Prostaglandin H synthase dependent metabolism of diethylstilbestrol by ram seminal vesicle cell cultures

Prostaglandin H synthase (PHS) peroxidase dependent metabolic activation has been suggested to play a role in mediating adverse effects of various carcinogens. Recently, we derived a cell line from ram seminal vesicles (SEMV cells) to conduct studies on the PHS-mediated metabolism of estrogens and xenobiotics in intact cells with the goal of relating this to an endpoint for genotoxicity inducible in this in vitro model. The present paper describes the drug-metabolizing capability of SEMV cells which has been investigated using radiolabeled diethylstilbestrol (DES) and analysing culture extracts by means of reverse phase HPLC with on-line radioactivity detection and after enzymatic hydrolysis of conjugate fractions. The synthetic estrogen DES is converted to sulfate conjugates and to the oxidative metabolite Z,Z-dienestrol (Z,Z-DIES) in a time-dependent manner. Compounds expected to modulate PHS-dependent co-oxidation of DES increased (arachidonic acid) or inhibited (indomethacin) Z,Z-DIES formation of SEMV cells in culture. A comparison of rates of arachidonic acid turnover to prostaglandins on the one hand and DES oxidation on the other reveals that DES is oxidized despite the presence of competing endogenous cosubstrates of PHS peroxidase. The results clearly indicate that SEMV cells catalyze PHS-dependent oxidation of DES as well as carrying out phase II metabolism in the absence of detectable monooxygenase activity. These features and recent data showing that DES can induce micronuclei in SEMV cells makes them an attractive model for further investigations of the role of PHS in mediating the genotoxicity of DES and other xenobiotics.

Accumulation of phosphocreatine and creatine in the cells and fluid of mouse seminal vesicles is regulated by testosterone

We have recently established that phosphocreatine (PCr), a high-energy phosphate compound known to serve as an intracellular energy reserve, accumulates in the seminal vesicular fluid (SVF) of the mouse and the rat. To investigate whether the accumulation of PCr in the extracellular fluid of the seminal vesicles of mice is androgen-dependent, young adult mice (Swiss Webster, 6-7 wk old) were orchidectomized. Involution of the seminal vesicles following orchidectomy resulted in the total absence of SVF. Administration of testosterone propionate (TP) 2 wk later at a daily dose of 5 micrograms/g b.w. caused a rapid increase in the weights of seminal vesicle tissue (SVT) and SVF and also increased the concentration of PCr in SVF. The concentration of PCr in SVF increased rapidly from 3.0 mumol/g on Day 2 to a peak value of 11.1 +/- 0.5 mumol/g on Day 6. The increase in PCr concentration in SVF coincided with the enhanced rate of secretion of specific proteins by androgen-responsive epithelial cells. The creatine (Cr) concentration in SVF also increased from 12.6 mumol/g on Day 2 to 41.1 +/- 4.6 mumol/g on Day 8. The concentrations of PCr in SVF of TP-treated mice were about twice those in the age-matched intact controls. The concentrations of PCr and of Cr in SVT also increased from 1.1 +/- 0.5 mumol/g and 1.7 +/- 0.8 mumol/g, respectively, on Day 0 to the steady-state levels of 5.3 +/- 0.7 mumol/g and 14.8 +/- 2.7 mumol/g by Day 8. These results demonstrate that the accumulation of PCr in the fluid of mouse seminal vesicle is regulated by androgen.

Identification of endogenous sugar-binding proteins in the accessory sex glands of NMRI mice. A histochemical and biochemical study

In the present study we report on the histotopographical distribution of carbohydrate-binding proteins in the prostate and seminal vesicle of sexually mature NMRI mice using a panel of fluorescein-isothiocyanate labelled neoglycoproteins and asialoglycoproteins. Additionally, biochemical analysis using affinity chromatography and SDS-gel electrophoresis was performed to purify and characterize the respective proteins from the tissue. Our histochemical results clearly demonstrate the presence of endogenous receptors for the carbohydrate part of glycoconjugates in both glands. In the prostate a distinct staining was seen after incubation with melibiose-BSA-FTC, glucuronic acid-BSA-FTC and asialofetuin-FTC (only in the ventral prostate). In the epithelium of the seminal vesicle a weak staining occurred after incubation with asialofetuin-FTC and maltose-FTC. In the stroma of both accessory sex glands a distinct binding of several (neo)glycoproteins specific for beta-galactoside-binding proteins was observed which could be attributed to a beta-galactoside-binding lectin. Indeed biochemical analysis ascertained presence of such a histochemically detectable activity. We assume that the carbohydrate-binding proteins of the stroma, which were obviously linked to the elastic fibers, could play a role in the organisation of the extracellular matrix in the interstitium of the glands.

Basal cells of H-Dunning tumor are myoepithelial cells. A comparative immunohistochemical and ultrastructural study with male accessory sex glands and mammary gland

Recent immunohistochemical studies have shown that basal cells in human prostatic epithelium are not myoepithelial cells. Since in the literature the Dunning tumor, originally described as a rat prostate carcinoma derived from the dorsolateral prostate of a Copenhagen rat, was reported to have myoepithelial cells, a comparative immunohistochemical and ultrastructural study was performed in the H-, HIF- and AT3-lines of the Dunning tumor, the male accessory sex glands (ventral, dorsal, lateral prostate, coagulating gland, bulbourethral gland) and the mammary gland of both Copenhagen and Wistar rats. Mono- and polyclonal antibodies directed against intermediate filament proteins (cytokeratin, desmin, vimentin) and the contractile proteins (alpha-actin, muscle type specific myosin, tropomyosin) were used along with phalloidin decoration of F-actin. As in the human prostate, none of the rat prostate lobes in either strains did contain basal cells expressing cytokeratin along with alpha-actin, myosin and tropomyosin Cells representing fully differentiated myoepithelial cells, however, were present as anticipated in the mammary gland, the bulbourethral gland and the H-tumor line of the Dunning tumor. This finding is difficult to reconcile with the contention of a prostatic origin of the H-Dunning tumor. Further studies are required to classify the epithelial parental tissue in order to define the true origin of the H-Dunning tumor and the tumor lines derived thereof.

[3H]thymidine uptake by the epididymis, seminal vesicles and prostate gland during postnatal development of the rat

The uptake of [3H]thymidine by the epididymis, ventral prostate gland and seminal vesicles was determined in vivo for rats aged 15, 20, 25, 30, 35, 45 and 55 days. The pattern of uptake varied considerably between organs and generally was different from patterns of growth measured as mass or ratio of mass of DNA:tissue. The 'initial segment' of the epididymis and caput and corpus epididymidis showed a similar pattern of [3H]thymidine uptake, being greatest in 15-day-old animals and declining thereafter. On Day 15 the cauda epididymidis had a lower uptake than more proximal regions of the epididymis, but it subsequently showed two significant peaks of increased uptake on Days 25-30 and Day 45. The uptake by the seminal vesicles was high on Day 15, fell to low levels on Day 20, increased considerably from Days 20 to 35, then gradually decreased from Day 35 to 55. The uptake by the prostate gland was a little lower than by the seminal vesicles on Days 15 and 20, then reduced to about the same level as non-reproductive tissues.

Complex carbohydrate histochemistry of the lateral prostate and seminal vesicle of the guinea pig

A systematic histochemical study of the complex carbohydrates of the lateral prostate and seminal vesicle of the guinea pig has been made. The complex carbohydrates of the guinea pig male accessory sex glands were partially characterized by various conventional carbohydrate histochemical methods including periodic acid-Schiff, selective periodate oxidation-Schiff reaction, Alcian blue staining at pH 2.5 and 1.0, and high iron diamine. The results indicated that neutral glycoconjugates with 1,2-glycol groups and sialic acids were present in the luminal border and apical cytoplasm of the glandular cells, basement membrane and connective tissue in the lamina propria of the lateral prostate. Similar patterns were demonstrated in the seminal vesicle except that there were relatively fewer or no neutral carbohydrates in the apical cytoplasm of the vesicular epithelial cells. The epithelial basement membrane and connective tissue at the epithelial-stromal interface of both glands were rich in acidic and sulphated glycosaminoglycans. Partial characterization by bovine testicular hyaluronidase indicated the presence of chondroitin sulphates in the lamina propria of the glands.

Postnatal growth of mouse seminal vesicle is dependent on 5 alpha-dihydrotestosterone

The seminal vesicles (SV) develop from the lower portion of the Wolffian ducts (WD) in response to androgens, which prevent their degeneration and subsequently stimulate organogenesis of the epididymis, vas deferens, seminal vesicles, and ejaculatory ducts. Earlier studies suggest that testosterone (T) is the active androgen for WD development. By contrast, development of urogenital sinus and external genitalia is dependent upon 5 alpha-dihydrotestosterone (DHT), produced by 5 alpha-reductase within the target tissue itself. To reevaluate the possible role of DHT during SV morphogenesis, SVs from 0-day-old (day of birth) mice were grown for 3, 6, or 9 days in either serum-free or serum-containing medium in the presence or absence of T (10(-7) M) or DHT (10(-8) M). The serum-free medium consisted of Ham's F-12-Dulbecco's Modified Eagle's Medium (1:1) containing insulin, transferrin, cholera toxin, BSA, and epidermal growth factor. The serum-containing medium was Ham's F-12-Dulbecco's Modified Eagle's Medium containing 10% fetal calf serum. Epithelial branching morphogenesis of SVs occurred in serum-free or serum-containing medium supplemented with either T or DHT and was comparable to that of SVs of similar ages in vivo. In serum-containing medium the DNA content of the cultures was about 2-fold higher in T-containing vs. T-deficient medium. However, in serum-free medium the DNA content was the same in cultures grown with or without T. SVs cultured under serum-free conditions in the presence of T plus 390 MSD (17 beta-N,N-diisopropylcarbamoyl-4-aza-5 alpha-androstan-3-one, an inhibitor of 5 alpha-reductase) were completely inhibited in their development, while in the presence of DHT plus 390 MSD, branching morphogenesis was comparable to that in SVs cultured in the presence of T or DHT alone. In medium lacking either T or DHT, SV development was inhibited. In addition, it was confirmed by TLC that [1 beta,2 beta-3H]T was converted into [3H]DHT at the ratio of 15.4% for the first 2 days and at 35.3% for the subsequent 2 days of the culture of SVs in serum-free medium. These data demonstrate that T is important as a precursor of DHT and DHT is the major androgen in the postnatal development of mouse SVs from the lower WD.

Time course of quantitative morphological changes of the autophagic-lysosomal compartment of murine seminal vesicle epithelial cells under the influence of vinblastine

Changes of the autophagic-lysosomal compartment (ALC) of the murine seminal vesicle epithelial cells were monitored by electron microscopic morphometry during 36 h following a single 10 mg/kg bw dose of vinblastine sulfate (VBL), a widely used tool to cause an accumulation of the autophagic vacuoles (AVs). Three morphologically distinct subcompartments of the ALC, i.e. early autophagic vacuoles (AV1) being presumably prelysosomal autophagosomes, advanced AVs (AV2) containing material under degradation and dense bodies (DB) were defined. The ALC and its subcompartments expanded after VBL in a two-phase reaction. The first subcompartments to react significantly were AV1 and AV2 (at 30 min) followed by DBs with a 30 min delay. The ALC then ceased to grow until the 90th min when a second expansion phase started peaking around 8 h with a cytoplasmic volume fraction 15 times larger than in the untreated control. This second growth was entirely brought about by the expansion of the two AV subcompartments. After 8 h the volume fraction of both AV1 and AV2 decreased to cause a gradual regression of the ALC. AV1, however, already ceased to expand as early as after 6 h, i.e. during the last 2 h of the expansion phase of the ALC. Comparison of this time curve with the one we previously measured in mouse liver shows considerable differences between the two cell types. The growth curves of the AV subcompartments in our experiment along with others' kinetic data obtained in steady state cells not treated with VBL show that segregation (= formation of AV1) is possibly stimulated by VBL in our system.

Localization and regulation of estrogen, progestin and androgen receptors in the seminal vesicle of the rhesus monkey

We have used monoclonal antibodies against the estrogen (E), progestin (P) and androgen (A) receptors (R) to study receptor localization and regulation in the seminal vesicles of rhesus monkeys under different hormonal conditions. The antibodies caused substantial shifts of the appropriately labeled receptors on sucrose gradients. ER levels were lower in intact males than in immature, castrate, and estrogen-treated castrates. With immunocytochemistry, ER were detectable only in stromal and smooth muscle cells, not the epithelium. The number of ER-positive stromal cells was significantly lower in intact males than in immature, castrate, and estrogen-treated castrates, and low in a DHT-treated castrate animal. Androgen receptors were localized in epithelial as well as stromal and smooth muscle cells, and the number of AR-positive stromal cells was highest in intact adults and lowest in castrated and immature animals. Estrogen treatment at the time of castration induced PR in the ER-positive stromal cells, prevented a decline in the number of AR-positive stromal cells, and caused stromal hypertrophy. In summary, in the seminal vesicle, as in the prostate, ER is restricted to the fibromuscular stroma, is suppressed by androgens, and can mediate induction of PR on estrogen treatment. Androgen receptors are present in epithelial as well as stromal and smooth muscle cells, but variations in hormonal state appear to affect regulation of AR more in the stroma than the epithelium.

Localization of metallothionein in the genital organs of the male rat

We studied the immunohistological localization of metallothionein (MT), a low molecular weight metal binding protein, in male rat genital organs (testis, epididymis, ejaculatory duct, seminal vesicle, coagulating gland, and prostate) by use of the avidin-biotin-peroxidase complex method. MT concentrations in testis, seminal vesicle, and prostate ranged from 15-30 micrograms/g tissue. In testis, seminiferous tubules with mature spermatozoa exhibited weak MT staining, whereas the tubules containing differentiating spermatogenic cells but not containing spermatozoa showed strong MT staining. No MT immunostaining was observed in Leydig cells. In growing rat testes, the pattern of MT immunostaining was found to change with development: MT was found in supporting cells only on Day 7, spermatogonia adjacent to basement membrane on Day 14, and spermatocytes localized in the central part of the tubules on Day 21. Strong MT immunostaining in the basal cells was a common feature in other genital tissues, except the ductus efferentes. In prostate, the strongest MT staining was found in the lateral lobe, and MT was localized in apocrine secretions in the dorsal lobe. The present results suggest a close association of MT with cell proliferation and differentiation, as well as possible involvement of MT in supply or storage of zinc ions.

Androgens affect the processing of secretory protein precursors in the guinea pig seminal vesicle. II. Identification of conserved sites for protein processing

The guinea pig seminal vesicle epithelium is an androgen-dependent tissue that synthesizes and secretes four major secretory proteins (SVP-1, SVP-2, SVP-3, and SVP-4). Sequencing of near full-length cDNA clones corresponding to the two most abundant mRNAs produced by the seminal vesicle reveals that all four secretory proteins are cleaved from two secretory protein precursors. Amino acid sequences from purified SVP-2 match the central region of the predicted amino acid sequences from the smaller cDNA clone, GP2 (581 nucleotides). Similar analysis demonstrates that the predicted amino acid sequence from the longer cDNA clone, GP1 (1368 nucleotides), codes for the related proteins SVP-3 and SVP-4 as well as SVP-1. The 43.2 kilodalton polyprotein precursor coded by GP1 contains two different sets of 24 amino acid tandemly repeated sequences. The two secretory protein precursors have extensive regions of peptide sequence homology, particularly in regions where protein processing must occur to produce the mature secretory proteins. Analysis of the predicted secondary structure of the two precursor polypeptides revealed a strong correlation between structural features and sites of protein processing.

Androgens affect the processing of secretory protein precursors in the guinea pig seminal vesicle. I. Evidence for androgen-regulated proteolytic processing

The guinea pig seminal vesicle epithelium synthesizes and secretes four major secretory proteins (SVP-1-4). Previous work has established that these four proteins are cleaved from two primary translation products in a complex series of protein processing reactions. The present studies suggest that these protein processing reactions are regulated by androgens. In vitro labeling of seminal vesicle proteins revealed significant differences in the patterns of secretory protein intermediates produced by tissue from intact and castrated animals. Seminal vesicle tissue explants from castrated animals secreted a subset of the processing intermediates secreted by tissue from intact animals. The changes in the patterns of secretory protein intermediates became more pronounced with increasing time after castration, and were fully reversible by treatment of castrated animals with testosterone, suggesting that androgens were affecting the processing or secretion of secretory protein precursors. Amino-terminal protein sequencing of secretory protein processing intermediates that accumulate in the seminal vesicle lumen after castration suggests that the guinea pig seminal vesicle contains an androgen-regulated proteolytic processing activity.

Roles of prepubertal androgen, estrogen or androgen plus prolactin on androgen-induced proliferative response of seminal vesicles in adult mice

Male mice castrated on day 0 after birth were pretreated daily with testosterone propionate (TP, 4 micrograms/g body weight), 17 beta-estradiol (E2, 0.2 micrograms/g body weight) or vehicle for 21 days starting from day 20. In another experiment, male mice were castrated on day 25; two pituitaries from 60-day-old females were immediately grafted under the capsule of the left kidney in one group. The castrated mice with or without grafts were pretreated daily with TP (4 or 20 micrograms/g body weight) for 36 days starting from day 25, and the left kidney was removed on day 60. Daily TP injections (4 micrograms/g body weight) were started again at 30 days after the end of pretreatments to examine androgen-induced proliferation, and incorporation of 5-[125I]iodo-2'-deoxyuridine into the whole seminal vesicles was used as an index of proliferation. In the neonatally castrated mice, both TP and E2 pretreatments given during the prepubertal period significantly increased seminal vesicle weight even long after the end of the pretreatments. However, androgen-induced proliferative response found in the neonatally castrated adult mice (poor response; long duration with a low peak) was changed to that found in mice castrated at adulthood (good response; short duration with a high peak) by the TP pretreatment only but not at all by the E2 pretreatment. In the mice castrated on day 25, a pharmacological dose of TP or TP plus hyperprolactin could not enhance or change the adult castration type of androgen-induced proliferation induced by physiological prepubertal androgens, although both treatments significantly enhanced the prepubertal growth of the seminal vesicles.

Effect of androgen pretreatments at adulthood on androgen-induced proliferative response of seminal vesicles in neonatally castrated mice

Male mice were castrated on days 0 and 60 after birth. The majority of the neonatally castrated mice were pretreated with androgen; the mice were given daily injections of testosterone propionate (TP; 4 or 8 micrograms/g body wt) for 20 or 30 days starting from day 60. Daily injections of TP (4 micrograms/g body wt) to examine androgen-induced proliferation were started from day 30 or 60 after the end of TP pretreatments or from day 60 after castration; on various days after starting TP injections, the weight and the incorporation of 5-[125I]iodo-2'-deoxyuridine into the whole seminal vesicles were determined as indices for proliferation. The seminal vesicles of neonatally castrated adult mice were characterized by long duration of androgen-induced proliferation (greater than 20 days) with a low peak (neonatal castration type), whereas the seminal vesicles of adult castrated mice were characterized by short duration of proliferation (10 days) with a high peak (adult castration type). In neonatally castrated adult mice, the neonatal castration type of androgen-induced proliferation was changed largely to the adult castration type when pretreatment with 8 micrograms/g body wt of TP had been given for 30 days. However, this effect gradually disappeared when the mice had been pretreated with decreasing amounts of TP for a shorter period. The present findings suggest that the defect in the androgen-induced proliferative response of mouse seminal vesicles induced by the absence of neonatal and prepubertal testicular androgens can be compensated by androgens given in adulthood, if enough androgen is given for a sufficiently long time.

Structure and steroidogenic enzymes of the seminal vesicles of the urohaze-goby (Glossogobius olivaceus)

The in vitro steroid metabolism in the seminal vesicles of the brackish water goby (urohaze-goby, Glossogobius olivaceus) was studied using males in the breeding season. The moderate activity of delta 5-3 beta-hydroxysteroid dehydrogenase was histochemically detected only in the epithelial cells of the organ, though these cells have the characteristics of secretory cells ultrastructurally. Cell-free homogenates (800 g supernatant fluid) of the whole tissue were aerobically incubated with 14C-labeled pregnenolone, progesterone, 17 alpha-hydroxyprogesterone, androstenedione, dehydroepiandrosterone, or testosterone in the presence of NAD+ or NADPH. Pregnenolone and dehydroepiandrosterone were converted to progesterone and androstenedione, respectively. Progesterone was transformed to 5 alpha-pregnane-3,20-dione (main product) and 17 alpha-hydroxyprogesterone. 17 alpha-Hydroxyprogesterone was metabolized into androstenedione (main product) and 17 alpha-hydroxy-5 alpha-pregnane-3,20-dione. From androstenedione, 5 alpha-androstane-3,17-dione (main product) and epiandrosterone were obtained. Testosterone was transformed to 5 alpha-dihydrotestosterone, 5 alpha-androstane-3 beta, 17 beta-diol, 5 alpha-androstane-3,17-dione, and androstenedione. These results indicate that the steroid metabolic patterns in the seminal vesicles of G. olivaceus are closely resembled to those in the testes.

Induction of functional cytodifferentiation in the epithelium of tissue recombinants. I. Homotypic seminal vesicle recombinants

Functional cytodifferentiation of seminal vesicle epithelium was investigated in tissue recombinants. Neonatal rat and mouse seminal vesicles were separated into epithelium and mesenchyme using trypsin. Epithelium and mesenchyme were then recombined in vitro to form interspecific rat/mouse homotypic recombinants. Growth as renal grafts in adult male athymic mice resulted in seminal vesicle morphogenesis in 70% of the recombinants (the remaining 30% failed to grow). Functional cytodifferentiation was judged by the expression of the major androgen-dependent secretory proteins characteristic of the seminal vesicles of adult rats and mice. Antibodies specific for each of these proteins were used to screen tissue sections by immunocytochemistry and to probe protein extracts by immunoblotting techniques. The heterospecific recombinants synthesized the full range of seminal vesicle secretory proteins that typifies the species providing the epithelium of the recombinant, not the mesenchyme. There was little functional variation between individual recombinants. The time course of development corresponded to that of intact neonatal seminal vesicles grown under the same conditions. Morphogenesis and functional cytodifferentiation were not evident after one week, but were well advanced after two weeks. Seminal vesicle recombinants grown for three weeks were indistinguishable morphologically and functionally from normal adult seminal vesicles. In addition, the ability of adult seminal vesicle epithelium to be induced to proliferate was examined. In association with neonatal seminal vesicle mesenchyme, the epithelium of the adult seminal vesicle proliferated and retained its normal functional activity. Thus, seminal vesicle functional cytodifferentiation can be faithfully reproduced in homotypic tissue recombinants. The methods used in this study will be used to investigate seminal vesicle development in instructive inductions of heterotypic epithelia.

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.

Phosphocreatine, an intracellular high-energy compound, is found in the extracellular fluid of the seminal vesicles in mice and rats

High levels of phosphocreatine, a compound known to serve as an intracellular energy reserve, were found in the fluid contained in seminal vesicle glands. The concentrations of phosphocreatine in the extracellular fluid in the mouse and rat were found to be 5.6 +/- 1.6 and 2.2 +/- 0.8 mumol/g, respectively, which are higher than the intracellular levels reported for smooth muscles. The creatine concentrations in the seminal vesicular fluid from these two species were 22.8 +/- 3.1 and 13.0 +/- 5.3 mumol/g, respectively. These creatine levels are approximately 100 and 65 times higher than the creatine levels in mammalian blood. Smaller amounts of ATP (phosphocreatine/ATP ratio of 20-40) and traces of ADP were also found. Comparison of the pattern of distribution of macromolecules (proteins and DNA) with the distribution of phosphocreatine between the cells and the fluid of the seminal vesicle indicates that cell lysis did not account for the phosphocreatine in the seminal vesicle fluid. Rather, the available evidence strongly suggests that this high-energy compound is actively secreted. We found that in the testes, the sperm are exposed to the highest known creatine concentration in any mammalian tissue studied. Based on these results and other recent reports, we propose that the extracellular phosphocreatine, ATP, and creatine are involved in sperm metabolism.

Proliferative response of seminal vesicle cells to androgen in mice castrated neonatally and pretreated with estrogen or androgen at adulthood

Seminal vesicle cells of neonatally castrated adult mice show poor response to androgen, compared to those of mice castrated at adulthood; effects of pretreatment with androgen or estrogen at adulthood on androgen-induced proliferation of the seminal vesicle cells were examined in neonatally castrated mice. Male mice castrated at day 0 after birth were pretreated with daily injections of testosterone propionate (TP, 100 micrograms/mouse), 17 beta-estradiol (E2, 5 micrograms/mouse) or vehicle for 20 days starting from day 60; daily TP injections (100 micrograms/mouse) for 30 days were started again from day 110 in all the pretreated mice to examine androgen-induced proliferation by incorporation of 5-[125I]iodo-2'-deoxyuridine into the whole seminal vesicles. Both TP and E2 pretreatments significantly increased the seminal vesicle weight found before TP treatment. However, androgen-induced proliferation of the seminal vesicle found in neonatally castrated mice (poor response; long duration with a low peak on day 3) was changed at least in part to that found in mice castrated at adulthood (good response; short duration with a high peak on day 3) only following the TP pretreatment but not at all following the E2 pretreatment. The E2 pretreatment induced poor androgen-induced proliferation with a low peak on day 7.

Regression of autophagic vacuoles in pancreatic acinar, seminal vesicle epithelial, and liver parenchymal cells: a comparative morphometric study of the effect of vinblastine and leupeptin followed by cycloheximide treatment

Treatment of mice with both leupeptin (0.06 mg/g body wt) and vinblastine (0.05 mg/g body wt) for 2 h caused a many-fold enlargement of the autophagic-lysosomal compartment of pancreatic acinar, seminal vesicle epithelial, and liver parenchymal cells. In all three types of cells a predominance of large, dense bodies was seen after leupeptin treatment and that of typical autophagic vacuoles were seen after vinblastine treatment. An exponential decrease of the volume fraction of autophagic vacuoles was observed in leupeptin-treated cells after the administration of cycloheximide (0.2 mg/g body wt). The half-life of autophagic vacuoles estimated from the decay curve was 5.3, 5.7, and 6.6 min for pancreatic, seminal vesicle, and liver cells, respectively. Our data suggest that sequestered cytoplasmic material rapidly enters the lysosomes in leupeptin-treated cells and accumulates in this compartment. In contrast, no regression of the autophagic vacuole compartment of pancreatic and seminal vesicle cells was observed after the administration of cycloheximide to animals pretreated with vinblastine, and only a slight decrease was seen in liver cells. These observations show that the lifetime of autophagic vacuoles is prolonged by vinblastine resulting in their accumulation in the cells. However, our measurements also lend support to the view that in addition to the accumulatory effect on undegraded cytoplasmic material, stimulation of sequestration may play a role in the enlargement of the autophagic lysosomal compartment after treatment with leupeptin as well as with vinblastine in all three types of cells investigated.

Induction of precocious maturation of spermatogenesis in infant rats by human menopausal gonadotropin and inhibition by simultaneous administration of gonadotropins and testosterone

This study was undertaken to determine if the initiation of spermatogenesis could be modified by the administration of gonadotropins and sex hormones in infant rats. Five-day-old rats were injected daily between the 5th and 11th days of life with test substances and killed on day 15. Administration of testosterone propionate (TP; 2.5 mg daily), human menopausal gonadotropin (hMG; 7.5 IU daily), or coadministration of both of these substances (TP + hMG) or administration of estradiol benzoate (15 micrograms daily) caused quantitative changes in premeiotic spermatogenesis, as measured by the mean cell counts per tubule cross-section. hMG caused an increased yield of type A1 spermatogonia (SgA1) from undifferentiated type A spermatogonia (UnA) and increased the yield of type B spermatogonia from SgA1. TP was not effective in stimulating first premeiotic spermatogenesis, and in contrast to hMG, it had a negative influence on the numbers of UnA and SgA1 and on the volume of Sertoli cell nucleus. Administration of TP + hMG or estradiol benzoate resulted in a significant increase in the numbers of UnA and SgA1, but inhibited cell differentiation. TP + hMG significantly reduced the rate of premeiotic spermatogenesis. The results demonstrate that precocious numerical stabilization of premeiotic spermatogenesis can be achieved by the application of hMG. TP applied alone was able to induce peripheral androgenic effects (seminal vesicle weight) 100% greater than those produced by administration of hMG, but was not able to stimulate seminal tubule function. TP applied together with hMG produced inhibition of spermatogenesis. This effect might be due to the inhibition of Sertoli cell function by the direct influence of testosterone. In contrast to testosterone, estradiol may play a stimulatory role in the multiplication of the reserve stem cells of the first spermatogenesis of the rat.

Scanning-electron-microscopical study of the seminal vesicle, coagulating gland, ampullary gland and ventral prostate in the golden hamster

A study of the internal surfaces of the seminal vesicle, coagulating gland, ampullary gland and ventral prostate of the golden hamster was carried out by scanning electron microscopy. The internal surface of each of these glands was found to display characteristic features in topography and in arrangements of the microvilli. The features are useful in the identification of these glandular tissues in situ.

Growth of rat seminal vesicle epithelial cells in culture: neurotransmitters are required for androgen-regulated synthesis of tissue-specific secretory proteins

Epithelial cells from enzymically dispersed seminal vesicle tissue of castrated adult rats were grown on collagen-coated surfaces in serum-containing medium for up to 6 weeks. Androgens were neither required for growth nor were they mitogenic. They also failed to induce the synthesis of tissue-specific secretory proteins that serve as markers of androgen action in vivo. A variety of potential growth factors and culture procedures (such as feeder layers, extracellular matrices, collagen gels, and growth from tissue explants) were examined for their ability to support androgen action. Testosterone and 5 alpha-dihydrotestosterone were only able to induce seminal vesicle secretory protein synthesis in the presence of neurotransmitters (acetylcholine, noradrenaline, or serotonin). The mechanism of this permissive effect of neurotransmitters on androgenic induction has been examined. It is not related to their mitogenic activity since other mitogens (epidermal growth factor and corticosterone) did not facilitate androgen action. Agents that raise intracellular cAMP were also ineffective so cAMP is probably not involved, but the phosphatidyl inositol pathway may be important.