The B-cell lymphoma/leukemia-2 (Bcl-2) family proteins are central regulators of cell death having both anti- and pro-apoptotic biochemical action. In humans, six anti-apoptotic members of this family have been identified, Bcl-2, Bcl-x_L, Bcl-B, Bcl-W, Bfl-1, and Mcl-1, further divided into three groups on the basis of their Bcl-2 homology, in which the BH3 domain explicate the main role in the anti-apoptotic signaling (1).

Bcl-2 and the anti-apoptotic proteins Mcl-1 and Bcl-x_L were found to be co-expressed at relatively high levels in a substantial proportion of heterogeneous breast tumors, including clinically aggressive basal-like cancers (2–5). The anti-apoptotic Bcl-2 proteins neutralize the cell-killing function of the pro-apoptotic family members engaging their BH3 domains. Therefore, small-molecule designed to target BH3 domain such as the mimetic ABT-737, −263 and −199 showed therapeutic potential for treating cancer (6–8). Although, ABT-263 evidenced promising results for solid tumor such as small lung cancer cells and other non-hematological malignancies, the clinical trial was early stopped due to its severe side effect (7). Finally, only ABT-199 was recently approved (April 2016) by US-FDA as Venetoclax for the pharmacological treatment of Chronic Lymphocytic Leukemia (8). Currently, the activity of Bcl-2 family inhibitors is the subject of interest in an intense area of research concerning therapeutic agents against cancer, as demonstrated by the recent patent literature (9). Cancer, a complex genetic disease resulting from mutation of oncogenes or tumour suppressor genes, can be developed due to alteration of signalling pathways; it has been well known to have numerous links to programmed cell death (PCD). Despite the remarkable progress in the classification of the different cell death modes according to the morphological presentation, signalling pathways and type of stimuli, cell death in vivo often comprises a complex interplay between apoptosis, necrosis/necroptosis, a novel form of caspase-independent PCD, and autophagy (10). Apoptosis, necrosis/necroptosis and autophagy can all occur independent of, or simultaneously with, each other. In some situations, a specific stimulus evokes only one of the processes but in other situations, a combined cell death phenotype is observed in response to the same stimulus (10). In this view, it was found that Bcl-x_L/Bcl-2 plays an important role in autophagic process (11), thanks to its binding with Beclin 1, an autophagy-related protein (12,13). The interaction between Beclin 1 and Bcl-x_L/Bcl-2 can be inhibited by the small-molecule ABT-737 at low doses, which stimulates autophagy without inducing apoptosis (14). Furthermore, it was discovered that a novel Bcl-x_L inhibitor, Z36, induces autophagic cell death, but not apoptosis, in in vitro cancer model, blocking the interaction between Bcl-x_L and Beclin-1 (15). The autophagic process promotes also necrosis in apoptosis-deficient cells and although necrosis has been considered a passive form of cell death, there is now the evidence that, instead, it represents a different type of PCD, orchestrated by autophagy, demonstrable only when apoptosis is inhibited (16–18).

JY-1-106 is a mimetic of the BH3 α-helical ‘death domain’ of the pro-apoptotic Bcl-2 proteins (19). In many cancer types, excess Bcl-x_L and Mcl-1 bind to the BH3 domain inactivating the function of pro-apoptotic Bcl-2 proteins which promotes cell survival (20,21). JY-1-106, based on a trisarylamide framework, inhibits Bcl-x_L and Mcl-1 by binding the hydrophobic groove on the surfaces of those proteins which in turn sequesters the anti-apoptotic proteins through binding their hydrophobic groove that would normally bind BH3 domains. In this manner, JY-1-106 promotes apoptosis by disrupting the interaction of Bcl-x_L and Mcl-1 with the pro-apoptotic protein Bcl-2 homologous antagonist/killer-1 (Bak-1) in multiple cancer cell lines, sensitizes tumor cells to conventional chemotherapeutic agents and inhibits tumor growth in a xeno-graft model of lung cancer (19).

Retinoids are molecules derivative by metabolism of vitamin A. One of its natural isoforms, the all-trans Retinoic acid (RA), is able to evocate autophagy and apoptosis depending on the doses administered (22). RA differentiation properties stimulates synthetic chemical approaches for several other compounds, which explicates their biochemical effects through two types of nuclear receptors, retinoic acid receptors (RARs) and retinoid X receptors (RXRs), consisting of α, β, and γ isoforms (23). Targeting this latter class of receptor, RXRs, with combined treatment with PPARγ agonist, we were able to induce cell death in breast cancer models with different estrogen receptors (ERs) profile and p53 expression and functioning. Therefore, combination therapies could represent a strategy for lowering single drug dose (24,25). Pre-clinical observations indicate that, beside triple negative profile, breast cancer cell display also resistance to retinoids due to the high expression of RARγ (26,27). Herein we tested the effect of JY-1-106 Bcl-x_L/Mcl-1 inhibitor in combination with a RARγ selective retinoid SR11253, highlighting massive autophagy and necrosis but not apoptosis in triple-negative breast cancer (TNBC) cells MDA-MB-231, the most aggressive breast cancer subtype used as a basal-like tumor cell model.

The heterogeneity of breast cancer classified them in base of a specific biochemical markers profile based on estrogen receptors (ER), progesterone receptors (PR) as well as human epidermal growth factor receptor 2 (HER2) expression to address pharmacological intervention. The TNBC did not express any of these receptors (ER-/PR-/HER2-) therefore, is the most aggressive breast cancer type (28). Clinical/Pharmacological protocols for TNBC are limited to surgery, radiation, and systemic chemotherapy due to the lack of more specific therapeutic targets (28). TNBC cells line represent an important tool for screening and searching better treatment for this type of cancer (27). Recently, the suppression of Mcl-1 expression by microRNA-101 was able to inhibits cell progression in TNBC (29). Significantly, almost the 70% of breast cancers overexpress anti-apoptotic Bcl-2 family members evidencing how inhibition of specific targets belong to this family could represent an attractive way for breast cancer treatment (30). Therefore, Mcl-1 represent an interesting target for TNBC treatment. In this study, we tested the JY-1-106 a Bcl-x_L/Mcl-1 inhibitor (α-helix mimetic for BH3 domain) in MDA-MB-231 TNBC cells line. Although preliminary studies, our results show that this compound, in combination with SR11253, has the capability to strongly reduce MDA-MB-231 cell viability, stimulating autophagy and necrosis. Autophagosome is evidenced by MDC staining (Fig. 2B, green staining) and, as consequence, the inducing cell death by necrosis by DAPI staining and LDH release (Fig. 2B, blue staining and C). The existence of a ‘programmed necrosis’ seems to be conditional only to apoptosis inhibition (18,31,32). It is worth to note that a novel form of PCD, named necroptosis, was recently discovered, although the molecular mechanisms of this process need to be further elucidated. Necroptosis is characterized by necrotic cell death morphology and activation of autophagy related to inflammatory response (10).

Here we found that JY-1-106-treated cells did not show any features of apoptosis, since DAPI staining do not highlighted chromatin condensation, indicative of apoptotic bodies' formation (Fig. 2B, blue staining). Instead, in the cellular model used, we observed vacuoles formation after 48 h incubation upon JY-1-106, with a maximum between 72 and 96 h (data not shown). The combination with RARγ SR11253 inhibitor massively amplified this process (Fig. 2B, green staining). To confirm the hypothesis that autophagy promotes necroptosis in apoptosis-deficient cells (18) we evidenced an increase in lactate dehydrogenase LDH release from damaged cells. LDH activity was enhanced after 96 h for both compounds, alone and or in combination (Fig. 2C) the result, corroborates the DAPI staining that show nuclear swelling (indicate by white arrow) but not chromatin condensation (Fig. 2B, blue staining).

In the complexity of the biochemical mechanisms governing TNBC cells, the negative modulation of RARα in favor to RARγ shown cell proliferation, cancer survival and tumor growth in MMTV-Myc onco-mice (26). Experimental evidence established that the resistance to vitamin-A derivatives of the ER-negative breast cancer cells has been linked to a down-regulation of RARα levels (26,33). In MDA-MB-231 cells, it was reported a very low expression of RARα while RARγ is strongly overexpressed (27). The activation of the RARα pathway is related to tumor growth inhibition, differentiation and cell death, whereas RARγ was functionally linked to the promotion of tumor growth. The pharmacologic activation of RARα or inhibition of RARγ activity reduces cancer cell growth and the enhancing of the RARα/RARγ ratio is favorable to cell death (33). In this context, the pharmacologic inhibition of RARγ controlled by SR11253 reduces cancer cell growth, enhancing the RARα/RARγ ratio, favorable to cell death (26). RARγ antagonist SR11253 alone inhibited the proliferation of MDA-MB-231 cells which was not further inhibited by RA or the RARα agonist Am580 individually, as was expected due to the low expression of RARα. It is notable that both compounds, alone or in combination, had no effect on the modulation of RARγ (Fig. 3B). JY-1-106 by itself induced expression of RARα (Fig. 3A) with a favorable ratio of RARα/RARγ which helps cell death (Fig. 3C). In HL60 cells, a model of pro-mielocitic leukemia hematologic malignant, we demonstrated that RARα expression was unaffected by JY-1-106 and only RARγ was downregulated with the combined treatment (34). The results obtained here and the others in HL60 leukemia cells indicate that the impact of JY-1-106 and retinoid receptor compounds is dependent upon cell type and exist a cross talk between Bcl-x_L/Mcl-1 activity and RARs expression profile, since the BH3 mimetic is able to modulate RARs. In any case, the finality of this cross talking is to induce cell death following either apoptosis (in leukemia) or authophagy/necrosis (in TNBC). The p53 protein is a critical transcriptional activator promoting apoptosis, autophagy and therefore necrosis (35,36). Whereas the functions of p53 in promoting apoptosis and autophagy are well established, recently it was also identified to have a role in activating necrosis. Vaseva et al (36) show that p53 stimulates necrotic cell death in tumor cells genetically deficient to undergo apoptosis triggering mitochondrial permeability transition pore. In MDA-MB-231 cells, the p53 harbor a tumor-derived mutation (Arg280 to Lys280) in the DNA Binding Domain which still maintain the positive charge to interact with the phosphate backbone of the DNA consensus sequence (37,38). In our set of experiments we have shown a strong upregulation of the p53 mRNA using the Bcl-xL inhibitor with no additional effect of the RARγ antagonist after 96 h incubation. These findings suggest p53 involvement during the autophagic/necrotic by JY-1-106 (Fig. 3D) highlighting that the action of this molecule on p53 is independent by the co-treatment. Therefore, JY-1-106 assume an interesting profile for preclinical TNBC treatment, considering that also promote RARα expression without altering RARγ (39). Therapy-induced autophagy and necrosis in cancer treatments has been investigated and may be therapeutically useful since they are in early phase clinical trials (40). It worth to note that, last year the molecule ABT-199 was approved by US-FDA as Venetoclax (April 2016). Venetoclax represents the first pharmacological agent today in therapy, which targets specifically Bcl-2 pathway, for the treatment of Chronic Lymphocytic Leukemia, in patients harboring specific genetic characteristic (8). Our results showed a synergistic effect in reducing cell viability and inducing autophagy and necrosis by the combination of the Bcl-x_L/Mcl-1 inhibitor JY-1-106 with a specific RARγ antagonist. The combined treatment seems to be an attractive strategy for controlling cancer progression in basal-like tumor cell model.