Expression of oestrogen receptors (GPER, ESR1, ESR2) in human ductuli efferentes and proximal epididymis.

Oestrogen targeting in the human genital ducts is still not well-known. In fact, to date, the localization of oestrogen receptors, ESR1 and ESR2, is controversial and the presence of the membrane oestrogen receptor GPER (G protein-coupled oestrogen receptor) is unexplored. This study has investigated the expression of GPER, ESR1, ESR2 in human ductuli efferentes and proximal caput epididymis by immunohistochemistry and Western blot analysis. Furthermore, the presence of PELP1 (proline-glutamic acid-leucine-rich protein 1), a co-regulator of the oestrogen receptors, was also evaluated. In ductuli efferentes, GPER and ESR1 were clearly localized in all epithelial cells, while ESR2 was evidenced only in ciliated cells. Conversely, the epithelial cells of proximal caput epididymis revealed moderate GPER immunoreactivity, the absence of ERS1 and the occasional presence of ESR2. Furthermore, PELP1 was observed in ciliated cells of ductuli efferentes and in principal cells of proximal caput epididymis. Therefore, this study firstly demonstrated the expression of GPER in human male genital ducts, revealing a new mediator of oestrogen action in these anatomical sites. ESR1 and ESR2 were differentially localized in the two genital tracts together with PELP1, but cell sites of ERs and their co-regulator were not homogeneous. So, a different regional/cellular association of GPER with the classical oestrogen receptors was highlighted, suggesting that oestrogen action could be mediated by GPER, ESR1, ESR2 in ductuli efferentes, while by GPER and, occasionally by ESR2, in proximal caput epididymis. This study suggests that the specific oestrogen-mediated functions in human genital ducts might result from the different local interactions of oestrogens with oestrogen receptors and their co-regulators.

Selective GPER activation decreases proliferation and activates apoptosis in tumor Leydig cells.

We have previously shown that estrogens binding to estrogen receptor (ER) α increase proliferation of Leydig tumor cells. Estrogens can also bind to G protein-coupled ER (GPER) and activation of this receptor can either increase or decrease cell proliferation of several tumor types. The aim of this study was to investigate GPER expression in R2C rat tumor Leydig cells, evaluate effects of its activation on Leydig tumor cell proliferation and define the molecular mechanisms triggered in response to its activation. R2C cells express GPER and its activation, using the specific ligand G-1, is associated with decreased cell proliferation and initiation of apoptosis. Apoptosis after G-1 treatment was asserted by appearance of DNA condensation and fragmentation, decrease in Bcl-2 and increase in Bax expression, cytochrome c release, caspase and poly (ADP-ribose) polymerase-1 (PARP-1) activation. These effects were dependent on GPER activation because after silencing of the gene, using a specific small interfering RNA, cyt c release, PARP-1 activation and decrease in cell proliferation were abrogated. These events required a rapid, however, sustained extracellular regulated kinase 1/2 activation. G-1 was able to decrease the growth of R2C xenograft tumors in CD1 nude mice while increasing the number of apoptotic cells. In addition, in vivo administration of G-1 to male CD1 mice did not cause any alteration in testicular morphology, while cisplatin, the cytotoxic drug currently used for the therapy of Leydig tumors, severely damaged testicular structure, an event associated with infertility in cisplatin-treated patients. These observations indicate that GPER targeting for the therapy of Leydig cell tumor may represent a good alternative to cisplatin to preserve fertility in Leydig tumor patients.

DAX-1, as an androgen-target gene, inhibits aromatase expression: a novel mechanism blocking estrogen-dependent breast cancer cell proliferation.

Sexual hormones, estrogens and androgens, determine biological response in a tissue- and gender-specific manner and have a pivotal role in endocrine-mediated tumorigenesis. In situ estrogen production by aromatase is a critical determinant for breast cancer growth and progression. On the contrary, clinical and in vitro studies indicate that androgens have a protective role in mammary carcinogenesis. Here, we demonstrated, in hormone-dependent breast cancer cells, the existence of a functional interplay between the androgen receptor (AR), the orphan nuclear receptor DAX-1 and the aromatase enzyme involved in the inhibition of the estrogen-dependent breast cancer cell proliferation exerted by androgen signaling. Indeed, our results revealed, in MCF-7 cells, that ligand-activated AR induces the expression of the orphan nuclear receptor DAX-1 by direct binding to a newly identified androgen-response-element within the DAX-1 proximal promoter. In turn, androgen-induced DAX-1 is recruited, in association with the corepressor N-CoR, within the SF-1/LRH-1 containing region of the aromatase promoter, thereby repressing aromatase expression and activity. In elucidating a novel mechanism by which androgens, through DAX-1, inhibit aromatase expression in breast cancer cell lines, these findings reinforce the theory of androgen- opposing estrogen-action, opening new avenues for therapeutic intervention in estrogen-dependent breast tumors.

Insulin and IR-beta in pig spermatozoa: a role of the hormone in the acquisition of fertilizing ability.

Recent studies have revealed that insulin, the main regulator of the glucose homeostasis in somatic cells, is expressed in human spermatozoa which are also able to secrete it. This study investigated the expression of insulin and insulin receptor beta in pig spermatozoa, at immunohistochemical protein and mRNA level. The immunofluorescence assay revealed that insulin and its receptor were co-localized in the sperm midpiece, while insulin was also detected in the acrosomal region. Western blot evidenced a 36 kDa band for insulin and a 95 kDa band for insulin receptor, such as reported in somatic cells. In addition, both insulin and insulin receptor transcripts were detected in pig spermatozoa. Interestingly, a possible biological role of the hormone was evidenced during pig sperm capacitation and acrosome reaction. In fact, the results showed that insulin (0.01 and 0.1 nm) can induce both the activities. A possible autocrine short loop of insulin in pig spermatozoa was suggested by the evaluation of the hormone secretion in both uncapacitated and capacitated spermatozoa. Furthermore, spontaneous sperm capacitation and acrosome reaction were stimulated by glucose and inhibited by the blockage of insulin release (nifedipine). In conclusion, this work has firstly demonstrated the expression of insulin and of its receptor, as well as the insulin secretion by pig spermatozoa, thereby suggesting an unexpected significance of the hormone in the acquisition of the male gamete fertilizing ability.

Effects of tri-iodothyronine on alternative splicing events in the coding region of cytochrome P450 aromatase in immature rat Sertoli cells.

Transient postnatal hypothyroidism in male rats induces a prolonged proliferation of immature Sertoli cells. This change in Sertoli cell replication at young ages is coincident with enhanced and prolonged aromatase activity that leads to a marked increase in the conversion of androgens into estrogens. Both events are drastically inhibited by tri-iodothyronine (T(3)) replacement either in vivo or in vitro. This study, after the immunolocalization of aromatase in cultured rat Sertoli cells, examined the effects elicited by T(3) on this enzyme, by simultaneously investigating three functional levels of aromatase: mRNA expression, protein content, and enzymatic activity. The immunolocalization of cytochrome P450 aromatase (P450 arom) was shown in the cytoplasm of cultured Sertoli cells from 15- and 21-day-old rats. Western blot analysis revealed an enhancement of aromatase protein content upon stimulation with N(6),2'-O-dibutyryladenosine-3':5'-cyclic monophosphate ((Bu)(2)cAMP) that was clearly down-regulated by T(3). The presence of a functional P450 arom protein in purified Sertoli cells was confirmed by the measurement of [(3)H]H(2)O released after incubation with [1 beta-(3)H]androst-4-ene-3,17-dione. With 100 nM T3, a decrease in both P450 arom mRNA levels and aromatase activity was observed. The aromatase enzymatic activity was strongly stimulated by (Bu)(2)cAMP and markedly down-regulated by T(3). In contrast, the strong increase in aromatase mRNA upon (Bu)(2)cAMP stimulation was apparently unaffected by T(3) administration. This paper shows how the identification of an altered transcript induced by T(3) coding for putative truncated and inactive aromatase protein might explain such a decrease in aromatase activity in T(3)-treated cells. On the basis of these results, it is concluded that at least two mechanisms could be involved in the down-regulatory effect of T(3) on aromatase activity in prepuberal Sertoli cells. The first mechanism is linked to a possible direct modulatory role for T(3) in the regulation of the aromatase promoter, whilst the second one is represented by the induction of altered transcripts coding for truncated and inactive aromatase proteins.

Aromatase expression in prepuberal Sertoli cells: effect of thyroid hormone.

Aromatase activity has recently been assumed as a Sertoli cell functional maturation marker since it is maximally expressed in prepuberal age then it dramatically decreases at puberty and is virtually absent in adult age. Neonatal hypothyroidism is associated with a prolonged proliferation of Sertoli cells. This immature stage persists concomitantly with a dramatic enhancement of aromatase activity reversed by triiodothyronine (T3) either in vivo or in vitro administration. Therefore, in the present study, after immunolocalisation of aromatase in the cytoplasm of cultured Sertoli cells as well as in testis section, we investigate the regulatory effects of T3 in the same cells just at the age when aromatase activity is reported to be maximally expressed. In this aim, the effects of thyroid hormone have been evaluated in 2-weeks-old rats, in basal condition and upon stimulation with dibutyryl cyclic AMP [(Bu)(2)cAMP] by simultaneously analysing three functional levels of aromatase, mRNA expression; protein content; enzymatic activity. Western-blot analysis of Sertoli cell extracts revealed a protein, which co-migrated with a 55 kDa protein detected in human placenta used a positive control. The presence of a functional P450 aromatase protein in purified Sertoli cells was confirmed by the measurement [3H]H(2)O released after incubation with [1beta-(3)H]androst-4-3,17-dione. At the dose used, T3 down-regulates basal aromatase activity, while aromatase mRNA expression was apparently not inhibited. It is noteworthy that aromatase content pattern evaluated by Western blot analysis did not tightly parallel the aromatase activity pattern which clearly displays the inhibitory effects of T3, in basal condition ad upon (Bu)(2)cAMP stimulation, simulating FSH stimulation. The detection of mRNA altered transcript coding for putative protein lacking both aromatic and heme-binding regions upon T3 treatment and unable to convert androgens into estrogens, provides a reasonable explanation for the observed discrepancies between aromatase protein pattern, P450arom mRNA levels and aromatase activity. The authors conclude that although the altered transcript induced by prolonged exposure to T3 is a mechanism by which T3 may down regulate aromatase activity, it cannot be ruled out a direct effect of this hormone at the transcription levels since a recognisable emisite for potential TR(s) binding is located in the promoter region of aromatase gene. Thus a further investigation on T3 modulator role on aromatase gene promoter should be pursued even utilising higher doses of T3.