Global ETD Search

11	FASN Negatively Regulates NF-kB/P65 Expression in Breast Cancer Cells by Disrupting Its Stability Barlow, Lincoln James 02 1900 (has links) Indiana University-Purdue University Indianapolis (IUPUI) / The overexpression of the multi-domain enzyme fatty acid synthase (FASN) has long been associated with poor clinical prognosis and treatment outcome in various cancers. Previous research in the Zhang lab has determined a role for FASN in mediating increases in non-homologous end-joining (NHEJ) DNA double-strand break repair activity allowing for increased cancer cell survival, and this mechanism was found to involve inhibition of NF-kB/p65. The mechanism responsible for the regulation of NF-kB/p65 by FASN in cancer cells, however, remains unknown. To this end, I was able to determine that FASN negatively regulates both the expression and activity of NF-kB/p65 in breast cancer cells, and that this effect was likely mediated by the 16-carbon saturated fatty acid palmitate, the end product of FASN catalytic activity. Specifically, FASN was found to negatively regulate p65 expression by disrupting its protein stability as a result of an increase in poly-ubiquitination of p65 protein and subsequent proteasomal degradation. Further, I found that the phosphorylation site Thr254 of p65 is involved in the regulation of p65 protein stability by FASN, in that mutation of this residue resulted in a disruption in p65 stability. Finally, I was able to determine that FASN likely inhibits the ability of the peptidyl-prolyl cis/trans isomerase Pin1 to assist in maintaining p65 stability, in that both siRNA knockdown and pharmacological inhibition of Pin1 resulted in a reduction of p65 expression in FASN shRNA knockdown cells. The determination of this signaling mechanism serves to expand our understanding of the role of FASN in breast cancer cells and has the potential to assist in uncovering more effective ways to target the oncogenic FASN pathway to kill breast tumor cells and to overcome resistance to drug treatment. breast cancer DNA repair FASN NF-kB palmitate protein stability
12	Rôle des exosomes sécrétés par le muscle squelettique au cours du développement des maladies métaboliques / The role of Skeletal muscle derived exosomes during the development of metabolic diseases Aswad, Hala 13 October 2016 (has links) Le muscle squelettique est le plus grand organe du corps humain. Il est maintenant admis que c'est un organe sécréteur de cytokines qui jouent un rôle important comme signaux paracrines et endocrines. Récemment, il a été démontré que le muscle squelettique sécrète aussi des nanovesicules appelées « exosomes ». Dans ce contexte, notre équipe a démontré que les exosomes sécrétés par les cellules musculaires avaient un effet paracrine et étaient impliqués dans la prolifération et la différenciation musculaire. Comme il est admis que la masse musculaire est affectée par différentes situations physiologiques (la nutrition et l'activité physique) ou pathologiques (obésité, le diabète et la sarcopénie), nous nous sommes demandés, dans un premier temps, quel était le rôle des exosomes dans la régulation de la masse musculaire et s'ils pouvaient modifier les dialogues muscle-organes insulino-sensibles au cours d'un régime riche en acide gras saturé. Ces travaux ont donné lieu à 2 articles publiés dans « Diabetologia ». Dans ces deux articles, nous avons démontré dans un modèle de souris que le muscle, en situation d'insulino-résistance due à un régime riche en acide gras saturé, sécrète plus d'exosomes. De plus, ces exosomes ont une composition modifiée en acides gras et en microARN. In vitro, cette nouvelle population d'exosomes affectent la prolifération des cellules receveuses i.e. ; cellules musculaires et cellules béta pancréatiques, in vitro, en régulant les gènes du cycle cellulaire et de différenciation dans les cellules musculaires receveuses et le gène pitx2 dans les cellules beta. Ces travaux suggèrent que les exosomes sécrétés par le muscle squelettique, perturbent l'homéostasie musculaire et pancréatique durant un régime riche en acide gras saturé.Dans un deuxième temps, nous avons réalisé une étude technique afin de déterminer les conditions optimales pour isoler la quantité maximale des exosomes, relarguées par les cellules musculaires. Cette étude, publiée dans « BMC Biotechnology », a démontré que cultiver des cellules musculaires dans un milieu sans exosomes de sérum de veau ou de cheval, ralentie leur prolifération et par conséquent leur différenciation. Ceci suggère que les exosomes des sérums des milieux de culture participent à la croissance des cellules musculaires. De façon intéressante, ce résultat mime le cross-talk entre myoblastes et myotubes précédemment démontré au laboratoire et laisse suggérer un rôle plus général des exosomes circulant dans les processus d'hypertrophie, hyperplasie mis en place durant le développement. De plus, ces résultats indiquent que les exosomes pourraient participer aux cross-talks entre espèces / Skeletal muscle (SkM) is considered as a secretory organ, it secretes cytokines named myokines that can act either locally (autocrine) or systemically (endocrine). In addition to myokines, SkM secretes nanovesicles named exosomes (SkM-Exos). Previous work from the laboratory have demonstrated that myotube- and myoblastderived exosomes were involved in the process of myogenesis and could transfer their content to target cells. In this work, we determined whether SkM-Exos wereinvolved in lipid-induced insulin resistance and participate in organ cross-talk during the development of obesity. Firstly, we determined the effect of high fat diet on SkM-Exo release and on their miRNA and lipid composition. In addition, we determined the biological effect of these exosomes on skeletal muscle and pancreatic recipient cells. Results are published in 2 separate papers in “Diabetologia”. In these two studies, exosomes were collected from quadriceps muscles of C57Bl/6 mice fed for 16 weeks with either a standard chow diet (SD) or an SD enriched with 20% palm oil (HP) or from C2C12 cells exposed to 0.5 mmol/l palmitate (EXO-Post Palm), oleate (EXO-Post Oleate) or BSA (EXO-Post BSA). We treated skeletal muscle cells or β pancreatic cells with these muscle-released exosomes. We found that exosomes from HP fed mice, EXO-Post Palm and EXO-Post Oleate induced myoblast and β pancreatic islet proliferation and modified the expressions of genes involved in cell cycle and muscle differentiation but did not alter insulin-induced Akt phosphorylation in muscle cells. Lipidomic analyses showed that exosomes from palmitate-treated cells were enriched in palmitate, indicating that exosomes likely transfer the deleterious effect of palm oil between muscle cells by transferring lipids. Also, we demonstrated that these exosomes likely transfer their miRNA contents resulting in beta pancreatic islet hypertrophy during type 2 diabetes mellitus (T2D). Moreover, muscle exosomes were incorporated into various tissues in vivo, including the pancreas and liver, suggesting that SkM could transfer specific signals through the exosomal route to key metabolic tissues in vivo. So, SkM derived exosomes altered muscle and β pancreatic cell homeostasis during lipid induced insulin resistant diet. Secondly, another work was conducted in order to answer to a technical problem about optimal conditions needed to obtain, in vitro, the highest concentration of exosomes from muscle cells when grown in a depleted-exosome medium. This work was published in “BMC Biotechnology”. In this study, we found that depleting culture media from exosomes affected skeletal muscle cell proliferation. In addition, removal of serum-EVs from culture medium affects gene and miRNA expressions and likely the proteome of the cells. Interestingly, our data showed that we can recapitulate the cross-talk between myoblast and myotubes previously demonstrated in the laboratory by using exosomes from serum as well. Indeed, serum derived-exosomes, like myotube derived-exosomes, can affect proliferation of myoblasts and induce their entrance in the differentiation process. This result implies that bovine exosomes can transfer specific signals to cells from unrelated species (i.e. ; to mice, rats and human) and thus that part of exosome composition is evolutionarily conserved between these lower and higher order mammalian species. Generally speaking, these results suggest that exosomes in body fluids could have an unsuspected function during embryogenesis and in the regulation of cellular adaptations that lead to hypertrophy, hyperplasia and metaplasia Exosomes Palmitate Prolifération Différentiation C2C12 MIN6B1 Cellules musculaire MicroARN Exosomes Palmitate Proliferation Differentiation C2C12 MIN6B1 Muscle cell MiRNA 572.4
13	Epigenetic regulations by insulin and histone deacetylase inhibitors of the insulin signaling pathway in muscle / Régulation épigénétiques par l’insuline et un inhibiteur des histones déacétylases sur la voie de signalisation de l’insuline dans le muscle Chriett, Sabrina 03 October 2016 (has links) L’émergence et le développement des maladies métaboliques est sous le contrôle de multiples facteurs génétiques et environnementaux. Le diabète et la résistance à l’insuline sont des maladies métaboliques caractérisées par des défauts dans la sécrétion de l’insuline ou son utilisation périphérique, ou les deux. L’insuline est l’hormone clé de l’utilisation du glucose, et régule également transcriptionnellement et épigénétiquement l’expression des gènes.En travaillant sur le muscle, l’implication de l’épigénétique dans la régulation de l’expression des gènes de la voie de l’insuline a été mis en évidence. L’hexokinase 2 (HK2) est régulée par l’insuline et participe au métabolisme glucidique. Le rôle de l’épigénétique y est démontré avec l’augmentation de l’acétylation des histones autour du site d’initiation de la transcription (SIT) de HK2 et l’accumulation d’une isoforme permissive des histones, H2A.Z. Ces deux phénomènes sont le signe d’une transcription permissive.Nous avons ensuite étudié le rôle de l’acétylation des histones dans les régulations amenées par l’insuline dans les myotubes L6. Nous avons utilisé le butyrate, un inhibiteur des histones deacetylase (HDACi), dans un contexte d’insulino-résistance induite par une lipotoxicité. Le butyrate a en partie restauré la sensibilité à l’insuline visible au niveau des phosphorylations de la PKB (protein kinase B) et de la MAPK (Mitogen-activated protein kinase), inhibées par le traitement au palmitate. Le butyrate a augmenté l’expression de l’ARNm et de la protéine d’IRS1. La surexpression génique d’IRS1 est épigénétique-dépendante car liée à une augmentation de l’acétylation des histones au SIT d’IRS1.L’ensemble de ces résultats démontre l’existence d’un lien entre les modifications épigénétique et l’action de l’insuline. Cela suggère qu’une intervention pharmacologique sur la machinerie épigénétique pourrait être un moyen d’améliorer le métabolisme, et l’insulino-résistance / Diabetes and insulin resistance are metabolic diseases characterized by altered glucose homeostasis due to defects in insulin secretion, insulin action in peripheral organs, or both. Insulin is the key hormone for glucose utilization and regulates gene expression via transcriptional and epigenetic regulations.We determined the epigenetic implications in the regulation of expression of insulin signaling pathway genes. Hexokinase 2 (HK2) is known to be upregulated by insulin and directs glucose into the glycolytic pathway. In L6 myotubes, we demonstrated that insulin-induced HK2 gene expression rely on epigenetic changes on the HK2 gene, including an increase in histone acetylation around the transcriptional start site (TSS) of the gene and an increase in the incorporation of the histone H2A.Z isoform – a histone variant of transcriptionally active chromatin. Both are epigenetic modifications compatible with increased gene expression.To elucidate the role of histone acetylation in the regulation of insulin signaling and insulin-dependent transcriptional responses in L6 myotubes, we investigated the effects of butyrate, an histone deacetylase inhibitor (HDACi), in a model of insulin resistance induced by lipotoxicity. Butyrate partly alleviated palmitate-induced insulin resistance by ameliorating insulin-induced PKB (protein kinase B) and MAPK (Mitogen-activated protein kinase) phosphorylations, downregulated with exposure to palmitate. Butyrate induced an upregulation of IRS1 gene and protein expression. The transcriptional upregulation of IRS1 was proven to be epigenetically regulated, with butyrate promoting increased histone acetylation around the TSS of the IRS1 gene.These results support the idea of the existence of a link between epigenetic modifications and insulin action. Pharmacological targeting of the epigenetic machinery might be a new approach to improve metabolism, especially in the insulin resistant condition.Key words: Muscle, insulin resistance, epigenetic, chromatin, histone acetylation, histone deacetylase inhibitor (HDACi), butyrate, palmitate Muscle Insulino-résistance Épigénétique Chromatine Histone acétylation Butyrate Palmitate Muscle Insulin resistance Epigenetic Chromatin Histone acetylation Histone deacetylase inhibitor (HDACi) Butyrate Palmitate 570
14	Effects of Free Fatty Acids on Insulin and Glucagon Secretion : – with special emphasis on the role of Free fatty acid receptor 1 Kristinsson, Hjalti January 2017 (has links) Prevalence of type 2 diabetes mellitus (T2DM) is still rising and even so in the juvenile population. Obesity is highly associated with increased risk for developing T2DM. The development has been related to elevated fasting concentrations of the pancreatic islet hormones insulin and glucagon as well as to an increase in plasma lipids that occurs during obesity. Specifically, research has indicated that chronic exposure to high levels of saturated free fatty acids cause dysfunction in islet alpha- and beta-cells. Fatty acids can affect islet cells by various mechanisms one of which is the G-protein coupled receptor FFAR1/GPR40. The role of the receptor in the effects of fatty acids on pancreatic islet-cell function is not clear. The aim of this thesis was to clarify the role of FFAR1 in how fatty acids, and more specifically the long-chain saturated fatty acid palmitate, affect insulin and glucagon secretion. In children and adolescents with obesity elevated fasting levels of insulin and glucagon were positively correlated with lipid parameters. Specifically, plasma triglycerides and free fatty acids were positively correlated with insulin and glucagon at fasting as well as with visceral adipose tissue volume. Elevated glucagon levels at fasting were associated with worsening of glucose tolerance in the same population. In in vitro studies of isolated human islets palmitate stimulated basal insulin and glucagon secretion as well as mitochondrial respiration at fasting glucose levels. The effect was mediated by FFAR1 and fatty acid beta-oxidation. At higher glucose concentrations the receptor was involved in the potentiation of insulin secretion from isolated human islets and insulin-secreting MIN6 cells. Furthermore, we found that the effects of palmitate on hormone secretion were associated with enhanced mitochondrial respiration mediated by FFAR1 Gαq signaling and PKC activity as well as increased intracellular metabolism induced by the fatty acid. When islets were exposed to palmitate for long time periods and in the presence of FFAR1 antagonist, normalized insulin and glucagon secretion during culture and insulin response to glucose after culture were observed. In MIN6 cells chronic palmitate treatment increased mitochondrial uncoupling irrespective of FFAR1 involvement. However, FFAR1 antagonism during palmitate exposure resulted in elevated respiration and reduced apoptosis. In conclusion, children and adolescents with obesity have elevated fasting concentrations of insulin and glucagon that correlate with free fatty acids and fatty acid sources. High glucagon levels are linked to worsening of glucose tolerance in these subjects. In vitro the combination or synergy of FFAR1 activation and intracellular metabolism caused by palmitate is decisive for both the short-term enhancement effects and the negative chronic effects on insulin and glucagon secretion. FFAR1 GPR40 palmitate lipotoxicity islets of Langerhans type 2 diabetes obesity Cell and Molecular Biology Cell- och molekylärbiologi
15	Fotoestabilidade e fototoxicidade de avobenzona e palmitato de retinila associados a diferentes fotoestabilizadores / Photostability and phototoxicity of avobenzone and vitamin A associated with different light stabilizers Scarpin, Marcela Silva 21 November 2017 (has links) Os filtros solares formam a base da indústria cosmética de proteção solar. Estas substâncias podem absorver ou refletir a radiação UV. Por essa radiação provocar danos à pele, fotoenvelhecimento, câncer, é necessário o uso de protetores solares. Com isso, nas últimas décadas, as formulações cosméticas passaram a ser acrescidas dessas substâncias, que protegem a pele do consumidor contra a radiação UV. As vitaminas também passaram a ser adicionadas à a formulações fotoprotetoras para atuarem como antioxidantes. No entanto, os filtros sofrem degradação na presença de luz (fotodegradação), além disso, sua combinação com vitaminas pode levar à formação de intermediários reativos os quais podem provocar dermatites de contato e reações fototóxicas na pele. A comunidade científica tem se empenhado para a utilização de testes alternativos ao uso de animais de experimentação, sendo que o teste de fototoxicidade 3T3 NRU PT (Neutral red uptake), em cultura de fibroblastos, tem sido o preconizado para essa finalidade. Assim, o objetivo deste trabalho é avaliar a fotoestabilidade e fototoxicidade da avobenzona e palmitato de retinila associadas a diferentes fotoestabilizadores, por meio do uso de cromatografia liquida de alta eficiência (CLAE) e cultura de fibroblastos em monocamadas, respectivamente. Para tal, foram desenvolvidas formulações fotoprotetoras contendo os filtros solares avobenzona (AVO) e metoxicinamato de etilexila (MTX) acrescidos ou não de palmitato de retinila (Pr), e de fotoestabilizadores (tris tetrametilhidroxipiperidiol - TTMHP, etilhexil metoxicrileno - EHMCR e Tris-bifenil Triazina - TBFT), que foram utilizados para melhorar a sua fotoestabilidade. Os resultados de fotoestabilidade por CLAE demonstraram que a avobenzona, o metoxicinamato de etilexila e o palmitato de retinila foram considerados fotoinstáveis, porém a adição do fotoestabilizador EHMCR melhorou a fotoestabilidade das mesmas. Já o fotoestabilizador TBFT e TTHMP melhoraram a fotoestabilidade da associação de filtros sem a presença do palmitato de retinila. As análises por espectrofotometria demonstraram que a inclusão do TBFT na associação de filtros (FB3) e a inclusão do EHMCR na associação de filtros e o palmitato de retinila (FB2Pr), melhoraram a fotoestabilidade de suas respectivas formulações. A fototoxicidade das associações de filtros solares, estabilizadores e palmitato de retinila foi avaliada por meio do uso de cultura de fibroblastos 3T3, que foi submetida à radiação UVA para a determinação da viabilidade celular na presença e ausência da radiação seguindo recomendações da OECD TG 432. Os resultados obtidos nos sugerem que, no estudo de fototoxicidade, a AVO e TBFT apresentaram potencial fototóxico. As associações contendo os filtros AVO e MTX, acrescidos ou não de Pr (C1C e C1PrC) foram consideradas fototóxicas. Quanto à adição dos fotoestabilizadores, observou-se que a adição dos fotoestabilizadores TBFT e EHMCR à associação de AVO, MTX também foi considerada fototóxica (C2 e C3, respectivamente). Entretanto a adição do fotoestabilizador EHMCR à associação AVO, MTX e Pr, foi considerada não fototóxica. Já a inclusão dos fotoestabilizadores TTMHP e TBFT à associação contendo AVO, MTX, Pr (C3Pr e C4Pr) foram consideradas fototóxicas. / Sunscreens form the basis of cosmetic sun protection industry. These substances can absorb or reflect UV radiation. The radiation causes UV-induced damages to the skin, photoaging, cancer; therefore the use of sunscreen is necessary. In recent decades, the cosmetic formulations are now added of those substances which protect the consumer\'s skin against UV radiation. Vitamins also began to be added to the photoprotective formulations to act as antioxidants. However, the filters are degraded in the presence of light (photodegradation), moreover, the combination with vitamins can lead to the formation of reactive intermediates which can cause contact dermatitis and phototoxic skin reactions. The scientific community has been engaged in the use of alternative assays to replace animal experimentation, and the 3T3 NRU phototoxicity test (Neutral Red Uptake) in fibroblasts culture, has been recommended for this purpose. The objective of this study is to evaluate the photostability and phototoxicity of avobenzone and vitamin A associated with different photostabilizers, through the use of high performance liquid chromatography (HPLC) and culture of fibroblast in monolayers, respectively. For this, were developed photoprotective formulations containing avobenzone (AVO) and ethylhexyl methoxycinnamate (MTX) with or without the presence of vitamin A palmitate (Pr), and photostabilizers (Tris Tetramethylhydroxypiperidinol Citrate - TTMHP, ethylhexyl methoxycrylene - EEMC, Tris-Biphenyl Triazine - TBFT ), which were used to enhance the sunscreens photostability. The results of photostability by HPLC demonstrated that avobenzone, ethylhexyl methoxycinnamate and retinyl palmitate were considered photounstable, but the addition of the EHMCR improved their photostability. The TBFT and TTHMP improved the photostability of the association of sunscreens without the retinyl palmitate. Results by spectrophotometry demonstrated that the TBFT inclusion in the association of sunscreens (FB3) and EHMCR inclusion with the association of sunscreens and retinyl palmitate (FB2Pr) improved the photostability of their respective formulations. Phototoxicity of sunscreens combinations, photostabilizers, and vitamin A was evaluated by using 3T3 fibroblasts culture, which has been subjected to UVA radiation for the determination of cell viability in the presence and absence of radiation, according to OECD TG 432. The results suggest that, in phototoxicity study, AVO and TBFT presented phototoxic potential. Combinations containing AVO and MTX filters, added or not of Pr (C1C and C1PrC) were considered phototoxic. Regarding the addition of the photostabilizers, it was observed that the addition of TBFT and EHMCR photostabilizers to the combination of AVO, MTX was also considered phototoxic (C2 and C3). However, the addition of EHMCR to AVO, MTX and Pr was considered non-phototoxic. The inclusion of the TTMHP and TBFT photostabilizers in the combination containing AVO, MTX, Pr (C3Pr and C4Pr) were considered phototoxic.
16	The effect of single nucleotide polymorphisms and metabolic substrates on the cellular distribution of mammalian BK channels Adeyileka-Tracz, Bernadette Ayokunumi January 2017 (has links) Humans are approximately 99% similar with inter-individual differences caused in part by single-nucleotide polymorphisms (SNPs), which poses a challenge for the effective treatment of disease. Bioinformatics resources can help to store and analyse gene and protein information to address this challenge, however these resources have limitations, so the collation and biocuration of gene and protein information is required. Using the large conductance calcium- and voltage-activated potassium channel, also known as the Big Potassium (BK) channel as an example, due to its ubiquitous expression and widespread varied role in human physiology, this study aimed to prioritise SNPs with the potential to affect the function of the channel. Using a BK channel resource created with bioinformatics tools and published literature, mSlo SNPs H55Q and G57A, located in the S0-S1 linker, were prioritised and selected for lab-based verification. These SNPs flank three cysteine residues proven to modulate channel cellular distribution via palmitoylation, a reversible process shown to increase protein association with the cell membrane. The SNPs alter the predicted palmitoylation status of C56, one of the cysteine residues located in the S0-S1 linker. The cellular distribution of BK channels incorporating the SNPs was assessed using confocal microscopy and revealed that the direction and magnitude of SNP mimetic cell membrane expression was closely related to the C56 predicted palmitoylation score; a 'C56 palmitoylation pattern' was observed. It was shown that exposure to metabolic substrates glucose, palmitate and oleate modulated SNP-mimetic cellular distribution and could invert the 'C56 palmitoylation pattern', indicating that there is interplay between the metabolic status of the cell and the amino-acid composition of the channel via palmitoylation. The creation of a novel BK channel resource in this thesis highlighted the limitations, and inter-dependency of bioinformatics and lab based experimentation, whilst SNP verification experiments solidified the link between S0-S1 cysteine residues and BK cellular distribution. BK channel function is linked with a number of physiological processes; thus, the potential clinical consequences of the SNPs prioritised in this thesis require further research. 610
17	Études des mécanismes d’adaptation du métabolisme énergétique dans le syndrome de Leigh de type canadien français : vers l’identification des cibles thérapeutiques Mukaneza, Yvette 10 1900 (has links) No description available. LSFC LRPPRC COX mTOR Rapamycin AMPK SIRT1 Palmitate Rapamycine
18	Rôle des exosomes sécrétés par le muscle strié squelettique au cours de la myogenèse et en situation d'insulino-résistance Forterre, Alexis 19 December 2012 (has links) (PDF) Les exosomes sont des nanovésicules de 30 à 100nm sécrétées dans le milieuextracellulaire par une grande majorité de types cellulaires. Entourés d'une bicouchelipidique similaire aux radeaux lipidiques, ils contiennent des protéines, de l'ARNm et desmicroARNs. Récemment, il a été montré que les exosomes pourraient participer auxdialogues moléculaires inter-organes, au même titre que les protéines solubles (hormones etcytokines). Au cours de cette thèse, nous avons émis l'hypothèse que le muscle squelettiquepourrait utiliser les exosomes comme mode de communication intercellulaire, en plus desmyokines qu'il sécrète. Nous avons montré en couplant des techniques de microscopieélectronique, de génomique, de biologie cellulaire et moléculaire, et d'analysesprotéomiques, que le muscle était capable de sécréter des exosomes, dont la compositionvariait au cours de la myogenèse. De plus, nous avons montré que les exosomes sécrétéspar les cellules prolifératrices et différenciées avaient des rôles distincts au cours de ladifférenciation myogénique, via le transfert des microARNs notamment.En parallèle, nous nous sommes intéressés aux exosomes sécrétés par le musclesquelettique en situation d'insulino-résistance induite par du palmitate. En utilisant unedouble approche in vitro et in vivo, nous avons montrés que les exosomes sécrétés par lacellule musculaire insulino-résistante ont une morphologie et une composition luminalemodifiée. Enfin, ces exosomes sécrétés sembleraient transmettre un signal délétère àd'autres cellules musculaires différenciées, et aux autres tissus insulino-sensibles, comme lepancréas. Exosome Muscle squelettique Palmitate MicroARNs Insulino-résistance
19	Development of an assay for fatty acyl-CoAs using liquid chromatography-electrospray ionization-tandem mass spectrometry and its application to the stable isotope labeling and quantitation of sphingolipid metabolism Haynes, Christopher Allen 16 November 2009 (has links) Fatty acyl-Coenzyme As are metabolites of lipid anabolism and catabolism. A method was developed for their quantitation in extracts of cultured mammalian cells using liquid chromatography-electrospray ionization-tandem mass spectrometry (LC-ESI-MS/MS). Palmitoyl-CoA (C16:0-CoA) is utilized for de novo sphingolipid biosynthesis catalyzed by serine palmitoyltransferase (SPT), which condenses palmitoyl-CoA and serine to form 3-ketosphinganine. After reduction to form sphinganine (Sa), dihydroceramide synthase (CerS) can N-acylate the Sa using a second fatty acyl-CoA molecule, forming dihydroceramide (DHCer). The CerS enzyme family utilizes different acyl chain lengths of fatty acyl-CoAs in an isoform-specific manner, resulting in DHCer with N-acyl chains ranging from C16 to C26 [and even longer] in mammalian tissues. DHCer is trans-4,5-desaturated to yield ceramide, which is further metabolized by the addition of moieties at the 1-O-position, forming sphingomyelin (SM) and ceramide monohexose (CMH). The rates of fatty acyl-CoA and sphingolipid biosynthesis were determined using stable isotope-labeling and LC-ESI-MS/MS analysis of the analyte isotopologues and isotopomers. Isotopic labeling of palmitoyl-CoA with [U-13C]-palmitate in HEK293 and RAW264.7 cells was robust and rapid (~ 60% labeling of the metabolite pool in 3 hr). Isotopic labeling of sphingolipids indicated utilization of [M + 16]-palmitoyl-CoA by SPT and CerS isoforms in both cell types. Metabolic flux modeling was applied to the data for [U-13C]-palmitate activation to [M + 16]-palmitoyl-CoA and its subsequent utilization in de novo sphingolipid biosynthesis, and this analysis indicated rapid turn-over rates for palmitoyl-CoA and ceramide in both cell types. Palmitate treatment of cultured cells alters their metabolic status and gene expression, therefore labeling of palmitoyl-CoA by treatment with [1-13C]-acetate was employed. A distribution of mass-shifted palmitoyl-CoA species (isotopologues) is observed based on the number of incorporations of [1-13C]-acetate during de novo biosynthesis, requiring computational analysis to derive two parameters: the isotopic enrichment of the precursor pool, and the fraction of palmitoyl-CoA that was biosynthesized during the experiment. Previous reports by others describe mass isotopomer distribution analysis (MIDA) and isotopomer spectral analysis (ISA) for this purpose, and both calculation approaches indicated concurrent results. In summary, the quantitation of fatty acyl-CoAs and their isotopic enrichment during stable isotope-labeling studies of lipid metabolism can provide data that significantly change the interpretation of analyte quantitation in these experiments, as demonstrated here for investigations of de novo sphingolipid biosynthesis. Serine palmitoyltransferase [1-13C]-acetate [U-13C]-palmitate HEK293 RAW264.7 Sphingolipids Radiolabeling Fatty acids
20	NANOINDENTATION OF A ZINC METAL SOAP MIXTURE FOR USE IN A LASER PRINTER Nimick, George A. 01 January 2015 (has links) At the start of this project, the possible choices of metal soaps had already been narrowed to include some of the zinc soaps used in this project. These zinc soaps are mixtures of zinc stearate and zinc palmitate of varying ratios purchased from a supplier. Zinc soap was chosen as result of its common use in various industries as a lubricant and mold release, which implied potential benefits in an electrophotographic printing system. These potential benefits include, but are not limited to, a more efficient transfer from a photoconductive drum and protection of the drum from mechanical and chemical degradation. Nanoindentation of these soaps was implemented in an effort to characterize each soap mixture and compare how the soap types differed from one another. Each sample was indented under a variety of different maximum loads and at different holding times to observe effects on the modulus, hardness, and, creep. The mechanical properties measured were then used to help distinguish differences between each type and provide an insight as to how or why one mixture may be preferable over another. The data could be utilized in conjunction with further testing to be used in a simulation of an interface of interest. Zinc Stearate Zinc Palmitate nanohardness zinc octadecanoate zinc hexadecanoate Other Materials Science and Engineering Other Mechanical Engineering

Search results