A Comparison of Azacitidine and Decitabine Activities in Acute Myeloid Leukemia Cell Lines

Background The cytidine nucleoside analogs azacitidine (AZA) and decitabine (DAC) are used for the treatment of patients with myelodysplastic syndromes and acute myeloid leukemia (AML). Few non-clinical studies have directly compared the mechanisms of action of these agents in a head-to-head fashion, and the agents are often viewed as mechanistically similar DNA hypomethylating agents. To better understand the similarities and differences in mechanisms of these drugs, we compared their in vitro effects on several end points in human AML cell lines. Methodology/Principal Findings Both drugs effected DNA methyltransferase 1 depletion, DNA hypomethylation, and DNA damage induction, with DAC showing equivalent activity at concentrations 2- to 10-fold lower than AZA. At concentrations above 1 µM, AZA had a greater effect than DAC on reducing cell viability. Both drugs increased the sub-G1 fraction and apoptosis markers, with AZA decreasing all cell cycle phases and DAC causing an increase in G2-M. Total protein synthesis was reduced only by AZA, and drug-modulated gene expression profiles were largely non-overlapping. Conclusions/Significance These data demonstrate shared mechanisms of action of AZA and DAC on DNA-mediated markers of activity, but distinctly different effects in their actions on cell viability, protein synthesis, cell cycle, and gene expression. The differential effects of AZA may be mediated by RNA incorporation, as the distribution of AZA in nucleic acid of KG-1a cells was 65∶35, RNA∶DNA.


Introduction
Azacitidine (AZA; VidazaH, Celgene Corp., Summit, NJ) and decitabine (DAC; DacogenH, Eisai Inc., Woodcliff Lake, NJ) are structurally related, but distinct, cytidine nucleoside analogs used clinically for the treatment of myelodysplastic syndromes (MDS) andacute myeloid leukemia (AML) [1,2]. AZA is a ribonucleoside and DAC is a deoxyribonucleoside [3]. Following cellular uptake and sequential phosphorylations, AZA is incorporated into both RNA and DNA [4][5][6]. In contrast, DAC is phosphorylated by different kinases and is incorporated solely into DNA [6]. Once incorporated into DNA, AZA and DAC have related mechanisms of action, including depletion of DNA methyltransferases (DNMTs) [6,7], hypomethylation of DNA [8,9], and induction of DNA damage [10,11]. In randomized controlled phase III clinical trials in patients with MDS, overall response rates with AZA and DAC have been similar [12][13][14][15]; however, overall survival rates have differed. Whereas AZA demonstrated a significantly increased median overall survival in higher-risk MDS patients (by 9.4 months) compared with conventional care regimens [14], DAC did not demonstrate a statistically significant improvement in survival in a similar clinical trial [15].
Mechanisms of action that might explain differences in clinical activities of AZA and DAC have not been clearly defined [16]. The conventional description of AZA and DAC as interchangeable DNA hypomethylating agents overlooks potential additional mechanisms of AZA activity which are mediated via incorporation into newly synthesized RNA, including rRNAs, tRNAs, mRNAs, and miRNAs. It has been shown that RNA incorporation can account for 80-90% of the AZA incorporated into cellular nucleic acid [4]. The functional consequences of AZA incorporation into RNA include alterations in the processing of tRNA and rRNAs, leading to inhibition of protein synthesis [5,[17][18][19][20]. In two recent publications, direct comparisons of AZA and DAC activities have been made [9,21]. Data support the distinction of AZA and DAC as non-equivalent agents. In one study, the sensitivities (EC 50 values) of a panel of human cancer cell lines to AZA and DAC showed no correlation, and an AML cell line selected for resistance to DAC remained sensitive to AZA [21]. In another head-to-head in vitro comparison of these agents, AZA and DAC had distinct effects on gene expression profiles in Kasumi-1 AML cells [9].
To increase our understanding of the different mechanisms underlying AZA and DAC activity in AML, we directly compared their in vitro effects on several end points in human AML cell lines. Specifically, we compared the dose-response effects of AZA and DAC on cell viability, protein synthesis, DNMT1 protein, DNA damage, DNA methylation, cell cycle, apoptosis, and gene expression. Additionally, we tested the relative incorporation of AZA into the DNA and RNA of KG-1a cells. We show that both drugs modulate markers affected by DNA incorporation; however, the drugs have distinctly different effects on cell viability, protein synthesis, cell cycle, and gene expression.

Cell Culture and Drug Treatments
Human AML cell lines (THP-1 and HL-60) and media (RPMI-1640 and MEM) were purchased from American Type Culture Collection (Manassas, VA). Other human AML cell lines (KG-1a and OCI-AML3) were purchased from DSMZ GmbH (Braunschweig, Germany). Cell lines were grown in their respective vendorrecommended culture media and passaged every 3-5 days. In all experiments, cells were seeded approximately 24 hours before drug treatment at 37uC, 5% CO 2 , and cells were treated daily with serial dilutions of freshly-prepared compounds. AZA was manufactured at Aptuit Inc. (Greenwich, CT) for Celgene, and DAC was purchased from Sigma-Aldrich (St. Louis, MO). The concentrations used in experiments include the maximum concentrations (C max ) achieved in human plasma at clinically used dosages and schedules of administration. Human plasma C max values are 3-11 mM AZA and 0.3-1.6 mM DAC [22,23,24]. Radiolabeled AZA, [ 14 C]-AZA, was supplied by Aptuit Inc., with the radiolabel on C-4 and a specific activity of 13.7 mCi/mmol.

Cell Viability
AML cells were seeded in triplicate at 1610 4 cells per well in 96-well plates and incubated overnight at 37uC, 5% CO 2 . Cells were treated daily with serial dilutions (0.02-50 mM) of freshlyprepared AZA or DAC and incubated at 37uC, 5% CO 2 for 72 hours. Cell viability was assessed 72 hours after the initial drug treatment using the CellTiter-Glo assay (Promega, Madison, WI). Luminescence was measured with a spectrophotometer (Molecular Devices, Sunnyvale, CA) at 1500 msec. EC 50 values were calculated in Prism version 5.01 (GraphPad Software, Inc., La Jolla, CA) using results from two or three independent experiments.

Western Analysis
AML cells were seeded in either 10-cm dishes at 2.5610 6 cells per dish, or 6-well plates at 5610 5 cells per well, and incubated overnight at 37uC, 5% CO 2 . Drug treated AML cells were lysed in RIPA buffer (Millipore, Billerica, MA), containing protease inhibitors (Roche Applied Sciences, Indianapolis, IN) and phosphatase inhibitors (Sigma-Aldrich), on ice for 30-60 minutes and then centrifuged to clear cell debris. Protein concentrations were determined using the BCA protein assay (Thermo Fisher Scientific Inc., Waltham, MA). Proteins were separated on Bis-Tris NuPAGE gels and transferred to nitrocellulose membranes. DNMT1, phospho-H2AX, cleaved-PARP, and a-tubulin were detected using the LI-COR Odyssey (LI-COR Biotechnology, Lincoln, NE) imaging system, following incubation with the appropriate primary and secondary antibodies. The phospho-H2AX (Ser 139) and cleaved-PARP antibodies were from Cell Signaling Technology Inc. (Danvers, MA). The a-tubulin and DNMT1 antibodies were from EMD Chemicals Inc. (Gibbstown, NJ) and Abcam Inc. (Cambridge, MA), respectively. The goat anti-rabbit IRDye 680 and goat anti-mouse IRDye 800CW secondary antibodies were from LI-COR. NuPAGE gels were purchased from Life Technologies Corporation (Carlsbad, CA).

Flow Cytometry
For determination of cell cycle distribution, AML cell lines were stained with NIM-DAPI reagent (Beckman Coulter, Fullerton, CA). Duplicate samples were stained with AnnexinV-FITC and 7-AAD reagents (Beckman Coulter) for determination of early and late apoptotic populations. Samples were processed according to manufacturer's instructions and analyzed on a Beckman Coulter Cell Lab Quanta MPL flow cytometer.

DNA Methylation Analysis
Genomic DNA was purified from cells using the DNeasy Blood and Tissue Kit (Qiagen, Valencia, CA) according to the manufacturer's instructions. DNA yield was quantitated on a NanoDrop 8000 spectrophotometer (Thermo Fisher Scientific Inc). DNAs (0.5 mg/sample) were submitted to EpigenDx (Worcester, MA) for LINE-1 methylation analysis. LINE-1 methylation was determined by pyrosequencing of bisulfiteconverted DNA. Percent LINE-1 methylation represents the average percentage methylation of four CpG sites in duplicate samples. DNAs were submitted to Expression Analysis Inc.

Gene Expression Analysis
Cells were lysed using TRIzol reagent (Life Technologies Corporation) and total RNA was isolated using miRNeasy (Qiagen). Double-stranded cDNA was synthesized using 200 ng of total RNA. Biotin-labeled cRNA was synthesized using MessageAmp aRNA kit (Ambion, Austin, TX), and 15 mg of cRNA was fragmented and hybridized to each human U133A 2.0 gene chipset (Affymetrix, Santa Clara, CA). The GC-RMA algorithm was used for analysis and all analyses were carried out using GeneSpring 7.3 (Agilent, Santa Clara, CA). Averaged signals from biological duplicate samples were used to determine foldchange (treated versus untreated), with absolute fold change of $1.7 defining regulated genes. NextBio was used to identify regulated biogroups (based on the Gene Ontology consortium) from lists of regulated genes.

Incorporation of Radiolabeled AZA into Nucleic Acid
Incorporation of [ 14 C]-AZA into the DNA and RNA of KG-1a cells was determined at Southern Research Institute (Birmingham, AL). KG-1a cells (1610 5 cells/mL, 36T75 flasks, 50 mL/flask) were incubated with 0.3 mM [ 14 C]-AZA for 24 hours. Radioactive measurement of the trichloroacetic acid (TCA)-precipitable fraction, representing total nucleic acid (RNA + DNA), was performed as previously described [25,26]. Alkali-stable, TCAprecipitable radioactivity is a measure of the incorporation of nucleosides into DNA. For its determination, cell lysates were incubated with 2N NaOH overnight at 37uC, prior to neutrali-zation, TCA-precipitation, and measurement of radioactivity. Radioactive measurement of the total TCA-insoluble radioactivity minus the alkali-stable TCA-insoluble activity represents the measure of alkali-labile radioactivity in the total TCA precipitate. The alkali-labile fraction of the total TCA precipitate represents RNA.

Metabolic Labeling
Cells were treated with AZA or DAC for 24 or 48 hours, replacing the media and adding freshly prepared AZA or DAC after 24 hours. Following drug treatments, cells were incubated with methionine/cysteine-free media for 30 minutes. Twenty mCi of 35 S-methionine and 35 S-cysteine were then added to cells for 1 hour. Cells were rinsed with methionine/cysteine-free media and then with PBS, prior to lysis in buffer (Promega) with protease inhibitors (Roche). Cell lysates were precipitated with 20% TCA for 1 hour on ice. The precipitate was filtered through a glass microfiber disc and rinsed extensively with cold 20% TCA, followed by cold ethanol. Radioactivity was measured using a scintillation counter. Radioactive counts were normalized to cell numbers, determined in parallel cultures using the CellTiter-Glo assay (Promega).

AML Cell Lines Have Differential Sensitivities to AZA Versus DAC
Four human AML cell lines were assessed for their sensitivity to daily treatment with AZA or DAC in 72 hour cell viability assays ( Figure 1, Figure S1). Dose-response curves and EC 50 values were established for each drug ( Table 1). All AML cell lines were sensitive to both drugs, with reduced cell viability observed at concentrations $1 mM; however, the maximal amounts of viability reduction with AZA and DAC differed. At high drug concentrations (.1 mM) AZA was consistently more potent than DAC, reducing cell viability to 0-20% at concentrations above 5 mM. DAC, in contrast, did not reduce cell viability below 40% at any concentration up to 50 mM.
The differential activity of AZA compared with DAC may be explained by differences in the targeted cell sub-populations of asynchronously growing cell cultures. The half-lives of AZA and DAC in cell culture are short (,8-12 hours), necessitating daily treatment to ensure continued exposure (data not shown). AZA may have activity in cells during all phases of the cell cycle via RNA incorporation, whereas DAC incorporation into DNA is restricted to the S-phase and may limit the number of affected cells at any given treatment time. To test the hypothesis that additional treatments with DAC could further reduce cell viability, a doseresponse evaluation was performed in KG-1a cells at 2, 3, 4, 5 and 6 days, with daily DAC addition ( Figure S2). Cell viability was further reduced at each later time point, with a reduction to ,15% cell viability by 6 days. These data demonstrate that to achieve a similar reduction in cell viability with DAC versus AZA, cells must be more extensively treated.

AZA Is Incorporated into Both RNA and DNA in KG-1a Cells
A previous study in a mouse leukemia cell line demonstrated that AZA incorporated into RNA and DNA at a ratio of approximately 85:15, respectively [4]. To determine the relative

AZA and DAC Have Different Effects on Protein Synthesis
Protein synthesis inhibition via RNA incorporation of AZA has been described as a mechanism of AZA activity [5]. The effects of AZA and DAC on protein synthesis were compared by metabolic labeling ( 35 S-methionine and 35 S-cysteine) of KG-1a and THP-1 cells after 24 and 48 hours of daily drug treatment ( Figure 3). AZA (2 mM) treatment significantly reduced protein synthesis in both cell lines, inhibiting protein synthesis at 48 hours by 51% and 58% in KG-1a and THP-1 cells, respectively. DAC did not reduce protein synthesis in either cell line at 2 mM. Significant inhibition of protein synthesis with AZA (2 mM), but not DAC, was also seen at 24 hours, with synthesis reduced by 41% and 43% in KG-1a and THP-1 cells, respectively. Notably, the AZA concentrations that affected protein synthesis (2-5 mM) were also concentrations at which greater effects on cell viability were observed for AZA versus DAC.  Figure 5A). The doses inducing maximal hypomethylation paralleled the doses that maximally depleted DNMT1 protein.
In addition to evaluating changes in the LINE-1 DNA methylation, we also evaluated DNA methylation changes at 1505 gene-specific CpG loci using the Illumina GoldenGate DNA methylation platform (Table S1). Methylation changes were summarized by plotting the number of highly methylated loci, defined as loci with beta scores .0.8, versus drug concentration. Similar to findings with LINE-1 DNA methylation, the Gold-enGate assay showed the greatest reduction in highly methylated CpG loci at concentrations of 1 mM AZA and 0.3 mM DAC in both cell lines ( Figure 5B). Similar changes in DNA methylation were observed with 72 hour drug treatments, using both DNA methylation assays (data not shown).

AZA and DAC Induce DNA Damage in KG-1a and THP-1 Cells
Induction of DNA damage by AZA and DAC was measured using phospho-H2AX (Ser 139) as a marker of double stranded DNA breaks. In drug-treated KG-1a and THP-1 cells, dose-and time-dependent induction of phospho-H2AX was observed with both AZA and DAC (Figure 4). In KG-1a cells, induction of phospho-H2AX above basal levels was observed at AZA concentrations $1 mM at 48 and 72 hour time points. DAC, in contrast, caused a significantly greater increase in phospho-H2AX at lower drug concentrations ($0.03 mM). Notably, DNA damage was induced at clinically-relevant drug concentrations for both drugs. Similar results were seen in the THP-1 cell line, with DAC having greater potency than AZA at inducing DNA damage;

AZA and DAC Have Differential Effects on Cell Cycle in KG-1a Cells
To better understand the differential effects observed with AZA and DAC in cell viability assays, we analyzed drug-treated (48 hours) KG-1a cells for dose-dependent changes in cell cycle by flow cytometry of NIM-DAPI-stained cells ( Figure 6A

AZA and DAC Increase Markers of Apoptosis in KG-1a Cells
The observation that AZA and DAC treatment cause an increase in the sub-G1 phase of the KG-1a cell cycle prompted us to explore drug-induced effects on markers of apoptosis. Dose-dependent effects of AZA and DAC on markers of apoptosis were evaluated by flow cytometry of KG-1a cells treated for 48 hours and stained with AnnexinV-FITC and 7-AAD to detect early and late apoptotic events ( Figure 6B). PARP cleavage was also evaluated by Western analysis ( Figure 6C). An increase in the percentage of KG-1a cells undergoing apoptosis was detected by both flow and Western analyses with AZA ($1 mM) and DAC ($0.03 mM). Similar results were observed at the 72 hour time point (data not shown). In both analyses, DAC was more potent than AZA at increasing markers of apoptosis. The greater cell kill observed with AZA versus DAC in viability assays (Figure 1), despite less effect on markers of apoptosis, suggests that mechanisms other than apoptosis are contributing to AZAmediated cell death.

AZA and DAC Regulate Different Genes in KG-1a Cells
To further explore similarities and differences in the mechanisms of action of AZA compared with DAC, the molecular pathways regulated by each drug were explored using geneexpression profiling of KG-1a cells treated with a dose range (0.3-3 mM) of each drug for 24 and 48 hours. Genes with an absolute fold change of $1.7 following drug treatment were defined as regulated genes. As shown in Table 2, AZA regulated few genes at 0.3 mM; however, higher concentrations (1-3 mM) significantly increased the number of genes regulated. DAC regulated more genes than AZA only at 0.3 mM for 48 hours. Generally, AZA  Table  S2. Venn analysis of the genes modulated by each drug revealed that the majority of genes regulated by AZA and DAC are drugspecific ( Figure 7). Equimolar concentrations (1 mM), as well as concentrations approximating equipotency on DNA hypomethylation (1 mM AZA versus 0.3 mM DAC), were compared. When comparing 1 mM concentrations at 24 hours, the number of uniquely regulated genes represented 90% and 67% of the total number of genes regulated by AZA and DAC, respectively.
Lists of the drug-regulated genes were analyzed using NextBio in order to identify the affected gene ontology biogroups. Table 3 lists the biogroups that were most significantly regulated by AZA and DAC in KG-1a cells treated for 24 and 48 hours. The biogroups most significantly regulated at each time point were different for AZA and DAC. AZA (1 mM) most significantly regulated biogroups representing metabolic processes, aminoacyl-tRNA ligase activity and mitochondrion at 24 hours, as well as mitosis, cell cycle, and cell division at 48 hours. In contrast, DAC (1 mM) significantly upregulated the cell differentiation biogroup at both 24 and 48 hours. The biogroup of genes representing aminoacyl-tRNA ligase activity was significantly regulated by both AZA and DAC; however, AZA upregulated this biogroup at 24 hours, while DAC downregulated this biogroup at 48 hours.

Discussion
In human AML cell lines we compared dose-dependent responses to AZA and DAC on cell viability, protein synthesis,  DNMT1 depletion, hypomethylation of DNA, induction of DNA damage, cell cycle, induction of apoptosis, and gene expression. Both AZA and DAC regulated molecular end points related to drug incorporation into DNA, including DNMT1 depletion, DNA hypomethylation, and induction of the DNA damage marker phospho-H2AX. DAC affected these DNA-mediated markers at concentrations 2-to 10-fold lower than those of AZA, likely due to greater incorporation of DAC into DNA [4,27]. Previous direct comparisons of the DNA hypomethylating activities of AZA and DAC have also shown that DAC is more potent in this regard [9,28]. The experiment in KG-1a cells evaluating AZA incorporation into RNA and DNA showed a distribution of 65% and 35%, respectively. If the rates of cellular uptake and nucleic acid incorporation for AZA and DAC are similar, a 3-fold decrease in potency on DNA-mediated markers would be expected when comparing equimolar amounts of AZA versus DAC. Differences in clinical dosing and scheduling may influence the extent of DNAmediated activities of these drugs in patients. Differences between the mechanisms of action of AZA and DAC were observed in their activities on cell viability, protein synthesis, cell cycle, and gene expression. Consistent differences in the dose-response curves of AZA compared with DAC on cell viability were observed in four human AML cell lines, with AZA having a greater effect than DAC at reducing cell viability at drug concentrations above 1 mM. Clinically achievable plasma concentrations are 3-11 mM AZA and 0.3-1.6 mM DAC [22,23,24]. It is important to note that AZA and DAC both caused depletion of DNMT1 protein and DNA hypomethylation, within the time-frame of the cell viability assessment; therefore, the differential effects on cell viability cannot be accounted for solely by epigenetic mechanisms. The greater potency of DAC versus AZA, based on calculated EC 50 values, does not take into account the plateau effect on cell viability observed with DAC, in which increasing drug concentrations above 1 mM did not lead to a further reduction in cell viability below 40% after 3 days. This plateau effect with DAC likely reflects the fact that DAC activity is specific to DNA incorporation in the S-phase of the cell cycle [29], and treating cells for additional days could further reduce cell viability. Although AZA incorporation into DNA would similarly be Sphase restricted, AZA incorporation into RNA should occur in all phases of the cell cycle. In fact, previous studies showed that AZA (2-8 mM) induction of apoptosis in the human AML cell line HL-60 was preferential to G1-phase cells and occurred in a short timeframe (4-8 hours), implicating an RNA mechanism [30,31].
AZA inhibited protein synthesis at 24 hours post-treatment, an effect occurring within the doubling time of these cells. Earlier time points were not evaluated. DAC, in contrast, did not inhibit protein synthesis. The inhibition of protein synthesis by AZA was observed at concentrations that reduced cell viability below that of DAC, suggesting that the anti-leukemic activity of AZA observed at drug concentrations .1 mM may be explained by mechanisms in addition to, or other than, DNA-mediated mechanisms. In multiple myeloma cell lines, AZA reduced IL6-Ra protein levels within 2 hours, and to an equal extent as cycloheximide, consistent with a mechanism involving protein synthesis inhibition [32]. Differences in cell cycle regulation with AZA and DAC were also observed in KG-1a cells. Although both drugs increased the sub-G1 fraction of cells, DAC caused a concomitant increase in G2-M and decrease in G0/G1 phases of the cell cycle, whereas AZA decreased all phases of the cell cycle. The increase in G2-M phase with DAC in KG-1a cells is consistent with previous observations in other hematopoietic tumor cell lines [33,34]. Both drugs increased markers of apoptosis, including Annexin V staining and cleaved-PARP. Increased apoptosis has also been observed with AZA and DAC treatment of other leukemic cell lines [11,30,31,33,[35][36][37]. The lesser effect of AZA compared with DAC on markers of apoptosis, despite greater cell killing with AZA, suggests that mechanisms other than apoptosis are contributing to AZA-mediated programmed cell death.
Finally, microarray analysis of gene expression in KG-1a cells revealed differences between AZA and DAC. At low concentrations (,0.3 mM), very few genes were regulated at the 24 and 48 hour time points by either drug (data not shown). In contrast, at high concentrations ($1 mM) over 1000 genes could be regulated (Table 2), and AZA regulated a greater number of genes compared with DAC. The concentrations of AZA that led to significant gene modulation were also the concentrations that affected cell viability. When comparing the lists of genes that were regulated by AZA (1 mM) and DAC (0.3 and 1 mM), a minority of genes were commonly regulated. It should be noted that 5-25% of the genes identified as ''commonly regulated'' in the overlapping Venn diagram were regulated by AZA and DAC in opposite directions, further suggesting mechanistic differences between these drugs. Our findings are consistent with a recently published gene expression comparison of AZA and DAC in the AML cell line Kasumi-1, although low concentrations of each drug (0.5 mM AZA and 0.05 mM DAC) were used in that study [9]. Pathway analysis of the regulated genes provided intriguing insights into the cellular actions of these drugs. AZA significantly downregulated genes involving cell cycle, cell division and mitosis, whereas DAC significantly upregulated genes involved in cell differentiation (Table 3).
These data illustrate similarities and differences in the mechanisms of action of AZA and DAC. Historically, these drugs have been viewed as mechanistically similar DNA hypomethylating agents, and both have been described as having dosedependent, dual mechanisms of action [1,2]. For DAC, the ''dual mechanism'' has referred to inhibition of cell proliferation at high doses and a DNA hypomethylation-mediated effect on gene reexpression at low doses, affecting processes of cell differentiation, tumor suppression, and stimulation of immune mechanisms [2]. For AZA, the ''dual mechanism'' has referred to cytotoxicity at high doses, via RNA and DNA incorporation, and DNA hypomethylation at lower doses [1]. Certainly both drugs have dose-dependent effects; however, previously described ''dual mechanisms'' of these drugs should not be interpreted as shared. We show that both drugs modulated markers of azanucleoside incorporation into DNA (DNMT1 depletion, DNA damage induction, and DNA hypomethylation); however, DAC demonstrated a greater effect on these markers. Also, although AZA and DAC increased the sub-G1 fraction of cells and markers of apoptosis, AZA demonstrated a greater effect on reducing cell viability and decreasing protein synthesis. It is clear that the antileukemic activities of AZA and DAC differ in vitro, with DAC acting solely through DNA-mediated mechanisms (epigenetic and/or DNA damage), and AZA acting via mechanisms in addition to, or other than, incorporation into DNA. Translational research will be key to understanding how the mechanistic differences observed between AZA and DAC in vitro will be best applied to the clinical utility of these drugs. Figure S1 AZA and DAC differentially affect cell viability in AML cell lines. Cell viability of AML cell lines, KG-1a and THP-1, was assessed after 72 hours of daily treatment with AZA or DAC (0-50 mM), using direct cell counts with trypan blue exclusion or MTS assay. Standard deviation was determined from triplicate wells of a single experiment, except for the KG-1a direct count data, which shows error as the range of duplicate wells. Found at: doi:10.1371/journal.pone.0009001.s001 (0.11 MB PPT) Figure S2 Extended dosing with DAC further reduces KG-1a cell viability. KG-1a cell viability was assessed at 2, 3, 4, 5 and 6 days, with daily DAC addition, using the CellTiter-Glo assay. Found at: doi:10.1371/journal.pone.0009001.s002 (0.14 MB PPT)