Project description:Pineoblastoma is a clinically aggressive childhood brain tumor that segregates into molecularly distinct subgroups. Mechanisms governing pineoblastoma pathogenesis, including developmental origins, remain poorly defined. Herein, we resolved the cellular composition of pineoblastoma and other pineal parenchymal tumors at single-cell resolution, aligning malignant cells with pineal gland development to retrace cellular origins. Integrative computational analyses mapped divergent pineoblastoma subgroups to cycling progenitors of the pinealocyte lineage. Lineage-specific perturbation of suspected drivers provoked the generation of genetically accurate preclinical models representing distinct molecular subgroups, while uncovering an oncogenic photoreceptor program conserved across pineoblastoma, retinoblastoma, and Group 3 medulloblastoma. Transcriptional activity of this program was acquired from cellular origin, incriminating photoreceptor identity as a common developmental vulnerability, substantiated as a strong dependency. Illuminated through multidisciplinary analysis of an uncommon, heterogeneous pediatric brain tumor, these advances motivate future studies evaluating developmentally encoded transcriptional programs of malignancy as potential therapeutic liabilities in clinically challenging entities.

Project description:Pineoblastoma is a clinically aggressive childhood brain tumor that segregates into molecularly distinct subgroups. Mechanisms governing pineoblastoma pathogenesis, including developmental origins, remain poorly defined. Herein, we resolved the cellular composition of pineoblastoma and other pineal parenchymal tumors at single-cell resolution, aligning malignant cells with pineal gland development to retrace cellular origins. Integrative computational analyses mapped divergent pineoblastoma subgroups to cycling progenitors of the pinealocyte lineage. Lineage-specific perturbation of suspected drivers provoked the generation of genetically accurate preclinical models representing distinct molecular subgroups, while uncovering an oncogenic photoreceptor program conserved across pineoblastoma, retinoblastoma, and Group 3 medulloblastoma. Transcriptional activity of this program was acquired from cellular origin, incriminating photoreceptor identity as a common developmental vulnerability, substantiated as a strong dependency. Illuminated through multidisciplinary analysis of an uncommon, heterogeneous pediatric brain tumor, these advances motivate future studies evaluating developmentally encoded transcriptional programs of malignancy as potential therapeutic liabilities in clinically challenging entities.

Project description:Pineoblastoma is a rare and aggressive embryonal tumor of childhood. The molecular heterogeneity within has not been systematically evaluated. In this study, we used methylation profiling to compare the signatures of pineoblastoma and other pineal parenchymal tumors to a reference cohort of brain tumor entities (GSE90496) , clinically relevant epigenomic subgroups with characteristics genomic/transcriptomic features are described.

Project description:NeuroD1 encodes a basic helix-loop-helix transcription factor involved in the development of neural and endocrine structures. NeuroD1 mRNA is highly abundant in the adult mammalian pineal gland and exhibits a developmental expression pattern similar to the retina. This is consistent with the common evolutionary origin of pinealocytes and retinal photoreceptors. Pinealocytes and retinal photoreceptors express a shared set of phototransduction genes and submammalian pinealocytes are photosensitive. In contrast to the retina, the pineal gland is a relatively homogeneous structure, composed 95% of pinealocytes. This makes the pineal gland a particularly useful model for understanding photoreceptor cell biology. The loss of NeuroD1 in the retina results in progressive photoreceptor degeneration and the molecular mechanisms underlying this retinal degeneration phenotype remain unknown. Similarly, the role that NeuroD1 plays in the pineal gland is unknown. To determine the function of NeuroD1 in the pineal gland and retina, a Cre/loxP recombination strategy was used to selectively target a NeuroD1 floxed allele and generate NeuroD1 conditional knockout (cKO) mice. Tissue specificity was conferred using Cre recombinase expressed under the control of the promoter of Crx, a transcription factor selectively expressed in the pineal gland and retina. Pineal and retinal tissues from two-month-old NeuroD1 cKO and control animals were used in microarray studies to identify candidate genes responsible for the photoreceptor degeneration phenotype.

Project description:NeuroD1 encodes a basic helix-loop-helix transcription factor involved in the development of neural and endocrine structures. NeuroD1 mRNA is highly abundant in the adult mammalian pineal gland and exhibits a developmental expression pattern similar to the retina. This is consistent with the common evolutionary origin of pinealocytes and retinal photoreceptors. Pinealocytes and retinal photoreceptors express a shared set of phototransduction genes and submammalian pinealocytes are photosensitive. In contrast to the retina, the pineal gland is a relatively homogeneous structure, composed 95% of pinealocytes. This makes the pineal gland a particularly useful model for understanding photoreceptor cell biology. The loss of NeuroD1 in the retina results in progressive photoreceptor degeneration and the molecular mechanisms underlying this retinal degeneration phenotype remain unknown. Similarly, the role that NeuroD1 plays in the pineal gland is unknown. To determine the function of NeuroD1 in the pineal gland and retina, a Cre/loxP recombination strategy was used to selectively target a NeuroD1 floxed allele and generate NeuroD1 conditional knockout (cKO) mice. Tissue specificity was conferred using Cre recombinase expressed under the control of the promoter of Crx, a transcription factor selectively expressed in the pineal gland and retina. Pineal and retinal tissues from two-month-old NeuroD1 cKO and control animals were used in microarray studies to identify candidate genes responsible for the photoreceptor degeneration phenotype. The Cre/loxP recombination strategy was used to target a NeuroD1 floxed allele and generate NeuroD1 conditional knockout mice (NeuroD1floxed::Crx-Cre+/-). NeuroD1 floxed mice (NeuroD1floxed::Crx-Cre-/-) served as the controls. Pineal glands and retinas from two-month-old control and conditional knockout mice were collected at ZT6 and ZT20. 3 pools of 6 pineal glands per genotype and respective time of day were collected for each sample. Similarly, 3 pools of 6 retinas each were also collected. RNA from each pool was extracted and hybridized on the Affymetrix Mouse 430 2.0 array.

Project description:Mutations in the microRNA processing genes DICER1 and DROSHA drive childhood cancers such as pineoblastoma, a brain tumor that resembles undifferentiated precursors of the pineal gland. To understand how microRNAs regulate proliferation of these progenitors, we developed a mouse model of pineoblastoma by ablating Drosha or Dicer1 in the developing pineal gland. The tumors that arise in these models resemble proliferative, undifferentiated embryonic progenitors. They are marked by loss of microRNAs, including the let-7 family, and de-repression of let-7 target genes. One upregulated let-7 target gene is the oncofetal transcription factor Plagl2, which activates expression of key pro-growth genes Igf2 and Ccnd2, and we show that small molecules targeting these two drivers block tumor growth. Thus, our results demonstrate that tumors driven by loss of microRNA processing may be therapeutically targeted by inhibiting downstream drivers of proliferation.

Project description:Mutations in the microRNA processing genes DICER1 and DROSHA drive childhood cancers such as pineoblastoma, a brain tumor that resembles undifferentiated precursors of the pineal gland. To understand how microRNAs regulate proliferation of these progenitors, we developed a mouse model of pineoblastoma by ablating Drosha or Dicer1 in the developing pineal gland. The tumors that arise in these models resemble proliferative, undifferentiated embryonic progenitors. They are marked by loss of microRNAs, including the let-7 family, and de-repression of let-7 target genes. One upregulated let-7 target gene is the oncofetal transcription factor Plagl2, which activates expression of key pro-growth genes Igf2 and Ccnd2, and we show that small molecules targeting these two drivers block tumor growth. Thus, our results demonstrate that tumors driven by loss of microRNA processing may be therapeutically targeted by inhibiting downstream drivers of proliferation.

Project description:Mutations in the microRNA processing genes DICER1 and DROSHA drive childhood cancers such as pineoblastoma, a brain tumor that resembles undifferentiated precursors of the pineal gland. To understand how microRNAs regulate proliferation of these progenitors, we developed a mouse model of pineoblastoma by ablating Drosha or Dicer1 in the developing pineal gland. The tumors that arise in these models resemble proliferative, undifferentiated embryonic progenitors. They are marked by loss of microRNAs, including the let-7 family, and de-repression of let-7 target genes. One upregulated let-7 target gene is the oncofetal transcription factor Plagl2, which activates expression of key pro-growth genes Igf2 and Ccnd2, and we show that small molecules targeting these two drivers block tumor growth. Thus, our results demonstrate that tumors driven by loss of microRNA processing may be therapeutically targeted by inhibiting downstream drivers of proliferation.

Project description:Mutations in the microRNA processing genes DICER1 and DROSHA drive childhood cancers such as pineoblastoma, a brain tumor that resembles undifferentiated precursors of the pineal gland. To understand how microRNAs regulate proliferation of these progenitors, we developed a mouse model of pineoblastoma by ablating Drosha or Dicer1 in the developing pineal gland. The tumors that arise in these models resemble proliferative, undifferentiated embryonic progenitors. They are marked by loss of microRNAs, including the let-7 family, and de-repression of let-7 target genes. One upregulated let-7 target gene is the oncofetal transcription factor Plagl2, which activates expression of key pro-growth genes Igf2 and Ccnd2, and we show that small molecules targeting these two drivers block tumor growth. Thus, our results demonstrate that tumors driven by loss of microRNA processing may be therapeutically targeted by inhibiting downstream drivers of proliferation.

Project description:Mutations in the microRNA processing genes DICER1 and DROSHA drive childhood cancers such as pineoblastoma, a brain tumor that resembles undifferentiated precursors of the pineal gland. To understand how microRNAs regulate proliferation of these progenitors, we developed a mouse model of pineoblastoma by ablating Drosha or Dicer1 in the developing pineal gland. The tumors that arise in these models resemble proliferative, undifferentiated embryonic progenitors. They are marked by loss of microRNAs, including the let-7 family, and de-repression of let-7 target genes. One upregulated let-7 target gene is the oncofetal transcription factor Plagl2, which activates expression of key pro-growth genes Igf2 and Ccnd2, and we show that small molecules targeting these two drivers block tumor growth. Thus, our results demonstrate that tumors driven by loss of microRNA processing may be therapeutically targeted by inhibiting downstream drivers of proliferation.