Testicular degeneration in Bclw-deficient mice.

To identify genes required for mammalian spermatogenesis, we screened lines of mutant mice created using a retroviral gene-trap system for male infertility. Homozygous ROSA41 male mice exhibit sterility associated with progressive testicular degeneration. Germ-cell defects are first observed at 19 days post-natal (p19). Spermatogenesis is blocked during late spermiogenesis in young adults. Gradual depletion of all stages of germ cells results in a Sertoli-cell-only phenotype by approximately six months of age. Subsequently, almost all Sertoli cells are lost from the seminiferous tubules and the Leydig cell population is reduced. Molecular analysis indicates that the gene mutated is Bclw, a death-protecting member of the Bcl2 family. The mutant allele of Bclw in ROSA41 does not produce a Bclw polypeptide. Expression of Bclw in the testis appears to be restricted to elongating spermatids and Sertoli cells. Potential roles for Bclw in testicular function are discussed.

A deficiency of lunatic fringe is associated with cystic dilation of the rete testis.

Lunatic fringe belongs to a family of beta1-3 N-acetyltransferases that modulate the affinity of the Notch receptors for their ligands through the elongation of O-fucose moieties on their extracellular domain. A role for Notch signaling in vertebrate fertility has been predicted by the intricate expression of the Notch receptors and their ligands in the oocyte and granulosa cells of the ovary and the spermatozoa and Sertoli cells of the testis. It has been demonstrated that disruption of Notch signaling by inactivation of lunatic fringe led to infertility associated with pleiotropic defects in follicle development and meiotic maturation of oocytes. Lunatic fringe null males were found to be subfertile. Here, we report that gene expression data demonstrate that fringe and Notch signaling genes are expressed in the developing testis and the intratesticular ductal tract, predicting roles for this pathway during embryonic gonadogenesis and spermatogenesis. Spermatogenesis was not impaired in the majority of the lunatic fringe null males; however, spermatozoa were unilaterally absent in the epididymis of many mice. Histological and immunohistochemical analysis of these testes revealed the development of unilateral cystic dilation of the rete testis. Tracer dye experiments confirm a block in the connection between the rete testis and the efferent ducts. Further, the dye studies demonstrated that many lunatic fringe mutant males had partial blocks of the connection between the rete testis and the efferent ducts bilaterally.

Cooperativity between Sertoli cells and testicular peritubular cells in the production and deposition of extracellular matrix components.

We examined the synthesis and deposition of extracellular matrix (ECM) components in cultures of Sertoli cells and testicular peritubular cells maintained alone or in contact with each other. Levels of soluble ECM components produced by populations of isolated Sertoli cells and testicular peritubular cells were determined quantitatively by competitive enzyme-linked immunoabsorbent assays, using antibodies shown to react specifically with Type I collagen, Type IV collagen, laminin, or fibronectin. Peritubular cells in monoculture released into the medium fibronectin (432 to 560 ng/microgram cell DNA per 48 h), Type I collagen (223 to 276 ng/microgram cell DNA per 48 h), and Type IV collagen (350 to 436 ng/microgram cell DNA per 48 h) during the initial six days of culture in serum-free medium. In contrast, Sertoli cells in monoculture released into the medium Type IV collagen (322 to 419 ng/microgram cell DNA per 48 h) but did not form detectable amounts of Type I collagen or fibronectin during the initial six days of culture. Neither cell type produced detectable quantities of soluble laminin. Immunocytochemical localization investigations demonstrated that peritubular cells in monoculture were positive for fibronectin, Type I collagen, and Type IV collagen but negative for laminin. In all monocultures most of the ECM components were intracellular, with scant deposition as extracellular fibrils. Sertoli cells were positive immunocytochemically for Type IV collagen and laminin but negative for fibronectin and Type I collagen. Co-cultures of peritubular cells and Sertoli cells resulted in interactions that quantitatively altered levels of soluble ECM components present in the medium. This was correlated with an increased deposition of ECM components in extracellular fibrils. The data correlated with an increased deposition of ECM components in extracellular fibrils. The data presented here we interpret to indicate that the two cell types in co-culture act cooperatively in the formation and deposition of ECM components. Results are discussed with respect to the nature of interactions between mesenchymal peritubular cell precursors and adjacent epithelial Sertoli cell precursors in the formation of the basal lamina of the seminiferous tubule.

Transforming growth factor beta gene expression and action in the seminiferous tubule: peritubular cell-Sertoli cell interactions.

The potential role of transforming growth factor beta (TGF beta) as a mediator of cell-cell interactions within the seminiferous tubule was investigated through an examination of the local production and action of TGF beta. Sertoli cells and peritubular (myoid) cells were isolated and cultured under serum-free conditions. Secreted proteins from Sertoli cells and peritubular cells were found to contain a component that bound to TGF beta receptors in RRA. Reverse-phase chromatography of Sertoli cell and peritubular cell secreted proteins fractionated a protein with similar biochemical properties as TGF beta 1. This fractionated protein also contained TGF beta bioactivity in its ability to inhibit growth of an epidermal growth factor-dependent cell line. Both peritubular cells and Sertoli cells contained a 2.4 kilobase mRNA species that hybridized in a Northern blot analysis with a TGF beta 1 cDNA probe. TGF beta 1 gene expression was not detected in freshly isolated germ cells. TGF beta 1 alone was not found to influence Sertoli cell nor peritubular cell proliferation with cells isolated from a midpubertal stage of development. The effects of hormones and TGF beta on Sertoli cell differentiation and function were assessed through an examination of transferrin production by Sertoli cells. TGF beta 1 had no effect on transferrin production nor the ability of hormones to influence transferrin production. The presence of peritubular cells in a coculture with Sertoli cells also did not affect the inability of TGF beta 1 to act on Sertoli cells. Although Sertoli cell function did not appear to be influenced by TGF beta 1, peritubular cells responded to TGF beta 1 through an increase in the production of a number of radiolabeled secreted proteins. TGF beta 1 also had relatively rapid effects on peritubular cell migration and the promotion of colony formation in culture. Cocultures of Sertoli cells and peritubular cells responded to TGF beta 1 by the formation of large cell clusters with ball-like structures. Data indicate that TGF beta may have an important role in influencing the differentiation and migration of peritubular cells. Observations demonstrate the local production of TGF beta within the seminiferous tubule by Sertoli cells and peritubular cells and suggest that TGF beta may have a role as a paracrine-autocrine factor involved in the maintenance of testicular function.

Regulation of Sertoli cell differentiation by the testicular paracrine factor PModS: potential role of immediate-early genes.

Testicular peritubular cells produce a paracrine factor, PModS, under androgen control that modulates Sertoli cell functions that are essential for the process of spermatogenesis. PModS has a more dramatic effect on Sertoli cell differentiated functions in vitro than any regulatory agent previously shown to influence the cell, including FSH. Investigation of the actions of PModS on a molecular level have used transferrin expression as a marker of Sertoli cell differentiation. PModS was found to stimulate transferrin gene expression while having no effect on transferrin mRNA stability. The ability of PModS to elevate transferrin mRNA levels was inhibited by cycloheximide. Therefore, the actions of PModS require ongoing protein synthesis and appear to be indirectly mediated through trans-acting early event genes. PModS was found to dramatically increase mRNA levels for c-fos, but had no effect on c-jun mRNA levels. The c-fos mRNA levels increased transiently within a few minutes to a maximal level of stimulation at 1 h and returned to basal levels within 6 h. The rise in c-fos mRNA preceded the elevation in transferrin mRNA, which started to increase at 2 h to a maximum level between 6-12 h that was maintained at high levels for several days in cell culture. Treatment of Sertoli cells with an antisense c-fos oligonucleotide was found to inhibit the actions of PModS on transferrin expression. Combined results support the hypothesis that PModS acts indirectly through transcription factors (e.g. c-fos) to induce Sertoli cell differentiated functions (e.g. transferrin expression). Therefore, PModS appears to act as a differentiation-type factor to promote and maintain optimal Sertoli cell function.

Transforming growth factor-alpha and epidermal growth factor receptor gene expression and action during pubertal development of the seminiferous tubule.

The potential role of transforming growth factor-alpha (TGF-alpha) as a mediator of cell-cell interactions in the growth and development of the testis was examined. Developing rat testes were collected, and preparations of mesenchymal-derived peritubular cells and epithelial-like Sertoli cells were isolated from prepubertal, midpubertal, and late pubertal rat testes. The developmental expression of TGF-alpha and its receptor, the epidermal growth factor receptor (EGFR), in whole testis and isolated cell types was determined using a nuclease protection assay. TGF-alpha and EGFR gene expression were predominant early in testis development and decreased during pubertal development. TGF-alpha expression was greatest in prepubertal peritubular cells. Sertoli cell TGF-alpha expression remained relatively constant during development, with a slight decline at the later pubertal stages. EGFR gene expression was predominant in peritublar cells throughout development. A low level of EGFR expression was detected in Sertoli cells. Scatchard analysis confirmed the presence of high affinity receptors on peritubular cells; however, no functional receptors were detected on Sertoli cells from any stage of development examined. Interestingly, low-level EGFR gene expression was also detected in pachytene spermatocytes and round spermatids. TGF-alpha was found to stimulate [3H] thymidine incorporation into DNA and increase cellular proliferation of peritubular cells from each developmental stage, while having no effect on Sertoli cells. The in vivo physiological significance of TGF-alpha was evaluated in a line of transgenic mice which overexpress TGF-alpha in the mature testis. These transgenic animals had no abnormal testicular morphology or alterations in spermatogenesis. Observations demonstrate that gene expression of TGF-alpha and its receptor is high during early pubertal stages when somatic cell growth is predominant and low at late pubertal stages when somatic cell proliferation is reduced. TGF-alpha can act as an autocrine/paracrine mitogen for the mesenchymal-derived peritubular cell, while actions on the Sertoli cell population are not evident. The observation that spermatogenic cells express the EGFR gene, although the protein remains to be identified, implies that TGF-alpha may potentially mediate Sertoli-germinal cell interactions.

Basic helix-loop-helix proteins can act at the E-box within the serum response element of the c-fos promoter to influence hormone-induced promoter activation in Sertoli cells.

The Sertoli cell is a terminally differentiated testicular cell in the adult required to maintain the process of spermatogenesis. Previously basic helix-loop-helix (bHLH) factors and c-fos have been shown to influence Sertoli cell-differentiated functions. The induction of Sertoli cell differentiation appears to involve the serum response element (SRE) of the c-fos promoter to activate c-fos and intermediate bHLH factor(s) that regulate down-stream Sertoli cell-differentiated genes (e.g. transferrin expression). The SRE of the c-fos promoter is influenced through the serum response factor (SRF). Interestingly, an E-box nucleotide sequence is present within the SRE. bHLH proteins act through E-box elements, and the current study investigates the possibility that bHLH proteins may directly influence the SRE of the c-fos promoter. The activation of the c-fos promoter in Sertoli cells was found to be inhibited with the overexpression of the inhibitory HLH protein Id. Analysis of major response elements within the c-fos promoter demonstrated that the expression of Id specifically inhibited the activation of SRE in Sertoli cells and no other elements tested. Mutations in the E-box of the SRE also inhibited the activation of SRE, suggesting the direct role of bHLH proteins in regulating SRE activity in Sertoli cells. In contrast, the activation of SRE containing a mutated E-box was comparable to wild-type SRE in control stromal cells. Analysis of SRE oligonucleotide gel mobility shift assays with nuclear extracts from Sertoli cells demonstrated the presence of both the SRF and the ubiquitously expressed bHLH protein E12/E47. In contrast, no E12/E47 was detected in the SRE oligonucleotide gel shift using control stromal cell nuclear extracts. Observations suggest the binding of E12/E47 to SRE may be a cell-specific event. The SRF and bHLH proteins appear to bind to the SRE and activate the c-fos promoter in Sertoli cells. Observations provide evidence that a bHLH protein can interact with the SRE of the c-fos promoter to influence hormone-induced promoter activation. Cross-talk between these nuclear transcription factors appears to be instrumental in the control of Sertoli cell-differentiated functions.

Transforming growth factor-beta (beta 1, beta 2, and beta 3) gene expression and action during pubertal development of the seminiferous tubule: potential role at the onset of spermatogenesis.

The potential role of transforming growth factor-beta (TGF beta) as a mediator of cell-cell interactions during the pubertal development of the seminiferous tubule was examined. Mesenchymal-derived peritubular cells and epithelial-like Sertoli cells were isolated from prepubertal, midpubertal, and late pubertal rat testes. The developmental expression of the multiple forms of TGF beta (TGF beta 1, -beta 2, and -beta 3) in whole testis and isolated somatic cell types was determined using a nuclease protection analysis. TGF beta 1 and TGF beta 2 mRNA expression was predominant in the immature testis and decreased at the onset of puberty. TGF beta 3 mRNA expression, the most abundant form of TGF beta present, peaked at an early pubertal stage, coincident with the initiation of spermatogenesis. Peritubular and Sertoli cells expressed each isoform of TGF beta during development. Peritubular cell mRNA expression of TGF beta 1, -beta 2, and -beta 3 decreased during pubertal development upon differentiation of this cell type. Sertoli cell expression of TGF beta 1 increased slightly and plateaued during pubertal development. TGF beta 2 mRNA expression was evident only in immature prepubertal Sertoli cells. Sertoli cell mRNA expression of TGF beta 3 increased transiently at the onset of puberty, corresponding with the peak of expression observed during the analysis of whole testicular development. Immunoblot analysis indicated that both cultured peritubular and Sertoli cells can produce the proteins for TGF beta 1, -beta 2, and -beta 3. Analysis of the hormonal regulation of TGF beta expression revealed that FSH caused a dramatic decrease in Sertoli cell TGF beta 2 expression while having no effect on TGF beta 1 or TGF beta 3 expression. Potential actions of TGF beta in the seminiferous tubule were also examined. TGF beta 1 inhibited TGF alpha-induced [3H]thymidine incorporation into peritubular cell DNA with cells from each developmental stage examined. TGF beta 1 had no effect on Sertoli cell proliferation. Previously, germinal cells have been shown to be responsive to TGF beta. This study demonstrates the potential of having a unique hormone-dependent pattern of TGF beta isoform expression during postnatal organ development. Observations demonstrate that the suppression of TGF beta 2 expression, in part in response to FSH, and the transient increase in TGF beta 3 expression correlate with the onset of puberty and the induction of spermatogenesis.

Regulation of ovarian cell growth through the local production of transforming growth factor-alpha by theca cells.

The rapid proliferation of a tissue often requires the local production of a specific growth factor. The ovarian follicle is a rapidly growing tissue which contains two primary somatic cell types, granulosa cells and theca cells. Theca cells and granulosa cells were isolated from bovine ovaries and cultured to assess the possible local production of a growth factor within the ovarian follicle. Serum-free conditioned medium from theca cells, but not from granulosa cells, was found to contain a component that specifically bound to the epidermal growth factor (EGF) receptor. Therefore, theca cells appear to produce an EGF-like substance as a potential regulator of follicle cell growth. This result provides physiological significance to the previous observation that granulosa cells contain EGF receptors and respond to EGF to increase cell proliferation. Transforming growth factor-alpha (TGF alpha) is a protein that is structurally and functionally related to EGF and binds to the EGF receptor. Using a molecular probe to TGF alpha, theca cells were found to express the TGF alpha gene, which is consistent with the presence of an EGF-like substance in conditioned medium, but granulosa cells had no detectable TGF alpha gene expression. Similar analysis with a molecular probe to EGF demonstrated the apparent lack of EGF gene expression in theca cells or granulosa cells. As previously demonstrated with granulosa cells, the data presented indicate that theca cells also contain high affinity EGF receptors. TGF alpha was found to stimulate the growth of both granulosa and theca cells. These observations imply that within the ovarian follicle TGF alpha is produced by theca cells, which can subsequently have both a paracrine and an autocrine role in regulating follicle cell proliferation. Results presented demonstrate production of TGF alpha by a normal adult mesenchymal tissue and provide an example of a growth factor-mediated mesenchymal-epithelial cell interaction between theca cells and granulosa cells.

Cytodifferentiation of granulosa cells induced by gonadotropin-releasing hormone promotes fibronectin secretion.

An analysis of the hormonal regulation of fibronectin production by granulosa cells showed that GnRH stimulated fibronectin secretion. GnRH increased fibronectin production 2.5- to 5-fold over that of control untreated cultures and greater than 20-fold over that of FSH-treated cultures. The GnRH concentration required for a minimal response was 10(-10) M, and that required for a maximal response was 10(-8) M. In contrast to the effects of GnRH, FSH suppressed fibronectin production to low or undetectable levels. In addition, FSH abolished the actions of GnRH on fibronectin production. Treatment of cultured granulosa cells with either (Bu)2cAMP or methylisobutylxanthine to influence cellular cAMP levels mimicked the actions of FSH on fibronectin secretion. Similar to FSH, both (Bu)2cAMP and methylisobutylxanthine abolished the actions of GnRH on fibronectin production. These results indicated that an increase in cAMP levels resulted in suppression of fibronectin secretion by granulosa cells and inhibition of the actions of GnRH. Insulin treatment of granulosa cells also suppressed fibronectin secretion, but to a lesser extent than FSH. In addition, insulin inhibited the actions of GnRH on fibronectin production by approximately 40-50% of stimulated levels. GnRH promoted a state of cytodifferentiation of the granulosa cell which had a high level of fibronectin production and, as shown previously, a low level of steroidogenesis. In contrast, FSH promoted a state of cytodifferentiation which had a low level of fibronectin production and a high level of steroidogenesis Both fibronectin and steroidogenic enzymes (e.g. aromatase) provide useful markers for an analysis of the cytodifferentiation of granulosa cells between these two distinct differentiated states. Results are discussed in relation to the possible mechanisms controlling granulosa cell cytodifferentiation and the possible functions of fibronectin in the ovary.

Hormonal regulation of thecal cell function during antral follicle development in bovine ovaries.

The hormonal regulation of thecal cell function was investigated with cells isolated at various stages of antral follicle development. Bovine thecal cells were isolated from small antral, medium antral, and large Graffian follicles (small, medium, and large ovarian follicles). Serum-free cultures of thecal cells were established and viable for a minimum of 6-8 days of culture. The purity of the thecal cell population was characterized cytochemically and was found to contain less than 5% endothelial cell and/or granulosa cell contamination. The steroidogenic capacity of this purified population of thecal cells in serum-free culture was examined through an analysis of androgen and progesterone production. Androgen production was high during the first 3 days of culture, then declined to undetectable levels. Production of androstenedione was approximately 10-fold higher than production of testosterone. Progesterone production remained relatively constant throughout the 8-day culture period. hCG was found to stimulate androgen production during days 1-3 of culture, but had a negligible effect on progesterone production. In contrast, hCG stimulated progesterone production during days 3-6 of culture, but had a negligible effect on androgen production. Insulin stimulated progesterone production during days 3-6 of culture, but had no effect on androgen or progesterone production during days 1-3 of culture. The minimum effective concentrations of hCG and insulin required to stimulate steroidogenesis of the thecal cells ranged from approximately 1-10 ng/ml. Addition of serum to the cultures decreased androgen production and suppressed the hormone responsiveness of the cells. Thecal cells in culture appear to alter their steroidogenic capacity from an androgen-producing cell to a progesterone-producing cell. Analysis of the developmental regulation of thecal cell function revealed that androgen production and hormone responsiveness were relatively constant in small, medium, and large follicles. In contrast, progesterone production and hormone responsiveness were highest in small follicles, intermediate in medium follicles, and lowest in large follicles. A more general analysis of the developmental regulation of thecal cell function examined the secretion of radiolabeled proteins. A large number of radiolabeled proteins were secreted by thecal cells, ranging in molecular mass from 5-500 kDa. Interestingly, insulin and hCG had no major effect on secretion of proteins by cells isolated from any of the stages of development examined.(ABSTRACT TRUNCATED AT 400 WORDS)

Estrogen regulation of thecal cell steroidogenesis and differentiation: thecal cell-granulosa cell interactions.

Estrogen regulation of thecal cell steroidogenesis and differentiation was investigated with cells from ovarian antral follicles. Bovine theca interna cells were isolated and cultured in serum-free conditions to evaluate the effects of estradiol on thecal cell production of androstenedione, testosterone, and progesterone. Estradiol increased thecal cell androgen production throughout a 6-day culture period; however, the basal and stimulated levels of androgen production diminished after day 3 of culture. Androstenedione accumulation was approximately 10-fold greater than that of testosterone. In contrast to the stimulatory effects that estradiol had on androgen production, estradiol suppressed progesterone production throughout the 6-day culture period. Comparison of the effects of estradiol and hCG on thecal cells from small (less than 5 mm), medium (5-10 mm), and large (greater than 10 mm) antral follicles demonstrated that estradiol stimulated androgen production to a greater extent than hCG with cells from all of these stages of follicle development. Estradiol stimulation of androstenedione was greater in theca from small follicles than in theca from medium or large follicles. In contrast, suppressive effects of estradiol on progesterone were most apparent on thecal cells from medium and large follicles and less apparent on theca from small follicles. Estradiol stimulated androstenedione production in a dose-dependent fashion, with a minimum effective concentration of 10(-9) M and a maximum effective concentration of 10(-7)-10(-6) M. Concentrations greater than 10(-6) M estradiol resulted in a decline in the stimulatory response and may be important in the preovulatory follicle to suppress thecal cell androgen production and initiate the process of luteinization. Progesterone production was slightly stimulated by 10(-9) M estradiol, whereas higher concentrations (10(-7)-5 x 10(-6) M) resulted in a dose-dependent suppression of progesterone production. Interestingly, combined treatment of thecal cells with estradiol and hCG resulted in a greater than additive stimulation of androstenedione production, and estradiol decreased the ability of hCG to stimulate progesterone production. Observations demonstrate that estradiol can dramatically alter thecal cell production of steroids and support a hypothesis that steroid-mediated interactions between granulosa and thecal cells play an important role in regulating cellular function within follicles. The data provide evidence that a local feedback loop may exist in ovarian follicles, where androgens produced by thecal cells are used as a substrate for granulosa cell aromatization into estrogens, which, in turn, may feed back to stimulate thecal cell production of androgens.(ABSTRACT TRUNCATED AT 400 WORDS)

Basic fibroblast growth factor (bFGF) gene expression and protein production during pubertal development of the seminiferous tubule: follicle-stimulating hormone-induced Sertoli cell bFGF expression.

The potential role of basic fibroblast growth factor (bFGF) as a mediator of cell-cell interactions in the growth and development of the testis was examined. Nuclease protection analysis was used to evaluate bFGF gene expression in the testis and other male reproductive tract tissues. bFGF expression was evident in seminal vesicle, prostate, epididymis, and, at low levels, testis of 20-day-old rats. The developmental expression of bFGF in whole testis and isolated somatic cells types was determined. Mesenchymal-derived peritubular cells and epithelial-like Sertoli cells were isolated from prepubertal, midpubertal, and late pubertal rat testes. In whole testis, bFGF expression is predominant early in prepubertal testicular development and decreases with sexual maturity. Both freshly isolated peritubular and Sertoli cells express bFGF at relatively constant levels during pubertal development, with a slight suppression at the late pubertal stages. Freshly isolated mature Leydig cells also expressed low levels of bFGF. Cultured Sertoli and peritubular cells produced bFGF-like proteins, including 18- and 24-kilodalton forms. Interestingly, FSH increased Sertoli cell bFGF gene expression and protein production. Previously, FSH and bFGF have been shown to stimulate immature Sertoli cell growth. The results of the current study suggest that the ability of FSH to regulate testis and Sertoli cell proliferation may in part be indirectly mediated through the local production and action of bFGF. bFGF has also previously been shown to localize in developing germinal cells. Therefore, FSH-induced Sertoli cell bFGF expression may mediate Sertoli-germinal cell interactions involved in the control of the spermatogenic process. Observations demonstrate the presence of bFGF at a time coinciding with active growth of the somatic cell populations of the seminiferous tubule. Potential roles for bFGF in the seminiferous tubule to consider include angiogenesis of the tubule, prepubertal Sertoli cell proliferation, and mediating Sertoli-germinal cell interactions.

Developmental and hormonal regulation of bovine granulosa cell function in the preovulatory follicle.

Bovine granulosa cells were isolated from small antral, medium antral, and large Graffian follicles (i.e. small, medium, and large preovulatory follicles). Serum-free cultures of granulosa cells were established and found to be viable for 3-6 days of cell culture. Radiolabeled granulosa cell-secreted proteins were obtained and analyzed electrophoretically. No major changes were detected in the protein profiles of small, medium, and large follicle granulosa cells. FSH and insulin, however, had a dramatic effect on granulosa cell-secreted proteins and increased the apparent production of 200K, 65K, 25K, and 15K proteins. The effects of these hormones on the radiolabeled secreted proteins were similar for small, medium, and large follicle granulosa cells. Aromatase activity was high for the first day of serum-free granulosa cell culture and subsequently declined to low levels. Both FSH and insulin alone stimulated aromatase activity, while a combination of hormones resulted in an additive response similar to the stimulation observed with 10% calf serum. Although the level of aromatase activity increased slightly with the size of the follicle, the effects of hormones were independent of follicle size. Progesterone production was low on days 1 and 2 of serum-free granulosa cell culture and high on days 3 and 6 of cell culture. Interestingly, FSH and insulin suppressed progesterone production on day 1 of cell culture for small and medium follicle granulosa cells, but not for large follicle cells. In contrast, hormones stimulated progesterone production on days 3 and 6 of granulosa cell culture, and the level of progesterone production increased with the size of the follicle. The stimulatory effects of hormones on days 3 and 6 of the culture were similar for medium and large follicle granulosa cells, but were altered for small follicle cells. Results indicate that when aromatase activity is high and stimulated by hormones, progesterone levels are low and generally suppressed by the same regulatory agents. Conversely when progesterone levels are high and hormone responsive, aromatase activity is low. The inverse relationship between aromatase activity and progesterone production implies that bovine granulosa cells alter their differentiated state in culture from an estrogen-producing cell to a progesterone-producing cell. Combined observations indicate that the results obtained on day 1 of culture probably reflect the developmental and hormonal regulation of granulosa cell function in the preovulatory follicle, while data obtained at later times in culture reflect the ability of the cell to synthesize progesterone and develop a luteinization-like activity.(ABSTRACT TRUNCATED AT 400 WORDS)

Regulation of Sertoli cell function and differentiation through the actions of a testicular paracrine factor P-Mod-S.

The current study was designed to investigate the actions of the testicular paracrine factor P-Mod-S on Sertoli cell function and differentiation. Transferrin production by Sertoli cells was stimulated by P-Mod-S to a greater extent than any individual regulatory agent and in a manner similar to a combination of FSH, insulin, retinol, and testosterone (FIRT). P-Mod-S had an additive response in combination with FIRT. The increase in transferrin production with a combination of P-Mod-S and FIRT is the highest level of stimulation (up to 8-fold) observed. These profound effects of P-Mod-S on Sertoli cell function implied a potential unique mechanism of action for the paracrine factor. FSH and FIRT significantly stimulated cAMP levels with both 60-min and 72-h treatments. In contrast, P-Mod-S had no effect on cAMP levels with a 60-min treatment and only a small increase with a 72-h treatment. Interestingly, P-Mod-S stimulated cGMP levels that remained above basal levels up to 72 h of treatment. FSH had no effect on cGMP levels. P-Mod-S did not affect inositol phosphate hydrolysis with treatments between 15 and 60 min. The actions of P-Mod-S on cGMP levels influenced Sertoli cell function on a molecular level. Northern blot analysis indicated that P-Mod-S and FIRT both stimulated the apparent levels of the 2.6-kilobase transcript of transferrin and the 1.7-kilobase transcript of androgen-binding protein. A solution hybridization procedure was used to quantitate the influence of P-Mod-S on Sertoli cell gene expression. P-Mod-S stimulated steady state levels of both transferrin and androgen-binding protein message approximately 2-fold, similar to the effects of FIRT. Both forms of P-Mod-S had similar biological activities and mechanisms of action. P-Mod-S (A) and P-Mod-S (B) both stimulated cGMP, altered Sertoli cell gene expression, and had profound effects on transferrin production. Although slightly different biochemically, both forms of P-Mod-S appear to be functionally similar. Combined observations indicate that the paracrine factor produced by peritubular cells, P-Mod-S, acts on Sertoli cells in part through a cGMP-mediated response to influence the expression of specific genes which subsequently have profound effects on Sertoli cell function and differentiation.

Transforming growth factor-alpha and -beta differentially regulate growth and steroidogenesis of bovine thecal cells during antral follicle development.

The actions and interactions of transforming growth factor-alpha (TGF alpha) and TGF beta on growth and differentiation of bovine thecal cells were investigated. Bovine thecal interna cells were isolated from small (less than 5 mm), medium (5-10 mm), and large (greater than 10 mm) antral follicles and cultured in the presence or absence of TGF alpha and/or TGF beta. Both [3H]thymidine incorporation and changes in cell number (i.e. DNA levels) were evaluated to determine effects on thecal cell growth. Short term treatment of cells with TGF alpha (18-24 h) stimulated thymidine incorporation, and longer term treatments (4 days) increased cell number. TGF beta suppressed thymidine incorporation below that observed in untreated cultures, but had no effect on cell number. When combined with TGF alpha, TGF beta suppressed the ability of TGF alpha to stimulate thymidine incorporation and increase cell number. The response to these growth factors was similar for cells isolated from the different stages of antral follicle development. The effects of TGF alpha and TGF beta on thecal cell differentiation were evaluated by quantitating changes in androstenedione and progesterone accumulation in cultures treated with TGFs in the absence (basal) or presence of hCG, estradiol (E2), or a combination of hCG and E2. E2 and hCG were included in this study because previous research has demonstrated that these hormones alter thecal cell steroidogenesis. Treatment with TGF alpha resulted in a suppression of basal and hormonally stimulated accumulation of androstenedione during days 0-3 of culture, whereas TGF beta did not significantly alter androstenedione accumulation. TGF alpha also suppressed progesterone accumulation during days 0-3 of culture in the absence or presence of hormones. In contrast, TGF beta stimulated accumulation of progesterone in cultures that did not contain E2, which suppressed progesterone during this period. Therefore, during days 0-3 of culture, TGF alpha appears to have suppressive effects on androstenedione and progesterone production, whereas TGF beta can stimulate progesterone production in the absence of E2. During days 3-6 of culture, thecal cell differentiation changes, and the capacity to produce androstenedione dramatically declines, while the capacity to produce progesterone increases. During this period, either TGF alpha or TGF beta slightly increased basal progesterone accumulation and partially suppressed the ability of hCG to stimulate progesterone. The effects of TGFs on thecal cell steroidogenesis were similar with cells isolated from the different stages of antral follicle development. Results from these studies provide evidence that THF alpha and TGF beta can modulate thecal cell growth and differentiation (i.e. steroidogenesis).(ABSTRACT TRUNCATED AT 400 WORDS)

Direct actions of kit-ligand on theca cell growth and differentiation during follicle development.

The direct actions of kit-ligand/stem cell factor (KL) in developing ovarian follicles were investigated. Previous studies have shown that granulosa cells express KL that can support oocyte development. The current study demonstrates that KL can also act directly on theca cells to promote cellular growth and differentiation. Through RT-PCR analysis it was shown that bovine granulosa cells express KL, and theca cells express the receptor c-kit. Bovine theca interna cells were isolated and cultured in serum-free conditions to study KL actions. KL stimulated theca cell growth in a dose-dependent manner as measured by [3H]thymidine incorporation into DNA when cells were cultured under subconfluent conditions. KL had no effect on theca cell androstenedione or progesterone production under these growth-permissive conditions. In contrast, KL stimulated theca cell androstenedione production but had no effect on progesterone production when theca cells were cultured under confluent (non-growth-permissive) conditions. Estradiol (10(-7) M) and human CG (100 ng/ml) were used as controls and regulated theca cell steroid production at any cell density. These results demonstrate that KL can directly stimulate theca cell growth and steroid production during follicular development. The observation that KL stimulated androstenedione production but not progesterone production suggests that KL promotes a follicular phase differentiated state in theca cells. The potential regulation of KL and c-kit expression during follicular development was studied using a specific quantitative RT-PCR procedure. Total RNA from granulosa cells (for KL) and theca cells (for c-kit) was examined from small (<5 mm), medium (5-10 mm), and large (>10 mm) size follicles. Steady state levels of KL messenger RNA were highest in granulosa cells from large size follicles and lowest in small and medium size follicles. No differences were observed in the steady state levels of c-kit messenger RNA in theca cells from small, medium, or large size follicles. The observation that KL expression is highest in large size follicles suggests that KL may be important for increased growth and steroid production in large and dominant follicles. Observations demonstrate that KL can dramatically alter theca cell function and support the hypothesis that local granulosa-theca cell interactions play an important role in regulating cellular function within ovarian follicles. This study identifies KL as the first granulosa cell-derived growth factor that can directly stimulate theca cell growth and androstenedione production in the absence of gonadotropins.

E-box and cyclic adenosine monophosphate response elements are both required for follicle-stimulating hormone-induced transferrin promoter activation in Sertoli cells.

Sertoli cells are the epithelial cells responsible for the onset of pubertal development and maintenance of spermatogenesis in the adult. Transferrin is one of the major secretory products expressed by differentiated Sertoli cells. Investigation of the transcriptional control of transferrin gene expression provides insight into the regulation of Sertoli cell differentiation. Analysis of the mouse transferrin (mTf) promoter reveals the presence of a number of conserved response elements that have previously been shown to regulate cell specific expression of the human transferrin (hTf) promoter. One of these elements is the human PRII region, which is a cAMP response element (CRE)-like element that is more than 80% conserved in the mTf promoter. The activation of the hTf promoter by FSH and cAMP in rat Sertoli cells has been shown to be mediated in part through the CRE-like PRII region and binding of the CRE binding protein (CREB). The present study investigates the role of PRII in the activation of mTf promoter by FSH and cAMP in rat Sertoli cells. Mutations in the PRII of the mTf promoter reduced FSH activation by only 50% and cAMP activation by more than 90%. In contrast, the mutant PRII mTf promoter construct was fully activated by a partially purified testicular paracrine activity PModS(S300). Gel shift experiments demonstrated that proteins that can bind a consensus CRE oligonucleotide also bind the PRII region of the mTf promoter. An immunoblot confirmed that CREB binds the PRII and promotes the gel shift observed. The hypothesis developed was that another cis-acting element in addition to the CRE-like PRII is also involved in FSH actions. A conserved response element in both the mTf and hTf promoters is the basic helix-loop-helix (bHLH) responsive E-box sequence. Both FSH and PModS (S300) activity were found to promote a mTf E-box gel shift that contained the E2A gene product the bHLH protein E47. Interestingly, mutations in the E-box of the mTf promoter completely abolished the PModS(S300) activation and partially (52%) inhibited the activation by FSH. In contrast, the mutant E-box mTf promoter construct was fully activated by cAMP. Finally a double mutation of both the PRII and the E-box completely abolished FSH activation of the mTf promoter. These results suggest that optimal activation of the mouse transferrin promoter by FSH requires both CREB binding to the CRE-like PRII region and bHLH binding to the E-box. Information is provided that indicates a number of Sertoli cell promoters contain a close association of E-box and CRE-like elements. Observations are discussed in regards to the potential interactions of the CRE and E-box response elements in mediating FSH actions in Sertoli cells.

Control of fibronectin synthesis by rat granulosa cells in culture.

The secreted and cellular [35S]methionine-radiolabeled proteins of cultured rat granulosa cells were separated by electrophoresis on sodium dodecylsulfate (SDS) polyacrylamide gradient slab gels. From 24 to 72 h of culture FSH increased the intensity of labeling of most of the secreted proteins. A 220,000-dalton protein, however, increased in intensity only in control cultures and became the major secreted protein after 72 h, comprising 20% of the total radiolabeled proteins. This protein was identified as fibronectin by immunoprecipitation. There was no increase in the secreted or cellular fibronectin in FSH- or testosterone- and insulin-treated cultures. These studies indicate that a component of extracellular matrix is a major secretory product of unstimulated immature granulosa cells. As hormones induce the differentiated functions of granulosa cells in culture, the secretion of fibronectin is inhibited.

Kit-ligand/stem cell factor induces primordial follicle development and initiates folliculogenesis.

Initiation of folliculogenesis through the induction of primordial follicle development in the ovary has an important role in determining the fertility and reproductive fitness of most mammalian species. The factors that control this critical process are largely unknown. The hypothesis tested in the current study was that kit-ligand/stem cell factor (KL) promotes the initiation and progression of primordial follicle development in the ovary. Ovaries from 4-day-old rats were maintained in organ culture for 5 and 14 days and treated with no factor (control), recombinant kit-ligand (KL), or gonadotropins (FSH and hCG). Follicles in ovarian sections were counted and histologically classified as primordial (stage 0), early primary (stage 1), primary (stage 2), transitional (stage 3), or preantral (stage 4). Fresh ovaries from 4-day-old rats contained 68% primordial follicles (stage 0) and 32% developing follicles (stages 1-4) per section. After 5 and 14 days in culture, section from control ovaries contained approximately 41% and 55%, respectively, developing follicles (stage 1-4) per section due to spontaneous development of primordial follicles. Spontaneous primordial follicle development was completely blocked by ACK-2, a c-kit antibody that blocks KL actions. This observation suggests that endogenous KL is necessary for primordial follicle development in vitro. After 14 days of KL treatment, sections from ovaries contained 17% primordial follicles (stage 0) and 83% developing follicles (stage 1-4) per section demonstrating a dramatic induction of primordial follicle development by KL. Gonadotropins (FSH and hCG) did not induce primordial follicle development but did increase the percentage of preantral follicles (stage 4) per section. This small increase in preantral follicles in response to gonadotropins was blocked by ACK-2 suggesting that KL may in part mediate gonadotropin actions after the initiation of primordial follicle development. Ovaries contained an average of 309+/-10 follicles per section. The total number of follicles per section did not significantly vary between treatments suggesting that the effects of KL were not due to an alteration in follicle number (i.e. survival). KL appears to be one of the first factors identified to be involved in the promotion of primordial follicle development. Results suggest that KL is necessary and sufficient to induce primordial follicle development and initiate folliculogenesis.