Runx1 Orchestrates Sphingolipid Metabolism and Glucocorticoid Resistance in Lymphomagenesis.

The three-membered RUNX gene family includes RUNX1, a major mutational target in human leukemias, and displays hallmarks of both tumor suppressors and oncogenes. In mouse models, the Runx genes appear to act as conditional oncogenes, as ectopic expression is growth suppressive in normal cells but drives lymphoma development potently when combined with over-expressed Myc or loss of p53. Clues to underlying mechanisms emerged previously from murine fibroblasts where ectopic expression of any of the Runx genes promotes survival through direct and indirect regulation of key enzymes in sphingolipid metabolism associated with a shift in the "sphingolipid rheostat" from ceramide to sphingosine-1-phosphate (S1P). Testing of this relationship in lymphoma cells was therefore a high priority. We find that ectopic expression of Runx1 in lymphoma cells consistently perturbs the sphingolipid rheostat, whereas an essential physiological role for Runx1 is revealed by reduced S1P levels in normal spleen after partial Cre-mediated excision. Furthermore, we show that ectopic Runx1 expression confers increased resistance of lymphoma cells to glucocorticoid-mediated apoptosis, and elucidate the mechanism of cross-talk between glucocorticoid and sphingolipid metabolism through Sgpp1. Dexamethasone potently induces expression of Sgpp1 in T-lymphoma cells and drives cell death which is reduced by partial knockdown of Sgpp1 with shRNA or direct transcriptional repression of Sgpp1 by ectopic Runx1. Together these data show that Runx1 plays a role in regulating the sphingolipid rheostat in normal development and that perturbation of this cell fate regulator contributes to Runx-driven lymphomagenesis. J. Cell. Biochem. 118: 1432-1441, 2017. © 2016 Wiley Periodicals, Inc.

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.

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-RAS(V12), 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 p14(Arf), whereas only RUNX1-ETO induced senescence in p16(Ink4a)-null cells. Correlation was noted between induction of p53, reactive oxygen species and phospho-p38, whereas p38(MAPK) 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.

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.

Evi-1 transforming and repressor activities are mediated by CtBP co-repressor proteins.

Ectopic production of the EVI1 transcriptional repressor zinc finger protein is seen in 4--6% of human acute myeloid leukemias. Overexpression also transforms Rat1 fibroblasts by an unknown mechanism, which is likely to be related to its role in leukemia and which depends upon its repressor activity. We show here that mutant murine Evi-1 proteins, lacking either the N-terminal zinc finger DNA binding domain or both DNA binding zinc finger clusters, function as dominant negative mutants by reverting the transformed phenotype of Evi-1 transformed Rat1 fibroblasts. The dominant negative activity of the non-DNA binding mutants suggests sequestration of transformation-specific cofactors and that recruitment of these cellular factors might mediate Evi-1 transforming activity. C-terminal binding protein (CtBP) co-repressor family proteins bind PLDLS-like motifs. We show that the murine Evi-1 repressor domain has two such sites, PFDLT (site a, amino acids 553--559) and PLDLS (site b, amino acids 584--590), which independently can bind CtBP family co-repressor proteins, with site b binding with higher affinity than site a. Functional analysis of specific CtBP binding mutants show site b is absolutely required to mediate both transformation of Rat1 fibroblasts and transcriptional repressor activity. This is the first demonstration that the biological activity of a mammalian cellular transcriptional repressor protein is mediated by CtBPs. Furthermore, it suggests that CtBP proteins are involved in the development of some acute leukemias and that blocking their ability to specifically interact with EVI1 might provide a target for the development of pharmacological therapeutic agents.

Loss of cell cycle control by deregulation of cyclin-dependent kinase 2 kinase activity in Evi-1 transformed fibroblasts.

The Evi-1 transcriptional repressor protein has two distinct zinc finger DNA binding domains designated ZF1 and ZF2 and is implicated in the progression of human and murine leukemias, in which it is abnormally expressed. In this report, we show that Evi-1-expressing Rat1 fibroblasts are anchorage independent, have an abbreviated G1 phase of the cell cycle, and have a reduced requirement for serum mitogens for S-phase entry. These biological changes are accompanied by a moderately increased production of cell cycle-regulatory proteins cyclin A and cyclin-dependent kinase (Cdk) 2, a dramatic deregulation of Cdk2 kinase activity, and a corresponding increase in the levels of hyperphosphorylated retinoblastoma protein (pRb). We show that the elevated cyclin A-Cdk2 activity is due to the combination of increased accumulation and stabilization of cyclin A bound to a faster-migrating species of Cdk2 believed to be the active threonine 160 phosphorylated form and a substantial reduction in complexed p27. Cyclin E kinase activity is also elevated due to a reduction in p27. A significant reduction in total cellular p27 protein levels and a moderate reduction in p27 mRNA are observed, but no changes in Cdk regulatory kinases and phosphatases occur. The Evi-1 transcriptional repressor domain and the ZF1 DNA binding domain are required for both cell transformation and induction of Cdk2 catalytic activity. We propose that one consequence of Evi-1 expression is to repress the transcription of target genes, which may include p27, that deregulate the normal control of the G1 phase of the cell cycle, providing a cellular proliferative advantage that contributes to transformation in vitro and leukemogenesis in vivo.

v-Jun represses c-jun proto-oncogene expression in vivo through a 12-O-tetradecanoylphorbol-13-acetate-responsive element in the proximal gene promoter.

c-jun proto-oncogene expression is extinguished in cells transformed by v-Jun; however, the mechanistic basis of this phenomenon has not been elucidated. c-jun mRNA levels are greatly reduced in v-Jun-transformed cells, and we show that this reduction is associated with a similar decrease in the rate of c-jun transcription. Transcriptional down-regulation was also evident in functional assays in which the c-jun gene promoter was approximately 10-fold less active in v-Jun-transformed cells than it was in normal cells. This reduction was largely attributable to a conserved 12-O-tetradecanoylphorbol-13-acetate-responsive element (TRE)-like motif at position -72 (the proximal junTRE) that was essential for efficient basal expression in normal cells but that conferred little, if any, detectable transcriptional activity in v-Jun-transformed cells. DNA-binding analysis showed that this element was recognized by a mixture of c-Jun/Fra and cyclic AMP-responsive element-binding protein/activating transcription factor-like complexes in normal cells but that v-Jun/Fra heterodimers predominated in v-Jun-transformed cells. Furthermore, ectopic expression of v-Jun repressed c-jun promoter activity in normal cells through the proximal junTRE. Thus, the deficit in transcription mediated by the junTRE correlates with and is most likely attributable to binding of v-Jun to this element in vivo. We also find that the c-jun promoter is refractory to induction via the stress-activated protein kinase/c-jun NH2-terminal kinase pathway in v-Jun-transformed cells, suggesting that v-Jun interferes with signal-regulated gene expression. Therefore, c-jun is an example of a cellular gene, the transcription of which is regulated negatively by v-Jun in vivo.

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 delta324, 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 delta324 can neither bind ZF1, repress transcription through this site nor transform Rat1 fibroblasts. Reconstitution studies demonstrate that the defect in delta324 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.

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 v-Jun oncoprotein replaces p39 c-Jun as the predominant AP-1 constituent in ASV17-transformed fibroblasts: implications for SAPK/JNK-mediated signal transduction.

We have investigated the expression of Jun family proteins and composition of AP-1 in chicken embryo fibroblasts before and after transformation by the v-Jun oncoprotein of ASV17. We show that p39 c-Jun is the predominant Jun family protein expressed in normal fibroblasts, and that heterodimers of c-Jun and Fos-related partners (Fra's) account for the majority of the AP-1 DNA binding activity. Unexpectedly, because ASV17-transformed fibroblasts do not express p39 c-Jun, v-Jun replaces c-Jun as the predominant AP-1 constituent in association with similar or identical Fra's. This substitution has little effect on the overall level of TRE-specific DNA binding activity, however it results in a profound reduction in TRE-dependent transcriptional activity and a striking defect in signal-regulated phosphorylation of the Jun component of AP-1; whilst agonists of SAPK/JNK kinases trigger transient N-terminal phosphorylation of c-Jun in normal fibroblasts, no corresponding modification of v-Jun occurs in ASV17-transformed cells. Because SAPK/JNK-mediated phosphorylation is thought to regulate c-Jun transcriptional activity and thereby cellular gene expression in response to extracellular signals, we propose that subversion of this signal transduction process by v-Jun is likely to contribute to oncogenesis by ASV17.

Differential regulation of AP-1 and novel TRE-specific DNA-binding complexes during differentiation of oligodendrocyte-type-2-astrocyte (O-2A) progenitor cells.

AP-1 is an ubiquitous transcription factor which is composed of the Jun and Fos proto-oncogene proteins and is thought to play a role in both cell proliferation and differentiation. We have used an immortal, bipotential oligodendrocyte-type-2 astrocyte progenitor cell line (O-2A/c-myc) which can differentiate into oligodendrocytes or type-2 astrocytes in vitro, to investigate whether AP-1 DNA-binding activity fluctuates during glial cell differentiation. Unexpectedly, DNA-mobility shift assays using a TRE-containing oligonucleotide derived from the promoter of the glial-specific gene, glial fibrillary acidic protein (GFAP/AP-1), revealed that O-2A/c-myc progenitor cells were devoid of conventional AP-1 DNA-binding complexes. O-2A/c-myc cells did however contain several novel GFAP/AP-1-specific DNA-binding complexes, which we have termed APprog. APprog complexes recognise the TRE consensus motif present in the GFAP/AP-1 oligonucleotide together with adjacent 3' sequences but do not contain c-Jun or any other known Jun-related proteins. When O-2A/c-myc cells underwent terminal differentiation APprog complexes were lost and conventional AP-1 DNA-binding activity became evident, particularly in astrocytes. These changes appear to be closely linked to the differentiation process since they did not occur in a derivative of the O-2A/c-myc cell line that contains an activated v-ras oncogene and which fails to differentiate under appropriate culture conditions. The inverse regulation of conventional AP-1 and APprog complexes within the O-2A lineage suggests that these factors may play a role in the regulation of glial cell differentiation or glial cell-specific gene expression.

Transcriptional activation by the v-Jun oncoprotein is independent of positive regulatory phosphorylation.

Growth factors, phorbol esters, and oncogenes such as ras, src, and sis are believed to stimulate c-Jun transcriptional activation by inducing increased phosphorylation at two serine residues (S63 and S73) within the N-terminal transactivation domain. Although S63 and S73 are conserved in the mutant v-Jun oncoprotein, they are not phosphorylated by two enzymes which target the corresponding residues in c-Jun in vitro; namely a partially purified c-Jun kinase from TPA-stimulated U937 cells and purified p54 mitogen activated protein (MAP) kinase. In addition, v-Jun activates transcription more strongly than c-Jun when fused to the Gal4 DNA-binding domain, and transcriptional activation by Gal4-v-Jun is unaffected when S63, S73, or both, are replaced with non-phosphorylatable alanine residues, amino acid substitutions which severely impair transcriptional activation by Gal4-c-Jun. The novel biochemical and transcriptional properties of v-Jun result from deletion of a 27 amino acid segment, termed delta, which is important for transforming activity. On the basis of these results we propose that unlike c-Jun, v-Jun transcriptional activation is independent of positive regulatory phosphorylation and that this may contribute to oncogenesis by v-Jun.