A Cell-Based Assay to Investigate Hypolipidemic Effects of Nonalcoholic Fatty Liver Disease Therapeutics.

In the recent past, there has been a growing interest in developing nonalcoholic fatty liver disease (NAFLD) and nonalcoholic steatohepatitis (NASH) therapeutics. As a result, a need for in vitro cell models of human hepatic steatosis and high-throughput assays to measure intracellular lipid levels has arisen. To address this growing need, we optimized the conditions based on the current literature to fatten HepG2 hepatocytes by adding a mixture of saturated and unsaturated fatty acids (oleate/palmitate, 2:1 molar ratio) without inducing any overt cytotoxicity. Our results indicate that hepatocytes fatten in a concentration- (0.75-1.5 mM of fatty acids) and time-dependent manner, with a substantial increase in intracellular lipid levels seen within 6 h. Additionally, a method to quantify lipid levels in cells using a fluorescent reagent that is more sensitive than that in conventional assays and adaptable for high-throughput screening is presented. Lastly, the utility of the in vitro cell model and an assay based on AdipoRed to measure hypolipidemic effects of therapeutic drugs is demonstrated using fenofibrate, a molecule that was previously shown to lower lipid levels in the liver.

Regulation of unsaturated fatty acid biosynthesis in Saccharomyces: the endoplasmic reticulum membrane protein, Mga2p, a transcription activator of the OLE1 gene, regulates the stability of the OLE1 mRNA through exosome-mediated mechanisms.

The Saccharomyces cerevisiae OLE1 gene encodes a membrane-bound Delta9 fatty-acid desaturase, whose expression is regulated through transcriptional and mRNA stability controls. In wild type cells grown on fatty acid-free medium, OLE1 mRNA has a half-life of 10 +/- 1.5 min (basal stability) that becomes highly unstable when cells are exposed to unsaturated fatty acids (regulated stability). Activation of OLE1 transcription is dependent on N-terminal fragments of two membrane proteins, Mga2p and Spt23p, that are proteolytically released from the membrane by a ubiquitin-mediated mechanism. Surprisingly, disruption of the MGA2 gene also reduces the half-life of the OLE1 transcript and abolishes fatty acid regulated instability. Disruption of its cognate, SPT23, has no effect on the half-life of the mRNA. Mga2p appears to have two distinct functions with respect to the OLE1 mRNA stability: a stabilizing effect in cells grown in fatty acid-free medium and a destabilizing function in cells that are exposed to unsaturated fatty acids. These functions are independent of OLE1 transcription and can confer basal and regulated stability on OLE1 mRNAs that are produced under the control of the unrelated GAL1 promoter. Expression of soluble, N-terminal fragments of Mga2p stabilize the transcript but do not confer fatty acid-regulated instability on the mRNA suggesting that the stabilizing functions of Mga2p do not require membrane processing and that modifications to the protein introduced during proteolysis may play a role in the destabilizing effect. An analysis of mutants that are defective in mRNA degradation indicate that the Mga2p-requiring control mechanism that regulates the fatty acid-mediated instability of the OLE1 transcript acts by activating exosomal 3' --> 5'-exonuclease degradation activity.

Maintenance and regulation of mRNA stability of the Saccharomyces cerevisiae OLE1 gene requires multiple elements within the transcript that act through translation-independent mechanisms.

The Saccharomyces cerevisiae OLE1 gene encodes a membrane-bound Delta-9 fatty acid desaturase, whose expression is regulated by unsaturated fatty acids through both transcriptional and mRNA stability controls. In fatty acid-free medium, the mRNA has a half-life of 10 +/- 1.5 min (basal stability) that drops to 2 +/- 1.5 min when cells are exposed to unsaturated fatty acids (regulated stability). A deletion analysis of elements within the transcript revealed that the sequences within the protein-coding region that encode transmembrane sequences and a part of the cytochrome b5 domain are essential for the basal stability of the transcript. Deletion of any of the three essential elements produced unstable transcripts and loss of regulated instability. By contrast, substitution of the 3'-untranslated region with that of the stable PGK1 gene did not affect the basal stability of the transcript and did not block regulated decay. Given that Ole1p is a membrane-bound protein whose activities are a major determinant of membrane fluidity, we asked whether membrane-associated translation of the protein was essential for basal and regulated stability. Insertion of stop codons within the transcript that blocked either translation of the entire protein or parts of the protein required for co-translation insertion of Ole1p had no effect. We conclude that the basal and regulated stability of the OLE1 transcript is resistant to the nonsense-mediated decay pathway and that the essential protein-encoding elements for basal stability act cooperatively as stabilizing sequences through RNA-protein interactions via a translation-independent mechanism.