Role of C/EBPβ-LAP and C/EBPβ-LIP in early adipogenic differentiation of human white adipose-derived progenitors and at later stages in immature adipocytes

We investigated the role of the major isoforms of CCAAT enhancer binding protein β (C/EBPβ), C/EBPβ-LAP and C/EBPβ-LIP, in adipogenesis of human white adipose-derived stromal/progenitor cells (ASC). C/EBPβ gene expression was transiently induced early in adipogenesis. At later stages, in immature adipocytes, the C/EBPβ mRNA and protein levels declined. The C/EBPβ-LIP protein steady-state level decreased considerably stronger than the C/EBPβ-LAP level and the C/EBPβ-LIP half-life was significantly shorter than the C/EBPβ-LAP half-life. The turn-over of both C/EBPβ-isoforms was regulated by ubiquitin/proteasome-dependent degradation. These data suggest that the protein stability of the C/EBPβ-isoforms is differentially regulated in the course of adipogenesis and in immature adipocytes. Constitutive overexpression of C/EBPβ-LIP had antiadipogenic activity in human ASC. C/EBPβ-LAP, which promotes adipogenesis in mouse 3T3-L1 preadipocytes by directly activating expression of the adipogenic keyregulator PPARγ2, induced the expression of PPARγ2 and of the adipocyte differentiation gene product FABP4 in confluent ASC in the absence of adipogenic hormones. At later stages after hormone cocktail-induced adipogenesis, in immature adipocytes, constitutive overexpression of C/EBPβ-LAP led to reduced expression of PPARγ2 and FABP4, C/EBPα expression was downregulated and the expression of the adipocyte differentiation gene products adiponectin and leptin was impaired. These findings suggest that constitutive overexpression of C/EBPβ-LAP induces adipogenesis in human ASC and negatively regulates the expression of adipogenic regulators and certain adipocyte differentiation gene products in immature adipocytes. We conclude the regulation of both C/EBPβ gene expression and C/EBPβ-LIP and C/EBPβ-LAP protein turn-over plays an important role for the expression of adipogenic regulators and/or adipocyte differentiation genes in early adipogenic differentiation of human ASC and at later stages in human immature adipocytes.     

Asiatic Acid Inhibits Adipogenic Differentiation of Bone Marrow Stromal Cells

Bone marrow mesenchymal stromal cells (BMSCs) are the common precursors for both osteoblasts and adipocytes. With aging, BMSC osteoblast differentiation decreases whereas BMSC differentiation into adipocytes increases, resulting in increased adipogenesis and bone loss. In the present study, we investigated the effect of asiatic acid (AA) on adipocytic differentiation of BMSCs. AA inhibited the adipogenic induction of lipid accumulation, activity of glycerol-3-phosphate dehydrogenase, and expression of marker genes in adipogenesis: peroxisome proliferation-activated receptor (PPAR)γ, adipocyte fatty acid-binding protein (ap) 2, and adipsin. Further, we found that AA did not alter clonal expansion rate and expression of C/EBPβ, upstream key regulator of PPARγ, and binding activity of C/EBPβ to PPARγ promoter was not affected by AA as well. These findings suggest that AA may modulate differentiation of BMSCs to cause a lineage shift away from the adipocytes, and inhibition of PPARγ by AA is through C/EBPβ-independent mechanisms. Thus, AA could be a potential candidate for a novel drug against osteoporosis.     

A proline-type fullerene derivative inhibits adipogenesis by preventing PPARγ activation

Obesity and its associated metabolic diseases represent some of the most rapidly expanding health issues worldwide, and, thus, the development of a novel chemical compound to suppress adipogenesis is strongly expected. We herein investigated the effects of water-soluble fullerene derivatives: a bis-malonic acid derivative and three types of proline-type fullerene derivatives, on adipogenesis using NIH-3T3 cells overexpressing PPARγ. One of the proline-type fullerene derivatives (P3) harboring three carboxy groups significantly inhibited lipid accumulation and the expression of adipocyte-specific genes, such as aP2, induced by the PPARγ agonist rosiglitazone. On the other hand, the bis-malonic acid derivative (M) and the 2 other proline-type fullerene derivatives (P1, P2), which have two carboxy groups, had no effect on PPARγ-mediated lipid accumulation or the expression of aP2. P3 fullerene also inhibited lipid accumulation induced by the combined stimulation with 3-isobutyl-1-methylxanthine (IBMX), dexamethasone, and insulin in 3T3-L1 preadipocytes. During the differentiation of 3T3-L1 cells into adipocytes, P3 fullerene did not affect the expression of C/EBPδ, C/EBPβ, or PPARγ, but markedly inhibited that of aP2 mRNA. These results suggest that P3 fullerene exhibits anti-obesity activity by preventing the activation of PPARγ.     

Antiadipogenic effect of carnosic acid,a natural compound present in Rosmarinus officinalis, is exerted through the C/EBPs and PPARγ pathways at the onset of the differentiation program

Background

Obesity is a serious health problem all over the world, and inhibition of adipogenesis constitutes one of the therapeutic strategies for its treatment. Carnosic acid (CA), the main bioactive compound of Rosmarinus officinalis extract, inhibits 3T3-L1 preadipocytes differentiation. However, very little is known about the molecular mechanism responsible for its antiadipogenic effect.

Methods

We evaluated the effect of CA on the differentiation of 3T3-L1 preadipocytes analyzing the process of mitotic clonal expansion, the level of adipogenic markers, and the subcellular distribution of C/EBPβ.

Results

CA treatment only during the first day of 3T3-L1 differentiation process was enough to inhibit adipogenesis. This inhibition was accompanied by a blockade of mitotic clonal expansion. CA did not interfere with C/EBPβ and C/EBPδ mRNA levels but blocked PPARγ, and FABP4 expression. C/EBPβ has different forms known as LIP and LAP. CA induced an increase in the level of LIP within 24 h of differentiation, leading to an increment in LIP/LAP ratio. Importantly, overexpression of LAP restored the capacity of 3T3-L1 preadipocytes to differentiate in the presence of CA. Finally, CA promoted subnuclear de-localization of C/EBPβ.

Conclusions

CA exerts its anti-adipogenic effect in a multifactorial manner by interfering mitotic clonal expansion, altering the ratio of the different C/EBPβ forms, inducing the loss of C/EBPβ proper subnuclear distribution, and blocking the expression of C/EBPα and PPARγ.

General significance

Understanding the molecular mechanism by which CA blocks adipogenesis is relevant because CA could be new a food additive beneficial for the prevention and/or treatment of obesity.     

Activated T-cells and pro-inflammatory cytokines differentially regulate prostaglandin E2 secretion by mesenchymal stem cells

In recent years it has become clear that mesenchymal stem or stromal cells (MSCs) are capable of modulating inflammatory and immune responses through interaction with a wide variety of cells. Whereas several studies indicated that PGE2 is one of the chief soluble mediators involved in these processes, here we investigated prostaglandin E2 (PGE2) production of murine bone marrow- (BM-) and adipose tissue- (Ad-) derived MSCs stimulated with pro-inflammatory cytokines TNF-α and IFN-γ, or co-cultured with ConA-induced T-cell blasts. We found that both MSC populations are able to produce high amounts of PGE2 in MSC/activated T-cell co-cultures. This effect was markedly attenuated when direct cell-cell contact was prevented in transwell system, indicating that the elicitation of the PGE2 secretion of MSCs is contact-dependent in this experimental setting. In contrast, when soluble recombinant pro-inflammatory cytokines were added to the MSC cultures, TNF-α and IFN-γ act synergistically to induce PGE2 production, whereas only high amount of TNF-α but not IFN-γ was able to do so alone. Although the PGE2 secretion by MSCs was completely abrogated by addition of indomethacin under all culture conditions tested, L-NMA, a NOS inhibitor could only partially inhibit it when the cells were elicited in the concomitant presence of TNF-α and IFN-γ. These results, combined with others, suggest that NO acts downstream of IFN-γ but upstream of COX2. Taken together, our findings demonstrate that the induction of PGE2 secretion by BM- and Ad-MSCs is not mediated by a single or unique, nonredundant molecular mechanism under different experimental conditions.     

罗格列酮对猪脂肪前体细胞分化过程中聚脂相关基因表达模式的影响

为了解罗格列酮对猪脂肪前体细胞诱导分化过程的影响, 利用胶原酶消化法分离猪皮下脂肪前体细胞, 采用含50 nmol/L胰岛素、100 nmol/L地塞米松及0.25 mmol/L 3-异丁基-1-甲基黄嘌呤的分化培养液Ⅰ(对照组)和在分化培养液Ⅰ中添加100 nmol/L罗格列酮的分化培养液Ⅱ(实验组)两种诱导分化方法对脂肪前体细胞进行诱导分化, 借助实时定量RT-PCR方法检测了细胞分化过程中聚脂相关基因的表达。结果显示: 罗格列酮对PPARγ、C/EBPα、FABP4、FASN和GPAT基因的表达有显著的上调作用, 而对PPARα有一定的下调作用。试验组中PPARα、PPARγ、C/EBPα、FABP4、FASN和GPAT等基因分别于48 h、48 h、48 h、108 h、60 h和24 h达到表达高峰, 此时的表达量分别是诱导前的1.7、48、3.3、487.5、5.8和3.6倍, GPAT同PPARα和FASN基因表达量间均达到显著相关(P<0.05); 而对照组中PPARα、PPARγ、C/EBPα、FABP4、FASN和GPAT等基因分别于84 h、96 h、48 h、96 h、36 h和36 h达到表达高峰, 此时的表达量分别是诱导前的2.1、11、1.6、216.5、3.5和2.8倍, GPAT同PPARα和FASN基因表达量间均达到极显著相关(P<0.01)。本实验结果表明: 罗格列酮不仅可以极大的促进PPARγ和C/EBPα基因的表达, 还能让其协同达到表达高峰; PPARγ和C/EBPα可能是调控猪脂肪前体细胞分化的关键转录因子; 在脂肪形成过程中, 甘油脂类的生物合成可能发生较早, 同时PPARα可能主要参与甘油脂类生物合成的调控。     

Serum regulates adipogenesis of mesenchymal stem cells via MEK/ERK‐dependent PPARγ expression and phosphorylation

Mesenchymal stem cells (MSCs) provide us an excellent cellular model to uncover the molecular mechanisms underlying adipogenic differentiation of adult stem cells. PPARγ had been considered as an important molecular marker of cells undergoing adipogenic differentiation. Here, we demonstrated that expression and phosphorylation of PPARγ could be found in bone marrow–derived MSCs cultured in expansion medium without any adipogenic additives (dexamethasone, IBMX, insulin or indomethacin). Then, PPARγ was dephosphorylated in MSCs during the process of adipogenic differentiation. We then found that inhibition of MEK activation by specific inhibitor (PD98059) counteracted the PPARγ expression and phosphorylation. However, expression and phosphorylation of PPARγ did not present in MSCs cultured in medium with lower serum concentration. When these MSCs differentiated into adipocytes, no phosphorylation could be detected to accompany the expression of PPARγ. Moreover, exposure of MSCs to higher concentration of serum induced stronger PPARγ expression, and subsequently enhanced their adipogenesis. These data suggested that activation of the MEK/ERK signalling pathway by high serum concentration promoted PPARγ expression and phosphorylation, and subsequently enhanced adipogenic differentiation of MSCs.     

Curcumin pretreatment prevents hydrogen peroxide-induced oxidative stress through enhanced mitochondrial function and deactivation of Akt/Erk signaling pathways in rat bone marrow mesenchymal stem cells

Lead (Pb) is an environmental and industrial contaminant that still represents a public health problem. Elevated Pb exposure has been inversely correlated with femoral bone density and associated with osteoporosis. In the last years, it has been shown that inhibition of osteogenesis from mesenchymal stem cells activates adipogenesis and vice versa. In this paper, we investigated the effect of Pb on the differentiation of 3T3-L1 fibroblasts to adipocytes which is the cell model most used to study adipogenesis. After induction of differentiation, 2 days post-confluent cells re-enter the cell cycle and undergo mitotic clonal expansion (MCE) followed by expression of genes that produce the adipocyte phenotype. The presence of concentrations of Pb up to 10 μM during differentiation of 3T3-L1 fibroblasts did not interfere with MCE but enhanced the accumulation of cytosolic lipids that occur during adipogenesis, as well as, the induction of PPARγ, the master gene in adipogenesis. It is known that PPARγ upregulation is subsequent to induction of C/EBPβ and ERK activation, which are early events in adipogenesis. We found that both events were enhanced by Pb treatment. Our results support a stimulatory effect of Pb on adipogenesis which involves ERK activation and C/EBPβ upregulation prior to PPARγ and adipogenesis activation.