Mated Drosophila melanogaster Females Require a Seminal Fluid Protein, Acp36DE, to Store Sperm Efficiently

Mated Drosophila melanogaster Females Require a Seminal Fluid Protein, Acp36DE, to Store Sperm Efficiently

Deborah M. Neubaum^1,a and Mariana F. Wolfner^a
^a Department of Molecular Biology and Genetics, Cornell University, Ithaca, New York 14853-2703

Corresponding author: Mariana F. Wolfner, Department of Molecular Biology and Genetics, 423 Biotechnology Bldg., Cornell University, Ithaca, NY 14853-2703., mfw5{at}cornell.edu (E-mail)

Communicating editor: L. PARTRIDGE

ABSTRACT

TOP
ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

Mated females of many animal species store sperm. Sperm storageprofoundly influences the number, timing, and paternity of thefemale's progeny. To investigate mechanisms for sperm storagein Drosophila melanogaster, we generated and analyzed mutationsin Acp36DE. Acp36DE is a male seminal fluid protein whose localizationin mated females suggested a role in sperm storage. We reportthat male-derived Acp36DE is essential for efficient sperm storageby females. Acp36DE¹ (null) mutant males produced and transferrednormal amounts of sperm and seminal fluid proteins. However,mates of Acp36DE¹ males stored only 15% as many sperm and produced10% as many adult progeny as control-mated females. Moreover,without Acp36DE, mated females failed to maintain an elevatedegg-laying rate and decreased receptivity, behaviors whose persistence(but not initiation) normally depends on the presence of storedsperm. Previous studies suggested that a barrier in the oviductconfines sperm and Acp36DE to a limited area near the storageorgans. We show that Acp36DE is not required for barrier formation,but both Acp36DE and the barrier are required for maximal spermstorage. Acp36DE associates tightly with sperm. Our resultsindicate that Acp36DE is essential for the initial storage ofsperm, and that it may also influence the arrangement and retentionof stored sperm.

DROSOPHILA melanogaster females, like females of many otheranimal species, store the sperm they receive during mating (reviewedin GILBERT et al. 1981 ; SANDER 1985 ; BIRKHEAD and MOLLER1993 ; NEUBAUM and WOLFNER 1999 ). Drosophila females havethree organs specialized for the retention of sperm, includinga long, coiled tubule called the seminal receptacle and twosac-like organs termed spermathecae (MILLER 1950 ). The femaleuses her stored sperm to fertilize several hundred eggs overthe 2 wk after a mating (LEFEVRE and JONSSON 1962 ). The abilityto store sperm is an integral part of the Drosophila patternof reproduction, and it may increase fecundity (COOK 1970 ; HIHARA 1981 ), minimize the biochemical and environmental hazardsassociated with copulation (THORNHILL and ALCOCK 1983 ; CHAPMANet al. 1995 ), and provide a milieu for sperm competition (HARSHMANand PROUT 1994 ; CLARK et al. 1995 , CLARK et al. 1999 ; CLARK and BEGUN 1998 ; HUGHES 1997 ; PRICE 1997 ). Moreover,Drosophila females link the presence of stored sperm to postmatingbehaviors such as egg laying and receptivity to remating (MANNING1962 , MANNING 1967 ; HIHARA 1981 ; SCOTT 1987 ; KALB etal. 1993 ; TRAM and WOLFNER 1998 ), which serves to furthermaximize progeny production.

The mechanisms that govern sperm storage in Drosophila and otheranimals are likely to require a combination of anatomical featuresand the action of molecules contributed by males and females(DEVRIES 1964 ; FOWLER 1973 ; BERTRAM et al. 1996 ; ARTHURet al. 1998 ; NEUBAUM and WOLFNER 1999 ). While previous studieshave focused on the morphology of the male and female genitalia(MILLER 1950 ; BAIRATI 1968 ), as well as the sperm storageorgans and the arrangement of sperm within them (FILOSI andPEROTTI 1975 ; HIHARA and HIHARA 1993 ), relatively littleis known about the molecules furnished by males or females thatare important for sperm storage.

Female D. melanogaster receive ~4000–6000 sperm in a singlemating and store up to ~1100 of them (GILBERT 1981 ). They useup to 600–800 sperm to fertilize eggs over the subsequent2 weeks (KAPLAN et al. 1962 ; GILBERT et al. 1981 ). That maleseminal fluid components play a role in the transfer or storageof sperm in females was first suggested by the low fertilityof repeatedly mated males (LEFEVRE and JONSSON 1962 ; HIHARA1981 ). KALB et al. 1993 obtained additional evidence favoringthis idea when they observed that the mates of male flies deficientin Acps, seminal fluid proteins derived from male accessoryglands, contained fewer sperm than normal at 6 hr postmating.In the accompanying article, TRAM and WOLFNER 1999 show thatthis phenotype results from a requirement for Acps for properstorage of sperm, rather than from insufficient sperm productionor transfer by Acp-deficient males.

We wished to identify specific molecules that mediate spermstorage. In particular, one Acp, Acp36DE, was a good candidatefor involvement in sperm storage on the basis of its localizationin the mated female genital tract (BERTRAM et al. 1996 ) andon data from CLARK et al. 1995 , which show a correlation ofalleles at this locus and levels of sperm competition in chromosomesfrom natural populations. We show here that Acp36DE is a majorplayer in the process of sperm storage.

Acp36DE is a large glycoprotein of 122 kD that is processedto a 68-kD form shortly after its transfer to females duringmating (BERTRAM et al. 1996 ). In mated females, Acp36DE localizesto two specific areas: Acp36DE binds to the lower oviduct onthe ventral side, just above the openings to the three spermstorage organs. Acp36DE also associates with the mass of spermand other seminal fluids in the uterus (the "sperm mass"). Aftermating, the sperm mass does not progress into the upper oviduct,but remains confined to the uterus, posterior to the site ofAcp36DE localization. These observations led us to propose amodel in which Acp36DE marks the presence of a barrier in themated female oviduct that blocks the movement of sperm intothe upper oviduct (BERTRAM et al. 1996 ). The mating plug secretions,which occupy the lower portion of the uterus, are proposed todelimit the sperm at the posterior. In this manner, sperm areconfined to a small region of the anterior uterus, which mayfacilitate their entry into the narrow openings of the storageorgans. Whether Acp36DE serves only as a marker of the barrierin the oviduct or comprises part or all of the barrier was notpossible to determine in the BERTRAM et al. 1996 study.

In mated eggless females, a proper barrier does not form inthe oviduct, and sperm (as well as Acp36DE) become mislocalizedinto the anterior oviduct near the ovaries (BERTRAM et al. 1996). If the formation of an oviduct barrier (and the concomitantfull localization of Acp36DE at the oviduct) is important forsperm storage, we predict that sperm storage will be compromisedin eggless females mated to normal males.

Here, we report the isolation and characterization of a nullmutation in Acp36DE. We show that this mutation severely compromisesthe ability of sperm of mutant males to be stored by their mates.To probe the mode of action of Acp36DE in sperm storage, wetested whether the presence of Acp36DE is necessary for spermto be properly restricted from entry into the upper oviduct.In addition, we used biochemical and genetic means to perturbthe association of Acp36DE with the sperm mass or with the posterioroviduct wall. We find that although Acp36DE is not necessaryfor the oviduct sperm barrier to form, the barrier is importantin sperm storage, and Acp36DE's localization correlates withthe efficiency of sperm storage. Furthermore, Acp36DE was foundto tightly associate with sperm and to enter the storage organs.

MATERIALS AND METHODS

TOP
ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

Fly strains and isolation of Acp36DE mutants:
A strain of Oregon-R flies made isogenic for chromosome 2 wastermed iso2. Three-day-old iso2 males were treated with 25 mMethyl methanesulfonate (EMS; LEWIS and BACHER 1968 ). A seriesof genetic crosses as in HERNDON and WOLFNER 1995 generated*/Df males, where * represents an EMS-mutagenized chromosomeand Df represents Df(2L)H2O, a deficiency that deletes 36A8-9;36E1-2 (SIMPSON 1983 ). Individual */Df males were tested bydot blot or Western blotting (VAN VACTOR et al. 1988 ; HERNDONand WOLFNER 1995 ) for loss or truncation of Acp36DE.

Acp36DE^P, kindly provided by A. Clark and C. Langley, containsa P-element insertion within the Acp36DE coding sequence (CLARKet al. 1994 ; BERTRAM et al. 1996 ; D. M. NEUBAUM and M. F.WOLFNER, unpublished results), which results in truncation ofthe protein. Acp36DE^P males appear to have normal fertility.

Homozygous bw sp tud¹ females (BOSWELL and MAHOWALD 1985 ) weremated to iso2-derived males to produce eggless daughters andspermless sons. Thus, the genetic background of eggless femalesis quite related to their control, iso2 females. Other balancersand markers are listed in LINDSLEY and ZIMM 1992 . All phenotypicanalyses described in this article were carried out using Acp36DE*/Dfflies. Controls were Oregon-R (for Western blots) or Acp36DE⁺/Dfmales, where the Acp36DE⁺ chromosome was derived from a strainclosely matched in genetic background to the mutants. This strainhad been maintained in parallel to the Acp36DE¹ and Acp36DE²mutant strains (for sperm counts and phenotypic assays).

Genetic analysis:
Acp36DE alleles were maintained by backcrossing Acp36DE*/CyOmales to CyO/Df females every generation. All phenotypes describedhere cosegregated. EMS-induced mutations at genomic locationsother than chromosome 2 were segregated away from the geneticbackground of Acp36DE* males as the number of backcrosses increased.

Nucleic acid and protein analysis:
Recent EST sequences deposited in the databases by the BerkeleyDrosophila Genome Project, in conjunction with our Northernblotting, have extended the Acp36DE sequence at the 5' end ofthe gene (W. SWANSON, personal communication; GenBank entryno. U85759 has been revised accordingly). The revised Acp36DEORF spans 2736 bp, the equivalent of 912 amino acids. Aminoacids 1–23 comprise a signal sequence conforming to thespecifications of VON HEIJNE 1983 , leading us to believe thatthis is the likely start of Acp36DE's ORF. The Acp36DE mutantlesions were identified by PCR-amplifying DNA from */Df fliesusing two primers that include XbaI linkers and derive from454 to 472 and 2774 to 2792 of the Acp36DE sequence (WOLFNERet al. 1997 ). Amplified products were sequenced directly orcloned into pBluescript II SK +/- (Stratagene, La Jolla, CA),and the sequences of both strands were determined using automatedcycle sequencing (Perkin-Elmer, Norwalk, CT/Applied Biosystems,Foster City, CA). Acp36DE⁺ cDNA sequence (WOLFNER et al. 1997) or PCR-generated Acp36DE genomic sequence was used for comparisonto mutant alleles.

Total poly(A)⁺ RNA was isolated from adult male Drosophila usingthe Total RNA isolation kit (Promega, Madison, WI). Northernblots were prepared as described in MONSMA and WOLFNER 1988, with ~10 µg RNA per lane, and were probed with random-primedAcp36DE or, as a control, ß-tubulin (BIALOJAN et al. 1984) DNA probes, followed by autoradiography.

Protein extracts from the genital tracts of 3-day-old */Df (2L)H2Omales were prepared and immunoblotted as described in MONSMAand WOLFNER 1988 . Blots were probed with affinity-purifiedAcp36DE (BERTRAM et al. 1996 ) or Acp26Aa (MONSMA and WOLFNER1988 ) primary antibodies diluted 1:1000 or 1:500, respectively,and with horseradish-peroxidase-conjugated secondary antibody(Sigma, St. Louis) diluted 1:2000. Proteins were visualizedby enhanced chemiluminescence (ECL; Amersham, Arlington Heights,IL).

Sperm motility, transfer, and quantitation:
Mature sperm were dissected from the seminal vesicle and testedfor motility by observing their sinuous tail undulations inphysiological buffer (CENCI et al. 1994 ).

To evaluate sperm transfer by mutant males, the genital tractsof females mated to Acp36DE¹/Df or control (Acp36DE⁺/Df) maleswere dissected at 30 min after the start of mating (~20 matingsper genotype). After removal of the ovaries and oviduct, themated female's uterus was squashed under a coverslip, causingthe sperm mass to spread flat. In double blind experiments,we assigned sperm spreads a score of 1–5 on the basisof the size and density of the spread viewed at x40 in a Zeiss(Thornwood, NY) Axioskop. Results were confirmed in duplicateexperiments.

Sperm stored in female genital tracts were fixed and stainedwith 2% orcein in 60% acetic acid (GILBERT 1981 ; GILBERT etal. 1981 ) and counted at x100 magnification using phase-contrastmicroscopy. Data were analyzed using the Statview 4.1 statisticsprogram (Fisher's t-tests and ANOVA). Total sperm stored wascalculated as the sum of those stored in the seminal receptacleand two spermathecae. Data for total sperm counts (see Table 2)were taken only from the subset of tracts that retained allthree organs after squashing, although additional data for individualorgans were taken from any sample that had intact and suitablysquashed organs.

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Table 1. Mean number of sperm stored over time in mated females

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Table 2. Mean number of sperm stored in Oregon-R or eggless females mated to Oregon-R males at 6 hr after the start of mating

Egg-laying, fertility, receptivity, and life-span assays of female mates of Acp36DE mutant males:
Control lines in all assays were overtly normal Acp36DE-positivelines retained from the mutagenesis experiment. Control andmutant lines were backcrossed every generation to Df/CyO stocksto isogenize genetic background and to avoid selection of modifiers.For all assays, Oregon-R females and hemizygous Df males (mutantor control) were collected a few hours after eclosion and aged3–5 days. Flies were maintained at constant temperature(24° ± 0.5°), humidity, and day/night cycle (12:12hr light:dark).

Egg-laying and receptivity responses were examined as describedin KALB et al. 1993 and HERNDON and WOLFNER 1995 .

The effect of Acp36DE on life span was assayed in experimentslike those of CHAPMAN et al. 1995 , with the exception thatmicrocauterized flies were not included. Each Oregon-R femalewas placed with a Acp36DE¹/Df or control (Acp36DE⁺/Df) malefor 2 days, but every third day was housed with a control maleto control for nonseminal fluid costs of mating, such as eggproduction (PARTRIDGE et al. 1987 ). A total of 30 females wereused per experimental group.

Using the Statview 4.1 statistics program, we performed ANOVAand Fisher's t-tests on data from all assays.

Sperm-binding assays:
In vivo assay: For all assays described in this paper, males and females wereheld in isolation for 3–5 days before mating. Female genitaltracts were dissected 30 min after the start of mating, andthe ovaries were removed. The mass of sperm present in the anterioruterus was then squeezed out of the torn oviduct by applyingpressure to the uterus. Sperm masses were transferred to a microfugetube, where 500 µl (>1000x volume) of buffer was added.Buffers contained 1x PBS ± 0.1% Tween 20 + 0.0, 0.1,0.5, or 1 M NaCl, and were adjusted to pH 5, 7, or 10 with 1N HCl or 1 N NaOH. In some experiments, samples were vortexedvigorously for 10 sec. All samples were incubated for 1 hr andthen spun in a microfuge for 5 min to pellet the sperm. Supernatantswere spun in a SpeedVac to reduce volume. Pellets and supernatantswere resuspended in 2x SDS-PAGE loading buffer, run on 10% SDS-PAGEgels, and Western blotted (MONSMA and WOLFNER 1988 ). Afterprobing with anti-Acp36DE, blots were stripped and reprobedwith anti-Acp26Aa (PARK and WOLFNER 1995 ). To determine whethersoluble Acp36DE was precipitated by any of the buffers, a parallelexperiment was performed using accessory gland homogenate (spunfree of particulate matter) in each of the buffers under similarconditions.

In vitro assay: Using 40 males per treatment, mature sperm were dissected fromthe seminal vesicle, while the accessory glands (AG) were homogenizedin protease-inhibitory buffer (PARK and WOLFNER 1995 ) and centrifugedbriefly to remove particulate matter. AG extracts (100 µl)were mixed with sperm (or not, as a control) for 1 hr at 4°with gentle shaking. Samples were then layered onto 30–70%sucrose gradients and spun for 20 min at 5000 x g in a swingingbucket rotor (SW50.1) at 4°. Fractions (250 µl) werecollected beginning at the top of the gradient and examinedunder a microscope for the presence of sperm. Samples were reducedin volume, loading buffer was added, and samples were run ongels and immunoblotted.

RESULTS

TOP
ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

Isolation of Acp36DE mutants:
Since the nature and severity of the Acp36DE mutant phenotypewas not predictable, we searched for mutations in Acp36DE witha screen based on protein expression rather than function. Toidentify mutant lines with decreased or absent Acp36DE expression,affinity-purified Acp36DE polyclonal antibodies (BERTRAM etal. 1996 ) were used to screen dot or Western blots (VAN VACTORet al. 1988 ; HERNDON and WOLFNER 1995 ) containing extractsof males heterozygous for a mutagenized chromosome 2 and a deficiencythat uncovers Acp36DE (*/Df males).

From 8805 mutagenized lines tested, we recovered two in whichfull-length Acp36DE was undetectable on Western blots of extractsof */Df males (Fig 1A). In contrast to wild-type males, whichhad a prominent 122-kD Acp36DE band (lane 1), Acp36DE¹/Df maleshad no detectable Acp36DE (lane 2), even when lanes were loadedwith extracts of 10-fold more flies than control lanes. Acp36DE¹/Dfmales did not make a detectable Acp36DE RNA transcript (Fig 1B).A second Acp36DE mutant, Acp36DE², gave rise to a 56-kDAcp36DE (Fig 1A, lane 3), whose signal on Western blots wasless intense than that of the wild-type Acp36DE. Acp36DE² islikely truncated and less abundant or less well recognized bythe polyclonal Acp36DE antibody. Acp36DE² tested normal in allfunctional assays and will not be discussed further in thisarticle.

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Figure 1. Molecular characterization of Acp36DE mutants. (A) A Western blot probed with anti-Acp36DE. Lanes contain extracts of accessory glands from 3-day-old virgin Oregon-R (wild-type) males (lane 1, one pair of accessory glands), Acp36DE¹/Df males (lane 2, 10 pairs), or Acp36DE²/Df males (lane 3, 10 pairs). (B) Northern blot of total RNA isolated from control or Acp36DE¹/Df males probed for Acp36DE mRNA (top) or, as a control, ß-tubulin mRNA (bottom). (C) Diagram of proteins encoded by the Acp36DE⁺ and Acp36DE¹ alleles. Acp36DE¹ is predicted to be truncated by a stop codon at amino acid 274 (CAA $->$ TAA).

Sequence analysis of Acp36DE¹ showed that a nonsense mutation,created by a C-to-T transition at position 823 in the ORF sequence,caused Gln²⁷⁴ to be replaced with a stop codon (Fig 1C). Theshortened open reading frame could encode a secreted proteinof ~28 kD, but no novel Acp36DE cross-reactive band of thisor any other size was detectable on immunoblots, presumablybecause Acp36DE¹ mRNA was destabilized by the mutation (SACHS1993 ; HERNDON and WOLFNER 1995 ). On the basis of the lackof detectable Acp36DE mRNA or protein, we conclude that Acp36DE¹is a null allele.

We believe the phenotypes described in the remainder of thisarticle are the result of mutations in the Acp36DE gene forthe following reasons. The phenotypes we describe are observedin Acp36DE¹/Df males, but not in Acp36DE¹/Acp36DE⁺ males, whichhave normal fertility. The fully recessive nature of the Acp36DE¹mutation indicates that the gene responsible for the phenotypeswe report below must lie in the region uncovered by Df(2L)H2O.The only known gene within this region with a mutation affectingmale fertility is blanks (36A8; 36B6); the bln¹ allele causesa postmeiotic differentiation defect so that bln mutants donot make sperm (CASTRILLON et al. 1993 ). Since the mutant malesdescribed in this article do make motile sperm (see below),they are unlikely to have a mutation in bln. Male sterile mutantsthat make motile sperm are rare (10 in 400, FITCH et al. 1998). Thus, the likelihood is very low that we induced simultaneously,in the small genetic region uncovered by Df(2L)H2O, two independentmutations, one that abolished production of Acp36DE and anotherthat resulted in semisterility despite production of normalamounts of motile sperm.

Acp36DE mutant males had normal viability and produced normal amounts of sperm and seminal fluid proteins other than Acp36DE:
Acp36DE mutant flies were fully viable and displayed no abnormalvisible morphological phenotypes. The accessory glands of mutantswere normal in morphology and size, and produced normal amountsof other Acps (including Acps 26Aa, 26Ab, 32CD, 62F, and 63F/64A, MONSMA and WOLFNER 1988 ; WOLFNER et al. 1997 ; data not shown),as well as the ejaculatory duct protein Est-6 (GILBERT 1981; data not shown).

Acp36DE mutant males produced abundant, morphologically normal,motile sperm. Sperm of mutant males are functional, since eggsfertilized by sperm of Acp36DE mutant males survived to adulthood,and the number of progeny produced by Acp36DE mutant males wasproportional to the number of sperm stored by their mates (seebelow). The time (± SE) Acp36DE¹/Df or control malesspent in copulation was not significantly different (t = 20.86± 0.533 and 23.29 ± 1.155 min, respectively; forAcp36DE¹/Df and Acp36DE⁺/Df, P = 0.1964). An opaque mass wasobserved in the uteri of females recently mated to Acp36DE¹/Dfmales (Fig 2A), but not in virgin females. When dissected, theopaque mass was found to contain hundreds of sperm tangled together.To evaluate the efficiency of sperm transfer, we dissected andsquashed uteri of mated females and scored the sperm spreadsusing phase-contrast microscopy. In a double-blind experiment,the mass of sperm transferred by mutant males (n = 20) was indistinguishablein size, area, and sperm density from the mass of sperm observedin females mated to control males (n = 20). This suggests thatAcp36DE¹ mutant males consistently transferred a number of spermsimilar to control males. TRAM and WOLFNER 1999 observed variabilityin sperm transfer by males lacking Acps. Our observation thatAcp36DE¹ males appear to transfer sperm normally suggests thatother Acps underlie effects on the uniformity of sperm transfer.

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Figure 2. Sperm in the genital tract of mated females. (A) A large mass of sperm (black arrow) is observed in the uterus of a female immediately after mating to a Acp36DE¹/Df male. Sperm are not mislocalized to the upper oviduct (arrowheads), but, as in wild-type matings, remain largely posterior to a boundary in the lower oviduct. Bar, 0.128 mm. (B) Inside the seminal receptacles of females mated to control males, the staining of sperm heads (e.g., white arrow) reveals numerous sperm arrayed in a roughly parallel fashion. (C) In females mated to Acp36DE¹/Df males, the seminal receptacle (shown) and spermathecae are mostly empty. (D) The few sperm that are present in mates of Acp36DE¹/Df males tend to clump in a nonparallel arrangement. Diffusely staining round nuclei are female somatic nuclei. (B–D) Bar, 0.009 mm.

Sperm stored in mates of Acp36DE¹/Df males were few in number and were arranged in a disorganized fashion:
On the basis of its localization in mated females (BERTRAM 1996),we hypothesized that lack of Acp36DE would affect the numberof sperm stored in females. Accordingly, we counted sperm inthe storage organs of mated females at 6 hr after mating, bywhich time sperm storage is complete (GILBERT 1981 ). In seminalreceptacles, on average, 17% as many sperm were stored by matesof Acp36DE¹/Df males as by mates of controls (P < 0.0001, Table 1). The few sperm that were present in the seminal receptaclesof mates of mutant males were in disorganized clumps, with thesperm heads in twisted disarray (Fig 2D), in contrast to themore parallel arrangement of sperm from control matings (Fig 2B).Similarly, at this time, spermathecae of Acp36DE¹/Df maleshad only 11% as many sperm on average as mates of controls.A summation of total sperm stored in the seminal receptacleand two spermathecae indicates that mates of Acp36DE¹/Df malesstored overall ~15% as many sperm as mates of control males.

To determine whether mates of Acp36DE¹/Df males lost (or used)sperm from the storage organs at the same rate as mates of controls,we compared the numbers of sperm stored by females at 6, 24,and 48 hr after mating (Fig 3, Table 1). Although females matedto Acp36DE¹/Df males stored far fewer sperm than females matedto controls, both types of female lost a similar proportionof stored sperm from their spermathecae over the first 48 hrafter mating and from their seminal receptacle over the first24 hr after mating. On the second day after mating, however,females mated to mutant males rapidly lost sperm from theirseminal receptacles, reducing the number stored to almost zero.In contrast, females mated to controls still retained ~50% ofthe initially stored sperm at 48 hr after mating. Thus, thoughthe primary effect of Acp36DE appears to be on the number ofsperm that initially get stored by females, absence of Acp36DEalso has an effect on the retention of sperm in the seminalreceptacle by day 2 after mating.

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Figure 3. Sperm depletion from the seminal receptacle (SR) or spermathecae (Sp) of mates of Acp36DE¹/Df or control males. Numbers are from Table 1. Note that in the first 48 hr after mating, few sperm are lost from the spermathecae of mates of Acp36DE¹/Df or control males, whereas in the seminal receptacle, mates of Acp36DE¹/Df males show a proportionally more rapid sperm depletion than mates of controls.

Mates of Acp36DE mutant males produced 10% as many progeny as mates of controls:
To address the role of Acp36DE in fertility, we determined thenumber of progeny from single matings of Acp36DE¹/Df or controlmales mated to wild-type females (Fig 4A). While Acp36DE¹/Dfmales were not sterile, their mates produced over the matingperiod only 10% as many progeny as females mated to controlmales (P < 0.001).

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Figure 4. Behavioral responses in females mated to Acp36DE mutant males. Data from a typical experiment are shown in each panel. In all cases, experiments were replicated three times, with similar results each time. Oregon-R females were tested as virgins (open diamonds) or after mating to a Acp36DE¹/Df male (solid squares), control male (open squares), or a spermless son of a bw sp tud¹ mother (solid circles). (A) Fertility: The mean number (± SE) of adult progeny obtained from virgin or mated females is shown for each day after mating. (B) Egg laying: The mean number (± SE) of eggs laid by virgin or mated females is shown for each day after mating. The numbers of females tested per group were 48 mates of Acp36DE¹/Df males, 23 mates of control males, and 17 virgins. (C) Receptivity: Oregon-R females were initially mated to a Acp36DE¹/Df male, a control male, or a spermless male. The cumulative percentage of females that were willing to mate again with a wild-type control male during a 1-hr challenge period is shown for each day after the initial mating. The numbers of females tested per group were 17 mates of Acp36DE¹/Df, 19 mates of control, and 11 mates of spermless. (D) Life span: Survival curves for females mated to Acp36DE mutant (solid squares) or control males (open squares) are shown. A total of 30 females were tested per group.

Moreover, progeny production by mates of Acp36DE¹/Df males showeda different pattern and kinetics from that of the controls (Fig 4A).Although female mates of Acp36DE¹/Df males laid a nearlynormal number of eggs on the first day after mating (see below),only 33% on average of those eggs ultimately gave rise to adults,suggesting that the remaining eggs were unfertilized. The majorityof progeny from Acp36DE¹/Df matings came from eggs laid on days1 and 2 after mating. Very few progeny resulted from eggs laidthree or more days after mating, suggesting that those eggswere nearly all unfertilized. In contrast, on average, >80%of eggs laid by control mates on each of the first through ninthday after mating gave rise to adults. These data are consistentwith the compromised storage and retention of sperm in matesof Acp36DE¹/Df males.

Mates of Acp36DE mutant males fail to maintain at least two sperm-storage-dependent behaviors:
Persistence of increased egg-laying rate and decreased receptivityto courtship for more than 1 day after mating depends on storedsperm in the female (MANNING 1962 , MANNING 1967 ; GARCIA-BELLIDO1964 ; KALB et al. 1993 ). Since lack of Acp36DE decreasessperm storage, we tested whether females mated to Acp36DE mutantmales can maintain these behavioral responses.

Egg laying: On the first day after mating, when the egg-laying rate is largelyindependent of sperm (KALB et al. 1993 ), mates of Acp36DE¹/Dfmales showed a robust response, laying a number of eggs equivalentto controls (P = 0.1082, Fig 4B). The high rate of egg layingwas not maintained in mates of Acp36DE¹/Df males. By the thirdday after mating, the number of eggs laid by Acp36DE¹ mateswas intermediate between and significantly different from thenumber laid by mates of controls (P = 0.0014) and that of virgins(P = 0.0022). On the fourth and subsequent days after mating,the number of eggs laid by Acp36DE¹ mates was indistinguishablefrom that of virgins (P = 0.1622) and significantly less thanthat of the controls (P = 0.0003, day 4; P < 0.0001, days5 and 6). By day 7 after mating, the number of eggs laid bycontrols had also declined, and the number of eggs laid by Acp36DE¹mates was indistinguishable from that of controls (P = 0.3236).

Receptivity: On the first day after mating, females mated to all classesof males remained unreceptive to remating (Fig 4C). Mates ofAcp36DE¹/Df males became receptive starting on the second dayafter mating and remated at frequencies similar to those ofvirgin females by the third day after mating. This pattern ofremating is similar to the behavior of mates of spermless males(KALB et al. 1993 ; Fig 4C).

Thus, in both egg-laying and receptivity assays, mates of Acp36DE¹mutants responded normally on the first day after mating, atime when these behaviors can be driven by Acps, without storedsperm (KALB et al. 1993 ). A response on day 1 is consistentwith the receipt of Acps other than Acp36DE by mates of Acp36DE¹mutants. Acp26Aa (HERNDON and WOLFNER 1995 ) and sex peptide(Acp70A, CHEN et al. 1988 ) stimulate egg laying, and sex peptidedepresses receptivity on the first day after mating. Mates ofAcp36DE¹/Df males did not maintain an elevated egg-laying rateor a depressed receptivity on the second and subsequent daysafter mating, when these behaviors depend on the presence ofstored sperm. The fall-off in egg laying and in mating recalcitranceon day 2 and later are not likely to result directly from Acp36DE,since this protein was not detectable in extracts of whole femalegenital tracts after 6 hr postmating (BERTRAM et al. 1996 ).

Life span of mated females was not affected by lack of Acp36DE from their mates:
CHAPMAN et al. 1995 demonstrated that the life span of femaleswas decreased in part by receipt of Acps during mating. In testsof the effects of the Acp36DE¹ mutation on the mates of mutantmales, we found no significant differences in the life spanof females mated to Acp36DE¹/Df relative to control males (P= 0.1566, Fig 4D). Thus, Acp36DE does not account to any significantdegree for the toxic effect of seminal fluid.

The barrier in the oviduct is important for sperm storage, but Acp36DE is not required for formation of this barrier:
The preceding experiments established a function for Acp36DEin sperm storage in females. We next addressed how Acp36DE mightexecute this function. Upon noting the presence of Acp36DE inthe oviduct, we had hypothesized that Acp36DE marked or waspart of a barrier that prevented sperm entry into the upperoviduct and corralled sperm to a region near the sperm storageorgans, thus facilitating their storage (BERTRAM et al. 1996). To investigate whether Acp36DE was required in females forbarrier formation, we mated normal females to Acp36DE¹/Df orAcp36DE⁺/Df males. The localization of sperm in females matedto control males (n = 20) or to Acp36DE¹/Df males (n = 20) didnot differ. Although a large mass of sperm was observed in theanterior uterus of females mated to null males, sperm did nottravel beyond this boundary to the upper genital tract (Fig 2A,arrowheads). Genital tracts of females mated to controlmales appeared identical to that shown in Fig 2A. Therefore,the presence of Acp36DE in the oviduct was not necessary tokeep sperm from mislocalizing to the upper genital tract.

We then reexamined our initial hypothesis and asked whetherthe establishment of a barrier and the presence of Acp36DE nearthe barrier was important for Acp36DE's function in sperm storage.To test this, we evaluated sperm storage in eggless femalesmated to normal (Oregon-R) males. In eggless females, a greatlyreduced amount of Acp36DE localizes to the oviduct, and a spermbarrier does not form (BERTRAM et al. 1996 ). We counted thenumber of sperm present in the storage organs of mated egglessfemales at 6 hr after mating, the time of maximal sperm storage(GILBERT 1981 ). Significantly fewer (P = 0.0086) sperm werestored in the seminal receptacles of eggless females relativeto Oregon-R females (Table 2). Likewise, significantly fewer(P < 0.0001) sperm were found in the spermathecae at thistime (Table 2). On average, eggless females stored 19% fewersperm than control females mated to normal males. However, notethat eggless females with their reduced oviductal localizationof Acp36DE still stored far more sperm than females mated toAcp36DE¹/Df males, who received no Acp36DE at all. The two experimentsdescribed above demonstrate that although Acp36DE is not necessaryto form the barrier, the presence of the barrier and/or thefull and normal localization of Acp36DE in the female is necessaryfor maximal sperm storage.

Acp36DE binds to sperm:
The association of Acp36DE with the sperm mass in the matedfemale genital tract (BERTRAM et al. 1996 ) could be importantfor its function in sperm storage. Alternatively, Acp36DE maybe present in the sperm mass without interacting specificallywith sperm. To assess the strength of the association of Acp36DEand sperm, we tested whether Acp36DE could be dissociated fromthe sperm mass in the presence of high salt, detergent, or extremepH. Sperm masses were removed from mated female genital tractsand placed in one of seven buffers (see MATERIALS AND METHODS; Fig 5 legend). After incubation, sperm were pelleted by centrifugation.The sperm fraction (pellet) and soluble fraction (supernatant)were assayed by Western blotting. Both the full-length (122kD) and processed (68 kD) Acp36DE products remained associatedwith sperm. In all treatments, >80% of both forms of Acp36DEremained associated with the sperm pellet (Fig 5, lanes 1–14).Vortexing the sperm samples at the start of incubation did notrelease more Acp36DE to the supernatant (data not shown). Exceptfor buffer 1, the presence of Acp36DE in the pellet was notcaused by precipitation (buffers 2–7 in Fig 5), sinceAcp36DE present in male accessory gland homogenates did notpellet when incubated alone (Fig 5, lanes 15 and 16), or whenmixed with the torn-open testes and seminal vesicles of spermlessmales (not shown). Moreover, a different seminal fluid protein,Acp26Aa (MONSMA and WOLFNER 1988 ; PARK and WOLFNER 1995 ),readily dissociated from sperm upon the addition of NaCl (Fig 5,lanes 5–14). This result suggests that the associationof Acp36DE with sperm is caused by biochemical features of Acp36DErather than by any nonspecific "stickiness" of sperm. We alsotested the association of a functional though truncated formof Acp36DE (Acp36DE^P, CLARK et al. 1994 ) with the sperm mass.The 56-kD Acp36DE^P interacted tightly with the sperm mass ina manner similar to full-length Acp36DE (data not shown). Thus,both Acp36DE and Acp36DE^P interact with the sperm mass in vivo,and this interaction is refractory to biochemical dissociation.

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Figure 5. The association of Acp36DE or Acp26Aa with the sperm mass in vivo. Western blot of sperm mass preparations probed with anti-Acp36DE or anti-Acp26Aa, showing proteins present in the pellet (P), which contains sperm, or the supernatant (S), which contains proteins that have dissociated from the sperm mass (lanes 1–14). Since the sperm masses were removed from mated females at 30 min after the start of mating, they show the processed products of Acp36DE (68 kD; and the female-specific, cross-reactive 64-kD band; BERTRAM et al. 1996

) or Acp26Aa (30, 28, and 23 kD; PARK and WOLFNER 1995

) normally present at that time. The components of seven PBS-based buffers are shown. As a control, accessory gland extract containing Acp36DE was incubated in each buffer without sperm (lanes 15 and 16 for buffer 2, data not shown for the other buffers). No precipitation of Acp36DE was observed for buffers 2–7, though slight precipitation occurred in buffer 1.

As a tool for further examination of Acp36DE-sperm interactions,we developed a sperm-binding assay to test whether Acp36DE couldassociate with sperm in vitro. Mature sperm dissected from theseminal vesicle were incubated for 1 hr with accessory glandhomogenates containing Acp36DE. Samples were then spun throughsucrose gradients until equilibrium was reached for the samplecomponents. Fractions taken from the gradients were assayedfor colocalization of Acp36DE and sperm. As shown in Fig 6,Acp36DE and sperm were both present in fractions ~70% into thegradient (around fraction 14, Fig 6A). In control assays withoutsperm, Acp36DE remained in the top 10–15% of the gradient(Fig 6D). In parallel experiments, Acp36DE^P was found in thesperm-containing fractions in a manner similar to the full-lengthprotein (Fig 6B; data not shown). Acp36DE made as a GST fusionprotein in Escherichia coli also migrated with sperm in thegradient (Fig 6C), suggesting that posttranslational modificationssuch as glycosylation are not required for binding of spermby Acp36DE, and that the presence of other Acps is dispensablefor Acp36DE binding to sperm. A control protein, Acp26Aa (MONSMAand WOLFNER 1988 ; PARK and WOLFNER 1995 ), did not bind tosperm in parallel assays (data not shown). Thus, Acp36DE caninteract with sperm in the absence of other Acps.

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Figure 6. The cosedimentation of endogenous Acp36DE and E. coli-made Acp36DE with sperm in vitro. Western blots of sucrose gradient fractions probed with anti-Acp36DE and the corresponding fractions that contain sperm. After spinning to equilibrium, the gradient was divided into 20 equally sized fractions ranging from 30% sucrose (fraction 1) to 70% sucrose (fraction 20). Sperm was mixed with accessory gland extracts of (A) wild-type males, (B) Acp36DE^P males, or (C) Acp36DE-GST fusion protein made in E. coli. As a control, (D) accessory gland extracts were tested without sperm. The increasing amount of sucrose in the deeper fractions of the gradient slightly retards mobility of the proteins in the gels. +, sperm seen in the fraction upon microscopic examination; -, no sperm detected in the fraction.

Acp36DE enters the sperm storage organs in a normal mating:
Although large amounts of Acp36DE were not detected inside thestorage organs of females in previous immunohistochemical experiments(BERTRAM et al. 1996 ), the impermeability of these chitin-linedorgans to the staining reagents, and possibly the brown colorof the spermathecae, prevented detection of small amounts ofAcp36DE in these tissues. The tight association of Acp36DE withsperm in the uterus suggests that the protein must either accompanythe sperm into the organs or rapidly dissociate from the spermas they are stored in the first hours after mating. To distinguishbetween these explanations, we assayed Acp36DE entry into thestorage organs by a method independent of immunohistochemistry.Using fine tweezers, we cleanly separated spermathecae and seminalreceptacles from the rest of the genital tract of mated females.Spermathecal and seminal receptacle homogenates from wild-typematings (Ore-R x Ore-R) were tested for Acp36DE on Western blots.Both organs contained full-length (122 kD) and processed (68kD) Acp36DE (Fig 7A, lanes 1 and 2) at 2 hr after the startof mating, though slightly more Acp36DE was observed in theseminal receptacle than in the spermathecae. The signal obtainedfrom ~120 spermathecae and ~60 seminal receptacles was ~10–50times fainter than the signal of a single female genital tractextract (uterus plus sperm storage organs). Thus, a small fractionof the total Acp36DE transferred to a female does enter eachof the sperm storage organs.

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Figure 7. Entry of Acp36DE into the storage organs and processing of Acp36DE in the absence of sperm or eggs. (A) Western blot of female sperm storage organ extracts probed with anti-Acp36DE. Each lane contains the spermathecae (Sp) or seminal receptacles (SR) of 62 mated females of Oregon-R (OreR, lanes 2 and 3) or eggless females (lanes 4 and 5), all dissected at 2 hr after the start of mating. Lane 1 contains an extract of one female genital tract (GT) with the ovaries removed and dissected at 30 min after the start of mating. 122 kD, Acp36DE (full length); 68 kD, Acp36DE (processed); 64- and 75-kD, female-specific, cross-reactive proteins (NEUBAUM 1999). (Acp36DE is expressed only in males.) (B) Western blot of 10 mated female genital tracts from OreR x OreR (lane 1) or spermless x eggless (lane 2) matings probed with anti-Acp36DE.

Since eggless females fail to localize Acp36DE properly in thelower oviduct, we tested whether Acp36DE could enter the storageorgans of eggless females. Eggless females mated to Ore-R malesstored an equivalent amount of full-length Acp36DE, but its68-kD processing product could not be detected in either thespermathecae or the seminal receptacles (Fig 7A, lanes 4 and5). The lack of detectable 68-kD Acp36DE in the sperm storageorgans of mated eggless females does not reflect a lack of processingin these females. Processing of Acp36DE in the female genitaltracts, which normally requires $>=$ 20 min after mating (BERTRAMet al. 1996 ), is independent of the presence of eggs or sperm(Fig 7B). Thus, we believe the lack of processed Acp36DE inthe sperm storage organs of mated eggless females may indicatethat storage can occur properly for only a brief time immediatelyafter mating, when full-length but not processed Acp36DE ispresent in the genital tract.

DISCUSSION

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ABSTRACT
MATERIALS AND METHODS
RESULTS
DISCUSSION
LITERATURE CITED

Storage of sperm by mated females is an important aspect ofthe reproductive strategy of many animals; yet its molecularbasis is poorly understood. In Drosophila, molecules requiredfor sperm storage are made by the male's accessory gland (TRAMand WOLFNER 1999 ). Here, we have identified the first moleculeessential for sperm storage, and we have shown that this protein,the Drosophila accessory gland protein Acp36DE, is a major contributorto the process of sperm storage in females.

Acp36DE¹ null mutant males made abundant, motile, morphologicallynormal sperm and transferred them in large numbers to femalesduring mating (Fig 2A). However, sperm failed to accumulateproperly in the storage organs of females mated to Acp36DE¹mutant males (Fig 2C and Fig D). A small number of sperm, roughly15% relative to wild-type controls, did enter the storage organsand were stored. Some of these sperm successfully fertilizedeggs (confirming that the sperm are functional), while otherswere lost from the storage organs at a greater rate than wild-typecontrols (Fig 3). As a result of storing few sperm, femalesmated to males lacking Acp36DE produced few progeny, only 10%of the number produced by females mated to normal males (Fig 4A).Moreover, the egg-laying and receptivity behaviors of femalesmated to Acp36DE-deficient mates reverted to a premated statewithin 2 or 3 days after mating instead of after the normal10–14 days (Fig 4B and Fig C). Thus, the lack of Acp36DEindirectly affected egg-laying and receptivity behaviors, andserved to minimize the number of progeny produced. While mutationsin Acp36DE did not result in complete sterility, the fecundityof mutant males was severely compromised. The direct and indirectphenotypes of Acp36DE mutants emphasize the importance thatfemale sperm storage has for the reproductive strategy of D.melanogaster and the role that male-derived proteins play inthis process.

Acp36DE appears to be one of the primary male proteins responsiblefor eliciting female sperm storage. Acp36DE¹/Df mutant maleselicited approximately the same level of sperm storage as maleswith genetically ablated accessory glands, who produce almostno Acps at all (TRAM and WOLFNER 1999 ). In contrast, the stimulationof egg laying, another postmating effect of males upon females,results from the cumulative but apparently independent effectsof at least two gene products, Acp26Aa (HERNDON and WOLFNER1995 ) and sex peptide (CHEN et al. 1988 ; MOSHITZKY et al.1996 ).

A protein that is needed for sperm storage might act at anyof several levels: helping sperm enter the storage organs, helpingsperm arrange themselves appropriately inside the organs, maintainingsperm viability over time, or controlling the release of spermover time. Our data favor the primary role of Acp36DE as beingin the entry of sperm into storage, though we describe observationsthat suggest a secondary effect of the protein in sperm arrangementin and release from storage. A possible role for Acp36DE inpromoting the entry of sperm into storage was suggested initiallyby the localization of Acp36DE protein in the female (BERTRAMet al. 1996 ). Since Acp36DE localization in the oviduct ofwild-type mated females was coincident with the upper limitat which sperm were observed in the genital tract, we suggestedthat Acp36DE marks or forms a barrier in the oviduct that confinessperm within an area from which they can be easily channeledinto the storage organs (BERTRAM et al. 1996 ). Here, we presentfour observations important for understanding the mode of actionof Acp36DE in sperm storage. (1) The presence of Acp36DE wasnot necessary for sperm to be restrained from entering the upperoviduct of mated females (i.e., for "barrier formation"). (2)In eggless females, inefficient barrier formation and incompletebinding of Acp36DE at the lower oviduct correlated with fewersperm stored. (3) Acp36DE tightly associated with sperm in vivo,and sperm and Acp36DE cosedimented in vitro. (4) Acp36DE wasfound in the sperm storage organs of mated females in both itsfull-length and processed forms. These points will be discussedin turn.

While the nature of the mechanism (or "barrier") that holdssperm in the posterior genital tract is unknown, it appearsto be intact in females mated to Acp36DE¹ null mutant males.Females mated to males lacking Acp36DE retained a large massof sperm in the uterus immediately after mating, and few, ifany, sperm were observed in the upper oviduct near the ovaries.Despite proper barrier formation, 85% fewer sperm were storedthan when Acp36DE was present. Thus, the presence of the barrierwas not sufficient alone for normal efficient sperm storage.

The reverse experiment, in which normal amounts of Acp36DE aresupplied but formation of the barrier is faulty, was performedby mating normal males to eggless females. In these matings,Acp36DE localization in the lower oviduct was weakened but noteliminated (BERTRAM et al. 1996 ). Eggless females stored significantlyfewer sperm (averaging 19% less overall) relative to wild-typematings. These data show that without an oviduct barrier, afull aliquot of Acp36DE is not sufficient for full sperm storage.Therefore, the barrier must play some role in sperm storage,even if it is indirect. The barrier may be important simplybecause it traps Acp36DE at a critical location within the genitaltract, from which Acp36DE exerts its action upon sperm storage.Alternatively, the activity of the barrier in sperm storagemay be independent of Acp36DE. However, both the barrier andAcp36DE are required for optimal sperm storage in D. melanogaster.

What sort of action might Acp36DE exert from its location atthe lower oviduct near the sperm storage organs? From the loweroviduct, Acp36DE could act on muscles or on the female nervoussystem to stimulate the storage organs to open or to begin contractionsthat pump sperm into storage. This type of mechanism is usedin Rhodnius prolixus, where accessory gland secretions are reportedto stimulate the genital ducts of females to contract (DAVEY1960 , DAVEY 1965 ). Drosophila females might require ductilecontractions to move sperm into storage, since the openingsto the storage organs are extremely narrow and may impose limitationson the undulatory movements of sperm (see LINLEY and SIMMONS1981 ). Interestingly, ARTHUR et al. 1998 report that D. melanogasterflies with female bodies but masculinized central nervous systemsstore dramatically fewer sperm than control females, indicatingthat the female nervous system plays an important role in Drosophilasperm storage. Alternatively, Acp36DE might complement the actionof a physical barrier by providing a chemical signal to spermto deflect them away from the upper regions of the genital tractand into the storage organs. Acp36DE and the sperm barrier maywork together to ensure the efficient storage of sperm beforethe advent of egg laying results in the unstored sperm beingpushed out of the uterus.

In addition to associating with the oviduct wall, Acp36DE alsoassociates in vivo and in vitro with the sperm mass. The Acp36DE-sperminteraction was strong enough to withstand vortexing and incubationin high salt, detergent, and extreme pH (Fig 5). Such stronginteractions are reminiscent of carbohydrate interactions oflectins and the proteins that bind to them (KOEHLER 1978 ; NICHOLSON and YANAGIMACHI 1979 ). As a glycoprotein, Acp36DEmay interact with moieties found on the surface of sperm. Thein vitro association of recombinant Acp36DE produced by E. colisuggests that the proteinaceous component of Acp36DE is sufficientto bind to sperm (Fig 6), but this result does not precludethe possible interaction of Drosophila Acp36DE's carbohydratewith sperm as well.

Since Acp36DE associated tightly with sperm in the uterus, wehypothesized that Acp36DE might enter the storage organs boundto sperm. Sperm enter the seminal receptacle earlier than thespermathecae and are stored there in greater numbers (GILBERT1981 ; TRAM and WOLFNER 1999 ). Consistent with our hypothesis,Acp36DE was detected inside the storage organs by 2 hr aftermating (Fig 7), with slightly more Acp36DE observed in the seminalreceptacle than in the spermathecae at this time. Thus, Acp36DEwas present at a time and place from which it might influencethe sperm once they are inside the organs, possibly helpingsperm to assume or retain an orderly parallel arrangement, orpreventing their premature loss from the organs. In this context,it is interesting that sperm in the storage organs of femalesmated to males lacking Acp36DE failed to assume their normalparallel configuration (Fig 2D). In addition to Acp36DE, anotherD. melanogaster seminal fluid molecule influences sperm storage:the ejaculatory product esterase-6, a carboxylesterase (GILBERT1981 ; GILBERT et al. 1981 ). In contrast to Acp36DE, nullmutations in esterase-6 decrease rather than increase the rateof sperm loss (GILBERT 1981 ), suggesting that this proteinoperates differently from Acp36DE.

The processed (68 kD) form of Acp36DE was detected in the storageorgans of wild-type but not eggless females, although full-lengthAcp36DE entered the storage organs of both types of femalesin approximately equivalent amounts (Fig 7). These observationsmay be explained if sperm stop entering storage earlier in egglessfemales, perhaps because of the impaired localization of Acp36DEat the oviduct. For 15–20 min after the start of mating,sperm and full-length Acp36DE (the only form available duringthat interval since processed products are not detected immediatelyafter mating, BERTRAM et al. 1996 ) begin entering the storageorgans, with Acp36DE possibly bound to the sperm. As the 68-kDform of Acp36DE begins to appear, it also enters the storageorgans. In eggless females, the mislocalization of sperm upthe oviduct may divert sperm (and Acp36DE) from entering thestorage organs.

Acp36DE is one of several Acp genes for which polymorphismsin natural populations were reported to correlate with levelsof sperm competition, specifically with the ability of storedsperm to resist displacement by sperm from a subsequent mate(CLARK et al. 1994 ). Given the role we demonstrate here forAcp36DE in the storage and retention of sperm, we propose thatthe effect of the wild-caught Acp36DE polymorphic alleles onsperm competition may reflect the action of the protein in storingand retaining sperm rather than an active participation in resistanceto competition.

In summary, Acp36DE plays a critical role in the entry of sperminto storage and influences the maintenance or release of storedsperm. To date, most mechanisms proposed to facilitate spermstorage derive from morphological and behavioral criteria (forreview see BIRKHEAD and MOLLER 1993 ; EBERHARD 1996 ; NEUBAUMand WOLFNER 1999 ). Our identification of Acp36DE as essentialfor sperm storage now permits a molecular genetic dissectionof this essential reproductive process.

FOOTNOTES

¹ Present address: Cardiovascular Research Center, MassachusettsGeneral Hospital/Harvard Medical School, 149 13th St., Charlestown,MA 02129.

ACKNOWLEDGMENTS

The authors are grateful to Drs. Ken Kemphues, Volker Vogt,and Uyen Tram for comments on the manuscript. We thank Dr. WillieSwanson for Acp36DE sequence analysis, Dr. Rollin Richmond foresterase-6 antibodies, Dr. Laura Herndon and Oliver Lung foradvice and protocols, and Eduardo Gonzalez for dedicated technicalassistance. This work was supported by sequential National ScienceFoundation grants to M.F.W. (IBN94-06171 and IBN97-23356); duringpart of this work, D.M.N. was supported by National Institutesof Health Training Grant T32-GM07617.

Manuscript received January 4, 1999; Accepted for publication June 28, 1999.

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