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.     

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.     

Rat seminiferous epithelium contains a unique junction (Ectoplasmic specialization) with signaling properties both of cell/cell and cell/matrix junctions

The seminiferous epithelium contains unique actin related cell-cell junctions, termed ectoplasmic specializations (ESs). Turnover of these junctions is fundamental to sperm release and to movement of spermatocytes from basal to adluminal compartments of the epithelium during spermatogenesis. In this study we report several novel observations related to the spatial and temporal distribution of integrin-related signaling molecules at ESs. We confirm the presence of beta(1)-integrin at these sites and further demonstrate co-localization of integrin linked kinase (ILK). beta(1)-Integrin and ILK were shown by immunoprecipitation to associate in whole cell lysates of seminiferous epithelium. This observation provides the first evidence for a direct beta(1)-integrin/ILK interaction in noncultured epithelium. Pan-cadherin and beta-catenin antibodies did not react at ESs. Rather, antibodies reacted with desmosome-like junctions that are present both at basal junctional complexes between Sertoli cells and at sites of attachment to spermatogenic cells. Focal adhesion kinase (FAK), a known integrin-associated molecule, did not codistribute with beta(1)-integrins and did not associate with these adhesion molecules in immunoprecipitation studies. Although FAK was expressed in the epithelium, it appeared to be limited to the cytoplasm of early spermatogenic cells. Significantly, polyclonal antibodies against phosphotyrosine-containing residues reacted strongly at ESs, with highest levels detected during sperm release and turnover of basal junction complexes. Our observations indicate that ESs share cell signaling features both of cell-cell junctions and of cell-extracellular matrix junctions.     

Sertoli cell ectoplasmic specializations in the seminiferous epithelium of the testosterone-suppressed adult rat

The Sertoli cell ectoplasmic specialization is a unique junctional structure involved in the interaction between elongating spermatids and Sertoli cells. We have previously shown that suppression of testicular testosterone in adult rats by low-dose testosterone and estradiol (TE) treatment causes the premature detachment of step 8 round spermatids from the Sertoli cell. Because these detaching round spermatids would normally associate with the Sertoli cell via the ectoplasmic specialization, we hypothesized that ectoplasmic specializations would be absent in the seminiferous epithelium of TE-treated rats, and the lack of this junction would cause round spermatids to detach. In this study, we investigated Sertoli cell ectoplasmic specializations in normal and TE-treated rat testis using electron microscopy and localization of known ectoplasmic specialization-associated proteins (espin, actin, and vinculin) by immunocytochemistry and confocal microscopy. In TE-treated rats where round spermatid detachment was occurring, ectoplasmic specializations of normal morphology were observed opposite the remaining step 8 spermatids in the epithelium and, importantly, in the adluminal Sertoli cell cytoplasm during and after round spermatid detachment. When higher doses of testosterone were administered to promote the reattachment of all step 8 round spermatids, newly elongating spermatids associated with ectoplasmic specialization proteins within 2 days. We concluded that the Sertoli cell ectoplasmic specialization structure is qualitatively normal in TE-treated rats, and thus the absence of this structure is unlikely to be the cause of round spermatid detachment. We suggest that defects in adhesion molecules between round spermatids and Sertoli cells are likely to be involved in the testosterone-dependent detachment of round spermatids from the seminiferous epithelium.     

Non-muscle cofilin is a component of tubulobulbar complexes in the testis

Tubulobulbar complexes are finger-like structures that form at the interface between maturing spermatids and Sertoli cells prior to sperm release and at the interface between two Sertoli cells near the base of the seminiferous epithelium. They originate in areas previously occupied by actin filament-associated intercellular adhesion plaques known as ectoplasmic specializations. Actin filaments also are associated with tubulobulbar complexes where they appear to form a network, rather than the tightly packed bundles found in ectoplasmic specializations. Cofilin, a calcium-independent actin-depolymerizing protein, previously has been identified in the testis, but has not been localized to specific structures in the seminiferous epithelium. To determine if cofilin is found in Sertoli cells and is concentrated at actin-rich structures, we reacted fixed frozen sections of rat testis, fixed fragmented tissue, and blots of seminiferous epithelium with pan-specific and non-muscle cofilin antibodies. In addition, GeneChip microarrays (Affymetrix, Santa Clara, CA) were utilized to determine the abundance of mRNA for all cofilin isoforms in Sertoli cells. Using the monoclonal pan-specific cofilin antibody, we found specific labeling exclusively at tubulobulbar complexes and not at ectoplasmic specializations. On one-dimensional (1D) Western blots this antibody reacted monospecifically with one band, and on 2D blots reacted with two dots, which we interpret as phosphorylated and nonphosphorylated forms of a single cofilin isotype. Messenger RNA for non-muscle cofilin in Sertoli cells is about 8.5-fold higher than for muscle-type cofilin. To confirm that the non-muscle isoform of cofilin is present at tubulobulbar complexes, we used antibodies specific to non-muscle cofilin for immunofluorescent localization. As with the pan-specific antibody, we found that the non-muscle cofilin antibody exclusively labeled tubulobulbar complexes. Results presented here indicate that non-muscle cofilin is concentrated at tubulobulbar complexes. Our results also indicate that cofilin is not concentrated at ectoplasmic specializations.     

Evidence that tubulobulbar complexes in the seminiferous epithelium are involved with internalization of adhesion junctions

Tubulobulbar complexes may be part of the mechanism by which intercellular adhesion junctions are internalized by Sertoli cells during sperm release. These complexes develop in regions where Sertoli cells are attached to adjacent cells by intercellular adhesion junctions termed ectoplasmic specializations. At sites where Sertoli cells are attached to spermatid heads, tubulobulbar complexes consist of fingerlike processes of the spermatid plasma membrane, corresponding invaginations of the Sertoli cell plasma membrane, and a surrounding cuff of modified Sertoli cell cytoplasm. At the terminal ends of the complexes occur clusters of vesicles. Here we show that tubulobulbar complexes develop in regions previously occupied by ectoplasmic specializations and that the structures share similar molecular components. In addition, the adhesion molecules nectin 2 and nectin 3, found in the Sertoli cell and spermatid plasma membranes, respectively, are concentrated at the distal ends of tubulobulbar complexes. We also demonstrate that double membrane bounded vesicles are associated with the ends of tubulobulbar complexes and nectin 3 is present on spermatids, but is absent from spermatozoa released from the epithelium. These results are consistent with the conclusion that Sertoli cell and spermatid membrane adhesion domains are internalized together by tubulobulbar complexes. PKCalpha, a kinase associated with endocytosis of adhesion domains in other systems, is concentrated at tubulobulbar complexes, and antibodies to endosomal and lysosomal (LAMP1, SGP1) markers label the cluster of vesicles associated with the ends of tubulobulbar complexes. Our results are consistent with the conclusion that tubulobulbar complexes are involved with the disassembly of ectoplasmic specializations and with the internalization of intercellular membrane adhesion domains during sperm release.     

Morphological changes in the rat sertoli cell induced by the microtubule poison carbendazim

Early morphological changes in the rat Sertoli cell induced by the fungicide carbendazim (methyl-2-benzimidazole carbamate; MBC), a metabolite of benomyl, were examined. Adult rats were treated with single doses of MBC (400mg/kg) or vehicle and examined by light and electron microscopy at 3 hr post-treatment. Sloughing of elongating spermatid clusters was observed in all stages of spermatogenesis, except for Stages III–V. Cleavage occurred near the apical region of the seminiferous epithelium where cytoplasmic processes of the Sertoli cell surround the heads of elongating spermatids. The cleaved cytoplasm remained attached to the sloughed spermatids and ectoplasmic specializations remained undamaged. Intact microtubules were observed in the apical Sertoli cell cytoplasm (including sloughed tissues) but were decreased in the body region, where aggregates of mitochondria were found. Cytoplasm near the cleavage site exhibited rarefaction, which was associated with swollen cisternae of endoplasmic reticulum. It appears that the mechanism of germ cell sloughing induced by MBC treatment involves the disruption of microtubules in the body region of the Sertoli cell, the retraction of cytoplasmic organelles and the swelling of endoplasmic reticulum.     

Rat testis motor proteins associated with spermatid translocation (dynein) and spermatid flagella (kinesin-II)

In this study, we report sites in the seminiferous epithelium of the rat testis that are immunoreactive with antibodies to the intermediate chain of cytoplasmic dynein and kinesin II. The study was done to determine whether or not microtubule-dependent motor proteins are present in Sertoli cell regions involved with spermatid translocation. Sections and epithelial fragments of perfusion-fixed rat testis were probed with an antibody (clone 74.1) to the intermediate chain of cytoplasmic dynein (IC74) and to kinesin-II. Labeling with the antibody to cytoplasmic dynein was dramatically evident in Sertoli cell regions surrounding apical crypts containing attached spermatids and known to contain unique intercellular attachment plaques. The antibody to kinesin II reacted only with spermatid tails. The levels of cytoplasmic dynein visible on immunoblots of supernatants collected from spermatid/junction complexes treated with an actin-severing enzyme (gelsolin) were greater than those of controls, indicating that at least some of the dynein may have been associated with Sertoli cell junction plaques attached to spermatids. Results are consistent with the conclusion that an isoform of cytoplasmic dynein may be responsible for the apical translocation of elongate spermatids that occurs before sperm release. Also, this is the first report of kinesin-II in mammalian spermatid tails.     

Ultrastructural observations on spermatozoa retained within the seminiferous epithelium after treatment with dibutyryl cyclic AMP

Spermiation was inhibited in the Syrian hamster by administering large doses of dibutyryl cyclic AMP. After treatment with dibutyryl cyclic AMP most stage VIII, IX, and X seminiferous tubules contained some mature spermatozoa within the seminiferous epithelium. The acrosomal membranes and plasma membranes of the unreleased spermatozoa remained intact, indicating that the spermatozoa had not been phagocytized by the Sertoli cells. Sertoli-spermatid junctional specializations were usually applied to the heads of the mature spermatozoa. The unreleased spermatozoa often appeared swollen with accumulated fluid located in the subacrosomal space. The accumulation of subacrosomal fluid in the unreleased spermatozoa seems to result from the absence of tubulobulbar complexes. That is, when tubulobular complexes fail to form the normal flow of cytoplasm into the tubulobular complexes is blocked resulting in an accumulation of fluid around the nucleus. Inhibition of spermiation may result from the absence of tubulobulbar complex formation. It is postulated that the tubulobulbar complex functions to transfer a chemical trigger from the maturing spermatid into the Sertoli cell. This chemical trigger may initiate the disappearance of the Sertoli-spermatid junctional specialization and induce spermiation.     

Ultrastructure of sustentacular (Sertoli) cells in the bovine testis

In the present communication, ultrastructural and cytochemical aspects of mature bovine Sertoli cells and their relationship to the different stages of germ cell development are described. As in other mammalian species, different types of junctional specializations exist between Sertoli and germ cells in the bovine seminiferous epithelium, including desmosome-like junctions, Sertoli cell ectoplasmic specializations and tubulobulbar complexes. The functional significance of the morphological results and the interactions of Sertoli and germ cells during spermatogenesis are discussed.     

Tubulobulbar complexes are intercellular podosome-like structures that internalize intact intercellular junctions during epithelial remodeling events in the rat testis

Tubulobulbar complexes are actin-related double-membrane projections that resemble podosomes in other systems and form at intercellular junctions in the seminiferous epithelium of the mammalian testis. They are proposed to internalize intact junctions during sperm release and during the translocation of spermatocytes through basal junction complexes between neighboring Sertoli cells. In this study we probe apical tubulobulbar complexes in fixed epithelial fragments and fixed frozen sections of rat and mouse testes for junction molecules reported to be present at apical sites of attachment (ectoplasmic specializations) between Sertoli cells and spermatids. The adhesion molecules nectin 2 (PVRL2), nectin 3 (PVRL3) and alpha 6 integrin (ITGA6) are present in the elongate parts of tubulobulbar complexes and concentrated at their distal ends. Tubulobulbar complexes contain cortactin (CTTN), a key component of podosomes, and vesicles at the distal ends of tubulobulbar complexes that contain junction molecules are related to early endosome antigen (EEA1). N-cadherin (CDH2), a protein reported to be present at ectoplasmic specializations, is not localized to these unique junctions or to tubulobulbar complexes but, rather, is primarily concentrated at desmosomes in basal regions of the epithelium. Our results are consistent with the conclusion that tubulobulbar complexes are podosome-like structures that are responsible for internalizing intact intercellular junctions during spermatogenesis.     

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.     

Adjudin-mediated Sertoli–germ cell junction disassembly affects Sertoli cell barrier function in vitro and in vivo

Adjudin, an analogue of lonidamine, affects adhesion between Sertoli and most germ cells, resulting in reversible infertility in rats, rabbits and dogs. Previous studies have described the apical ectoplasmic specialization, a hybrid-type of Sertoli cell–elongating/elongated spermatid adhesive junction, as a key target of adjudin. In this study, we ask if the function of the blood–testis barrier which is constituted by co-existing tight junctions, desmosome-gap junctions and basal ectoplasmic specializations can be maintained when the seminiferous epithelium is under assault by adjudin. We report herein that administration of a single oral dose of adjudin to adult rats increased the levels of several tight junction and basal ectoplasmic specialization proteins during germ cell loss from the seminiferous epithelium. These findings were corroborated by a functional in vitro experiment when Sertoli cells were cultured on Matrigel?-coated bicameral units in the presence of adjudin and transepithelial electrical resistance was quantified across the epithelium. Indeed, the Sertoli cell permeability barrier was shown to become tighter after adjudin treatment as evidenced by an increase in transepithelial electrical resistance. Equally important, the blood–testis barrier in adjudin-treated rats was shown to be intact 2 weeks post-treatment when its integrity was monitored following vascular administration of inulin-fluorescein isothiocyanate which failed to permeate past the barrier and enter into the adluminal compartment. These results illustrate that a unique mechanism exists to maintain blood–testis barrier integrity at all costs, irrespective of the presence of germ cells in the seminiferous epithelium of the testis.     

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.     

Sertoli-germ cell adherens junction dynamics in the testis are regulated by RhoB GTPase via the ROCK/LIMK signaling pathway

During spermatogenesis, cell-cell actin-based adherens junctions (AJs), such as ectoplasmic specializations (ESs), between Sertoli and germ cells undergo extensive restructuring in the seminiferous epithelium to facilitate germ cell movement across the epithelium. Although the mechanism(s) that regulates AJ dynamics in the testis is virtually unknown, Rho GTPases have been implicated in the regulation of these events in other epithelia. Studies have shown that the in vitro assembly of the Sertoli-germ cell AJs but not of the Sertoli cell tight junctions (TJs) is associated with a transient but significant induction of RhoB. Immunohistochemistry has shown that the localization of RhoB in the seminiferous epithelium is stage specific, being lowest in stages VII-VIII prior to spermiation, and displays cell-specific association during the epithelial cycle. Throughout the cycle, RhoB was localized near the site of basal and apical ESs but was restricted to the periphery of the nuclei in elongating (but not elongated) spermatids, spermatocytes, and Sertoli cells. However, RhoB was not detected near the site of apical ESs at stages VII-VIII. Furthermore, disruption of AJs in Sertoli-germ cell cocultures either by hypotonic treatment or by treatment with 1-(2,4-dichlorobenzyl)-indazole-3-carbohydrazide (AF-2364) also induced RhoB expression. When adult rats were treated with AF-2364 to perturb Sertoli-germ cell AJs in vivo, a approximately 4-fold induction in RhoB in the testis, but not in kidney and brain, was detected within 1 h, at least approximately 1-4 days before germ cell loss from the epithelium could be detected by histological analysis. The signaling pathway(s) by which AF-2364 perturbed the Sertoli-germ cell AJs apparently began with an initial activation of integrin, which in turn activated RhoB, ROCK1, (Rho-associated protein kinase 1, also called ROKbeta), LIMK1 (LIM kinase 1, also called lin-11 isl-1 mec3 kinase 1), and cofilin but not p140mDia and profilin via phosphorylation. Immunoprecipitation and immunoblots revealed that the induction of LIMK1 was mediated via an increase in its phospho-Ser but not phospho-Tyr content. Furthermore, Y-27632 ([(R)-(+)-trans-N-(4-pyridyl)-4-(1-aminoethyl)-cyclohexane-carboxamide, 2HCl]), a specific ROCK inhibitor, could effectively delay the AF-2364-induced germ cell loss from the seminiferous epithelium in vivo, illustrating that the integrin/RhoB/ROCK/LIMK pathway indeed plays a crucial role in the regulation of Sertoli-germ cell AJ dynamics. The fact that the RhoB pathway in the kidney and brain was not activated suggests that AF-2364 exerts its effects primarily at the testis-specific ES multiprotein complex structures between Sertoli cells and spermatids. In summary, this report illustrates that Sertoli germ cell AJ dynamics are regulated, at least in part, via the integrin/ROCK/LIMK/cofilin signaling pathway.     

gamma-Tubulin overexpression in Sertoli cells in vivo: I. Localization to sites of spermatid head attachment and alterations in Sertoli cell microtubule distribution

Sertoli cells play a number of roles in supporting spermatogenesis, including structural organization, physical and paracrine support of germ cells, and secretion of factors necessary for germ cell development. Studies with microtubule disrupting compounds indicate that intact microtubule networks are crucial for normal spermatogenesis. However, treatment with toxicants and pharmacologic agents that target microtubules lack cell-type selectivity and may therefore elicit direct effects on germ cells, which also require microtubule-mediated activities for division and morphological transformation. To evaluate the importance of Sertoli cell microtubule-based activities for spermatogenesis, an adenoviral vector that overexpresses the microtubule nucleating protein, gamma-tubulin, was used to selectively disrupt microtubule networks in Sertoli cells in vivo. gamma-Tubulin overexpression was observed to cause redistribution of Sertoli cell microtubule networks, and overexpression of a gamma-tubulin-enhanced green fluorescent protein fusion protein was observed to localize to the site of elongate spermatid head attachment to the seminiferous epithelium.     

Arrangement and possible function of actin filament bundles in ectoplasmic specializations of ground squirrel Sertoli cells

We have investigated the arrangement and function of actin filament bundles in Sertoli cell ectoplasmic specializations found adjacent to junctional networks and in areas of adhesion to spermatogenic cells. Tissue was collected, from ground squirrel (Spermophilus spp.) testes, in three ways: seminiferous tubules were fragmented mechanically; segments of intact epithelium and denuded tubule walls were isolated by using EDTA in a phosphate-buffered salt solution; and isolated epithelia and denuded tubule walls were extracted in glycerol. To determine the arrangement of actin bundles, the tissue was fixed, mounted on slides, treated with cold acetone (-20 degrees C), and then exposed to nitrobenzoxadiazole-phallacidin. Myosin was localized using immunofluorescence. To investigate the hypothesis that ectoplasmic specializations are contractile, glycerinated models were exposed to exogenous ATP and Ca++; then contraction was assessed qualitatively by using nitrobenzoxadiazole-phallacidin as a marker. Actin bundles in ectoplasmic specializations adjacent to junctional networks circumscribe the bases of Sertoli cells. When intact epithelia are viewed from an angle perpendicular to the epithelial base, honeycomb staining patterns are observed. Filament bundles in Sertoli cell regions adjacent to spermatogenic cells dramatically change organization during spermatogenesis. Initially, the bundles circle the region of contact between the developing acrosome and nucleus. They then expand to cover the entire head. As the spermatid flattens, filaments on one side of the now saucer-shaped head orient themselves parallel to the germ cell axis while those on the other align perpendicularly to it. Before sperm release, all filaments course parallel to the rim of the head. Contrary to the results we obtained with myoid cells, we could not convincingly demonstrate myosin in ectoplasmic specializations or induce contraction of glycerinated models. Our data are consistent with the hypothesis that actin in ectoplasmic specializations of Sertoli cells may be more skeletal than contractile.     

Spermiation in the Mouse: Contribution of the Invading Sertoli Cell Process to Adluminal Displacement of the Spermatid Head

At the maturation phase of spermiogenesis in mice, the spermatid heads that are embedded deeply in the epithelium of the seminiferous tubules dislocate toward the luminal surface. In the present study, to clarify the manner in which the spermatid head is displaced toward the lumen, morphological changes in spermatids and Sertoli cells were examined on ultrathin and thick sections stained with adenosine triphosphatase cytochemistry. During adluminal displacement, the spermatid head is surrounded by an invading process of Sertoli cell which invaginates into the spermatid cytoplasm to form complicated passages called the canal complex. At the site of the spermatid head, the wall of an invading Sertoli cell process folds to form a sheath in which the spermatid head is located. The sheath correspond to a structure known as ectoplasmic specialization. The invading Sertoli cell process also shows branching and swelling at the site where spermatid heads are present. The present results suggest that the canal complex is directly involved in the adluminal displacement of the spermatid head. Dynamic changes of invading Sertoli cell processes may produce the motive force for adluminal displacment of the spermatid head. Also, ectoplasmic specialization may contribute to the adluminal displacement of the spermatid possibly by mediating cell to cell interaction between the spermatid nucleus and the invading Sertoli cell process.     

Effects of vanadate on the assembly and disassembly of purified tubulin

Sodium-orthovanadate (100-700 microM) added to purified pig brain microtubule protein (molar ratios 13-90 moles vanadate/mole tubulin) inhibits to a considerable extent the assembly (up to 65%) and the disassembly rates (up to 60%) of microtubules, as determined by turbidimetry. Vanadate added to preformed microtubules did not appreciably alter the turbidity level of the samples, however, the disassembly rates were decreased in the same manner as when vanadate was added prior to polymerization. Microtubule protein kept on ice for 3-6 hours became more susceptible to vanadate than freshly prepared protein. The effect of vanadate was independent of the GTP concentration at which the polymerization assays were performed (0.025 to 1 mM GTP). In the presence of taxol, which increases the rate and extent of microtubule formation, vanadate had no effect on assembly rates. Disassembly was inhibited, however, much less than in the presence of vanadate alone. Electron microscopy and polyacrylamide gel electrophoresis did not reveal differences between microtubules prepared in the presence or in the absence of vanadate. This is consistent with the notion that vanadate does not interfere with the interaction between tubulin and the high-molecular weight microtubule-associated proteins. Apparently vanadate brings about an allosteric change of the microtubule protein(s) resulting in the abnormal polymerization kinetics of tubulin found in our study. The above results may be relevant for studies where the effects of vanadate on intracellular motility are interpreted as being solely due to a specific inhibition of ATPases.