Adipogenic and Antiapoptotic Protein Levels in Human Adipose Stromal Cells after Weight Loss

Objective: Obesity is a major risk factor for type 2 diabetes and cardiovascular disease. However, current strategies to achieve sustained weight loss are often unsuccessful. Fat reaccumulation might be favored by enhanced adipose cell differentiation or survival in the postreduced state. Research Methods and Procedures: We measured adipogenic and apoptotic protein expression in subcutaneous abdominal adipose stromal‐vascular cells from 10 obese patients (7 women and 3 men) that were obtained before and after a 16% weight loss in a medically supervised weight loss program. Results: After weight loss, protein expression was 2.4‐fold higher (p < 0.005) for p42 C/CAAT enhancer binding protein α, but there was no change for peroxisome proliferator‐activated receptor γ1; both of these are adipogenic regulators. For neuronal apoptosis inhibitory protein, a protein associated with adipose cell apoptotic resistance, there was a rise of 1.7‐fold (p < 0.02). Discussion: Alterations in C/CAAT enhancer binding protein α and neuronal apoptosis inhibitory protein expression occurred in human adipose stromal‐vascular cells after weight loss in a pilot study of 10 patients. It will be important for future studies to directly examine whether the adipogenic and antiapoptotic capacity of these cells is changed after weight loss.     

Cloning and expression of type XII collagen isoforms during bovine adipogenesis

In order to isolate candidate genes involved in bovine adipocyte differentiation, we have constructed a subtraction library from a clonal bovine intra-muscular pre-adipocyte (BIP) cell line using the suppression subtractive hybridization method. We have isolated a set of subtracted cDNA fragments whose respective mRNA levels are up-regulated during the adipogenic differentiation of BIP cells, and cloned cDNAs from a differentiated BIP-lambda ZAP II cDNA library. Two cDNA clones were highly homologous to the sequence of mouse and human type XII collagen alpha-1, determined by a BLAST homology search. As type XII collagen has been reported to have four types of splicing isoform, two clones were determined to be XII-1 and XII-2 splicing isoforms, respectively, because of a difference in the C-terminal NC1 domain. From the expression analysis of type XII collagen, the XIIA-2 isoform was mainly expressed in differentiated BIP cells and adipose tissues. Although the function of type XII collagen has not been established as yet, these results suggest that type XII collagen may be associated with adipocyte differentiation and adipose formation in cattle and is a potentially useful marker for adipogenesis.     

Label‐free quantitative chemical imaging and classification analysis of adipogenesis using mouse embryonic stem cells

Stem cells have received much attention recently for their potential utility in regenerative medicine. The identification of their differentiated progeny often requires complex staining procedures, and is challenging for intermediary stages which are a priori unknown. In this work, the ability of label‐free quantitative coherent anti‐Stokes Raman scattering (CARS) micro‐spectroscopy to identify populations of intermediate cell states during the differentiation of murine embryonic stem cells into adipocytes is assessed. Cells were imaged at different days of differentiation by hyperspectral CARS, and images were analysed with an unsupervised factorization algorithm providing Raman‐like spectra and spatially resolved maps of chemical components. Chemical decomposition combined with a statistical analysis of their spatial distributions provided a set of parameters that were used for classification analysis. The first 2 principal components of these parameters indicated 3 main groups, attributed to undifferentiated cells, cells differentiated into committed white pre‐adipocytes, and differentiating cells exhibiting a distinct protein globular structure with adjacent lipid droplets. An unsupervised classification methodology was developed, separating undifferentiated cell from cells in other stages, using a novel method to estimate the optimal number of clusters. The proposed unsupervised classification pipeline of hyperspectral CARS data offers a promising new tool for automated cell sorting in lineage analysis.      

Positive Modulation of the Adipoconversion of Adipoblasts Derived from Genetically Obese Rats by Sodium Butyrate

Using a new serum-free primary culture system, we have previously reported genotypic differences between adipoblasts derived from the epididymal adipose deposit of lean and obese 8-week-old Zucker and Wistar Diabetic Fatty (WDF) rats (15). In these strictly controlled culture conditions, obese-derived adipoblasts expressed low levels of the late markers of differentiation (lipid accumulation, GPDH). In order to further characterize obese-derived adipoblasts and analyze the critical relationship between growth and differentiation, growth arrest was induced in leanand obese-derived cultures using sodium butyrate treatment. Addition of 2.5 mM sodium butyrate to the serum-free medium from day 1 reduced markedly the growth of lean as well as obese-derived cells. Adipoconversion of lean-derived adipoblasts was not altered, similar levels of LPL and GPDH activities being obtained in control and butyrate-treated groups. By contrast, a marked increase in both activities was observed in obese-derived cultures, restoring the level of both markers of differentiation to the lean level. Similar results were obtained with adipoblasts derived from subcutaneous inguinal (ING) fat pad of obese Zucker as well as adipoblasts derived from ING and EPI fat deposits from obese WDF rats. Taken together, these results suggest that adipose deposits of these genetically obese rats contain a specific adipoblast population which differs from lean-derived adipoblasts in respect to its adipoconversion capacity andlor its stage of commitment to differentiation.     

Review: Animal model and the current understanding of molecule dynamics of adipogenesis

Among several potential animal models that can be used for adipogenic studies, Wagyu cattle is the one that presents unique molecular mechanisms underlying the deposit of substantial amounts of intramuscular fat. As such, this review is focused on current knowledge of such mechanisms related to adipose tissue deposition using Wagyu cattle as model. So abundant is the lipid accumulation in the skeletal muscles of these animals that in many cases, the muscle cross-sectional area appears more white (adipose tissue) than red (muscle fibers). This enhanced marbling accumulation is morphologically similar to that seen in numerous skeletal muscle dysfunctions, disease states and myopathies; this might indicate cross-similar mechanisms between such dysfunctions and fat deposition in Wagyu breed. Animal models can be used not only for a better understanding of fat deposition in livestock, but also as models to an increased comprehension on molecular mechanisms behind human conditions. This revision underlies some of the complex molecular processes of fat deposition in animals.     

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.     

MiR-15a/b promote adipogenesis in porcine pre-adipocyte via repressing FoxO1

Diabetes and many other metabolism syndromes are closely related to obesity. To reveal the underlying mechan ism of fat deposition, an increasing number of studies are focusing on the functions of miRNAs during adipocytes de velopment. Previous studies have proved that miR15a/b play important roles in multiple physiological processes; however, their functions during adipogenesis remain un clear. To reveal this, we detected the expression profiles of miR15a/b during adipogenesis in porcine preadipocyte, and found that their expression levels increased in the early stage of adipoeyte differentiation and dropped after day 4. Moreover, overexpression of miR15a/b in porcine pre adipocytes promoted adipocyte differentiation and lipid accumulation. Target genes of miR15a/b were predicted and examined, which revealed that Forkhead box protein O1 （FoxO1） is the target gene of miR15a/b. The inhibition of FoxO1 expression level caused by miR15a/b over expression had a positive effect on adipogenesis. Thus, we conclude that miR15a/b promote adipogenesis in porcine preadipocyte via repressing FoxO1.