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.     

Ultrastructure of spermiogenesis and spermatozoa in Marchalina hellenica (Gennadius) (Hemiptera: Sternorrhyncha,Marchalinidae)

The spermiogenesis, the sperm structure and the sperm motility of Marchalina hellenica (Gennadius) were examined. In the early spermiogenesis a centriolar apparatus was identified, but this structure is not involved in the production of the sperm flagellum. As in other Coccoidea, the flagellar axoneme originates by the activity of the thickened tip of the numerous microtubules surrounding the nuclear anterior region close to the periphery of the cell. This region pushes against a narrow cytoplasmic layer, giving rise to a papilla. In this region a novel structure, consisting of a regular network of thin filaments, arranged orthogonally to the bundle of microtubules, is visible. The sperm flagellum consists of a series of about 260 microtubules, regularly arranged in rings around the axial nucleus. This latter extends in the middle part of the sperm length. As usual in scale insects, sperm form a bundle, which in M. hellenica is composed of 64 sperm cells, surrounded by somatic cyst cells. The sperm bundle has an helicoidal array, with a cap of dense material at its apex, lending the anterior and the posterior region of the sperm bundle with a different structural organization. This difference is responsible of the different speed gradient observed in the helical wave propagating along the sperm bundle.     

日本沼虾精子发生的研究

对日本沼虾精子发生全过程的电镜观察表明：精原细胞核染色质分散,胞质内有线粒休、内质网的分布。初级精母细胞核染色质块状,不均匀地分布于核中,内质同多小泡多。次级精母细胞核染色质大多分布于核膜内侧,内质网聚集成团,精细胞分化形成精子的早期,胞核增大,核侧形成内质同多小泡的聚合体;中期的核内染色质浓缩,同时形成空囊状结构,     

Genesis of spermatodesms in Tylopsis liliifolia (Orthoptera: Phaneropterinae) and their transit in the male genital tract

The spermatodesms of Tylopsis liliifolia form in the most proximal follicular cysts and are composed of a large number of sperm held together by a cap located in the anterior region of the acrosome. The cap is formed by short thin fibrils, loosely arranged at random, probably derived from secretory activity of cells of the cyst wall. Compared to other Tettigoniidae, a peculiar feature is acrosomal wings that twist gradually around the anterior region of the nucleus; at the end of the twisting process, the region of the sperm acrosome, observed in cross section, shows a typical spiral form. Spermatodesms do not undergo any substantial changes in the spermiduct. The epithelial cells of the wall have secretory activity and many show marked spermiophagic activity, which is conducted by epithelial cell protrusions that envelop the gametes, taking them into the cytoplasm. When removed from seminal vesicles and observed in vivo, spermatodesms show accentuated corkscrew movement, and when observed by SEM, slight torsion. Thus organized, spermatodesms are transferred to the spermatophore during mating, where they are transformed before reaching the seminal receptacle.     

A transmission electron microscopy investigation: the membrane complex in spermatogenesis of <Emphasis Type="Italic">Fenneropenaeus chinensis</Emphasis>

The transforming characteristics of the membrane complex in spermatogenesis of Fenneropenaeus chinensis have been studied by using transmission electron microscopy. Two types of membrane complex have been investigated based on their sources: one originating from nucleus and the other from cytoplasm. The first one, consisted of annular structures, monolayer membrane blebs, and double or multi-lamellar membrane vesicles, emerges in the primary spermatocyte, then diffuses with the nuclear membrane and finally enters the cytoplasm. This type of membrane complex seems to play an important role in the materials transfusion from nucleus to cytoplasm, and it mainly exists inside the primary spermatocyte with some inside the secondary spermatocyte. The latter, originated from cytoplasm, is formed during the anaphase of spermiogenesis. It also exists in mature sperm, locating at both sides of the nucleus under the acrosomal cap. This type of membrane complex mainly comprises rings of convoluted membrane pouches, together with mitochondria, annular lamina bodies, fragments of endoplasmic reticulum, nuclear membrane and some nuclear particles. It releases vesicles and particles into the acrosomal area during the formation of the perforatorium, suggesting a combined function of the endoplasmic reticulum, mitochondria and Golgi’s mechanism.     

日本沼虾雄性生殖系统的研究：Ⅱ.精子的形态及超微结构

运用电镜和细胞化学技术研究了日本沼虾精子的形态结构,结果表明：日本沼虾精子属无鞭毛精子,为单一棘突型,呈图钉样,由主体和棘突构成;主体部分为帽状体,精核和细胞质带。帽状体由约２０根辐射状纤丝组成,纤丝上具横纹,并汇合帽状基部,由此向后延伸形成棘突。     

An ultrastructural analysis of mature sperm from the crayfish Pacifastacus leniusculus,Dana

Sperm from the crayfish, Pacifastacus leniusculus, resemble other reptantian sperm in that they are composed of an acrosome, subacrosomal region, nucleus, membrane lamellar complex, and spikes which radiate from the nuclear compartment. The acrosome (PAS positive vesicle) can be subdivided into three regions: the apical cap, crystalline inner acrosomal material, and outer acrosomal material which is homogeneous except for a peripheral electron dense band. The nucleus contains uncondensed chromatin and bundles of microtubules which project into the spikes. The orientation of the microtubule bundles relative to the nuclear envelope near the base of the subacrosomal region suggests that the nuclear envelope may function in the organization of the spike microtubules.     

Spermatophores of the salamander Ambystoma texanum

Living spermatozoa were observed in freshly deposited spermatophores and in fluid from vasa deferentia. In the distal, but not proximal, vas deferens spermatozoa moved together in whorls with heads and tails in alignment. Around the entire periphery of the spermatophore cap, similar slowly undulating groups of spermatozoa had their heads aligned and directed outward. Over time, some individual spermatozoa left the cap of the spermatophore and moved into the surrounding water (cap deterioration). Microscopical observations were made on spermatophore squashes and paraffin sections of spermatophores and vasa deferentia. Spermatozoa around the periphery of the cap were underlain by a PAS-positive membrane-like material. Cytoplasmic droplets, which were attached to spermatozoan necks in the vas deferens, were accumulated in the center of the spermatophore cap deep to the PAS-positive membrane. Spermatophore stalks were strongly PAS and Alcian blue positive and showed positive reaction for RNA. Tests for lipids and proteins were negative in the whole spermatophore. Electron microscopic observations showed the stalk of the spermatophore to be composed of rounded ‘balls’ of fibrous material. At the juncture of the stalk and cap a less dense fibrous material impacted the stalk enclosing many sperm tails and some heads and, although no attachment devices were visualized, the sperm were closely apposed to this material as was the spermatophore stalk. This finely filamentous material encircled the cap and was more prominent in some regions than others. The PAS-positive material detected with the light microscope was also observed with the electron microscope. It was circumferentially oriented and was composed of 200 Å packed filamentous densities. Sperm heads and tails were found lying external to the membrane, whereas only tails and cytoplasmic droplets occupied the core of the spermatophore. Cytoplasmic droplets were usually free of the sperm tail and contained membranous sacs and two types of nuage material.     

Cytochemical studies on the localization and functional properties of calcium in anterior pituitary cells

The localization of calcium and its functional properties in anterior pituitary cells were studied using a potassium pyroantimonate technique. In all kinds of secretory cells, the precipitates of the calcium-pyroantimonate complex were distributed on the limiting membrane of the secretory granule. They were present also in the cytoplasmic matrix, the mitochondrial matrix, small smooth vesicles, coated vesicles, and in the nuclear euchromatin area. The precipitates were usually seen at the contact region between the limiting membranes of two adjacent secretory granules, or between the granule limiting membrane and the plasma membrane. When the tissues were incubated in the medium containing A23187 (10 microM) for 5 min, the deposits on the granule limiting membrane were increased in number and those on the mitochondrial matrix were decreased; the reaction products almost disappeared on the limiting membranes of the secretory granules after membrane fusion following single or multigranular exocytosis induced by A23187-treatment. In addition, small vesicles in the capillary endothelium contained reaction precipitates. Based on these results we propose a hypothetical model for the relationship between the localization of calcium and secretory activity.     

ZYGOTE FORMATION IN ASCARIS LUMBRICOIDES (NEMATODA)

Ultrastructural observations of the in utero sperm of Ascaris lumbricoides reveal that it consists of a relatively clear, ameboid anterior region and a conical posterior region containing numerous surface membrane specializations, dense mitochondria, a lipid-like refringent body of variable size, and a dense nucleus which lacks an apparent nuclear envelope. No acrosomal complex was observed. Pseudopods emanating from the anterior cytoplasm make first contact with the primary oocytes and appear to be responsible for the localized removal of the extraneous coat covering the oolemma. Subsequently the gamete membranes interdigitate and finally fuse. Because this pseudopodial action appears similar to that reported for the acrosomal filaments in flagellated sperm, the anterior region of the Ascaris sperm is thought to serve an acrosomal function. Following gamete-membrane fusion, the sperm nucleus acquires a particulate appearance and becomes disorganized. Once inside the oocyte, the sperm cytoplasm consists of dense mitochondria, ribosomes, and vesicles derived from the surface membrane specializations. The refringent body, whose contents possibly contribute to the synthesis of ribosomes, is usually absent by the time the sperm cytoplasm attains a central position in the egg.     

日本沼虾精子的形态和超微结构研究

应用电子显微镜技术结合细胞化学方法对日本沼虾精子进行子形态和超微结构研究。结果显示,日本沼虾精子琪似外翻的伞状,无鞭毛,不运动的精子主要由前端棘突,中间帽状体和后主体部分组成,精子的核属非浓缩型,内布许多絮状物质,外无核膜包被,呈Ｆｅｕｌｇｅｎ阳性反应,位于后主体部内;中间帽状体的细胞质内含有一对中心粒和１５－２０根放射状排列的纤丝,纤丝在帽状体凸面中央汇聚并延伸成精子的棘突,棘突和放射状纤丝皆具     

Comparative histochemical observations on the contributions of the acrosomal vesicle and granule to the acrosomal cap in the spermatozoa of mammals

Summary By applying the periodic acid-Schiff technique to frozen sections of material fixed in weak Bouin's solution and extracted with hot pyridine, the contributions of the acrosomal vesicle and granule to the acrosomal cap have been observed in the maturing spermatozoa of the American opossum, guinea pig, rabbit, marmoset and chimpanzee. In the spermatids of the opossum, the acrosomal granule is not developed and the thin, homogeneous carbohydrate layer of the acrosomal cap is derived from the concentrated material of the acrosomal vacuole. In the guinea pig, both the acrosomal vesicle and granule make the greatest contributions to the carbohydrates of the acrosomal cap; these continue to maintain their identity in the head of mature sperm. In the rabbit, marmoset and chimpanzee, the carbohydrate material of acrosomal vesicle origin is less developed and constitutes a thin layer in the lateral portions of the acrosomal cap; the carbohydrate material in its anterior portions is mainly derived from the acrosomal granule which becomes flattened; there is also a slight thickening of the intermediate layer of the acrosomal cap in this region. The distinction between the carbohydrate contributions from the acrosomal vesicle and granule disappears in the fully formed acrosomal cap which shows a homogeneously PAS-positive intermediate layer. In the chimpanzee, the acrosomal vesicle makes a relatively very small contribution to the carbohydrate layer of the acrosomal cap which is mainly formed by spreading of material from the acrosomal granule.     

Fine structure of an elongated dorso-ventrally compressed echinoderm (holothuroidea) spermatozoon

The spermatozoon of Cucumaria pseudocurata is unique among those of the echinoderms in that it is tabloid in shape, i.e., elongated and dorsoventrally compressed. The sperm consists of a dorsal surface which contains an extensive striated rootlet-like structure located within a dorsal groove and a ventral surface which contains a medially situated acrosome. A single mitochondrion lies at the base of the nucleus. The flagellum is unusual in that a 9 + 3 tubular arrangement is observed in the mid-tail region. The acrosome consists of an acrosomal granule bounded by a limiting membrane and a surrounding periacrosomal layer. The granule is irregular in shape with the anterior-posterior surfaces flaring out, forming pockets in the periacrosomal material. The ventral granule surface bulges forming a close association with the plasma membrane. The dorsal surface is indented. Ventral to the depression (within the granule) is a small area containing a particulate-fibrous material. To the inside of the granule limiting membrane there is a second membrane-like structure (incomplete) which extends from the anterior-posterior surfaces around the dorsal face of the granule. Dorso-medial to the granule the periacrosomal layer contains a particulate-fibrous region lodged within the granule depression. This material is presumably the precursor of the acrosomal filament. Prominent cytoplasmic folds extend off from the basal flagellar region. The proximal and distal centrioles are situated perpendicular to one another within the mitochondrion. Centriolar satellite materials are associated with both centrioles. Toward the base of the tail the satellite of the distal centriole consists of nine radiating arms extending at an angle of 45° to the axis of the centriole. Each arm terminates in a dense thickening. The striated rootlet extends anteriorly from the distal centriole to just below the level of the acrosome.     

Structure of hematopoietic nodules in the ridgeback prawn,Sicyonia ingentis: Light and electron microscopic observations

The architecture and fine structure of the epigastric hematopoietic nodules of the ridgeback prawn, Sicyonia ingentis, are described. The nodules consist of a highly branched series of tubules that contain the maturing hemocytes within a connective tissue stroma. Hemocytes can exit the hematopoietic nodules by penetrating through fenestrations in the endothelial cell layer into the central hemal space or by migrating through the outer later of capsular cells and associated collagen fibrils. Four hemocyte categories were observed: agranular, small granule with cytoplasmic deposits, small granule without cytoplasmic deposits, and large granule hemocytes. This classification was based upon the presence, size, and type of cytoplasmic granules and the presence of cytoplasmic deposits. Only agranular cells and small granule hemocytes without cytoplasmic deposits appeared capable of division. Intermediate stages were observed between agranular hemocytes and small granule hemocytes with deposits and between small granule hemocytes without deposits and large granule hemocytes, suggesting existence of two distinct hemocyte lines.     

OOCYTE DIFFERENTIATION IN THE SEA URCHIN, ARBACIA PUNCTULATA, WITH PARTICULAR REFERENCE TO THE ORIGIN OF CORTICAL GRANULES AND THEIR PARTICIPATION IN THE CORTICAL REACTION

This paper presents morphological evidence on the origin of cortical granules in the oocytes of Arbacia punctulata and other echinoderms. During oocyte differentiation, those Golgi complexes associated with the production of cortical granules are composed of numerous saccules with companion vesicles. Each element of the Golgi complex contains a rather dense homogeneous substance. The vesicular component of the Golgi complex is thought to be derived from the saccular member by a pinching-off process. The pinched-off vesicles are viewed as containers of the precursor(s) of the cortical granules. In time, they coalesce and form a mature cortical granule whose content is bounded by a unit membrane. Thus, it is asserted that the Golgi complex is involved in both the synthesis and concentration of precursors utilized in the construction of the cortical granule. Immediately after the egg is activated by the sperm the primary envelope becomes detached from the oolemma, thereby forming what we have called the activation calyx (see Discussion). Subsequent to the elaboration of the activation calyx, the contents of cortical granules are released (cortical reaction) into the perivitelline space. The discharge of the constituents of a cortical granule is accomplished by the union of its encompassing unit membrane, in several places, with the oolemma.     

长毛对虾精子发生的研究：Ⅰ.精子的形态结构

利用电子显微镜技术结合细胞化学染色方法,研究长毛对虾精子形态结构,结果显示:长毛对虾精子由圆球状球体部和钉子状棘突部组成;精子全长约7μm;棘突及与之相联的球体表面平滑无突起,而与棘突相对的球体底面有指状突起。透射和冷冻蚀刻电镜显示:长毛对虾精子棘突包括顶体锥和顶体帽两部分;顶体锥向外突出形成精子的棘突,顶体帽覆盖在球体部的胞质及核区上方。成熟精子胞质极度退化,仅靠顶体帽边缘可见1—2个线粒体。球体的中央区域为近球形,呈Feul-gen阳性反应,为精子的核区。其结构松散,电子密度低,属非浓缩型,内布许多絮状物质,外由许多长短不一的膜性结构不规则排列成不连续的核膜结构。研究结果认为:长毛对虾精子属不动无鞭毛精子类型,其棘突部并非鞭毛结构而是顶体的位置。     

Spermatozoa ultrastructure of the pink shrimp Farfantepenaeus paulensis (Decapoda: Dendrobranchiata)

Braga, A.L., Nakayama, C.L., Suita de Castro, L.A. and Wasielesky, W. 2011. Spermatozoa ultrastructure of the pink shrimp Farfantepenaeus paulensis (Decapoda: Dendrobranchiata). —Acta Zoologica (Stockholm) 00 : 1–6. The spermatozoa ultrastructure of the pink shrimp Farfantepenaeus paulensis was investigated in this morphological study. Spermatophores and spermatozoa were analyzed by electron microscopy. The pink shrimp spermatophore is divided into two regions: the appendage and the spermatophore main body, where spermatozoa are grouped in a spermatic mass. Pink shrimp spermatozoa are unistellate and are composed of main body and single spike. The spermatozoa body comprises a perinuclear cytoplasmic band, nucleus, acrosomal cap, and subacrosomal region. The spermatozoa cell mean total length was 10.71 μm, the mean body diameter was 5.56 μm, and the mean spike length and diameter were 5.15 μm and 0.85 μm, respectively.     

The Elusive Acrosome of Chiton Sperm

Summary

In our study of spermiogenesis in the lined chiton Tonicella lineata, we traced the formation and migration of small Golgi vesicles to the apex of the sperm, where they fused to form an apical granule. This apical granule and other Golgi secretions tested positively for acid phosphatase. In preliminary experiments on fertilization, sperm swam inside open hull (chorion) cupules down to the surface of the egg and penetrated it. No micropyle was observed. Serial 1μm sections of eggs fixed during fertilization demonstrated that the sperm nucleus had penetrated not only the hull but also the vitelline and oocyte membranes. Serial thin sections showed that the tip of the anterior filament of the sperm had fused with a single microvillus of the oocyte membrane, creating a membranous tube through which the nucleus had entered the egg cortex. We suggest that the apical granule of chiton sperm is an acrosome that enables the nucleus to penetrate the egg membranes.     

Ultrastructure of the tubular nephron of the lizard Podarcis (= Lacerta) Taurica

The proximal, intermediate, and distal convoluted tubules of the neprhon of Podarcis (= Lacerta) taurica were examined by electron microscopy. Proximal tubule cells have large, apical cytoplasmic protrusions and microvilli interpreted to function in urate secretion. Adjacent cells are bound apically by tight junctions and desmosomes but interdigitate in their basal region. This situation is repeated in the other tubules with significant differences in intercellular space width. The basal surfaces bear numerous cytoplasmic processes. The intermediate tubule has proximal and distal segments each with dark, ciliated, and light cells, the cuboidal dark cells with dense cytoplasm constituting the main bulk of the wall. As the cells of the proximal and distal segments resemble those of the proximal and distal convoluted tubules, respectively, the intermediate tubule is considered as a transition region. The ciliated cell body has two broad processes extending from the lumen, one to the basement membrane and one to a foot process of a light cell. The light cell is surrounded by dark and ciliated cells. It does not reach the lumen, but contacts the basement membrane through a process running below a ciliated cell to form a mushroom-shaped structure in tubule cross-section, the light cell process forming the stalk and a ciliated cell the cap. The cilia probably propel the glomerular filtrate towards the distal convoluted tubule. This latter tubule has initial, middle, and terminal zones, all nonciliated but with different lumen widths and cell shapes.     

Relationship of saccular ultrastructure to otolith growth in the teleost Oreochromis niloticus

The sacculus of Oreochromis niloticus is anatomically separated from the utriculus and semicircular canals. The saccular wall is composed of the sensory epithelium, transitional epithelia, and squamous epithelium. Cellular granules are abundant in the sensory and transitional epithelia but scarce in the squamous epithelium. Over the dorsal side of the dorsal transitional epithelium there exists an oval patch of cells with distinctive microvilli. New finding is a shallow groove which extends from the anterior end of the sensory epithelium approximately halfway down along the ventral perimacular transitional epithelium. Small vesicles, which appear “empty” under transmission electron microscopy (TEM), are aggregated in the posterior region of the groove. These small vesicles are also present in both the sensory and transitional epithelia. A second kind of vesicle is comparatively large and appears filled with stainable contents. These vesicles are restricted to the sensory region. Both kinds of vesicles appear to be involved in apical secretion and possibly provide the otolithic membrane with fibers. The otolithic membrane is composed of a gelatinuous layer and subcupular meshwork. The meshwork appears to contribute to the formation of the otolith. The small empty vesicles appear to originate in sensory and transitional epithelial cells and may form the subcupular meshwork. The larger filled vesicles are derived predominantly from sensory cells in the sensory epithelium and appear to contribute to the gelatinuous layer of otoliths. © 1992 Wiley-Liss, Inc.