Adipogenesis-related increase of semicarbazide-sensitive amine oxidase and monoamine oxidase in human adipocytes

A strong induction of semicarbazide-sensitive amine oxidase (SSAO) has previously been reported during murine preadipocyte lineage differentiation but it remains unknown whether this emergence also occurs during adipogenesis in man. Our aim was to compare SSAO and monoamine oxidase (MAO) expression during in vitro differentiation of human preadipocytes and in adipose and stroma-vascular fractions of human fat depots. A human preadipocyte cell strain from a patient with Simpson-Golabi-Behmel syndrome was first used to follow amine oxidase expression during in vitro differentiation. Then, human preadipocytes isolated from subcutaneous adipose tissues were cultured under conditions promoting ex vivo adipose differentiation and tested for MAO and SSAO expression. Lastly, human adipose tissue was separated into mature adipocyte and stroma-vascular fractions for analyses of MAO and SSAO at mRNA, protein and activity levels. Both SSAO and MAO were increased from undifferentiated preadipocytes to lipid-laden cells in all the models: 3T3-F442A and 3T3-L1 murine lineages, human SGBS cell strain or human preadipocytes in primary culture. In human subcutaneous adipose tissue, the adipocyte-enriched fraction exhibited seven-fold higher amine oxidase activity and contained three- to seven-fold higher levels of mRNAs encoded by MAO-A, MAO-B, AOC3 and AOC2 genes than the stroma-vascular fraction. MAO-A and AOC3 genes accounted for the majority of their respective MAO and SSAO activities in human adipose tissue. Most of the SSAO and MAO found in adipose tissue originated from mature adipocytes. Although the mechanism and role of adipogenesis-related increase in amine oxidase expression remain to be established, the resulting elevated levels of amine oxidase activities found in human adipocytes may be of potential interest for therapeutic intervention in obesity.     

11β-hydroxysteroid Dehydrogenase 1 in Adipocytes: Expression is Differentiation-dependent and Hormonally Regulated

11β-hydroxysteroid dehydrogenase type 1 (11β-HSD-1) catalyses the reversible metabolism of physiological glucocorticoids (cortisol, corticosterone) to inactive metabolites (cortisone, 11-dehydrocorticosterone), thus regulating glucocorticoid access to receptors. 11β-HSD-1 expression is regulated during development and by hormones in a tissue specific manner. The enzyme is highly expressed in liver, where it may influence glucocorticoid action on fuel metabolism, processes also important in adipose tissue. Here we show that 11β-HSD-1 is expressed in white adipose tissue, in both the adipocyte and stromal/vascular compartments, and in the adipocyte cell lines 3T3-F442A and 3T3-L1. In these cells, 11β-HSD-1 expression is induced upon differentiation into adipocytes and is characteristic of a ‘late differentiation’ gene, with maximal expression 6-8 days after confluence is reached. In intact 3T3-F442A adipocytes the enzyme direction is predominantly 11β-reduction, activating inert glucocorticoids. The expression of 11β-HSD-1 mRNA is altered in fully differentiated 3T3-F442A adipocytes treated with insulin, dexamethasone or a combination of the hormones, in an identical manner to glycerol-3-phosphate dehydrogenase (GPDH) mRNA (encoding a key enzyme in triglyceride synthesis and a well-characterised marker of adipocyte differentiation). The demonstration of 11β-HSD-1 expression in adipocytes and its predominant reductase activity in intact 3T3-F442A adipocytes suggests that 11β-HSD-1 may play an important role in potentiating glucocorticoid action in these cells. 3T3-F442A and 3T3-L1 represent useful model systems in which to examine the factors which regulate 11β-HSD-1 gene expression and the role of 11β-HSD-1 in modulating glucocorticoid action in adipose tissue.     

Influence of high-fat diet on amine oxidase activity in white adipose tissue of mice prone or resistant to diet-induced obesity

Decreased monoamine oxidase (MAO) activity has been observed in adipose tissue of obese patients. Since substrates of MAO and semicarbazide-sensitive amine oxidase (SSAO) can modify adipocyte metabolism, this work investigates whether changes in amine oxidase activity may occur during white adipose tissue (WAT) development. We evaluated MAO and SSAO activities in WAT of high-fat diet (HFD) and low-fat diet fed mice. To distinguish the effect of HFD on its own from the effect of fat mass enlargement, obesity-prone transgenic line of the FVBn strain lacking beta3-adrenergic receptors (AR) but expressing human beta3-AR and alpha2-AR (mbeta3-/-, hbeta3+/+, halpha2+/-) was compared to its obesity-resistant control (mbeta3-/-, hbeta3+/+). As already reported, the former mice became obese while the latter resisted to HFD. No significant change in SSAO or MAO activity was found in WAT of both strains after HFD when expressing oxidase activity per milligram of protein. However, when considering the overall capacity of the fat depots to oxidize tyramine or benzylamine, there was an increase in MAO and SSAO activity only in the enlarged WAT of HFD-induced obese mice. Therefore, the comparison of these models allowed to demonstrate that the higher amine oxidase capacity hold in enlarged fat stores of obese mice is more likely the consequence of increased fat cell number rather than the result of an increased expression of MAO or SSAO in the adipocyte.     

Aortic carboxypeptidase-like protein is regulated by transforming growth factor beta in 3T3-L1 preadipocytes

Adipogenesis is characterized by early remodeling of the extracellular matrix, allowing preadipocytes to adopt a more spherical shape and optimize lipid accumulation as they mature. Aortic carboxypeptidase-like protein (ACLP), found in collagen-rich tissues including adipose tissue, is expressed in 3T3-L1 and 3T3-F442A preadipocytes, and is downregulated during adipogenesis. We now report that ACLP is found in medium conditioned by 3T3-L1 preadipocytes. Transforming growth factor (TGF) beta, a known modulator of fibrillar matrix protein production, increased ACLP expression by 2.4+/-0.4-fold (mean+/-SE; n=3) in 3T3-L1 preadipocytes, through a mechanism that requires p42/44 MAPK activity. Addition of TGFbeta to differentiation medium, which inhibits adipogenesis, raised ACLP levels in 3T3-L1 cells. However, sustained expression of ACLP in stable clones of 3T3-L1 or 3T3-F442A preadipocytes did not interfere with adipogenesis.     

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.     

Efficient adenoviral transduction of 3T3-F442A preadipocytes without affecting adipocyte differentiation

The preadipocyte cell lines 3T3-L1 and 3T3-F442A are widely used to study the cellular mechanisms of preadipocyte differentiation and mature adipocyte functions. However, transfection with naked DNA is inefficient in these cell lines. Adenoviral gene transfer is a powerful technique to induce high levels of transgene expression. After failing to obtain 3T3-F442A stable transfectants, we studied different techniques designed to enhance the efficiency of adenoviral transduction in fat cells. First, we compared the effects of two agents known to significantly enhance adenoviral transgene transduction, namely the cationic lipid lipofectamine and the cationic polymer polylysine. We show here that lipofectamine-assisted adenoviral transduction was more efficient in 3T3-F442A than in 3T3-L1 preadipocytes at all tested multiplicity of infection. Lipofectamine, and more efficiently polylysine, yielded high and sustained levels of adenoviral transgene expression in 3T3-F442A preadipocytes. Adenoviral transgene expression was maintained throughout the differentiation process. Furthermore, the two agents also efficiently enhanced adenoviral transduction in mature 3T3-F442A adipocytes. Interestingly, neither protocol affected the differentiation process, morphological features or protein expression of mature adipocytes. These approaches could be of interest to study fat cell differentiation and the functions of mature adipocytes.     

Transdifferentiation of preadipose cells into smooth muscle-like cells: role of aortic carboxypeptidase-like protein

Adipocyte differentiation involves dramatic cell shape alterations that are accompanied by changes in the expression of cytoskeletal and extracellular matrix (ECM) proteins. Aortic carboxypeptidase-like protein (ACLP) is a secreted protein associated with the extracellular matrix whose expression is induced during smooth muscle (SM) differentiation. We analyzed the expression of ACLP gene during adipocyte differentiation of 3T3-F442A, 3T3-L1, and Ob1771 preadipocytes. Our results show that ACLP mRNA and protein are expressed in growing cells and after commitment. Thereafter, their expression levels decrease, as opposed to that of aP2 and PPARgamma2. Consistent with these observations, ACLP mRNA is expressed in the stromal-vascular fraction of adipose tissue but not in the adipocyte fraction. Overexpression of ACLP in 3T3-F442A preadipocytes inhibits adipocyte differentiation at both morphological and molecular level. However, ACLP overexpression promotes transdifferentiation of preadipocytes into smooth muscle-like cells, which express specific markers such as SM22alpha, SM alpha-actin, SM-MHC, and caldesmon. These findings demonstrate that overexpression of a single extracellular matrix protein is sufficient to induce transdifferentiation and that ACLP may modulate the commitment of mesodermal cells into different lineages depending upon its pattern of expression.     

Studies of lipoprotein lipase during the adipose conversion of 3T3 cells.

Lipoprotein lipase activity is negligible in exponentially growing 3T3-L1 cells and 3T3-F442A cells, but develops in both lines when they reach a confluent state and undergo adipose conversion. 3T3-C2 cells, which undergo adipose conversion with extremely low frequency, do not develop the enzyme. The lipase activity of 3T3-L1 and 3T3-F442A is greatly enhanced by insulin and increases 80–180 fold during the adipose conversion. The lipase has the following characteristics in common with lipoprotein lipase from adipose and other tissues: it is dependent upon serum, is inhibited by 0.5–1.0 M sodium chloride, is recovered from acetone powders, has an alkaline pH optimum and is released from the cells by heparin. Like the lipoprotein lipase of tissue adipose cells, the enzyme of 3T3-L1 decays in the presence of cycloheximide with a half-time of about 25 min at 37°C.The ability of 3T3-F442A and 3T3-L1 to take up triglyceride from the medium depends almost completely upon lipoprotein lipase. They incorporate the fatty acids of a large fraction of a triglyceride emulsion added to the medium, and this utilization is stimulated by heparin. Very little of the glycerol portion of the triglyceride is incorporated. 3T3-C2, which lacks lipoprotein lipase, utilizes very little of either the fatty acid or the glycerol portion of triglyceride.The relevance of external lipid or lipoprotein to both the adipose conversion and the appearance of lipoprotein lipase was tested using confluent cultures in medium depleted of these components. In the presence of serum whose lipoproteins have been removed by flotation, lines 3T3-F442A and 3T3-L1 undergo adipose conversion as completely as in the presence of untreated serum, and lipoprotein lipase activity appears at essentially the same rate. In medium whose serum supplement has been extracted with acetone:ethanol, 3T3-F442A cells undergo adipose conversion to nearly the same extent as in untreated serum, and develop nearly the same increase in lipoprotein lipase activity.Unless even very low concentrations of lipids or lipoprotein are saturating it can be concluded that the adipose conversion does not depend upon external lipids or lipoproteins for its induction; rather the differentiation program is built into the cell type and comes into operation when growth is arrested even in their absence. The source of fatty acids utilized for triglyceride synthesis, however, may be affected by the amount of lipid provided to the cells.     

Alterations of peroxisome proliferator-activated receptor delta activity affect fatty acid-controlled adipose differentiation

Fatty acids have been postulated to regulate adaptation of adipose mass to nutritional changes by controlling expression of genes implicated in lipid metabolism via activation of nuclear receptors. Ectopic expression of the nuclear receptors PPARgamma or PPARdelta promotes adipogenesis in fibroblastic cells exposed to thiazolidinediones or long-chain fatty acids. To investigate the role of PPARdelta in fatty acid regulation of gene expression and adipogenesis in a preadipose cellular context, we studied the effects of overexpressing the native receptor or the dominant-negative PPARdelta mutant in Ob1771 and 3T3-F442A cells. Overexpression of PPARdelta enhanced fatty acid induction of the adipose-related genes for fatty acid translocase, adipocyte lipid binding protein, and PPARgamma and fatty acid effects on terminal differentiation. A transactivation-deficient form of PPARdelta mutated in the AF2 domain severely reduced these effects. Findings are similar in Ob1771 or 3T3-F442A preadipose cells. These data demonstrate that PPARdelta plays a central role in fatty acid-controlled differentiation of preadipose cells. Furthermore, they suggest that modulation of PPARdelta expression or activity could affect adaptive responses of white adipose tissue to nutritional changes.     

Benzylamine antihyperglycemic effect is abolished by AOC3 gene invalidation in mice but not rescued by semicarbazide-sensitive amine oxidase expression under the control of aP2 promoter

Semicarbazide-sensitive amine oxidase (SSAO) is a transmembrane enzyme that metabolizes primary amines from endogenous or dietary origin. SSAO is highly expressed in adipose, smooth muscle and endothelial cells. In each of these cell types, SSAO is implicated in different biological functions, such as glucose transport activation, extracellular matrix maturation and leucocyte extravasation, respectively. However, the physiological functions of SSAO and their involvement in pathogenesis remain uncompletely characterized. To better understand the role of adipose tissue SSAO, we investigated whether it was necessary and/or sufficient to produce the antihyperglycemic effect of the SSAO-substrate benzylamine, already reported in mice. Therefore, we crossed SSAO-deficient mice invalidated for AOC3 gene and transgenic mice expected to express human SSAO in an adipocyte-specific manner, under the control of aP2 promoter. The aP2?Chuman AOC3 construct (aP2?ChAOC3) was equally expressed in the adipose tissue of mice expressing or not the native murine form and almost absent in other tissues. However, the corresponding SSAO activity found in adipose tissue represented only 20?% that of control mice. As a consequence, the benzylamine antihyperglycemic effect observed during glucose tolerance test in control was abolished in AOC3-KO mice but not rescued in mice expressing aP2?ChAOC3. The capacity of benzylamine or methylamine to activate glucose uptake in adipocytes exhibited parallel variations in the corresponding genotypes. Although the aP2?ChAOC3 construct did not allow a total rescue of SSAO activity in adipose tissue, it could be assessed from our observations that adipocyte SSAO plays a pivotal role in the increased glucose tolerance promoted by pharmacological doses of benzylamine.     

Increased monoamine oxidase and semicarbazide-sensitive amine oxidase activities in white adipose tissue of obese dogs fed a high-fat diet

Adipocytes express two types of amine oxidases: the cell surface semicarbazide-sensitive amine oxidase (SSAO) and the mitochondrial monoamine oxidase (MAO). In human abdominal subcutaneous adipose tissue, it has been reported that SSAO substrates stimulate glucose transport and inhibit lipolysis while MAO activity is decreased in obese patients when compared to age-matched controls. However, no information has been reported on visceral WAT. To further investigate the obesity-induced regulations of MAO and SSAO in white adipose tissue (WAT) from different anatomical locations, enzyme activities and mRNA abundance have been determined on tissue biopsies from control and high-fat fed dogs, an obesity model already described to be associated with arterial hypertension and hyperinsulinemia. MAO activity was increased in the enlarged omental WAT of diet-induced obese dogs, but not in their mesenteric WAT, another intra-abdominal fat depot. Subcutaneous WAT did not exhibit any change in MAO activity, as did the richest MAO-containing tissue: liver. Similarly, SSAO was increased in omental WAT of diet-induced obese dogs, but was not modified in other WAT and in aorta. The increase in SSAO activity observed in omental WAT likely results from an increased expression of the AOC3 gene since mRNA abundance and maximal benzylamine oxidation velocity were increased. Finally, plasma SSAO was decreased in obese dogs. Although the observed regulations differ from those found in subcutaneous WAT of obese patients, this canine model shows a tissue- and site-specific regulation of peripheral MAO and SSAO in obesity.