Functions of BCL-X L at the Interface between Cell Death and Metabolism

The BCL-2 homolog BCL-X L , one of the two protein products of BCL2L1, has originally been characterized for its prominent prosurvival functions. Similar to BCL-2, BCL-X L binds to its multidomain proapoptotic counterparts BAX and BAK, hence preventing the formation of lethal pores in the mitochondrial outer membrane, as well as to multiple BH3-only proteins, thus interrupting apical proapoptotic signals. In addition, BCL-X L has been suggested to exert cytoprotective functions by sequestering a cytosolic pool of the pro-apoptotic transcription factor p53 and by binding to the voltage-dependent anion channel 1 (VDAC1), thereby inhibiting the so-called mitochondrial permeability transition (MPT). Thus, BCL-X L appears to play a prominent role in the regulation of multiple distinct types of cell death, including apoptosis and regulated necrosis. More recently, great attention has been given to the cell death-unrelated functions of BCL-2-like proteins. In particular, BCL-X L has been shown to modulate a number of pathophysiological processes, including-but not limited to-mitochondrial ATP synthesis, protein acetylation, autophagy and mitosis. In this short review article, we will discuss the functions of BCL-X L at the interface between cell death and metabolism

Functions of BCL-X L

The BCL-2 homolog BCL-XL, one of the two protein products of BCL2L1, has originally been characterized for its prominent prosurvival functions. Similar to BCL-2, BCL-XL binds to its multidomain proapoptotic counterparts BAX and BAK, hence preventing the formation of lethal pores in the mitochondrial outer membrane, as well as to multiple BH3-only proteins, thus interrupting apical proapoptotic signals. In addition, BCL-XL has been suggested to exert cytoprotective functions by sequestering a cytosolic pool of the pro-apoptotic transcription factor p53 and by binding to the voltage-dependent anion channel 1 (VDAC1), thereby inhibiting the so-called mitochondrial permeability transition (MPT). Thus, BCL-XL appears to play a prominent role in the regulation of multiple distinct types of cell death, including apoptosis and regulated necrosis. More recently, great attention has been given to the cell death-unrelated functions of BCL-2-like proteins. In particular, BCL-XL has been shown to modulate a number of pathophysiological processes, including—but not limited to—mitochondrial ATP synthesis, protein acetylation, autophagy and mitosis. In this short review article, we will discuss the functions of BCL-XL at the interface between cell death and metabolism

Novel Agonist Bioisosteres and Common Structure-Activity Relationships for The Orphan G Protein-Coupled Receptor GPR139

GPR139 is an orphan class A G protein-coupled receptor found mainly in the central nervous system. It has its highest expression levels in the hypothalamus and striatum, regions regulating metabolism and locomotion, respectively, and has therefore been suggested as a potential target for obesity and Parkinson’s disease. The two aromatic amino acids (L)-Trp and (L)-Phe have been proposed as putative endogenous agonists, and three structurally related benzohydrazide, glycine benzamide, and benzotriazine surrogate agonist series have been published. Herein, we assayed 158 new analogues selected from a pharmacophore model, and identified 12 new GPR139 agonists, containing previously untested bioisosteres. Furthermore, we present the first combined structure-activity relationships, and a refined pharmacophore model to serve as a rationale for future ligand identification and optimization

EML4-ALK induces cellular senescence in mortal normal human cells and promotes anchorage-independent growth in hTERT-transduced normal human cells

Background: Chromosomal inversions involving anaplastic lymphoma kinase (ALK) and echinoderm microtubule associated protein like 4 (EML4) generate a fusion protein EML4-ALK in non-small cell lung cancer (NSCLC). The understanding of EML4-ALK function can be improved by a functional study using normal human cells. Methods: Here we for the first time conduct such study to examine the effects of EML4-ALK on cell proliferation, cellular senescence, DNA damage, gene expression profiles and transformed phenotypes. Results: The lentiviral expression of EML4-ALK in mortal, normal human fibroblasts caused, through its constitutive ALK kinase activity, an early induction of cellular senescence with accumulated DNA damage, upregulation of p16INK4A and p21WAF1, and senescence-associated β-galactosidase (SA-β-gal) activity. In contrast, when EML4-ALK was expressed in normal human fibroblasts transduced with telomerase reverse transcriptase (hTERT), which is activated in the vast majority of NSCLC, the cells showed accelerated proliferation and acquired anchorage-independent growth ability in soft-agar medium, without accumulated DNA damage, chromosome aberration, nor p53 mutation. EML4-ALK induced the phosphorylation of STAT3 in both mortal and hTERT-transduced cells, but RNA sequencing analysis suggested that the different signaling pathways contributed to the different phenotypic outcomes in these cells. While EML4-ALK also induced anchorage-independent growth in hTERT-immortalized human bronchial epithelial cells in vitro, the expression of EML4-ALK alone did not cause detectable in vivo tumorigenicity in immunodeficient mice. Conclusions: Our data indicate that the expression of hTERT is critical for EML4-ALK to manifest its in vitro transforming activity in human cells. This study provides the isogenic pairs of human cells with and without EML4-ALK expression

Resveratrol and aspirin eliminate tetraploid cells for anticancer chemoprevention

La tétraploïdie – cellule contenant le double du génome d’une cellule diploïde – est considérée comme un état métastable, à l’origine de l’aneuploïdie des cancers. Présentes dans les lésions précancéreuses, les cellules tétraploïdes sont associées à la progression tumorale. Etant donné le rôle clé de la tétraploïdie au cours de l’oncogenèse, le développement d’agents pharmacologiques éliminant spécifiquement les cellules tétraploïdes pourrait permettre de prévenir et limiter l’évolution vers un état cancéreux. Afin d'identifier des composés délétères pour les cellules tétraploïdes, nous avons développé une méthode de criblage basée sur la vidéomicroscopie à fluorescence automatisée. La chimiothèque de l'Institute of Chemistry and Cell Biology (ICCB) a été criblée, et nous avons mis en évidence plusieurs hits aux effets cytostatiques et/ou cytotoxiques préférentiels pour les cellules tétraploïdes. En raison de ses propriétés chimiopréventives, le resvératrol est le premier composé dont nous avons choisi de poursuivre la caractérisation. Sa sélectivité pour les cellules tétraploïdes a été confirmée sur différents types cellulaires, stables ou en cours de polyploïdisation. L’étude du mécanisme d’action anti-tétraploïde du resvératrol a permis d’identifier le senseur de la charge énergétique 5’-adenosine monophosphate-activated kinase (AMPK), comme une cible moléculaire responsable de la mort sélective des cellules tétraploïdes. Une série d’agents pharmacologiques activant directement ou indirectement AMPK – parmi lesquels l’aspirine et son métabolite le salicylate, dont l’action chimiopréventive a été établie par plusieurs études épidémiologiques et essais cliniques – a montré une toxicité préférentielle pour les cellules tétraploïdes. De la même manière que le resvératrol, ces agents éliminent les cellules tétraploïdes stables et limitent la polyploïdisation. Finalement, l’effet anti-tétraploïde du resvératrol et de l’aspirine a été évalué in vivo. L’administration orale de ces deux composés aux doses décrites comme chimiopréventives, réduit le développement des cellules épithéliales tétraploïdes et aneuploïdes des cryptes intestinales des souris ApcMin/+, le modèle murin de la polypose adénomateuse familiale. Collectivement les résultats de cette étude suggèrent que l’action chimiopréventive du resvératrol et de l’aspirine est associée à l’élimination des cellules tétraploïdes précurseur de tumeurs.Tetraploidy – cells that contain twice the normal amount of chromosomes – is a metastable state leading to aneuploidy in cancer. Tetraploid cells have been observed in precancerous lesions and constitute a step toward tumor progression. Given the importance of tetraploidization for oncogenesis, developing drugs that selectively target tetraploid cells should prevent cancer.To discover compounds toxic to tetraploid cells, we developed an assay-system based on automatic fluorescence videomicroscopy. We screened the Institute of Chemistry and Cell Biology (ICCB) chemical library and identified several hits exerting a selective cytostatic and/or cytotoxic effect on tetraploid cells. Due to its well known chemopreventive properties, resveratrol was the first compound we further characterized. Its selectivity for tetraploid cells was confirmed on various stable or polyploidizing cancer cell lines, as well as primary epithelial cells. The mechanism accounting for the preferential killing of tetraploid cells involves the 5’-adenosine monophosphate-activated kinase (AMPK) signaling pathway. A series of additional agents that stimulate AMPK – including aspirin and salicylate whose chemopreventive action have been established by several epidemiological studies and clinical trials – display a selective toxicity toward tetraploid cells. Similar to resveratrol, these drugs eliminate stable tetraploid cells and reduce polyploidization. Finally, we validated the anti-tetraploid effect of resveratrol and aspirin in vivo. Oral treatment with either of these two compounds at chemopreventive doses, repressed the accumulation of tetraploid and subsequently aneuploid intestinal epithelial cells from the crypts of the ApcMin/+ mouse model of familial adenomatous polyposis.Collectively, our results suggest that the chemopreventive action of resveratrol and aspirin involves the elimination of tetraploid cancer cell precursors

Immunosurveillance against tetraploidization-induced colon tumorigenesis

<p>Circumstantial evidence suggests that colon carcinogenesis can ensue the transient tetraploidization of (pre-)malignant cells. In line with this notion, the tumor suppressors APC and TP53, both of which are frequently inactivated in colon cancer, inhibit tetraploidization in vitro and in vivo. Here, we show that-contrarily to their wild-type counterparts-Tp53(-/-) colonocytes are susceptible to drug-induced or spontaneous tetraploidization in vitro. Colon organoids generated from tetraploid Tp53(-/-) cells exhibit a close-to-normal morphology as compared to their diploid Tp53(-/-) counterparts, yet the colonocytes constituting these organoids are characterized by an increased cell size and an elevated expression of the immunostimulatory protein calreticulin on the cell surface. The subcutaneous injection of tetraploid Tp53(-/-) colon organoids led to the generation of proliferating tumors in immunodeficient, but not immunocompetent, mice. Thus, tetraploid Tp53(-/-) colonocytes fail to survive in immunocompetent mice and develop neoplastic lesions in immunocompromised settings only. These results suggest that tetraploidy is particularly oncogenic in the context of deficient immunosurveillance.</p>

Pro-autophagic polyphenols reduce the acetylation of cytoplasmic proteins

Resveratrol is a polyphenol contained in red wine that has been amply investigated for its beneficial effects on organismal metabolism, in particular in the context of the so-called “French paradox,” i.e., the relatively low incidence of coronary heart disease exhibited by a population with a high dietary intake of cholesterol and saturated fats. At least part of the beneficial effect of resveratrol on human health stems from its capacity to promote autophagy by activating the NAD-dependent deacetylase sirtuin 1. However, the concentration of resveratrol found in red wine is excessively low to account alone for the French paradox. Here, we investigated the possibility that other mono- and polyphenols contained in red wine might induce autophagy while affecting the acetylation levels of cellular proteins. Phenolic compounds found in red wine, including anthocyanins (oenin), stilbenoids (piceatannol), monophenols (caffeic acid, gallic acid) glucosides (delphinidin, kuronamin, peonidin) and flavonoids (catechin, epicatechin, quercetin, myricetin), were all capable of stimulating autophagy, although with dissimilar potencies. Importantly, a robust negative correlation could be established between autophagy induction and the acetylation levels of cytoplasmic proteins, as determined by a novel immunofluorescence staining protocol that allows for the exclusion of nuclear components from the analysis. Inhibition of sirtuin 1 by both pharmacological and genetic means abolished protein deacetylation and autophagy as stimulated by resveratrol, but not by piceatannol, indicating that these compounds act through distinct molecular pathways. In support of this notion, resveratrol and piceatannol synergized in inducing autophagy as well as in promoting cytoplasmic protein deacetylation. Our results highlight a cause-effect relationship between the deacetylation of cytoplasmic proteins and autophagy induction by red wine components

Whole-genome duplication increases tumor cell sensitivity to MPS1 inhibition

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