Transcriptomic analysis of Simpson Golabi Behmel syndrome cells during differentiation exhibit BAT-like function.

High-throughput RNA sequencing of human Simpson-Golabi-Behmel syndrome cells (SGBS) was performed during the time-course of adipogenic differentiation at day 4 (D04), 6 (D06), 8 (D08), and 10 (D10) to characterize transcriptomic changes and to identify key patterns involved in adipogenesis and browning. In the comparisons, 932 and 384 overlapping transcripts were consistently up- and down-regulated, respectively. Combining the results of protein-protein interaction network analysis MCODE and CytoHubba, 55 up-regulated hub genes from four clusters and 9 down-regulated genes were identified. The up-regulated hub genes were mainly enriched in brown adipocyte differentiation, extracellular matrix organization, and valine, leucine, and isoleucine degradation. The enrichment of downregulated hub genes was related to NRF2 signalling and glutathione metabolism, indicating that oxidative stress also plays a role. Analysis of overlapping down-regulated genes, targets of transcription factors, revealed enrichment in the IL-18 signalling pathway, which is involved in browning process and extracellular matrix organization via actomyosin mechanics and integrin-extracellular matrix interactions. Finally, the comparison transcriptomic analysis with the gene signature reported by BATLAS and PROFAT web-based tools showed an increased percentage of the brown phenotype, confirming that differentiated SGBS cells at D06, D08, and D10 gradually acquire BAT-like function.

Latent TGFß-binding proteins regulate UCP1 expression and function via TGFß2.

OBJECTIVE: Activation of brown adipose tissue (BAT) in humans has been proposed as a new treatment approach for combating obesity and its associated diseases, as BAT participates in the regulation of energy homeostasis as well as glucose and lipid metabolism. Genetic contributors driving brown adipogenesis in humans have not been fully understood. METHODS: Profiling the gene expression of progenitor cells from subcutaneous and deep neck adipose tissue, we discovered new secreted factors with potential regulatory roles in white and brown adipogenesis. Among these, members of the latent transforming growth factor beta-binding protein (LTBP) family were highly expressed in brown compared to white adipocyte progenitor cells, suggesting that these proteins are capable of promoting brown adipogenesis. To investigate this potential, we used CRISPR/Cas9 to generate LTBP-deficient human preadipocytes. RESULTS: We demonstrate that LTBP2 and LTBP3 deficiency does not affect adipogenic differentiation, but diminishes UCP1 expression and function in the obtained mature adipocytes. We further show that these effects are dependent on TGFß2 but not TGFß1 signaling: TGFß2 deficiency decreases adipocyte UCP1 expression, whereas TGFß2 treatment increases it. The activity of the LTBP3-TGFß2 axis that we delineate herein also significantly correlates with UCP1 expression in human white adipose tissue (WAT), suggesting an important role in regulating WAT browning as well. CONCLUSIONS: These results provide evidence that LTBP3, via TGFß2, plays an important role in promoting brown adipogenesis by modulating UCP1 expression and mitochondrial oxygen consumption.

Elevated UCP1 levels are sufficient to improve glucose uptake in human white adipocytes.

Brown adipose tissue (BAT) has been considered beneficial for metabolic health by participating in the regulation of glucose homoeostasis. The browning factors that improve glucose uptake beyond normal levels are still unknown but glucose uptake is not affected in UCP1 knockout mice. Here, we demonstrate in human white adipocytes that basal/resting glucose uptake is improved by solely elevating UCP1 protein levels. Generating human white Simpson-Golabi-Behmel syndrome (SGBS) adipocytes with a stable knockout and overexpression of UCP1, we discovered that UCP1 overexpressing adipocytes significantly improve glucose uptake by 40%. Mechanistically, this is caused by higher glycolytic flux, seen as increased oxygen consumption, extracellular acidification and lactate secretion rates. The improvements in glucose handling are comparable to white-to-brown transitions, as judged by, for the first time, directly comparing in vitro differentiated mouse brown vs white adipocytes. Although no adipogenic, metabolic and mitochondrial gene expressions were significantly altered in SGBS cells, pharmacological inhibition of GLUT1 completely abrogated differences between UCP1+ and control cells, thereby uncovering GLUT1-mediated uptake as permissive gatekeeper. Collectively, our data demonstrate that elevating UCP1 levels is sufficient to improve human white adipocytes as a glucose sink without adverse cellular effects, thus not requiring the adrenergic controlled, complex network of browning which usually hampers translational efforts.

Diet-dependent function of the extracellular matrix proteoglycan Lumican in obesity and glucose homeostasis.

OBJECTIVE: Extracellular matrix remodeling is required for adipose expansion under increased caloric intake. In turn, inhibited expandability due to aberrant collagen deposition promotes insulin resistance and progression towards the metabolic syndrome. An emerging role for the small leucine-rich proteoglycan Lumican in metabolically driven nonalcoholic fatty liver disease sparks an interest in further understanding its role in diet-induced obesity and metabolic complications. METHODS: Whole body ablation of Lumican (Lum-/-) gene and adeno-associated virus-mediated over-expression were used in combination with control or high fat diet to assess energy balance, glucose homeostasis as well as adipose tissue health and remodeling. RESULTS: Lumican was found to be particularly enriched in the stromal cells isolated from murine gonadal white adipose tissue. Likewise murine and human visceral fat showed a robust increase in Lumican as compared to fat from the subcutaneous depot. Lumican null female mice exhibited moderately increased fat mass, decreased insulin sensitivity and increased liver triglycerides in a diet-dependent manner. These changes coincided with inflammation in adipose tissue and no overt effects in adipose expandability, i.e. adipocyte formation and hypertrophy. Lumican over-expression in visceral fat and liver resulted in improved insulin sensitivity and glucose clearance. CONCLUSIONS: These data indicate that Lumican may represent a functional link between the extracellular matrix, glucose homeostasis, and features of the metabolic syndrome.

Teneurin-2 (TENM2) deficiency induces UCP1 expression in differentiating human fat cells.

Under certain conditions UCP1 expressing adipocytes arise in white adipose tissue depots of both mice and humans. It is still not fully understood whether these cells differentiate de novo from specific progenitor cells or if they transdifferentiate from mature white adipocytes. Performing expression pattern analysis comparing adipocyte progenitor cells from deep and subcutaneous neck adipose tissue, we recently identified teneurin-2 (TENM2) enriched in white adipocyte progenitor cells. Here we tested whether TENM2 deficiency in adipocyte progenitor cells would lead to a brown adipocyte phenotype. By targeting TENM2 in SGBS preadipocytes using siRNA, we demonstrate that TENM2 knockdown induces both UCP1 mRNA and protein expression upon adipogenic differentiation without affecting mitochondrial mass. Furthermore, TENM2 knockdown in human SGBS adipocytes resulted in increased basal and leak mitochondrial respiration. In line with our previous observation these data suggest that TENM2 deficiency in human adipocyte precursors leads to induction of brown adipocyte marker genes upon adipogenic differentiation.

Comparative gene array analysis of progenitor cells from human paired deep neck and subcutaneous adipose tissue.

Brown and white adipocytes have been shown to derive from different progenitors. In this study we sought to clarify the molecular differences between human brown and white adipocyte progenitors cells. To this end, we performed comparative gene array analysis on progenitor cells isolated from paired biopsies of deep and subcutaneous neck adipose tissue from individuals (n = 6) undergoing neck surgery. Compared with subcutaneous neck progenitors, cells from the deep neck adipose tissue displayed marked differences in gene expression pattern, including 355 differentially regulated (>1.5 fold) genes. Analysis of highest regulated genes revealed that STMN2, MME, ODZ2, NRN1 and IL13RA2 genes were specifically expressed in white progenitor cells, whereas expression of LRRC17, CNTNAP3, CD34, RGS7BP and ADH1B marked brown progenitor cells. In conclusion, progenitors from deep neck and subcutaneous neck adipose tissue are characterized by a distinct molecular signature, giving rise to either brown or white adipocytes. The newly identified markers may provide potential pharmacological targets facilitating brown adipogenesis.

FTO deficiency induces UCP-1 expression and mitochondrial uncoupling in adipocytes.

Variants in the fat mass- and obesity-associated (FTO) gene are associated with obesity and body fat mass in genome-wide association studies. However, the mechanism by which FTO predisposes individuals to obesity is not clear so far. First mechanistic evidence was shown in Fto-negative mice. These mice are resistant to obesity due to enhanced energy expenditure, whereas the mass of brown adipose tissue remains unchanged. We hypothesize that FTO is involved in the induction of white adipose tissue browning, which leads to mitochondrial uncoupling and increases energy expenditure. Uncoupling protein 1 (Ucp-1) was significantly higher expressed in both gonadal and inguinal adipose depots of Fto(-/-) compared with Fto(+/+) littermates accompanied by the appearance of multivacuolar, Ucp-1-positive adipocytes in these tissues. By using lentiviral short hairpin RNA constructs, we established FTO-deficient human preadipocytes and adipocytes and analyzed key metabolic processes. FTO-deficient adipocytes showed an adipogenic differentiation rate comparable with control cells but exhibited a reduced de novo lipogenesis despite unchanged glucose uptake. In agreement with the mouse data, FTO-deficient adipocytes exhibited 4-fold higher expression of UCP-1 in mitochondria compared with control cells. The up-regulation of UCP-1 in FTO-deficient adipocytes resulted in enhanced mitochondrial uncoupling. We conclude that FTO deficiency leads to the induction of a brown adipocyte phenotype, thereby enhancing energy expenditure. Further understanding of the signaling pathway connecting FTO with UCP-1 expression might lead to new options for obesity and overweight treatment.

Renaissance of brown adipose tissue.

The recent discovery of functional brown adipose tissue in human adults raised this tissue again into the focus of current investigations concerning human energy homeostasis. Brown fat is a key thermogenic tissue and is essential for non-shivering thermogenesis in the human newborn and hibernating mammals. This review highlights the biological and molecular aspects of brown adipose tissue development and function from the embryonic state to childhood and adolescence.

Regulation of FTO and FTM expression during human preadipocyte differentiation.

In genome-wide association studies (GWAS), polymorphisms in the first intron of FTO were shown to be associated with body fat mass. However, the functional properties of FTO and its nearby gene FTM are largely unknown. We examined the expression of these genes in subcutaneous adipose tissue and in isolated preadipocytes of lean and obese women. In in vitro differentiated primary human preadipocytes and in SGBS preadipocytes we found a decline in FTO and FTM expression during adipogenic differentiation. When investigating the hormonal regulation of FTO and FTM in adipocytes, insulin was identified as a key factor regulating FTM expression indicating a potential role of FTM in insulin regulated adipocyte metabolism.

FTO - Friend or foe?

Fat mass and obesity associated gene ( FTO) is the most relevant polygene for obesity to date. It has been identified by genome wide association studies concerning body weight regulation. However, its functional relevance for the pathogenesis of obesity remains elusive. Studies in rodents provide data pointing to a central role of FTO through regulation of food intake. In addition, peripheral effects of FTO are also discussed in the literature. This review highlights the possible relevance of FTO for weight regulation and obesity development in central and peripheral tissues with a special focus on adipose tissue.

Anti-apoptotic action of exendin-4 in INS-1 beta cells: comparative protein pattern analysis of isolated mitochondria.

Glucagon like peptide-1 (Glp-1) exhibits beneficial effects on beta cell mass by both enhancing proliferation and inhibiting apoptosis. The precise mechanism of the anti-apoptotic effect of Glp-1 and Glp-1 mimetics like exendin-4 has remained elusive. Here, we studied cytokine-induced apoptosis in the pancreatic beta cell line INS-1 and performed a comparative mitochondrial protein pattern analysis using two-dimensional difference gel electrophoresis (2D-DIGE). Cytokine incubation of INS-1 cells increased caspase-3 activity about 3-fold, which was reduced by 60% in the presence of exendin-4. Production of reactive oxygen species in response to cytokines was completely prevented after preincubation with exendin-4. Highly purified mitochondria were obtained and mitochondrial proteins were labeled with Cy-dyes and separated on overlapping zoom 2D gels spanning a pH-range of 4-9. Protein spots with significant changes after cytokine and exendin-4 treatment were identified by MALDI mass spectrometry. Comparing all treatment conditions, comparative mitochondrial proteome analysis allowed to identify 33 different proteins, which were significantly altered between comparison groups. Changes in protein patterns revealed involvement of cytokine-induced electron transport chain damage. Thus, cytochrome bc1 complex subunit I and ATP synthase subunit beta were downregulated by 30-40%. This was abrogated by the presence of exendin-4. In conclusion, this study provides further insights into the role of mitochondria in cytokine-induced apoptosis. We show here that exendin-4 significantly counter-regulates the reduced abundance of electron transport chain proteins, leading to a reduction of oxidative stress and most likely contributing to the anti-apoptotic action of this drug.

Enhanced protection against cytokine- and fatty acid-induced apoptosis in pancreatic beta cells by combined treatment with glucagon-like peptide-1 receptor agonists and insulin analogues.

We recently showed that insulin analogues exhibit a beta-cell protective function. The aim of this study was to test if the anti-apoptotic activity of GLP-1 agonists and insulin analogues is mediated by different pathways and if combined treatment may provide augmented protection against beta-cell death. Incubation of INS-1 cells with cytokines or fatty acids increased the number of apoptotic cells and caspase 3 activity, which was reduced by pretreatment with GLP-1 and its receptor agonists exendin-4 and AVE0010 by 50-60%. Similar effects (about 40% reduction) were observed after pretreatment with several insulin analogues. Combined treatment revealed additive activity and resulted in prevention of both cytokine- and fatty acid-induced apoptosis by up to 80%. No acute Akt-phosphorylation in response to GLP-1 receptor agonists could be observed, however, it became detectable after 24-hour stimulation. Gene silencing of Akt2 increased cytokine-induced apoptosis 2-fold. Under these conditions the beta-cell protective activity of AVE0010 remained completely unaltered. We show here that the anti-apoptotic activity of GLP-1 and its receptor agonists AVE0010 and exendin-4 is enhanced by addition of insulin analogues and that the anti-apoptotic action of GLP-1 mimetics is mostly unrelated to Akt2 signaling. It is suggested that combination of GLP-1 receptor agonists and insulin analogues, specifically insulin glargine, may represent a new therapeutic option for preservation of beta-cell mass in type 2 diabetic patients.

Diagnostic impact of proton MR-spectroscopy versus image-guided stereotactic biopsy.

BACKGROUND: The aim of this study was to compare the diagnostic accuracy of (1)H MR-spectroscopy versus image-guided stereotactic biopsy. METHOD: A cohort of 83 consecutive patients with a broad spectrum of brain lesions were examined. Prior to stereotactic biopsy, the patients were subjected to (1)H MR-spectroscopy examination. Diagnostic accuracy of (1)H MR-spectroscopy and image guided stereotactic biopsy was determined for the largest diagnostic subgroups. Each diagnostic procedure was tested for concordance in every subgroup. FINDINGS: The subgroups of patients comprised: low grade glioma, high grade glioma (grades III and IV), lymphoma and metastasis. For the sensitivity of (1)H MR-spectroscopy ranged from 87.7 in high grade glioma to 92.3% in metastasis and for specificity from 93.3% for high grade glioma to 100% in low grade glioma. The highest positive predictive value of 100% was reached in the subgroup of low grade glioma. The highest negative predictive value was reached in lymphoma and metastasis, 100%. The kappa values were highly significant for all comparisons (p<0.001). The co-efficient ranged from 0.68 to 0.84. It was lowest in assessing high grade glioma and highest in lymphoma. CONCLUSION: Compared with each other (1)H MR-spectroscopy and image-guided stereotactic biopsy showed a moderate to good, statistically highly significant concordance. In patients in whom operation is at an increased risk e.g., due to severe medical illness, (1)H MR-spectroscopy as a noninvasive procedure may be sufficient to assess the diagnosis.

Diagnostic immunohistochemistry in neuromuscular disorders.

Most neuromuscular disorders display only non-specific myopathological features in routine histological preparations. However, a number of proteins, including sarcolemmal, sarcomeric, and nuclear proteins as well as enzymes with defects responsible for neuromuscular disorders, have been identified during the past two decades, allowing a more specific and firm diagnosis of muscle diseases. Identification of protein defects relies predominantly on immunohistochemical preparations and on Western blot analysis. While immunohistochemistry is very useful in identifying abnormal expression of primary protein abnormalities in recessive conditions, it is less helpful in detecting primary defects in dominantly inherited disorders. Abnormal immunohistochemical expression patterns can be confirmed by Western blot analysis which may also be informative in dominant disorders, although its role has yet to be established. Besides identification of specific protein defects, immunohistochemistry is also helpful in the differentiation of inflammatory myopathies by subtyping cellular infiltrates and demonstrating up-regulation of subtle immunological parameters such as cell adhesion molecules. The role of immunohistochemistry in denervating disorders, however, remains controversial in the absence of a reliable marker of muscle fibre denervation. Nevertheless, as well as the diagnostic value of immunocytochemical analysis it may also widen understanding of muscle fibre pathology as well as help in the development of therapeutic strategies.

Expression of drug resistance related proteins in sarcomas of the pulmonary artery and poorly differentiated leiomyosarcomas of other origin.

Sarcomas are known to develop resistance to current chemotherapeutic strategies, displaying a multidrug-resistant phenotype. Mechanisms involved in drug resistance include reduced cellular drug accumulation, drug detoxification as well as alterations in drug target specificity. In seven sarcomas of the pulmonary artery (SPA) and ten leiomyosarcomas of other origin, we studied the immunohistochemical expression of P-glycoprotein (P-gp), multidrug-resistance protein (MRP), lung resistance protein (LRP), metallothionein (MT) and topoisomerase IIalpha. Upregulation was found in tumour cells for P-gp but not for MRP in SPA and other leiomyosarcomas. Topoisomerase IIalpha was expressed at high levels in tissue of primary tumours as well as recurrent tumours. Both P-gp and topoisomerase IIalpha were present in numerous tumour-associated vessels. LRP was expressed at high levels in SPA but to a lesser extent in the other leiomyosarcomas. MT was expressed at low levels but was markedly present at the border of necrosis. The overall survival and the relapse-free survival did not correlate with the expression of these factors. There was no significant relationship between treated and non-treated patients with respect to the expression of the examined molecules. P-gp, but not MRP, may play a role in the development of drug resistance. P-gp, LRP and topoisomerase IIalpha contribute to drug resistance through expression in tumour-associated vessels. Unique high levels of topisomerase IIalpha reflect the high proliferation rate of these tumours. MT seems to serve as a detoxifying agent of metabolites at the border of necrosis. Our findings underline the fact that multiple factors contribute to chemoresistance and that examination of a spectrum of relevant molecules is probably necessary to plan the best therapy.

Apoptosis and muscle fibre loss in neuromuscular disorders.

The past decade has witnessed increasing evidence that besides necrosis, apoptotic cell death mechanisms contribute to muscle fibre loss in various neuromuscular conditions, including the muscular dystrophies, metabolic myopathies, and cases of denervation. The up-regulation of bax and bcl-2, both members of the bcl-2 family, indicate that the predominant effectors involve permeability transition pores in the mitochondrial membrane and subsequent caspase activation which confers the typical morphological and biochemical features of apoptosis such as DNA-fragmentation. It is likely that apoptotic degradation of nuclei and contractile elements is a localized event in muscle fibre segments leading to muscle fibre atrophy and finally loss in these disorders. Essential triggers of apoptosis seem to be homeostatic dysregulation as well as oxidative stress, with increased generation of free oxygen radicals and nitric oxide. In the absence of effective primary treatments, there is hope that interventions in muscle fibre apoptosis will bear promising therapeutic strategies.

Role of nitric oxide and nitric oxide synthases in experimental models of denervation and reinnervation.

Nitric oxide (NO) is a short-living free molecule synthesized by three different isoforms of nitric oxide synthases (NOS)-neuronal NOS, endothelial NOS, and inducible NOS-associated with neuromuscular transmission, muscle contractility, mitochondrial respiration, and carbohydrate metabolism in skeletal muscle. Neuronal NOS is constitutively expressed at the muscle fiber sarcolemma linked to the dystrophin-glycoprotein complex and concentrated at the neuromuscular endplate. There is increasing evidence that altered expression of neuronal NOS plays a role in muscle fiber damage in neuromuscular diseases such as dystrophinopathies and denervating disorders. Although there have been some previous conflicting results on the neuronal NOS expression pattern in denervated muscle fibers, it is now well established that denervation is associated with a down-regulation and disappearance of sarcolemmal neuronal NOS at synaptic/extrasynaptic or both sites. As NO has been shown to induce collapse and growth arrest on neuronal growth cones, down-regulation of sarcolemmal neuronal NOS may contribute to axonal regeneration and attraction to muscle fibers aiming at the formation of new motor endplates providing reinnervation and reconstitution of NOS expression. As NO serves as a retrograde messenger, it may trigger structural downstream events responsible for neuromuscular synaptogenesis and preventing polyneural innervation. Nevertheless, decreased NO production in denervation reduces the cytoprotective scavenger function of NO for superoxide anions promoting oxidative stress that is likely to be involved in muscle fiber damage and death. However, the multifaced role of NOS and NO under physiological and pathological conditions remains poorly understood on the basis of the current knowledge.

Expression of apoptosis-related proteins, p53, and DNA fragmentation in sarcomas of the pulmonary artery.

BACKGROUND: Apoptosis is a common feature in a variety of pathologic conditions. Induction of apoptosis through apoptotic stimuli such as, chemotherapy or radiation, presents new insights into tumor biology and therapy. In particular, members of the Bcl-2 family as well as the Fas system are known to be involved in the regulation of apoptosis in different tumor entities. METHODS: In the current study, the expression of the apoptosis-related molecules p53, Bax, Bcl-2, Fas (CD95), Fas-Ligand and perforin was examined in 7 patients with a sarcoma of the pulmonary artery. Furthermore, the TUNEL-method for the detection of apoptotic cells was applied as well as sequencing of the p53 gene. RESULTS: In the TUNEL assay, approximately 10% of the sarcoma cells displayed DNA fragmentation. In addition, Bax was expressed in tumor cells. Accumulation of p53 was evident in 4 of 7 patients (pAB 240 antibody), and 2 of them were positive for the pAB 1801 antibody. Only 1 case had a point mutation in Exon 5 of the p53 sequence. A few tumor cells showed a double labeling of Bax and p53. Bcl-2 could be detected only in tumor-associated lymphocytes. Finally, several lymphocytes could be stained with perforin, but none of the specimens showed a reactivity for Fas or Fas-Ligand. CONCLUSION: The expression of Bax indicated a possible role of this molecule in programmed cell death in pulmonary sarcomas. The limited coexpression of Bax and p53 suggested that induction of Bax can occur independently of p53. The detection of perforin in lymphocytes suggested a possible role for this molecule in apoptosis of the sarcoma cells. In contrast, the Fas system did not seem to play an essential role in sarcomas of the great vessels.