Proper cell communication within the ovarian follicle is critical for the growth and maturation of a healthy oocyte that can be fertilized and develop into an embryo. Cell communication within the follicle involves many signaling molecules and is affected by maternal age. Recent studies indicate that cell communication can be mediated through secretion and uptake of small membrane-enclosed vesicles. The goals of this study were to 1) identify cell-secreted vesicles (microvesicles and exosomes) containing miRNAs and proteins within ovarian follicular fluid and 2) determine if miRNA level differs in exosomes isolated from follicular fluid in young compared to old mares. We demonstrate the presence of vesicles resembling microvesicles and exosomes in ovarian follicular fluid using transmission electron microscopy and CD63-positive and RNA containing vesicles using flow cytometry. Moreover, proteomics analysis reveals that follicular fluid-isolated exosomes contain both known exosomal proteins and proteins not previously reported in isolated exosomes. MicroRNAs were detected in microvesicle and exosomes preparations isolated from follicular fluid by real-time PCR analysis. Uptake of fluorescent-labeled microvesicles by granulosa cells was examined using in vitro and in vivo approaches. MicroRNA expression profiling reveals that miRNAs in microvesicle and exosome preparations isolated from follicular fluid also are present within surrounding granulosa and cumulus cells. These studies revealed that cell communication within the mammalian ovarian follicle may involve transfer of bioactive material by microvesicles and exosomes. Finally, miRNAs present in exosomes from ovarian follicular fluid varied with the age of the mare, and a number of different miRNAs were detected in young vs. old mare follicular fluid.
The nuclear receptor transcription factor Dax1 is hypothesized to play a role in testicular development, although the mechanism of its action is unknown. Here, we present evidence that Dax1 plays an early essential role in fetal testis development. We hypothesize that upregulation of Sox9 expression in precursor somatic cells, a process required for their differentiation as Sertoli cells, depends on the coordinated expression of Dax1, Sry and another gene, Tda1. Our conclusion and model are based on the following experimental findings: (1) presence of a mutant Dax1 allele (Dax1-) results in complete gonadal sex reversal in C57BL/6JEi (B6) XY mice, whereas testes develop in DBA/2J (D2) and(B6×D2)F1 XY mice; (2) B6-DAX1 sex reversal is inherited as a complex trait that includes the chromosome 4 gene Tda1; (3) B6 Dax1-/Y fetal gonads initiate development as ovaries, even though Sry expression is activated at the correct time and at appropriate levels; (4) upregulation of Sox9 does not occur in B6 Dax1-/Y fetal gonads in spite of apparently normal Sryexpression; and (5) overexpression of Sry in B6 Dax1-/Y fetal gonads upregulates Sox9 and corrects testis development.
Previous reports suggested that humans and mice differ in their sensitivity to the genetic dosage of transcription factors that play a role in early testicular development. This difference implies that testis determination might be somewhat different in these two species. We report that the Fog2 and Gata4 transcription factors are haploinsufficient for testis determination in mice. Whether gonadal sex reversal occurs depends on genetic background (i.e., modifier genes). gonadal sex reversal ͉ haploinsufficiency ͉ sex determination ͉ Sry ͉ Sox9 D uring human fetal development, differentiation of the bipotential gonads into ovaries or testes depends on the proper dosage of transcription factors. For example, the presence of only a single functional copy of the autosomal transcription factor-encoding genes SF1, SOX9, or WT1 can result in the development of XY females, and duplication of a chromosomal region containing SOX9 can lead to the development of XX males (1-5). In contrast, the proper dosage of the transcription factors Sf1, Sox9, and Wt1 appears not to affect testicular development in mice because XY mice containing only a single copy of these genes develop testes (6-9). This apparent species difference suggested that the correct dosage of gonadal sexdetermining transcription factors is necessary for normal testis development in humans, whereas mice are less sensitive to these gene dosage effects (10-12).Studies in our laboratory indicate that genetic background plays an essential role in the process of gonadal sex determination in mice. Specifically, mice of the C57BL/6J (B6) inbred strain are exceptionally sensitive to disturbances in the early events of gonad development and thus provide a genetic ''litmus test'' for identifying genes that cause sex reversal. For example, the Sry POS gene carried on the Mus domesticus poschiavinus Y chromosome causes ovarian tissue development when present in C57BL/6J (B6) mice but not in DBA/2J (D2) or (B6 ϫ D2)F1 mice (13,14), and a mutant allele of the X-linked transcription factor Dax1 (Nr0b1) causes gonadal sex reversal in B6 but not D2 or (B6 ϫ D2)F1 XY mice (15). This ''B6 sensitivity'' is even stronger if the AKR/J Y chromosome (Y AKR ) is present. For example, if B6 mice are heterozygous for the T Orl mutation, they develop testes. If the Y AKR chromosome is present, however, they develop ovaries (16,17). These findings suggest that genetic background, not species differences, could explain apparent differences in transcription factor dosage sensitivity for gonad development in XY humans and mice. The fact that not all XY humans are sex-reversed if only a single copy of a normal SF1 or WT1 allele is present (18-20) supports this possibility, as does the fact that XY males carrying a mutant SRY gene can pass this allele on to XY daughters (for review, see ref. 21).To test the hypothesis that testis determination in XY mice is sensitive to levels of transcription factor gene dosage in a genetic background-dependent manner, we conducted experiments to determine wh...
BackgroundGonadal differentiation in the mammalian fetus involves a complex dose-dependent genetic network. Initiation and progression of fetal ovarian and testicular pathways are accompanied by dynamic expression patterns of thousands of genes. We postulate these expression patterns are regulated by small non-coding RNAs called microRNAs (miRNAs). The aim of this study was to identify the expression of miRNAs in mammalian fetal gonads using sheep as a model.MethodsWe determined the expression of 128 miRNAs by real time PCR in early-gestational (gestational day (GD) 42) and mid-gestational (GD75) sheep ovaries and testes. Expression data were further examined and validated by bioinformatic analysis.ResultsExpression analysis revealed significant differences between ovaries and testes among 24 miRNAs at GD42, and 43 miRNAs at GD75. Bioinformatic analysis revealed that a number of differentially expressed miRNAs are predicted to target genes known to be important in mammalian gonadal development, including ESR1, CYP19A1, and SOX9. In situ hybridization revealed miR-22 localization within fetal testicular cords. As estrogen signaling is important in human and sheep ovarian development, these data indicate that miR-22 is involved in repressing estrogen signaling within fetal testes.ConclusionsBased on our results we postulate that gene expression networks underlying fetal gonadal development are regulated by miRNAs.
Age-related decline in fertility is a consequence of low oocyte number and/or low oocyte competence resulting in pregnancy failure. Transforming growth factor (TGF)-β signalling is a well-studied pathway involved in follicular development and ovulation. Recently, small non-coding RNAs, namely microRNAs (miRNAs), have been demonstrated to regulate several members of this pathway; miRNAs are secreted inside small cell-secreted vesicles called exosomes. The overall goal of the present study was to determine whether altered exosome miRNA content in follicular fluid from old mares is associated with changes in TGF-β signalling in granulosa cells during follicle development. Follicular fluid was collected at deviation (n=6), mid-oestrus (n=6) and preovulation (n=6) for identification of exosomal miRNAs from young (3-12 years) and old (20-26 years) mares. Analysis of selected TGF-β signalling members revealed significantly increased levels of interleukin 6 (IL6) in granulosa cells from mid-oestrus compared with preovulatory follicles, and collagen alpha-2(I) chain (COL1A2) in granulosa cells from deviation compared with preovulatory follicles in young mares. In addition, granulosa cells from old mares had significantly altered levels of DNA-binding protein inhibitor ID-2 (ID2), signal transducer and activator of transcription 1 (STAT1) and cell division cycle 25A (CDC25A). Finally, changes in exosomal miRNA predicted to target selected TGF-β members were identified.
Mammalian gonadal sex-determining (GSD) genes are expressed in a unique population of somatic cells that differentiate into granulosa cells in XX gonads or Sertoli cells in XY gonads. The ability to efficiently isolate these somatic support cells (SSCs) during the earliest stages of gonad development would facilitate identifying 1) new candidate GSD genes that may be involved in cases of unexplained abnormal gonad development and 2) genes involved in the earliest stages of granulosa and Sertoli cell differentiation. We report the development of a unique mouse carrying two transgenes that allow XX and XY mice to be distinguished as early as Embryonic Day 11.5 (E11.5) and allow SSCs to be isolated from undifferentiated (E11.5) and early differentiated (E12.5) fetal gonads. The Mouse Genome 430v2.0 GeneChip (Affymetrix) was used to identify transcripts exhibiting a sexual dimorphic expression pattern in XX and XY isolated SSCs. The analysis revealed previously unidentified sexually dimorphic transcripts, including low-level expressed genes such as Sry, a gene not identified in other microarray studies. Multigene real-time PCR analysis of 57 genes verified that 53 were expressed in fetal gonads in a sexually dimorphic pattern, and whole-mount in situ hybridization analysis verified 4930563E18Rik, Pld1, and Sprr2d are expressed in XX gonads, and Fbln2, Ppargc1a, and Scrn1 are expressed in XY gonads. Taken together, the data provide a comprehensive resource for the spatial-temporal expression pattern of genes that are part of the genetic network underlying the early stages of mammalian fetal gonadal development, including the development of granulosa and Sertoli cells.
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