Androgen profiles during pubertal Leydig cell development in mice.

Postnatal Leydig cell (LC) development in mice has been assumed empirically to resemble that of rats, which have characteristic hormonal profiles at well-defined maturational stages. To characterize the changes in LC function and gene expression in mice, we examined reproductive hormone expression from birth to 180 days, and quantified in vivo and in vitro production of androgens during sexual maturation. Although the overall plasma androgen and LH profiles from birth through puberty were comparable to that of rats, the timing of developmental changes in androgen production and steroidogenic capacity of isolated LCs differed. In mice, onset of androgen biosynthetic capacity, distinguished by an acute rise in androstenedione and testosterone production and an increased expression of the steroidogenic enzymes, cytochrome P450 cholesterol side-chain cleavage enzyme and 17alpha-hydroxylase, occurred at day 24 (d24) rather than at d21 as reported in rats. Moreover, in contrast to persistently high testosterone production by pubertal and adult rat LCs, testosterone production was maximal at d45 in mice, and then declined in mature LCs. The murine LCs also respond more robustly to LH stimulation, with a greater increment in LH-stimulated testosterone production. Collectively, these data suggest that the mouse LC lineage has a delayed onset, and that it has an accelerated pace of maturation compared with the rat LC lineage. Across comparable maturational stages, LCs exhibit species-specific developmental changes in enzyme expression and capacity for androgen production. Our results demonstrate distinct differences in LC differentiation between mice and rats, and provide informative data for assessing reproductive phenotypes of recombinant mouse models.

[1]  M. Hardy,et al.  Gene Expression During Development of Fetal and Adult Leydig Cells , 2007, Annals of the New York Academy of Sciences.

[2]  Shengqing Wan,et al.  Key factors in the regulation of fetal and postnatal leydig cell development , 2007, Journal of cellular physiology.

[3]  R. Sharma,et al.  Isolation and culture of Leydig cells from adult rats , 2006, Indian Journal of Clinical Biochemistry.

[4]  S. Baker,et al.  Pubertal and adult Leydig cell function in Mullerian inhibiting substance-deficient mice. , 2005, Endocrinology.

[5]  D. B. Hales,et al.  Overview of steroidogenic enzymes in the pathway from cholesterol to active steroid hormones. , 2004, Endocrine reviews.

[6]  D. Robertson,et al.  5α-Reductase Isoenzymes 1 and 2 in the Rat Testis During Postnatal Development1 , 2003 .

[7]  P. Baker,et al.  Changes in Leydig Cell Gene Expression During Development in the Mouse1 , 2002, Biology of reproduction.

[8]  Thomas D. Schmittgen,et al.  Analysis of relative gene expression data using real-time quantitative PCR and the 2(-Delta Delta C(T)) Method. , 2001, Methods.

[9]  M. Hardy,et al.  Purification of rat leydig cells: increased yields after unit-gravity sedimentation of collagenase-dispersed interstitial cells. , 2001, Journal of andrology.

[10]  L. Parada,et al.  A molecular basis for estrogen-induced cryptorchidism. , 2000, Developmental biology.

[11]  A. McMahon,et al.  Localization of 17β-Hydroxysteroid Dehydrogenase/17-Ketosteroid Reductase Isoform Expression in the Developing Mouse Testis-Androstenedione Is the Major Androgen Secreted by Fetal/Neonatal Leydig Cells. , 2000, Endocrinology.

[12]  H. Ariyaratne,et al.  Changes in the Testis Interstitium of Sprague Dawley Rats from Birth to Sexual Maturity1 , 2000, Biology of reproduction.

[13]  H. Ariyaratne,et al.  Differentiation of adult Leydig cells in the neonatal rat testis is arrested by hypothyroidism. , 1998, Biology of reproduction.

[14]  P. Baker,et al.  Localisation and regulation of 17β-hydroxysteroid dehydrogenase type 3 mRNA during development in the mouse testis , 1997, Molecular and Cellular Endocrinology.

[15]  B. Robaire,et al.  Steady state steroid 5 alpha-reductase messenger ribonucleic acid levels and immunocytochemical localization of the type 1 protein in the rat testis during postnatal development. , 1995, Endocrinology.

[16]  M. Hardy,et al.  Differentiation of adult Leydig cells , 1995, The Journal of Steroid Biochemistry and Molecular Biology.

[17]  D. Phillips,et al.  Differential regulation of steroidogenic enzymes during differentiation optimizes testosterone production by adult rat Leydig cells. , 1993, Endocrinology.

[18]  H. L. Roepers-Gajadien,et al.  Postnatal development of testicular cell populations in mice. , 1993, Journal of reproduction and fertility.

[19]  D. D. de Rooij,et al.  Proliferative activity of gonocytes, Sertoli cells and interstitial cells during testicular development in mice. , 1991, Journal of reproduction and fertility.

[20]  T. Kuopio,et al.  Basement membrane and epithelial features of fetal-type Leydig cells in rat and human testis. , 1989, Differentiation; research in biological diversity.

[21]  M. Hardy,et al.  Kinetic studies on the development of the adult population of Leydig cells in testes of the pubertal rat. , 1989, Endocrinology.

[22]  P. O’Shaughnessy,et al.  Testicular steroid metabolism during development in the normal and hypogonadal mouse. , 1988, The Journal of endocrinology.

[23]  J. Kerr,et al.  The fate of fetal Leydig cells during the development of the fetal and postnatal rat testis. , 1988, Development.

[24]  G. Risbridger,et al.  Morphometric analysis of the components of the neonatal and the adult rat testis interstitium. , 1987, International journal of andrology.

[25]  G. Klinefelter,et al.  Effect of luteinizing hormone deprivation in situ on steroidogenesis of rat Leydig cells purified by a multistep procedure. , 1987, Biology of reproduction.

[26]  G. Niswender,et al.  Serum levels of follicle stimulating hormone, luteinizing hormone, prolactin, testosterone, 5 alpha-dihydrotestosterone, 5 alpha-androstane-3 alpha, 17 beta-diol, 5 alpha-androstane-3 beta, 17 beta-diol, and 17 beta-estradiol from male beagles with spontaneous or induced benign prostatic hyperplasia , 1981, Investigative urology.

[27]  J. Downing,et al.  Luteinizing hormone receptors and testosterone synthesis in two distinct populations of Leydig cells. , 1980, Endocrinology.

[28]  A. Schuetz,et al.  Age-related changes in conversion of 5α-androstan-17β-ol-3-one to 5α-androstane-3α,17β-diol and 5α-androstane-3β,17β-diol by rat testicular cells in vitro , 1979 .

[29]  M. Welsh,et al.  Sertoli cell capacity to metabolize C19 steroids: variation with age and the effect of follicle-stimulating hormone. , 1978, Endocrinology.

[30]  B. Gondos,et al.  Leydig cell differentiation in the prepubertal rabbit testis. , 1977, Biology of reproduction.

[31]  H. R. Lindner,et al.  Antigenic complexes of steroid hormones formed by coupling to protein through position 7: preparation from 4 -3-oxosteroids and characterization of antibodies to testosterone and androstenedione. , 1972, Steroids.

[32]  F. S. French,et al.  Metabolism of progesterone by rat testicular homogenates. IV. Further studies of testosterone formation in immature testis in vitro. , 1971, Endocrinology.

[33]  P. Baker,et al.  Failure of normal Leydig cell development in follicle-stimulating hormone (FSH) receptor-deficient mice, but not FSHbeta-deficient mice: role for constitutive FSH receptor activity. , 2003, Endocrinology.

[34]  R. Rasmussen Quantification on the LightCycler , 2001 .

[35]  M. Hardy,et al.  Variation in the End Products of Androgen Biosynthesis and Metabolism during Postnatal Differentiation of Rat Leydig Cells * , 1998 .

[36]  M. Hardy,et al.  10 – Isolation and Culture of Leydig Cells from Adult Rats , 1993 .