Multiple myeloma (MM) is a hematological malignancy, with an annual incidence of approximately 6.6 cases/100,000 people [1]. It is a plasma cells (PCs) neoplasm, which provides the function of secreting antibodies in the bone marrow (BM). This tumor is usually diagnosed by serum protein electrophoresis (SPEP), in which a distinctive M peak is evident, or by estimation of free light chains in urine [2]. MM cells are the malignant counterparts of long-lived PCs in the post-germinal center (GC), characterized by strong BM dependence and somatic hypermutation (SHM) of immunoglobulin (Ig) genes [3]. MM is affected by in-depth genetic alterations that occur during the progression of the disease, which is why it is generally recognized as a highly heterogeneous disease. Its evolutionary course starts with a pre-malignant status noted as monoclonal gammopathy of undetermined significance (MGUS) [4], a posterior stage termed smoldering MM (SMM) [5], and may ultimately escalate into symptomatic myeloma [2]. The hallmark genetic events (or aberrations) are commonly classified as primary and secondary events. Primary aberrations are grouped into two subgroups: non-hyperdiploidy, comprised of primary Ig (t) translocations involving the Ig heavy chain (IGH) in the 14q32 region including t(4;14), t(11;14), t(14;20), and the hyperdiploidy group comprised of trisomies of chromosomes 3, 5, 7, 9, 11, 15, 19 [6]. Multi-copy chromosomes carry genes whose overexpression may be responsible for the replicative potential of cells. The MGUS clone is subsequently affected by secondary abnormalities that may or may not lead to the transition to the MM [7]. Secondary abnormalities, also genetic, include MYC proto-oncogene (MYC) translocation, 17p or 1p32 chromosome deletion, 1q chromosome amplification or mutations of rat sarcoma virus (RAS) gene [NRAS proto-oncogene (NRAS) and KRAS proto-oncogene (KRAS)], B-Raf proto-oncogene (BRAF), mitogen-activated protein kinase (MAPK), and nuclear factor kappa-light chain enhancer of activated B cells (NF-κB) pathways or overexpression of the anti-apoptotic protein B cell lymphoma 2 (BCL-2) [8] (Figure 1).

Off-label drug use refers to the use of drugs under conditions other than those for which they were approved, such as dose, age of the patient, administration route, and contraindications [41]. This strategy is implemented to treat health problems for which there are no other currently approved drugs, for example in the case of uncommon diseases or specific subset of patients [42]. Off-label uses may prove particularly valuable in treating patients with an orphan disease, for which it may be the only available treatment [43].

The purpose of off-label use is to aid in the recovery of an individual patient. In oncology, pediatrics, geriatrics, and obstetrics, patient care can be difficult if off-label use is not employed [44, 45]. An estimate claims that off-label prescribing reaches 90% in the pediatric population or 40% in adults [46]. In oncology it achieves up to 50% of patients, and is widely applied in pediatric oncology [47]. The use of off-label drugs is believed to have contributed to an overall cure rate of more than 70% in pediatric malignancies [48]. Underlining, consequently, that cancer patients can benefit greatly from this phenomenon. One issue raised, however, is that the use of off-label drugs is not always supported by solid scientific evidence [41]. Scientific review and investigation of medications, that are tested and approved for a given condition, help protect the patient as much as possible from side effects. By using off-label drugs, this protection may be compromised [49], so they should be used in a precise and controlled manner.

Several patients with different tumors expressing the same target therefore may benefit from off-label prescription [50]. This concept is carefully translated into MM. Accordingly, it is possible to employ a variety of off-label drugs that can block the de-regulated molecular pathways in this cancer.

The RAS/RAF/MEK/ERK pathway is a critical intermediary of many essential biological processes. It is involved in cell proliferation, migration, survival, and angiogenesis. Members of the RAS protein subfamily, NRAS, KRAS, and HRAS, function as molecular switches in cellular signal transduction. These small guanosine triphosphate hydrolases (GTPases) activate RAF-kinases, which in turn phosphorylate MEKs and finally ERK-kinases.

MAPK-pathway mutations are one of the most common mutations found in MM [37]. It is also intriguing to note that the number of patients with mutations appears to be higher in relapsed disease [39]. The literature data on the prognostic significance of mutations on the MAPK pathway do not follow a univocal trend but, on the contrary, seem to be conflicting. While some research groups have found negative effects of NRAS mutations [51], others have observed a negative effect in KRAS mutations [52], and still others have found no prognostic effect [53]. Despite the high prevalence of mutations activating the MAPK pathway, these controversial results can be explained by considering that only some of the mutations effectively appear to activate it.

It has been previously demonstrated that only KRAS G12D and BRAF V600E consistently resulted in phosphorylation of the ERK downstream target (Figure 2). Other mutations were associated with increased phospho-ERK levels in only a small percentage of cases.

As a consequence of the difficulty in targeting RAS, to date only one specific inhibitor has been identified for the KRAS G12C mutation, but this is rare in MM [54]. An investigation was conducted using the inhibitor tipifarnib, which was found to inhibit RAS and to have limited activity in MM patients. It also does not diminish, significantly, the activation of the MAPK pathway [55]. Along the lines of what was observed, the emphasis shifted to MAPK pathway inhibitors having downstream targets of RAS, which include BRAF and MEK.

Due to several pitfalls, it is necessary to accomplish patients screening. In a number of malignancies, it has been noted how, in the absence of the mutation involving BRAF, treatment of patients with inhibitors of this mutation can drive an increase in RAS signaling those results in activation of the pathway. This effect would appear to be triggered by a decrease in negative feedback at the level of RAS [56], binding of wild-type BRAF to CRAF, and subsequent MAPK signaling through CRAF [57, 58].

Attention must also be paid to how to identify patients who benefit from inhibition of the MAPK pathway [59]. A retrospective study that examined the effects of treatment with trametinib (MEK 1/2 inhibitor) illustrates this problem well. In that study, patients with mutations determining MAPK pathway triggering or carrying oncogenic mutations in NRAS, KRAS, and BRAF were selected. Of this cohort of patients, only 40% achieved at least a partial response (PR) when treated with trametinib coupled with other drugs, whereas only 10% exhibited at least a PR when treated solely with trametinib [60].

This underscores the critical importance, in terms of therapeutic efficacy, of precisely identifying patients who might be eligible for MAPK pathway inhibition. Several recent studies have therefore included only patients with the BRAF V600E/K mutation, which has been shown to consistently activate ERK and has also been closely examined in a variety of other cancers. In addition, several potent BRAF V600E mutation-specific inhibitors are available, such as vemurafenib, encorafenib, and dabrafenib. Approximately 5% of patients harbor a BRAF V600E clone or subclone. Early data on targeting the BRAF V600E mutation in patients with MM have been contradictory: some studies have shown treatment efficacy in RRMM patients with the mutation [61, 62], while others did not detect any response [63, 64].

Although BRAF targeting is effective in tumor types carrying mutant BRAF, however, there is rapid resistance against BRAF inhibitors. This phenomenon can be explained by several mechanisms among which one of the most frequent involves the acquisition of activating mutations upstream or downstream of BRAF in NRAS or MEK, leading to alternative signaling and bypass of BRAF [65, 66]. In addition, MEK inhibition has been seen to induce therapeutic resistance through upregulation of other signaling pathways, such as the PI3K/AKT pathway [67]. To circumvent these resistance mechanisms, it has been suggested to combine BRAF inhibition with MEK inhibition in a way that acts on two of the interactors involved in the signaling pathway. These approaches have been found to be very efficient in melanoma cases and, notably, dual inhibition has been more effective than BRAF inhibition alone [68]. Currently, dual inhibition is the most widely used strategy in MM studies.

The BCL-2 gene family encodes more than 20 proteins that regulate the intrinsic apoptosis pathway and are fundamental to the balance between cell survival and death [71].

The BCL-2 family proteins can be categorized into three groups, namely antiapoptotic multidomain proteins (such as BCL-2, BCL-XL, and MCL-1), proapoptotic multidomain proteins [like BCL-2-associated X (BAX), BCL-2 antagonist/killer (BAK), and BCL-2-related ovarian killer (BOK)], and proapoptotic BCL-2 homology domain 3 (BH3)-only members [e.g., P53 up-regulated modulator of apoptosis (PUMA), NOXA, BH3 interacting-domain death agonist (BID), and BLC-2 interacting mediator of cell death (BIM)] [71].

BCL-2 family proteins are capable of giving rise to different interactions; however, their corresponding interaction turns out to be selective and specific. For example, BIM and PUMA can bind all members of the anti-apoptotic multidomain BCL-2 family, whereas NOXA binds only to MCL-1 [72, 73]. In contrast, BCL-2 associated agonist of cell death (BAD) interacts with BCL-XL and BCL-2, but not with MCL-1 [72, 74].

The intrinsic pathway involves the mitochondria and after receiving the stimulus, the pro-apoptotic BH3-only members bind and neutralize the antiapoptotic proteins. This leads to oligomerization of multi-domain pro-apoptotic member (BAX/BAK) present on mitochondrial membrane surface whose activation leads to permeabilization and formation of pores in outer mitochondrial membrane, releasing various apoptotic mediators [high-temperature requirement protein A2 (HtrA2), also called Omi, second mitochondria-derived activator of caspase (Smac)/direct inhibitor of apoptosis (IAP)-binding protein with low pI (DIABLO), cytochrome c, endonuclease G (Endo G) and apoptosis-inducing factor (AIF)] [75]. BAK may contribute to early mitochondrial fragmentation while BAX is probably more important for subsequent pores development and degeneration in the outer membrane [75]. The release of cytochrome c in cytosol causes the association of apoptosis protease-activating factor 1 (APAF-1) and ATP/dATP to form intracellular apoptosome that activates caspase-9 [76]. Disrupted mitochondria also produce Smac/DIABLO, which releases caspase-3 from X-linked IAP (XIAP)-mediated inhibition. The role of IAP is to act a guardian inside a cell to defend against the mediator of apoptosis (HtrA2/Omi, Smac/DIABLO) by binding to caspase-3/-9 whereas Endo G and AIF operate independently of caspase causing chromatin condensation and fragmentation. Anti-apoptotic members of the BCL-2 family, through direct protein interactions involving binding to their BH3 motifs, inhibit the activity of BAK/BAX. Inhibition of the anti-apoptotic members of this protein family has been accepted in clinical practice being that BCL-2 family members are key regulators of common apoptotic pathways [77].

Several BH3 mimetics have entered clinical trials [78], although, due to the absence of a trustworthy validation assay to directly test the mitochondrial activity of new candidate BH3 mimetics, there have been many erroneous reports of agents advertised as BH3 mimetics despite their off-target mechanisms of action. BH3 profiling assesses the activity of a compound at the mitochondrial level by measuring cytochrome c release as a marker for mitochondrial outer membrane permeabilization.

Villalobos-Ortiz et al. [79] proposed a comprehensive biochemical toolkit consisting of BH3 profiling in conjunction with the high-throughput Annexin V/Hoechst viability assay for validation of BH3 mimetic candidates. In order to accredit mitochondrial assays of BH3 mimetics, they performed a BH3 profiling method (iBH3) that consists of exposing mitochondria to standardized concentrations of BH3 peptides and measuring outer mitochondrial membrane permeabilization by cytochrome c release using flow cytometry [79].

Another approach was proposed by Bhola et al. [80] who developed a high-throughput method to assess the sensitivity to BH3 mimetics of tumors within 24 h of excision, providing data demonstrating that the very process of prolonged ex vivo propagation rapidly alters chemical vulnerabilities relative to the primary tumor [80].

The same authors nicely demonstrated a relationship between BCL-2 pathway and RAS signaling in cancer stem cell providing the rational to design new strategy to treat resistant cancers [81].

Drugs mimicking the action of BH3-only proteins indirectly lead to BAX/BAK activation. This allows permeabilization of the mitochondrial outer membrane, apoptosome formation and subsequent caspase activation and apoptosis. This is particularly true in the treatment of chronic lymphatic leukemia, typified by the approval of the BCL-2 inhibitor venetoclax as a particularly effective rescue therapy for this disease [70]. The ability of venetoclax is to bind BCL-2, through high-affinity binding, causing blockade of its signaling in the cell; this is the mechanism of action that is responsible for the TP53-independent apoptotic event [82] (Figure 3).

Chronic lymphocytic leukemia cells can effectively evade apoptosis due to their marked dependence on BCL-2 activity; in other malignancies, distinct members of the BCL-2 family by contrast may have a greater influence. This is the situation in MM. Indeed, in PC and MM, previous preclinical studies have indicated that MCL-1 may be the major anti-apoptotic analog of BCL-2 [8]. Based on this, venetoclax being specific for BCL-2, its clinical trial in MM patients has begun with moderate enthusiasm.

However, it has been demonstrated in MM cell lines and in primary patient samples that venetoclax is highly effective in a specific subgroup of MM with t(11;14), which is present in approximately 20% of MM, mainly because of the higher BCL-2/MCL-1 messenger RNA (mRNA) ratio [83].

Nevertheless, even among patients with t(11;14) myeloma, the response rate is only 40–60% [84]. Knockdown of CCND1 has been shown to fail to induce resistance to venetoclax, suggesting that t(11;14) and CCND1 have no direct roles in response to venetoclax [85].

To further explore the biology responsible for venetoclax sensitivity in myeloma and to potentially identify additional biomarkers, Gupta and colleagues [85] performed a data analysis based on assessment of RNA-sequencing and assay for transposase-accessible chromatin (ATAC)-sequencing from samples of patients screened for venetoclax sensitivity. The identical analysis was also conducted using cell lines. Venetoclax-sensitive myeloma is enriched in B-cell-associated genes that are not typically expressed in PCs [85, 86]. The expression of these genes could not be explained completely by t(11;14) because such genes were observed almost exclusively in venetoclax-sensitive t(11;14) and were mostly absent in venetoclax-resistant t(11;14). No single gene was consistently expressed in all sensitive cell lines or patient samples, suggesting that a panel of genes or cell surface markers may be required to distinguish sensitive and resistant myeloma.

Through ATAC-sequencing analysis, they also identified a pattern of B-cell-like chromatin accessibility in venetoclax-sensitive cell lines, suggesting increased binding of transcription factors at some of these accessible sites. Overexpression of one of these transcription factors, basic leucine zipper ATF-like transcription factor (BATF), led to increased sensitivity to venetoclax. BATF is an essential B-cell developmental transcription factor which is activated during the B-cell receptor signaling, with subsequent activation-induced deaminase expression and class change recombination. However, its expression and role in PCs are not understood [87]. BATF represses and promotes transcription depending on the presence of other transcription factors, including the PC transcription factor interferon regulatory factor 4 (IRF4), and may contribute to the venetoclax-sensitive transcription program in PCs through alterations in chromatin accessibility. Thus, despite possessing the characteristics of terminally differentiated PCs, venetoclax-sensitive myeloma aberrantly preserves or reactivates aspects of the B-cell program, including dependence on BCL-2 that is normally downregulated during differentiation.

Although both BCL-2 expression and the BCL-2/BCL-XL ratio are higher in venetoclax-sensitive cell lines and patients, they show a significant degree of overlap when comparing sensitive and resistant samples, thus making it difficult to select a specific cut-off that is useful for clinical decision-making [84, 88].

MM is accompanied by high genomic instability reflected in multiple genetic abnormalities involving several cancer pathways; therefore, MM is typically characterized by high heterogeneity. The progress to discover sensitive genomic targets against which to develop novel agents with the potential to improve patient survival has made remarkable progress. However, these efforts have been severely challenged by the intricate biology of the disease and the molecular mechanisms of MM.

Despite all the progress, MM is still incurable in most patients. Future hopes are therefore directed toward identifying additional therapeutic strategies and new targets for its treatment.

In this review, we summarized the RAS/RAF/MEK/ERK and BCL-2 signaling pathway describing their involvement in the pathogenesis of MM and the therapeutic approaches developed on them.

The efficacy of these therapeutic agents was tested on different MM cell lines and in MM patients and produced encouraging results. MEK inhibitors in combination with other kinase or mutant gene inhibitors have shown promising results in patients with RRMM. The combination delays the onset of acquired resistance resulting in increased progression-free survival and overall patient survival.

Similarly, the BCL-2 inhibitor venetoclax as monotherapy and in combination with other anti-myeloma agents has demonstrated improved outcomes in early clinical trials in MM patients with BCL-2 overexpression regarding the cytogenetic status.

With the availability of different types of treatment, over time it will be more complex to choose which treatment approach is most suitable for the patient and, as a result, it becomes necessary to understand how to incorporate such strategies into existing treatment approaches. An appropriate option might be to use a different combination of pathway-specific drugs that, by interacting with each other, could reduce the likelihood of developing drug resistance.

This could be further aided through deep molecular analysis of MM cells profile of the single patient, which would allow the identification of patients who would benefit from these drugs.