Characterization of an acrosomal matrix protein in hamster and bovine spermatids and spermatozoa.

Experiments have been carried out characterizing an Mr 22,000 protein present in the acrosomes of hamster and bull spermatozoa. The Mr 22,000 protein is resistant to solubilization in detergent solutions containing high or low salt and has a pI of -5.2. With various lectins, the protein from hamster sperm was shown to be sparingly glycosylated with N-acetylglucosamine, mannose, and galactose while that from the bull demonstrated a slight reactivity for galactose. Using a specific monoclonal antibody (MAB 4/18), the Mr 22,000 polypeptide has been localized exclusively to the acrosomes of mature testicular and epididymal hamster and bovine sperm. Acrosomal components of differentiating bovine and hamster spermatids in tissue sections did not react with the monoclonal antibody, although the protein was present in immunoblots of round spermatids. In bovine sperm, MAB 4/18-staining at the ultrastructural level with immunogold-labeled second antibody was present as a reticulum throughout the acrosomal cap and as punctate aggregates in the equatorial segment. In hamster sperm, MAB 4/18-reactivity was present along the periphery of the acrosome in conjunction with matrix components (M1 and M2), as well as along the inner acrosomal membrane. These observations indicate that the acrosomes of bovine and hamster sperm possess an immunologically related Mr 22,000 protein and suggest that differences in MAB 4/18-staining of spermatids and spermatozoa is a result of epitope modification and/or a change in accessibility of the epitope to the antibody probe during the course of spermiogenesis. Based on its localization and solubility properties, we suggest that the Mr 22,000 protein, in conjunction with other polypeptides, forms a structural framework to maintain acrosomal shape and/or compartmentalize acrosomal contents.     

A Simple Staining Procedure for Detecting the true Acrosome Reaction in Buffalo (Bubalus bubalis) Spermatozoa

A simple dual staining procedure for detecting the true acrosome reaction in dried smears of buffalo spermatozoa is described. Trypan blue is used first to differentiate live from dead spermatozoa and the dried smears which have been prepared are stained with Giemsa for acrosome evaluation. Four categories of spermatozoa were recognized: A) live, intact acrosome (acrosome pink, postnuclear cap clear); B) dead, intact acrosome (acrosome pink, postnuclear cap blue); C) live, detached acrosome (acrosome clear, postnuclear cap clear); and D) dead, detached acrosome (acrosome clear, postnuclear cap blue). The procedure is simple, rapid and convenient for assessing true acrosome reaction in buffalo spermatozoa. Simultaneous assessment of sperm viability and its acrosomal status in dried smears makes this procedure attractive because the true acrosome reaction can be studied thoroughly at a later state after the incubation period.     

Localisation of low molecular weight sperm antigens during capacitation and acrosome reaction

FITC-labelled sperm-specific antibodies against hamster spermatozoa were utilized as probes in acrosome reaction assays. An indirect immunofluorescence test demonstrated the localisation of two sperm proteins of 19 kDa and 23 kDa on the anterior acrosomal cap region of washed cauda epididymal sperm. These proteins were not detected in reacted acrosome or on immature or immotile sperm. Antisperm agglutinating antibodies specific to these two low molecular weight sperm antigens could be useful probes for evaluating the acrosomal status of mammalian spermatozoa.     

Specific labelling by peanut agglutinin of the outer acrosomal membrane of the human spermatozoon

Experiments to bind fluorescein-conjugated Arachis hypogea (peanut) agglutinin (FITC-PNA) to washed human spermatozoa demonstrated that this lectin binds to the acrosome region in air-dried preparations. Since there was no binding when labelling was performed in suspension, and comparable labelling to that seen in air-dried preparations was seen when spermatozoa treated with saponin (to lyse the plasma membrane) were labelled in suspension, the lectin must bind to an intracellular structure, probably the outer acrosomal membrane. This was confirmed by ultrastructural localization of colloidal gold-conjugated lectin in saponin-treated spermatozoa. Treatment of spermatozoa with the detergent Nonidet P-40 caused a marked change in the binding pattern: more spermatozoa showed binding in the equatorial segment of the acrosome with no binding in the anterior cap region. A comparable, less marked, change was seen when spermatozoa were incubated overnight under conditions known to support the capacitation and spontaneous acrosome reactions. Treatment with the calcium ionophore A23187 for 1 h to induce acrosome reactions artificially in uncapacitated spermatozoa resulted in the appearance of patchy acrosome fluorescence. From these experiments it is concluded that PNA binds specifically to the outer acrosomal membrane, and that FITC-PNA-labelling may be used to monitor the human sperm acrosome reaction.     

Unistellate spermatozoa of decapods: comparative evaluation and evolution of the morphology

Decapod unistellate spermatozoa are primarily characterized by the presence of a single appendage (spike) extending from the acrosome. Among decapods, this type of spermatozoon is found only in shrimps of the families Sicyoniidae, Penaeidae, and Solenoceridae (suborder Dendrobranchiata) and of the infraorder Caridea (suborder Pleocyemata). This review comparatively discusses the morphological diversity of unistellate spermatozoal ultrastructure among these decapods, as well as the role of the primary structures involved in the fertilization and spermatozoal capacitation. Furthermore, the use of the unistellate spermatozoal ultrastructure to support phylogenetic relationships and of the current phylogenetic evidences to investigate the evolution of spermatozoa of decapods is discussed. Morphologically, the main differences between caridean and dendrobranchiate unistellate spermatozoa are the shape of the main body (inverted cup-shaped, and spherical, bulged or elongate, respectively) and complexity of the acrosomal region. The latter is directly related to the type of fertilization. For example, dendrobranchiates have more complex acrosomal regions than that carideans, and fertilization involves a visible acrosome reaction, which is not observed in carideans. Ultrastructural changes of spermatozoa throughout capacitation are unknown in carideans, but for dendrobranchiates generally occur in the acrosomal vesicle and subacrosomal region throughout attachment of the spermatophore to the thelycum, enabling fertilization by the spermatozoa. Comparative evaluation of spermatozoal morphology and current phylogenetic evidences corroborates the hypothesis that the spermatozoal spike of carideans and dendrobranchiates is the result of convergent evolution.     

Immunolocalization of bovine sperm protease BSp120 by light and electron microscopy during capacitation and the acrosome reaction: its role in in vitro fertilization

Mammalian fertilization involves various steps in which the participation of specific enzymes has been demonstrated by numerous studies. Acrosin is one of the most widely acrosomal protease in mammalian spermatozoa studied, including bovine; however, other proteases have also been described. A new trypsin-like serine protease named bovine serine protease of 120 kDa (BSp120) and its pre-cursor BSp66 (66 kDa) were identified in bovine spermatozoa. Cytological and ultrastructural immunolocalization studies on BSp120 were performed in live and fixed cells. Immunoflorescence assays with specific polyclonal antibodies revealed localization of BSp120 on the sperm head, with a signal homogeneously distributed over the acrosome resembling a horseshoe. After the acrosome reaction, sperm showed a patchy pattern in the acrosomal cap. Immune electron microscopy analysis indicated that BSp120 is located over the head plasma membrane of capacitated spermatozoa and acrosome reacting spermatozoa. To assess BSp120 function in sperm-oocyte interaction, in vitro fertilization studies were conducted. Oocytes were incubated with spermatozoa pre-treated with anti-BSp120, anti-guinea pig acrosin, and anti-BSp120 plus anti-guinea pig acrosin. Pre-treatment of bovine spermatozoa with antibodies towards each protein did not significantly modify fertilization rates. However, when both anti-acrosin and anti-BSp120 antibodies were simultaneously added, there was a significant decrease in the fertilization rate, suggesting that both enzymes may be required for fertilization. Altogether, the results from the present study described the localization of BSp120 over the acrosome of bovine sperm, and suggest its involvement in fertilization.     

Three‐dimensional reconstruction of black tiger prawn (Penaeus monodon) spermatozoa using serial block‐face scanning electron microscopy

Serial Block‐Face Scanning Electron Microscopy (SBF‐SEM) was used in this study to examine the ultrastructural morphology of Penaeus monodon spermatozoa. SBF‐SEM provided a large dataset of sequential electron‐microscopic‐level images that facilitated comprehensive ultrastructural observations and three‐dimensional reconstructions of the sperm cell. Reconstruction divulged a nuclear region of the spermatophoral spermatozoon filled with decondensed chromatin but with two apparent levels of packaging density. In addition, the nuclear region contained, not only numerous filamentous chromatin elements with dense microregions, but also large centrally gathered granular masses. Analysis of the sperm cytoplasm revealed the presence of degenerated mitochondria and membrane‐less dense granules. A large electron‐lucent vesicle and “arch‐like” structures were apparent in the subacrosomal area, and an acrosomal core was found in the acrosomal vesicle. The spermatozoal spike arose from the inner membrane of the acrosomal vesicle, which was slightly bulbous in the middle region of the acrosomal vesicle, but then extended distally into a broad dense plate and to a sharp point proximally. This study has demonstrated that SBF‐SEM is a powerful technique for the 3D ultrastructural reconstruction of prawn spermatozoa, that will no doubt be informative for further studies of sperm assessment, reproductive pathology and the spermiocladistics of penaeid prawns, and other decapod crustaceans. J. Morphol. 277:565–574, 2016. © 2016 Wiley Periodicals, Inc.     

Spermatozoa of murid rodents from Africa: morphological diversity and evolutionary trends

The diversity of the structural organization of the spermatozoa of African murid rodents is described at the light and transmission electron microscopical level of resolution. In most species the sperm head is falciform in shape but it varies somewhat in overall breadth, width, and length. A typical perforatorium is present and the acrosome splits into a large head cap over the convex surface and a smaller ventral segment similar to the sperm head of most Asian and Australasian murids. In a few species, however, the morphology is very different. In Acomys and Uranomys spermatozoa, the apical hook is more bilaterally flattened, has a large apical acrosomal region, and no separate ventral segment. Two species of Aethomys have, in addition to an apical hook, a 4μ long extension of the cytoskeletal material that projects from the concave surface of the sperm head, whereas in Dasymys two large ventral processes extend from the upper concave region which contain nuclear material basally and a huge extension of cytoskeleton apically. In Aethomys chrysophilus type B, the sperm nucleus is unique in form and often has a central region in which threads of chromatin can be seen; it is capped by a massive acrosome whose apical segment is complex and convoluted in structure. Stochomys longicaudatus appears to have a conical sperm head, and in all three Lophuromys species the sperm head is spatulate in shape with the flat, plate-like nucleus capped by a thin acrosome. The evolutionary trends in changes of sperm head shape and design of these rodents are discussed. It is suggested that some of the differences in morphology may relate to the variation in structural organization of the coats around the egg through which the spermatozoon has to pass in order for fertilization to occur.     

The assessment of human sperm morphology in surface replica preparations for transmission electron microscopy

Human spermatozoa were treated with the detergents Hyamine 2389, Triton X-100, or sodium dodecyl sulphate (SDS) and surface replica preparations and Papanicolaou-stained smears made. From the ultrastructural studies it was found that Hyamine caused a dissolution of the plasmalemma to reveal the outer acrosomal membrane that was often absent over the anterior cap region; whereas Triton, in addition, caused severe damage to the entire acrosome. Treatment with SDS rapidly cleaved the tails from the majority of the spermatozoa, stripped the plasmalemma from both the head and tail regions of the cells, and also removed the whole of the outer acrosomal membrane plus most of the acrosomal contents. However, when viewed in the Papanicolaou-stained preparations, the spermatozoa were all of apparently normal morphology. These studies make it clear that some caution must be used when interpreting human sperm morphology assessments made under the light microscope. While it is not suggested that the more involved technique of surface replication should be used in routine semen analyses, it does represent a valuable technique for use with research material.     

Immunocytological characterization of the outer acrosomal membrane (OAM) during acrosome reaction in boar

In order to study the acrosome reaction in boar, spermatozoa were incubated in a calcium-containing medium in the presence of the calcium ionophore A23187. The time course of the acrosome reaction was assessed by phase-contrast microscopy and correlated with the movement characteristics of the spermatozoa determined by means of multiple-exposure photography (MEP). Different stages of the acrosome reaction could be observed by indirect immunofluorescence using an antibody fraction raised in rabbits against the isolated outer acrosomal membrane (OAM). At the start of the acrosome reaction, a bright fluorescence located exclusively at the acrosomal cap of the sperm head could be observed, whereas after 60-120 min, the fluorescence vanished, indicating the complete loss of the OAM. However, to gain more insight into the stages of the plasma membrane and OAM during the acrosome reaction, immunoelectron-microscopical studies were performed using anti-OAM antibodies detected by the protein-A gold method. Ultrathin sections and total preparations in combination with transmission electron microscopy (TEM) confirmed, that boar spermatozoa start their acrosome reaction by a vesiculation of the plasma membrane, thus exposing the heavily labelled OAM, which is then lost as sheets or large vesicles. The newly exposed inner acrosomal membrane did not show any labelling with gold, thereby indicating clear differences in the antigenicity of both acrosomal membranes.     

Immunocytological characteriziation of the outer acrosomal membrane (OAM) during acrosome reaction in boar

Summary In order to study the acrosome reaction in boar, spermatozoa were incubated in a calcium-containing medium in the presence of the calcium ionophore A23187. The time course of the acrosome reaction was assessed by phasecontrast microscopy and correlated with the movement characteristics of the spermatozoa determined by means of multiple-exposure photography (MEP). Different stages of the acrosome reaction could be observed by indirect immunofluorescence using an antibody fraction raised in rabbits against the isolated outer acrosomal membrane (OAM). At the start of the acrosome reaction, a bright fluorescence located exclusively at the acrosomal cap of the sperm head could be observed, whereas after 60–120 min, the fluorescence vanished, indicating the complete loss of the OAM. However, to gain more insight into the stages of the plasma membrane and OAM during the acrosome reaction, immunoelectron-microscopical studies were performed using anti-OAM antibodies detected by the protein-A gold method. Ultrathin sections and total preparations in combination with transmission electron microscopy (TEM) confirmed, that boar spermatozoa start their acrosome reaction by a vesiculation of the plasma membrane, thus exposing the heavily labelled OAM, which is then lost as sheets or large vesicles. The newly exposed inner acrosomal membrane did not show any labelling with gold, thereby indicating clear differences in the antigenicity of both acrosomal membranes.     

锯缘青蟹精子超微结构的研究

利用光镜和电镜观察了锯缘青蟹成熟精子的形态和超微结构。精子呈陀螺形，无鞭毛，在较宽的一端环生着１０余辐射臂。精子由球状的顶体、核杯以及核衍生的辐射臂三部分组成。顶体包括顶体管和顶体囊，后者包绕在顶体管的中央管周围，并可分为头帽带，内层和外层区。顶体被杯状的核包裹，仅头帽露于精子表面。成熟的精子中，位于核杯和顶体管之间的核膜出现局部断续或消失，中心粒和一些胞器出现的核杯腔中。     

Development of ability to penetrate the cumulus oophorus by hamster spermatozoa capacitated in vitro,in relation to the timing of the acrosome reaction

Hamster spermatozoa were tested for their ability to penetrate the intact cumulus matrix at low sperm:egg ratios (approximately 3:1). Uncapacitated spermatozoa attached to the surface of the cumulus and could not penetrate. Spermatozoa capacitated in vitro began to be able to penetrate after about 2 hr of preincubation, coincidentally with the first appearance of hyperactivation and spontaneous acrosome reactions. In all, 628 in vitro incubated spermatozoa were evaluated on and in cumuli: 270 could penetrate, but only ten of these were judged to have intact, “unmodified” acrosomes. Almost all spermatozoa capable of penetrating showed optically “modified” and swelling acrosomal caps, and this confirms previous observations on cumulus penetration in vivo. Penetration appeared limited to a phase in capacitation prior to completion of the acrosome reaction, as spermatozoa that had lost the acrosomal cap penetrated poorly and showed reduced viability. Penetration of the cumulus was inhibited by the hyaluronidase inhibitor sodium aurothiomalate. Cumulus penetrating ability could result either from a change in surface properties of the sperm at capacitation, which renders them less “sticky” to the matrix, or from release or activation of a “cumulus lysin.” We conclude that the ability to enter the cumulus matrix coincides with physiological changes in spermatozoa that occur during a terminal phase of capacitation preceding complete loss of the acrosomal cap, and that initiation of this process in vivo must precede sperm-zona contact.     

Ultrastructural localization of labeled acrosomal glycoproteins during in vivo fertilization in the rabbit

Rabbit spermatozoa were labeled predominantely in their acrosomal glycoproteins by 1-³H-glucosamine during spermiogenesis. Ova fertilized in vivo by spermatozoa labeled 22 days earlier were analyzed by fine-structure autoradiography for the localization of the label. The latter was found associated with 1) the fused membranes of the acrosomal cap remaining on the zona pellucida surface, 2) the material released on the zona surface after the acrosome reaction and possibly detectable after tannic acid fixation, 3) the equatorial segment of the sperm head and the preequatorial swellings, and 4) other sperm components, eg, the sperm tail. No labeling, on the other hand, was detected on the denuded leading edge of spermatozoa found either in the penetration slit or in the perivitelline space. Our observations suggest the involvement of acrosomal glycoproteins in different mechanisms of sperm/zona pellucida interaction but are not in favor of a major role of (enzymatic) glycoproteins bound to the inner acrosomal membrane during the penetration of the zona pellucida.     

Role of monoclonal antibody J-23 in inducing acrosome reactions in capacitated mouse spermatozoa.

A monoclonal antibody (J-23) to the 15 kDa component on the sperm head, the acceptor, which functions in zona binding, was shown to induce the acrosome reaction in capacitated cells, but not in fresh cells. The antibody recognized its epitope in the acrosomal cap region of fresh spermatozoa and in the equatorial region on washed and capacitated spermatozoa. However, equatorial expression did not depend on the acrosome reaction, since washing fresh spermatozoa increased the percentage with equatorial fluorescence, but did not increase the percentage with reacted acrosomes. The data indicate that the acrosome reaction can be induced in capacitated spermatozoa in the absence of zona glycoproteins.     

三疣梭子蟹精子顶体反应前后胞内Ca~(2+)的变化

应用激光扫描共聚焦显微镜(LSCM)和Fluo-3/AM荧染技术对三疣梭子蟹精子顶体反应前后的胞内Ca2 变化进行了观察和检测.结果显示,在精子顶体反应过程中,胞内Ca2 主要分布在细胞核、穿孔器和胞质膜残存处,胞内Ca2 浓度([Ca2 ]I)总体上呈现先上升后下降的趋势.顶体反应前精子的平均荧光强度为35.95±5.71;穿孔器前伸、顶体囊膜翻转阶段精子的平均荧光强度为66.80±7.35;顶体囊膜脱落、顶体丝形成阶段精子的平均荧光强度为3.87±2.82;上述各阶段间精子荧光强度有极显著差异(P<0.01).顶体反应穿孔器前伸、顶体囊膜翻转阶段的精子相比顶体反应前精子,[Ca2 ]I显著提高;而在顶体囊膜脱落、顶体丝形成阶段,[Ca2 ]I则急剧下降,只在顶体丝基部胞质膜残存处有微量Ca2 存在.初步探讨了三疣梭子蟹精子顶体反应前后胞内Ca2 变化的功能.     

Fine structure of the unistellate sperm of the shrimp, Sicyonia ingentis (Natantia)

Sperm of the prawn Sicyonia ingentis were studied cytochemically and ultrastructurally. Striking cytological differences were noted between these natantian sperm and previously studied reptantian sperm. In general, the S. ingentis sperm are composed of a spherical main body that is partially encompassed by a morphologically diverse cap region, from which extends a single appendage or spike. The main body houses an uncondensed, Feulgen-positive nuclear region that is partially surrounded by a cytoplasmic band. A single layer of small, 600 Å, vesicles lines the periphery of the cytoplasmic band. Large membranous vesicles extend from the inner surface of the cytoplasmic band into the nuclear region. The nucleus is separated from the cap or acrosomal complex by a dense plate and a highly organized crystalline lattice, which is composed of geometric squares that are approximately 350 Å in dimension. The cap region also contains convoluted membrane pouches; a central granular core; spherical bodies; an electron-dense, saucer-shaped plate; and a large anterior granule. The convoluted membrane pouches and anterior granule are periodic acid-Schiff (PAS) positive. The anterior granule also demonstrates RNAase-stable red fluorescence with acridine orange staining. A spiralled spike, approximately 6 μm long, extends from the anterior end of the cap. The cap and spike are bound by a double membrane, which results from the fusion of the plasma membrane and the convoluted pouch membrane. The sperm's acrosome is thought to be composed of the two PAS-positive cap components and the spike.     

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.     

Structural changes in sperm from the fiddler crab, Uca tangeri (Crustacea, Brachyura), during the acrosome reaction.

The acrosome reaction (AR) was induced in sperm from the brachyuran crustacean Uca tangeri either by mixing male and female gametes in filtered seawater or by treating the spermatozoa with the divalent cation ionophore A23187. This latter method provided a sufficient number of reacted spermatozoa to allow a detailed ultrastructural study of the AR. The process consists of two separate phases: a) initial release of the acrosomal vesicle contents, and b) further elongation of the acrosomal filament, which causes reversal of the rigid capsule limiting the acrosomal vesicle contents. The elongate acrosomal filament consists of an apical perforatorium and a basal columnar structure called here the proximal piece. The former derives from the perforatorium of the uninduced sperm stage with only small ultrastructural changes. The proximal piece forms from myelin-like membrane layers which are initially distributed all around the subacrosomal region and then accumulate in a column at the perforatorial base, thus promoting a sudden forward projection of the perforatorium. The AR in brachyurans is thought to be a passive mechanism that utilizes the negative pressure exerted on the nucleus--caused by emptying of the acrosomal vesicle--for an organized accumulation of membrane-rich material immediately behind the perforatorium, with the final result of the raising of a 3 microns long acrosomal filament.     

Ultrastructural localization of proacrosin and acrosin in ram spermatozoa

Proacrosin and acrosin were localized immunocytochemically at the electron microscope level in ram spermatozoa undergoing an ionophore-induced acrosome reaction. Antigenicity was preserved after fixation with 0.5% w/v ethyl-(dimethylaminopropyl)-carbodimide, and an antibody preparation was used that reacted with all major forms of ram acrosin. All stages of the acrosome reaction could be observed in a single preparation. At the earliest stage, labeling was observed throughout the acrosomal contents, which were just beginning to disperse. As dispersal proceeded, labeling diminished, being associated only with visible remnants of the acrosomal matrix. By the time the acrosome had emptied, almost no labeling could be detected on the inner acrosomal membrane. The relationship between matrix dispersal and proacrosin activation was studied in isolated ram sperm heads. While proacrosin was prevented from activating, the acrosomal matrix remained compact; but as activation proceeded, the matrix decondensed and dispersed in close parallel. By the time proacrosin activation was complete, the acrosomal contents had almost entirely disappeared. We conclude that proacrosin is distributed throughout the acrosomal contents as an intrinsic constituent of the acrosomal matrix. During the acrosome reaction, proacrosin activation occurs, resulting directly in decondensation of the matrix. All the contents of the acrosome including acrosin disperse and, by the time the acrosome is empty and the acrosomal cap is lost, only occasional traces of acrosin remain on the inner acrosomal membrane. Since the acrosomal cap is normally lost during the earliest stages of zona penetration, acrosin's role in fertilization is unclear: it does not appear to be a zona lysin bound to the inner acrosomal membrane.