Expression of cathepsin H in differentiating rat spermatids: immunoelectron microscopic study

The expression of cathepsin H (CH) in differentiating rat spermatids was studied by an immunoelectron microscopic technique. Cathepsin H was detected in the acrosome throughout differentiation steps but cathepsins B, D, and L and lysosomal membrane protein (LGP107) were not. Early in the formation of the acrosome, CH signals were observed in Golgi vesicles but not in acrosomal vesicles. At steps 3–4, CH signals were associated with a fibrous material attached to the inner surface of the vesicle membrane on the Golgi side. At steps 5–6, this fibrous material accumulated to form an electron-dense sheet to which CH signals were confined. The rest of the acrosome was negative for the enzyme. At steps 11–12, the CH-positive fibrous sheet expanded from the apical to the ventral side of the sperm head. After step 16, the surface of outer dense fibers in the flagellar axoneme and reticulated bodies were stained for CH. In epididymal sperm, CH signals were detected in the acrosome as well as on the surface of the outer dense fibers running from the middle to the principal piece. By immunofluorescence staining, CH was found to be localized to the acrosome, middle piece, and principal piece.     

Studies on the fine structure of the mammalian testis. I. Differentiation of the spermatids in the cat (Felis domestica)

The differentiation of cat spermatids was studied in thin sections examined with the electron microscope. The Golgi complex of the spermatid consists of a central aggregation of minute vacuoles, partially surrounded by a lamellar arrangement of flattened vesicles. In the formation of the acrosome, one or more moderately dense homogeneous granules arise within vacuoles of the Golgi complex. The coalescence of these vacuoles and their contained granules gives rise to a single acrosomal granule within a sizable membrane-limited vacuole, termed the acrosomal vesicle. This adheres to the nuclear membrane and later becomes closely applied to the anterior two-thirds of the elongating nucleus to form a closed bilaminar head cap. The substance of the acrosomal granule occupies the narrow cleft between the membranous layers of the cap. The caudal sheath is comprised of many straight filaments extending backward from a ring which encircles the nucleus at the posterior margin of the head cap. Attention is directed to the frequent occurrence of pairs of spermatids joined by a protoplasmic bridge and the origin and possible significance of this relationship are discussed.     

STUDIES ON THE FINE STRUCTURE OF THE MAMMALIAN TESTIS : I. DIFFERENTIATION OF THE SPERMATIDS IN THE CAT (FELIS DOMESTICA)

The differentiation of cat spermatids was studied in thin sections examined with the electron microscope. The Golgi complex of the spermatid consists of a central aggregation of minute vacuoles, partially surrounded by a lamellar arrangement of flattened vesicles. In the formation of the acrosome, one or more moderately dense homogeneous granules arise within vacuoles of the Golgi complex. The coalescence of these vacuoles and their contained granules gives rise to a single acrosomal granule within a sizable membrane-limited vacuole, termed the acrosomal vesicle. This adheres to the nuclear membrane and later becomes closely applied to the anterior two-thirds of the elongating nucleus to form a closed bilaminar head cap. The substance of the acrosomal granule occupies the narrow cleft between the membranous layers of the cap. The caudal sheath is comprised of many straight filaments extending backward from a ring which encircles the nucleus at the posterior margin of the head cap. Attention is directed to the frequent occurrence of pairs of spermatids joined by a protoplasmic bridge and the origin and possible significance of this relationship are discussed.     

Influence of partial deletion of the Y chromosome on mouse sperm phenotype

Two congenic strains of mice (control, B10.BR/SgSn; mutant, B10.BR-Ydel/Ms with partial deletion of the Y chromosome) were examined. In control males, 22.6% of spermatozoa had abnormal heads; in mutant males, there were 64.2%, the most common being heads with flat acrosomes. Sodium dodecyl sulphate polyacrylamide gel electrophoresis of mature sperm proteins, followed by acrosin assay and acrosome silver staining, revealed a reduced concentration of acrosin in acrosomal caps in 35.8% of the spermatozoa in mutant males. Electron microscope analysis showed that some of the round, early spermatids in the mutants had normally formed acrosomal caps but lacked the proacrosomal granule and had no, or only scarce, acrosomal material. These observations indicate that formation of the acrosomal cap is controlled separately from the synthesis of the acrosomal material and suggest that some factors linked on the Y chromosome are involved in the control of acrosome development.     

Synacrosomal formation after cell fusion of round spermatids of Xenopus laevis

Cell fusion was induced by hypotonic medium in pairs of spermatids which were derived from single secondary spermatocytes. In a pair of fused spermatids, a single acrosome (synacrosome) eventually formed whenever the cell fusion was induced during the course of acrosomal formation. Direct observation of the process of synacrosomal formation was made on pairs of fused spermatids which had completed acrosomal formation. Two patterns occurred, namely, fusion of two acrosomes or enlargement of one with diminution of the other. The total volume of the two acrosomes before synacrosomal formation almost equaled the volume of the coalesced synacrosomes in fused spermatids. Neither colchicine nor cytochalasin B prevented synacrosomal formation in spermatids which were fused after each had completed acrosomal formation. These results indicate that neither microtubules nor microfilaments seem to play a role in the formation of a synacrosome in pairs of fused spermatids. However, cycloheximide did inhibit acrosomal formation when present during the early stage of acrosome differentiation in pairs of spermatids which had been fused just after second meiotic division. This fact indicates that acrosomal formation is mediated by some protein(s) which are synthesized during the initial period of acrosomal formation.     

Synacrosomal formation after cell fusion of round spermatids of Xenopus laevis

Cell fusion was induced by hypotonic medium in pairs of spermatids which were derived from single secondary spermatocytes. In a pair of fused spermatids, a single acrosome (synacrosome) eventually formed whenever the cell fusion was induced during the course of acrosomal formation. Direct observation of the process of synacrosomal formation was made on pairs of fused spermatids which had completed acrosomal formation. Two patterns occurred, namely, fusion of two acrosomes or enlargement of one with diminution of the other. The total volume of the two acrosomes before synacrosomal formation almost equaled the volume of the coalesced synacrosomes in fused spermatids. Neither colchicine nor cytochalasin B prevented synacrosomal formation in spermatids which were fused after each had completed acrosomal formation. These results indicate that neither microtubules nor microfilaments seem to play a role in the formation of a synacrosome in pairs of fused spermatids. However, cycloheximide did inhibit acrosomal formation when present during the early stage of acrosome differentiation in pairs of spermatids which had been fused just after second meiotic division. This fact indicates that acrosomal formation is mediated by some protein(s) which are synthesized during the initial period of acrosomal formation.     

Ultrastructure of spermiogenesis in the American alligator,Alligator mississippiensis (Reptilia,Crocodylia, Alligatoridae)

Testicular samples were collected to describe the ultrastructure of spermiogenisis in Alligator mississipiensis (American Alligator). Spermiogenesis commences with an acrosome vesicle forming from Golgi transport vesicles. An acrosome granule forms during vesicle contact with the nucleus, and remains posterior until mid to late elongation when it diffuses uniformly throughout the acrosomal lumen. The nucleus has uniform diffuse chromatin with small indices of heterochromatin, and the condensation of DNA is granular. The subacrosome space develops early, enlarges during elongation, and accumulates a thick layer of dark staining granules. Once the acrosome has completed its development, the nucleus of the early elongating spermatid becomes associated with the cell membrane flattening the acrosome vesicle on the apical surface of the nucleus, which aids in the migration of the acrosomal shoulders laterally. One endonuclear canal is present where the perforatorium resides. A prominent longitudinal manchette is associated with the nuclei of late elongating spermatids, and less numerous circular microtubules are observed close to the acrosome complex. The microtubule doublets of the midpiece axoneme are surrounded by a layer of dense staining granular material. The mitochondria of the midpiece abut the proximal centriole resulting in a very short neck region, and possess tubular cristae internally and concentric layers of cristae superficially. A fibrous sheath surrounds only the axoneme of the principal piece. Characters not previously described during spermiogenesis in any other amniote are observed and include (1) an endoplasmic reticulum cap during early acrosome development, (2) a concentric ring of endoplasmic reticulum around the nucleus of early to middle elongating spermatids, (3) a band of endoplasmic reticulum around the acrosome complex of late developing elongate spermatids, and (4) midpiece mitochondria that have both tubular and concentric layers of cristae. J. Morphol., 2010. © 2010 Wiley‐Liss, Inc.     

Equatorial segment protein defines a discrete acrosomal subcompartment persisting throughout acrosomal biogenesis

The equatorial segment of the acrosome underlies the domain of the sperm that fuses with the egg membrane during fertilization. Equatorial segment protein (ESP), a novel 349-amino acid concanavalin-A-binding protein encoded by a two-exon gene (SP-ESP) located on chromosome 15 at q22, has been localized to the equatorial segment of ejaculated human sperm. Light microscopic immunofluorescent observations revealed that during acrosome biogenesis ESP first appears in the nascent acrosomal vesicle in early round spermatids and subsequently segregates to the periphery of the expanding acrosomal vesicle, thereby defining a peripheral equatorial segment compartment within flattened acrosomal vesicles and in the acrosomes of early and late cap phase, elongating, and mature spermatids. Electron microscopic examination revealed that ESP segregates to an electron-lucent subdomain of the condensing acrosomal matrix in Golgi phase round spermatids and persists in a similar electron-lucent subdomain within cap phase spermatids. Subsequently, ESP was localized to electron-dense regions of the equatorial segment and the expanded equatorial bulb in elongating spermatids and mature sperm. ESP is the earliest known protein to be recognized as a marker for the specification of the equatorial segment, and it allows this region to be traced through all phases of acrosomal biogenesis. Based on these observations, we propose a new model of acrosome biogenesis in which the equatorial segment is defined as a discrete domain within the acrosomal vesicle as early as the Golgi phase of acrosome biogenesis.     

Membrane trafficking machinery components associated with the mammalian acrosome during spermiogenesis.

Active trafficking from the Golgi apparatus is involved in acrosome formation, both by delivering acrosomal contents to the nascent secretory vesicle and by controlling organelle growth and shaping. During murine spermiogenesis, Golgi antigens (giantin, beta-COP, golgin 97, mannosidase II) are detected in the acrosome until the late cap-phase spermatids, but are not found in testicular spermatozoa (maturation-phase spermatids). This suggests that Golgi-acrosome flow may be relatively unselective, with Golgi residents retrieved before spermiation is complete. Treatment of spermatogenic cells with brefeldin A, a drug that causes the Golgi apparatus to collapse into the endoplasmic reticulum, disrupted the Golgi in both pachytene spermatocytes and round spermatids. However, this treatment did not affect the acrosomal granule, and some beta-COP labeling on the acrosome of elongating spermatids was maintained. Additionally, N-ethylmaleimide sensitive factor, soluble NSF attachment proteins, and homologues of the t-SNARE syntaxin and of the v-SNARE VAMP/synaptobrevin, as well as members of the rab family of small GTPases, are associated with the acrosome (but not the acrosomal granule) in round and elongated spermatids. This suggests that rab proteins and the SNARE machinery for membrane recognition/docking/fusion may be involved in trafficking during mammalian acrosome biogenesis.     

Visualization and characterization of the acrosome reaction of human spermatozoa by immunolocalization with monoclonal antibody

A monoclonal antibody generated against hamster epididymal spermatozoa and recognizing an antigen within the acrosome was used in conjunction with FITC-antimouse immunoglobulin as a marker of the human acrosome during sperm development, capacitation, and the acrosome reaction. The specificity of binding of the monoclonal antibody was assessed using immunolocalization by epi-fluorescence and electron microscopy. Immunofluorescence revealed that antibody bound over the entire anterior acrosome in hamster and human spermatozoa. Ultrastructural localization indicated that antigen was predominantly present on the inner face of the outer acrosomal membrane and within the acrosomal content. Qualitative specificity was studied using a highly purified preparation of hamster acrosomes in an enzyme-linked immunosorbent assay. Since the antibody rapidly visualized human acrosomes, it was used to detect abnormal acrosome morphology of mature spermatozoa and to mark spermatids present in the ejaculate. During incubation in capacitating medium, changes in the immunofluorescence of live or methanol fixed spermatozoa were correlated with incubation interval and the ability of spermatozoa to fuse with zona-free hamster oocytes. Spermatozoa bound to zona-free hamster oocytes displayed no fluorescence, confirming that acrosome loss occurred before spermatozoa attached to the vitellus.     

Simple histochemical stain for acrosomes on sperm from several species

The acrosome reaction is an exocytotic process that enables a sperm to penetrate the zona pellucida and fertilize an egg. The process involves the fenestration and vesiculation of the sperm plasma membrane and outer acrosomal membrane releasing the acro somal contents. Many different methods have been devel oped to detect the acrosomal status of sperm. These techniques are sometimes complicated, costly, and can be used on only a few species. The aim of this study was to develop an efficient and inexpensive method to assess the acrosomal status of sperm from a variety of species. We prepared and fixed sperm from humans, cattle, swine, rabbits, guinea pigs, and mice and stained them with Coomassie G250. The acrosomes were stained intensely blue in color. Following capacitation, some sperm were incubated for 1 hr with 10 microM calcium ionophore A23187 to induce the acrosome reaction. They were also stained with Coomassie G-250. Ionophore-treated sperm lacked Coomassie staining over the acrosomal region. Differential interference contrast (DIC), bright field microscopy or Pisum sativum agglutinin staining confirmed that the acrosomes of sperm from these species were reacted in response to calcium ionophore treatment and the acrosome reaction frequencies matched results with Coomassie staining. These results demonstrate that the acrosomal status of mammalian sperm from several species can be determined easily and reliably using this simple Coomassie Blue G-250 staining method.     

Ultrastructural study of spermiogenesis in a rare desert amphisbaenian Diplometopon zarudnyi

Spermiogenesis, in particular the head differentiation of Diplometopon zarudnyi, was studied at the ultrastructural level by Transmission Electron Microscope (TEM). The process includes acrosomal vesicle development, nuclear elongation, chromatin condensation and exclusion of excess cytoplasm. In stage I, the proacrosomal vesicle occurs next to a shallow fossa of the nucleus, and a dense acrosomal granule forms beneath it. This step commences with an acrosome vesicle forming from Golgi transport vesicles; simultaneously, the nucleus begins to move eccentrically. In stage II, the round proacrosomal vesicle is flattened by projection of the nuclear fossa, and the dense acrosomal granule diffuses into the vesicle as the fibrous layer forms the subacrosomal cone. Circular manchettes surrounded by mitochondria develop around the nucleus, and the chromatin coagulates into small granules. The movement of the nucleus causes rearrangement of the cytoplasm. The nucleus has uniform diffuse chromatin with small indices of heterochromatin. The subacrosome space develops early, enlarges during elongation, and accumulates a thick layer of dark staining granules. In stage III, the front of the elongating nucleus protrudes out of the spermatid and is covered by the flat acrosome; coarse granules replace the small ones within the nucleus. One endonuclear canal is present where the perforatorium resides. In stage IV, the chromatin concentrates to dense homogeneous phase. The circular manchette is reorganized longitudinally. The Sertoli process covers the acrosome and the residues of the cytoplasmic lobes are removed. In stage V, the sperm head matures.     

Ultrastructure of subcellular fractions of bull spermatozoa after hyamine treatment

Summary Ejaculated bull spermatozoa (SZ) were washed and incubated with a cationic surface active agent, Hyamine 2389, and centrifuged using 2-step discontinuous sucrose density gradient. The washed SZ, Hyamine-treated SZ and subcellular spermatozoal fractions obtained after centrifugation were prepared for electron microscopy. The washing did not cause any major structural changes in SZ. The Hyamine treatment of SZ disrupted the outer acrosome membranes. The anterior part of acrosome (the acrosomal cap) was detached retaining its integrity, or forming vesicles by fusing with the cell membrane as in true acrosome reaction. Because of this structural similarity in vesicle formation, Hyamine is assumed to be a suitable experimental initiator for acrosome reaction. The loosened acrosomal membranes were harvested almost totally by the centrifugation. The acrosomes were seen as loosened U-shaped unbroken acrosomal caps or as vesicles with fuzzy acrosomal material. The lightest particles were vesicles consisting of smooth membranes, formed evidently of sperm cell membrane. A negligible amount of fibrous sheaths were also among acrosomal membranes but no other sperm parts were encountered.The authors are thankful to Mrs. Marita Aaltonen, Mrs. Sirpa From, Miss Ulla Mäntylä, Mr. Mauno Lehtimäki and Mr. Urpo Reunanen for their skilful technical assistance.     

Differentiation of the acrosomal complex in ostrich (Struthio camelus) spermatids

The acrosomal complex of ostrich sperm consists of a small, cone-shaped acrosome and a slender, cylindrical perforatorium housed within a deep endonuclear canal. The perforatorium is almost exclusively endonuclear in location and is only covered by the acrosome at its point of origin in the apical subacrosomal space. The development of the acrosome is generally similar to that described in other non-passerine birds. Small proacrosomal granules (vesicles) emanating from the Golgi apparatus coalesce to form a large, membrane-bound acrosomal vesicle filled with homogeneous, electron-dense material. The acrosomal vesicle attaches to the nucleus via a shallow depression and subsequently collapses to form the typical cap-like acrosome of non-passerine birds. In ostrich spermatids the endonuclear canal becomes obvious when the collapsed acrosomal vesicle has assumed a dumbbell-shaped appearance. The perforatorium, which originates from moderately electron-dense material contained within the apical subacrosomal space, expands within the deepening endonuclear canal. The material of the perforatorium does not originate in the form of an obvious granule as in chicken and budgerigar spermatids. Indications are that in ostrich spermatids the developing acrosome plays a role in the shaping of the tip of the nucleus. The perforatorium, however, appears to represent a residual structure that has no specifically identified function. © 1996 Wiley-Liss, Inc.     

Intra-acrosomal organization of a 90-kilodalton antigen during spermiogenesis in the rat

The localization of an acrosomal protein was studied using a monoclonal antibody MN7 raised against mouse spermatozoa. MN7 specifically recognized the anterior acrosome of several mammalian (mouse, rat, hamster) spermatozoa fixed with paraformaldehyde. An immunoblot study with periodate treatment showed that MN7 recognized a carbohydrate region of a 90 kDa protein in an extract of mouse and rat cauda epididymal spermatozoa. The change in distribution of the MN7 antigen during acrosome development was investigated in the rat testis using the pre-embedding immunoperoxidase technique. The antigen first appeared in the proacrosomic granules of spermatids in steps 1–2. Small vesicles adjacent to the outer acrosomal membrane and the developing acrosomic system were immunoreactive during steps 4–7. The majority of the antigen was then redistributed to the head-cap portion during steps 8–18, and finally restricted to the anterior acrosome in the step 19-spermatid. These results suggest that the antigen is transported to the acrosome by way of the vesicles that originate from the Golgi apparatus during early spermiogenesis, and are then delivered to the final destination within the acrosome by the intra-acrosomal migration during late spermiogenesis.     

Carbendazim-induced abnormal development of the acrosome during early phases of spermiogenesis in the rat testis

Effects of a single, high dose of orally administered carbendazim (100 mg/kg) on acrosome formation in the early phases of spermiogenesis were examined by electron microscopy and immunocytochemistry up to day 7.5 post-treatment. No obvious abnormality of acrosome development was noted in the Golgi phase spermatids on day 1.5 post-treatment. On day 3, step 1 spermatids were seen in stage III seminiferous tubules. In stage V tubules at this post-treatment interval, direct connections between the trans-side saccules of the Golgi stacks and the outer acrosomic membranes were observed in step 5 spermatids. Similar direct connections between these two organelles were also observed in the advanced round spermatids in later stages at days 4.5 and 7.5. On day 4.5, step 1 and 3 spermatids were seen in stage V tubules. On day 7.5, round spermatids with various abnormalities of acrosome development were observed in stage VII tubules, in addition to the discontinuous and granular acrosomes reported previously. These features were not observed in testes of control animals. In the immunocytochemical analysis using an antibody mMN7 that recognizes a protein delivered from the Golgi apparatus to the acrosome, spermatids exposed to carbendazim showed various abnormal immunostaining patterns in the acrosomes. On the other hand, strong immunoreactivity was observed in the Golgi saccules connecting to the acrosomes. These results suggest that in testis treated with carbendazim acrosome development is impaired during the early phases of spermiogenesis, and material supply from the Golgi apparatus to the acrosome is perturbed, which is a possible cause of the abnormal development. Received: 31 March 1998 / Accepted: 28 May 1998     

Appearance of an intra-acrosomal antigen during the terminal step of spermiogenesis in the rat

Summary In a survey of sperm antigens in the rat, a new intra-acrosomal antigen was found using a monoclonal antibody MC41 raised against rat epididymal spermatozoa. The MC41 was immunoglobulin G₁ and recognized spermatozoa from rat, mouse and hamster. Indirect immunofluorescence with MC41 specifically stained the crescent region of the anterior acrosome of the sperm head. Immuno-gold electron microscopy demonstrated that the antigen was localized within the acrosomal matrix. Immunoblot study showed that MC41 recognized a band of approximately 165000 dalton in the extract of rat sperm from the cauda epididymidis. Immunohistochemistry with MC41 demonstrated that the antigen was first detected in approximately step-2 spermatids, and distributed over the entire cytoplasmic region of spermatids from step 2 to early step 19. The head region became strongly stained in late step-19 spermatids and then in mature spermatozoa. Distinct immunostaining was not found in the developing acrosome of spermatids throughout spermiogenesis. These results suggest that the MC41 antigen is a unique intra-acrosomal antigen which is accumulated into the acrosome during the terminal step of spermiogenesis.     

Localization of boar sperm proacrosin during spermatogenesis and during sperm maturation in the epididymis.

The localization of proacrosin was determined by using colloidal gold labeling and electron microscopy of boar germ cells during spermiogenesis to post-ejaculation. Proacrosin was first localized in round spermatids during the Golgi phase of spermiogenesis; it was associated with the electron-dense granule, or acrosomal granule that was conspicuous within the acrosome. It remained within the acrosomal granule during the cap and acrosome phases of spermiogenesis. At these stages, there was no apparent association of the proacrosin molecule with the acrosomal membranes. During the maturation phase of spermiogenesis, proacrosin was seen to become dispersed into all regions of the acrosome except the equatorial segment. When sperm from different segments of the epididymis and ejaculated sperm were examined, localization was observed throughout the acrosome except for the equatorial segment. Here proacrosin appeared to be localized on both the inner and outer acrosomal membranes as well as with the acrosomal matrix, although further studies are required to verify the membrane localization. No labeling was seen on the plasma membrane. These data suggest that the synthesis and movement of proacrosin to sites in the acrosome are controlled by an as yet unknown process. The absence of proacrosin on the plasma membrane of mature ejaculated sperm makes it unlikely that this enzyme plays a role in sperm-zona adhesion prior to capacitation.     

Deficiency in the omega-3 fatty acid pathway results in failure of acrosome biogenesis in mice

An omega-3 fatty acid, docosahexaenoic acid (DHA), is enriched in testicular membrane phospholipids, but its function is not well understood. The Fads2 gene encodes an enzyme required for the endogenous synthesis of DHA. Using Fads2-null mice (Fads2-/-), we found in our preceding studies that DHA deficiency caused the arrest of spermiogenesis and male infertility, both of which were reversed by dietary DHA. In this study, we investigated a cellular mechanism underlying the DHA essentiality in spermiogenesis. Periodic acid-Schiff staining and acrosin immunohistochemistry revealed the absence of acrosomes in Fads2-/- round spermatids. Acrosin, an acrosomal marker, was scattered throughout the cytoplasm of the Fads2-/- spermatids, and electron microscopy showed that proacrosomal granules were formed on the trans-face of the Golgi. However, excessive endoplasmic reticulum and vesicles were present on the cis-face of the Golgi in Fads2-/- spermatids. The presence of proacrosomal vesicles but lack of a developed acrosome in Fads2-/- spermatids suggested failed vesicle fusion. Syntaxin 2, a protein involved in vesicle fusion, colocalized with acrosin in the acrosome of wild-type mice. In contrast, syntaxin 2 remained scattered in reticular structures and showed no extensive colocalization with acrosin in the Fads2-/- spermatids, suggesting failed fusion with acrosin-containing vesicles or failed transport and release of syntaxin 2 vesicles from Golgi. Dietary supplementation of DHA in Fads2-/- mice restored an intact acrosome. In conclusion, acrosome biogenesis under DHA deficiency is halted after release of proacrosomal granules. Misplaced syntaxin 2 suggests an essential role of DHA in proper delivery of membrane proteins required for proacrosomal vesicle fusion.     

Vital staining and acrosomal evaluation of bovine sperm

Dried smears prepared from vitally stained sperm were evaluated as a method of simultaneously determining sperm viability and acrosomal morphology. A combination Fast Green FCF-Eosin B stain was used. The stained smears were examined at × 1, 250 using differential interference contrast microscopy (DIC). For comparison, the percentage of sperm with intact acrosomes was also determined from wet smears using DIC. Acrosomal morphology was not altered by the staining procedure, as the percentage of intact acrosomes was similar whether quantitated from wet or stained smears. Absence of eosinophilic staining in the acrosome was used as an indication of sperm viability. The percentage of sperm with unstained acrosomes was highly correlated with the percentage of intact acrosomes quantitated from stained smears. Thus, vital staining provided an indication of sperm viability comparable to acrosomal integrity, a highly reliable technique. The major advantages of using dried stained smears were more thorough examination of individual sperm without sperm activity interference, simultaneous evidence of sperm viability and morphology, and the opportunity to delay evaluation. In addition, diluting spermatozoa in complex or simple media with or without egg yolk or follicular fluid did not interfere with subsequent staining or acrosomal evaluation.