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.     

Integration of the mouse sperm fertilization-related protein equatorin into the acrosome during spermatogenesis as revealed by super-resolution and immunoelectron microscopy

Spermatids must precisely integrate specific molecules into structurally supported domains that develop during spermatogenesis. Once established, the architecture of the acrosome contributes to the acrosome reaction, which occurs prior to gamete interaction in mammals. The present study aims to clarify the morphology associated with the integration of the mouse fertilization-related acrosomal protein equatorin (mEQT) into the developing acrosome. EQT mRNA was first detected by in situ hybridization in round spermatids but disappeared in early elongating spermatids. The molecular size of mEQT was approximately 65 kDa in the testis. Developmentally, EQT protein was first detected on the nascent acrosomal membrane in round spermatids at approximately step 3, was actively integrated into the acrosomal membranes of round spermatids in the following step and then participated in acrosome remodeling in elongating spermatids. This process was clearly visualized by high-resolution fluorescence microscopy and super-resolution stimulated emission depletion nanoscopy by using newly generated C-terminally green-fluorescent-protein-tagged mEQT transgenic mice. Immunogold electron microscopy revealed that mEQT was anchored to the acrosomal membrane, with the epitope region observed as lying 5–70 nm away from the membrane and was associated with the electron-dense acrosomal matrix. This new information about the process of mEQT integration into the acrosome during spermatogenesis should provide a better understanding of the mechanisms underlying not only acrosome biogenesis but also fertilization and male infertility.     

The Golgi apparatus segregates from the lysosomal/acrosomal vesicle during rhesus spermiogenesis: structural alterations

The acrosome is an acidic secretory vesicle containing hydrolytic enzymes that are involved in the sperm's passage across the zona pellucida. Imaging of the acrosomal vesicle and the Golgi apparatus in live rhesus monkey spermatids was accomplished by using the vital fluorescent probe LysoTracker DND-26. Concurrently, the dynamics of living spermatid mitochondria was visualized using the specific probe MitoTracker CMTRos and LysoTracker DND-26 detected the acrosomal vesicle from its formation through spermatid differentiation. LysoTracker DND-26 also labeled the Golgi apparatus in spermatogenic cells. In spermatocytes the Golgi is spherical and, in round spermatids, it is localized over the acrosomal vesicle, as confirmed by using polyclonal antibodies against Golgin-95/GM130, Golgin-97, and Golgin-160. Using both live LysoTracker DND-26 imaging and Golgi antibodies, we found that the Golgi apparatus is cast off from the acrosomal vesicle and migrates toward the sperm tail in elongated spermatids. The Golgi is discarded in the cytoplasmic droplet and is undetectable in mature ejaculated spermatozoa. The combined utilization of three vital fluorescent probes (Hoechst 33342, LysoTracker DND-26, and MitoTracker CMTRos) permits the dynamic imaging of four organelles during primate spermiogenesis: the nucleus, the mitochondria, the acrosomal vesicle, and the Golgi apparatus.     

CASK is in the mammalian sperm head and is processed during epididymal maturation

Upon adhesion to the zona pellucida or egg extracellular matrix, sperm undergo regulated exocytosis of the acrosomal vesicle. CASK is an adaptor protein that has been implicated in coupling neuronal cell adhesion to regulated exocytosis. In neurons, this scaffolding molecule is associated with several types of transmembrane receptor complexes and connects cell adhesion molecules with ion channels, the actin cytoskeleton, and the cell's exocytotic machinery. We hypothesized CASK might also be an important link between zona pellucida binding and the sperm acrosome reaction. RT-PCR experiments indicated CASK is transcribed in mouse testis. The full size (120 kDa) CASK protein was present in testis from mouse and pig. Immunoblots of mature porcine and murine sperm revealed that the 120 kDa molecule was much less abundant than in testis but the antibody also recognized a group of smaller proteins migrating at 55-65 kDa. Immunofluorescence experiments indicated both the full length and smaller CASK immunoreactive products were found only in the acrosomal region of spermatids and mature sperm and not in other testicular cell types. CASK immunofluorescence was lost following the acrosome reaction. During epididymal maturation, the abundance of the full size CASK decreased and the CASK fragments increased. These results suggest that CASK may be proteolytically processed during epididymal maturation. Because sperm acquire the ability to bind the zona pellucida, acrosome react, and fertilize eggs during epididymal maturation, CASK processing may play a role in the acquisition of these functions.     

Localization of sperm antigen SP-10 during the six stages of the cycle of the seminiferous epithelium in man

The distribution of the sperm protein SP-10 was investigated in plastic-embedded samples of human testes by light and electron microscopy. An immunogold and silver enhancement technique, in conjunction with a monoclonal antibody (MHS-10) raised against SP-10, was used to localize the protein. SP-10 was detected in spermatids at each of the six stages of the cycle of the seminiferous epithelium. Light microscopy showed immunoreactive material at the circumference of developing acrosomes in the early steps of spermiogenesis. As differentiation proceeded and cell shape changed from round to elongated, immunoreactive material appeared in an arc, which gradually became a V shape bordering the spermatid nucleus. The area of the immunoreactive material and its shape corresponded to that of the developing acrosome. At the electron microscopic level, gold particles indicative of the presence of SP-10 were detected on electron-dense material found within the developing acrosomal vesicle in early steps of spermiogenesis. As the electron density of the acrosome increased, a high concentration of gold particles was seen in the vesicle matrix. The gold particles gradually became associated with the inner and outer acrosomal membranes of the most mature spermatids.     

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.     

Haprin,a novel haploid germ cell-specific RING finger protein involved in the acrosome reaction

The acrosome reaction (i.e. the exocytosis of the sperm vesicle) is a prerequisite for fertilization, but its molecular mechanism is largely unknown. We have identified a cDNA clone for a gene named haprin, which encodes a haploid germ cell-specific RING finger protein. This protein is a novel member of the RBCC (RING finger, B-box type zinc finger, and coiled-coil domain) motif family that has roles in several cellular processes, such as exocytosis. It is transcribed exclusively in testicular germ cells after meiotic division. Western blot and immunohistochemical analyses showed the molecular weight of Haprin protein to be Mr approximately 82,000. It was localized in the acrosomal region of elongated spermatids and mature sperm and was not present in acrosome-reacted sperm. The specific antibody against the RING finger domain of Haprin inhibited the acrosome reaction in permeabilized sperm. These results indicated that the novel RBCC protein Haprin plays a key role in the acrosome reaction and fertilization.     

Zonadhesin assembly into the hamster sperm acrosomal matrix occurs by distinct targeting strategies during spermiogenesis and maturation in the epididymis

Zonadhesin is the only sperm protein known to bind in a species-specific manner to the zona pellucida. The zonadhesin precursor is a mosaic protein with a predicted transmembrane segment and large extracellular region composed of cell adhesion, mucin, and tandem von Willebrand D domains. Because the precursor possesses a predicted transmembrane segment and localizes to the anterior head, the mature protein was presumed to be a sperm surface zona pellucida-binding protein. In this study of hamster spermatozoa, we demonstrate that zonadhesin does not localize to the sperm surface but is instead a constituent of the acrosomal matrix. Immunoelectron microscopy revealed that distinct targeting pathways during spermiogenesis and sperm maturation in the epididymis result in trafficking of zonadhesin to the acrosomal matrix. In round spermatids, zonadhesin localized specifically to the acrosomal membrane, where it appeared to be evenly distributed between the outer and inner membrane domains. Subsequent redistribution of zonadhesin resulted in its elimination from the inner acrosomal membrane and restriction to the outer acrosomal membrane of the apical and principal segments and the contents of the posterior acrosome. During sperm maturation in the epididymis, zonadhesin dissociated from the outer acrosomal membrane and became incorporated into the forming acrosomal matrix. These data suggest an important structural role for zonadhesin in assembly of the acrosomal matrix and further support the view that the species specificity of zona pellucida adhesion is mediated by egg-binding proteins contained within the acrosome rather than on the periacrosomal plasma membrane.     

Spermiogenesis and sperm structure in the crabUca tangeri (Crustacea,Brachyura), with special reference to the acrosome differentiation

Summary Early spermatids of the crabUca tangeri consists of the nucleus of granular chromatin and the cytoplasm, which contains a proacrosomal vesicle in close association with membrane lamellae. In the mid spermatids an invagination of the acrosomal vesicle membrane gives rise to the formation of the perforatorium, a spindle-shaped tubule which encloses tubular membranous structures. The pair of centrioles located at the base of the acrosome is not directly involved in perforatorial differentiation. The acrosomal vesicle shows a heterogeneous content composed of the operculum, the thickened ring, and three layers of different materials concentrically arranged around the perforatorium. During the late spermatid stage the nuclear profile differentiates numerous slender arms and the chromatin arranges into fibers. Membranous tubules from the cytoplasm become incorporated into the tubular structures of the perforatorium. The mature spermatozoon has the typical structure of the branchyuran sperm, with a complex acrosome, cupped by the nucleus, and a thin cytoplasmic band intervening between the former main elements. The centrioles are degenerate. The nuclear arms are unusually numerous (more than 20) and lack microtubules or microtubular derivatives.     

Identification and characterization of RING-finger ubiquitin ligase UBR7 in mammalian spermatozoa

The ubiquitin-proteasome system (UPS) controls intracellular protein turnover in a substrate-specific manner via E3-type ubiquitin ligases. Mammalian fertilization and particularly sperm penetration through the oocyte vitelline coat, the zona pellucida (ZP), is regulated by UPS. We use an extrinsic substrate of the proteasome-dependent ubiquitin-fusion degradation pathway, the mutant ubiquitin UBB⁺¹, to provide evidence that an E3-type ligase activity exists in sperm-acrosomal fractions. Protein electrophoresis gels from such de novo ubiquitination experiments contained a unique protein band identified by tandem mass spectrometry as being similar to ubiquitin ligase UBR7 (alternative name: C14ORF130). Corresponding mRNA was amplified from boar testis and several variants of the UBR7 protein were detected in boar, mouse and human sperm extracts by Western blotting. Genomic analysis indicated a high degree of evolutionary conservation, remarkably constant purifying selection and conserved testis expression of the UBR7 gene. By immunofluorescence, UBR7 was localized to the spermatid acrosomal cap and sperm acrosome, in addition to hotspots of proteasomal activity in spermatids, such as the cytoplasmic lobe, caudal manchette, nucleus and centrosome. During fertilization, UBR7 remained with the ZP-bound acrosomal shroud following acrosomal exocytosis. Thus, UBR7 is present in the acrosomal cap of round spermatids and within the acrosomal matrix of mature boar spermatozoa. These data provide the first evidence of ubiquitin ligase activity in mammalian spermatozoa and indicate UBR7 involvement in spermiogenesis.     

Plasma-membrane glycoproteins during spermiogenesis and in the spermatozoa of some Orthoptera

Summary Orthoptera spermatids and spermatozoa from two species of Tettigoniidae and from one of Acrididae were analysed by means of the fluorescent lectins, concanavalin A or wheat-germ agglutinin, with the aim of finding -D mannose· -D glucose· N-acetylglucosamine and sialic acid sugar residues in their plasmamembrane glycoproteins. Labelling with lectins shows remarkable changes occurring in the plasma membrane during spermiogenesis. In early spermatids, the whole cell surface is labelled, but in mature spermatids and spermatozoa, a noticeable fluorescence is restricted to the membrane that covers the acrosome. The end piece of the tail of Acrididae spermatids and spermatozoa fluoresces after wheat-germ agglutinin labelling. The intense labelling of acrosomal area is independent of acrosomal size and shape, as shown by the marked differences observed in the acrosomes of Tettigoniidae compared with Acrididae: in the former, the acrosome is a well-developed structure with an arrow-like shape, but in Acrididae, the acrosome resembles a small vesicle in the anterior tip of the cell. The large amount of some sugar residues in the plasma membrane covering the acrosome is discussed in relation to the features observed in other species, and also in connection with the physiology of the male gamete prior or during fertilization.     

Assembly of spermatid acrosome depends on microtubule organization during mammalian spermiogenesis

The acrosome is a secretory vesicle attached to the nucleus of the sperm. Our hypothesis is that microtubules participate in the membrane traffic between the Golgi apparatus and acrosome during the first steps of spermatid differentiation. In this work, we show that nocodazole-induced microtubule depolarization triggers the formation of vesicles of the acrosomal membrane, without detaching the acrosome from the nuclear envelope. Nocodazole also induced fragmentation of the Golgi apparatus as determined by antibodies against giantin, golgin-97 and GM130, and electron microscopy. Conversely, neither the acrosome nor the Golgi apparatus underwent fragmentation in elongating spermatids (acrosome- and maturation-phase). The microtubule network of round spermatids of azh/azh mice also became disorganized. Disorganization correlated with fragmentation of the acrosome and the Golgi apparatus, as evaluated by domain-specific markers. Elongating spermatids (acrosome and maturation-phase) of azh/azh mice also had alterations in microtubule organization, acrosome, and Golgi apparatus. Finally, the spermatozoa of azh/azh mice displayed aberrant localization of the acrosomal protein sp56 in both the post-acrosomal and flagellum domains. Our results suggest that microtubules participate in the formation and/or maintenance of the structure of the acrosome and the Golgi apparatus and that the organization of the microtubules in round spermatids is key to sorting acrosomal proteins to the proper organelle.     

Ultrastructure of spermiogenesis of Philippia (Psilaxis) oxytropis,with special reference to the taxonomic position of the architectonicidae (Gastropoda)

Summary Spermiogenesis of the architectonicid Philippia (Psilaxis) oxytropis was studied using transmission electron microscopy. Both spermatids and mature sperm of Philippia show features comparable to sperm/spermatids of euthyneuran gastropods (opisthobranchs, pulmonates) and not mesogastropods (with which the Architectonicidae are commonly grouped). These features include: (1) Accumulation of dense material on the outer membrane of anterior of the early spermatid nucleus — this material probably incorporated into the acrosome; (2) Structure of the unattached and attached spermatid acrosome (apical vesicle, acrosomal pedestal) accompanied by curved (transient) support structures; (3) Formation of the midpiece by individual mitochondrial wrapping around the axonemal complex, and the subsequent fusion and metamorphosis of the mitochondria to form the midpiece; (4) Presence of periodically banded coarse fibres surrounding the axonemal doublets and intra-axonemal rows of granules. A glycogen piece occurs posterior to the midpiece but is a feature observed in both euspermatozoa of mesogastropods (and neogastropods) and in sperm of some euthyneurans.Despite the lack of paracrystalline material or glycogen helices within the midpiece (both usually associated with sperm of euthyneurans), the features of spermiogenesis and sperm listed indicate that the Architectonicidae may be more appropriately referable to the Euthyneura than the Prosobranchia.Abbreviations a acrosome - ap anterior region of acrosomal pedestal - as support structures of spermatid acrosome - av apical vesicle of acrosome (acrosomal vesicle of un-attached acrosome) - ax axoneme - b basal region of acrosomal pedestal - c centriole - cf coarse fibres - cr cristal derivative of midpiece - db intra-axonemal dense granules - drs dense ring structure - gg glycogen granules - gp glycogen piece - G Golgi complex - m mitochondrion - mt microtubules - n nucleus - pm plasma membrane - sGv small Golgi vesicles     

Tetraspanin family protein CD9 in the mouse sperm: unique localization, appearance, behavior and fate during fertilization

A tetraspanin family protein, CD9, has not previously been identified in sperm cells. Here, we characterize sperm CD9 in the mouse, including its unique localization in sperm, appearance during spermatogenesis, and behavior and fate during mouse fertilization. In sperm, CD9 is an inner acrosomal membrane-associated protein, not a plasma membrane-associated protein. Its molecular weight is approximately 24 kDa throughout its processing, from testicular germ cells to acrosome-reacted sperm. A temporal difference was found between mRNA and protein expression; CD9 mRNA was detected in the stages from spermatogonia through round spermatids showing the strongest levels in midpachytene spermatocytes. CD9 protein was detected in the cytoplasm throughout the stages from spermatogonia to spermatocytes. While CD9 was weakly expressed in the spermatids from step 1 through step 14, the signals became clearly positive at the marginal region of the anterior acrosome in elongated spermatids. After the acrosome reaction, the majority of sperm CD9 was retained in the inner acrosomal membrane, but some quantity of CD9 was found on the plasma membrane covering the equatorial segment as detected by immunogold electron microscopy using anti-CD9 antibody. CD9 was maintained on the sperm head after reaching the perivitelline space of CD9-deficient eggs that were recovered after natural mating with wild males. Thus, this study characterizes CD9 in sperm development and fertilization.     

C-terminal kinesin motor KIFC1 participates in acrosome biogenesis and vesicle transport

We have identified a possible role for the KIFC1 motor protein in formation of the acrosome, an organelle unique to spermatogenesis. KIFC1, a C-terminal kinesin motor, first appears on membrane-bounded organelles (MBOs) in the medulla of early spermatids followed by localization to the acrosomal vesicle. KIFC1 continues to be present on the acrosome of elongating spermatids as it flattens on the spermatid nucleus; however, increasing amounts of KIFC1 are found at the caudal aspect of the spermatid head and in distal cytoplasm. The KIFC1 motor is also found in the nucleus of very immature round spermatids just prior to its appearance on the acrosome. In some cases, KIFC1 appears localized just below the nuclear membrane adjacent to the subacrosomal membrane. We demonstrate that KIFC1 is associated with importin beta and colocalizes with this nuclear transport factor on curvilinear structures associated with the spermatid nuclei. These data support a model in which KIFC1, perhaps in association with nuclear factors, assists in the formation and/or elongation of the spermatid acrosome. This article represents the first demonstration of a direct association of a molecular motor with the spermatid acrosome, the formation of which is essential for fertilization.     

ELECTRON MICROSCOPE STUDIES ON SPERM DIFFERENTIATION IN MARINE ANNELID WORMS. I. SPERM FORMATION IN IKEDOSOMA GOGOSHIMENSE

The ultrastructur of spermatozoa and the changes through which they are differentiated during sperm formation in an echiuroid were observed under the electron microscope. Many spermatids are connected to one central cytoplasmic mass and the sperm differentiation proceeds synchronously in one sperm-ball. Dense plate-like structures appear in the cytoplasm of early spermatids and disappear soon. In the process of nuclear condensation, many electron-dense aggregates appear in homogeneously textured chromonema and the aggregates are packed together to form a uniformly dense nucleus. Near the centriole at the opposite side from the central mass, the mitochondria fuse together to form one large middle-piece mitochondrion and the acrosomal vesicle is formed from the Golgi-complex. The differentiating acrosome in the late spermatid moves to the anterior tip of the head. In the completed acrosome, a flocculent substance accumulates in the conspicuously expanded invaginated pocket of the acrosomal vesicle and two kinds of material of different electron density fill the inside of the acrosomal vesicle. The spermatozoa remain connected to the central mass at the lateral side of the head until they become fully mature and are packed into the nephridia before spawning.     

A comparative study on the fine structure of developing spermatozoa in the isopod,Oniscus asellus,and the amphipod,Orchestoidea sp.

Summary Developing spermatids and mature spermatozoa from the isopod, Oniscus asellus and the amphipod, Orchestoidea sp. have been examined with the light microscope and the electron microscope and have been found to have similar morphologies. As spermiogenesis proceeds the nucleus migrates to one pole of the spermatid at which point an acrosome, contiguous rod, and cross-striated tail develop. The acrosomal vesicle elongates to a cone-shaped, mature acrosome lying at the apex of a cross-striated tail and nucleus which are situated at approximate forty-five degrees to each other. The cross-striated tail originates as an evagination of the spermatid plasma membrane near the acrosomal vesicle. The tail eventually grows to lengths of four to five hundred microns. The mature, tail-like appendage is cross-striated at major 750 to 800 Å, and minor 125 to 150 Å, periodicities. When observed in vitro, mature sperm of both species appear non-motile.Possible homologies of this unusual spermatozoon with other types of spermatozoa are made and it is concluded that: 1) isopod and amphipod spermatozoa should be classified as non-flagellate; 2) the cross-striated tail, previously thought to be a flagellum, is a non-motile structure associated in development and possible function with the acrosome; and 3) the rodlike structure contiguous with the acrosome is similar to perforatoria described in some vertebrate sperm.Supported by U.S.P.H.S. Grant No. NB-06285 and Training Grant No. 5-Tl-GM-202. — The author wishes to express his grateful appreciation for the technical assistance given by Miss Ann Barnett during the course of this investigation.     

Ultrastructure of spermiogenesis in a freshwater stingray, Himantura signifer

Ultrastructural changes of spermatids during spermiogenesis in a freshwater stingray, Himantura signifer, are described. Differentiation of spermatids begins with modification of the nuclear envelope adjacent to the Golgi apparatus, before the attachment of the acrosomal vesicle. A fibrous nuclear sheath extends over the nuclear surface from the site of acrosomal adherence. The conical apical acrosome is formed during nuclear elongation. At the same time, chromatin fibers shift from an initially random arrangement, assume a longitudinal orientation, and become helical before final nuclear condensation. An axial midpiece rod is formed at the posterior end of nucleus and connects to the base of the sperm tail. Numerous spherical mitochondria surround the midpiece axis. The tail originating from the posterior end of the midpiece is composed of the usual 9 + 2 axoneme accompanied by two longitudinal columns, which are equal in size and round in cross section. The two longitudinal columns are absent at the end piece. A distinctive feature of freshwater stingray sperm is its spiral configuration.     

Changes in distribution and molecular weight of the acrosomal protein acrin2 (MC41) during guinea pig spermiogenesis and epididymal maturation

In this study, we examined the localization and characteristics of an intra-acrosomal protein, acrin2 (MC41), during guinea pig spermiogenesis and post-testicular sperm maturation in the epididymis, using the monoclonal antibody MC41. Immunoelectron microscopy demonstrated not only a specific domain localization of acrin2 in the apical segment of the guinea pig sperm acrosome, but also its dynamic behavior according to the spermatid differentiation and passage through the epididymis, as follows: acrin2 was exclusively localized in the membrane of the endoplasmic reticulum of early-stage spermatids but was not detectable in the developing acrosome until spermatids reached the maturation phase. In the final stage of spermiogenesis, acrin2 became localized in the outer acrosomal membrane (OAM)/matrix-associated materials both in the small region posterior to the dorsal matrix and along the ventral margin of the acrosomal apical segment. The acrosomal location of acrin2 in caput epididymidal sperm was almost identical to that observed in the final step spermatids, but during maturation it became progressively more restricted in area until on distal cauda epididymidal sperm it remained only in the dorsal region. In Western blot analysis, the MC41 antibody recognized a 165-kDa protein in the mature sperm extract. Furthermore, it was demonstrated that molecular weight reduction of the protein occurred during sperm passage through the epididymis. These findings indicate that acrin2 changes progressively in both distribution and size during development and maturation of the acrosome.