4 research outputs found
Alterations in the mitochondrial responses to PENAO as a mechanism of resistance in ovarian cancer cells
OBJECTIVE: The purpose of this study was to test PENAO, a promising new organoarsenical that is in phase 1 testing in patients with solid tumours, on a range of ovarian cancer cell lines with different histotypes, and to understand the molecular basis of drug resistance exhibited by the endometrioid ovarian cancer cell line, SKOV-3. METHODS: Proliferation arrest and cell death induced by PENAO in serous (OVCAR-3), endometrioid (SKOV-3, TOV112D), clear cell (TOV21G) and mucinous (EFO27) ovarian cancer cells in culture, and anti-tumour efficacy in a murine model of SKOV-3 and OVCAR-3 tumours, were measured. Cells were analysed for cell cycle arrest, cell death mechanisms, reactive oxygen species production, mitochondrial depolarisation, oxygen consumption and acid production. RESULTS: PENAO demonstrated promising anti-proliferative activity on the most common (serous, endometrioid) as well as on rare (clear cell, mucinous) subtypes of ovarian cancer cell lines. No cross-resistance with platinum-based drugs was evident. Endometrioid SKOV-3 cells were, however, shown to be resistant to PENAO in vitro and in a xenograft mouse model. This resistance was due to an ability to cope with PENAO-induced oxidative stress, notably through heme oxygenase-1 induction, and a shift in metabolism towards glycolysis. The adaptive glycolytic shift in SKOV-3 was targeted using a mTORC1 inhibitor in combination with PENAO. This strategy was successful with the two drugs acting synergistically to inhibit cell proliferation and to induce cell death via apoptosis and autophagy. CONCLUSION: Mitochondria/mTOR dual-targeting therapy may constitute a new approach for the treatment of recurrent/resistant forms of epithelial ovarian cancer
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EXPERIMENTAL THERAPEUTICS AND PHARMACOLOGY
The multifunctional protein - tissue inhibitor of metalloproteinases-1 (TIMP-1) - has been associated with poor prognosis in several types of cancers including glioblastomas. Glioblastomas are the most common and malignant primary brain tumor known for being highly invasive and resistant to therapy. New treatment strategies are continuously being explored and currently vascular endothelial growth factor (VEGF) inhibitors administered in combination with Irinotecan is the most promising second line treatment. TIMP-1 has been associated with decreased response to chemotherapy in breast and colorectal cancer and especially the family of topoisomerase (TOP) inhibitors, such as Irinotecan, has been suggested to be affected by TIMP-1. In the present study, we investigated whether a high TIMP-1 expression in glioblastoma cells played a role in TOP inhibitor resistance. We established two TIMP-1 over-expressing cell lines and evaluated the sensitivity towards the TOP1 inhibitor SN-38 and the TOP2 inhibitor Epirubicin using a viability and a cytotoxicity assay. In addition, we investigated the invasive features of the cells in a brain slice culture model as well as in an orthotopic xenograft model. The results showed that TIMP-1 over-expressing U87MG cell line sub-clones were significantly more resistant than the controls when exposed to SN-38 and Epirubicin. The same tendency was seen for the TIMP-1 over-expressing A172 sub-clones. No significant differences in invasion patterns were observed for TIMP-1 over-expressing sub-clones when compared to controls. In conclusion, the present study suggests that TIMP-1 over-expression reduces the effect of TOP inhibitors in the glioblastoma cell line U87MG. There was no significant effect of TIMP-1 over-expression on tumor cell invasion. The association found between TIMP-1 cellular levels and the effect of TOP inhibitors needs to be validated in clinical patient material. Pediatric supratentorial high-grade astrocytomas (pHGAs) and diffuse intrinsic pontine gliomas (DIPG) are devastating pediatric malignancies for which no effective therapies exist. Poly-(ADP-Ribose)-Polymerase (PARP) protein expression is found in ∼60% of DIPGs suggesting PARP may be a potential therapeutic target. PARP1/2 were characterized by Western-blotting in normal human astrocytes (NHA), pHGA cell lines (SJG2, SF-188), DIPG cell lines (DIPG-M, DIPG58), and one murine brainstem glioma cell line (mBSG). Cell viability in response to different dosages of Olaparib, Veliparib, or Niraparib was determined using the MTT Assay. PARP activity, apoptosis, and DNA damage was determined by Western blotting against PAR, cleaved PARP, and phosphorylated yH2AX, respectively. Cell cycle phases were analyzed using FACS and western blot for p21. Western blotting demonstrated that, compared with NHAs, PARP1 were highly expressed in SJG2, DIPG-M, and DIPG-58 cells. PARP2 expression was only detected in SJG2 cells. All PARP inhibitors reduced PARP activity as indicated by reduced PAR levels. Olaparib reduced SJG2, mBSG, DIPG58 and DIPGM cell viability at concentrations of 5 or 10uM uM (P < 0.05), Whereas Niraparib induced cytotoxicity at concentrations of 2uM and above (P < 0.05). Olaparib and Niraparib induced DNA damage and apoptosis in SJG2 at doses of 5, 10uM and 2, 5, 10uM, respectively. Niraparib induced G2 arrest in mBSG demonstrated by FACS and increased levels of p21 (P < 0.05). Our data provides in vitro evidence that PARP inhibition may be an effective therapeutic avenue for treatment of pHGA and DIPG. Furthermore while all PARP inhibitors suppress PARP activity not all PARP inhibitors reduce cell viability. Thus not all PARP inhibitors can be expected to be equally efficacious in a clinical trial setting. Toca 511 (vocimagene amiretrorepvec), an amphotropic retroviral replicating vector (RRV), can successfully and safely deliver a functional, optimized yeast cytosine deaminase (CD) gene to tumors in orthotopic glioma models. Within infected cells, CD converts 5-fluorocytosine (5-FC) to the anti-cancer drug 5-FU. The combination of Toca 511 with oral extended release 5-FC (Toca FC), is currently in clinical trials for recurrent High Grade Glioma (HGG, NCT01156584 and NCT01470794). Temozolomide (TMZ), in combination with radiation therapy, is the most commonly used first-line chemotherapy treatment for patients with glioblastoma, the most common and aggressive form of primary brain cancer. A separate study (Takahashi et al., this meeting) addresses the potential radiation synergy with Toca 511/5-FC treatment. A subset of patients with certain genetic alterations does not respond well to TMZ treatment and the overall median survival for patients who respond remains poor, suggesting combinatorial approaches may be necessary to significantly improve patient outcomes. To determine whether Toca 511 and 5-FC therapy is compatible with TMZ, we examined the effect of TMZ in combination with Toca 511 and 5-FC in TMZ-sensitive and resistant glioma lines both in vitro and in vivo. We show that in vitro TMZ delays but does not prevent RRV spread, nor interfere with Toca 511 and 5-FC mediated cell killing in glioma tumor cells, and in vivo there is no significant hematologic effect from the combination of 5-FC and the clinically relevant dose of TMZ. A synergistic long-term survival advantage is observed in mice bearing an orthotopic TMZ-sensitive glioma tumor after Toca 511 administration followed by co-administration of TMZ in combination with 5-FC. These results provide support for the investigation of this novel combination treatment strategy for patients with newly diagnosed glioblastoma. BACKGROUND: LAZ is a 21-aminosteroid that has radioprotective effects against radiation-induced lipid peroxidation. Also antiproliferative effects have been reported against glioblastoma cell lines. DESIGN/METHODS: LAZ PEGylated liposomes (Lipo G) were developed at the University of Houston.. Glioblastoma cell line U87-expressing firefly luciferase reporter gene (100,000 cells in 2 µL) was injected intracranially in each SCID mouse. There were 4 treatment groups (n = 8-9, each): brain model (M) without treatment (control), radiation 2Gy weekly (M + R), Lipo G at 5 mg/kg dose intraperitoneally twice per week (M + L) and radiation with Lipo G (M + R + L). Treatment lasted three weeks. Tumor size was monitored using bioluminescence imaging (BLI), in each mouse. Mice were sacrificed after 3 weeks. Brain was harvested. Lipid peroxidation of brain tissues was quantified by measuring malondialdehyde (MDA) as a surrogate biomarker. Survival was evaluated using Kaplan Meier analysis at P= 0.05. RESULTS: BLI intensity was 4002.03 ± 1737.67, 2034 ± 737.72, 1387.36 ± 684.53 and 2498.89 ± 2521.32 % for M, M + R, M + L and M + R + L, respectively. Tumor size of the M + L group was reduced by 65% compared to control. There was no significant difference in tumor size of radiated groups compared to control group. MDA brain concentration in M + L and M + R + L groups was significantly less than in M + R group (8.27 ± 0.78 and 10.37 ± 3.30 µM/gm vs. 23.09± 3.79 µM/gm). The survival mean was 22.67, 25.33, 25.22 and 27.13 days for M, M + R, M + R + L and M + L groups, respectively. Mean survival of LAZ treated groups (M + L and M + R + L) was significantly longer than that of the control group. CONCLUSIONS: LAZ liposomal formulations reduced tumor growth by 65%. LAZ also protected brain tissue from radiation-induced lipid peroxidation by reducing MDA concentration by 50%. These provocative data warrant further investigation of LAZ as a radiation protectant and chemotherapeutic agent. Patients with malignant brain tumors have a median survival of approximately one year following diagnosis, regardless of currently available treatments which include surgery followed by radiation and chemotherapy. Improvement in the survival of brain cancer patients requires the design of new therapeutic modalities that take advantage of common phenotypes. One such phenotype is the metabolic dysregulation that is a hallmark of cancer cells. It has therefore been postulated that one approach to treating brain tumors may be by metabolic alteration such as that which occurs through the use of the ketogenic diet (KD). The KD is high-fat, low-carbohydrate diet that induces ketosis and has been utilized for the non-pharmacologic treatment of refractory epilepsy. We and others have shown that this diet enhances survival and potentiates standard therapy in mouse models of malignant gliomas, yet the anti-tumor mechanisms are not fully understood. It has been previously shown that caloric restriction, which induces ketosis, reduces microvessel density in mouse and human brain tumor models, suggesting an anti-angiogenic effect. We now report that in animals fed KetoCal® (KC)(4:1 fat:protein/carbohydrates) ad libitum, peritumoral edema is significantly reduced early in tumor progression when compared to those fed a standard rodent diet. Gene expression profiling demonstrated that KC decreases the expression of the gene encoding vascular endothelial growth factor B (VEGFB) and angiopoetin 1 receptor (TEK). Furthermore, protein analysis showed a reduction of platelet endothelial cell adhesion molecule 1 (PECAM1/CD31) in tumors from animals maintained on KC. Taken together our data suggests that KC alters the angiogenic processes involved in malignant progression of gliomas. A greater understanding of the effects of the ketogenic diet as an adjuvant therapy will allow for a more rational approach to its clinical use