We conclude that vitamin A supply to the fetus is critical in determining the number of nephrons. Data available thus far on the frequency of mild VAD during pregnancy and on the long-term consequences of inborn nephron deficit highlight the clinical relevance of the present study.
In adulthood, the action of androgens on seminiferous tubules is essential for full quantitatively normal spermatogenesis and fertility. In contrast, their role in the fetal testis, and particularly in fetal germ cell development, remains largely unknown. Using testicular feminized (Tfm) mice, we investigated the effects of a lack of functional androgen receptor (AR) on fetal germ cells, also named gonocytes. We demonstrated that endogenous androgens/AR physiologically control normal gonocyte proliferation. We observed an increase in the number of gonocytes at 17.5 days postconception resulting from an increase in proliferative activity in Tfm mice. In a reciprocal manner, gonocyte proliferation is decreased by the addition of DHT in fetal testis organotypic culture. Furthermore, the AR coregulator Hsp90␣ (mRNA and protein) specifically expressed in gonocytes was down-regulated in Tfm mice at 15.5 days postconception. To investigate whether these effects could result from direct action of androgens on gonocytes, we collected pure gonocyte preparations and detected AR transcripts therein. We used an original model harboring a reporter gene that specifically reflects AR activity by androgens and clearly demonstrated the presence of a functional AR protein in fetal germ cells. These data provide in vivo and in vitro evidence of a new control of endogenous androgens on gonocytes identified as direct target cells for androgens. Finally, our results focus on a new pathway in the fetal testis during the embryonic period, which is the most sensitive to antiandrogenic endocrine disruptors.androgen receptor ͉ fetal testis ͉ gonocytes ͉ Tfm D uring mammalian development, androgens produced by the fetal testis are the most important hormones controlling the masculinization of the reproductive tract and the genitalia (1). In the absence of production or action of androgens, genetic males are outwardly female in appearance. In the testis, the requirement for androgens for proper function has been demonstrated by studies of the murine testicular feminization (Tfm) mutation, androgen receptor-null mutants, and human testosterone insensitive syndrome (2-5). It is also established that from puberty onward, germ cells are the targets of androgens (spermatogenic arrest at the late spermatocyte/spermatid stage) with evidence pointing to an effect mediated by Sertoli cells (2, 6-8).There are various lines of evidence that point to a role for androgens in fetal germ cell development. First, cases of androgen insensitivity and low androgen levels are associated with a high risk of testicular cancer (9-11), which may result from altered development of gonocytes. Second, there is general agreement that the decrease in sperm count (12, 13) and the increase in the incidence of testicular cancer (9, 14) observed in many countries result from endocrine disruptor (particularly antiandrogens) exposure during the fetal testis development (15). Recent investigations show that in utero exposure to an antiandrogenic disruptor (Vinclozolin) can inf...
Vitamin A and its metabolic derivatives are known to be key signalling molecules in regulating morphogenetic events in vertebrate development. Here we investigated their possible involvement during mammalian kidney development using paired rat metanephros organ culture. Metanephroi were explanted from 14-day-old embryos and cultured for six days in a chemically defined medium containing a retinoid at a dose of 10(-11) to 10(-4) M. Retinol, all-trans and 9-cis retinoic acid were able to promote metanephros growth and differentiation in vitro. A significant increase in the number of nephrons was observed from 10(-8) M of retinol and 10(-10) M of all-trans retinoic acid, before any change in growth parameters. A threefold increase in the number of nephrons was obtained at a dose of 10(-6) M. At low retinoid concentrations, there was a modulating effect of triiodothyronine on retinoid-stimulated nephrogenesis since the absence of triiodothyronine in the medium enhanced the nephrogenic stimulation. Exposure of metanephroi from 13-day-old embryos to all-trans retinoic acid (10(-7) M) led to a sixfold increase of nephron formation. Finally, we analyzed the branching pattern of the ureteric bud and showed that within 48 hours of culture, it was significantly more developed upon retinoid exposure. In conclusion, this study demonstrates that retinoic acid is a key regulator of renal organogenesis in controlling nephrogenic induction processes and ureteric bud patterning, and that the younger the metanephros, the greater the effect.
Vitamin A and its derivatives have been shown to promote kidney development in vitro in a dose-dependent fashion. To address the molecular mechanisms by which all- trans-retinoic acid (RA) may regulate the nephron mass, rat kidneys were removed on embryonic day 14( E14) and grown in organ culture under standard or RA-stimulated conditions. By using RT-PCR, we studied the expression of the glial cell line-derived neurotrophic factor (GDNF), its cell surface receptor-α (GDNFR-α), and the receptor tyrosine kinase c-ret, known to play a major role in renal organogenesis. Expression of GDNF and GDNFR-α transcripts was high at the time of explantation and remained unaffected in culture with or without RA. In contrast, c-ret mRNA level, which was low in E14 metanephros and dropped rapidly in vitro, was increased by RA in a dose-dependent manner. The same is true at the protein level. Exogenous GDNF barely promotes additional nephron formation in vitro. Thus the present data establish c-ret as a key target of retinoids during kidney organogenesis.
Development of the metanephric kidney during embryogenesis can be altered both in vivo and in vitro by exposure to gentamicin, which may lead to oligonephronia. To study the role of the ureteric bud in nephron deficit genesis, we used metanephros organ cultures exposed to gentamicin as a model of impaired nephrogenesis. Ultrastructural localization of the antibiotic showed that by eight hours it was already present within the epithelial cells of the ureteric bud and in its growing ends, and also trapped in the adjacent blastema. Using confocal microscopy and image analysis, we devised a quantitative approach to analyze the branching pattern of the ureteric bud, and showed that by 24 hours of culture, despite no change of explants growth, gentamicin had significantly decreased the number of branching points. This effect involved the early branching events and was limited to end buds that had no nephron anlagen nearby. Our findings indicate that impaired branching morphogenesis of the ureteric bud is the likely event of gentamicin-induced nephron deficit.
SummaryThe successful application of the maize transposable element system AciDs as a genome mutagen in heterologous plant species has recently proved the versatility and power of this technique in plant molecular biology. However, the frequency of Ac/Ds transposition is considerably lower in Arabidopsis thaliana than in most other dicot plant species that have been studied. Since previous research has established that transcripts derived from monocot genes can be alternatively processed in dicot plants, we have investigated both the efficiency of intron splicing and poiyadenylation of the maize Ac transposase pre-mRNA in Arabidopsis thaliana, Nicotiana tabacum, Nicotiana plumbaginifolia and Zea mays. In this paper, we demonstrate that intron 4 is alternatively spliced within Arabidopsis, using cryptic 5' and 3' splice sites within the intron sequence, leading to a heterogeneous population of full length transposase transcript. Furthermore, analysis of transposase transcript polyadenylation revealed that at least four alternative poly(A) sites were utilized between introns 2 and 3, resulting in truncated transposase transcripts. Finally, by Northern blotting, we established that the truncated transposase transcript was the most abundant form of transposase message in Arabidopsis. In contrast to these findings, the alternative splicing and premature polyadenylation of Ac message in Arabidopsis was unparalleled in the other species examined. We suggest that the poor frequency of transposition of Ac in Arabidopsis may be in part due to the low quantity of correctly processed transposase transcript available in this species.
During mammalian development, androgens produced by the fetal testis are the most important hormones controlling the masculinization of the reproductive tract and the genitalia. New findings show that the male germ line is the most sensitive to anti-androgenic endocrine disruptors during the embryonic period. In a recent study, we reported that endogenous androgens physiologically control germ cell growth in the male mouse fetus during early fetal life. In the present study, we extended this result by showing the presence of a functional androgen receptor in the gonocytes in the latter part of the fetal life. We also studied the effect of androgens on the development of the somatic testicular cells using the Tfm mice which carry a naturally inactivating mutation of the androgen receptor. Fetal Leydig cells are largely independent of endogenous androgens during fetal development whereas fetal Sertoli cell number is decreased following a default of peritubular myoid cells differenciation. They also point to the gonocyte as a special target for androgens during the embryonic period and indicate a novel mechanism of androgen action on gonocytes. Elucidation of this new pathway in the fetal testis will clarify not only fetal testis physiology but also the effects of environmental anti-androgens that act during fetal life and open new perspectives for future investigations into the sensitivity of fetal germ cell to androgens.
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