Differentiation induces up-regulation of plasma membrane Ca(2+)-ATPase and concomitant increase in Ca(2+) efflux in human neuroblastoma cell line IMR-32

Precise regulation of intracellular Ca(2+) concentration ([Ca(2+)](i)) is achieved by the coordinated function of Ca(2+) channels and Ca(2+) buffers. Neuronal differentiation induces up-regulation of Ca(2+) channels. However, little is known about the effects of differentiation on the expression of the plasma membrane Ca(2+)-ATPase (PMCA), the principal Ca(2+) extrusion mechanism in neurons. In this study, we examined the regulation of PMCA expression during differentiation of the human neuroblastoma cell line IMR-32. [Ca(2+)](i) was monitored in single cells using indo-1 microfluorimetry. When the Ca(2+)-ATPase of the endoplasmic reticulum was blocked by cyclopiazonic acid, [Ca(2+)](i) recovery after small depolarization-induced Ca(2+) loads was governed primarily by PMCAs. [Ca(2+)](i) returned to baseline by a process described by a monoexponential function in undifferentiated cells (tau = 52 +/- 4 s; n = 25). After differentiation for 12-16 days, the [Ca(2+)](i) recovery rate increased by more than threefold (tau = 17 +/- 1 s; n = 31). Western blots showed a pronounced increase in expression of three major PMCA isoforms in IMR-32 cells during differentiation, including PMCA2, PMCA3 and PMCA4. These results demonstrate up-regulation of PMCAs on the functional and protein level during neuronal differentiation in vitro. Parallel amplification of Ca(2+) influx and efflux pathways may enable differentiated neurons to precisely localize Ca(2+) signals in time and space.     

Biochemical and electrophysiological differentiation profile of a human neuroblastoma (IMR-32) cell line

A human neuroblastoma cell line (IMR-32), when differentiated, mimics large projections of the human cerebral cortex and under certain tissue culture conditions, forms intracellular fibrillary material, commonly observed in brains of patients affected with Alzheimer's disease. Our purpose is to use differentiated IMR-32 cells as an in vitro system for magnetic field exposure studies. We have previously studied in vitro differentiation of murine neuroblastoma (N1E-115) cells with respect to resting membrane potential development. The purpose of this study was to extend our investigation to IMR-32 cells. Electrophysiological (resting membrane potential, V(m)) and biochemical (neuron-specific enolase activity [NSE]) measurements were taken every 2 d for a period of 16 d. A voltage-sensitive oxonol dye together with flow cytometry was used to measure relative changes in V(m). To rule out any effect due to mechanical cell detachment, V(m) was indirectly measured by using a slow potentiometric dye (tetramethylrhodamine methyl ester) together with confocal digital imaging microscopy. Neuron-specific enolase activity was measured by following the production of phosphoenolpyruvate from 2-phospho-d-glycerate at 240 nm. Our results indicate that in IMR-32, in vitro differentiation as characterized by an increase in NSE activity is not accompanied by resting membrane potential development. This finding suggests that pathways for morphological-biochemical and electrophysiological differentiations in IMR-32 cells are independent of one another.     

Down regulation of ribosomal protein mRNAs during neuronal differentiation of human NTERA2 cells

We have analysed the expression of 32 ribosomal protein (RP) mRNAs during retinoic acid induced neuronal differentiation of human NTERA2 cells. Except for a new S27 variant (S27v), all were down regulated both in selectively replated differentiated neurons and the most differentiated continuous cultures, i.e., non-replated cultures. However, the expression profiles of the individual RP mRNAs were different, most (L3, L7, L8, L10, L13, L23a, L27a, L36a, L39, P0, S2, S3, S3a, S4X, S6, S9, S12, S13, S16, S19, S20, S23, and S27a) exhibited a constant down regulation, whereas a few were either initially constant (L11, L32, S8, and S11) or up regulated (L6, L15, L17, L31, and S27y) and then down regulated. The expression of S27v remained elevated in the most differentiated continuous cultures but was down regulated in replated differentiated neurons. The down regulation of RP mRNAs was variable: the expression levels in differentiated replated neurons were between 10% (S3) and 90% (S11) of the levels in undifferentiated cells. The ratio between rRNA and RP mRNA changed during the differentiation; in differentiated neurons there were, on average, about half the number of RP mRNAs per rRNA as compared to undifferentiated cells. The expression profiles of a few translation-related proteins were also determined. EF1alpha1, EF1beta1, and EF1delta were down regulated, whereas the expression of the neuron and muscle specific EF1alpha2 increased. The reduction in the expression of RP mRNAs was coordinated with a reduction in the expression level of the proliferation marker PCNA. The expression levels of most RP mRNAs were lower in purified differentiated post-mitotic neurons than in the most differentiated continuous cultures, despite similar levels of PCNA, suggesting that both the differentiation state and the proliferative status of the cells affect the expression of RP mRNAs.     

The oxidant defense system in human neuroblastoma IMR-32 cells predifferentiation and postdifferentiation to neuronal phenotypes

Differentiated neurons were investigated for their susceptibility to oxidative damage based on variations in the oxidant defense system occurring during differentiation. The main antioxidant enzymes and substances in human neuroblastoma (IMR-32) cells were evaluated pre- and post-differentiation to a neuronal phenotype. The activity of CuZn superoxide dismutase (CuZnSOD) and Mn superoxide dismutase (MnSOD) and the concentration of CuZnSOD were higher, but the activity and concentration of catalase were lower after differentiation. Differentiated cells had higher activity of glutathione peroxidase (GPx), lower concentration of total glutathione, a higher ratio of oxidised/reduced glutathione and lower activity of glucose-6-phosphate dehydrogenase than undifferentiated cells. We conclude that differentiated neuronal cells may be highly susceptible to oxidant-mediated damage based on the relative activities of the main antioxidant enzymes and on a limited capacity to synthesise and/or recycle glutathione.     

MicroRNA-432 contributes to dopamine cocktail and retinoic acid induced differentiation of human neuroblastoma cells by targeting NESTIN and RCOR1 genes

MicroRNA (miRNA) regulates expression of protein coding genes and has been implicated in diverse cellular processes including neuronal differentiation, cell growth and death. To identify the role of miRNA in neuronal differentiation, SH-SY5Y and IMR-32 cells were treated with dopamine cocktail and retinoic acid to induce differentiation. Detection of miRNAs in differentiated cells revealed that expression of many miRNAs was altered significantly. Among the altered miRNAs, human brain expressed miR-432 induced neurite projections, arrested cells in G0–G1, reduced cell proliferation and could significantly repress NESTIN/NES, RCOR1/COREST and MECP2. Our results reveal that miR-432 regulate neuronal differentiation of human neuroblastoma cells.     

Nerve Growth Factor-Induced Differentiation in Neuroblastoma Cells Expressing TrkA but Lacking p75NGFR

Abstract: Nerve growth factor (NGF) binds to two distinct cell surface receptors, TrkA, which is a receptor tyrosine kinase, and p75^NGFR, whose role in NGF-induced signal transduction remains unclear. We have found that human neuroblastoma IMR-32 cells express TrkA, but p75^NGFR expression was not detectable in these cells by northern blot analysis, immunoblotting, or chemical crosslinking experiments. Despite the lack of p75^NGFR expression, subnanomolar concentrations of recombinant human NGF induced neurite outgrowth, tyrosine phosphorylation, and immediate early gene expression in these cells. These results strongly suggest that NGF-induced neuronal differentiation in IMR-32 cells is initiated through TrkA in the absence of p75^NGFR. Thus, IMR-32 cells may provide a model for studying neurotrophic effects of NGF on adult striatal cholinergic neurons, which also lack p75^NGFR expression.