ABSTRACT
Purpose: Although there have been improvements in the management of metastatic retinoblastoma, most patients do not survive, and all patients suffer from multiple short- and long-term treatment toxicities. Reliable and informative models to assist clinicians are needed. Thus we developed and comprehensively characterized a novel preclinical platform of primary cell cultures and xenograft models of metastatic retinoblastoma to provide insights into the molecular biology underlying metastases and to perform drug screening for the identification of hit candidates with the highest potential for clinical translation. Methods: Orbital tumor, bone marrow, cerebrospinal fluid, and lymph node tumor infiltration specimens were obtained from seven patients with metastatic retinoblastoma at diagnosis, disease progression, or relapse. Tumor specimens were engrafted in immunodeficient animals, and primary cell lines were established. Genomic, immunohistochemical/immunocytochemical, and pharmacological analysis were performed. Results: We successfully established five primary cell lines: two derived from leptomeningeal, two from orbital, and one from lymph node tumor dissemination. After the intravitreal or intraventricular inoculation of these cells, we established cell-derived xenograft models. Both primary cell lines and xenografts accurately retained the histological and genomic features of the tumors from which they were derived and faithfully recapitulated the dissemination patterns and pharmacological sensitivity observed in the matched patients. Conclusions: Ours is an innovative and thoroughly characterized preclinical platform of metastatic retinoblastoma developed for the understanding of tumor biology of this highly aggressive tumor and has the potential to identify drug candidates to treat patients who currently lack effective treatment options.
Subject(s)
Retinal Neoplasms , Retinoblastoma , Animals , Humans , Retinoblastoma/drug therapy , Retinoblastoma/genetics , Neoplasm Recurrence, Local , Cell Line , Disease Models, Animal , Retinal Neoplasms/drug therapy , Retinal Neoplasms/geneticsABSTRACT
Most reports about copy number alterations (CNA) in retinoblastoma relate to patients with intraocular disease and features of children with extraocular relapse remain unknown, so we aimed to describe the CNA in this population. We evaluated 23 patients and 27 specimens from 4 centers. Seventeen cases had extraocular relapse after initial enucleation and six cases after an initial preservation attempt. We performed an analysis of CNA and BCOR gene alteration by SNP array (Single Nucleotide Polymorfism array), whole-exome sequencing, IMPACT panel and CGH array (Array-based comparative genomic hybridization). All cases presented CNA at a higher prevalence than those reported in previously published studies for intraocular cases. CNA previously reported for intraocular retinoblastoma were found at a high frequency in our cohort: gains in 1q (69.5%), 2p (60.9%) and 6p (86.9%), and 16q loss (78.2%). Other, previously less-recognized, CNA were found including loss of 11q (34.8%), gain of 17q (56.5%), loss of 19q (30.4%) and BCOR alterations were present in 72.7% of our cases. A high number of CNA including 11q deletions, 17q gains, 19q loss, and BCOR alterations, are more common in extraocular retinoblastoma. Identification of these features may be correlated with a more aggressive tumor warranting consideration for patient management.
ABSTRACT
An uncommon subgroup of unilateral retinoblastomas with highly aggressive histological features, lacking aberrations in RB1 gene with high-level amplification of MYCN (MCYNamplRB1+/+) has only been described as intra-ocular cases treated with initial enucleation. Here, we present a comprehensive clinical, genomic, and pharmacological analysis of two cases of MCYNamplRB1+/+ with orbital and cervical lymph node involvement, but no central nervous system spread, rapidly progressing to fatal disease due to chemoresistance. Both patients showed in common MYCN high amplification and chromosome 16q and 17p loss. A somatic mutation in TP53, in homozygosis by LOH, and high chromosomal instability leading to aneuploidy was identified in the primary ocular tumor and sites of dissemination of one patient. High-throughput pharmacological screening was performed in a primary cell line derived from the lymph node dissemination of one case. This cell line showed resistance to broad spectrum chemotherapy consistent with the patient's poor response but sensitivity to the synergistic effects of panobinostat-bortezomib and carboplatin-panobinostat associations. From these cells we established a cell line derived xenograft model that closely recapitulated the tumor dissemination pattern of the patient and served to evaluate whether triple chemotherapy significantly prolonged survival of the animals. We report novel genomic alterations in two cases of metastatic MCYNamplRB1+/+ that may be associated with chemotherapy resistance and in vitro/in vivo models that serve as basis for tailoring therapy in these cases.
ABSTRACT
Importance: Comprehensive understanding of the genomic and gene-expression differences between retinoblastoma tumors from patients with bilateral disease may help to characterize risk and optimize treatment according to individual tumor characteristics. Objective: To compare the genomic features between each eye and a specimen from an orbital relapse in patients with bilateral retinoblastoma. Design, Setting, and Participants: In this case, 2 patients with retinoblastoma underwent upfront bilateral enucleation. Tumor samples were subjected to genomic and gene-expression analysis. Primary cell cultures were established from both of the tumors of 1 patient and were used for gene-expression studies. Main Outcomes and Measures: Whole-exome sequencing was performed on an Illumina platform for fresh tumor samples and DNA arrays (CytoScan or OncoScan) were used for paraffin-embedded samples and cell lines. Gene-expression analysis was performed using Agilent microarrays. Germinal and somatic alterations, copy number alterations, and differential gene expression were assessed. Results: After initial bilateral enucleation, patient 1 showed massive choroidal and laminar optic nerve infiltration, while patient 2 showed choroidal and laminar optic nerve invasion. Patient 1 developed left-eye orbital recurrence and bone marrow metastasis less than 1 year after enucleation. Both ocular tumors showed gains on 1q and 6p but presented other distinct genomic alterations, including an additional gain in 2p harboring the N-myc proto-oncogene (MYCN) in the left tumor and orbital recurrence. Similar copy number alterations between the orbital recurrence and the left eye supported the origin of the relapse, with an additional 11q loss only detected in the orbital relapse. Specimens from patient 2 showed common copy number gains and losses, but further evolution rendered a 2p gain spanning MYCN in the left tumor. For this patient, microarray expression analysis showed differential expression of the MYCN and the forkhead box protein G1 (FOXG1) gene pathways between the left and right tumors. Conclusions and Relevance: Differential genomic and gene expression features were observed between tumors in 2 patients with bilateral disease, confirming intereye heterogeneity that might be considered if targeted therapies are used in such patients. Chromosomal alteration profile supported the origin of the orbital recurrence from the homolateral eye in 1 patient. Loss in chromosome 11q may have been associated with extraocular relapse in this patient.
Subject(s)
Gene Expression Regulation, Neoplastic/genetics , Genetic Heterogeneity , Genomics , Retinal Neoplasms/genetics , Retinoblastoma/genetics , Transcriptome , Cell Line, Tumor , DNA Copy Number Variations , DNA, Neoplasm/genetics , Eye Enucleation , High-Throughput Nucleotide Sequencing , Humans , Loss of Heterozygosity , Polymorphism, Single Nucleotide , Proto-Oncogene Mas , Retinal Neoplasms/pathology , Retinoblastoma/pathology , Exome SequencingABSTRACT
La crotoxina, el mayor componente tóxico del veneno de serpiente cascabel sudamericana Crotalus durissus terrificus, es una fosolipasa A2 neurotóxica que ejerce su acción bloqueando la transmisión neuromuscular. Actúa primariamente alterando la liberación de acetilcolina de las terminales nerviosas mediante un mecanismo todavía no elucidado. Actúa también en membranas postsinápticas estabilizando el receptor de acetilcolina en una configuración inactiva semejante al estado de desensibilización. La crotoxina comprende dos subnuidades distintas: una fosoflipasa A2 básica y débilmente tóxica (componente B) y una acídica y no tóxica (componente A) que no posee actividad enzimática. La subunidad de fosfolipasa A2 se une en forma inespecífica y no saturable a membranas biológicas, mientras que en presencia delo componente A interacciona solamente con un limitado número de sitios de unión de alta afinidad presentes en membranas sinápticas pero no en eritrocitos. Experimentos de unión realizados con vesículas fosfolipídicas unilamelares de diferente composición indicaron que algunos de los fosfolípidos cargados negativamente, como los mono y difosfoinositósidos, podrían ser parte del sitio aceptor de crotoxina. La crotoxina es en realidad una mexcla de diversas isoformas de estructura peptídica similar pero no idéntica. Estas isoformas difieren levemente en su actividad enzimática y farmacológica. Estudios realizados con anticuerpos policonales preparados contra ambas subunidades anticomponente B (Fab) inhiben la actividad fosfolipasa A2 y neutralizan la potencia letal, lo que sugiere que los sitios tóxicos y catalíticos de la crotoxina están relacionados