Abstract
The mechanisms underlying the antifertility effects of hyperprolactinemia have yet to be established in an appropriate experimental model. Hyperprolactinemia is a known side effect of fluphenazine, a broad spectrum, long-acting phenothiazine known to be dopamine type-D2 receptor antagonist. In our earlier study in adult male rats, we reported that fluphenazine at a dose of 3 mg/kg/day suppressed serum FSH but not testosterone (T) through increasing dopamine (DA) metabolism in the pituitary gland, within 60 days. Fluphenazine treatment affected sperm quality and male rats treated with fluphenazine sired fewer litters. The effects of fluphenazine-induced hyperprolactinemia on sperm quality appeared to be related to reduced FSH. We now report that FSH suppression enhanced the uptake of acridine orange (AO), a DNA intercalating, fluorescent dye by the fluphenazine- treated caput epididymal sperms with concomitant reduction in the uptake of thiolspecific monobromobimane (mBBr) fluorescent dye in vitro, suggesting greater accessibility of DNA intercalating dye to sperm chromatin and reduction in free sperm protein thiols. The concomitant increase in AO and decrease in mBBr fluorescence was suggestive of loose chromatin packaging in caput epididymal sperms after treatment with fluphenazine at 3 mg/kg/day for 60 days. The suppression in levels of protamine (P1) in caput epididymal sperms suggested that chromatin hypocompaction was due to reduced deposition of protamines in sperm chromatin. Reduction in testicular levels of cyclic adenosyl 3′, 5′ monophosphate response element modulator (CREMτ) and P1 further suggested that reduced deposition was indeed due to reduced synthesis. The concomitant reduction in testicular levels of transition protein 1 (TP1) and transition protein 2 (TP2) also suggested that hypoprotamination was due to reduced synthesis of these proteins crucial for facilitating P1 deposition. The effect appeared to have occurred at the level of translation of CREMτ, since its transcript levels were unaffected whereas those of TP1, TP2 and P1 and protamine were upregulated. The study led to the view that the effects of FSH suppression were manifest on the posttranscriptional modifications of CREMτ, as also on transcript repression of TP1, TP2, P1, which do the RNA-binding proteins bring about. Reduction in FSH did not decrease ABP expression in the testis, which has recently been implicated in the expression of transition protein 1 in vitro. However, a significant reduction was evident after fluphenazine treatment, in the immunoexpression of testicular cAMP, the mediator of FSH effects in the Sertoli cells and putative mediator of ABP effects in the spermatids. The study suggests that fluphenazine-induced hyperprolactinemia suppressed FSH and affected a putative cAMP-dependent mechanism underlying posttranscriptional modification of spermatidal genes involved in chromatin condensation, presumably by reducing the availability/secretion of ABP, a paracrine regulator of spermiogenesis in vitro.
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References
De Rosa M, Zarrilli S, Vitale G, et al. Six months of treatment with cabergoline restores sexual potency in hyperprolactinemic males: an open longitudinal study monitoring nocturnal penile tumescence. J Clin Endocrinol Metab 2004, 89: 621–5.
Katovich MJ, Cameron DF, Murray FT, Gunsalus GL. Alterations of testicular function induced by hyperprolactinemia in the rat. J Androl 1985, 6: 179–89.
Laszczynska M, Sluczanowska-Glabowska S, Piasecka M, Skowron J, Debinska-Szymanska T. Germ cells with nuclear DNA fragmentation related to apoptotic cells in rat testis in experimental hyperprolactinemia induced by metoclopramide. Folia Histochem Cytobiol 2002, 40: 163–4.
Bartke A. Hyperprolactinemia and male reproduction. In: Paulsen JD, Negro-Vilar A, Lucina E, Martini L eds. Andrology, male fertility and sterility. New York: Academic Press. 1986, 101–23.
Gill-Sharma MK, D’Souza S, Padwal V, et al. Antifertility effects of estradiol in adult male rats. J Endocrinol Invest 2001, 24: 598–607.
Okada H, Iwamoto T, Fujioka H, et al. Hyperprolactinaemia among infertile patients and its effect on sperm functions. Andrologia 1996, 28: 197–202.
Eggert-Kruse W, Schwalbach B, Gerhard I, Tilgen W, Runnebaum B. Influence of serum prolactin on semen characteristics and sperm function. Int J Fertil 1991, 36: 243–51.
Gill-Sharma MK, Aleem M, Sethi G, et al. Antifertility effects of fluphenazine in adult male rats. J Endocrinol Invest 2003, 26: 316–26.
Grover A, Sairam M, Smith CE, Hermo L. Structural and functional modifications of Sertoli cells in the testis of adult follicle-stimulating hormone receptor knockout mice. Biol Reprod 2004, 71: 117–29.
Krishnamurthy H, Danilovitch N, Morales CR, Sairam MR. Qualitative and quantitative decline in spermatogenesis of the follicle stimulating hormone receptor knockout (FORKO) mouse. Biol Rep 2000, 62: 1146–59.
Krishnamurthy K, Kats R, Danilovitch N, Javeshghani D, Sairam RM. Intercellular communication between Sertoli cells and Leydig cells in the absence of follicle stimulating hormone receptor signaling. Biol Rep 2001, 65: 1201–7.
Saxlund MA, Sadler-Riggleman I, Skinner MK. Role of basic helix-loop-helix (bHLH) and CREB transcription factors in the regulation of Sertoli cell androgen-binding protein expression. Mol Reprod Dev 2004, 68: 269–78.
Murty GS, Rani CS, Moudgal NR, Prasad MR. Effect of passive immunization with specific antiserum to FSH on the spermatogenic process and fertility of adult male bonnet monkeys (Macaca radiata). J Reprod Fertil 1979, 26 (Suppl.): 147–63.
McLachlan RI, Robertson DM, De Kretser DM, Burger HG. Advances in the physiology of Inhibin and Inhibin-related peptides. Clin Endocrinol 1988, 29: 77–114.
Blok LJ, Hoogerbrugge JW, Themmen AP, Baarends WM, Post M, Grootegoed JA. Transient down-regulation of androgen receptor messenger ribonucleic (mRNA) expression in Sertoli cells by follicle stimulating hormone is followed by up-regulation of androgen receptor mRNA and protein. Endocrinology 1992, 13: 1343–9.
Armstrong DT, Moon YS, Fritz IB, Dorrington JH. Synthesis of estradiol 17 by Sertoli cells in culture: Stimulation by FSH and dibutyrl camp. In: French FS, Hansson V, Ritzen EM, Nayfeh SN eds. Hormonal regulation of spermatogenesis. New York: Plenum Press. 1975, 85.
Lamas M, Sassone-Corsi P. The dynamics of the transcriptional response to cyclic adenosine 3′–5′-monophosphate: recurrent inducibility and refractory phase. Mol Endocrinol 1997, 11: 1415–24.
Dym M, Raj HG, Lin YC, et al. Is FSH required for maintenance of spermatogenesis in adult rats? J Reprod Fertil 1979, 26 (Suppl.): 175–81.
Anthony CT, Danzo BJ, Orgebin-Crist MC. Investigations on the relationship between sperm fertilizing ability and androgen-binding protein in the restricted rat. Endocrinology 1984, 114: 1413–8.
Anthony CT, Danzo BJ, Orgebin-Crist MC. Investigations on the relationship between sperm fertilizing ability and androgen-binding protein in the hypophysectomized, pregnenoloneenolone injected rat. Endocrinology 1984, 114: 1419–25.
Ritzen EM, Boitani C, Parvinen M, French FC, Feldman M. Stage dependent secretion of ABP by rat seminiferous tubules. Mol Cell Endocrinol 1982, 25: 25–33.
Joseph DR. Structure, function and regulation of androgen-binding protein/sex hormone-binding globulin. Vitam Horm 1994, 49: 197–280.
Reventos J, Sullivan PM, Joseph DR, Gordon JW. Tissue-specific expression of the rat androgen-binding protein/sex hormone-binding globulin gene in transgenic mice. Mol Cell Endocrinol 1993, 96: 69–73.
Della-Maria JD, Gerard A, Franck P, Gerard H. Effects of androgen-binding protein (ABP) on spermatid tnp1 expression in vitro. Mol Cell Endocrinol 2002, 198: 131–41.
Kierszenbaum AL. Transition nuclear proteins during spermiogenesis: Unrepaired DNA breaks not allowed. Mol Rep Dev 2001, 58: 357–8.
Caron N, Veilleux S, Boissonneault G. Stimulation of DNA repair by the spermatidal TP1 protein. Mol Reprod Dev 2001, 58: 437–43.
Blendy JA, Kaestner KH, Weinbauer GF, Nieschlag E, Schutz G. Severe impairment of spermatogenesis in mice lacking the CREM gene. Nature 1996, 380: 162–5.
Shalgi R, Seligman J, Kosower NS. Dynamics of thiol status of rat spermatozoa during maturation: Analysis with the flourescent labelling agent monobromobimane. Biol Rep 1989, 40: 1037–45.
Lowry OH, Roseborough NJ, Farr AL, Randall RJ. Protein measurement with folin phenol reagent. J Biol Chem 1951, 193: 265–75.
Laemmli UK. Cleavage of structural proteins during the assembly of the head of bacteriophage T4. Nature 1970; 227: 680–5.
Kistler WS, Henriksen K, Mali P, Parvinnen M. Sequential expression of nucleoproteins during rat spermiogenesis. Exp Cell Res 1996, 225: 274–81.
Hue D, Staub C, Perrard-Sapori MH, et al. Meiotic differentiation of germinal cells in three-week cultures of whole cell population from rat seminiferous tubules. Biol Reprod 1998, 59: 379–87.
Klemm U, Lee CH, Burfeind P, Hake S, Engel W. Nucleotide sequence of a cDNA encoding rat protamine and the haploid expression of the gene during rat spermatogenesis. Biol Chem Hoppe Seyler 1989, 370: 293–301.
Foulkes NS, Mellstrom B, Benusiglio E, Sassone-Corsi P. Developmental switch of CREM function during spermatogenesis: from antagonist to activator. Nature 1992, 355: 80–4.
Selva DM, Tirado OM, Toran N, Suarez-Quin CA, Reventos J, Munell F. Meiotic arrest and germ cell apoptosis in androgen-binding protein transgenic mice. Endocrinology 2000, 141: 1168–77.
Pascolini R, Ceccarelli P, Gargiulo AM, Lorvik S. Immunohistochemical localization of cyclic AMP and ultrastructural demonstration of adenylate cyclase activity in the testis of Esox lucius at time of spermiation. Cell Tissue Res 1985, 239: 443–5.
Lee K, Haugen HS, Clegg CH, Braun RE. Premature translation of protamine1 mRNA causes precocious nuclear condensation and arrests spermatid differentiation in mice. Proc Natl Acad Sci USA 1995, 92: 12451–5.
Meistrich ML, Brook WA, Grimes SR, Platz RD, Hnilica LS. Nuclear protein transitions during spermatogenesis. Fed Proc 1978, 37: 2522–5.
Yu YE, Zhang Y, Unni E, et al. Abnormal spermatogenesis and reduced fertility in transition nuclear protein 1-deficient mice. Proc Natl Acad Sci USA 2000, 97: 4683–8.
Nantel F, Monaco L, Foulkes NS, et al. Spermiogenesis deficiency and germ cell apoptosis in CREM-mutant mice. Nature 1996, 380: 162–6.
Foulkes NS, Schlotter F, Pevet P, Sassone-Corsi P. Pituitary hormone FSH directs the CREM functional switch during spermatogenesis. Nature 1993, 362: 264–7.
Dierich A, Sairam MR, Monaco L, et al. Impairing follicle-stimulating hormone (FSH) signaling in vivo: targeted disruption of the FSH receptor leads to aberrant gametogenesis and hormonal imbalance. Proc Natl Acad Sci USA 1998, 95: 13612–7.
Porto C, Lazari MF, Lygia A, Bardin WC, Gunsalus GL. Receptors for androgen binding protein: Internalization and intracellular signalling. J Steroid Biochem Mol Biol 1995, 53: 561–5.
Nakhla AM, Khan MS, Rosner W. Biologically active steroids activate receptor-bound human sex hormone-binding globulin to cause LNCaP cells to accumulate adenosine 3′,5′-monophosphate. J Clin Endocrinol Metab 1990, 71: 398–404.
Munell F, Suarez-Quian CA, Selva DM, Tirado OM, Reventos J. Androgen-binding protein and reproduction: where do we stand? J Androl 2002, 23: 598–609.
Peri A, Krausz C, Cioppi F, et al. Cyclic adenosine 3′,5′-monophosphate-responsive element modulator gene expression in germ cells of normo- and oligoazoospermic men. J Clin Endocrinol Metab 1998, 83: 3722–6.
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Aleem, M., Choudhari, J., Padwal, V. et al. Hyperprolactinemia affects spermiogenesis in adult male rats. J Endocrinol Invest 28, 39–48 (2005). https://doi.org/10.1007/BF03345528
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DOI: https://doi.org/10.1007/BF03345528