Anna Kilbey

The Evi-1 proto-oncogene encodes a transcriptional repressor activity associated with transformation.

The myeloid transforming gene Evi-1 encodes a protein with two zinc finger domains, designated ZF1 and ZF2, with distinct DNA binding specificities. For the first time we demonstrate that Evi-1 has transcriptional repressor activity which is directly proportional to the amount of Evi-1 protein in cells. Repression has been observed with two distinct promoters: the minimal HSV-1 tk promoter and a VP16 inducible adenovirus E1b minimal promoter. Optimal repression is DNA binding dependent and is mediated by either ZF1 or a heterologous GAL4 DNA binding domain (GAL4DBD) but is significantly less efficient through the ZF2 binding site. Both GAL4DBD/Evi-1 fusion and non-fusion proteins have been used to map the repressor activity to a proline-rich region located within amino acids 514 – 724 between the ZF1 and ZF2 domains. Constitutive expression of mutant proteins lacking the repressor domain are defective for transformation of Rat1 fibroblasts demonstrating that this region is required for the oncogenic activity of the Evi-1 protein. These studies show that the Evi-1 gene encodes a transcriptional repressor and has important implications for the mechanism of action of the Evi-1 protein both in development and in the progression of some myeloid leukaemias.

The Runx genes as dominant oncogenes

We have shown previously that Runx2 is a frequent target (approximately equal to 30%) for proviral insertion in murine leukemia virus (MLV) induced T cell tumors in CD2-MYC transgenic mice. Further investigation of a large panel of these tumors revealed that a small number also contain insertions at either Runx3 or Runx1. None of the tumors contained insertions at more than one family member, but in each case proviral insertion was associated with a high level of expression from the upstream (P1) promoter of the respective target gene. Moreover, we confirmed that transcriptional activation of Runx1 does not affect the integrity of the coding sequence, as previously observed for Runx2. These observations suggest that the three Runx genes act as functionally redundant oncogenes in T-cell lymphoma development. To explore the oncogenic potential of Runx2 further we created transgenic mice that over-express this gene in the T cell compartment. These CD2-Runx2 animals show a preneoplastic enlargement of the CD8 immature single positive (ISP) thymocyte pool and develop lymphomas at a low incidence. Although the CD8 ISP population is greatly increased, unlike their wild type counterparts these cells are largely non-cycling. Co-expression of c-MYC in this lineage accentuates the CD8 ISP skew and induces rapid tumor development, confirming the potent synergy that exists between these two oncogenes. Experiments designed to understand the nature of the observed synergy are ongoing and are based on the hypothesis that Runx2 may exert a survival effect in c-MYC expressing tumors in vivo while c-MYC may rescue cells from the antiproliferative effects of Runx2. The oncogenic potential of Runx1 is also being assessed using primary murine embryonic fibroblasts (MEFs). These studies have revealed that while Runx1 exerts a growth suppressive effect in wild type cells a growth promoting effect is seen in the absence of p53, suggesting that the Runx genes may harbor latent oncogene-like properties.

Gene array analysis reveals a common Runx transcriptional programme controlling cell adhesion and survival

The Runx genes are important in development and cancer, where they can act either as oncogenes or tumour suppressors. We compared the effects of ectopic Runx expression in established fibroblasts, where all three genes produce an indistinguishable phenotype entailing epithelioid morphology and increased cell survival under stress conditions. Gene array analysis revealed a strongly overlapping transcriptional signature, with no examples of opposing regulation of the same target gene. A common set of 50 highly regulated genes was identified after further filtering on regulation by inducible RUNX1-ER. This set revealed a strong bias toward genes with annotated roles in cancer and development, and a preponderance of targets encoding extracellular or surface proteins, reflecting the marked effects of Runx on cell adhesion. Furthermore, in silico prediction of resistance to glucocorticoid growth inhibition was confirmed in fibroblasts and lymphoid cells expressing ectopic Runx. The effects of fibroblast expression of common RUNX1 fusion oncoproteins (RUNX1-ETO, TEL-RUNX1 and CBFB-MYH11) were also tested. Although two direct Runx activation target genes were repressed (Ncam1 and Rgc32), the fusion proteins appeared to disrupt the regulation of downregulated targets (Cebpd, Id2 and Rgs2) rather than impose constitutive repression. These results elucidate the oncogenic potential of the Runx family and reveal novel targets for therapeutic inhibition.

RUNX1 transformation of primary embryonic fibroblasts is revealed in the absence of p53

The mammalian Runx gene family (Runx1–3) are transcription factors that play essential, lineage-specific roles in development. A growing body of evidence implicates these genes as mutational targets in cancer where, in different contexts, individual family members have been reported to act as tumour suppressors, dominant oncogenes or mediators of metastasis. We are exploring these paradoxical observations by ectopic expression of RUNX genes in primary murine embryonic fibroblasts where, in common with a number of other dominant oncogenes, RUNX1 induces senescence-like growth arrest in the presence of an intact p19ARF-p53 pathway. We now report that, in MEFs lacking functional p53, RUNX1 has apparently prooncogenic effects on cell growth that include cytoskeletal reorganization, reduced contact inhibition at confluence and accelerated tumour expansion in vivo. On the other hand, RUNX1 conferred no obvious growth advantage at low cell density and actually delayed entry of primary MEFs into S phase. We also found that ectopic RUNX1 interferes with the morphological and growth responses of p53-null MEFs to TGFβ indicating that these effects are mediated by overlapping pathways. These observations help to elucidate the context-dependent consequences of loss and gain of Runx activity.

Evi-1 ZF1 DNA binding activity and a second distinct transcriptional repressor region are both required for optimal transformation of Rat1 fibroblasts

The Evi-1 gene encodes a zinc finger transcriptional repressor protein that normally plays a role in development and is frequently activated in myeloid leukaemias. Evi-1 has two distinct DNA binding domains, ZF1 and ZF2, and a defined repressor domain but the function of the remainder of the molecule is unknown. The ZF2 and repressor domains have been shown to be required for transformation and we show here that ZF1 is also required. An alternative splice variant of Evi-1, designated Δ324, encodes a protein which lacks a portion of the ZF1 DNA binding domain and the intervening amino acids 239–514 (designated IR) located between ZF1 and the repressor domain. We show that Δ324 can neither bind ZF1, repress transcription through this site nor transform Rat1 fibroblasts. Reconstitution studies demonstrate that the defect in Δ324 is partially complemented by recreating the ZF1 DNA binding activity. However, full function also requires the IR region which has transcriptional repressor activity. This study shows therefore, that ZF1, ZF2 and repressor domains and the IR region all contribute to the transformation efficiency of the Evi-1 protein.

Runx2 disruption promotes immortalization and confers resistance to oncogene-induced senescence in primary murine fibroblasts

The Runx genes play paradoxical roles in cancer where they can function either as dominant oncogenes or tumor suppressors according to context. We now show that the ability to induce premature senescence in primary murine embryonic fibroblasts (MEF) is a common feature of all three Runx genes. However, ectopic Runx-induced senescence contrasts with Ras oncogene-induced senescence, as it occurs directly and lacks the hallmarks of proliferative stress. Moreover, a fundamental role for Runx function in the senescence program is indicated by the effects of Runx2 disruption, which renders MEFs prone to spontaneous immortalization and confers an early growth advantage that is resistant to stress-induced growth arrest. Runx2(-/-) cells are refractory to H-Ras(V12)-induced premature senescence, despite the activation of a cascade of growth inhibitors and senescence markers, and are permissive for oncogenic transformation. The aberrant behavior of Runx2(-/-) cells is associated with signaling defects and elevated expression of S-G(2)-M cyclins and their associated cyclin dependent kinase activities that may override the effects of growth inhibitory signals. Coupling of stress responses to the cell cycle represents a novel facet of Runx tumor suppressor function and provides a rationale for the lineage-specific effects of loss of Runx function in cancer.

Runx Regulation of Sphingolipid Metabolism and Survival Signaling

The Runx genes (Runx1, 2, and 3) regulate cell fate in development and can operate as either oncogenes or tumor suppressors in cancer. The oncogenic potential of ectopic Runx expression has been shown in transgenic mice that develop lymphoma in potent synergy with overexpressed Myc, and in established fibroblasts that display altered morphology and increased tumorigenicity. Candidate oncogenic functions of overexpressed Runx genes include resistance to apoptosis in response to intrinsic and extrinsic stresses. In a search for gene targets responsible for this aspect of Runx phenotype, we have identified three key enzymes in sphingolipid metabolism (Sgpp1, Ugcg, and St3gal5/Siat9) as direct targets for Runx transcriptional regulation in a manner consistent with survival and apoptosis resistance. Consistent with these changes in gene expression, mass spectrometric analysis showed that ectopic Runx reduces intracellular long-chain ceramides in NIH3T3 fibroblasts and elevated extracellular sphingosine 1 phosphate. Runx expression also opposed the activation of c-Jun-NH(2)-kinase and p38(MAPK), key mediators of ceramide-induced death, and suppressed the onset of apoptosis in response to exogenous tumor necrosis factor alpha. The survival advantage conferred by ectopic Runx could be partially recapitulated by exogenous sphingosine 1 phosphate and was accompanied by reduced phosphorylation of p38(MAPK). These results reveal a novel link between transcription factor oncogenes and lipid signaling pathways involved in cancer cell survival and chemoresistance.

RUNX1 and its fusion oncoprotein derivative RUNX1-ETO induce senescence-like growth arrest independently of replicative stress

A role for the RUNX genes in cancer fail-safe processes has been suggested by their induction of senescence-like growth arrest in primary murine fibroblasts and the failure of RAS-induced senescence in Runx2-deficient cells. We now show that RUNX1 induces senescence in human primary fibroblasts. High-affinity DNA binding is necessary but not sufficient, as shown by the functional attenuation of the truncated RUNX1/AML1a isoform and the TEL-RUNX1 fusion oncoprotein. However, a similar phenotype was potently induced by the RUNX1-ETO (AML1-ETO) oncoprotein, despite its dominant-negative potential. A detailed comparison of H-RASV12, RUNX1 and RUNX1-ETO senescent phenotypes showed that the RUNX effectors induce earlier growth stasis with only low levels of DNA damage signaling and a lack of chromatin condensation, a marker of irreversible growth arrest. In human fibroblasts, all effectors induced p53 in the absence of detectable p14Arf, whereas only RUNX1-ETO induced senescence in p16Ink4a-null cells. Correlation was noted between induction of p53, reactive oxygen species and phospho-p38, whereas p38MAPK inhibition rescued cell growth markedly. These findings indicate a role for replication-independent pathways in RUNX and RUNX1-ETO senescence, and show that the context-specific oncogenic activity of RUNX1 fusion proteins is mirrored in their distinctive interactions with fail-safe responses.

The Evi1 proto-oncoprotein blocks endomitosis in megakaryocytes by inhibiting sustained cyclin-dependent kinase 2 catalytic activity

The 3q21q26 syndrome leukaemias are characterised by dystrophic megakaryocytes, elevated platelet counts, ectopic EVI1 protein production and poor prognosis. To investigate the molecular basis of this disease, we developed a model system to examine the biological activity of EVI1 in a megakaryocyte progenitor cell line. For this purpose, Evi1 was conditionally expressed in human erythroleukaemia cells (HEL) that progress along the megakaryocyte lineage in the presence of 12‐O‐tetradecanoylphorbol 13‐acetate (TPA). TPA‐stimulated HEL cells normally undergo: (1) growth arrest; (2) altered morphology; (3) endomitosis and (4) characteristic changes in gene expression, including reduction of the erythroid‐specific glycophoryn A and elevation of the specific glycoproteins GPIIIa and GPVI. Enforced Evi1 expression alone had no effect upon HEL cell proliferation or differentiation but a phenotype was manifest upon stimulation to differentiate. Evi1‐expressing, TPA‐treated HEL cells still showed growth arrest, had reduced and enhanced glycophoryn A and GPIIIa mRNAs, respectively, but failed to significantly elevate GPVI mRNA. This was accompanied by inhibition of endomitosis and altered cell morphology. Sustained CDK2 catalytic activity, typically associated with megakaryocyte endomitosis, was dramatically decreased in TPA‐stimulated Evi1‐expressing HEL cells because of significantly reduced levels of cyclin A. Therefore, enforced Evi1 expression could inhibit megakaryocyte differentiation although retention of some characteristic molecular changes, in combination with a block in endomitosis and altered morphology, suggest a defect in lineage progression. These results suggest that ectopic Evi1 expression contributes to a defective megakaryocyte differentiation programme and is likely to contribute to the phenotype observed in 3q21q26 syndrome leukaemias.

ETV6/RUNX1 abrogates mitotic checkpoint function and targets its key player MAD2L1.

Approximately 25% of childhood B-cell precursor acute lymphoblastic leukemia have an ETV6/RUNX1 (E/R) gene fusion that results from a t(12;21). This genetic subgroup of leukemia is associated with near-triploidy, near-tetraploidy, and trisomy 21 as rather specific types of secondary changes. Here, we show that, unlike various controls, E/R-expressing Ba/F3 clones acquire a tetraploid karyotype on prolonged culture, corroborating the assumption that E/R may attenuate the mitotic checkpoint (MC). Consistent with this notion, E/R-expressing diploid murine and human cell lines have decreased proportions of cells with 4N DNA content and a lower mitotic index when treated with spindle toxins. Moreover, both RUNX1 and E/R regulate mitotic arrest-deficient 2 L1 (MAD2L1), an essential MC component, by binding to promoter-inherent RUNX1 sites, which results in down-regulation of MAD2L1 mRNA and protein in E/R-expressing cells. Forced expression of E/R also abolishes RUNX1-induced reporter activation, whereas E/R with a mutant DNA-binding site leads to only minor effects. Our data link for the first time E/R, MC, and MAD2L1 and provide new insights into the function of the E/R fusion gene product. Although tetraploidy is an almost exclusive feature of E/R-positive leukemias, its rarity within this particular subgroup implies that further yet unknown factors are required for its manifestation.