The hedgehog signalling pathway in tumorigenesis and development

Expression profiling of cancer-related genes in human keratinocytes following non-lethal ultraviolet B irradiation

Ultraviolet B irradiation initiates and promotes skin cancers, photo-aging, and immune suppression. In order to elucidate the effect of these processes at the level of gene expression, we used cDNA microarray technology to examine the effect of ultraviolet B irradiation on 588 cancer-related genes in human keratinocytes at 1, 6, and 24 h post-irradiation with a mildly cytotoxic dose of ultraviolet B (170 mJ/cm(2)). The viability of the irradiated keratinocytes was 75% at 24 h post-irradiation. Various cytokeratins and transcription factors were up-regulated within 1 h post-irradiation. After 6 h, expression of a variety of genes related to growth regulation (e.g. p21(WAF1), notch 4, and smoothened), apoptosis (e.g. caspase 10, hTRIP, and CRAF1), DNA repair (ERCC1, XRCC1), cytokines (e.g. IL-6, IL-13, TGF-beta, and endothelin 2), and cell adhesion (e.g. RhoE, and RhoGDI) were altered in human keratinocytes. These data suggest the changes in a cascade of gene expression in human keratinocytes occurring within 24 h after UVB exposure. Although the roles of these cellular genes after UVB-irradiation remain to be elucidated, microarray analysis may provide a new view of gene expression in epidermal keratinocytes following UVB exposure.

Genomic organization and embryonic expression of Suppressor of Fused, a candidate gene for the split-hand/split-foot malformation type 3

The genes for human and mouse Suppressor of Fused (SU(FU)/Su(Fu)) in the Hedgehog signaling pathway were characterized and found to contain 12 exons. Human SU(FU) localized on chromosome 10q24-25 between the markers D10S192 and AFM183XB12. We detected three additional SU(FU) isoforms, two of which have lost their ability to interact with the transcription factor GLI1. Expression analysis using whole mount in situ hybridization revealed strong expression of Su(Fu) in various mouse embryonic tissues. SU(FU) was considered a candidate gene for the split-hand/split-foot malformation type 3 (SHFM3). However, no alterations in the SU(FU) gene were found in SHFM3 patients.

Expression of the Sonic Hedgehog receptor "PATCHED" in basal cell carcinomas and odontogenic keratocysts

Basal cell carcinoma (BCC) is a common invasive skin lesion in Caucasians. Odontogenic keratocysts (OKs) are developmental, non-inflammatory oral cysts. They can be sporadic and/or multiple and are locally destructive. Basal cell naevus syndrome (BCNS) comprises both multiple BCCs and multiple OKs, in addition to several other systemic manifestations. The genetic defect underlying this autosomal dominant syndrome is a germ line mutation in the Sonic Hedgehog receptor PATCHED (PTCH) gene. For this study, a rabbit anti-peptide PTCH antiserum was produced. Immunohistochemistry procedures were performed using PTCH antibody and commercially produced GLI-1 antibody (downstream member in the hedgehog pathway) to stain 11 BCNS-OKs, eight sporadic OKs, two BCNS-BCCs, and six sporadic BCCs. Most of these lesions had been previously screened for PTCH mutation. Most BCCs (n=7) demonstrated moderate staining, with the heaviest staining in the outer palisading cell layer, except a BCNS-BCC which had mutation proximal to the sequence used for production of immunogenic peptide; this demonstrated only weak staining. Although moderate to heavy staining with PTCH antibody was demonstrated in the epithelium of both types of OK (n=19), a quite different pattern of staining of the basal cell layer was observed in the two patient groups. In BCNS, OK staining was heaviest in basal epithelial layers. In contrast, staining in non-BCNS odontogenic keratocysts was exclusively located in the superficial epithelial layers. Up-regulation of PTCH and GLI-1 protein was demonstrated in both BCCs and OKs. The pattern of PTCH expression matched the PTCH transcript pattern previously reported in BCCs and appeared sufficiently characteristic in OKs to allow differentiation between syndromic and non-syndromic cysts.

Sonic hedgehog regulates gastric gland morphogenesis in man and mouse

BACKGROUND & AIMS

Gastric epithelial renewal is an asymmetric process. A stem cell located halfway up the tubular unit gives rise to both a basal gland region and a luminal pit compartment, but the mechanisms responsible for the maintenance of this asymmetry are obscure. We investigated whether Sonic hedgehog (Shh), an established polarizing signal protein during development, is expressed and functional in the adult human and murine stomach.

METHODS

Expression of Shh and putative transcriptional targets was investigated using immunoblot and immunohistochemistry. Mice were treated with the Shh inhibitor cyclopamine and examined for expression levels of Shh targets and proliferation of gastric epithelial cells.

RESULTS

Shh was expressed in the stomach. In cyclopamine-treated mice, we observed decreased expression of HNF3beta, Islet (Isl)-1 and BMP4, 3 putative Shh target genes. Inhibition of Shh markedly enhanced gastric epithelial proliferation and affected the cell cycle of gastric epithelial gland cells, whereas pit cells remained unaffected.

CONCLUSIONS

Shh controls the expression of at least 3 factors important for epithelial differentiation and is a negative regulator of gastric gland cell proliferation. Shh is a candidate polarizing signal in the maintenance of gastric pit-gland asymmetry.

In silico mining of EST databases for novel pre-implantation embryo-specific zinc finger protein genes

Progress in the understanding of early mammalian embryo development has been severely hampered by scarcity of study materials. To circumvent such a constraint, we have developed a strategy that involves a combination of in silico mining of new genes from expressed sequence tags (EST) databases and rapid determination of expression profiles of the dbEST-derived genes using a PCR-based assay and a panel of cDNA libraries derived from different developmental stages and somatic tissues. We demonstrate that in a random sample of 49 independent dbEST-derived zinc finger protein genes mined from a mouse embryonic 2-cell cDNA library, more than three-quarters of these genes are novel. Examination of characteristics of the human orthologues derived from these mouse genes reveals that many of them are associated with human malignancies. Expression studies have further led to the identification of three novel genes that are exclusively expressed in mouse embryos before or up to the 8-cell stage. Two of the genes, designated 2czf45 and 2czf48 (2czf for 2-cell zinc finger), are zinc finger protein genes coding for a RBCC protein with a RFP domain and a protein with three C2H2 fingers, respectively. The third gene, designated 2cpoz56, codes for a protein with a POZ domain that is often associated with zinc finger proteins. These three genes are candidate genes for regulatory or other functions in early embryogenesis. The strategy described in this report should generally be applicable to rapid and large-scale mining of other classes of rare genes involved in other biological and pathological processes. Mol. Reprod. Dev. 59:249-255, 2001.

Hedgehog acts as a somatic stem cell factor in the Drosophila ovary

Secreted signalling molecules of the Hedgehog (Hh) family have many essential patterning roles during development of diverse organisms including Drosophila and humans. Although Hedgehog proteins most commonly affect cell fate, they can also stimulate cell proliferation. In humans several distinctive cancers, including basal-cell carcinoma, result from mutations that aberrantly activate Hh signal transduction. In Drosophila, Hh directly stimulates proliferation of ovarian somatic cells. Here we show that Hh acts specifically on stem cells in the Drosophila ovary. These cells cannot proliferate as stem cells in the absence of Hh signalling, whereas excessive Hh signalling produces supernumerary stem cells. We deduce that Hh is a stem-cell factor and suggest that human cancers due to excessive Hh signalling might result from aberrant expansion of stem cell pools.

Xmeis1, a protooncogene involved in specifying neural crest cell fate in Xenopus embryos

Meis1 (Myeloid Ecotropic viral Integration Site 1) is a homeobox gene that was originally isolated as a common site of viral integration in myeloid tumors of the BXH-2 recombinant inbred mice strain. We previously isolated a Xenopus homolog of Meis1 (Xmeis1). Here we show that Xmeis1 may play a significant role in neural crest development. In developing Xenopus embryos, Xmeis1 displays a broad expression pattern, but strong expression is observed in tissue of neural cell fate, such as midbrain, hindbrain, the dorsal portion of the neural tube, and neural crest derived branchial arches. In animal cap explants, overexpression of Xmeis1b, an alternatively spliced form of Xmeis1, induces expression of neural crest marker genes in the absence of mesoderm. Moreover, Xmeis1b induces XGli-3 and XZic3, pre-pattern genes involved at the earliest stages of neural crest development, and like these two genes, can induce ectopic pigmented cell masses when overexpressed in developing embryos. Misexpression of Xmeis1b also induces ectopic expression of neural crest markers along the antero-posterior axis of the neural tube in developing Xenopus embryos. In contrast, Xmeis1a, another splice variant, is much less effective at inducing these effects. These data suggest that Xmeis1b is involved in neural crest cell fate specification during embryogenesis, and can functionally intersect with the Gli/Zic signal transduction pathway.

Growth regulation by oncogenes--new insights from model organisms

A great deal of work has focused on how oncogenes regulate the cell cycle during normal development and in cancer, yet their roles in regulating cell growth have been largely unexplored. Recent work in several model organisms has demonstrated that homologs of several oncogenes regulate cell growth and has suggested that some of the effects of oncogenes on the cell cycle may be a result of growth promotion. These studies have also suggested how growth and cell-cycle progression may be coupled.

Senescence bypass screen identifies TBX2, which represses Cdkn2a (p19(ARF)) and is amplified in a subset of human breast cancers

To identify new immortalizing genes with potential roles in tumorigenesis, we performed a genetic screen aimed to bypass the rapid and tight senescence arrest of primary fibroblasts deficient for the oncogene Bmi1. We identified the T-box member TBX2 as a potent immortalizing gene that acts by downregulating Cdkn2a (p19(ARF)). TBX2 represses the Cdkn2a (p19(ARF)) promoter and attenuates E2F1, Myc or HRAS-mediated induction of Cdkn2a (p19(ARF)). We found TBX2 to be amplified in a subset of primary human breast cancers, indicating that it might contribute to breast cancer development.

Fibroblasts and dermal gene therapy: a minireview

This review highlights our current understanding of the biology of, survival of, and transgene expression by genetically modified fibroblasts (GMFb) carrying stably integrated transgenes in vivo. Experimental data demonstrate that three elements will enhance expression by and survival of GMFb in vivo: a matrix scaffolding to take the place of the existing dermis, the presence of elements of the extracellular matrix in the construct used to move GMFb to the in vivo setting, and the utilization of immortalized fibroblasts to carry the transgenes. Although moving GMFb to an in vivo setting is an invasive procedure, there are a number of clinical settings where GMFb appear to be the suitable cell for gene therapy.

Erythroid differentiation in vitro is blocked by cyclopamine, an inhibitor of hedgehog signaling

Adult hematopoietic differentiation is a developmental process that employs many of the same molecular mechanisms as embryogenesis. To explore the possibility that hedgehog signaling is involved in the control of hematopoietic differentiation, we screened a panel of human leukemia cell lines for the expression of Patched1 and Smoothened, the receptor and coreceptor for hedgehog ligands. Expression was found in multiple cell lines, and Patched1 expression was detected in normal marrow. Induction of myeloid differentiation in cell lines downregulated expression of both genes. When normal marrow mononuclear cells were grown in semisolid medium in the presence of 10 microM cyclopamine, development of colonies of granulocytic/monocytic lineage was unaffected in terms of both number and morphology. The number of erythroid colonies, however, was significantly reduced (P < 0.01). Furthermore, hemoglobinization was substantially delayed relative to controls in those erythroid colonies that did form. Incubation of hematopoietic progenitors with Shh-N and GM-CSF resulted in increased granulocyte/monocyte colonies (P < 0.01); the increase was blocked by cyclopamine. Incubation of hematopoietic progenitors with Shh-N and stem cell factor resulted in larger erythroid colonies. These results suggest that elements of the hedgehog signaling pathway are involved in the control of hematopoietic differentiation.