Expression profiling during adipocyte differentiation of 3T3-L1 fibroblasts

The 3T3-L1 cell line is a well-established and commonly used in vitro model to assess adipocyte differentiation. Over the course of several days confluent 3T3-L1 cells can be converted to adipocytes in the presence of an adipogenic cocktail. Changes in gene expression were measured by DNA microarrays at three time points (24 h, 4 days, and 1 week) during the course of differentiation from preadipocytes to mature adipocytes. Several functional categories of genes were affected by adipocyte conversion. In addition, seven genes were found to be commonly altered by 5-fold or more by adipocyte conversion at all three time points. Lipocalin 2, haptoglobin, serum amyloid A3, stearoyl-CoA desaturase, and 11beta-hydroxysteroid dehydrogenase 1 were induced while actin alpha2 and procollagen VIII alpha1 were suppressed by adipocyte differentiation. Further study of the regulation of these genes and pathways will lead to an increased understanding of the biochemical pathways involved in adipocyte differentiation and possibly to the identification of new therapeutic targets for treatment of obesity and other metabolic diseases.     

Adipokine gene expression in dog adipose tissues and dog white adipocytes differentiated in primary culture.

Obesity and its associated disorders are increasing in companion animals, particularly in dogs. We have investigated whether genes encoding key adipokines, some of which are implicated in the pathologies linked to obesity, are expressed in canine adipose tissues. Using RT-PCR, mRNAs encoding the following adipokines were detected in dog white adipose tissue: adiponectin, leptin, angiotensinogen, plasminogen activator inhibitor-1, IL-6, haptoglobin, metallothionein-1 and 2, and nerve growth factor. The adipokine mRNAs were present in all fat depots examined. Fractionation of adipose tissue by collagenase digestion showed that each gene was expressed in mature adipocytes. The mRNA for TNFalpha was not evident in adipose tissue, but was detected in isolated adipocytes. Fibroblastic preadipocytes from gonadal white fat were differentiated into adipocytes in primary culture and adipokine expression examined before and after differentiation (days 0 and 11, respectively). Each adipokine gene expressed in dog white adipocytes was also expressed in the differentiated cells. These results demonstrate that dog white adipose tissue expresses major adipokine genes, expression being in the adipocytes. Investigation of adipokine production and function will provide insight into the mechanisms involved in obesity-related pathologies in dogs and serve as a model for the related human diseases.     

The novel gene fad158, having a transmembrane domain and leucine-rich repeat, stimulates adipocyte differentiation

Adipocyte differentiation is known to be regulated by a complex array of genes known as master regulators. Using a subtraction method, we previously isolated 102 genes that are expressed in the early stage of adipocyte differentiation. One of these genes named fad158 (factor for adipocyte differentiation 158) seems to be a novel gene, since there is no significantly similar gene listed in databases. Both mouse and human fad158 encode 803 amino acids and contain 4 transmembrane regions and 8 leucine-rich repeat motifs. Expression of fad158 was induced at an early stage in differentiating 3T3-L1 cells and was observed in the skeletal muscle. When the expression was knocked down with an antisense method in 3T3-L1 cells, the accumulation of oil droplets was reduced. Moreover, on overexpression of fad158 in NIH-3T3 cells, which are fibroblasts and do not usually differentiate into adipocytes, stable transformants accumulated oil droplets and showed an elevated expression of adipocyte marker genes, indicating that these cells had differentiated into mature adipocytes. fad158 has the ability to regulate adipocyte differentiation positively, especially at an early stage.     

Crucial roles of D-type cyclins in the early stage of adipocyte differentiation

Cyclin D2 was isolated as one of the genes expressed early in adipogenesis. The expression of cyclin D2 increased temporarily early on and then again late in the differentiation process. The expression of cyclin D1 and cyclin D3, the other D-type cyclins, was also transiently induced early during adipocyte differentiation. RNAi (RNA interference)-mediated knockdown of cyclin D1, D2, or D3 inhibited the differentiation of 3T3-L1 cells into lipid-laden adipocytes. Moreover, the knockdown of cyclin D1 or D3 significantly inhibited mitotic clonal expansion (MCE), while silencing of the cyclin D2 gene had a milder effect on MCE. Each of the D-type cyclins seems to play a crucial role in adipocyte differentiation by regulating MCE.     

Characterization of the long pentraxin PTX3 as a TNFalpha-induced secreted protein of adipose cells

Exposure of preadipocytes to long-chain fatty acids induces the expression of several markers of adipocyte differentiation. In an attempt to identify novel genes and proteins that are regulated by fatty acids in preadipocytes, we performed a substractive hybridization screening and identified PTX3, a protein of the pentraxin family. PTX3 mRNA expression is transient during adipocyte differentiation of clonal cell lines and is absent in fully differentiated cells. Stable overexpression of PTX3 in preadipocytes has no effect on adipocyte differentiation. In line with this, PTX3 mRNA is expressed in the stromal-vascular fraction of adipose tissue, but not in the adipocyte fraction; however, in 3T3-F442A adipocytes, the PTX3 gene can be reinduced by tumor necrosis factor alpha (TNFalpha) in a dose-dependent manner. This effect is accompanied by PTX3 protein secretion from both 3T3-F442A adipocytes and explants of mouse adipose tissue. PTX3 mRNA levels are found to be higher in adipose tissue of genetically obese mice versus control mice, consistent with their increased TNFalpha levels. In conclusion, PTX3 appears as a TNFalpha-induced protein that provides a new link between chronic low-level inflammatory state and obesity.     

C/EBPalpha regulation of the growth-arrest-associated gene gadd45.

CCAAT/enhancer-binding protein alpha (C/EBPalpha) is expressed in postmitotic, differentiated adipocytes and is required for adipose conversion of 3T3-L1 cells in culture. Temporal misexpression of C/EBPalpha in undifferentiated adipoblasts leads to mitotic growth arrest. We report here that growth arrest- and DNA damage-inducible gene 45 (gadd45) is preferentially expressed in differentiated 3T3-L1 adipocytes similar to phenotype-associated genes. Furthermore, C/EBPalpha transactivates a reporter plasmid containing 1.5 kb of the gadd45 promoter region. The proto-oncogene myc, which inhibits adipocyte differentiation, abrogates C/EBPalpha activation of gadd45. gadd45 is known to be a target of the tumor suppressor p53 in a G1 checkpoint activated by DNA damage. Immunoprecipitation of radiolabeled proteins with conformation-specific antibodies revealed that wild-type p53 is expressed throughout 3T3-L1 adipocyte development, including the postmitotic period characterized by the accumulation of gadd45 and C/EBPalpha. A stable 3T3-L1 subline was engineered to express a dominant negative p53, human p53(143ala). The p53(143ala) subline differentiated to adipocytes and showed appropriate developmental expression of gadd45. These findings suggest that postmitotic growth arrest is coupled to adipocyte differentiation via C/EBPalpha stimulation of growth arrest-associated and phenotype-associated genes.     

Regulation of metallothionein gene expression and secretion in rat adipocytes differentiated from preadipocytes in primary culture.

The gene encoding metallothionein, a low mol. wt. metal binding and stress response protein, is expressed in white adipose tissue. In the present study, metallothionein (MT-1) gene expression and factors regulating metallothionein production have been examined in adipocytes induced to differentiate from fibroblastic preadipocytes in primary cell culture. On the induction of differentiation, the metallothionein-1 gene was strongly expressed in the cells and metallothionein released into the medium. A peak in metallothionein-1 mRNA level and metallothionein secretion occurred at 2 and 10 days post-differentiation, respectively, with a decrease in protein release after this time. The metallothionein-1 gene was expressed in the adipocytes prior to the adipsin and lipoprotein lipase genes, suggesting that it is an early marker of adipocyte differentiation. The addition of the glucocorticoid, dexamethasone, led to a substantial increase in metallothionein-1 mRNA in the cells and metallothionein secretion. Insulin and leptin also stimulated metallothionein production, although the effect was small. Neither noradrenaline nor the beta3-adrenoceptor agonist, BRL 37 344, altered metallothionein release but forskolin and bromo-cAMP were stimulatory, markedly increasing both metallothionein-1 level and metallothionein secretion. It is suggested that metallothionein is a novel secretory product of the differentiated white adipocyte and that its production is regulated particularly by glucocorticoids and through a cAMP-dependent pathway.     

Hyperphagia and Obesity in Na,K‐ATPase α2 Subunit‐Defective Mice

Objective: The Na,K‐ATPase α2 subunit gene (Atp1a2) is expressed in the brain, skeletal muscles, heart, and adipocytes. Specific function of the α2 subunit, such as involvement in differentiation and function of adipocytes, has not been addressed. The aim of this study was to examine whether Atp1a2‐defective heterozygous mice show obesity and reveal the mechanisms underlying the obesity. Research Methods and Procedures: We measured the differentiation and glucose uptake function of in vitro‐differentiated adipocytes derived from embryonic fibroblasts of Atp1a2‐defective mice. Food intake, body temperature, metabolic rate, and spontaneous activity and mRNA levels of neuropeptide genes were compared between the heterozygous and wild‐type adult mice. Results: Atp1a2 heterozygous female mice developed obesity after middle age. The time course of in vitro adipocyte differentiation of embryonic fibroblasts isolated from wild type, heterozygous, and homozygous mice was not different, glucose and Rb uptake activities of the in vitro‐differentiated adipocytes were not altered, and the effects of insulin on glucose uptake and those of monensin and ouabain on Rb uptake were similar among the genotypes. However, food intake in the light phase was significantly greater in the heterozygous mice than the wild type in the 24‐hour dark‐light cycle, whereas it was similar under constant‐light condition. Body temperature, metabolic rate at rest, and spontaneous motor activity of the heterozygous mice were similar to those of the wild type. Orexin mRNA level was lower in heterozygous than wild‐type mice. Discussion: The Na,K‐ATPase α2 subunit is not involved in the differentiation or in glucose and Rb uptake function of in vitro‐differentiated adipocytes. Hyperphagia is the likely primary cause of obesity in Atp1a2 heterozygous mice.     

The proteomic analysis of an adipocyte differentiated from human mesenchymal stem cells using two-dimensional gel electrophoresis

Adipose tissues play a crucial endocrine role in the control of whole body glucose homeostasis and insulin sensitivity. Considering the current substantial rise in obesity and obesity-related diseases, including diabetes, it is important to understand the molecular basis of adipocyte differentiation and its control. In this study, we have analyzed the protein expression inherent to adipogenic differentiation, by 2-DE, MALDI-TOF, and RT-PCR. This study focused on proteins that were differentially expressed by the differentiation of human mesenchymal stem cells (hMSCs) to adipocytes. We conducted 2-DE for each set of proteins in the cytosol of adipocytes that had differentiated from hMSC, in a pH range from 3-10. Thirty-two protein spots were shown to have different expression levels. Among these, eight up-regulated proteins were identified by MALDI-TOF/MS, as the following: syntaxin binding protein 3, OSBP-related protein 3, phosphodiesterase, glycophorin, immunoglobulin kappa chain variable region, peroxisome proliferative activated receptor gamma (PPAR-gamma), bA528A10.3.1 (novel protein similar to KIAA01616, isoform 1), and T cell receptor V-beta 4. Four proteins: syntaxin-3, OSBP-related protein 3, PPAR-gamma and glycophorin were associated with adipogenesis.     

Expression and secretion of inflammation-related adipokines by human adipocytes differentiated in culture: integrated response to TNF-alpha

The expression profile of a series of adipokine genes linked to inflammation has been examined by quantitative PCR during the differentiation of human preadipocytes to adipocytes in primary culture, together with the integrated effects of TNF-alpha on the expression of these adipokines in the differentiated adipocytes. Expression of the genes encoding adiponectin, leptin, and haptoglobin was highly differentiation dependent, the mRNA being undetectable predifferentiation with the level peaking 9-15 days postdifferentiation. Although angiotensinogen (AGT) and monocyte chemoattractant protein-1 (MCP-1) were both expressed before differentiation, the mRNA level increased markedly on differentiation. The expression of nerve growth factor (NGF) and plasminogen activator inhibitor-1 (PAI-1) fell after differentiation, whereas that of TNF-alpha and IL-6 changed little. Measurement of adiponectin, leptin, MCP-1, and NGF in the medium by ELISA showed that the protein secretion pattern paralleled cellular mRNA levels. Treatment of differentiated human adipocytes with TNF-alpha (5 or 100 ng/ml for 24 h) significantly decreased the level of adiponectin, AGT, and haptoglobin mRNA (by 2- to 4-fold), whereas that of leptin and PAI-1 was unchanged. In contrast, TNF-alpha induced substantial increases in IL-6, TNF-alpha, metallothionein, MCP-1, and NGF mRNAs, the largest increase being with MCP-1 (14.5-fold). MCP-1 and NGF secretion increased 8- to 10-fold with TNF-alpha, whereas leptin and adiponectin did not change. These results demonstrate that there are major quantitative changes in adipokine gene expression during differentiation of human adipocytes and that TNF-alpha has a pleiotropic effect on inflammation-related adipokine production, the synthesis of MCP-1 and NGF being highly induced by the cytokine.     

Vanillin induces adipocyte differentiation in 3T3-L1 cells by activating extracellular signal regulated kinase 42/44

AimsTo investigate the effect of vanillin, a dietary component, on adipocyte differentiation and the mechanism involved in the process using 3T3-L1 murine preadipocytes.Main methodsThe effect of vanillin on adipocyte differentiation was detected by Oil Red O analysis. The activation of extracellular signal regulated kinase 42/44 (ERK 42/44), Akt, expression of the key regulator of adipocyte differentiation peroxisome proliferators-activated receptor (PPARγ) and its target gene glucose transporter 4 (GLUT4) were detected by western blotting. Glucose uptake assay was used to determine the insulin sensitivity of adipocytes differentiated by vanillin treatment. To confirm the role of ERK 42/44 and Akt, Oil Red O analysis was performed with cells differentiated in the presence or absence of ERK inhibitor U0126 or Akt kinase 1/2 inhibitor.Key findingsVanillin induced adipocyte differentiation in 3T3-L1 cells in a dose dependent manner and also increased the expression levels of PPARγ and its target gene GLUT4. The adipocytes differentiated by vanillin exhibited insulin sensitivity as demonstrated by a significant increase in glucose uptake. Vanillin treatment activated the phosphorylation of ERK 42/44 during the initial phase of adipocyte differentiation but there was no significant change in the Akt phosphorylation status.SignificanceThe data show that vanillin induces adipocyte differentiation in 3T3-L1 cells by activating ERK42/44 and these adipocytes are insulin sensitive in nature.     

Proteome analysis of adipogenesis

Adipose tissue plays a crucial endocrine role in controlling whole body glucose homeostasis and insulin sensitivity. Given the substantial rise in obesity and obesity-related diseases such as diabetes, it is important to understand the molecular basis of adipocyte differentiation and its control. Many studies have successfully exploited gene array technology to monitor changes in the profile of expressed genes during adipocyte differentiation, although this method only measures changes at the level of individual mRNA species. Using two-dimensional polyacrylamide gel electrophoresis, high-throughput image analysis, and candidate picking coupled with sequencing mass spectrometry, we have followed the changes in protein expression profile that occur during the differentiation of 3T3-L1 fibroblasts into adipocytes in response to dexamethasone, isobutyl methyl xanthine and insulin, or to the PPARgamma agonist, ciglitazone. Using this technique we have found alterations in the profile of over 2000 protein species during adipogenesis. Our studies reveal previously unknown alterations during adipogenesis in the expression or mobility (on sodium dodecyl sulfate-polyacrylamide gel electrophoresis) of coactosin, which promotes actin filament destabilization, several signalling molecules, including RhoGDI-1, RhoGDI-2 and EHD1, and NEDD5 a protein involved in cytokinesis.     

peg10, an imprinted gene, plays a crucial role in adipocyte differentiation

An imprinted gene, paternally expressed gene (peg) 10, was isolated as one of the genes expressed early in adipogenesis. The expression of peg10 was elevated after the addition of inducers, and was detected in adipocyte differentiable 3T3-L1 cells, but not observed in the non-adipogenic cell line NIH-3T3. Moreover, the knockdown of peg10 by RNA interference (RNAi) inhibited the differentiation of 3T3-L1 cells into lipid-laden adipocytes. Interestingly, peg10 RNAi-treatment reduced the expressions of C/EBPbeta and C/EBPdelta, and inhibited mitotic clonal expansion. These findings strongly indicate that peg10 plays a crucial role at the immediate early stage of adipocyte differentiation.