Expression of Snail transcriptional factor is a determinant in the acquisition of a mesenchymal phenotype by epithelial tumor cells. However, the regulation of the transcription of this gene is still unknown. We describe here the characterization of a human SNAIL promoter that contains the initiation of transcription and regulates the expression of this gene in tumor cells. This promoter was activated in cell lines in response to agents that induce Snail transcription and the mesenchymal phenotype, as addition of the phorbol ester PMA or overexpression of integrin-linked kinase (ILK) or oncogenes such as Ha-ras or v-Akt. Although other regions of the promoter were required for a complete stimulation by Akt or ILK, a minimal fragment (À78/ þ 59) was sufficient to maintain the mesenchymal specificity. Activity of this minimal promoter and SNAIL RNA levels were dependent on ERK signaling pathway. NFjB/p65 also stimulated SNAIL transcription through a region located immediately upstream the minimal promoter, between À194 and À78. These results indicate that Snail transcription is driven by signaling pathways known to induce epithelial to mesenchymal transition, reinforcing the role of Snail in this process.
High expression of the peroxisome proliferator-activated receptor ␣ (PPAR␣) differentiates brown fat from white, and is related to its high capacity of lipid oxidation. We analyzed the effects of PPAR␣ activation on expression of the brown fat-specific uncoupling protein-1 (ucp-1) gene. Activators of PPAR␣ increased UCP-1 mRNA levels severalfold both in primary brown adipocytes and in brown fat in vivo. Transient transfection assays indicated that the (؊4551)UCP1-CAT construct, containing the 5-regulatory region of the rat ucp-1 gene, was activated by PPAR␣ co-transfection in a dose-dependent manner and this activation was potentiated by Wy 14,643 and retinoid X receptor ␣. The coactivators CBP and PPAR␥-coactivator-1 (PGC-1), which is highly expressed in brown fat, also enhanced the PPAR␣-dependent regulation of the ucp-1 gene. Deletion and point-mutation mapping analysis indicated that the PPAR␣-responsive element was located in the upstream enhancer region of the ucp-1 gene. This ؊2485/؊2458 element bound PPAR␣ and PPAR␥ from brown fat nuclei. Moreover, this element behaved as a promiscuous responsive site to either PPAR␣ or PPAR␥ activation, and we propose that it mediates ucp-1 gene up-regulation associated with adipogenic differentiation (via PPAR␥) or in coordination with gene expression for the fatty acid oxidation machinery required for active thermogenesis (via PPAR␣).
SummaryUnicellular eukaryotes that lack mitochondria typically contain related organelles such as hydrogenosomes or mitosomes. To characterize the evolutionary diversity of these organelles, we conducted an expressed sequence tag (EST) survey on the freeliving amoeba Mastigamoeba balamuthi, a relative of the human parasite Entamoeba histolytica. From 19 182 ESTs, we identified 21 putative mitochondrial proteins implicated in protein import, amino acid interconversion and carbohydrate metabolism, two components of the iron-sulphur cluster (Fe-S) assembly apparatus as well as two enzymes characteristic of hydrogenosomes. By immunofluorescence microscopy and subcellular fractionation, we show that mitochondrial chaperonin 60 is targeted to small abundant organelles within Mastigamoeba. In transmission electron micrographs, we identified doublemembraned compartments that likely correspond to these mitochondrion-derived organelles, The predicted organellar proteome of the Mastigamoeba organelle indicates a unique spectrum of functions that collectively have never been observed in mitochondrion-related organelles. However, like Entamoeba, the Fe-S cluster assembly proteins in Mastigamoeba were acquired by lateral gene transfer from e-proteobacteria and do not possess obvious organellar targeting peptides. These data indicate that the loss of classical aerobic mitochondrial functions and acquisition of anaerobic enzymes and Fe-S cluster assembly proteins occurred in a free-living member of the eukaryote super-kingdom Amoebozoa.
Phytanic acid (3,7,11,15-tetramethylhexadecanoic acid) is a phytol-derived branched-chain fatty acid present in dietary products. Phytanic acid increased uncoupling protein-1 (UCP1) mRNA expression in brown adipocytes differentiated in culture. Phytanic acid induced the expression of the UCP1 gene promoter, which was enhanced by co-transfection with a retinoid X receptor (RXR) expression vector but not with other expression vectors driving peroxisome proliferator-activated receptor (PPAR)alpha, PPARgamma or a form of RXR devoid of ligand-dependent sensitivity. The effect of phytanic acid on the UCP1 gene required the 5' enhancer region of the gene and the effects of phytanic acid were mediated in an additive manner by three binding sites for RXR. Moreover, phytanic acid activates brown adipocyte differentiation: long-term exposure of brown preadipocytes to phytanic acid promoted the acquisition of the brown adipocyte morphology and caused a co-ordinate induction of the mRNAs for gene markers of brown adipocyte differentiation, such as UCP1, adipocyte lipid-binding protein aP2, lipoprotein lipase, the glucose transporter GLUT4 or subunit II of cytochrome c oxidase. In conclusion, phytanic acid is a natural product of phytol metabolism that activates brown adipocyte thermogenic function. It constitutes a potential nutritional signal linking dietary status to adaptive thermogenesis.
Protists that live under low-oxygen conditions often lack conventional mitochondria and instead possess mitochondrion-related organelles (MROs) with distinct biochemical functions. Studies of mostly parasitic organisms have suggested that these organelles could be classified into two general types: hydrogenosomes and mitosomes. Hydrogenosomes, found in parabasalids, anaerobic chytrid fungi, and ciliates, metabolize pyruvate anaerobically to generate ATP, acetate, CO 2 , and hydrogen gas, employing enzymes not typically associated with mitochondria. Mitosomes that have been studied have no apparent role in energy metabolism. Recent investigations of free-living anaerobic protists have revealed a diversity of MROs with a wider array of metabolic properties that defy a simple functional classification. Here we describe an expressed sequence tag (EST) survey and ultrastructural investigation of the anaerobic heteroloboseid amoeba Sawyeria marylandensis aimed at understanding the properties of its MROs. This organism expresses typical anaerobic energy metabolic enzymes, such as pyruvate:ferredoxin oxidoreductase, [FeFe]-hydrogenase, and associated hydrogenase maturases with apparent organelle-targeting peptides, indicating that its MRO likely functions as a hydrogenosome. We also identified 38 genes encoding canonical mitochondrial proteins in S. marylandensis, many of which possess putative targeting peptides and are phylogenetically related to putative mitochondrial proteins of its heteroloboseid relative Naegleria gruberi. Several of these proteins, such as a branched-chain alpha keto acid dehydrogenase, likely function in pathways that have not been previously associated with the well-studied hydrogenosomes of parabasalids. Finally, morphological reconstructions based on transmission electron microscopy indicate that the S. marylandensis MROs form novel cup-like structures within the cells. Overall, these data suggest that Sawyeria marylandensis possesses a hydrogenosome of mitochondrial origin with a novel combination of biochemical and structural properties.It is now widely accepted that the most recent common ancestor of extant eukaryotes possessed an endosymbiont-derived mitochondrial organelle of alphaproteobacterial ancestry (see reference 16 for a recent review). Although most wellknown eukaryotes contain mitochondria that aerobically respire to produce ATP, a vast diversity of anaerobic eukaryotic lineages have been discovered that lack classical mitochondrial structures. Instead of mitochondria, biochemically diverse double-membrane-bounded organelles have been found that function under low-oxygen conditions (for recent reviews, see references 5, 6, 17, 23, 54, and 57). The discovery and recent investigations of the functions of these mitochondrion-related organelles (MROs) has greatly expanded our understanding of both the conservation and diversity of functions that these organelles can perform.A number of protist lineages, including the parabasalids, several anaerobic ciliate groups, and anaerobic chy...
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