Constitutive c-ets2 expression in M1D+ myeloblast leukemic cells induces their differentiation to macrophages.

The expression of c-ets2 is rapidly induced in a variety of myelomonocytic cell lines as they differentiate into macrophages. We find that constitutive expression of c-ets2 in the M1D+ myeloblast leukemic cell line (M1ets2) is sufficient to push these cells to a more differentiated state. The expression of several differentiation-specific genes is upregulated in M1ets2 cells, including those encoding macrophage-specific lysozyme M and tumor necrosis factor alpha, which are involved in bacteriolytic and inflammatory processes, respectively. Transcription factors c-jun and junB, previously shown to induce partial macrophage differentiation when overexpressed in myelomonocytic leukemia cell lines, are also upregulated in M1ets2 cells. The upregulation of junB is the result of a direct interaction of Ets2 with ets binding sites of the junB promoter, since transient or constitutive Ets2 expression in M1D+ cells activates junB transcription via ets binding sites. In addition, transfection of a dominant negative mutant of Ets2, devoid of its transcriptional activation domain, greatly reduces transcriptional activities of the junB promoter in M1ets2 cells. Finally, unlike their parental M1D+ counterparts, M1ets2 cells secrete the macrophage colony-stimulating factor, CSF-1, and are able to phagocytize. Taken together, these results show that when the immature myeloid M1D+ cell line constitutively expresses c-ets2, these cells acquire different functions of mature macrophages.

The Ets2 transcription factor inhibits apoptosis induced by colony-stimulating factor 1 deprivation of macrophages through a Bcl-xL-dependent mechanism.

Bcl-xL, a member of the Bcl-2 family, inhibits apoptosis, and its expression is regulated at the transcriptional level, yet nothing is known about the transcription factors specifically activating this promoter. The bcl-x promoter contains potential Ets binding sites, and we show that the transcription factor, Ets2, first identified by its sequence identity to v-ets of the E26 retrovirus, can transactivate the bcl-x promoter. Transient expression of Ets2 results in the upregulation of Bcl-xL but not of Bcl-xS, an alternatively spliced gene product which induces apoptosis. Ets2 is ubiquitously expressed at low levels in a variety of cell types and tissues but is specifically induced to abundant levels during macrophage differentiation. Since Bcl-xL is also upregulated during macrophage differentiation, we asked whether the bcl-x could be a direct downstream target gene of Ets2 in macrophages. BAC1.2F5 macrophages, which are dependent on macrophage colony-stimulating factor 1 (CSF-1) for their growth and survival, were used in these studies. We show that CSF-1 stimulation of BAC1.2F5 macrophages results in the upregulation of expression of ets2 and bcl-xL with similar kinetics of induction. In the absence of CSF-1, these macrophages undergo cell death by apoptosis, whereas constitutive expression of Ets2 rescues these cells from cell death, and bcl-xL is upregulated. These results strongly suggest a novel role of Ets2 in affecting apoptosis through its regulation of Bcl-xL transcription.

Cross-family interaction between the bHLHZip USF and bZip Fra1 proteins results in down-regulation of AP1 activity.

Heterodimerization among the basic-leucine zipper (bZIP) proteins or among the basic-helix-loop-helix-leucine zipper (bHLHZip) proteins confers a multitude of combinational activities to these transcription factors. To further examine the function of the bHLHZip protein, USF, we screened for cellular proteins which could directly interact with USF using the yeast two-hybrid system. A bZip protein, Fra1, was found to efficiently interact with USF. USF specifically interacts with Fra1 but not with other closely related family members, c-Fos, Fra2, FosB, or with c-Jun. Both the bHLHZip and the N-terminal regions of Fra1 are required for efficient interaction with USF. In vivo association between USF and Fra1 has been demonstrated by co-immunoprecipitation. Expression of exogenous USF led to a decrease in AP1-dependent transcription in F9 cells. Co-expression of exogenous Fra1 restored the AP1 activity in a dose-dependent manner. These data show that USF and Fra1 physically and functionally interact demonstrating that cross-talk occurs between factors of distantly related transcription families.

cDNA cloning and characterization of the transcriptional activities of the hamster peroxisome proliferator-activated receptor haPPAR gamma.

We have isolated a cDNA corresponding to the hamster peroxisome proliferator-activated receptor haPPAR gamma, a member of the steroid nuclear hormone receptor superfamily of transcription factors. haPPAR gamma mRNA is highly expressed in adipose tissue, and is expressed in lung, heart, kidney, liver and spleen to a lower extent. Thus, haPPAR gamma may function in activating the transcription of target genes in a variety of tissues, including those not particularly subjected to peroxisomal beta-oxidation. haPPAR gamma binds efficiently in the presence of retinoid X receptor alpha (RXR alpha) to a peroxisome proliferator response element (PPRE) first identified in the acyl-CoA oxidase (ACO) promoter, the rate-limiting enzyme of peroxisomal beta-oxidation. The gene (ACO) encoding this enzyme has been previously shown to be under the transcriptional control of mouse PPAR (mPPAR). Although binding of haPPAR gamma/RXR alpha on the PPRE of the ACO promoter in vitro is similar to that observed for mPPAR/RXR alpha, we show that the transcriptional activities of mPPAR and haPPAR gamma are regulated differently in vivo in response to peroxisome proliferators and heterodimerization with RXR.

The basic region/helix-loop-helix/leucine repeat transcription factor USF interferes with Ras transformation.

Upstream stimulatory factor (USF) is a transcription factor of the basic region/helix-loop-helix/leucine repeat family. It shares the same DNA-binding sequence as the myc oncogene. Based on the three-dimensional structures, its DNA-binding domain is structurally related to that of Max, the partner of Myc. In addition, USF can form heterodimers with a related factor, Fos-interacting protein/upstream stimulatory factor 2 (FIP/USF2), which has been shown to directly interact with Fos. In view of the provocative relationship of USF with other factors involved in cell proliferation, we investigated whether USF could also play a role in cellular growth control. In this study, we report that USF is not an oncogene, but interferes with Ras-driven transformation. This inhibitory effect is independent of USF transactivating domains, but requires its DNA-binding activity. However, the minimal USF DNA-binding domain does not display this inhibitory effect, and even slightly enhances Ras transformation. On the basis of these data, we propose that USF may play an important role in the control of cell growth and proliferation, through both binding to promoter sequences and specific protein/protein interactions.

Complete sequencing of the murine USF gene and comparison of its genomic organization to that of mFIP/USF2.

USF is a transcription factor able to stimulate promoter activity upon binding to an upstream sequence identical to that recognized by the protooncogene Myc. However, despite extensive biochemical characterization, nothing is known concerning its physiological function. A USF-related protein able to interact with Fos and known as FIP/USF2 has been reported. Its genomic structure in mouse has been recently characterized. We present here the cloning and characterization of the murine USF gene. It consists of 10 exons, the first of which is noncoding, and the gene spans 8 kb of DNA. We show that the murine USF protein is almost identical to its human counterpart, but that an intron not conserved between human and murine USF genes curiously has been conserved between human USF and murine FIP/USF2. Otherwise, the splicing pattern of murine USF and FIP/USF2 is exactly conserved. We also demonstrate that the murine USF promoter is located more than 2.5 kb upstream of the first coding ATG, in a region displaying divergent promoter activity. Finally, we show that an Mx1-related sequence is present less than 3 kb downstream of the murine USF gene, in a tail-to-tail position. Taken together, these data indicate that the murine USF gene is very similar to the murine FIP/USF2 gene and is potentially bracketed by two other transcription units on the other DNA strand.

Synergistic effects of colony-stimulating factor 1 and leukemia inhibitory factor in inducing early myeloid cell differentiation.

Cells of the M1D+ murine myeloid leukemic cell line differentiate into macrophages in response to either leukemia inhibitory factor (LIF) or interleukin 6. Previously, it was shown that LIF treatment of M1D+ cells leads to an increased expression of colony-stimulating factor (CSF) receptor mRNA encoded by c-fms. CSF-1, a macrophage growth factor, induces the survival, growth, and differentiation of mononuclear phagocytes but has not been implicated in the regulation of early myeloid cell differentiation. Here we show that low-dose LIF treatment of M1D+ cells results in CSF-1 secretion and CSF-1 receptor up-regulation. CSF-1, when applied alone, induces some M1D+ adherence and the up-regulation of lysozyme M, a macrophage-specific marker. Finally, we show that when applied together, LIF and CSF-1 act synergistically to induce macrophage morphology, phagocytosis, and the expression of the macrophage-specific markers CD11b/Mac-1 alpha chain, lysozyme M, FcgammaRII, and JE/MCP.1. These results indicate that instead of being part of exclusive pathways, as thought until this work, LIF and CSF-1 can function synergistically to further stimulate the early stages of myeloid differentiation.