The E3 ubiquitin ligase complex component COP1 regulates PEA3 group member stability and transcriptional activity.

In this study, we report that the PEA3 group members interact with the mammalian really interesting new gene (RING) E3 ubiquitin ligase constitutive photomorphogenetic 1 (COP1), which mediates ubiquitylation and subsequent proteasome degradation of the p53 and c-Jun transcription factors. This interaction is mediated by the central region of COP1 including the coiled-coil domain and two COP1-interacting consensus motifs localized in the well-conserved N-terminal transactivation domain of the PEA3 group members. At the transcriptional level, COP1 reduces the transcriptional activity of ERM and the two other PEA3 group proteins on Ets-responsive reporter genes; this effect being dependent on the RING domain of COP1 and the two COP1-interacting motifs of ERM. Reduced transcriptional activity was, however, not related to COP1-induced changes in ERM stability. In fact, increased ubiquitylation and subsequent proteasome-mediated degradation of ERM is achieved only when COP1 is expressed with DET1, a key COP1 partner within the ubiquitylation complex. Conversely, we show that the depletion of COP1 or DET1 by small interference RNA (siRNA) in U2OS cells stabilizes endogenous ERM whereas only COP1 knockdown enhances expression of ICAM-1, a gene regulated by this transcription factor. These results indicate that COP1 is a complex regulator of ERM and the two other PEA3 group members.

The 26S proteasome system degrades the ERM transcription factor and regulates its transcription-enhancing activity.

ERM is a member of the ETS transcription factor family. High levels of the corresponding mRNA are detected in a variety of human breast cancer cell lines, as well as in aggressive human breast tumors. As ERM protein is almost undetectable in these cells, high degradation of this transcription factor has been postulated. Here we have investigated whether ERM degradation might depend on the proteasome pathway. We show that endogenous and ectopically expressed ERM protein is short-lived protein and undergoes proteasome-dependent degradation. Deletion mutagenesis studies indicate that the 61 C-terminal amino acids of ERM are critical for its proteolysis and serve as a degradation signal. Although ERM conjugates with ubiquitin, this post-translational modification does not depend on the C-terminal domain. We have used an Ets-responsive ICAM-1 reporter plasmid to show that the ubiquitin-proteasome pathway can affect transcriptional function of ERM. Thus, ERM is subject to degradation via the 26S proteasome pathway, and this pathway probably plays an important role in regulating ERM transcriptional activity.

Regulation of the Ets-1 transcription factor by sumoylation and ubiquitinylation.

Sumoylation and ubiquitinylation reversibly regulate the activity of transcription factors through covalent attachment to lysine residues of target proteins. We examined whether the Ets-1 transcription factor is modified by sumoylation and/or ubiquitinylation. Among four potential SUMO motifs in Ets-1, we identified lysines 15 and 227 within the LK(15)YE and IK(227)QE motifs, as being the sumoylation acceptor sites. Using transfection of Ets-1 wildtype (WT) or its sumoylation deficient version (Ets-1 K15R/K227R), as well as WT or mutant proteins of the SUMO pathway, we further demonstrated that the E2 SUMO-conjugating enzyme Ubc9 and a E3 SUMO ligase, PIASy, can enhance Ets-1 sumoylation, while a SUMO protease, SENP1, can desumoylate Ets-1. We also found that Ets-1 is modified by K48-linked polyubiquitinylation independently of the sumoylation acceptor sites and is degraded through the 26S proteasome pathway, while sumoylation of Ets-1 does not affect its stability. Finally, sumoylation of Ets-1 leads to reduced transactivation and we demonstrated that previously identified critical lysine residues in Synergistic Control motifs are the sumoylation acceptor sites of Ets-1. These data show that Ets-1 can be modified by sumoylation and/or ubiquitinylation, with sumoylation repressing transcriptional activity of Ets-1 and having no clear antagonistic action on the ubiquitin-proteasome degradation pathway.

[Multiple post-translational modifications implied in the gene expression regulation: example of the sumoylation of Ets factors]. / Multiples modifications post-traductionnelles impliquées dans la régulation de l'expression génique: exemple de la sumoylation des facteurs Ets.

To regulate the spatiotemporal expression of their target genes, the transcription factors undergo post-translational modifications of which the most studied is phosphorylation. Acetylation and ubiquitinylation on lysine residues also exert a role in the transcription, as it is the case for the regulation of the activity of the huge family of Ets transcription factors. Recently, sumoylation, a post-translational modification similar to ubiquitinylation, was described as playing a crucial role in the inhibition of the activity of these factors.

Cloning and expression analysis of a cDNA that encodes a leech hemerythrin.

We report the cDNA sequence of a leech hemerythrin. A cDNA was isolated from a Theromyzon tessulatum cDNA library and encodes a 120 amino acid protein of about 14 kDa. The predicted protein contains the hemerythrin signature sequence and the iron ligand residues previously identified in crystal structures of hemerythrin and myohemerythrin. The protein displayed the highest identity to myohemerythrin, a non-heme iron-binding protein described in sipunculids. Expression analysis indicated that the mRNA is widely expressed in leech and is stage specific in appearance, being absent after the two first blood meals, appearing after the last blood meal during the period preceding oogenesis and disappearing after egg laying.

The PEA3 group of ETS-related transcription factors. Role in breast cancer metastasis.

The ets genes encode eukaryotic transcription factors that are involved in tumorigenesis and developmental processes. The signature of the Ets family is the ETS-domain, which binds to sites containing a central 5'-GGAA/T-3' motif. They can be sub-classified primarily because of the high amino acid conservation in their ETS-domains and, in addition, in the conservation of other domains generally characterized as transactivating. This is the case for the PEA3 group, which is currently made up of three members, PEA3/E1AF, ER81/ETV1 and ERM, which are more than 95% identical in the ETS-domain and more than 85% in the transactivation acidic domain. The members of the PEA3 group are activated through both the Ras-dependent and other kinase pathways, a function which emphasizes their involvement in several oncogenic mechanisms. The expression pattern of the three PEA3 group genes during mouse embryogenesis suggests that they are differentially regulated, probably to serve important functions such as tissue interaction. Although the target genes of these transcription factors are multiple, their most frequently studied role concerns their involvement in the metastatic process. In fact, PEA3 group members are over-expressed in metastatic human breast cancer cells and mouse mammary tumors, a feature which suggests a function of these transcription factors in mammary oncogenesis. Moreover, when they are ectopically over-expressed in non-metastatic breast cancer cells, these latter become metastatic with the activation of transcription of matrix metalloproteinases or adhesion molecules, such as ICAM-1.

Therostasin, a novel clotting factor Xa inhibitor from the rhynchobdellid leech, Theromyzon tessulatum.

Therostasin is a potent naturally occurring tight-binding inhibitor of mammalian Factor Xa (K(i), 34 pm), isolated from the rhynchobdellid leech Theromyzon tessulatum. Therostasin is a cysteine-rich protein (8991 Da) consisting of 82 amino acid residues with 16 cysteine residues. Its amino acid sequence has been determined by a combination of techniques, including Edman degradation, enzymatic cleavage, and matrix-assisted laser desorption/ionization time-of-flight mass spectrometry (MALDI-TOF MS) on the native and s-beta-pyridylethylated compound. Sequence analysis reveals that it shares no significant homology with other Factor Xa inhibitors except for the putative reactive site. Moreover, it contains a signature pattern for proteins of the endothelin family, potent vasoconstrictors isolated in mammal and snake venom. Therostasin cDNA (825 bp) codes for a polypeptide of 82 amino acid residues preceded by 19 residues, representing a signal peptide sequence. As for the other known inhibitors of Factor Xa, therostasin is expressed and stored in the cells of the leech salivary glands.

The Ets domain transcription factor Erm distinguishes rat satellite glia from Schwann cells and is regulated in satellite cells by neuregulin signaling.

Distinct glial cell types of the vertebrate peripheral nervous system (PNS) are derived from the neural crest. Here we show that the expression of the Ets domain transcription factor Erm distinguishes satellite glia from Schwann cells beginning early in rat PNS development. In developing dorsal root ganglia (DRG), Erm is present both in presumptive satellite glia and in neurons. In contrast, Erm is not detectable at any developmental stage in Schwann cells in peripheral nerves. In addition, Erm is downregulated in DRG-derived glia adopting Schwann cell traits in culture. Thus, Erm is the first described transcription factor expressed in satellite glia but not in Schwann cells. In culture, the Neuregulin1 (NRG1) isoform GGF2 maintains Erm expression in presumptive satellite cells and reinduces Erm expression in DRG-derived glia but not in Schwann cells from sciatic nerve. These data demonstrate that there are intrinsic differences between these glial subtypes in their response to NRG1 signaling. In neural crest cultures, Erm-positive progenitor cells give rise to two distinct glial subtypes: Erm-positive, Oct-6-negative satellite glia in response to GGF2, and Erm-negative, Oct-6-positive Schwann cells in the presence of serum and the adenylate cyclase activator forskolin. Thus, Erm-positive neural crest-derived progenitor cells and presumptive satellite glia are able to acquire Schwann cell features. Given the in vivo expression of Erm in peripheral ganglia, we suggest that ganglionic Erm-positive cells may be precursors of Schwann cells.

Characterization of the human and mouse ETV1/ER81 transcription factor genes: role of the two alternatively spliced isoforms in the human.

The Ets transcription factors of the PEA3 group--E1AF/PEA3, ETV1/ER81 and ERM--are almost identical in the ETS DNA-binding and the transcriptional acidic domains. To accelerate our understanding of the molecular basis of putative diseases linked to ETV1 such as Ewing's sarcoma we characterized the human ETV1 and the mouse ER81 genes. We showed that these genes are both encoded by 13 exons in more than 90 kbp genomic DNA, and that the classical acceptor and donor splicing sites are present in each junction except for the 5' donor site of intron 9 where GT is replaced by TT. The genomic organization of the ETS and acidic domains in the human ETV1 and mouse ER81 (localized to chromosome 12) genes is similar to that observed in human ERM and human E1AF/PEA3 genes. Moreover, as in human ERM and human E1AF/PEA3 genes, a first untranslated exon is upstream from the first methionine, and the mouse ER81 gene transcription is regulated by a 1.8 kbp of genomic DNA upstream from this exon. In human, the alternative splicing of the ETV1 gene leads to the presence (ETV1 alpha) or the absence (ETV1 beta) of exon 5 encoding the C-terminal part of the transcriptional acidic domain, but without affecting the alpha helix previously described as crucial for transactivation. We demonstrated here that the truncated isoform (human ETV1 beta) and the full-length isoform (human ETV1 alpha) bind similarly specific DNA Ets binding sites. Moreover, they both activate transcription similarly through the PKA-transduction pathway, so suggesting that this alternative splicing is not crucial for the function of this protein as a transcription factor. The comparison of human ETV1 alpha and human ETV1 beta expression in the same tissues, such as the adrenal gland or the bladder, showed no clear-cut differences. Altogether, these data open a new avenue of investigation leading to a better understanding of the functional role of this transcription factor.

Molecular characterization of the zebrafish PEA3 ETS-domain transcription factor.

The PEA3 subfamily of ETS-domain proteins play important roles in regulating transcriptional activation and have been implicated in several tumorigenic processes. Here we describe the identification of a further member of this family from zebrafish which most likely represents a homologue of PEA3. A high degree of sequence conservation is observed in the ETS DNA-binding domain and acidic transcriptional activation domain. The DNA binding specificity of zebrafish PEA3 is virtually identical to that exhibited by mammalian family members and is autoregulated by cisacting inhibitory domains. Transcriptional activation by zebrafish PEA3 is potentiated by the ERK MAP kinase and protein kinase A pathways. During embryogenesis, PEA3 is expressed in complex spatial and temporal patterns in both mesodermal somites and ectodermal tissues including the brain, dorsal spinal chord and neural crest. Our characterisation of zebrafish PEA3 furthers our understanding of its molecular function and its expression profile suggests a novel role in cell patterning in the early vertebrate embryo.

The transcription of the intercellular adhesion molecule-1 is regulated by Ets transcription factors.

The Ets family of transcription factors comprises several members which are involved to regulate gene transcription. Although several consensus binding sites for Ets proteins can be found in a wide series of promoter, only a limited number of them are indeed activated by these transcription factors. The human intercellular adhesion molecule-1 (ICAM-1) plays a crucial role in immune responses by enabling the binding of effector cells to various target cell types. ICAM-1 is constitutively expressed at different levels in the absence of stimuli in different cell types, and its expression is upregulated by several proinflammatory cytokines. We have here examined the transcriptional regulation of human ICAM-1 expression by Ets proteins, and more particularly by ERM, a member of this family of transcription factors. Transient transfection assays revealed that Ets-2 and ERM significantly activate the transcription of ICAM-1 promoter, whereas the less-related Ets family member, Spi-1/Pu.1, failed to do so. Transfection of a series of ICAM-1 promoter deletion mutants together with ERM expression plasmids have shown that an Ets responsive element is located within the first 176 bp upstream from the translational start site. Electrophoretic mobility shift assays and DNase I footprinting analysis have enabled us to identify two Ets binding sites at positions -158 and -138 from the ATG, respectively. Site directed mutagenesis of these elements has shown that the distal site is the major element required for the ERM-mediated activation of the ICAM-1 promoter. We can thus conclude that expression of ICAM-1 can be regulated by Ets transcription factors.

Structure-function relationships of the PEA3 group of Ets-related transcription factors.

The PEA3 group of transcription factors belongs to the Ets family and is composed of PEA3, ERM, and ER81, which are more than 95% identical within the DNA-binding domain--the ETS domain--and which demonstrate 50% aa identity overall. We present here a review of the current knowledge of these transcription factors, which possess functional domains responsible for DNA-binding, DNA-binding inhibition, and transactivation. Recent data suggest that these factors are targets for signaling cascades, such as the Ras-dependent ones, and thus may contribute first to the nuclear response to cell stimulation and second to Ras-induced cell transformation. The expression of the PEA3 group members in numerous developing murine organs, and, especially, in epithelial-mesenchymal interaction events, suggests a key role in murine organogenesis. Moreover, their expression in certain breast cancer cells suggests a possible involvement of these genes in the appearance, progression, and invasion of malignant cells.

Primary structure of a myohemerythrin-like cadmium-binding protein, isolated from a terrestrial annelid oligochaete.

Two isoforms of a cadmium-binding protein (Cd-BP 14a and Cd-BP 14b) were isolated from the terrestrial oligochaete annelid, Allolobophora caliginosa. The complete amino acid sequence of the major isoform Cd-BP 14a (molecular mass: 13441 Da; 119 residues) and the amino-terminal sequence (57 residues) of Cd-BP 14b were determined. The sequence of Cd-BP 14a is highly similar to that of myohemerythrins present in marine invertebrates. Furthermore, as myohemerythrins, Cd-BP 14a and Cd-BP 14b bind two atoms of iron and their ultraviolet/visible spectra are typical of non-heme iron-binding proteins. Three substitutions were found in the amino-terminal half of the proteins at positions 19, 21 and 41. The substitutions at positions 19 and 21 are conservative, whereas that at position 41 consists of the replacement of an aspartate residue in isoform a by a lysine residue in isoform b. To our knowledge, it is the first report of a protein belonging to the hemerythrin family in a terrestrial invertebrate.

Expression of the PEA3 group of ETS-related transcription factors in human breast-cancer cells.

The PEA3 group of transcription factors belongs to the ets family and is composed of 3 known members, PEA3, ERM and ER81, which are more than 95% identical within the DNA-binding ETS domain and exhibit 50% aa identity overall. Recently, transgenic mice bearing the c-erbB-2/neu oncogene have been shown to over-express PEA3 mRNA in mammary adenocarcinomas, suggesting a role for this gene family in mammary tumorigenesis. In the present work we characterized the mRNA expression levels of PEA3-group genes in a series of human epithelial breast cell lines. Each of the 3 genes was highly expressed in normal human HMEC 1001-7 and HMEC 219-4 cells. In breast-cancer cell lines, the 3 genes were highly expressed in the ER- MDA-MB-436, MDA-MB-330, MDA-MB-231 and BT-20 cell lines, but not in the ER+ MDA-MB-134-VI and ZR-75-1 cells. In an attempt to characterize the PEA3-group proteins in breast-cancer cells, we first produced and characterized specific antibodies against each of these 3 proteins. The anti-ERM and anti-ER81 antibodies recognized specific strong bands at approximately 72 kDa and 62 kDa, corresponding to ERM and ER81, respectively, in MDA-MB-231 and Hs-578T cells expressing significant levels of the 3 mRNAs. No protein was detected in MCF-7 cells expressing low levels of mRNA for PEA3-group-family genes, or in ZR-75-1 cells, where mRNA was undetectable by Northern blot. Although in vitro-translated PEA3 is specifically immunoprecipitated by anti-PEA3 anti-serum, we were unable to immunoprecipitate PEA3 protein from MDA-MB-231 and Hs-578T cells. In order to study the transcription factor activity of ERM, PEA3 and ER81 proteins in mammary-cancer cells, we tested their ability to transactivate a reporter plasmid containing 3 Ets-binding sites, and were able to show that, in all the breast-cancer cells tested, transfected ERM, PEA3 and ER81 are able to transactivate. Although the target genes of the PEA3 group of transcription factors in breast-cancer cells have yet to be determined, these genes have a potential role in the regulation of growth and the progression of human breast cancer.

The ETS family member ERM contains an alpha-helical acidic activation domain that contacts TAFII60.

Transcription factors are modular entities built up of discrete domains, some devoted to DNA binding and others permitting transcriptional modulation. The structure of DNA binding domains has been thoroughly investigated and structural classes clearly defined. In sharp contrast, the structural constraints put on transactivating regions, if any, are mostly unknown. Our investigations focus on ERM, a eukaryotic transcription factor of the ETS family. We have previously shown that ERM harbours two transactivating domains (TADs) with distinct functional features: AD1 lies in the first 72 amino acids of ERM, while AD2 sits in the last 62. Here we show that AD1 is a bona fide acidic TAD, for it activated transcription in yeast cells, while AD2 did not. AD1 contains a 20 amino acid stretch predicted to form an alpha-helix that is found unchanged in the related PEA3 and ER81 transcription factors. Circular dichroism analysis revealed that a 32 amino acid peptide encompassing this region is unstructured in water but folds into a helix when the hydrophobic solvent trifluoroethanol is added. The isolated helix was sufficient to activate transcription and mutations predicted to disrupt it dramatically affected AD1-driven transactivation, whereas mutations decreasing its acidity had more gentle effects. A phenylalanine residue within the helix was particularly sensitive to mutations. Finally, we observed that ERM bound TAFII60 via AD1 and bound TBP and TAFII40, presumably via other activation domains.

The ETS-related transcription factor ERM is a nuclear target of signaling cascades involving MAPK and PKA.

Recent studies support a model for signal transduction from activated receptor tyrosine kinases to Ras which, in turn, activates the pathway of the mitogen-activated protein kinase (MAPK). Although some members of the Ets transcription factor family have been shown to be activated by this signaling pathway, no data are available on the activation of the PEA3 group of Ets proteins. This group is composed of three members -- PEA3, ER81 and ERM -- which are very similar in the DNA-binding domain, the ETS domain, in the 32 residue amino-terminal acidic domain and in the 61 residue carboxy-terminal domain. First of all we demonstrated that ERM-transfected cells contain a positive labeling in the nucleus, and we concluded that a nuclear localization signal might be situated in the ETS domain. We then showed that of four putative reporter plasmids, ERM activated the artificial 3 x TORU plasmid which contains an Ets binding site contiguous to an AP1 one. This transactivation enhancement requires the presence of the ERM amino-terminal domain. In contrast, although the lack of the carboxy-terminal domain induced a decrease in transactivation, this latter domain is not crucial. By using the E74-reporter plasmid system which is not basically activated by ERM, we showed that the activation of the Ras/Raf-1/MAPK pathway significantly enhanced ERM-mediated transactivation. The deletion of the amino-terminal transactivation domain abolished the capacity of stimulated MAPK to activate ERM. We also demonstrated that ERM can also be activated through the protein kinase A (PKA), another signaling pathway. Nevertheless, the MAPK and PKA activation of ERM are not synergistic. Finally, we showed that this Ets transcription factor is in vitro phosphorylated by both activated ERK-2 and activated PKA. ERM has thus been identified as a transcription factor which is a target for two different signaling pathways and might therefore be involved in the mitogenic response of cells.

Two functionally distinct domains responsible for transactivation by the Ets family member ERM.

The recently cloned human Ets transcription factor ERM is closely related to the ER81 and PEA3 genes. Here, we report the functional analysis of the DNA-binding and transactivation properties of ERM. Specific DNA-binding by ERM requires the ETS domain, conserved in all members of the Ets family and is inhibited by an 84 residue long central region and the carboxy-terminal tail. Two fragments of ERM are transferrable activation domains: alpha, which sits in the 72 first residues and encompasses the acidic domain conserved between ERM, ER81 and PEA3, and the carboxy-terminal tail which also bears a DNA-binding inhibition function. Deletion of alpha strongly reduces transactivation by ERM. Moreover, alpha and the carboxy-terminal tail exhibit functional synergism, suggesting that they activate transcription through different mechanisms. In support of this idea, we demonstrate that VP16 squelches transactivation by alpha but not by the carboxy-terminal tail. This result also indicates that alpha and VP16 may share common limiting cofactors. alpha and the carboxy-terminal tail do not seem to be conserved within the whole Ets family, indicating that the specificity of ERM may rely on interactions with distinct cofactors.

Molecular characterization of mouse 17 beta-hydroxysteroid dehydrogenase IV.

17 beta-hydroxysteroid dehydrogenases (17 beta-HSD) catalyze the conversion of estrogens and androgens at the C17 position. The 17 beta-HSD type I, II, III and IV share less than 25% amino acid similarity. The human and porcine 17 beta-HSD IV reveal a three-domain structure unknown among other dehydrogenases. The N-terminal domains resemble the short chain alcohol dehydrogenase family while the central parts are related to the C-terminal parts of enzymes involved in peroxisomal beta-oxidation of fatty acids and the C-terminal domains are similar to sterol carrier protein 2. We describe the cloning of the mouse 17 beta-HSD IV cDNA and the expression of its mRNA. A probe derived from the human 17 beta-HSD IV was used to isolate a 2.5 kb mouse cDNA encoding for a protein of 735 amino acids showing 85 and 81% similarity with human and porcine 17 beta-HSD IV, respectively. The calculated molecular mass of the mouse enzyme amounts to 79,524 Da. The mRNA for 17 beta-HSD IV is a single species of about 3 kb, present in a multitude of tissues and expressed at high levels in liver and kidney, and at low levels in brain and spleen. The cloning and molecular characterization of murine, human and porcine 17 beta-HSD IV adds to the complexity of steroid synthesis and metabolism. The multitude of enzymes acting at C17 might be necessary for a precise control of hormone levels.

Molecular characterization of the ets-related human transcription factor ER81.

The PEA3 group is a homogeneous group of the ets transcription factor family and is composed of three known members, PEA3, ERM and ER81, which, on the amino acid (AA) level, are more than 95% identical within the DNA-binding domain (the Ets domain), more than 85% within a 32 AA domain (the acidic domain) localized in the amino-terminus and almost 50% identical overall. By screening a human kidney cDNA library with a specific probe obtained from mouse ER81, we isolated two clones of 1.6 and 1.5 kb in length encoding a 458 AA open reading frame. When compared to mouse ER81, the present human ER81 lacks the last 13 AA of the acidic domain and the 5 AA contiguous to the carboxy-terminal part of the acidic domain. Of the 458 AA of the human ER81 protein, 97% are identical to mouse ER81. Gel shift analysis indicates that the full-length human ER81 protein is able to bind specifically to an oligonucleotide containing the binding sites recognized by most of the Ets proteins. By transient expression in RK13 mammalian cells, human ER81 protein transactivated a reporter plasmid containing Ets binding sites, indicating that this molecule is a bonafide transcriptional activator, while by expression in Cos-1 transfected cells, we detected the presence of human ER81 protein in the nucleus using immunocytochemistry. In human tissues, ER81 mRNA is very highly expressed in brain, highly expressed in testis, lung and heart, moderately in spleen, small intestine, pancreas and colon, weakly in liver, prostate and thymus, very weakly in skeletal muscle, kidney and ovary and not in placenta and peripheral blood leukocytes. Analysis of human solid or haematopoietic tumour cell lines showed that most of them did not express ER81 detectably. Database searches revealed that ETV1 mRNA is highly similar to human ER81 described here, although it contains the full-length acidic domain present in mouse ER81. By screening a genomic DNA library, we characterized the intron-exon junction within the acidic domain of human ER81 and we showed that this junction corresponds to the site where the remaining AA of the acidic domain of ETV1 or mouse ER81 are inserted.

[Transcription factors of the PEA3 group in mammary cancer]. / Les facteurs de transcription du groupe PEA3 dans le cancer mammaire.

Prognosis factors such as mutated or amplified oncogenes are used in the treatment of breast cancer. We have recently shown that the members of the PEA3 group (ER81, ERM and PEA3) from the transcription factor family of the ets genes are overexpressed in breast cancer tumors arising from MMTV-neu transgenic animals. Moreover, we have shown that ER81, and in a lesser extent ERM and PEA3, are not expressed in the estrogen and/or progesterone receptor-positive mammary cancer cell lines, whereas they are expressed in the receptor negative ones. Our research interest in now focused on the role(s) of these oncogenes in the development and the regulation of breast tumors.