Project description:Retinoblastoma are childhood eye tumors arising from retinal precursor cells. Two distinct retinoblastoma subtypes with different clinical behavior have been described based on gene expression and methylation profiling. Using consensus clustering of DNA methylation analysis from retinoblastomas, we identified a MYCN-driven of subtype 2 retinoblastomas characterized by DNA hypomethylation and high expression of genes involved in protein synthesis. Subtype 2 retinoblastomas outside the MYCN-driven were characterized by high expression of genes from mesodermal development, including NKX2-5. Knockdown of MYCN expression in retinoblastoma cell models caused growth arrest and reactivated a subtype 1-specific photoreceptor signature. These molecular changes suggest that removing the driving force of MYCN oncogenic activity rescues molecular circuitry driving subtype 1 biology. The MYCN-RB gene signature generated from the cell models better identified MYCN-driven retinoblastoma than MYCN amplification and could identify cases that may benefit from MYCN-targeted therapy. MYCN drives tumor progression in a molecularly defined retinoblastoma subgroup, and inhibiting MYCN activity could restore a more differentiated and less aggressive tumor biology

Project description:Background Retinoblastoma is a pediatric eye cancer associated with RB1 loss or MYCN amplification (RB1+/+MYCNA). There are controversies concerning the existence of molecular subtypes within RB1-/- retinoblastoma. To test whether these molecular subtypes exist, we performed molecular profiling. Methods Genome-wide mRNA expression profiling was performed on 76 primary human retinoblastomas. Expression profiling was complemented by genome-wide DNA profiling and clinical, histopathological, and ex vivo drug sensitivity data. Findings RNA and DNA profiling identified major variability between retinoblastomas. While gene expression differences between RB1+/+MYCNA and RB1-/- tumors seemed more dichotomous, differences within the RB1-/- tumors were gradual. Tumors with high expression of a photoreceptor gene signature were highly differentiated, smaller in volume and diagnosed at younger age compared to tumors with low photoreceptor signature expression. Tumors with lower photoreceptor expression showed increased expression of genes involved in M-phase and mRNA and ribosome synthesis and increased frequencies of somatic copy number alterations. Interpretation Molecular, clinical and histopathological differences between RB1-/- tumors are best explained by tumor progression, reflected by a gradual loss of differentiation and photoreceptor expression signature. Since copy number alterations were more frequent in tumors with less photoreceptorness, genomic alterations might be drivers of tumor progression. Fresh frozen material from 76 primary human retinoblastoma samples were profiled with Affymetrix human genome u133 plus 2.0 PM microarray

Project description:Background Retinoblastoma is a pediatric eye cancer associated with RB1 loss or MYCN amplification (RB1+/+MYCNA). There are controversies concerning the existence of molecular subtypes within RB1-/- retinoblastoma. To test whether these molecular subtypes exist, we performed molecular profiling. Methods Genome-wide mRNA expression profiling was performed on 76 primary human retinoblastomas. Expression profiling was complemented by genome-wide DNA profiling and clinical, histopathological, and ex vivo drug sensitivity data. Findings RNA and DNA profiling identified major variability between retinoblastomas. While gene expression differences between RB1+/+MYCNA and RB1-/- tumors seemed more dichotomous, differences within the RB1-/- tumors were gradual. Tumors with high expression of a photoreceptor gene signature were highly differentiated, smaller in volume and diagnosed at younger age compared to tumors with low photoreceptor signature expression. Tumors with lower photoreceptor expression showed increased expression of genes involved in M-phase and mRNA and ribosome synthesis and increased frequencies of somatic copy number alterations. Interpretation Molecular, clinical and histopathological differences between RB1-/- tumors are best explained by tumor progression, reflected by a gradual loss of differentiation and photoreceptor expression signature. Since copy number alterations were more frequent in tumors with less photoreceptorness, genomic alterations might be drivers of tumor progression.

Project description:Background: Mutation of the RB1 gene is necessary but not sufficient for the development of retinoblastoma. The nature of events occurring subsequent to RB1 mutation is unclear, as is the retinal cell-of-origin of this tumour. Methods: Gene expression profiling of 21 retinoblastomas was carried out to identify genetic events that contribute to tumorigenesis and to obtain information about tumour histogenesis. Results: Expression analysis showed a clear separation of retinoblastomas into two groups. Group 1 retinoblastomas express genes associated with a range of different retinal cell types, suggesting derivation from a retinal progenitor cell type. Recurrent chromosomal alterations typical of retinoblastoma, for example, chromosome 1q and 6p gain and 16q loss were also a feature of this group, and clinically they were characterised by an invasive pattern of tumour growth. In contrast, group 2 retinoblastomas were found to retain many characteristics of cone photoreceptor cells and appear to exploit the high metabolic capacity of this cell type in order to promote tumour proliferation. Conclusion: Retinoblastoma is a heterogeneous tumour with variable biology and clinical characteristics. Kapatai, G et al. Br J Cancer (2013) 109, 512-525 doi: 10.1038/bjc.2013.283

Project description:Retinoblastoma is a childhood cancer of the developing retina that initiates with biallelic inactivation of the RB1 gene. To develop a laboratory model of human retinoblastoma formation, we made induced pluripotent stem cells (iPSCs) from 15 participants with germline RB1 mutations. After 45 days in culture, the retinal organoids were dissociated and injected into the vitreous of eyes of immunocompromised mice to support retinoblastoma tumor growth. Retinoblastomas formed from retinal organoids made from patient-derived iPSCs had molecular, cellular and genomic features indistinguishable from human retinoblastomas.

Project description:Retinoblastoma is a childhood cancer of the developing retina that initiates with biallelic inactivation of the RB1 gene. To develop a laboratory model of human retinoblastoma formation, we made induced pluripotent stem cells (iPSCs) from 15 participants with germline RB1 mutations. After 45 days in culture, the retinal organoids were dissociated and injected into the vitreous of eyes of immunocompromised mice to support retinoblastoma tumor growth. Retinoblastomas formed from retinal organoids made from patient-derived iPSCs had molecular, cellular and genomic features indistinguishable from human retinoblastomas.

Project description:MYCNOS (MYCN opposite strand) is co-amplified with MYCN in pediatric cancers including retinoblastoma. MYCNOS encodes several RNA variants whose functions have not been elucidated in retinoblastoma. Here, we attempted to decipher the role of MYCNOS variant 1 (MYCNOS1) on the activity of MYCN-amplified retinoblastoma. We observed that MYCNOS1 supports progression of retinoblastoma. Inhibition of MYCNOS1 expression may be needed to suppress MYCN activity when treating MYCN-amplified cancers without RB1 mutation.

Project description:The most frequent focal alterations in human retinoblastoma are RB mutation and MYCN amplification. Whether MYCN overexpression drives retinoblastoma has not been assessed in model systems. Here, we show that Rb inactivation collaborates strongly with MYCN overexpression to lead to retinoblastoma in mice. MYCN overexpression in the context of Rb inactivation increased the expression of MYC, E2F and ribosome related gene sets, promoted excessive proliferation and led to retinoblastoma with anaplastic changes. Part of our study compares expression profiles in Rbnull vs Rbnull/MYCN overexpressing retinas collected at 12 days after birth.

Project description:Retinoblastoma is a childhood retinal tumor that initiates in response to biallelic RB1 inactivation. We show that post-mitotic human cone precursors are uniquely sensitive to the oncogenic effects of Rb depletion. Rb knockdown induced cone precursor proliferation in prospectively isolated populations. SNP-array analysis of two Rb/p130-depleted cone precursor cell lines, revealing no megabase-size loss of heterozygosity (LOH) or copy number alterations (CNAs). SNP-array analysis of one Rb/p130-depleted (tumor 1) or one Rb-depleted (tumor 2) cone precursor-derived tumors, revealing no megabase-size LOH or CNAs, consistent with the lack of DNA copy number alterations in some retinoblastomas. Thus, the cone precursor tumors resembled human retinoblastomas at the molecular cytogenetic level. High resolution SNP-array DNA copy number analyses were performed using CytoScan® HD (Affymetrix, 901835) according to the manufacturer's directions. Data were analyzed using Chromosome Analysis Suite 2.0 (Affymetrix). DNA was extracted from two Rb/p130 depleted cone precursor cell lines and two cryopreserved mouse retinoblastoma samples from eyes xenograted with Rb/p130 or Rb depleted cone precursors. Affymetrix SNP analysis on retinoblastoma cell lines Y79, RB176, and WERI were used as control. Normal human genome 19 was used as reference.

Project description:Background: MYCN gene is a transcription factor whose amplification and overexpression can lead to tumorigenesis. In retina, MYCN overexpression is related to tumorigenesis of retinoblastoma, a childhood cancer. Purpose: To find out differentially expressed genes in MYCN-overexpressing cells, which will give information of MYCN-related gene expression and possibly find out new pathways in mechanism of retinoblastoma tumorigenesis with MYCN overexpression. Methods: MYCN-overexpressing cells were taken from MYCN electroporated E14 chicken retina and kept in culture. Unelectroporated E14 chicken retina central region was dissected as a control. Total RNA was extracted and sequenced on Illumina NovaSeq 6000. The data were used for differential expression analysis and GO/Pathway enrichment analysis.