The Bcl-2 family proteins are key regulators of apoptosis in human diseases and cancers. Though known to block apoptosis, Bcl-2 promotes cell death through an undefined mechanism. Here, we show that Bcl-2 interacts with orphan nuclear receptor Nur77 (also known as TR3), which is required for cancer cell apoptosis induced by many antineoplastic agents. The interaction is mediated by the N-terminal loop region of Bcl-2 and is required for Nur77 mitochondrial localization and apoptosis. Nur77 binding induces a Bcl-2 conformational change that exposes its BH3 domain, resulting in conversion of Bcl-2 from a protector to a killer. These findings establish the coupling of Nur77 nuclear receptor with the Bcl-2 apoptotic machinery and demonstrate that Bcl-2 can manifest opposing phenotypes, induced by interactions with proteins such as Nur77, suggesting novel strategies for regulating apoptosis in cancer and other diseases.
TR3, an immediate-early response gene and an orphan member of the steroid-thyroid hormone-retinoid receptor superfamily of transcription factors, regulates apoptosis through an unknown mechanism. In response to apoptotic stimuli, TR3 translocates from the nucleus to mitochondria to induce cytochrome c release and apoptosis. Mitochondrial targeting of TR3, but not its DNA binding and transactivation, is essential for its proapoptotic effect. Our results reveal a mechanism by which a nuclear transcription factor translocates to mitochondria to initiate apoptosis.
Thyroid hormones and retinoic acid function through nuclear receptors that belong to the steroid/thyroid-hormone receptor superfamily. Thyroid hormone receptors (TRs) and retinoic acid receptors (RARs) require auxiliary nuclear proteins for efficient DNA binding. Here we report that retinoid X receptors RXR alpha is one of these nuclear proteins. RXR alpha interacts both with TRs and with RARs, forming heterodimers in solution that strongly interact with a variety of T3/retinoic acid response elements. Transfection experiments show that RXR alpha can greatly enhance the transcriptional activity of TR and RAR at low retinoic acid concentrations that do not significantly activate RXR alpha itself. Thus, RXR alpha enhances the transcriptional activity of other receptors and its own ligand sensitivity by heterodimer formation. Our studies reveal a new subclass of receptors and a regulatory pathway controlling nuclear receptor activities by heterodimer formation.
Retinoid response pathways are mediated by two classes of receptors, the retinoic acid receptors (RARs) and the retinoid X receptors (RXRs). A central question is whether distinct response pathways are regulated by these two classes of receptors. The observation that the stereoisomer 9-cis-retinoic acid binds with high affinity to RXRs suggested that this retinoid has a distinct role in controlling RXR activity, but it was almost simultaneously discovered that RXRs function as auxiliary receptors for RARs and related receptors, and are essential for DNA binding and function of those receptors. Hence, although RARs seem to operate effectively only as heterodimeric RAR/RXR complexes, RXRs themselves apparently function predominantly, if not exclusively, as auxiliary receptors. Here we report that 9-cis-retinoic acid induces RXR homodimer formation. Our results demonstrate a new mechanism for retinoid action by which a ligand-induced homodimer mediates a distinct retinoid response pathway.
Retinoids are known to inhibit the growth of hormone-dependent but not that of hormone-independent breast cancer cells. We investigated the involvement of retinoic acid (RA) receptors (RARs) in the differential growth-inhibitory effects of retinoids and the underlying mechanism. Our data demonstrate that induction of RAR by RA correlates with the growth-inhibitory effect of retinoids. The hormone-independent cells acquired RA sensitivity when the RAR expression vector was introduced and expressed in the cells. In addition, RA sensitivity of hormone-dependent cells was inhibited by a RAR-selective antagonist and the expression of RAR antisense RNA. Introduction of RAR␣ also restored RA sensitivity in hormone-independent cells, but this restoration was accomplished by the induction of endogenous RAR expression. Furthermore, we show that induction of apoptosis contributes to the growth-inhibitory effect of RAR. Thus, RAR can mediate retinoid action in breast cancer cells by promoting apoptosis. Loss of RAR, therefore, may contribute to the tumorigenicity of human mammary epithelial cells.
SUMMARY Non-steroidal anti-inflammatory drugs (NSAIDs) exert their anti-cancer effects through cyclooxygenase-2 (COX-2)-dependent and -independent mechanisms. Here we report that Sulindac, an NSAID, induces apoptosis by binding to retinoid X receptor-α (RXRα). We identified an N-terminally-truncated RXRα (tRXRα) in several cancer cell lines and primary tumors, which interacted with the p85α subunit of phosphatidylinositol-3-OH kinase (PI3K). Tumor necrosis factor-α (TNFα) promoted tRXRα interaction with the p85α, activating PI3K/AKT signaling. When combined with TNFα, Sulindac inhibited TNFα-induced tRXRα/p85α interaction, leading to activation of the death receptor-mediated apoptotic pathway. We designed and synthesized a Sulindac analog K-80003, which has increased affinity to RXRα but lacks COX inhibitory activity. K-80003 displayed enhanced efficacy in inhibiting tRXRα-dependent AKT activation and tRXRα tumor growth in animals.
TR3, also known as NGFI-B or nur77, is an immediate-early response gene and an orphan member of the steroid/thyroid/retinoid receptor superfamily. We previously reported that TR3 expression was induced by apoptotic stimuli and was required for their apoptotic effect in lung cancer cells. Here, we present evidence that TR3 was also induced by epidermal growth factor (EGF) and serum and was required for their mitogenic effect in lung cancer cells. Ectopic expression of TR3 in both H460 and Calu-6 lung cancer cell lines promoted their cell cycle progression and BrdU incorporation, while inhibition of TR3 expression by the small interfering RNA approach suppressed the mitogenic effect of EGF and serum. Analysis of TR3 mutants showed that both TR3 DNA binding and transactivation were required for its mitogenic effect. In contrast, they were dispensable for its apoptotic activity. Furthermore, confocal microscopy analysis demonstrated that TR3 functioned in the nucleus to induce cell proliferation, whereas it acted on mitochondria to induce apoptosis. In examining the signaling that regulates the mitogenic function of TR3, we observed that coexpression of constitutive-active MEKK1 inhibited TR3 transcriptional activity and TR3-induced proliferation. The inhibitory effect of MEKK1 was mediated through activation of Jun N-terminal kinase, which efficiently phosphorylated TR3, resulting in loss of its DNA binding. Together, our results demonstrate that TR3 is capable of inducing both proliferation and apoptosis in the same cells depending on the stimuli and its cellular localization.TR3 (also known as NGFI-B and nur77) (6,17,44), an immediate-early response gene, is an orphan member of the steroid/thyroid/retinoid receptor superfamily, whose members mainly act as transcriptional factors to positively or negatively regulate gene expression (22,41,67). The role of TR3 in cell proliferation was suggested by numerous observations showing that its expression is rapidly induced by several mitogenic inducers, including serum growth factor, epidermal growth factor (EGF), and fibroblast growth factor (6,9,13,17,35,44,58). However, whether TR3 expression has a causal role in promoting cell proliferation remains to be illustrated. Recent evidence also indicates that the expression of TR3 is required for apoptosis. TR3 was rapidly induced by T-cell receptor signaling in immature thymocytes and T-cell hybridomas (39, 60). Overexpression of a dominant-negative TR3 protein (60) or inhibition of TR3 expression by antisense TR3 mRNA (39) inhibited T-cell-receptor-induced apoptosis, whereas constitutive expression of TR3 resulted in massive cell death (57, 64).
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