Identification of actin in boar spermatids and spermatozoa by immunoelectron microscopy

Actin was localized in testicular spermatids and in ionophore-treated ejaculated sperm of boar by use of a monoclonal anti-actin antibody labeled with colloidal gold. With the on-grid postembedding immunostaining of Lowicryl K4M sections, actin was identified in the subacrosomal region of differentiating spermatids, in the microfilaments of the surrounding Sertoli cells, and in the myoid cells of the tubular wall. Ejaculated sperm, labeled with the preembedding method, showed actin between the plasma membrane and the outer acrosomal membrane of the equatorial segment. Indirect immunofluorescence was positive in the equatorial segment and in the acrosomal cap of intact sperm, whereas reacted sperm at the anterior head region retained fluorescence only in the inner acrosomal membrane. Rhodamine-phalloidin failed to stain intact and reacted sperm. The distribution of actin in sperm head membranes (inner acrosomal membrane, membranes of the equatorial segment), which are retained after the acrosome reaction, is discussed.     

Spermatid translocation in the rat seminiferous epithelium: coupling membrane trafficking machinery to a junction plaque

In this study, we demonstrate that specialized junction plaques that occur between Sertoli cells and spermatids in the rat testis support microtubule translocation in vitro. During spermatogenesis, Sertoli cells are attached to spermatids by specialized adhesion junctions termed ectoplasmic specializations (ESs). These structures consist of regions of the plasma membrane adherent to the spermatid head, a submembrane layer of tightly packed actin filaments, and an attached cistern of endoplasmic reticulum. It has been proposed that motor proteins on the endoplasmic reticulum interact with adjacent microtubules to translocate the junction plaques, and hence the attached spermatids, within the epithelium. If this hypothesis is true, then isolated junctions should support microtubule transport. To verify this prediction, we have mechanically isolated rat spermatids, together with their attached ESs, and tested them for their ability to transport microtubules in vitro. Most assays were done in the presence of 2 mg/ml testicular cytosol and at room temperature. ESs attached to spermatids supported microtubule translocation. In some cases in which motility events were detected, microtubules moved smoothly over the junction site. In others, the movement was slow but progressive, saltatory and "inch-worm-like." No motility was detected in the absence of exogenous ATP or in the presence of apyrase (an enzyme that catalyses the breakdown of ATP). Our results are consistent with the microtubule-based motility hypothesis of spermatid translocation.     

Structural abnormalities in spermatids together with reduced sperm counts and motility underlie the reproductive defect in HIP1-/- mice

Huntingtin interacting protein 1 (HIP1) is an endocytic adaptor protein with clathrin assembly activity that binds to cytoplasmic proteins, such as F-actin, tubulin, and huntingtin (htt). To gain insight into diverse functions of HIP1, we characterized the male reproductive defect of HIP1(-/-) mice from 7 to 30 weeks of age. High levels of HIP1 protein were expressed in the testis of wild-type mice as seen by Western blots and as a reaction over Sertoli cells and elongating spermatids as visualized by immunocytochemistry. Accordingly, major structural abnormalities were evident in HIP1(-/-) mice with vacuolation of seminiferous tubules caused by an apparent loss of postmeiotic spermatids and a significant reduction in mean profile area. Remaining spermatids revealed deformations of their heads, flagella, and/or acrosomes. In some Sertoli cells, ectoplasmic specializations (ES) were absent or altered in appearance accounting for the presence of spherical germ cells in the epididymal lumen. Quantitative analyses of sperm counts from the cauda epididymidis demonstrated a significant decrease in HIP1(-/-) mice compared to wild-type littermates. In addition, computer-assisted sperm analyses indicated that velocities, amplitude of lateral head displacements (ALH), and numbers and percentages of sperm in the motile, rapid, and progressive categories were all significantly reduced in HIP1(-/-) mice, while the numbers and percentages of sperm in the static category were greatly increased. Taken together, these various abnormalities corroborate reduced fertility levels in HIP1(-/-) mice and suggest a role for HIP1 in stabilizing actin and microtubules, which are important cytoskeletal elements enabling normal spermatid and Sertoli cell morphology and function.     

Sperm head shaping in ratites: New insights,yet more questions

Head shaping in mammalian sperm is regulated by a number of factors including acrosome formation, nuclear condensation and the action of the microtubular manchette. A role has also been suggested for the attendant Sertoli cells and the perinuclear theca (PT). In comparison, relatively little information is available on this topic in birds and the presence of a PT per se has not been described in this vertebrate order. This study revealed that a similar combination of factors contributed to head shaping in the ostrich, emu and rhea, although the Sertoli cells seem to play a limited role in ratites. A fibro-granular structure analogous to the mammalian PT was identified, consisting of sub- and post-acrosomal components. The latter was characterized by stage-specific finger-like projections that appeared to emanate from the cytoplasmic face of the nuclear envelope. They were particularly obvious beneath the base of the acrosome, and closely aligned, but not connected to, the manchette microtubules. During the final stages of chromatin condensation and elongation of the sperm head the projections abruptly disappeared. They appear to play a role in stabilizing the shape of the sperm head during the caudal translocation of the spermatid cytoplasm.     

THE FINE STRUCTURE OF DIFFERENTIATING SPERMATOZOA AND SERTOLI CELLS IN THE GONAD OF THE POND SNAIL, LYMNAEA STAGNALIS

The fine structure has been examined, of spermatogonia, spermatocytes,early spermatids, late spermatids and early spermatozoa nestlingagainst Sertoli cells in the gonad of Lymnaea stagnalis. Changes in the Sertoli cells are linked with the phases of spermdifferentiation. Details on differentiation particularly ofthe head of the sperm, are presented. (Received 14 March 1981;     

The consequences of actin disruption at Sertoli ectoplasmic specialization sites facing spermatids after in vivo exposure of rat testis to cytochalasin D

Cytochalasin D (CD) was used to perturb actin filaments of the Sertoli ectoplasmic specialization (ES)--a cytoskeletal complex of the Sertoli cell related to spermatids. CD (500 microM for 6 h) produced a loss of 88% of the ES facing the head region of early (Step 8) elongating spermatids as compared to vehicle (dimethylsulfoxide:saline) controls. Nitrobenzoxadiazole-phallacidin staining of F-actin revealed a CD-related loss of uniform fluorescence over the head of elongated spermatids. To examine for a possible relationship between the presence of actin and cell attachment at ES sites, hypertonic fixatives were introduced to provoke cell shrinkage and stress ES-associated junctions. After osmotic stress, cell-to-cell adhesion at ES sites remained intact in vehicle-treated animals. CD treatment caused Sertoli cells to separate from elongating spermatids at sites where ES had been lost from the Sertoli cell surface. It is suggested that actin of the ES plays a role in cell-to-cell interaction analogous to its possible role at the Sertoli cell barrier. In CD-treated animals, structures resembling tubulobulbar complexes frequently developed at sites where ES was lost, suggesting that the loss of ES has a facilitatory role in tubulobulbar complex formation. It is hypothesized that tubulobulbar complexes are devices that rid the cells of ES-associated junctional links to effect dissociation of the spermatid from the Sertoli cell during spermiation. Spermatids at Step 8 of development are known to become oriented with their acrosomes facing the base of the Sertoli cell. After CD treatment, a 5.8-fold increase in malorientation of Step 8 spermatids was noted. A role for the ES cytoskeletal complex in orienting the spermatid acrosome toward the basal aspect of the Sertoli cell is also suggested.     

Microtubule polarity in Sertoli cells: a model for microtubule-based spermatid transport

Bundles of microtubules occur adjacent to ectoplasmic specializations (ESs) that line Sertoli cell crypts and support developing spermatids. These microtubules are oriented parallel to the direction of spermatid movement during spermatogenesis. We propose a model in which ESs function as vehicles, and microtubules as tracks, for microtubule-based transport of spermatids through the seminiferous epithelium. Microtubule polarity provides the basis for the direction of force generation by available mechanoenzymes. As part of a more general study designed to investigate the potential role of microtubule-based transport during spermatogenesis, we have studied the polarity of cytoplasmic microtubules of Sertoli cells. Rat testis blocks were incubated in a lysis/decoration buffer, with and without exogenous purified bovine brain tubulin. This treatment results in the decoration of endogenous microtubules with curved tubulin protofilament sheets (seen as hooks in cross section). The direction of curvature of the hooks indicates microtubule polarity; that is, clockwise hooks are seen when viewing microtubules from the plus to the minus end. We found that, in Sertoli cells, most of the hooks were orientated in the same direction. Significantly, when viewed from the base of the epithelium, hooks pointed in a clockwise direction. The clockwise direction of dynein arms on axonemes of sperm tails, in the same section, provided an internal check of the section orientation. Electron micrographs of fields of seminiferous epithelium were assembled into montages for quantitative analysis of microtubule polarity. Our data indicate that Sertoli cell cytoplasmic microtubules are of uniform polarity and are orientated with their minus ends toward the cell periphery. These observations have significant implications for our proposed model of microtubule-based transport of spermatids through the seminiferous epithelium.     

Immunocytochemical localization of actin and tubulin in rat testis and spermatozoa

Using commercial monoclonal antibodies against actin and tubulin (alpha and beta), the respective antigens were localized on semithin and ultrathin sections of the rat testis. Tubulin immunofluorescence was found in the socalled manchette surrounding the heads of the maturating spermatids as well as the sperm tail. The distribution pattern varied with sperm development. Modified Sertoli cells found at the transition between the seminiferous tubules and the rete testis displayed much filamentous tubulin-reactive material. The immunofluorescence findings could be confirmed at the ultrastructural level using the indirect immunogold method. Actin immunofluorescence was demonstrated in vascular smooth muscle cells, interstitial macrophages and - most intensely - in peritubular cells. Inside the seminiferous tubules the Sertoli cell junctions and the ectoplasmic specializations of the Sertoli cells that follow the outer contour of spermatid heads displayed distinct actin immunofluorescence. In addition to the locations mentioned, actin-like immunoreactivity was visualized at the ultrastructural level in the chromatoid body and the subacrosomal space of spermatids as well as on the outer dense fibers of the sperm tail. Immunoblotting experiments with actin antibodies showed that in extracts from testicular spermatozoa, intact or fragmented into heads and tails, from isolated Sertoli cells grown in vitro, and from testis tissue in addition to authentic actin a protein was present in sperm tail extracts that strongly bound the actin antibody. This protein may be an actin-related protein and may be responsible for the actin-like immunoreactivity of the outer dense fibers of the sperm tail.     

Ultrastructure of germ cells, the Leydig cells, and Sertoli cells during spermatogenesis in Boleophthalmus pectinirostris (Teleostei, Perciformes, Gobiidae)

The ultrastructures of germ cells, Leydig cells, and Sertoli cells during spermatogenesis in male Boleophthalmus pectinirostris were investigated by electron microscopic observations. During the period of maturation divisions, well-developed Leydig cells have three major morphological characteristics: a vesicular nucleus, mitochondria with tubular cristae, and a number of smooth endoplasmic reticulum. Based on cytoplasmic features, it appears that Leydig cells are responsible for the synthesis of male sex steroids. Although no clear evidence of steroidogenesis was found in the Sertoli cells, they were found to perform a phagocytic function in the seminiferous lobules. Most Sertoli cells contain granules thought to represent deposited glycogen or lipid but there is no indication of a transfer of nutrients to the spermatids. During the period of germ cell degeneration, several characteristics of phagocytosis appear in the cytoplasm of the Sertoli cells. In particular, it is assumed that the Sertoli cells are involved in the degeneration and resorption of undischarged spermatids after spermiation. No acrosome of the sperm is formed. The structure of the spermatozoon in B. pectinirostris is very similar and closely resembles to those of suborder Gobioidei (perciform type teleosts). The flagellum or sperm tail shows the typical 9+2 array of microtubules.     

Immunocytochemical localization of actin and tubulin in rat testis and spermatozoa

Summary Using commercial monoclonal antibodies against actin and tubulin ( and ), the respective antigens were localized on semithin and ultrathin sections of the rat testis. Tubulin immunofluorescence was found in the socalled manchette surrounding the heads of the maturating spermatids as well as the sperm tail. The distribution pattern varied with sperm development. Modified Sertoli cells found at the transition between the seminiferous tubules and the rete testis displayed much filamentous tubulin-reactive material. The immunofluorescence findings could be confirmed at the ultrastructural level using the indirect immunogold method. Actin immunofluorescence was demonstrated in vascular smooth muscle cells, interstitial macrophages and — most intensely — in peritubular cells. Inside the seminiferous tubules the Sertoli cell junctions and the ectoplasmic specializations of the Sertoli cells that follow the outer contour of spermatid heads displayed distinct actin immunofluorescence. In addition to the locations mentioned, actin-like immunoreactivity was visualized at the ultrastructural level in the chromatoid body and the subacrosomal space of spermatids as well as on the outer dense fibers of the sperm tail.Immunoblotting experiments with actin antibodies showed that in extracts from testicular spermatozoa, intact or fragmented into heads and tails, from isolated Sertoli cells grown in vitro, and from testis tissue in addition to authentic actin a protein was present in sperm tail extracts that strongly bound the actin antibody. This protein may be an actin-related protein and may be responsible for the actin-like immunoreactivity of the outer dense fibers of the sperm tail.     

Acroplaxome, an F-actin-keratin-containing plate, anchors the acrosome to the nucleus during shaping of the spermatid head

Nuclear shaping is a critical event during sperm development as demonstrated by the incidence of male infertility associated with abnormal sperm ad shaping. Herein, we demonstrate that mouse and rat spermatids assemble in the subacrosomal space a cytoskeletal scaffold containing F-actin and Sak57, a keratin ortholog. The cytoskeletal plate, designated acroplaxome, anchors the developing acrosome to the nuclear envelope. The acroplaxome consists of a marginal ring containing keratin 5 10-nm-thick filaments and F-actin. The ring is closely associated with the leading edge of the acrosome and to the nuclear envelope during the elongation of the spermatid head. Anchorage of the acroplaxome to the gradually shaping nucleus is not disrupted by hypotonic treatment and brief Triton X-100 extraction. By examining spermiogenesis in the azh mutant mouse, characterized by abnormal spermatid/sperm head shaping, we have determined that a deformity of the spermatid nucleus is restricted to the acroplaxome region. These findings lead to the suggestion that the acroplaxome nucleates an F-actin-keratin-containing assembly with the purpose of stabilizing and anchoring the developing acrosome during spermatid nuclear elongation. The acroplaxome may also provide a mechanical planar scaffold modulating external clutching forces generated by a stack of Sertoli cell F-actin-containing hoops encircling the elongating spermatid nucleus.     

Cytoskeletal involvement in spermiation and sperm transport

The process of spermiation and sperm transport was studied using specific inhibitors of cytoskeletal elements. Within 12-24 hr after the intratesticular injection of taxol, a compound that acts to stabilize microtubules and inhibit microtubule-related processes, an unusually large number of microtubules was seen within the body of the Sertoli cell. At the same time, transport of elements within the seminiferous epithelium was affected. At the end of stage VI of the cycle, step 19 spermatids were maintained in the deep recesses of the Sertoli cell and not transported to the rim of the seminiferous tubule lumen. At stage VIII, residual bodies remained at, or near, the rim of the tubule and were not transported to the base of the tubule. They underwent only partial degradation at this site, indicating that there may have been two phases involved in their dissolution--one autophagic and one phagocytic, but the latter did not occur since the residual bodies were not transported to Sertoli lysosomes at the base of the tubule. The observations suggest that microtubules are involved in transport processes within the seminiferous epithelium. Within 1-12 hr after the intratesticular injection of 500 microM cytochalasin D, a compound which interferes with actin-related processes, normal appearing tubulobulbar complexes were not present. The tubular portion (distal tube) of the complex did not initiate development. It was assumed that filaments (which were identified as such using NBD-phallacidin and the S-1 fragment of myosin) played an important role in the development of this portion of the complex. Cells did not eliminate cytoplasm normally, as evidenced by an enlarged cytoplasmic droplet, further emphasizing the published role for tubulobulbar complexes in cytoplasmic elimination. Although sperm were released normally from stage VIII tubules, many remained within the tubular lumen and did not traverse the duct system. Cytochalasin did not inhibit fluid secretion by the Sertoli cell, as demonstrated by efferent duct ligation, but did alter myoid cell actin cytoskeletal organization, suggesting that myoid cell contractility is primarily responsible for transport of sperm. Overall, the observations suggest that cytoskeletal activity of the Sertoli cell is important for several aspects of the spermiation process as well as sperm transport.     

Histopathology of the male reproductive system induced by the fungicide benomyl

Benomyl is an effective fungicide that has been in use for many years. This chemical and its primary metabolite, carbendazim, are microtubule poisons that are relatively nontoxic to all mammalian organs, except for the male reproductive system. Its primary effects, at moderate to low dosages, are on the testis, where it causes sloughing of germ cells in a stage-dependent manner. Sloughing is caused by the effects of the chemical on microtubules and intermediate filaments of the Sertoli cell. These effects spread to dividing germ cells and also lead to abnormal development of the head of elongating spermatids. At higher dosages, it causes occlusion of the efferent ducts, blocking passage of sperm from the rete testis to epididymis. The mechanism of occlusion appears to be related to fluid reabsorption, sperm stasis, followed by leukocyte chemotaxis, sperm granulomas, fibrosis and often the formation of abnormal microcanals. The occlusion results in a rapid swelling of the testis and ultimately seminiferous tubular atrophy and infertility. In conclusion, studies that reveal long term testicular atrophy following chronic or subchronic exposure to a toxicant should be re-examined for histopathological lesions in the efferent ductules and head of the epididymis. Lesions in the male track that cause blockage may induce permanent testicular damage and a decrease in sperm production.     

Actin-related intercellular junctions in the germinal compartment of the testis in Poecilia reticulata (Teleostei,Poeciliidae)

Summary In this paper we present evidence for the presence of actin-related junctions between neighboring Sertoli cells and between Sertoli cells and spermatids in the testis of the guppy (Poecilia reticulata). In the guppy, spermatogenesis occurs in spermatocysts that are lined by a simple squamous to cuboidal epithelium formed of Sertoli cells. At a certain stage of differentiation, elongate spermatids occur in Sertoli cell recesses in the apical surface of Sertoli cells. When evaluated by electron microscopy, junctions occur between Sertoli cells and spermatids situated in the recesses. In these regions, obvious linkages occur between the plasma membrane of Sertoli cell recesses and the adjacent spermatids. Moreover, large concentrations of microfilaments occur in the Sertoli cell cytoplasm immediately underlying the crypts. Also, junctional complexes are apparent between neighboring Sertoli cells near the apical surface of the epithelium. These complexes consist of microfilament-related components (probably contributing to both tight and adhesion junctions), which occur closest to the lumen, and intermediate-filament related desmosomes, which occur more basally. In fixed frozen sections of guppy testis, probes for filamentous actin (rhodamine phalloidin) and myosin II (polyclonal antisera raised against human platelet myosin II) react with function regions between neighboring Sertoli cells and between Sertoli cells and spermatids. We conclude that actin-related junctions occur at both these sites and that the actin networks have contractile properties because they contain myosin II.     

A study of Sertoli-spermatid tubulobulbar complexes in selected mammals

Tubulobulbar complexes (TBCs) were found in nine mammalian species (opossum, vole, guinea-pig, mouse, hamster, rabbit, dog, monkey and human) primarily originating from the plasma membrane overlying the acrosome of late spermatids. Fewer complexes (4–10) were noted in these species than has been previously reported for the rat (up to 24). TBCs were not seen emanating from round spermatids or those elongated spermatids located within the deep recesses of the Sertoli cell, but they appeared as the spermatids came to reside much closer to the tubular lumen in preparation for release. TBCs developed in areas deficient or lacking in Sertoli filaments and endoplasmic reticulum (ectoplasmic specialization). In general their structural configuration was similar to that shown in the rat, although minor differences were noted. Fine fibrils were observed connecting the distal portion of the spermatid tube with the Sertoli plasma membrane forming a bristle-coated pit. The length of TBCs from most species studied was 1–2 μm, whereas those of the opossum extended 6–8 μm into an apical Sertoli process. TBCs were degraded within the Sertoli cell by its lysosomes prior to sperm release, and for most species there was evidence indicating that formation of more than one generation of TBCs occurred. As sperm release approached, TBCs formed preferentially from the leading edge of spermatids with spatulate heads. The Sertoli cell gradually withdrew from around the spermatid head until only the tip of the head was embedded within the Sertoli cell. This region of contact frequently demonstrated TBCs. The proposed functions of TBCs are reviewed and discussed in light of these findings from other species.     

An ultrastructural study of the effect of a diabetogenic dose of alloxan on the secretory ameloblasts of the rat incisor

Sertoli cells of the ground squirrel (Spermophilus lateralis), a seasonal breeder, were examined by light and electron microscopy and their structure, particularly the organization of the cytoskeleton, was related to events that occur in the seminiferous epithelium during spermatogenesis. Among the events considered and described are the apical movement of elongate spermatids, withdrawal of residual cytoplasm from germ cells, transport of smooth endoplasmic reticulum (SER) between the base and apex of the Sertoli cells, and sperm release. These events are dramatically evident in this species because the seminiferous epithelium is thin, i.e., there are few germ cells, and both the germ cells and Sertoli cells are large. Sertoli cells of the ground squirrel have a remarkably well developed cytoskeleton. Microfilaments occur throughout the cell but are most evident in ectoplasmic specializations associated with junctions. Intermediate filaments occur around the nucleus, as a layer at the base of the cell, and adjacent to desmosome-like junctions with germ cells. Intermediate filaments, together with microtubules, are also abundant in regions of the cell involved with the transport of SER, in cytoplasm associated with elongate spermatids, and in processes that extend into the residual cytoplasm of germ cells. Our observations of ultrastructure are consistent with the hypothesis that Sertoli cell microtubules are involved with the movement of germ cells within the seminiferous epithelium, and further implicate these structures as possibly playing a role in the retraction of residual cytoplasm from germ cells and the intracellular transport of SER. The abundance and organization of intermediate filaments suggest that these cytoskeletal elements may also be involved with events that occur during spermatogenesis.     

Increased germ cell degeneration and reduced germ cell:Sertoli cell ratio in stallions with low sperm production

To determine the relationship between germ cell degeneration or germ cell:Sertoli cell ratio and daily sperm production, testes were obtained during the months of May to July (breeding season) and November to January (nonbreeding season) from adult (4 to 20-yr-old) stallions with either high (n = 15) or low (n = 15) sperm production. Serum was assayed for concentrations of LH, FSH and testosterone. Testes were assayed for testosterone content and for the number of elongated spermatids, after which parenchymal samples were prepared for histologic assessment. Using morphometric procedures, the types and numbers of spermatogonia, germ cells and Sertoli cells were determined. High sperm producing stallions had greater serum testosterone concentration, total intratesticular testosterone content, testicular parenchymal weight, seminiferous epithelial height, diameter of seminiferous tubules, numbers of A and B spermatogonia per testis, number of Sertoli cells per testis, and number of B spermatogonia, late primary spermatocytes, round spermatids and elongated spermatids per Sertoli cell than low sperm producing stallions (P < 0.05). The number of germ cells (total number of all spermatocytes and spermatids in Stage VIII tubules) accommodated by Sertoli cells was reduced in low sperm producing stallions (18.6 +/- 1.3 germ cells/Sertoli cell) compared with that of high sperm producing stallions (25.4 +/- 1.3 germ cells/Sertoli cell; P < 0.001). The conversion from (yield between) early to late primary spermatocytes and round to elongated spermatids was less efficient for the low sperm producing stallions (P < 0.05). Increased germ cell degeneration during early meiosis and spermiogenesis and reduced germ cell:Sertoli cell ratio was associated with low daily sperm production. These findings can be explained either by a compromised ability of the Sertoli cells to support germ cell division and/or maturation or the presence of defects in germ cells that predisposed them to degeneration.     

Nectin couples cell-cell adhesion and the actin scaffold at heterotypic testicular junctions

Actin-based cell-cell adherens junctions (AJs) are crucial not only for mechanical adhesion but also for cell morphogenesis and differentiation. While organization of homotypic AJs is attributed mostly to classic cadherins, the adhesive mechanism of heterotypic AJs in more complex tissues remains to be clarified. Nectin, a member of a family of immunoglobulin-like adhesion molecules at various AJs, is a possible organizer of heterotypic AJs because of its unique heterophilic trans-interaction property. Recently, nectin-2 (-/-) mice have been shown to exhibit the defective sperm morphogenesis and the male-specific infertility, but the role of nectin in testicular AJs has not been investigated. We show here the heterotypic trans-interaction between nectin-2 in Sertoli cells and nectin-3 in spermatids at Sertoli-spermatid junctions (SspJs), heterotypic AJs in testes. Moreover, each nectin-based adhesive membrane domain exhibits one-to-one colocalization with each actin bundle underlying SspJs. Inactivation of the mouse nectin-2 gene causes not only impaired adhesion but also loss of the junctional actin scaffold at SspJs, resulting in aberrant morphogenesis and positioning of spermatids. Localization of afadin, an adaptor protein of nectin with the actin cytoskeleton, is also nectin-2 dependent at SspJs. These results indicate that the nectin-afadin system plays essential roles in coupling cell-cell adhesion and the cortical actin scaffold at SspJs and in subsequent sperm morphogenesis.     

Observations on rat sertoli ectoplasmic (‘junctional’) specializations in their association with germ cells of the rat testis

The ectoplasmic (‘junctional’) specialization, a subsurface modification of the Sertoli cell that is often seen facing germ cells, was studied in relation to the development and maturation of these germ cells. This structure is composed of sub-surface bundles of filaments and more deeply placed endoplasmic reticulum. The data indicate that these subsurface modifications of Sertoli cells are reutilized in a cyclic fashion, being transferred from their position facing late spermatids to one opposing less mature germ cells. Ectoplasmic specializations appeared to function mechanically in grasping the heads of the spermatids which are undergoing the elongation and maturation phases of spermiogenesis rather than in actually attaching Sertoli cells to these germ cells. It is postulated that the ectoplasmic specialization imparts rigidity to that area of the Sertoli cell that surrounds the head region of the germ cell, forming a recess and a mantle by which the germ cell may be moved toward the base or toward the surface of the seminiferous epithelium. The observed linkage of microtubules to the cisternae of the complex provided a morphological basis for the changes in the cytoarchitecture of the Sertoli cell, which must accompany these movements.     

细胞松弛素E对大鼠生精细胞发育的影响

本文采用微丝抑制剂——细胞松弛素E对大鼠生精细胞发育的影响作了形态学观察,特别对支持细胞骨架复合体的作用进行了较为详细的研究。结果表明睾丸内注射0.1ml,1000μmol/L～2000μmol/L,细胞松弛素E,6-14小时后,光镜下可见曲细精管上皮排列疏松,组合紊乱,有的生精上皮基底部出现双核和三核的圆形细胞和多核巨精子细胞,管腔内出现未成熟的精子;在第ⅤⅢ～Ⅸ期曲细精管上皮中,有许多第8、第9期的精子细胞顶体不指向基底方向,属定向不正的精子。电镜下,实验组动物可见一些面向第8-18期精子细胞顶体的支持细胞骨架复合体出现不同程度的缺如,有的断裂成小段;有的破坏仅发生在顶体上方;有的几乎全部丢失,并有类管球复合体的形成。另外,在高渗液处理下,可见精子细胞顶体和支持细胞间的间隙扩大。最后对微丝在精子发育中的作用进行了讨论。