Abstract
Many human cancers over-express B cell lymphoma 2 (Bcl-2) or X-linked inhibitor of apoptosis (IAP) proteins to evade cell death. The pro-apoptotic ARTS (Sept4_i2) protein binds directly to both Bcl-2 and XIAP and promotes apoptosis by stimulating their degradation via the ubiquitin-proteasome system (UPS). Here we describe a small molecule, A4, that mimics the function of ARTS. Microscale thermophoresis assays showed that A4 binds XIAP, but not cellular inhibitor of apoptosis protein 1 (cIAP1). A4 binds to a distinct ARTS binding pocket in the XIAP-BIR3 (baculoviral IAP repeat 3) domain. Like ARTS, A4 stimulated poly-ubiquitylation and UPS-mediated degradation of XIAP and Bcl-2, but not cIAP1, resulting in caspase-9 and -3 activation and apoptosis. In addition, over-expression of XIAP rescued HeLa cells from A4-induced apoptosis, consistent with the idea that A4 kills by antagonizing XIAP. On the other hand, treatment with the SMAC-mimetic Birinapant induced secretion of tumour necrosis factor-α (TNFα) and killed ~50% of SKOV-3 cells, and addition of A4 to Birinapant-treated cells significantly reduced secretion of TNFα and blocked Birinapant-induced apoptosis. This suggests that A4 acts by specifically targeting XIAP. The effect of A4 was selective as peripheral blood mononuclear cells and normal human breast epithelial cells were unaffected. Furthermore, proteome analysis revealed that cancer cell lines with high levels of XIAP were particularly sensitive to the killing effect of A4. These results provide proof of concept that the ARTS binding site in XIAP is “druggable”. A4 represents a novel class of dual-targeting compounds stimulating apoptosis by UPS-mediated degradation of important anti-apoptotic oncogenes.
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Introduction
Apoptosis is essential to maintain tissue homeostasis and protect against various diseases, including cancer1. Caspases, a family of cysteine proteases, are the central executioners of apoptosis2. The activity of caspases is inhibited through the action of the inhibitor of apoptosis (IAP) proteins3. There are eight human IAPs, yet only X-linked IAP (XIAP) directly inhibits caspases, whereas cellular inhibitor of apoptosis proteins (cIAPs) prevent the formation of pro-apoptotic signalling complexes at the extrinsic apoptotic pathways. XIAP contains three baculoviral IAP repeats (BIRs), which serve as protein–protein interaction domains for direct binding and inhibition of caspases 3, 7 and 94,5. In addition, it contains an ubiquitin-associated domain, which enables the binding of poly-ubiquitin conjugates and a RING domain required for its E3 ligase activity6,7,8. The regulation of apoptosis critically relies on regulated protein degradation by the ubiquitin-proteasome system9,10,11. XIAP functions as an E3 ligase to promote degradation of several pro-apoptotic proteins, such as SMAC and ARTS12,13,14.
Apoptosis is also regulated by B cell lymphoma 2 (Bcl-2) family members, which control mitochondrial outer membrane permeabilization (MOMP)15,16. This family contains pro- and anti-apoptotic proteins that can form complexes via a common BH3 domain15,17,18,19,20. Importantly, high levels of the anti-apoptotic Bcl-2 protein are characteristic of many haematologic malignancies as well as certain solid cancers15,21,22,23,24.
To stimulate apoptosis, the function of IAPs needs to be overcome. This occurs by the action of IAP antagonists, such as SMAC/Diablo25,26, Omi/HtrA227 and ARTS28. ARTS (Sept4_i2) is a pro-apoptotic protein encoded by the Septin 4 (Sept4) gene and the only splice variant of Sept4 that promotes apoptosis29,30. Studies in human and mice show that ARTS acts as a tumour suppressor protein. Sept4/ARTS-deficient mice develop various spontaneous tumours, and they have highly accelerated lymphomagenesis in the Eu-Myc model31,32. In addition, ARTS expression is lost in >70% of leukaemia patients, in 50% of lymphoma patients and in a significant fraction of hepatocellular carcinoma patients31,33 (S. Larisch and H. Steller, unpublished data). In living cells, ARTS localizes to the mitochondrial outer membrane (MOM) where it binds to Bcl-213. Upon induction of apoptosis, ARTS translocates to the cytosol and directly binds and antagonizes XIAP. This leads to de-repression and release of non-lethal active caspases from XIAP upstream of MOMP. In turn, these caspases can cleave substrates, such as Bid, resulting in MOMP and execution of apoptosis13,34. ARTS stimulates the degradation of XIAP by promoting its ubiquitylation13,35. In addition, ARTS acts as a scaffold to bring XIAP into close proximity with Bcl-2 and promote its degradation34. Thus, ARTS functions as a dual antagonist of both XIAP and Bcl-2 upstream of MOMP. Importantly, ARTS acts as a physiological antagonist of XIAP. Sept4/ARTS-deficient mice express elevated levels of XIAP protein, demonstrating that ARTS limits the levels of XIAP in vivo. Moreover, knockdown of ARTS in HeLa cells and intestinal epithelial cells from Sept4/ARTS knockout (KO) mice are protected against apoptotic cell death13,36. In addition, Sept4/ARTS-deficient mice have increased numbers of hematopoietic stem and progenitor cells (HSPCs) and hair follicle stem cells that are resistant to apoptosis31,37. Furthermore, the resistance of Sept4/ARTS-null HSPCs to apoptosis and the cell-autonomous lymphoproliferation is suppressed by the loss of XIAP function in Sept4/ARTS/XIAP double-KO mice31. Collectively, these results demonstrate the important physiological role of ARTS in regulating apoptosis and as a tumour suppresor in vivo through its role as a specific XIAP antagonist.
ARTS differs from all other known IAP antagonists by its distinct mode of binding to XIAP14,38. Moreover, ARTS specifically induces degradation of XIAP and Bcl-213,28,34. Significantly, over-expression of both XIAP and Bcl-2 contributes to tumorigenesis and have become major targets for developing anti-cancer therapeutics39,40,41,42. IAP antagonists were initially designed based on the N-terminal peptide sequence AVPI found in the Drosophila Reaper/Hid and SMAC/Diablo5,43,44. SMAC mimetics (SMs) bind with high affinity to cIAPs and lower affinity to XIAP and they can degrade cIAPs, but not XIAP38,45,46,47,48. Here we describe the identification of the first ARTS-mimetic small molecule, A4. This compound binds directly to the unique binding site of ARTS in XIAP-BIR3, but not to cIAP1. A4 promotes proteasome-mediated degradation of both XIAP and Bcl-2, caspase activation and apoptosis. Over-expression of XIAP inhibits A4-induced cell death, consistent with the idea that XIAP is a major target for A4.
Materials and methods
Cell line culture and reagents
HeLa (human cervical cancer cells), A375 (human malignant melanoma cells), Jurkat (human leukaemia T cells) and HEK-293-T (human embryonic kidney cells) were purchased from ATCC.
The DKO BAK/BAX MEFs (mouse embryonic fibroblasts) were kindly provided to us by Dr. Joe Opferman, St. Jude, Memphis, TN, USA, and by Dr. Reuven Stein, Tel-Aviv University, Israel.
MEFs cells, HeLa, A375 and HEK-293-T cells were grown in complete DMEM medium (1% sodium pyruvate, 1% l-glutamate, 1% Pen-strep and 10% fetal bovine/calf serum).
Jurkat and T47D (human metastatic ductal breast carcinoma cells) cells were grown in complete RPMI medium (1% sodium pyruvate, 1% l-glutamate, 1% Pen-strep and 10% heat-inactivated fetal bovine/calf serum).
184A1 (normal human breast epithelial cells) were grown in DMEM/F12 complete medium (1% sodium pyruvate, 1% l-glutamate, 1% Pen-strep, 5% donor horse serum, 100 ng/ml cholera toxin, 20 ng/ml epidermal growth factor, 0.5 mg/ml hydrocortisone, 10 µg/ml insulin).
All cell lines were checked for mycoplasma and kept under passage 10.
Staurosporine (STS) was purchased from Fermentek (cat#62996-74-1.5) and Birinapant from Biovision (cat#5297).
Preparation of A4 stock and work solution
The A4 small molecule (MW 440.92 g/mol as powder, SMILES: COC(=O)c1[nH]c2ccc(Cl)cc2c1NC(=O)C[NH + ]1CC[NH + ](Cc2ccccc2)CC1) was purchased from eMolecules, Inc., eMolecule ID: 4424446 (Supplier InterBioScreen STOCK2S-13772). A4 was dissolved in dimethyl sulfoxide (DMSO) to a stock solution of 30–50 mM, followed by intensive pipetting and centrifugation at 300 × g for 30 s. Next, the A4 suspension was incubated in a 37 °C bath for 1 min, mixed thoroughly by pipetting and spun down again. A4 stock solution was aliquoted in Eppendorf tubes (7–10 µl/tube) and stored in −80 °C. Aliquots were only used once to avoid freeze and thaw of the compound. Before using in an experiment, an A4 aliquot was thawed, spun down (same settings) and mixed by tapping gently at the lower part of the Eppendorf tube. Next, the compound solution was diluted 1:100 in warm complete medium in a 15 ml conical tube to a concentration of 0.3–0.5 mM and mixed well by tilting the closed vial up and down (do not vortex). The diluted A4 solution was then diluted again to the desired final concentration (10–30 µM) and added to the cells.
Antibodies
ARTS—mouse monoclonal anti-ARTS antibody, specifically targeting the unique c-terminal sequence of ARTS (but not other Septin 4 splice variants) at a dilution of 1:1000 (Sigma A4471).
XIAP—mouse monoclonal anti-XIAP antibody (BD cat#610717) at a dilution of 1:1000. Or rabbit polyclonal anti-XIAP (sc-11426) at a dilution of 1:2000.
Bcl-2—mouse monoclonal anti-Bcl-2 antibody (BD cat#610538) at a dilution of 1:1000. Or rabbit polyclonal anti-Bcl-2 by Proteintech (26593-1-AP) or DB Biotech (P22-A cat#DB 132-0.05) at a dilution of 1:5000 for both.
Actin—mouse monoclonal anti-actin antibody (ImmunoTM cat#08691002) at a dilution of 1:50,000.
Cleaved PARP (cPARP)—rabbit polyclonal anti-PARP antibody (Abcam cat#ab4830) at a dilution of 1:1000.
Ubiquitin—mouse monoclonal anti-ubiquitin (Santa Cruz sc-8017) at a dilution of 1:2000.
Myc—monoclonal mouse anti-Myc (Cell Signaling cat#2276s) at a dilution of 1:1000.
Tubulin—monoclonal rat anti-tubulin (Abcam cat#YOL1/34) at a dilution of 1:6000.
GAPDH—polyclonal goat anti-GAPDH (Abcam cat#ab9483) at a dilution of 1:2000.
BAX—rabbit polyclonal anti-Bax (Proteintech 50599-2-Ig) at a dilution of 1:6000.
cIAP1—goat polyclonal anti-cIAP1/HIAP-2 antibody (R&D cat#AF8181) at a dilution of 1:1000.
Cleaved caspase-3—for immunofluorescence we used purified rabbit anti-active caspase-3 antibody clone C92-605 (BD cat#559565) at a dilution of 1:400.
Cleaved caspase-3—to detect cleaved caspase-3 by western blot we used rabbit monoclonal antibody anti-active Caspase-3 Asp175 (BD cat#cs9664) at a dilution of 1:1000.
Screening of A4 killing effect on 94 tumour cell lines
Screening of 94 different cancer cell lines spanning over 18 human tissues was performed by Oncolead Ltd. The company used an identical platform to the one NIH, NCI-60 uses to assess the effect of a compound on the viability of a variety of tumour cell lines. Briefly, cells are treated with a series of six dilutions of a compound for 72 h (compound is replenished daily). After 72 h, cells were fixed (living cells are attached to the plate), and then washed to remove dead and dying cells. Cells were then stained with a dye (sulforhodamine B) that dyes all proteins purple, which is measured by a plate reader and provides quantification of living cells. The number of cells treated with the compound is compared to the number of cells treated with DMSO (solvent). The inhibitory concentration (IC) value was calculated by taking the number of cells after 72 h of treatment and dividing by the number of cells after 72 h treatment with DMSO (C). IC50 is the value calculated from the dose–response plot, which is the concentration of the compound that has 50% decrease of the IC.
Cell viability assays
XTT Cell Proliferation Kit (Biological Industries cat#20-300-1000) and Presto blue cell viability reagent (Invitrogen cat#A13262) were used according to the manufacturer’s instructions. Six thousand to 10,000 cells per well were seeded in Falcon® 96-well Clear Flat Bottom TC-treated Culture Microplate (#353072) and grown for 24 h. Treatment with A4 was added for 24 h following incubation at 37 °C with XTT or the Presto blue reagents for 2 h. The intensity of the colour was measured using BioTeK ELISA synergyHT microplate reader (for XTT 450 nm excitation and 630 nm emission, for Presto blue assay 560 nm excitation and 590 nm emission). Using both these viability assays, we determined cell viability by normalizing the results in the treated cells to cells treated with DMSO (fold change to DMSO). Dot plots are composed of independent experiments, and each independent experiment was done in triplicates or more.
Caspase-9 activity assay
One million cells per well were seeded in 6-well plates. After 24 h, the cells were treated with 20 μM A4 for 3, 6 and 24 h. The cells were collected with phosphate-buffered saline (PBS) and washed again with PBS. The cells were centrifuged at 500 × g for 10 min. Cleaved caspase-9 activity was then measured in these samples by Caspase-9 Fluorometric Assay Kit (by BioVision cat#K118) according to the manufacture’s protocol. Fluorescence levels were measured by an ELISA spectrophotometer (400 nm excitation and 505 nm emission). The results were normalized by the absolute value (OD) of the DMSO control to evaluate the caspase-9 activity.
Caspase-Glo 3/7 assay system (Promega cat#G8090)
Cells were cultured in 96 wells (8000 cells/well) and were treated with A4 (20 µM). After overnight incubation at 37 °C, 5% CO2 incubator Caspase-Glo® reagent (Promega, USA) was added to each well according to the manufacturer’s instructions and plates were incubated at room temperature for 1 h. Luminescence of each sample was measured using a plate-reading infinite M200PRO, TECAN luminometer.
Annexin V/PI staining
Jurkat cells were treated with A4 plus or minus the caspase inhibitor Q-VD-Oph (ab141421) for 24 h (1–10 µM) and stained for Annexin V/PI according to the manufacturer’s instructions (Novus cat#NBP2-29373). Q-VD-Oph was added 30 min prior to the addition of A4. Flow cytometry was performed using FACSCanto II (BD) and data were analysed using the FlowJo software (Treestar).
Immunofluorescence detecting active caspase-3
For immunofluorescence and confocal microscopy, cells were grown on cover glasses (Marienfeld, Lauda-Konigshofen, Germany) and treated with A4 for either 6 or 24 h. Next, the cells were washed three times with PBS and fixed with 4% paraformaldehyde for 15 min at room temperature (RT), followed by three additional PBS washes. Permeabilization was performed with 0.1% Triton X-100 in 50 mM Tris pH 7.2 for 3 min, after which the cells were washed with PBS and incubated in blocking buffer (20% normal goat serum and 1% BSA in PBS) for 30 min at RT. Cells were then incubated with the antibody for cleaved caspase-3 (1:400 by BD cat#559565) diluted in PBS containing 1% BSA, for 1 h at RT, followed by three PBS washes. The cover glasses were then incubated with the secondary antibody for 1 h at RT. After washing with PBS, they were mounted using VECTASHIELD mounting medium with 4′, 6-diamidino-2-phenylindole. Immunofluorescent images were taken with a Nikon A1R confocal microscope.
Treatment with proteasome inhibitors
Cells were pre-incubated with 20 µM of MG-132 (APExBIO cat#A2585) or Bortezomib (APExBIO cat#A2614) for 6 h. Twenty micromoles of A4 was added in the last 2 h of incubation with the proteasome inhibitors.
Site-directed mutagenesis of XIAP expression construct
We have mutated two key amino acids at the distinct binding site of ARTS within XIAP-BIR3. Using the GFP-WT-XIAP expression construct, we mutated amino acids S278A and N280A (GFP-DM-XIAP). As a control we used the GFP-WT-XIAP and the GFP-empty-vector. A detailed description is in the Supplementary Materials and methods.
Transfections reagents
For transient transfections, the following reagents were used according to the manufacturer’s instructions: Transit-X2 (Mirus), jetPEI (Polyplus) and PolyJet (SignaGen).
SDS-PAGE and western blot analysis
Cells were lysed in whole-cell extract buffer [25 mM HEPES, pH 7.7, 0.3 M NaCl, 1.5 mM MgCl2, 0.2 mM EDTA, 0.1% Triton X-100, 100 μg/ml phenylmethylsulfonyl fluoride (PMSF) and protease inhibitor cocktail (Roche, 1:100 dilution)] and placed on ice for 30 min (vortexing once after 15 min). After 30 min, the samples were centrifuged at 13,000 × g for 10 min at 4 °C. The supernatants containing total protein were measured for protein concentration using Bio-Rad Protein Assay Dye Reagent Concentrate Kit. Forty to 100 µg protein was separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) (12%), followed by transfer to a PVDF membrane. The membranes were blocked with 5% (w/v) non-fat dried skimmed milk powder in PBS supplemented with 0.05% Tween-20 (PBS-T) for 1 h at RT. Next, primary antibodies were added at 4 °C overnight or for 2 h at room temperature. Membranes were then incubated with secondary antibody for 1 h at RT and washed three times for 15 min each with PBS-T. Western Bright ECL (Advansta) was added to the membrane for 30–60 s and analysed using Image Quant LAS-4000 (GE Healthcare Life Sciences) and Image Quant LAS-4000 software (GE Healthcare Life Sciences).
Co-immunoprecipitation
HEK-293-T cells were transfected with either GFP-empty-vector, GFP-WT-XIAP or GFP-DM-XIAP and allowed them to express the constructs for 24 h. All samples were co-transfected with 6-Myc-ARTS (Myc tag is located at the N′ terminus). Next, the cells were harvested and lysed with radioimmunoprecipitation assay (RIPA) buffer (Tris-HCl pH 7.5 50 mM, NaCl 150 mM, NP-40 (Igepal) 0.3%) containing protease inhibitor cocktail (Complete, Roche) and 100 μg/ml PMSF. Antibodies were used at 5 µg per 1000 µg protein and were incubated overnight rotating at 4 °C. The next day, agarose beads conjugated to protein A/G (Santa Cruz Biotechnology) were added for 4 h with rotation at 4 °C. Samples were centrifuged at 4 °C for 5 min and washed five times with RIPA buffer. Proteins were eluted from beads by 10 min of boiling in sample buffer and separated on 12% SDS-PAGE gel, followed by western blot analysis.
In vivo ubiquitylation assay
All cells were transiently transfected with a Ub-HA (ubiquitin-tagged with HA) construct and treated with proteasome inhibitor (Bortezomib or MG-132, at 20 µM for 6 h). In addition, for Bcl-2 in vivo ubiquitylation assay, cells were co-transfected with Ub-HA and GFP-vector/Bcl-2-GFP (GFP tag is attached to the N′ terminus of Bcl-2). After 4 h of proteasome inhibitor incubation, A4 (20 μM) or DMSO was added to the medium for an additional 2 h. After 6 h of Bortezomib/MG-132 along with 2 h of A4 treatments, the cells were harvested and lysed using RIPA buffer (Tris-HCl pH 7.5 50 mM, NaCl 150 mM, NP-40 (Igepal) 0.3%) containing protease inhibitor cocktail (Complete, Roche), 100 μg/ml PMSF, 5 mM N-ethylmaleimide and 5 mM iodoacetamide to preserve ubiquitin chains. Following 15 min of centrifugation (10,000 × g, 4 °C), the supernatant was transferred into a clean Eppendorf tube. A ubiquitination assay using immunoprecipitation with anti-XIAP antibody (sc-11426 or BD #610717) (endogenous XIAP was pulled down) or anti-Bcl-2 (Proteintech #26593-1-AP or DB Biotech P22-A cat#DB 132-0.05) (over-expressed Bcl-2 was pulled down) was performed as described above with 5 µg antibody per 1000 µg protein. Poly-ubiquitylated forms of Bcl-2 or XIAP were detected using anti-Ub Ab (Santa Cruz sc-8017).
SKOV-3 rescue assay and evaluation of Birinapant-induced apoptosis
The SKOV-3 rescue assay was performed based on Gaither et al.49. Specifically, SKOV-3 cells were seeded in 96-well plates in replicates of four for each treatment. After 24 h, the cells were treated with Birinapant (1 µM) for 24 h in the presence or absence of A4 (2.5 and 5 μM). The cells were then washed once with 100 μl of PBS. Next, 100 μl of Presto blue reagent (diluted 1:5 in PBS) was added to each well and the cells were incubated at 37 °C for 2 h. After the 2-h incubation, absorbance was measured using a fluorescence spectrometer (emission 560 nm, excitation 590 nm).
Detection of TNF-α levels in condition media
SKOV-3 cells were treated for 24 h with A4 alone (10 µM), Birinapant alone (1 µM) and a combination of the two compounds. DMSO was used as a negative control. Tumour necrosis factor-α (TNFα) levels in supernatants were measured using ELISA Max standard sets (Cat#430203 BioLegend), according to the manufacturer’s protocol.
Computational screen
Three hundred thousand commercially available molecules were selected from a set of ~3 million and were screened using LeadIT and SeeSAR software suits from BioSolveIT. This computational screen-identified compounds with predicted binding affinities in the micromolar to nanomolar range, as assessed by the HYDE scoring function50. The 100 top-ranked molecules exhibiting best docking scores were determined. The ARTS unique binding site in XIAP-BIR3 was extrapolated by analysing XIAP-SMAC crystal structures from the PDB and our data, described by Bornstein et al.14. A detailed description is provided in the Supplementary Materials and methods.
Computational analysis of ARTS versus SMAC binding sites in XIAP-BIR3
Using the site mapping information on the unique ARTS binding site in XIAP-BIR314, we performed a preliminary virtual screen using Glide51 into the 3HL5.PDB crystal structure52. Compounds identified as described above were docked into the model both with and without water present in the active site using a standard protocol.
MST binding assays
Microscale thermophoresis (MST) binding assays were performed by CreLux, a WuXi AppTech company in Germany, using recombinant ARTS, XIAP, Bcl-2 and cIAP1 proteins. Specifically, for performing experiments with untagged XIAP, a fluorescent label (NT650) was covalently attached to the protein (Maleimide coupling). The labelling was performed in a buffer containing 50 mM HEPES pH 7.0, 150 mM NaCl and 0.005% Tween-20. A detailed description is provided in the Supplementary Materials and methods.
Proteomic data
All proteomic data for cell lines available at EMBL-EBI Expression Atlas repository was downloaded (https://www.ebi.ac.uk/gxa/home). This included in total 13 datasets, of which 10 included cell lines represented in our set of 93 cell lines. Proteomic data was retrieved for 40 out of 93 cell lines. From each dataset, data for four genes were curated: ACTB, GAPDH, XIAP and Bcl-2. The first two were used for normalization of expression levels of XIAP and Bcl-2. All data were log 10 transformed and ratios between XIAP or Bcl-2 and either of the normalizing genes were calculated. A Wilcoxon’s rank sum test was used to compare the IC50 values (μM) between the different types of tumour cells. The test was performed for several pairs of cancer types (Supplementary Table 1).
Data filtering and correlation analysis
In order to inspect relatedness between A4 IC50 and XIAP or Bcl-2 expression, the cell lines were catalogued based on their tissue/organ of origin, and analysis was performed on tissues/organs represented by at least four different cell lines (Supplementary Tables 1 and 2). We further excluded values (expression ratios) that were >1.0, considering such values for these specified genes are likely biased. Indeed, in these samples expression levels of GAPDH or Actin were 2–3 orders of magnitude lower than those found in other samples. We then calculated correlation between XIAP expression ratios using both Pearson and Spearman correlations. Correlations were calculated and tested for significance using function cor.test in R package “stats”. Correlation was considered significant for p < 0.05.
Statistical analysis
All graphs were made using the PRISM software. Significance was evaluated using PRISM’s one-way analysis of variance. p < 0.05 was considered significant.
Results
Structure-based computational screen for molecules targeting the unique binding site of ARTS in XIAP-BIR3
Both SMAC and ARTS bind to the BIR3 domain in XIAP14,38,53. Using the site mapping information of both ARTS and SMAC, we performed an in silico screen using Glide54 Schrodinger55 into the 3HL5.PDB crystal structure52. All XIAP ligands found in the computational screen were bound to the SMAC site (“SMAC binding pocket”, Fig. 1a), but not to the ARTS binding site (Fig. 1b). Figure 1b illustrates the distinct nature of the binding pockets for ARTS and SMAC within XIAP-BIR3. To further demonstrate that the BIR3 domain in XIAP contains a distinct binding site for ARTS, we generated a double mutant expression construct of XIAP (DM XIAP) in which two amino acids were replaced with Alanine (S278A and N280A). Immunoprecipitation assays revealed a strong reduction in the ability of ARTS to bind to this mutant XIAP, as compared to wild type (WT) (Fig. 1c). This confirms that XIAP contains a distinct binding site for ARTS in its BIR3 domain.
Previous efforts have exclusively focused on compounds binding to the SMAC pocket53,56,57. To identify compounds that bind specifically to the ARTS binding pocket, a structure-based computational docking screen was performed. Overlay of the 100 top-ranked docking compounds revealed that they cover all the different sub-pockets within the surface of the ARTS-specific binding site (Fig. 1d). This indicates that the binding surface of XIAP-BIR3 was thoroughly explored by the screening protocol. Compound A4, one of the top-ranked molecules, is predicted to form three H-bond interactions with the protein backbone of the distinct ARTS binding site: between T271 and a nitrogen of the piperazine ring and between F270 and the other nitrogen plus the amide nitrogen (Fig. 1e). However, it is also possible that A4 interacts with the backbone of T274 instead of T271 (Fig. 1f, g). Interestingly, the docking map reveals unusually curved docking positions, so that the ligand turns away from the SMAC binding site. This exposes the indole ring to the surface, suggesting that it may be the ARTS-accessible surface (Fig. 1g). A4 is a methyl 5-chloro-3-[[2-[4-(phenylmethyl) piperazin-1-yl]acetyl]amino]-1H-indole-2-carboxylat. It conforms well with Lipininski’s rule of five and hence has promising chemical properties for potential future drug development.
A4 induces caspase-mediated cell death
The effects of our top-ranked molecules were first tested on A375, a melanoma cell line expressing high levels of XIAP, and a Jurkat T-lymphoma cell line expressing high levels of Bcl-2. This initial functional screen tested for the death-inducing effect of 76 out of the 100 top scoring compounds using the PrestoBlue™ Cell Viability Reagent and XTT Cell Viability Kit. Figure 2a shows representative results for some of these compounds in comparison to the pro-apoptotic reagent STS. From these screens, we identified A4 as a potent cell killer (Fig. 2aI, II and Supplementary Fig. 1a, b). A4 also induced cell death of HeLa, Jurkat and T47D human cancer cells (Fig. 2bII, 2cI, II, 2bI, 2cI and 5cII, respectively). Notably, treating these cells with A4 resulted in increased levels of cleaved caspase-3 and elevated activity of cleaved caspase-3 and -7 (Fig. 3aI–III, 3bI and Fig. 3c, respectively). Moreover, increased levels and activity of cleaved caspase-9 were detected in A375 cells upon treatment with A4 (Fig. 3bII and 3d, respectively), and this was associated with a strong decrease in cell numbers (Supplementary Fig. 1c, d). Finally, using Annexin V/PI FACS analysis and cPARP as an apoptotic marker, we found that treatment with the caspase inhibitor Q-VD-Oph blocked A4-induced apoptosis (Fig. 3e–g). These results indicate that A4, like ARTS, promotes apoptosis through activation of both caspase-3 and -9.
A4 binds directly to XIAP and stimulates proteasome-mediated degradation of both XIAP and Bcl-2
The endogenous ARTS protein binds directly to XIAP and Bcl-228,34. Similarly, using MST assays we found that A4 showed a relatively high binding affinity for recombinant XIAP (Kd = 348 nM), but no binding to cIAP1 (Fig. 4a, and data not shown, CreLux). To examine whether A4 can mimic the function of ARTS, we tested whether A4 can stimulate the degradation of both XIAP and Bcl-2, a feature that distinguishes ARTS from other known pro-apoptotic proteins. We tested some of our other top-ranked compounds for their ability to reduce endogenous levels of XIAP and Bcl-2 in several cell lines. A4 showed a pronounced effect by decreasing both these target proteins and was selected for further characterization (data of other compounds is not shown). A dose-dependent decrease in XIAP levels in A4-treated HeLa cells was associated with increased apoptosis (Fig. 4b). Reduction of XIAP and Bcl-2 levels was seen as soon as 2 h following treatment with A4 (Fig. 4c, d). This effect is specific as no reduction of cIAP1 was observed at this time point (Fig. 4d). Next, we found that addition of two different proteasome inhibitors (MG-132 and Bortezomib) to A4-treated cells restored levels of XIAP and Bcl-2 in A375 and HeLa cells, respectively (Fig. 4e, f). Finally, using in vivo ubiquitylation assays, we showed a substantial increase in accumulation of poly-ubiquitylated forms of Bcl-2 and XIAP in A4-treated HEK-293-T (Fig. 4g, h). This suggests that A4-induced reduction of XIAP and Bcl-2 protein levels occurs through ubiquitin-proteasome system (UPS)-mediated degradation. Since Bcl-2 acts by binding and neutralizing the pro-apoptotic function of Bax, and because A4 reduces Bcl-2 levels, we also examined if the levels of Bax affected A4-induced apoptosis. For this purpose, we treated Bax/Bax DKO MEFs with A4 and compared them with WT MEFs. We observed a significant reduction of caspase-9 activity and cPARP in the Bax/Bax DKO MEFs as compared to WT MEFs (Supplementary Fig. 2a). This suggests that A4-induced killing is affected by Bax. We conclude that A4 mimics the function of ARTS with respect to UPS-mediated degradation of XIAP and Bcl-2, the activation of caspase-3 and -9, and the induction of apoptosis.
A4 kills specifically by targeting XIAP
To determine the specificity of A4 killing for various types of cancer, a panel of 94 cancer cell lines representing 18 different types of cancers were tested. The IC50 values for each cell line treated with A4 were determined (Oncolead Ltd). The cancers that were most sensitive to A4 killing were of haematological origin (8/12 different cell lines), melanoma (3/5 lines), pancreatic cancer and 4/7 lung cancers. Importantly, peripheral blood mononuclear cells (PBMCs), representing healthy normal cells, and 184A1, a normal human epithelium mammary gland cell, were not killed by A4 (Fig. 5a, Supplementary Table 1 and Fig. 5cI, respectively). To explore whether the levels of XIAP and Bcl-2 protein affect the sensitivity to A4, we analysed the available web proteomes and looked for a correlation. While data regarding XIAP expression levels were found in most proteomes (28 of 32 proteomes), Bcl-2 expression data were only detected in few (9 of 32 proteomes) (data not shown). A significant correlation was found between XIAP expression levels (ratio to actin, GAPDH) and the sensitivity to A4 (IC50, µM) in breast, ovary and kidney carcinomas (Fig. 5bI, II and Supplementary Tables 1 and 2). Cancer cell lines with high levels of XIAP were particularly sensitive to the killing effect of A4 (Fig. 5bI, II and Supplementary Tables 1 and 2). These results support the idea that A4 is a specific XIAP antagonist, and they suggest that A4 has the potential for treating cancers over-expressing XIAP. To further confirm that A4 functions as a specific antagonist for XIAP, we performed a SKOV-3 rescue assay49. SKOV-3 ovarian carcinoma cells are highly sensitive to SMs49. SMs act by antagonizing cIAPs, an event that leads to cell death when complemented by an XIAP-dependent increase in TNFα production47,48,58. In SKOV-3 cells, XIAP is required for TNFα production, which recruits cIAP into a complex that activates caspase-8 and apoptosis through the extrinsic pathway (Fig. 6a)49. Knockdown of XIAP in SKOV-3 cells bestowed resistance to SMs49. We utilized this assay to investigate the specificity of A4 for XIAP compared to cIAPs. Treatment with 1 μM of the SM Birinapant for 24 h killed ~50% of SKOV-3 cells. Importantly, addition of A4 to Birinapant-treated cells significantly blocked Birinapant-induced apoptosis (Fig. 6b). Moreover, Birinapant treatment resulted in secretion of TNFα into the media of SKOV-3 cells, and addition of A4 significantly reduced secreted TNFα (Fig. 6c). Next, we found that over-expression of XIAP abolished A4-induced cell death (Fig. 6dI, II). Collectively, these results indicate that A4 mimics the function of ARTS by inducing apoptosis through specifically antagonizing XIAP. Based on our results we propose two alternative models for the mechanism of A4 action. The first model proposes that upon binding to XIAP, A4 induces an allosteric conformational change that results in the activation of XIAP E3 ligase activity, possibly by facilitating interaction of the RING motif with ubiquitin-conjugating (E2) enzymes. In this model, A4 causes a general increase in XIAP-mediated ubiquitylation and degradation of both XIAP and Bcl-2. An alternative model is that A4, like ARTS, binds directly to both XIAP and Bcl-2 with either low affinity or for a short time (“hit and run”). This recruits XIAP into close proximity with Bcl-2 and stimulates ubiquitylation and proteasome-mediated degradation of the complex. In both models, reduction of XIAP and Bcl-2 levels in cancer cells “addicted” to high levels of these proteins initiate apoptosis (Fig. 6e).
Discussion
We identified a small-molecule A4 that mimics at least some of the properties of the pro-apoptotic ARTS protein. A4 is a methyl 5-chloro-3-[[2-[4-(phenylmethyl) piperazin-1-yl]acetyl]amino]-1H-indole-2-carboxylat with a relatively simple chemical structure that conforms with Lipininski’s rule of five, making it well suited for possible future chemical modifications. Despite its small size, A4 recapitulates a number of specific biochemical and functional properties previously described for ARTS. First, like ARTS, A4 binds to XIAP-BIR3 but not cIAP1. Second, A4, like ARTS, can initiate the ubiquitylation and degradation of XIAP and Bcl-2, resulting in caspase activation and apoptosis (Figs. 4g, h, 3a–g)13,34. Third, A4 specifically antagonizes the function of XIAP, but not cIAP1, as demonstrated by inhibition of the apoptotic effect of A4 in XIAP-over-expressing cells (Fig. 6dI–II, 1c) and by its ability to suppress SM-induced cell death in the SKOV-3 assay (Fig. 6a–c). Collectively, these observations support the conclusion that A4 is a small-molecule ARTS mimetic. A4 was identified by showing highest docking affinity to the ARTS binding epitope in XIAP-BIR3, which is distinct from that of SMAC (Fig. 1b, d)14. This is in stark contrast to all currently published XIAP ligands that bind to the SMAC binding site of XIAP (Fig. 1a). These findings have important implications and suggest that the ARTS binding site in XIAP is “druggable”, and that A4 is a promising candidate for future development as a distinct anti-cancer drug.
Dual down-regulation of both major anti-apoptotic proteins, XIAP and Bcl-2, has been reported to cause enhanced apoptosis, increased sensitivity to chemotherapy and can overcome resistance of cancer cells59,60,61. To the best of our knowledge, A4 is the first compound shown to promote degradation of both these important anti-apoptotic proteins.
Significantly, cancer cells expressing high levels of XIAP were particularly sensitive to killing by A4, whereas no effect was observed on non-malignant PBMCs (Fig. 5a, b and Supplementary Table 1) and on 184A1 normal human epithelium mammary gland cells (Fig. 5cI). This suggests that A4 has selective activity towards cancer cells.
Bcl-2 is an important target for cancer therapy since it is highly expressed in a wide range of cancers, which renders them resistant to apoptotic stimuli and chemotherapeutic agents18,21,23,62,63. A series of high-affinity, small-molecule Bcl-2 inhibitors have been developed64,65, and the BH3-mimetic compound and Bcl-2-specific inhibitor Venetoclax (ABT-199) has been approved by the Food and Drug Administration for cancer treatment66,67,68,69,70. However, it remains an important goal to extend the utility of these agents to other types of cancer71,72. XIAP is another promising drug target for cancer therapy38,45,46,73. Silencing of XIAP was found to sensitize cells to chemotherapy and TRAIL receptor agonists and reduce resistance to chemotherapy45. In addition, XIAP can form heteromeric complexes with other IAPs and regulate cIAP stability74,75. Interestingly, targeting XIAP can bypass Bcl-2-mediated resistance to TRAIL and cooperate with TRAIL to suppress pancreatic cancer growth in vitro and in vivo76. Together, these observations point to a connection between the intrinsic and extrinsic apoptotic pathways, and specifically to the overlapping roles of XIAP and Bcl-2 for the regulation of cell death. Because our results suggest a dual function of A4 as an inhibitor of both XIAP and Bcl-2, it may be effective against a wide range of tumours over-expressing either one or both these proteins.
The vast majority of compounds that are currently developed as IAP antagonists (mainly SMs) act by binding and inhibiting XIAP rather than degrading it38,73. Similarly, BH3 mimetics, such as Venetoclax, act by binding and inhibiting Bcl-220,72. Therefore, another attractive feature of A4 is that it stimulates the UPS-mediated degradation of both XIAP and Bcl-2 rather than binding and inhibiting its function (Fig. 4b–h). Target protein degradation has emerged as a promising therapeutic strategy, particularly in cancer, and proteolysis-targeting chimaeras (PROTACs) are currently developed18,77,78. Advantages include the potential to reduce systemic drug concentration and its possible accompanying cytotoxic side effects, and the ability to reduce the load of increased expression of target protein, which are often inhibitory proteins78. Since many types of cancers become “addicted” to high levels of Bcl-2 and/or XIAP, we propose that drugs that can promote their degradation would be of significant interest. In this context we suggest that A4 can have a considerable promise in this regard. Similar to PROTACS, A4 promotes UPS-mediated degradation of its substrates (Fig. 4g, h), and it may be possible to exploit this feature to develop drugs with substantially improved therapeutic abilities.
We consider two main models for the mechanism of A4 action: (A) upon binding to XIAP, A4 induces an allosteric conformational change that results in activation of XIAP E3 ligase activity, possibly by facilitating interaction of the RING motif with ubiquitin-conjugating (E2) enzymes. In this model, A4 causes a general increase in XIAP-directed ubiquitylation, thereby explaining the increase in proteasome-mediated degradation of both XIAP and Bcl-2. A similar mechanism involving a conformational change was shown for the action of SMs on cIAP179,80. In order to explain A4-induced degradation of Bc-2, this model proposes that A4 stimulates the general E3 ligase activity of XIAP, perhaps by inducing a conformation that is more favourable for interaction with an E2 ubiquitin-conjugating enzyme (Fig. 6e). Moreover, this model assumes important kinetic differences in the poly-ubiquitylation and degradation of Bcl-2 versus XIAP: (A) Bcl-2 would be the preferred substrate during the initial phase, followed by self-conjugation of XIAP. (B) An alternative model is that A4 binds directly to both XIAP and Bcl-2, thereby recruiting them into close proximity to stimulate ubiquitylation and proteasome-mediated degradation (Fig. 6e). In either model, reduction of both XIAP and Bcl-2 in cancer cells “addicted” to high levels of these proteins stimulates apoptosis.
Overall, we described here the identification of an ARTS-mimetic compound, which represents a novel promising approach for development of cancer therapy. We suggest that A4 represents a novel class of ARTS-mimetic compounds acting by dual degradation of its target proteins and provides a promising starting point for the potential development of distinct anti-cancer drugs.
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Acknowledgements
We thank Hermann Steller for thoughtful discussions of the manuscript. We thank Dr. Fabrice E. Benchetrit for his help with the initial screen of the compounds. We also thank Dr. Maya Lalzar for thorough proteome analysis, and Dr. Moran Jerabek for helpful suggestions, performing and analysing the MST binding assays (at Crelux a WuXi AppTech company Ltd, Germany). We are grateful to Drs. Joe Opferman, St. Jude, Memphis, TN, USA, and Dr. Reuven Stein, Tel-Aviv University, Israel for sharing with us the DKO BAK/BAX MEFs. D.M. is a recipient of a presidential scholarship from the University of Haifa. Medicinal Chemistry analysis by Dr. David Sheppard and MST assays (CreLuX Ltd) were funded by ARTSaVIT Ltd. This work was funded by Israel Science Foundation (ISF) Grant 822/12 (to S.L.) and by a generous grant award from the Hymen Milgrom Trust (to S.L.).
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Mamriev, D., Abbas, R., Klingler, FM. et al. A small-molecule ARTS mimetic promotes apoptosis through degradation of both XIAP and Bcl-2. Cell Death Dis 11, 483 (2020). https://doi.org/10.1038/s41419-020-2670-2
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DOI: https://doi.org/10.1038/s41419-020-2670-2
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