A patient-designed tissue-engineered model of the infiltrative glioblastoma microenvironment.

Glioblastoma is an aggressive brain cancer characterized by diffuse infiltration. Infiltrated glioma cells persist in the brain post-resection where they interact with glial cells and experience interstitial fluid flow. We use patient-derived glioma stem cells and human glial cells (i.e., astrocytes and microglia) to create a four-component 3D model of this environment informed by resected patient tumors. We examine metrics for invasion, proliferation, and putative stemness in the context of glial cells, fluid forces, and chemotherapies. While the responses are heterogeneous across seven patient-derived lines, interstitial flow significantly increases glioma cell proliferation and stemness while glial cells affect invasion and stemness, potentially related to CCL2 expression and differential activation. In a screen of six drugs, we find in vitro expression of putative stemness marker CD71, but not viability at drug IC50, to predict murine xenograft survival. We posit this patient-informed, infiltrative tumor model as a novel advance toward precision medicine in glioblastoma treatment.

The nuclear DICER-circular RNA complex drives the deregulation of the glioblastoma cell microRNAome.

The assortment of cellular microRNAs ("microRNAome") is a vital readout of cellular homeostasis, but the mechanisms that regulate the microRNAome are poorly understood. The microRNAome of glioblastoma is substantially down-regulated in comparison to the normal brain. Here, we find malfunction of the posttranscriptional maturation of the glioblastoma microRNAome and link it to aberrant nuclear localization of DICER, the major enzymatic complex responsible for microRNA maturation. Analysis of DICER's nuclear interactome reveals the presence of an RNA binding protein, RBM3, and of a circular RNA, circ2082, within the complex. Targeting of this complex by knockdown of circ2082 results in the restoration of cytosolic localization of DICER and widespread derepression of the microRNAome, leading to transcriptome-wide rearrangements that mitigate the tumorigenicity of glioblastoma cells in vitro and in vivo with correlation to favorable outcomes in patients with glioblastoma. These findings uncover the mechanistic foundation of microRNAome deregulation in malignant cells.

Correction to: Multiple receptor tyrosine kinases converge on microRNA-134 to control KRAS, STAT5B, and glioblastoma.

Following publication of the article, the author named as "B Dey", wished to point out that his full name is "Bijan K. Dey". This was not reflected in the typesetting of the article, and as a consequence the article is not visible on Pub Med when a search is conducted on his full name.

Multiple receptor tyrosine kinases converge on microRNA-134 to control KRAS, STAT5B, and glioblastoma.

Receptor tyrosine kinases (RTKs) are co-deregulated in a majority of glioblastoma (GBM), the most common and most deadly brain tumor. We show that the RTKs MET, EGFR, and PDGFR regulate microRNA-134 (miR-134) in GBM. We find that miR-134 is downregulated in human tumors and cancer stem cells and that its expression inversely correlates with the activation of MET, EGFR, and PDGFR. We demonstrate that miR-134 inhibits cancer cell and stem-cell proliferation, survival, and xenograft growth, as well as cancer stem-cell self-renewal and stemness. We identify KRAS and STAT5B as targets of miR-134, and establish molecular and functional links between RTKs, miR-134, KRAS/STAT5B and malignancy in vitro and in vivo. We show that miR-134 induction is required for the anti-tumor effects of RTK inhibitors. We also uncover the molecular pathways through which RTKs regulate miR-134 expression and demonstrate the involvement of MAPK signaling and the KLF4 transcription factor. We therefore identify miR-134 as a novel RTK-regulated tumor-suppressive hub that mediates RTK and RTK-inhibitor effects on GBM malignancy by controlling KRAS and STAT5B.

Demonstration of human papillomavirus (HPV) genomic amplification and viral-like particles from CaSki cell line in SCID mice.

We demonstrate that from the CaSki cervical cancer cell line, integrated HPV-16 genome was amplified and viral-like particles were generated in an in vivo SCID mouse model. The in vivo tumor growth of several HPV-containing cell lines and 2 HPV-negative cell lines was examined in SCID mice. Tumor growth was noted with the HeLa, CaSki, ME-180, and MS751 cell lines within 2 months after subcutaneous injection. Squamous differentiation was appreciated in focal areas of tumors derived from CaSki and ME-180. In the CaSki tumors, DNA in situ hybridization revealed homogeneous staining of nuclei in some cells in the differentiated areas, suggesting HPV genomic amplification. In contrast, punctate or speckled patterns of hybridization were identified in the less differentiated areas, suggesting continued integration of the HPV genome. Immunocytochemical staining for HPV-16 L1 capsid protein showed it to be concentrated in cells from the differentiated areas, correlating with the results of hybridization. Electron microscopic studies revealed 50 nm uniform particles, consistent with HPV viral-like particles, in the nuclei of some cells in well-differentiated areas. Furthermore, Southern transfer and hybridization of the Hirt's extract from the CaSki tumors was positive for HPV-16 DNA, indicating non-integrated, low molecular weight HPV-16 DNA. Our results show HPV genomic amplification of integrated viral DNA and generation of HPV viral-like particles in CaSki cancer cells in SCID mice and that viral DNA amplification and the formation of viral-like particles are coupled to cellular differentiation. This experimental model provides a potential system for studying the molecular pathogenesis of HPV infections.

Hammerhead ribozyme cleavage of hamster prion pre-mRNA in complex cell-free model systems.

The cleavage properties of a trans-acting hammerhead ribozyme targeted 51 bases upstream of the putative splicing branch point in the hamster prion pre-mRNA intron were investigated in cell-free model systems in vitro. The specificity of cleavage was demonstrated by the inability of this ribozyme to cleave a non-homologous synthetic message encoding part of the beta amyloid peptide precursor, beta APP, and by the inability of the prion pre-mRNA to be cleaved by a ribozyme targeted to beta amyloid peptide precursor mRNA. Also, the addition of total RNA isolated from rat brain had only a minimal effect on the cleavage of the prion substrate pre-mRNA by the ribozyme. Finally neither the presence of 100 ng of nuclear or cytoplasmic proteins were found to affect the rate of cleavage in vitro.