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.     

Ultrastuctural and cytochemical study of spermatogenesis in Scrobicularia plana (Mollusca,Bivalvia)

The ultrastructure of the mature spermatozoa and spermatogenesis of the bivalve Scrobicularia plana are described. Support cells extend from the basal lamina to the lumen of the testis and are laterally connected to the germinal epithelium. Germ cells present intercellular bridges and flagella since the spermatogonial stage. While spermatogonia and spermatocytes appear connected to support cells by desmosome-like junctions, elongated spermatids are held at the acrosomal region by support cell finger-like processes. During spermiogenesis, the acrosomal vesicle differentiates from a golgian saccule and then migrates to the nuclear apex. A microtubular manchette arising from centrioles surrounds the acrosomal vesicle, the nucleus, and the mitochondria at the time these three organelles start their elongation, disappearing after that. The mature spermatozoon of S. plana lacks a distinct midpiece because the mitochondria extend from the region of the pericentriolar complex along the nucleus anteriorly for approximately 1.4 μm. The features of this bivalve type of modified spermatozoon are compared with those of other animal groups having similar modifications.     

Comparative studies of testicular structure and sperm morphology among copulatory and non-copulatory sculpins (Cottidae: Scorpaeniformes: Teleostei)

Testicular structure of 9 species and sperm head morphology of 19 species of Cottidae were observed in order to clarify relationships between morphological characteristics of the male reproductive organ and reproductive mode (copulation or non-copulation). Morphological structure of the testis was divided into the following five types based on the sperm transfer and reservoir system: (1) a non-duct type in which the sperm duct is not a distinct exterior structure, but the tube for sperm transport traverses along the testis as an interior structure; (2) an anterior duct type with distinct anterior sperm ducts traversing along the testis; (3) a posterior duct type with distinct anterior sperm ducts traversing along the dorsal hilus of testis and posterior sperm ducts extending to the rear of the testis; (4) an anterior duct posterior vesicle type with distinct anterior sperm ducts traversing along the testis, and the right and left sperm ducts fusing in the rear of testis, forming the seminal vesicle; (5) a non-duct posterior vesicle type in which sperm ducts do not accompany the testis, and the testis and seminal vesicle are connected directly or through posterior sperm ducts. It is thought that in Cottidae the non-duct type of reproductive organ is primitive, and the anterior duct type is common to all non-copulating species. The testes and accompanying seminal vesicle were seen only in copulating species. Sperm head morphology was divided into three types according to the length/width ratio: oval type ≤2, intermediate type >2 and ≤3, and slender type >3. The type of sperm head corresponded closely to the reproductive mode; non-copulating species had oval sperm head, and copulating species had intermediate or slender ones. These results suggest that the structure of the testis and the morphology of the sperm head evolved from testes with anterior sperm ducts and oval sperm heads to testes with an associated seminal vesicle and slender sperm heads in association with the evolution from non-copulatory to copulatory reproduction in Cottidae.     

A fine structural study of the testicular wall and spermatogenesis in the crinoid,Florometra serratissima (Echinodermata)

The testicular wall and the process of spermatogenesis in the crinoid, Florometra serratissima, has been studied at the fine structural level. The testicular wall is composed of three layers: a perivisceral layer consisting of nerve processes, muscle fibers, and epithelial cells; a haemal sinus containing haemal fluid, collagen-like fibers, and haemocytes; and a germinal layer consisting of germinal and interstitial cells. The germinal layer is elaborated into numerous folds that project into the lumen of the testis and a branch of the haemal channel extends through the core of each fold. Evidence suggesting that nutrients are carried to the testis and germinal cells via the haemal system is presented. Spermatogonia are concentrated around the base of each fold and spermatocytes line the more distal regions. Spermatids occur at the luminal surface of the germinal layer and spermatozoa fill the testicular lumen. Interstitial cells phagocytize spermatozoa and may also transfer nutrients to spermatids. The nucleus of spermatogonia is large and contains one or two nucleoli. The cytoplasm contains numerous organelles, lipid granules, and a distal and proximal centriole, each with a satellite complex. A striated rootlet extends from the distal centriole. During first meiotic prophase, the distal centriole loses its striated rootlet and produces a flagellum, the proximal centriole loses its satellite complex, the nucleolus disappears, and proacrosomal vesicles are synthesized by the Golgi complex. During spermiogenesis, most of the mitochondria appear to fuse to form a single, large mitochondrion, the nuclear chromatin condenses, and superfluous cytoplasm is lost by autophagocytosis. The formation and definitive positioning of the acrosomal vesicle and periacrosomal material at the apex of the nucleus is described in detail.     

An Electronmicroscopic Study of the Microgamete of Haemoproteus columbae Kruse*

SYNOPSIS. Microgametes of Haemoproteus columbae were studied by light microscopy and electron microscopy, using the single-stage replication technic. The filiform microgamete has a swelling or vesicle near the round end; the opposite end is asymmetrically tapered. The gamete is polarized, for it travels in sinuous movements with the round end (the putative anterior end) directed forward. There is no flagellum or undulating membrane and no mitochondrion. The vesicle may contain energy reserves for locomotion or lytic enzymes for penetration. Tubular material often is seen coming from the vesicle and anterior end and may be a kind of acrosomal filament.     

Ultrastructure of spermatogenesis in the sea star,Asterina minor

The ultrastructural features of spermatogenesis were investigated in the hermaphroditic sea star Asterina minor. The primordial germ cells in the genital rachis contain small clusters of electron-dense material (nuage material) and a stack of annulate lamellae. They also have a flagellum and basal body complex situated close to the Golgi complex. After the development of the genital rachis into the ovotestis, spermatogenic cells increase in number and differentiation begins. Nuage material is observed in spermatogonia, but it gradually disappears in spermatocytes. The annulate lamellae do not exist beyond the early spermatogonial stage. By contrast, a flagellum and basal body complex are found throughout spermatogenesis. The Golgi-derived proacrosomal vesicles appear in the spermatocyte and coalesce to form an acrosomal vesicle in the early spermatid. The process of acrosome formation is as follows: (1) a lamella of endoplasmic reticulum (ER) continuous with the outer nuclear membrane encloses the posterior portion of the acrosomal vesicle; (2) the vesicle attaches to the cell membrane with its anterior portion; (3) periacrosomal material accumulates in the space between the acrosomal vesicle and the ER; (4) the nucleus proper changes its features to surround the acrosome; (5) amorphous, electron-dense material is deposited under the electron-dense disk; and (6) the nucleus forms a hollow opposite the electron-dense material.     

SPERMIOGENESIS IN THE PULMONATE SNAIL, EUHADRA HICKONIS 1. ACROSOME FORMATION

Electron microscopical observations of the course of acrosomal differentiation in Euhadra hickonis show that the vesicular component of the mature acrosome is produced by early Golgi activity, whereas an equivalent amount of material that forms a basal component is added later to the outside of the vesicle. It is also suggested that similar material which concurrently accumulates against part of the outer surface of the nuclear envelope is finally incorporated into the basal part of the acrosome.
In the early spermatid, which has a highly polymorphic nucleus, material derived from the well-developed Golgi complex accumulates within a network of tubules in its central maturing zone to form a single acrosomal vesicle ca. 150 nm in diameter. The next stage is characterized by the strikingly spherical shape of the nucleus, as well as by the addition of electron-dense material to the outside of the nuclear envelope over the future anterior surface, and to its inside in the posterior region where the centriolar fossa will form.
At mid-spermiogenesis the Golgi complex moves posteriorly away from the acrosomal vesicle, which remains in the anterior cytoplasm. A growing mass of densely filamentous material forms a hollowed hemisphere around one side of the vesicle. This complex approaches the coated anterior part of the nuclear envelope, turning if necessary so that the filamentous material is in the lead, and the latter merges with the electron-dense material at the center of the coated area. As the late spermatid nucleus elongates, this material passes through a series of changes in arrangement and electron density, finally forming a homogeneously particulate element of medium density that surrounds the proximal half of the acrosomal vesicle and caps the slender tip of the nucleus in the mature spermatozoon.     

Ultrastructure of spermatozoa correlated with phylogenetic relationship between Heteropneustes fossilis and Rana tigrina

A study using transmission electron microscopy (TEM) of the spermatozoa of Rana tigrina and Heteropneustes fossilis in all phases of the annual reproductive cycle revealed that there was a phylogenetic relationship between them. The spermatozoa of H. fossilis appeared horseshoe-shaped, somewhat oval or wedge-shaped at the anterior end and broader at the posterior end. The horseshoe-shaped spermatozoan nucleus was observed during spermiogenesis of R. tigrina but later changed into a finger shape at maturity. The posterior end of the nuclei of mature spermatozoa of R. tigrina was blunt. The extremely dense homogenized nucleus was capped with an acrosomal vesicle in both species suggesting a definite phylogenetic inter-relationship between them.     

Structure of the testis and genital duct of freshwater stingray, Himantura signifer (Elasmobranchii: Myliobatiformes: Dasyatidae)

The light microscopic structure of the testis and genital duct system of the freshwater stingray Himantura signifer was observed. The testis is composed of lobes having numerous spermatocysts in a dorsoventral zonated arrangement. The germinal papilla at the middorsal surface of the testicular lobe is the origin site of spermatocyst development, where mesenchymal-like cells are predominantly found. The association of a Sertoli cell precursor with a spermatogonium marks the onset of spermatocyst formation and development. The newly formed spermatocysts at the dorsal end of the germinal zone replace the older ones, which are sequentially moved to the ventral side and are termed spermatogonial, spermatocyte, spermatid, spermatozoal, and degenerate zones. In the degenerate zone, the spermatocysts deteriorate after releasing the spermatozoa into the intratesticular duct, where they are further transported through the extratesticular duct system and finally stored at the seminal vesicle. The epithelial lining of the genital duct is a pseudostratified ciliated columnar with no muscular layer underneath; thus, sperm are conveyed through ciliary activity. The interesting features of the present study are the finding of mesenchymal-like cells in the germinal papilla and the nonaggregated formation of sperm in the seminal vesicle.     

Spermatogenesis in the blue swimming crab, Portunus pelagicus, and evidence for histones in mature sperm nuclei

Spermatogenesis in the blue swimming crab, Portunus pelagicus, is described by light and electron microscopy. The testis is composed of anterior (AT) and posterior (PT) lobes, that are partitioned into lobules by connective tissue trabecula, and further divided into zones (germinal, transformation and evacuation), each with various stages of cellular differentiation. The vas deferens is classified into three distinct regions: anterior (AVD), median (MVD), and posterior (PVD), on the presence of spermatophores and two secretions, termed substance I and II. Based on the degree and patterns of heterochromatin, spermatogenesis is classified into 13 stages: two spermatogonia (SgA and SgB), six primary spermatocytes (leptotene, zygotene, pachytene, diplotene, diakinesis, and metaphase), a secondary spermatocyte (SSc), three spermatids (St 1-3), and a mature spermatozoon. Spermatid stages are differentiated by chromatin decondensation and the formation of an acrosomal complex, which is unique to brachyurans. Mature spermatozoa are aflagellated, and have a nuclear projection and a spherical acrosome. AUT-PAGE and Western blots show that, during chromatin decondensation, there is a reduction of most histones, with only small amounts of H2B and H3 remaining in mature spermatozoa.     

Ultrastructural investigations of testes and spermiogenesis in two species of halacarid mites (Halacaridae, Actinedida, Actinotrichida): Thalassarachna basteri from the Baltic Sea and Halacarellus thomasi from McMurdo Sound (Antarctica)

Testes and sperm cells of two species of halacarid mites, Thalassarachna basteri from the Baltic Sea and Halacarellus thomasi from McMurdo Sound (Antarctica), were investigated. Testes are paired structures, composed of a glandular and a germinal part. The testicular lumen is filled with a very complex secretion that contributes to sperm cell aggregates. Early spermatids of T. basteri display unusual chromatin condensation within the nucleus, but the formation of an acrosomal complex with a small acrosomal vesicle and a long acrosomal filament can be regarded as typical for the group. Tubular invaginations of the plasmalemma occur at the cell periphery. A deep, ring-like infold divides the cell into one part containing the chromatin body and another containing mainly the invaginations and the acrosomal complex. The mature sperm cell is ovoid, aflagellate and surrounded by a distinct secretion sheath. In H. thomasi only a limited number of spermiogenesis stages were observable. Chromatin condensation was rather similar and peripheral invaginations also occurred. However, no acrosomal complex was observed in the early stages. The division of the mature sperm cells into two halves was even more pronounced in H. thomasi, since one half of the cell contained masses of convoluted structures. The same half also contained a structure that remotely resembled an acrosomal complex. The observed differences between T. basteri and H. thomasi sperms support the placing of the two halacarids in separate genera.     

Ultrastructural evidence for Sertoli-like cells in the testis of the asteroid,Luidia clathrata (Say) (Echinodermata: Platyasterida)

Non-germinal cells arise adjacent to the basal lamina and extend between the numerous germinal celli. Nuclei of these non-germinal cells may be positioned near the basal lamina or more peripherally between the spermatocytes. Thin cytoplasmic processes extend between the spermatocytes to the spermatids. These cytoplasmic processes vary in electron density from the cytoplasm of the germinal cells. These non-germinal cells closely resemble the vertebrate Sertoli cell.     

Spermatogenesis in a trichuroid nematode,Trichuris muris—I. Fine structure of spermatogonia

Spermatogonial structure in the hologonic testis of T. muris was investigated by light and electron microscopy. Chromosomal configurations indicating a diploid complement of 6 were visible at the light microscope level. A high nucleus-to-cytoplasm ratio, polysomes, few Golgi complexes and mitochondria were the main ultrastructural features of the spermatogonial cells. Numerous intercellular bridges, linking up to 4 cells in a single section, were resolved. Desmosomal attachment points were present between conjoined cells and processes of non-germinal sustentacular cells were in close association. This arrangement is discussed in relation to germinal and non-germinal cells in other invertebrate and vertebrate organisms.     

Transmission and scanning electron microscopy of the male reproductive system of Schistosoma margrebowiei Le Roux, 1933

The structure of the male reproductive system of Schistosoma margrebowiei as viewed by light, scanning and transmission electron microscopy is described. The cirrus tube opens at the genital pore without the presence of a cirrus and is spongy and leaf-like. The structure of the germinal and non-germinal cells of the testes are described. The spermatozoon consists of a head, without an acrosome, and a flagellum with a 9 + 0 arrangement of microtubules in the axial filament. A large mass of mitochondria is situated in the anterior end of the head and cortically arranged longitudinally running microtubules are present. The apical region of the epithelial cells of the vas deferens extends into the lumen of the duct forming convoluted lamellae. This arrangement, together with the presence of dense bodies within the cells, suggests that these cells have a secretory function.     

The ultrastructure of the spermatozoa of Epipedobates flavopictus (Amphibia,Anura, Dendrobatidae), with comments on its evolutionary significance

We describe, for the first time, the spermatozoon ultrastructure of a dendrobatid frog, Epipedobates flavopictus. Mature spermatozoa of E. flavopictus are filiform, with a moderately curved head and a proportionally short tail. The acrosomal vesicle is a conical structure that covers the nucleus for a considerable distance. A homogeneous subacrosomal cone lies between the acrosome vesicle and the nucleus. The nucleus contains a nuclear space at its anterior end, and electron-lucent spaces and inclusions. No perforatorium is present. In the midpiece, the proximal centriole is housed inside a deep nuclear fossa. Mitochondria are scattered around the posterior end of the nucleus and inside the undulating membrane in the anterior portion of the tail. In transverse section the tail is formed by an U-shaped axial fiber connected to the axoneme through an axial sheath, which supports the undulating membrane. The juxta-axonemal fiber is absent. The spermatozoon of E. flavopictus has several characteristics not observed before in any anurans, such as a curved axial fiber, absence of a juxta-axonemal fiber, and presence of mitochondria in the typical undulating membrane. Our results endorse the view that, in anurans, the conical perforatorium and subacrosomal cone are homologous and that Dendrobatidae should be grouped within Bufonoidea rather than Ranoidea.     

The polymerization of actin: II. how nonfilamentous actin becomes nonrandomly distributed in sperm: evidence for the association of this actin with membranes

At an early stage in spermiogenesis the acrosomal vacuole and other organelles including ribosomes are located at the basal end of the cell. From here actin must be transported to its future location at the anterior end of the cell. At no stage, in the accumulation of actin in the periacrosomal region is the actin sequested in a membrane-bounded compartment such as a vacuole or vesicle. Since filaments are not present in the periacrsomoal region during the accumulation of the actin even though the fixation of these cells is sufficiently good to distinguish actin filaments in thin section, the actin must accumulate in the nonfilamentous state.     

ELECTRON MICROSCOPE STUDIES ON SPERM DIFFERENTIATION IN MARINE ANNELID WORMS. II. SPERM FORMATION IN ARENICOLA BRASILIENSIS

The course of spermiogenesis in arenicola brasiliensis was observed with the electron microscope. The spermatogonia floating in the body cavity seem to proliferate and differentiate to mature spermatozoa in the coelomic fluid. More than a hundred spermatids are connected to one large central mass of cytoplasm and spermiogenesis proceeds synchronously in one cluster, which changes into a sperm-disc during maturation. The pre-acrosomal vesicle originates from the Golgi-body and gradually changes into the acrosomal vesicle of peculiar structure like a cup upside down. In the process of differentiation of the acrosome, a part of the material in the acrosomal vesicle is transferred into the space between the vesicle and the nucleus. The posterior one-third of the cylindrical nucleus is surrounded by four middle-piece mitochondria. The flagellar axoneme originates from one of the centrioles, which is located near a posterior pit in the nucleus.     

Fine structure of Lasaea subviridis and Mysella tumida sperm (Bivalvia,Galeommatacea)

Summary Lasaea subviridis and Mysella tumida sperm resemble the primitive spermatozoan type, but exhibit several unique morphological features. L. subviridis sperm heads vary in shape and size owing to differing degrees of nuclear condensation. A fully mature, heterogenous acrosomal vesicle with an associated axial rod is present. Up to 50% of L. subviridis sperm in developing gonads have conspicuously angled flagella that propel the sperm cells in irregular helical paths. This may represent a penultimate stage in sperm development because the remainder of the sperm cells have posteriorly-directed flagella and swim in a nonhelical anterior direction. A trend toward a reduction in both nuclear condensation and swimming ability may be a long-term consequence of increasing degrees of localized, but non-internal self-fertilization in marine invertebrates that brood. Mysella tumida sperm are monomorphic and possess numerous microvilli (30–60 nm in diameter and up to 5.7 m in length) that resemble stereocilia and radiate from the cell membrane surrounding the basal body. In this species, the sperm cell does not have an axial rod, and the complex acrosomal vesicle contains five distinct zones of varying electron opacity. One of these zones is a transverse, electron-opaque band that is apparently composed of rolled-up membrane. Following acrosomal breakdown, this membrane unfolds to cover the anterior tip of the sperm cell. Although both L. subviridis and M. tumida are hermaphroditic, the relative size of their male investments is conspicuously different. Approximately 40–50% of the M. tumida gonadal volume is testis compared with about 5% of that in L. subviridis.     

Steganoderma szidati n. sp. (Trematoda: Zoogonidae) from Galaxias maculatus (Jenyns) and G. platei Steindachner in Patagonia,Argentina

Steganoderma szidati n. sp. is described from the intestine of two freshwater fishes, Galaxias maculatus and G. platei (Galaxiidae), from Andean lakes in Patagonia, Argentina. This freshwater zoogonid species fits in the genus Steganoderma (sensu Bray, 1987) because of the length of the caeca and the position of the vitelline follicles. The new species is characterised by possesing 6-13 vitelline follicles situated between the anterior margin of the ventral sucker and the poterior margin of the testis. The gonads are in the anterior hindbody and the ovary is anterior to the right testis. The cirrus has two conspicuous spines at its distal end, and the seminal vesicle always exhibits a constriction. The excretory vesicle never reaches the level of the posterior margin of the testes.