Synthesis of a testosterone-dependent secretory protein by rat seminal vesicle-derived cell lines.

Primary cell cultures were established from explants of rat seminal vesicle. The establishment of primary cell cultures required, among other factors, the presence of testosterone. Two cell populations were detected in such primary cultures: fibroblast-like cells and epithelial-like cells; the latter encompassed a subtype of small cells and a subtype of large squamous cells (most likely the result of a degenerative process acting upon the former). Histochemical, as well as electron-microscopical observations, indicated the presence of a persistent secretory activity in the small epithelial cells; fibroblast and large squamous epithelial cells were inactive in this respect. Staining of the cells with a peroxidase-conjugated antibody and analysis of the proteins produced in the presence of labelled methionine, showed that one of the major rat seminal vesicle secretory proteins, namely RSV-IV, was also produced. Conditions which favoured the growth of epithelial cells, rather than of fibroblasts, were determined. The use of nearly homogeneous cell populations and the use of collagen-coated Petri dishes, allowed the cloning of two independently obtained permanent cell lines, namely SVC-1 and SVC-2. The in vitro growth rate of both cell lines was modulated by the amount of testosterone in the medium. Both cell lines were able to synthesize a significant amount of RSV-IV protein under testosterone control.     

Isolation and culture of rat seminal vesicle epithelial cells : The use of the secretory protein SVS IV as a functional probe

A method for the isolation and culture of seminal vesicle epithelial cells obtained from control and androgen-primed sexually-immature, uncastrated rats is described. This method allows the establishment of monolayer cultures from aggregates of seminal vesicle epithelial cells isolated after trypsin and collagenase digestion. Phase contrast and transmission electron microscopic methods demonstrate that cell aggregates, after attaching to the substrate, establish within 48 h a colony-like, epithelial-like growth pattern. Immunofluorescent localization studies of SVS IV, an androgen-dependent secretory protein purified from rat seminal vesicle secretion, show that cultured seminal vesicle epithelial cells are immunoreactive. An electrophoretic analysis of [35S]methionine-labeled secretory proteins immunoprecipitated with rabbit anti-SVS IV serum demonstrate that, whereas SVS IV is newly-synthesized and accumulated in the medium of cultured seminal vesicle cells established from androgen primed rats, cultured cells from control rats appear to synthesize and accumulate SVS IV in a precursor form. Results of this work show that seminal vesicle epithelial cells in culture not only retain several structural features representative of the tissue but also serve as a potential system for the study of androgen action.     

Secretory cell activity in the hamster seminal vesicle following castration. A morphometric ultrastructural study

The ultrastructure of hamster seminal vesicle epithelium was studied 7, 14, 21 and 28 days after castration using a stereological approach. The results show that castration promotes epithelial reorganization, mainly characterized by reduced epithelial cell size and number, decreased rough endoplasmic reticulum and Golgi complex, increased lysosomes and lipid droplets, increased apical secretory granule size and number, and increased intracellular secretory products per average epithelial cell. It is concluded that after testosterone withdrawal the secretory activity of hamster seminal vesicle epithelial cells, although reduced, is not abolished, and that exocytosis is relatively more reduced than secretory protein production. We suggest that an extracellular androgen source is responsible for secretory activity not being lost in the epithelial cells of castrated hamster seminal vesicle.     

Fine structural studies of rat seminal vesicle in castrated and intact animals following estrogen treatment.

The effect of estradiol and/or testosterone upon secretion by seminal vesicle in castrated and intact rats was assessed in young adult Sprague-Dawley rats, using light microscopy (LM), transmission (TEM) and scanning (SEM)electron microscopy. Hormones were injected daily for ten days beginning ten days after castrations were performed. The normal rat seminal vesicle, as revealed by SEM, was characterized by a large saccular lumen with highly folded walls. Cell surfaces were covered with microvilli, or occasionally displayed a protruding, ruffled surface, sparsely covered with short microvilli. Cytology was normal in testosterone-treated animals. Estradiol treatment of castrated animals stimulated secretion by seminal vesicle epithelial cells as evidenced by the presence of normal secretory bodies, the presence of RER, and moderately hypertrophied Golgi complexes. These glands were not heavier than were glands from castrated, untreated animals, although the epithelial cells were significantly taller. Secretion was maintained in intact animals treated with estradiol, although glands were smaller and epithelial height was reduced. Estradiol and testosterone treatment in combination did not appear to have an additive effect on secretion, weight of the gland, or epithelial height. The following results support the hypothesis that estrogen-induced prolactin synthesis and release may be involved in the mechanism by which estradiol effected stimulation of seminal vesicle epithelium. Prolactin-treated, castrated animals exhibited focal areas of stimulated epithelium. In hypophysectomized animals (untreated controls), the seminal vesicle epithelium retained some secretory bodies and secretory fluid in the glandular lumen; epithelial height was taller than that in castrated controls. Estrogen treatment reduced the epithelial height to that of castrated controls; there was no evidence of secretion. This suggests that in the absence of anterior pituitary hormones, including prolactin, the stimulatory effect of estradiol on seminal vesicle epithelium was nullified. In adrenalectomized/castrated animals, estradiol treatment stimulated secretion in seminal vesicle epithelium just as in non-adrenalectomized/castrated animals. This indicates that the adrenal gland plays a non-essential role in the action of estrogen on seminal vesicle epithelium.     

Identification of low density lipoprotein receptor-related protein-2/megalin as an endocytic receptor for seminal vesicle secretory protein II

The low density lipoprotein receptor-related protein-2/megalin (LRP-2) is an endocytic receptor that is expressed on the apical surfaces of epithelial cells lining specific regions of the male and female reproductive tracts. In the present study, immunohistochemical staining revealed that LRP-2 is also expressed by epithelial cells lining the ductal region and the ampulla of the rat seminal vesicle. To identify LRP-2 ligands in the seminal vesicle, we probed seminal vesicle fluid with 125I-labeled LRP-2 in a gel-blot overlay assay. A 100-kDa protein (under non-reducing conditions) was found to bind the radiolabeled receptor. The protein was isolated and subjected to protease digestion, and the proteolytic fragments were subjected to mass spectroscopic sequence analysis. As a result, the 100-kDa protein was identified as the seminal vesicle secretory protein II (SVS-II), a major constituent of the seminal coagulum. Using purified preparations of SVS-II and LRP-2, solid-phase binding assays were used to show that the SVS-II bound to the receptor with high affinity (Kd = 5.6 nM). The binding of SVS-II to LRP-2 was inhibited using a known antagonist of LRP-2 function, the 39-kDa receptor-associated protein RAP. Using a series of recombinant subfragments of SVS-II, the LRP-2 binding site was mapped to a stretch of repeated 13-residue modules located in the central portion of the SVS-II polypeptide. To evaluate the ability of LRP-2 to mediate 125I-SVS-II endocytosis and lysosomal degradation, ligand clearance assays were performed using differentiated mouse F9 cells, which express high levels of LRP-2. Radiolabeled SVS-II was internalized and degraded by the cells, and both processes were inhibited by antibodies to LRP-2 or by RAP. The results indicate that LRP-2 binds SVS-II and can mediate its endocytosis leading to lysosomal degradation.     

Fine structure of male genital tracts of some Acrididae and Tettigoniidae (Insecta: Orthoptera)

A morphological, histological and ultrastructural study was carried out on the spermiducts and seminal vesicles of some species of Acrididae and Tettigoniidae. In all the species examined, the spermiducts and seminal vesicles have a monolayered secretory epithelium. Only the species of Acrididae have the sac with a flattened epithelium. Furthermore, in the most distal tubule region of the seminal vesicles of Eyprepocnemis plorans plorans, a rather characteristic secretory mechanism was found: the cytoplasm of the epithelial cells contained a large vesicle delimited by tightly packed microvilli. Numerous small vesicles open into this large vesicle which gradually dilates to merge with the apical plasma membrane releasing its contents into the lumen. Spermiophagic activity was found in all the species investigated. In the Tettigoniidae, this activity was found only in some epithelial cells of the seminal vesicle wall; in the species of the Acrididae the spermiophagic activity was carried out in the spermiduct lumen by an epithelial‐type cellular group. Spermiophagic activity is discussed as well as its role in the reproduction of these insects.     

Vasoactive intestinal peptide stimulates apical secretion in hamster seminal vesicle epithelial cells in culture

In this study, we investigated the presence of vasoactive intestinal peptide (VIP) receptors in the epithelial cells of the hamster seminal vesicle, by using cell clusters isolated from the gland and cultivated in a serum-free bicameral culture system. An immunocytochemical approach and autoradiographic and biochemical binding experiments with 125I-VIP as radioligand were performed. The effect of this neuropeptide on cultured cell proliferation and protein secretory activity was also analysed. The release of trichloroacetic-acid-precipitable radioactive material by epithelial cells to the apical and basal compartments of the bi-chamber was estimated in absolute and relative terms. The results of this work indicate that: (1) VIP receptors are present in the membranes of clusters of epithelial cells from seminal vesicles and are further maintained in cultured cells; (2) VIP does not exert any mitogenic effect in these cells; (3) VIP affects the directionality of secretion, favouring the absolute and relative amounts of protein released to the apical compartment of the bi-chamber. The expression of VIP receptors in the epithelial cells of the hamster seminal vesicle and the direct secretagogue-like activity of this neuropeptide in these cells might be affected by other factors, namely, androgens.     

Testosterone interferes with the kinetics of endocytosis in the hamster seminal vesicle

Endocytosis was studied in the seminal vesicle secretory cells of castrated and control hamsters in order to investigate the effect of testosterone withdrawal in the endocytic activity of these cells. Horseradish peroxidase was injected into the glands lumen after removal of their contents, and tracer distribution was qualitatively studied, and the number of labeled endocytic vesicles quantitatively analyzed, following 5, 20, 40 and 60 min incubation. The following compartments are labeled both in castrate and control cells: 1), endocytic vesicles; 2), vacuoles with or without secretory material; 3), multivesicular bodies; 4), Golgi cisternae; 5), intercellular spaces; 6), sub-epithelial space. The pattern of labeling is lighter in castrate than in control cells and the labeling of Golgi cisternae, which correlates with a significant peak in the number of endocytic vesicles, is observed later in castrated animals than in controls: 40 min vs 20 min. Exocytosis, as evaluated through the fraction of secretory protein released in vitro, decreases following castration. Endocytosis performed in castrated, pilocarpine treated animals shows that the Golgi labeling, coinciding with numerous labeled endocytic vesicles, is advanced from 40 to 20 min after stimulation of exocytosis. The results show that, in the seminal vesicle secretory cells a) the endocytic pathway does not depend on testosterone; b) testosterone withdrawal decreases endocytosis and delays the kinetics of labeling and; c) endocytosis couples to exocytosis, probably so regulating the apical cell membrane area.     

Testosterone interferes with the kinetics of endocytosis in the hamster seminal vesicle

Endocytosis was studied in the seminal vesicle secretory cells of castrated and control hamsters in order to investigate the effect of testosterone withdrawal in the endocytic activity of these cells. Horseradish peroxidase was injected into the glands lumen after removal of their contents, and tracer distribution was qualitatively studied, and the number of labeled endocytic vesicles quantitatively analyzed, following 5, 20, 40 and 60 min incubation. The following compartments are labeled both in castrate and control cells: 1), endocytic vesicles; 2), vacuoles with or without secretory material; 3), multivesicular bodies; 4), Golgi cisternae; 5), intercellular spaces; 6), sub-epithelial space. The pattern of labeling is lighter in castrate than in control cells and the labeling of Golgi cisternae, which correlates with a significant peak in the number of endocytic vesicles, is observed later in castrated animals than in controls: 40 min vs 20 min. Exocytosis, as evaluated through the fraction of secretory protein released in vitro, decreases following castration. Endocytosis performed in castrated, pilocarpine treated animals shows that the Golgi labeling, coinciding with numerous labeled endocytic vesicles, is advanced from 40 to 20 min after stimulation of exocytosis. The results show that, in the seminal vesicle secretory cells a) the endocytic pathway does not depend on testosterone; b) testosterone withdrawal decreases endocytosis and delays the kinetics of labeling and; c) endocytosis couples to exocytosis, probably so regulating the apical cell membrane area.     

Ultrastructure of the vasa deferentia of the mediterranean flour moth

Each vas deferens of the Mediterranean flour moth, Anagasta kuehniella (Zeller), consists of a short swollen portion immediately below the testis, another swollen portion that forms a seminal vesicle, and an elongate lower portion that empties into one arm of the ductus ejaculatoris duplex. Three types of epithelial cells occur sequentially. Phagocytic cells that engulf debris from the testis form the anterior two-thirds of the first swollen portion. Tall secretory cells form the distal third of the first swollen region and extend to the seminal vesicles. The secretory cells surround a slit-like lumen and appear to function as a valve between the two swollen regions. Many membrane-enclosed secretory granules are stored at the apical ends of the cells and are released into the lumen together with small amounts of the surrounding cytoplasm. The granules remain intact while they are in the male tract. A second type of secretory cell forms the walls of the seminal vesicles and the lower vasa deferentia. These cells produce secretory granules whose contents become dispersed through the semen. PTA-chromic acid staining indicates that the seminal plasma has a high glycoprotein content. A thin muscle layer is basal to the epithelial cells. Both apyrene and eupyrene sperm undergo some development in the vasa deferentia. The epithelial cells, muscle, and stored sperm all undergo extensive changes with age.     

Immunocytochemical localization of insulin-like immunoreactivity in mouse seminal vesicle

Insulin-like immunoreactivity was localized in tissue sections and cell cultures of mouse seminal vesicle using the indirect technique of immunocytochemistry. Seminal vesicles were cut into fragments, fixed in 2.5% glutaraldehyde, embedded in epoxy resin, sectioned at 1 micron, and transferred to glass slides. Epithelial cell cultures of seminal vesicle were grown on coverslips in Dulbecco's Minimal Essential Medium for 4-6 days and fixed in 2.5% glutaraldehyde. Sections (etched with sodium ethanolate) or coverslips were incubated in guinea pig antiporcine insulin antiserum, in antiserum immunoabsorbed with porcine insulin, or in normal guinea pig serum. For indirect immunocytochemistry, incubation with primary antiserum was followed by treatment with rabbit anti-guinea pig immunoglobulin (Ig) G conjugated to peroxidase, or with protein A and then rabbit peroxidase anti-peroxidase (PAP). Finally, treated samples were incubated in phenylenediamine-pyrocatechol-H2O2 substrate mixture for 6-8 min at room temperature. Specific immunoreactivity to insulin antisera was confined to the epithelium of the seminal vesicle in tissue sections. No staining occurred in subepithelial connective tissue. Specific immunoreactivity was also observed in the cytoplasm of cultured seminal vesicle epithelial cells.     

Induction of functional cytodifferentiation in the epithelium of tissue recombinants. II. Instructive induction of Wolffian duct epithelia by neonatal seminal vesicle mesenchyme

When grown as renal grafts in adult male hosts, the upper (cranial), middle and lower (caudal) portions of fetal mouse and rat Wolffian ducts developed into epididymis, epididymis plus ductus deferens, and seminal vesicle, respectively. In heterotypic tissue recombinants, the epithelia from upper and middle Wolffian ducts were instructively induced to undergo seminal vesicle morphogenesis by neonatal seminal vesicle mesenchyme. Functional cytodifferentiation was examined in these recombinants using antibodies against major androgen-dependent, seminal vesicle-specific secretory proteins. The instructively induced Wolffian duct epithelia synthesized normal amounts of all of the secretory proteins characteristic of mature seminal vesicles, as judged by immunocytochemistry on tissue sections and gel electrophoresis plus immunoblotting of secretions extracted from the recombinants. In heterospecific recombinants composed of rat and mouse tissues, the seminal vesicle proteins induced were specific for the species that had provided the epithelium. This showed that the seminal vesicle epithelium in the recombinants was derived from instructively induced Wolffian duct epithelium and not from epithelial contamination of the mesenchymal inductor. Upper Wolffian duct epithelium, instructively induced to undergo seminal vesicle morphogenesis, did not express epididymis-specific secretory proteins, showing that its normal development had been simultaneously repressed.     

Fine structure of the seminal vesicle epithelium of the mouse and golden hamster

The seminal vesicle epithelium of the mouse and golden hamster was examined by light microscopy and by transmission and scanning electron microscopy. By transmission electron microscopy, in the seminal vesicle epithelium of both animals secretory epithelial cells which consisted of mostly light and a few dark cells were observed. The epithelial cells possessed secretory granules which contained a densely stained core. The secretory granules in the mouse epithelium reacted weakly with periodic acid-Schiff (PAS) stain and were slightly stained with alcian blue (AB), and those in the golden hamster exhibited strongly positive reactions with PAS and AB. The nuclei in the mouse tissue were spherical or ovoid, and those in the golden hamster tissue had a few lobes. By scanning electron microscopy, the apical surfaces of most of the epithelial cells were commonly flat or domed, and those of some epithelial cells protruded into the lumen as apocrine-like processes, or possessed small and large orifices. Besides the epithelial cells, there were cells characterized by pseudopodium-like cytoplasmic projections, a few membranous structures, an irregular nucleus, and cytoplasm containing a few dense bodies, in the basal portions of the epithelial cells, or between the basal lamina and the epithelial cells. These cells of the two species were similar in their features.     

Stereology and ultrastructure of the seminal vesicle of C57/BL/6J mice following chronic alcohol ingestion

Excessive alcohol consumption causes metabolic changes and pathologic alterations in testes and accessory sex organ in different animal species. The aim of the present study was to evaluate the macroscopic, histologic and ultrastructural alterations provoked by chronic ingestion of different ethanol concentrations over increasing periods of time on the secretory epithelium of the seminal vesicle of C57/BL/6J mice in using stereological methods. Sixty male adult mice were divided into three experimental groups: Control, Alcoholic 25% and Alcoholic 35%, respectively, receiving tap water and tap water containing ethanol diluted to 25 and 35 degrees Gay Lussac. All mice were fed with the same solid diet. After 150 and 250 days of treatment the animals were sacrificed and the seminal vesicles were collected and processed for light and transmission electron microscopy. The cellular, cytoplasmic and nuclear volumes and the area density of autophagic and secretory vacuoles were measured. The histologic alterations observed in the alcoholic mice consisted of a reduction in epithelial size and cell volume, with maintenance of the same nuclear and cytoplasmic ratio as verified in the control groups. The ultrastructural alterations were: increased density of dense body area, decreased density of secretory granule area, and dilated rough endoplasmic reticulum and Golgi cisternae. We conclude that chronic ethanol ingestion causes depleting morphologic alterations in the epithelial cells of the seminal vesicle and negatively affects the secretory process of this gland.     

Ultrastructure and innervation of water buffalo (Bubalus bubalis) seminal vesicle.

The lining epithelium of secretory end pieces and central glandular duct in the seminal vesicle of the water buffalo (Bubalus bubalis) consists of columnar principal and small polymorphous basal cells. A system of intercellular and even intracellular canaliculi enlarges the secretory surface. The most prominent organelle of the columnar principal cells is the granular endoplasmic reticulum, forming large aggregates of parallel lamellae. Using antibodies against the neural cell adhesion molecule L1 and the neural marker protein gene product 9.5 (PGP 9.5), the innervation pattern of the seminal vesicle becomes evident. The muscular layer surrounding the propria contains a dense network of unmyelinated fibers. Thicker bundles traverse the muscular layer to reach the propria. Around glandular secretory tubules and below the epithelial lining of the glandular duct a tightly woven subepithelial plexus is observed which sends short penetrating branches into the basal zone of the epithelium. These intraepithelial nerves are devoid of Schwann cells and basal lamina (naked axons) and are situated within the intercellular spaces between principal and basal cells. Acetylcholinesterase histochemistry with short (1-2 h) incubation times, dopamine-beta-hydroxylase immunohistochemistry and ultrastructural study of transmitter-containing vesicles was performed. The results suggest that muscular contraction in the seminal vesicle is predominantly under the influence of the sympathetic nervous system, whereas secretory epithelial function is regulated by both sympathetic and parasympathetic fibers.     

Growth-mediated, density-dependent inhibition of endocytosis in cultured arterial smooth muscle cells

The effects of cell density and growth upon fluid phase endocytosis were investigated in quiescent and growing cultures of monkey arterial smooth muscle cells. Cells were maintained in a quiescent state of growth in 5% plasma-derived serum. Subsequent exposure of subconfluent cultures to the specific mitogens, platelet-derived growth factor (PDGF), epidermal growth factor (EGF), fibroblast growth factor (FGF), or to whole blood serum, resulted in up to 4-fold increases in the rate of fluid endocytosis/cell. The changes began several hours after entry into G1 phase of the cell cycle and continued through S. The fraction of cells entering the growth cycle was variable (PDGF=FGF>EGF) and a close correlation existed between the rate of endocytosis and the fraction of [³H]thymidine-labelled cells (r = 0.929, p<0.01). At a range of cell densities, the rate of fluid endocytosis/cell was similar in sparse, confluent and post-confluent cultures of quiescent cells; in contrast, in growing cells there was density-dependent inhibition of endocytosis. Furthermore, when quiescent cells were in contact with each other and were then exposed to mitogens, the growth response was diminished and there was only a 25–50% increase in the rate of endocytosis, even in the presence of high concentrations of growth factors.These studies indicate that the influence of cell density upon fluid endocytosis in arterial smooth muscle cells is indirect in that it represents a secondary effect of decreased mitogenic response to specific growth factors.     

Redistribution and recycling of internalized membrane in seminal vesicle secretory cells

This study was performed to clarify the fate of membrane constituents internalized from the apical domain in secretory cells, in particular their possible recycling and the compartments involved in it. Glycoproteins of the apical membrane of seminal vesicle secretory cells from guinea-pig were covalently labeled in vitro (0°C, 20 min) with ³H-galactose and the epithelium incubated for 15 min (37°C, first incubation) to allow endocytosis. The label which was not internalized was then exposed to enzymatic hydrolysis (0°C, 30 min) and the epithelium re-incubated to allow membrane movement for 15 and 30 min (37°C, 2nd incubation). After each step of the protocol, tissue pieces were fixed and processed for electron microscope autoradiography and the results studied by morphometric analysis. Following labeling, 99% of the silver grains were associated with the apical domain of the cell membrane (AD). After the 1st incubation at 37°C, 30° of the grains were inside the cells in association with the cytoplasmic vesicles (Cyt ves), secretory vacuoles (SV), Golgi vesicles (GV), Golgi cisternae (GC), multivesicular bodies (MVB), lysosomes (LYS), and the cell membrane basolateral domain (BLD). About 58% of non-internalized radioactivity was removed by hydrolysis. During the 2nd incubation at 37°C the concentration of label increased in BLD and LYS, decreased in SV and MVB, and fluctuated in GC, GV and AD. The distribution of grains observed at 15 min, as compared using the χ-square test, was highly significantly different from that expected without recycling. The results show that cell membrane glycoproteins internalized at the cell apex recycle back to the membrane apical domain and are consistent with the involvement of GC and SV in the recycling pathway. Membrane shuttle between the apical and basolateral domains of the cell membrane is also suggested by these observations.     

beta-N-acetylglucosaminidase in the reproductive organs and seminal plasma of the bull

The highest specific activity of beta-N-acetylglucosaminidase (beta-NAG) was found in the different parts of the epididymis, where the activity seemed to be partly in secretory and partly in non-secretory, tissue-bound form. Epididymal spermatozoa also contained moderate beta-NAG activity. The beta-NAG was separated by chromatofocussing and anion exchange chromatography with HPLC into multiple forms with distinct pI values (8.0-4.0). The cauda epididymidis, ampulla and the seminal vesicles formed the major secretory sources of the high beta-NAG activity in bull seminal plasma. The major secretory forms of beta-NAG in caput and cauda epididymidis showed distinct elution profiles. In the fractionation with gel filtration on Sepharose 6B, the beta-NAG activities derived from bull testis and caput epididymidis had smaller molecular weights than did the secretory enzymes in seminal plasma, seminal vesicle secretion and cauda epididymidis. Maximum activity of all beta-NAG isoenzymes was observed at pH 5.0. They were almost totally inactivated at 60 degrees C and about 75-80% of the activity was lost at 55 degrees C. All the isoenzymes were strongly inhibited by thiol reagents but not with other metal ions and chelating agents. Histochemical studies showed a strong granular (lysosomal) reaction for beta-NAG in basal cells and basal parts of the principal cells in all but the initial segment of the epididymis. An apical (secretory) reaction was prominent in the distal caput and corpus as well as in distal cauda. After the distal caput the luminal sperm mass became increasingly mixed with a beta-NAG-positive material. The epithelial cells of the ampulla and seminal vesicle displayed a moderate apical (secretory) reaction.     

Characterization of glycoconjugates of guinea pig seminal vesicle by lectin histochemistry

In the present study, the expression of glycoconjugates in the guinea pig seminal vesicle was localized and partially characterized by lectin histochemistry using a battery of 30 different lectins specific for different carbohydrate residues. The results indicate that the glandular epithelium of the guinea pig seminal vesicle exhibits complex glycoconjugates rich in Man, -GlcNAc, -Gal, /-GalNAc, Fuc and complex NeuAc(2,6)Gal/GalNAc residues, as shown by its positive reactions to most lectins used. The Golgi region of the luminal secretory epithelial cells expresses a complex glycoconjugate pattern, as shown by its strong reactions to Man-(PSA, GNA), -GlcNAc-(S-WGA, PWA, DSA, UDA), -Gal- (RCA-I and -II), /-GalNAc-(SBA, Jac, VVA, BPA) and complex NeuAc-(SNA) specific lectins, indicating that the secretory epithelial cells are active in glycosylation and secretion process. It was also shown in the present study that the basal and luminal epithelial cells are different in their glycoconjugates. The basal epithelial cells are rich in NeuAc(2,3)Gal residues as they are stained specifically by MAA. The fibroblasts in the epithelial-smooth muscle interface and the smooth muscle cells close to the glandular epithelium are shown to express more glycoconjugates as they are stained intensely by GS-I-B4, GS-II and SBA. However, their role in the epithelial-stromal interaction in the seminal vesicle remains to be elucidated. In summary, the present study reports for the first time on the lectin binding patterns of the guinea pig seminal vesicle, and the results show that the seminal vesicle epithelium elaborates and secretes glycoconjugates in a complex pattern. Some of the lectins might be useful as histochemical markers for the secretory activity and specific structural components in the guinea pig seminal vesicle. © 1998 Chapman & Hall     

Radiosensitivity of mouse seminal vesicle cells which show proliferative response to androgen and estrogen

Injections of either androgen or estrogen have been shown to induce proliferation of epithelial cells in the seminal vesicle of castrated mice. Uptake of 5-[125I]iodo-2'-deoxyuridine [( 125I]IdUrd) by the whole seminal vesicle was used as an index for cell proliferation. Although uptake of [125I]IdUrd induced by androgen was about four times as great as that induced by estrogen, both values decreased with a similar pattern after irradiation. Uptake of [125I]IdUrd showed a dose-dependent decrease up to 1000 rad; the values remained unchanged until 4000 rad. Uptake of [125I]IdUrd by the radiosensitive cell population was calculated by subtracting [125I]IdUrd uptake attributable to the radioresistant cell population from total [125I]IdUrd uptake. Androgen- and estrogen-responsive cells were equally sensitive to irradiation. Recovery of androgen-responsive cells from radiation-induced decrease was examined with or without androgen stimulation. Although recovery occurred without androgen, it was significantly enhanced by androgen stimulation following irradiation. Irradiation seems useful for investigation of kinetic characteristics of epithelial stem cells in the seminal vesicle of mice.