Lewis X-Containing Neoglycoproteins Mimic the Intrinsic Ability of Zona Pellucida Glycoprotein ZP3 to Induce the Acrosome Reaction in Capacitated Mouse Sperm

doi:10.1095/biolreprod.103.023820

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Gamete Biology

Lewis X-Containing Neoglycoproteins Mimic the Intrinsic Ability of Zona Pellucida Glycoprotein ZP3 to Induce the Acrosome Reaction in Capacitated Mouse Sperm¹

William F. Hanna³, Candace L. Kerr³, Joel H. Shaper⁴, and William W. Wright²^,3

Division of Reproductive Biology,³ Department of Biochemistry and Molecular Biology, Johns Hopkins University Bloomberg School of Public Health, Baltimore, Maryland 21205 The Johns Hopkins Kimmel Cancer Center and Department of Pharmacology and Molecular Sciences,⁴ Johns Hopkins University School of Medicine, Baltimore, Maryland 21231

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The binding of zona pellucida (ZP) glycoprotein ZP3 to mousesperm surface receptors is mediated by protein-carbohydrateinteractions. Subsequently, ZP3 induces sperm to undergo theacrosome reaction, an obligatory step in fertilization. We havepreviously identified Lewis X (Le^x; Galß4[Fuc ${alpha}$ 3]GlcNAc)as a potent inhibitor of in vitro sperm-ZP binding (Johnstonet al. J Biol Chem 1998; 273:1888–1895). This glycan isrecognized by $~$ 70% of the ZP3 binding sites on capacitated, acrosome-intactmouse sperm, whereas Lewis A (Le^a; Galß3[Fuc ${alpha}$ 4]GlcNAc)is recognized by most of the remaining sites (Kerr et al. BiolReprod 2004; 71:770–777). Herein, we test the hypothesisthat Le^x- and Le^a-containing glycans, when clustered on a neoglycoprotein,bind ZP3 receptors on sperm and induce sperm to undergo theacrosome reaction via the same signaling pathways as ZP3. Resultsshow that a Le^x-containing neoglycoprotein induced the acrosomereaction in a dose-dependent and capacitation-dependent manner.A Le^a-containing neoglycoprotein also induced sperm to undergothe acrosome reaction but was less potent than Le^x-containingneoglycoproteins. In contrast, neoglycoproteins containing ß4-lactosamine(Galß4GlcNAc), Lewis B (Fuc ${alpha}$ 2Galß3[Fuc ${alpha}$ 4]GlcNAc),and sialyl-Le^x glycans were inactive, as were four other neoglycoproteinswith different nonfucosylated glycans. Consistent with theseresults, unconjugated Le^x- and Le^a-capped glycans were dose-dependentinhibitors, which at saturation, reduced the ZP-induced acrosomereaction by about 60% and 30%, respectively. Experiments utilizingpharmacological inhibitors suggest that induction of the acrosomereaction by solubilized ZP and Le^x- and Le^a-containing neoglycoproteinsrequire the same calcium-dependent pathway. However, only theZP-induced acrosome reaction requires a functional G_i protein.Thus, Le^x-containing neoglycoproteins bind to a major classof ZP3 receptors on capacitated sperm. A Le^a-containing neoglycoproteinbinds a second ZP3 receptor but is a less-potent inducer ofthe acrosome reaction.

acrosome reaction, fertilization, gamete biology, sperm

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

In the mouse, fertilization is characterized by a sequence ofsteps initiated by adhesion of acrosome-intact sperm to thezona pellucida (ZP) and ends with sperm-egg fusion and egg activation[1]. The ZP is composed of three glycoproteins (ZP1, ZP2, andZP3) that form the extracellular matrix surrounding the egg[2]. There is considerable evidence that the adhesion of spermto the ZP involves the interaction of specific sperm surfacemolecules with ZP3. Current models posit that O-linked oligosaccharidesare essential for this interaction [2]. Following adhesion,the binding of ZP3 to sperm-surface receptors stimulates a seriesof intracellular second messengers. In response, the plasmamembrane and underlying outer acrosome membrane are vesiculatedand shed along with the contents of the acrosome. This process,called the acrosome reaction, is required for sperm to penetratethe ZP and reach the egg plasma membrane. Currently, it is assumedbut not proven that the O-linked glycans on ZP3 and complementarysperm surface molecules proposed to mediate sperm-ZP adhesionare also the functional ligands and receptors that mediate theacrosome reaction. Additionally, the structure of one or moresperm-binding, O-linked glycans, and the identity of their complementarysperm surface receptors remain open questions.

Several steps in the fertilization cascade can be replicatedby in vitro assays. We and others have used a competitive, invitro sperm-ZP binding assay to identify glycans that inhibitthe binding of sperm to ZP-enclosed eggs [3, 4]. The prevailinginterpretation is that glycans that effectively inhibit thissperm-ZP binding mimic the structures of authentic sperm-bindingglycans on ZP3. Using this approach, we demonstrated that aLewis X (Le^x; Galß4[Fuc ${alpha}$ 3]GlcNAc)-containing glycanwas a high-affinity (IC₅₀ $~$ 0.5 µM), competitive inhibitorof sperm-ZP binding. Consistent with those results, recent experimentsindicated that Le^x-Lactose (Lac) and Le^x are recognized by $~$ 70%of the ZP3 binding sites on capacitated, acrosome-intact mousesperm [5]. Those experiments also identified a second classof ZP3 binding sites that recognize Lewis A (Le^a; Galß3[Fuc ${alpha}$ 4]GlcNAc),which is an isomer of Le^x. However, those experiments did notidentify the biological functions of these two classes of sites.It is possible that Le^x, Le^a, or both bind to receptors thatmediate the ZP3-induced acrosome reaction. Alternatively, thesebinding sites may act only as ZP adhesion molecules. ZP3 would,therefore, trigger the acrosome reaction by binding to a secondset of sperm surface molecules. In this alternative scenario,sperm-ZP3 interactions would be reminiscent of the interactionsof lymphocytes and the vascular endothelium. A series of distinctand specific cellular interactions are required for lymphocytesto bind and exit blood vessels. One interaction requires thebinding of cell surface carbohydrates to complementary siteson the opposing cell surface (reviewed in [6]).

The primary purpose of the experiments described herein wasto test the hypothesis that the two classes of ZP3 binding sites,which recognize Le^x or Le^a, are functional receptors. To thisend, we examine whether Le^x- or Le^a-containing neoglycoproteinsinduce capacitated mouse sperm to undergo the acrosome reaction.Additionally, by use of neoglycoproteins derivatized with otherglycans, we examined whether this response of sperm was specificfor Le^x and Le^a. Neoglycoproteins, rather than unconjugatedglycans, were used because the induction of the acrosome reactionrequires multivalency of functional oligosaccharides on ZP [7].Additionally, to further test whether Le^x-Lac and Le^a-Lac boundto ZP3 receptors, we examined whether these unconjugated glycanswere dose-dependent inhibitors of the ZP-induced acrosome reaction.Finally, by use of specific pharmacological inhibitors, we examinedwhether the neoglycoprotein-induced acrosome reaction requiresthe same signal transduction pathways in sperm as the ZP-inducedacrosome reaction [8].

MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

Culture Media

For most experiments, the culture medium used was Medium 199(M199; Gibco, Gaithersburg, MD), containing 0.4% crystallineBSA (Gibco) and 273 µM sodium pyruvate (M199-CM). Incubationsof sperm in this medium were conducted at 37°C in 5% CO₂.For experiments requiring the use of uncapacitated sperm, amodified Medium 199 (M199-NCM) was used. M199-NCM was preparedfrom sodium bicarbonate-free Medium 199, and contained 0.1%polyvinyl alcohol, 25 mM Hepes (pH 7.4), 26 mM sodium chloride,0.01% BSA, and 273 µM sodium pyruvate. Incubations performedin M199-NCM were carried out at 37°C in air. In experimentsthat used pertussis toxin to block the acrosome reaction, M199-CMwas supplemented with either 100 ng/ml pertussis toxin (Calbiochem,La Jolla, CA) or vehicle (50 mM sodium chloride, 10 mM sodiumphosphate, pH 7.0).

Neoglycoproteins and Oligosaccharides

All neoglycoproteins were BSA-based and were purchased fromeither Sigma (St. Louis, MO) or Dextra Labs (Reading, U.K.).The oligosaccharide structures, levels of substitution, andsuppliers are summarized in Figure 1. Neoglycoproteins weresolubilized in distilled water and stored as 0.1% stock solutionsat –20°C prior to use. The neoglycoprotein Glc₄-BSAwas used as a negative control in all experiments. The concentrationsof neoglycoproteins are presented as micromoles of polypeptidebackbone rather than micromoles of oligosaccharide. The unconjugatedoligosaccharides ßGal-Lac (Galß4GlcNAcß3Galß4Glc;Calbiochem), Le^x-Lac (Galß4[Fuc ${alpha}$ 3]GlcNAcß3Galß4Glc;Dextra Labs) and Le^a-Lac (Galß3[Fuc ${alpha}$ 4]GlcNAcß3Galß4Glc;Dextra Labs) were used as competitive inhibitors of the ZP-inducedacrosome reaction. These oligosaccharides were stored as stocksolutions in distilled water at a concentration of 2.2 mM at–20°C.

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FIG. 1. Neoglycoproteins used in this study and tested for their ability to induce the acrosome reaction. The oligosaccharides are coupled to lysine residues on the BSA via alkyl spacers. Abbreviations that include Lac refer to the presence of an extra lactose at the reducing termini of the neoglycoprotein's oligosaccharides. The average levels of substitution (moles of glycan per mole of BSA) are supplied for all neoglycoproteins tested and were determined by matrix-assisted laser/desorption ionization, time-of-flight (MALDI-TOF) mass spectrometry by the manufacturer

Preparation of ZP

Zonae pellucidae were isolated from frozen ovaries of 6- to7-wk-old ICR mice (Harlan BioProducts, Indianapolis, IN) onPercoll (Amersham-Pharmacia, Piscataway, NJ) density gradientsas described previously [9]. ZP fragments were suspended indistilled water and solubilized by heating for 30 min at 60°C.The concentration of solubilized ZP was estimated using theQuantiGold protein assay (Diversified Biotech, Boston, MA) andis expressed in terms of ZP equivalents per microliter, basedon the calculation that one ZP contains 3 ng of protein [10].Samples of solubilized ZP were fractionated by SDS-PAGE andsilver-stained to assess purity. Solubilized ZP were dispensedinto single-use aliquots and stored at –80°C untilused.

Isolation of Sperm

Sperm were isolated from CD-1 retired breeders with minor modificationsto previously described methods [11]. Briefly, the caudae epididymidesof three mice were placed in 0.5 ml of medium and minced. Thesperm were allowed to swim out of the tissue for 15 min, atwhich time the tissue fragments were removed. The sperm suspensionwas then pipetted to the bottom of a polypropylene culture tube(12 x 75 mm) containing 1.25 ml of medium and incubated for45 min. During this time, motile sperm swam into the upper portionof the tube. Once the incubation was complete, the top quarter( $~$ 440 µl) of the medium in the culture tube was removed,placed in a culture dish, and covered with medium-washed mineraloil (Sigma). The sperm that were contained in this fractionwere counted on a hemacytometer and were incubated immediatelywith test substances. Sperm suspensions that contained fewerthan 60 000 sperm per milliliter (after swim-up) were discarded.Typically, ideal sperm preparations isolated using this protocolyield 60 000–90 000 sperm per milliliter. The use of animalsfor these experiments was approved by the Animal Care and UseCommittee of the Johns Hopkins University Bloomberg School ofPublic Health.

Incubations with ZP and Neoglycoproteins

All incubations were carried out in 25 µl in microcentrifugetubes (0.5 ml). Test substances (dissolved in water) were addedto an equal volume of 2x medium and diluted to a final volumeof 15 µl with 1x medium. Reaction mixtures were warmedto 37°C and equilibrated with 5% CO₂ in air or with airalone prior to the addition of sperm. Immediately after swim-up,10 µl of the sperm suspension (60 000–90 000 cells)was added to the reaction tubes and incubated with test substancesfor 90 min. Pilot studies demonstrated that 90-min incubationsprovided the highest percentage of acrosome-reacted sperm whentreated with solubilized ZP without an increase in the percentageof negative control sperm (incubated without ZP) that underwenta spontaneous acrosome reaction. In experiments that employedthe T-type calcium-channel inhibitor flunarizine (Calbiochem),sperm incubations were adjusted to either 2.2 µM flunarizineor 0.1% dimethyl sulfoxide (DMSO; vehicle) immediately followingswim-up. It should be noted that flunarizine has been reportedto interact with Na⁺ channels and dopamine D₂ receptors in neuronalcells, and inhibits catecholamine release from chromaffin cells[12, 13]. There is no evidence for roles for these activitiesin the ZP3-induced acrosome reaction. In experiments that requiredthe use of pertussis toxin, the pertussis toxin (or vehicle)was present throughout sperm isolation (including swim-up) andincubation with agonists. Previous studies have demonstratedthat pertussis toxin has no significant effect on capacitation[14].

Determination of Acrosomal Status

Once the incubation was complete, sperm were pelleted at 500x g for 5 min at room temperature, the supernatant was removed,and the sperm were fixed in 70% ethanol for 10 min. Fixed spermwere transferred to SuperFrost Plus microscope slides (FisherScientific, Suwanee, GA) and air-dried overnight. To visualizethe acrosomes, cells were stained with a fluorescein isothiocyanate-conjugatedArachis hypogea (peanut) agglutinin (FITC-PNA; Vector Labs,Burlingame, CA), which has been used previously to discriminatebetween acrosome-intact and acrosome-reacted sperm. PNA hasbeen demonstrated to bind both the outer acrosomal membraneand certain components of the acrosomal matrix [15, 16]. Slideswere stained with 100 µg/ml FITC-PNA (in PBS) for 10 minand rinsed in PBS for 5 min. Samples were mounted in Vectashield(Vector Labs) containing 0.5 µg/ml propidium iodide asa counterstain. Slides were viewed immediately after stainingon a Nikon Eclipse E800 microscope (Nikon, Tokyo, Japan) witha triple-band filter (DAPI/FITC/TRITC) at 400x magnification.Sperm that displayed continuous green staining along their acrosomalarcs were defined as acrosome-intact; those that displayed nogreen staining or punctate staining were defined as acrosome-reacted[9]. Prior to counting, all slides were coded, and slides werecounted blindly. All experiments were conducted at least threetimes. Each time, three to five independent replicates of eachtest group were analyzed, and 200 sperm from each replicatewere counted. In the event that treatment with a negative control(Glc₄-BSA or 0 µM test substance) resulted in $≥$ 15% acrosome-reactedsperm, data from the entire experiment were discarded. Typically,1 out of 10 experiments was discarded because the backgroundin the assay exceeded this cutoff value.

Competitive Acrosome Reaction Assays

For experiments in which unconjugated oligosaccharides wereused to inhibit the acrosome reaction, sperm were isolated undercapacitating conditions by swim-up. Immediately thereafter,aliquots of sperm were incubated for 15 min in the absence offree glycan or in the presence of a dose response (0.18 µMto 3.6 µM) of either Le^x-Lac or Le^a-Lac. Additionally,separate aliquots of sperm were incubated with 3.6 µMßGal-Lac as the negative control. Following this incubation,total heat-solubilized ZP sufficient to bring the ZP3 contentof the incubation to $~$ 90 nM was added (see [9] for estimationof the amount of ZP3 in a preparation of total, heat-solubilizedZP). Samples were incubated at 37°C for 90 min and thensubjected to FITC-PNA staining, as described above.

Statistical Analysis

Dose-response curves were analyzed as previously described [4].Briefly, data were fit to a rectangular hyperbola, and regressionanalysis was performed using the SigmaPlot program (SPSS, Chicago,IL). This program estimated ED₅₀ value (concentration of heat-solubilizedZP or of a neoglycoprotein causing a half-maximal inductionof the acrosome reaction) and the IC₅₀ value (molar concentrationof an unconjugated glycan producing a half-maximal inhibitionin the ZP-induced acrosome reaction), as well as maximal stimulationor inhibition of the acrosome reaction. The program also determinedhow well the data fit the regression line (R² and P values).A linear dose-response was observed with one neoglycoprotein,and those data were subjected to linear regression analysis.Where appropriate, comparisons of individual means were accomplishedby analysis of variance, with the Fisher protected least significantdifference testing using StatView 4.5.1 (SAS, Cary, NC). Inall analyses, data were defined as statistically significantat P < 0.05.

RESULTS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The Neoglycoprotein Le^x-Lac-BSA Induces the Acrosome Reaction in a Dose-Dependent Manner

Recent studies identify Le^x-containing oligosaccharides as high-affinity,competitive inhibitors for $~$ 70% of ZP3 binding sites on capacitatedmouse sperm [5]. Therefore, we reasoned that if these oligosaccharidesbind a ZP3 receptor, a neoglycoprotein containing multiple copiesof Le^x should induce sperm to undergo the acrosome reactionin a glycan structure-specific manner. To test this prediction,we first incubated capacitated mouse sperm with increasing dosesof Le^x-Lac-BSA, which contains the pentasaccharide Galß4[Fuc ${alpha}$ 3]GlcNAcß3Galß4Glc(19 M glycan/M BSA; Fig. 1-ii). In the presence of Le^x-Lac-BSA,sperm underwent the acrosome reaction in a dose-dependent mannerwith saturation reached at $~$ 40% of acrosome-reacted sperm, afourfold increase over untreated sperm (Fig. 2A). Regressionanalysis demonstrated that the data fit a rectangular hyperbola(R² = 0.98, P < 0.05) and estimated an EC₅₀ of 350 nM Le^x-Lac-BSA.

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FIG. 2. A Le^x-Lac containing neoglycoprotein induces the acrosome reaction in a glycan structure-dependent manner. A) Dose-response analyses were conducted with the neoglycoproteins Le^x-Lac-BSA (closed circles) and ${alpha}$ Gal-Lac-BSA (open circles) that contain the oligosaccharides Galß4[Fuc ${alpha}$ 3]GlcNAcß3Galß4Glc and Gal ${alpha}$ 3Galß4GlcNAcß3Galß4Glc, respectively. Sperm were incubated with these neoglycoproteins at the following concentrations: 0, 0.375, 0.75, 1.5, 2.25, and 3 µM (based on neoglycoprotein concentration). The negative control neoglycoprotein Glc₄-BSA was tested at 3 µM (diagonally-striped bar). Solubilized mouse ZP served as a positive control (vertically-striped bar) and was tested at a concentration of 7.5 ZP/µl, which constitutes a saturating dose in our experiments (data not shown). Following the incubations, sperm were fixed and stained to determine whether they possessed intact acrosomes. These data (mean ± SEM; n $≥$ 3) are expressed as the percentage of sperm that were acrosome-reacted after the incubation. Saturating doses of Le^x-Lac-BSA (3 µM) and ZP (7.5/µl) are not statistically different, whereas both are significantly higher than 3 µM Glc₄-BSA. There was no statistically significant response to ${alpha}$ Gal-Lac-BSA by sperm. B) A comparison of the activities of two Le^x-containing neoglycoproteins that differ both in the length of their glycans and their levels of substitution was conducted. Sperm were incubated with 2 µM Glc₄-BSA (30 µM Glc₄ glycan; diagonally-striped bar), 2 µM Le^x-Lac-BSA (38 µM Le^x-Lac glycan), which contains a reducing terminus lactose spacer, or with 2 µM Le^x-BSA (22 µM Le^x glycan), which lacks this lactose spacer (black bars). All data (mean ± SEM; n = 4) are expressed as the percentage of sperm that are acrosome-reacted after the incubation. Bars with different superscripts are statistically different. C) To test whether an N-acetylglucosamine-containing neoglycoprotein could induce the acrosome reaction, sperm were incubated with 2 µM Glc₄-BSA (diagonally-striped bar), 2 µM Le^x-BSA (black bar), or 2 µM GlcNAc-BSA (horizontally-striped bar). These data (mean ± SEM; n = 4) are expressed as the percentage of sperm that are acrosome-reacted after incubation. Bars with different superscripts are statistically different (P < 0.05)

Incubation of sperm with heat-solubilized ZP, the positive controlfor these experiments, also produced a dose-dependent stimulationof the acrosome reaction. Regression analysis estimated an EC₅₀of 3.2 ZP/µl, which is equivalent to 39 nM ZP3 (basedon [10]). Figure 2A shows that a maximally stimulating doseof ZP (7.5 ZP/µl) induced $~$ 40% of the sperm to undergothe acrosome reaction, comparable with previously publishedwork [17]. Thus, in our hands, saturating doses of Le^x-Lac-BSAand ZP produced comparable results.

To ensure that the effects observed with Le^x-Lac-BSA were duespecifically to the Le^x-Lac oligosaccharide, sperm were incubatedwith 3 µM of the negative control neoglycoprotein Glc₄-BSA,which contains a tetrasaccharide of glucose (Fig. 1-i). Glucoseresidues have not been reported on any mature ZP glycoproteinsand therefore should neither bind the ZP3 receptor nor stimulatethe acrosome reaction [18, 19]. The percentage of sperm thatunderwent the acrosome reaction in response to 3 µM Glc₄-BSAwas statistically comparable to the percentage of acrosome-reactedsperm observed in the absence of neoglycoprotein (Fig. 2A).

We next compared the abilities of Le^x-Lac-BSA and Le^x-BSA (Fig. 1-iii)to induce the acrosome reaction. These neoglycoproteinsdiffer with respect to the presence or absence of a lactosespacer. There were two reasons for this comparison. First, theglycan on Le^x-Lac-BSA is potentially twice as long as the glycanon Le^x-BSA (20 Å versus 10 Å from the reducing tothe nonreducing terminus). It was possible that the distanceof the Le^x trisaccharide from the surface of the BSA moleculeinfluenced its accessibility to its corresponding sperm receptorand thus its biological activity. Second, we used commerciallyavailable neoglycoproteins for this study. A demonstration thatthis lactose spacer does not affect biological activity of aneoglycoprotein would allow us to test the largest repertoireof commercially available reagents. Figure 2B demonstrates that2 µM Le^x-Lac-BSA and 2 µM Le^x-BSA were equally effectiveat induction of the acrosome reaction. Thus, the presence orabsence of the lactose spacer at the reducing terminus of theglycan did not affect the ability of the neoglycoprotein toinduce the acrosome reaction.

It should also be noted that the level of substitution of Le^x-Lac-BSA(19 M glycan/M BSA) and Le^x-BSA (11 M glycan/M BSA) differed,whereas their ability to induce the acrosome reaction was similar.These results were confirmed and expanded by the observationthat 2 µM Le^x-Lac-BSA (containing 9 M glycan/M BSA) wasequally effective at inducing the acrosome reaction (data notshown). Thus, the percentage of sperm that underwent the acrosomereaction was comparable, despite a twofold increase in the levelof substitution (from 9 to 19 M glycan/M BSA).

Neoglycoproteins Containing Linear Oligosaccharides with a Nonreducing Terminal ${alpha}$ 3-Galactosyl Residue Do Not Induce the Acrosome Reaction

There is considerable evidence for the presence of ${alpha}$ -galactose-cappedoligosaccharides on ZP3 and for the ability of oligosaccharidescontaining the structure Gal ${alpha}$ 3Galß4GlcNAc to inhibitboth the binding of sperm to a ZP-enclosed egg and the bindingof isolated ZP3 to capacitated mouse sperm [3–5]. Thus, ${alpha}$ -galactose-capped glycans on ZP3 may be functional agonistsfor a ZP3 receptor. However, female mice that do not expressthe gene responsible for adding nonreducing terminal ${alpha}$ 3-galactosylresidues to glycoproteins are, nonetheless, fertile [20]. Thus,whether ${alpha}$ 3-galactose-capped glycans are effective agonists fora sperm surface ZP3 receptor is an open question. To addressthis, we incubated sperm with increasing doses of the neoglycoprotein ${alpha}$ Gal-Lac-BSA, which contains the pentasaccharide Gal ${alpha}$ 3Galß4GlcNAcß3Galß4Glc(Fig. 1-iv). Sperm did not respond to ${alpha}$ Gal-Lac-BSA at any concentrationtested (0–3 µM; Fig. 2A). An additional neoglycoproteinthat contains only the trisaccharide Gal ${alpha}$ 3Galß4GlcNAcwas also tested with similar results observed (data not shown).The maximum dose of ${alpha}$ Gal-Lac-BSA (3 µM) is equivalent to26.4 µM ${alpha}$ Gal-Lac oligosaccharide (taking into account thereare an average of 8.8 moles of ${alpha}$ Gal-Lac oligosaccharide per moleof BSA). This concentration of oligosaccharide is fivefold higherthan the IC₅₀ value obtained in competitive sperm-ZP adhesionassays using free oligosaccharides containing nonreducing terminal ${alpha}$ -galactosyl residues.

GlcNAc-BSA, ßGal-BSA, and Sialyl-Le^x-BSA Do Not Induce the Acrosome Reaction

The data presented so far suggest that a major class of spermsurface ZP3 binding sites, which recognize Le^x-containing glycans,are functional receptors. Kerr et al. [5] indicate that theseglycans are recognized by this class of sites in a structure-specificmanner. Therefore, if these ZP3 binding sites are in fact functionalreceptors, then glycans that are not recognized by this classof sites should be incapable, when clustered on a neoglycoprotein,to induce the acrosome reaction. The next experiments testedthis prediction. The first neoglycoprotein tested was GlcNAc-BSA(Fig. 1-v). GlcNAcß4GlcNAcß4GlcNAc is unableto competitively inhibit either the binding of sperm to an intactZP-enclosed egg or the binding of fluorochrome-labeled ZP3 tosperm [4, 5]. However, Shur and colleagues [21] have generateddata in support of the proposition that a sperm surface formof the enzyme ß4-galactosyltransferase-1 (ß4GalT-1)binds nonreducing terminal GlcNAc residues on ZP3, which leadsto the acrosome reaction. In the current experiment, sperm wereincubated with 2 µM Glc₄-BSA, Le^x-BSA, or the neoglycoproteinGlcNAc-BSA. GlcNAc-BSA did not increase the percentage of spermthat underwent the acrosome reaction when compared to the negativecontrol, Glc₄-BSA. In contrast, sperm incubated with an equivalentamount of Le^x-BSA did undergo the acrosome reaction (Fig. 2C).

Recent work from our laboratory also indicates that the fucosylresidue of Le^x is required for creation of a high-affinity ligandfor a major class of ZP3 binding sites [5]. If this class ofZP3 binding sites is a functional receptor, a neoglycoproteincontaining the nonfucosylated glycan, Galß4GlcNAc(ßGal-BSA, Fig. 1-vi) should not induce the acrosomereaction. To test this prediction, we compared the activityof Le^x-BSA with that of the neoglycoprotein ßGal-BSA.At a concentration of 2 µM, ßGal-BSA was completelyinactive (Fig. 3A).

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FIG. 3. The fucosyl residue of the neoglycoprotein Le^x-BSA is critical for induction of the acrosome reaction; sialyl-Le^x-BSA is inactive. A) To test whether the fucosyl residue was required for the activity of Le^x-BSA, sperm were incubated with 2 µM Glc₄-BSA (diagonally-striped bar), Le^x-BSA (black bar), or ßGal-BSA, which contains the oligosaccharide Galß4GlcNAc (white bar). B) To test the activity of a sialyl-Le^x-containing neoglycoprotein on the acrosome reaction, sperm were incubated with the following neoglycoproteins at a concentration of 2 µM: Glc₄-BSA (diagonally-striped bar), Le^x-BSA (black bar), and sialyl-Le^x-BSA and sialyl-ßGal-BSA (horizontally- and vertically-striped bars). These data (mean ± SEM; n = 4) are expressed as the percentage of sperm that are acrosome-reacted after incubation. Bars with different superscripts are statistically different (P < 0.05)

While Le^x-containing glycans are recognized by a major classof ZP3 binding sites on capacitated mouse sperm, these samesites do not recognize sialyl-Le^x. Therefore, sialyl-Le^x-BSA,which contains the glycan Neu5Ac ${alpha}$ 3Galß4[Fuc ${alpha}$ 3]GlcNAc(Fig. 1-ix), should not induce the acrosome reaction. In thisexperiment, the neoglycoprotein sialyl-ßGal-BSA, whichcontains the nonfucosylated oligosaccharide Neu5Ac ${alpha}$ 3Galß4GlcNAc(Fig. 1-x), was also tested. This second glycan was examinedbecause P-selectin, which recognizes sialyl-Le^x has been localizedto the heads of porcine sperm, and a monoclonal antibody thatrecognizes L-selectin binds the heads of human sperm [22, 23].In the current experiment, sperm were incubated in 2 µMGlc₄-BSA, Le^x-BSA, sialyl-Le^x-BSA, or sialyl-ßGal-BSA.As expected, Le^x-BSA induced the acrosome reaction (Fig. 3B).In contrast, sperm did not respond to sialyl-Le^x-BSA, demonstratingthat the addition of an ${alpha}$ 3-sialyl residue to the Lewis X resultsin a glycan that is unable to induce the acrosome reaction.Sialyl-ßGal-BSA was also inactive. These results,combined with the observation that GlcNAc-BSA and ßGal-BSAdo not induce the acrosome reaction, further support the conclusionthat the major class of ZP3 binding sites, which recognize Le^xand the sperm surface receptor activated by Le^x-Lac-BSA, arethe same sperm surface molecules. Additionally, these data donot implicate a role for sperm surface selectins in mouse sperm-ZPinteractions.

The Neoglycoprotein Le^x-Lac-BSA Is More Active at Inducing the Acrosome Reaction than Le^a-Lac-BSA

Recent work from our laboratory has led to the proposal thatLe^a-Lac is recognized by $~$ 30% of the ZP3 binding sites on capacitatedmouse sperm [5]. Furthermore, those sites do not recognize Le^x-containingglycans. This raises the question of whether the binding sitesthat recognize Le^a-Lac are also functional ZP3 receptors. Toaddress this issue, sperm were incubated with increasing concentrations(0, 0.375, 0.75, 1.5, 2.25, and 3 µM) of the neoglycoproteinLe^a-Lac-BSA, which contains the oligosaccharide Galß3[Fuc ${alpha}$ 4]GlcNAcß3Galß4Glc(Fig. 1-vii). As a positive control, an aliquot of sperm wasalso treated with 3 µM Le^x-Lac-BSA. Results demonstratedthat Le^a-Lac-BSA induced the acrosome reaction in a dose-dependentmanner (Fig. 4A). However, there were two major differencesbetween this dose response and the dose responses obtained withLe^x-Lac-BSA.

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FIG. 4. Le^a-Lac-BSA is a less-potent inducer of the acrosome reaction than Le^a-Lac-BSA. A) To test whether Le^a-Lac-BSA (which contains an isomer of Le^x) is capable of inducing the acrosome reaction, sperm were incubated with increasing amounts (0, 0.375, 0.75, 1.5, 2.25, and 3 µM) of Le^a-Lac-BSA and assessed for the presence or absence of their acrosomes. Three-micromolar Le^x-Lac-BSA (black bar) served as a positive control. The effect of 3 µM Le^x-Lac-BSA is threefold higher than the effect of 3 µM Le^a-Lac-BSA. The error bars for these data are within the dimension of the circles. B) To determine whether the addition of an ${alpha}$ 2-fucosyl residue alters activity of Le^a-Lac-BSA, sperm were incubated with 2 µM Glc₄-BSA (diagonally-striped bar), Le^a-Lac-BSA (vertically-striped bar), or Le^b-Lac-BSA, which contains the oligosaccharide Fuc ${alpha}$ 2Galß3[Fuc ${alpha}$ 4]GlcNAcß3Galß4Glc (white bar). All data (mean ± SEM; n = 4) are expressed as the percentage of sperm that are acrosome-reacted after incubation. Bars with different superscripts are statistically different (P < 0.05)

First, while the dose response to Le^x-Lac-BSA described a rectangularhyperbola (see Fig. 2), the response to Le^a-Lac-BSA was linear(R² = 0.86, P < 0.05). Second, Le^a-Lac-BSA was substantiallyless potent than Le^x-Lac-BSA in inducing the acrosome reaction.While saturation with Le^x-Lac-BSA was reached by 0.75 µM(Fig. 2A), Le^a-Lac-BSA at that concentration did not inducethe acrosome reaction. Additionally, at 3 µM neoglycoprotein,the fourfold induction of the acrosome reaction by Le^a-Lac-BSAwas significantly less than the sevenfold induction by Le^x-Lac-BSA(Fig. 4A).

Based on the observation that Le^a-Lac-BSA is less effectiveat inducing the acrosome reaction than Le^x-Lac-BSA, we testedwhether the activity of Le^a-Lac-BSA could be enhanced by addingan ${alpha}$ 2-fucosyl residue to the Lewis A structure, yielding theLewis B glycan structure. This was accomplished by incubatingsperm with 2 µM Glc₄-BSA, Le^a-Lac-BSA, or Le^b-Lac-BSA,which contains the oligosaccharide Fuc ${alpha}$ 2Galß3[Fuc ${alpha}$ 4]GlcNAcß3Galß4Glc (Fig. 1-viii). Results demonstrated thatthe addition of the second fucosyl residue to the Le^a oligosaccharideresulted in a glycan that, when clustered on a neoglycoprotein,was incapable of inducing sperm to undergo the acrosome reaction(Fig. 4B).

Le^x-Lac and Le^a-Lac are Dose-Dependent Inhibitors of the ZP-Induced Acrosome Reaction

The data presented thus far are consistent with the conclusionthat Le^x-BSA and Le^x-Lac-BSA are able to bind a major classof sperm surface ZP3 receptors and, consequently, stimulatesperm to undergo the acrosome reaction. Additionally, our datasuggest that Le^a-Lac-BSA induces the acrosome reaction via asecond class of ZP3 receptors. However, results from those experimentsdo not exclude the possibility that these neoglycoproteins areacting via sites on the sperm surface, which are not authenticZP3 receptors. However, if Le^x-Lac-BSA and Le^a-Lac-BSA are ligandsfor two distinct ZP3 receptors on capacitated sperm, then unconjugatedLe^x-Lac and Le^a-Lac should act as competitive inhibitors forthe ZP-induced acrosome reaction. Additionally, Le^x-Lac shouldbe a more effective inhibitor of the acrosome reaction thanLe^a-Lac. To test these predictions, sperm were preincubatedfor 15 min with or without increasing concentrations (0.18 to3.6 µM) of Le^x-Lac or Le^a-Lac, or with 3.6 µM ßGal-Lac,the negative control oligosaccharide. Following this incubation,sperm were incubated for an additional 90 min with medium aloneor with heat-solubilized ZP (equivalent to $~$ 90 nM ZP3). Resultsdemonstrate a dose-dependent inhibition of the ZP-induced acrosomereaction by Le^x-Lac (Fig. 5). Regression analysis demonstratedan excellent fit of the data to a rectangular hyperbola (R²= 0.95, P < 0.05). This analysis estimated an IC₅₀ of 121± 16 nM Le^x-Lac with a saturating dose of glycan ( $≥$ 0.9µM) reducing the ZP-induced acrosome reaction to approximately40% of control. In contrast, ßGal-Lac did not inhibitthe acrosome reaction. Le^a-Lac was also a dose-dependent inhibitorof the ZP-induced acrosome reaction, and the dose response tothis glycan also described a rectangular hyperbola (Fig. 5;R² = 0.92, P < 0.05). However, while this glycan was a high-affinity,competitive inhibitor of the acrosome reaction, with an IC₅₀of 189 ± 35 nM, a saturating dose ( $≥$ 0.9 µM) reducedthe ZP-induced acrosome-reacted sperm to only about 70% of control.Two-way analysis of variance verified that Le^x-Lac was a morepotent than Le^a-Lac as a competitive inhibitor of the ZP-inducedacrosome reaction. It is noteworthy that the dose-dependenteffects of Le^x-Lac and Le^a-Lac on the ZP-induced acrosome reactionare almost identical to their dose-dependent inhibition of thebinding of ZP3 to capacitated, acrosome-intact mouse sperm [5].Thus, the data presented herein support the hypothesis thatboth unconjugated Le^x- and Le^x-containing neoglycoproteins binda major class of ZP3 receptors and capacitated mouse sperm,in response to the neoglycoprotein, undergo the acrosome reaction.These data also support the conclusion that less-abundant ZP3binding sites, which differentially recognize Le^a-Lac, are alsofunctional receptors. However, Le^x-Lac-BSA is a more potentinducer of the acrosome reaction than Le^a-Lac-BSA.

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FIG. 5. Unconjugated Le^x-Lac and Le^a-Lac are dose-dependent competitive inhibitors of the ZP-induced acrosome reaction. To directly test the prediction that Le^x-Lac and Le^a-Lac bind to sperm surface ZP3 receptors, these glycans were assayed for their abilities to inhibit the ZP3-induced acrosome reaction. Sperm were preincubated for 15 min at 37°C in 5% CO₂ with 0 to 3.6 µM Le^x-Lac or Le^a-Lac or 3.6 µM ßGal-Lac, which served as the negative control glycan. Following this incubation, reaction mixtures were supplemented with either medium alone, or solubilized ZP estimated to generate a final ZP3 concentration of 90 nM. Sperm were then incubated for an additional 90 min at 37°C in 5% CO₂. These data (mean ± SEM; n = 3) are expressed as the percentage of sperm that are acrosome-reacted after incubation. Bars with different superscripts are statistically different (P < 0.05)

Capacitation Is a Prerequisite for the Sperm to Undergo the Acrosome Reaction in Response to Le^x-Lac-BSA

The ability of sperm to undergo the ZP-induced acrosome reactionis regulated by a maturation-like phenomenon called capacitation[24]. In order for sperm to undergo the acrosome reaction inresponse to the ZP, they must first become capacitated [25].While the molecular mechanisms underlying capacitation remainunder investigation, it is clear that this process requiresthe activation of a tyrosine kinase and changes in membranefluidity, intracellular ions (Ca²⁺, HCO₃^–), and secondmessengers (cAMP and protein kinase A) [26].

The data presented thus far demonstrate that a Le^x-containingneoglycoprotein is the most effective mimic of ZP3 that we tested.Thus, the Le^x-Lac-BSA-induced acrosome reaction should alsobe capacitation-dependent. To test this, sperm were culturedin medium that supports capacitation (M199-CM) or medium thatdoes not (M199-NCM) to obtain populations of either capacitatedor uncapacitated sperm. We used two independent criteria tocharacterize the capacitation status of sperm. First, crudeprotein extracts prepared from sperm incubated in either M199-CMor M199-NCM were subjected to Western blot analysis with a monoclonalantibody against phosphotyrosine. It has been demonstrated thata subset of sperm proteins become tyrosine phosphorylated duringcapacitation [27]. Western blot analysis of proteins from spermcultured in capacitating (M199-CM) and noncapacitating (M199-NCM)media displayed banding patterns that were consistent with previouslypublished results (data not shown). Additionally, aliquots ofthese sperm were incubated with solubilized ZP and assayed fortheir ability to undergo the ZP-induced acrosome reaction. Asexpected, sperm cultured in M199-CM acrosome-reacted in responseto ZP, whereas sperm cultured in M199-NCM did not (Fig. 6).Based on these criteria, we defined sperm isolated in M199-CMas capacitated and sperm from M199-NCM as uncapacitated.

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FIG. 6. Capacitation of sperm is a prerequisite for the Le^x-Lac-BSA-induced acrosome reaction. Sperm incubated in either M199-CM (white bars) or M199-NCM (black bars) were treated with Glc₄-BSA (2 µM), solubilized ZP (7.5/µl), or Le^x-Lac-BSA (2 µM), and tested for their ability to undergo the acrosome reaction. These data (mean ± SEM; n = 6) are expressed as the percentage of sperm that are acrosome-reacted after incubation. Bars with different superscripts are statistically different (P < 0.05)

To test the effect of capacitation on the neoglycoprotein-inducedacrosome reaction, capacitated and uncapacitated sperm wereincubated with 2 µM Le^x-Lac-BSA or 2 µM of the negativecontrol neoglycoprotein Glc₄-BSA. Reminiscent of the activityof solubilized ZP, Le^x-Lac-BSA was able to induce the acrosomereaction only in capacitated sperm (Fig. 6). This demonstratesthat both the ZP-induced and Le^x-Lac-BSA-induced acrosome reactionsare capacitation-dependent, supporting the hypothesis that Le^x-containingneoglycoproteins can bind to ZP3 receptors on sperm and canmimic the biological activity of ZP3.

Evidence that Le^x-Lac-BSA and Le^a-Lac-BSA Induce Sperm to Undergo the Acrosome Reaction via the Same Calcium-Dependent Pathway as ZP3

While the binding of ZP3 to its receptor results in the acrosomereaction, it is simply the first in a series of events thatoccur in the sperm that lead to acrosomal exocytosis. Presently,at least two independent signaling pathways have been identifiedin sperm upon binding ZP3 that lead to the acrosome reaction.One pathway involves an increase in intracellular calcium levels,which is posited to occur via the sequential action of spermsurface T-type calcium channels, IP3-mediated release of Ca⁺²from the acrosome, and a sustained influx of calcium into spermvia the sperm surface, to store-operated Trp-2 channels [28–31].Thus, if Le^x-Lac-BSA or Le^a-Lac-BSA binds to sperm surface ZP3receptors, inhibitors of specific parts of the pathway downstreamfrom these receptors should block the induction of the acrosomereaction by these neoglycoproteins.

To test the requirement of a functional T-type calcium channel,sperm were incubated with 2 µM Le^x-Lac-BSA, 3 µMLe^a-Lac-BSA, or seven heat-solubilized ZP per milliliter andin the presence or absence of flunarizine, a well-characterizedinhibitor of such channels. The dose of flunarazine that wasused, 2.2 µM, is the reported IC₅₀ dose for this compound[32]. As a control, sperm were treated with an equal volumeof the solvent for flunarazine, DMSO. Figure 7, A and B showthat flunarizine completely blocked induction of the acrosomereaction by heat-solubilized ZP, by Le^x-Lac-BSA, and by Le^a-Lac-BSA.In contrast, flunarazine did not reduce the low percentage ofsperm that underwent a spontaneous acrosome reaction in thepresence of the negative control neoglycoprotein, Glc₄-BSA.Thus, flunarizine inhibited the Le^x-Lac-BSA-, Le^a-Lac-BSA-,and ZP-acrosome reaction stimulations, but not the spontaneousacrosome reactions. To confirm that flunarazine was acting viaT-type calcium channels in mouse sperm, we also tested the effectof a second T-type calcium-channel inhibitor, amiloride, onthe Le^x-Lac-BSA-induced acrosome reaction. This inhibitor haspreviously been shown to block T-type calcium currents in dispersedspermatogenic cells [33]. Fifty-micromolar amiloride completelyblocked the ability of Le^x-Lac-BSA to induce the acrosome reaction(Table 1). Because T-type calcium channels allow the influxof Ca⁺² from the surrounding medium into sperm, we further testedthe requirement of the Le^x-Lac-BSA-induced acrosome reactionfor extracellular calcium. Sperm were incubated with 3 µMLe^x-Lac-BSA, 7 ZP/µl, or 3 µM Glc₄-BSA in the presenceor absence of 3.75 mM EGTA, a calcium chelator. Results showedthat EGTA completely blocked both the Le^x-Lac-BSA and ZP-inducedacrosome reaction (Table 1).

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FIG. 7. The ZP-acrosome reaction and the Le^x-Lac-BSA and Le^a-Lac-BSA acrosome reactions require a functional T-type calcium channel. A) Capacitated sperm were incubated with 2 µM Glc₄-BSA, 7.5 ZP/µl, or 2 µM Le^x-Lac-BSA in 2.2 µM flunarizine (black bars) or vehicle (white bars) for 90 min. B) Capacitated sperm were incubated with 3 µM Glc₄-BSA, 7.5 ZP/µl, or 3 µM Le^a-Lac-BSA in 2.2 µM flunarizine (black bars) or vehicle (white bars) for 90 min. Data (mean ± SEM; n $≥$ 3) are expressed as the percentage of sperm that are acrosome-reacted after incubation. Asterisks indicate where results of inhibitor treatment are significantly lower than vehicle treatment

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TABLE 1. Effect of amiloride, EGTA, and 2-APB on neoglycoprotein and ZP-induced acrosome reactions.*

Current models of the acrosome reaction posit that the influxof calcium into sperm via T-type calcium channels is followedby the IP3-mediated release of intracellular stores of calciumand the sustained influx of calcium into sperm through a store-operated,Trp-2 channel [29, 31, 34]. To test whether the later part ofthe calcium-dependent pathway is activated by Le^x-Lac-BSA, spermwere incubated with 3 µM Le^x-Lac-BSA or 7 ZP/µl,and with 50 µM 2-APB or vehicle (DMSO) for this inhibitor.2-ABP blocks IP3-stimlated release of intracellular calciumstores and inhibits Trp-1 channels [35, 36]. It is unknown whether2-APB also inhibits Trp-2 channels. Results of this experimentshow that incubation of sperm with 50 µM 2-APB blockedthe ability of both solubilized ZP and Le^x-Lac-BSA to inducethe acrosome reaction (Table 1). However, it had no effect onthe spontaneous acrosome reaction of sperm incubated with thenegative control, Glc₄-BSA. Thus, taken together, the effectsof flunarazine, EGTA, and 2-APB described above support thehypothesis that Le^x-Lac-BSA and Le^a-Lac-BSA induce the acrosomereaction via the same calcium-dependent pathway as ZP3.

The second intracellular pathway activated in sperm by ZP3 involvesa G_i protein, which can be inhibited by pertussis toxin, a compoundthat inactivates G_i proteins via ADP-ribosylation of the alphasubunit [14]. To determine whether Le^x-Lac-BSA and Le^a-Lac-BSAalso activate this second pathway, sperm were incubated withthese neoglycoproteins, with heat-solubilized ZP or the negativecontrol, Glc₄-BSA, in the presence or absence of 100 ng/ml pertussistoxin. This concentration of pertussis toxin is 10 times theamount required to inhibit the ZP-induced acrosome reaction[14]. In accordance with previous reports, sperm treated withpertussis toxin did not undergo the ZP-induced acrosome reaction.In contrast, pertussis toxin did not inhibit the ability ofeither 2 µM Le^x-Lac-BSA (Fig. 8A) or 3 µM Le^a-Lac-BSAto induce the acrosome reaction (Fig. 8B). We also conductedpreliminary experiments with the muscarinic receptor antagonistquinuclidinyl benzilate (QNB), which also blocks the ZP-inducedacrosome reaction [37]. In our experiments, 50 µM QNBinhibited the ZP-induced acrosome reaction, but not the Le^x-Lac-BSA-inducedacrosome reaction (data not shown). These data demonstrate thatthe neoglycoproteins Le^x-Lac-BSA and Le^a-Lac-BSA induce theacrosome reaction in a G_i protein-independent manner.

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FIG. 8. The neoglycoprotein-induced acrosome reaction is pertussis toxin-insensitive. A) Sperm were incubated with 2 µM Glc₄-BSA, 7.5 ZP/µl, or 2 µM Le^x-Lac-BSA in 100 ng/ml of pertussis toxin (black bars) or vehicle (white bars) for 90 min. B) Sperm were incubated with 3 µM Glc₄-BSA, 7.5 ZP/µl, or 3 µM Le^a-Lac-BSA in 100 ng/ml of pertussis toxin (black bars) or vehicle (white bars) for 90 min. Data (mean ± SEM; n $≥$ 3) are expressed as the percentage of sperm that are acrosome-reacted after incubation. Asterisks indicate where inhibitor blocked the acrosome reaction (as compared to vehicle)

DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
REFERENCES

The Neoglycoproteins Le^x-Lac-BSA and Le^x-BSA Bind to and Activate a Major Class of ZP3 Receptors on Sperm in a Glycan Structure-Specific Manner

The current paradigm for fertilization postulates that the interactionbetween the sperm and the ZP is a complex series of events.One of the first events is chiefly adhesive in nature and maybe mediated by O-linked glycans on ZP3 and corresponding spermsurface proteins [2]. A subsequent step involves the activationof at least two signaling pathways in sperm that lead to theinduction of the acrosome reaction. Experiments presented hereinhave addressed the issue of whether the sperm surface ZP3 bindingsites that recognize Le^x are, in fact, functional receptors.Pharmacologically, sperm surface sites involved in adhesionto the ZP, but not in the acrosome reaction, would be characterizedas acceptors because they would not trigger a biological eventin the sperm. On the other hand, a true receptor is definedas a molecule that triggers an intracellular signal in the cellupon binding its ligand. Our previous studies demonstrated thatLe^x-containing glycans were high-affinity inhibitors of sperm-ZPbinding [4]. Additionally, these glycans are ligands for $~$ 70%of the ZP3 binding sites detectable on capacitated mouse sperm[5]. However, neither of these studies could discriminate whetherthese glycans bound a sperm surface receptor or acceptor. Thiscurrent study indicates that BSA-based neoglycoproteins containingLe^x mimic the effect of solubilized ZP on the acrosome reactionby binding and activating a major class of ZP3 receptors. BothZP3 and Le^x-Lac-BSA act in a dose-dependent and saturable mannerand require prior capacitation of sperm. Seven other neoglycoproteinscontaining other, related glycan structures were inactive atthe doses tested, as summarized in Table 2. Finally, unconjugatedLe^x-Lac, but not the related nonfucosylated tetrasaccharide(ßGal-Lac), was a dose-dependent inhibitor of theZP-induced acrosome reaction. As described by the IC₅₀ and percentmaximal inhibition, Le^x-Lac had almost identical inhibitoryeffects on this process and on the saturable and specific bindingof fluorescently labeled ZP3 to sperm [5]. Taken together, thesedata support the conclusion that Le^x-containing oligosaccharidesbind in a glycan structure-specific manner to a major classof ZP3 receptors on the sperm surface, and when clustered ona polypeptide backbone, initiate the acrosome reaction.

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TABLE 2. Summary of the acrosome reaction-inducing activities of the neoglycoproteins tested in this report

The finding that Le^x-containing neoglycoproteins mimic the abilityof ZP3 to induce the acrosome reaction leads to the issue ofwhether the native glycans on ZP3 contain Le^x structures. Acomplicating factor in the structural analysis of the mouseZP's oligosaccharides is the scarcity of biological materialthat is available for complete and systematic study. Recentstructural analysis of the major O-linked glycans from totalmouse ZP3 did not detect Le^x structures [38]. Furthermore, ourlaboratory and others [39] have attempted to identify Le^x structureson the mouse ZP by immunocytochemistry or Western blotting withLe^x-specific monoclonal antibodies; these efforts have provedinconclusive. While these studies are certainly important, onemust take into account two important aspects of protein glycosylation.

First, glycoproteins exhibit a substantial degree of heterogeneityin their oligosaccharide structures, and our understanding ofglycoform diversity is limited by our technology. For example,P0, a major glycoprotein component of myelin, contains one N-linkedglycosylation site that was originally demonstrated by nuclearmagnetic resonance (NMR) and fast atom bombardment-mass spectrometry(FAB-MS) to carry a distinct sulfated glycan structure, humannatural killer cell carbohydrate epitope (HNK-1) (3-O-SO₃H-GlcUAß3Galß4GlcNAc-R)[40]. However, more recent NMR and MS techniques have establishedthat this one glycosylation site can carry at least 13 differentoligosaccharide structures, of which only 40% contain the HNK-1epitope [41]. By extrapolation to the ZP glycoproteins, themajority of the ZP3 oligosaccharides may not contain Le^x structures.There may be numerous glycan structures on the ZP glycoproteinsthat have not been identified to date due to their low abundancein the ZP.

Second, while the issue of whether Le^x-containing glycans arepresent on ZP3 remains unresolved, data presented here and elsewhere[5] provide important information regarding the glycan structurespecificity of the major class of ZP3 receptors. Clearly, thisreceptor contains a binding site for a fucosyl residue or asaccharide that closely mimics fucose, and the presentationof this residue is evidently important.

Le^a-Lac-BSA Binds to and Activates a Second Class of ZP3 Receptors on Sperm

Le^a-Lac binds to a second class of ZP3 binding sites, whichhave low affinity, if any, for Le^x-Lac [5]. The experimentsdescribed herein examined whether these less-abundant ZP3 bindingsites are functional receptors. Our data demonstrate that Le^a-Lac-BSAstimulates sperm to undergo the acrosome reaction. Additionalexperiments document that unconjugated Le^a-Lac is a saturableand specific inhibitor of the ZP-induced acrosome reaction.As described by the IC₅₀ and percent maximal inhibition, Le^a-Lachad almost identical inhibitory effects on this process andon the saturable and specific binding of fluorescently labeledZP3 to sperm [5]. Therefore, the most direct interpretationof these data is that the sperm surface sites, which bind Le^a-Lac,represent a second class of ZP3 receptors. To our knowledge,the data presented herein and in [5] provide the direct firstevidence that mouse sperm express multiple ZP3 receptors thatare distinguishable by their glycan binding specificity.

While Le^a-Lac-BSA induces the acrosome reaction by capacitatedmouse sperm, it is clearly less potent than Le^x-Lac-BSA. Thedifference in the response to these two neoglycoproteins hasa number of potential causes. The potency of these two neoglycoproteinsmay be dependent on the numbers of their respective sperm surfaceZP3 receptors. The class of receptors, which recognize Le^x-Lac,clearly predominates. Alternatively, while Le^a-Lac is a ligandfor a class of ZP3 receptors on sperm, Le^a-Lac-BSA may be lesseffective than Le^x-containing neoglycoproteins at inducing thestructural changes in a ZP3 receptor that are needed to activateintracellular signal transduction pathways.

Le^x-Lac-BSA and Le^a-Lac-BSA Activate a Calcium-Dependent Pathway, but Not a G_i Protein-Dependent Pathway

The data presented in this report support the conclusion thatLe^x-Lac-BSA and Le^a-Lac-BSA bind to distinct classes of ZP3receptors on sperm, and that this binding activates the samecalcium-dependent pathways in sperm as ZP3. Similar to the responseof capacitated mouse sperm to heat-solubilized ZP, the responseto these two neoglycoproteins requires a functional T-type calciumchannel. Consistent with current models of the ZP-induced acrosomereaction, the Le^x-Lac-BSA-induced acrosome reaction is alsoinhibited by chelation of extracellular calcium with EGTA andby blocking release of intracellular calcium stores with 2-APB.

While the ZP-induced acrosome reaction was sensitive to pertussistoxin, an inhibitor of G_i proteins, it did not block the neoglycoprotein-inducedacrosome reaction. Our data do not address the issue of whetherLe^x-Lac-BSA or Le^a-Lac-BSA activate a G_i protein but do indicatethat such activation, if it occurs, is unnecessary for inductionof the acrosome reaction by these two neoglycoproteins. Additionally,our data suggest that activation of the calcium-dependent pathwayis sufficient for the induction of the acrosome reaction bythese two neoglycoproteins. Why is activation of the calcium-dependentpathway sufficient for Le^x-Lac-BSA or Le^a-Lac-BSA to inducethe acrosome reaction while a G_i protein-dependent pathway isalso required for the ZP-induced acrosome reaction?

First, treatment of capacitated sperm with a calcium ionophorewill induce the acrosome reaction [29, 42–45]. Thus, arise in free intracellular calcium levels of sufficient magnitudeis adequate to induce capacitated sperm to undergo the acrosomereaction. Second, studies in other cell types (e.g., lymphocytes)indicate that an increase in the numbers of cell surface receptorsthat are cross-linked by a single ligand can potentiate theresulting elevation in free intracellular calcium levels (seefor example [46, 47]). By extrapolation to sperm, it is possiblethat Le^x-Lac-BSA and Le^a-Lac-BSA cross-link a larger numberof ZP3 receptors than ZP3 itself. In our studies, there wasan average of nine or more potential sperm binding glycans oneach molecule of Le^x-Lac-BSA and Le^a-Lac-BSA. Thus, a singlemolecule of these two neoglycoproteins might cross-link multipleZP3 receptors on a given capacitated sperm. In contrast, recentdata indicate that there is an average of 11 O-linked glycanson each molecule of ZP3 [48]. However, as available evidencesuggests that these glycans are structurally diverse, only asmall subset of the 11 glycans may bind ZP3 receptors [19].Thus, Le^x-Lac-BSA and Le^a-Lac-BSA may be able to cross-linka larger number of ZP3 receptors, and consequently cause a largerincrease in intracellular free calcium levels than the naturalligand, ZP3. This might be sufficient to make the G_i protein-mediatedpathway dispensable for the induction of the acrosome reaction.

Contrasting Data Concerning Glycan Structures Recognized by Mouse ZP3 Receptors

Using three different experimental approaches [4, 5], our laboratoryhas identified the Le^x trisaccharide as a high-affinity ligandfor a major class of ZP3 receptors on mouse sperm. Additionally,our data indicate that the structural isomer of Le^x, Le^a, recognizesa second, less-abundant class of ZP3 receptors. Thus, whilethe specific glycans on ZP3 that bind sperm surface receptorshave yet to be defined, our data support the hypothesis thatthere are, at minimum, two functional glycans on the ZP thatbind distinct receptors on the surface of capacitated mousesperm [4, 49, 50]. However, our conclusion about characteristicsof sperm-binding glycans differs from conclusions of other laboratories.Consideration of the studies by these other laboratories is,therefore, warranted.

Tulsiani and colleagues [49, 51, 52] have proposed that a singleclass of ZP3 receptors on sperm recognizes nonreducing terminalmannose, GlcNAc and GalNAc residues. This proposal comes fromstudies of the binding of mouse sperm to mannose-BSA, GlcNAc-BSA,and GalNAc-BSA, and induction of the acrosome reaction by theseneoglycoproteins. Sperm bound to GlcNAc-BSA, GalNAc-BSA, andMannose-BSA immobilized on Sepharose beads, but not to Glc-BSAor Gal-BSA [53]. A single class of sperm surface molecules wasshown to be responsible for this binding activity because unconjugatedmannose, GlcNAc, and GalNAc inhibited the binding of sperm toneoglycoproteins containing any one of these three monosaccharides.This apparent binding of a single class of sperm surface moleculesto three different monosaccharides is unexpected given the theorythat sperm bind to the ZP in a glycan-structure-specific manner[54].

Tulsiani and colleagues also demonstrated that neoglycoproteinscontaining mannose, GlcNAc, or GalNAc, but not Gal or Glc, inducedcapacitated mouse sperm to undergo the acrosome reaction [51,52, 55]. This induction was blocked by the L-type calcium-channelinhibitors, verapamil and diltiazem, but not by the T-type calcium-channelinhibitor, amilioride [51]. The inhibitory activity of verapamiland diltiazem but not of amilioride is significant because currentdata indicate that ZP3 receptors on mouse sperm, when boundto the ZP, activate a T-type calcium channel [30].

A second model posits that ß4-galactosyltransferase1 (ß4-Gal T1) is the primary ZP3 receptor on the surfaceof mouse sperm and, as such, binds nonreducing terminal GlcNAcresidues on ZP3 (see [21] for review). Immunocytochemistry localizedß4-Gal T1 to the plasma membrane overlying the acrosomeand antibodies to ß4-Gal T1 induced sperm to undergothe acrosome reaction [56, 57]. Forced ß4 galactosylationreduced, but did not eliminate, the ability of ZP3 to act asa competitive inhibitor of sperm-ZP binding [58]. Additionally,de novo expression of ß4-Gal T1 in frog eggs renderedthem responsive to ZP3. Finally, in vitro, neither anti-ß4-GalT1 nor solubilized ZP glycoproteins induce ß4-GalT1-null sperm to undergo the acrosome reaction. However, otherdata do not support the view that mouse sperm surface ß4-GalT1 acts as the primary sperm surface receptor for ZP3. Monovalentfluorescent probes localized ß4-Gal T1 to the posteriorsperm head, not to the plasma membrane overlying the acrosome.Those same studies demonstrated that the binding of polyvalentanti-ß4-Gal T1 immunoglobulin G to mouse sperm causedthe movement of ß4-Gal T1 from the posterior regionof the sperm head to the plasma membrane overlying the acrosome[59]. Additionally, in three of five experiments, sperm fromß4-Gal T1-null mice were shown to bind radiolabeledZP3 [60]. In experiments in which this binding was observed,the amount of radiolabeled ZP3 bound by ß4-Gal T1-nullsperm was 30% to 50% the amount of radiolabeled ZP3 bound tosperm from wild-type mice. Because only a single dose of radiolabeledZP3 was tested in these experiments, it was impossible to distinguishwhether sperm lacking ß4-Gal T1 had fewer ZP3 bindingsites or bound ZP3 with lower affinity. Additionally, two laboratoriesfailed to observe inhibition of sperm-ZP binding by oligosaccharideswith terminal GlcNAc residues [3, 4]. Finally, in vivo, ß4-GalT1-null sperm are fertile [60]. Recently, Shur and colleagues[50] presented data supporting the hypothesis that in vitro,sperm from ß4-Gal T1-null mice bind the zona via aZP3-independent mechanism. The authors raised the possibilitythat the ligand on the ZP for ß4-Gal T1-null spermwas an adsorbed oviductal glycoprotein. However, it seems unlikelythat an adsorbed oviductal glycoprotein would act in vivo asthe sole ligand for sperm, which lack ß4-Gal T1. Thissame protein, which is soluble in oviductal fluid, would competewith the same protein adsorbed on the ZP for binding sites onthe sperm surface.

While the data obtained from our studies disagree with datafrom other laboratories, those other data are still the subjectof active debate and experimentation. Therefore, all currentmodels of sperm-ZP interactions, including those posited byour laboratory, deserve further exploration. Emphasis shouldbe placed on testing these models in intact animals. Our model,presented here and in [5], support the hypothesis that thereare two distinct ZP3 binding sites on the sperm surface thatcan be distinguished by their affinities for Le^x-Lac and Le^a-Lac.Our in vitro studies indicate that these sites are functionalreceptors, which when bound to ZP3 or other high-affinity ligands,stimulate capacitated mouse sperm to undergo the acrosome reactionvia a calcium-dependent mechanism.

ACKNOWLEDGMENTS

We are grateful to Ms. Janet Folmer for technical assistancewith fluorescence microscopy; Drs. Jurrien Dean and Philip Castlefor advice and instruction on ZP isolation; Dr. Pablo Viscontifor technical assistance with sperm protein tyrosine phosphorylationexperiments; and Drs. Ronald Schnaar, Martin Charron, and HarveyFlorman for informative discussions.

FOOTNOTES

¹ This work was supported by National Institute for Child Healthand Human Development (NICHD) 1 R01 HD-35699 and by the JohnsHopkins University Population Center (P30-HD-06268). W.F.H.and C.L.K. were supported in part by NICHD 5T32 HD-07276.

² Correspondence: William W. Wright, Johns Hopkins UniversityBloomberg School of Public Health, Department of Biochemistryand Molecular Biology, Room 3508, 615 N. Wolfe St., Baltimore,MD 21205. FAX: 410 614 2356; wwright1{at}jhem.jhmi.edu

Received: 30 September 2003.

First decision: 21 October 2003.

Accepted: 9 April 2004.

REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
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Gamete Biology

Lewis X-Containing Neoglycoproteins Mimic the Intrinsic Ability of Zona Pellucida Glycoprotein ZP3 to Induce the Acrosome Reaction in Capacitated Mouse Sperm1

Lewis X-Containing Neoglycoproteins Mimic the Intrinsic Ability of Zona Pellucida Glycoprotein ZP3 to Induce the Acrosome Reaction in Capacitated Mouse Sperm¹