Combination Of mTOR Inhibition Research Articles

Mammalian target of rapamycin inhibition protects glioma cells from temozolomide-induced cell death

Glioblastoma is an incurable brain tumor with a median survival below two years. Trials investigating targeted therapy with inhibitors of the kinase mTOR have produced ambiguous results. Especially combination of mTOR inhibition with standard temozolomide radiochemotherapy has resulted in reduced survival in a phase II clinical trial. To date, this phenomenon is only poorly understood. To recreate the therapeutic setting in vitro, we exposed glioblastoma cell lines to co-treatment with rapamycin and temozolomide and assessed cell viability, DNA damage and reactive oxygen species. Additionally, we employed a novel translatomic based mass spectrometry approach (“mePROD”) to analyze acute changes in translated proteins. mTOR inhibition with rapamycin protected glioblastoma cells from temozolomide toxicity. Following co-treatment of temozolomide with rapamycin, an increased translation of reactive oxygen species (ROS)-detoxifying proteins was detected by mass spectrometry. This was accompanied by improved ROS-homeostasis and reduced DNA damage. Additionally, rapamycin induced the expression of the DNA repair enzyme O-6-methylguanine-DNA methyltransferase (MGMT) in glioblastoma cells with an unmethylated MGMT gene promotor. Inhibition of mTOR antagonized the cytotoxic effects of temozolomide in vitro. The induction of antioxidant defences and MGMT are two underlying candidate mechanisms. Further functional experiments in vitro and in vivo are warranted to characterize this effect that appears relevant for combinatorial therapeutic strategies.

MTOR Inhibition and T-DM1 in HER2-Positive Breast Cancer.

Inhibition of mTOR increases the antitumor activity of T-DM1, supporting that the combination of mTOR inhibitors and antibody-drug conjugates warrants clinical evaluation in patients with HER2-positive breast cancer.

Role of mTOR As an Essential Kinase in SCLC.

SCLC represents 15% of all lung cancer diagnoses in the United States and has a particularly poor prognosis. We hypothesized that kinases regulating SCLC survival pathways represent therapeutically targetable vulnerabilities whose inhibition may improve SCLC outcome. A short-hairpin RNA (shRNA) library targeting all human kinases was introduced in seven chemonaive patient-derived xenografts (PDX) and the cells were cultured invitro and invivo. On harvest, lost or depleted shRNAs were considered as regulating-cell survival pathways and deemed essential kinases. Unsupervised hierarchical cluster analysis of recovered shRNAs separated the PDXs into two clusters, suggesting kinase-based heterogeneity among the SCLC PDXs. A total of 23 kinases were identified as essential in two or more PDXs, with mechanistic Target of Rapamycin (mTOR) a candidate essential kinase in four. mTOR phosphorylation status correlated with PDX sensitivity to mTOR kinase inhibition, and mTOR inhibition sensitized the PDX to cisplatin and etoposide. In the PDX in which mTOR was defined as essential, mTOR inhibition caused a 43% decrease in tumor volume at 21 days (p < 0.01). Combining mTOR inhibition with cisplatin and etoposide decreased PDX tumor volume 96% compared with cisplatin and etoposide alone at 70 days (p < 0.002). Chemoresistance did not develop with the combination of mTOR inhibition and cisplatin and etoposide in mTOR-essential PDX over 105 days. The prevalence of phospho-mTOR-Ser-2448 in a tissue microarray of chemonaive SCLC was 27%, thus, identifying an important SCLC subtype that might benefit from the addition of mTOR inhibition to standard chemotherapy. These studies reveal that kinases can define SCLC subgroups, can identify therapeutic vulnerabilities, and can potentially be used to optimize therapeutic approaches. Significance We used functional genomics to identify kinases regulating SCLC survival. mTOR was identified as essential in a subset of PDXs. mTOR inhibition decreased PDX growth, sensitized PDX to cisplatin and etoposide, and prevented chemoresistance.

Combination of mTOR inhibition and paclitaxel as a personalised strategy in the context of MYC-amplified high-grade serous ovarian cancer

Abstract Background The extreme genomic heterogeneity of high-grade serous ovarian carcinoma (HGSOC) is a major barrier to precision medicine approaches. We have developed mutational signature analysis from shallow whole genome sequencing (sWGS) for molecular stratification and therapeutic prediction. PARP inhibitor therapy has significant survival advantage for women with germline BRCA1/2 mutations, but treatments and predictive biomarkers for women without homologous recombination deficiency have not been developed. MYC amplification is the most common driver in HGSOC, present in 42% of the TCGA cases. The best responder from the phase 1 trial of AZD2014 (dual m-TORC1/2 inhibitor) and paclitaxel in HGSOC had a mutation in MYC and we have hypothesised that biosynthetic effects of MYC are mediated through the mTOR pathway and blocked by AZD2014 perturbation. Methods Primary ovarian cancer spheroids were purified from 28 human ascites and profiled with sWGS. Ex-vivo therapeutic response was measured to four standard of care chemotherapeutic agents and eight inhibitors targeting nodal points of the PI3K and DNA damage repair pathways. RNA seq data from the TCGA HGSOC cohort was used to establish the genes whose expression was highly correlated with the expression of MYC. Results Ex-vivo assays were predictive of first-line clinical response to chemotherapy agents (P Conclusions Our results suggest that therapeutic strategies combining paclitaxel and inhibition of mTOR pathway can be used as personalised treatment in the context of MYC-amplified HGSOC. We are currently examining gene expression after AZD2014 pertubation in HGSOC models and performing the genomic analysis of cases from the phase 1 trial of AZD2014 and paclitaxel. Legal entity responsible for the study The authors. Funding Academy of Medical Sciences, Addenbrookes Charitable Trust, Cancer Research UK, University of Cambridge. Disclosure F.C. Martins: Research grant / Funding (self), The Clinical Lectureship from the Experimental Medicine Initiative is partly funded by AstraZeneca: AstraZeneca. All other authors have declared no conflicts of interest.

Abstract LB-78: Effects of rapamycin and fasting-cycles therapy on differential stress resistance and sensitization in breast cancer mouse models

Abstract Short-term starvation (STS) has been shown to be effective in both protection of normal cell and tissues and the sensitization of a variety of tumors during chemotherapy treatment. This condition of protection/sensitization of different cell types under the same condition has been named differential stress resistance (DSR). Although the effects of fasting have been mainly attributed to reduced glucose and circulating IGF1 levels, the involvement of signaling genes regulated by glucose and growth factors in these effects of fasting remain poorly understood. In this study we have administered the mTor inhibitor rapamycin in combination with STS and with the chemotherapy drug doxorubicin to shed light on the role of mTOR in the STS response and on its role in mediating DSR. In a mouse allograft model for breast cancer (4T1) we show that STS and rapamycin have an additive effect in reducing tumor progression, which confirms the possibility that STS-mediated effects on cancer cells are not due to the up-regulation of mTOR. Surprisingly, we observed that the administration of rapamycin during chemotherapy sensitizes the mice to the drug leading to an increased mortality. However, this sensitizing effect could be reversed by STS. In summary, the combination of mTor inhibition by rapamycin and STS have additive effects in retarding breast cancer tumor growth and also prevent the chemotherapy-dependent sensitization of normal cells caused by rapamycin alone. Because rapamycin is used for the treatment of certain tumors in humans, these results may have important implications for the safety of therapies using a combination of rapamycin and chemotherapy and indicate that the combination of Tor inhibitors and STS should be tested clinically. Citation Format: Stefano Di Biase, Sebastian Brandorst, Min Wei, Valter Longo. Effects of rapamycin and fasting-cycles therapy on differential stress resistance and sensitization in breast cancer mouse models. [abstract]. In: Proceedings of the 105th Annual Meeting of the American Association for Cancer Research; 2014 Apr 5-9; San Diego, CA. Philadelphia (PA): AACR; Cancer Res 2014;74(19 Suppl):Abstract nr LB-78. doi:10.1158/1538-7445.AM2014-LB-78

Abstract OT2-6-13: A randomized phase 2 study of the triplet combination of ridaforolimus (RIDA), dalotuzumab (DALO) and exemestane (EX) compared to the ridaforolimus, exemestane doublet in high proliferation, estrogen receptor positive (ER+) advanced breast cancer

Abstract Background: The clinical benefit of combination of mTOR inhibition and anti-hormonal therapy has been previously established and represents a new standard of care for patients with hormone receptor positive (HR+) advanced breast cancer (ABC). Preclinical evaluation of the mTOR pathway demonstrates that dual inhibition of IGFR and mTOR may be additive or synergistic and abrogates the feedback activation of AKT due to rapamycin analog mTOR inhibitors. A completed phase 1 study of the combination of the mTOR inhibitor, RIDA and the anti-IGFR antibody, DALO demonstrated preliminary signals of anti-tumor activity. This was further evaluated in a recently completed phase 2 study of RIDA-DALO compared to exemestane in ER+ ABC. Final safety and efficacy results from that phase 2 study will be reported at this meeting (see Baselga et al). Building upon the clinical synergies of mTOR and EX as well as the biologic relationship of the mTOR and IGFR pathways, a clinical study has been initiated to evaluate the triplet combination of RIDA-DALO-EX compared to RIDA-EX. Methods: This is a multicenter, international, randomized phase 2 study of the triplet combination of RIDA (10 mg by mouth daily for 5 out of every 7 days), DALO (10 mg/kg IV weekly), and EX (25 mg QD) compared to RIDA (30 mg by mouth daily for 5 out of every 7 days) and EX (25 mg QD) in high KI67 (≥15%) expressing ER+, ABC. Approximately 84 patients will be randomized 1:1 to either triplet or doublet therapy. Key eligibility criteria include: HR+ and HER-2 negative measurable ABC, prior therapy with a non-steroidal aromatase inhibitor, and KI67 labeling index ≥15%. The primary endpoint of the study is progression free survival (PFS). Key secondary endpoints include evaluation of percent (%) reduction from baseline in the sum of imaging measurements (target lesion diameters or volumes) at 16 weeks between the two arms, and overall response rates. The sample size is event driven with a target of 38 PFS events, which provides approximately 80% power, at 1-sided alpha of 0.1, to detect a HR of 0.5, corresponding to an approximate 100% improvement in median PFS, from 10.6 to 21.2 months. Safety parameters or adverse experiences of special interest include hyperglycemia, stomatitis, mucosal inflammation, pneumonitis and hearing loss. Accrual has been completed with results expected in May 2014. Citation Information: Cancer Res 2013;73(24 Suppl): Abstract nr OT2-6-13.

Combined targeting of AKT and mTOR synergistically inhibits proliferation of hepatocellular carcinoma cells

BackgroundDue to the frequent dysregulation of the PI3K/AKT/mTOR signaling pathway, mTOR represents a suitable therapeutic target in hepatocellular carcinoma (HCC). However, emerging data from clinical trials of HCC patients indicate that mTOR inhibition by RAD001 (Everolimus) alone has only moderate antitumor efficacy which may be due to the feedback activation of AKT after mTOR inhibition. In this study, we analyzed the effects of dual inhibition of mTOR and AKT on the proliferation of HCC cell lines. In addition, we measured the feedback activation of each of the AKT isoforms after mTOR inhibition in HCC cell lines and their enzymatic activity in primary samples from HCC patients.MethodsThe activation status of specific AKT isoforms in human HCC samples and corresponding healthy liver tissue was analyzed using an AKT isoform specific in vitro kinase assay. AKT isoform activation after mTOR inhibition was analyzed in three HCC cell lines (Hep3B, HepG2 and Huh7), and the impact of AKT signaling on proliferation after mTOR inhibition was investigated using the novel AKT inhibitor MK-2206 and AKT isoform specific knockdown cells.ResultsAKT isoforms become differentially activated during feedback activation following RAD001 treatment. The combination of mTOR inhibition and AKT isoform knockdown showed only a weak synergistic effect on proliferation of HCC cell lines. However, the combinatorial treatment with RAD001 and the pan AKT inhibitor MK-2206 resulted in a strong synergism, both in vitro and in vivo. Moreover, by analyzing primary HCC tissue samples we were able to demonstrate that a hotspot mutation (H1047R) of PI3KCA, the gene encoding the catalytic subunit of PI3K, was associated with increased in vitro kinase activity of all AKT isoforms in comparison to healthy liver tissue of the patient.ConclusionOur results demonstrate that dual targeting of mTOR and AKT by use of RAD001 and the pan AKT inhibitor MK-2206 does effectively inhibit proliferation of HCC cell lines. These data suggest that combined treatment with RAD001 and MK-2206 may be a promising therapy approach in the treatment of hepatocellular carcinoma.

Synergistic Control of Acute GvHD: Effectively Down-Regulating T Cell Proliferation and Cytotoxicity with Combined mTOR Inhibition and CD28:CD80/86 Costimulation Blockade.

AbstractAbstract 2998 Introduction:GvHD remains the most deadly complication of HSCT despite current prevention strategies. To address the unmet need for better GvHD control, we have created a non-human primate (NHP) model with which to rigorously test mechanism and efficacy of novel therapeutics. In this study, we determined whether a novel combination of mTOR inhibition (with sirolimus) and CD28:CD80/86 costimulation blockade (with belatacept) could control GvHD. Here we show for the first time that these two agents combine synergistically to prevent both the clinical and immunologic manifestations of primate aGvHD. Methods:Rhesus macaque recipients were irradiated (9.6 Gy in 2 fractions at 7cGy/min), and then transplanted with G-CSF-mobilized PBSC from a haplo-identical donor (1–5×108 TNC/kg). Recipients were treated with either sirolimus alone (n = 4, troughs targeted at 5–10 ng/mL), belatacept alone (receiving weekly doses of 20 mg/kg), or combination therapy. Clinical GvHD was monitored using our previously described NHP grading scale (Miller et al., Blood 2010), and multiparameter flow cytometric analysis was performed. Results:Untreated controls (n = 5) developed rapid, severe histopathologically-proven aGvHD and succumbed rapidly (MST = 7 days). Recipients treated with either sirolimus or belatacept alone were partially protected from the clinical manifestations of GvHD. Sirolimus-treated recipients (n = 6) developed predominantly GI disease (with diarrhea but no elevation of bilirubin) and had an MST of 14 days (Figure 1). Recipients treated with belatacept alone (n = 3) developed primarily liver aGvHD (bilirubin rapidly rising to 6–30 × normal with histologically-confirmed lymphocytic infiltration) and an MST of 11 days. In striking contrast, recipients treated with combined sirolimus + belatacept (n = 5) demonstrated neither uncontrolled diarrhea nor hyperbilirubinemia at the timed terminal analysis (1 month post-transplant).We employed multiparameter flow cytometry to determine the immunologic consequences of sirolimus and belatacept on T cell proliferation (using Ki-67 expression) and cytotoxity (using granzyme B expression). We found that the clinical synergy observed with combined therapy was recapitulated immunologically. Thus, while untreated aGvHD was associated with rampant CD8+ proliferation (with 83 +/− 14% Ki-67+ CD8+ vs 4.7 +/− 0.6% pre-transplant), sirolimus or belatacept as monotherapy both partially controlled proliferation (35 +/− 3% and 65 +/− 23% Ki-67+ CD8+ with sirolimus or belatacept, respectively). Combined sirolimus + belatacept dramatically reduced proliferation (to 8 +/− 3%, favorably comparing with 13% Ki-67+ CD8+ T cells using standard Calcineurin Inhibitor/Methotrexate (CNI/MTX) prophylaxis).Sirolimus and belatacept both also partially controlled GvHD-related T cell cytotoxicity. Thus, while untreated aGvHD was associated with excessive granzyme B expression in CD8+ T cells (82 +/− 2% granzyme Bvery high CD8+ cells vs 0.3 +/− 0.2% pre-transplant) sirolimus or belatacept monotherapy also partially controlled cytotoxicity (8 +/− 1% and 35 +/− 1% granzyme Bvery high with sirolimus or belatacept, respectively). Combination therapy dramatically reduced the proportion of these cells, to 1.5 +/− 0.8 % granzyme Bvery high, favorably comparing with 4% granzyme Bvery high using CNI/MTX.The ability of sirolimus, belatacept, or the combination to control Ki-67 and Granzyme B expression closely correlated with survival (Figure 2A, B) supporting a pathogenic role for these highly proliferative and cytotoxic cells in aGvHD pathology. Moreover, significant co-expression of granzyme B in the Ki-67+ cells was observed (Figure 2C) suggesting that dual-positive Ki-67/Granzyme B cells may mark a pathogenic population, amenable to tracking in the peripheral blood. Implications:These results reveal a previously undiscovered synergy between sirolimus and belatacept in the control of primate aGvHD, and provide support for future clinical investigation of this novel prevention strategy. They also identify CD8+/Ki-67+/Granzyme Bvery high dual-positive T cells as a potentially sensitive biomarker of GvHD pathogenesis, amenable to monitoring in either the blood or in GvHD target organs. [Display omitted] [Display omitted] Disclosures:No relevant conflicts of interest to declare.

Abstract 5402: Pre-clinical treatment of adrenal cortical carcinoma with a combination of small molecule inhibitors to IGF-1R and mTOR

Abstract Adrenocortical carcinoma (ACC) is a rare, aggressive cancer of the adrenal cortex. The five-year survival rate is 10-20% due to late diagnosis and lack of effective systemic therapy. The only treatment options available are surgical resection and chemotherapy in the form of mitotane; however, up to 95% of patients are not responsive to treatment, so new therapies are needed. Research has shown that the mitogenic hormone insulin-like growth factor 2 (IGF-2) is overexpressed in 93% of sporadic cases of ACC. IGF-2 binds to the receptor tyrosine kinase IGF receptor 1 (IGF-1R). Inhibition of IGF-1R has been shown to be effective against ACC in animal studies using IGF-1R targeted therapies. The major IGF-1R signaling pathway is phosphotidylinositol-3′-kinase (PI3′K), which activates AKT leading to the activation of mTOR, the mammalian target of rapamycin. Recent research has shown that mTOR may be a viable target for inhibition to treat tumors. Work in our lab has shown that a combination of mTOR inhibition by rapamycin and IGF1-R inhibition by either PQ401 or NVP-AEW54 at sub optimal doses blocks proliferation of human ACC H295R cells compared to application of either drug alone. Further investigation will be conducted in a mouse model system to determine the effects of the mTOR inhibitor everlimus (RAD001) alone and in combination with IGF1-R inhibitor OSI-906 to determine possible synergistic effects of the drugs that can be clinically applicable to treat ACC. Citation Format: {Authors}. {Abstract title} [abstract]. In: Proceedings of the 101st Annual Meeting of the American Association for Cancer Research; 2010 Apr 17-21; Washington, DC. Philadelphia (PA): AACR; Cancer Res 2010;70(8 Suppl):Abstract nr 5402.

Effect of mTOR inhibition on sensitivity of triple-negative breast cancer cells to epidermal growth factor inhibition

1055 Background: The outcome for patients with triple negative (TN) cancers is poor at least in part because of a lack of targeted therapies. Although 50% of TN breast cancers over-express EGFR, the use of EGFR inhibitors as single agents in patients with unselected and TN metastatic breast cancers has produced disappointing results. Likewise, mTOR inhibitors have modest activity as single agents in metastatic breast cancer. mTOR inhibitors have been demonstrated to activate the Akt pathway by a possible feedback mechanism, which could potentially sensitize TN breast cancer cells to upstream inhibitors. We have previously demonstrated that EGFR inhibitors in combination with rapamycin (RAPA) decrease cell survival, increase apoptosis, and are synergistic in TN breast cancer cells, compared to any of the agents alone (AACR 2008). We, therefore, evaluated the combination of mTOR and EGFR inhibition in vivo. Methods: Athymic mice were inoculated with TN (MDA-MB-231) breast cancer cells. One week after cell inoculation, mice were treated with vehicle, lapatinib 75mg/kg by mouth daily, RAPA 3mg/kg IP biweekly, or the combination. After 4 weeks of treatment, mice were sacrificed and tumors were assessed for target proteins by Western blotting and immunohistochemistry Results: The combination of RAPA and lapatinib resulted in a significant decrease in TN breast tumor volume (76 mm3), compared to rapamycin alone (133 mm3, p = 0.01), lapatinib alone (183 mm3, p &lt; 0.0001) or control (188 mm3, p = 0.005). Neither lapatinib nor RAPA alone inhibited tumor growth significantly compared to control (p &gt; 0.05). Interestingly, in contrast to our findings in vitro, the increase in pAkt noted in RAPA treated tumors was not decreased by lapatinib, despite the significant decrease in tumor size in tumors treated with the combination. Conclusions: These studies demonstrate that the combination of mTOR inhibition and lapatinib significantly inhibit TN breast cancer growth, compared with either agent alone. Given the lack of targeted therapies in TN breast cancers, these data support the possibility that mTOR inhibition can sensitize TN breast cancers to EGFR inhibitors. A clinical trial evaluating the combination of lapatinib and RAD001 as second-line therapy for TN metastatic breast cancer is planned. [Table: see text]

Combined mTOR inhibition and post-transplant infusion of alloantigen-specific Treg promotes long-term graft survival in otherwise unmanipulated hosts (141.42)

Abstract Protocols that achieve donor-specific tolerance of MHC-mismatched organ grafts remain an unmet clinical goal. We report a strategy that combines post-transplant administration of alloAg-specific Treg (AAsTreg) with inhibition of the mammalian target of rapamycin (Rapa) (mTOR) to promote long-term, donor-specific heart graft survival. AAsTreg selection was achieved by co-culture of CD4+CD25+ Treg with immature dendritic cells (DC) in the presence of conditioned media. This rendered cells that potently inhibited T cell proliferation in an Ag-specific manner. However, AAsTreg remained unable to control T cell activation when stimulated by mature DC, - a phenomenon dependent on IL-6 release. Exploiting the in vivo inhibitory effects of Rapa on inflammatory cytokine (IL-6) production, T cell proliferation and graft infiltration, AAsTreg were administered post-transplant (d7) in combination with short-term Rapa. AAsTreg exerted a pro-tolerogenic effect: &amp;gt;80% long-term graft survivors [LTS] (MST&amp;gt;150d). Polyclonal Treg exerted an inferior protective effect: 40% LTS (MST=45d). Moreover, the pro-tolerogenic effect was Ag-specific as AAsTreg selected against third party DC failed to prolong graft survival. Significantly, LTS exhibited alloreactive T cell anergy. Thus, combination of mTOR inhibition with AAsTreg is an effective, clinically-applicable approach to promote long-term graft survival.

Targeting the AIB1 Oncogene through Mammalian Target of Rapamycin Inhibition in the Mammary Gland

Amplified in breast cancer 1 (AIB1), an estrogen receptor (ER) coactivator, is frequently amplified or overexpressed in human breast cancer. We previously developed a transgenic mouse model in which AIB1 can act as an oncogene, giving rise to a premalignant hyperplastic mammary phenotype as well as to a high incidence of mammary tumors that are primarily ER(+). In this model, the AIB1 transgene is responsible for continued activation of the insulin-like growth factor-I receptor, suggesting a role for the activation of the phosphatidylinositol 3-kinase/Akt/mammalian target of rapamycin (mTOR) pathway in the premalignant phenotype and tumor development. Here we show that treatment of AIB1 transgenic mice with the mTOR inhibitor RAD001 reverts the premalignant phenotype. Furthermore, treatment of cell lines derived from AIB1-dependent mammary tumors with RAD001 in culture leads to a G(1) cell cycle arrest. Lastly, tumor growth after injection of ER(+) AIB1 tumor cell lines into wild-type animals is inhibited by RAD001 treatment. In this ER(+) model, inhibition of tumor growth by RAD001 was significantly better than inhibition by the antiestrogen 4-hydroxytamoxifen alone, whereas a combination of both RAD001 and 4-hydroxytamoxifen was most effective. Based on these results, we propose that the combination of mTOR inhibition and ER-targeted endocrine therapy may improve the outcome of the subset of ER(+) breast cancers overexpressing AIB1. These studies provide preclinical support for the clinical development of RAD001 and suggest that AIB1 may be a predictive factor of RAD001 response.

A Phase I Dose Escalation Study of the mTOR Inhibitor Sirolimus and MEC Chemotherapy Targeting Signal Transduction in Leukemic Stem Cells for Acute Myeloid Leukemia.

In vitro studies have suggested that AML cells are sensitive to treatment with the mammalian target of rapamycin (mTOR) inhibitor, rapamycin. In particular, mTOR inhibition is known to enhance the sensitivity of primary AML cells and AML stem cells to etoposide based chemotherapy leading to inhibition of leukemic SRC activity in NOD/SCID mice. To determine the feasibility of applying this approach in vivo, we performed a Phase I dose escalation study of the mTOR inhibitor sirolimus (rapamycin) with a combination chemotherapy induction regimen in adults with relapsed or refractory non-M3 AML. The purpose of this trial was to determine the safety and dose limiting toxicities of sirolimus and chemotherapy in this patient population. Patients received a loading dose of oral sirolimus on day 1 followed 24 hours later by daily doses of oral sirolimus on days 2–7 plus MEC (mitoxantrone 8 mg/m2/day IV, etoposide 100 mg/m2/day IV, and cytarabine 1000 mg/m2/day IV) on days 1–5. Five sirolimus dose levels were explored by a standard 3+3 design. Sirolimus was studied at loading doses from 3–15 mg and daily doses from 1–5 mg/d. Clinical response was assessed by bone marrow biopsy upon hematologic recovery or day 42, whichever occurred first. 23 adults (14 women, 9 men) of median age 58 (range 22 to 65) with relapsed, refractory, or secondary AML were treated with sirolimus and MEC. Five subjects had antecedent hematologic disorders or prior leukemogenic chemotherapy, 18 had relapsed or refractory disease. Sirolimus was well tolerated and did not increase non-hematologic toxicity of MEC chemotherapy. Asymptomatic, reversible liver transaminase or bilirubin elevations occurred in 4 patients, two of which were > grade 2. One patient with a history of prior cytarabine cerebellar toxicity (unknown at the time of study entry) developed reversible cerebellar ataxia. Three patients died of complications related to bacterial infections during chemotherapy-induced aplasia. Dose limiting toxicity was prolonged myelosuppression at the highest planned dose level and was responsible for one treatment-related death due to infectious complications from unresolved aplasia on study day 119. For the first four dose levels the median time to ANC recovery >500/uL among evaluable patients was 27 days (range16–38). Pharmacokinetic data showed that doses of 3 mg and higher consistently achieved rapamycin levels considered therapeutic in solid organ transplantation (4–9.2 ug/L). Bone marrow studies in 2/2 evaluable patients on dose level 4 (12 mg loading dose and 4 mg per day sirolimus) showed inhibition of p70S6 kinase phosphorylation consistent with effective inhibition of mTOR at this dose level. Complete remissions occurred in four patients, all treated for first relapse. Two patients subsequently proceeded to allogeneic transplantation. These results indicate that the combination of mTOR inhibition and chemotherapy is feasible in human AML and establish an appropriate dose for phase II studies to be 12mg loading dose followed by 4 mg daily. Patient recruitment at this dose is ongoing. Confirmation of the efficacy of this regimen, which targets signal transduction in leukemic < stem cells, is planned in a randomized phase II trial at the cooperative group level.

Synergistic effect of targeting mTOR by rapamycin and depleting ATP by inhibition of glycolysis in lymphoma and leukemia cells

The mammalian target of rapamycin (mTOR) pathway plays important roles in regulating nutrient metabolism and promoting the growth and survival of cancer cells, which exhibit increased glycolysis for ATP generation. In this study, we tested the hypothesis that inhibition of the mTOR pathway and glycolysis would synergistically impact the energy metabolism in cancer cells and may serve as an effective therapeutic strategy to kill malignant cells. Using human lymphoma cells and leukemia cells, we demonstrated that the combination of rapamycin, an mTOR inhibitor, with a glycolytic inhibitor produced synergistic cytotoxic effect, as evidenced by apoptosis and cell growth inhibition assays. Mechanistic studies showed that inhibition of the mTOR pathway by rapamycin alone sufficiently suppressed the phosphorylation of the downstream molecules p70S6K and 4E-BP-1, but only caused a moderate cytostatic effect. Combination of mTOR inhibition and blockage of glycolysis synergistically suppressed glucose uptake and severely depleted cellular ATP pools, leading to significant enhancement of cell killing. In contrast, combination of rapamycin and ara-C did not increase cytotoxicity in vitro. Our findings suggest that targeting mTOR pathway in combination with inhibition of glycolysis may be an effective therapeutic strategy for hematological malignancies. This mechanism-based drug combination warrants further investigation in preclinical and clinical settings.