Multiple regulation of testicular steroidogenesis

One single injection of ethylene dimethane sulfonate (EDS) to mature rats causes specific degeneration of testicular Leydig cells which is complete after 3 days. At this time no steroidogenic activities can be detected, indicating that Leydig cells are the source of steroids. The mechanism of this cytotoxic effect of EDS has been investigated with isolated cells. Extensive protein alkylation has been shown to occur in Leydig cells, Sertoli cells and hepatocytes. Steroid production by Leydig cells is always inhibited by EDS, but cytotoxic effects of EDS could only be demonstrated in Leydig cells from mature rats or tumour tissue and not in Leydig cells from immature rats. A new population of Leydig cells develops during the next 2-5 weeks after EDS treatment. In hypophysectomized rats this repopulation only occurs when hCG is given daily. FSH has no effects. The proliferative activity in the interstitial tissue increases within 2 days after administration of hCG or EDS and there are indications that LH and locally produced factors are involved in the proliferation of Leydig cells or Leydig cell precursor cells. Inhibition of cAMP production with inhibitors of adenylate cyclase results in an enhancement of the LH-stimulated steroid production similar to that observed with an LHRH agonist and phospholipase C (PLC). Since the effects of LHRH and PLC on protein phosphorylation and steroid production are similar and different from LH or active phorbol esters, it is proposed that LHRH and PLC may stimulate steroid production via liberation of calcium from a specific intracellular pool. Sterol carrier protein2 (SCP2) which is specifically localized in Leydig cells and regulated by LH probably plays a role in the delivery of cholesterol to the mitochondria although the mechanism of this carrier function is not clear. The results indicate that regulation of Leydig cell development and the steroidogenic activities by gonadotrophins and locally produced factors occur via different transducing systems and regulatory pathways.     

Sterol carrier protein 2 (non-specific lipid transfer protein) is localized in membranous fractions of Leydig cells and Sertoli cells but not in germ cells.

The cellular and subcellular distribution of sterol carrier protein 2 (SCP2; nsL-TP) was reinvestigated in rat testicular cells by Western blotting and immunocytochemistry, using the affinity purified antibody against rat liver SCP2. Western blot analysis revealed high levels of the protein in the somatic cells of the testis, e.g., Leydig and Sertoli cells whereas it could not be detected in germ cells. This cellular localization of SCP2 was confirmed by Northern blotting. Immunocytochemical techniques revealed that in Leydig cells, immunoreactive proteins were concentrated in peroxisomes. Although SCP2 was also detected in Sertoli cells, a specific subcellular localization could not be shown. SCP2 was absent from germ cells. Analysis of subcellular fractions of Leydig cells showed that SCP2 is membrane bound without detectable amounts in the cytosolic fraction. These results are at variance with data published previously which suggested that in Leydig cells a substantial amount of SCP2 was present in the cytosol and that the distribution between membranes and cytosol was regulated by luteinizing hormone. The present data raise the question in what way SCP2 is involved in cholesterol transport between membranes in steroidogenic cells but also in non-steroidogenic cells.     

Differences between the regulation of cholesterol side-chain cleavage in Leydig cells from mice and rats

A Leydig cell culture system has been used to study the in vitro modulation by luteinizing hormone (LH) of steroidogenesis in Leydig cells isolated from mice and immature rats. Mouse Leydig cells precultured for 24 h in the presence of increasing concentrations of LH (1 ng-1 microgram/ml) showed a dose-dependent decrease of the maximal LH-stimulated testosterone production. After pretreatment with 1 microgram LH/ml, maximal LH-stimulated testosterone production. After production in the presence of excess 20 alpha-hydroxycholesterol (a cholesterol side-chain cleavage substrate) were reduced to approx. 50% of control values. The possible site of action of LH is probably prior to pregnenolone, because testosterone production in the presence of excess pregnenolone was not affected by the LH pretreatment. Immature rat Leydig cells showed no decrease of maximal steroid production after 24 h culture in the presence of 1 microgram LH/ml. These results indicate that the regulation of the cholesterol side-chain cleavage activity during long-term LH action is different in mouse and rat Leydig cells. The properties of the cholesterol side-chain cleavage enzyme in mouse and rat Leydig cells were further investigated with different hydroxylated cholesterol derivatives as substrates. Steroid production by mouse Leydig cells in the presence of (22R)-22 hydroxycholesterol was similar as in the presence of LH. In contrast, steroidogenesis in rat Leydig cells in the presence of (22R)-22 hydroxycholesterol was at least 10-fold higher than in the presence of LH. It is concluded that the cholesterol side-chain cleaving enzyme in the mouse Leydig cell operates at its maximal capacity during short-term LH stimulation and can be inhibited after long-term LH action, whereas in the rat Leydig cell only a fraction of the potential activity is used during short-term LH stimulation, which is not affected during long-term LH action.     

The aging Leydig cell: 2. Two distinct populations of Leydig cells and the possible site of defective steroidogenesis

Using metrizamide gradient centrifugation two populations of Leydig cells were found in both 60-90 day-old and 24 month-old rats. Cells from both Band 2 (B2) and Band 3 (B3) responded to LH stimulation with increased cyclic AMP formation; however, only B3 cells produced significant amounts of testosterone. Cells from both B2 and B3 of the old rats synthesized less cyclic AMP and testosterone than cells from their younger counterparts. In response to LH stimulation, 0.01 - 1.0 mIU/ml, no appreciable difference of cyclic AMP formation could be detected between young and old Leydig cells. Maximal testosterone production occurred when 1 mIU/ml LH was used. Only when LH concentration was increased to 10 and 100 mIU/ml, did young Leydig cells produce significantly more cyclic AMP than old Leydig cells. After addition of 5X10(-7)M of pregnenolone or progesterone to the incubation medium, both young and old Leydig cells produced comparable amounts of testosterone. These results demonstrate no impairment of old rat Leydig cells to synthesize testosterone from pregnenolone and progesterone.     

Are polyphosphorylated phospholipids involved in the hormonal control of cholesterol side-chain cleavage activity in tumour Leydig cells?

The possible role of LH or dcAMP induced changes in polyphosphorylated phospholipid metabolism in the regulation of cholesterol side-chain cleavage activity has been studied in tumour Leydig cells. Mitochondria isolated from LH-stimulated Leydig cells were 400% more active in pregnenolone production than mitochondria from control cells. Steroid production in isolated mitochondria from control cells could be stimulated only 25% by cytosol fractions from stimulated cells and 100 microM phosphatidyl inositol-4'-phosphate (PtdIns4P). Other polyphosphorylated phospholipids were either inactive or showed aspecific effects. During a preincubation period tumour cells were labelled with [32P]phosphate and steady-state labelling was obtained for the pholyphosphorylated phospholipids after 40-60 min. [32P]Phosphate incorporation in Ptd Ins4P, phosphatidyl inositol (PtdIns), phosphatidyl choline (PtChl), phosphatidyl ethanolamine (PtdEtn) and cardiolipin (CL) was not affected by treatment of the Leydig cells with LH which stimulated (6-fold), or with cycloheximide which suppressed (4-fold) steroid production. A 25% increase of phosphate incorporation by LH was observed only in phosphatidyl inositol-4',5'-biphosphate (PtdIns4,5P2). 32P Incorporation in PtdIns4,5P2, PtdIns,PtdEtn and CL was stimulated by quinacrine 50 microM. Under these conditions the LH-stimulated pregnenolone production but not the 25-hydroxycholesterol dependent pregnenolone production, was completely inhibited. The results obtained with isolated mitochondria and intact cells indicate that increased levels of polyphosphorylated phospholipids are not consistently correlated with increased mitochondrial pregnenolone production. This argues against an important role of polyphosphorylated phospholipids in the hormonal regulation of cholesterol side-chain cleavage activity in tumour Leydig cells.     

An oestrogen-producing seminoma responsible for gynaecomastia.

In feminising testicular tumours, oestrogens can be either secreted by the tumour itself or produced by normal Leydig cells in response to paracrine and/or endocrine stimulation by hCG. Typical hormonal Leydig cell tumour patterns include: plasma oestradiol levels > 300 pmol/l on day 3 following an hCG injection, reduced plasma testosterone, and normal plasma hCG and gonadotrophin levels. Except for elevated plasma oestradiol levels, opposite results are observed in seminomas. We report a case of oestrogen-secreting seminoma mimicking a Leydig cell tumour. A 24-year-old Caucasian patient had complained of gynaecomastia for 6 months before admission. Hormonal pattern was typical of Leydig cell tumour. A 1.4 cm tumour was found in the left testis and confirmed on sonography. Considering the likely diagnosis of Leydig cell tumour, the patient was treated by tumourectomy. Surprisingly, pathological examination revealed a pure seminoma. Perifusion experiments showed that the tumour was able to secrete significant amounts of oestradiol. In addition, hCG induced a two-fold increase in oestradiol production from perifused tumour explants. Immunohistochemistry revealed that the tumour was composed of nests of seminoma cells intermingled with lymphoid infiltrates. Tumour cells also expressed aromatase, the hCG/LH receptor and the Leydig cell marker relaxin-like factor, but were betahCG-negative. These results demonstrate that a pure seminoma of the testis is able to synthesise and secrete oestrogens. They also illustrate that the body of proof favouring the diagnosis of feminising Leydig cell tumour of the testis is not rigorously specific.     

Hormonal regulation of androgen production by the Leydig cell

The control of androgen production by the Leydig cell is dependent upon the episodic secretion of hormone (LH), which is released from the anterior pituitary gland in pulses of high biological activity. This mode of episodic LH secretion supports steroidogenic enzyme activity in the testis through interaction with LH receptors and stimulation of the adenylate cyclase/protein kinase sequence, leading to phosphorylation of key intermediates in the steroid biosynthetic pathway. The plasma membrane events that are rapidly activated by the specific interaction of LH or hCG with Leydig cell receptors include increased binding of guanyl nucleotide, and stimulation of cAMP-independent, Ca²⁺dependent phosphorylation of a 44,500 Mr protein, with the characteristics of the adenylate cyclase nucleotide regulatory unit. Hormonal activation of adenylate cyclase is affected by Ca²⁺ with the same concentration-dependence, suggesting that nucleotide-induced phosphorylation is related to activation of the catalytic cyclase unit.In addition to the characteristic increases in pregnenolone synthesis and androgen production, gonadotropin-stimulated Leydig cells show prominent changes in LH receptor content and steroidogenic activity that modify their subsequent responses to hormonal signals. Thus, after exposure to increased LH and hCG levels in vivo and in vitro, LH receptors show an initial transient increase (up-regulation) followed by a marked decrease (down-regulation) and a prolonged depletion of LH receptor sites. Large doses of hCG cause “early” (prior to pregnenolone) and “late” steroidogenic lesions (17α-hydroxylase, 17–20 desmolase) that are independent of receptor loss. The early lesion is partly due to reduced activity of HMG CoA reductase, and is mainly attributable to the increased activity of an inhibitory protein factor that modulates the activity of cholesterol side chain cleavage enzyme in Leydig cell mitochondria. In contrast, the late steroidogenic lesion is related to the nuclear actions of E₂ produced during hormonal action. After hCG stimulation, an increase in nuclear E₂ binding was accompanied by an early rise of RNA polymerase activities within 45 min coincident with the maximal increases in circulating testosterone and estradiol levels. These events were followed by the emergence of an E₂-induced protein of Mr 27,000 at 3–6 h, and by reduction in the activity of 17α-hydroxylase/17–20 desmolase, and a decrease in microsomal cytochrome P-450. The negative effects of LH upon receptors and steroidogenic responses appear to be characteristic of the adult Leydig cell, and do not occur in the immature or fetal Leydig cell, where only up-regulation was demonstrated in vivo or in vitro. The temporal and functional nature of the steroidogenic lesions provide further insight into the intracellular control mechanisms that regulate the androgen biosynthetic pathways of the mature Leydig cell.     

Characterization of the homologous and heterologous desensitization of rat Leydig-tumour-cell adenylate cyclase.

The homologous and heterologous desensitization of rat Leydig-tumour-cell adenylate cyclase induced by lutropin (LH) was characterized with the aid of forskolin and cholera toxin. Forskolin stimulated cyclic AMP production in a dose-dependent manner, with linear kinetics up to 2h. Forskolin also potentiated the action of LH on cyclic AMP production, but was only additive with cholera toxin. Preincubation of rat Leydig tumour cells with LH (1.0 micrograms/ml) for 1 h produced a desensitization of the subsequent LH (1.0 micrograms/ml)-stimulated cyclic AMP production, whereas the responses to cholera toxin (5.0 micrograms/ml), forskolin (100 microM), LH plus forskolin or cholera toxin plus forskolin were unaltered. In contrast, preincubation with LH for 20h produced a desensitization to all the stimuli tested. When rat Leydig tumour cells were preincubated for 1h with forskolin or dibutyryl cyclic AMP, the only subsequent response that was significantly altered was that to LH plus forskolin after preincubation with forskolin. However, preincubation for 20h with forskolin or dibutyryl cyclic AMP induced a desensitization to all stimuli subsequently tested. LH produced a rapid (0-1h) homologous desensitization, which was followed by a slower (2-8h)-onset heterologous desensitization. Forskolin and dibutyryl cyclic AMP were only able to induce heterologous desensitization. The rate of desensitization induced by either forskolin or dibutyryl cyclic AMP was similar to the rate of heterologous desensitization induced by LH. These results demonstrate that in purified rat Leydig tumour cells LH produces an initial homologous desensitization of adenylate cyclase that involves a cyclic AMP-independent lesion at or proximal to the guanine nucleotide regulatory protein (G-protein). This is followed by heterologous desensitization, which can also be induced by forskolin or dibutyryl cyclic AMP, thus indicating that LH-induced heterologous desensitization of rat Leydig-tumour-cell adenylate cyclase involves a cyclic AMP-dependent lesion that is after the G-protein.     

Gonadotropin release and redistribution of calcium-activated, phospholipid-dependent protein kinase in phorbol-stimulated rat pituitary cells

The effect of phorbol esters on calcium-activated, phospholipid-dependent kinase (protein kinase C) and luteinizing hormone (LH) secretion was examined in cultured rat anterior pituitary cells. The potent tumor promoter 12-O-tetra-decanoylphorbol-13-acetate (TPA) stimulated LH secretion and activated pituitary protein kinase C in the presence of calcium and phosphatidylserine. The enzyme activity present in cytosol and particulate fractions was eluted at about 0.05 M NaCl during DE52-cellulose chromatography. Preincubation of pituitary cells with TPA markedly decreased cytosolic protein kinase C activity and increased enzyme activity in the particulate fraction. The maximal TPA-induced change in enzyme activity, with a 76% decrease in cytosol and a 4.3-fold increase in the particulate fraction, occurred within 10 min. The dose-dependent changes in protein kinase C redistribution in TPA-treated cells were correlated with the stimulation of LH release by the phorbol ester. These results suggest that activation of protein kinase C by TPA is associated with intracellular redistribution of the enzyme and is related to the process of secretory granule release from gonadotrophs.     

Temporal changes in rat Leydig cell function after the induction of bilateral cryptorchidism

Adult rats were made bilaterally cryptorchid and studied at intervals of 3, 7, 14 or 21 days to study temporal changes in Leydig cell function. Serum FSH and LH levels were measured and the cross-sectional area of the Leydig cells assessed by morphometry. The function of the Leydig cells was judged by the binding of 125I-labelled hCG to testicular tissue in vitro and the testosterone response of the testis to hCG stimulation in vitro. By 3 days after cryptorchidism, the binding of labelled hCG to testicular tissue was significantly decreased compared to that of controls, but the testes were able to respond to hCG stimulation in vitro. At 7, 14 and 21 days after cryptorchidism, an enhanced testosterone response was observed and the size of the Leydig cells was significantly greater than that of the controls, which indicated increased secretory activity by the cryptorchid testis. Although serum FSH levels were significantly elevated after 3 days of cryptorchidism, serum LH levels did not rise until 7 days, thereby suggesting that the loss of receptors is unlikely to result from down-regulation by LH. The reduced testosterone response of the cryptorchid testis in vivo to low doses of hCG and the enhanced response at high doses are probably related to the reduced blood flow to the cryptorchid testis and the decreased sensitivity of the Leydig cells induced by LH/hCG receptor loss.     

The effect of lutropin on specific protein synthesis in tumour Leydig cells and in Leydig cells from immature rats

The amount of (35)S incorporated into the various proteins after separation by electrophoresis on sodium dodecyl sulphate/polyacrylamide gels was used as an estimate of their synthesis in the Leydig cells. Increased synthesis of proteins with apparent mol.wts. 27000 and 29000 was observed 3h after addition of lutropin to tumour Leydig cells. Incubation of Leydig cells from immature rats with lutropin (100ng/ml) for 2h or longer resulted in increased synthesis of proteins with apparent mol.wts. 11000, 21000, 27000 and 29000. At higher concentrations (>/=100ng/ml) of lutropin there was a decrease in the synthesis of a protein with apparent mol.wt. 13000. The amount of lutropin required for the stimulation of protein synthesis in both types of Leydig cells was similar to that needed for stimulation of steroidogenesis. Lutropin-stimulated specific protein synthesis was not due to increased concentrations of testosterone, however, because (1) addition of testosterone to the cells had no effect on the synthesis of the proteins, and (2) inhibition of steroidogenesis with elipten phosphate (an inhibitor of the cholesterol side-chain-cleavage enzyme complex) did not abolish the effect of lutropin. The stimulation of specific protein synthesis was also not due to contaminating follitropin in the lutropin preparation. Addition of actinomycin D to the cells at the start of the incubation prevented the effect of lutropin on specific protein synthesis, indicating that mRNA synthesis may be needed for this effect of lutropin. Incubation of the cells with cycloheximide for 30min after labelling of the proteins did not result in a detectable decrease in the amounts of the lutropin-induced proteins, indicating that their half-life is longer than 30min.     

Lutropin stimulates de novo synthesis of short-lived proteins required for lutropin-dependent steroid production in tumour Leydig cells

Continuous protein synthesis is required for the hormonal regulation of cholesterol side chain cleavage activity. A protein with a short half-life (t1/2 = 2-13 min) is believed to play an important role, but the regulation of the synthesis of this putative rapidly-turning-over protein is largely unknown. The steroid production rate in tumour Leydig cells can be increased more than 4-fold after addition of lutropin. However, steroid production by cells preincubated for 60 min with medium containing cycloheximide (89 microM) could not be stimulated when lutropin was added to the medium. Thus, the putative protein with the short half-life is apparently not derived from a stable precursor protein. Moreover, in tumour Leydig cells incubated with low concentrations of cycloheximide (0.2-0.8 microM), inhibition of steroid production was significantly greater in lutropin-stimulated cells than in control cells. These results support the hypothesis that lutropin regulates the de novo synthesis of rapidly-turning-over proteins by increasing the rate of initiation of the translation step of protein synthesis.     

Evidence for a Sertoli cell, FSH-suppressible inhibiting factor(s) of testicular steroidogenic activity

By using a model of immature porcine Leydig and Sertoli cells cultured in serum free defined medium, we evidenced a paracrine control of Leydig cell steroidogenic activity by Sertoli cells via a secreted inhibiting protein(s). This protein(s), partially purified using gel filtration (M.W. 20,000-30,000) suppresses the steroidogenic responsiveness to LH/hCG by decreasing the specific LH/hCG binding (52% decrease) and hormone steroid biosynthesis (73% decrease) at a level(s) located between cAMP production and pregnenolone formation. The suppression of this inhibitor(s) by FSH, in a dose dependent manner, is one mechanism by which FSH "sensitizes" Leydig cell response to LH/hCG stimulation.     

The aging Leydig cell: 1. Testosterone and adenosine 3',5'-monophosphate responses to gonadotropin stimulation in rats

Plasma testosterone levels before and after a single injection of hCG were significantly lower in 24-month old rats than 60--90 day old animals (p less than 0.001). Even with repeated hCG administration for three weeks, plasma testosterone levels of old rats could not be restored to levels present in unstimulated young rats. In response to in vitro LH and 8-bromo-cyclic AMP stimulation, purified young Leydig cells produced significantly higher amounts of testosterone than Leydig cells from old rats. Maximal testosterone formation of the young Leydig cells in response to LH was 42.0 +/- 6.88 ng/10(6) cells, while cells from old rats produced only 16.8 +/- 3.69 ng/10(6) cells (p less than 0.01). However, the dose of LH at which one half maximal response (ED50) occurred was 0.1 mIU/ml for young Leydig cells and 0.05 mIU/ml for old Leydig cells. Basal and 1.0 mIU LH-stimulated cyclic AMP formation were comparable in both groups, but cyclic AMP formation in response to 10 mIU of LH was significantly less in the old rats (p less than 0.05). Present results demonstrate impaired steroidogenic capacity of old rats both in vivo and in vitro. Decreased testosterone response in old rats most likely is the consequence of understimulation of Leydig cells by gonadotropin; however, there appear to be additional intrinsic defects in old Leydig cells.     

Characterization of protein tyrosine kinase activity in murine Leydig tumor cells

The activity of protein tyrosine kinase (EC 2.7.1.37) was characterized from Leydig tumor cells (M5480A) using the synthetic peptide NH2-Glu-Asp-Ala-Glu-Tyr-Ala-Ala-Arg-Arg-Arg-Gly-COOH as a substrate. Relatively high tyrosine-specific protein kinase activity (about 135 pmol/mg protein per min) was detected in a particulate fraction (30 000 X g pellet) and was found to be linear as a function of time and protein concentration. The enzymic activity in the particulate fraction was stimulated 1.4-fold by 0.02% Nonidet P-40 as judged by 32PO4 incorporated into the peptide. Phosphorylation of endogenous proteins in M5480A particulate fractions with [gamma-32P]ATP resulted in several alkali-resistant radiolabeled bands in polyacrylamide gels in the presence of sodium dodecyl sulfate. Included in this group was a major radiolabeled doublet with an apparent molecular-weight in the range of 50 000-54 000. Phosphoamino acid analysis of hydrolysates of these eluted proteins indicated the presence of phosphotyrosine. Several alkali-resistant radio-labeled bands, including a major doublet with an apparent molecular-weight of 32 000, were also detected after culturing M5480A cells in the presence of 32PO4. These studies demonstrate the presence of high levels of protein tyrosine kinase activity in Leydig tumor cells and of endogenous protein substrates for this enzyme activity.     

Lutropin-dependent protein phosphorylation and steroidogenesis in rat tumour Leydig cells

Tumour Leydig cells have been incubated in the presence or absence of lutropin (luteinizing hormone, ;LH'). Stimulation of cells with lutropin (1000ng/ml) in the presence of 1-methyl-3-isobutylxanthine (0.25mm) resulted in increased steroid production and increased protein phosphorylation. When pregnenolone metabolism was inhibited, basal pregnenolone production was 26.9+/-7.4ng/60min per 10(6) cells; stimulated production was 156.1+/-39.5ng/60min per 10(6) cells (means+/-s.d., n=4). Lutropin-dependent phosphorylated proteins of molecular mass 17000, 22000, 24000, 33000 and 57000Da were detected. A significant increase of [(32)P]P(i) incorporation into these phosphorylated proteins was observed concomitant with the increased pregnenolone production. The occurrence of the phosphoproteins in nuclei, mitochondria and postmitochondrial-supernatant was investigated. The 17000Da phosphoprotein was found in the nuclear fraction, whereas the 22000, 24000, 33000 and 57000Da phosphoproteins were localized in the postmitochondrial-supernatant fraction. Of the cholesterol-side-chain-cleavage activity, 80.3+/-6.1% (mean+/-s.d., n=5) was present in the mitochondrial fraction isolated from tumour Leydig cells, and this activity was 2.5-fold increased when cells had been preincubated with lutropin/1-methyl-3-isobutylxanthine (basal production: 194.6+/-28.6ng/30min per mg of protein; lutropinstimulated production: 498.8+/-91.5ng/30min per mg of protein; means+/-s.d., n=3). The similarities in the kinetics of the phosphorylation of proteins and the pregnenolone production after addition of lutropin/1-methyl-3-isobutylxanthine indicate that the phosphoproteins could be involved in the lutropin-dependent increase in steroidogenesis in tumour Leydig cells. It remains to be demonstrated, however, to what extent the phosphoproteins outside the mitochondria can influence the cholesterol-side-chain-cleavage activity inside the mitochondria.     

Effect of luteinizing hormone deprivation in situ on steroidogenesis of rat Leydig cells purified by a multistep procedure

Depriving rats of luteinizing hormone (LH) causes Leydig cells to lose smooth endoplasmic reticulum and diminishes their P450 C17-hydroxylase/C17,20-lyase activity (Wing et al., 1984). LH administration to hypophysectomized rats prevents these changes in Leydig cell structure and function (Ewing and Zirkin, 1983). We adopted a multistep procedure of rat Leydig cell isolation to study the trophic effects of LH on steroidogenesis in the Leydig cell. Our method employs vascular perfusion, enzymatic dissociation, centrifugal elutriation, and Percoll gradient centrifugation. The purified Leydig cell fraction obtained after Percoll density-gradient centrifugation contains 95% well-preserved 3 beta-hydroxysteroid dehydrogenase (3 beta-HSD)-staining cells with ultrastructural characteristics of Leydig cells. These Leydig cells produced 248 and 29 ng of testosterone/10(6) Leydig cells when incubated for 3 h with and without a maximally stimulating concentration of ovine LH. Purified Leydig cells obtained from control rats and rats treated with testosterone-estradiol (T-E) implants for 4 days to inhibit LH production were incubated with a saturating concentration (2 microns) of pregnenolone. Leydig cells from control and T-E-implanted rats produced 537 and 200 ng of testosterone/10(6) Leydig cells X 3 h, respectively, suggesting a defect in the steroidogenic reactions converting pregnenolone to testosterone in Leydig cells from T-E-implanted rats. By using rabbit antibodies to the P450 C17-hydroxylase/C17,20-lyase pig microsomal enzyme, immunoblots of one-dimensional sodium dodecyl sulfate polyacrylamide gels of Leydig cell microsomal protein from control and 4- and 12-day T-E implanted rats revealed a continued loss of enzyme as the period of LH withdrawal continues. These results show that Leydig cells from animals deprived of LH had diminished capacity to convert pregnenolone to testosterone and reduced P450 C17-hydroxylase/C17,20-lyase content.     

Protein kinase C in cytosol and cell membranes of concanavalin A-stimulated rat thymocytes

In concanavalin A-treated thymus cells and phytohemagglutinin-treated spleen cells, the distribution of protein kinase C is changed. Shortly after addition of plant lectins, the activity of protein kinase C increased in the cytosol and decreased in the particulate fraction. 2 h later, the activity of protein kinase C decreased in the cytosol and increased in the particulate fraction. Membrane binding of protein kinase C and tion of DNA synthesis showed the same dependency on concanavalin A concentration. A long-term membrane binding of protein kinase C seems to be essential for lymphocyte stimulation.