Imiquimod directly inhibits Hedgehog signalling by stimulating adenosine receptor/protein kinase A-mediated GLI phosphorylation.

Imiquimod (IMQ), a nucleoside analogue of the imidazoquinoline family, is used in the topical treatment of basal cell carcinoma (BCC) and other skin diseases. It is reported to be a TLR7 and TLR8 agonist and, as such, initiates a Th1 immune response by activating sentinel cells in the vicinity of the tumour. BCC is a hedgehog (HH)-driven malignancy with oncogenic glioma-associated oncogene (GLI) signalling activated in a ligand-independent manner. Here we show that IMQ can also directly repress HH signalling by negatively modulating GLI activity in BCC and medulloblastoma cells. Further, we provide evidence that the repressive effect of IMQ on HH signalling is not dependent on TLR/MYD88 signalling. Our results suggest a mechanism for IMQ engaging adenosine receptors (ADORAs) to control GLI signalling. Pharmacological activation of ADORA with either an ADORA agonist or IMQ resulted in a protein kinase A (PKA)-mediated GLI phosphorylation and reduction in GLI activator levels. The activation of PKA and HH pathway target gene downregulation in response to IMQ were abrogated by ADORA inhibition. Furthermore, activated Smoothened signalling, which positively signals to GLI transcription factors, could be effectively counteracted by IMQ. These results reveal a previously unknown mode of action of IMQ in the treatment of BCC and also suggest a role for ADORAs in the regulation of oncogenic HH signalling.

Cooperation between GLI and JUN enhances transcription of JUN and selected GLI target genes.

Sustained Hedgehog (HH) signaling is implicated in basal cell carcinoma of the skin and other types of cancer. Here we show that GLI1 and GLI2, the main transcriptional activators of the HH pathway, directly regulate expression of the activator protein 1 (AP-1) family member JUN, a transcription factor controlling keratinocyte proliferation and skin homeostasis. Activation of the JUN promoter by GLI is dependent on a GLI-binding site and the AP-1 sites known to be involved in self-activation of JUN. Transcription of JUN is greatly enhanced in the presence of GLI and requires activated JUN protein. GLI2act is a more potent activator than GLI1 in these experiments and physical interaction with phosphorylated JUN was only detected for GLI2act. The synergistic effect of GLI and JUN extends to the activation of further GLI target genes as shown by shRNA-mediated knockdown of JUN in human keratinocytes. Some of these cooperatively activated genes are involved in cell-cycle progression, which is consistent with a significant reduction of the proliferative potential of GLI in the absence of JUN. These results suggest a novel connection between HH/GLI pathway activity and JUN, which may contribute to the oncogenic activity of HH/GLI signaling in skin.

Analysis of gene expression using high-density and IFN-gamma-specific low-density cDNA arrays.

The combination of high and low density cDNA filter array technology potentially permits both the identification of subsets of induced genes and convenient and rapid multisample expression profiling of such subsets under a variety of conditions. The JAK/STAT1 pathway for IFN-gamma signaling in human cells has been well characterized, but the extent and importance of additional pathways remain to be established. Here, using high-density filter arrays of the RZPD UniGene set, we identified 18 novel IFN-gamma-inducible genes. Expression profiling was carried out using low-density arrays representing both novel and known IFN-gamma-inducible genes. Initial experiments failed to detect evidence for any novel non-JAK-dependent pathways in cells expressing a kinase-dead JAK2. The data, however, validated the potential of the combined methods in establishing rapid and convenient expression profiling of several hundred genes in response to any ligand of choice.

Characterization of a widely expressed gene (LUC7-LIKE; LUC7L) defining the centromeric boundary of the human alpha-globin domain.

We have identified the first gene lying on the centromeric side of the alpha-globin gene cluster on human 16p13.3. The gene, called 16pHQG;16 (HGMW-approved symbol LUC7L), is widely transcribed and lies in the opposite orientation with respect to the alpha-globin genes. This gene may represent a mammalian heterochromatic gene, encoding a putative RNA-binding protein similar to the yeast Luc7p subunit of the U1 snRNP splicing complex that is normally required for 5' splice site selection. To examine the role of the 16pHQG;16 gene in delimiting the extent of the alpha-globin regulatory domain, we mapped its mouse orthologue, which we found to lie on mouse chromosome 17, separated from the mouse alpha-cluster on chromosome 11. Establishing the full extent of the human 16pHQG;16 gene has allowed us to define the centromeric limit of the region of conserved synteny around the human alpha-globin cluster to within an 8-kb segment of chromosome 16.

Comparative genome analysis delimits a chromosomal domain and identifies key regulatory elements in the alpha globin cluster.

We have cloned, sequenced and annotated segments of DNA spanning the mouse, chicken and pufferfish alpha globin gene clusters and compared them with the corresponding region in man. This has defined a small segment ( approximately 135-155 kb) of synteny and conserved gene order, which may contain all of the elements required to fully regulate alpha globin gene expression from its natural chromosomal environment. Comparing human and mouse sequences using previously described methods failed to identify the known regulatory elements. However, refining these methods by ranking identity scores of non-coding sequences, we found conserved sequences including the previously characterized alpha globin major regulatory element. In chicken and pufferfish, regions that may correspond to this element were found by analysing the distribution of transcription factor binding sites. Regions identified in this way act as strong enhancer elements in expression assays. In addition to delimiting the alpha globin chromosomal domain, this study has enabled us to develop a more sensitive and accurate routine for identifying regulatory elements in the human genome.

Expression and characterization of soluble and membrane-bound human nucleoside triphosphate diphosphohydrolase 6 (CD39L2).

Ecto-nucleoside-triphosphate diphosphohydrolase-6 (eNTPDase6(1), also known as CD39L2) cDNA was expressed in mammalian COS-1 cells and characterized using nucleotidase assays as well as size exclusion, anion exchange, and cation exchange chromatography. The deduced amino acid sequence of eNTPDase6 is more homologous with the soluble E-type ATPase, eNTPDase5, than other E-type ATPases, suggesting it may also be soluble. To test this possibility, both the cell membranes and the growth media from eNTPDase6-transfected COS-1 cells were assayed for nucleotidase activities. Activity was found in both the membranes and the media. Soluble eNTPDase6 preferentially exhibits nucleoside diphosphatase activity, which is dependent on the presence of divalent cations. Western blot analysis of eNTPDase6 treated with PNGase-F indicated both soluble and membrane-bound forms are glycosylated. However, unlike some membrane-bound ecto-nucleotidases, the eNTPDase6 activity was not specifically inhibited by deglycosylation with peptide N-glycosidase F. Soluble eNTPDase6 hydrolyzed nucleoside triphosphates poorly and nucleoside monophosphates not at all. Analysis of the relative rates of hydrolysis of nucleoside diphosphates (GDP = IDP > UDP > CDP >> ADP) suggests that soluble eNTPDase6 is a diphosphatase most likely not involved in regulation of ADP levels important for circulatory hemostasis.

Cloning, mapping and expression of UBL3, a novel ubiquitin-like gene.

A novel Drosophila melanogaster gene UBL3 was characterized and shown to be highly conserved in man and Caenorhabditis elegans (C. elegans). The human and mouse homologues were cloned and sequenced. UBL3 is a ubiquitin-like protein of unknown function with no conserved homologues in yeast. Mapping of the human and mouse UBL3 genes places them within a region of shared gene order between human and mouse chromosomes on human chromosome 13q12-13 and telomeric mouse chromosome 5 (MMU5).

PHF2, a novel PHD finger gene located on human chromosome 9q22.

We have isolated and characterized a novel PHD finger gene, PHF2, which maps to human Chromosome (Chr) 9q22 close to D9S196. Its mouse homolog was also characterized and mapped to the syntenic region on mouse Chr 13. The predicted human and mouse proteins are 98% identical and contain a PHD finger domain, eight possible nuclear localization signals, two potential PEST sequences, and a novel conserved hydrophobic domain. Northern analysis shows widespread expression of PHF2 in adult tissues, while in situ hybridization on mouse embryos reveals staining in the neural tube and dorsal root ganglia significantly above a ubiquitous low level expression signal. From its expression pattern and its chromosomal localization, PHF2 is a candidate gene for hereditary sensory neuropathy type I, HSN1.

The CD39-like gene family: identification of three new human members (CD39L2, CD39L3, and CD39L4), their murine homologues, and a member of the gene family from Drosophila melanogaster.

The human lymphoid cell activation antigen CD39 is a known E-type apyrase that hydrolyzes extracellular ATP and ADP, a function important in homotypic adhesion, platelet aggregation, and removal by activated lymphocytes of the lytic effect of ATP. The recently identified putative rat homologue of CD39L1 has been shown to have E-type ecto-ATPase activity, by hydrolyzing extracellular ATP. We have characterized three novel CD39-like transcripts, CD39L2, CD39L3, and CD39L4, which share extensive amino acid homology with other nucleotide triphosphatases in vertebrates, invertebrates, and plants, suggesting that these genes also encode proteins with ecto-nucleotidase activity. Isolation and sequencing of full-length cDNA clones for each gene identified putative proteins of 485, 529, and 429 amino acids. The expression pattern of all five human members of the gene family was analyzed. CD39L2, CD39L3, and CD39L4 were mapped on the human genome, and the murine homologues identified with the putative map locations were assigned on the basis of regions of conserved gene order between human and mouse chromosomes. The map location of mcd39l4 places the gene within a region associated with audiogenic seizure susceptibility in mouse. This disorder is characterized by convulsions induced by loud high-frequency sound and has been shown to be associated with increased nucleotide triphosphatase activity.

The human homologue of the ninjurin gene maps to the candidate region of hereditary sensory neuropathy type I (HSNI).

The human ninjurin gene was isolated from a cDNA library enriched for transcripts from band 9q22. A 1.2-kb message was detected for ninjurin in all human tissues studied. The full-length sequence codes for a putative 152-amino-acid protein with 89% identity to the rat ninjurin protein. The mouse homologue was isolated and showed 98% amino acid identity to the rat protein. Mapping by FISH localized mouse ninjurin to mouse chromosome 13, a region that shows synteny with human chromosome 9q22. Genomic characterization of the human gene revealed four exons covering less than 10 kb. The map position of the human gene is between the genetic markers D9S196 and D9S197 on human chromosome band 9q22. This places the gene within the candidate regions for the degenerative neurological disorder hereditary sensory neuropathy type I and the cancer predisposition syndrome multiple self-healing squamous epitheliomata.

Gorlin syndrome: identification of 4 novel germ-line mutations of the human patched (PTCH) gene. Mutations in brief no. 137. Online.

PTCH, the human homologue of the Drosophila segment polarity gene, patched, has been identified as the gene responsible for Gorlin or nevoid basal cell carcinoma syndrome (NBCCS). We report here the characterization of four novel mutations in the human PTCH gene in germ-line DNA from Gorlin patients. All mutations lead to truncation of the predicted protein product. Also included is a list of putative polymorphic nucleotide postions in the sequence covered by published primers.

Germline mutations of the CDKN2 gene in UK melanoma families.

Germline mutations in CDKN2 on chromosome 9p21, which codes for the cyclin D kinase inhibitor p16, and more rarely, mutations in the gene coding for CDK4, the protein to which p16 binds, underlie susceptibility in some melanoma families. We have sequenced all exons of CDKN2 and analysed the CDK4 gene for mutations in 27 UK families showing evidence of predisposition to melanoma. Five different germline mutations in CDKN2 were found in six families. Three of the mutations (Met53Ile, Arg24Pro and 23ins24) have been reported previously. We have identified two novel CDKN2 mutations (88delG and Ala118Thr) which are likely to be associated with the development of melanoma, because of their co-segregation with the disease and their likely functional effect on the CDKN2 protein. In binding assays the protein expressed from the previously described mutation, Met53Ile, did not bind to CDK4/CDK6, confirming its role as a causal mutation in the development of melanoma. Ala118Thr appeared to be functional in this assay. Arg24Pro appeared to bind to CDK6, but not to CDK4. No mutations were detected in exon 2 of CDK4, suggesting that causal mutations in this gene are uncommon. The penetrance of these mutant CDKN2 genes is not yet established, nor is the risk of non-melanoma cancer to gene carriers.

Cloning and mapping of a human and mouse gene with homology to ecto-ATPase genes.

The human CD39-like-1 gene (CD39L1) was isolated from a selected cDNA library enriched for transcripts from regions of human Chromosome (Chr) 9q. Database searches with sequences of one group of clones from the selected cDNA library showed strong amino acid homology to the lymphoid cell activation antigen CD39, an ecto-apyrase gene from human and mouse. The full-length sequence for CD39L1 identified a putative 472 amino acid protein with greater than 60% identity with the chicken muscle ecto-ATPase protein, as well as homology to a number of other known ecto-ATPases and ecto-apyrases from rat, garden pea, yeast, and Toxoplasma gondii. A high level of amino acid identity suggests that CD39L1 is closely related to the chicken muscle ecto-ATPase. The presence of the human ABC2 gene on an overlapping cosmid and hybridizations to somatic cell mapping panels suggest that CD39L1 maps to human Chr 9q34. A mouse homolog was isolated (showing greater than 78% nucleotide sequence identity) and mapped by FISH to mouse Chr 2, the syntenic region of human 9q34. The genomic structure of CD39L1 reveals 9 exons covering less than 7 kb.

The mouse homolog of PKD1: sequence analysis and alternative splicing.

We have cloned and sequenced the mouse transcript homologous to human polycystic kidney disease 1 (PKD1). The predicted protein is 79% identical to human PKD1 and shows the presence of most of the domains identified in the human sequence. Since the mouse homolog is transcribed from a unique gene and there are no transcribed, closely related copies as has been observed for human PKD1, we have been able to investigate alternative splicing of the transcript. At the junction of exons 12 and 13, several different splicing variants lead to a predicted protein that would be secreted. These forms are predominantly found in newborn brain, while in kidney the transcript homologous to the previously described human RNA predominates.

FKHL15, a new human member of the forkhead gene family located on chromosome 9q22.

FKHL15 was isolated from a cDNA library enriched for transcripts from 9q22. Isolation and sequencing of a 3.5-kb cDNA clone identified a putative 376-amino-acid protein with greater than 80% homology over a 100-amino-acid stretch to the forkhead DNA-binding domain. The FKHL15 gene contains a region rich in alanine residues, frequently associated with transcriptional repression. The forkhead genes are believed to play important roles in development and differentiation in many different organisms and have also been implicated in the development of some tumors. The map position of FKHL15 on 9q22 places the gene within the candidate regions for the cancer predisposition syndrome multiple self-healing squamous epitheliomata and the degenerative neurological disorder hereditary sensory neuropathy type I. This is a region frequently lost in squamous cell cancer.

Distribution and developmentally regulated expression of murine polycystin.

PKD1, the gene that is mutated in approximately 85% of autosomal dominant polycystic kidney disease (ADPKD) cases in humans, has recently been identified (Eur. PKD Consortium. Cell 77: 881-894, 1994; also, erratum in Cell 78: 1994). The longest open-reading frame of PKD1 encodes polycystin, a novel approximately 460-kDa protein that contains a series of NH2-terminal adhesive domains (J. Hughes, C. J. Ward, B. Peral, R. Aspinwall, K. Clark, J. San Millan, V. Gamble, and P. C. Harris. Nat. Genet. 10: 151-160, 1995; and Int. PKD Consortium. Cell 81: 289-298, 1995) and several putative transmembrane segments. To extend studies of polycystin to an experimentally accessible animal, we have isolated a cDNA clone encoding the 3' end of Pkd1, the mouse homologue of PKD1, and raised a specific antibody to recombinant murine polycystin. This antibody was used to determine the subcellular localization and tissue distribution of the protein by Western analysis and immunocytochemistry. In the mouse, polycystin is an approximately 400-kDa molecule that is predominantly found in membrane fractions of tissue and cell extracts. It is expressed in many tissues including kidney, liver, pancreas, heart, intestine, lung, and brain. Renal expression, which is confined to tubular epithelia, is highest in late fetal and early neonatal life and drops 20-fold by the third postnatal week, maintaining this level into adulthood. Thus the temporal profile of polycystin expression coincides with kidney tubule differentiation and maturation.

The translocation t(8;16)(p11;p13) of acute myeloid leukaemia fuses a putative acetyltransferase to the CREB-binding protein.

The recurrent translocation t(8;16)(p11;p13) is a cytogenetic hallmark for the M4/M5 subtype of acute myeloid leukaemia. Here we identify the breakpoint-associated genes. Positional cloning on chromosome 16 implicates the CREB-binding protein (CBP), a transcriptional adaptor/coactivator protein. At the chromosome 8 breakpoint we identify a novel gene, MOZ, which encodes a 2,004-amino-acid protein characterized by two C4HC3 zinc fingers and a single C2HC zinc finger in conjunction with a putative acetyltransferase signature. In-frame MOZ-CBP fusion transcripts combine the MOZ finger motifs and putative acetyltransferase domain with a largely intact CBP. We suggest that MOZ may represent a chromatin-associated acetyltransferase, and raise the possibility that a dominant MOZ-CBP fusion protein could mediate leukaemogenesis via aberrant chromatin acetylation.