Regionalization of transmembrane glycoproteins in the plasma membrane of boar sperm head is revealed by fracture-label

We used fracture-label and surface labeling techniques to characterize the distribution and topology of wheat germ agglutinin (WGA) receptors in the plasma membrane of boar sperm heads. We show that freeze- fracture results in preferential, but not exclusive, partition of WGA- binding sites with the outer (exoplasmic) half of the plasma membrane. Labeling of the inner (protoplasmic) half of the membrane is significant, and is denser over the areas that overlie the acrosome. Exoplasmic membrane halves are uniformly labeled. Analysis of freeze- fracture replicas revealed that the distribution of intramembrane particles over protoplasmic faces parallels that of WGA-binding sites as observed by fracture-label. Coating of intact spermatozoa with cationized ferritin results in drastic reduction of the labeling of both protoplasmic and exoplasmic membrane halves. Labeling of sperm cells lysed by short hypotonic shock fails to reveal the presence of WGA-binding sites at the inner surface of the plasma membrane. We conclude that: (a) all WGA-binding glycoconjugates are exposed at the outer surface of the membrane; (b) some of these glycoconjugates correspond to transmembrane glycoproteins that, on fracture, partition with the inner half of the membrane; (c) these transmembrane proteins are accumulated in the region of the plasma membrane that overlies the acrosome; and (d) parallel distribution of intramembrane particles and WGA-binding glycoproteins provides renewed support for the view of particles as the morphological counterpart of integral membrane proteins.     

Topographical and planar distribution of Helix pomatia lectin-binding glycoconjugates in secretory granules and plasma membrane of pancreatic exocrine acinar cells of the rat: demonstration of membrane heterogeneity

The lectin-gold technique was used to detect Helix pomatia lectin (HPL) binding sites directly on thin sections of rat pancreas embedded in Lowicryl K4M and on freeze-fractured preparations of rat pancreas submitted to fracture label. On thin sections of acinar cells, whereas the content of zymogen granules was negative or weakly labeled, the limiting membrane displayed a high degree of labeling. In the Golgi complex, labeling by HPL was localized on the trans saccules and the limiting membrane of the condensing vacuoles. The latter appeared to be more intensely labeled than the membrane of the zymogen granules. Intense labeling by HPL was also observed along the microvilli and the plasma membrane. In contrast to the weak labeling of the zymogen-granule content, labeling of the acinar lumen was intense. Fracture-label preparations revealed preferential partition of HPL-binding sites to the exoplasmic half of the zymogen-granule and plasma membranes. The population of zymogen granules was, however, heterogeneous with respect to labeling intensity; the exoplasmic fracture-face of the plasma membrane was intensely and uniformly labeled, while the protoplasmic membrane halves were only weakly labeled. These observations were further confirmed and extended by the thin-section fracture-label approach. In addition, favorable profiles of thin sections of freeze-fractured zymogen granules showed that the labeling was not associated with the external surface of the limiting membrane, but rather localized over the exoplasmic fracture-face. We conclude that 1) zymogen granules contain little HPL-binding glycoconjugates, 2) HPL-binding sites are preferentially associated with the exoplasmic half of the zymogen-granule and plasma membranes, and 3) the limiting membrane of the immature condensing vacuoles carries a greater number of HPL-binding sites than that of the mature zymogen granules. These last, in turn, constitute a heterogenous population with respect to labeling density. These results support the current view that glycoconjugates are directed toward the lumen in secretory granules but become external to the cell surface after fusion of the secretory-granule membrane with the plasma membrane. Also, the results reflect membrane modifications during the maturation process of secretory granules in the exocrine pancreas in which glycoproteins are removed from the limiting membrane of the granule to become soluble and secreted with the content.     

Surface alterations during the capacitation of mammalian spermatozoa

Capacitation is the process by which mammalian sperm acquire the ability to undergo the acrosome reaction which, in turn, is a prerequisite for sperm-egg fusion and penetration. Until recently, it was thought that capacitation involved subtle physiological and chemical changes which had no morphological counterparts even at the electron microscopic level. However, it has now been shown by a number of investigators that material associated with the plasma membrane surface is either lost or extensively redistributed during in vitro or in vivo capacitation. We have made use of lectins and antibodies as probes of the sperm surface during capacitation and the acrosome reaction. Concanavalin A (Con A), wheat germ agglutinin (WGA) and soybean agglutinin (SBA) have been used in conjunction with fluorescent tags (FITC) and ultrastructural markers (ferritin, hemocyanin) to study the surface of golden hamster, guinea pig, mouse and human spermatozoa. Con A and WGA label the plasma membrane overlying the acrosomal region quite uniformly on these species. After capacitation there is a specific loss (or masking) of lectin binding sites over the acrosomal region of the sperm head in all species examined. Antibodies prepared against sperm and specific antibodies to a cell surface protein (fibronectin) were also tagged with fluorescent or ultrastructural markers and used to label the surfaces of sperm before and after capacitation. These probes also indicate a specific loss of surface associated material over the acrosomal surface after capacitation. These results are consistent with the notion that there is a general removal of surface components during capacitation and that this denuding of the surface is a prerequisite for the following membrane fusion events involved in the acrosome reaction and sperm-egg fusion.     

Protein translocation across the endoplasmic reticulum. I. Detection in the microsomal membrane of a receptor for the signal recognition particle

Thin-section and critical-point-dried fracture-labeled preparations are used to determine the distribution and partition of glycophorin- associated wheat germ agglutinin (WGA) binding sites over protoplasmic and exoplasmic faces of freeze-fractured human erythrocyte membranes. Most wheat germ agglutinin binding sites are found over exoplasmic faces. Label is sparse over the protoplasmic faces. These results contrast with previous observations of the partition of band 3 component where biochemical analysis and fracture-label of concanavalin A (Con A) binding sites show preferential partition of this transmembrane protein with the protoplasmic face. Presence of characteristic proportions of WGA and Con A binding sites over each fracture face is interpreted to indicate the operation of a stochastic process during freeze-fracture. This process appears modulated by the relative expression of each transmembrane protein at either surface as well as by their association to components of the erythrocyte membrane skeleton.     

Structural and cytochemical differentiation of membrane elements of the apical membrane of amphibian urinary bladder epithelial cells. A label fracture study

It is now generally accepted that ADH-induced increase in water permeability in responsive epithelia is associated with the insertion of specific structures in the apical membrane of epithelial cells. Up to now, these structures have only been recognized in freeze-fractured preparations and their chemical nature is still unknown. In this study, we used the label-fracture method (Pinto da Silva and Kan, J. Cell Biol., 99, 1156-1161, 1984) to investigate the distribution of wheat germ agglutinin (WGA) on the luminal plasma membrane of freeze-fractured frog urinary bladder epithelial cells. With label-fracture, the cytochemical markers are seen superimposed with the conventional high resolution image of the E face. Label-fracture of tissue treated for 15 min with WGA and subsequently labeled with colloidal gold coated with ovomucoid showed uniform distribution of gold particles along the exoplasmic fracture face. Stereomicrographs show that the gold label is under the fracture face as it is attached to the outer surface of the membrane. Preincubation of the bladder with WGA for 3 hr induced a segregation of the intramembranous particles of the apical plasma membrane. In this condition, we observed a co-distribution of WGA-gold complexes with the segregated particles on the E face. This indicates that WGA-binding sites are located on glycoproteins which probably comprise the large intramembranous particles dispersed on the exoplasmic faces of freeze-fractured luminal membranes. In contrast, the numerous small intramembrane particles observed on P faces remained evenly distributed even after exposure to WGA and are, therefore, unrelated to WGA receptor sites. After WGA treatment, ADH still induced the formation of aggregates inside the smooth domains. A few WGA-binding sites appeared to be associated to these aggregates.     

Label-fracture: a method for high resolution labeling of cell surfaces

We introduce here a technique, "label-fracture," that allows the observation of the distribution of a cytochemical label on a cell surface. Cell surfaces labeled with an electron-dense marker (colloidal gold) are freeze-fractured and the fracture faces are replicated by plantinum/carbon evaporation. The exoplasmic halves of the membrane, apparently stabilized by the deposition of the Pt/C replica, are washed in distilled water. The new method reveals the surface distribution of the label coincident with the Pt/C replica of the exoplasmic fracture face. Initial applications indicate high resolution (less than or equal to 15 nm) and exceedingly low background. "Label-fracture" provides extensive views of the distribution of the label on membrane surfaces while preserving cell shape and relating to the freeze-fracture morphology of exoplasmic fracture faces. The regionalization of wheat germ agglutinin receptors on the plasma membranes of boar sperm cells is illustrated. The method and the interpretation of its results are straightforward. Label-fracture is appropriate for routine use as a surface labeling technique.     

Changes of Con A Receptor Sites on Mammalian Sperms during Capacitation and Acrosome Reaction

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Sialyl glycoprotein distribution on the plasma membrane of ejaculated ram spermatozoa

Localization of sialyl residues on unfixed ejaculated ram sperm membrane using the direct covalent probes of either ferritin hydrazide or latex hydrazide revealed a unique regional distribution on the plasmalemma covering the sperm head only. Three different labelling zones were identified based on the intensity and the nature of the sialyl glycoconjugates: a patchy-like zone which included the plasma membrane overlaying the post-nuclear cap and the convex side of the apical body of the acrosome; highly ordered heavily labelled zones including the plasmalemma adjacent to the concave apical body of the acrosome and to the posterior part of the equatorial acrosomal segment; a paucity-labelling zone which included the plasma membrane underlying the principal acrosomal region and the anterior part of the equatorial acrosomal segment. The possible physiological role of the highly ordered labelled zones is discussed.     

Goat sperm membrane: lectin-binding sites of sperm surface and lectin affinity chromatography of the mature sperm membrane antigens.

The cell surface glycoproteins of goat epididymal maturing spermatozoa have been investigated using lectins as surface probes that interact with specific sugars with high affinity. Concanavalin A (ConA) and wheat-germ agglutinin (WGA) showed high affinity for mature cauda epididymal sperm agglutination, whereas RCA2, kidney beans lectin and peanut agglutinin caused much lower or little agglutination of the cells. The mature sperm exhibited markedly higher efficacy than the immature caput epididymal sperm for binding both ConA and WGA, as evidenced by sperm agglutination and the binding of the fluorescence isothiocyanate (FITC)-labelled lectins. FITC-ConA binds uniformly to the entire mature sperm surface whereas FITC-WGA binds to the acrosomal cap region of the head. The FITC-RCA2 mainly labelled the posterior head of mature cauda sperm. However, no WGA-specific glycoprotein receptors could be detected in sperm plasma membrane (PM) by WGA-Sepharose affinity chromatography. The data implied that the epididymal sperm maturation is associated with a marked increase in the ConA/WGA receptors and that WGA receptors may be glycolipids rather than glycoproteins. Analysis of the ConA receptors of cauda sperm PM identified by ConA-Sepharose affinity chromatography and subsequent resolution in SDS-PAGE demonstrated the presence of five glycopolypeptides of different concentrations (98, 96, 43, 27 and 17 kDa) of goat sperm membrane. The immunoblot of these ConA-specific glycopeptides with anti-sperm membrane antiserum showed that 98- and 96-kDa receptors are immunoresponsive.     

Biochemical characterization of the PH-20 protein on the plasma membrane and inner acrosomal membrane of cynomolgus macaque spermatozoa

Preparations of sperm membranes (plasma membranes and outer acrosomal membranes) and denuded sperm heads were isolated from macaque sperm, and the PH-20 proteins present were characterized by Western blotting, hyaluronic acid substrate gel analysis, and a microplate assay for hyaluronidase activity. Because we have shown previously that PH-20 is located on the plasma membrane and not on the outer acrosomal membrane, the PH-20 in the membrane preparations was presumed to be plasma membrane PH-20 (PM-PH-20). PM-PH-20 had an apparent molecular weight of 64 kDa and the optimum pH for its hyaluronidase activity was 6.5. The PH-20 associated with denuded sperm heads was localized by immunogold label to the persistent inner acrosomal membrane (IAM) and was presumed to be IAM-PH-20, which included a major 64 kDa form and a minor 53 kDa form. The 53 kDa form was not detected in extracts of denuded sperm heads from acrosome intact sperm that were boiled in nonreducing sample buffer, but was present in extracts of sperm heads from acrosome reacted sperm and in the soluble material released during the acrosome reaction, whether or not the samples were boiled. Substrate gel analysis showed that the hyaluronidase activity of the 53 kDa form of PH-20 was greatest at acid pH, and this activity was probably responsible for the broader and lower optimum pH of IAM hyaluronidase activity. When hypotonic treatment was used to disrupt the sperm acrosome and release the acrosomal contents, less than 0.05% of the total hyaluronidase activity was released. The PH-20 protein released by hypotonic treatment was the 64 kDa form and not the 53 kDa form, suggesting that its source might be the disrupted plasma membranes. Our experiments suggest that the soluble form of hyaluronidase, which is released at the time of the acrosome reaction, is derived from the IAM. This soluble hyaluronidase is composed of both the 64 kDa form and 53 kDa form of PH-20. The 53 kDa form appears to be processed from the 64 kDa form at the time of the acrosome reaction. Mol. Reprod. Dev. 48:356–366, 1997. © 1997 Wiley-Liss, Inc.     

Heterogeneous distribution of plasma membrane glycoconjugates in pancreatic acinar cells

Flow-cytometric studies of lectin binding to individual acinar cells have been carried out in order to analyse the distribution of membrane glycoconjugates in cells from different areas of the pancreas: duodenal lobule (head) and splenic lobule (body and tail). The following fluoresceinated lectins were used: wheat germ agglutinin (WGA), Tetragonolobus purpureus agglutinin (TP) and concanavalin A (Con A), which specifically bind to N-acetyl D-glucosamine and sialic acid, L-fucose and D-mannose, respectively. In both pancreatic areas, two cell populations (R1 and R2) were identified according to the forward scatter (size). On the basis of their glycoconjugate pattern, R1 cells displayed higher density of WGA and TP receptors than R2 cells throughout the pancreas. Although no difference in size was found between the cells from duodenal and splenic lobules, N-acetyl D-glucosamine and/or sialic acid and L-fucose residues were more abundant in plasma membrane cell glycoconjugates from the duodenal lobule. The results provide evidence for biochemical heterogeneity among individual pancreatic cells according to the distribution of plasma membrane glycoconjugates.     

Detection of acrosome-reacted toad sperm based on specific lectin binding to the inner acrosomal membrane

When the sperm of the toad Bufo japonicus were treated with fluorescein isothiocyanate (FITC)-conjugated peanut agglutinin (PNA), soybean agglutinin (SBA), or Dolichos biflorus agglutinin (DBA), a few sperm fluoresced at the acrosomal region. The number of sperm showing this lectin binding to the acrosome increased significantly upon mild sonication of the sperm suspension. Electron microscopy revealed that ferritin-conjugated PNA bind not to the outer acrosomal and overlying plasma membranes, but specifically to the surface of the inner acrosomal membrane exposed by sonication. Both the percentage of FITC-PNA-labeled sperm and the activity of vitelline coat lysin released by sperm increased in good correlation with increasing sonication time, although the PNA-labeled sperm decreased in number upon longer sonication. These results indicate that the binding of FITC-PNA to the sperm provides a reliable measure of the acrosome reaction of Bufo sperm.     

Zona pellucida protein binding ability of porcine sperm during epididymal maturation and the acrosome reaction

In many mammals, the first interaction between gametes during fertilization occurs when sperm contact the zona pellucida surrounding the egg. Although porcine sperm first contact the zona pellucida via their plasma membrane, the regions of the sperm surface that display zona receptors have not been determined. We have used the Alexa 488 fluorophore conjugated to solubilized porcine zona pellucida proteins to observe zona receptors on live boar sperm. Zona proteins bound live, acrosome-intact sperm on the anterior portion of the sperm head, concentrated in a thin band over the acrosomal ridge. When sperm membranes were permeabilized by fixation or acrosome reactions induced by the ionophore A23187, zona binding was extended to a broad area covering the entire acrosomal region. Zona binding proteins were present in the acrosomes of sperm from all regions of the epididymis. In contrast, zona binding sites were found on the plasma membrane of most sperm from the corpus and cauda epididymis, but on only 6% of caput epididymal sperm. In conclusion, acrosome-intact boar sperm exhibit concentrated zona protein binding over the acrosomal ridge and acquire this binding in the corpus region of the epididymis, correlating with the developmental stage at which sperm gain the ability to fertilize oocytes.     

Lectin-binding sites on the plasma membranes of rabbit spermatozoa: Changes in surface receptors during epididymal maturation and after ejaculation

Modifications in rabbit sperm plasma membranes during epididymal passage and after ejaculation were investigated by used of three lectins: concanavalin A (Con A); Ricinus communis I (RCA(I)); and wheat germ agglutinin (WGA). During sperm passage from caput to cauda epididymis, agglutination by WGA drastically decreased, and agglutination by RCA(I) slightly decreased, although agglutination by Con A remained approximately unchanged. After ejaculation, spermatozoa were agglutinated to a similar degree or slightly less by Con A, WGA, and RCA(I), compared to cauda epididymal spermatozoa. Ultrastructural examination of sperm lectin-binding sites with ferritin- lectin conjugates revealed differences in the densities of lectin receptors in various sperm regions, and changes in the same regions during epididymal passage and after ejaculation. Ferritin-RCA(I) showed abrupt changes in lectin site densities between acrosomal and postacrosomal regions of sperm heads. The relative amounts of ferritin-RCA(I) bound to heads of caput epididymal or ejaculated spermatozoa. Tail regions were labeled by ferritin RCA(I) almost equally on caput and cauda epididymal spermatozoa, but the middle-piece region of ejaculated spermatozoa was slightly more densely labeled than the principal-piece region, and these two regions on ejaculated spermatozoa were labeled less than on caput and cuada epididymal spermatozoa. Ferritin-WGA densely labeled the acrosomal region of caput epididymal spermatozoa, although labeling of cauda epidiymal spermatozoa was relatively sparse except in the apical area of the acrosomal region. Ejaculated spermatozoa bound only a few molecules of ferritin-WGA, even at the highest conjugate concentrations used. Caput epididymal, but not cauda epididymal or ejaculated spermatozoa, bound ferritin-WGA in the tail regions. Dramatic differences in labeling densities during epididymal passage and after ejaculation were not found with ferritin-Con A.     

Isolation of the outer acrosomal membrane from bull sperm.

A procedure is described for subcellular fractionation of bull sperm which allows the isolation of outer acrosomal membrane without the use of detergent. After washing to remove seminal plasma contaminants, the acrosomal membrane is removed by homogenization and separated on a two-step sucrose gradient. The isolated membranes have been characterized by light and electron microscopy and enzyme analysis. While the acrosomal enzymes hyaluronidase and acrosin are bound to the isolated membranes, they represent only a small percentage of the total activity and therefore do not provide reliable marker enzymes for this fraction. Subcellular fractionation of sperm also yields information on the solubility of acrosomal enzymes. Two types of acrosomal enzymes have been identified on the basis of their distribution in gradient fractions. Both alpha-fucosidase and beta-N-acetyl glucosaminidase are concentrated in the soluble fraction of the gradient. In contrast, over 70% of the acrosin and hyaluronidase activity remains associated with the sperm pellet. These differences in solubility of these enzymes may reflect differences in their function in fertilization.     

On tight-junction structure

We have analyzed previous thin-section and freeze-fracture observations of the tight junction. We propose that the tight-junction strands represent intramembranous, cylindrical, inverted micelles. At the junctional site, the exoplasmic halves of the plasma membranes are fused into a continuous leaflet. Therefore, topologically and structurally the tight junction is viewed as the outcome of a process of linear fusion between the plasma membranes of epithelial cells. The extracellular spaces delimited by the junction are separated by two distinct exoplasmic membrane halves and the cylindrical micelles. Junctional stability, fostered by the environmental symmetry of the cytoplasmic milieux of contiguous cells, may be maintained by transmembrane integral proteins at the junctional site, interacting at the cytoplasmic surface with cytoskeletal components.     

Phosphatidylcholine and phosphatidylinositol-specific phospholipases C of bull and rabbit spermatozoa.

Acrosomal reaction is an essential prerequisite to fertilization. The changes in lipid composition of sperm membranes cause fusion of the plasma and outer acrosomal membranes that results in the exocytosis of acrosomal contents. We report that both bull and rabbit spermatozoa contain a phosphatidylcholine-specific phospholipase C (PC-PLC) that hydrolyzes L-alpha-dipalmitoyl-(choline-methyl-14C-153.0 Ci/mmol and a phosphatidylinositol-specific phospholipase C (PI-PLC) that hydrolyzes L-alpha-(Myo-Inositol-2-3H (N)-5.2 Ci mmol. PI-PLC from bull sperm acrosome has been purified 568 x fold with a specific activity 6.25 +/- 0.6 nmol/min/mg protein, km 0.004 mM, and Vmax 12 nmol/min/mg protein. Both enzymes had optimum at pH 7.5. The activity of PC-PLC remained unaffected by varying concentrations of Ca2+, whereas PI-PLC activity was significantly increased. The bulk of PI-PLC was found to be associated with inner acrosomal membrane of bull and rabbit sperm, while PC-PLC was found in the outer acrosomal membranes in the bull sperm and the plasma membrane of the rabbit sperm. Both enzymes are compartmentalized in sperm cell.     

Interaction of the sperm adhesive protein, bindin, with phospholipid vesicles. I. Specific association of bindin with gel-phase phospholipid vesicles

Bindin is a 30,000-mol-wt protein of sea urchin sperm that is responsible for the specific adhesion of the sperm acrosomal process to the vitelline layer covering the egg plasma membrane during fertilization. Sulfated glycoconjugates are believed to be the egg surface receptors for bindin, but the mechanism by which bindin associates with the sperm acrosomal membrane is unknown. Here I report that bindin specifically associates with phospholipid vesicles in vitro. Interaction of the bindin polypeptide with liposomes was found to cause an increase in the density of the liposomes and induce the aggregation of the vesicles. A novel property of this association of bindin with membranes was that it required phospholipids in a gel phase. The interaction of bindin with liposomes was greatly reduced at temperatures above the phase transition temperature. The interaction of bindin with gel-phase vesicles appeared to be reversible, since the aggregated vesicles dissaggregated as the temperature was raised above the phase transition temperature. Association of bindin with the bilayer did not alter the accessibility of the polypeptide to cleavage by trypsin, which suggests that most of the polypeptide chain remains exposed at the surface of the membrane.     

Sperm plasma membrane breakdown during Drosophila fertilization requires sneaky, an acrosomal membrane protein

Fertilization typically involves membrane fusion between sperm and eggs. In Drosophila, however, sperm enter eggs with membranes intact. Consequently, sperm plasma membrane breakdown (PMBD) and subsequent events of sperm activation occur in the egg cytoplasm. We previously proposed that mutations in the sneaky (snky) gene result in male sterility due to failure in PMBD. Here we support this proposal by demonstrating persistence of a plasma membrane protein around the head of snky sperm after entry into the egg. We further show that snky is expressed in testes and encodes a predicted integral membrane protein with multiple transmembrane domains, a DC-STAMP-like domain, and a variant RING finger. Using a transgene that expresses an active Snky-Green fluorescent protein fusion (Snky-GFP), we show that the protein is localized to the acrosome, a membrane-bound vesicle located at the apical tip of sperm. Snky-GFP also allowed us to follow the fate of the protein and the acrosome during fertilization. In many animals, the acrosome is a secretory vesicle with exocytosis essential for sperm penetration through the egg coats. Surprisingly, we find that the Drosophila acrosome is a paternally inherited structure. We provide evidence that the acrosome induces changes in sperm plasma membrane, exclusive of exocytosis and through the action of the acrosomal membrane protein Snky. Existence of testis-expressed Snky-like genes in many animals, including humans, suggests conserved protein function. We relate the characteristics of Drosophila Snky, acrosome function and sperm PMBD to membrane fusion events that occur in other systems.     

Differential binding of gold-labeled zona pellucida glycoproteins mZP2 and mZP3 to mouse sperm membrane compartments.

Egg zona pellucida glycoproteins mZP3 and mZP2 serve as primary and secondary sperm receptors, respectively, during initial stages of fertilization in mice [Wassarman (1988) A. Rev. Biochem. 57, 415-442]. These receptors interact with complementary egg-binding proteins (EBPs) located on the sperm surface to support species-specific gamete adhesion. Results of whole-mount autoradiographic experiments suggest that purified egg mZP3 and mZP2 bind preferentially to acrosome-intact (AI) and acrosome-reacted (AR) sperm heads, respectively [Bleil and Wassarman (1986) J. Cell Biol. 102, 1363-1371]. Here, we used purified egg mZP2, egg mZP3 and fetuin, which were coupled directly to colloidal gold ('gold-probes'), to examine binding of these glycoproteins to membrane compartments of AI and AR sperm by transmission electron microscopy. mZP3 gold-probes were found associated primarily with plasma membrane overlying the acrosomal and post-acrosomal regions of AI sperm heads. They were also found associated with plasma membrane overlying the post-acrosomal region of AR sperm heads. mZP2 gold-probes were found associated primarily with inner acrosomal membrane of AR sperm heads, although some gold was associated with outer acrosomal membrane of AI sperm that had holes in plasma membrane overlying the acrosome. Fetuin gold-probes, used to assess background levels of binding, were bound at relatively low levels to plasma membrane and inner acrosomal membrane of AI and AR sperm, respectively. None of the gold-probes exhibited significant binding to sperm tails, or to red blood cells and residual bodies present in sperm preparations. These results provide further evidence that mZP2 and mZP3 bind preferentially to heads of AR and AI sperm, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)