ALBERT

Description: Bortezomib (BTZ) was recently evaluated in a randomized Phase 3 clinical trial which compared standard chemotherapy (cytarabine, daunorubicin, etoposide; ADE) to standard therapy with BTZ (ADEB) for de novo pediatric acute myeloid leukemia. While the study concluded that BTZ did not improve outcome overall, we examined patient subgroups benefitting from BTZ-containing chemotherapy using proteomic analyses. The proteasome inhibitor BTZ disrupts protein homeostasis and activates cytoprotective heat shock responses. We measured total heat shock factor 1 (HSF1) and phosphorylated HSF1 (HSF1-pSer326) in leukemic cells from 483 pediatric patients using Reverse Phase Protein Arrays. HSF1-pSer326 phosphorylation was significantly lower in pediatric AML compared to CD34+ non-malignant cells. We identified a strong correlation between HSF1-pSer326 expression and BTZ sensitivity. BTZ significantly improved outcome of patients with low-HSF1-pSer326 with a 5-year event-free survival of 44% (ADE) vs. 67% for low-HSF1-pSer326 treated with ADEB (P=0.019). To determine the effect of HSF1 expression on BTZ potency in vitro, cell viability with HSF1 gene variants that mimicked phosphorylated (S326A) and non-phosphorylated (S326E) HSF1-pSer326 were examined. Those with increased HSF1 phosphorylation showed clear resistance to BTZ vs. those with wild type or reduced HSF1-phosphorylation. We hypothesize that HSF1-pSer326 expression could identify patients that benefit from BTZ-containing chemotherapy.

Description: Activation of double-stranded RNA-activated Protein Kinase (PKR) is associated with growth inhibition and cell death. PKR is normally dormant in cells and is activated in response to stress challenge (e.g. viral infection, chemotherapy, factor withdrawal). The presence of active kinase under growth conditions is generally not observed. PKR expression and activation status was determined in four ALL cell lines: REH, CCRF-CEM, MOLT4, and RS(4;11). PKR was found to be expressed and phosphorylated in all the cell lines. The presence of active PKR suggests the kinase may be important for cellular homeostasis in ALL cells. The best characterized substrate of PKR is eIF2α. Phosphorylation of eIF2α was examined to determine if PKR phosphorylation levels correlated with phosphorylation of the kinase’s primary substrate. Phosphorylated eIF2α was detected in all the cell lines except RS(4;11) cells. The lack of observed phosphorylated eIF2α in the RS(4;11) cells was due to the low abundance of the eIF2α protein. Another substrate of PKR is B56α, a B regulatory subunit of Protein Phosphatase 2A (PP2A). B56α comprises a mitochondrial PP2A isoform that serves as the BCL2 phosphatase and promotes cell death in response to chemotherapeutic agents. PKR was found to phosphorylate B56α at serine 28 in REH cells to promote mitochondrial PP2A activity and BCL2 phosphatase function. Loss of PKR by shRNA results in phosphorylation of BCL2 and the cells become resistant to the chemotherapeutic drug etoposide. Inhibition of PKR by pharmacologic inhibitor or shRNA in REH cells results in loss of B56α expression suggesting that phosphorylation may be required for stability of the B subunit. However, phosphorylation of B56α is not required for its stability since mutant S28A B56α protein is readily expressed in cells. A clue to an alternative mechanism was provided by the eIF2α phosphorylation status and B56α expression pattern in the four ALL cell lines. RS(4;11) cells display little if any B56α protein while the other three ALL cell lines express the B subunit. REH, CCRF-CEM, and MOLT4 cells exhibited ~ 3X higher mitochondrial PP2A activity compared to RS(4;11) cells. The lack of mitochondrial PP2A activity in RS(4;11) cells is likely due to a lack of B56α. Since RS(4;11) cells have active PKR but lack phosphorylated eIF2α, the possibility arises that B56α expression may depend on phosphorylated eIF2α. The mechanism how PKR promotes B56α expression appears to involve the proteasome since a proteasome inhibitor can block loss of the B subunit when PKR is suppressed. A role for eIF2α is suggested since salubrinal, a drug that promotes eIF2α phosphorylation by preventing the dephosphorylation of the molecule increased expression of B56α protein. It has recently been found that eIF2α phosphorylation can activate the PI3K/AKT signaling cascade. Suppression of PKR in REH cells blocks AKT phosphorylation suggesting that PKR may positively regulate AKT in these cells. It appears that the mechanism how PKR promotes B56α expression involves the PI3K/AKT cascade since inhibition of this signaling pathway using LY294002 blocks expression of the B subunit. Since B56α mediated mitochondrial PP2A activity promotes cell death in response to chemotherapeutic agents, it is likely that the normally pro-survival PI3K/AKT pathway may serve a role in stress signaling in ALL cells by supporting B56α expression to promote BCL2 phosphatase activity. These findings indicate that PKR can regulate the BCL2 phosphatase at multiple levels in ALL cells. Understanding the complex regulatory pathway how PKR controls PP2A and BCL2 will be necessary for designing effective therapies for the treatment of ALL.

Description: The bone marrow microenvironment (BME) critically supports hematopoietic stem cells and protects leukemia cells from chemotherapy, immune surveillance, and related stresses. A critical component of the BME is the mesenchymal stem cell (MSC). Dan Link’s group demonstrated that MSC are essential for human hematopoiesis, particularly as a source of SDF-1, which regulates homing, proliferation, and differentiation of HSC. Moreover, studies from our group and others have demonstrated that MSC protect leukemia cells from chemotherapy. At present, very little is known about MSC derived from AML patients, and an understanding of the proteomic makeup of these cells in the leukemia microenvironment could help to elucidate mechanisms involved in supporting their pro-tumor function. We used reverse phase protein array analysis (RPPA) to compare the expression of 151 proteins in MSC derived from AML BMs (N = 106) with those from healthy donors (N = 71). The expression of 45 of these proteins was deemed significantly different (p 〈 0.01) between the two sets. AML MSC expressed higher levels of p53 and p21 (CDKN1A), and the expression of the latter was correlated with other proteins within each MSC set. Using beta-galactosidase staining, AML MSC were found to undergo senescence more frequently than normal MSC. Elevated p21 in AML MSC is consistent with this finding. While 15 proteins were positively, and 20 proteins negatively, correlated with p21 expression in normal MSC, there were only three proteins positively, and nine negatively, correlated in AML-derived MSC. In normal MSC, SMAD1 (a key component in MSC growth and differentiation involving multiple receptors like TGF beta and BMP) expression and AKT signaling were low when p21 is expressed. However, in AML MSC this association was not seen, albeit a negative correlation with ITGAL was observed. SMAD1 expression was higher in normal MSC. In normal MSC, the expression of SMAD1 was negatively correlated with PPARG and NPM1, and was positively correlated with the expression of phosphorylated ELK. The opposite relationship was seen in AML MSC (i.e., PPARG and NPM1 exhibited positive correlation with SMAD1 and phosphorylated ELK was negatively correlated with the protein). While the significance of these relationships remains to be determined it is interesting to note that PPARG is a key regulator of adipocyte differentiation in MSC, so perhaps this alteration of SMAD/PPARG in AML MSC could impede their differentiation potential. In an accompanying abstract from our group, we report that AML MSC are primed toward osteoblastic differentiation and do not differentiate into adipocytes (Battula VL et al, ASH 2014). The RPPA data on PPARG is consistent with this finding. SMAD1 also positively regulates miR-21. Since p21 is a miR-21 target, it seems possible that the differences in expression could be attributed to SMAD1 and miR-21 signaling. We analyzed miR-21 expression in normal and AML-derived MSC (N = 10, each) using qRT-PCR and found a statistically significant (p =0.014) increase in its expression in normal MSC relative to their disease counterparts. When anti-miR-21 was transduced into healthy donor MSC, which caused a 3-fold increase in p21 (but no difference in cyclin D1 expression, another miR-21 target whose expression was also increased in AML MSC). AML MSC also exhibited higher protein expression of the B55 alpha subunit (PPP2R2A) of protein phosphatase 2A (PP2A). This expression contrasted interestingly with that of leukemia cells, since we have previously reported low PPP2R2A levels in AML blasts associated with shorter remission durations (Ruvolo et al Leukemia 2011). Furthermore, AKT phosphorylation was negatively correlated with PPP2R2A expression in AML blasts, and normal MSC, but there was no correlation between PPP2R2A and phosphorylated AKT in AML MSC. Also, expression of PPP2R2A was positively correlated with the expression of the survival protein NOL3 (ARC) which may provide new clues to possible survival mechanisms in AML MSC. In summary, these findings represent insights into the proteomic profiling of normal and AML MSC. Results suggest that senescence (via p21), differentiation potential (involving SMAD/PPARG pathway), and survival signaling (including PP2A/AKT) are altered in AML MSC. Studies are underway to determine how these variations in MSC properties impact the AML microenvironment. Disclosures Carter: Tetralogic Pharmaceuticals: Research Funding.

Description: Patients with CLL experience generalized immune suppression, susceptibility to infections and secondary malignancies that likely involve complex bi-directional interactions between leukemic cells, components of the tumor microenvironment and immune effectors. CLL cells are capable of secreting IL-10 and exhibit regulatory functions comparable to that of normal B10 cells, a regulatory B cell subset that suppresses effector T-cell function through STAT3-mediated production of IL-10. However, the underlying mechanisms governing IL-10 production by CLL cells are not fully understood. The chemokine CXCL12 is constitutively secreted by bone marrow stroma in CLL, and binds CXCR4 to direct chemotaxis, support tumor survival and activate various signaling pathways, including STAT3. Thus, we investigated if CXCL12 can enhance IL-10 production by activating the STAT3 pathway in CLL. Using peripheral blood mononuclear cells (PBMC) from 24 CLL patients who had not received therapy for ≥2 years, we showed that CXCL12 can enhance IL-10 production by CLL cells by activating S727-STAT3. This effect was CXCR4-mediated since blocking the CXCR4-CXCL12 interaction with a blocking antibody abolished CXCL12-induced IL-10 production. Addition of the STAT3 inhibitor curcubitacin to the culture also abrogated CXCL12-induced IL-10 production, confirming an important role for S727-STAT3 as a mediator of CXCL12-CXCR4-induced IL-10 production by CLL cells. We next determined if activation of the CXCR4-CXCL12-STAT3-IL10 pathway in CLL is important in mediating their immunoregulatory function. Culture of primary CLL withCXCL12 induced significantly more suppression of CD3+ T cell function, including TNF-α, IFN-γ and IL-2 production, and CD107a degranulation, compared to CD3+ T cells cultured with untreated CLL cells or with CXCL12 alone. The addition of IL-10 blocking antibody to the co-culture completely reversed T cell dysfunction, supporting an important for IL-10 in CLL-mediated T-cell suppression. IL-10 has been reported to induce T cell suppression through phosphorylation of Y705-STAT3.. Blocking IL-10 also prevented CLL-induced phosphorylation of Y705-STAT3 in T cells, confirming an important role for CLL-derived IL-10 in activation of Y705-STAT3 and induction of T cell dysfunction. Lenalidomide is an immune-modulatory drug with clinical efficacy in CLL and was recently reported to inhibit STAT3 phosphorylation. To investigate if lenalidomide can inhibit CXCL12-induced STAT3 phosphorylation, we treated CLL cells with lenalidomide and measured p-S727-STAT3 levels. Exposure of CLL cells to 10µM/ml lenalidomide prevented CXCL12-induced increase in p-S727-STAT3 and resulted in significant reduction in the IL-10 response by CLL cells. Lenalidomide also suppressed IL-10-induced Y705-STAT3 phosphorylation in healthy T cells, thus reversing CLL-induced T cell dysfunction. We next confirmed the in vivo relevance of our findings using PBMC cryopreserved from patients treated with lenalidomide monotherapy (NCT00535873). When compared to pretreatment samples, CLL cells from on-treatment samples produced less IL-10 and showed significantly improved T cell function. We thus conclude that the capacity of CLL to produce IL-10 is mediated by the CXCL12-CXCR4-STAT3 pathway and may contribute to immunodeficiency in patients. Lenalidomide can reverse CLL-induced immunosuppression through multiple mechanisms that involve abrogation of the CXCL12-CXCR4-S727STAT3-mediated IL-10 response by CLL B cells and prevention of IL-10-induced phosphorylation of Y705-STAT3 in T cells. Disclosures Estrov: incyte: Consultancy, Research Funding. Wierda:Glaxo-Smith-Kline Inc.: Research Funding; Celgene Corp.: Consultancy. Rezvani:Pharmacyclics: Research Funding.

Description: Galectins are a family of b-galactoside binding proteins with effects on cell adhesion, apoptosis, cell cycle, and mRNA processing. Galectin-3 (LGALS3) is unique among galectins by having an N terminal region of roughly 130 amino acids that allows for multimerization and binding to other proteins independent of carbohydrate binding. In addition to promoting BCL2 gene expression and mitochondrial integrity, LGALS3 (along with LGALS1) positively regulates RAS signaling and thus stabilizes survival proteins dependent on ERK phosphorylation such as MCL-1. The pro-survival functions of LGALS3 and other galectins suggest that their targeting could be therapeutic for cancers including AML. Indeed, LGALS3 expression is a predictor of poor prognosis in acute myeloid leukemia (AML), as reported by Cheng and colleagues (Blood 2013) for patients with non-M3 AML and CN-AML. The modified pectin GCS-100 (La Jolla Pharmaceutical, San Diego, CA), now in a Phase II clinical trial for chronic kidney disease, binds and blocks the function of LGALS3. We report that GCS-100 suppresses the growth of AML cell lines OCI-AML3, THP-1, and HL60 in vitro as a single agent, at doses under the 250 ug/mL (i.e., within clinically-achievable concentrations). Short-term treatment of cells (i.e., 〈 6 hr) potently suppressed phosphorylation of AKT and ERK and reduced expression of BCL2 and MCL-1. Because LGALS3 positively regulates anti-apoptotic BCL2 family members, the Raz group has suggested targeting galectins to enhance efficacy of BH3 mimetic drugs (Harazano et al Cancer Metastasis Review 2013). We found that GCS-100 potently synergized with ABT-737 to kill OCI-AML3 cells: while 1 uM ABT-737 or 125 ug/mL GCS-100 reduced total viable cells by ~ 30% and induced apoptosis in 〈 20% of cells after 48 hr as single agents, their combination at those doses and time point reduced viable cells by ~ 94% and induced apoptosis in ~ 70% of cells. Suppression of LGALS3 by lentiviral shRNA reduced BCL2 gene expression as determined by qRT-PCR and augmented killing with ABT-737. Lentiviral suppression of LGALS3 protected cells from GCS-100 at doses of 250 ug/mL but reduction of the galectin failed to protect cells from higher doses of the drug (i.e., 500 ug/mL). This result suggests other galectins are likely inhibited at higher doses of the agent. We used gene expression profiling (GEP) on Illumina HT12v4 human whole-genome arrays to assess more broadly the molecular effects of inhibiting galectins in AML cell lines OCI-AML3 and THP-1 treated with 250 ug/mL or 500 ug/ml GCS-100 for 24 hr. Data were analyzed by Gene Set Enrichment Analysis (GSEA) using gene sets from the Molecular Signatures Database (www.broadinstitute.org/gsea/msigdb/). GSEA suggested that GCS-100 promotes differentiation and inhibits genes associated with proliferation. Multiple upregulated gene sets suggest that there may be a release of a differentiation block as a result of GCS-100 treatment. Furthermore, two gene sets suggest that GCS-100 behaves similar to a GSK3 inhibitor: Known pathways regulated by GSK3 in hematopoietic stem cells are mTOR and Wnt/beta Catenin. Inhibition of Wnt/beta Catenin can release a differentiation block. Consistent with GCS-100 promoting cell differentiation, lentiviral shRNA reduced LGALS3 protein 〉 90% in THP-1 cells and increased CD11b expression, suggesting increased differentiation, compared to cells with control shRNA. GCS-100 was tested in an in vitro model of the bone marrow microenvironment using BM-derived mesenchymal stromal cell (MSC). MSC can protect leukemia cells from a variety of clinically relevant chemotherapy drugs including AraC. GCS-100 was effective at killing AML cells despite the presence of MSC. Both THP-1 and OCI-AML3 cells exhibited 〉 80% and 〉 60% reduction of viable cells, respectively, despite the presence of MSC when treated with 250 ug/mL GCS-100 for 72 hours. In addition, GCS-100 was found to block adhesion of OCI-AML3 cells to MSC suggesting that GCS-100 could be effective in mobilizing AML cells. In summary, our findings suggest that GCS-100 can induce apoptosis in AML cells as a single agent or in combination with the BH3 mimetic ABT-737. The agent is effective even in the presence of MSC suggesting it could be efficacious in the leukemia niche. These findings suggest GCS-100 could be effective for AML therapy. Disclosures Rolke: La Jolla Pharmaceutical Company: Employment. Tidmarsh:La Jolla Pharmaceutical Company: Employment.