NEK2 mediates ALDH1A1-dependent drug resistance in multiple myeloma

INTRODUCTION

Multiple myeloma (MM), a difficult-to-treat and in most cases incurable neoplasm of the hematopoietic bone marrow, is characterized by clonal expansion of malignant, antibody-producing plasma cells. MM is the second most common blood cancer, accounts for ~1–2% of newly diagnosed cancers overall, and is disproportionately represented in the elderly population [1]. Myeloma cells exhibit numerous gene expression changes and cytogenetic aberrations that frequently affect the immunoglobin heavy-chain locus on chromosome 14 as well as loci on chromosomes 1, 13 and 17 [2–5]. Abnormalities of this sort underlie not only aggressive disease resulting in poor clinical outcome, but also promote acquisition of drug resistance by myeloma cells. With regard to the mechanism of drug resistance in myeloma, Greenman et al. implicated deregulated protein kinases [6]. Additional drivers of drug resistance include aberrant expression of transcription factors, mutations in tumor suppressor genes and distorted cell cycle regulation [7]. Despite these advances, additional research is warranted to enhance our understanding of the genetic pathways of myeloma drug resistance.

The recent discovery of drug-resistant tumor subclones in patients with myeloma [8–10] has shed light on the long-standing clinical observation that the response to myeloma chemotherapy is often heterogeneous and sometimes even lesion-specific [11]. Overcoming drug-resistant myeloma in the clinic is a serious challenge that requires new approaches based on results from high-throughput proteomic and genetic analysis tools, such as global gene expression profiling (GEP), RNA sequencing and whole-exome or whole-genome sequencing, which must be combined with sophisticated bioinformatics and biostatistics algorithms [12]. Our group has recently performed sequential GEP analysis of myeloma samples at baseline (newly diagnosed disease), in the course of high-dose chemotherapy and tandem autologous stem cell transplantation (ASCT), and at relapse. This effort uncovered 56 genes tightly associated with drug resistance and rapid disease relapse in myeloma. Intriguingly, 10 of the top 20 genes fell into a well-established chromosomal instability (CIN) signature of cancer [13]. Additionally, we recently reported that ALDH1, a marker of myeloma initiating cells (TICs), is also linked to the CIN signature [14]. High expression of this signature has been shown to predict poor clinical outcome and confer multidrug resistance (MDR) to myeloma and other forms of cancer [13, 15, 16]. The mechanism linking ALDH1 and CIN with MDR has not yet been established.

The human genome contains 19 aldehyde dehydrogenase-encoding ALDH genes and 3 pseudogenes [17]. Aldehyde dehydrogenases are not only crucial for protecting cells from toxic aldehydes, but are also known to play important roles in cancer development, retinoic acid metabolism and drug resistance [17]. For example, high activity of ALDH1A1 and ALDH2 increases the risk of ethanol-induced cancers [18, 19]. ALDH2 is required for embryo survival and early morphogenesis in mice [20]. In humans, deletions of ALDH3A1 or ALDH3A2 cause Sjogren-Larson syndrome [21]; mutations in ALDH4A1 underlie type II hyperprolinemia [22]; mutations in ALDH5A14 cause mental retardation, ataxia and seizures [23]; and allelic variants of ALDH18A1 result in hyperammonemia [24]. Because of their importance for drug metabolism and oncogenesis, ALDH1, ALDH2 and ALDH3 are the most extensively studied members of the ALDH family of enzymes [25, 26]. Normal cells contain two ALDH1 isoforms, ALDH1A1 and ALDH3A1, but the expression of these proteins has also been associated with drug resistance in cancer stem cells (CSCs) [27]. The Aldefluor assay, which permits investigators to detect and separate ALDH1-expressing cells from cells that lack ALDH1 expression, has led to a wave of cancer studies that have implicated ALDH1 in drug resistance of adenocarcinoma of lung [28], melanoma [29], breast cancer [30] and hematopoietic tumors, such as myeloma [8, 10].

This study took advantage of the Aldefluor assay to elucidate the role of ALDH1 in MDR in myeloma in greater depth. We show that A1 is the dominant isoform of ALDH1 in MM. Enforced expression of ALDH1A1 in myeloma cells led to increased activity of the drug efflux pump, ABCB1, and to more vigorous tumor growth in mice. We also demonstrate that over-expression of ALDH1A1 in myeloma leads to elevated NEK2 levels, using a mechanism that includes 9-cis retinoic acid-dependent RXRα signaling [31]. Taken together, our results support the notion that ALDH1A1 is a promoter of drug resistance in myeloma that is worthy of consideration for therapeutic targeting in order to overcome MDR and improve the outcome of patients with myeloma.

RESULTS

Increased expression of ALDH1A1 in serial myeloma samples from the same patients

To evaluate whether the expression of ALDH1 exhibits changes in the course of myeloma therapy and disease progression, we queried the mRNA levels of the three most well-studied members of the ALDH1 gene family, ALDH1A1, ALDH1B1, and ALDH1A3, in 9 patients with myeloma for which the following four serial, microarray-based gene expression profiles (GEPs) were available: at diagnosis, prior to the first and second autologous stem cell transplant, and after the second transplant. Message levels of ALDH1A1, but not of the other family members, increased substantially in 9 of 9 (100%) patients (Figure 1A-C). This result not only indicated that ALDH1A1 is the predominant form of ALDH1 in myeloma, but also suggested that the gene is upregulated in response to standard-of-care myeloma therapy. Next, we sought to determine whether ALDH1A1 is also the chief representative of the ALDH1 family in two human myeloma cell lines (HMCLs) that were selected for mechanistic studies on myeloma drug resistance: ARP1 and OPM1. We took advantage of the Aldefluor^® assay, which relies on flow sorting to fractionate cells that exhibit ALDH1 activity (designated ALDH1⁺) from cells that do not (ALDH1^-) [14], to separate ARP1 and OPM1 cells according to ALDH1 status and then used qPCR analysis to show that ALDH1A1 is more highly expressed in ALDH1⁺ than ALDH1^- cells (Figure 1D). Differences of this sort were not observed for ALDH1B1 and ALDH1A3 (not shown). This finding encouraged us to use ARP1 and OPM1 cells as experimental model system to evaluate the mechanisms by which ALDH1A1 promotes drug resistance in myeloma.

Over-expression of ALDH1A1 promotes resistance to myeloma drugs in vitro

To assess whether enforced expression of ALDH1A1 in myeloma cells leads to heightened tolerance to myeloma drugs in vitro, we transduced ARP1 and OPM1 cells with a lentivirus-delivered, EF1-alpha promoter-driven full-length cDNA of ALDH1A1. As one would have expected, western analysis demonstrated over-expression of ALDH1A1 protein in both cell lines (designated ARP1^OE and OPM1^OE) compared to controls transduced with non-coding “empty vector” (designated ARP1^EV and OPM1^EV, Figure 2A). Next, we employed the eFluxx-ID™ multidrug resistance assay to evaluate the possibility that up-regulation of ALDH1A1 leads to increased drug efflux activity in myeloma. Cells were treated with specific inhibitors of 3 different drug export pumps; i.e., verapamil for ABCB1, MK-571 for ABCC1, and Novobiocin for ABCG2, or left untreated (control). Under conditions of ABCB1 (but not ABCC1 or ABCG2) inhibition, ARP1^OE and OPM1^OE cells exhibited significantly greater drug efflux activity than ARP1^EV and OPM1^EV cells: the mean fluorescence intensity (MFI) increased by 50 and 32 units, respectively (Figure 2B). The finding suggested that ALDH1A1 enhanced the drug export activity of myeloma cells in an ABCB1-dependent manner. Next we performed soft-agar colony formation assays to assess the possibility that ALDH1A1 promotes drug resistance in myeloma. Figure 2C shows that ARP1^OE and OPM1^OE cells were less sensitive to bortezomib (Bz) and doxorubicin (Dox) than ARP1^EV and OPM1^EV cells. Flow cytometric determination of immunoreactivity to annexin V, a marker of apoptotic cell death, revealed the same picture, as treatment of cells for 48 hrs with Bz (4 nM or 8 nM) or Dox (50 nM or 100 nM) caused less death in the “OE” than “EV” sample (Figure 2D). The results presented in panels C and D lent further support to the contention that ALDH1A1 renders myeloma cell drug resistance.

Enforced expression of ALDH1A1 increases tolerance to myeloma drugs in vivo

To extend these observations to an animal model of human myeloma, we transferred ARP1^OE and ARP1^EV cells to immunodeficient NOD.Cγ Rag1 mice. Starting on day 7 post IV transfer of 1.5 × 10⁶ tumor cells, half the mice were treated with Bz (1 mg/kg, twice weekly IP) and half were left untreated (control). Figure 3 shows that 27 days after cell propagation, the ARP1^OE tumors that developed in untreated mice were significantly larger (2.52 cm³ on average; n = 5) than the ARP1^EV tumors (1.24 cm³). Similarly, in Bz-treated mice, ARP1^OE tumors were larger (2.48 cm³) than ARP1^EV tumors (0.57 cm³). We conclude that treatment with Bz had little if any impact on ARP1^OE tumors (1.6% difference in tumor volume in treated vs. untreated mice) but was highly effective in case of ARP1^EV tumors (54% difference). This result provided evidence that up-regulation of ALDH1A1 in myeloma mitigates the response to treatment with proteasome inhibitor.

NEK2 is involved in the mechanism by which ALDH1A1 promotes drug resistance in myeloma

Following up on our previous work demonstrating that up-regulation of NEK2 leads to therapy resistance and inferior survival in patients with MM [14], we decided to explore whether NEK2 might be involved in the mechanism by which ALDH1A1 promotes drug resistance in myeloma. NEK2 gene expression was found significantly higher in ALDH1+ than in ALDH1- MM cells, fractionated by using Aldefluor^®-based cell sorting from 3 MM lines [14]. qPCR analysis confirmed this finding (Figure 4A) and further demonstrated that high expression of NEK2 is also a feature of ARP1^OE / OPM1^OE relative to ARP1^EV / OPM1^EV cells (Figure 4B). Because NEK2 promotes drug resistance by virtue of activating the myeloma drug efflux pump, ABCB1, in dependence on pAKT and pBCL2 levels [14], we decided to compare the level of these proteins in ARP1 and OPM2 cells that either over-expressed ALDH1A1 (OE) or transfected with empty vector (EV). Figure 4C shows that compared to EV cells, OE cells harbored higher levels of NEK2, ABCB1, pAKT and pBCL2 by western blotting. To further validate the involvement of NEK2 in ALDH1A1-induced drug resistance, NEK2-targeting shRNA was transduced into ALDH1A1-overexpressing ARP1 and OPM1 cells. In both cases, this led to reduced levels of NEK2, ABCB1, pAKT and pBCL2 proteins by western analysis (Figure 5A), decreased activity of the drug efflux pump by eFluxx-ID analysis (Figure 5B) and lessened colony formation upon treatment with bortezomib (5nM) or without treatment (Figure 5C). The apparent association of high ALDH1A1 and NEK2 levels is consistent with the hypothesis that NEK2 contributes to ALDH1A1-dependent drug resistance in myeloma.

NEK2 is activated by 9-cis retinoic acid-dependent RXRα signaling in myeloma

To elucidate the mechanism by which ALDH1A1 activates NEK2 in myeloma, we interrogated the chromatin immunoprecipitation sequencing (ChIP-Seq) database from the University of California Santa Cruz (UCSC) for chromatin occupancy patterns at the NEK2 promoter and NEK2 coding region. This revealed a significant footprint of retinoic X receptor alpha (RXRα) binding in 4 of 4 cell lines for which this information was available: GM78, hESC, HepG and SKSH (Figure 6A). Because RXRα is the receptor for 9-cis retinoic acid (9CRA), an important ligand of the cellular RXRα signal transduction pathway, the ChIP-Seq result suggested that ALDH1A1 regulates NEK2 transcription by generating 9CRA. To follow up on this hypothesis, we treated APR1 and OPM1 cells for 4 or 8 hrs with 5nM 9CRA in vitro. qPCR analysis demonstrated heightened expression of NEK2 in all cases, with a particularly strong increase in the 4-hr ARP1 sample (Figure 6B). Western blotting of whole cell lysates after treatment of cells with 5nM 9CRA for 48 hrs confirmed the PCR result at the protein level (Figure 6C). The data presented in Figure 6 lends credence to a model that implicates RXRα/9CRA-dependent transactivation of NEK2 in myeloma drug resistance RXRα (Figure 6D).

DISCUSSION

MM is a difficult-to-treat malignancy of terminally differentiated B-lymphocytes that exhibits complex genetic/epigentic abnormalities and frequently evolves into treatment-refractory fatal disease [9]. Karyotypic changes are detected in ~30% of newly diagnosed patients, with number and complexity of changes correlating with disease stage, prognosis and response to therapy [32]. Comparing microarray-based gene expression profiles of myeloma samples serially collected from the same patients at different disease progression and treatment stages, we found the chromosomal instability (CIN) gene signature strongly increased after induction chemo- and tandem ASCT therapy, and tightly linked to poor prognosis of patients with myeloma [13]. More recently, we showed that ALDH1 is a marker of tumor initiating cells and drug resistance in myeloma, and that the CIN signature is more highly expressed in ALDH1⁺ than ALDH1^- myeloma cells [14]. Consistent with that, CD138^-ALDH1⁺ cells were found to be more clonogenic and tumorigenic than CD138⁺ALDH1^- cells [33]. Because ALDH1 positivity, as determined by Aldefluor analysis, reflects the combined output of different aldehyde dehydrogenase activities – namely ALDH1A1, ALDH1B1 and ALDH1A3 et al. – we here dissected the ALDH1⁺ phenotype and demonstrated that ALDH1A1 is the predominant isoform in myeloma. Additionally, we showed that enforced expression of ALDH1A1 in two myeloma cell lines (ARP1, OPM1) led to both increased clono- and tumorigenicity and heightened tolerance to two widely used myeloma drugs (bortezomib, doxorubicin).

Our previous study demonstrated that as many as 5 of 17 genes found to be significantly up-regulated in ALDH1⁺ myeloma cells encode cell cycle-dependent protein kinases; specifically, CDC2, TTK, AURKA, AURKB and, of importance here, NEK2 [14]. Because cell cycle-dependent protein kinases are thought to be a major underlying reason for CIN and drug resistance in cancer [13, 14, 34], we hypothesized that NEK2 might be involved in the mechanism by which ALDH1A1 promotes therapy resistance in myeloma. This hypothesis was in line with evidence that up-regulation of NEK2 in myeloma prognosticates inferior survival and is strongly associated with CIN and drug resistance [13]. We found that ALDH1A1 induced NEK2 expression at the mRNA and protein levels. Furthermore, shRNA-dependent “knockdown” of NEK2 led to a drop of proteins crucial for cellular drug export (ABCB1) and survival (pAKT, pBCL2). Considering that NEK2 activates AKT and ABCB1 in myeloma [13], it is possible that ALDH1A1 promotes drug resistance by activating the NEK2-AKT pathway. It is also possible that the activation (phosphorylation) of BCL2 in ALDH1⁺ myeloma cells is a consequence of heightened CIN-NEK2-AKT signaling. BCL2 is a pro-survival protein that protects myeloma cells from drug-induced death [35] and is often over-expressed in cancer cells exhibiting the CIN phenotype, even though it should be down regulated following drug-dependent mitotic arrest [15, 36, 37]. Additional studies are warranted to elucidate the regulation of BCL2 in response to CIN-NEK2-AKT activation.

ALDH1A1 catalyzes the oxidation of retinal (retinaldehyde) to the corresponding retinoic acid (RA) [38], which – upon binding to retinoic acid receptors (RAR) and/or retinoid X receptors (RXR) – initiates downstream RA signaling. ALDH1A1-dependent generation of RA is important for growth and differentiation of normal and malignant cells [38, 39], including normal hematopoietic stem cells [38]. In embryonic cancer/stem cells and induced pluripotent stem (iPS) cells, RA signaling has been linked to CIN, based on increased occurrence of micronuclei and decreased expression of survivin [40]. Since ALDH1A1 generates two different RAs – the widely known all-trans retinoic acid (ATRA) and the lesser known 9-cis retinoic acid (9CRA) – and our previous work on myeloma pointed to ATRA as an important signaling ligand [39], this research concentrated initially on ATRA. However, treatment of myeloma cells with ATRA left NEK2 levels unchanged upon qPCR analysis (data not shown). We also investigated whether enforced up-regulation of the ATRA receptor, RARα, might make a difference – because RARα2 (not RARα1) is important for myeloma [39, 41], we used RARα2 for that purpose. We found no change in NEK2 using qPCR and western analyses (results not shown). These findings indicated that ATRA is not involved in the mechanism by which ALDH1 regulates NEK2 and led us to refocus attention on 9CRA. This resulted in the discovery that ALDH1A1 promotes NEK2 transcription in a 9CRA/RXRα-dependent fashion. The result is in agreement with ChIP-Seq data gathered by other investigators, demonstrating NEK2 promoter occupancy by the 9CRA-specific receptor, RXRα, in different four cell lines.

In conclusion, this study implicates ALDH1A1 as an important drug resistance and tumor progression gene in multiple myeloma. The mechanism of ALDH1A1 includes up-regulation and activation of NEK2, AKT and BCL2, but many details remain outstanding. Small-drug inhibitors that specifically target ALDH1A1 may be considered for therapeutic regimens aimed at overcoming drug resistance in myeloma.

MATERIALS AND METHODS

Cell culture

Human myeloma cell lines, APR1 and OPM1 were cultured at 37°C and 5% CO₂ in RPMI 1640 (Gibco, Grand Island, NY) supplemented with 10% heat-inactivated fetal calf serum (Gibco, Grand Island, NY) and penicillin and streptomycin (100 µg/mL, Sigma, St. Louis, MO).

Reagents

Antibodies to NEK2 (sc-55601) and ABCB1 (sc-55510) were purchased from Santa Cruz Biotechnology (Dallas, Texas), and antibodies to ALDH1A1 (catalog number 12035), pAKT (3787), pBCL2 (2827) and β-actin (4967) from Cell Signaling Technology (Danvers, MA). All-trans retinoic acid, doxorubicin, doxycycline hyclate and 9-cis retinoic acid were procured from Sigma (St. Louis, MO). Bortezomib was obtained from Millennium (Cambridge, MA).

ALDEFLUOR assay, flow cytometry, and fluorescence-activated cell sorting (FACS)

The ALDEFLUOR assay (Stem Cell Technologies, Vancouver, Canada) was performed according to the recommendations of the manufacturer. Briefly, one million cells were re-suspended in 1mL assay buffer and incubated with activated ALDEFLUOR substrate (5 µL) at 37°C in a water bath (30 min). Cells treated with diethylaminobenzaldehyde (DEAB, 5 µL) were used as control. Cells were centrifuged, re-suspended in ice-cold assay buffer, and either analyzed by flow cytometry or sorted using a FACS Aria (Becton Dickinson).

Quantitative reverse-transcription PCR (qPCR)

Total RNA was extracted with the assistance of a RNeasy RNA isolation kit (Qiagen) and reverse transcribed using the SuperScript III RT kit and oligo dT primers (Invitrogen, Carlsbad, CA). PCR primers were purchased from Integrated DNA Technologies (Coralville, IA). Fold changes were calculated using the ΔΔC_t method and β-actin message as reference.

Soft-agar clonogenicity assay

Clonogenic growth was evaluated in 12-well plates after seeding 10,000 myeloma cells in 0.5 mL 0.33% agar/RPMI 1640 (Invitrogen, Carlsbad, CA) supplemented with 10% FCS. Cells were incubated (37°C, 5% CO₂) and fed with the same medium twice in the first week, and then treated with drugs or left untreated (control) for another 2 weeks. One colony was defi ned if more than 40 cells were observed. Plates were imaged and colonies were enumerated using Image J freeware. The latter entailed threshold adjustment using the Adjust Manu bar followed by colony counting using the Measure Manu bar [13].

Western blots

Western blots were performed to determine expression levels of proteins in MM cells [39]. Briefly, cells were lysed using the Mammalian Cell Extraction Kit (K269–500) from Biovision (Milpitas, CA). 10 μg of protein were loaded, fractionated by SDS-PAGE in 4–12% polyacrylamide gels, and transferred to nitrocellulose. Membranes were blocked with 5% non-fat dry milk in Tris buffered saline (TBS) containing 0.05% Tween-20 (TBST) prior to incubation overnight at 4°C with primary antibodies. Protein bands were visualized using HRP-conjugated secondary antibodies and SuperSignal West Pico (Pierce, Rockford, IL). Blots were subsequently stripped and re-probed for β-actin as loading control.

Gene expression profiling (GEP) and data analysis

GEP was performed on Affymetrix U133 Plus2.0 microarrays as previously described [13, 42]. GEP access number of primary myeloma sequential samples reported in this paper is GSE19554.

Lentiviral gene transduction

Lentivirus containing cDNA gene expression or shRNA knockdown cassettes was constructed as described previously [43, 44]. The plasmid containing the human ALDH1A1 full-length open-reading frame, NM_000689, was provided by Health Sciences Center (HSC) Core Research Facilities, University of Utah. Primer sequences for PCR-based cloning of ALDH1A1 cDNA were as follows: 5’-GGG GTT TAA ACA TGT CAT CCT CAG GCA CGC CAG AG-3’ (forward) and 5’- GGG GTT TAA ACT TAT GAG TTC TTC TGA GAG ATT TTC ACT GTG AC-3’ (reverse). The ALDH1A1 coding sequence was cloned into the lentiviral vector, pWPI. NEK2-targeted shRNA was cloned into vector, pLVTH, using the following PCR primers: 5’-GAT CCC CGG AGG AAG AGT GAT GGC AAG ATT CAA GAG ATC TTG CCA TCA CTC TTC CTC CTT TTT A-3’ and a nonsense scrambled oligonucleotide (5’-GAT CCC CGA CAC GCG ACT TGT ACC ACT TCA AGA GAG TGG TAC AAG TCG CGT GTC TTT TTA-3’) were obtained from Integrated DNA Technologies (Coralville, IA). Recombinant lentivirus was produced in 293T cells. Transduction efficiency, determined by flow cytometry of fluorescent reporter gene, was ~95%.

Apoptosis and dye-efflux multidrug-resistance assays

Programmed cell death was determined with the help of the flow-cytometric Annexin V apoptosis detection kit APC (catalog number 88–8007) from eBioscience (San Diego, CA). One million cells were washed in PBS and suspended in 1 mL binding buffer. Fluorochrome-conjugated antibody to Annexin V (5 μL) was added to the cell suspension (100 μL). Cells were incubated for 15 min at room temperature, washed and re-suspended in binding buffer and subjected to flow analysis. Drug resistance was measured using the eFluxx-ID™ Multidrug resistance assay as previously described [13]. Briefly, 500,000 cells were incubated (30 min, 37°C, water bath) with detection reagent, Golden dye, either with specific inhibitors of ABCB1, ABCC1 and ABCG2 drug export pumps or without inhibitors (control). Cells were washed and re-suspended in cold PBS for flow analysis, using MCF7 cells as reference.

Human myeloma xenografts in mice

All animal work was performed in accordance with the guidelines of the Institutional Animal Care and Use Committee of the University of Iowa under Animal Study Protocol 1202033. ARP1-ALDH1A1^OE cells and ARP1^EV cells (1.5 × 10⁶) were injected subcutaneously in the abdominal area of 6–8-week old NOD.Cγ -Rag1 mice (Jackson laboratory, Bar Harbor, Maine). Beginning on day 7 post cell transfer, mice were treated with bortezomib (1 mg/kg IP) twice weekly until humane endpoints were reached. Tumor volume was measured using a caliper and mice were sacrificed by CO₂ asphyxiation when tumor diameter reached 20 mm.

Statistical analysis

All values were analyzed using two-tailed Student’s t-test and expressed as mean ± SD. A p value of 5% (*, P < 0.05) was considered significant.

ACKNOWLEDGEMENTS

The authors are grateful to DNA facility of University of Iowa for the technical support and to Justin Fishbaugh, George Rasmussen and Heath Vignes in the Flow Cytometry Facility, which is a Carver College of Medicine / Holden Comprehensive Cancer Center core research facility at the University of Iowa. This work was supported by National Cancer Institute grants R01CA152105 (to F.Z.), R01CA151354 (to S.J.), T32 HL07734(EW) and P30 CA086862; the Leukemia Lymphoma Society TRP (to F.Z., 6246–11 and 6094–12); institutional start-up funds from the Department of Internal Medicine, Carver School of Medicine, University of Iowa (to F.Z. and G.T.).

Conflict of interest

None of the authors above has disclosed a conflict of interest with this submission.

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