With the emerging role of NF-kappa B in cancer it is important that its responses to stimuli relevant to tumor progression and therapy are understood. Here, we demonstrate that NF-kappa B induced by cytotoxic stimuli, such as ultraviolet light (UV-C) and the chemotherapeutic drugs daunorubicin/doxorubicin, is functionally distinct to that seen with the inflammatory cytokine TNF and is an active repressor of antiapoptotic gene expression. Surprisingly, these effects are mediated by the RelA(p65) NF-kappa B subunit. Furthermore, UV-C and daunorubicin inhibit TNF-induced NF-kappa B transactivation, indicating that this is a dominant effect. Consistent with this, mechanistic studies reveal that UV-C and daunorubicin induce the association of RelA with histone deacetylases. RelA can therefore be both an activator and repressor of its target genes, dependent upon the manner in which it is induced. This has important implications for the role of NF-kappa B in tumorigenesis and the use of NF-kappa B inhibitors in cancer therapy.
Maddocks, O. D. K. et al. (2017) Modulating the therapeutic response of tumours to dietary serine and glycine starvation. Nature, 544(7650), pp. 372-376.There may be differences between this version and the published version. You are advised to consult the publisher's version if you wish to cite from it.http://eprints.gla.ac.uk/140432/ AbstractThe non-essential amino acids serine and glycine are used in multiple anabolic processes that support cancer cell growth and proliferation (reviewed in ref. 1). While some cancer cells upregulate de novo serine synthesis 2,3,4 , many others rely on exogenous serine for optimal growth 5,6,7 . Restriction of dietary serine and glycine can reduce tumour growth in xenograft and allograft models 7,8 . Here we show that this observation translates into more clinically relevant autochthonous tumours in genetically engineered mouse models of intestinal cancer (driven by Apc inactivation) or lymphoma (driven by Myc activation). The increased survival following dietary restriction of serine and glycine in these models was further improved by antagonizing the anti-oxidant response. Disruption of mitochondrial oxidative phosphorylation (using biguanides) led to a complex response that could improve or impede the anti-tumour effect of serine and glycine starvation. Notably, Krasdriven mouse models of pancreatic and intestinal cancers were less responsive to depletion of serine and glycine, reflecting an ability of activated Kras to increase the expression of enzymes that are part of the serine synthesis pathway and thus promote de novo serine synthesis.To assess the effect of dietary serine and glycine (SG) restriction in autochthonous tumour models, we used genetically engineered mouse models (GEMMs) of lymphoma (Eμ-Myc) and intestinal tumours (defective Apc). Eμ-Myc mice develop pre-neoplastic lesions within 28-42 days after birth 9 , and adenoma initiation is evident days after birth in Apc Min/+ mice 10 . Accordingly, Apc Min/+ mice carried high tumour numbers at 80 days, which subsequently increased in size but not number (Extended Data Fig. 1a). Transferring mice from normal chow diet to experimental diets 60-80 days after birth showed that an SG-free diet significantly extended survival in these models carrying pre-malignant lesions (Fig. 1a, b), with a slightly lower tumour burden in Apc Min/+ mice on the SG-free diet at clinical end point (Extended Data Fig. 1a). The diet reproducibly decreased serum SG from around 150 μM to 65 μM (Fig. 1c-e), while showing minimal or inconsistent impact on other amino acids, glucose and lactate (Fig. 1c, d and Extended Data Figs 1b, 2a, b), These results were further validated using an inducible intestinal tumour model (Lgr5-creER;Apc fl/fl ); transferring mice to the SG-free diet a week after induction. Again, the experimental diet caused a significant increase in survival compared to control diet (containing purified amino acids) or normal chow (containing whole protein as a source of amino acids) (Fig. 1f). (c, control, n = 14; control,...
The ability of a cell to undergo mitochondrial apoptosis is governed by pro- and anti-apoptotic members of the BCL-2 protein family. The equilibrium of pro- versus anti-apoptotic BCL-2 proteins ensures appropriate regulation of programmed cell death during development and maintains organismal health. When unbalanced, the BCL-2 family can act as a barrier to apoptosis and facilitate tumour development and resistance to cancer therapy. Here we discuss the BCL-2 family, their deregulation in cancer and recent pharmaceutical developments to target specific members of this family as cancer therapy.
One mechanism by which a cell affords protection from the transforming effects of oncogenes is via the action of the tumor suppressor, ARF, which activates p53 by inactivating Mdm2. Many oncogenes have also been shown to activate the transcription factor NF-kappa B, which can contribute toward the malignant phenotype in many ways, including an ability to antagonize p53. Here we find that ARF inhibits NF-kappa B function and its antiapoptotic activity independent of Mdm2 and p53. ARF represses the transcriptional activation domain of the NF-kappa B family member RelA by inducing its association with the histone deacetylase, HDAC1. Further, we show that the response of NF-kappa B to the oncogene Bcr-Abl is determined by the ARF status of the cell. These results reveal an important function of ARF that can regulate the NF-kappa B response to oncogene activation.
The budding yeast spindle pole body (SPB) not only organizes the astral and nuclear microtubules but is also associated with a number of cell-cycle regulators that control mitotic exit. Here, we describe that the core SPB component Nud1p is a key protein that functions in both processes. The astral microtubule organizing function of Nud1p is mediated by its interaction with the g-tubulin complex binding protein Spc72p. This function of Nud1p is distinct from its role in cellcycle control: Nud1p binds the spindle checkpoint control proteins Bfa1p and Bub2p to the SPB, and is part of the mitotic exit network (MEN) in which it functions upstream of CDC15 but downstream of LTE1. In conditional lethal nud1-2 cells, the MEN component Tem1p, a GTPase, is mislocalized, whereas the kinase Cdc15p is still associated with the SPB. Thus, in nud1-2 cells the failure of Tem1p to interact with Cdc15p at the SPB probably prevents mitotic exit. Keywords: Cdc15p/mitotic exit network/Nud1p/spindle pole body/Tem1p
The ARF tumour suppressor is a central component of the cellular defence against oncogene activation. In addition to activating p53 through binding Mdm2, ARF possesses other functions, including an ability to repress the transcriptional activity of the antiapoptotic RelA(p65) NF‐κB subunit. Here we demonstrate that ARF induces the ATR‐ and Chk1‐dependent phosphorylation of the RelA transactivation domain at threonine 505, a site required for ARF‐dependent repression of RelA transcriptional activity. Consistent with this effect, ATR and Chk1 are required for ARF‐induced sensitivity to tumour necrosis factor α‐induced cell death. Significantly, ATR activity is also required for ARF‐induced p53 activity and inhibition of proliferation. ARF achieves these effects by activating ATR and Chk1. Furthermore, ATR and its scaffold protein BRCA1, but not Chk1, relocalise to specific nucleolar sites. These results reveal novel functions for ARF, ATR and Chk1 together with a new pathway regulating RelA NF‐κB function. Moreover, this pathway provides a mechanism through which ARF can remodel the cellular response to an oncogenic challenge and execute its function as a tumour suppressor.
The BH3-mimetic ABT-737 and an orally bioavailable compound of the same class, navitoclax (ABT-263), have shown promising antitumor efficacy in preclinical and early clinical studies. Although both drugs avidly bind Bcl-2, Bcl-x L , and Bcl-w in vitro, we find that Bcl-2 is the critical target in vivo, suggesting that patients with tumors overexpressing Bcl-2 will probably benefit. In human non-Hodgkin lymphomas, high expression of Bcl-2 but not Bcl-x L predicted sensitivity to ABT-263. Moreover, we show that increasing Bcl-2 sensitized normal and transformed lymphoid cells to ABT-737 by elevating proapoptotic Bim. In striking contrast, increasing Bcl-x L or Bcl-w conferred robust resistance to ABT-737, despite also increasing Bim. Cell-based protein redistribution assays unexpectedly revealed that ABT-737 disrupts Bcl-2/Bim complexes more readily than Bcl-x L /Bim or Bcl-w/Bim complexes. These results have profound implications for how BH3-mimetics induce apoptosis and how the use of these compounds can be optimized for treating lymphoid malignancies. (Blood. 2012;119(24):5807-5816) IntroductionDefects in the mitochondrial apoptotic pathway regulated by the Bcl-2 family of proteins play a major role in cancer development and in conferring chemoresistance. 1 Within the family, Bax and Bak are essential for mitochondrial membrane permeabilization and cell death. 2 Prosurvival proteins (Bcl-2, Bcl-x L , Bcl-w, Mcl-1, A1) oppose Bax and Bak and ensure mitochondrial integrity and cell survival. 1 These prosurvival proteins also interact with distant relatives that share only 1 Bcl-2 Homology region, BH3, that is critical for their proapoptotic function. The BH3-only proteins such as Bim, Bad, Puma, and Noxa act as stress sensors and relieve the inhibition of Bax and Bak by the prosurvival proteins.The clinical efficacy of most anticancer therapeutics primarily reflects their ability to induce apoptosis. Resistance to conventional anticancer therapeutics (eg, etoposide) is often because of a failure to activate BH3-only proteins, for example because of mutation of the tumor suppressor p53, which is critical for transcriptional induction of Puma and Noxa after DNA damage. 3 Overexpression of prosurvival Bcl-2 proteins, or silencing of BH3-only protein expression, are also associated with inferior therapeutic outcomes. 4,5 BH3-mimetic drugs, such as ABT-737, were developed to directly counter such apoptotic blocks. ABT-737 binds avidly to Bcl-2, Bcl-x L , and Bcl-w, but not Mcl-1 or A1. 6,7 In preclinical studies, it demonstrated single agent efficacy against tumors with low Mcl-1 or A1 levels, such as follicular lymphoma (FL), chronic lymphocytic leukemia (CLL), and small cell lung carcinoma (SCLC). ABT-737 shows limited toxicity toward normal cells, although there is transient reduction of platelets and lymphocytes. 6,8 , an orally bioavailable compound in the same class with similar target specificity, also exhibited efficacy in various cancer-derived cell lines both in vitro and in vivo, 6,9,10 and is undergoing p...
Analysis of publicly available genomic and gene expression data demonstrates that MCL1 expression is frequently elevated in breast cancer. Distinct from other pro-survival Bcl-2 family members, the short half-life of MCL-1 protein led us to investigate MCL-1 protein expression in a breast cancer tissue microarray and correlate this with clinical data. Here, we report associations between high MCL-1 and poor prognosis in specific subtypes of breast cancer including triple-negative breast cancer, an aggressive form that lacks targeted treatment options. Deletion of MCL-1 in the mammary epithelium of genetically engineered mice revealed an absolute requirement for MCL-1 in breast tumorigenesis. The clinical applicability of these findings was tested through a combination of approaches including knock-down or inhibition of MCL-1 to show triple-negative breast cancer cell line dependence on MCL-1 in vitro and in vivo. Our data demonstrate that high MCL-1 protein expression is associated with poor outcome in breast cancer and support the therapeutic targeting of MCL-1 in this disease.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
Contact Info
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Product
Resources
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.
