The spermatogenesis of crustaceans: The external morphology of the spermatozoa of heterocypris incongruens,ramdohr (Ostracoda)

In various papers on the original spermatozoon of the Ostracoda, its helicoidal disposition has been indicated as the principle characteristic of this gamete, at cell structure level as well as in its external morphology. Through a combined study with scanning electron microscope (SEM) and transmission electron microscope (TEM), we have been able to establish the corresponding relationship between the cell architecture and the spermatozoon's external morphology. In the case of Heterocypris incongruens, the helicoidal relief of the gamete's external surface along the greatest part of its length, is the result of the twisting and undulating of a structure derived from the nucleus' external membrane, endoplasmic reticulum, and Golgi apparatus, called “feather-like organelle.” In keeping with the shape of this surface relief, the spermatozoon can be divided into three regions: An anterior one with a corkscrew form, a middle one showing a relief in the form of a screw with four threads, and a posterior or tail one without helicoidal relief. Finally, we discuss the different criteria existing on the possible orientation of this spermatozoon when it moves, as well as the functional advantages that the possession of a filiform, helicoidal, and mobile gamete represents.     

Scanning electron microscopy of ejaculated baboon (Papio anubis) spermatozoon.

Scanning electron microscopy has been used in order to provide the morphological study including comparative measurements of the main parts of the Baboon spermatozoon. If the dimensions of the head and the mid-piece are fairly close to the human spermatozoon, the Baboon spermatozoon is practically twice as long as the human one. In the Baboon spermatozoon, the head appears smooth with only a light ransversal furrow at the level of its posterior third, which probably marks the limit of the posterior border of the equatorial segment. The mid-piece, a conical trunk, is larger in its anterior part than at the level of its posterior extremity. The end-piece appears very short as compared with the total length of the sperm cell. The technical modalities of the preparation and the possibility of artifacts are briefly discussed.     

The flagellar apparatus of spermatozoa in fish. Ultrastructure and evolution

Chondrichthyes possess an evolved type of spermatozoa. Their flagellar apparatus is characterized by the presence of flagellar roots which form the axis of the midpiece, and the existence of one or two lateral elements associated with the axoneme. Osteichthyes, mainly teleosteans, show a great diversity of spermatic forms. The primitive spermatozoon with a 9 + 2 pattern flagellum is common. The primitive spermatozoon has evolved along different lines. The spermatic diversity which results from this is mainly evident in the structure of the flagellar apparatus. In the animal kingdom the primitive spermatozoon with a 9 + 2 pattern flagellum, present in primitive metazoa, is retained in phyla where external fertilization is maintained. The main evolutionary tendencies--elongation, aflagellarity or biflagellarity--are generally connected with the acquisition of internal fertilization. These evolutionary tendencies are found in teleosteans. It is not possible to link aflagellarity or biflagellarity of the gamete in certain fishes to this method of fertilization. Only the elongation of the spermatozoon is connected, in certain cases, with internal fertilization, but this cannot be taken as general.     

Behavior of the spermatozoon during sperm-blastomere fusion and its significance for fertilization (Saccoglossus kowalevskii: hemichordata)

Summary Association of spermatozoa with blastomeres removed from the egg envelope was studied in order to investigate sperm membrane behavior under circumstances unlike those attending fertilization of normal envelope-enclosed eggs. Under the altered circumstances all parts of the surface of the sperm cell were afforded the opportunity of meeting blastomere plasma membrane. Nevertheless, in each case the spermatozoon first became activated, an acrosomal tubule formed, and it was this organelle alone which fused and established continuity with the blastomere plasma membrane. This behavior of the spermatozoon with respect to the denuded blastomere parallels the behavior of the sperm cell with respect to the envelope-enclosed egg at fertilization. Since the sperm cell behaves so similarly in two situations which are so different with respect to what the spermatozoon encounters, this behavior is considered to reflect the inherent nature of the spermatozoon, and analysis of this behavior in relation to a blastomere is considered to be valid also in relation to an egg during fertilization. It is concluded that membrane fusion, involving the acrosomal tubule of an activated spermatozoon, is the only means by which gametic union is established and that these are obligatory rather than fortuitous features of sperm-egg association in Saccoglossus. It is suggested that these features are probably obligatory also in other species which exhibit this pattern of sperm-egg association.This investigation was supported by Research Grant HD-00007 from the National Institutes of Health, United States Public Health Service.     

The penetration of the spermatozoon through the sea urchin egg surface at fertilization : Observations from the outside on whole eggs and from the inside on isolated surfaces

The external and cytoplasmic surfaces of the sea urchin egg at fertilization have been examined with the scanning electron microscope (SEM). The outside events were documented by glueing eggs to polylysine coated glass plates, adding sperm and fixing rapidly. To reveal the inner aspects of the surface as the sperm travels through it to reach the egg cytoplasm, the fertilized egg surface was isolated in 0.3 M KC1, 0.35 M glycine, 2 mM MgCl₂, 2 mM EGTA, pH 7.5, glued onto a polylysine-coated plate and processed for the SEM. The events of spermatozoon attachment, membrane fusion, sperm entry, rotation and detachment into the egg cytoplasm as well as the associated cortical changes are described. The egg cortex is revealed to be a uniform network of fibrous bundles.The spermatozoon initially attaches to the egg surface by the acrosomal filament. As membrane fusion occurs between the gametes, the plasma membrane of the egg engulfs the sperm, the cortical granules start to discharge and a spreading surface deformation, possibly caused by a cortical contraction, is initiated. The perpendicularly entering spermatozoon is surrounded by a cluster of elongate microvilli which appear to have 235 nm vesicles associated with their bases. The sperm is prevented by the cortex from directly entering the egg cytoplasm and lies upon the egg surface between the plasma membrane and the matrix of cortical fibers. It is subsequently rotated additionally to enter the egg cytoplasm with the posterior end first. A scar is left in the cortex where the spermatozoon penetrated. The egg cortex is shown to consist of 50–200 nm uniformly arranged fibers, and its thickness ranges from 0.2 to 0.5 μm. It is speculated that this structure may be contractile.     

扩张莫尼茨绦虫(圆叶目:裸头科)精子的扫描结构

自Gresson 1962在Nature上报道了绦虫的精子发生及结构以来,至今已报道了近70种绦虫的精子结构。法国Justine（1991,1995,1998）对寄生动物的精子结构有较深人的研究,并对寄生扁虫的精子结构及其系统学意义有相关综述,对绦虫精子的系统学特征研究中,概述了11个目、43属、56种真绦虫精子结构的相关信息,不仅从精子的结构,而且从精子的发生过程来研究其系统意义,归结出真绦虫的一些共源性状如：绦虫的成熟精子中缺乏线粒体并且存在冠状体结构;     

Sperm morphology of the Eurasian beaver, Castor fiber: an example of a species of rodent with highly derived and pleiomorphic sperm populations

The structural organization of the spermatozoon from the Eurasian beaver, Castor fiber (Family: Castoridae), was determined and compared to that of other sciuromorph rodents. The beaver spermatozoon has a head, which is variable in form but usually paddle-shaped, with a small nucleus and very large acrosome, and a tail that is relatively short compared to that of most other rodents. Transmission electron microscopy indicates that in most testicular spermatozoa the acrosome projects apically, although in a few it becomes partly flexed. During the final stages of maturation, however, the acrosome becomes highly folded so that the apical segment comes to lie alongside part of the acrosome that occurs lateral to the nucleus, with, in some cases, fusion taking place between the outer acrosomal membranes. The sperm nucleus is wedge-shaped, being broader basally and narrowing apically with an occasional large nuclear vacuole occurring. This spermatozoon structure is markedly different from that found in the other species of Geomyoidea, which is the sister group of the Castoridae. The findings thus emphasize the highly divergent nature of the beaver spermatozoon and demonstrate that, within the proposed Infraorder Castorimorpha, very large differences in sperm structure have evolved.     

The morphology of the squirrel spermatozoon: A highly complex male gamete with a massive acrosome

This study describes the morphology of the spermatozoon from the cauda epididymidis of representative members of two squirrel subfamilies, the Sciurinae and Callosciurinae, as determined by fluorescent, scanning, and transmission electron microscopy. All species examined possess a massive apical segment of the sperm acrosome. It varied markedly in the extent of its caudal flexion but was always much larger, and more complex, than that of the spermatozoon of most other rodents so far documented, although somewhat similar to that of some hystricomorph species. Because this sperm form appears to be present within at least two of the three major living clades of Rodentia, it is possible that it is the ancestral condition within this mammalian order. J. Morphol., 2011. © 2011 Wiley‐Liss, Inc.     

Substructure of a cytoskeletal complex associated with the hamster sperm acrosome

Whole mount and thin section preparations of intact and selectively disrupted hamster spermatozoa revealed an organized array of cytoplasmic filaments associated with specific regions of the acrosome. The filaments were localized along the ventral surface of the spermatozoon and extended from its tip, distally to the anterior margin of the equatorial segment. Individual filaments were 11-13 nm in diameter and they were aligned parallel to one another to form a two-dimensional sheet oriented in the long axis of the spermatozoon. The filament complex adhered preferentially to the cytoplasmic surface of the outer acrosomal membrane rather than the plasma membrane. Examination of disrupted spermatozoa revealed that the distribution of this cytoskeletal assembly correlated with the distribution of a specific acrosomal matrix component. The possible role of this complex in the acrosome reaction or in the organization of acrosomal matrix domains is discussed.     

大鳞副泥鳅精子结构研究

用光学显微镜和透射电子显微镜对大鳞副泥鳅精子的结构进行研究。结果表明,大鳞副泥鳅的精子主要分为头部、中段和尾部;头部无顶体,在光学显微镜下近圆形,在透射电子显微镜下纵切亦近圆形,主要由细胞核组成,核内染色质致密,核内有核空泡,核外可见清晰核膜,核外可见细胞质,细胞质很少且紧贴细胞核,细胞质外是质膜,质膜在细胞质外呈波浪状;头部后端有一较浅的植入窝,约占核的1/4,植入窝的长轴几乎与细胞核的长轴平行,植入窝内有中心粒复合体;精子的中片与头部无明显分割,位于头部的后方,由中心粒复合体和袖套组成,袖套两边不对称,中心粒复合体由近端中心粒和远端中心粒组成,近端中心粒与远端中心粒之间呈一钝角;精子尾部无侧鳍,可分为主段和末段,尾部主段具有典型的＂9＋2＂的轴丝结构。精子头长为（1.79±0.28）μm,中片长为（1.86±0.42）μm,尾长为（28.06±2.78）μm,全长为（31.65±2.82）μm。     

Spermiogenesis and structure of spermatozoa in the oribatid mite,Hafenrefferia gilvipes (C.L. Koch) (Acari,Oribatida)

The process of spermiogenesis and the structure of spermatozoa in the mite, Hafenrefferia gilvipes (Koch) were studied ultrastructurally. Spermiogenesis was divided into six stages. The spermatids at stage 1 have the usual structure. At stage 2 the structure of the mitochondria and their distribution in the spermatid start to change, leading to the formation of specific mitochondrial derivatives which are subsequently incorporated into the nucleus of the spermatozoon. Parallel to the transformation of mitochondria occurs a reorganization of the nuclear material. The fully formed spermatozoon has a tadpole-like shape, with the cell nucleus located in the distended part of the cell, and containing mitochondrial derivatives in its karyoplasm. Acrosome, flagellum and centrioles are absent. The participation of peripherally distributed microtubules, present in spermatids at stages 4 to 6, in the shaping of the spermatozoon has been suggested.     

黄姑鱼（ Nibea albiflora） 与大黄鱼（ Pseudosciaena crocea） 精子超微结构的观察与比较

应用扫描电镜（SEM）与透射电镜（TEM）观察了黄姑鱼和大黄鱼精子的超微结构。结果显示,黄姑鱼和大黄鱼精子无论在形态、大小还是超微结构上都十分相似。黄姑鱼和大黄鱼精子均由头部、中段和尾部（鞭毛）3部分组成。精子头部形状近似椭圆形,无顶体,细胞核呈肾形。中心粒复合体位于细胞核背侧,近、远端中心粒相互垂直,远端中心粒分化成基体并形成轴丝。中段的袖套呈筒状,4～5个圆形的线粒体围绕轴丝呈环形排列。精子尾部为单鞭毛,轴丝为典型“9＋2”结构,鞭毛表面质膜形成不规则侧鳍。     

Ultrastructural investigation of spermatogenesis in the nemerine wormProcephalothrix sp. (Palaeonemertini, Anopla)

Spermatogenesis and sperm structure of the nemertine wormProcephalothrix sp. were studied by transmission electron microscopy. It is shown that a flagellum and proacrosomal vesicles are common in spermatogonia and spermatocytes as in spermatogenesis of a number of marine invertebrates with external fertilization. Originally, the animals were collected asProcephalothrix spiralis but they were found to have a type of spermatozoon different from that ofP. spiralis as described by Turbeville & Ruppert (1985). The re-identification of the material collected in the Japan Sea has shown that the features are characteristic, ofP. spiralis (Coe, 1930). This finding suggests thatP. spiralis shows variations in different parts of the world.     

Conformational changes in the NS3 protease from hepatitis C virus strain Bk monitored by limited proteolysis and mass spectrometry.

Conformational changes occurring within the NS3 protease domain from the hepatitis C virus Bk strain (NS3(1-180)) under different physico-chemical conditions either in the absence or in the presence of its cofactor Pep4A were investigated by limited proteolysis experiments. Because the surface accessibility of the protein is affected by conformational changes, when comparative experiments were carried out on NS3(1-180) either at different glycerol concentrations or in the presence of Pep4A, differential peptide maps were obtained from which protein regions involved in the structural changes could be inferred. The surface topology of isolated NS3(1-180) in solution was essentially consistent with the crystal structure of the protein with the N-terminal segment showing a high conformational flexibility. At higher glycerol concentration, the protease assumed a more compact structure showing a decrease in the accessibility of the N-terminal segment that either was forced to interact with the protein or originate intermolecular interactions with neighboring molecules. Binding of the cofactor Pep4A caused the displacement of the N-terminal arm from the protein moiety, leading this segment to again adopt an open and flexible conformation, thus suggesting that the N-terminus of the protease contributes only marginally to the stability of the complex. The observed conformational changes might be directly correlated with the activation mechanism of the protease by either the cosolvent or the cofactor peptide because they lead to tighter packing of the substrate binding site.     

Comparative ultrastructure of the spermatozoa of three crayfish species: Austropotamobius torrentium,Pacifastacus leniusculus,and Astacus astacus (Decapoda: Astacidae)

This study reports about the spermatozoal ultrastructure of three species of astacid crayfish, i.e., the stone crayfish Austropotamobius torrentium, signal crayfish Pacifastacus leniusculus, and noble crayfish Astacus astacus. The acrosome is a cup shaped and electron‐dense structure at the anterior of the spermatozoon and comprises three layers of differing electron densities filled with parallel filaments that extend from the base to the apical zone. The acrosome was significantly longer in A. astacus than in P. leniusculus and the shortest acrosome belongs to A. torrentium. The width of the acrosome was significantly narrower in A. torrentium than in P. leniusculus and the widest acrosome belongs to A. astacus. The L:W ratio was significantly greater in A. torrentium than in P. leniusculus and the lowest ratio belongs to A. astacus. Radial arms are visible on each side of the acrosome or nucleus in sagittal view and wrap around the spermatozoon. Each radial arm comprises a parallel bundle of microtubules arranged along the long axis within a sheath. The nucleus, with decondensed material, is located in the posterior of the cell. All parts of the spermatozoon are tightly enclosed within an extracellular capsule. Despite a well‐conserved general structure and similarity of pattern among these spermatozoa, differences in the dimensions of the acrosome within the studied species may be useful to help distinguish the different crayfish species. J. Morphol., 2013. © 2013 Wiley Periodicals, Inc.     

Spermatozoon structure and motility in the anuran Lepidobatrachus laevis

Synthetic human gonadotropin releasing hormone (GnRH) injections were used for induction of spermatozoon release followed by cloacal lavage or mechanical stimulation of sperm release in Lepidobatrachus laevis . Light microscopic observations of Lepidobatrachus laevis spermatozoa indicated an acrosomal segment with a length of 4.1 μm delineated by an indentation, a nuclear region of 12.6 μm in length and a midpiece of 0.87 μm in length. The tail was 54.9 μm long by 1.35 μm wide with two lateral axial fibers and a central undulating membrane. At the electron microscopic level, the unusual tail had two complete axonemes that emanated from the distal centriole. The tail also contained two axial fibers 77 nm in diameter medial to the axonemes and was connected by an undulating membrane. An unusual accessory cell adherent to the head of the spermatozoon was noted in freshly obtained suspensions of spermatozoa. Spermatozoa with the accessory cell were motile and a subsequent loss of motility was correlated with the shedding of the accessory cell.     

Semicystic spermatogenesis and biflagellate spermatozoon ultrastructure in the Nile electric catfish Malapterurus electricus (Teleostei: Siluriformes: Malapteruridae)

Spermatogenesis and spermatozoon ultrastructure in the Nile electric catfish Malapterurus electricus are described using scanning and transmission electron microscopy. Although the testis organization conforms to the ‘unrestricted’ spermatogonial type, the species has a rare type of spermatogenesis not previously described among catfishes, ‘semicystic’, in which the cyst ruptures before the spermatozoon stage. Spermiogenesis also involves some peculiar features such as condensation of the chromatin in the posterior part of the nucleus to form a compact electron‐dense mass with some irregular electron‐lucent lacunae, while the uppermost part of the nucleus is a loose electron‐lucent area, absence of the nuclear rotation and, as a consequence, the centriolar complex and the initial segment of each flagellum arise directly in a position perpendicular to the basal pole of the nucleus, and occurrence of numerous vesicles in the midpiece. In addition, spermiogenesis includes migration of the diplosome and mitochondria to the basal pole of the nucleus, formation of two moderate nuclear fossae, each of which contains the centriolar complex, development of two independent flagella and elimination of the excess cytoplasm. The mature spermatozoon has a more or less round head with no acrosome or acrosomal vesicle, a long midpiece with numerous mitochondria and vesicles and two long tails or flagella having the classical axoneme structure of 9 + 2 microtubular doublet pattern and with no lateral fins and membranous compartment. These findings suggest that the ultrastructural features of spermiogenesis and spermatozoa of M. electricus are synapomorphies of types I and II spermiogenesis and spermiogenesis is closely similar to the type described in the Nile catfish Chrysichthys auratus.     

Immunocytochemical localization of phospholipase A2 in hamster spermatozoa.

Antibodies raised against porcine pancreatic phospholipase A2 (PLA2) react in immunoblottings with both the antigen as well as with one protein band of about 14 kDa from hamster spermatozoa extracts. Immunoblottings of proteins extracted from spermatozoon head and tail fractions also show similar results. Anti-PLA2 purified IgGs were employed for light and electron microscopic immunocytochemistry in order to detect PLA2 in hamster cauda epididymal spermatozoa. When whole mount spread spermatozoa were used under light (employing the PAP complex) or electron microscopy (using anti-rabbit gold conjugated), the acrosomal area of the gametes shows a noticeable labelling; a characteristic which is not observed in samples treated with the pre-immune serum. Immunocytochemistry undertaken in ultrathin sections from spermatozoon samples embedded in Lowicryl, demonstrates that the antigen appears preferentially distributed in the acrosome. Besides, sperm tails showed a scattered distribution of gold granules in the mitochondria of the midpiece. Results suggest that the antibody used recognizes a PLA2 which is preferentially located in the acrosome and mitochondria. On the other hand, the presence of a surface PLA2 in the plasma membrane covering the acrosome is suggested. This surface PLA2 would be probably related to the acrosome reaction phenomenon that occurs in the spermatozoon before penetrating the oocyte.     

An Ultrastructural Study of the Spermatozoa from Prionospio cf. queenslandica and Tripolydora sp.: Two Spionid Polychaetes with Different Reproductive Methods

The fine structure of the spermatozoa of two spionids is described. The spermatozoon of Prionospio cf. queenslandica is typical of an animal utilizing external fertilization, in having a subspheroidal nucleus, a midpiece composed of unmodified rounded mitochondria surrounding two centrioles and a free flagellum. The acrosome is unusual in showing bilateral symmetry. The spermatozoon of Tripolydora sp. resembles that of spionids utilizing spermatophores, in possessing an extremely elongate nucleus and midpiece. The nucleus is penetrated by the 9+2 axoneme for its entire length, linking with a single centriole at the anterior end. Platelets surround the nucleus and intermingle with the mitochondria of the midpiece, which terminates with an annulus. The acrosome shows some internal vesiculation and substructuring. Sperm structure in relation to reproductive methods is discussed and the view of external fertilization as primitive is questioned.     

Subcellular distribution of calcium during spermatogenesis of zebrafish,Danio rerio

Calcium plays a variety of vital regulatory functions in many physiological and biochemical events in the cell. The aim of this study was to describe the ultrastructural distribution of calcium during different developmental stages of spermatogenesis in a model organism, the zebrafish (Danio rerio ), using a combined oxalate–pyroantimonate technique. Samples were treated by potassium oxalate and potassium pyroantimonate during two fixation stages and examined using transmission electron microscopy to detect electron dense intracellular calcium. The subcellular distribution of intracellular calcium was characterized in spermatogonium, spermatocyte, spermatid, and spermatozoon stages. The area which is covered by intracellular calcium in different stages was quantified and compared using software. Isolated calcium deposits were mainly detectable in the cytoplasm and the nucleus of the spermatogonium and spermatocyte. In the spermatid, calcium was partially localized in the cytoplasm as isolated deposits. However, most calcium was transformed from isolated deposits into an unbound pool (free calcium) within the nucleus of the spermatid and the spermatozoon. Interestingly, in the spermatozoon, calcium was mainly localized in a form of an unbound pool which was detectable as an electron‐dense mass within the nucleus. Also, sporadic calcium deposits were scattered in the midpiece and flagellum. The proportional area which was covered by intracellular calcium increased significantly from early to late stages of spermatogenesis. The extent of the area which was covered by intracellular calcium in the spermatozoon was the highest compared to earlier stages. Calcium deposits were also observed in the somatic cells (Sertoli, myoid, Leydig) of zebrafish testis. The notable changes in the distribution of intracellular calcium of germ cells during different developmental stages of zebrafish spermatogenesis suggest its different homeostasis and physiological functions during the process of male gamete development.