Adipogenesis of murine embryonic stem cells in a three-dimensional culture system using electrospun polymer scaffolds

A mechanistic understanding of adipose tissue differentiation is critical for the treatment and prevention of obesity and type 2 diabetes. Conventional in vitro models of adipogenesis are preadipocytes or freshly isolated adipocytes grown in two-dimensional (2D) cultures. Optimal results using in vitro tissue culture models can be expected only when adipocyte models closely resemble adipose tissue in vivo. Thus the design of an in vitro three-dimensional (3D) model which faithfully mimics the in vivo environment is needed to effectively study adipogenesis. Pluripotent embryonic stem (ES) cells are a self-renewing cell type that can readily be differentiated into adipocytes. In this study, a 3D culture system was developed to mimic the geometry of adipose tissue in vivo. Murine ES cells were seeded into electrospun polycaprolactone scaffolds and differentiated into adipocytes in situ by hormone induction as demonstrated using a battery of gene and protein expression markers along with the accumulation of neutral lipid droplets. Insulin-responsive Akt phosphorylation, and beta-adrenergic stimulation of cyclic AMP synthesis were demonstrated in ES cell-derived adipocytes. Morphologically, ES cell-derived adipocytes resembled native fat cells by scanning electron and phase contrast microscopy. This tissue engineered ES cell-matrix model has potential uses in drug screening and other therapeutic developments.     

Adipogenesis induced by human adipose tissue-derived stem cells

Adipose tissue-derived stem cells (ASCs), including preadipocytes, may play an important role in de novo adipogenesis and are expected to be a useful external source of cells for adipose tissue engineering. In this study, we examined in vivo adipogenesis up to 24 weeks after implantation, induced by human ASCs that were isolated from adipose tissues and expanded in vitro. ASCs proliferated in vitro in the presence of basic fibroblast growth factor (bFGF), and the number of cells increased by more than 1000-fold at the fourth passage. The ability to differentiate into mature adipocytes was maintained up to the third passage. We incorporated designated numbers of third-passage-expanded cells into a type I collagen scaffold and implanted them into the back of nude mice with or without controlled-release bFGF. After the implantation of 2 x 10(6) ASCs with controlled-release bFGF, the greatest cross-sectional surface area of adipose tissue in the scaffold was 1.19 mm(2) at 12 weeks and 2.14 mm(2) at 24 weeks. About 2 x 10(6) ASCs with controlled-release bFGF was the best condition for total adipogenesis. Immunohistochemical analysis with antihuman vimentin antibody showed that the area of human-origin adipose tissue was maximum in the group with 8 x 10(6) ASCs incorporated in a scaffold at both 12 and 24 weeks. The amount of human-origin adipose tissue increased in all groups with implanted ASCs from 12 to 24 weeks. Only trace of human-origin adipose tissue was observed in other groups implanted ASCs. Our results show that human ASCs not only function as progenitor cells for in vivo adipogenesis, but also induce de novo adipogenesis for long period.     

4E-BP1 regulates the differentiation of white adipose tissue

4E Binding protein 1 (4E-BP1) suppresses translation initiation. The absence of 4E-BP1 drastically reduces the amount of adipose tissue in mice. To address the role of 4E-BP1 in adipocyte differentiation, we characterized 4E-BP1^−/− mice in this study. The lack of 4E-BP1 decreased the amount of white adipose tissue and increased the amount of brown adipose tissue. In 4E-BP1^−/− MEF cells, PPARγ coactivator 1 alpha (PGC-1α) expression increased and exogenous 4E-BP1 expression suppressed PGC-1α expression. The level of 4E-BP1 expression was higher in white adipocytes than in brown adipocytes and showed significantly greater up-regulation in white adipocytes than in brown adipocytes during preadipocyte differentiation into mature adipocytes. The amount of PGC-1α was consistently higher in HB cells (a brown preadipocyte cell line) than in HW cells (a white preadipocyte cell line) during differentiation. Moreover, the ectopic over-expression of 4E-BP1 suppressed PGC-1α expression in white adipocytes, but not in brown adipocytes. Thus, the results of our study indicate that 4E-BP1 may suppress brown adipocyte differentiation and PGC-1α expression in white adipose tissues.     

Adipocytes and macrophages secretomes coregulate catecholamine-synthesizing enzymes

Obesity associates with macrophage accumulation in adipose tissue where these infiltrating cells interact with adipocytes and contribute to the systemic chronic metabolic inflammation present in immunometabolic diseases. Tyrosine hydroxylase (TH) and phenylethanolamine N-methyltransferase (PNMT) are two of the main enzymes of catecholamines (CA) synthesis. Adipocytes and macrophages produce, secrete and respond to CA, but the regulation of their synthesis in the interplay between immune and metabolic systems remains unknown. A model of indirect cell coculture with conditioned medium (CM) from RAW 264.7 macrophages with or without LPS-activation and 3T3-L1 adipocytes and preadipocytes was established to study the effect of cellular secretomes on the expression of the above enzymes. During the adipocyte differentiation process, we found a decrease of TH and PNMT expression. The secretome from LPS-activated macrophages downregulated TH and PNMT expression in preadipocytes, but not in mature adipocytes. Mature adipocytes CM induced a decrease of PNMT levels in RAW 264.7 macrophages. Pre and mature adipocytes showed a similar pattern of TH, PNMT and peroxisome proliferator-activated receptor gamma expression after exposure to pro and anti-inflammatory cytokines. We evidenced macrophages and adipocytes coregulate the expression of CA synthesis enzymes through secretome, with non-inflammatory signaling networks possibly being involved. Mediators released by macrophages seem to equally affect CA production by adipocytes, while adipocytes secretome preferentially affect AD production by macrophages. CA synthesis seems to be more determinant in early stages of adipogenic differentiation. Our results suggest that CA are key signaling molecules in the regulation of immune-metabolic crosstalk within the adipose tissue.     

脂肪来源干细胞诱导分化为神经元样细胞的实验研究

目的： 研究脂肪来源干细胞（ASCs）的分离、纯化、扩增以及在体外定向分化为神经元样细胞的能力。 方法: 获取并培养正常人的ASCs，倒置显微镜下观察其形态；流式细胞仪检测其免疫表型。全反式维甲酸（ATRA）诱导ASCs在体外分化为神经元样细胞，倒置显微镜观察神经元样细胞的形态，逆转录-聚合酶链反应（RT-PCR）检测巢蛋白基因的表达；免疫组织化学染色法和Western blotting法检测神经丝蛋白（NF）和神经元烯醇化酶（NSE）的表达。 结果: ASCs呈纤维样贴壁生长，体外培养易扩增；ASCs表达相关抗原CD29和CD105，不表达CD31、CD34、CD45和HLA-DR；不同扩增代数的ASCs经诱导剂的作用可呈现典型的神经元样细胞形态，巢蛋白基因及NF、NSE均呈阳性表达。 结论: 脂肪组织中分离培养的ASCs具有体外大量扩增并保持低分化状态的特性，以及定向分化为神经元样细胞的能力, 是一种可用于神经系统疾病治疗的种子细胞。     

Characterization of transplanted green fluorescent protein+ bone marrow cells into adipose tissue

Following transplantation of green fluorescent protein (GFP)-labeled bone marrow (BM) into irradiated, wild-type Sprague-Dawley rats, propagated GFP(+) cells migrate to adipose tissue compartments. To determine the relationship between GFP(+) BM-derived cells and tissue-resident GFP(-) cells on the stem cell population of adipose tissue, we conducted detailed immunohistochemical analysis of chimeric whole fat compartments and subsequently isolated and characterized adipose-derived stem cells (ASCs) from GFP(+) BM chimeras. In immunohistochemistry, a large fraction of GFP(+) cells in adipose tissue were strongly positive for CD45 and smooth muscle actin and were evenly scattered around the adipocytes and blood vessels, whereas all CD45(+) cells within the blood vessels were GFP(+). A small fraction of GFP(+) cells with the mesenchymal marker CD90 also existed in the perivascular area. Flow cytometric and immunocytochemical analyses showed that cultured ASCs were CD45(-)/CD90(+)/CD29(+). There was a significant difference in both the cell number and phenotype of the GFP(+) ASCs in two different adipose compartments, the omental (abdominal) and the inguinal (subcutaneous) fat pads; a significantly higher number of GFP(-)/CD90(+) cells were isolated from the subcutaneous depot as compared with the abdominal depot. The in vitro adipogenic differentiation of the ASCs was achieved; however, all cells that had differentiated were GFP(-). Based on phenotypical analysis, GFP(+) cells in adipose tissue in this rat model appear to be of both hematopoietic and mesenchymal origin; however, infrequent isolation of GFP(+) ASCs and their lack of adipogenic differentiation suggest that the contribution of BM to ASC generation might be minor.     

The brown adipose cell: a model for understanding the molecular mechanisms of insulin resistance

Type 2 diabetes mellitus is a complex metabolic disease that occurs when insulin secretion can no longer compensate insulin resistance in peripheral tissues. At the molecular level, insulin resistance correlates with impaired insulin signalling. This review provides new insights into the molecular mechanisms of insulin action and resistance in brown adipose tissue and pinpoints the role of this tissue in the control of glucose homeostasis. Brown adipocytes are target cells for insulin and IGF-I action, especially during late foetal development when insulin supports survival and promotes both adipogenic and thermogenic differentiation. The main pathway involved in insulin induction of adipogenic differentiation, monitored by fatty acid synthase expression, is the cascade insulin receptor substrate (IRS)-1/phosphatidylinositol 3-kinase (PI3K)/Akt. Glucose transport in these cells is maintained mainly by the activity of GLUT4. Acute insulin treatment stimulates glucose transport largely by mediating translocation of GLUT4 to the plasma membrane, involving the activation of IRS-2/PI3K, and the downstream targets Akt and protein kinase C zeta. Tumour necrosis factor (TNF-alpha) caused insulin resistance on glucose uptake by impairing insulin signalling at the level of IRS-2. Activation of stress kinases and phosphatases by this cytokine contribute to insulin resistance. Furthermore, brown adipocytes are also target cells for rosiglitazone action since they show a high expression of peroxisome proliferator activated receptor gamma, and rosiglitazone increased the expression of the thermogenic uncoupling protein 1. Rosiglitazone ameliorates insulin resistance provoked by TNF-alpha, completely restoring insulin-stimulated glucose uptake in parallel to the insulin signalling cascade. Accordingly, foetal brown adipocytes represent a model for investigating insulin action, as well as for the mechanism by which rosiglitazone increase insulin sensitivity under situations that mimic insulin resistance.     

The creation of an in vitro adipose tissue that contains a vascular-adipocyte complex

An increased demand for soft-tissue substitutes has impelled the development of an in vitro adipose tissue. Ideally, such a tissue should contain a vascular network that can deliver blood throughout the construct following its engraftment. This study describes the in vitro fabrication of a pre-vascularized adipose tissue entirely using a self-assembly approach. Adult human adipose stromal cells (ASCs) provided the foundation for this construct. These cells were cultured at high density in the presence of elevated levels of ascorbate prior to adipocytic induction. Vascular support cells consisting of dermal fibroblasts, mixtures of adipose stromal cells and bone marrow mesenchymal stem cells (MSCs) were introduced to sustain an extensive vascular network formed by human umbilical vein endothelial cells (HUVECs). MSCs were introduced to serve as perivascular cells. The resulting construct contained a vascular-adipose tissue continuum that was held together by basement membrane molecules. This construct contains multiple cell types that are typically found in adipose tissue: adipocytes, pre-adipocytes, stem cells, fibroblasts, vascular cells, and perivascular support cells. As such, these constructs can be employed both for in vitro studies to assay cellular interactions between vasculature and other components of adipose tissue. Further, they can also be engrafted into athymic hosts to study vascular and adipocyte stability.     

Porous poly(lactic-co-glycolic acid) microsphere as cell culture substrate and cell transplantation vehicle for adipose tissue engineering

Tissue engineering often requires ex vivo cell expansion to obtain a large number of transplantable cells. However, the trypsinization process used to harvest ex vivo expanded cells for transplantation interrupts interactions between cultured cells and their extracellular matrices, facilitating apoptosis and consequently limiting the therapeutic efficacy of the transplanted cells. In the present study, open macroporous poly(lactic-co-glycolic acid) (PLGA) microspheres were used as a cell culture substrate to expand human adipose-derived stromal cells (ASCs) ex vivo and as a cell transplantation vehicle for adipose tissue engineering, thus avoiding the trypsinization necessary for transplantation of ex vivo expanded cells. Human ASCs cultured on macroporous PLGA microspheres in stirred suspension bioreactors expanded 3.8-fold over 7 days and differentiated into an adipogenic lineage. The apoptotic activity of ASCs cultured on microspheres was significantly lower than that of trypsinized ASCs. ASCs cultured on microspheres survived much better than trypsinized ASCs upon transplantation. The implantation of ASCs cultured on microspheres resulted in much more extensive adipose tissue formation than the implantation of ASCs cultured on plates, trypsinized, and subsequently mixed with microspheres. Ex vivo cell expansion and transplantation using this system would improve the therapeutic efficacy of cells over the current methods used for tissue engineering.     

Extracellular matrix mineralization and osteoblast gene expression by human adipose tissue-derived stromal cells.

Human adipose tissue represents an abundant reservoir of stromal cells with potential utility for tissue engineering. The current study demonstrates the ability of human adipose tissue-derived stromal cells to display some of the hallmarks of osteoblast differentiation in vitro. Following treatment with ascorbate, beta-glycerophosphate, dexamethasone, and 1,25 dihydroxy vitamin D(3), adipose tissue-derived stromal cells mineralize their extracellular matrix based on detection of calcium phosphate deposits using Alizarin Red and von Kossa histochemical stains. Fourier transform infrared analysis demonstrates the apatitic nature of these crystals. Mineralization is accompanied by increased expression or activity of the osteoblast-associated proteins osteocalcin and alkaline phosphatase. These and other osteoblast-associated gene markers are detected based on polymerase chain reaction. In contrast, the adipocyte gene markers--leptin, lipoprotein lipase, and peroxisome proliferator activated receptor gamma2--are reduced under mineralization conditions, consistent with the reciprocal relationship postulated to exist between adipocytes and osteoblasts. The current work supports the presence of a multipotent stromal cell population within human extramedullary adipose tissue. These findings have potential implications for human bone tissue bioengineering.     

The cellular structure and lipid/protein composition of adipose tissue surrounding chronically stimulated lymph nodes in rats

To test the hypothesis that chronic immune stimulation of a peripheral lymph node induces the formation of additional mature adipocytes in adjacent adipose tissue, one popliteal lymph node of large male rats was stimulated by local injection of 10 microg or 20 microg lipopolysaccharide three times a week for 6 weeks. Adipocyte volumes in sites defined by their anatomical relations to the stimulated and homologous unstimulated popliteal lymph nodes were measured, plus adipocyte complement of the popliteal depot, and the lipid and protein content of adipocytes and adipose stroma. The higher dose of lipopolysaccharide doubled the mass of the locally stimulated lymph node and the surrounding adipose tissue enlarged by the appearance of additional mature adipocytes. Similar but smaller changes were observed in the popliteal adipose depot of the unstimulated leg and in a nodeless depot. The lipid content of the adipocytes decreased and that of the stroma increased dose-dependently in all samples measured but the changes were consistently greater in the depot surrounding the stimulated lymph node. The protein content of both adipocytes and stroma increased in samples surrounding the stimulated node. We conclude that chronic immune stimulation of lymphoid tissues induces the formation of more adipocytes in the adjacent adipose tissue. These findings suggest a mechanism for the selective hypertrophy of lymphoid-containing adipose depots in the HIV-associated adipose redistribution syndrome.     

Stimulatory effect of immunoglobulins and Fc fragments on glucose oxidation and glucose transport by adipocytes

Following our demonstration that human IgG, its Fc fragments and IgM stimulate lipogenesis in adipocytes, we embarked on a study to investigate whether these proteins stimulate the oxidation and transport of glucose by adipocytes, and whether such a stimulation is mediated through the insulin receptor. Using a simplified method for the measurement of [14C]-carbon dioxide produced from [U-14C]-glucose by rat adipocytes, we demonstrated that both IgG, Fc fragments and IgM produced a dose-dependent stimulation of oxidation of glucose by adipocytes. These proteins also produced a stimulation of 3-o-methylglucose uptake by adipocytes. IgG, Fc Fragments and IgM did not, however, alter specific binding of insulin to adipocytes. These data provide further evidence that human IgG and IgM may have a role in regulating metabolic activity of adipose tissue. These effects are exerted independently of the insulin receptor and are probably mediated through the interaction of its Fc fraction with putative Fc receptors on the adipocyte membrane. A similar interaction may be important in the regulation of metabolic activity of other cells with Fc receptors.     

Stimulatory effect of immunoglobulins and Fc fragments on glucose oxidation and glucose transport by adipocytes.

Following our demonstration that human IgG, its Fc fragments and IgM stimulate lipogenesis in adipocytes, we embarked on a study to investigate whether these proteins stimulate the oxidation and transport of glucose by adipocytes, and whether such a stimulation is mediated through the insulin receptor. Using a simplified method for the measurement of [14C]-carbon dioxide produced from [U-14C]-glucose by rat adipocytes, we demonstrated that both IgG, Fc fragments and IgM produced a dose-dependent stimulation of oxidation of glucose by adipocytes. These proteins also produced a stimulation of 3-o-methylglucose uptake by adipocytes. IgG, Fc Fragments and IgM did not, however, alter specific binding of insulin to adipocytes. These data provide further evidence that human IgG and IgM may have a role in regulating metabolic activity of adipose tissue. These effects are exerted independently of the insulin receptor and are probably mediated through the interaction of its Fc fraction with putative Fc receptors on the adipocyte membrane. A similar interaction may be important in the regulation of metabolic activity of other cells with Fc receptors.     

Metabolic control through hepatocyte and adipose tissue cross-talk in a multicompartmental modular bioreactor

Physiological processes involve a complex network of signaling molecules that act through paracrinal or endocrinal pathways; however, traditional in vitro models cannot mimic these interactions because of the lack of a dynamic cross-talk between cells belonging to different tissues. The multicompartmental modular bioreactor is a novel cell culture system where hepatocytes and adipose tissue are shown to interact in a more physiological manner. In the multicompartmental modular bioreactor, cells and tissues can be cultured in a common medium, which flows through the system acting as the bloodstream. Primary rat hepatocytes and adipose tissue were cultured separately and together in conventional conditions and in the bioreactor. Urea synthesis, albumin secretion, glycerol, free fatty acid, and glucose concentrations were analyzed and compared. The dynamic connected culture of adipose tissue and hepatocytes led to a significant enhancement of hepatic function in terms of increase of albumin and urea production with respect to conventional cultures. Interestingly, the glycerol gradually released from adipose tissue was buffered in the dynamic connected culture, manifesting a homeostatic-like control. These data show that the dynamic culture not only improves hepatocyte function, but also allows a cross-talk between tissues, leading to enhanced metabolic regulation in vitro.     

Fast isolation and expansion of multipotent cells from adipose tissue based on chitosan-selected primary culture

Adipose-derived adult stem cells (ASCs) have gained much attention because of their multipotency and easy access. Here we describe a novel chitosan-based selection (CS) system instead of the conventional plastic adherence (PA) to obtain the primary ASCs. The minimal amount of adipose tissue for consistent isolation of ASCs is reduced from 10 mL to 5 mL. The selection is based on the specific interaction between cells and chitosan materials, which separate ASCs by forming spheroids during primary culture. The primary culture period was reduced from 4 days to one day and more ASCs (ten-fold expansion) were achieved in a week. The average duration for obtaining 1 × 10⁷ cells takes about seven days from 5 mL of adipose tissue, compared to 14 days using the conventional PA method from 10 mL of adipose tissue. The replicative senescence of CS-ASCs is not evident until the fifteenth passage (vs. eighth for the PA-ASCs). The obtained ASCs (CS-ASCs) have less doubling time for the same passage of cells and show greater stemness than those obtained from the conventional PA method (PA-ASCs). Moreover, CS-ASCs undergo trilineage differentiation more effectively than PA-ASCs. The greater differentiation potential of CS-ASCs may be associated with the enrichment and maintenance of CD271 positive cells by chitosan selection of primary culture.     

Glucose uptake and triglyceride synthesis in adipose tissue of spontaneously and renal hypertensive rats (Alterations revealed by adrenalectomy)

Rats with renal and spontaneous hypertension do not differ from control normotensive rats in¹⁴C-glucose uptake and triglyceride synthesis by the adipose tissue in vitro, both with and without insulin stimulation. Adrenalectomy (which eliminates the stabilizing effect of the corticosteroid hormones on the adipocyte membrane) reveals the differences between the hypertensive and normotensive rats in the response of the adipose tissue to insulin. While the adrenalectomized control rats show a significantly lowered sensitivity of the adipocytes to insulin, the adrenalcetomized hypertensive rats do not reveal a noticeable change in glucose uptake and triglyceride synthesis under insulin stimulation of glucose transport (the adipose tissue of hypertensive rats doesn't notice adrenalectomy).The data obtained may indicate changes in the properties of the adipocyte membranes of rats with chronic arterial hypertension and suggest the presence of an extensive alteration of the function of cell membranes in both types of hypertension.     

Multiple symmetric lipomatosis. Ultrastructural investigation of the tissue and preadipocytes in primary culture

Multiple symmetric lipomatosis (MSL) is characterized by enlarging, painless fat deposits in the neck and upper trunk. The pathogenesis of MSL is unknown. Owing to localization of MSL fat deposits in the neck and interscapular region, it has been suggested that they could originate from brown fat. However, the histological appearance of MSL adipose tissue is that of white fat, with prevailing monovacuolar adipocytes. Nevertheless, MSL adipocytes are smaller than adipocytes of the common white adipose tissue and show peculiar metabolic features. The ultrastructure of MSL lesions has been not described. The present work investigated the ultrastructural morphology of MSL adipose tissue and lipomatous adipocyte precursors maintained in long-term culture. Samples of lipomatous tissue were obtained from patients affected with MSL undergoing surgical lipectomy. Portion of the tissue was processed for electron microscopy; the rest was digested with collagenase, and isolated preadipocytes from the stromal-vascular fraction were cultured up to 15 days. Cultured cells were prepared for electron microscopy in situ and their morphology compared with human white adipose tissue preadipocytes and rat brown preadipocytes cultured in parallel. Results show the following. 1) Adipocytes of MSL are not monovacuolar and resemble the largest adipocytes that can be found in rat and human brown fat. 2) Some morphological features of MSL adipocyte precursors resemble brown adipocyte more than white: cultured MSL preadipocytes transiently develop large mitochondria with parallel cristae resembling those of the brown fat cell and maintain a multivacuolar lipid deposit in culture, i.e. a typical feature of brown preadipocytes. 3) Some morphological features suggest a neoplastic nature of MSL adipocytes. Taken together, these findings suggest that MSL is a neoplastic disease which could originate in brown fat.