Hedgehog signaling in the neural crest cells regulates the patterning and growth of facial primordia

Facial abnormalities in human SHH mutants have implicated the Hedgehog (Hh) pathway in craniofacial development, but early defects in mouse Shh mutants have precluded the experimental analysis of this phenotype. Here, we removed Hh-responsiveness specifically in neural crest cells (NCCs), the multipotent cell type that gives rise to much of the skeleton and connective tissue of the head. In these mutants, many of the NCC-derived skeletal and nonskeletal components are missing, but the NCC-derived neuronal cell types are unaffected. Although the initial formation of branchial arches (BAs) is normal, expression of several Fox genes, specific targets of Hh signaling in cranial NCCs, is lost in the mutant. The spatially restricted expression of Fox genes suggests that they may play an important role in BA patterning. Removing Hh signaling in NCCs also leads to increased apoptosis and decreased cell proliferation in the BAs, which results in facial truncation that is evident by embryonic day 11.5 (E11.5). Together, our results demonstrate that Hh signaling in NCCs is essential for normal patterning and growth of the face. Further, our analysis of Shh-Fox gene regulatory interactions leads us to propose that Fox genes mediate the action of Shh in facial development.     

Regulation of endothelial cell differentiation and arterial specification by VEGF and Notch signaling

Analysis of molecular and cellular mechanisms underlying vascular development in vertebrates indicates that initially vasculogenesis occurs when a primary capillary plexus forms de novo from endothelial cell precursors derived from nascent mesodermal cells. Transplantation experiments in avian embryos demonstrate that embryonic endothelial cells originate from two different mesodermal lineages: splanchnic mesoderm and somites. Genetic analysis of mouse and zebrafish reveals that vascular endothelial growth factor (VEGF)/Flk1 and Notch signaling play crucial roles throughout embryonic vascular development. VEGFA plays a major role in endothelial cell proliferation, migration, survival, and regulation of vascular permeability. Flk1, the primary VEGFA receptor, is the earliest marker of the developing endothelial lineage and is essential for endothelial differentiation during vasculogenesis. Notch signaling has been demonstrated to directly induce arterial endothelial differentiation. Recent studies suggest that Notch signaling is activated downstream of VEGF signaling and negatively regulates VEGF-induced angiogenesis and suppresses aberrant vascular branching morphogenesis. In addition to altering endothelial cell fate through Notch activation, VEGFA directly guides endothelial cell migration in an isoform-dependent manner, modifying vascular patterns. Interestingly, genetic studies in mice show that many molecules involved in VEGF or Notch signaling must be tightly regulated for proper vascular formation. Taken together, VEGF and Notch signaling apparently coordinate vascular patterning by regulating each other.     

Sustained Hedgehog signaling is required for basal cell carcinoma proliferation and survival: conditional skin tumorigenesis recapitulates the hair growth cycle

Temporally and spatially constrained Hedgehog (Hh) signaling regulates cyclic growth of hair follicle epithelium while constitutive Hh signaling drives the development of basal cell carcinomas (BCCs), the most common cancers in humans. Using mice engineered to conditionally express the Hh effector Gli2, we show that continued Hh signaling is required for growth of established BCCs. Transgene inactivation led to BCC regression accompanied by reduced tumor cell proliferation and increased apoptosis, leaving behind a small subset of nonproliferative cells that could form tumors upon transgene reactivation. Nearly all BCCs arose from hair follicles, which harbor cutaneous epithelial stem cells, and reconstitution of regressing tumor cells with an inductive mesenchyme led to multilineage differentiation and hair follicle formation. Our data reveal that continued Hh signaling is required for proliferation and survival of established BCCs, provide compelling support for the concept that these tumors represent an aberrant form of follicle organogenesis, and uncover potential limitations to treating BCCs using Hh pathway inhibitors.     

Meckel's cartilage differentiation is dependent on hedgehog signaling

The hedgehog (Hh) signaling pathway has been shown to be essential for craniofacial development. Although mandibular arch derivatives are largely absent in Shh null mice, little is known about the role of Hh signaling during Meckel's cartilage development per se. Mandible development is dependent on the morphogenesis of Meckel's cartilage, which then serves as a template for subsequent skeletal differentiation. In this study, we examine the biological function of Hh signaling during Meckel's cartilage development in vivo and in vitro. E13.5 Shh null mice present a small mesenchymal condensation in the region of a presumptive Meckel's cartilage in the hypoplastic mandibular arch. By E15.5, the Shh mutant exhibits a mere remnant of the mandibular arch, without evidence of Meckel's cartilage differentiation. Further, wild-type embryonic (E11 or E12) mandibular explants cultured for up to 5 days in the presence of cyclopamine, a steroidal alkaloid that specifically disrupts the Hh signaling pathway, exhibit a stage-dependent inhibition of Meckel's cartilage chondroblast differentiation to mature chondrocytes. This phenotype can be rescued by exogenous FGF8, a downstream effector of Hh signaling. Taken together, our results indicate that the Hh signaling pathway is critical to Meckel's cartilage ontogenesis and the rate of chondrogenesis, but not to initial primordium formation. The reliance on Hh signaling is stage dependent.     

Tissue- and stage-specific modulation of Wingless signaling by the segment polarity gene lines

Wnt signaling controls a variety of developmental programs but the mechanisms by which the same signal leads to distinct outputs remain unclear. To address this question, we identified stage-specific modulators of Wingless (Wg) signaling in the Drosophila embryonic epidermis. We show that lines (lin) is essential for Wg-dependent patterning in dorsal epidermis. lin encodes a novel protein that acts cell-autonomously, downstream or in parallel to Armadillo (Arm) and upstream of Wg-dependent target genes. Lin can accumulate in nuclei of cells signaled by Wg, suggesting that signaling promotes entry of Lin into the nucleus, where it cooperates with Arm and Pangolin. Thus, a stage-specific modulator is used to mediate Wg signaling activity in dorsal patterning. Hedgehog (Hh) controls half of the parasegmental pattern dorsally and antagonizes Wg function to do so. Lin can accumulate in the cytoplasm of cells signaled by Hh, suggesting that Hh antagonizes Wg function by prohibiting Lin from entering the nucleus.     

Paracrine sonic hedgehog signaling derived from tumor epithelial cells: a key regulator in the pancreatic tumor microenvironment

Activation of the hedgehog (Hh) signaling pathway is involved in embryo development and tumorigenesis. While normal pancreatic tissue exhibits little Hh pathway activity, patients with pancreatic adenocarcinoma have high levels of Hh pathway signaling in both the tumor epithelia and the surrounding stromal tissue. Hh ligands expressed by pancreatic cancers promote tumor growth indirectly by activating Hh signaling in the surrounding stroma. This paracrine activation of Hh signaling in the tumor microenvironment provides a more favorable environment for tumor cellular proliferation, metastasis, and resistance to therapy. Taken together, these findings are of valuable implications for the use of Hh pathway inhibitors currently in development and inhibition of the Hh pathway paracrine loop in pancreatic cancer.     

VEGF signaling is required for the assembly but not the maintenance of embryonic blood vessels.

Here we investigated the importance of vascular endothelial growth factor (VEGF) signaling to the de novo formation of embryonic blood vessels, vasculogenesis, as opposed to the maintenance of blood vessels. We found that antagonizing the activity of the VEGF signaling pathway by using soluble VEGF receptor 1 (sFlt1) or VEGF antibodies inhibited vasculogenesis that occurs in embryos and in cultures of 7.5 days postcoitus prevascular mesoderm. Antagonist treatment resulted in the formation of clusters of endothelial cells not normally observed during vasculogenesis. In contrast, when embryos with established vasculatures or cultures of vascularized mesoderm were treated with sFlt1 or VEGF antibodies, no discernible alterations to the preexisting blood vessels were observed. These observations indicate that, although VEGF signaling is required to promote the mesenchymal to epithelial transition by which angioblasts assemble into nascent endothelial tubes, it is not required by endothelial cells to maintain their organization as an endothelium.     

斑马鱼血管系统的发育遗传学研究进展

斑马鱼血管系统在原肠胚形成后不久便开始发育，血管系统的发育过程可分为血管发生和血管生成这两个不同的阶段，其过程受到多种信号通路的的调控，这些信号协同作用，以确保血管发育的正常进行。文中综述了主要以模式生物斑马鱼来研究的血管发育遗传的过程，并介绍调节血管发育进程的一些关键的调控。以斑马鱼为模式生物来研究血管系统的发育遗传学，为理解人类血管的发育和再生，为缺血性疾病和肿瘤等疾病的治疗提供了新的途径。     

Early formation of the vascular system in quail embryos

The relation between vascular development and translocation of the splanchnic mesodermal layers was studied in presomite to 20-somite quail embryos by scanning electron microscopy. In addition, serially sectioned embryos were stained immunohistochemically with monoclonal antibodies (αQH1 or αMB1) specific for endothelial and hemopoietic cells. By the formation of the foregut the anterior borders of the two splanchnic mesodermal layers of a presomite embryo are translocated to the lateral and ventral sides of the foregut and fuse in the ventral midline of a 4-somite embryo. Meanwhile the splanchnic mesoderm differentiates into a splanchnic mesothelial layer and a plexus of endothelial cells, facing the endoderm. From 4 somites onward the foregut is covered by a single endothelial plexus. At first the endothelial precursors bordering the anterior intestinal portal and those in the area of the ventral mesocardium lumenize, subsequently giving rise to the endocardium of the heart tube. Hereafter, the pharyngeal arch arteries and the dorsal aortae develop from the remaining precursors. During formation of the pharyngeal arches, the pharyngeal arch arteries maintain their connections with the splanchnic plexus through the developing ventral pharyngeal veins. After disappearance of the dorsal mesocardium, the midpharyngeal endothelial strand, which is a longitudinal strand of proendocardial cells, remains connected to the foregut. This strand will contribute to the formation of the pulmonary venous drainage into the left atrium. A bilateral accumulation of cardiac jelly developing between the promyocardium and proendocardial plexus only suggests that the heart develops from two tubes. The proendocardial layer, however, is not divided by the ventral mesocardium but initially forms just one endocardial heart tube. © 1993 Wiley-Liss, Inc.     

Dosage-sensitive requirement for mouse Dll4 in artery development

Involvement of the Notch signaling pathway in vascular development has been demonstrated by both gain- and loss-of-function mutations in humans, mice, and zebrafish. In zebrafish, Notch signaling is required for arterial identity by suppressing the venous fate in developing artery cells. In mice, the Notch4 receptor and the Delta-like 4 (Dll4) ligand are specifically expressed in arterial endothelial cells, suggesting a similar role. Here we show that the Dll4 ligand alone is required in a dosage-sensitive manner for normal arterial patterning in development. This implicates Dll4 as the specific mammalian endothelial ligand for autocrine endothelial Notch signaling, and suggests that Dll4 may be a suitable target for intervention in arterial angiogenesis.     

Zebrafish ift57, ift88, and ift172 intraflagellar transport mutants disrupt cilia but do not affect hedgehog signaling

Cilia formation requires intraflagellar transport (IFT) proteins. Recent studies indicate that mammalian Hedgehog (Hh) signaling requires cilia. It is unclear, however, if the requirement for cilia and IFT proteins in Hh signaling represents a general rule for all vertebrates. Here we examine zebrafish ift57, ift88, and ift172 mutants and morphants for defects in Hh signaling. Although ift57 and ift88 mutants and morphants contained residual maternal protein, the cilia were disrupted. In contrast to previous genetic studies in mouse, mutations in zebrafish IFT genes did not affect the expression of Hh target genes in the neural tube and forebrain and had no quantitative effect on Hh target gene expression. Zebrafish IFT mutants also exhibited no dramatic changes in the craniofacial skeleton, somite formation, or motor neuron patterning. Thus, our data indicate the requirement for cilia in the Hh signal transduction pathway may not represent a universal mechanism in vertebrates. Developmental Dynamics 238:1744–1759, 2009. © 2009 Wiley‐Liss, Inc.     

低氧培养对间充质干细胞生物学的影响

背景：氧参与细胞内ATP的合成以供细胞代谢,氧浓度也是调节细胞生理功能的重要因素。骨髓间充质干细胞的生理病理活动是在低氧状态下进行,其发生机制还不完全清楚。 目的：回顾分析低氧培养对间充质干细胞生物学的影响的研究进展。 方法：应用计算机检索1997-01/2011-10 PubMed 数据库相关文章,检索词为“mesenchymal stem cells,hypoxia,HIF”;同时检索同期万方数据库、维普资讯网数据库和中国知网数据库相关文章,检索词“间充质干细胞,低氧培养,缺氧诱导因子”,共检索到文献1 120篇,最终纳入符合标准的文献48篇进行分析。 结果与结论：低氧预处理的骨髓间充质干细胞凋亡率将降低,其作用机制是通过上调血管内皮生长因子表达、抑制p53凋亡信号的表达以及促进抗凋亡蛋白Bcl-2的高表达来降低细胞凋亡。低氧下骨髓间充质干细胞通过抑制WNT信号通路和骨形态发生蛋白信号通路等通路,增加损伤组织的增殖能力;缺氧组织可诱导间充质干细胞迁移至缺氧区域,参与此过程的主要信号通路包括：血管内皮生长因子信号通路、基质细胞衍生因子1信号通路以及c-Met信号通路;低氧可提高间充质干细胞的黏附性,主要通过诱导细胞骨架蛋白以及细胞间黏附分子的高表达而实现;缺氧下间充质细胞增加Angiopoietin-1和血管内皮生长因子等因子的表达来促进细胞分化。     

Role of VEGF and tissue hypoxia in patterning of neural and vascular cells recruited to the embryonic heart

We hypothesized that oxygen gradients and hypoxia‐responsive signaling may play a role in the patterning of neural or vascular cells recruited to the developing heart. Endothelial progenitor and neural cells are recruited to and form branched structures adjacent to the relatively hypoxic outflow tract (OFT) myocardium from stages 27–32 (ED6.5–7.5) of chick development. As determined by whole mount confocal microscopy, the neural and vascular structures were not anatomically associated. Adenoviral delivery of a VEGF trap dramatically affected the remodeling of the vascular plexus into a coronary tree while neuronal branching was normal. Both neuronal and vascular branching was diminished in the hearts of embryos incubated under hyperoxic conditions. Quantitative analysis of the vascular defects using our recently developed VESGEN program demonstrated reduced small vessel branching and increased vessel diameters. We propose that vascular and neural patterning in the developing heart share dependence on tissue oxygen gradients but are not interdependent. Developmental Dynamics 238:2760–2769, 2009. © 2009 Wiley‐Liss, Inc.     

Targeted expression of GLI1 in the salivary glands results in an altered differentiation program and hyperplasia

Hedgehog (Hh) signaling is a regulator of salivary gland morphogenesis, but its role in postnatal glands has only recently begun to be addressed. To examine the effects of deregulated Hh signaling in the salivary gland, we expressed the Hh effector protein GLI1, in salivary epithelial cells using both cytokeratin 5 and mouse mammary tumor virus (MMTV) transgenic systems. Ectopic pathway activation resulted in restrained acinar differentiation, formation of cystic lesions, and prominent appearance of ductal structures. Moreover, induced expression of GLI1 aids the formation of hyperplastic lesions, which closely resemble GLI1-induced changes in murine skin and mammary glands, suggesting that GLI1 targets cells with similar characteristics in different tissues. Furthermore, GLI1-expressing salivary epithelial cells are actively dividing, and GLI1-induced lesions are proliferative, an incident accompanied by enhanced expression of the Hh target genes, cyclin D1, and Snail. GLI1-induced salivary lesions regress after transgene withdrawal and become histologically normalized. Taken together, our data reveal the ability of GLI1 to modulate salivary acinar differentiation and to promote proliferation of ductal epithelial cells.     

The function and expansion of the Patched- and Hedgehog-related homologs in C. elegans

The Hedgehog (Hh) signaling pathway promotes pattern formation and cell proliferation in Drosophila and vertebrates. Hh is a ligand that binds and represses the Patched (Ptc) receptor and thereby releases the latent activity of the multipass membrane protein Smoothened (Smo), which is essential for transducing the Hh signal. In Caenorhabditis elegans, the Hh signaling pathway has undergone considerable divergence. Surprisingly, obvious Smo and Hh homologs are absent whereas PTC, PTC-related (PTR), and a large family of nematode Hh-related (Hh-r) proteins are present. We find that the number of PTC-related and Hh-r proteins has expanded in C. elegans, and that this expansion occurred early in Nematoda. Moreover, the function of these proteins appears to be conserved in Caenorhabditis briggsae. Given our present understanding of the Hh signaling pathway, the absence of Hh and Smo raises many questions about the evolution and the function of the PTC, PTR, and Hh-r proteins in C. elegans. To gain insights into their roles, we performed a global survey of the phenotypes produced by RNA-mediated interference (RNAi). Our study reveals that these genes do not require Smo for activity and that they function in multiple aspects of C. elegans development, including molting, cytokinesis, growth, and pattern formation. Moreover, a subset of the PTC, PTR, and Hh-r proteins have the same RNAi phenotypes, indicating that they have the potential to participate in the same processes.