Distribution of unipolar brush cells and other calretinin immunoreactive components in the mammalian cerebellar cortex

We have compared the distribution of unipolar brush cells (UBCs) in the cerebellum of Brazilian opossum (Monodelphis domestica), mouse, guinea pig, rabbit, cat, and Rhesus monkey, using an antiserum to calretinin which is present in those cells. The morphology and calretinin staining intensity of the UBCs remains constant across species. As a general trend, in all species studied, UBCs are particularly enriched in the vestibulocerebellum. Interspecies differences, however, were noted in the distribution of UBCs across other regions of the cerebellar cortex. A major variation involves the extent of the UBC-rich region of the ventral portion of the paraflocculus. The distribution of UBCs in non-vestibular vermal folia also varies substantially. UBCs are deployed in more or less distinct parasagittal zones in the vermis of the opossum, rabbit, cat, and macaque. The density of UBCs decreases progressively from medial to lateral portions of the same folium and is lowest in the lateral, posterior portions of the cerebellar hemispheres (crus II) and in the dorsal portion of the paraflocculus. In cat and macaque, the decrease in the density of UBCs across the intermediate cortex is more gradual than in the other species. The data indicate that the UBCs play a more prominent role in the modulation of sensorimotor transformations in carnivores and primates than in smaller mammals and should not be considered a vestigial form of neuron. In addition to the UBCs, calretinin antibody distinctly stains the following neurons in different species: granule cells and parallel fibers in all species except rabbit and cat; Golgi cells, especially in rat and macaque; Lugaro-like cells, especially in mouse, rat, and macaque; basket cells in macaque; subsets of mossy fibers in all species; and subsets of climbing fibers in all species but guinea pig. Usually, the distribution of UBCs is related to that of calretinin stained granule cells and mossy fibers.     

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.     

Transitional states of acrosomal exocytosis and proteolytic processing of the acrosomal matrix in guinea pig sperm

In this study, we adapted a FluoSphere bead-binding assay to study the exposure and release of guinea pig sperm acrosomal components during the course of capacitation and acrosomal exocytosis. Prior to capacitation or the initiation of exocytosis, acrosomal proteins were not accessible to FluoSpheres coated with antibodies against two acrosomal matrix (AM) proteins, AM67 and AM50; during the course of capacitation and ionophore-induced acrosomal exocytosis, however, we detected the transient exposure of the solid-phase AM proteins on the surface of guinea pig sperm using the antibody-coated fluorescent beads. Several different transitional stages leading to complete acrosomal exocytosis were classified, and we propose these represent true, functional intermediates since some of the AM proteins are orthologues of mouse proteins that bind the zona pellucida (ZP) of unfertilized eggs. In addition, we present evidence that implicates acrosin in the proteolytic processing of AM50 during AM disassembly. Thus, we propose that the transitional states of acrosomal exocytosis involve early binding of AM proteins to the ZP (by what visually appear to be "acrosome-intact" sperm), maintenance of ZP binding that coincides with the progressive exposure of AM proteins, and gradual proteolytic disassembly of the AM to allow sperm movement through the ZP. We feel this "transitional states" model provides a more refined view of acrosomal function that supports a move away from the widely held, overly simplistic, and binary "acrosome-reaction" model, and embraces a more dynamic view of acrosomal exocytosis that involves intermediate stages of the secretory process in ZP binding and penetration.     

Mouse sperm protein sp56 is a component of the acrosomal matrix

Previously, we identified the guinea pig sperm acrosomal matrix glycoprotein AM67 and demonstrated that it is most closely related to mouse sperm sp56, initially reported to be a cell-surface protein. On the contrary, our studies demonstrated that sp56 is an intra-acrosomal component. Based upon the homology between guinea pig AM67 and mouse sp56, we hypothesized that sp56 was part of the acrosomal matrix, a structure that had yet to be demonstrated to exist in mouse sperm. In this paper, we show that sp56 first appeared in late meiotic cells and accumulated during spermiogenesis, the haploid stage of spermatogenic cell development. Using affinity-purified anti-peptide antisera, we determined that the molecular weight of sp56 in cauda epididymal sperm approximated that of guinea pig AM67 ( approximately 67 000 M:(r)) and that sp56 was present in a high molecular weight, disulfide-linked complex. The forms of sp56 in pachytene spermatocytes and spermatids had higher molecular weights than was found for the sperm form; the size differences were apparently due to alterations in carbohydrate side chains. The sp56 complex could not be solubilized by the nonionic detergent Triton X-100 but remained associated with the dorsal surface of the mouse sperm head, demonstrating that sp56 is a component of the mouse sperm acrosomal matrix.     

The subacrosomal granule and its evolution during spermiogenesis in a lizard

Summary Some aspects of spermiogenesis have been studied in the testis of the teiid lizard Cnemidophorus lemniscatus lemniscatus by electron microscopy. Shortly after the acrosomal vesicle is lodged in a nuclear concavity of the spermatid, a dense granule differentiates in the center of the subacrosomal space. It is cone-shaped and shows a longitudinal striation. Its base applies to the acrosomal membrane and, through this, to the acrosomal granule. Its rounded vertex causes a depression of the nuclear membranes which, initially juxtaposed, separates at this point to form a vesicle. The granule develops and becomes a rod when spermiogenesis is advanced and the subacrosomal space has taken the form of a secondary cap. The rod is cylindrical, retains its original striation and has a convex acrosomal end. It encloses the vesicle formed by the nuclear envelope in its base and follows the apex of the nucleus. Meanwhile, the acrosomal granule loses its identity and the acrosomal cap is filled with a dense substance, in which a fringe of translucent material differentiates. This fringe lies in the dorsal and apical margins of the acrosome and is incompletely divided by longitudinal crests of the dense acrosomal substance. A projection of the Sertoli cell forms an accessory cap which envelops the acrosome and is in turn covered by the cytoplasm of the spermatid, constituting an intricate association. Two reflex membranes underlie the plasmalemma in the outer surface of the projection of the Sertoli cell. They are continuous with one another at their ends and with the cell membrane in the edge of pores. In the peripheral cytoplasm of the spermatid facing the accessory cap, numerous microtubules run longitudinally. By means of thin membranes some are interconnected or connected with the plasmalemma, from which they seem to originate.This research forms part of project N. 31.26.S1-0244 supported by the Consejo Nacional de Investigaciones Científicas y Tecnológicas     

Fucoidin inhibits attachment of guinea pig spermatozoa to the zona pellucida through binding to the inner acrosomal membrane and equatorial domains

Our previous study has shown that fucoidin, an algal heteropolysaccharide, is a potent inhibitor of sperm-zona binding in the guinea pig, hamster and human. To visualize the surface site of fucoidin binding, a biotinated derivative (B-Fuc) of the native fucoidin was prepared. B-Fuc retained the inhibitory activity and was used in conjunction with FITC-avidin to localize its binding sites on guinea pig spermatozoa using fluorescence microscopy. In living acrosome-reacted spermatozoa, B-Fuc bound predominantly to the inner acrosomal membrane and equatorial segment domains. The binding was effectively competed by a 10-fold excess of native fucoidin, but not by a 10-fold excess of heparin or a 20-fold excess of biotinated normal rabbit serum IgG. B-Fuc binding patterns on dead spermatozoa were quite different from that of living spermatozoa. The post-acrosomal region, rather than the inner acrosomal membrane and equatorial domains, was intensely labeled. This indicates the importance of using living cells in assessing true surface binding sites whenever possible. We conclude that the inner acrosomal membrane and/or equatorial domains are critical for zona binding in the guinea pig.     

Inhibition of fertilization of the rabbit ova in vitro by the antibody to the inner acrosomal membrane of rabbit spermatozoa

The antibody to the rabbit sperm inner acrosomal membrane, raised in guinea pig, completely inhibited the fertilization of rabbit ova in vitro. The F(ab')2 of the antibody was equally effective in inhibiting fertilization. The antibody appeared to exert its inhibitory effect by binding to the inner acrosomal membrane of acrosome-reacted sperm. The antibody-treated sperm did not attach to or penetrate the zona pellucida. Thus, anti-IAM offers a great potential as a contraceptive agent.     

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.     

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.     

Role of microtubule-dependent membrane trafficking in acrosomal biogenesis

The role of microtubule-based trafficking in acrosomal biogenesis was examined by studying the effects of colchicine on spermiogenesis. In electron micrographs of untreated cap-phase mouse spermatids, coated vesicles were always seen on the apex and caudal margins of the developing acrosomal cap. The increase in volume and the accumulation of materials in the acrosome during the Golgi and cap phases were observed to occur via fusion of vesicles at various sites on the growing acrosome. By studying the acid phosphatase localization pattern and colchicine-treated spermatids, the role of clathrin-coated vesicles became clear. Coated vesicle formation at the caudal margin of the acrosome appeared to be responsible for the spreading and shaping of the acrosome over the surface of the nucleus and also established distinct regional differences in the acrosome. In colchicine-treated spermatids, the Golgi apparatus lost its typical membranous stack conformation and disintegrated into many small vesicles. Acrosome formation was retarded, and there was discordance of the spread of the acrosomal cap with that of the modified nuclear envelope. Many symplasts were also found because of the breakdown of intercellular bridges. Colchicine treatment thus indicated that microtubule-dependent trafficking of transport vesicles between the Golgi apparatus and the acrosome plays a vital role in acrosomal biogenesis. In addition, both anterograde and retrograde vesicle trafficking are extensively involved and seem to be equally important in acrosome formation. This work was supported by grants 83-0211-B-002-184 and 93-2320-B-320-012 from the National Science Council, Taiwan, Republic of China.     

锯缘青蟹精子发生的超微结构

采用透射电镜观察锯缘青蟹精子发生过程中超微结构的变化,结果表明：精原细胞椭圆形,染色质分布于核膜周围,胞质中具嵴少的线粒体,内质网小泡等。初级精母细胞染色质呈非浓缩状,胞质中具众 内质网小泡,特殊的膜系及晶格状结构。次级精母细胞核质间出现由内质小泡聚集成的腔。     

乌梢蛇精子头部形成的超微结构

摘要：为了解乌梢蛇（Zaocys dhumnades）精子形成的规律,用透射电镜对其头部超微结构进行了观察。结果表明,乌梢蛇精子头部形成可分为4个阶段：阶段Ⅰ,前顶体囊泡内的颗粒物质融合形成1个顶体颗粒而发育为顶体囊泡,随着顶体囊泡的增大,在顶体囊泡与核膜之间形成了致密的纤维物质层。阶段Ⅱ,顶体囊泡变扁平,顶体颗粒分散...     

Spermiogenesis in the Marine Shrimp, Sicyonia ingentis

Spermiogenesis in the marine prawn Sicyonia ingentis was examined using transmission electron microscopy. The acrosomal vesicle, derived from the fusion of pro-acrosomal vesicles blebbed from the nuclear envelope, contains the membrane pouches, anterior granule and a spike. The anterior granule is formed from the coalescence of granular aggregates within the proacrosomal vesicles. Primordia underlying the apical acrosomal vesicle membrane polymerize to form a spike approximately 6 μm long. The convoluted pouch membranes arise from the posterior acrosomal vesicle membrane. Lateral and apical portions of the acrosomal vesicle are surrounded by a pentalaminar membrane comprised of the spermatid plasma membrane and the acrosomal vesicle membrane. Subacrosomal structures include the dense saucer plate, granular core and crystalline lattice. These components condense just posterior to the acrosomal vesicle and are separated from the chromatin by a nuclear plate.
The spermatid nucleus becomes surrounded by rough endoplasmic reticulum (RER) and membranous lamellar bodies. RER gives rise to smooth endoplasmic reticulum. These membrane systems degenerate, forming a band of reticular elements around the lateral and posterior portions of the nucleus. The nucleus undergoes condensation followed by decondensation with concomitant breakdown of the nuclear envelope. The resultant chromatin is fibrillar in appearance.     

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.     

Outer acrosomal membrane of guinea pig spermatozoa: Isolation and structural characterization

We describe a protocol to isolate a highly enriched fraction of outer acrosomal membrane from guinea pig spermatozoa and present new data on the ultrastructure of this membrane domain. Cauda epididymal spermatozoa were suspended into a low ionic strength buffer and subjected to brief homogenization; this stripped the plasma membrane from the spermatozoa and severed the acrosomal apical segment from the spermatozoon. The crescent-shaped apical segments retained the outer acrosomal membrane and specific components of the acrosomal matrix. Enriched fractions of apical segments were isolated on discontinuous sucrose gradients and the outer acrosomal membrane purified by subsequent centrifugation onto Percoll density gradients. The isolated outer acrosomal membrane did not form vesicles, but instead rolled up into spiral sheets. Both thin section and negatively stained specimens revealed a paracrystalline arrangement of filaments associated with the luminal surface of the membrane. The isolated outer acrosomal membrane revealed a limited number of polypeptides by SDS-PAGE, and the polypeptide pattern was distinct from the plasma membrane fraction. The isolated acrosomal membranes possessed no oubain sensitive Na+, K+-ATPase activity, whereas about 20% of the ATPase activity of the plasma membrane enriched fraction was inhibited by oubain. The potential function of the structural differentiations of the outer acrosomal membrane in the membrane fusion events of the acrosome reaction is discussed.     

The effect of triisopropyl phosphate on the mobility of surface concanavalin a receptors and on the locomotion of polymorphonuclear leucocytes

The non-phosphorylating organophosphorus compound triisopropyl phosphate, which is known to inhibit rabbit leucocyte locomotion, can stimulate the locomotion of guinea pig leucocytes under certain conditions. Different methods of preparing guinea pig leucocyte monolayers can give preparations with different proportions of motile cells. With preparations that contain relatively slowly moving cells triisopropyl phosphate increases the number of stationary cells without significantly affecting the speed of the cells that remain motile. Most rabbit leucocytes labelled with fluorescein-labelled concanavalin A form caps within 5–10 min at 37 °C. In contrast the rate of cap formation in guinea pig leucocytes is much slower and after 20 min many cells have only random patches. Triisopropyl phosphate accelerates cap formation in guinea pig leucocytes but not in rabbit leucocytes. The local anaesthetic nupercaine inhibits cap and patch formation in rabbit and guinea pig leucocytes. Inhibition of rabbit leucocyte locomotion is induced by concanavalin A at 1 μg/ml. These results are briefly related to the known effects of triisopropyl phosphate on the isolated leucocyte plasma membrane.     

Two major acrosomal proteins act on different parts of the oocyte vitelline coat in the abalone, Haliotis discus

Two proteins of molecular weights 20,000 (20K) and 15,500 (15.5K) are the major soluble substances released from the acrosomal vesicle of the abalone, Haliotis discus, spermatozoon. A crude preparation of them has been shown to possess lytic activity on the oocyte vitelline coat (VC). To elucidate the role(s) of each acrosomal protein (AP) in VC lysis, oocytes were examined after treatment with various AP preparations. The VC, which is about 1 micron thick, is composed of thin outer and inner electron-dense layers and a thick main layer of a fine filamentous feltwork. When oocytes were treated with a crude preparation containing both APs, the outer layer disappeared and the feltwork of the main layer loosened extensively. A preparation containing predominantly the 20K AP dissolved the outer layer completely and the main layer to some extent, whereas another preparation containing predominantly the 15.5K AP caused loosening of the main layer without alteration of the outer layer, suggesting that the 20K AP acts on the outer layer, whereas the 15.5K AP acts on the main layer. However, when purified, each AP by itself failed to dissolve the VC, although lysis occurred in a 1:1 mixture of these preparations. Moreover, when the oocytes were pretreated with the 20K AP and thoroughly washed, the 15.5K AP alone could induce lysis. These results suggest that the lysis of the outer layer requires both APs but not simultaneously. The 15.5K AP, which is located posteriorly in the acrosomal vesicle, must be released to act on the VC following the action of the 20K AP.     

Cytochemical and Western Blot Analysis of the Subcompartmentalization of the Acrosome in Rodents using Soybean Lectin

In the present study, the formation and development of the acrosome during spermiogenesis in four different rodent species (rat, mouse, hamster and guinea pig) was compared by means of cytochemical and blotting techniques using a lectin from soybean (SBA). This lectin recognizes specifically the acrosome of the four species at all steps of formation. At the ultrastructural level, SBA-binding pattern was similar in the acrosome of the rat, mouse and hamster. SBA preferentially labelled the electron-lucent area of the acrosome in early spermatids (Golgi and cap phases) and the outer region of the acrosome in mature spermatids (acrosome and maturation phase). The lectin binding pattern was more complex in the guinea pig acrosome. Three different subdomains can be established in the early acrosome of the guinea pig. The lectin bound the three subdomains but mainly a thin fold which spreads over the nucleus during the cap phase. In the acrosome phase, SBA strongly reacted with the principal segment. In contrast, no reactivity was observed in most of this segment in maturation phase spermatids. In this phase, SBA bound preferentially a thin area covering the dorsal region of the apical segment. Lectin blots of detergent-extracted testes indicated that SBA only recognizes proteins of high molecular weight (>100kD) in the four species studied. The results obtained in the present study suggest that the development of acrosomal subdomains is very similar in the mouse, rat and hamster but shows a more complex pattern in the guinea pig.     

Inner acrosomal membrane of mammalian spermatozoa: its properties and possible functions in fertilization

The inner acrosomal membrane (IAM) develops during the spermatid stage of differentiation as that portion of the Golgi-derived acrosome granule that tightly associates with the condensing sperm nucleus. In some mammalian species, an electron-dense proteinaceous material accumulates between the IAM and the nuclear envelope, collectively comprising the "perforatorium." Evidence, including its partial purification and its structural resistance to detergents and sonication, suggests that the IAM is an unusually resiliant membrane. Dense paracrystalline arrays of intramembranous particles, a lack of lectin-mediated receptor modulation, and its lack of participation in sperm-egg fusion suggest that the IAM lacks the same degree of fluidity as the egg surface plasmalemma. Observations using monoclonal antibodies, however, suggest that some specific antigenic modulations may be possible within the IAM. Its structural rigidity is of obvious mechanical value during sperm penetration through the zone pellucida. An additional role as a scaffold for putative zona lysin material remains controversial. Biochemical evidence suggests that acrosin, for example, is not entirely soluble and that some remains sperm-associated, depending on the conditions of acrosome disruption. Nevertheless, morphological studies do not agree on acrosin's specific localization to the IAM. Currently there is only very limited information concerning the localization of the other acrosomal enzymes to the IAM. Another possible role for the IAM in some species may be in recognizing the zona pellucida. Evidence for this derives from the observation that fucoidin, a fucose heteropolysaccharide, inhibits guinea pig sperm-zona binding, and bound fucoidin can be localized to the IAM and equatorial regions of the living acrosome-reacted spermatozoa. Finally, the IAM may have a role in early recognition/adhesion with the colemma.