We have used a mRNA differential display technique to identify new genes involved in the reprogramming of gene expression during the adipose conversion of mouse 3T3 preadipocyte cell lines. We report here on the identification and cloning of a novel adipose-specific cDNA encoding a predicted membrane protein of 413 amino acids. The level of the corresponding 3.2-kilobase mRNA is tremendously increased during 3T3-L1 and 3T3-F442A differentiation into adipocytes. A single, very abundant 3.2-kilobase transcript is also found in inguinal and epididymal white adipose tissues and in interscapular brown adipose tissue but not in any other tissues examined. Its expression in adipose tissue is under tight nutritional regulation. The level of this novel 3.2-kilobase transcript becomes virtually nondetectable during fasting but is dramatically increased when fasted mice are refed a high carbohydrate diet. Based on its adipose specificity and dietary regulation, the novel gene product has been designated adiponutrin. The expression of adiponutrin mRNA is also 50-fold elevated in genetically obese fa/fa rats, indicating a link between adiponutrin and obesity. Western blot and confocal imagery analyses with epitope-tagged protein transiently expressed in 3T3-L1 adipocytes, and COS cells show that adiponutrin strictly localizes to membranes and is absent from the cytosol. Sequence analysis reveals homologies with several other members of related eukaryotic proteins, including a human paralog, which has been recently described in vesicular transport mechanisms. This leads us to suggest that adiponutrin could be involved in vesicular targeting and protein transport restricted to the adipocyte function.
Tumor necrosis factor-␣ (TNF␣) is involved in the physiological and biological abnormalities found in two opposite metabolic situations: cachexia and obesity. In an attempt to identify novel genes and proteins that could mediate the effects of TNF␣ on adipocyte metabolism and development, we have used a differential display technique comparing 3T3-L1 cells exposed or not to the cytokine. We have isolated a novel adipose cDNA encoding a TNF␣-inducible 470-amino acid protein termed TIARP, with six putative transmembrane regions flanked by a large amino-terminal and a short carboxyl-terminal domain, a structure reminiscent of channel and transporter proteins. Commitment into the differentiation process is required for cytokine responsiveness. The differentiation process per se is accompanied by a sharp emergence of TIARP mRNA transcripts, in parallel with the expression of the protein at the plasma membrane. Transcripts are present at high levels in white and brown adipose tissues, and are also detectable in liver, kidney, heart, and skeletal muscle. Whereas the biological function of TIARP is presently unknown, its pattern of expression during adipose conversion and in response to TNF␣ exposure as a transmembrane protein mainly located at the cell surface suggest that TIARP might participate in adipocyte development and metabolism and mediate some TNF␣ effects on the fat cell as a channel or a transporter. Tumor necrosis factor-alpha (TNF␣)1 exerts a wide range of effects on cells and tissues. In addition to its immunological functions, TNF␣ also markedly alters adipose tissue development and metabolism. Surprisingly, TNF␣ seems to be involved in the pathophysiology of two opposite metabolic disorders (1). High plasma levels of TNF␣ likely play an important role in the onset of cachectic states observed during cancer or severe infectious diseases (2). By contrast, more recent studies have indicated that the cytokine is overexpressed in adipose tissue of obese rodents or humans, and that this locally produced TNF␣ may be involved in the obesity-linked insulin resistance (3). Thus, since abnormalities in its production or action are associated with alterations in body fat mass, TNF␣ is likely an important effector of adipose tissue development and metabolism in vivo.Many in vitro studies also support the view that TNF␣ has profound effects on lipid metabolism and adipocyte differentiation. TNF␣ was reported to inhibit lipid storage by reducing synthesis and activity of several proteins essential for lipogenesis, such as lipoprotein lipase (4) and acetyl-coenzyme A carboxylase (5), or by inhibition in the expression and/or function of the insulin-sensitive glucose transporter GLUT4 pathway (6). Otherwise TNF␣ is able to stimulate lipolysis in adipocytes by different mechanisms (7,8). In addition to the above effects on lipid storage or mobilization, TNF␣ potently inhibits adipose conversion and even causes a dramatic de-differentiation of adipocytes in culture (9). Prevention of adipose conversion by TNF␣ has been es...
OBJECTIVECeramide is now recognized as a negative regulator of insulin signaling by impairing protein kinase B (PKB)/Akt activation. In different cells, two distinct mechanisms have been proposed to mediate ceramide inhibition of PKB/Akt: one involving atypical protein kinase C zeta (PKCζ) and the other the protein phosphatase-2 (PP2A). We hypothesized that ceramide action through PKCζ or PP2A might depend on plasma membrane (PM) structural organization and especially on caveolin-enriched domain (CEM) abundance.RESEARCH DESIGN AND METHODSWe have used different PKCζ mutant constructs or the PP2A inhibitor, okadaic acid (OKA), to selectively inhibit PKCζ- and PP2A-dependent pathways in cells expressing different caveolin-1 levels and evaluated the impact of insulin and ceramide on PKB/Akt activity in different PM subdomains.RESULTSAlthough the PKCζ-mediated negative effect of ceramide on insulin-stimulated PKB/Akt was dominant in adipocytes, a ceramide action through PP2A outside CEMs, prevented by OKA, was also unraveled. To test the importance of CEM to direct ceramide action through the PKCζ pathway, we treated 3T3-L1 preadipocytes devoid of CEMs with ceramide and we saw a shift of the lipid-negative action on PKB/Akt to a PP2A-mediated mechanism. In fibroblasts with low CEM abundance, the ceramide-activated PP2A pathway dominated, but could be shifted to a ceramide-activated PKCζ pathway after caveolin-1 overexpression.CONCLUSIONSOur results show that ceramide can switch from a PKCζ-dependent mechanism to a PP2A pathway, acting negatively on PKB/Akt, and hence revealing a critical role of CEMs of the PM in this process.
Aims/hypothesis Recent experiments in liver and adipocyte cell lines indicate that palmitate can induce endoplasmic reticulum (ER) stress. Since it has been shown that ER stress can interfere with insulin signalling, our hypothesis was that the deleterious action of palmitate on the insulin signalling pathway in muscle cells could also involve ER stress. Methods We used C2C12 and human myotubes that were treated either with palmitate or tunicamycin. Total lysates and RNA were prepared for western blotting or quantitative RT-PCR respectively. Glycogen synthesis was assessed by [ 14 C]glucose incorporation. Results Incubation of myotubes with palmitate or tunicamycin inhibited insulin-stimulated protein kinase B (PKB)/ v-akt murine thymoma viral oncogene homologue 1 (Akt). In parallel, an increase in ER stress markers was observed. Pre-incubation with chemical chaperones that reduce ER stress only prevented tunicamycin but not palmitateinduced insulin resistance. We hypothesised that ER stress activation levels induced by palmitate may not be high enough to induce insulin resistance, in contrast with tunicamycin-induced ER stress. Indeed, tunicamycin induced a robust activation of the inositol-requiring enzyme 1 (IRE-1)/ c-JUN NH 2 -terminal kinase (JNK) pathway, leading to serine phosphorylation of insulin receptor substrate 1 (IRS-1) and a decrease in IRS-1 tyrosine phosphorylation. In contrast, palmitate only induced a very weak activation of the IRE1/ JNK pathway, with no IRS1 serine phosphorylation. Conclusions/interpretation These data show that insulin resistance induced by palmitate is not related to ER stress in muscle cells.
Caveolins form plasmalemnal invaginated caveolae. They also locate around intracellular lipid droplets but their role in this location remains unclear. By studying primary adipocytes that highly express caveolin-1, we characterized the impact of caveolin-1 deficiency on lipid droplet proteome and lipidome. We identified several missing proteins on the lipid droplet surface of caveolin-deficient adipocytes and showed that the caveolin-1 lipid droplet pool is organized as multi-protein complexes containing cavin-1, with similar dynamics as those found in caveolae. On the lipid side, caveolin deficiency did not qualitatively alter neutral lipids in lipid droplet, but significantly reduced the relative abundance of surface phospholipid species: phosphatidylserine and lysophospholipids. Caveolin-deficient adipocytes can form only small lipid droplets, suggesting that the caveolin-lipid droplet pool might be involved in lipid droplet size regulation. Accordingly, we show that caveolin-1 concentration on adipocyte lipid droplets positively correlated with lipid droplet size in obese rodent models and human adipocytes. Moreover, rescue experiments by caveolin- green fluorescent protein in caveolin-deficient cells exposed to fatty acid overload demonstrated that caveolin-coated lipid droplets were able to grow larger than caveolin-devoid lipid droplets. Altogether, these data demonstrate that the lipid droplet-caveolin pool impacts on phospholipid and protein surface composition of lipid droplets and suggest a functional role on lipid droplet expandability.
Adipocytes specialized in the storage of energy as fat are among the most caveolae-enriched cell types. Loss of caveolae produces lipodystrophic diabetes in humans, which cannot be reversed by endothelial rescue of caveolin expression in mice, indicating major importance of adipocyte caveolae. However, how caveolae participate in fat cell functions is poorly understood. We investigated dynamic conditions of lipid store fluctuations and demonstrate reciprocal regulation of caveolae density and fat cell lipid droplet storage. We identified caveolin-1 expression as a crucial step in adipose cell lines and in mice to raise the density of caveolae, to increase adipocyte ability to accommodate larger lipid droplets, and to promote cell expansion by increased glucose utilization. In human subjects enrolled in a trial of 8 weeks of overfeeding to promote fattening, adipocyte expansion response correlated with initial caveolin-1 expression. Conversely, lipid mobilization in cultured adipocytes to induce lipid droplet shrinkage led to biphasic response of cavin-1 with ultimate loss of expression of cavin-1 and -3 and EHD2 by protein degradation, coincident with caveolae disassembly. We have identified the key steps in cavin/caveolin interplay regulating adipocyte caveolae dynamics. Our data establish that caveolae participate in a unique cell response connected to lipid store fluctuation, suggesting lipid-induced mechanotension in adipocytes.
We have studied the expression of the Id1, Id2, and Id3 genes during adipose differentiation of 3T3-F442A cells. All three Id mRNAs are present in preadipose cells, but the mRNA for Id3 is the most abundant. All three Id mRNAs sharply decline in the course of adipose differentiation, and their virtual disappearance precedes differentiation. The decrease in Id2 and Id3 is associated with adipose differentiation rather than with growth arrest since it is not observed in 3T3-C2 cells, a fibroblast line with a very low susceptibility to adipose conversion. The decline in Id2 and Id3 mRNAs is associated with a reduced transcription rate of the two genes. Id1 mRNA is reduced in amount during adipose conversion of 3T3-F442A cells, but the decrease is also observed in resting 3T3-C2 cells and is associated with very little decrease in transcription of the gene. Addition of fresh serum reactivates Id3 gene expression in quiescent 3T3-C2 cells but not in adipose 3T3-F442A cells. Stably transformed preadipose cells expressing an Id3 cDNA under the control of a viral promoter are virtually unable to differentiate. We postulate that the Id3 protein is a negative regulator of fat cell formation and presumably acts by preventing an as yet unidentified basic helix-loop-helix protein from activating the program of differentiation.In eukaryotes, the basic helix-loop-helix (bHLH) motif confers on proteins the ability to bind DNA in a sequence-specific manner (25). DNA binding requires dimerization through the helix-loop-helix domain (11, 34), but it is the basic domain that binds to DNA (11,53). Among proteins containing the bHLH motif are the members of the MyoD family. These regulatory proteins, specific to skeletal muscle, are able to induce muscle differentiation of various nonmyoblast cells (7,54). It is thought that in order to activate transcription of the genes participating in muscle differentiation, MyoD must form heterodimers with the bHLH proteins encoded by the ubiquitously expressed E2A gene discovered by Murre et al. (39). Since both MyoD and E2A proteins are present in undifferentiated myoblasts, an explanation is required as to how muscle precursor cells are prevented from differentiating. Such an explanation was provided by the discovery of Id proteins (4).Ids are a group of ubiquitous nuclear proteins that possess the helix-loop-helix domain but are missing the basic domain and therefore cannot bind DNA. The initial discovery of Id1 was followed by those of Id2 (48), Id3 (9), and Id4 (44). Id1 is present at high levels in proliferating myoblasts and is strongly down-regulated when myotubes are formed. Therefore, it appeared likely that Id1 prevented differentiation of muscle precursor cells by forming nonfunctional heterodimers with bHLH proteins required for differentiation and that when myoblasts ceased multiplying, the fall in Id1 released these bHLH proteins, which then became free to activate the genes participating in myogenesis (55). The products of the E2A gene and MyoD were likely candidates for heterod...
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