The discovery of translocations that involve one of the genes of the ETS family (ERG, ETV1, ETV4 and ETV5) has been a major advance in understanding the molecular basis of prostate cancer (PC). Each one of these translocations results in deregulated expression of one of the ETS proteins. Here, we focus on the mechanism whereby overexpression of the ETV4 gene mediates oncogenesis in the prostate. By siRNA technology, we show that ETV4 inhibition in the PC3 cancer cell line reduces not only cell mobility and anchorage-independent growth, but also cell proliferation, cell cycle progression and tumor growth in a xenograft model. Conversely, ETV4 overexpression in the nonmalignant human prostate cell line (RWPE) increases anchorage-independent growth, cell mobility and cell proliferation, which is probably mediated by downregulation of p21, producing accelerated progression through the cell cycle. ETV4 overexpression is associated with changes in the pattern of E-cadherin and N-cadherin expression; the cells also become spindle-shaped, and these changes are characteristic of the so-called epithelial to mesenchymal transition (EMT). In RWPE cells overexpressing ETV4 EMT results from a marked increase in EMT-specific transcription factors such as TWIST1, SLUG1, ZEB1 and ZEB2. Thus, whereas ETV4 shares with the other ETS proteins (ERG, ETV5 and ETV1) a major role in invasiveness and cell migration, it emerges as unique in that it increases at the same time also the rate of proliferation of PC cells. Considering the wide spectrum in the clinical course of patients with PC, it may be highly relevant that ETV4 is capable of inducing most and perhaps all of the features that make a tumor aggressive.
Background: ETV4 is one of the ETS proteins overexpressed in prostate cancer (PC) as a result of recurrent chromosomal translocations. In human prostate cell lines, ETV4 promotes migration, invasion, and proliferation; however, its role in PC has been unclear. In this study, we have explored the effects of ETV4 expression in the prostate in a novel transgenic mouse model. Methods: We have created a mouse model with prostate-specific expression of ETV4 (ETV4 mice). By histochemical and molecular analysis, we have investigated in these engineered mice the expression of p21, p27, and p53. The implications of our in vivo findings have been further investigated in human cells lines by chromatin-immunoprecipitation (ChIP) and luciferase assays. Results: ETV4 mice, from two independent transgenic lines, have increased cell proliferation in their prostate and two-thirds of them, by the age of 10 months, developed mouse prostatic intraepithelial neoplasia (mPIN). In these mice, cdkn1a and its p21 protein product were reduced compared to controls; p27 protein was also reduced. By ChIP assay in human prostate cell lines, we show that ETV4 binds to a specific site (-704/-696 bp upstream of the transcription start) in the CDKN1A promoter that was proven, by luciferase assay, to be functionally competent. ETV4 further controls CDKN1A expression by downregulating p53 protein: this reduction of p53 was confirmed in vivo in ETV4 mice. Conclusions: ETV4 overexpression results in the development of mPIN but not in progression to cancer. ETV4 increases prostate cell proliferation through multiple mechanisms, including downregulation of CDKN1A and its p21 protein product: this in turn is mediated through direct binding of ETV4 to the CDKN1A promoter and through the ETV4-mediated decrease of p53. This multi-faceted role of ETV4 in prostate cancer makes it a potential target for novel therapeutic approaches that could be explored in this ETV4 transgenic model.
PNH is a rare acquired clonal disorder of the hematopoietic stem cell, characterized by a somatic mutation that inactivates the X-linked PIGA gene: this in turn results in deficiency on the cell surface of all proteins anchored by the glycosylphosphatidylinositol (GPI) molecule. Two of these proteins,CD55 andCD59, are complement regulators and their deficiency is responsible for the susceptibility of red cells (RBCs) from the mutant clone to lysis by activated complement. Since oxidative damage is another well-known mechanism of hemolysis (as in G6PD deficient red cells), we have investigated whether this plays a role also in PNH. To this end, we have carried out experiments on RBCs from healthy donors and on PNH-like RBCs (obtained in vitro from the same donors through the use of anti-CD55 and anti-CD59 blocking moAb). After exposure to AB0-compatible serum (in which thecomplement alternative pathway was activated by mild acidification) all PNH-like (but not normal) RBCs were lysed. In parallel experiments in which complement was blocked by eculizumab (ECU) - a moAb that binds to the complement component C5 and controls intravascular hemolysis in PNH patients - we measured the levels of reactive oxygen species (ROS) by the dichlorofluorescin diacetate assay. We found no significant difference of ROS levels between normal RBCs and PNH-like RBCs. We next tested in a similar way G6PD-deficient RBCs, because these are known to be exquisitely sensitive to oxidative damage. We found that ROS levels were significantly higher in the G6PD deficient RBCs that have been made PNH-like (Fig. 1). Thus, complement activation on the surface of PNH-like RBCs results in the production of ROS that can be demonstrated when C5-blockade prevents complement-mediated lysis of RBCs. The notion that G6PD deficiency can interact with PNH was strongly corroborated by the clinical observation of a 40yo woman from Sardinia (Italy) with a 2 years history of pancytopenia, who then developed florid hemolytic PNH: she had anemia with normal granulocyte and platelet counts, dark urine, high reticulocytosis, LDH up to 5x upper normal level, 95% GPI-negative granulocytes. When the patient was started on ECU. LDH levels promptly returned to normal, PNH RBCs rose from 20% (before ECU) to 42%, but reticulocyte count (~250x109/L) and blood transfusion requirement remained high (10 units in the last year). 39% of the GPI-negative RBCs had bound C3 fragments The peripheral blood smear revealed marked macro-anisocytosis, poikilocytosis, spherocytes, and hemighosts: a picture consistent with oxidative damage as seen in G6PD deficient patients during a hemolytic attack. The RBC G6PD activity was about one-half of normal (5 IU/g Hb), and DNA analysis revealed heterozygosity for the G6PD Mediterranean (Med) mutation. By mRNA sequence analysis we found that the GPI-negative clone expressed only the G6PD Med allele, suggesting that the PIG-A mutation took place in a stem cell in which the normal G6PD gene was on the inactive X-chromosome (G6PD, like PIG-A, is on the X chromosome); therefore, all the patients' PNH RBCs were also all G6PD deficient. We have previously shown that the clinical expression of PNH can be influenced by inherited factors: specifically, a polymorphism of the complement receptor 1 (CR1) gene correlates with the blood transfusion requirement of patients on ECU (Rondelli et al, Haematologica 2014). However, the patient here reported was homozygous for the more favorable allele ofCR1. Instead, in keeping with our experimental data, the poor response to ECU seen in this patient results probably from a unique interaction, within the same population of RBCs, between the acquired PNH abnormality and her inherited G6PD deficiency This type of interaction is novel and it seems to have pharmacogenetic implications. Indeed, on its own G6PD deficiency affects mildly the clinical expression of PNH, because complement activation causes RBC lysis regardless; however, paradoxically, when the lysis of PNH RBCs is prevented by C5 blockade, complement activation results in oxidative damage, with which PNH G6PD deficient RBCs are unable to cope. Except for one case previously reported by Oni et al (Blood 1970), this is the first detailed study of PNH associated with G6PD deficiency. Since in some parts of the world the frequency of G6PD deficiency can be as high as 30% or more, we expect that more cases of this association will be discovered in the future. Figure 1 Figure 1. Disclosures No relevant conflicts of interest to declare.
5055 Classical chronic myeloproliferative neoplasms (MPNs) are amongst the best-characterized neoplasms associated with one of a set of specific somatic mutations, the most common of which is in the JAK2 gene. MPN is a relatively rare condition, and it could be surmised that it develops preferentially in people who have an increased tendency to somatic mutations, i. e. an increased somatic mutation rate (μ). Since measuring μ is rather labor-intensive, in this study we have measured instead the frequency of peripheral blood granulocytes that have inactivating mutations in a reporter gene, namely the gene PIG-A, a gene whose protein product is required for numerous glycosyl-phosphatidylinositol-anchored proteins to become surface bound. Since several such proteins are displayed by normal granulocytes, mutant cells can be numbered accurately by flow cytometry; and the frequency (ƒ) of such mutant cells may be a good surrogate of μ (Peruzzi et al. Mutation Research. 2010, 705:3). We have determined ƒ in 74 patients with MPN (including 29 with polycythemia vera (PV), 17 with essential thrombocythemia (ET), 16 with primary myelofibrosis (PMF) 12 with post-PV/post-ET (PPV/PET) MF. Overall the proportion of those with a JAK2(V617F) mutation was 90%. In a subset of 59 of these patients, who had “uncomplicated” MPNs, the median of ƒ was no different compared to 142 healthy controls (4. 74×10−6vs. 4. 87×10−6: Figure 1). However, in a subset of 15, consisting of patients who in addition to MPN had at least one primary malignancy (2 had lymphomas and 13 had one of several types of solid tumors), the median value of ƒ was 15. 22×10−6, i. e. significantly elevated (Mann Whitney test: MPNs vs. MPNs with a second neoplasm, p<0. 013; Healthy controls vs. MPNs with a second neoplasm, p<0. 005: Figure 1). Clearly we cannot automatically extrapolate from our reporter gene, PIG-A, to the actual probability that another gene undergoes somatic mutation; besides, the rate of mutation of JAK2 is influenced by the local genomic context. With that proviso, our data suggest that JAK2 mutations are unlikely to result from an overall increased mutation rate. In keeping with this notion, we found no correlation between the value of ƒ and the allelic burden of JAK2(V617F) (R2= 0. 001): i. e., there is no evidence for genetic instability in MPNs (although, once there is a JAK2 mutation, this may produce a mutator phenotype). On the other hand, an intrinsically increased mutation rate does play a significant role in subjects with multiple neoplasms. This is not surprising: but, to the best of our knowledge, for patients who did not otherwise appear to be ‘cancer-prone’, direct evidence for this is provided here for the first time. Disclosures: No relevant conflicts of interest to declare.
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