Chronic propranolol treatment causes desensitization of the steroidogenic response in testicular interstitial cells but does not alter protein kinase C.

We investigated effects of chronic propranolol treatment on the secretory response of rat testicular interstitial cells (testosterone secretion) to subsequent in vitro stimulation with activators of protein kinase-C (PK-C) (L-propranolol, phorbol 12, 13-dibutyrate (PDBu), LHRH) or activators of protein kinase A (PK-A), (hCG or dibutyryl cAMP (dbcAMP)). We determined [3H]PDBu binding and PK-C activity in these cells. Treatment of rats with propranolol (Inderal 500 mg/L of water for 5 weeks) reduced by 48%, 50% and 29% the L-propranolol-, LHRH- or PDBu-induced testosterone secretion, respectively, when compared to cells from controls. This desensitization in testosterone secretion in vitro was also present when the testicular interstitial cells were stimulated with hCG or dbcAMP (secretion decreased by 65%/57%, respectively, when compared to cells from control rats). Challenging the cells originated from rats that received propranolol chronically with the addition in vitro of propranolol resulted in an additional reduction of the hCG/dbcAMP-stimulated testosterone secretion. Chronic propranolol-induced desensitization was not associated with a loss in [3H]PDBu binding or a decrease in PK-C activity. Chronic propranolol-induced desensitization can be uncoupled from down-regulation of protein kinase C. The effector responsible for the desensitization could be distal to the protein kinase C and protein kinase A.

ATP inhibits insulin-degrading enzyme activity.

We studied the ability of ATP to inhibit in vitro the degrading activity of insulin-degrading enzyme. The enzyme was purified from rat skeletal muscle by successive chromatographic steps. The last purification step showed two bands at 110 and 60 kDa in polyacrylamide gel. The enzyme was characterized by its insulin degradation activity, the substrate competition of unlabeled to labeled insulin, the profile of enzyme inhibitors, and the recognition by a specific antibody. One to 5 mM ATP induced a dose-dependent inhibition of insulin degradation (determined by trichloroacetic acid precipitation and insulin antibody binding). Inhibition by 3 mM adenosine 5'-diphosphate, adenosine 5'-monophosphate, guanosine 5'-triphosphate, pyrophosphate, beta-gamma-methyleneadenosine 5'-triphosphate, adenosine 5'-O-(3 thiotriphosphate), and dibutiryl cyclic adenosine 5'-monophosphate was 74%, 4%, 38%, 46%, 65%, 36%, and 0%, respectively, of that produced by 3 mM ATP. Kinetic analysis of ATP inhibition suggested an allosteric effect as the plot of 1/v (insulin degradation) versus ATP concentration was not linear and the Hill coefficient was more than 1 (1.51 and 2.44). The binding constant for allosteric inhibition was KiT = 1.5 x 10(-7) M showing a decrease of enzyme affinity induced by ATP. We conclude that ATP has an inhibitory effect on the insulin degradation activity of the enzyme.

Propranolol stimulates histone phosphorylation by a putative PK-C in partially purified homogenate of rat testicular interstitial cells. A possible mechanism for increased testosterone secretion by propranolol.

The beta-adrenoceptor blocker propranolol stimulated testosterone secretion by rat testicular interstitial cells (Leydig cell-enriched preparation) in vitro at concentrations ranging from 10(-5) M to 10(-4) M. Treatment of these cells with H7 (20 microM), an inhibitor of protein kinase C, reduced the stimulatory effect of L-propranolol on testosterone secretion by about 5-fold. At concentrations ranging from 31.25 microM to 1000 microM, L-propranolol reduced [3H]phorbol 12,13-dibutyrate binding (IC50 = 75 microM) to rat testicular interstitial cells. At similar concentrations, L-propranolol displaced the binding of [3H]phorbol 12,13-dibutyrate to the homogenate of these cells by only 5%. These findings suggest that the effect of L-propranolol on [3H]phorbol 12,13-dibutyrate binding could be indirect, possibly by increasing the concentration of a chemical mediator interacting with the regulatory domain of protein kinase C. At even lower concentrations (10(-9) M to 10(-7) M), propranolol added directly to the reaction mixture with protein kinase C partially purified from rat testicular interstitial cells increases the phosphorylation of histone. This phosphorylation was comparable to that obtained with (25 microg/ml) phosphatidylserine. The D- and L-stereoisomers of propranolol were equally active. A complete reversal of this propranolol effect on histone phosphorylation was achieved with (20 microM) H-7. In the absence of Ca2+, propranolol was not able to phosphorylate the histone. Taken together, these results suggest that protein kinase C could be the putative kinase involved in this reaction and that its activation by propranolol may be due to interaction of the drug with the regulatory domain of the enzyme at a site differing from the site of interaction with phorbol 12,13-dibutyrate. The ability of propranolol to activate the putative protein kinase C could be related to its stimulatory effect on testosterone secretion by Leydig cells.

Pretreatment with phorbol ester and an LHRH agonist reduces testosterone production and protein kinase C activity in rat Leydig cells challenged with PDBu and LHRH.

We have investigated the role of protein kinase C (PK-C) in luteinizing hormone-releasing hormone (LHRH)-induced testosterone secretion from purified rat Leydig cells (70-80-day old Sprague-Dawley rats) by pretreating the cells in vitro with 200 mM phorbol 12,13-dibutyrate (PDBu) (a known procedure to down-modulate this enzyme in most cell types) and 1 muM [D-Ala6,Des-Gly10]-LHRH ethylamide, an LHRH agonist (LHRH-A). Following pretreatment we measured PK-C activity and secretion of testosterone in response to subsequent challenges with the PK-C activator PDBu (20-2000 nM) and with LHRH (0.001-1.0 muM) and the Ca(2+)-mobilizing secretagogue A23187 (0.1-100 microM) in the same cell preparation. PDBu and LHRH-A pretreatments caused a reduction in testosterone secretion in response to subsequent exposure to PDBu or LHRH. Both pretreatments decreased PK-C activity in crude and purified extracts of the same cells. The magnitude of reduction of the secretory response was greater than that of enzyme activity for both PDBu and LHRH-A pretreatment (68.9% reduction of testosterone secretion vs 54.7% reduction of PK-C activity in PDBu-pretreated cells and 78.6% reduction of testosterone production vs 36.6% reduction of PK-C activity in LHRH-A-pretreated cells). The effect of phorbol ester pretreatment on PDBu- or LHRH-stimulated testosterone secretion and PK-C activity was specific (no measurable effect with 4 alpha-PDBu, an inactive phorbol ester). While PDBu and LHRH-A pretreatment reduced Leydig cell responsiveness to PDBu or LHRH, the secretion of testosterone in response to the Ca2+ -mobilizing secretagogue A23187 was similar in PDBu- and LHRH-A-pretreated and in control (non-pretreated) cells. We conclude that down-modulation of protein kinase C by prolonged exposure of Leydig cells to phorbol esters or LHRH-A results in decreased PK-C activity and testosterone secretion. These results provide the first evidence that pretreatment with LHRH-A, which does not enter the cell, can affect the steroidogenesis and PK-C activity responses to PDBu (the intracellular ligand of PK-C).

Propranolol stimulates testicular interstitial fluid formation and testosterone secretion in rats.

We investigated the effect of intratesticularly injected propranolol on testicular interstitial fluid (TIF) formation and on testosterone levels in the TIF of intact adult male Wistar rats (4-9 rats per group). dl-propranolol at doses of 0.6, 1.2, or 6.0 mg/kg was injected into the left (L) testis whereas the right (R) testis (control testis) received vehicle. dl-propranolol (6.0 mg/kg) caused a significant increase in both TIF volume (329%) and TIF levels of testosterone (257%) in the L testis but not in the R (control) testis 3 h post-injection. In rats treated simultaneously with human chorionic gonadotropin (hCG, 5 IU/rat, sc) the same dose or propranolol (6.0 mg/kg) significantly increased the stimulatory effect of hCG on testosterone secretion by 1.8-fold, but hCG did not modify the stimulatory effect of propranolol on TIF volume. These results demonstrate a direct stimulatory effect of propranolol on TIF volume and testosterone secretion, both under basal and hCG-stimulated conditions.

Pretreatment with phorbol ester and an LHRH asgonist reduces testosterone production and protein kinase C activity in rat Leydig cells challenged with PDBu and LHRH

We have investigated the role of protein kinase C (PK-C) in luteinizing hormone-releasing hormone (LHRH)-induced testosterone secretion from purified rat Leydig cells (70-80-day old Sprague-Dawley rats) by pretreating the cells in vitro with 200 mM phorbol 12,13-dibutyrate (PDBu) (a known procedure to down-modulate this enzyme in most cell types) and 1 muM [D-Ala6,Des-Glyl0]-LHRH ethylamide, an LHRH agonist (LHRH-A). Following pretreatment we measured PK-C activity and secretion of testosterone in response to subsequent challenges with the PK-C activator PDBu (20-2000 nM) and with LHRH (0.001-1.0 muM) and the Ca2+ mobilizing secretagogue A23187 (0.1-1OO muM) in the same cell preparation. PDBu and LHRH-A pretreatments caused a reduction in testosterone secretion in response to subsequent exposure to PDBu or LHRH. Both pretreatments decreased PK-C activity in crude and purified extracts of the same cells. The magnitude of reduction of the secretory response was greater than that of enzyme activity for both PDBu and LHRH-A pretreatment (68.9 per cent reduction of testosterone secretion vs 54.7 per cent reduction of PK-C activity in PDBu-pretreated cells and 78.6 per cent reduction of testosterone production vs 36.6 per cent reduction of PK-C activity in LHRH-A-pretreated cells). The effect of phorbol ester pretreatment on PDBu- or LHRH-stimulated testosterone secretion and PK-C activity was specific (no measurable effect with 4 alpha-PDBu, an inactive phorbol ester). While PDBu and LHRH-A pretreatment reduced Leydig cell responsiveness to PDBu or LHRH, the secretion of testosterone in response to the Ca2+ -mobilizing secretagogue A23187 was similar in PDBu- and LHRH-A-pretreated and in control (non-pretreated) cells. We conclude that down-modulation of protein kinase C by prolonged exposure of Leydig cells to phorbol esters or LHRH-A results in decreased PK-C activity and testosterone secretion. These results provide the first evidence that pretreatment with LHRH-A, which does not enter the cell, can affect the steroidogenesis and PK-C activity responses to PDBu (the intracellular ligand of PK-C).

Propranolol stimulates testicular interstitial fluid formation and testosterone secretion in rats

We investigated the effect of intratesticularly injected propranolol on testicular interstitial fluid (TIF) formation and on testosterone levels in the TIF of intact adult male Wistar rats (4-9 rats per group). D1-propranolol at doses of 0.6, 1.2 or 6.0 mg/kg was injected into the left (L) testis whereas the right (R) testis (control testis) received vehicle. d1-propranolol (6.0 mg/kg) caused a significant increase in both TIF volume (329 per cent) and TIF levels of testosterone (257 per cent) in the L testis but not in the R (control) testis 3 h post-injection. In rats treated simultaneously with human chorionic gonadotropin (hCG, 5 IU/rat, sc) the same dose of propranolol (6.0 mg/kg) significantly increased the stimulatory effect of hCG on testosterone secretion by 1.8-fold, but hCG did not modify the stimulatory effect of propranolol on TIF volume. These results demonstrate a direct stimulatory effect of propranolol on TIF volume and testosterone secretion, both under basal and hCG-stimulated conditions.

Inhibitory action of in vitro ethanol and acetaldehyde exposure on LHRH-and phorbol ester-stimulated testosterone secretion by rat testicular interstitial cells.

Ethanol and acetaldehyde have been shown to inhibit testicular steroidogenesis. However the mechanism(s) of signal transduction involved in their action is still unclear. We examined the possible involvement of phospholipid-sensitive, calcium-dependent protein kinase (protein Kinase C, PK-C) in the intracellular mechanism of action of ethanol and acetaldehyde by stimulating testosterone production in rat testicular interstitial cells with LHRH and the phorbol ester PDBu, both of which activate PK-C at receptor (LHRH) and post-receptor (PDBu) sites. Ethanol (2000 mg %) inhibited 10(-7) M LHRH and 200 nM PDBu-stimulated testosterone production by 81 +/- 4.7% and 60 +/- 20.4%, respectively. Acetaldehyde (20 mg %) reduced the amount of testosterone produced by 10(-7) M LHRH and 200 nM PDBu by 59.4 +/- 1.2% and 52.5 +/- 5.4% respectively. Basal testosterone levels were unaffected by ethanol and reduced by acetaldehyde. However, the functional test of cell viability by preincubating cells with these doses of ethanol and acetaldehyde did not decrease their ability to respond appropriately to subsequent stimulation with LHRH, demonstrating that cell viability was unaffected by incubation with these drugs. The data presented here suggest that direct ethanol and acetaldehyde exposure results in a reduced ability of the testicular interstitial cells to respond to stimulation of PK-C pathway.

Inhibitory action of in vitro ethanol and acetaldehyde exposure on LHRH-and phorbol ester-stimulated testosterone secretion by rat testicular interstitial cells.

Ethanol and acetaldehyde have been shown to inhibit testicular steroidogenesis. However the mechanism(s) of signal transduction involved in their action is still unclear. We examined the possible involvement of phospholipid-sensitive, calcium-dependent protein kinase (protein Kinase C, PK-C) in the intracellular mechanism of action of ethanol and acetaldehyde by stimulating testosterone production in rat testicular interstitial cells with LHRH and the phorbol ester PDBu, both of which activate PK-C at receptor (LHRH) and post-receptor (PDBu) sites. Ethanol (2000 mg

) inhibited 10(-7) M LHRH and 200 nM PDBu-stimulated testosterone production by 81 +/- 4.7

and 60 +/- 20.4

, respectively. Acetaldehyde (20 mg

) reduced the amount of testosterone produced by 10(-7) M LHRH and 200 nM PDBu by 59.4 +/- 1.2

and 52.5 +/- 5.4

respectively. Basal testosterone levels were unaffected by ethanol and reduced by acetaldehyde. However, the functional test of cell viability by preincubating cells with these doses of ethanol and acetaldehyde did not decrease their ability to respond appropriately to subsequent stimulation with LHRH, demonstrating that cell viability was unaffected by incubation with these drugs. The data presented here suggest that direct ethanol and acetaldehyde exposure results in a reduced ability of the testicular interstitial cells to respond to stimulation of PK-C pathway.

Fluoride and phosphatidylserine induced inhibition of cytosolic insulin-degrading activity.

Cytosol (C) (100,000 x g/60 min, supernatant) from liver, brain and testis (Wistar male rats) are shown to contain insulin degrading activity (C-IDA). The regulation of C-IDA in these fractions by ligands that activate G protein and PKC were examined C-IDA from liver, brain and testis was inhibited 76%; 64% and 50% by 50 mM F- respectively. Chromatography of C fraction from liver on Sephadex G-50 in presence of 1 M (NH4)2SO4 and 20% (v/v) glycerol (experimental condition to remove guanine nucleotides from G proteins) decreased in about 3-fold aluminum fluoride effect on C-IDA. Mg++ (from 5mM to 10 mM) enhanced fluoride effects by inhibiting fully C-IDA. Phosphatidylserine in presence of ATP completely inhibited C-IDA; this inhibition was 31.3% mediated by a phosphorylation reaction. It is concluded that cytosol from different tissues contain proteins capable to associate ligands as aluminum fluoride and PS to regulate C-IDA. It is proposed a mechanism of protein-protein interaction to modulate C-IDA.

Fluoride and phosphatidylserine induced inhibition of cytosolic insulin-degrading activity.

Cytosol (C) (100,000 x g/60 min, supernatant) from liver, brain and testis (Wistar male rats) are shown to contain insulin degrading activity (C-IDA). The regulation of C-IDA in these fractions by ligands that activate G protein and PKC were examined C-IDA from liver, brain and testis was inhibited 76

; 64

and 50

by 50 mM F- respectively. Chromatography of C fraction from liver on Sephadex G-50 in presence of 1 M (NH4)2SO4 and 20

(v/v) glycerol (experimental condition to remove guanine nucleotides from G proteins) decreased in about 3-fold aluminum fluoride effect on C-IDA. Mg++ (from 5mM to 10 mM) enhanced fluoride effects by inhibiting fully C-IDA. Phosphatidylserine in presence of ATP completely inhibited C-IDA; this inhibition was 31.3

mediated by a phosphorylation reaction. It is concluded that cytosol from different tissues contain proteins capable to associate ligands as aluminum fluoride and PS to regulate C-IDA. It is proposed a mechanism of protein-protein interaction to modulate C-IDA.

Fluoride and phosphatidylserine induced inhibition of cytosolic insulin-degrading activity.

Cytosol (C) (100,000 x g/60 min, supernatant) from liver, brain and testis (Wistar male rats) are shown to contain insulin degrading activity (C-IDA). The regulation of C-IDA in these fractions by ligands that activate G protein and PKC were examined C-IDA from liver, brain and testis was inhibited 76

; 64

and 50

by 50 mM F- respectively. Chromatography of C fraction from liver on Sephadex G-50 in presence of 1 M (NH4)2SO4 and 20

(v/v) glycerol (experimental condition to remove guanine nucleotides from G proteins) decreased in about 3-fold aluminum fluoride effect on C-IDA. Mg++ (from 5mM to 10 mM) enhanced fluoride effects by inhibiting fully C-IDA. Phosphatidylserine in presence of ATP completely inhibited C-IDA; this inhibition was 31.3

mediated by a phosphorylation reaction. It is concluded that cytosol from different tissues contain proteins capable to associate ligands as aluminum fluoride and PS to regulate C-IDA. It is proposed a mechanism of protein-protein interaction to modulate C-IDA.

Modulatory effects of adrenergic agonists on testosterone secretion from rat dispersed testicular cells or Percoll-purified Leydig cells.

1. Freshly dispersed testicular interstitial cells as well as Percoll-purified Leydig cells were studied in vitro in order to evaluate the effect of adrenergic agonists on testosterone (T) secretion. 2. Epinephrine and phenylephrine did not change the rate of T release under basal conditions in freshly dispersed interstitial cells, but enhanced it during human chorionic gonadotropin (hCG) stimulation. Norepinephrine and clonidine had no effect on T secretion. 3. In contrast, in Percoll-purified Leydig cells epinephrine increased T release both under basal and hCG-stimulated conditions. 4. These data demonstrate that neurotransmitters may participate in T secretion from isolated Leydig cells.

Modulatory effects of adrenergic agonists on testosterone secretion from rat dispersed testicular cells or Percoll-purified Leydig cells

Freshly dispersed testicular interstitial cells as well as Percoll-purified Leydig cells were studied in vitro in order to evaluate the effect of adrenergic agonists on testosterone (T) secretion. Epinephrine and phenylephrine did not change the rate of T release under basal conditions in freshly dispersed interstitial cells, but enhanced it during human chorionic gonadotropin (hCG) stimulation. Norepinephrine and clonidine had no effect on T secretion. In contrast, in Percoll-purified Leydig cells epinephrine increased T release both under basal and hCG-stimulated conditions. These data demonstrate that neurotransmitters may participate in T secretion from isolated Leydig cells