Global ETD Search

141	Bioactivités de cryptides marins : quels potentiels pour la santé humaine ? / Bioactivities of marine cryptides : what potential for human health ? Ben Henda, Yesmine 01 December 2014 (has links) Les ressources marines constituent un réservoir considérable de substances actives, en particulier, de peptides bioactifs appelés cryptides. Les cryptides, qui sont initialement dissimulés au cœur des protéines, sont libérés lors de la digestion ou lors de procédés protéolytiques industriels. Ces cryptides pourraient procurer des bienfaits physiologiques ou assurer une protection contre des pathologies telles que celles du syndrome métabolique. Dans ce contexte, nous nous sommes intéressés à l’action de certains cryptides marins sur des cibles impliquées dans l’hypertension, le diabète et l’obésité. Nous avons pu mettre en évidence que certains cryptides pouvaient cibler in vitro plusieurs facteurs de risques associés au développement des anomalies du syndrome métabolique. / Marine products represent an important source of active substances, in particular bioactive peptides called cryptides. Cryptides are hidden within the sequence of a parent protein and are released during digestion or industrial proteolytic processes. These cryptides could provide physiological benefit or protection against diseases such as those of metabolic syndrome. In this context, we investigated the action of some marine cryptides on hypertension, diabetes and obesity. We demonstrated that some cryptides can target in vitro several factors associated with the development of metabolic syndrome. Cryptides Syndrome métabolique Enzyme de conversion de l'angiotensine Adipocytes blancs humains sous-cutanés Activité inhibitrice Cryptides Metabolic syndrome Angiotensin converting enzyme Subcutaneous human white adipocyte Inhibitory activity
142	Identification and characterization of the control of murine MSC differentiation by the ADP receptors P2Y12 and P2Y13 Biver, Galadrielle 17 March 2014 (has links) Extracellular nucleotides act as local intercellular messengers. In response to various stimuli, nucleotides can be released from the cytosol of damaged cells, exocytosis vesicles and efflux through membrane channel. In the extracellular fluids, nucleotides are rapidely degraded by ecto-nucleotidases, such as CD39,CD39L1 and CD73. Extracellular nucleotides activate the P2 receptor family .This family of receptors can be divided into 2 groups: P2X1-7R ( ionotropic receptors) and P2YR ( G protein-coupled receptors). Nowadays, there are eight accepted human P2Y receptors: P2Y1,2,4,6,11,12,13,14.<p>To determine the physiological roles of P2Y receptor family, our laboratory generated different strains of P2Y knockout mice (P2Y4 ,6 and 13). In collaboration with A. Gartland ,I. And Arnett TR Orriss ( Sheffield and London University) ,it has been observed that the P2Y13R-/- mice exhibit an impaired bone tissue metabolism that leads to a reduction in the volume of the femoral trabecular bone and the number of trabeculae. This phenotype is correlated with the decrease in the number of osteoblasts at the endo-cortical bone surface .<p>We therefore examined whether P2Y13 R activation was involved in the osteogenic differentiation of mesenchymal stem cells (MSCs). In the first part of our work we have shown that :<p>Induction of the MSCs differentiation is associated with the release of ATP and its conversion to ADP (agonist of the P2Y13R). ATP release probably involves the pannexine1 while the conversion of ATP into ADP is probably due to the activity of the ecto-nucleotidase CD39L1.<p>ADP stimulation of P2Y13 R+/+ (but not P2Y13 R-/-) adherent bone marrow stromal cells (BMSC) increased significantly the formation of alkaline phosphatase-colony forming units (CFU-ALP), as well as the expression of osteoblastic genes such as Osterix involved in the maturation of pre-osteoblasts into osteoblasts. The number of CFU-ALP obtained from P2Y13 R-/- BMSC and the level of osteoblastic gene expression after osteogenic stimulation were also strongly reduced compared to those obtained in wild-type cell cultures. In contrast, when P2Y13 R-/- BMSCs were incubated in an adipogenic medium, the number of adipocytes generated and the level of adipogenic gene expression (PPARγ2 and Adipsin) were higher than those obtained in P2Y13 R+/+ MSC. We also observed a significant increase of the number of bone marrow adipocytes in tibia of P2Y13 R-/- mice. <p>The P2ry12 gene deletion (also activated by ADP) also affects the ability of BMSCs to differentiate into osteoblasts but stimulates adipogenic differentiation.<p>In a second part of our work ,we have shown that the pro- osteogenic action of P2Y13R is indirect. Indeed ,this receptor is not expressed by MSCs but by adherent myeloid cells present in the bone marrow cell cultures (characterized by the expression of CD11b and CD45 markers) .In addition, we observed that following receptor activation by ADP ,these myeloid cells produce BMP2 factor.<p>We therefor propose that the stimulation of MSCs differentiation induces CD45- adherent cells to release ATP that is converted into ADP, most probably by the up-regulated CD39L1 ectonucleotidase. This ADP stimulates P2Y12R and P2Y13R expressed by CD45+/CD11b+ myeloid cells leading to the release of the osteogenic factor BMP2. This cytokine favours the maturation of pre-osteoblasts into osteoblasts and concomitantly inhibits the maturation of pre-adipocytes.<p> / Doctorat en Sciences / info:eu-repo/semantics/nonPublished Sciences exactes et naturelles Biologie Cellular signal transduction Osteoblasts Mesenchymal stem cells Transduction du signal cellulaire Cellules osseuses Cellules souches mésenchymateuses adipocytes ostéoblastes cellules souches mésenchyamteuses signalisation cellulaire
143	Direct evidence of brown adipocytes in different fat depots in children Rockstroh, Denise, Landgraf, Kathrin, Wagner, Isabel Viola, Gesing, Julia, Tauscher, Roy, Lakowa, Nicole, Kiess, Wieland, Bühligen, Ulf, Wojan, Magdalena, Till, Holger, Blüher, Matthias, Körner, Antje January 2015 (has links) Recent studies suggested the persistence of brown adipocytes in adult humans, as opposed to being exclusively present in infancy. In this study, we investigated the presence of brown-like adipocytes in adipose tissue (AT) samples of children and adolescents aged 0 to 18 years and evaluated the association with age, location, and obesity. For this, we analysed AT samples from 131 children and 23 adults by histological, immunohistochemical and expression analyses. We detected brown-like and UCP1 positive adipocytes in 10.3% of 87 lean children (aged 0.3 to 10.7 years) and in one overweight infant, whereas we did not find brown adipocytes in obese children or adults. In our samples, the brown-like adipocytes were interspersed within white AT of perirenal, visceral and also subcutaneous depots. Samples with brown-like adipocytes showed an increased expression of UCP1 (>200fold), PRDM16 (2.8fold), PGC1α and CIDEA while other brown/beige selective markers, such as PAT2, P2RX5, ZIC1, LHX8, TMEM26, HOXC9 and TBX1 were not significantly different between UCP1 positive and negative samples. We identified a positive correlation between UCP1 and PRDM16 within UCP1 positive samples, but not with any other brown/beige marker. In addition, we observed significantly increased PRDM16 and PAT2 expression in subcutaneous and visceral AT samples with high UCP1 expression in adults. Our data indicate that brown-like adipocytes are present well beyond infancy in subcutaneous depots of non-obese children. The presence was not restricted to typical perirenal locations, but they were also interspersed within WAT of visceral and subcutaneous depots. info:eu-repo/classification/ddc/610 ddc:610
144	FTO obesity risk variants are linked to adipocyte IRX3 expression and BMI of children: relevance of FTO variants to defend body weight in lean children? Landgraf, Kathrin, Scholz, Markus, Kovacs, Peter, Kiess, Wieland, Körner, Antje January 2016 (has links) Background: Genome-wide association studies have identified variants within the FTO (fat mass and obesity associated) locus as the strongest predictors of obesity amongst all obesity-associated gene loci. Recent evidence suggests that variants in FTO directly affect human adipocyte function through targeting IRX3 and IRX5 and thermogenesis regulation. Aim: We addressed the relevance of this proposed FTO-IRX pathway in adipose tissue (AT) of children. Results: Expression of IRX3 was higher in adipocytes compared to SVF. We found increased adipocyte-specific expression of IRX3 and IRX5 with the presence of the FTO risk haplotype in lean children, whereas it was unaffected by risk variants in obese peers. We further show that IRX3 expression was elevated in isolated adipocytes and AT of lean compared to obese children, particularly in UCP1-negative adipocytes, and inversely correlated with BMI SDS. Independent of BMI, IRX3 expression in adipocytes was significantly related to adipocyte hypertrophy, and subsequent associations with AT inflammation and HOMA-IR in the children. Conclusion: One interpretation of our observation of FTO risk variants linked to IRX3 expression and adipocyte size restricted to lean children, along with the decreased IRX3 expression in obese compared to lean peers, may reflect a defense mechanism for protecting body-weight, which is pertinent for lean children. info:eu-repo/classification/ddc/601 ddc:601
145	Obezita a obezogeny / Obesity and Obesogens Dvořáková, Jana January 2019 (has links) The prevalence of obesity has already epidemic dimensions. Recently, the obesogens have been identified as the main cause in addition to excessive food intake, the lack of physical activity and the genetic background. These substances damage the metabolic processes, interfere with the hormonal functions and impair the energy balance in behalf of gaining weight and obesity. The theoretical part of this work deals with obesity, adipose tissue, lipid droplet and obesogens. From the obesogens there is closely specified a group of persistent organic pollutants (POP) from which one representative was used in the practical part of this work. The aim of the practical part was to describe the cellular model of differentiation the mesenchymal stem cell into adipocytes and to investigate the effect of one of the most frequently occurring obesogen on the expression genes of lipid metabolism and insulin signalling pathway. The morphological changes were observed in cells during differentiation (at days 0, 4, 10 and 21). The mesenchymal cells of the elongated spindle shape changed into adipocytes filled with lipid droplets. Oil Red O staining was used for quantification of accumulated lipids. The differentiation to adipocytes was confirmed by fluorescence immunocytochemistry using a specific protein FABP4. The...
146	Roles of Protein Arginine Methyltransferase 7 and Jumonji Domain-Containing Protein 6 in Adipocyte Differentiation: A Dissertation Hu, Yu-Jie 28 October 2015 (has links) Regulation of gene expression comprises a wide range of mechanisms that control the abundance of gene products in response to environmental and developmental changes. These biological processes can be modulated by posttranslational modifications including arginine methylation. Among the enzymes that catalyze the methylation, protein arginine methyltransferase 7 (PRMT7) is known to modify histones to repress gene expression. Jumonji domain-containing protein 6 (JMJD6) is a putative arginine demethylase that potentially antagonize PRMT7. However, the biological significance of these enzymes is not well understood. This thesis summarizes the investigation of both PRMT7 and JMJD6 in cell culture models for adipocyte differentiation. The results suggest that PRMT7 is not required for the differentiation, whereas JMJD6 is necessary for the differentiation by promoting the expression of the lineage determining transcription factors peroxisome proliferator-activated receptor γ (PPARγ) and CCAAT/enhancerbinding proteins (C/EBPs). The underlying mechanisms by which JMJD6 regulate differentiation involve transcriptional and post-transcriptional control of gene expression. Unexpectedly, the adipogenic function of JMJD6 is independent of its enzymatic activity. Collectively, the present research reveals a novel role of JMJD6 in gene regulation during the differentiation of adipocytes. Adipocytes Cell Differentiation Gene Expression Regulation Protein-Arginine N-Methyltransferases Dissertations, UMMS Biochemistry Cell Biology Cellular and Molecular Physiology Enzymes and Coenzymes
147	A Role for TNMD in Adipocyte Differentiation and Adipose Tissue Function: A Dissertation Senol-Cosar, Ozlem 30 June 2016 (has links) Adipose tissue is one of the most dynamic tissues in the body and is vital for metabolic homeostasis. In the case of excess nutrient uptake, adipose tissue expands to store excess energy in the form of lipids, and in the case of reduced nutrient intake, adipose tissue can shrink and release this energy. Adipocytes are most functional when the balance between these two processes is intact. To understand the molecular mechanisms that drive insulin resistance or conversely preserve the metabolically healthy state in obese individuals, our laboratory performed a screen for differentially regulated adipocyte genes in insulin resistant versus insulin sensitive subjects who had been matched for BMI. From this screen, we identified the type II transmembrane protein tenomodulin (TNMD), which had been previously implicated in glucose tolerance in gene association studies. TNMD was upregulated in omental fat samples isolated from the insulin resistant patient group compared to insulin sensitive individuals. TNMD was predominantly expressed in primary adipocytes compared to the stromal vascular fraction from this adipose tissue. Furthermore, TNMD expression was greatly increased in human preadipocytes by differentiation, and silencing TNMD blocked adipogenic gene induction and adipogenesis, suggesting its role in adipose tissue expansion. Upon high fat diet feeding, transgenic mice overexpressing Tnmd specifically in adipose tissue developed increased epididymal adipose tissue (eWAT) mass without a difference in mean cell size, consistent with elevated in vitro adipogenesis. Moreover, preadipocytes isolated from transgenic epididymal adipose tissue demonstrated higher BrdU incorporation than control littermates, suggesting elevated preadipocyte proliferation. In TNMD overexpressing mice, lipogenic genes PPARG, FASN, SREBP1c and ACLY were upregulated in eWAT as was UCP-1 in brown fat, while liver triglyceride content was reduced. Transgenic animals displayed improved systemic insulin sensitivity, as demonstrated by decreased inflammation and collagen accumulation and increased Akt phosphorylation in eWAT. Thus, the data we present here suggest that TNMD plays a protective role during visceral adipose tissue expansion by promoting adipogenesis and inhibiting inflammation and tissue fibrosis. Adipocytes Adipogenesis Brown Adipose Tissue Adiposity Insulin Insulin Resistance Membrane Proteins Tissue Expansion Dissertations, UMMS Adipose Tissue, Brown Cell Biology Cellular and Molecular Physiology Developmental Biology
148	Defining the Importance of Fatty Acid Metabolism in Maintaining Adipocyte Function: A Dissertation Christianson, Jennifer L. 27 April 2009 (has links) Although once considered a simple energy storage depot, the adipose tissue is now known to be a powerful regulator of whole body insulin sensitivity and energy metabolism. This metabolically dynamic organ functions to safely store excess fatty acid as triglyceride, thereby preventing lipotoxicity in peripheral tissues and the development of insulin resistance. In addition, the adipose tissue acts as an endocrine organ and secretes factors, called adipokines, which influence whole body insulin sensitivity and glucose homeostasis. Therefore, understanding adipose tissue development and biology is essential to understanding whole body energy metabolism. A master regulator of adipose tissue development and whole body insulin sensitivity is the nuclear receptor, PPARγ. Due to the importance of this nuclear receptor in maintaining adipocyte function, disruptions in PPARγ activity result in severe metabolic abnormalities, such as insulin resistance and type 2 diabetes. Conversely, PPARγ activation by synthetic agonists ameliorates these conditions, demonstrating the potent control this nuclear receptor has on whole body metabolism. Therefore, understanding how PPARγ expression and activity are regulated, particularly in the adipose tissue, is paramount to understanding the pathogenesis of type 2 diabetes. While there are several synthetic PPARγ agonists available, identifying the endogenous ligand or ligands is still an area of intense investigation. Since fatty acids can induce PPARγ activation, in the first part of this thesis, I screened several fatty acid metabolizing enzymes present in the adipocyte to identify novel modulators of PPARγ activity. These studies revealed that the fatty acid Δ9 desaturase, Stearoyl CoA Desaturase 2 (SCD2), is absolutely required for 3T3-L1 adipogenesis and to maintain adipocyte-specific gene expression in fully differentiated cells. Although SCD2 does not appear to regulate PPARγ ligand production, it does potently regulate PPARγ activity by maintaining the synthesis of PPARγ protein. Surprisingly, this effect was found only with SCD2 and not with the highly homologous protein, SCD1. Therefore, these findings identify separate cellular functions for these SCD isoforms and reveal a novel and essential role for fatty acid desaturation in the adipocyte. Equally important to understanding PPARγ regulation is identifying the downstream mechanisms by which PPARγ activation improves insulin sensitivity. Evidence suggests that the PPARγ target gene, Cidea, is involved in mediating insulin sensitivity by binding to lipid droplets and promoting lipid storage in the adipocyte. Therefore, the second part of thesis provides mechanistic detail into Cidea function by showing that the carboxy terminal 104 amino acids is necessary and sufficient for lipid droplet targeting and the stimulation of triglyceride storage. However, these studies also identified a novel function for Cidea, which requires both the carboxy and amino termini: to induce larger and fewer droplets from smaller dispersed droplets, indicating the possible fusion of droplets. Perhaps this striking change in lipid droplet morphology allows tighter packing and more efficient storage of triglyceride and identifies a novel role for Cidea in lipid metabolism. The results presented in this thesis elucidate key aspects of lipid metabolism that maintain adipocyte function: SCD2 is required to maintain PPARγ protein expression in the mouse; Cidea is a downstream effector of PPARγ activity by promoting efficient triglyceride storage. Therefore, these findings enhance our understanding of adipocyte biology. Adipocytes Fatty Acids Adipogenesis Apoptosis Regulatory Proteins Amino Acids, Peptides, and Proteins Cells Lipids Tissues
149	CONTRIBUTION OF THE UNFOLDED PROTEIN RESPONSE (UPR) TO ADIPOGENESIS AND WHOLE BODY ENERGY HOMEOSTASIS Basseri, Sana 04 1900 (has links) <p>The endoplasmic reticulum (ER) is a specialized organelle that facilitates correct protein folding and maturation. Disruptions in ER homeostasis lead to ER stress and activation of a series of signal transduction cascades known as the unfolded protein response (UPR), which acts to restore ER homeostasis. In recent years, ER stress and UPR dysfunction have been linked to obesity, fatty liver and insulin resistance. Lipid-laden adipocytes, the main cellular component of white adipose tissue (WAT), play a critical role in whole body energy homeostasis as well as lipid and carbohydrate metabolism. Mature adipocytes, which are metabolically active endocrine cells, differentiate from precursor fibroblast-like preadipocytes, through a process called adipogenesis, leading to formation of cells capable of secreting numerous proteins, cytokines and hormones. ER homeostasis and UPR activation are essential to the function/differentiation of highly secretory cells, however, the role of ER stress/UPR activation in adipogenesis had previously not been examined. We hypothesized that<em> adipogenesis may rely on physiological UPR activation to accommodate the demand on the ER for increased folding and secretion of proteins.</em></p> <p>Initial experiments examining UPR activation during 3T3-L1 adipogenesis identified that expression of ER stress/UPR markers was modulated during adipocyte differentiation. Furthermore, inhibition of ER stress/UPR activation by the chemical chaperone, 4-phenyl butyric acid (4-PBA), inhibited adipogenesis and blunted high fat-diet induced weight gain in 4-PBA supplemented mice. These findings suggested that UPR activation modulates adipogenesis and adipose tissue metabolism.</p> <p>Subsequently, we sought to identify novel candidate ER stress/UPR responsive genes that may be involved in adipogenesis and WAT metabolism. The expression of a recently recognized ER stress-responsive gene, T-cell death associated gene 51 (TDAG51) was identified to be differentially regulated during adipogenesis. However, the function of TDAG51 in adipogenesis or energy regulation was not known. Studies from this thesis showed that TDAG51 protein expression is attenuated by ER stress/UPR activation in preadipocytes and declines during adipogenesis. Based on these results, and given the importance of adipogenesis in WAT function and whole body energy metabolism, it was<em> </em>hypothesized that<em> TDAG51 may be a novel regulator of adipogenesis and energy homeostasis.</em> Indeed, as reported here, knock-down or absence of TDAG51 (<em>TDAG51<sup>-/-</sup></em>) in pre-adipocytes increased lipogenesis and lead to earlier and more potent expression of adipogenic markers.</p> <p>Finally, we investigated whether absence of TDAG51 in mice affected adiposity and metabolic outcomes. Consistent with the <em>in vitro </em>results, we found that <em>TDAG51<sup>-/-</sup></em><sup> </sup>mice fed a standard chow diet, exhibited an age-associated increase in WAT, developed fatty liver, and exhibited insulin resistance as compared to wild-type mice.</p> <p>Taken together, the findings in this thesis indicate that physiological UPR activation and the UPR-responsive gene TDAG51 play important roles in regulating adipogenesis, lipogenesis and whole-body energy metabolism. Thus, therapeutic approaches aimed at modulating ER folding capacity, UPR activation and/or TDAG51 expression may have great potential in the treatment of obesity and its co-morbidities.</p> / Doctor of Philosophy (PhD) Endoplasmic Reticulum Stress TDAG51 Adipocytes Obesity White Adipose Tissue Endocrinology, Diabetes, and Metabolism Medical Cell Biology
150	Exploring adipose tissue through spatial ATAC sequencing / Utforskning av fettvävnad genom rumslig ATAC-sekvensering Leira Mas, Martí January 2024 (has links) Fettvävnaden är en viktig regulator för ämnesomsättningen och uppvisar en komplex cellulär arkitektur som påverkar olika fysiologiska och patologiska processer. Dess heterogena natur är relativt ostrukturerad och består huvudsakligen av bräckliga feta adipocyter och immunceller. Dessa komplikationer försvårar studier av mikroarkitekturen - som är avgörande för att förstå dess beteende - vilket nyligen har gynnats av teknik med rumslig upplösning, som möjliggör studier av genomiska profiler samtidigt som informationen från vävnaden bevaras. I detta arbete undersöks kromatindynamiken i fettvävnad med hjälp av den nyutvecklade Spatial Assay for Transposase-Accessible Chromatin med sekvensering med hög genomströmning (Spatial ATAC-seq). Med fokus på subkutan vit fettvävnad samlades prover in från en individ som led av fetma före och fem år efter en bariatrisk operation för att studera förändringar i samband med betydande viktnedgång. Studien omfattar detaljer för både experimentella protokoll och avancerade beräkningsverktyg för dataanalys, inklusive användning av en utvecklingsversion av Semla-paketet för att integrera data om rumslig tillgänglighet och kromatintillgänglighet. Analysen visade på en mångsidig cellulär arkitektur och distinkta genomiska egenskaper i vävnaden, vilket framhävde förekomsten av specifika celltyper som AdipoLEP-liknande adipocyter och infiltrerande immunceller. Denna studie visade att det är möjligt att tillämpa Spatial ATAC-seq för att undersöka de molekylära mekanismerna i fettvävnad som ligger till grund för metabol hälsa och sjukdom, särskilt i samband med fetma och viktminskning. / Adipose tissue is a critical regulator of metabolism, exhibiting a complex cellular architecture that influences various physiological and pathological processes. Its heterogeneous nature is relatively unstructured, mainly formed by fragile fatty adipocytes and immune cells. These intricacies complicate the study of its microarchitecture – crucial for understanding its behaviour – which has recently benefitted from spatially resolved technologies, that enable the study of genomic profiles while keeping the information from the tissue. This work explores the chromatin dynamics of adipose tissue using the newly developed Spatial Assay for Transposase-Accessible Chromatin with high throughput sequencing (Spatial ATAC-seq). Focusing on subcutaneous white adipose tissue, samples were collected from an individual suffering from obesity before and five years after bariatric surgery to study changes associated with significant weight loss. The study comprises details for both experimental protocols and advanced computational tools for data analysis, including the use of a development version of Semla package to integrate spatial and chromatin accessibility data. The analysis revealed a diverse cellular architecture and distinct genomic features across the tissue, highlighting the presence of specific cell types such as AdipoLEP-like adipocytes and infiltrating immune cells. This study demonstrated the feasibility of applying Spatial ATAC-seq in investigating the molecular mechanisms of adipose tissue underlying metabolic health and disease, particularly in the context of obesity and weight loss. adipose tissue biology adipocytes spatial ATAC sequencing spatial transcriptomics Semla fettvävnad biologi adipocyter rumslig ATAC-sekvensering rumslig transkriptomik Semla Biochemistry and Molecular Biology Biokemi och molekylärbiologi

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