaster, female sperm storage is critical for maximal reproductive success [1]. Approximately 4000 sperm are transferred to a Drosophila female during mating but ∼80% are expelled from the uterus when the first egg is laid [2]. The remaining sperm are stored for up to two weeks in two types of female storage organs, a single seminal receptacle and a pair of spermathecae [2]. Stored sperm can be used for fertilization in the absence of continued mating.

There is relatively little known about the factors that govern sperm storage in the female reproductive tract. In flies, male accessory gland proteins contribute to this process and sperm derived from Drosophila males that are lacking the seminal fluid protein Acp36DE are inefficiently transferred from the uterus to the sperm storage organs [3], [4], [5]. Acp36DE is thought to mediate sperm storage by inducing favourable conformational changes in the female reproductive tract [5].

We have previously shown that Amo is a sperm enriched protein that is essential for fertility and sperm storage in Drosophila melanogaster [6]. Amo is a homolog of the human transient receptor potential channel TRPP2, encoded by the Polycystic Kidney Disease 2 gene (PKD2) [6], [7]. Mutations in human PKD2 result in autosomal dominant polycystic kidney disease [8]. TRPP2 channels are evolutionarily conserved, calcium-permeable nonselective cation channels that are localized in the endoplasmic reticulum (ER) and in cilia, but the physiological function of these ion channels in vivo is poorly understood [9], [10], [11], [12], [13], [14]. Drosophila males with amo mutations are sterile; they produce motile sperm that are transferred to the uterus but the sperm do not reach the female storage organs [6], [7]. Taken together the data suggests that Amo could be a mediator of directional sperm movement.

In the present study we investigate the role of Amo in sperm motility within the female reproductive tract. We show that although Amo is expressed in the endoplasmic reticulum (ER) during earlier stages of spermatogenesis, it is the flagellar localization at the tip of the sperm tail, which is critical for making sperm storage competent. This finding coupled with Amo's role in directional sperm movement prompted us to hypothesize that Drosophila sperm might swim tail first. We used in vivo imaging of dual labelled sperm to demonstrate that wild type Drosophila sperm do in fact navigate backwards in the female reproductive tract. In addition, we discovered that sperm exhibit activated flagellar beating upon transfer to the uterus. Amo mutant sperm remain capable of reverse motility but fail to display hyperactivation, suggesting that activated flagellar beating is a requirement for sperm storage in flies.

Results

Flagellar Amo is required for proper Sperm Storage

Drosophila males with Amo mutations produce motile sperm that are transferred to the uterus but do not reach the female storage organs (Figure 1A–D, Figure S1A–C and Video S1 and S2). To gain insights into the physiological function of Amo we studied its cellular distribution in the male germline. Amo exhibits a unique and distinct expression pattern during spermatogenesis (Figure 1). In spermatocytes, Amo is localized in the endoplasmic reticulum (ER, Figure 1 E and F) as shown by co-localization with the ER marker protein disulfide isomerase (Figure S2) [15]. In mature sperm, however, Amo clusters at the tip of the sperm tail (Figure 1G and H). This expression pattern closely resembles the distribution of mammalian TRPP2, which is also found in the ER and in primary cilia [10]. It is unknown which localization of TRPP2 is functionally important. In Drosophila, Amo might be required in the ER of developing spermatocytes to make sperm storage-capable later in development. Alternatively, since TRPP2 channels are thought to have an evolutionarily conserved role in ciliary signalling, we hypothesized that the flagellar localization of this ion channel might be essential for regulating directional motility and sperm storage [16], [17].

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Figure 1. Amo is Expressed in the Male Germ Line and is Required for Sperm Storage in Drosophila.

A. Amo mutant males are sterile. Progeny produced from mating wild type and amo−/− males with wild type females (n = 10). B. Schematic model of the Drosophila male reproductive system. Testis (t), seminal vesicles (sv), accessory gland (ag), ejaculatory duct (ed). C, D. Female reproductive tract after mating with wild type (C) or amo−/− sperm (D) (sperm tails labelled with dj-GFP: green, DAPI-labelled nuclei: blue; scale bar: 100 µm). In (D) there are no sperm in either the seminal receptacle or the spermathecae. E. Expression pattern of Amo in testis (anti-Amo: green, nuclear DAPI staining: blue; scale bars 50 µm); inset: Amo staining in amo−/− testis. F. Intracellular localization of Amo in spermatocytes (scale bars 50 µm); inset: Amo staining in amo−/− testis. G. Fluorescence labelling of mature sperm (anti-Amo: green, concavalin A: red, DAPI: blue; scale bar 20 µm). H. Localization of Amo in mature sperm (anti-Amo: green; scale bar 20 µm).

https://doi.org/10.1371/journal.pone.0020031.g001

In order to investigate this question, we took advantage of a mutation in human TRPP2, D511V, which causes autosomal dominant polycystic kidney disease [18]. This missense amino acid substitution has been reported to eliminate TRPP2 channel function in vitro and to act in a dominant negative fashion in over-expression systems [12], [19]. This is presumably because TRPP2 forms multimeric complexes that require all subunits to be functional. We mutated the corresponding aspartate in Drosophila Amo to valine (AmoD627V) (Figure 2A), and then expressed wild type and AmoD627V transgenic channels in amo mutant flies. The wild type transgene rescued the sperm storage phenotype and its subcellular distribution was identical to that of the native protein (Figure 2B–H, Figure S1A–D, and Figure S3). In contrast, AmoD627V was unable to restore normal levels of sperm storage (Figure 2B and Figure S1E). Although the mutant protein could be detected in the ER of spermatocytes (Figure 2I and J), it was absent at the tip of the mature sperm tail (Figure 2K), suggesting that this mutation resulted in a flagellar trafficking defect in vivo. To test whether AmoD627V acts in a dominant negative fashion we co-expressed wild type and mutant AmoD627V in amo null flies and found that male sterility could still be fully rescued (Figure 2B, Figure S1F, Figure S4, and Figure S6). Since both wild type and mutant forms of Amo are expressed in the ER but only wild type Amo is found at the tip of the sperm tail, the lack of a dominant negative effect is likely due to the failure of AmoD627V to be incorporated into the flagellar pool of Amo, which is required for sperm storage. These results are consistent with the idea that localization at the distal end of the sperm tail is essential for Amo function in vivo.

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Figure 2. Amo Localization at the Tip of the Sperm Tail is Required for Sperm Storage.

A. The human ADPKD patient mutation PKD2D511V maps to the third transmembrane domain of PKD2, left panel. The aspartate in postition 511 (highlighted in red) is highly conserved throughout evolution (right panel). B. Fertility tests with amo mutant males mated to wild type females reveal that loss of amo is rescued by transgenic expression of either 1 or 2 copies wild type Amo but not by AmoD627V on the 3rd chromosome (black bars: no transgene, dark grey: one copy of transgenic Amo, light grey: two copies of the transgenes, white: transheterozygous males; N = 10). C–K. Subcellular localization of Amo in testis and mature sperm. Localization of native Amo in testis, spermatocytes and mature sperm of WT males (C–E), amo mutant males expressing a wild type Amo transgene (F–H) or the AmoD627V transgene (I–K). Scale bars for testis and spermatocytes (C, D, F, G, I, J): 50 µm; for sperm tails (E, H, K): 20 µm.

https://doi.org/10.1371/journal.pone.0020031.g002

Drosophila Sperm Move Backwards in the female reproductive tract

The requirement for Amo at the flagellar tip coupled with its pivotal role in directed sperm motility prompted us to ask how Amo could regulate head first movement? We hypothesized that sperm might travel in reverse or tail first rather than in a forward direction. In order to explore this possibility, we adapted methods that allowed us to assay directional sperm movement within the female reproductive tract in real time [20]. We generated male flies with dual colour sperm: sperm tails labelled with green fluorescent protein (GFP) and heads labelled with red fluorescent protein (RFP) (Figure 3). This combination of tags allowed us to use high-speed confocal microscopy to track the course and direction of sperm movement (Videos S1, S2, S3, S4, S5, and S6). We show that sperm in the female reproductive tract move backwards both in the uterus and in the seminal receptacle (Figure 3C and D and Video S3). Of 222 sperm observed in 11 independent experiments, all but two sperm heads trailed the sperm tail (Figure 3D). This establishes that Drosophila sperm swim backwards in the female reproductive tract in vivo. This pattern of directed motility has not been reported for sperm of any other species.

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Figure 3. Drosophila Sperm Navigate Backwards in the Female Reproductive Tract.

A. Schematic model of the Drosophila female reproductive system. Ovary (ov), spermathecae (sp), seminal receptacle (sr), uterus (ut). B. Schematic of a mature sperm, showing the acrosome in pink and the sperm tail in green. C. Drosophila sperm tracking in the seminal receptacle (sperm tail labeled with dj-GFP: green, sperm head labeled with Prot-B-DsRed: red). D. The vast majority of sperm swim backward (n = 222 sperm, N = 11 flies).

https://doi.org/10.1371/journal.pone.0020031.g003

Amo Mutant Sperm are Capable of Backward Swimming

The localization of Amo at the rear end of the flagellum makes it an appealing regulator of reverse sperm motility. One can envision two potential roles for Amo in this process. Amo might be required for the specific flagellar waveforms that result in backward motion. In this scenario, Amo mutant sperm would be expected to lack reverse motility. Alternatively, reverse motility could be the default direction for Drosophila sperm and Amo might act as a sensor at the leading edge, serving a distinct pathfinding function. In order to test these possibilities, we generated amo mutant flies producing dual labelled sperm and mated these males to wild type female. We found that amo mutant sperm still are capable of backwards swimming, both in the uterus and in the seminal receptacle (N = 13; of 143 sperm only 9 showed forward movement, Video S4). Therefore, factors other than impaired backward swimming directionality must cause the sperm storage defect in amo mutant sperm.

Drosophila Sperm exhibit Amo-dependent Activation in the Uterus

To characterize sperm motility patterns in both wild type and amo mutant sperm we analyzed beat frequency and swimming speed in vitro and in vivo, respectively. We found that wild type sperm released from the uterus immediately after mating have a significantly higher beat frequency when compared to sperm released from the male seminal vesicle, suggesting that Drosophila sperm undergo an activation step similar to what has been described for capacitated mammalian sperm (Figure 4A) [21], [22]. Although the baseline beat frequency of amo mutant sperm was similar to wild type, they failed to demonstrate an increase in beat frequency when released from the uterus (Figure 4A). This defect in sperm activation was rescued by a wild type amo transgene. To test whether the decreased beat frequency of amo mutant sperm translated into altered swimming speed of sperm in vivo, we tracked the movement of sperm heads in the uterus (Figure 4B and Video S5). Consistent with the observed decrease in beat frequency, the swimming speed of amo mutant sperm in the uterus was reduced significantly when compared to wild type sperm (Figure 4C and Figure S5). In addition, the dynamic distribution of sperm was altered in the amo mutant. Immediately after mating, wild type sperm clustered near the entrance of the sperm storage organs in the upper third of the uterus (Figure 4D), whereas amo mutant sperm did not show this distribution pattern (Figure 4E). Taken together, these defects in sperm function are likely to explain the inability of amo mutant sperm to reach the female sperm storage organs.

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Figure 4. Amo Regulates Sperm Beat Frequency, Swimming Speed and Dynamic distribution in the Uterus.

A. The sperm beat frequency is higher in sperm dissected from mated uteri (N = 22, wild type, solid bars) compared with sperm dissected from seminal vesicles (N = 26 wild type, hatched bars). The intrauterine increase in sperm beat frequency is absent in amo mutant sperm (N = 20 seminal vesicles, hatched bars N = 30 uteri solid bars) but is rescued upon expression of a wild type amo transgene in an amo null background (N = 22 seminal vesicles, N = 20 uteri). B. Tracking of an individual amo−/− sperm head (scale bar 20 µm). C. Average sperm speed in the female reproductive tract (calculated from N = 7 experiments). D. Representative tracking experiment of wild type sperm in the female reproductive tract (scale bar 40 µm, pseudocolor depicts the time of tracking during the experiment: 1000 frames/experiment). E. Representative tracking experiment of amo mutant sperm in the female reproductive tract (scale bar 20 µm).

https://doi.org/10.1371/journal.pone.0020031.g004

Discussion

In the current study we demonstrate that Amo, a member of the TRPP2 ion channel family, is required at the distal end of the sperm flagellum for directed sperm transit to the female storage organs. This is consistent with a conserved role for TRPP2 (aka polycystin-2 or PKD2) channels in ciliary structures. In C. elegans, TRPP2 is found at the ciliated endings of male specific sensory neurons where it is postulated to sense cues from its mate, resulting in stereotypical male mating behaviours [23], [24]. Similarly, in mammals, TRPP2 localizes to primary cilia on renal epithelial cells as well as embryonic node cells and is thought to function as a mechanosensitive channel [14], [25], [26], [27], [28]. Therefore, TRPP2 channels appear to play a sensory role in a variety of ciliary contexts.

Amo's unique distribution in the flagellum led us to investigate the behaviour of sperm in the female reproductive tract. Our studies reveal several novel findings. First, we used real-time analysis of sperm expressing red and green fluorescent proteins in the head and tail respectively to show that shortly after mating, wild type Drosophila sperm travel backwards in the uterus and seminal receptacle. As far as we know, this type of motility has not been reported for sperm of any other species. One potential rationale for this type of directional movement is that it would permit sperm to “back in” to the female storage organs. This is supported by analyses of sperm organization within the female seminal receptacle [29], [30]. Sperm in the proximal portion of the seminal receptacle have been observed to cluster in a dense mass with heads pointed toward the entrance of the receptacle while the tails extend distally. Teleologically this is an attractive arrangement since sperm clustered with their heads toward the opening of the seminal receptacle would be available to exit head first, facilitating fertilization of eggs arriving from the oviduct.

Secondly we show that wild type Drosophila sperm acquire hyperactivated flagellar beating upon transfer to the female uterus. This is similar to mammalian sperm capacitation, a process that “switches on” spermatozoa, thus rendering them capable of fertilizing an egg [22], [31]. Hyperactivated motility is a characteristic feature of the capacitated sperm phenotype and is critical for fertilization. Hyperactivation is required for penetration of the zona pellucida as well as for sperm release from the oviduct, which serves as a sperm storage reservoir in some mammals. Acquisition of hyperactivated motility appears to be triggered by an increase in intracellular calcium that depends on the activity of the Catsper family of sperm enriched calcium channels [32], [33].

Amo is a logical mediator of sperm motility in Drosophila. In addition to its favourable localization in the sperm tail, TRPP2 proteins are calcium permeable non-selective cation channels [17]. Analysis of sperm motility in Amo mutant sperm reveal that they are capable of generating a backward trajectory but they exhibit clear defects in hyperactivation and swimming speed and they fail to accumulate near the entrance to the storage organs. Therefore, reverse movement may be necessary but is not sufficient for sperm storage to occur.

In summary we show that Amo localization defines a unique niche at the leading edge of sperm, which are traveling tail first. Activation of Amo serves to modulate flagellar beating and guides a backward trajectory into the sperm storage organs. In keeping with an evolutionarily conserved sensory role for TRPP2 channels in cilia we postulate that Amo is ideally located to receive cues upon transfer to the female reproductive tract. The nature of the stimuli to which the TRPP2 channel complex responds remains a matter of investigation. But in the light of our data and recent evidence from vertebrate models it is tempting to speculate that ligands rather than mechanical cues are critical for triggering TRPP2-mediated signalling [16], [27], [34].

Materials and Methods

Flies and husbandry

Amo knockout flies (amo1) have been described [6]. Transgenic flies expressing wild type and mutant Amo (D627V) were generated by BestGene Inc. (USA) using site-specific recombination with an attP landing site on the second chromosome (Bloomington stock number 9732) [35]. The genomic rescue construct contained the genomic region of amo, (CG6504) and approximately 1 kb of 5′ flanking sequence [6]. The mutation in the amo (CG6504) genomic rescue construct was generated by site-directed mutatgenesis using standard procedures. We sequenced all constructs to verify that no errors were introduced by PCR. Flies expressing the wild type and mutant genomic rescue constructs were crossed into the amo null background for analysis of fertility, sperm storage and sperm dynamics. Flies expressing Protamine-B-labelled with red fluorescent protein (ProtB-DsRed) on the third chromosome were kindly provided by John Belote and a line expressing don-juan-GFP (dj-GFP) on the third chromosome was obtained from Barbara Wakimoto [20], [36]. These lines were recombined to yield a strain expressing both fluorescent proteins on the same third chromosome. Flies expressing GFP tagged protein disulfide isomerase were obtained from Bloomington (stock number 6839). All flies were reared according to standard procedures and maintained at 25°C.

Immunofluorescence

Dissection and preparation of testis and sperm as well as the anti-Amo antiserum (1∶3000) have been described [6]. Anti-rabbit Alexa fluor® 488 antibodies (1∶1000; Molecular Probes, USA) were used for visualization. Sperm tails were stained with Alexa fluor®-594 conjugated concavalin A (dilution 1∶20, Molecular Probes, USA) and sperm heads by 4′,6-Diamidin-2-phenylindol (DAPI). Images were recorded using a Zeiss LSM510 confocal microscope (Zeiss, Germany).

Fertility assay

Males of various genotypes were separated upon eclosion and maintained in isolation 3 days prior to mating. Single pair matings with w1118 (wt) virgin females were performed for 5 days. At that time both parents were removed from the vial. The number of progeny that eclosed from each vial was counted. Ten vials were scored for each genotype.

Analysis of sperm beat frequency

Three-day old virgin male and/or female flies were used for these studies. Males were mated to w1118 females and mating was interrupted after 20 minutes. To analyze the beat frequency, sperm were released from a seminal vesicle or from a mated-uterus into a Petri dish containing HEPES-buffered saline solution (145 mM NaCl, 4 mM KCl, 1 mM MgCl2, 1.3 mM CaCl2, 5 mM D-glucose, 10 mM 4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid (HEPES), pH 7.4). Seven areas around the sperm mass were recorded. Three sperm tails per area were analyzed. One hundred fifty frames were acquired per area at a frame rate of 50 Hz. Sperm beating was recorded on an inverted microscope (DIC 20x, Olympus IX81, USA) with a charge-coupled camera device (Hamamatsu C9100-02; Hamamatsu Photonics, USA). Beat frequency was analysed using ImageJ software (NIH, USA, http://rsb.info.nih.gov/ij/).

Live imaging of sperm in the female reproductive tract

Freshly hatched males (dj-GFP, ProtB-DsRed in a wild type or amo−/− background) and virgin w1118 females were separated for four days prior to mating. Immediately after termination of mating, female flies were anaesthetised with CO2 and dissected in HEPES-buffered saline solution using fine forceps. The lower reproductive tract was removed without compression of the uterus by gently severing the ovipositor from surrounding cuticle and longitudinally opening the mid-ventrum. The digestive tract was severed close to the anus and the ovaries were removed at the base of the lateral oviducts. Female reproductive tracts were aspirated using a Pasteur pipette and transferred to a 15 µm slide 2×9 well (ibidi GmbH, Martinsried, Germany, #81806), containing 70 µl HEPES-buffered saline solution per well. Real-time imaging of dual-colour fluorescently labelled sperm in the female reproductive tract was performed on a microscope ZEISS LSM 510 DUO equipped with a LD LCI Plan-Apochromat 25x/0.8 glycerine objective (both from Carl Zeiss MicroImaging, Jena, Germany). Microscopic analysis was started within five minutes after unsolicited termination of mating. Excitation of the fluorophores (GFP and DsRed) was performed at 489 and 532 nm, respectively. For simultaneous detection of the red and green fluorescence, the LSM 5 Live confocal scanner was used, collecting emitted fluorescence in the range 495–525 nm for the dj-GFP fusion protein, and 560–675 nm for ProtB-DsRed. 5000 images were recorded per sample at 15 frames per second with 512×512 pixels and a pixel dwell time of 112 µs. (acquisition software: ZEN 2009, Carl Zeiss MicroImaging, Jena, Germany). Image analysis and sperm tracking were performed using Imaris tracking software (Bitplane, Zurich, Switzerland).

Statistics

Data are presented as mean values ± s.e.m. (N = number of experiments, n = observations within an experiment). Unpaired student's t-Test was used for statistical analysis between two groups. Analysis of sperm dynamics and subcellular localization of TRPP2 wild type and mutant transgenes was performed in a blinded fashion.

Supporting Information

Figure S1.

Sperm Storage Organs Dissected From Females Mated With Wild Type or amo−/− Flies. A. Schematic model of the female reproductive system. Ovary (ov), spermathecae (sp), seminal receptacle (sr), uterus (ut). BF. Seminal receptacles dissected 3060 minutes after observed mating. Wild type virgin females were mated to males of different genotypes as indicated: B. Wild type, C. amo−/−, D. amo−/−;P[amo], E. amo−/−;P[amoD627V], and F. amo−/−;P[amo/amoD627V].

https://doi.org/10.1371/journal.pone.0020031.s001

(TIF)

Figure S2.

Amo Localizes to the Endoplasmic Reticulum (ER) in Spermatocytes. A. Intracellular localization of Amo in spermatocytes (Anti-Amo 1∶3000, scale bar 20 µm). B. Expression pattern of the ER marker PDI-GFP in spermatocytes. C. Merged images.

https://doi.org/10.1371/journal.pone.0020031.s002

(TIF)

Figure S3.

Amo Expression by Western Blot Analysis. Lysates were prepared from male flies of various genotypes and subjected to immunoprecipitation with anti-Amo antisera. Western blots were probed with anti-Amo antisera.

https://doi.org/10.1371/journal.pone.0020031.s003

(TIF)

Figure S4.

Subcellular Localization of Amo in Amo/AmoD627V Transheterozygous Sperm. Immunofluorescent labeling of sperm of the genotype amo−/−; P[amo/amoD627V]. A. DAPI. B. Concavalin A. C. Anti-Amo. D. Merged image. Scale bar 20 µm.

https://doi.org/10.1371/journal.pone.0020031.s004

(TIF)

Figure S5.

Analysis of Sperm Speed in the Uterus. Frequency distribution of sperm speed in the female reproductive tract (wt: green, amo−/−: blue, N = 7 for each genotype).

https://doi.org/10.1371/journal.pone.0020031.s005

(TIF)

Figure S6.

Absence of a Dominant Negative Effect of AmoD627V. Fertility tests using heterozygous amo+/ mutant males show that introduction of one (dark grey bars) or two copies (light grey bars) of transgenic AmoD627V (3rd chromosome) does not result in impaired fertility.

https://doi.org/10.1371/journal.pone.0020031.s006

(TIF)

Video S1.

Wild Type Sperm in the Female reproductive Tract. Live imaging of wild type sperm bearing dj-GFP and ProtB-DsRed transgenes in the female uterus and seminal receptacle. Green fluorescent protein (sperm tails, green) and red fluorescent protein (sperm heads, magenta) were detected simultaneously. Isolated sperm head movement (white) in the uterus and the seminal receptacle is also demonstrated.

https://doi.org/10.1371/journal.pone.0020031.s007

(MOV)

Video S2.

Amo−/− in the Female Reproductive Tract. Live imaging of amo−/− sperm bearing dj-GFP and ProtB-DsRed transgenes in the female reproductive tract. Since amo−/− sperm do not reach the storage organs, there are no sperm visualized in the seminal receptacle. There is only background autofluorescence detected. Isolated Sperm head movement (white) in the uterus is also demonstrated.

https://doi.org/10.1371/journal.pone.0020031.s008

(MOV)

Video S3.

Single Sperm Movement in the Female Reproductive Tract. Live imaging of a single wild type sperm labelled with dj-GFP and ProtB-DsRed transgenes in the seminal receptacle is demonstrated. The sperm moves tail first.

https://doi.org/10.1371/journal.pone.0020031.s009

(MOV)

Video S4.

Single Sperm Movement of amo−/− Sperm in the Female Reproductive Tract. Live imaging of a single amo−/− sperm labelled with dj-GFP and ProtB-DsRed transgenes. The sperm moves backwards.

https://doi.org/10.1371/journal.pone.0020031.s010

(MOV)

Video S5.

Tracking of Sperm in the Female Reproductive Tract. Representative tracking of sperm heads in the uterus. Each sperm head (magenta) is marked with a dot. The pseudocolor bar at the right represents the time of tracking during the experiment.

https://doi.org/10.1371/journal.pone.0020031.s011

(MOV)

Video S6.

Wild Type Sperm in the Female Reproductive Tract. Real-time imaging of dual-colour fluorescently labelled wild type sperm in the seminal receptacle and uterus.

https://doi.org/10.1371/journal.pone.0020031.s012

(MOV)

Acknowledgments

Dr. John Belote graciously provided the fly stock expressing Protamine-B labelled with red fluorescent protein. Dr. Barbara Wakimoto generously provided the don-juan-GFP (dj-GFP) line on the third chromosome.

Author Contributions

Conceived and designed the experiments: MK TW. Performed the experiments: MK AH WL KC SC . Analyzed the data: MK AH WL CM TW . Wrote the paper: MK TW.

References

  1. 1. Neubaum DM, Wolfner MF (1999) Wise, winsome, or weird? Mechanisms of sperm storage in female animals. Curr Top Dev Biol 41: 67–97.
  2. 2. Bloch Qazi MC, Heifetz Y, Wolfner MF (2003) The developments between gametogenesis and fertilization: ovulation and female sperm storage in Drosophila melanogaster. Dev Biol 256: 195–211.
  3. 3. Neubaum DM, Wolfner MF (1999) Mated Drosophila melanogaster females require a seminal fluid protein, Acp36DE, to store sperm efficiently. Genetics 153: 845–857.
  4. 4. Bloch Qazi MC, Wolfner MF (2003) An early role for the Drosophila melanogaster male seminal protein Acp36DE in female sperm storage. J Exp Biol 206: 3521–3528.
  5. 5. Avila FW, Wolfner MF (2009) Acp36DE is required for uterine conformational changes in mated Drosophila females. Proc Natl Acad Sci U S A 106: 15796–15800.
  6. 6. Watnick TJ, Jin Y, Matunis E, Kernan MJ, Montell C (2003) A flagellar polycystin-2 homolog required for male fertility in Drosophila. Curr Biol 13: 2179–2184.
  7. 7. Gao Z, Ruden DM, Lu X (2003) PKD2 cation channel is required for directional sperm movement and male fertility. Curr Biol 13: 2175–2178.
  8. 8. Mochizuki T, Wu G, Hayashi T, Xenophontos SL, Veldhuisen B, et al. (1996) PKD2, a gene for polycystic kidney disease that encodes an integral membrane protein. Science 272: 1339–1342.
  9. 9. Cai Y, Maeda Y, Cedzich A, Torres VE, Wu G, et al. (1999) Identification and characterization of polycystin-2, the PKD2 gene product. J Biol Chem 274: 28557–28565.
  10. 10. Kottgen M, Benzing T, Simmen T, Tauber R, Buchholz B, et al. (2005) Trafficking of TRPP2 by PACS proteins represents a novel mechanism of ion channel regulation. EMBO J 24: 705–716.
  11. 11. Hanaoka K, Qian F, Boletta A, Bhunia AK, Piontek K, et al. (2000) Co-assembly of polycystin-1 and -2 produces unique cation-permeable currents. Nature 408: 990–994.
  12. 12. Koulen P, Cai Y, Geng L, Maeda Y, Nishimura S, et al. (2002) Polycystin-2 is an intracellular calcium release channel. Nat Cell Biol 4: 191–197.
  13. 13. Venglarik CJ, Gao Z, Lu X (2004) Evolutionary conservation of Drosophila polycystin-2 as a calcium-activated cation channel. J Am Soc Nephrol 15: 1168–1177.
  14. 14. Pazour GJ, San Agustin JT, Follit JA, Rosenbaum JL, Witman GB (2002) Polycystin-2 localizes to kidney cilia and the ciliary level is elevated in orpk mice with polycystic kidney disease. Curr Biol 12: R378–380.
  15. 15. Bobinnec Y, Marcaillou C, Morin X, Debec A (2003) Dynamics of the endoplasmic reticulum during early development of Drosophila melanogaster. Cell Motil Cytoskeleton 54: 217–225.
  16. 16. Gallagher AR, Germino GG, Somlo S Molecular advances in autosomal dominant polycystic kidney disease. Adv Chronic Kidney Dis 17: 118–130.
  17. 17. Kottgen M (2007) TRPP2 and autosomal dominant polycystic kidney disease. Biochim Biophys Acta 1772: 836–850.
  18. 18. Reynolds DM, Hayashi T, Cai Y, Veldhuisen B, Watnick TJ, et al. (1999) Aberrant splicing in the PKD2 gene as a cause of polycystic kidney disease. J Am Soc Nephrol 10: 2342–2351.
  19. 19. Ma R, Li WP, Rundle D, Kong J, Akbarali HI, et al. (2005) PKD2 functions as an epidermal growth factor-activated plasma membrane channel. Mol Cell Biol 25: 8285–8298.
  20. 20. Manier MK, Belote JM, Berben KS, Novikov D, Stuart WT, et al. Resolving mechanisms of competitive fertilization success in Drosophila melanogaster. Science 328: 354–357.
  21. 21. Fraser LR The “switching on” of mammalian spermatozoa: molecular events involved in promotion and regulation of capacitation. Mol Reprod Dev 77: 197–208.
  22. 22. Suarez SS (2008) Control of hyperactivation in sperm. Hum Reprod Update 14: 647–657.
  23. 23. Barr MM, DeModena J, Braun D, Nguyen CQ, Hall DH, et al. (2001) The Caenorhabditis elegans autosomal dominant polycystic kidney disease gene homologs lov-1 and pkd-2 act in the same pathway. Curr Biol 11: 1341–1346.
  24. 24. Barr MM, Sternberg PW (1999) A polycystic kidney-disease gene homologue required for male mating behaviour in C. elegans. Nature 401: 386–389.
  25. 25. McGrath J, Somlo S, Makova S, Tian X, Brueckner M (2003) Two populations of node monocilia initiate left-right asymmetry in the mouse. Cell 114: 61–73.
  26. 26. Nauli SM, Alenghat FJ, Luo Y, Williams E, Vassilev P, et al. (2003) Polycystins 1 and 2 mediate mechanosensation in the primary cilium of kidney cells. Nat Genet 33: 129–137.
  27. 27. Kottgen M, Buchholz B, Garcia-Gonzalez MA, Kotsis F, Fu X, et al. (2008) TRPP2 and TRPV4 form a polymodal sensory channel complex. J Cell Biol 182: 437–447.
  28. 28. Boehlke C, Kotsis F, Patel V, Braeg S, Voelker H, et al. Primary cilia regulate mTORC1 activity and cell size through Lkb1. Nat Cell Biol 12: 1115–1122.
  29. 29. Pattarini JM, Starmer WT, Bjork A, Pitnick S (2006) Mechanisms underlying the sperm quality advantage in Drosophila melanogaster. Evolution 60: 2064–2080.
  30. 30. Heifetz Y, Rivlin PKBeyond the mouse model: using Drosophila as a model for sperm interaction with the female reproductive tract. Theriogenology 73: 723–739.
  31. 31. Suarez SS, Pacey AA (2006) Sperm transport in the female reproductive tract. Hum Reprod Update 12: 23–37.
  32. 32. Navarro B, Kirichok Y, Chung JJ, Clapham DE (2008) Ion channels that control fertility in mammalian spermatozoa. Int J Dev Biol 52: 607–613.
  33. 33. Qi H, Moran MM, Navarro B, Chong JA, Krapivinsky G, et al. (2007) All four CatSper ion channel proteins are required for male fertility and sperm cell hyperactivated motility. Proc Natl Acad Sci U S A 104: 1219–1223.
  34. 34. Hofherr A, Kottgen M TRPP Channels and Polycystins. Adv Exp Med Biol 704: 287–313.
  35. 35. Venken KJ, Carlson JW, Schulze KL, Pan H, He Y, et al. (2009) Versatile P[acman] BAC libraries for transgenesis studies in Drosophila melanogaster. Nat Methods 6: 431–434.
  36. 36. Santel A, Winhauer T, Blumer N, Renkawitz-Pohl R (1997) The Drosophila don juan (dj) gene encodes a novel sperm specific protein component characterized by an unusual domain of a repetitive amino acid motif. Mech Dev 64: 19–30.