miR-128-3p regulates 3T3-L1 adipogenesis and lipolysis by targeting <Emphasis Type="Italic">Pparg</Emphasis> and <Emphasis Type="Italic">Sertad2</Emphasis>

Differentiation of adipocytes and their aggregation to adipose tissue are critical for mammalian growth and development. MicroRNAs (miRNAs) are a class of endogenous small non-coding RNAs that play important roles in adipogenesis and lipid metabolism. miR-128-3p may contribute to adipose tissue development according to the previous studies. However, the role of miR-128-3p in the process of preadipocyte differentiation and lipid metabolism is not yet understood. The purpose of this research was to investigate the biological function and molecular mechanism of miR-128-3p in 3T3-L1 cells. In the present study, we found that miR-128-3p was downregulated during the process of 3T3-L1 preadipocyte differentiation. Overexpression of miR-128-3p obstructed the expressions of adipogenic marker genes as well as the lipid droplets accumulation and triglyceride content, suggesting the importance of miR-128-3p for adipogenesis. Moreover, miR-128-3p could lead to the retardation of cell proliferation in 3T3-L1 preadipocytes. Further evidences showed that, as a negative regulator of adipogenesis, miR-128-3p could directly target peroxisome proliferator-activated receptor γ (Pparg) which resulted in the suppression of 3T3-L1 preadipocyte differentiation, and miR-128-3p could also bind with SERTA domain containing 2 (Sertad2) which drove triglyceride hydrolysis and lipolysis. In addition, inhibition of Sertad2 with siRNA displayed the same effects as overexpression of miR-128-3p. Our research demonstrated that miR-128-3p impeded 3T3-L1 adipogenesis by targeting Pparg and Sertad2, resulting in the obstruction of preadipocyte differentiation and promotion of lipolysis. Taken together, this study offers profound insight into the mechanism of miRNA-mediated adipogenesis and lipid metabolism.     

Direct and indirect effects of leptin on preadipocyte proliferation and differentiation

Leptin has been shown to reduce body fat in vivo. Adipocytes express the leptin receptor; therefore, it is realistic to expect a direct effect of leptin on adipocyte growth and metabolism. In vitro studies examining the effect of leptin on adipocyte metabolism require supraphysiological doses of the protein to see a decrease in lipogenesis or stimulation of lipolysis, implying an indirect action of leptin. It also is possible that leptin reduces adipose mass by inhibiting preadipocyte proliferation (increase in cell number) and/or differentiation (lipid filling). Thus we determined direct and indirect effects of leptin on preadipocyte proliferation and differentiation in vitro. We tested the effect of leptin (0-500 ng/ml), serum from leptin-infused rats (0.25% by volume), and adipose tissue-conditioned medium from leptin-infused rats (0-30% by volume) on preadipocyte proliferation and differentiation in a primary culture of cells from male Sprague-Dawley rat adipose tissue. Leptin (50 ng/ml) stimulated proliferation of preadipocytes (P<0.05), but 250 and 500 ng leptin/ml inhibited proliferation of both preadipocyte and stromal vascular cell fractions (P<0.01), as measured by [3H]thymidine incorporation. Serum from leptin-infused rats inhibited proliferation of the adipose and stromal vascular fractions (P=0.01), but adipose tissue-conditioned medium had no effect on proliferation of either cell fraction. None of the treatments changed preadipocyte differentiation as measured by sn-glycerophosphate dehydrogenase activity. These results suggest that leptin could inhibit preadipocyte proliferation by modifying release of a factor from tissue other than adipose tissue.     

Growth of preadipocyte cell lines and cell strains from rodents in serum-free hormone-supplemented medium

Ob17 is a clonal cell line isolated from the epididymal fat pad of C57 BL/6J ob/ob mouse that differentiates into adiposelike cells in serum-supplemented medium. In serum-free medium, this cell line shows increased growth under the addition of insulin, transferrin, fibroblast growth factor (FGF), and a factor present in extract of rat submaxillary gland (SMGE). This medium is referred to as 4F. Epidermal growth factor or nerve growth factor cannot replace SMGE, whereas partially purified platelet extract can substitute for FGF but only partially for SMGE. 4F Medium is able to support the proliferation of cells from other established preadipocyte clonal lines, HGFu and 3T3-F442A, and also of preadipocyte cells isolated from the stromal-vascular fraction of rat and mouse adipose tissues. In each case 4F medium is insufficient to support the differentiation of these cells into adipocytes. Ob17 cells grown and maintained in serum-free hormone-supplemented medium retain the ability to convert to adiposelike cells after serum addition. This serum requirement for differentiation cannot be substituted by the addition of growth hormone or of other putative adipogenic factors, or both. The results are discussed with respect to the requirements for growth and differentiation of the 3T3-L1 and 1246 preadipocyte cell lines previously described.     

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.     

Adipogenic and lipolytic effects of chronic glucocorticoid exposure

Glucocorticoids have been proposed to be both adipogenic and lipolytic in action within adipose tissue, although it is unknown whether these actions can occur simultaneously. Here we investigate both the in vitro and in vivo effects of corticosterone (Cort) on adipose tissue metabolism. Cort increased 3T3-L1 preadipocyte differentiation in a concentration-dependent manner, but did not increase lipogenesis in adipocytes. Cort increased lipolysis within adipocytes in a concentration-dependent manner (maximum effect at 1-10 μM). Surprisingly, removal of Cort further increased lipolytic rates (～320% above control, P < 0.05), indicating a residual effect on basal lipolysis. mRNA and protein expression of adipose triglyceride lipase and phosphorylated status of hormone sensitive lipase (Ser563/Ser660) were increased with 48 h of Cort treatment. To test these responses in vivo, Sprague-Dawley rats were subcutaneously implanted with wax pellets with/without Cort (300 mg). After 10 days, adipose depots were removed and cultured ex vivo. Both free fatty acids and glycerol concentrations were elevated in fed and fasting conditions in Cort-treated rats. Despite increased lipolysis, Cort rats had more visceral adiposity than sham rats (10.2 vs. 6.9 g/kg body wt, P < 0.05). Visceral adipocytes from Cort rats were smaller and more numerous than those in sham rats, suggesting that adipogenesis occurred through preadipocyte differentiation rather than adipocyte hypertrophy. Visceral, but not subcutaneous, adipocyte cultures from Cort-treated rats displayed a 1.5-fold increase in basal lipolytic rates compared with sham rats (P < 0.05). Taken together, our findings demonstrate that chronic glucocorticoid exposure stimulates both lipolysis and adipogenesis in visceral adipose tissue but favors adipogenesis primarily through preadipocyte differentiation.     

Expression and regulation of pOb24 and lipoprotein lipase genes during adipose conversion

Lipoprotein lipase (LPL) and pOb24 mRNAs are known to be early markers of adipose cell differentiation. Comparative studies of the expression of pOb24 and LPL genes during adipose conversion of Ob1771 preadipocyte cells and in mouse adipose tissue have shown the following: 1) the expression of both genes takes place at confluence; this event can also be triggered by growth arrest of exponentially growing cells at the G1/S stage of the cell cycle; 2) In contrast to glycerol-3-phosphate dehydrogenase mRNA, the emergence of pOb24 and lipoprotein lipase mRNAs requires neither growth hormone or tri-iodothyronine as obligatory hormones nor insulin as a modulating hormone; 3) in mouse adipose tissue, pOb24 mRNA is present at a high level in stromal-vascular cells and at a low level in mature adipocytes, and in contrast LPL mRNAs are preferentially expressed in mature adipocytes. Thus, these two genes do not appear to be regulated in a similar manner, as also shown by the differential inhibition of their expression by tumor necrosis factor (TNF) and transforming growth factor-beta (TGF-beta).     

Modulation by phenobarbital of the differentiation of 3T3 preadipocytes

The effect of phenobarbital upon the differentiation of two preadipocyte cell lines, 3T3 F442A and 3T3 L-1, was examined by measuring the synthesis and secretion of lipoprotein lipase. Extracellular enzyme was measured by treating intact cells with heparin, and the intracellular enzyme was subsequently assayed in cell homogenates. When confluent cultures of 3T3 F442A cells were treated with insulin, the cells underwent differentiation as indicated by increased activity of lipoprotein lipase within 6 days, followed in turn by increased levels of protein and triglyceride. Addition of phenobarbital with insulin enhanced total lipoprotein lipase, protein, and triglyceride content. The activity of lipoprotein lipase accumulated in the heparin-releasable fraction during differentiation was increased 2- to 3-fold and the intracellular enzyme was enhanced 15- to 20-fold by the addition of phenobarbital. The ability of phenobarbital to modulate differentiation was dependent upon the time of addition. When added early in the postconfluent period, there was a greater increase in lipoprotein lipase activity than when the drug was added at later times. Phenobarbital also stimulated lipoprotein lipase in differentiating 3T3 L-1 cells in the presence of insulin, although lipoprotein lipase activity was moderately enhanced by phenobarbital alone in these cells. These results suggest that phenobarbital may affect the conversion of adipoblasts into preadipocytes and thereby increase the proportion of cells susceptible to the differentiating stimulus.     

Prokineticin Receptor 1 as a Novel Suppressor of Preadipocyte Proliferation and Differentiation to Control Obesity

Background

Adipocyte renewal from preadipocytes occurs throughout the lifetime and contributes to obesity. To date, little is known about the mechanisms that control preadipocyte proliferation and differentiation. Prokineticin-2 is an angiogenic and anorexigenic hormone that activate two G protein-coupled receptors (GPCRs): PKR1 and PKR2. Prokineticin-2 regulates food intake and energy metabolism via central mechanisms (PKR2). The peripheral effect of prokineticin-2 on adipocytes/preadipocytes has not been studied yet.

Methodology/Principal Findings

Since adipocytes and preadipocytes express mainly prokineticin receptor-1 (PKR1), here, we explored the role of PKR1 in adipose tissue expansion, generating PKR1-null (PKR1^−/−) and adipocyte-specific (PKR1^ad−/−) mutant mice, and using murine and human preadipocyte cell lines. Both PKR1^−/− and PKR1^ad−/− had excessive abdominal adipose tissue, but only PKR1^−/− mice showed severe obesity and diabetes-like syndrome. PKR1^ad−/−) mice had increased proliferating preadipocytes and newly formed adipocyte levels, leading to expansion of adipose tissue. Using PKR1-knockdown in 3T3-L1 preadipocytes, we show that PKR1 directly inhibits preadipocyte proliferation and differentiation. These PKR1 cell autonomous actions appear targeted at preadipocyte cell cycle regulatory pathways, through reducing cyclin D, E, cdk2, c-Myc levels.

Conclusions/Significance

These results suggest PKR1 to be a crucial player in the preadipocyte proliferation and differentiation. Our data should facilitate studies of both the pathogenesis and therapy of obesity in humans.     

Growth of preadipocyte cell lines and cell strains from rodents in serum-free hormone-supplemented medium

Summary Ob17 is a clonal cell line isolated from the epididymal fat pad of C57 BL/6J ob/ob mouse that differentiates into adiposelike cells in serum-supplemented medium. In serum-free medium, this cell line shows increased growth under the addition of insulin, transferrin, fibroblast growth factor (FGF), and a factor present in extract of rat submaxillary gland (SMGE). This medium is referred to as 4F. Epidermal growth factor or nerve growth factor cannot replace SMGE, whereas partially purified platelet extract can substitute for FGF but only partially for SMGE. 4F Medium is able to support the proliferation of cells from other established preadipocyte clonal lines, HGFu and 3T3-F442A, and also of preadipocyte cells isolated from the stromal-vascular fraction of rat and mouse adipose tissues. In each case 4F medium is insufficient to support the differentiation of these cells into adipocytes. Ob17 cells grown and maintained in serum-free hormone-supplemented medium retain the ability to convert to adiposelike cells after serum addition. This serum requirement for differentiation cannot be substituted by the addition of growth hormone or of other putative adipogenic factors, or both. The results are discussed with respect to the requirements for growth and differentiation of the 3T3-L1 and 1246 preadipocyte cell lines previously described. This work was supported by the “Centre National de la Recherche Scientifique” (Grant 1208-Biochimie du Développement and Grant 4162-Endocrinologie), by the “Ministère de la Recherce et de la Technologie” (Grant 81-L-1322), by the “Fondation pour la Recherche Médicale,” by NATO (Grant 1704), and by the “Institut National de la Santé et de la Recherche Médicale” (Grant 827006).     

Hormonal regulation of postnatal chicken preadipocyte differentiation in vitro

This study was designed to develop a culture system from the stromal-vascular fraction of chicken adipose tissue that can be used to characterize hormones that promote preadipocyte differentiation. Abdominal adipose tissue was excised from 2 to 4-week-old male broilers (Gallus domesticus) by sterile dissection. The stromal-vascular cell fraction from the adipose tissue was isolated by collagenase digestion, filtration, and subsequent centrifugation. These preadipocytes were seeded in six well culture plates and proliferated to confluency in 10% fetal bovine serum in DMEM/F12 (50:50) medium. At confluency, experiments were initiated to determine hormonal requirements for differentiation. Insulin (100 nM) stimulated expression of citrate lyase and sn-glycerol-3-phosphate dehydrogenase relative to lactate dehydrogenase in the presence of 2.5% chicken serum (P<0.05), but not with 10% chicken serum (P>0.05). Triiodothyronine (T(3), 1 nM) and insulin-like growth factor 1 (100 ng/ml) had no effect on differentiation. Dexamethasone (Dex, 1 microM) stimulated differentiation in 2.5 or 10% chicken serum (P<0.05). Insulin, Dex and 2.5% chicken serum stimulated enzymatic differentiation to the extent of 10% chicken serum, but heparin (10 U/ml) addition, in combination with insulin and Dex was necessary to stimulate lipid filling of adipocytes.     

Optimization of the differentiation of human preadipocytes in vitro

This study aimed at developing an optimal protocol for proliferation and differentiation of preadipocytes that is a prerequisite for constructing an ideal biohybrid composed of viable adipose precursor cells in a three-dimensional matrix. Such an implant could represent an adequate solution for correcting soft tissue defects, e.g., extensive deep burns or tumor resections. Preadipocytes were isolated from human subcutaneous adipose tissue samples and cultured in Dulbecco's modified eagle medium (DMEM)/Ham's F12 medium (F12) or OPTIMEM medium with or without the addition of human serum (hS) or fetal calf serum (FCS). The advantages of fibronectin-coated culture dishes for preadipocyte yield after isolation and differentiation were evaluated. After culture expansion, differentiation was induced by insulin, isobutylmethylxanthine, pioglitazone, dexamethasone, and transferrin in the absence of serum. The extent of differentiation was assayed by measuring the activity of glycerophosphate dehydrogenase as well as counting of differentiated versus undifferentiated cells. Our results show that fibronectin coating does not only strongly increase the yield of preadipocytes after isolation from adipose tissue but also significantly enhances differentiation of precursor cells to mature adipocytes. For optimal cell expansion, DMEM/F12 is more promoting than OPTIMEM and culturing with FCS shows a slightly better proliferation compared with hS supplementation. Differentiation, in contrast, is significantly improved when hS is used instead of FCS during proliferation. Our results smooth the way for autologous preadipocyte culturing and show that hS for preadipocyte culturing opens new and promising perspectives for adipose tissue engineering by optimizing in vitro expansion in cell culture and inducing substantial differentiation.     

Conversion to adipocytes of a clonal bone marrow preadipocyte line (H-1/A) and fatty acid composition of the resultant adipocytes

Conversion to adipocytes and fatty acid composition were investigated in a clonal bone marrow preadipocyte line (H-1/A). The growing cells exhibited a fibroblastic appearance. After the cessation of growth, triacylglyceride (TG) synthesis in the cells increased as they incorporated precursor from the growth medium and became adipocytes. Hydrocortisone and insulin accelerated the TG synthesis in H-1/A cells in a dose-dependent manner when they were cultured in the growth medium containing 10% horse serum. The rate of conversion to adipocytes was reduced as the concentration of horse serum was decreased, and this reduction was not influenced by the addition of insulin and/or hydrocortisone. These results suggest that conversion to adipocytes of H-1/A cells is primarily dependent on some component(s) of the serum. Conversion to adipocytes of the cells may involve a process of differentiation since the conversion was completely inhibited when the cells were cultured in the presence of bromodeoxyuridine. Fatty acid composition was significantly different between adipose H-1/A cells and adipocytes derived from other marrow preadipocyte line MC3T3-G2/PA6 cells. Unsaturated fatty acids accounted for 76% of the fatty acid composition of adipose H-1/A cells; in contrast, saturated fatty acids constituted 65% of the fatty acid composition of the adipose MC3T3-G2/PA6 cells. These results suggest that there is a heterogeneity of preadipocytes in bone marrow. These two preadipocyte lines thus provide a useful tool for the study of marrow adipocytes and can also be used to analyze the hematopoietic microenvironment through studies of the effect of these cells on hematopoietic cell proliferation.     

Tumor Necrosis Factor‐α Stimulates Cell Proliferation in Adipose Tissue‐Derived Stromal‐Vascular Cell Culture: Promotion of Adipose Tissue Expansion by Paracrine Growth Factors

Objective: Elevated levels of tumor necrosis factor‐α (TNF‐α) protein and mRNA have been reported in adipose tissue from obese humans and rodents. However, TNF‐α has catabolic and antiadipogenic effects on adipocytes. Addressing this paradox, we tested the hypothesis that paracrine levels of TNF‐α, alone or together with insulin‐like growth factor‐I (IGF‐I), support preadipocyte development. Research Methods and Procedures: Cultured stromal‐vascular cells from rat inguinal fat depots were exposed to serum‐free media containing insulin and 0.2 nM TNF‐α, 2.0 nM TNF‐α, or 0.2 nM TNF‐α + 1.0 nM IGF‐I at different times during 7 days of culture. Results: TNF‐α inhibited adipocyte differentiation as indicated by a reduction in both immunocytochemical reactivity for the preadipocyte‐specific antigen (AD3; early differentiation marker) and glycerol‐3‐phosphate dehydrogenase activity (late differentiation marker). Early exposure (Days 1 through 3 of culture) to 0.2 nM TNF‐α did not have a long term effect on inhibiting differentiation. Continuous exposure to 0.2 nM TNF‐α from Days 1 through 7 of culture resulted in a 75% increase in cell number from control. There was a synergistic effect of 0.2 nM TNF‐α + 1 nM IGF‐I on increasing cell number by Day 7 of culture to levels greater than those observed with either treatment applied alone. Discussion: These data suggest that paracrine levels (0.2 nM) of TNF‐α alone or in combination with IGF‐I may support adipose tissue development by increasing the total number of stromal‐vascular and/or uncommitted cells within the tissue. These cells may then be recruited to become preadipocytes or may alternatively serve as infrastructure to support adipose tissue growth.     

Effects of transforming growth factor β1 and basic fibroblast growth factor on lipoprotein lipase activity in primary cultures of chicken (Gallus domesticus) adipocyte precursors

• 1.1. The effect of TGF-β and bFGF on lipoprotein lipase activity in chicken adipocyte precursors was investigated.
• 2.2. Lipoprotein lipase activity was reduced by up to 80% by incubation with TGF-β whereas bFGF had no effect.
• 3.3. Contrary to that found with the 3T3-L1 preadipocyte cell line it was not necessary for TGF-β to be present prior to the start of differentiation in order to be effective.
• 4.4. Incubation of adipocyte precursors with actinomycin D abolished the effect of TGF-β suggesting that synthesis of a protein effector is required.
• 5.5. These results indicate differences in responsiveness to TGF-β and bFGF between primary chicken adipocyte precursors and some preadipocyte cell lines.

     

HRASLS3 is a PPARgamma-selective target gene that promotes adipocyte differentiation

The prevalence of obesity and its associated metabolic diseases worldwide has focused attention on understanding the mechanisms underlying adipogenesis. The nuclear receptor PPARgamma has emerged as a central regulator of adipose tissue function and formation. Despite the identification of numerous PPARgamma targets involved in a range of processes, from lipid droplet formation to adipokine secretion, information is still lacking on targets downstream of PPARgamma that directly affect fat cell differentiation. Here we identify HRASLS3 as a novel PPARgamma regulated gene with a role in adipogenesis. HRASLS3 expression increases during the differentiation of preadipocyte cell lines and is highly expressed in white and brown adipose tissue in mice. HRASLS3 expression is induced by PPARgamma ligands in preadipocyte cell lines as well in adipose tissue in vivo. We demonstrate that the HRASLS3 promoter contains a functional PPAR response element and is a direct target for regulation by PPARgamma/RXR heterodimers. Finally, we show that overexpression of HRASLS3 augments PPARgamma-driven lipid accumulation and adipogenesis, whereas siRNA-mediated knockdown of HRASLS3 expression decreases differentiation. Together, these results identify HRASLS3 as one of the downstream effectors of PPARgamma action in adipogenesis.     

Reconstituted basement membrane potentiates in vivo adipogenesis of 3T3-F442A cells

Adipocytes forming fat pad in vivo are surrounded by well developed basement membranes. Synthesis of basement membrane is enhanced during in vitro differentiation of preadipocyte line. In order to know the role of basement membrane in adipogenesis in vivo, we injected 3T3-F442A preadipocytes subcutaneously into nude mice together with or without the reconstituted basement membrane, Matrigel. Histological sections of the fat pads newly formed by injecting the cell alone showed dense population of immature adipocytes and microvessels within 2 weeks and they matured rapidly. In contrast, injection of the cells together with Matrigel showed sparse adipocytes after 2 weeks and they matured slowly over the period of 6 weeks. Quantification of the process by measuring the weight, DNA content, triglyceride content and glycerophosphate dehydrogenase (GPDH) activity of the fat pads showed that injection of the cell alone resulted in early maturation of adipose tissue with fewer adipocytes while the presence of Matrigel decelerated but potentiated the maturation of adipose tissue with 2 fold contents of DNA, triglyceride and GPDH activity. We thus showed that reconstituted basement membrane (Matrigel) supported the survival and maturation of adipocytes. This revised version was published online in July 2006 with corrections to the Cover Date.