Annette Künkele

Targeted Expression of Mutated ALK Induces Neuroblastoma in Transgenic Mice

ALK inhibitors induce complete tumor regression in a mouse model of ALK-driven neuroblastoma. Driving Neuroblastoma: A wALK in the Park Correlation doesn’t prove causation. For example, even though you may always see your neighbors walking their dog right before you find that odiferous pile of unscooped pooh, unless you directly witness a walkaway or use DNA testing to trace the culprit, you can’t prove that they did it. Demonstrating causation is even more important in cancer biology—just finding a prevalent mutation in people with a particular type of cancer isn’t enough to show that mutation is actually relevant to disease. Heukamp et al. now address the potential causative role of anaplastic lymphoma kinase (ALK) mutations in neuroblastoma. ALK mutations are found in most familial and some sporadic cases of neuroblastoma, a malignant tumor that affects children. To determine whether ALK mutations can drive the development of neuroblastoma, the authors introduced the most common ALK mutation into neural crest stem cells in mice. Tumors driven by this mutation resembled human neuroblastomas physiologically and mimicked the genetic structure of the disease. Mutated ALK and MYCN, another driver mutation for neuroblastoma, combined synergistically for tumor development. Heukamp et al. then used their new model to demonstrate that an ALK inhibitor currently in preclinical testing induced complete tumor regression in these mice; however, it remains to be seen whether these inhibitors will be useful in treating neuroblastoma in people. Activating anaplastic lymphoma kinase (ALK) mutations were recently detected in most familial and 10% of sporadic neuroblastomas. However, the role of mutated ALK in tumorigenesis remains elusive. We demonstrate that targeted expression of the most frequent and aggressive variant, ALKF1174L, is tumorigenic in mice. Tumors resembled human neuroblastomas in morphology, metastasis pattern, gene expression, and the presence of neurosecretory vesicles as well as synaptic structures. This ALK-driven neuroblastoma mouse model precisely recapitulated the genetic spectrum of the disease. Chromosomal aberrations were syntenic to those in human neuroblastoma, including 17q gain and MYCN oncogene amplification. Targeted ALKF1174L and MYCN coexpression revealed a strong synergism in inducing neuroblastoma with minimal chromosomal aberrations, suggesting that fewer secondary hits are required for tumor induction if both oncoproteins are targeted. Treatment of ALKF1174L transgenic mice with the ALK inhibitor TAE-684 induced complete tumor regression, indicating that tumor cells were addicted to ALKF1174L activity. We conclude that an activating mutation within the ALK kinase domain is sufficient to induce neuroblastoma development, and ALK inhibitors show promise for treating human neuroblastomas harboring ALK mutations.

MYCN and ALKF1174L are sufficient to drive neuroblastoma development from neural crest progenitor cells

Neuroblastoma is an embryonal tumor with a heterogeneous clinical course. The tumor is presumed to be derived from the neural crest, but the cells of origin remain to be determined. To date, few recurrent genetic changes contributing to neuroblastoma formation, such as amplification of the MYCN oncogene and activating mutations of the ALK oncogene, have been identified. The possibility to model neuroblastoma in mice allows investigation of the cell of origin hypothesis in further detail. Here we present the evidence that murine neural crest progenitor cells can give rise to neuroblastoma upon transformation with MYCN or ALKF1174L. For this purpose we used JoMa1, a multipotent neural crest progenitor cell line, which is kept in a viable and undifferentiated state by a tamoxifen-activated c-Myc transgene (c-MycERT). Expression of MYCN or ALKF1174L, one of the oncogenic ALK variants identified in primary neuroblastomas, enabled these cells to grow independently of c-MycERT activity in vitro and caused formation of neuroblastoma-like tumors in vivo in contrast to parental JoMa1 cells and JoMa1 cells-expressing TrkA or GFP. Tumorigenicity was enhanced upon serial transplantation of tumor-derived cells, and tumor cells remained susceptible to the MYC-inhibitor, NBT-272, indicating that cell growth depended on functional MYCN. Our findings support neural crest progenitor cells as the precursor cells of neuroblastoma, and indicate that neuroblastomas arise as their malignant progeny.

Functional Tuning of CARs Reveals Signaling Threshold above Which CD8+ CTL Antitumor Potency Is Attenuated due to Cell Fas–FasL-Dependent AICD

Künkele and colleagues demonstrate in a solid tumor model that CARs with the highest in vitro activity exhibit attenuated antitumor potency in vivo as CTLs expressing hyperactive CARs are susceptible to activation-induced cell death; CARs tuned for moderate signaling outputs mediate effective tumor eradication. Chimeric antigen receptor (CAR) development is biased toward selecting constructs that elicit the highest magnitude of T-cell functional outputs. Here, we show that components of CAR extracellular spacer and cytoplasmic signaling domain modulate, in a cooperative manner, the magnitude of CD8+CTL activation for tumor-cell cytolysis and cytokine secretion. Unexpectedly, CAR constructs that generate the highest in vitro activity, either by extracellular spacer length tuning or by the addition of cytoplasmic signaling modules, exhibit attenuated antitumor potency in vivo, whereas CARs tuned for moderate signaling outputs mediate tumor eradication. Recursive CAR triggering renders CTLs expressing hyperactive CARs highly susceptible to activation-induced cell death (AICD) as a result of augmented FasL expression. CAR tuning using combinations of extracellular spacers and cytoplasmic signaling modules, which limit AICD of CD8+CTLs, may be a critical parameter for achieving clinical activity against solid tumors. Cancer Immunol Res; 3(4); 368–79. ©2015 AACR.

Pharmacological activation of the p53 pathway by nutlin-3 exerts anti-tumoral effects in medulloblastomas

Medulloblastomas account for 20% of pediatric brain tumors. With an overall survival of 40%-70%, their treatment is still a challenge. The majority of medulloblastomas lack p53 mutations, but even in cancers retaining wild-type p53, the tumor surveillance function of p53 is inhibited by the oncoprotein MDM2. Deregulation of the MDM2/p53 balance leads to malignant transformation. Here, we analyzed MDM2 mRNA and protein expression in primary medulloblastomas and normal cerebellum and assessed the mutational status of p53 and MDM2 expression in 6 medulloblastoma cell lines. MDM2 expression was elevated in medulloblastomas, compared with cerebellum. Four of 6 medulloblastoma cell lines expressed wild-type p53 and high levels of MDM2. The tumor-promoting p53-MDM2 interaction can be inhibited by the small molecule, nutlin-3, restoring p53 function. Targeting the p53-MDM2 axis using nutlin-3 significantly reduced cell viability and induced either cell cycle arrest or apoptosis and expression of the p53 target gene p21 in these 4 cell lines. In contrast, DAOY and UW-228 cells harboring TP53 mutations were almost unaffected by nutlin-3 treatment. MDM2 knockdown in medulloblastoma cells by siRNA mimicked nutlin-3 treatment, whereas expression of dominant negative p53 abrogated nutlin-3 effects. Oral nutlin-3 treatment of mice with established medulloblastoma xenografts inhibited tumor growth and significantly increased survival. Thus, nutlin-3 reduced medulloblastoma cell viability in vitro and in vivo by re-activating p53 function. We suggest that inhibition of the MDM2-p53 interaction with nutlin-3 is a promising therapeutic option for medulloblastomas with functional p53 that should be further evaluated in clinical trials.

The KDM1A histone demethylase is a promising new target for the epigenetic therapy of medulloblastoma.

BackgroundMedulloblastoma is a leading cause of childhood cancer-related deaths. Current aggressive treatments frequently lead to cognitive and neurological disabilities in survivors. Novel targeted therapies are required to improve outcome in high-risk medulloblastoma patients and quality of life of survivors. Targeting enzymes controlling epigenetic alterations is a promising approach recently bolstered by the identification of mutations in histone demethylating enzymes in medulloblastoma sequencing efforts. Hypomethylation of lysine 4 in histone 3 (H3K4) is also associated with a dismal prognosis for medulloblastoma patients. Functional characterization of important epigenetic key regulators is urgently needed.ResultsWe examined the role of the H3K4 modifying enzyme, KDM1A, in medulloblastoma, an enzyme also associated with malignant progression in the closely related tumor, neuroblastoma. Re-analysis of gene expression data and immunohistochemistry of tissue microarrays of human medulloblastomas showed strong KDM1A overexpression in the majority of tumors throughout all molecular subgroups. Interestingly, KDM1A knockdown in medulloblastoma cell lines not only induced apoptosis and suppressed proliferation, but also impaired migratory capacity. Further analyses revealed bone morphogenetic protein 2 (BMP2) as a major KDM1A target gene. BMP2 is known to be involved in development and differentiation of granule neuron precursor cells (GNCPs), one potential cell of origin for medulloblastoma. Treating medulloblastoma cells with the specific KDM1A inhibitor, NCL-1, significantly inhibited growth in vitro.ConclusionWe provide the first evidence that a histone demethylase is functionally involved in the regulation of the malignant phenotype of medulloblastoma cells, and lay a foundation for future evaluation of KDM1A-inihibiting therapies in combating medulloblastoma.

Long-term follow-up of pediatric patients receiving total body irradiation before hematopoietic stem cell transplantation and post-transplant survival of >2 years.

Total body irradiation (TBI) treatment eradicates malignant cells and suppresses the immune system before hematopoietic stem cell transplantation (HSCT). The radiation dose is limited by its toxicity to healthy organs. Many reports describe long‐term sequelae from TBI in adults, but comparable data for pediatric patients are scarce.

MiR-34a deficiency accelerates medulloblastoma formation in vivo.

Previous studies have evaluated the role of miRNAs in cancer initiation and progression. MiR‐34a was found to be downregulated in several tumors, including medulloblastomas. Here we employed targeted transgenesis to analyze the function of miR‐34a in vivo. We generated mice with a constitutive deletion of the miR‐34a gene. These mice were devoid of mir‐34a expression in all analyzed tissues, but were viable and fertile. A comprehensive standardized phenotypic analysis including more than 300 single parameters revealed no apparent phenotype. Analysis of miR‐34a expression in human medulloblastomas and medulloblastoma cell lines revealed significantly lower levels than in normal human cerebellum. Re‐expression of miR‐34a in human medulloblastoma cells reduced cell viability and proliferation, induced apoptosis and downregulated the miR‐34a target genes, MYCN and SIRT1. Activation of the Shh pathway by targeting SmoA1 transgene overexpression causes medulloblastoma in mice, which is dependent on the presence and upregulation of Mycn. Analysis of miR‐34a in medulloblastomas derived from ND2:SmoA1(tg) mice revealed significant suppression of miR‐34a compared to normal cerebellum. Tumor incidence was significantly increased and tumor formation was significantly accelerated in mice transgenic for SmoA1 and lacking miR‐34a. Interestingly, Mycn and Sirt1 were strongly expressed in medulloblastomas derived from these mice. We here demonstrate that miR‐34a is dispensable for normal development, but that its loss accelerates medulloblastomagenesis. Strategies aiming to re‐express miR‐34a in tumors could, therefore, represent an efficient therapeutic option.

Chemoreduction improves eye retention in patients with retinoblastoma: a report from the German Retinoblastoma Reference Centre.

Background Retinoblastoma is the most common intraocular childhood tumour. Although mortality is low in Western countries, long-term sequelae, including secondary tumours, compromised vision or loss of one or both eyes are common. Chemoreduction combined with focal treatment is currently the leading conservative treatment for retinoblastoma, with success rates of 50–75% reported. We assessed a new chemoreduction protocol using intravenous cyclophosphamide with reduced dose of carboplatin on eye retention in patients with retinoblastoma. Procedure The 40 patients with retinoblastomas in 56 eyes were treated between 1995 and 2004 at the German Retinoblastoma Reference Centre Essen. The 6-cycle chemotherapy used vincristine (days 1, 22, 43, 64, 85, 106), etoposide (days 22, 43, 85, 106), carboplatin (days 1, 43, 64, 106), and cyclophosphamide (days 1, 22, 64, 85). Mean follow-up was 101 months. Most patients received additional hyperthermia, some received local treatment with laser coagulation, cryotherapy and/or β-ray brachytherapy. Therapy failure was defined as progression requiring enucleation or external beam radiotherapy (EBRT). Results Primary chemotherapy was successful in 42 of 56 eyes (75%). Therapy success and visual acuity at age 6 years correlated with the International Classification of Retinoblastoma (ICRB) group. Age at diagnosis (> or <6 months) correlated with relapse, but not with therapy failure or visual acuity at 6 years of age. ICRB group did not correlate with occurrence of relapse. Conclusions In this retrospective single-centre study, chemoreduction, including cyclophosphamide, with or without focal treatment, effectively controlled retinoblastoma progression without requiring enucleation or EBRT. Addition of cyclophosphamide is safe, and allows reduction of carboplatin.

Preclinical Assessment of CD171-Directed CAR T Cell Adoptive Therapy For Childhood Neuroblastoma: CE7 Epitope Target Safety and Product Manufacturing Feasibility

Purpose: The identification and vetting of cell surface tumor-restricted epitopes for chimeric antigen receptor (CAR)–redirected T-cell immunotherapy is the subject of intensive investigation. We have focused on CD171 (L1-CAM), an abundant cell surface molecule on neuroblastomas and, specifically, on the glycosylation-dependent tumor-specific epitope recognized by the CE7 monoclonal antibody. Experimental Design: CD171 expression was assessed by IHC using CE7 mAb in tumor microarrays of primary, metastatic, and recurrent neuroblastoma, as well as human and rhesus macaque tissue arrays. The safety of targeting the CE7 epitope of CD171 with CE7-CAR T cells was evaluated in a preclinical rhesus macaque trial on the basis of CD171 homology and CE7 cross reactivity. The feasibility of generating bioactive CAR T cells from heavily pretreated pediatric patients with recurrent/refractory disease was assessed. Results: CD171 is uniformly and abundantly expressed by neuroblastoma tumor specimens obtained at diagnoses and relapse independent of patient clinical risk group. CD171 expression in normal tissues is similar in humans and rhesus macaques. Infusion of up to 1 × 108/kg CE7-CAR+ CTLs in rhesus macaques revealed no signs of specific on-target off-tumor toxicity. Manufacturing of lentivirally transduced CD4+ and CD8+ CE7-CAR T-cell products under GMP was successful in 4 out of 5 consecutively enrolled neuroblastoma patients in a phase I study. All four CE7-CAR T-cell products demonstrated in vitro and in vivo antitumor activity. Conclusions: Our preclinical assessment of the CE7 epitope on CD171 supports its utility and safety as a CAR T-cell target for neuroblastoma immunotherapy. Clin Cancer Res; 23(2); 466–77. ©2016 AACR.

Neoadjuvant/adjuvant treatment of high-risk retinoblastoma: a report from the German Retinoblastoma Referral Centre

Background Retinoblastoma can extend beyond the structures of the eye, where cells can enter the bloodstream and cause metastases. Various types of protocols for adjuvant treatment risk-adapted according to histopathological risk factors are used worldwide. Methods Between 1997 and 2009, 420 children were diagnosed with retinoblastoma at the German Retinoblastoma Referral Centre and risk factors were assessed. Patients with post-laminar optic nerve infiltration or choroid or minor scleral invasion received six courses of adjuvant chemotherapy using vincristine, etoposide, carboplatin and cyclophosphamide (group 1). Patients with microscopic extension beyond the sclera to the resection margin of the optic nerve or potential spread due to vitrectomy received chemotherapy plus orbital radiotherapy (group 2). Neoadjuvant chemotherapy was performed in patients with local extraocular invasion detected on MRI. Results Following this protocol, 42 of the 420 patients and 21 referred from other centres showed high-risk histopathological factors qualifying for adjuvant therapy (57 in group 1 and 6 in group 2). Seven of the 63 patients received neoadjuvant and adjuvant treatment. During a mean follow-up of 5.8 (range 0.4–15.4) years, one of six patients in group 2 developed metastases and died. No patients died from toxicity. The 5-year overall survival was 100% for group 1 and 80% for group 2. Conclusions This retrospective single-site study reveals a 10% incidence of high-risk features in children with retinoblastoma diagnosed at the German Retinoblastoma Referral Centre. Overall survival rates of 98.3% underline the safety of this adjuvant chemotherapy protocol and its efficiency in preventing metastasis.