Lisandra Muñoz scite author profile

Despite advances in multimodal therapy, neuroblastomas with hemizygous deletion in chromosome 11q (20%-30%) undergo consecutive recurrences with poor outcome. We hypothesized that patients with 11q-loss may share a druggable molecular target(s) that can be exploited for a precision medicine strategy to improve treatment outcome. SNP arrays were combined with next-generation sequencing (NGS) to precisely define the deleted region in 17 primary 11q-loss neuroblastomas and identify allelic variants in genes relevant for neuroblastoma etiology. We assessed PARP inhibitor olaparib in combination with other chemotherapy medications using both and models. We detected that haploinsufficiency and allelic variants are common genetic hallmarks of 11q-loss neuroblastomas. On the basis of the distinct DNA repair pathways triggered by ATM and PARP, we postulated that 11q-loss may define a subgroup of neuroblastomas with higher sensitivity to PARP inhibitors. Noteworthy, concomitant treatment with olaparib and DNA alkylating agent temozolomide potently inhibited growth of cell lines harboring 11q-loss. This drug synergism was less potent when temozolomide was exchanged for cisplatin or irinotecan. Intact 11q cells concomitantly treated with ATM inhibitor displayed growth arrest and enhanced apoptosis, revealing a role for ATM in the mechanism that mediates sensitivity to temozolomide-olaparib. Interestingly, functional TP53 is required for efficacy of this treatment. In an model, coadministration of temozolomide-olaparib resulted in sustained xenograft regression. Our findings reveal a potent synergism between temozolomide and olaparib in treatment of neuroblastomas with 11q-loss and provide a rationale for further clinical investigation. .

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Autophagy inhibition as a promising therapeutic target for laryngeal cancer

García-Mayea

Mir

Muñoz

et al. 2019

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miR‐200c and phospho‐AKT as prognostic factors and mediators of osteosarcoma progression and lung metastasis

et al. 2016

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Lung metastasis is the major cause of death in osteosarcoma patients. However, molecular mechanisms underlying this metastasis remain poorly understood. To identify key molecules related with pulmonary metastasis of pediatric osteosarcomas, we analyzed high‐throughput miRNA expression in a cohort of 11 primary tumors and 15 lung metastases. Results were further validated with an independent cohort of 10 primary tumors and 6 metastases. In parallel, we performed immunohistochemical analysis of activated signaling pathways in 36 primary osteosarcomas. Only phospho‐AKT associated with lower overall survival in primary tumors, supporting its role in osteosarcoma progression. CTNNB1 expression also associated with lower overall survival but was not strong enough to be considered an independent variable. Interestingly, miR‐200c was overexpressed in lung metastases, implicating an inhibitory feed‐back loop to PI3K‐AKT. Moreover, transfection of miR200c‐mimic in U2‐OS cells reduced phospho‐AKT levels but increased cellular migration and proliferation. Notably, miR‐200c expression strongly correlated with miR‐141 and with the osteogenic inhibitor miR‐375, all implicated in epithelial to mesenchymal transition. These findings contrast epithelial tumors where reduced miR‐200c expression promotes metastasis. Indeed, we noted that osteosarcoma cells in the lung also expressed the epithelial marker CDH1, revealing a change in their mesenchymal phenotype. We propose that miR‐200c upregulation occurs late in osteosarcoma progression to provide cells with an epithelial phenotype that facilitates their integration in the metastatic lung niche. Thus, our findings identify phospho‐AKT in the primary tumor and miR‐200c later during tumor progression as prognostic molecules and potential therapeutic targets to prevent progression and metastasis of pediatric osteosarcomas.

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Supplementary Figure 4 from Deletion of 11q in Neuroblastomas Drives Sensitivity to PARP Inhibition

Sanmartín¹,

Muñoz²,

Piqueras³

et al. 2023

Preprint

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Lisandra Muñoz

Deletion of 11q in Neuroblastomas Drives Sensitivity to PARP Inhibition

Autophagy inhibition as a promising therapeutic target for laryngeal cancer

miR‐200c and phospho‐AKT as prognostic factors and mediators of osteosarcoma progression and lung metastasis

Supplementary Figure 4 from Deletion of 11q in Neuroblastomas Drives Sensitivity to PARP Inhibition

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