RESUMEN
Glioblastoma multiforme (GBM) is the most malignant form of brain tumor and is associated with resistance to conventional therapy and poor patient survival. Prostate apoptosis response (Par)-4, a tumor suppressor, is expressed as both an intracellular and secretory/extracellular protein. Though secretory Par-4 induces apoptosis in cancer cells, its potential in drug-resistant tumors remains to be fully explored. Multicellular spheroids (MCS) of cancer cells often acquire multi-drug resistance and serve as ideal experimental models. We investigated the role of Par-4 in Tamoxifen (TAM)-induced cell death in MCS of human cell lines and primary cultures of GBM tumors. TCGA and REMBRANT data analysis revealed that low levels of Par-4 correlated with low survival period (21.85 ± 19.30 days) in GBM but not in astrocytomas (59.13 ± 47.26 days) and oligodendrogliomas (58.04 ± 59.80 days) suggesting low PAWR expression as a predictive risk factor in GBM. Consistently, MCS of human cell lines and primary cultures displayed low Par-4 expression, high level of chemo-resistance genes and were resistant to TAM-induced cytotoxicity. In monolayer cells, TAM-induced cytotoxicity was associated with enhanced expression of Par-4 and was alleviated by silencing of Par-4 using specific siRNA. TAM effectively induced secretory Par-4 in conditioned medium (CM) of cells cultured as monolayer but not in MCS. Moreover, MCS were rendered sensitive to TAM-induced cell death by exposure to conditioned medium (CM)-containing Par-4 (derived from TAM-treated monolayer cells). Also TAM reduced the expression of Akt and PKCζ in GBM cells cultured as monolayer but not in MCS. Importantly, combination of TAM with inhibitors to PI3K inhibitor (LY294002) or PKCζ resulted in secretion of Par-4 and cell death in MCS. Since membrane GRP78 is overexpressed in most cancer cells but not normal cells, and secretory Par-4 induces apoptosis by binding to membrane GRP78, secretory Par-4 is an attractive candidate for potentially overcoming therapy-resistance not only in malignant glioma but in broad spectrum of cancers.
RESUMEN
The mechanisms underlying the differentiation of Mesenchymal stem cells (MSCs) toward neuronal cell type are not clearly understood. Earlier, we reported that laminin-1 induces neurite outgrowth in human MSCs via c-Jun/AP-1 activation through ERK, JNK, and Akt pathways. In this study, we demonstrate that laminin-1 increases the expression of proneural gene, neuroD1 and induces the expression of immediate-early biomarkers of neuronal cell-programming-Egr1, Egr3, PC3, and PC4. Gene expression profiling of MSCs cultured on laminin-1 and Poly-l-lysine for 12 h revealed differential regulation of 267 genes (>1.5 fold, p < 0.05), predominantly in the category of nervous system development and affected the pathways involved in TGF-ß/TNF-α signaling, regulation of MAPK and JNK cascade. Data for 11 selected genes related to nervous system development was validated by real time PCR. Transcriptional regulatory network analysis revealed c-Jun as the key transcription factor regulating majority of differentially expressed genes and identified Disrupted in schizophrenia 1, as a novel target of c-Jun. Modeling and analysis of biological network showed selective induction of Growth Arrest and DNA damage 45 (GADD45B) and repression of NF-κB inhibitor A (NFκBIA). Collectively, our findings provide the basis for understanding the molecular mechanisms associated with laminin-1-induced neurogenic expression in MSCs.