Tumor suppressor p53 protects cells from genomic insults and is a target of mutation in more than 50% of human cancers. Stress-mediated modification and increased stability of p53 promote p53 interaction with chromatin, which results in transcription of target genes that are critical for the maintenance of genomic integrity. We recently discovered that TRIM24, an E3-ubiquitin ligase, ubiquitinates and promotes proteasome-mediated degradation of p53. Here, we show that TRIM24 is destabilized by ATM-mediated phosphorylation of TRIM24S768 in response to DNA damage, which disrupts TRIM24-p53 interactions and promotes the degradation of TRIM24. Transcription of TRIM24 is directly induced by damage-activated p53, which binds p53 response elements and activates expression of TRIM24. Newly synthesized TRIM24 interacts with phosphorylated p53 to target it for degradation and termination of the DNA damage response. These studies indicate that TRIM24, like MDM2, controls p53 levels in an autoregulatory feedback loop. However, unlike MDM2, TRIM24 also targets activated p53 to terminate p53-regulated response to DNA damage. Tumor suppressor p53 maintains the genomic integrity of a cell in response to a variety of cellular stresses, including DNA damage, oncogenic stress, telomere dysfunction, and hypoxia (1-3). When exposed to stress stimuli, p53 acts as a central relay to determine how the cells respond, whether by apoptosis, cell cycle arrest, senescence, DNA repair, shifts in cell metabolism, or autophagy (4). Multiple signaling pathways converge on p53 to control its protein stability and activities, primarily by posttranslational modifications (PTMs) of p53 at specific amino acid residues (5-7). One of the major pathways that negatively regulate p53 protein stability is the ubiquitin-proteasome system, which adds polymerized chains of ubiquitin to p53 to target it for degradation (8, 9). The importance of this mechanism for cellular homeostasis is illustrated by p53-dependent embryonic lethality with germ line deletion of murine Mdm2 (10), the first identified E3-ubiquitin ligase for p53 (11-13). However, a striking observation is that p53 degradation occurs even in Mdm2-deficient mouse tissues during cellular recovery after DNA damage (14). In addition, a recent report suggests that the p53-MDM2 feedback loop is dispensable for p53 stability after DNA damage in vivo (15). This suggested that a negative-feedback loop, which controls p53 protein levels, remains operable even in the absence of Mdm2. A collection of more than 15 E3-ubiquitin ligases that directly regulate p53 stability, including Pirh2, COP1, ARF-BP1 and others, are now known (16-18). These ligases stimulate p53 ubiquitination and degradation by directly modifying lysine residues, but their specific or redundant roles in regulation of p53 and how they themselves are regulated remain largely unknown.We found that TRIM24 was an E3-ubiquitin ligase that negatively regulates p53 by directly targeting p53 for ubiquitination via a conserved RING domain (19). TRI...
Conditional overexpression of histone reader Tripartite motif containing protein 24 (TRIM24) in mouse mammary epithelia (Trim24COE) drives spontaneous development of mammary carcinosarcoma tumors, lacking ER, PR and HER2. Human carcinosarcomas or metaplastic breast cancers (MpBC) are a rare, chemorefractory subclass of triple-negative breast cancers (TNBC). Comparison of Trim24COE metaplastic carcinosarcoma morphology, TRIM24 protein levels and a derived Trim24COE gene signature reveals strong correlation with human MpBC tumors and MpBC patient-derived xenograft (PDX) models. Global and single-cell tumor profiling reveal Met as a direct oncogenic target of TRIM24, leading to aberrant PI3K/mTOR activation. Here, we find that pharmacological inhibition of these pathways in primary Trim24COE tumor cells and TRIM24-PROTAC treatment of MpBC TNBC PDX tumorspheres decreased cellular viability, suggesting potential in therapeutically targeting TRIM24 and its regulated pathways in TRIM24-expressing TNBC.
The RNA-binding proteins, FUS, EWSR1, and TAF15 (FET protein family) are frequently fused to transcription factors, and the resulting oncogenic fusion proteins characterize various sarcomas. These fusion proteins act as aberrant transcription factors and promote oncogenic gene expression profiles. FET family rearranged sarcomas include Ewing Sarcoma, desmoplastic round cell tumors, myxoid liposarcoma, and clear cell sarcoma, amongst others. A growing body of work suggests that, independently of Lysine Specific Demethylase 1 (LSD1) demethylase activity, LSD1’s association with FET family oncogenic transcription factors is critical for FET-rearranged sarcoma development and progression. Extensive ongoing work aims to characterize the functional relationship of LSD1 and EWS/FLI, as well as the anti-tumor effect of disrupting that interaction. SP-2577 is an oral, first-in-class, small molecule with reversible, noncompetitive inhibition of LSD1 demethylase activity (IC50: 25–50 nM) and, importantly, also disrupts LSD1 protein-protein interactions. In vitro and in vivo data demonstrate SP-2577, or analogs, reverses EWS/ETS-mediated transcriptional regulation at both up- and downregulation target genes, leading to significant tumor growth inhibition in Ewing Sarcoma mouse xenograft studies. In this study, we set out to expand our understanding of SP-2577’s efficacy in diverse FET-rearranged malignancies including desmoplastic small round cell tumor (DSCRT: EWSR1/WT1), myxoid liposarcoma (ML: FUS/DDIT3), and clear cell sarcoma (CCS: EWS/ATF1). To examine whether these additional FET-rearranged sarcomas are sensitive to LSD1 scaffolding inhibition, we measured viability of Ewing sarcoma cells A673, TC32, TTC-446, and SK-N-MC, clear cell sarcoma cell lines SU-CCS-1, DTC-1, myxoid liposarcoma cell lines DL-221, 402-91, and 1765-92, and DSCRT patient derived xenograft organoids from SJDSRCT046151, X0069, SJDSRCT046155 after 96 hours of treatment with the clinical compound SP-2577, a first generation compound SP-2509, an inactive control, SP2513, and, a TCP-scaffold based, irreversible inhibitor of LSD1, OG-L002. While SP-2513 and OG-L002 had no activity against these cells SP-2509 and SP-2577 demonstrated potent activity across cell lines in vitro. Preliminary in vivo assessment of SP-2577 efficacy in DSCRT PDX SJDSRCT046151 resulted in a significant delay in time to event (p<0.02). Together, these data demonstrate that the unique scaffolding inhibition function of SP-2577 is essential for reducing cell viability through LSD1 targeting. Currently, we are elucidating changes to the transcriptome and proteome following SP-2577 treatment, in vitro. These data, in combination with results from the ongoing dose expansion phase 1 trial of SP-2577 in select sarcoma patients, may offer further mechanistic insight into the dependency of FET-rearranged sarcomas on LSD1 scaffolding functions and potentially lead to identifying biomarkers of sensitivity and response. Citation Format: Galen Rask, Emily R. Theisen, Aundrietta D. Duncan, Daniela Y. Santiesteban. Targeting LSD1 protein scaffolding function in FET-rearranged sarcomas with SP-2577 [abstract]. In: Proceedings of the AACR-NCI-EORTC Virtual International Conference on Molecular Targets and Cancer Therapeutics; 2021 Oct 7-10. Philadelphia (PA): AACR; Mol Cancer Ther 2021;20(12 Suppl):Abstract nr P087.
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