Spatiotemporal dynamics of androgen signaling underlie sexual differentiation and congenital malformations of the urethra and vagina

Larkins, Christine E.; Enriquez, Ana Beatriz; Cohn, Martin J.

doi:10.1073/pnas.1610471113

Cited by 14 publications

(13 citation statements)

References 54 publications

(59 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In contrast, in females the Müllerian epithelium of the uterovaginal canal contacts the endodermal epithelium of the urethra in a caudal position near the vaginal introitus. In mice the cranial positioning of the Müllerian duct-UGS junction in males is due to signaling through androgen receptors in the mesenchyme (Larkins et al, 2016). Patients with congenital adrenal hyperplasia (and thus elevated androgen levels) are masculinized to variable degrees (Speiser et al, 2010), and in many cases the vagina does not terminate caudally in the vaginal vestibule, but instead is attached to the urethra in a more cranial position (Larkins et al, 2016).…”

Section: Discussionmentioning

confidence: 99%

“…In mice the cranial positioning of the Müllerian duct-UGS junction in males is due to signaling through androgen receptors in the mesenchyme (Larkins et al, 2016). Patients with congenital adrenal hyperplasia (and thus elevated androgen levels) are masculinized to variable degrees (Speiser et al, 2010), and in many cases the vagina does not terminate caudally in the vaginal vestibule, but instead is attached to the urethra in a more cranial position (Larkins et al, 2016). The localization of AR observed in mesenchyme associated with the human vaginal plate/urethral junction is in the appropriate position to alter the Müllerian duct-UGS junction should androgen levels be elevated.…”

Section: Discussionmentioning

confidence: 99%

See 1 more Smart Citation

Molecular mechanisms of development of the human fetal female reproductive tract

Kurita²,

et al. 2017

View full text Add to dashboard Cite

Human female reproductive tract development rests mostly upon hematoxilyn and eosin stained sections despite recent advances on molecular mechanisms in mouse studies. We report application of immunohistochemical methods to explore the ontogeny of epithelial and mesenchymal differentiation markers (keratins, homobox proteins, steroid receptors), transcription factors and signaling molecules (TP63 and RUNX1) during human female reproductive tract development. Keratins 6, 7, 8, 10, 14 and 19 (KRT6, KRT7, KRT8, KRT10, KRT14, KRT19) were expressed in a temporally and spatially dynamic fashion. The undifferentiated Müllerian duct and uterovaginal canal, lined by simple columnar epithelia, expressed KRT7, KRT8 and KRT19. Glandular derivatives of the Müllerian duct (uterine tube, uterine corpus and endocervix) maintained expression of these keratins, while tissues that undergo stratified squamous differentiation (exocervix and vagina) expressed KRT6, KRT14 and KRT10 during development in an age-dependent fashion. TP63 and RUNX1 were expressed prior to KRT14, as these two transcription factors are known to be upstream from KRT14 in developing Müllerian epithelium. In the vagina, KRT10, a marker of terminal differentiation, appeared after endogenous estrogens transformed the epithelium to a thick glycogenated squamous epithelium. Uroplakin, a protein unique to urothelium, was expressed only in the bladder, urethra and vaginal introitus, but not in the female reproductive tract itself. Mesenchymal differentiation was examined through immunostaining for HOXA11 (expressed in uterine mesenchyme) and ISL1 (expressed in vaginal mesenchyme). A detailed ontogeny of estrogen receptor alpha (ESR1), progesterone receptor (PGR) and the androgen receptor (AR) provides the mechanistic underpinning for the teratogenicity of estrogens, progestins and androgens on female reproductive tract development. Immunohistochemical analysis of differentiation markers and signaling molecules advance our understanding of normal development of the human female reproductive tract. These observations demonstrate remarkable similarities in mouse and human female reproductive tract development, but also highlight some key differences.

show abstract

Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Molecular mechanisms of development of the human fetal female reproductive tract

Kurita²,

et al. 2017

View full text Add to dashboard Cite

show abstract

“…The incompatibility in angiogenesis may have resulted from growth rate mismatch between an outstanding performance in the Large White and ordinary performance in the Min pig ( Zhang 1986 ). The androgen receptor signaling pathway is important for sexual development in both males and females ( Chang et al 2013 ; Larkins et al 2016 ), and the incompatibility in it may have affected hybrid inviability or hybrid male inviability during the embryo development.…”

Section: Resultsmentioning

confidence: 99%

Genetic Architecture Underlying Nascent Speciation—The Evolution of Eurasian Pigs under Domestication

Xie

Wang

Fan

et al. 2021

Molecular Biology and Evolution

View full text Add to dashboard Cite

Speciation is a process whereby the evolution of reproductive barriers leads to isolated species. Although many studies have addressed large-effect genetic footprints in the advanced stages of speciation, the genetics of reproductive isolation in nascent stage of speciation remains unclear. Here, we show that pig domestication offers an interesting model for studying the early stages of speciation in great details. Pig breeds have not evolved the large X-effect of hybrid incompatibility commonly observed between “good species.” Instead, deleterious epistatic interactions among multiple autosomal loci are common. These weak Dobzhansky–Muller incompatibilities confer partial hybrid inviability with sex biases in crosses between European and East Asian domestic pigs. The genomic incompatibility is enriched in pathways for angiogenesis, androgen receptor signaling and immunity, with an observation of many highly differentiated cis-regulatory variants. Our study suggests that partial hybrid inviability caused by pervasive but weak interactions among autosomal loci may be a hallmark of nascent speciation in mammals.

show abstract

“…In mice, the Müllerian duct/UGS junction becomes situated cranially in males and more caudally in females, even though the initial point of contact of the Müllerian ducts with the UGS is high (near the bladder) in both sexes. The subsequent male/female positional difference in mice is attributed to the timing and the duration of androgen action during fetal stages (Larkins et al, 2016). The absence of androgen action in females accounts for a more caudal positioning of the Müllerian duct/UGS junction in mice, while androgen action in males accounts for the more cranial positioning of the Müllerian duct/UGS junction.…”

Section: Female Reproductive Tract Developmentmentioning

confidence: 99%

“…The mechanism of this sexually dimorphic positioning of the Müllerian duct/UGS junction in humans has not been explored adequately. However, the proposed role of androgens (based upon mouse studies) in positioning the Müllerian duct/UGS junction in males and females (Larkins et al, 2016) is doubtful in humans for several reasons: (a) The initial cranial position of the human Müllerian duct/UGS junction described previously (Cunha et al, 2018c;Koff, 1933) in males is established at about 8 weeks of gestation when androgen levels are low or non-existent. (b) The fetal testes begin testosterone production at about 8-10 weeks of gestation (Siiteri and Wilson, 1974).…”

Section: Female Reproductive Tract Developmentmentioning

confidence: 99%

Reproductive tract biology: Of mice and men

et al. 2019

View full text Add to dashboard Cite

The study of male and female reproductive tract development requires expertise in two separate disciplines, developmental biology and endocrinology. For ease of experimentation and economy, the mouse has been used extensively as a model for human development and pathogenesis, and for the most part similarities in developmental processes and hormone action provide ample justification for the relevance of mouse models for human reproductive tract development. Indeed, there are many examples describing the phenotype of human genetic disorders that have a reasonably comparable phenotype in mice, attesting to the congruence between mouse and human development. However, anatomic, developmental and endocrinologic differences exist between mice and humans that (1) must be appreciated and (2) considered with caution when extrapolating information between all animal models and humans. It is critical that the investigator be aware of both the similarities and differences in organogenesis and hormone action within male and female reproductive tracts so as to focus on those features of mouse models with clear relevance to human development/pathology. This review, written by a team with extensive expertise in the anatomy, developmental biology and endocrinology of both mouse and human urogenital tracts, focusses upon the significant human/mouse differences, and when appropriate voices a cautionary note regarding extrapolation of mouse models for understanding development of human male and female reproductive tracts.

show abstract

Spatiotemporal dynamics of androgen signaling underlie sexual differentiation and congenital malformations of the urethra and vagina

Cited by 14 publications

References 54 publications

Molecular mechanisms of development of the human fetal female reproductive tract

Molecular mechanisms of development of the human fetal female reproductive tract

Genetic Architecture Underlying Nascent Speciation—The Evolution of Eurasian Pigs under Domestication

Reproductive tract biology: Of mice and men

Contact Info

Product

Resources

About