Project description:Wolffian duct maintenance and differentiation is predominantly driven by the androgen action, which is mediated by the androgen receptor (AR). It is well established that the mesenchyme indicates the fate and differentiation of epithelial cells. However, in vivo developmental requirement of mesenchymal AR in Wolffian duct development is still undefined. By designing a mesenchyme-specific Ar knockout (ARKO), we discovered that the loss of mesenchymal Ar led to the bilateral or unilateral degeneration of caudal Wolffian ducts and cystic formation at the cranial Wolffian ducts. Ex vivo culture of ARKO Wolffian ducts invariably resulted in bilateral defects, suggesting that some factor(s) originating from surrounding tissues in vivo might promote Wolffian duct survival and growth even in the absence of mesenchymal Ar. Mechanistically, we found cell proliferation was significantly reduced in both epithelial and mesenchymal compartments; but cell apoptosis was not affected. Transcriptomic analysis by RNA-seq revealed differentially expressed genes associated with morphological and cellular changes in ARKO male embryos (i.e. reduced cell proliferation and decreased number of epithelial cells). Mesenchymal differentiation into smooth muscle cells that are critical for morphogenesis was also impaired in ARKO male embryos. Taken together, our results demonstrate the crucial roles of the mesenchymal AR in Wolffian duct maintenance and morphogenesis in mice.

Project description:Precursors for the male and female reproductive tracts (also known as the Wolffian duct and the Müllerian duct) co-exist in a mammalian embryo before sexual differentiation. The Wolffian duct and Müllerian duct are surrounded by their own mesenchymes in the mesonephros, which can be distinguished by their specific expression of Gli1 and Amhr2, respectively. In the XX embryo, during sexual differentiation, the Wolffian duct degenerates. In this study, by tracking the fate of the Gli1+ Wolffian duct mesenchyme in the tamoxifen inducible genetic lineage tracing model Gli1-CreER; Rosa-Tomato, we demonstrate that the Wolffian duct mesenchyme does not regress along with the Wolffian duct epithelium in the XX embryo. Instead, the Wolffian duct mesenchyme is repurposed and becomes a unique mesenchymal population in the female reproductive tract. Profiling the transcriptomes and chromatin accessibilities of the Gli1+ Wolffian duct mesenchyme in XX and XY during sexual differentiation (E14.5 and E16.5) shows signaling pathways and transcriptional factors that potentially involves the female and male fate differentiation of the Gli1+ Wolffian duct mesenchyme. Comparing the transcriptomes between the Gli1+ Wolffian duct mesenchyme and the Amhr2+ Müllerian duct mesenchyme from the neonatal uterus reveals similarities and differences between the two mesenchymal populations in the female reproductive tract. Ex vivo ablation of the Wolffian duct mesenchyme stunted the growth of the fetal female reproductive tract. In summary, our discovery of the contribution of the Wolffian duct mesenchyme to the female reproductive tract provides new insights into our understanding of sexual differentiation of reproductive tracts.

Project description:Wolffian/epididymal duct morphogenesis highly coordinates with its specialized function of providing microenvironment for sperm maturation. Without normal development of Wolffian duct, male infertility will result. Therefore, it is important to understand the cellular and molecular mechanisms that regulated Wolffian duct morphogenesis. Our previous study showed that mediolateral intercalation of epithelial cells was a major driver of ductal elongation. In addition, radial intercalation of mesenchymal cells surrounding the duct also played roles in Wolffian duct morphogenesis, and all of these cell re-arrangements were regulated by protein tyrosine kinase 7 (PTK7), a member of the planar cell polarity (PCP) non-canonical Wnt pathway. In this study, we showed that PTK7 regulated assemblies of extracellular matrix (ECM) at the basement membrane and throughout the mesenchyme. Abnormal assembly of laminin, collagen IV, and nephronectin at the basement membrane and fibrosis-like deposition of fibrilla collagen in the interstitium were observed in Ptk7 knockout Wolffian ducts. Meanwhile, PTK7 regulated activity levels of small GTPase RAC1 and myosin II in the mesenchyme of the Wolffian duct. Activity levels of RAC1 and myosin II decreased in the Ptk7 knockout mesenchyme compared to controls. When in-vitro-cultured Wolffian ducts were treated with collagenase IV, cross-link of fibrilla collagen was reduced, Wolffian duct elongation and coiling was reduced significantly, and cyst-like bulge was developed in the epithelial duct. When Wolffian ducts were treated with RAC1 inhibitor NSC23766, fibrilla collagen in the mesenchyme was disassembled, and Wolffian duct elongation was suppressed significantly. Our finding suggested that PTK7 regulated ECM assembly in the mesenchyme likely through regulating RAC1 and myosin II activities. Dynamic assembly and remodeling of ECM were important to Wolffian duct morphogenesis.

Project description:Wnt9b permits the androgen action in promoting Wolffian duct

Project description:In an XX embryo, the Wolffian duct regresses under the control of the mesenchymal transcription factor COUP-TFII. To understand cellular and molecular actions underlying Wolffian duct regression, we preformed transcriptomic analyses of XX mesonephroi with or without Coup-tfII and genome-wide analysis of COUP-TFII chromatin occupancy in XX mesonephroi. The integrative analysis of COUP-TFII genome-wide binding and transcriptomic analysis revealed the suppression of muscle differentiation and extracellular matrix genes by COUP-TFII and identified a group of COUP-TFII’s potential transcriptional partners in the mesenchyme that potentially facilitate Wolffian duct regression. These findings provide insights into the molecular action of COUP-TFII in the Wolffian duct mesenchyme and identify a list of biologically relevant candidate genes and pathways for future functional analyses in sexual differentiation of reproductive tracts.

Project description:Here we compared the expression of an engineered kidney tissue, created by recombining an in vitro budded Wolffian duct with fresh E13 metanephric mesenchyme, with that of three in vivo rat embryonic kidney timepoints (E13, E18, and week 4) Keywords: time course

Project description:To rigorously examine the role of b-catenin dependent transcription, we created mice deficient for the transcriptional output of beta-catenin in skeletal mesenchyme (bcat-dTF-Dermo1-cKO) and compare the transcriptional profiles to that of the beta-catenin conditional KO mice in skeletal mesenchyme (bcat-Dermo1-cKO).

Project description:The bladder’s remarkable regenerative capacity in response to injury had been thought to reside exclusively in its basal and intermediate cells. While examining consequences of DNA methyltransferase 1 (Dnmt1) inactivation in mouse embryonic bladder epithelium, we made the surprising discovery that Wolffian duct epithelial cells also support bladder regeneration. Conditional inactivation of Dnmt1 in mouse urethral and bladder epithelium triggered widespread apoptosis, depleted basal and intermediate bladder cells and disrupted Uroplakin protein expression. These events coincided with recruitment of Wolffian duct epithelial cells into Dnmt1 mutant urethra and bladder where they were reprogrammed to express bladder markers including FOXA1, Keratin 5, P63 and Uroplakin. This is the first evidence that Wolffian duct epithelial cells can be summoned in vivo to replace damaged bladder epithelium and function as a cell reservoir for bladder regeneration.

Project description:Wnt9b is expressed in the ureteric bud of the kidney at all stages of development. In Wnt9b mutants, the ureteric bud forms but the metanephric mesenchyme is never induced to undergo differentiation. We used microarrays to compare differences in gene expression between wildtype and Wnt9b mutants. To focus on direct targets, mesenchymes isolated away from the E11.5 ureteric bud were assayed

Project description:During male development, the testes move from a high intraabdominal position and descend into the scrotum. The gubernaculum, an inguinoscrotal ligament connecting the testis to the lower abdomen, is believed to play a critical role in this process. The first stage of testicular descent is controlled by INSL3, insulin like3 hormone, produced in testicular Leydig cells. Deletion of Insl3 or its receptor, Rxfp2, in mice causes cryptorchidism. We produced Cre/loxP regulated shRNA transgenic mice targeting RXFP2 expression. We have shown that the transgene was able to reduce Rxfp2 gene expression and thus behaved as a hypomorphic allele of Rxfp2. Variable degrees of uni-and bilateral cryptorchidism was detected in males with the activated shRNA transgene on an Rxfp2+/- background. Conditional suppression of Rxfp2 in the gubernaculum led to cryptorchidism. Gene expression analysis of a mutant cremasteric sac using Illumina microarrays indicated abnormal expression of a significant number of genes in Wnt/β-catenin and Notch pathways. We have demonstrated profound changes in the expression pattern of β-catenin, Notch1, desmin, and androgen receptor (AR) in Rxfp2-/- male embryos, indicating the role of INSL3 in proliferation, differentiation, and survival of specific cellular components of the gubernaculum. We have shown that INSL3/RXFP2 signaling is essential for myogenic differentiation and maintenance of AR-positive cells in the gubernaculum. Males with the deletion of β-catenin or Notch1 in the gubernacular ligament demonstrated abnormal development. Our data indicates that β-catenin and Notch pathways are potential targets of INSL3 signaling during gubernacular development. Total RNA obtained from the cremasteric sac of cryptorchid Tg(shRxfp1) males compared to the wild-type control cremasteric sac.