Does the urorectal septum fuse with the cloacal membrane?

The development of the cloaca in the human embryo

Subdivision of cloaca into urogenital and anorectal passages has remained controversial because of disagreements about the identity and role of the septum developing between both passages. This study aimed to clarify the development of the cloaca using a quantitative 3D morphological approach in human embryos of 4–10 post‐fertilisation weeks. Embryos were visualised with Amira 3D‐reconstruction and Cinema 4D‐remodelling software. Distances between landmarks were computed with Amira3D software. Our main finding was a pronounced difference in growth between rapidly expanding central and ventral parts, and slowly or non‐growing cranial and dorsal parts. The entrance of the Wolffian duct into the cloaca proved a stable landmark that remained linked to the position of vertebra S3. Suppressed growth in the cranial cloaca resulted in an apparent craniodorsal migration of the entrance of the Wolffian duct, while suppressed growth in the dorsal cloaca changed the entrance of the hindgut from cranial to dorsal on the cloaca. Transformation of this ‘end‐to‐end’ into an ‘end‐to‐side’ junction produced temporary ‘lateral (Rathke's) folds’. The persistent difference in dorsoventral growth straightened the embryonic caudal body axis and concomitantly extended the frontally oriented ‘urorectal (Tourneux's) septum’ caudally between the ventral urogenital and dorsal anorectal parts of the cloaca. The dorsoventral growth difference also divided the cloacal membrane into a well‐developed ventral urethral plate and a thin dorsal cloacal membrane proper, which ruptured at 6.5 weeks. The expansion of the pericloacal mesenchyme followed the dorsoventral growth difference and produced the genital tubercle. Dysregulation of dorsal cloacal development is probably an important cause of anorectal malformations: too little regressive development may result in anorectal agenesis, and too much regression in stenosis or atresia of the remaining part of the dorsal cloaca.

Development of the human tail bud and splanchnic mesenchyme

The purpose of this paper was to shed some light on anorectal development from a viewpoint of the tail bud and splanchnic mesenchyme for better understanding of the morphogenesis of the human anorectum. Human embryos ranging from Carnegie stage 11 to 23 (CS 11 to 23) were adopted in this study. Seventeen embryos preserved at the Congenital Anomaly Research Center of Kyoto University Graduate School of Medicine were histologically examined. The cloaca, extending caudally to the hindgut, was dramatically enlarged, particularly both its dorsal portion and membrane, that is, the cloacal membrane resulting from the development of the tailgut derived from the tail bud. The splanchnic mesenchyme surrounding the hindgut was spread out in the direction of the urorectal septum ventrally, suggesting that it participated in the formation of the septum. No fusion of the urorectal septum and the cloacal membrane was found. The splanchnic mesenchyme proliferated and developed into smooth muscle (circular and longitudinal) layers from cranial to caudal along the hindgut. The tail bud seems to cause both the adequate dilation of the dorsal cloaca and the elongation of the cloacal membrane; its dorsal portion in particular will be necessary for normal anorectal development. The splanchnic mesenchyme developed and descended toward the pectinate line and formed the internal sphincter muscle at the terminal bowel.

Analysis of genitourinary anomalies in patients with VACTERL (Vertebral anomalies, Anal atresia, Cardiac malformations, Tracheo-Esophageal fistula, Renal anomalies, Limb abnormalities) association

The goal of this study was to describe a novel pattern of genitourinary (GU) anomalies in VACTERL association,which involves congenital anomalies affecting the vertebrae,anus, heart, trachea and esophagus, kidneys, and limbs.We collected clinical data on 105 patients diagnosed with VACTERL association and analyzed a subset of 89 patients who met more stringent inclusion criteria. Twenty-one percent of patients have GU anomalies, which are more severe (but not more frequent) in females. Anomalies were noted in patients without malformations affecting the renal, lower vertebral, or lower gastrointestinal systems. There should be a high index of suspicion for the presence of GU anomalies even in patients who do not have spatially similar malformations.

Hoxd-13 expression in the development of hindgut in ethylenethiourea-exposed fetal rats

PURPOSE

Hoxd-13, as one of the most posterior genes among Hox genes, was reported to play a critical role in the development of the most posterior alimentary canal in vertebrates. This study investigated the expression pattern of Hoxd-13 in the hindgut development of the normal and ethylenethiourea (ETU)-exposed rat embryos with anorectal malformations (ARMs) to find out the possible role of Hoxd-13 in the hindgut development and anorectal morphogenesis.

MATERIAL AND METHOD

The ETU murine model of ARMs was used via ETU 1% (125 mg/kg) on gestational day (gD) 10. Embryos were harvested via cesarean delivery on gD13 to gD21. Temporal and spatial expression of Hoxd-13 was evaluated in the normal fetal rats (n = 215) and ARMs rats (n = 218) using immunohistochemistry staining, reverse transcriptase polymerase chain reaction, and Western blot analysis.

RESULTS

Immunohistochemistry staining revealed that Hoxd-13 expression was confined to the epithelium of the hindgut, cloacal membrane, and urogenital sinus as well as the mesenchyme of the urorectal septum at all gestations in the normal group; however, in the ARMs group, the signal specific for Hoxd-13 was weak in the epithelium of the hindgut and cloacal membrane as well as the mesenchyme of the urorectal septum. Western blot analysis and reverse transcriptase polymerase chain reaction revealed that the level of Hoxd-13 expression was significantly decreased in the ARMs embryos compared with that in the normal embryos on gD13 to gD16 (P < .05) rather than on gD18 to gD21.

CONCLUSIONS

The aberrations in spatiotemporal expression pattern of Hoxd-13 on gD13 to gD16 suggested that Hoxd-13 may be an essential inductive signal for normal development of the hindgut, and altered expression may contribute to the abnormal development of the hindgut and accordingly lead to ARMs.

Embryonic development of the striated muscle complex in rats with anorectal malformations

PURPOSE

Many patients with anorectal malformations (ARMs) continue to have postoperative anal dysfunction. The striated muscle complex (SMC) is one of the most important factors that influence defecation function. To explore the development of SMC in ARMs, the authors investigated the pelvic muscle development in rat embryos affected with ARMs.

METHODS

Anorectal malformation embryos were induced by ethylenethiourea on the 10th gestational day (E10). Normal rat embryos and embryos with ARMs from E13 to E21 were serial-sectioned in the sagittal, transverse, and coronal planes, stained with H&E and immunohistochemistry staining using specific antibodies to myogenin. Temporal and spatial sequence was carried out on SMC.

RESULTS

On E16, in normal group, SMC appeared fibroid structure in normal rats; SMC arose from bulbocavernosus muscle and ran backward, parallel to the perineal skin, and loosely surrounded the anal canal and urethra. Although in ARM rats the rectum was absent, the location and appearance of SMC were similar to the normal group. On E18, in normal group, SMC musculature became much thicker than on E16 and SMC gave off 2 branches outside anterior to the rectum. Striated muscle complex surrounded the rectum more tightly. However, in ARM rats, obvious changes of SMC could be noted. In detail, SMC in ARMs were characterized by abnormal location, appearance, and path. Striated muscle complex shifted obviously cephalad, ventrally, and medianward and converged inferior to the rectal terminus and posterior to the urethra. The distance between SMC musculature and the perineal skin increased. This structure surrounded the fiberlike tissue posterior to the urethra. Under high-power view, there was connective tissue among intermuscular bundles, and the structure was disordered. During the following gestational days, SMC in normal and ARM groups continued their own tendency, respectively.

CONCLUSIONS

This study illustrated the development of the SMC in normal and ARM rats. On E16, the location and appearance of SMC in ARM rats were similar to the normal rats, and at this time, the ectopic rectal orifice could be noted. From E18 on, the maldevelopment of SMC could be observed in ARM rats. These observations suggested that the morphological changes of SMC take place after the occurrence of abnormal anorectum.

Developmental processes and ectodermal contribution to the anal canal in mice

The anorectal canal has two origins; the upper part is derived from endoderm and the lower part is derived from ectoderm. The process of ectodermal contribution to the canal remains unclear. To understand the development of this area, serial sagittal sections of mouse embryos were made every 12h from embryonic day 13.0 (E13.0) to E18.5. Three-dimensional (3-D) reconstructions were obtained from these sections. At the time of the disappearance of the cloacal membrane (E13.5), the endodermal lining reached the site of disintegrated membrane. Thus, the whole canal was of endodermal origin. The transitional zone between the dorsal end of the primary perineum and tail was thicker than other ectodermal epithelia. In this region, it changed from an acute to obtuse angle. After it straightened out and formed the canal, the secondary perineum appeared caudally. During these processes, the external sphincter appeared in the underlying mesenchyme of the thick ectoderm and functioned as a drawstring to form the ectodermal anal canal.

Urorectal septum malformation sequence: prenatal progression, clinical report, and embryology review

The urorectal septum malformation sequence (URSMS) is characterized by severe abnormalities of the urorectal septum (URS) and urogenital organs. The primary defect in this condition appears to be a deficiency in caudal mesoderm leading to the malformation of the URS and other structures in the pelvic region. Recent clinical reports discuss prental findings of URSMS [Lubusky et al. (2006); Prenatal Diagnosis 26: 345-349]. However, here we present a case of URSMS with prenatal findings not previously described, review the literature on URSMS, and summarize current embryological understanding of the pathology seen in hindgut development. The unique prenatal finding in the patient was an abdominally located cystic mass that was first seen at 18 weeks of gestation. Over the next 6 weeks, the mass decreased in size until it disappeared. Concurrent with reduction of the cyst, ascites developed. The patient displayed several traditional URSMS indicators including abnormal bladder and dysplastic kidneys. Our findings give additional insight into the embryology of urorectogenital development. Specifically, they suggest that the cystic mass may have been a persistent urachus prior to septation of the cloaca. Postnatal evaluation confirmed a URSMS diagnosis; the newborn had ambiguous genitalia, hypoplastic kidneys, absent uterus, imperforate anus, smooth perineum, and overall underdeveloped urogenital structures.

Mutational analyses of UPIIIA, SHH, EFNB2 and HNF1beta in persistent cloaca and associated kidney malformations

OBJECTIVES

'Persistent cloaca' is a severe malformation affecting females in which the urinary, genital and alimentary tracts share a single conduit. Previously, a Uroplakin IIIA (UPIIIA) mutation was reported in one individual with persistent cloaca, and UPIIIA, Sonic Hedgehog (SHH), Ephrin B2 (EFNB2) and Hepatocyte Nuclear Factor 1beta (HNF1beta) are expressed during the normal development of organs that are affected in this condition. HNF1beta mutations have been associated with uterine malformations in humans, and mutations of genes homologous to human SHH or EFNB2 cause persistent cloaca in mice.

PATIENTS AND METHODS

We sought mutations of coding regions of UPIIIA, SHH, EFNB2 and HNF1beta genes by direct sequencing in a group of 20 patients with persistent cloaca. Most had associated malformations of the upper renal tract and over half had impaired renal excretory function. The majority of patients had congenital anomalies outside the renal/genital tracts and two had the VACTERL association.

RESULTS

Apart from a previously described index case, we failed to find UPIIIA mutations, and no patient had a SHH, EFNB2 or HNF1beta mutation.

CONCLUSION

Persistent cloaca is only rarely associated with UPIIIA mutation. Despite the fact that SHH and EFNB2 are appealing candidate genes, based on their expression patterns and mutant mice phenotypes, they were not mutated in these humans with persistent cloaca. Although HNF1beta mutations can perturb paramesonephric duct fusion in humans, HNF1beta was not mutated in persistent cloaca.

Tissue fusion and cell sorting in embryonic development and disease: biomedical implications

Throughout embryonic development, segregated epithelial and/or mesenchymal cell populations make contact and fuse to shape new tissue units. This process, known as tissue fusion, is a key event in many essential morphogenetic mechanisms and its disruption can lead to congenital malformations. Another mechanism whereby complex tissues can arise involves a cell sorting process in which originally intermixed cells de-mix to generate distinct phases or layers. Different organisms use a combination of tissue fusion and cell sorting to acquire shape. Although the two processes appear to differ mechanistically, they are intricately linked inasmuch as they both involve the same molecular determinants and contribute to the same body plan. We aim to discuss the role of adhesion molecules and cell dynamics in tissue fusion and cell sorting, providing examples of their impact in embryonic development. Finally, we will advance the concept that malignant invasion may be viewed as cell sorting in reverse. Supplementary material for this article can be found on the BioEssays website (http://www.interscience.wiley.com/jpages/0265-9247/suppmat/index.html).

Development of the primary mouth in Xenopus laevis

The initial opening between the gut and the outside of the deuterostome embryo breaks through at the extreme anterior. This region is unique in that ectoderm and endoderm are directly juxtaposed, without intervening mesoderm. This opening has been called the stomodeum, buccopharyngeal membrane or oral cavity at various stages of its formation, however, in order to clarify its function, we have termed this the "primary mouth". In vertebrates, the neural crest grows around the primary mouth to form the face and a "secondary mouth" forms. The primary mouth then becomes the pharyngeal opening. In order to establish a molecular understanding of primary mouth formation, we have begun to examine this process during Xenopus laevis development. An early step during this process occurs at tailbud and involves dissolution of the basement membrane between the ectoderm and endoderm. This is followed by ectodermal invagination to create the stomodeum. A subsequent step involves localized cell death in the ectoderm, which may lead to ectodermal thinning. Subsequently, ectoderm and endoderm apparently intercalate to generate one to two cell layers. The final step is perforation, where (after hatching) the primary mouth opens. Fate mapping has defined the ectodermal and endodermal regions that will form the primary mouth. Extirpations and transplants of these and adjacent regions indicate that, at tailbud, the oral ectoderm is not specifically required for primary mouth formation. In contrast, underlying endoderm and surrounding regions are crucial, presumably sources of necessary signals. This study indicates the complexity of primary mouth formation, and lays the groundwork for future molecular analyses of this important structure.

Cellular proliferation in the urorectal septation complex of the human embryo at Carnegie stages 13-18: a nuclear area-based morphometric analysis

In order to analyse the patterns of cellular proliferation both in the mesenchyme of the urorectal septum (URS) and in the adjacent territories (posterior urogenital mesenchyme, anterior intestinal mesenchyme and cloacal folds mesenchyme), as well as their contribution to the process of cloacal division, a computer-assisted method was used to obtain the nuclear area of 3874 mesenchymal cells from camera lucida drawings of nuclear contours of selected sections of human embryos [Carnegie stages (CSs) 13-18]. Based on changes in the size of the nucleus during the cellular cycle, we considered proliferating cells in each territory to be those with a nuclear area over the 75th percentile. The URS showed increasing cell proliferation, with proliferation patterns that coincided closely with cloacal folds mesenchyme, and with less overall proliferation than urogenital and intestinal mesenchymes. Furthermore, at CS 18, we observed the beginning of the rupture in the cloacal membrane; however, no fusion has been demonstrated either between the URS and the cloacal membrane or between the cloacal folds. The results suggest that cloacal division depends on a morphogenetic complex where the URS adjacent territories could determine septal displacement at the time that their mesenchymes could be partially incorporated within the proliferating URS.

Spatiotemporal distribution of apoptosis during normal cloacal development in mice

To understand normal cloacal developmental processes, serial sagittal sections of mouse embryos were made every 6 hrs from embryonic day 11.5 (E11.5) to E13.5. During cloacal development to form the urogenital sinus and anorectal canal, fusion of the urorectal septum with the cloacal membrane was not observed, and the ventral and dorsal parts of the cloaca were continuously connected by the canal until disappearance of the cloacal membrane to open the vestibule formed by the urogenital sinus and anorectal canal to the outside at E13.5. Ventral shifting of the dorsal part of the cloaca was observed until E12.5. The dorsal part was transformed in accordance with ventral shifting. In addition, apoptosis was seen to occur around the dorsal part. However, from E12.25, apoptotic cells are observed in a linear arrangement in the urorectal septum just ventral to the peritoneal cavity. Interestingly, extension of this line reaches the area of the cloacal membrane disintegrated by apoptosis. The present findings suggest that in the early stages (until E12.0), distribution of apoptosis in mesenchyme around the dorsal part of the cloaca might be strongly related to the transformation and ventral shifting of this part. Conversely, the apoptosis pattern in urorectal septum mesenchyme in later stages (from E12.0) might be involved in transformation of the urorectal septum and disintegration of the cloacal membrane.

Clarification of the processes that lead to anorectal malformations in the ETU-induced rat model of imperforate anus

BACKGROUND

Ethylenethiourea (ETU) administered to timed-pregnant rats can induce anorectal malformations (ARMs) in about 80% of rat fetuses, thus providing an ideal animal model to study the embryogenesis of ARMs. The current study was undertaken to investigate the embryogenetic events that may be responsible for the development of ARMs in rats.

METHODS

Time-mated pregnant rats were divided randomly into control and experimental groups. The experimental rats received 1% ETU (125 mg/kg) by gavage on gestational day 10, and control rats received only the vehicle. Their embryos were harvested by cesarean section on gestational days 13, 14, 15, and 16. They were fixed and embedded in paraffin and serially sectioned in either the sagittal or transverse plane. The sections were stained with H&E, examined, and photographed. The comparative morphogenesis of the hindgut, cloaca, and tailgut of age-matched embryos was studied.

RESULTS

The key abnormalities in the experimental embryos were: (1) maldevelopment of cloaca and urorectal septum with no sign of the fusion between the urorectal septum and the cloacal membrane, (2) delay of tailgut regression, (3) abnormal and massive apoptotic cell death involving the posterior cloacal wall, and (4) underdevelopment of the dorsal aspect of the cloaca and its membrane. The type of ARM that was developing was discernible by gestational day 15 and 16.

CONCLUSIONS

ARMs induced by ETU in rat embryos seem to be caused by the cumulative effect of aberrations in the development of several components of the hindgut and cloaca. Variation in the extent of maldevelopment of these structures may result in a spectrum of ARMs.