HOXDeRNA activates a cancerous transcription program and super-enhancers genome-wide.

Background: The origin and genesis of highly malignant and heterogenous glioblastoma brain tumors remain unknown. We previously identified an enhancer-associated long non-coding RNA, LINC01116 (named HOXDeRNA here), that is absent in the normal brain but is commonly expressed in malignant glioma. HOXDeRNA has a unique capacity to transform human astrocytes into glioma-like cells.

Inhibition of the epigenetically activated miR-483-5p/IGF-2 pathway results in rapid loss of meningioma tumor cell viability.

Purpose: Meningioma is the most common primary central nervous system tumor often causing serious complications, and presently no medical treatment is available. The goal of this study was to discover miRNAs dysregulated in meningioma, and explore miRNA-associated pathways amenable for therapeutic interventions.

Methods: Small RNA sequencing was performed on meningioma tumor samples to study grade-dependent changes in microRNA expression.

Secreted PGK1 and IGFBP2 contribute to the bystander effect of miR-10b gene editing in glioma.

MicroRNA-10b (miR-10b) is an essential glioma driver and one of the top candidates for targeted therapies for glioblastoma and other cancers. This unique miRNA controls glioma cell cycle and viability via an array of established conventional and unconventional mechanisms. Previously reported CRISPR-Cas9-mediated miR-10b gene editing of glioma cells and established orthotopic glioblastoma in mouse models demonstrated the efficacy of this approach and its promise for therapy development.

Promoter and enhancer RNAs regulate chromatin reorganization and activation of miR-10b/HOXD locus, and neoplastic transformation in glioma.

miR-10b is silenced in normal neuroglial cells of the brain but commonly activated in glioma, where it assumes an essential tumor-promoting role. We demonstrate that the entire miR-10b-hosting HOXD locus is activated in glioma via the cis-acting mechanism involving 3D chromatin reorganization and CTCF-cohesin-mediated looping. This mechanism requires two interacting lncRNAs, HOXD-AS2 and LINC01116, one associated with HOXD3/HOXD4/miR-10b promoter and another with the remote enhancer.

A nuclear function for an oncogenic microRNA as a modulator of snRNA and splicing.

Background: miRNAs are regulatory transcripts established as repressors of mRNA stability and translation that have been functionally implicated in carcinogenesis. miR-10b is one of the key onco-miRs associated with multiple forms of cancer. Malignant gliomas exhibit particularly striking dependence on miR-10b.

Glioblastoma-Derived Extracellular Vesicles Facilitate Transformation of Astrocytes via Reprogramming Oncogenic Metabolism.

Glioblastoma (GBM) may arise from astrocytes through a multistep process involving a progressive accumulation of mutations. We explored whether GBM-derived extracellular vesicles (EVs) may facilitate neoplastic transformation and malignant growth of astrocytes. We utilized conditioned media (CM) of cultured glioma cells, its sequential filtration, diverse cell-based assays, RNA sequencing, and metabolic assays to compare the effects of EV-containing and EV-depleted CM.

IMP-3 protects the mRNAs of cyclins D1 and D3 from GW182/AGO2-dependent translational repression.

IGF-2 mRNA binding protein 3 (IGF2BP3, IMP-3) is a well-known post-transcriptional regulatory factor of gene expression, mainly involved in embryonic development and oncogenesis. We have previously demonstrated that a subset of IMP-3 targets, such as the mRNAs of cyclins D1, D3 and G1, are positively regulated by IMP-3, and that this regulation depends on nuclear localization of IMP-3. In the present study, we show that as a first step following a knock-down of IMP-3, the protein levels of the cyclins rapidly decrease, while their mRNAs remain stable and associated with the polyribosomes, though not translated.

[Fragmentation of the coding region chromatin of trp-dioxygenase (to) and tyr-aminotransferase (tat) genes in their active and repressed state by micrococcal nuclease].

The blot-hybridization technique-assisted we have studied the pattern of fragmentation by mirococcal nuclease (MNase) of DNA tyr-aminotransferase (tat) and trp-dioxygenase (to) genes in active (in rat cell liver nuclei) and repressed (in brain nuclei) states. It was provided, over a wide range of enzyme concentration two types of fragments are mainly produced: near full-size to- and tat-transcription unit (19,000 and 11,000 bp, respectively) and their large (from 1500 bp) heterogeneous in length. To-and tat-fragments of both kinds are preserved in hydrolyzates at limit of MNase digestion of total chromatin DNA when nuclease breaks occur in nearly all accessible sites of chromatin.