Differences between human and mouse alpha-fetoprotein expression during early development

Alpha-fetoprotein (AFP) is the major serum protein during development. AFP is one of the earliest proteins to be synthesised by the embryonic liver. The synthesis of AFP decreases dramatically after birth and only trace amounts are expressed in the adult liver. The tissue distribution of AFP in early human embryogenesis has not been defined. We have studied the expression pattern of AFP mRNA in human and mouse embryos by in situ hybridisation. In humans, AFP is expressed in the hepatic diverticulum at 26 d postovulation as it differentiates from the foregut endoderm (i.e. in the most primitive hepatocytes). It is also expressed in the endoderm of the gastrointestinal tract and in the yolk sac at this age. AFP is subsequently expressed in the mesonephros and transiently in the developing pancreas. In the mouse, no expression of AFP was observed in the mesonephros but other sites of expression were similar. Thus AFP has a distinct temporospatial expression pattern during the embryonic period and this differs between human and mouse species. It is interesting that AFP is expressed by tumours such as primitive gastrointestinal, renal cell and pancreatic tumours as well as those of hepatocyte origin. This distribution reflects the sites of AFP expression during development.     

Laser‐mediated cell ablation during post‐implantation mouse development

BACKGROUND: Laser‐mediated cell ablation is a powerful tool that has been used to understand cell fate in a variety of externally developing organisms but has not been used during mammalian post‐implantation development. RESULTS: We describe a method pairing laser ablation with murine embryo culture and establish parameters that can be used to precisely ablate cells in the selected field with minimal disruption to adjacent cells or the underlying cell matrix. Ablation of a large domain of endoderm, followed by ～1 day of culture results in a phenotypically normal embryo and gut tube, indicating that laser ablation is compatible with normal development. We next focused on one of the three precursor populations that have been shown to produce the liver bud. Ablations of a single progenitor domain result in a unilateral delay in the liver bud while the contralateral side is unaffected. CONCLUSIONS: We demonstrate that laser ablation is a specific and useful technique for studying cell fate in the mouse embryo. This method represents a powerful advance in developmental studies in the mouse and can be used to provide information on the specification of organs, differentiation, cell migration, and vital tissue interactions during development. Developmental Dynamics, 242:1202–1209, 2013. © 2013 Wiley Periodicals, Inc.     

Cystathionine γ-lyase expression during avian embryogenesis

Cystathionine γ-lyase (CSE) is a key enzyme in the trans-sulphuration pathway for the biosynthesis of cysteine from methionine and catalyses the hydrolysis of cystathionine into cysteine. It has been reported to be expressed in mammalian liver and kidney but so far no comprehensive developmental expression analysis of CSE has been available. We cloned a 600 bp fragment of chick CSE cDNA and analysed its expression pattern during avian embryonic development until embryonic day 13. We found CSE expression in various developing organs including the notochord, eye, neural tube, limb bud mesenchyme and sclerotomal compartment of the somites. Notably, prominent expression was found in renal epithelia throughout kidney development, i.e. in the tubular structures of pronephros, mesonephros and metanephros. Our data introduce CSE as a novel marker gene to study avian kidney development.     

Tissue factor expression during human and mouse development.

In the adult organism the cellular distribution of tissue factor (TF) expression corresponds to biological boundary layers forming a hemostatic barrier ready to activate blood coagulation after tissue injury. Whether TF expression might also play a role in development is unknown. To determine the significance of TF in ontogenesis, we examined the pattern of TF expression in mouse development and compared it with the distribution of TF in human post-implantation embryos and fetuses of corresponding gestational age. At early embryonic periods of murine (6.5 and 7.5 pc) and human (stage 5) development, there was strong expression of TF in both ectodermal and entodermal cells. In situ hybridization and immunohistochemistry demonstrated that TF mRNA and protein were expressed widely in epithelial areas with high levels of morphogenic activity during organogenesis. Staining for TF was seen during ontogenetic development in tissues such as epidermis, myocardium, bronchial epithelium, and hepatocytes, which express TF in the adult organism. Surprisingly, during renal development and in adults, expression of TF differed between humans and mice. In humans, maturing stage glomeruli were stained for TF whereas in mice, TF was absent from glomeruli but was present in the epithelia of tubular segments. In neuroepithelial cells, there was a substantial expression of TF. Moreover, there was robust TF expression in tissues such as skeletal muscle and pancreas, which do not express it in the adult. In contrast, expression of the physiological ligand for TF, factor VII, was not detectable during early stages of human embryogenesis using immunohistochemistry. The temporal and spatial pattern of TF expression during murine and human development supports the contention that TF serves as an important morphogenic factor during embryogenesis.     

Spred2 expression during mouse development

SPREDs (Sprouty‐related proteins with Ena/Vasodilator‐stimulated phosphoprotein homology‐1 domain) are known membrane‐associated modulators of receptor tyrosine kinases by inhibiting the mitogen‐activated protein kinase (MAPK) signaling pathway. Although Spred2^?/? mice exhibit dwarfism and increase of early haematopoiesis, the precise expression and role of SPRED2 in mouse development remains unknown. Here, we demonstrate a detailed Spred2 expression pattern during mouse development using X‐Gal stainings from samples of a gene‐trapped Spred2 mouse line. In early stages, Spred2 was highly expressed in ectodermal and mesodermal tissues, and later on in developing neural tissue, heart, lung, intestine, urogenital tract, and limbs. Strikingly, we observed that Spred2 was mainly expressed at leading edges of further outgrowing structures and in folds of newly forming grooves. Therefore, SPRED2 is likely involved in the regulation of dynamic developmental processes. These new data provide valuable information for further studies regarding the still enigmatic physiological SPRED functions during mouse development. Developmental Dynamics 239:3072–3085, 2010. © 2010 Wiley‐Liss, Inc.     

MMP‐2 expression during early avian cardiac and neural crest morphogenesis

Matrix metalloproteinase‐type 2 (MMP‐2) degrades extracellular matrix, mediates cell migration and tissue remodeling, and is implicated in mediating neural crest (NC) and cardiac development. However, there is little information regarding the expression and distribution of MMP‐2 during cardiogenesis and NC morphogenesis. To elucidate the role of MMP‐2, we performed a comprehensive study on the temporal and spatial distribution of MMP‐2 mRNA and protein during critical stages of early avian NC and cardiac development. We found that ectodermally derived NC cells did not express MMP‐2 mRNA during their initial formation and early emigration but encountered MMP‐2 protein in basement membranes deposited by mesodermal cells. While NC cells did not synthesize MMP‐2 mRNA early in migration, MMP‐2 expression was seen in NC cells within the cranial paraxial and pharyngeal arch mesenchyme at later stages but was never detected in NC‐derived neural structures. This suggested NC MMP‐2 expression was temporally and spatially dependent on tissue interactions or differed within the various NC subpopulations. MMP‐2 was first expressed within cardiogenic splanchnic mesoderm before and during the formation of the early heart tube, at sites of active pharyngeal arch and cardiac remodeling, and during cardiac cushion cell migration. Collectively, these results support the postulate that MMP‐2 has an important functional role in early cardiogenesis, NC cell and cardiac cushion migration, and remodeling of the pharyngeal arches and cardiac heart tube. Anat Rec 259:168–179, 2000. © 2000 Wiley‐Liss, Inc.     

Diversified expression patterns of autotaxin,a gene for phospholipid‐generating enzyme during mouse and chicken development

Autotaxin (ATX), or nucleotide pyrophosphatase‐phosphodiesterase 2, is a secreted lysophospholipase D that generates bioactive phospholipids that act on G protein–coupled receptors. Here we show the expression patterns of the ATX gene in mouse and chicken embryos. ATX has a dynamic spatial and temporal expression pattern in both species and the expression domains during neural development are quite distinct from each other. Murine ATX (mATX) is expressed immediately rostral to the midbrain‐hindbrain boundary, whereas chicken ATX (cATX) is expressed in the diencephalon and later in the parencephalon‐synencephalon boundary. In the neural tube, cATX is expressed in the alar plate in contrast to mATX in the floor plate. ATX is also expressed in the hindbrain and various organ primordia such as face anlagen and skin appendages of the mouse and chicken. These results suggest conserved and non‐conserved roles for ATX during neural development and organogenesis in these species. Developmental Dynamics 236:1134–1143, 2007. © 2007 Wiley‐Liss, Inc.     

Comparative expression of mouse and chicken Shisa homologues during early development.

During vertebrate embryogenesis, fibroblast growth factor (FGF) and Wnt signaling have been implicated in diverse cellular processes, including cell growth, differentiation, and tissue patterning. The recently identified Xenopus Shisa protein promotes head formation by inhibiting Wnt and FGF signaling through its interaction with the immature forms of Frizzled and FGF receptors in the endoplasmic reticulum, which prevents their posttranslational maturation. Here, we describe the mouse and chicken homologues of Xenopus Shisa. The mouse and chicken Shisa proteins share, respectively, 33.6% and 33.8% identity with the Xenopus homolog. In situ hybridization analysis shows that mouse shisa is expressed throughout embryonic development, predominantly in the anterior visceral endoderm, headfolds, somites, forebrain, optic vesicle, and limb buds. Cross-species comparison shows that the expression pattern of cshisa closely mirrors that of mshisa. Our observations indicate that the Shisa family genes are typically expressed in tissues known to require the modulation of Wnt and FGF signaling.     

Origin and development of the pronephros in the chick embryo

The process by which the pronephros develops was morphologically examined in chick embryos from Hamburger-Hamilton stage (ST) 8+ to ST34. The intermediate mesoderm, from which the pronephros arises, was first seen as a faint ridge of undifferentiated mesoderm between the segmental plate and lateral plate at ST8+. It formed a cell cord at the level of the 6th to the presumptive 13th somites at ST9 to ST10. This cell cord then separated into dorsal and ventral parts, the former becoming the nephric duct and the latter the tubules by ST14. The primordia of the external glomeruli (PEGs) appeared at ST15 through some epithelial cells protruding in the nephrostome (the opening of the nephric tubule into the body cavity). PEGs formed gradually in the caudal direction until ST18, while the pronephric tubules and PEGs in cranial locations disappeared. At this stage, only a few PEGs remained at the level of the 13th and 14th somites and these developed from ST23 to ST29 to become ultrastructurally similar to the glomeruli of the functional kidney. From these observations in the avian pronephros, we infer that the pronephric duct and tubules both form from a cell cord in the intermediate mesoderm and at the same time, but later develop differently.     

Molecular characteristics and alterations during early development of the human vagina

Unresolved questions remain concerning the derivation of the vagina with respect to the relative contributions from the Müllerian ducts, the urogenital sinus, and the Wolffian ducts. Recent molecular and cellular studies in rodents have opened up a large gap between the level of understanding of vaginal development in mice and understanding of human vaginal development, which is based on histology. To compare the findings in mice with human vaginal development and to address this gap, we analysed molecular characteristics of the urogenital sinus, Wolffian ducts, and Müllerian ducts in 8-14-week-old human specimens using immunohistochemical methods. The monoclonal antibodies used were directed against cytokeratin (CK) 14, CK19, vimentin, laminin, p63, E-cadherin, caspase-3, Ki67, HOX A13, and BMP-4. The immunohistochemical analysis revealed that, during weeks 8-9, the epithelium of the Müllerian ducts became positive for p63 as p63-positive cells that originated from the sinus epithelium reached the caudal tip of the fused Müllerian ducts via the Wolffian ducts. The lumen of the fused Müllerian ducts was closed by an epithelial plug that contained both vimentin-positive and vimentin-negative cells. Subsequently, the resulting epithelial tube enlarged by proliferation of basal p63-positive cells. The first signs of squamous differentiation were detected during week 14, with the appearance of CK14-positive cells. According to our results, all three components, namely, the urogenital sinus, Wolffian ducts, and Müllerian ducts, interacted during the formation of the human vagina. The sinus epithelium provided p63-positive cells, the Wollfian ducts acted as a 'transporter', and the Müllerian ducts contributed the guiding structure for the vaginal anlagen. Epithelial differentiation began at the end of the period studied and extended in a caudo-cranial direction. The present study is one of the first to provide up-to-date molecular correlates for human vaginal development that can be compared with the results of cell biological studies in rodents.     

Cytokeratin expression and early lens development

Summary Immunohistochemical analysis of cytokeratins and vimentin in human, rabbit and rat lens epithelium during development revealed transient coexpression of both types of intermediate filaments. Cytokeratins were still detectable after the closure of the lens vesicle (rat and rabbit embryos 13 days post conception) and in the epithelial cells located at the anterior side of the lens in 7-week-old human embryos. Different monoclonal antibodies against cytokeratin 8 reacted differently in lens cells but not in other embryonic tissues. In addition, early human and rabbit specimens exhibited cytokeratin immunostaining in the neuroectodermal cells of the eye cup as well as in the surrounding mesenchyme, and in the hyaloid artery. Possible explanations for the loss of cytokeratins during the differentiation of ectodermal and neuroectodermal cells are discussed.Supported by a grant from the Fritz Thyssen Stiftung (M.K.) and by the Deutsche Forschungsgemeinschaft (Ch. V.; Wa 359-9)     

Requirements for Jag1-Rbpj mediated Notch signaling during early mouse lens development

Background: During vertebrate lens development, the lens placode in the embryonic ectoderm invaginates into a lens vesicle, which then separates from the surface epithelium, followed by two waves of fiber cell differentiation. In the mouse, multiple labs have shown that Jag1‐Notch signaling is critically required during the second wave of lens fiber cell formation. However, Notch signaling appears to play no obvious role during lens induction or morphogenesis, although multiple pathway genes are expressed at these earlier stages. Results: Here, we explored functions for Notch signaling specifically during early lens development, by using the early‐acting AP2α‐Cre driver to delete Jag1 or Rbpj. We found that Jag1 and Rbpj are not required during lens induction, but are necessary for proper lens vesicle separation from the surface ectoderm. Conclusions: We conclude that precise levels of Notch signaling are essential during lens vesicle morphogenesis. In addition, AP2α‐Cre‐mediated deletion of Rbpj resulted in embryos with cardiac outflow tract and liver deformities, and perinatal lethality. Developmental Dynamics 241:493–504, 2012. © 2012 Wiley Periodicals, Inc.