Ralf Wiedemuth

RNA interference targeting survivin exerts antitumoral effects in vitro and in established glioma xenografts in vivo

Malignant glioma represents the most common primary adult brain tumor in Western industrialized countries. Despite aggressive treatment modalities, the median survival duration for patients with glioblastoma multiforme (GBM), the highest grade malignant glioma, has not improved significantly over past decades. One promising approach to deal with GBM is the inactivation of proteins essential for survival or progression of glioma cells by means of RNA interference (RNAi) techniques. A likely candidate for an RNAi therapy of gliomas is the inhibitor of apoptosis protein survivin. Survivin is involved in 2 main cellular processes–cell division and inhibition of apoptosis. We show here that stable RNAi of survivin induced polyploidy, apoptosis, and impaired proliferation of human U343-MG, U373-MG, H4, and U87-MG cells and of primary glioblastoma cells. Proteome profiler arrays using U373-MG cells identified a novel set of differentially expressed genes upon RNAi-mediated survivin knockdown. In particular, the death receptor TRAIL R2/DR5 was strongly upregulated in survivin-depleted glioma cells, inducing an enhanced cytotoxic response of allogeneic human NK cells. Moreover, an experimental in vivo therapy using polyethylenimine (PEI)/siRNA complexes for survivin knockdown efficiently blocked tumor growth of established subcutaneous U373-MG tumors and enhanced survival of NMRInu/nu mice orthopically transplanted with U87-MG cells. We conclude that survivin is functionally relevant in gliomas and that PEI-mediated exogenous delivery of siRNA targeting survivin is a promising strategy for glioblastoma therapy.

DAP12-Based Activating Chimeric Antigen Receptor for NK Cell Tumor Immunotherapy

NK cells are emerging as new effectors for immunotherapy of cancer. In particular, the genetic engraftment of chimeric Ag receptors (CARs) in NK cells is a promising strategy to redirect NK cells to otherwise NK cell–resistant tumor cells. On the basis of DNAX-activation protein 12 (DAP12), a signaling adaptor molecule involved in signal transduction of activating NK cell receptors, we generated a new type of CAR targeting the prostate stem cell Ag (PSCA). We demonstrate in this article that this CAR, designated anti–PSCA-DAP12, consisting of DAP12 fused to the anti-PSCA single-chain Ab fragment scFv(AM1) confers improved cytotoxicity to the NK cell line YTS against PSCA-positive tumor cells when compared with a CAR containing the CD3ζ signaling chain. Further analyses revealed phosphorylation of the DAP12-associated ZAP-70 kinase and IFN-γ release of CAR-engineered cells after contact with PSCA-positive target cells. YTS cells modified with DAP12 alone or with a CAR bearing a phosphorylation-defective ITAM were not activated. Notably, infused YTS cells armed with anti–PSCA-DAP12 caused delayed tumor xenograft growth and resulted in complete tumor eradication in a significant fraction of treated mice. The feasibility of the DAP12-based CAR was further tested in human primary NK cells and confers specific cytotoxicity against KIR/HLA-matched PSCA-positive tumor cells, which was further enhanced by KIR-HLA mismatches. We conclude that NK cells engineered with DAP12-based CARs are a promising tool for adoptive tumor immunotherapy.

Giant Cell Glioblastoma Is Associated With Altered Aurora B Expression and Concomitant p53 Mutation

Giant cell glioblastoma (gcGB), a subtype of GB, is characterized by the presence of numerous multinucleated giant cells. The prognosis for gcGB is poor, but it may have a better clinical outcome compared with classic GB. The molecular alterations that lead to the multinucleated cell phenotype of gcGB have not been elucidated. Giant cell GB has a higher frequency of the tumor suppressor protein p53 mutations than GB, however, and a role for the mitotic Aurora B kinase has been suggested. We analyzed Aurora B expression in gcGB (n = 28) and GB (n = 54) patient tumor samples by immunohistochemistry; 17 gcGB and 22 GB samples were analyzed at the DNA and mRNA levels. No mutations in the Aurora B gene (AURKB) were found, but its mRNA and protein levels were significantly higher in gcGB than in GB. Fifty-nine percent of gcGB samples but only 18% of the GB samples showed p53 mutations. Ectopic overexpression of Aurora B induced a significant increase inthe proportion of multinucleated cells in p53 mutant U373-MG, but not in p53 wild-type U87-MG, glioma cells. RNAi of p53 in U87-MG cells led to an increase in the fraction of multinucleated cells that was further augmented by ectopic overexpression of Aurora B. These results suggest that loss of p53 function and dysregulated Aurora B protein levels might represent factors that drive the development of multinucleated cells in gcGB.

Survivin safeguards chromosome numbers and protects from aneuploidy independently from p53.

BackgroundSurvivin, a member of the inhibitor of apoptosis (IAP) gene family, has a dual role in mitosis and in apoptosis. It is abundantly expressed in every human tumor, compared with normal tissues. During mitosis Survivin assembles with the chromosomal passenger complex and regulates chromosomal segregation. Here, we aim to explore whether interference with the mitotic function of Survivin is linked to p53-mediated G1 cell cycle arrest and affects chromosomal stability.MethodsIn this study, we used HCT116, SBC-2, and U87-MG and generated corresponding isogenic p53-deficient cells. Retroviral vectors were used to stably knockdown Survivin. The resulting phenotype, in particular the mechanisms of cell cycle arrest and of initiation of aneuploidy, were investigated by Western Blot analysis, confocal laser scan microscopy, proliferation assays, spectral karyotyping and RNAi.ResultsIn all cell lines Survivin-RNAi did not induce instant apoptosis but caused polyplodization irrespective of p53 status. Strikingly, polyploidization after knockdown of Survivin resulted in merotelic kinetochore spindle assemblies, γH2AX-foci, and DNA damage response (DDR), which was accompanied by a transient p53-mediated G1-arrest. That p53 wild type cells specifically arrest due to DNA damage was shown by simultaneous inhibition of ATM and DNA-PK, which abolished induction of p21waf/cip. Cytogenetic analysis revealed chromosomal aberrations indicative for DNA double strand break repair by the mechanism of non-homologous end joining (NHEJ), only in Survivin-depleted cells.ConclusionOur findings suggest that Survivin plays an essential role in proper amphitelic kinetochore-spindle assembly and that constraining Survivin’s mitotic function results in polyploidy and aneuploidy which cannot be controlled by p53. Therefore, Survivin critically safeguards chromosomal stability independently from p53.

Optical Analysis of Glioma: Fourier-Transform Infrared Spectroscopy Reveals the IDH1 Mutation Status

Purpose: Somatic mutations in the human cytosolic isocitrate dehydrogenase 1 (IDH1) gene cause profound changes in cell metabolism and are a common feature of gliomas with unprecedented predictive and prognostic impact. Fourier-transform infrared (FT-IR) spectroscopy addresses the molecular composition of cells and tissue and was investigated to deduct the IDH1 mutation status. Experimental Design: We tested the technique on human cell lines that were transduced with wild-type IDH1 or mutated IDH1 and on 34 human glioma samples. IR spectra were acquired at 256 positions from cell pellets or tissue cryosections. Moreover, IR spectra were obtained from fresh, unprocessed biopsies of 64 patients with glioma. Results: IDH1 mutation was linked to changes in spectral bands assigned to molecular groups of lipids and proteins in cell lines and human glioma. The spectra of cryosections of brain tumor samples showed high interpatient variability, for example, bands related to calcifications at 1113 cm−1. However, supervised classification recognized relevant spectral regions at 1103, 1362, 1441, 1485, and 1553 cm−1 and assigned 88% of the tumor samples to the correct group. Similar spectral positions allowed the classification of spectra of fresh biopsies with an accuracy of 86%. Conclusions: Here, we show that vibrational spectroscopy reveals the IDH1 genotype of glioma. Because it can provide information in seconds, an implementation into the intraoperative workflow might allow simple and rapid online diagnosis of the IDH1 genotype. The intraoperative confirmation of IDH1 mutation status might guide the decision to pursue definitive neurosurgical resection and guide future in situ therapies of infiltrative gliomas. Clin Cancer Res; 24(11); 2530–8. ©2017 AACR. See related commentary by Hollon and Orringer, p. 2467

Chromosomal instability induced by increased BIRC5/Survivin levels affects tumorigenicity of glioma cells

BackgroundSurvivin, belonging to the inhibitor of apoptosis (IAP) gene family, is abundantly expressed in tumors. It has been hypothesized that Survivin facilitates carcinogenesis by inhibition of apoptosis resulting in improved survival of tumorigenic progeny. Additionally, Survivin plays an essential role during mitosis. Together with its molecular partners Aurora B, Borealin and inner centromere protein it secures bipolar chromosome segregation. However, whether increased Survivin levels contribute to progression of tumors by inducing chromosomal instability remains unclear.MethodsWe overexpressed Survivin in U251-MG, SVGp12, U87-MG, HCT116 and p53-deficient U87-MGshp53 and HCT116p53−/− cells. The resulting phenotype was investigated by FACS-assisted cell cycle analysis, Western Blot analysis, confocal laser scan microscopy, proliferation assays, spectral karyotyping and in a U251-MG xenograft model using immune-deficient mice.ResultsOverexpression of Survivin affected cells with knockdown of p53, cells harboring mutant p53 and SV40 large T antigen, respectively, resulting in the increase of cell fractions harboring 4n and >4n DNA contents. Increased γH2AX levels, indicative of DNA damage were monitored in all Survivin-transduced cell lines, but only in p53 wild type cells this was accompanied by an attenuated S-phase entry and activation of p21waf/cip. Overexpression of Survivin caused a DNA damage response characterized by increased appearance pDNA-PKcs foci in cell nuclei and elevated levels of pATM S1981 and pCHK2 T68. Additionally, evolving structural chromosomal aberrations in U251-MG cells transduced with Survivin indicated a DNA-repair by non-homologous end joining recombination. Subcutaneous transplantation of U251-MG cells overexpressing Survivin and mycN instead of mycN oncogene alone generated tumors with shortened latency and decreased apoptosis. Subsequent SKY-analysis of Survivin/mycN-tumors revealed an increase in structural chromosomal aberrations in cells when compared to mycN-tumors.ConclusionsOur data suggest that increased Survivin levels promote adaptive evolution of tumors through combining induction of genetic heterogeneity with inhibition of apoptosis.

Janus face-like effects of Aurora B inhibition: antitumoral mode of action versus induction of aneuploid progeny

The mitotic Aurora B kinase is overexpressed in tumors and various inhibitors for Aurora B are currently under clinical assessments. However, when considering Aurora B kinase inhibitors as anticancer drugs, their mode of action and the role of p53 status as a possible predictive factor for response still needs to be investigated. In this study, we analyzed the effects of selective Aurora B inhibition using AZD1152-HQPA/Barasertib (AZD1152) on HCT116 cells, U87-MG, corresponding isogenic p53-deficient cells and a primary glioblastoma cell line. AZD1152 treatment caused polyploidy and non-apoptotic cell death in all cell lines irrespective of p53 status and was accompanied by poly-merotelic kinetochore-microtubule attachments and DNA damage. In p53 wild-type cells a DNA damage response induced an inefficient pseudo-G1 cell cycle arrest, which was not able to halt ongoing endoreplication of cells. Of note, release of tumor cells from AZD1152 resulted in recovery of aneuploid progenies bearing numerical and structural chromosomal aberrations. Yet, AZD1152 treatment enhanced death receptor TRAIL-R2 levels in all tumor cell lines investigated. A concomitant increase of the activating natural killer (NK) cell ligand MIC A/B in p53-deficient cells and an induction of FAS/CD95 in cells containing p53 rendered AZD1152-treated cells more susceptible for NK-cell-mediated lysis. Our study mechanistically explains a p53-independent mode of action of a chemical Aurora B inhibitor and suggests a potential triggering of antitumoral immune responses, following polyploidization of tumor cells, which might constrain recovery of aneuploid tumor cells.

Radiation-Induced RhoGDIβ Cleavage Leads to Perturbation of Cell Polarity: A Possible Link to Cancer Spreading

The equilibrium between proliferation and apoptosis is tightly balanced to maintain tissue homeostasis in normal tissues and even in tumors. Achieving and maintaining such a balance is important for cancer regrowth and spreading after cytotoxic treatments. Caspase‐3 activation and tumor cell death following anticancer therapy as well as accompanying cell death pathways are well characterized, but their association to homeostasis of cancerous tissue and tumor progression remains poorly understood. Here we proposed a novel mechanism of cancer spreading induced by caspase‐3. RhoGDIβ, known as a direct cleavage substrate of caspase‐3, is overexpressed in many epithelial cancers. The N‐terminal‐truncated RhoGDIβ (ΔN‐RhoGDIβ) is accumulated in caspase‐3‐activated cells. Stable expression of ΔN‐RhoGDIβ in HeLa cells did not induce apoptosis, but impaired directional cell migration in a wound‐healing assay accompanied by a perturbed direction of cell division at the wound edge. Subcellular protein fractionation experiments revealed that ΔN‐RhoGDIβ but not wild‐type RhoGDIβ was present in the detergent‐soluble cytoplasmic and nuclear fractions and preferentially associated with Cdc42. Furthermore, Cdc42 activity was constitutively inhibited by stable expression of ΔN‐RhoGDIβ, resulting in increased radiation‐induced compensatory proliferation linking to RhoA activation. Thus, ΔN‐RhoGDIβ dominant‐negatively regulates Cdc42 activity and contributes to loss of polarity‐related functions. The caspase‐3‐cleaved RhoGDIβ is a possible determinant to promote cancer spreading due to deregulation of directional organization of tumor cell population and inhibition of default equilibrium between proliferation and apoptosis after cytotoxic damage. J. Cell. Physiol. 231: 2493–2505, 2016.

Abstract LB-308: Effects of the IDH1 R132H mutation on redox status and metabolism are cell type dependent but independent from D-2-hydroxyglutarate accumulation

IDH1 R132H mutations are considered to play a key role in the development of low grade gliomas and therefrom derived secondary glioblastomas (GBM). Wild type IDH1 converts isocitrate to α-ketoglutarate (a-KG) while reducing NADP+. IDH1R132H has a neomorphic enzymatic function using a-KG to generate high amounts of the oncometabolite D-2-hydroxyglutarate (D-2-HG). While the effects of D-2-HG have been subject to intense research, D-2-HG independent effects of IDH1R132H on energy homeostasis and redox status are not well studied. Here we demonstrate that IDH1R132H transduction but not D-2-HG alone leads to significantly decreased Krebs cycle metabolite concentrations and proliferation in U87 and the primary GBM cell line HT7606 as well as in immortalized astrocytes SVGp12. Furthermore, IDH1R132H mutation, but not D-2-HG treatment, resulted in a significant drop in NADPH levels in tumor cells (U87 and HT7606), whereas immortalized astrocytes retained normal NADPH levels. Since NAPDH levels can be restored via the reaction of the NAD-kinase, we analyzed NAD levels and enzymes involved in NAD-synthesis in our cell lines. Indeed we found a significant drop of NAD levels and in the activity of the NAD-dependent enzyme sirtuin in IDH1R132H mutant U87 and HT7606 but not in NADPH stable SVGp12-IDH1R132H. Interestingly, there were marked differences in expression of NAD-synthesis enzymes between the different cell-lines. In particular, NAMPT-levels were much higher in U87 and HT7606 then in astrocytes (SVGp12) and significantly decreased in U87-IDH1R132H and HT7606-IDH1R132H. Importantly, we also found decreased levels of NAMPT in primary tumor tissues and patient derived glioma cell lines with IDH1 R132H compared to wild type gliomas. Altogether our results for the first time show that the IDH1 mutation directly affects energy homeostasis and redox status in a cell-type dependent manner. We hypothesize that this leads to a drop in NADPH and NAD-levels during malignant progression, resulting in a disadvantage for proliferating tumor cells. This is in line with the favorable prognosis and good response to chemo- and radiation therapy clinically observed in IDH-mutated gliomas. Our findings suggest that the impaired metabolism in IDH1-mutant tumors might be a promising target for future therapies. Citation Format: Evelin Schrock, Julia Biedermann, Khalil Abou-El-Ardat, Matthias Lehmann, Marina Conde, Mirko Peitzsch, Susan Richter, Ralf Wiedemuth, Matthias Meinhardt, William P. J. Leenders, Christel Herold-Mende, Graeme Eisenhofer, Simone P. Niclou, Leoni Kunz-Schughart, Achim Temme, Barbara Klink. Effects of the IDH1 R132H mutation on redox status and metabolism are cell type dependent but independent from D-2-hydroxyglutarate accumulation. [abstract]. In: Proceedings of the 107th Annual Meeting of the American Association for Cancer Research; 2016 Apr 16-20; New Orleans, LA. Philadelphia (PA): AACR; Cancer Res 2016;76(14 Suppl):Abstract nr LB-308.

MPTH-11ANAPLASTIC MENINGIOMAS WHO GRADE III LACK OF SOMATIC AKT1-MUTATIONS AND SHOW AN OVEREXPRESSION OF EGF-RECEPTORS

BACKGROUND: The AKT1 mutation was newly described in a subset of meningiomas and inhibitors of this mutation have shown promise in clinical trials in multiple cancer types. We sought to determine the frequency of the AKT1 mutation as well as the expression level of multiple growth factor receptors in a large series of patients with Anaplastic meningiomas (AM) WHO °III. METHODS: Patients with AM °III were tested for the AKT1 (E17K) mutation using PCR technique. Additionally, the expression level of the epidermal growth factor receptor (EGFR), the platelet derived growth factor receptor 1alpha (PDGFR) and the vascular endothelial growth factor receptor (VEGFR) was detected by immunohistochemistry (IHC) using the indirect peroxidase technique on tissue multi arrays (TMA) of paraffin-embedded specimens. Staining was evaluated using a semi-quantitative scoring system. Chi-square test was used for statistical evaluation. RESULTS: We identified 22 AM °III patients with 45 tumors (median follow-up of 8 years). None of the examined 45 tumor samples in this cohort showed an AKT1 mutation (0%). Regarding the IHC, recurrent AM showed increasing proliferation with each recurrence. Overexpression of EGFR was associated with malignancy (p < 0.01) and increased with recurrence (median score 2.3). The median overall survival rate for patients with EGFR overexpression was 2.2 years. In contrast, the overall survival of patients with low EGFR expression was not reached yet (p < 0.05). While PDGFR and VEGFR scores were high in malignant tumors, the difference in comparison with benign meningiomas was not significant. A further finding is a marked survival benefit in our patients cohort in respect to the extent of resection when repeated operations were performed (p = 0.025). CONCLUSIONS: Somatic AKT1 mutations are absent in anaplastic meningiomas WHO grade III. Additionally, our data demonstrate that the overexpression of EGFR in AM might make this receptor valuable as a therapeutic target for their treatment.