HDAC3 Activity is Essential for Human Leukemic Cell Growth and the Expression of β-catenin, MYC, and WT1

Therapy of acute myeloid leukemia (AML) is unsatisfactory. Histone deacetylase inhibitors (HDACi) are active against leukemic cells in vitro and in vivo. Clinical data suggest further testing of such epigenetic drugs and to identify mechanisms and markers for their efficacy. Primary and permanent AML cells were screened for viability, replication stress/DNA damage, and regrowth capacities after single exposures to the clinically used pan-HDACi panobinostat (LBH589), the class I HDACi entinostat/romidepsin (MS-275/FK228), the HDAC3 inhibitor RGFP966, the HDAC6 inhibitor marbostat-100, the non-steroidal anti-inflammatory drug (NSAID) indomethacin, and the replication stress inducer hydroxyurea (HU). Immunoblotting was used to test if HDACi modulate the leukemia-associated transcription factors β-catenin, Wilms tumor (WT1), and myelocytomatosis oncogene (MYC). RNAi was used to delineate how these factors interact. We show that LBH589, MS-275, FK228, RGFP966, and HU induce apoptosis, replication stress/DNA damage, and apoptotic fragmentation of β-catenin. Indomethacin destabilizes β-catenin and potentiates anti-proliferative effects of HDACi. HDACi attenuate WT1 and MYC caspase-dependently and -independently. Genetic experiments reveal a cross-regulation between MYC and WT1 and a regulation of β-catenin by WT1. In conclusion, reduced levels of β-catenin, MYC, and WT1 are molecular markers for the efficacy of HDACi. HDAC3 inhibition induces apoptosis and disrupts tumor-associated protein expression.


Introduction
It is estimated that there will be 437,033 new cases of leukemia and 309,006 deaths associated worldwide in 2018 [1]. Predictions state that more than 21,450 people will be diagnosed with acute myeloid leukemia (AML) and nearly 10,920 people will die from it alone in the USA in 2019 [2]. This warrants the search for new therapeutic strategies. The transcription factor β-catenin appears bifunctional molecules suppresses cell proliferation and angiogenesis. Remarkably, normal cells are spared by such treatment [35,36]. Whether NSAIDs combine favorably with HDACi against leukemic cells is an interesting option that remains to be investigated.
In order to fully develop the therapeutic potential of HDACi, some key questions need to be resolved. For example, 18 human HDACs fall into the classes I, II, III, and IV and it has to be further clarified if a pharmacological inhibition of subsets or even single HDACs can produce anti-leukemic effects. Moreover, further molecular mechanisms and markers have to be identified to use HDACi effectively. We set out to answer these questions. Our data demonstrate that HDAC3 activity is a key factor for the survival and the maintenance of tumor-and stemness-associated transcription factors in AML cells.

Responses of Leukemic Cells to LBH589
We analyzed the responses of human AML cell lines (FLT3-ITD-positive MV4-11 and JAK2V617F-positive HEL cells) to the pan-HDACi LBH589. We noted a significant time-and dose-dependent accumulation of annexin-V-FITC-positive cells. After 24 h, 10 nM LBH589 induced a three-fold increase in annexin-V-FITC-positive MV4-11 cells, which corresponds to 16% apoptotic cells. 30 nM LBH589 caused a four-fold increase of apoptosis in MV4-11 cells and a six-fold increase of apoptotic cells in HEL cells, which corresponds to 34% and 67% dead cells ( Figure 1A; see Supplementary Figure S1 for exemplary dot plots).
The analysis of the cell cycle distributions of LBH589-treated cells revealed that 10 nM LBH589 significantly increased the number of MV4-11 cells in the G1 phase by 20% and reduced the number of S phase cells by 18%. Such changes also occurred in HEL cells as a trend. 30 nM LBH589 augmented the subG1 fraction, which represents cells with fragmented DNA, by 23% in MV4-11 and by 30% in HEL cell cultures ( Figure 1B). These increased levels of the subG1 fractions were linked to a decline of the G1 and S phase populations in both cell lines and 30 nM LBH589 reduced the number of HEL cells in S phase significantly by 9% ( Figure 1B).
In both cell types, the novel and specific HDAC6 inhibitor marbostat-100 [26] caused a slight and insignificant increase in their G1 phase populations at the expense of S phase populations. Marbostat-100 did not induce apoptosis in MV4-11 and HEL cell cultures ( Figure 1A,B and Supplementary Figure S1). Thus, pro-apoptotic effects of LBH589 are unlikely caused by its inhibitory effect on HDAC6.
To corroborate these results, we analyzed further apoptosis markers, the cleavage of the executioner caspase-3 and the caspase-dependent cleavage of PARP1 [29,55]. Congruent with our flow cytometry analyses, we detected significant caspase-3 activation and cleaved PARP1 in MV4-11 and HEL cells incubated with 30 nM LBH589 for 24 h ( Figure 1C). Compared to HEL cells, MV4-11 cells have much lower levels of PARP1, which are more evident as cleaved PARP1 in apoptotic MV4-11 cells. It is currently unknown whether HDACi induce PARP1 that is subsequently cleaved or if our antibodies recognize cleaved PARP1 better than its full-length form.
These data indicate that low levels of LBH589 mainly promote cell cycle arrest and higher doses lead to the induction of apoptosis and the fragmentation of DNA in MV4-11 and HEL cell cultures.  50 nM, 500 nM, and 1 µM) for 24 h. Cells were stained with annexin-V-FITC/propidium iodide (PI) and analyzed by flow cytometry (n = 3; mean + SD; two-way ANOVA; * p ≤ 0.05; ** p ≤ 0.01; *** p ≤ 0.001; **** p ≤ 0.0001). (B) Cells were incubated with HDACi as stated in (A). Fixed cells were stained with PI and cell cycle distributions were analyzed by flow cytometry (n = 3; mean + SD; two-way ANOVA; * p ≤ 0.05; ** p ≤ 0.01; *** p ≤ 0.001; **** p ≤ 0.0001). (C) Cells were treated with 10 nM or 30 nM LBH589 for 24 h. Indicated proteins were detected via Western blot (cl., cleaved; fl., full-length) with HSP90 and β-actin as loading controls (n = 3). Please note that compared to HEL cells MV4-11 cells have far less full-length PARP1 and that the lot of the anti-PARP1 antibody may have preferentially recognized the cleaved form of PARP1. (D) Regrowth of the human leukemia cell lines MV4-11 and HEL. Cells were treated with 10 nM or 30 nM LBH589 for 24 h. Thereafter, cells were washed twice with PBS and reseeded. Cells were stained with trypan blue and viable cells were counted after 4 days (n = 3; mean + SD; one-way ANOVA; **** p ≤ 0.0001).
Cancers 2019, 11, 1436 5 of 20 We additionally analyzed the ability of these cells to regrow at low density once the treatment with HDACi had been stopped. We treated MV4-11 and HEL cells with 10 or 30 nM LBH589 for 24 h. Thereafter, the cells were harvested and washed twice for withdrawal of HDACi. The proliferation of the cells was determined at day 4 after discontinuation of the treatment. Regrowth of MV4-11 was nearly prevented by 10 nM LBH589 and HEL cells were unable to regrow after an exposure to 30 nM LBH589 ( Figure 1D).
These data indicate that low levels of LBH589 mainly promote cell cycle arrest and higher doses lead to the induction of apoptosis and the fragmentation of DNA in MV4-11 and HEL cell cultures.

Reduction of β-Catenin upon Class I HDAC Inhibition
Since β-catenin is relevant for the growth and survival of leukemic cells [3][4][5][6][7][8][9], we tested whether LBH589 alters the expression of this protein in leukemic cells. Western blot analyses of MV4-11 and HEL cells revealed that β-catenin was significantly degraded after incubation with LBH589. This led to the advent of an additional band that was revealed by the β-catenin antibody (Figure 2A). The β-catenin mRNA levels were not decreased by LBH589 (data not shown).
As LBH589 blocks class I, II, and IV HDACs [22], we addressed whether class I HDACs and/or HDAC6 prevent the processing of β-catenin. We inhibited HDAC1-3 with MS-275 [22] and HDAC6 with marbostat-100 [26]. We noticed that MS-275 caused the cleavage of PARP1 and β-catenin together with an activation of caspase-3 in both cell lines (Figure 2A). LBH589 and MS-275 also promoted an accumulation of

Reduction of β-Catenin upon Class I HDAC Inhibition
Since β-catenin is relevant for the growth and survival of leukemic cells [3][4][5][6][7][8][9], we tested whether LBH589 alters the expression of this protein in leukemic cells. Western blot analyses of MV4-11 and HEL cells revealed that β-catenin was significantly degraded after incubation with LBH589. This led to the advent of an additional band that was revealed by the β-catenin antibody (Figure 2A). The βcatenin mRNA levels were not decreased by LBH589 (data not shown).
To exclude that the processing of β-catenin in response to HDACi is an artifact of permanent leukemic cell cultures, we incubated the LTC FFM12 with LBH589. As in permanent cell lines, LBH589 led to a cleavage of β-catenin and PARP1 ( Figure 2B).
Next, we compared the β-catenin levels of MV4-11 and HEL cells with the β-catenin levels in normal PBMCs. We included colorectal cancer cells with wild-type (RKO cells) or mutant β-catenin (HCT116 cells) for comparison. We found a similar expression of β-catenin in PBMCs, RKO, HEL, and MV4-11 cells. HCT116 cells showed the expected [56] overexpression of mutant β-catenin ( Figure  2C). These data suggest that β-catenin is wild-type in MV4-11 and HEL cells.
We noted the occurrence of β-catenin cleavage products in cells with a high activity of the apoptosis executioner enzyme caspase-3 ( Figure 2A), which can cleave β-catenin [16,17]. Therefore, we speculated that caspases process β-catenin in AML cells exposed to pro-apoptotic doses of LBH589. We tested this hypothesis with the pan-caspase inhibitor z-VAD-FMK. Incubation of AML cells with LBH589 and z-VAD-FMK prevented the occurrence of β-catenin cleavage products and restored the levels of full-length β-catenin ( Figure 2D). We observed similar data for MS-275 and FK228 and the efficiency of z-VAD-FMK was proven as abrogated activation of caspase-3 and intact PARP1 (Supplementary Figure S3).
To complement these analyses, we tested for putative alterations of the expression and phosphorylation-dependent activation of GSK3β, which promotes the proteasomal degradation of βcatenin [15]. We noted that HDACi do not alter total and phosphorylated GSK3β in MV4-11 and FFM12 cells ( Figure 2B,D).
LBH589, MS-275, and FK228 increased the levels of ɣH2AX and promoted apoptosis of MV4-11 cells (Figure 2A, and Supplementary Figure S3). DNA double strand breaks, which are generated upon DNA fragmentation by caspase-activated DNase, can also induce ɣH2AX [57,58]. Therefore, such an accumulation of ɣH2AX might be a consequence of apoptotic DNA fragmentation. To test this, we incubated MV4-11 cells with HDACi and z-VAD-FMK. We found that this accumulation of ɣH2AX could only be partially abrogated with z-VAD-FMK (Supplementary Figure S3). These data agree with previous reports indicating that HDACs are gatekeepers of genomic integrity [21,28,[59][60][61].
To exclude that the processing of β-catenin in response to HDACi is an artifact of permanent leukemic cell cultures, we incubated the LTC FFM12 with LBH589. As in permanent cell lines, LBH589 led to a cleavage of β-catenin and PARP1 ( Figure 2B).
Next, we compared the β-catenin levels of MV4-11 and HEL cells with the β-catenin levels in normal PBMCs. We included colorectal cancer cells with wild-type (RKO cells) or mutant β-catenin (HCT116 cells) for comparison. We found a similar expression of β-catenin in PBMCs, RKO, HEL, and MV4-11 cells. HCT116 cells showed the expected [56] overexpression of mutant β-catenin ( Figure 2C). These data suggest that β-catenin is wild-type in MV4-11 and HEL cells.
We noted the occurrence of β-catenin cleavage products in cells with a high activity of the apoptosis executioner enzyme caspase-3 ( Figure 2A), which can cleave β-catenin [16,17]. Therefore, we speculated that caspases process β-catenin in AML cells exposed to pro-apoptotic doses of LBH589. We tested this hypothesis with the pan-caspase inhibitor z-VAD-FMK. Incubation of AML cells with LBH589 and z-VAD-FMK prevented the occurrence of β-catenin cleavage products and restored the levels of full-length β-catenin ( Figure 2D). We observed similar data for MS-275 and FK228 and the efficiency of z-VAD-FMK was proven as abrogated activation of caspase-3 and intact PARP1 (Supplementary Figure S3).
To complement these analyses, we tested for putative alterations of the expression and phosphorylation-dependent activation of GSK3β, which promotes the proteasomal degradation of β-catenin [15]. We noted that HDACi do not alter total and phosphorylated GSK3β in MV4-11 and FFM12 cells ( Figure 2B,D).
LBH589, MS-275, and FK228 increased the levels of

Reduction of β-Catenin upon Class I HDAC Inhibition
Since β-catenin is relevant for the growth and survival of leukemic cells [3][4][5][6][7][8][9], we tested wh LBH589 alters the expression of this protein in leukemic cells. Western blot analyses of MV4-1 HEL cells revealed that β-catenin was significantly degraded after incubation with LBH589. Th to the advent of an additional band that was revealed by the β-catenin antibody (Figure 2A). T catenin mRNA levels were not decreased by LBH589 (data not shown).
As LBH589 blocks class I, II, and IV HDACs [22], we addressed whether class I HDACs a HDAC6 prevent the processing of β-catenin. We inhibited HDAC1-3 with MS-275 [22] and H with marbostat-100 [26]. We noticed that MS-275 caused the cleavage of PARP1 and β-c together with an activation of caspase-3 in both cell lines (Figure 2A). LBH589 and MS-27 promoted an accumulation of ɣ H2AX indicating replication stress and/or DNA damage MV4-11 and HEL cells ( Figure 2A). We could confirm [26] that LBH589 attenuates the express HDAC6 in leukemic cells. Moreover, LBH589 as well as marbostat-100 effectively inhibit HD which is evident as accumulation of acetylated tubulin [26,28,29]. Congruent with Figure marbostat-100 did not evoke the activation of caspase-3 or the processing of β-catenin (Figure To exclude that the processing of β-catenin in response to HDACi is an artifact of perm leukemic cell cultures, we incubated the LTC FFM12 with LBH589. As in permanent cell LBH589 led to a cleavage of β-catenin and PARP1 ( Figure 2B).
Next, we compared the β-catenin levels of MV4-11 and HEL cells with the β-catenin lev normal PBMCs. We included colorectal cancer cells with wild-type (RKO cells) or mutant β-c (HCT116 cells) for comparison. We found a similar expression of β-catenin in PBMCs, RKO, and MV4-11 cells. HCT116 cells showed the expected [56] overexpression of mutant β-catenin (F

Reduction of β-Catenin upon Class I HDAC Inhibition
Since β-catenin is relevant for the growth and survival of leukemic cells [3][4][5][6][7][8][9], we LBH589 alters the expression of this protein in leukemic cells. Western blot analyses HEL cells revealed that β-catenin was significantly degraded after incubation with LB to the advent of an additional band that was revealed by the β-catenin antibody (Fig catenin mRNA levels were not decreased by LBH589 (data not shown).
As LBH589 blocks class I, II, and IV HDACs [22], we addressed whether class I HDAC6 prevent the processing of β-catenin. We inhibited HDAC1-3 with MS-275 [2 with marbostat-100 [26]. We noticed that MS-275 caused the cleavage of PARP1 together with an activation of caspase-3 in both cell lines (Figure 2A). LBH589 an promoted an accumulation of ɣ H2AX indicating replication stress and/or DNA MV4-11 and HEL cells ( Figure 2A). We could confirm [26] that LBH589 attenuates th HDAC6 in leukemic cells. Moreover, LBH589 as well as marbostat-100 effectively i which is evident as accumulation of acetylated tubulin [26,28,29]. Congruent wit marbostat-100 did not evoke the activation of caspase-3 or the processing of β-catenin To exclude that the processing of β-catenin in response to HDACi is an artifac leukemic cell cultures, we incubated the LTC FFM12 with LBH589. As in perma LBH589 led to a cleavage of β-catenin and PARP1 ( Figure 2B).
Next, we compared the β-catenin levels of MV4-11 and HEL cells with the β-c normal PBMCs. We included colorectal cancer cells with wild-type (RKO cells) or m H2AX [57,58]. Therefore, such an accumulation of

Reduction of β-Catenin upon Class I HDAC Inhibition
Since β-catenin is relevant for the growth and survival of leukemic cells [3][4][5][6][7][8][9], we tested whether LBH589 alters the expression of this protein in leukemic cells. Western blot analyses of MV4-11 and HEL cells revealed that β-catenin was significantly degraded after incubation with LBH589. This led to the advent of an additional band that was revealed by the β-catenin antibody (Figure 2A). The βcatenin mRNA levels were not decreased by LBH589 (data not shown).
To exclude that the processing of β-catenin in response to HDACi is an artifact of permanent leukemic cell cultures, we incubated the LTC FFM12 with LBH589. As in permanent cell lines, LBH589 led to a cleavage of β-catenin and PARP1 ( Figure 2B).
Next, we compared the β-catenin levels of MV4-11 and HEL cells with the β-catenin levels in H2AX might be a consequence of apoptotic DNA fragmentation. To test this, we incubated MV4-11 cells with HDACi and z-VAD-FMK. We found that this accumulation of Cancers 2019, 11, x 0.01; *** p ≤ 0.001; **** p ≤ 0.0001). (C) Cells were treated Indicated proteins were detected via Western blot (cl., cleav as loading controls (n = 3). Please note that compared to H length PARP1 and that the lot of the anti-PARP1 antibody cleaved form of PARP1. (D) Regrowth of the human leukem treated with 10 nM or 30 nM LBH589 for 24 h. Thereafter reseeded. Cells were stained with trypan blue and viable ce + SD; one-way ANOVA; **** p ≤ 0.0001).

Reduction of β-Catenin upon Class I HDAC Inhibition
Since β-catenin is relevant for the growth and surviva LBH589 alters the expression of this protein in leukemic c HEL cells revealed that β-catenin was significantly degrad to the advent of an additional band that was revealed by t catenin mRNA levels were not decreased by LBH589 (data As LBH589 blocks class I, II, and IV HDACs [22], we HDAC6 prevent the processing of β-catenin. We inhibited with marbostat-100 [26]. We noticed that MS-275 cause together with an activation of caspase-3 in both cell line promoted an accumulation of ɣ H2AX indicating rep MV4-11 and HEL cells ( Figure 2A). We could confirm [26] HDAC6 in leukemic cells. Moreover, LBH589 as well as which is evident as accumulation of acetylated tubulin marbostat-100 did not evoke the activation of caspase-3 or To exclude that the processing of β-catenin in respo leukemic cell cultures, we incubated the LTC FFM12 w LBH589 led to a cleavage of β-catenin and PARP1 ( Figure   H2AX Cancers 2019, 11, 1436 6 of 20 could only be partially abrogated with z-VAD-FMK (Supplementary Figure S3). These data agree with previous reports indicating that HDACs are gatekeepers of genomic integrity [21,28,[59][60][61].
We summarize that LBH589 induced apoptosis concomitant with an attenuation of β-catenin.
Cancers 2019, 11, x 6 of 20 We summarize that LBH589 induced apoptosis concomitant with an attenuation of β-catenin. During the analysis of various AML cell lines, we noticed that the human myoblast cell line KG1 was sensitive to apoptosis induction by LBH589, but retained β-catenin ( Figure 3A-C). We observed a dose-dependent accumulation of acetylated histones and of acetylated tubulin in LBH589-treated KG1 cells ( Figure 3A,B). This was associated with a dose-dependent cleavage of PARP1 ( Figure 3A,C) and a significant increase in early and late apoptotic cells in KG1 cell cultures (Supplementary Figure

Indomethacin Can Accentuate Anti-Proliferative Effects of LBH589
During the analysis of various AML cell lines, we noticed that the human myoblast cell line KG1 was sensitive to apoptosis induction by LBH589, but retained β-catenin ( Figure 3A-C). We observed a dose-dependent accumulation of acetylated histones and of acetylated tubulin in LBH589-treated KG1 cells ( Figure 3A,B). This was associated with a dose-dependent cleavage of PARP1 ( Figure 3A,C) and a significant increase in early and late apoptotic cells in KG1 cell cultures (Supplementary Figure  S4). Such an independence of apoptosis induction and β-catenin processing was also found in the AML-LTC FFM05 (data not shown).
Cancers 2019, 11, x 7 of 20 S4). Such an independence of apoptosis induction and β-catenin processing was also found in the AML-LTC FFM05 (data not shown). Differences in the HDACi-mediated regulation of β-catenin in MV4-11 cells and KG1 cells cannot be explained by differences in total and phosphorylated GSK3β, as these are unaltered by HDACi Differences in the HDACi-mediated regulation of β-catenin in MV4-11 cells and KG1 cells cannot be explained by differences in total and phosphorylated GSK3β, as these are unaltered by HDACi ( Figures 2D and 3C). Moreover, we could prove the efficacy of LBH589 in both MV4-11 and KG1 cells as accumulation of acetylated forms of histone H3 and tubulin ( Figure 3A,B).
A common response of primary and permanent cell lines to LBH589 is a reduction of MYC ( Figure 3B,C and Supplementary Figure S5) and this occurs irrespective of β-catenin in KG1 cells ( Figure 3B,C). Furthermore, in contrast to the caspase-dependent processing of β-catenin in MV4-11 cells ( Figure 2D), the HDACi-mediated attenuation of MYC cannot be rescued by anti-apoptotic concentrations of z-VAD-FMK in KG1 cells ( Figure 3C).
The frequently prescribed NSAID indomethacin [62] has been reported to reduce β-catenin expression in chronic myeloid leukemia (CML) cells [33]. We noted a detectable effect of indomethacin against β-catenin in KG1 cells ( Figure 3D). Therefore, we tested whether a reduction of β-catenin by indomethacin combines favorably with LBH589 against KG1 cells. KG1 cells hardly recovered at low density from a previous treatment with 30 nM LBH589 until day 4 after treatment discontinuation. A near complete inhibition of proliferation until day 4 was caused by 50 nM LBH589. Indomethacin dose-dependently suppressed the recovery of cells after drug removal and potentiated long-lasting anti-proliferative effects of LBH589 at a low dose of 10 nM ( Figure 3E).
These data suggest that indomethacin promotes LBH589-evoked anti-leukemic effects.

HDAC3 Activity Is Required to Maintain β-Catenin, MYC, and WT1
Specific HDACi are considered as agents that can eliminate cancer cells at a low cost of side-effects [18][19][20]. Since HDAC3 is required for the survival and genomic integrity of leukemic cells [59,60,[63][64][65], we speculated that the pro-apoptotic and DNA-damaging effects of LBH589 and MS-275 are due to an inhibition of HDAC3. To test this, we blocked HDAC3 with its specific inhibitor RGFP966 [59,60,63,65,66]. We applied a maximal dose of 10 µM because RGFP966 does not inhibit any other HDAC at a dose up to 15 µM in a biochemical assay [66]. Flow cytometry of fixed, propidium iodide (PI)-stained cells MV4-11 cells revealed that treatment with RGFP966 for 24 h dose-dependently triggered an increase of the subG1 fractions in AML cell cultures. 1, 5, and 10 µM RGFP966 increased the subG1 fractions from 8% to 11%, 18%, and 25%, respectively. This effect was significant for 5-10 µM RGFP966 and it was associated with a significant reduction of cells in S phase and G2/M phase ( Figure 4A).
Pan-caspase inhibition with z-VAD-FMK prevented DNA fragmentation measured as subG1 fraction and the reduction of cells in G2/M phase by 10 µM RGFP966. Moreover, z-VAD-FMK in combination with 5-10 µM RGFP966 increased the numbers of cells in G1 phase significantly. The reduction of S phase cells by RGFP966 was though not affected by z-VAD-FMK ( Figure 4A). These findings suggest that RGFP966 causes apoptosis of MV4-11 cells and that this prevents an accumulation of cells in the G1 and G2/M phases in response to RGFP966.
It is often unknown if the inhibition of one single HDAC is sufficient to attenuate oncogenic proteins. Therefore, we tested for a potential impact of RGFP966 on the leukemia-and stemness-associated transcription factors β-catenin, MYC, and WT1. We found that RGFP966 reduced WT1 and led to the advent of a WT1 cleavage product ( Figure 4C), which is seen in leukemic cells undergoing apoptosis [29,55]. A loss of WT1 has consistently been noted in K562 cells treated with FK228 [29]. RGFP966 also attenuated the expression of β-catenin and MYC in a dose-dependent manner and led to the occurrence of a β-catenin cleavage product ( Figure 4D).

Reduction of β-Catenin upon Class I HDAC Inhibition
Since β-catenin is relevant for the growth and survival of leukemic cells [3-9 LBH589 alters the expression of this protein in leukemic cells. Western blot anal HEL cells revealed that β-catenin was significantly degraded after incubation wi to the advent of an additional band that was revealed by the β-catenin antibody catenin mRNA levels were not decreased by LBH589 (data not shown).
As LBH589 blocks class I, II, and IV HDACs [22], we addressed whether cla HDAC6 prevent the processing of β-catenin. We inhibited HDAC1-3 with MS-2 with marbostat-100 [26]. We noticed that MS-275 caused the cleavage of PA together with an activation of caspase-3 in both cell lines (Figure 2A). LBH58 promoted an accumulation of ɣ H2AX indicating replication stress and/or D MV4-11 and HEL cells (Figure 2A). We could confirm [26] that LBH589 attenuat HDAC6 in leukemic cells. Moreover, LBH589 as well as marbostat-100 effectiv which is evident as accumulation of acetylated tubulin [26,28,29]. Congruent marbostat-100 did not evoke the activation of caspase-3 or the processing of β-ca To exclude that the processing of β-catenin in response to HDACi is an ar leukemic cell cultures, we incubated the LTC FFM12 with LBH589. As in pe LBH589 led to a cleavage of β-catenin and PARP1 ( Figure 2B).
Next, we compared the β-catenin levels of MV4-11 and HEL cells with the normal PBMCs. We included colorectal cancer cells with wild-type (RKO cells) (HCT116 cells) for comparison. We found a similar expression of β-catenin in P and MV4-11 cells. HCT116 cells showed the expected [56] overexpression of muta 2C). These data suggest that β-catenin is wild-type in MV4-11 and HEL cells.
We noted the occurrence of β-catenin cleavage products in cells with a apoptosis executioner enzyme caspase-3 (Figure 2A), which can cleave β-cateni we speculated that caspases process β-catenin in AML cells exposed to pro LBH589. We tested this hypothesis with the pan-caspase inhibitor z-VAD-FMK. cells with LBH589 and z-VAD-FMK prevented the occurrence of β-catenin clea restored the levels of full-length β-catenin ( Figure 2D). We observed similar d FK228 and the efficiency of z-VAD-FMK was proven as abrogated activation of PARP1 (Supplementary Figure S3).
To complement these analyses, we tested for putative alterations of t phosphorylation-dependent activation of GSK3β, which promotes the proteasom catenin [15]. We noted that HDACi do not alter total and phosphorylated GSK FFM12 cells ( Figure 2B,D).
LBH589, MS-275, and FK228 increased the levels of ɣH2AX and promoted a cells ( H2AX indicating replication stress and DNA damage ( Figure 4D). To assess if this increase in treated with 10 nM or 30 nM LBH589 for 24 h. Thereafter, cells were washed twice wi reseeded. Cells were stained with trypan blue and viable cells were counted after 4 days ( + SD; one-way ANOVA; **** p ≤ 0.0001).

Reduction of β-Catenin upon Class I HDAC Inhibition
Since β-catenin is relevant for the growth and survival of leukemic cells [3][4][5][6][7][8][9], we LBH589 alters the expression of this protein in leukemic cells. Western blot analyses HEL cells revealed that β-catenin was significantly degraded after incubation with LB to the advent of an additional band that was revealed by the β-catenin antibody (Fig  catenin mRNA levels were not decreased by LBH589 (data not shown).
As LBH589 blocks class I, II, and IV HDACs [22], we addressed whether class I HDAC6 prevent the processing of β-catenin. We inhibited HDAC1-3 with MS-275 [2 with marbostat-100 [26]. We noticed that MS-275 caused the cleavage of PARP1 together with an activation of caspase-3 in both cell lines (Figure 2A). LBH589 an promoted an accumulation of ɣ H2AX indicating replication stress and/or DNA MV4-11 and HEL cells (Figure 2A). We could confirm [26] that LBH589 attenuates th HDAC6 in leukemic cells. Moreover, LBH589 as well as marbostat-100 effectively i which is evident as accumulation of acetylated tubulin [26,28,29]. Congruent wit marbostat-100 did not evoke the activation of caspase-3 or the processing of β-catenin To exclude that the processing of β-catenin in response to HDACi is an artifac leukemic cell cultures, we incubated the LTC FFM12 with LBH589. As in perma LBH589 led to a cleavage of β-catenin and PARP1 ( Figure 2B).
Next, we compared the β-catenin levels of MV4-11 and HEL cells with the β-c normal PBMCs. We included colorectal cancer cells with wild-type (RKO cells) or m (HCT116 cells) for comparison. We found a similar expression of β-catenin in PBM and MV4-11 cells. HCT116 cells showed the expected [56] overexpression of mutant β-2C). These data suggest that β-catenin is wild-type in MV4-11 and HEL cells.
We noted the occurrence of β-catenin cleavage products in cells with a high apoptosis executioner enzyme caspase-3 (Figure 2A), which can cleave β-catenin [16 we speculated that caspases process β-catenin in AML cells exposed to pro-apo LBH589. We tested this hypothesis with the pan-caspase inhibitor z-VAD-FMK. Incu cells with LBH589 and z-VAD-FMK prevented the occurrence of β-catenin cleavag restored the levels of full-length β-catenin ( Figure 2D). We observed similar data f FK228 and the efficiency of z-VAD-FMK was proven as abrogated activation of casp PARP1 (Supplementary Figure S3).
To complement these analyses, we tested for putative alterations of the e phosphorylation-dependent activation of GSK3β, which promotes the proteasomal de catenin [15]. We noted that HDACi do not alter total and phosphorylated GSK3β FFM12 cells ( Figure 2B,D).
LBH589, MS-275, and FK228 increased the levels of ɣH2AX and promoted apop cells ( H2AX is linked to DNA damage or a consequence of DNA fragmentation by apoptosis [57,58], we incubated MV4-11 cells with 1 µM RGFP966. We chose this dose as it does not evoke significant DNA fragmentation ( Figure 4A) and stained cells for 53BP1 foci by immunofluorescence. We chose this marker by virtue of its ability to stain DNA breaks within foci [67]. We could readily detect 53BP1 foci formation associated with 53BP1 nuclear translocation in RGFP966-treated MV4-11 cells (Figure 4E), indicating DNA damage.
Due to the accumulation of Cancers 2019, 11, x 5 of 20 0.01; *** p ≤ 0.001; **** p ≤ 0.0001). (C) Cells were treated with 10 nM or 30 nM LBH589 for 24 h. Indicated proteins were detected via Western blot (cl., cleaved; fl., full-length) with HSP90 and β-actin as loading controls (n = 3). Please note that compared to HEL cells MV4-11 cells have far less fulllength PARP1 and that the lot of the anti-PARP1 antibody may have preferentially recognized the cleaved form of PARP1. (D) Regrowth of the human leukemia cell lines MV4-11 and HEL. Cells were treated with 10 nM or 30 nM LBH589 for 24 h. Thereafter, cells were washed twice with PBS and reseeded. Cells were stained with trypan blue and viable cells were counted after 4 days (n = 3; mean + SD; one-way ANOVA; **** p ≤ 0.0001).

Reduction of β-Catenin upon Class I HDAC Inhibition
Since β-catenin is relevant for the growth and survival of leukemic cells [3][4][5][6][7][8][9], we tested whether LBH589 alters the expression of this protein in leukemic cells. Western blot analyses of MV4-11 and HEL cells revealed that β-catenin was significantly degraded after incubation with LBH589. This led to the advent of an additional band that was revealed by the β-catenin antibody (Figure 2A). The βcatenin mRNA levels were not decreased by LBH589 (data not shown).
To exclude that the processing of β-catenin in response to HDACi is an artifact of permanent leukemic cell cultures, we incubated the LTC FFM12 with LBH589. As in permanent cell lines, LBH589 led to a cleavage of β-catenin and PARP1 ( Figure 2B).
Next, we compared the β-catenin levels of MV4-11 and HEL cells with the β-catenin levels in normal PBMCs. We included colorectal cancer cells with wild-type (RKO cells) or mutant β-catenin (HCT116 cells) for comparison. We found a similar expression of β-catenin in PBMCs, RKO, HEL, and MV4-11 cells. HCT116 cells showed the expected [56] overexpression of mutant β-catenin ( Figure  2C). These data suggest that β-catenin is wild-type in MV4-11 and HEL cells.
We noted the occurrence of β-catenin cleavage products in cells with a high activity of the apoptosis executioner enzyme caspase-3 (Figure 2A), which can cleave β-catenin [16,17]. Therefore, we speculated that caspases process β-catenin in AML cells exposed to pro-apoptotic doses of LBH589. We tested this hypothesis with the pan-caspase inhibitor z-VAD-FMK. Incubation of AML cells with LBH589 and z-VAD-FMK prevented the occurrence of β-catenin cleavage products and restored the levels of full-length β-catenin ( Figure 2D). We observed similar data for MS-275 and FK228 and the efficiency of z-VAD-FMK was proven as abrogated activation of caspase-3 and intact PARP1 (Supplementary Figure S3).
To complement these analyses, we tested for putative alterations of the expression and phosphorylation-dependent activation of GSK3β, which promotes the proteasomal degradation of βcatenin [15]. We noted that HDACi do not alter total and phosphorylated GSK3β in MV4-11 and FFM12 cells ( Figure 2B,D).
LBH589, MS-275, and FK228 increased the levels of ɣH2AX and promoted apoptosis of MV4-11 cells (Figure 2A, and Supplementary Figure S3). DNA double strand breaks, which are generated upon DNA fragmentation by caspase-activated DNase, can also induce ɣH2AX [57,58]. Therefore, such an accumulation of ɣH2AX might be a consequence of apoptotic DNA fragmentation. To test this, we incubated MV4-11 cells with HDACi and z-VAD-FMK. We found that this accumulation of ɣH2AX could only be partially abrogated with z-VAD-FMK (Supplementary Figure S3). These data agree with previous reports indicating that HDACs are gatekeepers of genomic integrity [21,28,[59][60][61].
H2AX and 53BP1 foci in response to HDACi (Figure 2A, Figure 4D,E, and Supplementary Figure S3), we asked whether the reduced stability of β-catenin, MYC, and WT1 could also occur upon replication stress/DNA damage. Therefore, we assessed a putative regulation of these proteins by hydroxyurea (HU). We chose this clinically widely used drug, because it is a bona fide inducer of replication stress and DNA damage. Moreover, HU leads to a caspase-dependent processing of WT1 in leukemic cells [29,55]. HU dose-dependently reduced full-length β-catenin and led to the appearance of cleaved β-catenin. Furthermore, HU reduced MYC and caused an accumulation of 5 of 20 0.001; **** p ≤ 0.0001). (C) Cells were treated with 10 nM or 30 nM LBH589 for 24 h. oteins were detected via Western blot (cl., cleaved; fl., full-length) with HSP90 and β-actin ontrols (n = 3). Please note that compared to HEL cells MV4-11 cells have far less full-1 and that the lot of the anti-PARP1 antibody may have preferentially recognized the of PARP1. (D) Regrowth of the human leukemia cell lines MV4-11 and HEL. Cells were 10 nM or 30 nM LBH589 for 24 h. Thereafter, cells were washed twice with PBS and lls were stained with trypan blue and viable cells were counted after 4 days (n = 3; mean ay ANOVA; **** p ≤ 0.0001).

β-Catenin upon Class I HDAC Inhibition
nin is relevant for the growth and survival of leukemic cells [3][4][5][6][7][8][9], we tested whether e expression of this protein in leukemic cells. Western blot analyses of MV4-11 and led that β-catenin was significantly degraded after incubation with LBH589. This led an additional band that was revealed by the β-catenin antibody (Figure 2A). The βlevels were not decreased by LBH589 (data not shown).
blocks class I, II, and IV HDACs [22], we addressed whether class I HDACs and/or t the processing of β-catenin. We inhibited HDAC1-3 with MS-275 [22] and HDAC6 -100 [26]. We noticed that MS-275 caused the cleavage of PARP1 and β-catenin n activation of caspase-3 in both cell lines (Figure 2A). LBH589 and MS-275 also umulation of ɣ H2AX indicating replication stress and/or DNA damage [21] in L cells (Figure 2A). We could confirm [26] that LBH589 attenuates the expression of emic cells. Moreover, LBH589 as well as marbostat-100 effectively inhibit HDAC6, t as accumulation of acetylated tubulin [26,28,29]. Congruent with Figure 1A,B, id not evoke the activation of caspase-3 or the processing of β-catenin (Figure 2A). that the processing of β-catenin in response to HDACi is an artifact of permanent ultures, we incubated the LTC FFM12 with LBH589. As in permanent cell lines, cleavage of β-catenin and PARP1 ( Figure 2B). ompared the β-catenin levels of MV4-11 and HEL cells with the β-catenin levels in We included colorectal cancer cells with wild-type (RKO cells) or mutant β-catenin for comparison. We found a similar expression of β-catenin in PBMCs, RKO, HEL, s. HCT116 cells showed the expected [56] overexpression of mutant β-catenin (Figure suggest that β-catenin is wild-type in MV4-11 and HEL cells. the occurrence of β-catenin cleavage products in cells with a high activity of the tioner enzyme caspase-3 (Figure 2A), which can cleave β-catenin [16,17]. Therefore, that caspases process β-catenin in AML cells exposed to pro-apoptotic doses of ted this hypothesis with the pan-caspase inhibitor z-VAD-FMK. Incubation of AML 89 and z-VAD-FMK prevented the occurrence of β-catenin cleavage products and els of full-length β-catenin ( Figure 2D). We observed similar data for MS-275 and fficiency of z-VAD-FMK was proven as abrogated activation of caspase-3 and intact entary Figure S3). ment these analyses, we tested for putative alterations of the expression and -dependent activation of GSK3β, which promotes the proteasomal degradation of βnoted that HDACi do not alter total and phosphorylated GSK3β in MV4-11 and ure 2B,D). S-275, and FK228 increased the levels of ɣH2AX and promoted apoptosis of MV4-11 , and Supplementary Figure S3). DNA double strand breaks, which are generated mentation by caspase-activated DNase, can also induce ɣH2AX [57,58]. Therefore, lation of ɣH2AX might be a consequence of apoptotic DNA fragmentation. To test ed MV4-11 cells with HDACi and z-VAD-FMK. We found that this accumulation of nly be partially abrogated with z-VAD-FMK (Supplementary Figure S3). These data ious reports indicating that HDACs are gatekeepers of genomic integrity [21,28,59-H2AX without altering the acetylation levels of histone H3 (Supplementary Figure S7).
A loss of proliferation-associated transcription factors as well as replication stress/DNA damage can cause a permanent growth arrest [13,21]. Assessment of regrowth capacities showed that RGFP966 doses that significantly evoked apoptosis also restrained proliferation after drug removal. Moreover, 5 µM RGFP966 were about as effective as 30 nM LBH589 ( Figure 4F).
These data suggest that HDAC3 is necessary for AML cell survival and the maintenance of β-catenin, MYC, WT1, and the prevention of replication stress and DNA damage.
On the one hand, a reduction of MYC led to a reduction of WT1, indicating that MYC promotes the expression of WT1. On the other hand, a reduction of WT1 increased the levels of MYC ( Figure 5A,B). Furthermore, a reduction of WT1 increased the levels of β-catenin, signifying that WT1 negatively regulates both β-catenin and MYC. A knockdown of β-catenin produced no effects on MYC and WT1 ( Figure 5A,B). Flow cytometry assessing PI showed that the reduction of these three proteins up to 48 h did not affect the vitality of MV4-11 cells ( Figure 5B). Hence, the interplay between MYC and WT1 is not a consequence of cell death.
These data illustrate that MYC and WT1 regulate each other and that WT1 reduces β-catenin levels in MV4-11 cells.
MYC and WT1 ( Figure 5A,B). Flow cytometry assessing PI showed that the reduction of these three proteins up to 48 h did not affect the vitality of MV4-11 cells ( Figure 5B). Hence, the interplay between MYC and WT1 is not a consequence of cell death.
These data illustrate that MYC and WT1 regulate each other and that WT1 reduces β-catenin levels in MV4-11 cells.

Discussion
We showed that LBH589 evoked growth arrest and apoptosis in leukemic cells. As this effect was also seen with MS-275, FK228 and RGFP966, we concluded that class I HDACs, and particularly HDAC3, were necessary for the survival of leukemic cells. The compromised survival of HDACiexposed leukemic cells is associated with an accumulation of the replication stress/DNA damage marker ɣH2AX and with the formation of 53BP1 foci. 1 µM RGFP966 evokes replication stress/DNA damage without massive apoptotic DNA damage and z-VAD-FMK cannot abrogate ɣH2AX accumulation in HDACi-treated leukemic cells. From these data we deduced that HDACi-induced replication stress/DNA damage precedes apoptotic DNA fragmentation, which can also trigger the formation of ɣH2AX [57,58]. Others also report that a pharmacological interference with HDAC3 triggers replication stress, DNA damage, cell death, and enhanced chemosensitivity of lymphocytic and myeloid leukemia cells [59,60,63,65,69]. Such data are consistent with the reported impaired DNA repair capacities of HDACi-treated leukemic cells [21,28,[59][60][61]63,64,70].

Discussion
We showed that LBH589 evoked growth arrest and apoptosis in leukemic cells. As this effect was also seen with MS-275, FK228 and RGFP966, we concluded that class I HDACs, and particularly HDAC3, were necessary for the survival of leukemic cells. The compromised survival of HDACi-exposed leukemic cells is associated with an accumulation of the replication stress/DNA damage marker

β-Catenin upon Class I HDAC Inhibition
nin is relevant for the growth and survival of leukemic cells [3][4][5][6][7][8][9], we tested whether e expression of this protein in leukemic cells. Western blot analyses of MV4-11 and led that β-catenin was significantly degraded after incubation with LBH589. This led an additional band that was revealed by the β-catenin antibody (Figure 2A). The βlevels were not decreased by LBH589 (data not shown).
blocks class I, II, and IV HDACs [22], we addressed whether class I HDACs and/or t the processing of β-catenin. We inhibited HDAC1-3 with MS-275 [22] and HDAC6 -100 [26]. We noticed that MS-275 caused the cleavage of PARP1 and β-catenin n activation of caspase-3 in both cell lines (Figure 2A). LBH589 and MS-275 also umulation of ɣ H2AX indicating replication stress and/or DNA damage [21] in L cells (Figure 2A). We could confirm [26] that LBH589 attenuates the expression of emic cells. Moreover, LBH589 as well as marbostat-100 effectively inhibit HDAC6, t as accumulation of acetylated tubulin [26,28,29]. Congruent with Figure 1A,B, id not evoke the activation of caspase-3 or the processing of β-catenin (Figure 2A). that the processing of β-catenin in response to HDACi is an artifact of permanent ultures, we incubated the LTC FFM12 with LBH589. As in permanent cell lines, cleavage of β-catenin and PARP1 ( Figure 2B). ompared the β-catenin levels of MV4-11 and HEL cells with the β-catenin levels in We included colorectal cancer cells with wild-type (RKO cells) or mutant β-catenin for comparison. We found a similar expression of β-catenin in PBMCs, RKO, HEL, s. HCT116 cells showed the expected [56] overexpression of mutant β-catenin (Figure suggest that β-catenin is wild-type in MV4-11 and HEL cells. the occurrence of β-catenin cleavage products in cells with a high activity of the tioner enzyme caspase-3 (Figure 2A), which can cleave β-catenin [16,17]. Therefore, that caspases process β-catenin in AML cells exposed to pro-apoptotic doses of ted this hypothesis with the pan-caspase inhibitor z-VAD-FMK. Incubation of AML 89 and z-VAD-FMK prevented the occurrence of β-catenin cleavage products and els of full-length β-catenin ( Figure 2D). We observed similar data for MS-275 and

Reduction of β-Catenin upon Class I HDAC Inhibition
Since β-catenin is relevant for the growth and survival of leukemic ce LBH589 alters the expression of this protein in leukemic cells. Western b HEL cells revealed that β-catenin was significantly degraded after incuba to the advent of an additional band that was revealed by the β-catenin a catenin mRNA levels were not decreased by LBH589 (data not shown).
As LBH589 blocks class I, II, and IV HDACs [22], we addressed wh HDAC6 prevent the processing of β-catenin. We inhibited HDAC1-3 wit with marbostat-100 [26]. We noticed that MS-275 caused the cleavag together with an activation of caspase-3 in both cell lines (Figure 2A) promoted an accumulation of ɣ H2AX indicating replication stress a MV4-11 and HEL cells (Figure 2A). We could confirm [26] that LBH589 a HDAC6 in leukemic cells. Moreover, LBH589 as well as marbostat-100 which is evident as accumulation of acetylated tubulin [26,28,29]. Co marbostat-100 did not evoke the activation of caspase-3 or the processing To exclude that the processing of β-catenin in response to HDACi leukemic cell cultures, we incubated the LTC FFM12 with LBH589. A LBH589 led to a cleavage of β-catenin and PARP1 ( Figure 2B).
Next, we compared the β-catenin levels of MV4-11 and HEL cells normal PBMCs. We included colorectal cancer cells with wild-type (RKO (HCT116 cells) for comparison. We found a similar expression of β-cate and MV4-11 cells. HCT116 cells showed the expected [56] overexpression 2C). These data suggest that β-catenin is wild-type in MV4-11 and HEL c We noted the occurrence of β-catenin cleavage products in cells apoptosis executioner enzyme caspase-3 (Figure 2A), which can cleave β we speculated that caspases process β-catenin in AML cells exposed LBH589. We tested this hypothesis with the pan-caspase inhibitor z-VAD cells with LBH589 and z-VAD-FMK prevented the occurrence of β-cate H2AX accumulation in HDACi-treated leukemic cells. From these data we deduced that HDACi-induced replication stress/DNA damage precedes apoptotic DNA fragmentation, which can also trigger the formation of

β-Catenin upon Class I HDAC Inhibition
nin is relevant for the growth and survival of leukemic cells [3][4][5][6][7][8][9], we tested whether e expression of this protein in leukemic cells. Western blot analyses of MV4-11 and led that β-catenin was significantly degraded after incubation with LBH589. This led an additional band that was revealed by the β-catenin antibody (Figure 2A). The βlevels were not decreased by LBH589 (data not shown).
As HDAC3 has functions that are dependent and independent of its catalytic activity [71] it is important that RGFP966 phenocopies a genetic depletion of HDAC3 in transformed hematopoietic cells [65]. Since up to 15 µM RGFP966 specifically inhibits HDAC3 [66], our experimental settings with 1-10 µM RGFP966 likely revealed specific functions of HDAC3 activity. Hence, targeting HDAC3 seems to be a promising strategy to decrease β-catenin, MYC, and WT1, and to eliminate leukemic cells through replication stress/DNA damage and apoptosis. Our flow cytometry data demonstrated that RGFP966 decreased the numbers of cells in the G1 and G2/M phases dependent on caspases. The S phase populations were not rescued though when z-VAD-FMK was applied with RGFP966. This also applied to the accumulation of Since β-catenin is relevant for the growth and survival of leukemic cells [3][4][5][6][7][8][9], we tested whether LBH589 alters the expression of this protein in leukemic cells. Western blot analyses of MV4-11 and HEL cells revealed that β-catenin was significantly degraded after incubation with LBH589. This led to the advent of an additional band that was revealed by the β-catenin antibody (Figure 2A). The βcatenin mRNA levels were not decreased by LBH589 (data not shown).
To exclude that the processing of β-catenin in response to HDACi is an artifact of permanent leukemic cell cultures, we incubated the LTC FFM12 with LBH589. As in permanent cell lines, LBH589 led to a cleavage of β-catenin and PARP1 ( Figure 2B).
Next, we compared the β-catenin levels of MV4-11 and HEL cells with the β-catenin levels in normal PBMCs. We included colorectal cancer cells with wild-type (RKO cells) or mutant β-catenin (HCT116 cells) for comparison. We found a similar expression of β-catenin in PBMCs, RKO, HEL, and MV4-11 cells. HCT116 cells showed the expected [56] overexpression of mutant β-catenin ( Figure  2C). These data suggest that β-catenin is wild-type in MV4-11 and HEL cells.
We noted the occurrence of β-catenin cleavage products in cells with a high activity of the apoptosis executioner enzyme caspase-3 (Figure 2A), which can cleave β-catenin [16,17]. Therefore, we speculated that caspases process β-catenin in AML cells exposed to pro-apoptotic doses of LBH589. We tested this hypothesis with the pan-caspase inhibitor z-VAD-FMK. Incubation of AML cells with LBH589 and z-VAD-FMK prevented the occurrence of β-catenin cleavage products and restored the levels of full-length β-catenin ( Figure 2D). We observed similar data for MS-275 and FK228 and the efficiency of z-VAD-FMK was proven as abrogated activation of caspase-3 and intact PARP1 (Supplementary Figure S3).
To complement these analyses, we tested for putative alterations of the expression and phosphorylation-dependent activation of GSK3β, which promotes the proteasomal degradation of βcatenin [15]. We noted that HDACi do not alter total and phosphorylated GSK3β in MV4-11 and FFM12 cells ( Figure 2B,D).
LBH589, MS-275, and FK228 increased the levels of ɣH2AX and promoted apoptosis of MV4-11 cells (Figure 2A, and Supplementary Figure S3). DNA double strand breaks, which are generated upon DNA fragmentation by caspase-activated DNase, can also induce ɣH2AX [57,58]. Therefore, such an accumulation of ɣH2AX might be a consequence of apoptotic DNA fragmentation. To test this, we incubated MV4-11 cells with HDACi and z-VAD-FMK. We found that this accumulation of ɣH2AX could only be partially abrogated with z-VAD-FMK (Supplementary Figure S3). These data agree with previous reports indicating that HDACs are gatekeepers of genomic integrity [21,28,[59][60][61].
H2AX, which was largely unaffected by z-VAD-FMK. Therefore, we concluded that S phase stalling and replication stress/DNA damage induction by RGFP966 was due to a genuine induction of replication stress/DNA damage that halted cell cycle progression. Further studies are underway to determine the targets of HDAC3 that control cellular responses to replication stress and DNA damage and whether cells slip from G2/M phase to G1 phase or die out of G2/M phase through mitotic catastrophe.
We further show that the extent of β-catenin processing by caspases tied in with a failure of leukemic cells to recover from HDACi-induced stress. Accordingly, a destabilization of β-catenin with indomethacin combined superiorly with HDACi. This finding could be due to the destabilization of β-catenin by both HDACi and NSAIDs, but NSAIDs exert multiple effects [35,62,72,73]. However, while several NSAIDs repress transcription factors of the NF-κB family, which can be a driver of tumorigenesis in hematopoietic and solid tumor cells, indomethacin does not inactivate NF-κB, AP1, and cancer-relevant kinases. Nonetheless, indomethacin activates PPAR Cancers 2019, 11, x 0.01; *** p ≤ 0.001; **** p ≤ 0.0001). (C) Cells were treated with 10 nM or 30 nM LBH Indicated proteins were detected via Western blot (cl., cleaved; fl., full-length) with HSP9 as loading controls (n = 3). Please note that compared to HEL cells MV4-11 cells have length PARP1 and that the lot of the anti-PARP1 antibody may have preferentially re cleaved form of PARP1. (D) Regrowth of the human leukemia cell lines MV4-11 and HE treated with 10 nM or 30 nM LBH589 for 24 h. Thereafter, cells were washed twice w reseeded. Cells were stained with trypan blue and viable cells were counted after 4 days + SD; one-way ANOVA; **** p ≤ 0.0001).

Reduction of β-Catenin upon Class I HDAC Inhibition
Since β-catenin is relevant for the growth and survival of leukemic cells [3][4][5][6][7][8][9], w LBH589 alters the expression of this protein in leukemic cells. Western blot analyse HEL cells revealed that β-catenin was significantly degraded after incubation with L to the advent of an additional band that was revealed by the β-catenin antibody (Fi catenin mRNA levels were not decreased by LBH589 (data not shown).
As LBH589 blocks class I, II, and IV HDACs [22], we addressed whether class HDAC6 prevent the processing of β-catenin. We inhibited HDAC1-3 with MS-275 [ with marbostat-100 [26]. We noticed that MS-275 caused the cleavage of PARP together with an activation of caspase-3 in both cell lines (Figure 2A). LBH589 a promoted an accumulation of ɣ H2AX indicating replication stress and/or DNA MV4-11 and HEL cells (Figure 2A). We could confirm [26] that LBH589 attenuates t HDAC6 in leukemic cells. Moreover, LBH589 as well as marbostat-100 effectively which is evident as accumulation of acetylated tubulin [26,28,29]. Congruent wi marbostat-100 did not evoke the activation of caspase-3 or the processing of β-caten To exclude that the processing of β-catenin in response to HDACi is an artifa leukemic cell cultures, we incubated the LTC FFM12 with LBH589. As in perm LBH589 led to a cleavage of β-catenin and PARP1 ( Figure 2B).
Next, we compared the β-catenin levels of MV4-11 and HEL cells with the βnormal PBMCs. We included colorectal cancer cells with wild-type (RKO cells) or m (HCT116 cells) for comparison. We found a similar expression of β-catenin in PBM and MV4-11 cells. HCT116 cells showed the expected [56] overexpression of mutant β 2C). These data suggest that β-catenin is wild-type in MV4-11 and HEL cells.
We noted the occurrence of β-catenin cleavage products in cells with a high apoptosis executioner enzyme caspase-3 (Figure 2A), which can cleave β-catenin [1 we speculated that caspases process β-catenin in AML cells exposed to pro-apo LBH589. We tested this hypothesis with the pan-caspase inhibitor z-VAD-FMK. Inc cells with LBH589 and z-VAD-FMK prevented the occurrence of β-catenin cleavag restored the levels of full-length β-catenin ( Figure 2D). We observed similar data FK228 and the efficiency of z-VAD-FMK was proven as abrogated activation of casp PARP1 (Supplementary Figure S3).
To complement these analyses, we tested for putative alterations of the phosphorylation-dependent activation of GSK3β, which promotes the proteasomal d catenin [15]. We noted that HDACi do not alter total and phosphorylated GSK3β FFM12 cells ( Figure 2B,D).
LBH589, MS-275, and FK228 increased the levels of ɣH2AX and promoted apop cells (Figure 2A, and Supplementary Figure S3). DNA double strand breaks, whic upon DNA fragmentation by caspase-activated DNase, can also induce ɣH2AX [5 such an accumulation of ɣH2AX might be a consequence of apoptotic DNA fragm this, we incubated MV4-11 cells with HDACi and z-VAD-FMK. We found that this ɣH2AX could only be partially abrogated with z-VAD-FMK (Supplementary Figure agree with previous reports indicating that HDACs are gatekeepers of genomic int 61]. [74] and an activation of PPAR Cancers 2019, 11, x 0.01; *** p ≤ 0.001; **** p ≤ 0.0001). (C) Cells were t Indicated proteins were detected via Western blot (cl as loading controls (n = 3). Please note that compar length PARP1 and that the lot of the anti-PARP1 a cleaved form of PARP1. (D) Regrowth of the human treated with 10 nM or 30 nM LBH589 for 24 h. Th reseeded. Cells were stained with trypan blue and v + SD; one-way ANOVA; **** p ≤ 0.0001).

Reduction of β-Catenin upon Class I HDAC Inhibiti
Since β-catenin is relevant for the growth and su LBH589 alters the expression of this protein in leuk HEL cells revealed that β-catenin was significantly d to the advent of an additional band that was reveal catenin mRNA levels were not decreased by LBH58 As LBH589 blocks class I, II, and IV HDACs [2 HDAC6 prevent the processing of β-catenin. We inh with marbostat-100 [26]. We noticed that MS-275 together with an activation of caspase-3 in both c promoted an accumulation of ɣ H2AX indicati MV4-11 and HEL cells (Figure 2A). We could confir HDAC6 in leukemic cells. Moreover, LBH589 as w which is evident as accumulation of acetylated tu marbostat-100 did not evoke the activation of caspa To exclude that the processing of β-catenin in leukemic cell cultures, we incubated the LTC FFM LBH589 led to a cleavage of β-catenin and PARP1 (F Next, we compared the β-catenin levels of MV normal PBMCs. We included colorectal cancer cells (HCT116 cells) for comparison. We found a similar and MV4-11 cells. HCT116 cells showed the expected 2C). These data suggest that β-catenin is wild-type i We noted the occurrence of β-catenin cleavag apoptosis executioner enzyme caspase-3 ( Figure 2A we speculated that caspases process β-catenin in LBH589. We tested this hypothesis with the pan-cas cells with LBH589 and z-VAD-FMK prevented the restored the levels of full-length β-catenin ( Figure  FK228 and the efficiency of z-VAD-FMK was prove PARP1 (Supplementary Figure S3).
To complement these analyses, we tested f phosphorylation-dependent activation of GSK3β, w catenin [15]. We noted that HDACi do not alter to FFM12 cells ( Figure 2B,D).
LBH589, MS-275, and FK228 increased the leve cells ( Figure 2A, and Supplementary Figure S3). D upon DNA fragmentation by caspase-activated DN such an accumulation of ɣH2AX might be a conseq this, we incubated MV4-11 cells with HDACi and z ɣH2AX could only be partially abrogated with z-VA agree with previous reports indicating that HDACs 61]. by glitazones can attack the leukemic stem cell pool in CML [75]. Additional investigations are justified to define the beneficial effects of NSAIDs on leukemic cells and their stem cells. This also applies to solid tumor cells form breast, colon, lung, and prostate, for which bifunctional conjugates of indomethacin with SAHA are potent inhibitors of growth and angiogenesis [35,36]. For example, compound 11b, an indomethacin-SAHA fusion molecule that selectively inhibits COX2 and HDAC6 > HDAC8 > HDAC3 > HDAC2 > HDAC1, inhibits the proliferation of androgen-dependent prostate carcinoma cells [35]. Further studies may find a relevance of HDAC8 inhibition by this compound, because this class I HDAC is also a valid target in AML cells [76]. The finding that compound 11b is effective against cancer cells and selective for COX2 is promising because COX1 is a constitutively expressed housekeeping enzyme while COX2 is induced upon inflammation [35]. Independent thereof is the consensus that the anti-tumor effects of NSAIDs are not directly linked to their inhibitory effects on COX1/COX2, but rather on other effects. These include among others the suppression of β-catenin and aberrant WNT signaling [32,33,35,73].
Caspases -3, -6, -7, and -8 catalyze the degradation of β-catenin [16,17] in solid tumor cells and in vitro. Our data collected with z-VAD-FMK suggest that caspases cleave β-catenin in HDACi-treated leukemic cells. Consistent with this idea, we see β-catenin cleavage products with a similar size as the ones seen by others under apoptotic conditions and caspase activation [16,17]. Further experiments are necessary to decipher which caspases or other enzymes process β-catenin in leukemic cells and why only a subset of HDACi-treated leukemic cells cleaves β-catenin.
We demonstrate that MYC and WT1 have an antagonistic relationship, with MYC activating WT1 and WT1 suppressing MYC. We also show a regulation of β-catenin through WT1 in leukemic cells. Data collected with kidney-, solid tumor-, and CML-derived cells coherently show that WT1 can repress the expression of MYC [47,48]. However, the opposite effect of WT1 on MYC has also been reported in such cells [54,77]. Culture conditions as well as a context-dependent regulation may explain such discrepancies. Moreover, different isoforms of WT1 can determine whether it has a role as an oncogene or a tumor suppressor [49]. Our data illustrating an accumulation of β-catenin upon a reduction of WT1 in leukemic cells corresponds to an observed negative impact of WT1 on β-catenin signaling in breast cancer cells [51], Sertoli cells forming the blood-testis barrier [50], and podocytes within the kidney [52]. WT1 also impairs β-catenin/WNT signaling via other pathways in vitro and in vivo [53], but one cannot exclude that there is a cell type-specific interplay between β-catenin and WT1 [54]. It likewise remains to be clarified whether the mutual control of MYC and WT1 has further implications, for example for their antagonistic effects on the cell cycle regulator p21 [78,79]. The concomitant loss of all three transcription factors in HDACi-treated cells demonstrates that an inhibition of HDACs, and particularly of HDAC3, overwrites such regulatory effects and leads to their loss by caspase-dependent and -independent mechanisms. Our data additionally suggest that the reduction of MYC by HDACi may lead to a reduction of WT1 in leukemic cells, but not vice versa.
The elimination of β-catenin does not affect MYC and we see no mutual regulation of β-catenin and MYC in leukemic cells. Accordingly, we found that MYC was decreased in HDACi-treated cells irrespective of whether they retained β-catenin. While this lack of coregulation between β-catenin and MYC is unexpected [11,39,40], others also found that an attenuation of β-catenin by BC2059 did not affect MYC levels in leukemic cells [23]. Moreover, this work shows that a similar reduction of β-catenin by LBH589 or BC2059 leads to either a clear or no reduction of MYC. Hence, LBH589 triggers processes that decrease MYC largely independent of β-catenin. It is also possible that the wild-type or mutant status of β-catenin has an impact on its relevance in cells and onto MYC expression. Our data suggest that β-catenin is wild-type in the leukemic cell lines that we analyzed. This finding agrees with the notion that only a subset of AML cases overexpresses β-catenin [4][5][6]. Moreover, an elimination of β-catenin restricts the proliferation of a limited number of AML cells [11] and variable combination indices resulted from LBH589/BC2059 cotreatment schedules in primary AML cells [23]. Furthermore, a dysregulation of β-catenin in leukemic cells does not always imply their addiction to β-catenin [11]. This also holds true for colon cancer cells with mutant β-catenin [56] and β-catenin does not affect a lethal growth of lymphoma in mice [10]. Likewise, if β-catenin was the only critical factor for leukemic cell growth, indomethacin would be far more useful for leukemia treatment.
Our finding that single elimination of β-catenin, MYC, and WT1 does not kill MV4-11 cells may equally hint that HDACi trigger complex apoptosis cascades that cannot be mimicked by a depletion of one stemness-associated transcription factor. Furthermore, a remaining expression of β-catenin, MYC, and WT1 may have ensured the survival of the investigated cells. Maybe a combined inhibition and a more prolonged reduction of these factors halts cell proliferation. Such an idea is supported by the finding that a CRISPR-Cas9-based deletion of β-catenin requires over 10 days to eliminate HEL cells [39]. Since β-catenin cleavage products exert biologically important functions [16], it is equally plausible that RNAi-mediated depletion cannot mimic the effect of HDACi-induced processing of β-catenin in response to a treatment with HDACi. Moreover, other HDACi-triggered mechanisms, including replication stress and DNA damage [21], may be more relevant inducers of cell death. This idea agrees with the finding that HU also triggers the processing of β-catenin.
Remarkably, MYC is of predictive value for therapy success of AML patients who are treated with HDACi [19] and we show that MYC is a target of RGFP966. Whether RGFP966 is useful in the clinic remains to be resolved. In rodents, repetitive applications of RGFP966 were safe and produced beneficial effects without toxicity to normal tissues [65,66,80]. Our data illustrate that a reduction of MYC, irrespective of whether β-catenin is cleaved or not, is a good marker for apoptosis induction by HDACi. In addition to the HDAC1/HDAC2-dependent transcriptional regulation of MYC in pancreatic carcinoma cells [81], our data collected with RGFP966 suggest that HDAC3 supports the expression of MYC in leukemic cells. Consistent with these data, others found that HDAC3 is necessary for the growth of MYC-driven lymphoma [65]. Nonetheless, we cannot rule out that HDAC1 and HDAC2 maintain the expression of β-catenin, MYC, and WT1 in leukemic cells. Moreover, faster migrating products of MYC in LBH589-treated HL60 AML cells suggest a possible proteolysis of MYC [23]. Irrespective thereof, the data that we collected with z-VAD-FMK suggest that HDACi decrease MYC independent of caspase activation.
Regarding WT1, HDACi trigger a loss of the WT1 protein through an induction of the E2 ubiquitin conjugase UBCH8 and a shutdown of the WT1 promoter [46]. As recent data demonstrate caspase-dependent processing of WT1 upon replication stress and DNA damage in leukemic cells [55,82], caspases may as well degrade WT1 upon an inhibition of class I HDACs in leukemic cells. The details on how HDACi alter the expression, stability, acetylation, and other posttranslational modifications of β-catenin, MYC, and WT1 as well as the physiological consequences thereof should be analyzed in future research.
Taken together, our results show that a loss of β-catenin, MYC, and WT1 are molecular markers for beneficial effects of HDACi. The data also suggest combining class I HDACi with indomethacin against leukemic cells.

Real-Time PCR-TaqMan (qRT-PCR)
Total RNA and first strand DNA were obtained according to standard protocols. TaqMan-PCR was performed in triplicate using ABI PRISM 7700 (Applied Biosystems, Darmstadt, Germany). "Assays-on-demand" for β-catenin transcripts were used according to the manufacturer's instructions (Assay-ID: beta-Catenin-Hs01076483_m1; Applied Biosystems, Darmstadt, Germany). Sequence detector software SDS 2.0 (Applied Biosystems, Carlsbad, USA) was used for data analysis. CT values were exported into excel worksheets for calculation of fold changes using the comparative CT method. The internal reference gene was GUS, oligonucleotides ENF1102 (GAAAATATGTGGTTGGAGAGCTCATT) and ENR1162 (CCGAGTGAAGATCCCCTTTTTA), and probe ENPR1142 (Fam-CCAGCACTCGTCGGT GACTGTTCA-Tamra).

Conclusions
In conclusion, we demonstrated that low doses of LBH589, MS-275, FK228, and RGFP966 induced apoptosis, replication stress/DNA damage, and a lasting growth arrest of AML cells. Thus, inhibition of HDAC3 seems to be sufficient to compromise the genomic integrity and the survival of such cells. A loss of the transcription factors β-catenin, MYC, and WT1 marks the efficacy of HDACi. HDAC3 activity is a key factor for the maintenance of the expression of these tumor-and stemness-associated transcription factors in AML cells. RNAi-based loss-of-function approaches illustrate a previously unidentified cross-regulation between β-catenin, MYC, and WT1 in leukemic cells. Furthermore, our study suggests that the frequently used non-steroidal anti-inflammatory drug indomethacin potentiates long-lasting anti-proliferative effects of HDACi.

Reduction of β-Catenin upon Class I HDAC Inhibition
Since β-catenin is relevant for the growth and survival of leukemic cells [3][4][5][6][7][8][9], we teste LBH589 alters the expression of this protein in leukemic cells. Western blot analyses of M HEL cells revealed that β-catenin was significantly degraded after incubation with LBH589 to the advent of an additional band that was revealed by the β-catenin antibody (Figure 2 catenin mRNA levels were not decreased by LBH589 (data not shown).
As LBH589 blocks class I, II, and IV HDACs [22], we addressed whether class I HDA HDAC6 prevent the processing of β-catenin. We inhibited HDAC1-3 with MS-275 [22] an with marbostat-100 [26]. We noticed that MS-275 caused the cleavage of PARP1 and together with an activation of caspase-3 in both cell lines (Figure 2A). LBH589 and M promoted an accumulation of ɣ H2AX indicating replication stress and/or DNA dama MV4-11 and HEL cells (Figure 2A). We could confirm [26] that LBH589 attenuates the exp HDAC6 in leukemic cells. Moreover, LBH589 as well as marbostat-100 effectively inhibi which is evident as accumulation of acetylated tubulin [26,28,29]. Congruent with Fig  marbostat-100 did not evoke the activation of caspase-3 or the processing of β-catenin (Fig To exclude that the processing of β-catenin in response to HDACi is an artifact of p leukemic cell cultures, we incubated the LTC FFM12 with LBH589. As in permanent LBH589 led to a cleavage of β-catenin and PARP1 ( Figure 2B).
Next, we compared the β-catenin levels of MV4-11 and HEL cells with the β-catenin normal PBMCs. We included colorectal cancer cells with wild-type (RKO cells) or mutant (HCT116 cells) for comparison. We found a similar expression of β-catenin in PBMCs, R and MV4-11 cells. HCT116 cells showed the expected [56] overexpression of mutant β-caten H2AX, Figure S4: Flow cytometry assessing effects of LBH589 on KG1 cells, Figure S5: LBH589 is effective in FFM12 cells, Figure S6: Examples of dot plots collected by flow cytometry of RGFP966-treated MV4-11 cells, Figure S7: HU decreases β-catenin and MYC, Figure S8: Full scans of Western blot data.