Hh-responsive Cells Research Articles

Saikosaponin B1 and Saikosaponin D inhibit tumor growth in medulloblastoma allograft mice via inhibiting the Hedgehog signaling pathway.

Medulloblastoma (MB), accounting for nearly 10% of all childhood brain tumors, are implicated with aberrant activation of the Hedgehog (Hh) signaling pathway. Saikosaponin B1 (SSB1) and Saikosaponin D (SSD), two bioactive constituents of Radix Bupleuri, are reported to have many biological activities including anticancer activities. In our work, we evaluated the inhibition of SSB1 and SSD on MB tumor growth in allograft mice and explored the underlying mechanisms. The associated biological activity was investigated in Shh Light II cells, an Hh-responsive fibroblast cell line, using the Dual-Glo® Luciferase Assay System. First, SSB1 (IC50, 241.8nM) and SSD (IC50, 168.7nM) inhibited GLI-luciferase activity in Shh Light II cells stimulated with ShhN CM, as well as Gli1 and Ptch1 mRNA expression. In addition, both compounds suppressed the Hh signaling activity provoked by smoothened agonist (SAG) or excessive Smoothened (SMO) expression. Meanwhile, SSB1 and SSD did not inhibit glioma-associated oncogene homolog (GLI) luciferase activity activated by abnormal expression of downstream molecules, suppressor of fuse (SUFU) knockdown or GLI2 overexpression. Consequently, SSB1 (30mg/kg, ip) and SSD (10mg/kg, ip) displayed excellent in vivo inhibitory activity in MB allografts, and the tumor growth inhibition ratios were approximately 50% and 70%, respectively. Our findings, thus, identify SSB1 and SSD significantly inhibit tumor growth in MB models by inhibiting the Hedgehog pathway through targeting SMO.

Loss of Primary Cilia Drives Switching from Hedgehog to Ras/MAPK Pathway in Resistant Basal Cell Carcinoma

Basal cell carcinomas (BCCs) rely on Hedgehog (HH) pathway growth signal amplification by the microtubule-based organelle, the primary cilium. Despite naive tumor responsiveness to Smoothened inhibitors (Smoi), resistance in advanced tumors remains common. Although the resistant BCCs usually maintain HH pathway activation, squamous cell carcinomas with Ras/MAPK pathway activation also arise, and the molecular basis of tumor type and pathway selection are still obscure. Here, we identify the primary cilium as a critical determinant controlling tumor pathway switching. Strikingly, Smoothened inhibitor-resistant BCCs have an increased mutational load in ciliome genes, resulting in reduced primary cilia and HH pathway activation compared with naive or Gorlin syndrome patient BCCs. Gene set enrichment analysis of resistant BCCs with a low HH pathway signature showed increased Ras/MAPK pathway activation. Tissue analysis confirmed an inverse relationship between primary cilia presence and Ras/MAPK activation, and primary cilia removal in BCCs potentiated Ras/MAPK pathway activation. Moreover, activating Ras in HH-responsive cell lines conferred resistance to both canonical (vismodegib) and noncanonical (atypical protein kinase C and MRTF inhibitors) HH pathway inhibitors and conferred sensitivity to MAPK inhibitors. Our results provide insights into BCC treatment and identify the primary cilium as an important lineage gatekeeper, preventing HH-to-Ras/MAPK pathway switching.

HH responsive cells contribute to vsmc accumulation following vascular injury

HH responsive cells contribute to vsmc accumulation following vascular injury

Curcumin regulates cell fate and metabolism by inhibiting hedgehog signaling in hepatic stellate cells

Accumulating evidence indicates that Hedgehog (Hh) signaling becomes activated in chronic liver injury and plays a role in the pathogenesis of hepatic fibrosis. Hepatic stellate cells (HSCs) are Hh-responsive cells and activation of the Hh pathway promotes transdifferentiation of HSCs into myofibroblasts. Targeting Hh signaling may be a novel therapeutic strategy for treatment of liver fibrosis. We previously reported that curcumin has potent antifibrotic effects in vivo and in vitro, but the underlying mechanisms are not fully elucidated. This study shows that curcumin downregulated Patched and Smoothened, two key elements in Hh signaling, but restored Hhip expression in rat liver with carbon tetrachloride-induced fibrosis and in cultured HSCs. Curcumin also halted the nuclear translocation, DNA binding, and transcription activity of Gli1. Moreover, the Hh signaling inhibitor cyclopamine, like curcumin, arrested the cell cycle, induced mitochondrial apoptosis, reduced fibrotic gene expression, restored lipid accumulation, and inhibited invasion and migration in HSCs. However, curcumin's effects on cell fate and fibrogenic properties of HSCs were abolished by the Hh pathway agonist SAG. Furthermore, curcumin and cyclopamine decreased intracellular levels of adenosine triphosphate and lactate, and inhibited the expression and/or function of several key molecules controlling glycolysis. However, SAG abrogated the curcumin effects on these parameters of glycolysis. Animal data also showed that curcumin downregulated glycolysis-regulatory proteins in rat fibrotic liver. These aggregated data therefore indicate that curcumin modulated cell fate and metabolism by disrupting the Hh pathway in HSCs, providing novel molecular insights into curcumin reduction of HSC activation.

Villification in the mouse: Bmp signals control intestinal villus patterning.

In the intestine, finger-like villi provide abundant surface area for nutrient absorption. During murine villus development, epithelial Hedgehog (Hh) signals promote aggregation of subepithelial mesenchymal clusters that drive villus emergence. Clusters arise first dorsally and proximally and spread over the entire intestine within 24 h, but the mechanism driving this pattern in the murine intestine is unknown. In chick, the driver of cluster pattern is tensile force from developing smooth muscle, which generates deep longitudinal epithelial folds that locally concentrate the Hh signal, promoting localized expression of cluster genes. By contrast, we show that in mouse, muscle-induced epithelial folding does not occur and artificial deformation of the epithelium does not determine the pattern of clusters or villi. In intestinal explants, modulation of Bmp signaling alters the spatial distribution of clusters and changes the pattern of emerging villi. Increasing Bmp signaling abolishes cluster formation, whereas inhibiting Bmp signaling leads to merged clusters. These dynamic changes in cluster pattern are faithfully simulated by a mathematical model of a Turing field in which an inhibitor of Bmp signaling acts as the Turing activator. In vivo, genetic interruption of Bmp signal reception in either epithelium or mesenchyme reveals that Bmp signaling in Hh-responsive mesenchymal cells controls cluster pattern. Thus, unlike in chick, the murine villus patterning system is independent of muscle-induced epithelial deformation. Rather, a complex cocktail of Bmps and Bmp signal modulators secreted from mesenchymal clusters determines the pattern of villi in a manner that mimics the spread of a self-organizing Turing field.

Enthesis fibrocartilage cells originate from a population of Hedgehog-responsive cells modulated by the loading environment.

Tendon attaches to bone across a specialized tissue called the enthesis. This tissue modulates the transfer of muscle forces between two materials, i.e. tendon and bone, with vastly different mechanical properties. The enthesis for many tendons consists of a mineralized graded fibrocartilage that develops postnatally, concurrent with epiphyseal mineralization. Although it is well described that the mineralization and development of functional maturity requires muscle loading, the biological factors that modulate enthesis development are poorly understood. By genetically demarcating cells expressing Gli1 in response to Hedgehog (Hh) signaling, we discovered a unique population of Hh-responsive cells in the developing murine enthesis that were distinct from tendon fibroblasts and epiphyseal chondrocytes. Lineage-tracing experiments revealed that the Gli1 lineage cells that originate in utero eventually populate the entire mature enthesis. Muscle paralysis increased the number of Hh-responsive cells in the enthesis, demonstrating that responsiveness to Hh is modulated in part by muscle loading. Ablation of the Hh-responsive cells during the first week of postnatal development resulted in a loss of mineralized fibrocartilage, with very little tissue remodeling 5 weeks after cell ablation. Conditional deletion of smoothened, a molecule necessary for responsiveness to Ihh, from the developing tendon and enthesis altered the differentiation of enthesis progenitor cells, resulting in significantly reduced fibrocartilage mineralization and decreased biomechanical function. Taken together, these results demonstrate that Hh signaling within developing enthesis fibrocartilage cells is required for enthesis formation.

Tu1651 Indian Hedgehog Is Required for Intestinal Adenoma Formation

Introduction: Activating mutations in the Hedgehog pathway are found in basal cell carcinomas and medulloblastomas. The role of Hedgehog signaling in intestinal tumorigenesis has not yet been clarified. Hedgehog is expressed by differentiated enterocytes and signals in a paracrine manner from the epithelium to the mesenchyme. Hedgehog controls mesenchymal factors such as Bone Morphogenetic Proteins and Activins which negatively regulate the proliferation of precursor cells. Since Indian Hedgehog (Ihh) is the major Hedgehog expressed in the intestinal epithelium we decided to study the potential role of Ihh signaling in intestinal adenoma formation.Methods: In order to study the effect of loss of Ihh signaling in sporadic tumorigenesis we conditionally deleted Ihh in adult mice in the intestinal epithelium using the Cyp1a1Cre promoter. These compound mice were crossed with conditional mutant Apc mice to generate Cyp1a1Cre-Ihh-Apc mice. At 4-7 weeks of age mice were intraperitoneally injected with 80 mg/kg β-naphthoflavone for 5 days. Cyp1a1Cre-IhhApc littermates served as controls. Four months after recombination, we sacrificed and analyzed the mice (n=15). Results: Ihh expression was upregulated in polyps of Cyp1a1CreIhh-Apc mice as assessed by in situ hybridization. Deletion of Ihh resulted in a marked reduction of 90.3% in the number of polyps (17.2 ± 13.65 polyps per mouse vs. 1.7 ± 1.5, P < 0.01). The average polyp size did not differ between groups. Neither did the number of proliferating or apoptotic cells in the polyps, as assessed by immunostaining for BrdU and cleaved caspase 3. Hh responsive cells in the adenomawere restricted to themesenchyme. In those adenomas that did develop in Ihh mutant mice, we observed a remarkable loss of α-sma/desmin double positive smooth muscle cells. COX2 is expressed early in adenoma to carcinoma transition and believed to play an important role in adenoma formation. Stromal cells are known to be a source of COX2. In accordance with this, examination of Cox2 expression by Q-PCR and immunostaining showed up regulation in polyps ofCyp1a1Cre-Ihh -Apc mice in compared to normal intestinal epithelium (P < 0.01, resp. P < 0.05). In contrast, Cox2 expression in the polyps of Cyp1a1Cre-Ihh-Apc mice was not significantly up regulated. Conclusion: Surprisingly, in contrast to its role as an anti-proliferative signal in the normal epithelium, Ihh acts as a tumor promoter. Our data show that Ihh signaling is increased during intestinal adenoma formation and as in the normal intestine Ihh signaling is exclusively from the epithelium to the mesenchyme. Loss of Ihh signaling is associated with major changes in the composition of the adenoma mesenchyme and decreased Cox2 expression, which significantly impairs adenoma formation.

Tu1653 Farnesoid X Receptor (FXR) Represses Matrix Metalloproteinase 7 (MMP7) Expression in Intestinal Epithelial Cells

Introduction: Activating mutations in the Hedgehog pathway are found in basal cell carcinomas and medulloblastomas. The role of Hedgehog signaling in intestinal tumorigenesis has not yet been clarified. Hedgehog is expressed by differentiated enterocytes and signals in a paracrine manner from the epithelium to the mesenchyme. Hedgehog controls mesenchymal factors such as Bone Morphogenetic Proteins and Activins which negatively regulate the proliferation of precursor cells. Since Indian Hedgehog (Ihh) is the major Hedgehog expressed in the intestinal epithelium we decided to study the potential role of Ihh signaling in intestinal adenoma formation.Methods: In order to study the effect of loss of Ihh signaling in sporadic tumorigenesis we conditionally deleted Ihh in adult mice in the intestinal epithelium using the Cyp1a1Cre promoter. These compound mice were crossed with conditional mutant Apc mice to generate Cyp1a1Cre-Ihh-Apc mice. At 4-7 weeks of age mice were intraperitoneally injected with 80 mg/kg β-naphthoflavone for 5 days. Cyp1a1Cre-IhhApc littermates served as controls. Four months after recombination, we sacrificed and analyzed the mice (n=15). Results: Ihh expression was upregulated in polyps of Cyp1a1CreIhh-Apc mice as assessed by in situ hybridization. Deletion of Ihh resulted in a marked reduction of 90.3% in the number of polyps (17.2 ± 13.65 polyps per mouse vs. 1.7 ± 1.5, P < 0.01). The average polyp size did not differ between groups. Neither did the number of proliferating or apoptotic cells in the polyps, as assessed by immunostaining for BrdU and cleaved caspase 3. Hh responsive cells in the adenomawere restricted to themesenchyme. In those adenomas that did develop in Ihh mutant mice, we observed a remarkable loss of α-sma/desmin double positive smooth muscle cells. COX2 is expressed early in adenoma to carcinoma transition and believed to play an important role in adenoma formation. Stromal cells are known to be a source of COX2. In accordance with this, examination of Cox2 expression by Q-PCR and immunostaining showed up regulation in polyps ofCyp1a1Cre-Ihh -Apc mice in compared to normal intestinal epithelium (P < 0.01, resp. P < 0.05). In contrast, Cox2 expression in the polyps of Cyp1a1Cre-Ihh-Apc mice was not significantly up regulated. Conclusion: Surprisingly, in contrast to its role as an anti-proliferative signal in the normal epithelium, Ihh acts as a tumor promoter. Our data show that Ihh signaling is increased during intestinal adenoma formation and as in the normal intestine Ihh signaling is exclusively from the epithelium to the mesenchyme. Loss of Ihh signaling is associated with major changes in the composition of the adenoma mesenchyme and decreased Cox2 expression, which significantly impairs adenoma formation.

Hedgehog (Hh) Reporter Activity Assay

This protocol is for testing responses of a candidate cell line/cell lines to Hh ligands or Hh pathway agonists stimulation. This protocol can also be adapted to screen small molecule libraries or biologics that contain activities to either increase or decrease Hh pathway responses. Canonical Hh signaling activity transcriptionally induces Hh target genes that contain consensus Gli binding element. Hh-responsive cells transiently or stably expressing luciferase protein under the regulation of the Gli promoter element can be used to report stimulus-dependent Hh-pathway activity., 该方案用于测试候选细胞系/细胞系对Hh配体或Hh通路激动剂刺激的反应。 该方案还可以适于筛选含有增加或降低Hh通路反应的活性的小分子文库或生物制剂。 规范Hh信号活动转录诱导含有共有Gli结合元件的Hh靶基因。 在Gli启动子元件的调节下瞬时或稳定表达荧光素酶蛋白的Hh反应性细胞可用于报告刺激依赖性Hh-途径活性。

Alcohol Activates the Hedgehog Pathway and Induces Related Procarcinogenic Processes in the Alcohol‐Preferring Rat Model of Hepatocarcinogenesis

Alcohol consumption promotes hepatocellular carcinoma (HCC). The responsible mechanisms are not well understood. Hepatocarcinogenesis increases with age and is enhanced by factors that impose a demand for liver regeneration. Because alcohol is hepatotoxic, habitual alcohol ingestion evokes a recurrent demand for hepatic regeneration. The alcohol-preferring (P) rat model mimics the level of alcohol consumption by humans who habitually abuse alcohol. Previously, we showed that habitual heavy alcohol ingestion amplified age-related hepatocarcinogenesis in P rats, with over 80% of alcohol-consuming P rats developing HCCs after 18months of alcohol exposure, compared with only 5% of water-drinking controls. Herein, we used quantitative real-time PCR and quantitative immunocytochemistry to compare liver tissues from alcohol-consuming P rats and water-fed P rat controls after 6, 12, or 18months of drinking. We aimed to identify potential mechanisms that might underlie the differences in liver cancer formation and hypothesized that chronic alcohol ingestion would activate Hedgehog (HH), a regenerative signaling pathway that is overactivated in HCC. Chronic alcohol ingestion amplified age-related degenerative changes in hepatocytes, but did not cause appreciable liver inflammation or fibrosis even after 18months of heavy drinking. HH signaling was also enhanced by alcohol exposure, as evidenced by increased levels of mRNAs encoding HH ligands, HH-regulated transcription factors, and HH target genes. Immunocytochemistry confirmed increased alcohol-related accumulation of HH ligand-producing cells and HH-responsive target cells. HH-related regenerative responses were also induced in alcohol-exposed rats. Three of these processes (i.e., deregulated progenitor expansion, the reverse Warburg effect, and epithelial-to-mesenchymal transitions) are known to promote cancer growth in other tissues. Alcohol-related changes in Hedgehog signaling and resultant deregulation of liver cell replacement might promote hepatocarcinogenesis.

The intrahepatic signalling niche of hedgehog is defined by primary cilia positive cells during chronic liver injury

In vertebrates, canonical Hedgehog (Hh) pathway activation requires Smoothened (SMO) translocation to the primary cilium (Pc), followed by a GLI-mediated transcriptional response. In addition, a similar gene regulation occurs in response to growth factors/cytokines, although independently of SMO signalling. The Hh pathway plays a critical role in liver fibrosis/regeneration, however, the mechanism of activation in chronic liver injury is poorly understood. This study aimed to characterise Hh pathway activation upon thioacetamide (TAA)-induced chronic liver injury in vivo by defining Hh-responsive cells, namely cells harbouring Pc and Pc-localised SMO. C57BL/6 mice (wild-type or Ptc1(+/-)) were TAA-treated. Liver injury and Hh ligand/pathway mRNA and protein expression were assessed in vivo. SMO/GLI manipulation and SMO-dependent/independent activation of GLI-mediated transcriptional response in Pc-positive (Pc(+)) cells were studied in vitro. In vivo, Hh activation was progressively induced following TAA. At the epithelial-mesenchymal interface, injured hepatocytes produced Hh ligands. Progenitors, myofibroblasts, leukocytes and hepatocytes were GLI2(+). Pc(+) cells increased following TAA, but only EpCAM(+)/GLI2(+) progenitors were Pc(+)/SMO(+). In vitro, SMO knockdown/hGli3-R overexpression reduced proliferation/viability in Pc(+) progenitors, whilst increased proliferation occurred with hGli1 overexpression. HGF induced GLI transcriptional activity independently of Pc/SMO. Ptc1(+/-) mice exhibited increased progenitor, myofibroblast and fibrosis responses. In chronic liver injury, Pc(+) progenitors receive Hh ligand signals and process it through Pc/SMO-dependent activation of GLI-mediated transcriptional response. Pc/SMO-independent GLI activation likely occurs in Pc(-)/GLI2(+) cells. Increased fibrosis in Hh gain-of-function mice likely occurs by primary progenitor expansion/proliferation and secondary fibrotic myofibroblast expansion, in close contact with progenitors.

Hedgehog pathway and pediatric nonalcoholic fatty liver disease

It is unclear why the histology of pediatric and adult nonalcoholic fatty liver disease (NAFLD) sometimes differs. In adults, severity of portal inflammation and fibrosis correlate with Hedgehog pathway activity. Hedgehog (Hh) signaling regulates organogenesis, but is silent in adult livers until injury reinduces Hh ligand production. During adolescence, liver development is completed and children's livers normally lose cells that produce and/or respond to Hh ligands. We postulated that fatty liver injury interferes with this process by increasing Hh ligand production, and theorized that hepatic responses to Hh ligands might differ among children according to age, gender, and/or puberty status. Using unstained liver biopsy slides from 56 children with NAFLD, we performed immunohistochemistry to assess Hh pathway activation and correlated the results with clinical information obtained at biopsy. Fibrosis stage generally correlated with Hh pathway activity, as demonstrated by the numbers of Hh-ligand-producing cells (P < 0.0001) and Hh-responsive (glioma-associated oncogene 2-positive [Gli2]) cells (P = 0.0013). The numbers of Gli2(+) cells also correlated with portal inflammation grade (P = 0.0012). Two distinct zonal patterns of Hh-ligand production, portal/periportal versus lobular, were observed. Higher portal/periportal Hh-ligand production was associated with male gender. Male gender and prepuberty were also associated with ductular proliferation (P < 0.05), increased numbers of portal Gli2(+) cells (P < 0.017) and portal fibrosis. The portal/periportal (progenitor) compartment of prepubescent male livers exhibits high Hh pathway activity. This may explain the unique histologic features of pediatric NAFLD because Hh signaling promotes the fibroductular response.

Correspondence

We agree with Dr. Coombes and Dr. Syn that Hedgehog (Hh) signaling may be an important factor influencing liver regeneration, and in particular the development of the ductular reaction and progenitor cell expansion. We have not particularly assessed the Hh signaling in patients with alcoholic hepatitis. Studies have shown that hedgehog-responsive progenitor cells proliferate in liver injury and accumulate in humans with alcoholic liver disease correlating with disease severity.1, 2 This observation is particularly interesting because Hh signaling has been shown to participate in progenitor cell activation and proliferation in adults and to induce hepatoblast proliferation during embryogenesis, but has to be shut off to allow hepatoblast commitment and differentiation.3 These findings suggest that Hh signaling may be implicated in the accumulation of progenitor cells in the liver, promoting proliferation and preventing differentiation. Although inhibition of Hh signaling seems to reduce progenitor cell response and liver regeneration in animal models of liver injury, the role of these cells in liver regeneration is not yet completely understood, and the contribution of Hh-responsive progenitor cells to newly generated hepatocytes has not been elucidated. Further studies are warranted to elucidate this question. The association of inflammation with progenitor cell proliferation has been described but has never been investigated in alcoholic hepatitis. We agree that inflammation and progenitor cell proliferation are key events in alcoholic hepatitis, thus its relationship should be specifically investigated. In our study it was not possible to investigate the inflammatory cell populations infiltrating the damaged liver, but the overall quantification of inflammatory cells by standard histological methods did not show a positive correlation with progenitor cell expansion and mortality. The results of our study raise the question whether liver progenitor cell expansion is a marker of liver injury in acute-on-chronic conditions or the result of an inefficient liver regeneration attempt. The assessment of liver progenitor cell expansion and differentiation in human samples together with mechanistic studies in relevant animal models of liver injury will help in understanding the role of progenitor cells in liver regeneration and disease outcome and its contribution to liver repair. Pau Sancho-Bru M.D.*, José Altamirano M.D.*, Ramon Bataller M.D.*, * Institut d'Investigacions Biomèdiques August Pi i Sunyer (IDIBAPS), Centro de Investigación Biomédica en Red de Enfermedades Hepáticas y Digestivas, Barcelona, Spain.

Identification of Hedgehog pathway responsive glioblastomas by isocitrate dehydrogenase mutation

The Hedgehog (Hh) pathway regulates the growth of a subset of adult gliomas and better definition of Hh-responsive subtypes could enhance the clinical utility of monitoring and targeting this pathway in patients. Somatic mutations of the isocitrate dehydrogenase (IDH) genes occur frequently in WHO grades II and III gliomas and WHO grade IV secondary glioblastomas. Hh pathway activation in WHO grades II and III gliomas suggests that it might also be operational in glioblastomas that developed from lower-grade lesions. To evaluate this possibility and to better define the molecular and histopathological glioma subtypes that are Hh-responsive, IDH genes were sequenced in adult glioma specimens assayed for an operant Hh pathway. The proportions of grades II–IV specimens with IDH mutations correlated with the proportions that expressed elevated levels of the Hh gene target PTCH1. Indices of an operational Hh pathway were measured in all primary cultures and xenografts derived from IDH-mutant glioma specimens, including IDH-mutant glioblastomas. In contrast, the Hh pathway was not operational in glioblastomas that lacked IDH mutation or history of antecedent lower-grade disease. IDH mutation is not required for an operant pathway however, as significant Hh pathway modulation was also measured in grade III gliomas with wild-type IDH sequences. These results indicate that the Hh pathway is operational in grades II and III gliomas and glioblastomas with molecular or histopathological evidence for evolvement from lower-grade gliomas. Lastly, these findings suggest that gliomas sharing this molecularly defined route of progression arise in Hh-responsive cell types.

Reply:

Reply: Balsano et al. studied Huh7.5 cells to evaluate the effects of Hedgehog (Hh) signaling on lipotoxicity. They concluded that Hh pathway inhibitors might be harmful in nonalcoholic fatty liver disease (NAFLD) because inhibiting Hh signaling in the malignant hepatocytes increased lipid accumulation. It is difficult to apply findings in cultured cancer cells to advance understanding of metabolism in nonmalignant hepatocytes because metabolism is fundamentally different in malignant and nonmalignant cells. Compared to benign hepatocytes, for example, malignant hepatocytes rely much more heavily on glycolysis (the Warburg effect).1 More important, nonmalignant hepatocytes are not Hh-responsive. Thus, hepatocytes in NAFLD livers would not be expected to respond directly to treatment with an Hh inhibitor. Rather, mature hepatocytes produce Hh ligands when injured. These hepatocyte-derived Hh ligands, in turn, initiate Hh signaling in neighboring stromal and progenitor cells. It is the Hh signaling in those nonhepatocyte cell types that drives hepatic fibrogenesis, recruitment of inflammatory cells, vascular remodeling, and progenitor accumulation.2 Thus, the desired “targets” for Hh inhibitors in NAFLD are nonparenchymal cells that participate in fibrogenic repair, not the hepatocytes per se. Finally, because Hh signaling inhibits lipogenesis in Hh-responsive cells,3 it is predictable that inhibiting Hh signaling would increase lipid accumulation in Huh7.5 cells. Triglyceride synthesis actually protects hepatocytes from toxic fatty acids.4 Thus, although not directly examined, Hh pathway inhibition might have improved Huh7.5 cell viability by enhancing lipogenesis. We hope that our response is helpful to the authors and thank them for their interest in our work.

A Role for Transcription Factor STAT3 Signaling in Oncogene Smoothened-driven Carcinogenesis

Activation of the Hedgehog (Hh) pathway is known to drive development of basal cell carcinoma and medulloblastomas and to associate with many other types of cancer, but the exact molecular mechanisms underlying the carcinogenesis process remain elusive. We discovered that skin tumors derived from epidermal expression of oncogenic Smo, SmoM2, have elevated levels of IL-11, IL-11Rα, and STAT3 phosphorylation at Tyr(705). The relevance of our data to human conditions was reflected by the fact that all human basal cell carcinomas examined have detectable STAT3 phosphorylation, mostly in keratinocytes. The functional relevance of STAT3 in Smo-mediated carcinogenesis was revealed by epidermal specific knockout of STAT3. We showed that removal of STAT3 from mouse epidermis dramatically reduced SmoM2-mediated cell proliferation, leading to a significant decrease in epidermal thickness and tumor development. We also observed a significant reduction of epidermal stem/progenitor cell population and cyclin D1 expression in mice with epidermis-specific knockout of STAT3. Our evidence indicates that STAT3 signaling activation may be mediated by the IL-11/IL-11Rα signaling axis. We showed that tumor development was reduced after induced expression of SmoM2 in IL-11Rα null mice. Similarly, neutralizing antibodies for IL-11 reduced the tumor size. In two Hh-responsive cell lines, ES14 and C3H10T1/2, we found that addition of Smo agonist purmorphamine is sufficient to induce STAT3 phosphorylation at Tyr(705), but this effect was abolished after IL-11Rα down-regulation by shRNAs. Taken together, our results support an important role of the IL-11Rα/STAT3 signaling axis for Hh signaling-mediated signaling and carcinogenesis.

Hedgehog-responsive mesenchymal clusters direct patterning and emergence of intestinal villi

In the adult intestine, an organized array of finger-like projections, called villi, provide an enormous epithelial surface area for absorptive function. Villi first emerge at embryonic day (E) 14.5 from a previously flat luminal surface. Here, we analyze the cell biology of villus formation and examine the role of paracrine epithelial Hedgehog (Hh) signals in this process. We find that, before villus emergence, tight clusters of Hh-responsive mesenchymal cells form just beneath the epithelium. Cluster formation is dynamic; clusters first form dorsally and anteriorly and spread circumferentially and posteriorly. Statistical analysis of cluster distribution reveals a patterned array; with time, new clusters form in spaces between existing clusters, promoting approximately four rounds of villus emergence by E18.5. Cells within mesenchymal clusters express Patched1 and Gli1, as well as Pdgfrα, a receptor previously shown to participate in villus development. BrdU-labeling experiments show that clusters form by migration and aggregation of Hh-responsive cells. Inhibition of Hh signaling prevents cluster formation and villus development, but does not prevent emergence of villi in areas where clusters have already formed. Conversely, increasing Hh signaling increases the size of villus clusters and results in exceptionally wide villi. We conclude that Hh signals dictate the initial aspects of the formation of each villus by controlling mesenchymal cluster aggregation and regulating cluster size.

The Path to Chemotaxis and Transcription Is Smoothened

The Hedgehog (Hh) family of secreted proteins governs the development of numerous tissues by regulating the activity of the Gli family of transcription factors. Emerging evidence shows that Hh also functions as a chemoattractant in several processes through a noncanonical pathway independent of Gli-mediated transcription. How Hh-responsive cells execute transcriptional versus chemotactic responses is a key issue. Data now suggest that altered subcellular localization of the transducer Smoothened, which functions in both the canonical and noncanonical pathways, is responsible for eliciting distinct Hh outputs.

The Hedgehog Signal Induced Modulation of Bone Morphogenetic Protein Signaling: An Essential Signaling Relay for Urinary Tract Morphogenesis

BackgroundCongenital diseases of the urinary tract are frequently observed in infants. Such diseases present a number of developmental anomalies such as hydroureter and hydronephrosis. Although some genetically-modified mouse models of growth factor signaling genes reproduce urinary phenotypes, the pathogenic mechanisms remain obscure. Previous studies suggest that a portion of the cells in the external genitalia and bladder are derived from peri-cloacal mesenchymal cells that receive Hedgehog (Hh) signaling in the early developmental stages. We hypothesized that defects in such progenitor cells, which give rise to urinary tract tissues, may be a cause of such diseases.Methodology/Principal FindingsTo elucidate the pathogenic mechanisms of upper urinary tract malformations, we analyzed a series of Sonic hedgehog (Shh) deficient mice. Shh−/− displayed hydroureter and hydronephrosis phenotypes and reduced expression of several developmental markers. In addition, we suggested that Shh modulation at an early embryonic stage is responsible for such phenotypes by analyzing the Shh conditional mutants. Tissue contribution assays of Hh-responsive cells revealed that peri-cloacal mesenchymal cells, which received Hh signal secreted from cloacal epithelium, could contribute to the ureteral mesenchyme. Gain- and loss-of-functional mutants for Hh signaling revealed a correlation between Hh signaling and Bone morphogenetic protein (Bmp) signaling. Finally, a conditional ablation of Bmp receptor type IA (BmprIA) gene was examined in Hh-responsive cell lineages. This system thus made it possible to analyze the primary functions of the growth factor signaling relay. The defective Hh-to-Bmp signaling relay resulted in severe urinary tract phenotypes with a decrease in the number of Hh-responsive cells.Conclusions/SignificanceThis study identified the essential embryonic stages for the pathogenesis of urinary tract phenotypes. These results suggested that Hh-responsive mesenchymal Bmp signaling maintains the population of peri-cloacal mesenchyme cells, which is essential for the development of the ureter and the upper urinary tract.

Hedgehog pathway activation parallels histologic severity of injury and fibrosis in human nonalcoholic fatty liver disease

The Hedgehog (HH)-signaling pathway mediates several processes that are deregulated in patients with metabolic syndrome (e.g., fat mass regulation, vascular/endothelial remodeling, liver injury and repair, and carcinogenesis). The severity of nonalcoholic fatty liver disease (NAFLD) and metabolic syndrome generally correlate. Therefore, we hypothesized that the level of HH-pathway activation would increase in parallel with the severity of liver damage in NAFLD. To assess potential correlations between known histologic and clinical predictors of advanced liver disease and HH-pathway activation, immunohistochemistry was performed on liver biopsies from a large, well-characterized cohort of NAFLD patients (n = 90) enrolled in the Nonalcoholic Steatohepatitis Clinical Research Network (NASH CRN) Database 1 study. Increased HH activity (evidenced by accumulation of HH-ligand-producing cells and HH-responsive target cells) strongly correlated with portal inflammation, ballooning, and fibrosis stage (each P < 0.0001), supporting a relationship between HH-pathway activation and liver damage. Pathway activity also correlated significantly with markers of liver repair, including numbers of hepatic progenitors and myofibroblastic cells (both P < 0.03). In addition, various clinical parameters that have been linked to histologically advanced NAFLD, including increased patient age (P < 0.005), body mass index (P < 0.002), waist circumference (P < 0.0007), homeostatic model assessment of insulin resistance (P < 0.0001), and hypertension (P < 0.02), correlated with hepatic HH activity. In NAFLD patients, the level of hepatic HH-pathway activity is highly correlated with the severity of liver damage and with metabolic syndrome parameters that are known to be predictive of advanced liver disease. Hence, deregulation of the HH-signaling network may contribute to the pathogenesis and sequelae of liver damage that develops with metabolic syndrome.