PI3K/AKT/mTOR Signaling Is a Significant Druggable Pathway In Infant Acute Lymphoblastic Leukemia (ALL)

Abstract Introduction Infant acute lymphoblastic leukemia (ALL) is an orphan disease with unmet need for safe effective therapies. This is an urgent problem because conventional chemotherapies are ineffective and have life-threatening toxicities in infants. Although the MLL rearrangements occurring in 75% of cases are associated with poor outcome, survival is inferior whether MLL is rearranged or not. We recently reported that infant ALL proved sensitive to obatoclax mesylate (GeminX Pharmaceuticals; now an indirect, wholly owned subsidiary of Teva Pharmaceutical Industries Ltd.) in vitro regardless of poor prognostic features including MLL gene rearrangement. Moreover, we showed that the leukemia cell killing by obatoclax involved apoptosis, necroptosis and autophagy (Urtishak et al., Blood 2013). Therefore, the recent pharmaceutical abandonment of obatoclax led us to search for similarly acting drugs, the Results of which identified the well-known antipsychotic thioridazine as a candidate for potential repurposing. Methods Correlative analyses were performed between basal gene expression profiles at leukemia diagnosis and single agent obatoclax EC50 values from MTT assays in 47 cases of infant ALL from the Children's Oncology Group P9407 trial (25 MLL-AF4; 8 MLL-ENL; 7 other MLL-rearranged; 7 MLL-germline) in order to find a priori determinants of obatoclax sensitivity; significant genes were further studied by Ingenuity Pathway Analysis (IPA). A search for similarly acting compounds was conducted by Connectivity Map analysis of gene expression profiles of MLL-AF4 ALL cell lines after obatoclax treatment. MTT assays without and with cell death pathway inhibition, Western blot and flow cytometric cell death assays, and phosphoflow cytometric signaling analyses were utilized to investigate activity and target modulation by potential candidates. Results IPA identified significant correlations between basal gene expression of the mTOR and downstream intersecting eIF4/p70S6K signaling programs and obatoclax EC50 in all 47 primary cases of infant ALL, as well as in the subset of the 25 cases with MLL-AF4 rearrangements. Consistent with the relevance of this pathway in leukemia cell killing that was suggested by the basal gene expression profiles in the primary cases, the Connectivity Map analysis of obatoclax-treated cell lines for compound matching returned a number of highly ranked PI3K/AKT/mTOR signal transduction inhibitors as potential obatoclax substitutes. Three of the compounds (LY294002, wortmannin, thioridazine) were not only cytotoxic in MLL-AF4 ALL cell lines, but also they abrogated PI3K/AKT/mTOR signaling as indicated by robust inhibition of phosphorylated S6. Of these compounds, the phenothiazine derivative thioridazine, which has been used clinically for decades as a neuroleptic, was of high interest because of potential advantages of drug repurposing for more rapid drug advancement. Moreover, detailed flow cytometric and Western blot analyses, and MTT assays of thioridazine in the presence of cell death pathway inhibitors validated activation of all three cell death mechanisms in the MLL-AF4 ALL cell lines similarly to obatoclax. Conclusions Thioridazine is a well-known antipsychotic drug that also has recently recognized properties as a PI3K/AKT/mTOR signaling inhibitor and as an inhibitor of other pathways relevant to cancer. In MLL-AF4 ALL cell lines characterized by the most common chromosomal translocation in infant ALL, single-agent thioridazine is highly cytotoxic, robustly inhibits PI3K/AKT/mTOR signaling and, moreover, like obatoclax, demonstrates activity as a multi-cell-death pathway agonist. Further preclinical studies now are warranted to determine the extent to which thioridazine inhibits PI3K/AKT/mTOR signaling and causes leukemia cell killing in primary infant ALL cells in vitro and in vivo. The repurposing strategy that this drug may allow could have promise to streamline drug development in infant ALL where the need for new therapies is so urgent. Disclosures: No relevant conflicts of interest to declare.

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Differential gene expression profiles of human leukemia cell lines exposed to benzene and its metabolites

Environmental Toxicology and Pharmacology ◽

10.1016/j.etap.2011.06.001 ◽

2011 ◽

Vol 32 (2) ◽

pp. 285-295 ◽

Cited By ~ 10

Author(s):

Sailendra Nath Sarma ◽

Youn-Jung Kim ◽

Jae-Chun Ryu

Keyword(s):

Gene Expression ◽

Differential Gene Expression ◽

Cell Lines ◽

Expression Profiles ◽

Leukemia Cell ◽

Gene Expression Profiles ◽

Human Leukemia ◽

Human Leukemia Cell ◽

Leukemia Cell Lines ◽

Differential Gene

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Novel Synthetic Histone Deacetylase Inhibitor, SK-7041, Has Potent Anti-Proliferative Activity in Acute Myeloid Leukemia Cell Lines.

Blood ◽

10.1182/blood.v110.11.2854.2854 ◽

2007 ◽

Vol 110 (11) ◽

pp. 2854-2854

Author(s):

Sung-Soo Yoon ◽

Eunkyung Bae ◽

Juwon Park ◽

Yongjun Cha ◽

Young Y. Lee ◽

...

Keyword(s):

Gene Expression ◽

Histone Deacetylase ◽

Cell Lines ◽

Histone Deacetylase Inhibitors ◽

Expression Profiles ◽

Leukemia Cell ◽

Gene Expression Profiles ◽

Myelogenous Leukemia ◽

G1 Arrest ◽

Cancer Cell Growth

Abstract Histone acetyltransferase (HAT) and histone deacetylase (HDAC) activities determine the acetylation status of histones, which regulates gene expression through chromatin remodeling. Aberrant histone acetylation is known to play a key role in leukemogenesis. Thus, histone deacetylase inhibitors (HDACIs) are emerging as a new class of anti-cancer agents for leukemia. In this study, we examined anti-proliferative effects of novel hybrid synthetic HDACI, SK-7041, in various acute myelogenous leukemia (AML) cell lines (KG-1, HL-60, HEL, U937, ML-1). SK-7041 induced the time-dependent hyperacetylation of histones H3 and H4 in AML cell lines. It preferentially inhibited the enzymatic activities of HDAC1 and HDAC2, as compared with the other HDAC isotypes, indicating that class I HDAC is the major target of SK-7041. All the cell lines tested showed similar patterns of growth inhibition by SK-7041. Their IC50 values were approximately 0.5 mM at 72 hours incubation. SK-7041 effectively induced the apoptosis via activation of caspase-3, -7, -9, and PARP, but not caspase-8. SK-7041 enhanced G1 arrest via decreasing Cyclin D1 expression and increasing p21 expression. Changes in gene expression profiles after treating KG-1 cells with various concentrations of SK-7041 were assessed using a cDNA microarray consisting of distinct cDNAs of cancer-related genes. 7 genes, namely RGL1, FYN, CARD9, ABCA7, TNFRSF6B, CASP9, and ENPP2 were induced substantially (Global M >2.0) and 8 genes, namely PTPN7, CD34, INSIG1, IL16, LHX6, TRIB3, BID, and PDCD4 were reduced substantially (Global M < 2.0). In conclusion, this study showed SK-7041 inhibited cancer cell growth and caused characteristic gene expression profile changes in AML cells. The alteration in levels of acetylated histones was closely associated with expression of specific cancer-related genes in AML cells.

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Pan-Anti-Apoptotic BCL-2 Family Inhibitor, Obatoclax, Activates Autophagic Cell Death Pathway and Has Potent Cytotoxicity in Infant and Pediatric MLL-Rearranged Leukemias

Blood ◽

10.1182/blood.v112.11.2647.2647 ◽

2008 ◽

Vol 112 (11) ◽

pp. 2647-2647

Author(s):

Alena Y. Zhang ◽

Blaine W. Robinson ◽

Li-San Wang ◽

Kajia Kao ◽

Lori Cory ◽

...

Keyword(s):

Gene Expression ◽

Cell Death ◽

Cell Lines ◽

Family Members ◽

Rt Pcr ◽

Basal Expression ◽

Cell Death Pathway ◽

Vehicle Treatment ◽

Change In Mean ◽

Mtt Assays

Abstract Cell death pathways are desired targets of small molecule inhibitors since their deregulation plays an important role in chemotherapy resistance. Obatoclax binds to the BH3 pocket of anti-apoptotic BCL-2 family proteins, inhibiting their interactions with pro-apoptotic BCL-2 family members. Before we found potent obatoclax activity in MLL/AF4+ cell lines and 6 MLL rearranged (MLL+) leukemias. In apoptosis assays of the cell lines obatoclax increases TUNEL staining but minimally activates caspase 3 (Rege ASH 2005; Zhang AACR 2007). In this study, we tested the cytotoxicity of obatoclax in additional MLL+ leukemias and investigated its mechanism of action with a focus on autophagy (ATG), since ATG proteins such as beclin 1 also interact with anti-apoptotic BCL-2 family members. Methods: MLL partner genes were determined by molecular/cytogenetic methods. 17 primary MLL+ leukemias including the original 6 (12 ALL/11 infants, 1 child; 3 AML/1 each infant, child, adolescent; 2 bilineal/2 infants) were tested in MTT assays after 72 h obatoclax exposures. MTT assays on cytotoxic drug-obatoclax combinations were performed in a primary MLL/AF4+ ALL and interactions were studied by response surface modeling. MCL-1/BAK complex inhibition was tested in this ALL by co-IP/immunoblot analysis. Cell death and ATG were studied in obatoclax treated RS4:11 and/or SEM-K2 cells by PI flow, LC3 and p62 Western blot analysis and EM, using doxorubicin as a control for apoptosis. Gene expression changes after vehicle treatment vs. obatoclax treatment at the IC50 and IC90 for 6 h were studied using Affymetrix HG_U133 Plus2.0 arrays. Differentially expressed genes overall and those specifically associated with ATG were queried by ANOVA (p<0.01, ≥50% change in mean expression considered as significant). Q-RT PCR analysis of basal expression levels of select ATG genes (BECN1, WIPI1, MAP1LC3B) was performed in 10 of the 17 primary cases and correlations with the IC50 values were determined using Pearson correlation coefficients and their levels of significance. Changes in the expression patterns of these genes after vehicle treatment vs. treatment with obatoclax at the IC50 for 6 h and 48 h were compared in 6 cases by Q-RT PCR and cluster analysis. Results: MLL partner genes were AF4, ENL and other in 6, 5 and 1 ALL, respectively; AF9 in 2 and AF6 in 1 AML; and AF4 and ENL in 1 each bilineal leukemia. The single agent IC50’s of obatoclax suggested greater sensitivity in ALL (13–834 nM; median 104 nM) than AML (243–488nM; median 341 nM), and were 79 nM and 508 nM in the bilineal leukemias. In addition to synergy with ARAC, ADR, VP16 and DEX (Zhang AACR 2007) there was synergy with LASP and VCR in the primary MLL/AF4+ ALL. In the same ALL obatoclax decreased MCL-1/BAK dimers, suggesting interaction with the MCL-1 target, and obatoclax increased high molecular weight MCL-1/BAK complexes and decreased MCL-1, the latter of which would also decrease MCL-1/BAK dimers. Obatoclax treatment of RS4:11 and SEM-K2 cells increased PI staining and LC-3I to LC-3II conversion; EM analysis of SEM-K2 cells revealed phagophores, autophagosomes and autophagolysosomes indicative of ATG induction. Lack of p62 accumulation showed that ATG was not blocked. EM findings of apoptosis occurred in SEM-K2 cells after doxorubicin exposure. ATG was not the most affected pathway in microarray analyses of obatoclax treated SEM-K2 and RS4:11 cells, but specific analysis of ATG-related genes showed WIPI1 and MAP1LC3B upregulation. Moreover, the basal expression of BECN1 was positively correlated with obatoclax activity in the 10 primary cases (r =0.659; p=0.038), which is consistent with importance of this pathway in the drug response. ATG gene expression analysis in obatoclax treated primary MLL+ cases identified 2 patient clusters; in one cluster obatoclax decreased BECN1 and increased WIPI1 expression; in the other ATG gene expression changes were more variable. Conclusions: Obatoclax induces cell death in MLL+ leukemias via the ATG pathway even though they are apoptosis competent. This is distinct from the apoptosis activation in other cancer cell types and indicates that the targets of obatoclax are disease-specific. The activity in a broad spectrum of MLL+ leukemias indicates that obatoclax is a promising molecularly targeted agent for this population.

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A Multi-Center and Multi-National Program To Assess the Clinical Accuracy of the Molecular Subclassification of Leukemia by Gene Expression Profiling.

Blood ◽

10.1182/blood.v106.11.757.757 ◽

2005 ◽

Vol 106 (11) ◽

pp. 757-757 ◽

Cited By ~ 5

Author(s):

Torsten Haferlach ◽

Alexander Kohlmann ◽

Guiseppe Basso ◽

Marie-Christine Bene ◽

James R. Downing ◽

...

Keyword(s):

Gene Expression ◽

Cell Lines ◽

Research Study ◽

Expression Profiles ◽

Blast Crisis ◽

Leukemia Cell ◽

Gene Expression Profiles ◽

Chronic Phase ◽

High Reproducibility ◽

Clinical Accuracy

Abstract Microarray analysis can identify differentially expressed genes associated with distinct clinical and therapeutically relevant classes of both pediatric and adult leukemias. Recently, the MILE (Microarray Innovations in Leukemia) research study program has been launched in 10 centers: 7 from the European Leukemia Network (ELN, WP13) and 3 from the US. In this study, which will include 4,000 patients, the clinical accuracy of gene expression profiles of 16 acute and chronic leukemia subclasses, MDS, and non-leukemia as control will be assessed as compared to current routine diagnostic workup. Each center is trained on an identical microarray protocol and uses the same laboratory equipment, kits, and reagents for target preparation (Affymetrix HG-U133 Plus 2.0). First, the intra- and inter-laboratory comparability was investigated using 2 different cell line samples, MCF-7 and HEPG2, with different amounts of starting material (1 μg and 5 μg input for cDNA synthesis). Also, each center prepared in parallel total RNA and processed replicate samples from three leukemia pts (AML with t(8;21), CML, and CLL). We found a high reproducibility among the different centers: unsupervised analyses accordingly group the two different cell lines distinct from the three types of leukemia samples. In hierarchical clustering and principal component analysis the non-leukemia samples are clearly distinct from the leukemia samples and no clustering of the individual centers can be seen. Remarkably, for the replicates of the leukemia samples the squared correlation coefficients of gene expression range between 0.975 and 0.997 for CML, between 0.975 and 0.998 for CLL, and between 0.970 and 0.999 for the AML with t(8;21). Secondly, the samples were analyzed by a classification algorithm. The algorithm was trained on a database that contains gene expression profiles of >1,600 leukemia patients and cell lines and can distinguish 16 different classes of leukemia, MDS, and non-leukemia. Several methods are used to form linear classifiers for all 18 * (18 – 1)/2 = 153 class pairs. The average cross-validation accuracy is 91% or higher. Miscalls are predominantly seen in the distinction between MDS and AML with normal karyotype. The accuracy of resubstitution (application of the classifier to the data forming the classifier) is 100%. For the new data accurate predictions for the non-leukemia cell lines, AML with t(8;21), and CLL were observed. Interestingly, the CML in blast crisis is predicted as AML with other abnormalities. This may be due to the fact that the classifier was trained on CML in chronic phase only. In conclusion, for the first time an international multi-center research study demonstrates a very high reproducibility of microarray analyses performed at different centers for the same leukemia samples. This lays the foundation for an international clinical research initiative evaluating the application of microarrays in the diagnosis and classification of hematological malignancies.

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