Localization of a proteasomal antigen in human spermatozoa: immunohistochemical electron microscopic study

The ultrastructural localization of a proteasomal antigen in human spermatozoa was studied by means of immunolabeling with the MPC21 monoclonal antibody and secondary gold labeled antibody with 1.4 nm gold particles in combination with silver enhancement reaction using pre-embedding technique. The labeling was found in the acrosomal and postacrosomal regions, in the connecting-piece (neck) and, in some cases, in the middle-piece and also in the residual bodies. There was no significant reaction in condensed chromatin. In some abnormal forms of spermatozoa, in which the chromatin was not well condensed, the labeling in nuclei was present. The nuclear vacuoles with looser chromatin were usually strongly labeled. The nuclei of cells representing different stages of spermatogenesis, that were present in semen samples, were also labeled.     

Immunolocalization of a 25-kilodalton protein in mouse testis and epididymis.

We have recently observed that a polyclonal antibody raised against a mouse epididymal luminal fluid protein (MEP 9) recognizes a 25-kDa antigen in mouse testis and epididymis [Rankin et al., Biol Reprod 1992; 46:747-766]. This antigen was localized by light and electron microscopic immunohistochemistry. The immunoreactivity in the testis was found in the residual cytoplasm of the elongated spermatids, in the residual bodies, and in the cytoplasmic droplets of spermatozoa. In the epididymis, the epithelial principal cells were stained from the distal caput to the distal cauda. Immunogold labeling in the principal cells showed diffuse distribution without preferential accumulation in either the endocytic or the secretory apparatus of the cells. In the epididymal lumen, the immunoreactivity was restricted to the sperm cytoplasmic droplets. No membrane-specific labeling was observed in luminal spermatozoa, cytoplasmic droplets, or isolated sperm plasma membranes. Three weeks after hemicastration or severance of the efferent ducts, a normal distribution of the immunoreactive sites was found in the epididymis. Immunoreactivity, was also detected in the epididymal epithelium of immature mice as well as in that of XXSxr male mice having no spermatozoa in the epididymis. These results suggest that the immunoreactivity seen in the principal cells originates from synthesis rather than endocytosis of the testicular protein from disrupted cytoplasmic droplets. Furthermore, these results suggest that the 25-kDa protein is synthesized independently by both testis and epididymis.     

Spermiogenesis in the bullfrog (Rana catesbeiana): a study of cytoplasmic events including cell volume changes and cytoplasmic elimination

The process by which spermatid cytoplasmic volume is reduced and cytoplasm eliminated during spermiogenesis was investigated in the bullfrog Rana catesbeiana. At early phases of spermiogenesis, newly formed, rounded spermatids were found within spermatocysts. As acrosomal development, nuclear elongation, and chromatin condensation occurred, spermatid nuclei became eccentric within the cell. A cytoplasmic lobe formed from the caudal spermatid head and flagellum and extended toward the seminiferous tubule lumen. The cytoplasmic lobe underwent progressive condensation whereby most of its cytoplasm became extremely electron dense and contrasted sharply with numerous electron-translucent vesicles contained therein. At the completion of spermiogenesis, many spermatids with their highly condensed cytoplasm still attached were released from their Sertoli cell into the lumen of the seminiferous tubule. There was no evidence of the phagocytosis of residual bodies by Sertoli cells. Because spermatozoa are normally retained in the testis in winter and are not released until the following breeding season, sperm were induced to traverse the duct system with a single injection of hCG. Some spermatids remained attached to their cytoplasm during the sojourn through the testicular and kidney ducts; however, by the time the sperm reached the Wolffian duct, separation had occurred. The discarded cytoplasmic lobe (residual body) appeared to be degraded with the epithelium of the Wolffian duct. It was determined that the volume of the spermatid was reduced by 87% during spermiogenesis through a nuclear volume decrease of 76% and cytoplasmic volume decrease of 95.3%.     

Spermatogenesis and spermiogenesis in Didymocystis wedli Ariola, 1902 (Didymozoidae, Digenea).

The ultrastructure of the male reproductive system of Didymocystis wedli was studied for the first time, demonstrating spermiogenesis and spermatogenesis at different cell stages. The spermatozoa morphology was compared with that of other Digenea species. It was observed that the different cells of the spermatogenesis process follow the classic pattern reported for the majority of the parasitic platyhelminthes. During spermiogenesis, rootlet fibers, electrondense bodies and median cytoplasmic process were not observed. The mature spermatozoa of D. wedli were filiform, presenting nucleus, mitochondrion and two 9+1 axonemes, with a biflagellate distal extremity.     

The development of regionalized lipid diffusibility in the germ cell plasma membrane during spermatogenesis in the mouse

The lipids and proteins of sperm cells are highly regionalized in their lateral distribution. Fluorescence recovery after photobleaching studies of sperm membrane component lateral diffusibility have shown that the sperm plasma membrane is also highly regionalized in the extents and rates of diffusion of its surface components. These studies have also shown that regionalized changes in lateral diffusibility occur during the differentiative processes of epididymal maturation and capacitation. Unlike mammalian somatic cells, sperm cells exhibit large nondiffusing lipid fractions. In this paper, we will show that both regionalized lipid diffusibility and nondiffusing lipid fractions develop with the morphogenesis of cell shape during spermatogenesis in the mouse. Pachytene spermatocytes and round spermatids show diffusion rates and the nearly complete recoveries (80-90%) typical of mammalian somatic cells. In contrast, stage 10-11 condensing spermatids, testicular spermatozoa, cauda epididymal spermatozoa, as well as the anucleate structures associated with these later stages of spermatogenesis (residual bodies and the cytoplasmic droplets of condensing spermatids and testicular spermatozoa), exhibit large nondiffusing fractions. Both the diffusion rates and diffusing fractions observed on the anterior and posterior regions of the head of stage 10-11 condensing spermatids are the same as the values obtained for these regions on testicular spermatozoa. Possible mechanisms of lipid immobilization and possible physiological implications of this nondiffusing lipid are discussed.     

Evidence of aromatase localization in cytoplasmic droplet of human immature ejaculated spermatozoa

Lytochrome P450 aromatase is a microsomal enzyme catalyzing the conversion of androgens to estrogens. P450arom expression has been demonstrated in testicular and epididymal sperm cells of several species but very limited data have been reported about maturating human germ cells. In this study, human spermatozoa with cytoplasmic droplet anomaly have been utilized to investigate aromatase immunolocalization in the immature germ cells of human ejaculate. Immunodetection has utilized a polyclonal antiserum as primary antibody, a biotinylated IgG as secondary antibody and then the avidin-biotin-peroxidase complex amplification followed by the diaminobenzidine staining. A strong immunoreaction was observed in the cytoplasmic droplets retained around the midpiece of immature spermatozoa and also in the descending droplets of late maturing sperm, while the other cellular components were unstained. Therefore, this investigation has demonstrated, for the first time, aromatase immunolocalization in residual cytoplasm of human ejaculated sperm, suggesting cytoplasmic droplets as possible estrogen biosynthesis sites during human sperm differentiation.     

Immunoelectron microscopic distribution of actin in hamster spermatids and epididymal, capacitated and acrosome-reacted spermatozoa.

The distribution of actin in hamster sperm cells was studied during spermiogenesis, epididymal transit, in vitro capacitation and acrosome reaction by immunogold procedures using a polyclonal and two monoclonal antiactin antibodies. A predominant actin labeling (F-actin) was detected in the subacrosomal space of spermatids. Actin labeling was also observed under the plasma membrane of intercellular bridges and along the outer acrosomal membrane. In late spermatids there was both F-actin depolymerization and a loss of actin immunolabeling, thus suggesting a dispersion of G-actin monomers. No obvious labeling was evidenced in residual bodies. This pattern was observed with the three antiactin probes. In contrast, an actin labeling reappeared over the fibrous sheath of the flagellum in epididymal spermatozoa but only when the polyclonal antibody was used. Only one single actin reactive band was detected by immunoblotting of sperm extracts. Since the sperm tails were NBD phallacidin negative they were considered to contain either G-actin or actin oligomers rather than bundles of actin filaments. It is suggested that G-actin originating in the head of late spermatids was redistributed to the flagellum of epidymal spermatozoa. No further changes were noted after capacitation and acrosome reaction thus indicating no apparent effect on actin polymerization and distribution.     

Identification of TMCO2 as an acrosome‐associated protein during rat spermiogenesis

We isolated the transmembrane and coiled‐coil domains 2 (Tmco2) gene using a polymerase chain reaction‐based subtraction technique. Tmco2 is predominantly expressed in rat testes starting from 4 weeks of age. Rat TMCO2 consists of 187 amino acids with a predicted molecular mass of 20.6 kDa. When expressed in COS7 cells, TMCO2 was found as vesicle‐like structures in the cytoplasm, whereas TMCO2ΔTM lacking the transmembrane (TM) region was found diffused in the cytoplasm. These results suggest that the TM region in TMCO2 is essential for its specificity of localization. Immunocytochemical analyzes indicated that rat TMCO2 was localized as small semiluminate bodies or cap‐like structures in the vicinity of round spermatid nuclei and as curved lines associated with nuclei of elongated spermatids and caput epididymal spermatozoa. However, it was detected in only a small part of cauda epididymal spermatozoa. Double immunolabeling of the spermatids and spermatozoa with the anti‐TMCO2 antibody and the monoclonal anti‐MN7 antibody showed that TMCO2 was predominantly associated with the inner acrosomal membrane in spermatids and caput epididymal spermatozoa. Our findings suggest that TMCO2 might be involved in the process of acrosome biogenesis, especially binding of acrosome to a nucleus, during spermiogenesis.     

Regulated expression and ultrastructural localization of galectin-1, a proapoptotic beta-galactoside-binding lectin,during spermatogenesis in rat testis

Galectin-1, a highly conserved beta-galactoside-binding protein, induces apoptosis of activated T cells and suppresses the development of autoimmunity and chronic inflammation. To gain insight regarding the potential role of galectin-1 as a novel mechanism of immune privilege, we investigated expression and ultrastructural localization of galectin-1 in rat testis. Galectin-1 expression was assessed by Western blot analysis and immunocytochemical localization in testes obtained from rats aged from 9 to 60 days. Expression of this carbohydrate-binding protein was developmentally regulated, and its immunolabeling exhibited a stage-specific pattern throughout the spermatogenic process. Immunogold staining using the anti-galectin-1 antibody revealed the typical Sertoli cell profile in the seminiferous epithelium, mainly at stages X-II. During spermiation (stages VI-VIII), a strong labeling was observed at the luminal pole of seminiferous epithelium, localized on apical stalks of Sertoli cells, on heads of mature spermatids, and on bodies of residual cytoplasm. Moreover, spermatozoa released into the lumen showed a strong immunostaining. Following spermiation (stage VIII), galectin-1 expression was restored at the basal portion of Sertoli cells and progressively spread out through the whole cells as differentiation of germinal cells proceeded. Immunoelectron microscopy confirmed distribution of galectin-1 in nuclei and cytoplasmic projections of Sertoli cells and on heads and tails of late spermatids and residual bodies. Surface localization of galectin-1 was evidenced in spermatozoa from caput epididymis. Thus, the regulated expression of galectin-1 during the spermatogenic cycle suggests a novel role for this immunosuppressive lectin in reproductive biology.     

Spermiogenesis and sperm ultrastructure in Cichla intermedia with some considerations about Labroidei spermatozoa (Teleostei, Perciformes, Cichlidae)

Spermiogenesis and spermatozoal structure were studied in Cichla intermedia, a primitive species of Neotropical Cichlids. The analysis shows that spermiogenesis is characterized by chromatin compaction, flagellum development, nuclear rotation, nuclear fossa formation and residual cytoplasm elimination. In the spermatozoa, the head is round, the nucleus contains highly condensed filamentous clusters of chromatin and an acrosome is absent. The nuclear fossa is slightly eccentric and shows a projection that penetrates into the nuclear outline. The proximal centriole is located in the initial segment of the nuclear fossa. The midpiece and the cytoplasmic channel are long. The mitochondria, about 10 in number, are round or slightly elongated, disposed in two layers around the initial segment of the flagellum. The flagellum has a classical 9+2 axoneme and two lateral fins. The data available show that no characteristics of spermiogenesis or spermatozoa are exclusively found in members of the suborder Labroidei. However, three characteristics seem to be exclusively observed in Cichlidae: (1) compact filamentous clusters of chromatin; (2) slightly eccentric nuclear fossa; and, (3) number of mitochondria.     

Selective partitioning of plasma membrane antigens during mouse spermatogenesis

The selective partitioning of cell membrane components during mouse spermatogenesis has been examined using a heterologous antibody raised against isolated type B spermatogonia. The anti-type B spermatogonia rabbit IgG (ATBS) binds to isolated populations of mouse primitive type A spermatogonia, type A spermatogonia, type B spermatogonia, preleptotene spermatocytes, leptotene/zygotene spermatocytes, pachytene spermatocytes, round spermatids, residual bodies, and mature spermatozoa. Although immunofluorescent labeling is uniformly distributed on the cell surface of early spermatogenic cells, a discrete topographical localization of IgG is observed on testicular, epididymal, and vas deferens spermatozoa. The convex surface of the acrosome, postacrosomal region, and tail are labeled. Antibody does not bind to a broad area corresponding to the concave region of the acrosome. The antibody also binds to mouse somatic cells including Sertoli cells, Leydig cells, thymocytes, and splenocytes, but not to mature spermatozoa of the vole, rat, hamster, guinea pig, rabbit, or human. ATBS, after absorption with mouse splenocytes or thymocytes, does not react with any somatic cells examined by fluorescence except with Sertoli cells. In addition, all reactivity with testicular, epididymal, and was deferens spermatozoa is abolished. However, spermatogenic cells at earlier stages of differentiation, including residual bodies, still react strongly with the absorbed antibody. The number of surface receptor sites per cell for absorbed ATBS ranges from approximately 3 million on primitive type A spermatogonia to 1 million on round spermatids and on residual bodies. Spermatozoa, however, have only 0.003 million binding sites for absorbed ATBS, in contrast to 10 million sites for the unabsorbed antibody. It appears that receptor sites for absorbed ATBS are not masked by components of epididymal secretions. These data imply, therefore, that specific mechanisms operate at the level of the cell membrane during spermiogenesis to insure that some surface components, not required in the mature spermatozoon, are removed selectively by partitioning to that portion of the spermatid membrane destined for the residual body.     

A study of intercellular bridges during spermatogenesis in the rat

A morphological evaluation of intercellular bridges was undertaken during rat spermatogenesis. The dimensions and relationships of the bridges were shown to vary during different phases of spermatogenesis. Cellular divisions of spermatogonia and spermatocytes resulted in the partitioning of pre-existing bridges by complex structures termed bridge partitioning complexes, which are described in detail, as is the process whereby new bridges are formed. The structure of premeiotic bridges was generally consistent; however, during spermiogenesis, the structure of bridges and bridge contents were modified at specific phases of their development. The plasma membrane density associated with the cytoplasmic aspect of early step 1 spermatids separated into multiple dense bands that encircled the peripheral aspect of late step 1 spermatid bridges. By step 2 of spermiogenesis, these dense bands became associated with several cisternae of endoplasmic reticulum, which later coalesced into a single saccule that completely encircled the bridge structure by step 4. At steps 10-13 of spermiogenesis, the single saccule of endoplasmic reticulum vesiculated into many smaller cisternae. Also, filament-bounded densities (measuring 10-12 nm in diameter) appeared within the bridge channel. At step 17 of spermiogenesis, the filament-bounded densities were no longer apparent, but an anastomosing network of endoplasmic reticulum, often in the configuration of a sphere, occupied the entire central region of the bridge. In step 19 spermatids, the smooth endoplasmic reticulum within the bridge channel and the multiple cisternae lining the bridge density were gradually displaced. The subsurface density of bridges gradually lost its prominence. Some cytoplasmic lobes were connected by extremely narrow (approximately 22 nm) cytoplasmic channels. Similar-appearing channels were seen on the surface zone of cytoplasmic lobes or residual bodies, this observation suggesting that channels were sites of severence of bridges. Just prior to the separation or disengagement of the spermatid from the cytoplasmic lobe, selected bridges appeared to open to form large masses. After spermiation, residual bodies were not found joined by bridges; but from the size of some of the residual bodies, it was suspected that they were formed by coalescence of more than one cytoplasmic lobe. Freeze-fracture demonstrated few intramembranous particles on either the P or E face of the plasma membrane forming the bridge; this finding suggested bridge structures restricted free lateral movement of membrane constituents across the bridge.(ABSTRACT TRUNCATED AT 400 WORDS)     

Paired arrangement of nonhomologous centromeres during vertebrate spermiogenesis

Indirect immunofluorescence staining with human anti-kinetochore antibodies was used to study the position of centromeres during vertebrate spermiogenesis. Many species of Amphibia have a low chromosome number and very large spermatids and spermatozoa. The number of kinetochore dots correlates exactly with the haploid chromosome number. This implies that kinetochore duplication occurs in the interval between meiosis I and meiosis II. The nonhomologous centromeres are arranged in tandem during the entire course of spermiogenesis and in mature spermatozoa. A higher order centromere arrangement was found in spermiogenic cells of Anura and Urodela. In mammals, immunofluorescence analysis is complicated by the extreme condensation of chromatin during spermiogenesis and the high chromosome numbers. Nevertheless, centromere-centromere associations were observed in mammalian round spermatids and sporadically in testicular spermatozoa. This indicates that pair-wise association of centromeres is a universal principle of centromere arrangement at the postmeiotic stage.     

Immunohistochemical localization of a water channel, aquaporin 7 (AQP7), in the rat testis

Cell volume reduction is one of the most distinct morphological changes during spermiogenesis and may be largely attributable to water efflux from the cell. A strong candidate for a water efflux route, aquaporin 7 (AQP7), which is a water channel, was studied immunohistochemically in the rat testis. Immunoreactivity was restricted within the elongated spermatids, testicular spermatozoa, and residual bodies remaining in the seminiferous epithelium. Weak but distinct immunoreactivity was first observed in the cytoplasmic mass of the spermatid at step 8 of spermiogenesis. The Golgi-like apparatus became steadily immunoreactive at step 10. The plasma membrane covering the cytoplasmic mass showed strong immunoreactivity after step 16. At this step, the middle piece of the tail also showed immunoreactivity at the portion protruding into the lumen. The whole head and distal tail, where the elongated spermatid had only a limited amount of cytoplasm, showed no immunoreactivity throughout spermiogenesis. After spermiation, the immunoreactivity of AQP7 remained at the middle piece and in the cytoplasmic droplet in the testicular spermatozoon. The present observations suggest that AQP7 contributes to the volume reduction of spermatids, since this water channel protein is localized on the plasma membrane covering the condensing cytoplasmic mass of the elongated spermatid, and since the seminiferous tubule fluid is hypertonic.     

Proteins of demembraned mouse sperm heads. Characterization of a major sperm-unique component

A 15-kilodalton protein has been identified as a major component of the residual protein fraction of mouse epididymal/vas spermatozoal heads, demembraned by treatment with Triton X-100 and sequentially extracted with 1 M NaCl/2-mercaptoethanol/DNase I. Two-dimensional electrophoresis of that protein before and after treatment with alkaline phosphatase indicated that it is present in epididymal/vas spermatozoa as a series of five differentially phosphorylated molecules with pI 6.0-7.0. Cyto-immunofluorescence with an affinity-purified antibody to the 15-kDa protein localized that protein to a circumscribed region of the demembraned mouse sperm head mediad from the dorsal margin. By radioimmunoassay, the 15-kDa protein was shown to be sperm-unique and species-specific. The antibody was nonreactive with homogenates of meiotic spermatogenic cells and round spermatids (stages 1-11) but was reactive with a non-phosphorylated 15.5-kDa protein of elongating spermatids (stages 12-16) and testicular spermatozoa. Following alkaline phosphatase treatment, the spermatozoal 15-kDa protein migrated to the position of the spermatidal 15.5-kDa protein on a sodium dodecyl sulfate gel. Thus, we conclude that the 15-kDa protein of mouse spermatozoa is synthesized during the elongation phase of spermiogenesis (stages 12-16) and is phosphorylated in the terminal period of that phase and/or after excursion of spermatozoa from the seminiferous tubules.     

A light and electron microscopical study of spermatogenesis in Hydra cauliculata

Morphological changes in the interstitial cells were studied during their differentiation into spermatozoa. Development of the spermatogonium involves an increase in nuclear and nucleolar size, and the formation of a dense mass of cytoplasmic ribosomes. The mature spermatozoon has a relatively simple structure. The head consists of a bullet shaped, homogeneous nucleus, which lacks an acrosome but bears distal membrane specializations. The middle piece is composed of four large spherical mitochondria at the base of nucleus. A single flagellum projects from one of the two centrioles lodged between the mitochondria. The flagellum appears early during development in the primary spermatocyte. During spermiogenesis microtubules associated with the basal body flagellum complex appear to define the axis of chromatin condensation.     

La gouttelette cytoplasmique résiduelle du spermatozoïde

The cytoplasmic droplet of spermatozoa is a small outpouching of cytoplasm observed in man and many mammalian species. This cytoplasmic persistance on spermatozoa is of unknown significance. It is associated with infertility and is due to a spermiation or epididymal maturation abnormality. Several etiological mechanisms have been suggested. Seminal fructose and testosterone concentrations have been correlated with the presence of cytoplasmic droples. Creatine kinase, glucose 6-phosphate dehydrogenase enzymes in the droplet and products of lipid peroxidation could be used as biochemical markers of this cytological abnormality. There is a significant increase in cytoplasmic droplets in HIV seropositive and in khat addicted subjects. Deleterious effects on fertility could be due to membrane modifications of the spermatozoa and/or reactive oxygen species generation via enzymatic activities in the residual cytoplasm.     

Role of epithelial clear cells of the rat epididymis in the disposal of the contents of cytoplasmic droplets detached from spermatozoa

Upon release from the seminiferous epithelium, spermatoza show a small droplet of cytoplasm attached to the neck region. During transit of spermatozoa in the caput epididymidis, this cytoplasmic droplet migrates along the middle piece of the flagellum. In the corpus epididymidis, the droplet shows a lateral displacement, while in the cauda epididymidis it detaches from the spermatozoon. In the electron microscope, cytoplasmic droplets attached to spermatozoa were seen to contain numerous, short, straight or C-shaped, flattened membranous elements referred to as lamellae, small vesicles, and small particles (35-nm diameter) with a diffuse wall showing no apparent unit membrane. The lamellae were stacked closely on one another or arranged in a loose array. Structurally as well as cytochemically, with different cytochemical markers, the lamellae and vesicular elements failed to show any evidence of being components of the Golgi apparatus or elements of the endoplasmic reticulum. The lamellae, vesicular elements, and 35-nm particles were also seen free in the lumen of the corpus epididymidis but were especially prominent in the cauda epididymidis at a time when droplets were being released from spermatozoa. The lumen of the epididymis, as spermatozoa passed from the caput to the cauda epididymidis, was also noted to acquire progressively a flocculent background material. The epididymal epithelium is composed predominantly of principal and clear cells. The endocytic activity of clear cells was examined in rats at different time intervals after a single injection of cationic ferritin into the lumen of the cauda epididymidis. At 2 min the tracer was bound to the microvilli of these cells and was also observed within large coated and uncoated pits, subsurface coated vesicles, and numerous subsurface small uncoated vesicular membranous elements (150-200-nm diameter). At 5 min, in addition to the above structures, the tracer was present in endosomes, while at 15 and 30 min, pale and dense multivesicular bodies appeared labeled, respectively. At 1 and 2 hr, but more so at 6 hr large dense membrane-bound bodies identified cytochemically as secondary lysosomes became labeled. All of the above endocytic structures were also seen to contain the 35-nm particles, flattened or vesicular membranous profiles, and a fine flocculent background material reminiscent of those seen free in the lumen or found in cytoplasmic droplets attached to spermatozoa. (ABSTRACT TRUNCATED AT 400 WORDS)     

优雅蝈螽精子形成过程中核的形态结构变化观察（英文）

【目的】螽斯精子结构复杂,具有特征性的箭头状顶体,是研究昆虫精子形成的理想材料。为了研究螽斯精子形成过程中的动态变化机制,特别是细胞核的凝集机制和箭头状顶体的发生机制,本研究对优雅蝈螽Gampsocleis gratiosa精细胞和精子的细胞核进行了观察。【方法】选择发育良好的优雅蝈螽成虫精巢为研究材料,利用透射电镜技术、普通光学显微镜和荧光显微镜技术,制作光镜切片和电镜切片进行观察。【结果】根据其形态结构变化特征,将优雅蝈螽精子形成过程中的细胞核分为4个阶段：圆形核、叶形核、柱状核和成熟阶段。我们还通过常规HE染色,结合DNA特异性荧光探针DAPI,证明了圆形核时期,精细胞内具有两个明显的球状结构,一个为细胞核,另一个是原顶体;精子成熟阶段,精子尾部排出的细胞质微滴中含有DNA。【结论】优雅蝈螽精子形成过程中,精细胞的细胞核经历了显著的形态变化,精细胞核的形态变化与细胞骨架微管相关,细胞核塑形伴随着染色质的重组。本研究为进一步阐明直翅目昆虫精子形成的分子机制奠定了基础。