Enhancer of zeste homolog 2 (EZH2) is a mammalian histone methyltransferase that contributes to the epigenetic silencing of target genes and that regulates the survival and metastasis of cancer cells. EZH2 is overexpressed in aggressive solid tumors by mechanisms that remain unclear. Here, we show that the expression and function of EZH2 in cancer cell lines is inhibited by microRNA-101 (miR-101). Analysis of human prostate tumors revealed that miR-101 expression decreases during cancer progression, paralleling an increase in EZH2 expression. One or both of the two genomic loci encoding miR-101 were somatically lost in 37.5% of clinically localized prostate cancers (6/16) and 66.7% of metastatic disease (22/33). We propose that genomic loss of miR-101 in cancer leads to overexpression of EZH2 and concomitant dysregulation of epigenetic pathways, resulting in cancer progression.

Published Online November 13, 2008, Science DOI: 10.1126/science.1165395

The H19 locus belongs to a cluster of imprinted genes that is linked to the human Beckwith-Wiedemann syndrome. The expression of H19 and its closely associated IGF2 gene is frequently deregulated in some human tumors, such as Wilms' tumors. In these cases, biallelic IGF2 expression and lack of expression of H19 are associated with hypermethylation of the imprinting center of this locus. These observations and others have suggested a potential tumor suppressor effect of the H19 locus. Some studies have also suggested that H19 is an oncogene, based on tissue culture systems. We show, using in vivo murine models of tumorigenesis, that the H19 locus controls the size of experimental teratocarcinomas, the number of polyps in the Apc murine model of colorectal cancer and the timing of appearance of SV40-induced hepatocarcinomas. The H19 locus thus clearly displays a tumor suppressor effect in mice.

PNAS 2008 105:12417-12422; published ahead of print August 21, 2008, doi:10.1073/pnas.0801540105

Purhonen et al. (1) have refuted the data published in >50 reports (2, 3), neglecting to quote key articles or utilize relevant models, and have drawn unsubstantiated conclusions about the contribution of endothelial progenitor cells (EPCs) to tumor angiogenesis that are not supported by their nonquantitative data and superficially executed experiments. Their study (1) is flawed in experimental design and data interpretation. For example, they do not cite their own publication demonstrating the existence of VEGFR2+ EPCs (4) and neglect mentioning clinical validation (5, 6) and acknowledging mouse genetic models (2, 3), which provide convincing evidence for functional incorporation of EPCs into neovessels. Every figure lacks stereoconfocal-microscopic quantification of vessels that are presented as poorly defined longitudinal–linear streaks. Plasma VEGF-A levels were not measured in vivo in mice treated with VEGF-A, questioning their low level of VEGFR2+ EPC detection (3). Indeed, their FACS analysis is inaccurate because of (i) unconvincing CD31/VE-cadherin/VEGFR2 expression detected on MS-1 endothelium used as positive control and (ii) failure to show long-term marrow engraftment of donor-derived hematopoietic and authentic VEGFR2+LacZ+ colony-forming EPCs. APCmin mice develop only obstructive adenomas, rather than adenocarcinomas; therefore, it is an inappropriate model to study EPC incorporation, as Spring et al. (7) (not quoted) demonstrate that EPCs do not contribute to adenomas but contribute only to carcinomas/metastatic tumors. In the parabiotic model, wild-type EPCs compete with GPF+ EPCs, which underestimates EPC recruitment. Finally, study of 6-month-old VEGF-A-loaded Matrigel plugs in mice is impossible because Matrigel plugs are degraded within 2 months, particularly when VEGF-A by itself does not induce neoangiogenesis. No quantification of patent vessels in Matrigel plugs was provided. This article fails to disprove the established role of EPCs in supporting neoangiogenesis in certain tumors (3, 5) and metastatic transition (2)

PNAS 2008 105:E54; published ahead of print August 20, 2008, doi:10.1073/pnas.0804876105

The factors that guide DNA hypermethylation in cancer are poorly understood. We identified the candidate tumor-suppressor gene, RIL, as a frequent methylation target in cancer. Here, we report on a 12-bp polymorphic sequence around its transcription start site that creates a long allele. Methylation analysis showed that, in aging colon, colon cancer, and leukemias, the short allele had 2.1–3.1-fold higher methylation than the long allele (P<0.001). Short and long alleles had similar expression levels in EBV-transformed cell lines. Electrophorectic mobility shift assay showed that the inserted region of the long allele binds Sp1 and Sp3 transcription factors. Transfection of RIL allele-specific transgenes showed no effects of the additional Sp1 site on transcription early on, but methylation-seeded constructs showed gradually decreasing transcription from the short allele with eventual spreading of de novo methylation. By contrast, the long allele showed stable expression over time as measured by luciferase, and ~2–3-fold lower levels of methylation by bisulfite sequencing (P<0.001), suggesting that the polymorphic Sp1 site protects against time-dependent silencing. Our finding demonstrates that in some genes, hypermethylation in cancer is dictated by protein-DNA interactions at the promoters and provides a novel mechanism by which genetic polymorphisms can influence an epigenetic state.

PLoS Genet 4(8): e1000162. doi:10.1371/journal.pgen.1000162

On activation by receptors, the ubiquitously expressed class IA isoforms (p110alpha and p110beta) of phosphatidylinositol-3-OH kinase (PI(3)K) generate lipid second messengers, which initiate multiple signal transduction cascades1, 2, 3, 4, 5. Recent studies have demonstrated specific functions for p110alpha in growth factor and insulin signalling6, 7, 8. To probe for distinct functions of p110beta, we constructed conditional knockout mice. Here we show that ablation of p110beta in the livers of the resulting mice leads to impaired insulin sensitivity and glucose homeostasis, while having little effect on phosphorylation of Akt, suggesting the involvement of a kinase-independent role of p110beta in insulin metabolic action. Using established mouse embryonic fibroblasts, we found that removal of p110beta also had little effect on Akt phosphorylation in response to stimulation by insulin and epidermal growth factor, but resulted in retarded cell proliferation. Reconstitution of p110beta-null cells with a wild-type or kinase-dead allele of p110beta demonstrated that p110beta possesses kinase-independent functions in regulating cell proliferation and trafficking. However, the kinase activity of p110beta was required for G-protein-coupled receptor signalling triggered by lysophosphatidic acid and had a function in oncogenic transformation. Most strikingly, in an animal model of prostate tumour formation induced by Pten loss, ablation of p110beta (also known as Pik3cb), but not that of p110alpha (also known as Pik3ca), impeded tumorigenesis with a concomitant diminution of Akt phosphorylation. Taken together, our findings demonstrate both kinase-dependent and kinase-independent functions for p110beta, and strongly indicate the kinase-dependent functions of p110beta as a promising target in cancer therapy.

Nature 454, 776-779 (7 August 2008) | doi:10.1038/nature07091; Received 27 February 2008; Accepted 15 May 2008; Published online 25 June 2008 Lesen Sie mehr...