The role of nucleotide pyrophosphatase in Mullerian duct regression

Mullerian inhibiting substance (MIS), a glycoprotein from the fetal testis causing regression of the embryonic Mullerian duct, can be inhibited in vitro in the presence of Mn²⁺ by a wide range of nucleotides including GTP, NAD, ATP, AMP, and several nonhydrolyzable synthetic ATP analogs. Extracellular nucleotide pyrophosphatase (NPPase), an enzyme able to hydrolyze the wide variety of the nucleotides and analogs found to inhibit Mullerian duct regression, was studied by histochemical staining (H. Sierakowska and D. Shugar (1963) to determine if NPPase localized in or around the Mullerian duct during regression. Frozen sections of urogenital ridges from to rat fetuses (n = 77) were incubated with a-naphthyl thymidine-5′-phosphate (naphthyl TMP) and Fast Red TR. Nucleotide pyrophosphatase hydrolyzes naphthyl TMP, releasing naphthol, which then reacts with Fast Red to produce color at the enzyme site. Nucleotide hydrolysis was detected around regressing male (n = 16) Mullerian duct cells at days of gestation, but no hydrolysis was detected around female (n = 17) Mullerian duct cells at any stage. Controls (n = 24) incubated without substrate did not stain. Addition of exogenous ATP (n = 20) to the histochemical incubation medium inhibited nucleotide hydrolysis on male Mullerian ducts, suggesting that this staining is specific for pyrophosphatase activity. Results in vivo were confirmed in vitro by incubating day female rat urogenital ridges with MIS for 72 hr prior to histochemical staining. The addition of testosterone to MIS was obligatory to detect staining in vitro (n = 10). The localized NPPase activity around the regressing Mullerian duct suggests that NPPase may appear as a consequence of duct regression and may act to control the degree of membrane phosphorylation by degrading excess trinucleotides.     

Crossed graft of embryonic testis between quail and chick embryos: contribution to the study of the mechanism of female bird embryo masculinization]

Quail, or chick embryonic testes grafted respectively in the extraembryonic coelom of chick or quail embryos induce both a Mullerian duct regression and a masculinization of the female host gonads up to the differentiation of two testes, in some cases. Such a result confirms the fact evidenced previously in other bird species (chick and duck) that the testis-inducer is interspecific. Quail cells are not observed in histological sections of embryonic gonads of testis-grafted chicks. This allows to discard a possible influence of cells migrating from the graft to the host. The grafted testes act then through substance/s secreted in the blood stream. Present and previous experimental data strongly suggest that the same substance, i.e. the so-called anti-Mullerian hormone, is responsible for both MD regression and gonadal sex reversal.     

Paracrine-mediated apoptosis in reproductive tract development

In mammalian development, the signaling pathways that couple extracellular death signals with the apoptotic machinery are still poorly understood. We chose to examine Müllerian duct regression in the developing reproductive tract as a possible model of apoptosis during morphogenesis. The TGFbeta-like hormone, Müllerian inhibiting substance (MIS), initiates regression of the Müllerian duct or female reproductive tract anlagen; this event is essential for proper male sexual differentiation and occurs between embryonic days (E) 14 and 17 in the rat. Here, we show that apoptosis occurs during Müllerian duct regression in male embryos beginning at E15. Female Müllerian ducts exposed to MIS also exhibited prominent apoptosis within 13 h, which was blocked by a caspase inhibitor. In both males and females the MIS type-II receptor is expressed exclusively in the mesenchymal cell layer surrounding the duct, whereas apoptotic cells localize to the epithelium. In addition, tissue recombination experiments provide evidence that MIS does not act directly on the epithelium to induce apoptosis. Based on these data, we suggest that MIS triggers cell death by altering mesenchymal-epithelial interactions.     

PROCESS OF FUNCTIONAL SEX REVERSAL OF THE GONAD IN THE FEMALE GUPPY, POECILIA RETICULATA, TREATED WITH ANDROGEN BEFORE BIRTH

In the guppy, Poecilia reticulata , ovarian differentiation occurs during the embryonal life by 14 days after the preceding parturition. Testicular differentiation begins with the appearance of prominent aggregations of stroma cells in the gonadal hilus occurring by 18 days following the last parturition.
Oral administration of methyltestosterone (400 μ/g diet) to gravid guppies, begun 13–15 days after the preceding parturition and continued until the end of gestation, induced a male-type aggregation of somatic cells in the hilus of ovaries of female embryos. Gonads of newly born, androgenized females still had developing oocytes but were always provided with atypical clusters of stroma cells in their hilus. The gonads of affected female offspring developed successively into definite testes within 20 days after birth, displaying a precocious differentiation of the hilar stroma into sperm ducts and testicular interstitium, a concomitant initiation of spermatogenesis, and a conspicuous degeneration of oocytes. A successful masculinization of the somatic element, which may occur prior to that of the germ cells, in androgen-affected embryonic ovaries seems to be essential for the functional sex reversal of genetic females in the guppy.     

Timing and irreversibility of Müllerian duct inhibition in the embryonic reproductive tract of the human male

A study was undertaken to determine (1) the effects of endogenous Müllerian inhibiting substance (MIS) on the developing human fetal genital tract; (2) the time in fetal life when MIS is first capable of inhibiting the growth of the embryonic Müllerian ducts; and (3) the reversibility of the effects of MIS on the developing male Müllerian ducts. Human fetal reproductive tracts were transplanted and grown for sustained periods in vivo in athymic nude mice. The genital tracts from 12 male human fetuses, ages 51 to 68 days postovulation, were grafted without their associated gonads into castrated murine hosts and grown for 30 to 70 days. Controls consisted of genital tracts from 8 female human fetuses, ages day 53 to 70 that were grown under identical conditions. Male specimens grew to approximately one-half the size of female specimens and disclosed varying degrees of inhibition of the Müllerian duct system from absence of the Müllerian ducts in older specimens (after Day 63) to poorly segregated segments of stroma as the mildest defect (less than Day 61). It is concluded that (1) MIS secretion by the embryonic testes probably begins before Day 51 of gestation; (2) the effects of MIS are progressive during the so-called critical window; (3) the effects of MIS are permanent; and (4) the mesenchyme is an important target of MIS.     

Canine embryonic and fetal development: a review

The progression from a fertilized oocyte to a newborn puppy is a remarkable phenomenon that occurs in a period of approximately two months. Embryonic development encompasses the period of time at which three germ layers differentiate: ectoderm, mesoderm, and endoderm. Organ systems are formed from these germ layers, with most of the reproductive tract being derived from mesoderm. Organogenesis is complete prior to the fetal stage in canine embryos, but sexual differentiation occurs during the fetal stage. Sexual differentiation is a well-coordinated progression of events that is directed initially by the genotype of the developing embryo and fetus. Developing fetuses are inherently female and will develop as such in the absence of a Y chromosome. Male fetuses develop as the Y chromosome causes regression of the female duct system and development of the male duct system. Testicular descent in the canine begins in the fetal stage, but is not completed until after birth.     

Involution of the female Mullerian duct of the fetal rat in the organ-culture assay for the detection of Mullerian Inhibiting Substance

The study of Mullerian Inhibiting Substance (MIS) has been made possible because of the organ-culture bioassay devised by Picon ('69) for detecting MIS in vitro. We have studied the degeneration of the female Mullerian duct of the rat fetus, the target tissue of the assay, with electron microscopy. We have observed that the involution of the female Mullerian duct in the organ-culture assay follows a pattern of degeneration similar to the normal involution of the male Mullerian duct under the influence of MIS from the fetal testis (Price et al., '77). This involution involves alterations in the duct epithelium subsequent to a response of the mesenchyme surrounding the duct. The degeneration of a specific organ system under the direct influence of a specific factor, Mullerian Inhibiting Substance, represents an example of "programmed cell death."     

Müllerian inhibiting substance production and testicular migration and descent in the pouch young of a marsupial

The ontogeny of Müllerian inhibiting substance (MIS) production by the developing testis of an Australian marsupial, the tammar wallaby (Macropus eugenii), was determined during pouch life using an organ-culture bioassay of mouse fetal urogenital ridge. This information was related to the morphological events during testicular migration and descent. MIS biological activity was found in testes (but not ovaries or liver) of pouch young from 2 to 85 days of age. MIS production had commenced by day 2, which is within a day of the first gross morphological signs of testicular differentiation. Müllerian duct regression occurred between 10 and 30 days, which partly coincided with testicular migration to the inguinal region and enlargement of the gubernacular bulb (15 to 30 days). These observations are consistent with the hypothesis that MIS may be involved in testicular transabdominal migration. The epididymis commenced development and growth only after the testis had descended through the inguinal ring. This provides no support for the suggestion that the epididymis is involved in testicular descent into the scrotum. The basic sequence of events in post-testicular sexual differentiation in the wallaby is sufficiently similar to that seen in eutherian mammals to make it an excellent experimental model for future studies of testicular differentiation, migration and descent.     

Müllerian inhibiting substance in sex-reversed dogs

In normal males, Müllerian Inhibiting Substance (MIS), produced by testes during an embryonic critical period, is thought to induce regression of the Müllerian duct system, including the oviducts and uterus. In XX sex-reversed dogs, an apparent contradiction has been reported: The uterus persists in the presence of testes or ovotestes. The objective of this study is to determine whether testes of XX male and ovotestes of true hermaphrodite dogs produce MIS, and to examine the anatomy of Müllerian duct derivatives of affected dogs for evidence of regression. Gonadal samples were tested for MIS activity in a bioassay. The mean MIS activity score of XX males was similar to that of normal XY males and significantly greater than that of normal XX females. The mean MIS activity score of XX true hermaphrodites was intermediate between normal XX females and XY males. Within the true hermaphrodite group, ovotestes in which the proportion of testicular tissue was greater than or equal to 1/2 had higher MIS scores than those in which the proportion of testicular tissue was less than 1/2. XX males had a well-developed epididymis adjacent to each testis, but no oviducts. In true hermaphrodites, the oviduct regressed and an epididymis was present when greater than or equal to 1/2 of the adjacent ovotestis was testicular, and MIS activity in that gonad was high. A few ovotestes with intermediate levels of MIS activity had both an oviduct and an epididymis. Regression of the oviductal portion of the Müllerian duct system was positively correlated to the amount of testicular tissue and the MIS activity of the gonad, as would be predicted by Jost's original hypothesis.(ABSTRACT TRUNCATED AT 250 WORDS)     

Quantification of müllerian inhibiting substance in developing chick gonads by a competitive enzyme-linked immunosorbent assay

An immunoblotting method was used to purify a Müllerian-inhibiting substance (MIS)-specific antiserum. The serum was used to quantify the content of MIS in developing chick gonads by competitive enzyme-linked immunosorbent assay. From embryonic stages to the eleventh week after hatching, male chicken testes have a high content of MIS in the following two stages: (1) from the sixth to the eighth day and from the fourteenth to the twentieth day of incubation, and (2) from the second to the eighth week after hatching. The high content of MIS in the early embryonic stage is closely correlated with the natural pattern of Müllerian duct regression observed in the male embryo. From the sixth to the twelfth day of incubation, the female right ovary contains a higher content of MIS than that of the left ovary. Up to the fourteenth day of incubation, the content of MIS in the left ovary reaches maximum levels and then declines. The combination of MIS from right and left ovaries was found to be highest in the ninth to the fourteenth day of incubation, when the regression of the right Müllerian duct reached its highest peak. However, the question of the inability of MIS to cause regression of the female left Müllerian duct and the caudal part of the right duct is raised and discussed. The hypothesis that prenatal estrogenic hormone (diethylstilbestrol) protects the Müllerian duct has been reevaluated. It was found that estrogen does not reduce the MIS content in prenatally treated gonads.     

Müllerian inhibiting substance activity in bovine fetal, newborn and prepubertal testes

Mullerian Inhibiting Substance (MIS) activity in bovine fetal, newborn, and prepubertal testes was investigated. MIS was present in all fetuses studied during the 1st 6 weeks after birth. Activity was present but diminished at 8 weeks. Loss of activity appeared to coincide with the time of weaning. Electron microscopic studies of the neonate testes revealed highly active Sertoli cells with a morphology suggestive of a protein secreting cell, and implicate the Sertoli cell as the source of MIS. It is concluded that the neonate calf testes may be an excellent source of material for the isolation and biochemical characterization of MIS.     

A mesenchymal perspective of Müllerian duct differentiation and regression in Amhr2-lacZ mice

The Müllerian ducts give rise to the female reproductive tract, including the Fallopian tubes, uterus, cervix, and anterior vagina. In male embryos, the Müllerian ducts regress, preventing the formation of female organs. We introduced the bacterial lacZ gene, encoding beta-galactosidase (beta-gal), into the AMHR-II locus (Amhr2) by gene targeting in mouse embryonic stem (ES) cells to mark Müllerian duct differentiation and regression. We show that Amhr2-lacZ heterozygotes express beta-gal activity in an Amhr2-specific pattern. In the gonads, beta-gal activity was detected in Sertoli cells of the testes from 2 weeks after birth, and fetal ovaries and granulosa cells of the adult ovary. beta-gal activity was first detected in the rostral mesenchyme of the Müllerian ducts at 12.5 days post coitus (dpc) in both sexes but soon thereafter expression was found along the entire length of the Müllerian ducts with higher levels initially found in males. In females, beta-gal activity was restricted to one side of the ductal mesoepithelium, whereas in males beta-gal expression encircled the duct. beta-gal activity was also detected in the coelomic epithelium at 13.5 and 14.5 dpc. In male embryos, mesenchymal beta-gal activity permitted the visualization of the temporal and spatial pattern of Müllerian duct regression. This pattern was similar to that observed using a Müllerian duct mesoepithelium lacZ reporter, indicating a coordinated loss of Müllerian duct mesoepithelium and Amhr2-expressing mesenchyme.     

Neo-Timm and selenium stainable glial cells of the rat telencephalon

Summary The presence of endogenous growth-related polypeptide hormones, such as growth hormone (GH), somatomadin-C/insulin-like growth factor-1 (SM-C/IGF-1), prolactin (PRL) and Mullerian inhibiting substance (MIS) on chick embryonic tissues have been detected by electron microscopic (EM) immunocytochemistry. Antiserum against GH, anti-SM-C/IGF-1, anti-PRL and anti-MIS were used respectively as primary antibodies for immunolabeling probes by peroxidase (PO) and avidin-biotin complex (ABC)-gold ligands. Cross-reaction studies by ELISA showed negative or weak antigen-antibody interactions. Chick embryos, gonads, and Mullerian ducts (Mds) of various ages were fixed in 2.5% glutaraldehyde for 30 min. Washes in phosphate buffer were administered between each of the following incubations: (i) 2% BSA; (ii) primary antibody; (iii) biotinylated or PO-conjugated secondary antibody; (iv) avidin conjugated with gold particles. SM-C/IGF-1 bindings were negative on 1d embryonic disc, heavily stained on 2d endoderm. However, the GH bindings were found on the embryonic layers of 1d and 2d embryos, and increasing on the luminal epithelial cells of Mds during development. PRL was found in parallel with GH, but in less amount. The 10d Mds were double labeled with anti-SM-C/IGF-1-gold and anti-MIS-PO (MIS-PO), and the results showed SM-C/IGF-I negative, but MIS-PO positive bindings. This study provides the first immunocytochemical evidences for: (i) The presence of GH, SM-C/IGF-1, PRL and MIS bindings on chick embryonic tissues, and further supports their potential role as growth mediators during embryonic development. (ii) The amount of GH and MIS bindings were found correspondingly to their physiological status of Md growth or regression. (iii) MIS is secreted by the embryonic gonads.     

Synergistic cooperation between the beta-catenin signaling pathway and steroidogenic factor 1 in the activation of the Mullerian inhibiting substance type II receptor

Mullerian inhibiting substance type II receptor (MISRII) is a member of the transforming growth factor-beta superfamily. Mutations in mullerian inhibiting substance (MIS) or MISRII cause male sexual abnormalities, persistent mullerian duct syndrome, and pseudohermaphroditism. The spatial and temporal regulation of MIS and MISRII is important for its biological action. Male Wnt7a mutant mice do not undergo regression of mullerian ducts. Here we showed that the canonical Wnt signaling pathway regulated MISRII. The promoter MISRII was activated by beta-catenin expression, and this activation was dependent on TCF4-binding sites. The nuclear receptor superfamily member steroidogenic factor 1 (SF1) synergistically activated the MISRII promoter with beta-catenin. APC, a negative regulator of Wnt signaling, decreased SF1-mediated activation of the MISRII promoter in the colon carcinoma cell line SW480. We also showed a direct physical interaction between beta-catenin and SF1 by co-immunoprecipitation. Thus, our findings suggest that MISRII is a developmental target of Wnt7a signaling for mullerian duct regression during sexual differentiation.     

Non-cooperative oxygen binding in the erythrocytes of pre-implanted sheep embryos

The whole-blood oxygen equilibrium curve in sheep embryos at 17 days gestation was essentially hyperbolic, indicating non-cooperative O2 binding with Hill's coefficient, n approximately equal to 1.2. O2 affinity was higher in embryonic blood (P50 = 7.1 mmHg at pH = 7.4 and 39 degrees C) than in maternal blood (P50 = 32.6 mmHg at pH = 7.4 and 39 degrees C). The Bohr effect was apparently smaller in the embryo (delta log P50/delta pH = --0.52) than in maternal blood (--0.36).     

β-Catenin is essential for Müllerian duct regression during male sexual differentiation

During male sexual differentiation, the transforming growth factor-β (TGF-β) signaling molecule anti-Müllerian hormone (AMH; also known as Müllerian inhibiting substance, MIS) is secreted by the fetal testes and induces regression of the Müllerian ducts, the primordia of the female reproductive tract organs. Currently, the molecular identity of downstream events regulated by the AMH signaling pathway remains unclear. We found that male-specific Wnt4 expression in mouse Müllerian duct mesenchyme depends upon AMH signaling, implicating the WNT pathway as a downstream mediator of Müllerian duct regression. Inactivation of β-catenin, a mediator of the canonical WNT pathway, did not affect AMH signaling activation in the Müllerian duct mesenchyme, but did block Müllerian duct regression. These data suggest that β-catenin mediates AMH signaling for Müllerian duct regression during male sexual differentiation.     

Proteolytic processing of mullerian inhibiting substance produces a transforming growth factor-beta-like fragment

Mullerian inhibiting substance (MIS) is a differentiation factor that causes the Mullerian duct to regress during the development of the male reproductive tract. The active form is a disulfide-linked dimer consisting of two identical 70-kDa subunits. Recently, the amino acid sequence for MIS was deduced from its gene sequence and revealed that the carboxyl-terminal region shares homology with transforming growth factor (TGF)-beta. Since TGF-beta is produced as a large latent precursor that requires proteolytic activation for activity, we sought to determine if MIS might undergo a similar processing event. Here we demonstrate that typically 5 to 20% of the protein in MIS preparations is cleaved at a site 109 amino acids from the carboxyl terminus. Concurrent cleavages from both chains of the MIS dimer produces a 25-kDa TGF-beta-like fragment and a high molecular mass complex derived from the amino terminus of the protein. Although the two fragments are noncovalently linked, they remain tightly associated after cleavage, and thus are structurally organized like TGF-beta within its precursor. The same cleavage products also can be generated by limited proteolysis with plasmin, which provides a simple method for converting the entire preparation into the cleaved form. The plasmin-digested MIS is fully active in the organ culture assay.