Analysis of NTPDase2 in the cell membrane using fluorescence recovery after photobleaching (FRAP).

NTPDase2, a member of the CD39/NTPDase family, is an ecto-nucleotidase anchored to the plasma membrane by two transmembrane domains, with a catalytic site facing the extracellular space and preferentially hydrolyzing nucleoside triphosphates. While NTPDase2 is expressed in many cell types, its unique functionality, mobility and dynamics at the cell membrane remain unexplored. We therefore constructed a recombinant NTPDase2 linked to the yellow fluorescent protein (EYFP) to investigate its dynamics by confocal microscopy. The present study shows that the expression of EYFP-NTPDase2 in different cell lines does not affect its proliferation, migration and adhesion to extracellular matrices (ECM). Moreover, in human embryonic kidney cells 293 (HEK293) grown on collagen type I and fibronectin, EYFP-NTPDase2 fluorescence is greater in free plasma membrane regions than in cell-cell contacts, in comparison with cells grown on other substrates. Differences in the time required for fluorescence recovery after photobleaching (FRAP) in free membrane regions and cell-cell contacts indicate that the mobility of EYFP-NTPDase2 depends on the matrix to which the cells are attached. © 2018 International Society for Advancement of Cytometry.

Vinblastine and antihelmintic mebendazole potentiate temozolomide in resistant gliomas.

Glioblastoma (GBM) is a very aggressive tumor that has not had substantial therapeutic improvement since the introduction of temozolomide (TMZ) in combination with radiotherapy. Combining TMZ with other chemotherapeutic agents is a strategy that could be further explored for GBM. To search for molecular predictors of TMZ resistance, the TCGA (The Cancer Genome Atlas) database was utilized to assess the impact of specific genes on TMZ response. Patients whose tumors expressed low levels of FGFR3 and AKT2 responded poorly to TMZ. Combination treatment of vinblastine (VBL) plus mebendazole (MBZ) with TMZ was more effective in reducing cell number in most cultures when compared to TMZ alone, especially in cells with low expression levels of FGFR3 and AKT2. Cell cycle distribution and nuclear morphometric analysis indicated that the triple combination of TMZ, VBL and MBZ (TVM) was able to induce polyploidy and senescence, in addition to increasing the Notch3 RNA level in patient-derived gliomas. Thus, this set of data suggests that the triple combination of TMZ, VBL and MBZ may be a considerable therapeutic alternative for the TMZ-tolerant gliomas that harbor low expression of FGFR3/AKT2.

Embryonic periventricular endothelial cells demonstrate a unique pro-neurodevelopment and anti-inflammatory gene signature.

Brain embryonic periventricular endothelial cells (PVEC) crosstalk with neural progenitor cells (NPC) promoting mutual proliferation, formation of tubular-like structures in the former and maintenance of stemness in the latter. To better characterize this interaction, we conducted a comparative transcriptome analysis of mouse PVEC vs. adult brain endothelial cells (ABEC) in mono-culture or NPC co-culture. We identified > 6000 differentially expressed genes (DEG), regardless of culture condition. PVEC exhibited a 30-fold greater response to NPC than ABEC (411 vs. 13 DEG). Gene Ontology (GO) analysis of DEG that were higher or lower in PVEC vs. ABEC identified "Nervous system development" and "Response to Stress" as the top significantly different biological process, respectively. Enrichment in canonical pathways included HIF1A, FGF/stemness, WNT signaling, interferon signaling and complement. Solute carriers (SLC) and ABC transporters represented an important subset of DEG, underscoring PVEC's implication in blood-brain barrier formation and maintenance of nutrient-rich/non-toxic environment. Our work characterizes the gene signature of PVEC and their important partnership with NPC, underpinning their unique role in maintaining a healthy neurovascular niche, and in supporting brain development. This information may pave the way for additional studies to explore their therapeutic potential in neuro-degenerative diseases, such as Alzheimer's and Parkinson's disease.

Low Dose of Doxorubicin Potentiates the Effect of Temozolomide in Glioblastoma Cells.

Glioblastoma (GBM) is an aggressive brain tumor with temozolomide (TMZ)-based chemotherapy as the main therapeutic strategy. Doxorubicin (DOX) is not used in gliomas due to its low bioavailability in the brain; however, new delivery strategies and low doses may be effective in the long term, especially as part of a drug cocktail. Our aim was to evaluate the chronic effects of low doses of DOX and TMZ in GBM. Human U87-ATCC cells and a primary GBM culture were chronically treated with TMZ (5 µM) and DOX (1 and 10 nM) alone or combined. DOX resulted in a reduction in the number of cells over a period of 35 days and delayed the cell regrowth. In addition, DOX induced cell senescence and reduced tumor sphere formation and the proportion of NANOG- and OCT4-positive cells after 7 days. Low doses of TMZ potentiated the effects of DOX on senescence and sphere formation. This combined response using low doses of DOX may pave the way for its use in glioma therapy, with new technologies to overcome its low blood-brain barrier permeability.

Roles of OCT4 in tumorigenesis, cancer therapy resistance and prognosis.

OCT4 (POU5F1) is a major regulator of cell pluripotency and plays an important role not only during embryogenesis but also in tumorigenesis. It has been studied in various types of cancers, since stemness is an important factor for cancer growth and therapy. Here we present basic information about the OCT4 gene, its isoforms and pseudogenes besides discussing the current literature in which OCT4 is linked to cancer, emphasizing its roles in tumorigenesis and therapy. The majority of studies indicated a negative correlation between the expression of OCT4 and prognosis, and only in testicular germ cell tumor this correlation was positive. Using The Cancer Genome Atlas database we showed that OCT4 expression correlated negatively with patient survival in pancreatic cancer. All those different impacts of OCT4 on cancer indicate the biological complexity of this transcription factor in biology and, therefore, also in cancer.