小鼠胚胎心脏流出道嵴的发育

目的探讨小鼠胚胎心脏流出道嵴内α-平滑肌肌动蛋白(α-SMA)阳性细胞的来源及流出道嵴融合时间充质细胞超微结构的变化。方法用抗α-SMA、抗α-横纹肌肌动蛋白(α-SCA)单克隆抗体、PlexinA2探针,对胚龄10～14d小鼠胚胎心脏切片进行免疫组织化学和原位杂交染色;透射电镜观察胚龄12.5d时小鼠心流出道嵴的融合过程。结果胚龄10～11d,小鼠神经管及其周围、动脉囊和弓动脉壁可见PlexinA2阳性细胞,并沿动脉囊壁迁入流出道嵴内,部分细胞同时表达α-SMA。胚龄12d,PlexinA2阳性细胞分布在脊神经节、咽前间充质、主肺动脉隔以及主、肺动脉壁。主肺动脉隔显α-SMA强阳性,但动脉壁仅见少量α-SMA阳性细胞。胚龄12.5d,流出道嵴内致密间充质细胞团形成并开始融合,PlexinA2表达较弱,α-SMA表达呈强阳性。在流出道嵴融合开始后,嵴表面的内皮细胞带形成继而断裂消失,由含微丝少、排列稀疏的间充质细胞取代。两侧致密细胞团逐渐靠拢、融合。有的间充质细胞内含较多线粒体和微丝,细胞之间形成细胞连接点;有的间充质细胞含微丝少,细胞膜间断融合。结论流出道心内膜垫内α-SMA阳性间充质细胞来自神经嵴;内皮细胞-间充质细胞转化可能参与了流出道嵴融合;致密细胞团内间充质细胞富含微丝束和细胞连接点或发生细胞膜融合有助于流出道嵴的融合。     

Ontogeny of galanin‐immunoreactive elements in chicken embryo autonomic nervous system

To elucidate the main ontogenetic steps of galanin immunoreactivity within the extrinsic nerve supply of the alimentary tract, we undertook an immunohistochemical study of chicken embryo specimens. Fluorescence and streptavidin‐biotin‐peroxidase protocols were combined, using a galanin polyclonal antiserum, on transverse serial sections obtained from chicken embryos from embryonic Day 3 (E3) to hatching, and from 9‐day‐old newborn chicks. Galanin‐immunoreactive cells were first detected at E3.5 within the pharyngeal pouch region, the nodose ganglion, the primary sympathetic chain, primitive splanchnic branches and the caudal portion of the Remak ganglion. At E5.5 galanin‐immunoreactive cells and fibers appeared in the secondary (paravertebral) sympathetic chain, splanchnic nerves, peri‐ and preaortic plexuses, adrenal gland anlage and visceral nerves. Galanin‐immunoreactive cells also lay scattered along the vagus nerve, and in the intermediate zone of the thoracolumbar spinal cord. At E18, galanin‐immunoreactive cells and fibers were found along the entire Remak ganglion and around the gastrointestinal blood vessels. In post‐hatching‐9‐day old chicks, the para‐ and prevertebral ganglia, but not the intermediate zone of the spinal cord, contained galanin‐immunoreactive cells. Data indicate the presence of a consistent “galaninergic” nerve system supplying the chick embryonal gut wall. Whether this system has growth or differentiating role remains to be demonstrated. Its presence and distribution pattern in the later stages clearly support its well known role as a visceral neuromodulator of gut function. Anat Rec 262:266–278, 2001. © 2001 Wiley‐Liss, Inc.     

神经嵴细胞和胰岛因子1阳性细胞与小鼠胚胎心流出道发育的关系

目的 探讨迁移中的细胞视黄酸结合蛋白1(CRABP1)阳性神经嵴细胞、胰岛因子1(ISL-1)、阳性心肌前体细胞与小鼠胚胎心流出道发育的关系.方法 36只胚龄8.5～13d小鼠胚胎心连续石蜡切片,选用抗α-平滑肌肌动蛋白(α-SMA)、抗心肌肌球蛋白重链(MHC)、抗转录因子ISL-1、抗CRABP1和抗磷酸化组蛋白H3(PHH3)抗体,进行免疫组织化学及免疫荧光染色.结果 胚龄8.5～10d,ISL-1阳性心肌前体细胞相继出现在心背系膜、原始咽两侧、头面部、鳃弓核心间充质和心包腔背侧壁间充质,构成心管流出道发育的第二生心区.胚龄11～13d,ISL-1阳性细胞在咽前方聚集,形成特征性锥体形结构,并向升主动脉、肺动脉干及主肺动脉隔延伸.胚龄9d前,神经嵴细胞散在分布于ISL-1阳性细胞之间,流出道远侧端可见少量CRABP1和ISL-1双阳性细胞.胚龄10d,CRABP1阳性神经嵴细胞分布在ISL-1阳性鳃弓核心间充质周围.随着发育,弓动脉等处的神经嵴细胞逐渐失去CRABP1表达,开始表达α-SMA.结论 ISL-1阳性第二生心区是动态结构,胚龄8.5～10d时,在神经嵴细胞配合下,向心管动脉端添加心肌细胞;胚龄11d后,开始向平滑肌方向分化,参与升主动脉、肺动脉干和主肺动脉隔的发育.     

Gangliorhabdomyosarcoma: a histopathological and immunohistochemical study of three cases

A histopathological and immunoperoxidase study on three cases of genitourinary gangliorhabdomyosarcoma using a spectrum of conventional staining methods and antibodies against myoglobin, neuron-specific enolase and S-100 protein is presented. The results of the study have shown that differentiated myoblasts, ganglion cells and Schwann cells reacted positively with the particular antisera, but the majority of undifferentiated cells were negative. From the immunopathology results it was not possible to determine whether the undifferentiated cells were precursors of neural cells or myoblasts; the histological appearance resembled that of mesenchymal cells commonly seen in rhabdomyosarcomas. Theories concerning the origin of these tumours from neural crest ectomesenchyme or from neural crest and somitic mesenchyme are considered. Further study is needed to establish their histogenesis.     

The tyrosine hydroxylase gene is expressed in endoderm and pancreas of early quail embryos

The initial expression of the gene encoding tyrosine hydroxylase (TH) was studied in the trunk of quail embryos by in situ hybridization. We detected the presence of quail TH mRNA on embryonic day 3.5 (E3.5) in the sympathetic ganglia and aortic plexus, both neural crest derived structures. In contrast, the TH gene was expressed much earlier in the endodermal layer of E2 embryos, i. e. from the 8-somite stage onwards. TH mRNA was found also in the pancreatic bud, an endoderm-derived structure. The TH protein and catecholamines were subsequently looked for in these structures. TH immunoreactivity was found in cells of E2 explanted endoderm, but no catecholamine histofluorescence was observed before or after a few days in culture. TH-positive cells were also detected in cultures of pancreatic rudiments, explanted from E3 to E6 quail embryos. We suggest that the TH-positive cells of the endoderm are the progenitors of the catecholaminergic cells of the pancreas and of the enterochromaffin cells of the gut. The hypothesis that the TH-positive cells of the endoderm are involved in the expression of the catecholaminergic phenotype by neural crest cells is discussed.     

Immunolocalization of N-CAM in the heart of the early developing rat embryo

Background: Neural cell adhesion molecule (N-CAM) is important in the migration of neural crest cells and is expressed in the developing heart. The pattern of expression of N-CAM in the heart of early rat embryos was investigated to shed light on the potential role of N-CAM in cardiac neural crest cell migration. Methods: N-CAM expression was studied by immunohistochemistry in Sprague-Dawley rat hearts between embryonic days 11.5 and 15.5 HNK-1 immunoreactivity was also investigated for comparison with that of N-CAM. Results: A continuity of N-CAM immunoreactivity was transiently detected from the outflow tract to the recurrent nerve. N-CAM was also expressed around the sinus venosus, inferior vena cava, sinotrial septum, and coronary sinus, as well as on mesenchymal cells in the atrioventricular endocardial cushion tissues. Conclusions: The continuous N-CAM immunoreactivity from the outflow tract to the recurrent nerve appeared to represent the pathway along which cardiac neural crest cells migrate. N-CAM-immunoreactive sites around the sinus venosus may correspond to migrating neural crest cells that differentiate into nerve fibers or cardiac ganglia. Results indicate that N-CAM may play an important role in the migration, proliferation, and transformation of neural crest cells, thereby contributing to cardiac morphogenesis and to innervation around the heart and great arteries. © 1995 Wiley-Liss, Inc.     

Hes1 is required for the development of the superior cervical ganglion of sympathetic trunk and the carotid body

Hes1 gene represses the expression of proneural basic helix–loop–helix (bHLH) factor Mash1, which is essential for the differentiation of the sympathetic ganglia and carotid body glomus cells. The sympathetic ganglia, carotid body, and common carotid artery in Wnt1‐Cre/R26R double transgenic mice were intensely labeled by X‐gal staining, i.e., the neural crest origin. The deficiency of Hes1 caused severe hypoplasia of the superior cervical ganglion (SCG). At embryonic day (E) 17.5–E18.5, the volume of the SCG in Hes1 null mutants was reduced to 26.4% of the value in wild‐type mice. In 4 of 30 cases (13.3%), the common carotid artery derived from the third arch artery was absent in the null mutants, and the carotid body was not formed. When the common carotid artery was retained, the organ grew in the wall of the third arch artery and glomus cell precursors were provided from the SCG in the null mutants as well as in wild‐types. However, the volume of carotid body in the null mutants was only 52.5% of the value in wild‐types at E17.5–E18.5. These results suggest that Hes1 plays a critical role in regulating the development of neural crest derivatives in the mouse cervical region. Developmental Dynamics 241:1289–1300, 2012. © 2012 Wiley Periodicals, Inc.     

Development of the Juxta‐Oral Organ in Rat Embryo

The aim of this work is to clarify the development and morphology of the juxta‐oral organ (JOO) in rat embryos from Day (E)14 to 19. Furthermore, in the region of the JOO, an analysis was made of the expression of the monoclonal antibody HNK‐1, which recognizes cranial neural‐crest cells. In this study, we report that JOO develops from an epithelial condensation at the end of the transverse groove of the primitive mouth at E14. During E15, it invaginates and is disconnected from the oral epithelium. At E16, the JOO forms an solid epithelial cord with three parts (anterior, middle, and posterior) and is related to the masseter, temporal, medial pterygoid, and tensor veli palatini muscles. During E17‐19, no significant changes were detected in their position. Both the mesenchyme caudal to the anlage of the JOO at E14, as well as the mesenchyme that surrounds the bud of the JOO at E15, expressed positivity for HNK‐1. Our results suggest that the mesenchyme surrounding the JOO at E15 could emit some inductive signal for the JOO to reach its position at E16. This work shows for the first time that the cranial neural‐crest‐derived mesenchyme participates in the development of the JOO. Anat Rec, 2012. © 2012 Wiley Periodicals, Inc.     

Morphogenesis of the Manubrium of Sternum in Human Embryos: A New Concept

To revisit many theories on fetal development of the manubrium of the sternum, we examined 25 mid‐term fetuses at 6–9 weeks of gestation. The initial developmental stage of the manubrium was characterized by a distinct interclavicular mesenchyme that was continuous with the developing clavicles. Because parts of the clavicle in which endochondral ossification occurs originate from the neural crest, the interclavicular mesenchyme seems to be of the same origin. The sternal bands, possibly of the lateral plate origin, were restricted at the anterior ends of the ribs in the paired thoracic walls. The interclavicular mesenchyme extended caudally and laterally to reach the anterior ends of the first ribs, and thus the interclavicular mesenchyme expanded into the intercostoclavicular mesenchyme. Then, the primitive manubrium was delimited by the sternoclavicular joint and its related ligaments, all of which developed from the interclavicular and intercostoclavicular mesenchymes. Although the first ribs were attached to the intercostoclavicular mesenchyme, the former was vimentin‐negative in contrast to the latter, positive mesenchyme. Soon afterwards, the small upper end of the sternal bands was integrated into the intercostoclavicular mesenchyme to form the primitive manubrium. The infrahyoid muscles and their supplying nerves maintained a close topographical relation to the interclavicular or intercostoclavicular mesenchyme, whereas the pectoralis major muscle kept attachments to the sternal bands. Consequently, the manubrium of sternum appeared to develop in a complex way at a junction area between derivatives of the neural crest, lateral plate, and somite. Anat Rec, 2013. © 2012 Wiley Periodicals, Inc.     

Analysis of gene expression in PTHrP−/− mammary buds supports a role for BMP signaling and MMP2 in the initiation of ductal morphogenesis

Parathyroid hormone–related protein (PTHrP) acts on the mammary mesenchyme and is required for proper embryonic mammary development. In order to understand PTHrP's effects on mesenchymal cells, we profiled gene expression in WT and PTHrP^?/? mammary buds, and in WT and K14‐PTHrP ventral skin at E15.5. By cross‐referencing the differences in gene expression between these groups, we identified 35 genes potentially regulated by PTHrP in the mammary mesenchyme, including 6 genes known to be involved in BMP signaling. One of these genes was MMP2. We demonstrated that PTHrP and BMP4 regulate MMP2 gene expression and MMP2 activity in mesenchymal cells. Using mammary bud cultures, we demonstrated that MMP2 acts downstream of PTHrP to stimulate ductal outgrowth. Future studies on the functional role of other genes on this list should expand our knowledge of how PTHrP signaling triggers the onset of ductal outgrowth from the embryonic mammary buds. Developmental Dynamics 238:2713–2724, 2009. © 2009 Wiley‐Liss, Inc.     

Expression of Ret-, p75(NTR)-, Phox2a-, Phox2b-, and tyrosine hydroxylase-immunoreactivity by undifferentiated neural crest-derived cells and different classes of enteric neurons in the embryonic mouse gut.

Cells of the enteric nervous system are derived from the neural crest. Probes to a number of molecules identify neural crest-derived cells within the gastrointestinal tract of embryonic mice prior to their differentiation into neurons and glial cells. However, it is unclear whether the different markers are identifying all neural crest-derived cells. In this study the distribution of p75(NTR)-immunoreactivity was compared with that of Ret-, Phox2a-, Phox2b-, and tyrosine hydroxylase (TH) in undifferentiated neural crest-derived cells in the E10.5-E13.5 mouse intestine. Neural crest-derived cells colonise the embryonic mouse gut in a rostral-to-caudal wave between E9.5-E14, and differentiation into enteric neurons also occurs in a rostral-to-caudal wave. Thus, the most caudal neural crest-derived cells within the gut are undifferentiated. These most caudal neural crest-derived cells co-expressed p75(NTR)-, Phox2b- and Ret-immunoreactivity; at E10.5 a sub-population was also TH-positive. The most caudal cells did not show Phox2a-immunoreactivity at any stage. However, a sub-population of cells, which was rostral to the undifferentiated neural crest-derived cells, was Phox2a-positive, and these are likely to be cells beginning to differentiate along a neuronal lineage. The expression of Ret-, Phox2a-, Phox2b- and p75(NTR)-immunoreactivity by two classes of enteric neurons that differentiate prior to birth was also examined. Nitric oxide synthase (NOS) neurons showed Phox2b and Ret immunoreactivity at all ages, and Phox2a and p75(NTR) immunoreactivity only transiently. Calcitonin gene-related peptide (CGRP) neurons showed Phox2b and Ret-immunoreactivity, but not Phox2a immunoreactivity. It is concluded that all undifferentiated neural crest-derived cells initially express Phox2b, Ret, and p75(NTR); a sub-population of these cells also expresses TH transiently. Those cells that are beginning to differentiate along a neuronal lineage maintain their expression of Phox2b and Ret, and they start to express Phox2a, but down-regulate p75(NTR); those cells that differentiate along a glial lineage down-regulate Ret and maintain their expression of p75(NTR). Dev Dyn 1999;216:137-152.     

Comparison of c-Fos immunoreactivity in pancreatic beta cells and cells with neural crest origin in rats: an immunohistochemical study

Although a neural crest origin has been proposed for pancreatic beta cells, these cells are known to possess many similarities with neuronal cells. These similarities give rise to the hypothesis that undifferentiated neural crest cells can be transformed into beta cells. The objective of this study was to compare beta-cells and undifferentiated neural crest cells with respect to c-Fos immunoreactivity (c-Fos-IR), which plays a crucial role in certain cellular and biological processes and is used as a neuronal activity marker. For the purpose of the study, c-Fos-IR has been analysed by immunohistochemical methods in rat pancreatic beta cells, pulpal undifferentiated ectomesenchimal cells (PUECs) that are known to have a neural crest origin, and in small intestine fibroblasts which do not have a neural crest origin, in formaline-fixed, paraffin-embedded sections. There were no significant differences between beta-cells and PUECs in c-Fos-IR (p > 0.05) but there was a highly significant difference between fibroblasts and the other two type of cells ( p < 0.001). These results give rise to and support the suggestion that PUECs can be transformed into beta-cells.     

Regulation of the neurofibromatosis 2 gene promoter expression during embryonic development.

Mutations in the Neurofibromatosis 2 (NF2) gene are associated with predisposition to vestibular schwannomas, spinal schwannomas, meningiomas, and ependymomas. Presently, how NF2 is expressed during embryonic development and in the tissues affected by neurofibromatosis type 2 (NF2) has not been well defined. To examine NF2 expression in vivo, we generated transgenic mice carrying a 2.4-kb NF2 promoter driving beta-galactosidase (beta-gal) with a nuclear localization signal. Whole-mount embryo staining revealed that the NF2 promoter directed beta-gal expression as early as embryonic day E5.5. Strong expression was detected at E6.5 in the embryonic ectoderm containing many mitotic cells. beta-gal staining was also found in parts of embryonic endoderm and mesoderm. The beta-gal staining pattern in the embryonic tissues was corroborated by in situ hybridization analysis of endogenous Nf2 RNA expression. Importantly, we observed strong NF2 promoter activity in the developing brain and in sites containing migrating cells including the neural tube closure, branchial arches, dorsal aorta, and paraaortic splanchnopleura. Furthermore, we noted a transient change of NF2 promoter activity during neural crest cell migration. While little beta-gal activity was detected in premigratory neural crest cells at the dorsal ridge region of the neural fold, significant activity was seen in the neural crest cells already migrating away from the dorsal neural tube. In addition, we detected considerable NF2 promoter activity in various NF2-affected tissues such as acoustic ganglion, trigeminal ganglion, spinal ganglia, optic chiasma, the ependymal cell-containing tela choroidea, and the pigmented epithelium of the retina. The NF2 promoter expression pattern during embryogenesis suggests a specific regulation of the NF2 gene during neural crest cell migration and further supports the role of merlin in cell adhesion, motility, and proliferation during development.     

Spatial and temporal distribution of nerves, ganglia, and smooth muscle during the early pseudoglandular stage of fetal mouse lung development.

Neural tissue and smooth muscle appear early in the developing fetal lung, but little is known of their origin and subsequent distribution. To investigate the spatial and temporal distribution of nerves, ganglia, and airway smooth muscle during the early pseudoglandular stage, fetal mouse lungs at embryonic days (E) 11 to 14 were immunostained as whole-mounts and imaged by confocal microscopy. At E11, the primordial lung consisted of the future trachea and two budding epithelial tubules that were covered in smooth muscle to the base of the growing buds. The vagus and processes entering the lung were positive for the neural markers PGP 9.5 (protein gene product 9.5) and synapsin but no neurons were stained at this stage. An antibody to p75NTR revealed neural crest cells on the future trachea as well as in the vagus and in processes extending from the vagus to the lung. This finding indicates that even though neuronal precursors are already present at this stage, they are still migrating into the lung. By E12, neural tissue was abundant in the proximal part of the lung and nerves followed the smooth muscle-covered tubules to the base of the growing buds. At E13 and E14, a neural network of interconnected ganglia, innervated by the vagus, covered the trachea. The postganglionic nerves mainly followed the smooth muscle-covered tubules, but some extended out into the mesenchyme beyond the epithelial buds. Furthermore, we show in a model of cultured lung explants that neural tissue and smooth muscle persist and continue to grow and differentiate in vitro. By using fluorescent markers and confocal microscopy, we present the developing lung as a dynamic structure with smooth muscle and neural tissue in a prime position to influence growth and development.     

Gene tracing analysis reveals the contribution of neural crest‐derived cells in pituitary development

The anterior pituitary originates from the adenohypophyseal placode. Both the preplacode region and neural crest (NC) derive from subdivision of the neural border region, and further individualization of the placode domain is established by a reciprocal interaction between placodal precursors and NC cells (NCCs). It has long been known that NCCs are present in the adenohypophysis as interstitial cells. A recent report demonstrated that NCCs also contribute to the formation of pericytes in the developing pituitary. Here, we attempt to further clarify the role of NCCs in pituitary development using P0‐Cre/EGFP reporter mice. Spatiotemporal analyses revealed that GFP‐positive NCCs invaded the adenohypophysis in a stepwise manner. The first wave was detected on mouse embryonic day 9.5 (E9.5), when the pituitary primordium begins to be formed by adenohypophyseal placode cells; the second wave occurred on E14.5, when vasculogenesis proceeds from Atwell's recess. Finally, fate tracing of NCCs demonstrated that NC‐derived cells in the adenohypophysis terminally differentiate into all hormone‐producing cell lineages as well as pericytes. Our data suggest that NCCs contribute to pituitary organogenesis and vasculogenesis in conjunction with placode‐derived pituitary stem/progenitor cells.