ALBERT

Description: Initial therapy for Chronic Lymphocytic Leukemia (CLL) typically includes nucleoside analogs such as fludarabine. Mutations of p53 are uncommon in CLL patients at diagnosis, but are found at increased frequency in patients with prior treatment and are often associated with resistance to standard therapies including fludarabine. The causality of fludarabine treatment to p53 mutation has not been clearly defined. In previous work with the TCL-1 model of CLL, we demonstrated that mice with active leukemia do not have p53 mutations and respond to fludarabine therapy with a modest survival advantage (Johnson et al, Blood108:1334, 2006). We therefore initiated a randomized trial of fludarabine treatment (34mg/kg daily intraperitoneal injection for five days every 28 days) versus observation (treatment with volume-matched vehicle controls on the same dosing schedule) in TCL-1 transgenic mice prior to the onset of leukemia. The goals of this study were to determine if early treatment with fludarabine would 1) delay disease onset; 2) eventually yield a fludarabine-resistant phenotype; or 3) promote development of p53 mutations in mice developing progressive leukemia. Transgenic TCL-1 mice between the ages of eight and 12 weeks were continually treated with fludarabine (n=32) or saline (n=45) until death while being screened monthly for disease progression through changes in WBC count by peripheral blood differentiation smear, lymphocyte subsets by flow cytometry, and nodal and spleen exams. Despite continued treatment with fludarabine, drug resistance as manifested by leukemia and eventual death occurred. Median time to leukemia onset was 308 days (95% CI: 224, ∞) in the fludarabine group and 338 days (95% CI: 252, ∞) in the saline group. Thus, the risk of developing leukemia was not significantly different between the two groups. Of interest, p53 mutations in exons 2–11 were not found in either group (n=10 each) at the time of death. Microarray studies are currently underway to discover other genes differentially expressed between treated and untreated mice that might contribute to fludarabine resistance and will be presented. In conclusion, our data demonstrate that early fludarabine treatment in the TCL-1 transgenic model of CLL does not prevent onset of leukemia, but instead results in disease resistant to fludarabine. The source of fludarabine resistance in this mouse model was not through acquisition of p53 mutations, but rather an alternative unidentified mechanism(s).

Description: The heat shock protein Hsp90 functions to stabilize important cell survival- and proliferation-related kinases such as AKT, IKK, c-Src, Raf-1, and cdk9. Cancer cells have activated Hsp90 as compared to normal cells, making this a relevant therapeutic target to eliminate these kinases. The semi-synthetic geldanamycin derivative 17-allylamino-17-demethoxygeldanamycin (17-AAG) binds to and inhibits the activity of Hsp90, and previous work demonstrated the ability of 17-AAG to deplete AKT in several cancer types in vitro. A newer geldanamycin derivative, 17-(dimethylaminoethylamino)-17-demethoxygeldanamycin (DMAG) has improved pharmacological properties including solubility and oral bioavailability, and was shown to be more effective than 17-AAG in melanoma and pancreatic carcinoma mouse xenograft mouse models. We therefore examined the effects of 17-AAG and DMAG against CD19-positive tumor cells from CLL patients. Cell viability was examined by the MTT assay, and AKT and IKK protein expression was examined by immunoblot analysis. In samples from seven CLL patients, 1.0uM DMAG resulted in 31.5% viability (95% CI: 13.1–50.0%), compared to 61.5% viability (95% CI: 45.0–78.0%) using the same concentration of 17-AAG. In four CLL patient samples treated with 1.0uM DMAG for 24 hours, AKT was decreased an average of 72.5% (95% CI: 57.7–87.3%) relative to the untreated controls. This is in comparison to 1.0uM 17-AAG, which caused a 52.7% decrease in AKT (95%CI: 39.7–65.6%). IKK protein was also decreased at similar levels in all patient samples examined. This data indicates that in CLL cells, DMAG has superior activity both in cytotoxicity and in reduction of relevant Hsp90 client proteins. 17-AAG is currently undergoing Phase I clinical testing in CLL, and DMAG is completing phase I clinical development in solid tumor malignancies. Overall, our data and that of others support clinical development of DMAG in CLL, based on the improved pharmacologic properties, enhanced efficacy relative to 17-AAG, and expected down-regulation of target proteins. In addition, our in vitro observations support using measurement of protein down-regulation of AKT and IKK as pharmacodynamic biomarkers of activity in patients undergoing therapy with these agents.

Description: Inhibitors of histone deacetylase (HDAC) have generated major interest for the treatment of multiple cancers including B-cell Chronic Lymphocytic Leukemia (CLL). To date, HDAC inhibitors introduced for clinical development in CLL have been associated either with suboptimal activity relative to concentrations required to mediate cytotoxicity in vitro (Valproic Acid, MS-275, SAHA), or demonstrate unacceptable acute or long-term toxicities (depsipeptide) that limit their clinical potential. Fortunately, several alternative HDAC inhibitors are in pre-clinical or early clinical development. One such agent currently undergoing pre-clinical testing by the National Cancer Institute-sponsored RAID program is OSU-HDAC42 (s-HDAC-42), a novel, orally bioavailable phenylbutyrate-derived HDAC inhibitor with both in vitro and in vivo efficacy against prostate cancer cells. We therefore tested OSU-HDAC42 against CD19-positive cells obtained from patients with CLL to determine its potential in this disease. The LC50 of OSU-HDAC42 in CLL cells was 0.46 uM at 48 hours of continuous incubation by MTT assay, which was corroborated by annexin V-FITC/propidium iodide flow cytometry. To determine the minimum amount of time that OSU-HDAC42 must be present to induce cell death, cells were incubated for various times, washed, resuspended in fresh media without drug, then assessed by MTT at a total of 48 hours incubation. The effects of OSU-HDAC42 were eliminated in CLL cells when drug was removed after 4 or 6 hours. However, there was a gradual increase in effect over time, and by 16 hours, approximately 60% of the cytotoxicity achieved with continuous incubation was retained. OSU-HDAC42 induced acetylation of histone proteins H3 and H4 as early as 4 hours that was dose and time dependent. LC/MS interrogation of OSU-HDAC42-treated CLL cells is currently underway to determine specific post-translational modification changes of all histone proteins and variants. OSU-HDAC42 also was able to sensitize CLL cells to TNF-Related Apoptosis Inducing Ligand (TRAIL) at 24 hours in a dose-dependent manner, supporting its class I HDAC inhibitory activity as recently reported by Inoue and colleagues (Cancer Res.2006; 66:6785). Evidence of class II HDAC inhibitory activity was also observed with OSU-HDAC42 at 12 hours with acetylation of tubulin. Unlike depsipeptide, OSU-HDAC42 activated both caspase-8 and -9 followed by PARP processing. Cell death induced by OSU-HDAC42 was completely inhibited with pre-treatment by the pan-caspase inhibitor Z-VAD-FMK. In vivo experiments are underway to examine the efficacy of OSU-HDAC42 in several murine models of leukemia to confirm in vivo efficacy as well as influence on murine effector cells. Our data strongly support continued investigation of OSU-HDAC42 in CLL and related B-cell malignancies.

Description: Drug development in human chronic lymphocytic leukemia (CLL) has been limited by lack of a suitable animal model to adequately assess pharmacologic properties relevant to clinical application. A recently described TCL-1 transgenic mouse develops a chronic B-cell CD5+ leukemia that might be useful for such studies. Following confirmation of the natural history of this leukemia in the transgenic mice, we demonstrated that the transformed murine lymphocytes express relevant therapeutic targets (Bcl-2, Mcl-1, AKT, PDK1, and DNMT1), wild-type p53 status, and in vitro sensitivity to therapeutic agents relevant to the treatment of human CLL. We then demonstrated the in vivo clinical activity of low-dose fludarabine in transgenic TCL-1 mice with active leukemia. These studies demonstrated both early reduction in blood-lymphocyte count and spleen size and prolongation of survival (P = .046) compared with control mice. Similar to human CLL, an emergence of resistance was noted with fludarabine treatment in vivo. Overall, these studies suggest that the TCL-1 transgenic leukemia mouse model has similar clinical and therapeutic response properties to human CLL and may therefore serve as a useful in vivo tool to screen new drugs for subsequent development in CLL.

Description: Chronic Lymphocytic Leukemia (CLL) is an incurable disease with limited therapeutic options, especially for high-risk populations such as the del(17p13) patient subset. Currently available therapies for CLL, even if effective, can have significant detrimental effects on remaining T cells, leaving patients at risk of potentially lethal opportunistic infections. New agents with unique mechanisms of action, independence of key resistance pathways, and selectivity for tumor cells are crucial to make an impact on patient survival. Silvestrol, a structurally unique compound isolated from the plant genus Aglaia, exhibited potent activity against several tumor cell lines and moderate in vivo activity in the P388 mouse leukemia model (J. Org. Chem. 2004, 69:3350; ibid. 69:6156). Based on these results, we tested silvestrol against tumor cells obtained from CLL patients. The LC50 (concentration lethal to 50% of cells relative to untreated control) of silvestrol was 6.5 nM at 72 hours by MTT assay. We performed assays to determine CLL patient cell viability at 72 hours with or without drug washout at various times. In these studies, silvestrol showed up to 50% killing at 72 hours with only a four hour exposure, and reached maximum efficacy with a 24 hour exposure. Silvestrol was similarly effective against cells from CLL patients with or without del(17p13). Furthermore, there was no significant difference in silvestrol-mediated cytotoxicity between lymphoblastic cells with a ten-fold overexpression of Bcl-2 relative to control cells. In MTT assays using isolated CD3+ or CD19+ cells, and in whole blood from healthy volunteers and CLL patients, silvestrol demonstrated substantially more cytotoxicity toward B cells than T cells. We then tested silvestrol using Tcl-1 transgenic mice, which are initially normal but develop a slow-progressing B cell leukemia very similar to human CLL. Lymphocytes obtained from spleens of Tcl-1 mice with leukemia were incubated ex vivo with 80 nM silvestrol and analyzed by flow cytometry. Silvestrol produced an 88% reduction in the B cell percentage after 24 hours with no negative effect on the T cell percentage (8% increase), in contrast to 1 μM fludarabine, which affected both B cell (22% reduction) and T cell (14% reduction) subsets. Non-leukemic mice of the Tcl-1 background strain were treated with 1.0, 1.5 and 2.5 mg/kg/day silvestrol for 5 days to determine a tolerable dose. Three of five mice treated with 2.5 mg/kg/day died at the beginning of the second week of treatment. However, none of the animals treated at 1.0 or 1.5 mg/kg showed signs of toxicity or weight loss even after two full weeks of treatment and were normal at pathological examination. Tcl-1 mice with evidence of leukemia as determined by elevated leukocyte counts and enlarged spleens were then treated with silvestrol at 1.5 mg/kg/day × 5 days for two weeks. Treated mice experienced decreased overall leukocyte counts relative to vehicle controls. Furthermore, CD19+ cell numbers and percentages diminished substantially while the T cells were only mildly affected. Additional leukemic Tcl-1 mice are currently being treated and studies are underway examining the mechanism of action of silvestrol in CLL cells.