Exogenous administration of protease-resistant, non-matrix-binding IGFBP-2 inhibits tumour growth in a murine model of breast cancer.

BACKGROUND: Insulin-like growth factors (IGF-I and IGF-II) signal via the type 1 IGF receptor (IGF-1R) and IGF-II also activates the insulin receptor isoform A (IR-A). Signalling via both receptors promotes tumour growth, survival and metastasis. In some instances IGF-II action via the IR-A also promotes resistance to anti-IGF-1R inhibitors. This study assessed the efficacy of two novel modified IGF-binding protein-2 (IGFBP-2) proteins that were designed to sequester both IGFs. The two modified IGFBP-2 proteins were either protease resistant alone or also lacked the ability to bind extracellular matrix (ECM). METHODS: The modified IGFBP-2 proteins were tested in vitro for their abilities to inhibit cancer cell proliferation and in vivo to inhibit MCF-7 breast tumour xenograft growth. RESULTS: Both mutants retained low nanomolar affinity for IGF-I and IGF-II (0.8-2.1-fold lower than IGFBP-2) and inhibited cancer cell proliferation in vitro. However, the combined protease resistant, non-matrix-binding mutant was more effective in inhibiting MCF-7 tumour xenograft growth and led to inhibition of angiogenesis. CONCLUSIONS: By removing protease cleavage and matrix-binding sites, modified IGFBP-2 was effective in inhibiting tumour growth and reducing tumour angiogenesis.

The TGF-ß-Smad3 pathway inhibits CD28-dependent cell growth and proliferation of CD4 T cells.

Transforming growth factor-ß (TGF-ß) maintains self-tolerance through a constitutive inhibitory effect on T-cell reactivity. In most physiological situations, the tolerogenic effects of TGF-ß depend on the canonical signaling molecule Smad3. To characterize how TGF-ß/Smad3 signaling contributes to maintenance of T-cell tolerance, we characterized the transcriptional landscape downstream of TGF-ß/Smad3 signaling in resting or activated CD4 T cells. We report that in the presence of TGF-ß, Smad3 modulates the expression of >400 transcripts. Notably, we identified 40 transcripts whose expression showed Smad3 dependence in both resting and activated cells. This 'signature' confirmed the non-redundant role of Smad3 in TGF-ß biology and identified both known and putative immunoregulatory genes. Moreover, we provide genomic and functional evidence that the TGF-ß/Smad3 pathway regulates T-cell activation and metabolism. In particular, we show that TGF-ß/Smad3 signaling dampens the effect of CD28 stimulation on T-cell growth and proliferation. The impact of TGF-ß/Smad3 signals on T-cell activation was similar to that of the mTOR inhibitor Rapamycin. Considering the importance of co-stimulation on the outcome of T-cell activation, we propose that TGF-ß-Smad3 signaling may maintain T-cell tolerance by suppressing co-stimulation-dependent mobilization of anabolic pathways.

Endogenous inhibitors (GALFs) of 11beta-hydroxysteroid dehydrogenase isoforms 1 and 2: derivatives of adrenally produced corticosterone and cortisol.

Two isoforms of 11beta-HSD exist; 11beta-HSD1 is bi-directional (the reductase usually being predominant) and 11beta-HSD2 functions as a dehydrogenase, conferring kidney mineralocorticoid specificity. We have previously described endogenous substances in human urine, "glycyrrhetinic acid-like factors (GALFs)", which like licorice, inhibit the bi-directional 11beta-HSD1 enzyme as well as the dehydrogenase reaction of 11beta-HSD2. Many of the more potent GALFs are derived from two major families of adrenal steroids, corticosterone and cortisol. For example, 3alpha5alpha-tetrahydro-corticosterone, its derivative, 3alpha5alpha-tetrahydro-11beta-hydroxy-progesterone (produced by 21-deoxygenation of corticosterone in intestinal flora); 3alpha5alpha-tetrahydro-11beta-hydroxy-testosterone (produced by side chain cleavage of cortisol); are potent inhibitors of 11beta-HSD1 and 11beta-HSD2-dehydrogenase, with IC50's in range 0.26-3.0 microM, whereas their 11-keto-3alpha5alpha-tetrahydro-derivatives inhibit 11beta-HSD1 reductase, with IC50's in range 0.7-0.8 microM (their 3alpha5beta-derivatives being completely inactive). Inhibitors of 11beta-HSD2 increase local cortisol levels, permitting it to act as a mineralocorticoid in kidney. Inhibitors of 11beta-HSD1 dehydrogenase/11beta-HSD1 reductase serve to adjust the set point of local deactivation/reactivation of cortisol in vascular and other glucocorticoid target tissues, including adipose, vascular, adrenal tissue, and the eye. These adrenally derived 11-oxygenated C21- and C19 -steroidal substances may serve as 11beta-HSD1- or 11beta-HSD2-GALFs. We conclude that adrenally derived products are likely regulators of local cortisol bioactivity in humans.

Mucosal deformation from an impinging transonic gas jet and the ballistic impact of microparticles.

By means of a transonic gas jet, gene guns ballistically deliver microparticle formulations of drugs and vaccines to the outer layers of the skin or mucosal tissue to induce unique physiological responses for the treatment of a range of conditions. Reported high-speed imaging experiments show that the mucosa deforms significantly while subjected to an impinging gas jet from a biolistic device. In this paper, the effect of this tissue surface deformation on microparticle impact conditions is simulated with computational fluid dynamics (CFD) calculations. The microparticles are idealized as spheres of diameters 26.1, 39 and 99 microm and a density of 1050 kg m-3. Deforming surface calculations of particle impact conditions are compared directly with an immobile surface case. The relative velocity and obliquity of the deforming surface decrease the normal component of particle impact velocity by up to 30% at the outer edge of the impinging gas jet. This is qualitatively consistent with reported particle penetration profiles in the tissue. It is recommended that these effects be considered in biolistic studies requiring quantified particle impact conditions.

Colony-stimulating factor-1 plays a major role in the development of reproductive function in male mice.

Colony-stimulating factor-1 (CSF-1) is the principal regulator of cells of the mononuclear phagocytic lineage that includes monocytes, tissue macrophages, microglia, and osteoclasts. Macrophages are found throughout the reproductive tract of both males and females and have been proposed to act as regulators of fertility at several levels. Mice homozygous for the osteopetrosis mutation (csfm[op]) lack CSF-1 and, consequently, have depleted macrophage numbers. Further analysis has revealed that male csfm(op)/csfm(op) mice have reduced mating ability, low sperm numbers, and 90% lower serum testosterone levels. The present studies show that this low serum testosterone is due to reduced testicular Leydig cell steroidogenesis associated with severe ultrastructural abnormalities characterized by disrupted intracellular membrane structures. In addition, the Leydig cells from csfm(op)/ csfm(op) males have diminished amounts of the steroidogenic enzyme proteins P450 side chain cleavage, 3beta-hydroxysteroid dehydrogenase, and P450 17alpha-hydroxylase-lyase, with associated reductions in the activity of all these steroidogenic enzymes, as well as in 17beta-hydroxysteroid dehydrogenase. The CSF-1-deficient males also have reduced serum LH and disruption of the normal testosterone negative feedback response of the hypothalamus, as demonstrated by the failure to increase LH secretion in castrated males and their lack of response to exogenous testosterone. However, these males are responsive to GnRH and LH treatment. These studies have identified a novel role for CSF-1 in the development and/or regulation of the male hypothalamic-pituitary-gonadal axis.

Effects of an Igf1 gene null mutation on mouse reproduction.

Both sexes of adult mice homozygous for a targeted mutation of the Igf1 gene, encoding insulin-like growth factor 1, are infertile dwarfs (approximately 30% of normal size). The testes are reduced in size less than expected from the degree of dwarfism but sustain spermatogenesis only at 18% of the normal level. The epididymides are overall nearly allometric to the reduced body weight, but the distal regions of the duct, vas deferens, seminal vesicles, and prostate are vestigial. Despite the mutational impact on the epididymis, capacitated sperm are able to fertilize wild type eggs in vitro. It is hypothesized that the infertility of male mutants is caused by failure of androgenization resulting in absence of mating behavior, due to drastically reduced levels of serum testosterone (18% of normal). This hormonal deficiency was correlated with an ultrastructural analysis of mutant Leydig cells revealing a significant developmental delay, while assays in organ culture showed that the basal and LH-stimulated production of testosterone by testicular parenchyma is reduced in comparison with wild type controls. The female mutants fail to ovulate even after administration of gonadotropins, which is apparently the primary cause of their infertility, and possess an infantile uterus that exhibits a dramatic hypoplasia especially in the myometrium. The phenotypic manifestations of the mutation were correlated with the localization of transcripts for insulin-like growth factor I and its cognate receptor in wild type reproductive tissues by in situ hybridization.

Developmental changes in levels of luteinizing hormone receptor and androgen receptor in rat Leydig cells.

To further assess the hormonal response capabilities of Leydig cell progenitors (PLC) from 21-day-old rats, their levels of LH and androgen receptors (LH-R and AR) were measured and compared to those of isolated immature (ILC) and adult Leydig cells (ALC) from 35- and 90-day-old rats, respectively. Levels of LH receptor were estimated by Scatchard analysis of binding to [125I]hCG, and levels of LH receptor mRNA were determined by Northern blot analysis using a rat LH receptor antisense RNA probe. The numbers of LH receptors per cell measured by the binding study were 2,623 +/- 1,110 in PLC, 9,024 +/- 1,992 in ILC, and 39,896 +/- 15,234 in ALC (mean +/- SEM of four replicate experiments; ALC significantly greater than either PLC or ILC at P less than 0.05). The Northern blotting revealed three major bands [6.7, 2.6, and 2.3 kilobases (kb)] that were present in Leydig cells at all three ages and were not detected in HepG2 cells. When the steady state levels of the predominant 6.7-kb species were normalized to actin mRNA, PLC were 6.3-fold lower than ILC and 1.7-fold lower than ALC (n = 3 replicate isolations of poly(A) RNA). The 2.6- and 2.3-kb species exhibited similar trends. Levels of AR were estimated by immunoblotting using a polyclonal antibody against a synthetic peptide of the receptor (residues 14-32) that detected a 110-kilodalton AR protein. Levels of AR mRNA were estimated by Northern blot analysis, using a rat AR antisense RNA probe that detected a single 10-kb AR mRNA. The relative levels of AR protein were 1.0, 1.5, and 0.5 in PLC, ILC, and ALC, respectively (n = 3). Similar trends were observed for AR mRNA (n = 3). The observation that both LH and AR levels were lower in PLC compared to ILC is consistent with the hypothesis that the former are progenitors of Leydig cells.

Luteinizing hormone differentially regulates the secretion of testicular oxytocin and testosterone by purified adult rat Leydig cells in vitro.

The aims of the present study were to determine whether Leydig cells in vitro synthesize oxytocin, and whether LH modulates the secretion of oxytocin by Leydig cells. Highly purified adult Leydig cells were prepared from adult rats and cultured for 3 days in the presence or absence of 0.1 ng/ml ovine LH, and media were changed daily. The total amount of oxytocin present in the culture was estimated by RIA of cell extracts before culture (day 0) and at the end of day 3 of culture and in media on days 1-3. The content of immunoreactive oxytocin in cell extracts on day 0 (3.4 +/- 1.2 pg/10(6) cells) was significantly lower than the total amount that had been released into the medium and was present in the cell extracts at the end of day 3 (+LH, 27.8 +/- 3.3; -LH, 16.5 +/- 2.7 pg/10(6) cells), suggesting that Leydig cells are able to synthesize and secrete oxytocin. This hypothesis was supported by the observation that oxytocin release into the medium was significantly reduced during a 3-h treatment of Leydig cells with the protein synthesis inhibitor cycloheximide (5 micrograms/ml for 3 h). The role of LH in regulating testosterone production by Leydig cells is well defined, but whether LH also regulates oxytocin is unknown. Therefore, the effects of LH on oxytocin and testosterone production by Leydig cells were compared. The production of both hormones was stimulated by increasing doses of LH (0.001-100 ng/ml), but no further rise in oxytocin release could be elicited with amounts of LH greater than 0.1 ng/ml. Testosterone production, however, continued to increase with doses of LH up to 100 ng/ml. Furthermore, the two hormones differed in the rate of their responses to both 3- and 12-h exposures to LH; testosterone secretion increased more rapidly than that of oxytocin. These data provide direct evidence that adult Leydig cells produce immunoreactive oxytocin, and that their production of this peptide is regulated by LH.

Decreased cyclin A2 and increased cyclin G1 levels coincide with loss of proliferative capacity in rat Leydig cells during pubertal development.

Postnatal development of Leydig cells can be divided into three distinct stages of differentiation: initially they exist as mesenchymal-like progenitors (PLC) by day 21; subsequently, as immature Leydig cells (ILC) by day 35, they acquire steroidogenic organelle structure and enzyme activities but metabolize most of the testosterone they produce; finally, as adult Leydig cells (ALC) by day 90 they actively produce testosterone. The aims of the present study were to determine whether changes in proliferative capacity are associated with progressive differentiation of Leydig cells, and if the proliferative capacity of Leydig cells is controlled by known hormonal regulators of testosterone biosynthesis: LH, insulin-like growth factor I (IGF-I), androgen, and estradiol (E2). Isolated PLC, ILC, and ALC were cultured in DMEM/F-12 for 24 h followed by an additional 24 h in the presence of LH (1 ng/ml), IGF-I (70 ng/ml), 7alpha-methyl-19-nortestosterone (MENT, 50 nM), a synthetic androgen that is not metabolized by 5alpha-reductase, or E2 (50 nM). Proliferative capacity was measured by assaying [3H]thymidine incorporation and labeling index (LI). Messenger RNA (mRNA) and protein levels for cyclin A2 and G1, which are putative intracellular regulators of Leydig cell proliferation and differentiation, were measured by RT-PCR and immunoblotting, respectively. Thymidine incorporation was highest in PLC (9.24 +/- 0.21 cpm/10(3) cell, mean +/- SE), intermediate in ILC (1.74 +/- 0.07) and lowest in ALC (0.24 +/- 0.03). Similarly, LI was highest in PLC (13.42 +/- 0.30%, mean +/- SE), intermediate in ILC (1.95 +/- 0.08%), and undetectable in ALC. Cyclin A2 mRNA levels, normalized to ribosomal protein S16 (RPS16), were highest in PLC (2.76 +/- 0.21, mean +/- SE), intermediate in ILC (1.79 +/- 0.14), and lowest in ALC (0.40 +/- 0.06). In contrast, cyclin G1 mRNA levels were highest in ALC (1.32 +/- 0.16), intermediate in ILC (0.47 +/- 0.07), and lowest in PLC (0.12 +/- 0.02). The relative protein levels of cyclin A2 and G1 paralleled their mRNA levels. Increased proliferative capacity was observed in PLC and ILC, but not ALC, after treatment with either LH or IGF-I. Treatment with MENT increased proliferative capacity only in ILC and had no effect in any other group. Treatment with E2 decreased proliferative capacity in PLC but not in ILC or ALC. The changes in proliferative capacity after hormonal treatment paralleled cyclin A2 mRNA and were the inverse of cyclin G1 mRNA levels. We conclude that: 1) decreased cyclin A2 and increased cyclin G1 are associated with the withdrawal of the Leydig cell from the cell cycle; 2) the proliferative capacity of Leydig cells is regulated differentially by hormones and is progressively lost during postnatal differentiation.

Variation in the end products of androgen biosynthesis and metabolism during postnatal differentiation of rat Leydig cells.

The amount of testosterone (T) secreted by Leydig cells is determined by a balance between T biosynthetic and metabolizing enzyme activities. It has been established that 5alpha-androstan-3alpha,17beta-diol (3alpha-DIOL) is the predominant androgen secreted by the testes of immature rats during days 20-40 postpartum, whereas T is the major androgen by day 56. However, the underlying changes in T biosynthetic and metabolizing enzymes during Leydig cell development and their magnitudes have remained unclear. The aim of the present study was to define the developmental trends for T biosynthetic and metabolizing enzymes in Leydig cells at three distinct stages of pubertal differentiation: mesenchymal-like progenitors on day 21, immature Leydig cells on day 35, and adult Leydig cells on day 90. Production rates for precursor androgen (androstenedione), T, and 5alpha-reduced androgens [androsterone (AO) and 3alpha-DIOL] were measured in progenitor, immature, and adult Leydig cells in spent medium after 3 h in vitro. Steady state messenger RNA (mRNA) levels and enzyme activities of biosynthetic and metabolizing enzymes were measured in fractions of freshly isolated cells at each of the three stages. Unexpectedly, progenitor cells produced significant amounts of androgen, with basal levels of total androgens (androstenedione, AO, T, and 3alpha-DIOL) 14 times higher than those of T alone. However, compared with immature and adult Leydig cells, the capacity for steroidogenesis was lower in progenitor cells, with a LH-stimulated production rate for total androgens of 84.33 +/- 8.74 ng/10(6) cells x 3 h (mean +/- SE) vs. 330.13 +/- 44.19 in immature Leydig cells and 523.23 +/- 67.29 in adult Leydig cells. The predominant androgen produced by progenitor, immature, and adult Leydig cells differed, with AO being released by progenitor cells (72.08 +/- 9.02% of total androgens), 3alpha-DIOL by immature Leydig cells (73.33 +/- 14.52%), and T by adult Leydig cells (74.38 +/- 14.73%). Further examination indicated that changes in the predominant androgen resulted from differential gene expression of T biosynthetic and metabolizing enzymes. Low levels of type III 17beta-hydroxysteroid dehydrogenase (17betaHSD) mRNA and enzyme activity were present in progenitor cells compared with immature and adult Leydig cells. In contrast, levels of type I 5alpha-reductase (5alphaR) and 3alpha-hydroxysteroid dehydrogenase (3alphaHSD) mRNA and enzyme activities were dramatically lower in adult Leydig cells compared with those in progenitor and immature Leydig cells. Several T biosynthetic enzymes attained equivalent levels in immature and adult Leydig cells, but T was rapidly metabolized in the former to 3alpha-DIOL by high 5alphaR and 3alphaHSD activities, which were greatly reduced in the latter. Therefore, declines in 5alphaR and 3alphaHSD activities are hypothesized to be a major cause of the ascendancy of T as the predominant androgen end product produced by adult Leydig cells. These results indicate that steroidogenic enzyme gene expression is not induced simultaneously, but through sequential changes in T biosynthetic and metabolizing enzyme activities, resulting in different androgen end products being secreted by Leydig cells during pubertal development.

Immunohistochemical analysis of androgen effects on androgen receptor expression in developing Leydig and Sertoli cells.

Leydig and Sertoli cells are both targets of androgen action in the testis. Androgen exerts contrasting effects on the two cell types partially inhibiting steroidogenesis in adult Leydig cell and stimulating adult Sertoli cell functions required to support spermatogenesis. The developmental changes in the messenger RNA (mRNA) levels of androgen receptor (AR) also differ between Leydig and Sertoli cells, with Leydig cell AR mRNA being highest on day 35 postpartum, whereas Sertoli cell AR mRNA levels are highest on day 90. The purpose of the present study was to determine if the concentrations of AR in Leydig and Sertoli cells are differentially regulated during development using quantitative immunostaining. AR protein levels were measured in rat testes after hormonal treatments at three developmental stages: on days 21, 35, and 90 postpartum. At each age, five groups of animals were treated for 4 days with: 1) vehicle; 2) LHRH antagonist (NalGlu, 0.3 mg/kg BW.day) to suppress endogenous levels of androgen that accompany inhibition of LH and FSH secretion; 3) NalGlu + LH (0.2 mg/kg BW.day); 4) NalGlu + testosterone (T, at 7.5 mg/kg BW.day); and 5) NalGlu + MENT (a potent synthetic androgen, 7 alpha-methyl-19-nortestosterone, 0.7 mg/kg BW.day). AR protein was visualized by immunohistochemistry and measured by computer-assisted image analysis in Leydig and Sertoli cells using frozen sections of tests. After NalGlu treatment, AR levels in Leydig cells declined sharply to 42% and 31% of vehicle control (P < 0.01) in the 21 and 35 days postpartum age groups, respectively, but in 90-day-old rats there was no change. AR levels were partially maintained by exogenous LH, and completely maintained by exogenous androgen treatments in Leydig cells from 21- and 35-day-old rats, whereas in Leydig cells from 90-day-old rats, AR levels were unaffected in all treatment groups. In contrast, after NalGlu treatment, the AR concentration in Sertoli cells from 90-day-old rats were reduced to 32% of control (P < 0.01). Moreover, in Sertoli cells from 90-day-old rats, AR levels were partially maintained by LH and completely maintained by androgens. A similar trend was observed on day 35. On day 21, however, AR levels in immature Sertoli cells were unaffected in all treatment groups. These results indicate that androgen maximally stimulates AR levels in immature Leydig cells but is without significant effect in adult Leydig cells. In contrast, AR levels in Sertoli cells are more sensitive to androgen regulation in adult compared with immature animals. These findings indicate that there are distinct mechanisms controlling AR concentrations in Leydig and Sertoli cells during the development of the testis.

11 beta-Hydroxysteroid dehydrogenase alleviates glucocorticoid-mediated inhibition of steroidogenesis in rat Leydig cells.

Leydig cells from mature rat testes contain high levels of 11 beta-hydroxysteroid dehydrogenase (11HSD), an enzyme that oxidatively inactivates glucocorticoids. We have proposed that the 11HSD of Leydig cells protects the testis from the effects of high levels of glucocorticoids, as may occur in stress and Cushing's disease. In this paper we investigate whether testicular 11HSD by inactivating glucocorticoids diminishes their ability to inhibit testosterone (T) production. Corticosterone (B) and dexamethasone (DEX) inhibited T production by purified Leydig cells in a dose-dependent manner. Activity was diminished by 50% with 1.5 nM DEX vs. 0.4 microM B. The shapes of the inhibition curves were consistent with a saturable process; inhibition by both steroids was overcome with the glucocorticoid receptor antagonist RU486. We concluded that the effect was mediated by glucocorticoid receptors. Aldosterone, 11 beta-hydroxyprogesterone, and 11-deoxycorticosterone did not decrease T production. The greater potency of DEX compared to B may be due to its resistance to oxidative inactivation by 11HSD. As 11-dehydrocorticosterone, the product of the oxidation of B by 11HSD, did not inhibit T production, it was predicted that inactivation of 11HSD should enhance the inhibitory effect of B. Consistent with this prediction, inhibition by B was increased by carbenoxolone, an inhibitor of 11HSD, becoming more similar to that by DEX. Suppression of T production by DEX (which is not a substrate of 11HSD) was unaffected by carbenoxolone. We conclude that through reduction of the levels of inhibitory glucocorticoids, 11HSD has a novel role among Leydig cell steroid-metabolizing enzymes in the regulation of T production.

Effects of luteinizing hormone (LH) and androgen on steady state levels of messenger ribonucleic acid for LH receptors, androgen receptors, and steroidogenic enzymes in rat Leydig cell progenitors in vivo.

Adult Leydig cells differentiate postnatally from mesenchymal-like progenitor cells. The relative scarcity of LH receptors (LHRs) in progenitor cells indicates that additional hormones may be important in the initial phases of Leydig cell differentiation. High levels of androgen receptor (AR) in progenitor cells point to a role for androgen in these cells. In the present study, an LHRH antagonist, [Ac-D2Nal1,4C1DPhe2,D3Pal3,Arg5,DGlu6(anis ole adduct), DAla10]GnRH (NalGlu; 250 micrograms/kg body weight), was used to suppress endogenous secretion of both LH and androgen during days 14 to 21 postpartum in vivo. To examine the effects of LH and androgen on regulation of Leydig cell progenitors (PLCs), exogenous LH (5 micrograms/day), testosterone (T; 30 micrograms/day), or both were administered to NalGlu-treated rats. After 7 days of treatment, we examined the effects on testis weight, Leydig cell morphology, and T production. The steady state messenger RNA (mRNA) levels for LHR, AR, cytochrome P450 17 alpha-hydroxylase, and 3 alpha-hydroxysteroid dehydrogenase in purified PLCs were measured by reverse transcription-polymerase chain reaction, with ribosomal protein S16 as the internal control. Treatment with NalGlu significantly decreased testis weight, resulted in an abundance of mesenchymal-like cells over immature Leydig cells, lowered T production, and reduced the levels of several Leydig cell mRNAs. Treatment with exogenous LH or T maintained testis weight and Leydig cell morphology in NalGlu-treated rats. The mRNA levels for LHR, AR, and 3 alpha-hydroxysteroid dehydrogenase were significantly increased by LH or T. P450 17 alpha-hydroxylase mRNA levels were elevated by LH to control level but strikingly reduced by T. Combined treatment with LH and T further increased basal T production but did not elevate mRNAs beyond the levels obtained with each hormone alone. LH and androgen act similarly in PLCs in promoting Leydig cell differentiation with respect to morphological and molecular landmarks. These findings support the hypothesis that androgen as well as LH is involved in the differentiation of immature Leydig cells from mesenchymal-like progenitors.

Suppression of endogenous corticosterone levels in vivo increases the steroidogenic capacity of purified rat Leydig cells in vitro.

In vitro studies have shown that corticosterone (B) directly inhibits testosterone (T) production by purified Leydig cells but does so only at high concentrations. 11 beta-Hydroxysteroid dehydrogenase (11 beta-HSD) in Leydig cells oxidatively inactivates B, lowering its effective concentration, thus protecting against the suppressive effect of glucocorticoid on T production. The aim of the present study was to assess the significance of B at physiological levels in modulating T production and 11 beta-HSd activity in Leydig cells. To determine the effects of endogenous B on Leydig cell steroidogenesis, male rats (200-250 g body wt) were adrenalectomized (ADX), while control rats were subjected to sham surgery (SHAM). Seven days after surgery: T and LH were measured in serum; T production was measured in aliquots of spent culture media from 3-h incubations of purified Leydig cells; 11 beta-HSD activity and messenger RNA was measured in purified Leydig cells. ADX rats had elevated serum T (P < 0.05) in contrast to SHAM control or ADX rats that received B replacement (1 mg/100 g body wt per day, i.p., on the final 3 days). Serum LH levels were uninfluenced by ADX, with or without B replacement (SHAM), 0.45 +/- 0.16 ng/ml; ADX, 0.35 +/- 0.13 ng/ml; ADX + B, 0.61 +/- 0.09 ng/ml, NS, P > 0.05). This indicated that the alteration of T production was induced by a mechanism that is independent of LH. ADX nearly doubled LH-stimulated T production by purified Leydig cells, from 106.3 +/- 9.3 (SHAM) to 183.2 +/- 16.7 (ADX) ng/10(6) cells.3 h (mean +/- SEM for three replications of the experiment, P < or = 0.02). T production by Leydig cells from the ADX + B treatment group was suppressed to 53% of SHAM values, indicating that B inhibits T production after ADX. The oxidative activity of 11 beta-HSD in Leydig cells exceeded its reductive activity, and both activities declined after ADX. The decline in 11 beta-HSD activities after ADX was prevented by B replacement. Similarly, the steady state levels of 11 beta-HSD messenger RNA declined in Leydig cells after ADX, and this decline was prevented by B replacement. We conclude that physiological levels of B exert a tonic, negative control directly on Leydig cell steroidogenesis and also induce intracellular 11 beta-HSD activity, thereby protecting against B-mediated inhibition of T production. By modulating the level of active glucocorticoid in Leydig cells, 11 beta-HSD is thus a significant determinant of their steroidogenic capacity.

Kinetic studies on the development of the adult population of Leydig cells in testes of the pubertal rat.

The objective of this study was to determine whether postnatal increases in rat Leydig cell number result from differentiation of precursor cells, division of existing Leydig cells, or both. Our approach was 1) to examine changes in the absolute number of Leydig cells and potential precursor cells (macrophages, pericytes, and mesenchymal, endothelial, and myoid cells) per testis on day 19 of gestation (day -2) and days 7, 14, 21, 28, and 56 postpartum; 2) to examine the frequency with which mesenchymal and Leydig cells divide during prenatal and postnatal development; and 3) to identify and examine the fate of the progeny of Leydig and mesenchymal cell divisions during prenatal and postnatal development. Stereological methods were used to show that mesenchymal cells comprised 44% of the total interstitial cell population and Leydig cells 16% on day -2, whereas by day 56 postpartum the relationship had reversed; mesenchymal cells comprised 3% and Leydig cells 49%. These results suggested a precursor-product relationship between mesenchymal and Leydig cells because no such reciprocal relationship was observed between Leydig cells and macrophages, pericytes, endothelial, or myoid cells. Autoradiographic analysis of [3H]thymidine incorporation into mesenchymal and Leydig cells was consistent with this interpretation. In a series of pulse-chase experiments, the percentage of labeled mesenchymal and Leydig cells was measured after a single injection of [3H]thymidine on days 2, 14, 28, and 56 postpartum, each followed by sampling at timed intervals (between 1 h and 14 days) thereafter. Starting on day 14, the percentage of labeled Leydig cells was approximately 1% immediately after injection of [3H]thymidine and increased significantly to approximately 6% by 6 days after injection. No such increase was observed when rats were similarly injected starting on days 2, 28, and 56 postpartum. The rise in Leydig cell labeling between days 14 and 28 postpartum did not result in a decline in the number of silver grains over labeled Leydig cell nuclei, indicating that the increase in the percentage of labeled cells was not caused by Leydig cell division. These observations led us to conclude that the increase in Leydig cell labeling from days 14 to 28 was the result of recruitment from a compartment of labeled mesenchymal cells. In contrast, our analysis indicated that from day 28 postpartum and thereafter until the mature number of Leydig cells is attained, Leydig cells are generated by division of morphologically recognizable Leydig cells.

Developmental changes in glucocorticoid receptor and 11beta-hydroxysteroid dehydrogenase oxidative and reductive activities in rat Leydig cells.

Glucocorticoids directly regulate testosterone production in Leydig cells through a glucocorticoid receptor (GR)-mediated repression of the genes that encode testosterone biosynthetic enzymes. The extent of this action is determined by the numbers of GR within the Leydig cell, the intracellular concentration of glucocorticoid, and 11beta-hydroxysteroid dehydrogenase (11betaHSD) activities that interconvert corticosterone (in the rat) and its biologically inert derivative, 11-dehydrocorticosterone. As glucocorticoid levels remain stable during pubertal development, GR numbers and 11betaHSD activities are the primary determinants of glucocorticoid action. Therefore, in the present study, levels of GR and 11betaHSD messenger RNA (mRNA) and protein were measured in rat Leydig cells at three stages of pubertal differentiation: mesenchymal-like progenitors (PLC) on day 21, immature Leydig cells (ILC) that secrete 5alpha-reduced androgens on day 35, and adult Leydig cells (ALC) that are fully capable of testosterone biosynthesis on day 90. Numbers of GR, measured by [3H]dexamethasone binding, in purified cells were 6.34 +/- 0.27 (x 10(3) sites/cell; mean +/- SE) for PLC, 30.45 +/- 0.74 for ILC, and 32.54 +/- 0.84 for ALC. Although GR binding was lower in PLC, steady state levels for GR mRNA were equivalent at all three stages (P > 0.05). Oxidative and reductive activities of 11betaHSD were measured by assaying the conversion of radiolabeled substrates in incubations of intact Leydig cells. Both oxidative and reductive activities were barely detectable in PLC, intermediate in ILC, and highest in ALC. The ratio of the two activities favored reduction in PLC and ILC and oxidation in ALC (oxidation/reduction, 0.33 +/- 0.33 for PLC, 0.43 +/- 0.05 for ILC, and 2.12 +/- 0.9 for ALC, with a ratio of 1 indicating equivalent rates for both activities). The mRNA and protein levels of type I 11betaHSD in Leydig cells changed in parallel with 11betaHSD reductive activity, which increased gradually during the transition from PLC to ALC, compared with the sharp rise that was seen in oxidative activity. We conclude that Leydig cells at all developmental stages have GR and that their ability to respond to glucocorticoid diminishes as net 11betaHSD activity switches from reduction to oxidation. This provides a mechanism for the Leydig cell to regulate its intracellular concentration of corticosterone, thereby varying its response to this steroid during pubertal development.

Identification of a kinetically distinct activity of 11beta-hydroxysteroid dehydrogenase in rat Leydig cells.

Leydig cells are susceptible to direct glucocorticoid-mediated inhibition of testosterone biosynthesis but can counteract the inhibition through 11beta-hydroxysteroid dehydrogenase (11beta-HSD), which oxidatively inactivates glucocorticoids. Of the two isoforms of 11beta-HSD that have been identified, type I is an NADP(H)-dependent oxidoreductase that is relatively insensitive to inhibition by end product and carbenoxolone (CBX). The type I form has been shown to be predominantly reductive in liver parenchymal cells and other tissues. In contrast, type II, which is postulated to confer specificity in mineralocorticoid receptor (MR)-mediated responses, acts as an NAD-dependent oxidase that is potently inhibited by both end product and CBX. The identity of the 11beta-HSD isoform in Leydig cells is uncertain, because the protein in this cell is recognized by an anti-type I 11beta-HSD antibody, but the activity is primarily oxidative, more closely resembling type II. The goal of the present study was to determine whether the kinetic properties of 11beta-HSD in Leydig cells are consistent with type I, type II, or neither. Leydig cells were purified from male Sprague-Dawley rats (250 g), and 11beta-HSD was evaluated in Leydig cells by measuring rates of oxidation and reduction, cofactor preference, and inhibition by end product and CBX. Leydig cells were assayed for type I and II 11beta-HSD and MR messenger RNAs (mRNAs), and for type I 11beta-HSD protein. Leydig cell 11beta-HSD had bidirectional catalytic activity that was NADP(H)-dependent. This is consistent with the hypothesis that type I 11beta-HSD is present in rat Leydig cells. However, unlike the type I 11beta-HSD in liver parenchymal cells, the Leydig cell 11beta-HSD was predominantly oxidative. Moreover, analysis of kinetics revealed two components, the first being low a Michaelis-Menten constant (Km) NADP-dependent oxidative activity with a Km of 41.5 +/- 9.3 nM and maximum velocity (Vmax) of 7.1 +/- 1.2 pmol x min x 10(6) cells. The second component consisted of high Km activities that were consistent with type I:NADP-dependent oxidative activity with Km of 5.87 +/- 0.46 microM and Vmax of 419 +/- 17 pmol x min x 10(6) cells, and NADPH-dependent reductive activity with Km of 0.892 +/- 0.051 microM and Vmax of 117 +/- 6 pmol x min x 10(6) cells. The results for end product and CBX inhibition were also inconsistent with a single kinetic activity in Leydig cells. Type I 11beta-HSD mRNA and protein were both present in Leydig cells, whereas type II mRNA was undetectable. We conclude that the low Km NADP-dependent oxidative activity of 11beta-HSD in Leydig cells does not confirm to the established characteristics of type I and may reside in a new form of this protein. We also demonstrated the presence of the mRNA for MR in Leydig cells, and the low Km component could allow for specificity in MR-mediated responses.

Mechanism of androgen-induced thymolysis in rats.

To investigate the mechanism of androgen-induced thymolysis, the effects of various androgens, including testosterone (T), 19-nortestosterone, and 7 alpha-methyl-19-nortestosterone (MENT), were compared with those of estradiol and dexamethasone (DEX) in intact, castrated, and adrenalectomized male rats. The potency comparisons on thymus regression, based on mass of steroids, showed DEX to be the most potent, followed by estradiol and the androgens. Among the androgens, MENT was the most potent, followed by nortestosterone and T, an order similar to their anabolic potency on muscle. As the thymolytic effects of T and MENT were not altered by the concomitant administration of an aromatase inhibitor or a 5-reductase inhibitor, it was concluded that the effects of androgens were not mediated by their conversion to estrogens or 5 alpha-reduced metabolites. Involvement of glucocorticoid receptors in androgen action was excluded because mifepristone (an antiglucocorticoid) blocked DEX-induced, but not T- or MENT-induced, thymus regression. Flutamide, an antiandrogen, significantly blocked the thymolytic effect of T and MENT, providing further support for this conclusion. This suggested that the thymolytic action of androgens is an intrinsic property mediated via androgen receptors (AR). The occurrence of AR in the thymus was demonstrated by binding assays and the presence of AR messenger RNA (mRNA) by reverse transcriptase-polymerase chain reaction. Quantitative reverse transcriptase-polymerase chain reaction for AR mRNA in the thymus showed 6-fold more AR mRNA in the thymic epithelial cells than in the thymocytes. However, epithelial cells represent only a small fraction of the thymus. Hence, it is hypothesized that the androgens produce their thymolytic effects by stimulating the secretion of a factor(s) by the thymic epithelial cells that, in turn, causes regression of the thymus.

Hormonal regulation of oxidative and reductive activities of 11 beta-hydroxysteroid dehydrogenase in rat Leydig cells.

We have proposed that the 11 beta-hydroxysteroid dehydrogenase (11 beta-HSD) of Leydig cells protects against glucocorticoid-induced inhibition of testosterone (T) production. However, Leydig cells express type I 11 beta-HSD, which has been shown to be reductive in liver parenchymal cells. Because reduction would have the opposite effect of activating glucocorticoid, the present study was designed to determine: 1) whether Leydig cell 11 beta-HSD is primarily oxidative or reductive; and 2) whether oxidative and reductive activities are separately modified by known regulators of Leydig cell steroidogenic function. Leydig cells and liver parenchymal cells were purified from mature male Sprague-Dawley rats (250 g BW), and 11 beta-HSD oxidative and reductive activities were measured using radiolabeled substrates and TLC of triplicate media samples from 1-h incubations immediately after cell isolation. Enzyme activities also were examined in purified Leydig cells at the end of 3 days of culture in vitro in the presence of LH (10 ng/ml), dexamethasone (DEX, 100 nM), T (50 nM), or epidermal growth factor (EGF, 50 ng/ml). In confirmation of previous reports, the reductive activity of 11 beta-HSD was predominant over oxidation in liver parenchymal cells. In contrast, 11 beta-HSD oxidative activity prevailed over reduction in Leydig cells by a ratio of 2:1. The activities of 11 beta-HSD also were analyzed in Leydig cells that were purified 7 days after endogenous glucocorticoid levels were suppressed by adrenalectomy (ADX). Oxidative activity declined in Leydig cells after ADX (22.53 +/- 1.12 pmol/h.10(6) cells, mean +/- SEM vs. 31.47 +/- 1.48 pmol/.10(6) cells in sham-operated controls, P < 0.05), whereas there was no change in reductive activity. This indicated that physiologically active corticosterone is involved in maintaining the predominance of 11 beta-HSD oxidation. When enzyme activities were analyzed in Leydig cells after 3 days of hormonal treatment in vitro, oxidation and reduction were observed to change in opposing directions. Culture of Leydig cells from sham-operated control rats with either LH, T, or EGF resulted in declines in oxidative activity from 33.35 +/- 0.77 to 28.24 +/- 1.93, 27.30 +/- 0.96, and 24.13 +/- 1.02 pmol/ h.10(6) cells (x +/- SE), respectively. However, EGF stimulated 11 beta-HSD reductive activity in cultured Leydig cells from both control (from 18.97 +/- 1.10 to 27.16 +/- 0.71 pmol/h.10(6) cells and ADX rats (from 16.51 +/- 0.75 to 23.56 +/- 0.84 pmol/h.10(6) cells). Among the hormonal treatments, only DEX increased oxidative activity and simultaneously decreased reductive activity in Leydig cells from ADX rats. This increase accentuated the predominance of oxidative activity in Leydig cells, with a ratio of oxidative to reductive activity of 4:1 after DEX treatment, compared with 2:1 in controls that were untreated. We conclude that 11 beta-HSD activity in Leydig cells is primarily oxidative. Moreover, oxidation and reduction are regulated separately by hormones.