Background: Bioreduction of water-soluble tetrazolium salts (e.g., MTS, XTT, and MTT) to their respective formazans is generally regarded as an indicator of cell "redox activity." The reaction is attributed mainly to mitochondrial enzymes and electron carriers. However, MTT reduction may also be catalyzed by a number of other nonmitochondrial enzymes. The goal of this work was to establish the sites of MTT reduction in intact HepG2 human hepatoma cells in culture. Methods: In order to establish the subcellular localization of the sites of reduction of MTT, we imaged the formation of MTT-formazan deposits using backscattered light confocal microscopy. Mitochondria were visualized in viable cells using fluorescent dyes that bind in a manner dependent (JC-1 and TMRE) or independent (NAO) of mitochondrial electric potential. Results: Only 25-45% of MTT-formazan was associated with mitochondria after 25 min of incubation. No more than 25% of the mitochondrial area on images was occu-
MicroRNAs function as negative regulators of post-transcriptional gene expression, playing major roles in cellular differentiation. Several neuroblastoma cell lines can be induced to undergo differentiation by all-trans-retinoic acid (ATRA) and are used for modelling signalling pathways involved in this process. To identify miRNAs contributing to differentiation, we profiled 364 loci following ATRA treatment of neuroblastoma cell lines and found miR-10a and miR-10b to be highly over-expressed in SK-N-BE, LAN5, and SHSY-5Y. Ectopic over-expression of these miRNAs led to a major reprogramming of the transcriptome and a differentiated phenotype that was similar to that induced by ATRA in each of these cell lines. One of the predicted down-regulated miR-10a/b targets was nuclear receptor co-repressor 2 (NCOR2), a co-repressor of gene transcription which is known to suppress neurite outgrowth. NCOR2 was experimentally validated as a direct target of miR-10a/b, and siRNA mediated inhibition of this mRNA alone resulted in neural cell differentiation. Moreover, induction of differentiation could be blocked by ectopic up-regulation of NCOR2 using an expression construct lacking the miR-10a/b 3’ UTR target site. We conclude that miR-10a/b play major roles in the process of neural cell differentiation through direct targeting of NCOR2, which in turn induces a cascade of primary and secondary transcriptional alterations, including the down-regulation of MYCN.
SummaryExposure to light can destroy the ability of a molecule to fluoresce. Such photobleaching limits the use of fluorescence and confocal microscopy in biological studies. Loss of fluorescence decreases the signal-to-noise ratio and so image resolution; it also prevents the acquisition of meaningful data late during repeated scanning (e.g. when collecting three-dimensional images). The aim of this work was to investigate the role of oxygen in the photobleaching of fluorophores bound to DNA in fixed cells, and to explore whether anoxia could minimize such bleaching. Anoxia significantly reduced bleaching rates and changed the order of reaction of both propidium iodide (an intercalator) and chromomycin A 3 (a minor-groove binder) bound to DNA; it afforded the greatest protection at low photon fluxes. However, it had no effect on the bleaching of the green fluorescent protein (GFP) covalently attached to a histone and so bound to DNA, probably because the protein shielded the chromophore from oxygen. Bleaching of all three fluorophores depended on photon flux. Practical ways of minimizing bleaching were examined, and examples of three-dimensional images of DNA marked by propidium and GFP (collected under standard and optimized conditions) are presented.
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