XPO1 in B cell hematological malignancies: from recurrent somatic mutations to targeted therapy

Many recent publications highlight the large role of the pivotal eukaryotic nuclear export protein exportin-1 (XPO1) in the oncogenesis of several malignancies, and there is emerging evidence that XPO1 inhibition is a key target against cancer. The clinical validation of the pharmacological inhibition of XPO1 was recently achieved with the development of the selective inhibitor of nuclear export compounds, displaying an interesting anti-tumor activity in patients with massive pre-treated hematological malignancies. Recent reports have shown molecular alterations in the gene encoding XPO1 and showed a mutation hotspot (E571K) in the following two hematological malignancies with similar phenotypes and natural histories: primary mediastinal diffuse large B cell lymphoma and classical Hodgkin’s lymphoma. Emerging evidence suggests that the mutant XPO1 E571K plays a role in carcinogenesis, and this variant is quantifiable in tumor and plasma cell-free DNA of patients using highly sensitive molecular biology techniques, such as digital PCR and next-generation sequencing. Therefore, it was proposed that the XPO1 E571K variant may serve as a minimal residual disease tool in this setting. To clarify and summarize the recent findings on the role of XPO1 in B cell hematological malignancies, we conducted a literature search to present the major publications establishing the landscape of XPO1 molecular alterations, their impact on the XPO1 protein, their interest as biomarkers, and investigations into the development of new XPO1-targeted therapies in B cell hematological malignancies.

Exportin-1, also called chromosome region maintenance 1 (CRM1/XPO1), is a pivotal eukaryotic nuclear export protein that carries an extensive array of proteins from the nucleus to the cytoplasm. XPO1 is a member of the importin-β superfamily of karyopherins that mediates the translocation of numerous RNAs and cellular regulatory proteins, including tumor suppressor proteins (TSPs), such as p53, BRCA1, survivin, nucleophosmin, APC, and FOXO. XPO1 hydrophobic groove binds to the leucine-rich nuclear export signal (NES) domain of these “cargo” proteins. XPO1 is overactive in many cancer [1–7], and thus, XPO1 has been considered a potential anti-cancer target for decades.

The clinical validation of the pharmacological inhibition of XPO1 was recently achieved with the development of the selective inhibitor of nuclear export (SINE) compounds. SINEs are orally bioavailable small-molecule inhibitors of XPO1-mediated nuclear protein export [8–10].

Especially for hematological malignancies, many publications have highlighted the value and efficacy of several SINE agents, all of which have an interesting anti-tumor activity in patients with massive pre-treated hematological malignancies [2, 8, 9, 11–15]. Currently, the dominant SINE pharmacological agent, selinexor (KPT-330), is being assessed in phase 1 and 2 clinical trials for various cancers.

Furthermore, recent studies have focused on the characterization of the molecular alterations in the gene encoding XPO1 and showed a mutation hotspot (E571K) in the following two hematological malignancies with similar phenotypes and natural histories: primary mediastinal diffuse large B cell lymphoma (PMBL) and classical Hodgkin’s lymphoma (cHL) [12, 16]. Missense substitutions targeting XPO1 have also been previously reported at a low frequency (<5%) in chronic lymphocytic leukemia (CLL) and esophageal squamous cell carcinoma (ESCC), indicating that these mutations may also play a role in other oncogenic processes [17–19].

We conducted a literature search to present the recent major publications establishing the landscape of XPO1 molecular alterations, their impact on the XPO1 protein, their interest as biomarkers, and investigations into the development of new SINE therapies in B cell hematological malignancies.

The XPO1 protein was first identified by a genetic screening of Saccharomyces pombe and was recognized as a nuclear component maintaining the higher order of the chromosome structure [20]. Thereafter, XPO1 was described as a ubiquitous nuclear export protein of the karyopherin β family [21–23]. The human XPO1 gene is located on chromosome 2p15, which is close to the c-REL 2p16.1 locus, a locus well known to be gained or amplified in PMBL, germinal B-cell-like (GCB) diffuse large B cell lymphoma (DLBCL), and cHL.

The XPO1 protein 3D conformation and XPO1-mediated nuclear export require the action of Ran (Ras-related nuclear protein), a small G protein. A RanGTP-RanGDP gradient is maintained across the nuclear membrane due to the subcellular localization of Ran regulators. Indeed, RanGDP is converted into RanGTP through the action of RCC1 (regulator of chromosome condensation 1), the Ran guanine nucleotide exchange factor, which is tethered to the chromatin. In contrast, RanGAP, the GTPase-activating protein, is cytosolic or bound to the outer cytoplasmic side of the nuclear pore complex (NPC). RanGAP allows the dephosphorylation of RanGTP into RanGDP. As shown in Fig. 1, RanGTP and cargos bind XPO1 in a cooperative manner, forming stable ternary complexes that are exported through the NPC. These complexes are disassembled in the cytoplasm, cargos are released, and XPO1 is recycled back to the nucleus for further rounds of export [24]. The association–dissociation of XPO1-cargo complexes are, thus, regulated by the direct binding of Ran in a compartment-specific manner.

Schematic representation of XPO1-mediated nuclear export. RanGDP (D) is converted to RanGTP (T) through the action of RCC1 (the Ran guanine exchange factor). The export complex composed of RanGTP, cargo (C), and XPO1 (X) proteins shuttles through the nuclear pore complex (NPC) into the cytoplasm where RanGTP is dephosphorylated by the action of RanGAP, the Ran GTPase-activating protein. Cargo/XPO1 complexes are dissociated, and XPO1 shuttles back to the nucleus for further rounds of nuclear export

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Structural analyses have shed light on the XPO1-mediated export molecular mechanism. Crystal structures of XPO1 bound to various NES-cargos and ternary complexes of RanGTP/XPO1/cargos are available in the Protein Data Bank [25]. Human XPO1 is a 120-kDa protein containing 21 consecutive tandem HEAT repeats (H1–H21). Each HEAT repeat is formed by two antiparallel α-helices A and B connected by loops of varying lengths. The A helices align to form an outer convex surface whereas the B helices form an inner concave surface (Fig. 2) [26, 27]. The N-terminal HEAT and the C-terminal HEAT are in close proximity, and XPO1 adopts a ring or toroidal shape. The A helices of H11 and H12 form a hydrophobic groove that constitutes the NES-binding site. The so-called leucine-rich NES motif, which is present in XPO1 cargo proteins, is a short peptide sequence of 10 ordered amino acid residues as follows: Φ1X2-3Φ2X2-3-Φ3XΦ4, where Φ is either isoleucine, leucine, methionine, phenylalanine, or valine, and X is any other amino acids [28]. The hydrophobic side chain of NES fits into five hydrophobic pockets along the NES-binding groove [26, 27, 29]. The NES-binding groove of the unliganded XPO1 adopts a closed conformation, which is stabilized by the binding of the H9 loop to the inner surface of H11 and H12. In this inhibited conformation, the B-helix of H21 (called the C-helix) lies within the central cavity with its C-terminus closed to the NES-binding site [30]. The transition from this inactive state to an active state is dependent on the binding of both RanGTP and cargos. RanGTP associates with the inner surface of XPO1 due to the movement of the H9 loop and C-helix away from the inner surface [31]. In the cytoplasm, the ternary XPO1-cargo-RanGTP complexes are dissociated. The binding of the Ran-binding domains (RanBDs) present in RanGAP and the associated proteins Ran-binding proteins 1 and 2 (RanBP1/2) induces a movement of the H9 loop, driving the rotation and translation of H11 and H12 and the release of cargos [31, 32]. Thus, the affinity of XPO1 to its cargos is drastically reduced by the site-directed mutagenesis of residues within the NES-binding groove [28, 29]. Conversely, mutations of the residues within the H9 loop or the deletion of the C-helix increases the affinity of XPO1 to its cargos [26, 32] and reduces the rate of cargo release [31]. Furthermore, García-Santisteban et al. recently described a new cellular reporter to investigate XPO1 nuclear export activity and the functional consequences of the highly recurrent cancer-related E571K mutation [33]. They showed that this mutation increases the affinity of the XPO1 protein to NES sequences, which may shift the nucleocytoplasmic transportation and thus modify the cell equilibrium; thus, the mutant XPO1 E571K plays a role in carcinogenesis.

3D-XPO1 conformations illustrating its interaction with RanGTP, RanGTP-SNUPN, LMB, and KPT-285. (a) Ring-shaped XPO1 is colored blue to red in rainbow colors along the chain from the N-terminus to the C-terminus, showing the C-helix (red) autoinhibitory activity (PDB-ID 4FGV) [96], (b) XPO1 complexed with snurportin 1 (SNUPN) (PDB-ID 3GB8) [27], (c) with RanGTP, in magenta (PDB-ID 5DIS) [97], or (d) with both proteins (PDB-ID 3NC1) [28]. XPO1 inhibitors LMB (e) or KPT-185 (f) (both in red and arrowed) interacting with XPO1-RanGTP-RanBP1 (in gray) (PDB-ID, 4HAT [98], and 4GMX [9])

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As mentioned previously, NES sequences are diverse but conform to the consensus sequence Φ1X2-3Φ2X2-3-Φ3XΦ4. NESs were first described in the Rev protein of HIV and the cyclic AMP-dependent protein kinase inhibitor α (PKIα) [34, 35]. Currently, NESs have been identified in more than 200 proteins with various functions, such as cell cycle regulators, transcription factors, ribonucleoprotein complexes, translation factors, and viral proteins. NESs are compiled in the following comprehensive database: NESdb© [36, 37]. Among the XPO1 cargos, several proteins such as TSPs (p53, p73, FOXO1), growth regulators (RB, p21, CDC25, cyclin B1/D1), and anti-apoptotic molecules (nucleophosmin, survivin) control essential physiological cellular processes. Thus, correct XPO1 function is mandatory for normal cell homeostasis. In turn, abnormalities in nuclear export lead to diseases, including solid and hematologic cancers. In eukaryotes, RNAs are exported from the nucleus through the NPC. rRNAs (60S and 40S subunits), snRNAs, and a subset of miRNAs and mRNAs are exported in an XPO1-dependent manner [38, 39]. RNA export requires specific adaptor proteins, such as NDM3 [40].

Independently of its role in nuclear export, XPO1 is involved in the maintenance of chromosome integrity and the nucleation of microtubules at the kinetochore [41, 42]. With its partners (RanBP2, RanGAP, and RanGTP), XPO1 stabilizes the microtubules to the kinetochores, thereby allowing proper chromosome segregation [43]. XPO1 is also present at the centrosomes throughout the cell cycle. In complexes with RanGTP, XPO1 recruits pericentrin, the major centrosomal scaffold protein. Together with the microtubule nucleator ϒ-TuRC complexes, XPO1 permits spindle microtubule assembly [44]. Finally, RanGTP/XPO1 complexes bind nucleophosmin and maintain the fidelity of centrosome duplication [41, 44]. It is worth noting that the abnormal functioning of the dual XPO1 functions (nuclear export and mitosis regulation) could be highly deleterious for cells initiating and/or maintaining transformation processes.

In a recent work based on NGS, the high prevalence of a recurrent single nucleotide variant (SNV) (E571K) of XPO1 in both PMBL and cHL was demonstrated for the first time [12]. This mutation was observed in 25% of cases and appeared to be a specific genetic feature of these lymphomas as this mutation was observed at a very low frequency or was absent from mediastinal gray-zone lymphoma (MGZL) and GCB or activated B cell-like (ABC) DLBCL cases. In another recent study, recurrent XPO1 E571K mutations were found in a large cohort of 94 patients with cHL using digital PCR (Fig. 3) and NGS experiments [16]. This novel information might provide new guidance on driver events and tumorigenesis in cHL. In total, 24% of patients with cHL harbored the XPO1 E571K mutation. In this study, including 94 patients with all stage of cHL undergoing first-line treatment, the overall survival (OS) and progression-free survival (PFS) were similar between the mutated and wild-type patients at a median follow-up of 34.5 months. Furthermore, no alternative XPO1 variants were detected by NGS on cHL biopsies; however, to date, the impact of the highly selected E571K mutation in the pathogenesis of cHL remains unknown. Several proteins known to play a major role in cHL oncogenesis, including STAT1, FOXO1, or CIITA, have also been identified as cargo proteins [45–47]. Whether the XPO1 mutations impair the nucleus/cytoplasm transport of these proteins remains to be confirmed.

Positron emission tomography (PET) and digital PCR plots from a biopsy specimen and plasma cell-free DNA from a classical Hodgkin lymphoma patient with mediastinal involvement. Representative views of digital PCR (dPCR) plots (mutant samples) for XPO1 E571K quantification in a tumor (VAF = 0.3%, left) and plasma cell-free DNA (cfDNA) (VAF = 0.15%, right) from a cHL patient at diagnosis by droplet dPCR (Biorad). Data are displayed in a scatter plot based on the color of FAM and VIC events. Green, blue, orange, and black plots represent wild-type alleles, mutant alleles, both alleles in the same droplet, or no amplifications, respectively. VAF, variant allele fraction

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There is clear evidence for a pathological imbrication between PMBL and cHL, specifically the nodular sclerosis subtype; whether both might derive from thymic B cells is currently an area of discussion [48]. The fact that the XPO1 E571K mutation is enhanced in both these subtypes emphasizes the hypothesis of a common origin and a strong oncogenic role for this gene. The XPO1 mutation might serve as a distinctive genetic feature that facilitates the differential diagnosis of PMBL from DLBCL with mediastinal involvement, or MGZL, which are genetically similar but clearly distinct in their natural history and outcome [12, 49, 50].

Missense substitutions targeting XPO1 have also been previously described at a low frequency (<5%) by NGS experiments in CLL [17, 19] and ESCC [18]. Notably, in a recent report, XPO1 mutations were also detected in 38 of 486 (7.8%) CLL patients, 74% of which were E571K hotspot mutations [2]. An adverse prognostic impact was demonstrated with these XPO1 mutations, but the overall outcome was not poor in patients receiving ibrutinib. Although the oncogenic process of mutations in patients with CLL, PMBL, and cHL are unclear, the recurrent nature of XPO1 mutations in these malignancies strongly supports its involvement in the pathogenesis of the disease and suggests that these XPO1 mutations may occur in various oncogenic mechanisms.

The XPO1 overexpression process in cancer cells is not currently clearly known. Several mechanisms may be involved, such as chromosomal translocations or gain of copies of the XPO1 gene. It was recently demonstrated that a cryptic XPO1-MLLT10 fusion detected by RNA-sequencing is associated with the deregulation of the HOXA gene locus expression [51]. HOXA-independent activity of the XPO1-AF10 fusion protein could contribute to leukemogenesis in T cell acute lymphoblastic leukemia (T-ALL) via an abnormal transport of tumor suppressors and growth-regulatory cellular factors and/or the dominant negative inhibition of wild-type XPO1 [51].

Although the process of cyclin D1 nuclear import is insufficiently characterized in mantle cell lymphoma (MCL), the export of cyclin D1 complexes from the nucleus into the cytoplasm is established to be XPO1-dependent [52]. Indeed, the down-regulation of cyclin D1, which was accompanied by a substantial decrease of its target protein phospho-RB, was observed after a SINE agent KPT-185 treatment in MCL cells [53]. The t(11;14) nonrandom chromosomal translocation, leading to cyclin D1 overexpression that is typical of MCL disease, may also explain the XPO1 overexpression in MCL cells. This hypothesis must be confirmed in dedicated studies to define the precise mechanisms of the deregulation of XPO1.

It has also been reported that XPO1 and other nuclear import receptors, such as importin-7, are regulated positively by MYC and negatively by p53 [54], resulting in the modulation of ribosomal biogenesis. MYC appears to transcriptionally upregulate XPO1 as a part of a wide-ranging transcriptional program that also includes numerous ribosomal protein genes [55].

Recently, in 20 PMBL cases analyzed via CGH, a copy number gain in the XPO1 locus was observed in eight cases [12]. This rate was higher than that observed for ABC DLBCL (8/70, 11%) but similar to that observed for GCB DLBCL (21/74, 28%). A significant correlation was observed between the XPO1 copy number and the expression of the corresponding messenger RNA (mRNA), suggesting a gene dosage effect (P = 0.00106, Mann–Whitney test). Gains at the chromosome 2p16.1-2p15 locus, which contains both the REL and XPO1 genes, were commonly observed in GCB DLBCL, cHL, and PMBL cases [56–58] and may be an important mechanism of XPO1 overexpression in these hematological malignancies.

The conveniences of using plasma cell-free DNA (cfDNA) for tumor mutation detection include (i) noninvasive acquisition, (ii) ability to be collected at any time during the disease course, (iii) real-time detection and follow-up of biomarker dynamics, and (iv) probably fewer heterogeneity concerns than tumor tissue testing [59]. Notably, the idea of a “liquid biopsy” was recently featured for the first time in a series of DLBCL patients, for whom high-throughput sequencing of a panel of target genes was implemented with an outstanding detection of somatic variants both in the tumor and the plasma [60]. Undeniably, the testing of mutations in the cfDNA has been widely characterized in many cancer types and could potentially serve as a biomarker tool for MRD, revealing treatment success or disease relapse before the clinico-radiological symptoms [61–64].

In contrast, Lymphosight® technology [65], which is based on the quantification of clonotypic immunoglobulin rearrangements, can be used more extensively to predict relapse in DLBCL patients [66], but a VDJ rearrangement is not measurable in all patients (immunoglobulin-negative phenotype of PMBL [67]), and the technology is not suitable for tailoring a targeted therapy. Furthermore, a recent proof-of-concept report exposed, for the first time, that the detection and measurement of recurrent somatic mutations in the plasma cfDNA of patients with DLBCL by digital PCR is possible, easy, and reproducible [68]. cfDNA testing by digital PCR (dPCR) is emerging as an appropriate and helpful molecular tool for the management of DLBCL along with NGS methods.

Finally, a recent retrospective study, including 94 all-stage cHL patients undergoing a first-line therapy, demonstrated that the highly recurrent XPO1 E571K mutation is present in one-quarter of classical Hodgkin’s lymphoma patients [16]. Among these 94 patients, 50 had serial EDTA plasma samples obtained from blood collection concomitant with the diagnostic biopsy and at the end of chemotherapy/radiotherapy treatment. Patients with a detectable XPO1 mutation in plasma cfDNA by digital PCR at the end of treatment exhibited a tendency toward shorter progression-free survival compared to patients with undetectable mutations. These results advocate that the clearance of the XPO1 mutation in plasma cfDNA during and at the end of treatment may serve as a new prognostic marker for patients with detectable mutations. A study with a larger prospective cohort is needed to draw precise conclusions and determine whether this mutation monitoring adds new applicable value compared to positron emission tomography (PET) and whether this E571K variant can be targeted by SINE compounds for the treatment of cHL.

XPO1 overexpression positively correlated with a larger tumor size in ESCC [18]. Moreover, the XPO1-mutated tumor also showed upregulated protein levels compared with the matched adjacent normal esophageal epithelium, indicating a gain-of-function phenotype. In hematological malignancies, high levels of XPO1 are associated with shorter survival and are a poor prognostic factor in acute myeloid leukemia (AML) [69]. In this pathology, high XPO1 levels correlate with low MDM2 and high p53 levels.

Multiple myeloma (MM) cells have a higher XPO1 expression than bone marrow normal plasma cells and cells from monoclonal gammopathy of unknown significance (MGUS) patients [70].

An altered subcellular localization of XPO1 in MCL cell lines and primary cells and the knockdown of XPO1 gene expression resulted in the inhibition of MCL cell growth [71]. XPO1 is overexpressed in MCL cells and can regulate MCL cell proliferation, cell cycle progression, DNA damage response, and chromosomal stability, making it a promising therapeutic target for MCL management [71]. Another study confirmed these results and revealed that XPO1 overexpression has a negative prognostic impact on MCL overall disease survival [72]. This work highlighted that the induction of p53 by SINE agents could potently induce cell death in MCL, including those with high levels of XPO1. The unfavorable prognostic impact of high levels of XPO1 expression was also demonstrated in an impressive study in MM [73]. In this work, high XPO1 expression in MM patient cells was associated with lytic bone disease and a shorter survival, and bortezomib-resistant patient MM cells expressed higher XPO1 levels. The authors showed that SINE treatment induced potent and rapid apoptosis of MM cells in vitro and in vivo and further directly decreased bone resorption. These results are interesting additional data supporting a pathogenic role of XPO1 in hematological malignancies and providing the pre-clinical rational for the ongoing clinical development of selinexor.

Nevertheless, cHL patients with tumors harboring the E571K XPO1 mutation did not have a shorter PFS or OS than cLH patients with a wild-type XPO1 gene [16]. By contrast the E571K XPO1 mutation may have an unfavorable prognostic relevance for PMBL [12], which is in accordance with the observations reported for CLL [17].

Leptomycin B (LMB), an anti-fungal antibiotic produced by Streptomyces, was the first described XPO1 inhibitor (Fig. 4). In their seminal report, Kudo and colleagues showed that LMB binds XPO1 at a conserved cysteine residue (position 528 in the human protein, C528) [74]. The alkylation of this cysteine residue, within the hydrophobic groove of XPO1, by LBM disrupts XPO1/cargo interactions and prevents the binding of RanGTP. Thus, LMB blocks nuclear export. Interestingly, the substitution C528S has no impact on XPO1 function, but cells carrying the C528S mutation are completely resistant to LMB. Although highly potent, even at nano-molar concentrations, LMB cannot be used in the clinic because of its high toxicity [75]. Recently, using computational methods, several XPO1 inhibitors, called selective inhibitors of nuclear export (SINE), have been developed by Karyopharm Therapeutics (e.g., KPT-185 and KPT-330, also known as selinexor, Fig. 4). SINEs inhibit the formation of XPO1/cargo complexes. Moreover, the crystal structures of SINEs showed that they bind covalently to C528, such as LMB [8, 9]. A homozygous mutation in the cysteine residue (C528S), using the CRISPR/Cas9 technology in the Jurkat T-ALL cell line, confers cell resistance to selinexor [76]. This result validates the specificity of the SINE to its target, XPO1. SINEs display anti-proliferative and pro-apoptotic activities in various hematological malignancies in both in vivo and in vitro settings, including cell lines and primary cells [15]. The main results of published pre-clinical studies are presented in Table 1. SINEs inhibit the XPO1 nuclear export function and restore the nuclear localization of TSPs and cell cycle proteins, thus restoring their functions. Importantly, SINEs target tumor cells but not normal hematopoietic cells [8, 9]. SINEs can also indirectly restore TSP and cell cycle regulator functions. In addition to the high XPO1 expression found in AML cells, the NPM1 gene encoding nucleophosmin 1 is mutated in up to 35% of cases [77]. These mutations cause increased XPO1 binding and the mislocalization of nucleophosmin 1 in the cytoplasm [78]. KPT-185 restores the nuclear localization of nucleophosmin 1, resulting in cell cycle arrest and AML blast differentiation [79].

Chemical structures of leptomycin B and two SINE compounds. Chemical structures have been obtained from [99]

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Pre-clinical studies in CLL cells with a mutated XPO1 gene have not been reported thus far to our knowledge. However, in PMBCL and LH cell lines, KPT-185 inhibits cell proliferation and induces apoptosis, regardless of an amplified or mutated XPO1 gene status [12, 16].

Moreover, SINEs synergize with drugs used clinically to bypass the resistance that often occurs after treatment. In AML, topoisomerase (Topo) 2α (an XPO1 cargo) is aberrantly localized in the cytoplasm, leading to resistance to Topo2 inhibitors. Ranganathan and colleagues recently reported the synergistic activity of selinexor with Topo2 inhibitors (idarubicin, daunorubicin) in AML cell lines, primary AML blasts, and a murine xenograft model [80]. Mechanistically, selinexor restores the nuclear localization of Topo2, downregulates genes in the DNA damage response pathway and impairs homologous recombination for DNA repair. In AML, a high level of XPO1 correlates with a high level of p53 and a low level of mouse double minute 2 (MDM2, the negative regulator of p53). KPT-185 and Nutlin-3a, inhibitors of MDM2, display synergistic activity on apoptosis induction both in AML cells lines and primary cells [69]. Indeed, the nuclear accumulation of p53 induced by XPO1 inhibition is reinforced by the lack of p53 degradation resulting from MDM2 inhibition. Decitabine, an inhibitor of DNA methyltransferase that allows the re-expression of genes silenced during myeloid differentiation, appears to be efficient for some AML patients [81]. The pretreatment or priming of AML blasts with decitabine followed by selinexor enhances the induction of apoptosis in AML cell lines and primary AML blasts [82]. These effects are mediated by the re-expression of p21 and FOXO3A, which are XPO1 cargos that are silenced by the DNA methylation. In vivo, in a mouse model of AML, a selinexor/decitabine combination shows enhanced anti-leukemia activity.

CLL cells exhibit a constitutive activation of the BCR signaling pathway. Ibrutinib, which inhibits BTK (Bruton tyrosine kinase) expressed in CLL, is an effective therapy. However, acquired resistance to ibrutinib is frequent, partly due to a mutation in the BTK gene (C481S). The dual targeting of XPO1 by selinexor and BTK by ibrutinib elicits a synergistic effect both in vitro in primary cells and in vivo in the Eμ-TCL1 mouse model of CLL [83]. Importantly, the selinexor/ibrutinib combination bypasses the resistance due to the C481S BTK mutation.

The combination of an XPO1 inhibitor and liposomal doxorubicin appears highly effective in in vitro resistant MM models, xenograft studies, and ex vivo samples from patients with relapsed/refractory myeloma. In pre-clinical models, the anti-lymphoma activity of selinexor is enhanced through a combination with dexamethasone and everolimus, which target both NF-κB and mTOR [14]. A synergistic effect has been demonstrated with proteasome inhibitors (PIs), such as carfilzomib and bortezomib [84] and selinexor, the latter of which overcomes PI drug resistance in MM. This synergistic effect is mediated by blocking the phosphorylation of the IκB-α and the NF-κB p65 subunits, protecting IκB-α from proteasome degradation [13].

Although selinexor has shown its efficacy in phase I/II clinical trials (see below), its toxicity limits its administration. A new generation of SINE compounds has been designed by Karyopharm Therapeutics and assayed for efficacy in CLL and AML [85]. KPT-8602 acts similarly to selinexor; it inhibits XPO1/cargo interactions, induces apoptosis, and inhibits proliferation of primary CLL cells, AML cell lines, and AML blasts. In vivo, in mouse models of AML and CLL, KPT-8602 prolongs survival. More importantly, compared to selinexor, KPT-8602 appears to be less toxic because it has a reduced capacity to cross the blood–brain barrier and does not accumulate in the blood even after repetitive injections.

Resistance to therapy and relapse occur because of the inability of the currently used drugs to target the cancer-initiating cells (CICs) or leukemia-initiating cells (LICs). A CIC/LIC is defined as a cell, within the tumor population, that is able to self-renew, differentiate, and reproduce a tumor. Such an LIC has been described in AML [86, 87]. Selinexor appears to be active against primary AML cells, including LICs engrafted into immunodeficient mice. Moreover, selinexor shows limited toxicity against normal hematopoietic stem cells and progenitors [88].

The inhibition of RNA export and the impairment of ribosome biogenesis induce the death of MCL and MM. In MCL cells, KPT-185 induces a down-regulation of proliferation-related genes regardless of the status of p53 and, in turn, the inhibition of the cell cycle. Moreover, KPT-185 downregulates the expression of ribosomal proteins (from both the large 60S and the small 40S subunits). This affects heat shock factors, protein synthesis, and energy metabolism that are important for tumor cell proliferation and survival [53]. In MM cells, selinexor targets the RPL11 and RPL5 ribosomal proteins, decreases the 40S, 60S, and 80S ribosomal fractions, and disrupts the ribosomal function and translational machinery. This induced ribosomal stress leads to MM cell death [53].

XPO1 inhibition also represents a new therapeutic strategy for overcoming resistance to platinum-mediated apoptosis through both p53-dependent and p53-independent pathways [89]. The combination synergistically induced Topo 2α-mediated DNA damage and subsequent apoptosis. In solid tumor models, it has been demonstrated that selinexor acts synergistically with gemcitabine to promote apoptosis and reduce survival [90] and can enhance radiotherapy effects, providing a rational for such a combination in B cell malignancies [91], including non-Hodgkin lymphoma (NHL) and cHL.

Finally, in a model of synergistic colon/melanoma cancer, a combination of selinexor + programmed cell death 1 (PD-1 or PD-L1) blockade exerts considerable anti-tumor activity and shows significant immunomodulatory activity, inducing changes in the frequency and phenotype of immune cell populations, most notably in NK cells and activated T cells. These results support the future clinical evaluation of the combination of selinexor + PD-1/PD-L1 blockade, a strategy especially relevant in cHL [92]. Importantly, in vitro and in vivo experiments are providing the rational for the ongoing and future clinical trials based on the combination of XPO1 inhibitors and approved drugs (Table 2).

These data reinforce the concept of XPO1 as an anti-cancer target and SINEs as efficient anti-XPO1 drugs in human hematological malignancies.

Giving the pleiotropic and crucial role of XPO1 and the fact that the overexpression of XPO1 has been associated with resistance and aggressiveness in multiple tumor types, several clinical trials using drugs targeting XPO1 are currently ongoing in the field of hematological malignancies and solid tumors. The ongoing or terminated clinical trials testing the SINE selinexor compound in lymphoid malignancies are summarized in Table 2. Consolidated clinical results in CLL, MM, and NHL are still limited.

In a phase 1 dose-escalation study of selinexor in patients with heavily pre-treated NHL, among the 43 evaluable patients, an overall response rate of 28% was observed with a complete response rate of 5%. In the DLBCL cohort of 39 evaluable patients, the disease control rate was 51%, with overall response rate of 31%. Interestingly in DLBCL patients with MYC/BCL2 translocations, three of the four patients showed an objective response [93].

The toxicity profile of selinexor used as a single agent is currently well-known. In a phase 1 trial involving 189 patients with advanced solid tumors receiving selinexor, the most common treatment-related adverse events included fatigue (70%), nausea (70%), anorexia (66%), and vomiting (49%), which were generally grades 1 or 2. The most commonly reported grade 3 or 4 toxicities were thrombocytopenia (16%), fatigue (15%), and hyponatremia (13%). Clinically significant major organ or cumulative toxicities were rare. The maximum-tolerated dose was set at 65 mg/m² using a twice-a-week (days 1 and 3) dosing schedule [11]. Selinexor was significantly better tolerated when administered as a flat dose on an intermittent schedule. Pharmacokinetics analysis of selinexor revealed an increase (approximately 15 to 20%) in drug exposure when taken with food [94]. A phase I trial evaluated the combination of selinexor with fludarabine and cytarabine in pediatric R/R acute leukemia. The most common grade 3 non-hematologic toxicity was asymptomatic hyponatremia. Two patients who were treated at 70 mg/m² experienced reversible cerebellar toxicity, thereby defining the dose-limiting toxicity [95].

Interestingly, the new SINE compound KPT-8602 shows similar in vitro potency compared with selinexor but lower central nervous system penetration, which resulted in enhanced tolerability, even when dosed daily, and improved survival in CLL and AML murine models [80, 82].

XPO1 represents an exciting field located at the intersection between pathophysiology, diagnosis, and treatment of B cell malignancies. Many crucial points and burning questions need to be addressed. At the biological level, the respective role of XPO1 in distinct B/T cell malignancies is still largely unknown, and an accurate view of the cargo molecules (including proteins and RNAs) is still lacking. At the genetic level, the highly selected recurrent E571K mutation does not appear to impact the activity of SINE compounds, but its biological relevance, especially in cHL and PMBL, is still undetermined. Interestingly, this hot spot may be used as a simple MRD marker to complement PET scan imaging in these diseases. Finally, from a clinical point of view, blocking XPO1 activity represents a promising strategy in lymphoid malignancies and has synergistic effects with several drugs, including anthracyclines, gemcitabine, mTOR inhibitors, ibrutinib, immune check-points inhibitors or radiotherapy.

ABC:

Activated B-cell like

AML:

Acute myeloid leukemia

APC:

Adenomatous polyposis coli

BCR:

B-cell receptor

BD:

Binding domain

BRCA1:

Breast cancer 1

BRD4:

Bromodomain-containing protein 4

BTK:

Bruton tyrosine kinase

CAM-DR:

Cell adhesion-mediated drug resistance

CDC25A:

Cell division cycle 25 homolog A

cfDNA:

Cell-free DNA

CGH:

Comparative genomic hybridization

cHL:

Classical Hodgkin lymphoma

CIC:

Cancer-initiating cell

CLL:

Chronic lymphoid leukemia

CRM1:

Chromosome region maintenance 1

DLBCL:

Diffuse large B cell lymphoma

dPCR:

Digital PCR

ESCC:

Esophageal squamous cell carcinoma

FLT3:

FMS-like tyrosine kinase

FOXO:

Forkhead box class O

GC:

Germinal center

GCB:

Germinal B-cell-like

hnRNP:

Heterogeneous nuclear ribonucleoprotein

IL:

Interleukin

ITD:

Internal tandem duplication

LIC:

Leukemia-initiating cell

LMB:

Leptomycin B

MCL:

Mantle cell lymphoma

MDM2:

Mouse double minute 2

MGUS:

Monoclonal gammopathy of undetermined significance

MGZL:

Mediastinal gray-zone lymphoma

MM:

Multiple myeloma

MRD:

Minimal residual disease

mTOR:

Mammalian target of rapamycin

NES:

Nuclear export signal

NGS:

Next-generation sequencing

NHL:

Non-Hodgkin lymphoma

NPC:

Nuclear pore complex

PET:

Positron emission tomography

PMBL:

Primary mediastinal B cell lymphoma

PP2A:

Protein phosphatase 2A

RB:

Retinoblastoma protein

SINE:

small inhibitor of nuclear export

SNV:

Single-nucleotide variant

STAT:

Signal transducer and activator of transcription

T-ALL:

T-cell acute lymphoid leukemia

TNF:

Tumor necrosis factor

Topo:

Topoisomerase

TSP:

Tumor suppressor protein

XPO1:

Exportin 1

Funding

Not applicable.

Availability of data and materials

Data sharing is not applicable to this article as no datasets were generated or analyzed during the current study.

Authors’ contributions

VC, BS, and FJ drafted the manuscript. HM and AT helped to draft the manuscript and to draw the illustrations. All authors read and approved the final manuscript.

Competing interests

The authors declare that they have no competing interests.

Consent for publication

Not applicable.

Ethics approval and consent to participate

Not applicable.

Authors and Affiliations

1. Normandie Univ, INSERM U1245, UNICAEN, UNIROUEN, Caen, France

   Vincent Camus, Hadjer Miloudi, Brigitte Sola & Fabrice Jardin

2. Department of Hematology, Centre Henri Becquerel, Rouen, France

   Vincent Camus & Fabrice Jardin

3. Laboratoire de Biochimie Théorique, Institut de Biologie Physico-Chimique, CNRS, Université Paris Diderot, Paris, France

   Antoine Taly

Corresponding author

Correspondence to Brigitte Sola.

Open Access This article is distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution, and reproduction in any medium, provided you give appropriate credit to the original author(s) and the source, provide a link to the Creative Commons license, and indicate if changes were made. The Creative Commons Public Domain Dedication waiver (http://creativecommons.org/publicdomain/zero/1.0/) applies to the data made available in this article, unless otherwise stated.

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