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Crucial role of reversible phosphorylation in the mechanisms governing the biological functions of class IIa histone DeacetylasesMartin, Maud 27 May 2009 (has links)
Regulation of class IIa histone deacetylases (HDACs) phosphorylation is crucial because it provides the opportunity to control important developmental processes associated with these key enzymes. Indeed, the transcriptional repressor activity of class IIa HDAC is controlled via their phosphorylation-dependent nucleo-cytoplasmic shuttling. While a lot of efforts have been directed towards the identification of the inactivating kinases that phosphorylate class IIa HDACs, the identity of the antagonist phosphatase remained an open question. During this work, we found that protein phosphatase 2A (PP2A) is responsible for dephosphorylating the class IIa HDACs member HDAC7, thereby regulating its subcellular localization and repressor activity. In order to validate our model, functional consequences of these findings was illustrated during the two main biological processes involving HDAC7, i.e. T-cells apoptosis during negative selection and endothelial cells angiogenic activities during vascular network formation. Cellular PP2A represents a large population of trimeric holoenzymes containing a variable regulatory subunit, whose identity has a crucial role in determining the specificity of PP2A catalytic activity. In an effort to characterize the regulation of HDAC7 dephopshorylation, we identified the relevant PP2A holoenzyme regulating HDAC7 function during vasculogenesis and we found that, among diverse regulatory subunit isoforms, PP2A-Bα uniquely regulates endothelial cell angiogenic properties. PP2A-Bα silencing using small interfering RNAs results in a significant inhibition of endothelial cell tube formation and migration. These results establish PP2A, and more precisely the Bα containg PP2A holoenzyme, as an essential element in the regulation of the class IIa HDAC HDAC7 and unravel a first developmental function for the PP2A regulatory subunit Bα in the genesis of blood vessels.
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Exprese a purifikace kinasove domény ASK1 kinasy. / Expression and purification of kinase domain of ASK1 kinase.Bártová, Hana January 2010 (has links)
The goal of this diploma thesis was to find optimal conditions for expression of ASK1 kinase in prokaryotic expression system and to optimize purification protocol which enables preparing of milligram amounts of stable and soluble protein. Different conditions of expression were tested in E. coli cells including temperature of expression, cultivation medium or the length of induction. Different methods of purification were tested during the development of the purification protocol. The final protocol is based on chelate chromatography followed by gel permeation chromatography. The result of the diploma thesis is a protocol that allows preparing 1 mg of pure ASK1 kinase from 1 liter of medium.
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Protein complexes in neurodegenerative diseasesHouston, Nicola Patricia January 2012 (has links)
The 14-3-3 family of proteins are important signalling proteins involved in a number of cellular processes. These include cell cycle regulation, apoptosis, signal transduction and cell signalling. There is also considerable evidence in the literature that 14-3-3 proteins play a vital role in the pathology of neurodegenerative diseases, including Alzheimer’s, Parkinson’s, Huntington’s and Prion disease. The neurodegenerative disease of focus in this research is Spinocerebellar Ataxia Type 1 (SCA1). SCA1 is a polyglutamine-repeat disease and the interaction of the disease protein ataxin-1 with 14-3-3 proteins leads to the toxic accumulation and subsequent protein aggregation which is characteristic of this disease. This study focused on attempting to elucidate the structure of various domains of the disease protein and also in identifying potential inhibitors of this deleterious interaction. Unfortunately, structural studies were not successful due to a number of caveats encountered in the expression and purification of the ataxin-1 protein domains. By utilising computational methods and small molecule inhibitors, a number of potential lead compounds which possess the ability to at least partly disrupt the interaction of 14- 3-3ζ have been identified. As 14-3-3 proteins play roles in other neurodegenerative diseases, successful identification of potential drug lead treatments can have far reaching benefits in a number of neurodegenerative diseases including SCA1. Lipid rafts are also involved in neurodegenerative disease pathology. Lipid rafts are cholesterol and sphingolipid rich domains which organise the plasma membrane into discrete microdomains and act as signalling platforms and processing centres which attach specific proteins and lipids. A number of disease proteins are processed at these membrane regions, including those involved in Alzheimer’s, Parkinson’s and Prion disease. This processing is a step which is critical in the pathology of disease and abnormal processing leads to the formation of toxic protein aggregates. Previous research in the lab identified the association of low levels of the five main brain isoforms of 14-3-3 proteins with rafts. This study expanded on this to positively identify the presence of the two phospho-forms of 14-3-3, α and δ. The mechanism by which 14-3-3 proteins associate with rafts was also investigated, indicating that 14-3-3 associates with rafts via an unidentified raftbound protein(s). In addition, the phosphorylation status and quaternary structure of 14-3-3 in the presence of sphingolipids has been explored.
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Cell cycle checkpoints in Caenorhabditis elegans: the 14-3-3 gene par-5 is required for germline development and DNA damage response / Checkpoints del ciclo celular en Caenorhabditis elegans: el gen 14-3-3, par-5, es necesario para el desarrollo y respuesta al daño genómico de la línea germinalAristizábal Corrales, David 13 June 2012 (has links)
14-3-3 proteins have been extensively studied from yeast to mammals, and are associated with multiple roles ranging from fundamental processes such as cell cycle, apoptosis and stress response to diseases such as neurodegeneration and cancer. Indeed, 14-3-3 proteins have been suggested as possible therapeutic targets in cancer treatment. There are seven 14-3-3 genes in mammals, whereas there are only two in Caenorhabditis elegans, ftt-2 and par-5. The ftt-2 gene is expressed only in somatic lineages, whereas par-5 expression is detected in both soma and germline. Although it is known that par-5 inactivation results in sterility, the role of this gene in germline development is poorly characterized. In the present study, we use a par-5 mutation and RNA interference to characterize par-5 functions in the germline. The lack of par-5 in germ cells causes cell cycle deregulation, the accumulation of endogenous DNA damage and genomic instability. Moreover, par-5 is required for checkpoint-induced cell cycle arrest in response to DNA-damaging agents. We propose a model whereby PAR-5 regulates CDK-1 phosphorylation to prevent premature mitotic entry. Even though mammalian 14-3-3 homologs have diverged into seven genes, we verified that the basic functions of 14-3-3 in cell cycle control have been conserved in C. elegans. Therefore, this study opens a new path to investigate molecular mechanisms of 14-3-3 proteins and establishes C. elegans as a suitable system to screen for genes (RNAi libraries or mutagenesis), and drugs which can modify 14-3-3 functions. / Las proteínas 14-3-3 han sido ampliamente estudiadas desde levadura hasta mamíferos y han sido asociadas con múltiples roles en procesos como ciclo celular, apoptosis y la respuesta al estrés. Así mismo estas proteínas se han visto involucradas en enfermedades neurodegenerativas y cáncer. De hecho, las proteínas 14-3-3 han sido propuestas como posibles agentes terapéuticos en el tratamiento contra el cáncer. En mamíferos existen 7 genes que codifican para proteínas 14-3-3, mientras en Caenorhabditis elegans solo hay dos, ftt-2 and par-5. El gen ftt-2 sólo es expresado en células somáticas, mientras par-5 se expresa tanto en células somáticas como en la línea germinal. Aunque se sabe que la inactivación de par-5 puede producir esterilidad, el rol de este gen en el desarrollo de la línea germinal no ha sido caracterizado. En este estudio, se usó una mutación de par-5 y RNA interferente para caracterizar la función de par-5 en la línea germinal. La falta de par-5 en la línea germinal causa una desregulación del ciclo celular, acumulación de daño genómico e inestabilidad genómica. Además, par-5 es requerido para el arresto celular inducido por el checkpoint en respuesta a los agentes que dañan el genoma. A partir de los resultados obtenidos, se propone un modelo según el cual PAR-5 regula la fosforilación de CDK-1 para prevenir la entrada prematura en mitosis. Aunque los homólogos de 14-3-3 en humanos han divergido en 7 genes, este estudio permitió verificar que las funciones básicas de las proteínas 14-3-3 en el control ciclo celular están conservadas en C. elegans. Por lo tanto, este estudio abre un nuevo camino para estudiar las funciones moleculares de las proteínas 14-3-3 y establece C. elegans como un modelo adecuado para la búsqueda de genes y/o drogas que modifiquen la función de las proteínas 14-3-3.
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Exoenzyme S of Pseudomonas aeruginosa : cellular targets and interaction with 14-3-3 /Yasmin, Lubna, January 2007 (has links)
Diss. (sammanfattning) Umeå : Univ., 2007. / Härtill 4 uppsatser.
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Host-parasite interactions in the dissemination of Toxoplasma gondiiKanatani, Sachie January 2017 (has links)
Toxoplasma gondii is an obligate intracellular parasite that infects virtually all warm-blooded organisms. Systemic dissemination of T. gondii in the organism can cause life-threatening infection that manifests as Toxoplasma encephalitis in immune-compromised patients. In addition, mounting evidence from epidemiological studies indicates a link between chronic Toxoplasma infection and mental disorders. To better understand the pathogenesis of toxoplasmosis, basic knowledge on the host-parasite interactions and the dissemination mechanisms are essential. Previous findings have established that, upon infection with T. gondii, dendritic cells (DCs) and microglia exhibit enhanced migration, which was termed the hypermigratory phenotype. As a result of this enhanced migration, DCs and microglia are used as vehicle cells for dissemination (‘Trojan horse’) which potentiates dissemination of T. gondii in mice. However, the precise mechanisms behind the hypermigratory phenotype remained unknown. In this thesis, we characterized host-parasite interactions upon infection with T. gondii and investigated the basic mechanisms behind the hypermigratory phenotype of T. gondii-infected DCs and microglia. In paper I, we observed that upon infection with T. gondii, DCs underwent rapid morphological changes such as loss of adhesiveness and podosomes, with integrin redistribution. These rapid morphological changes were linked to hypermotility and were induced by active invasion of T. gondii within minutes. T. gondii-infected DCs exhibited up-regulation of the C-C chemokine receptor CCR7 and chemotaxis towards the CCR7 chemotactic cue, CCL19. In paper II, we developed a 3-dimensional migration assay in a collagen matrix, which allowed us to characterize the hypermigratory phenotype in a more in vivo-like environment. The migration of T. gondii-infected DCs exhibited features consistent with integrin-independent amoeboid type of migration. T. gondii-induced hypermigration of DCs was further potentiated in the presence of CCL19 in a 3D migration assay. In paper III, we identified a parasite effector molecule, a Tg14-3-3 protein derived from parasite secretory organelles. Tg14-3-3 was sufficient to induce the hypermigratory phenotype. Transfection with Tg14-3-3-containing fractions or recombinant Tg14-3-3 protein induced the hypermigratory phenotype in primary DCs and in a microglial cell line. In addition, Tg14-3-3 localized in the parasitophorous vacuolar space and host 14-3-3 proteins were rapidly recruited around the parasitophorous vacuole. In paper IV, we found that mouse DCs dominantly express the L-type voltage-dependent calcium channel, Cav1.3. Cav1.3 was linked to the GABAergic signaling-induced hypermigratory phenotype. Pharmacological inhibition of Cav1.3 and knockdown of Cav1.3 abolished the hypermigratory phenotype in T. gondii infected DCs. Blockade of voltage-dependent calcium channels reduced the dissemination of T. gondii in a mouse model. In paper V, we showed that microglia, resident immune cells in the brain, also exhibited rapid morphological changes and hypermotility upon infection with T. gondii. However, an alternative GABA synthesis pathway was shown to be involved in the hypermigratory phenotype in microglia. In summary, this thesis describes novel host-parasite interactions, including host cell migratory responses and key molecular mechanisms that mediate the hypermigratory phenotype. The findings define a novel motility-related signaling axis in DCs. Thus, T. gondii employs GABAergic non-canonical pathways to hijack host cell migration and facilitate dissemination. We believe that these findings represent a significant step forward towards a better understanding of the pathogenesis of T. gondii infection. / <p>At the time of the doctoral defense, the following papers were unpublished and had a status as follows: Paper 4: Manuscript. Paper 5: Manuscript.</p>
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Phospholamban - Identification of novel interaction partnersKownatzki-Danger, Daniel 03 June 2021 (has links)
No description available.
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Componentes genéticos que afetam a via de direcionamento de proteínas organelares em Arabidopsis thaliana / Genetic components affecting organelar protein targeting in Arabidopsis thalianaSpoladore, Larissa 18 April 2016 (has links)
Nos eucariotos, a evolução dos sistemas de transporte molecular foi essencial pois seu alto grau de compartimentalização requer mecanismos com maior especificidade para a localização de proteínas. Com o estabelecimento das mitocôndrias e plastídeos como organelas da célula eucariota, grande parte dos genes específicos para sua atividade e manutenção foram transferidos ao núcleo. Após a transferência gênica, a maioria das proteínas passaram a ser codificadas pelo núcleo, sintetizadas no citosol e direcionadas às organelas por uma maquinaria complexa que envolve receptores nas membranas das organelas, sequências de direcionamento nas proteínas e proteínas citossólicas que auxiliam o transporte. A importação depende em grande parte de uma sequência na região N-terminal das proteínas que contém sinais reconhecidos pelas membranas organelares. No entanto, muito ainda não é compreendido sobre o transporte de proteínas organelares e fatores ainda desconhecidos podem influenciar o direcionamento sub-celular. O objetivo deste trabalho foi a caracterização da General Regulatory Factor 9 (GRF9), uma proteína da família 14-3-3 de Arabidopsis thaliana potencialmente envolvida no direcionamento de proteínas organelares, e a geração de um genótipo para ser utilizado na obtenção de uma população mutante para genes que afetam o direcionamento da proteína Tiamina Monofosfato Sintetase (TH-1). Após experimentos in vivo e in planta, foi observado que GRF9 interage com as proteínas duplo-direcionadas Mercaptopyruvate Sulfurtransferase1 (MST1) e a Thiazole Biosynthetic Enzyme (THI1), e com a proteína direcionada aos cloroplastos TH-1. Experimentos de deleção e interação in vivo mostraram que a região Box1 de GRF9 é essencial para a interação com THI1 e MST1. Com a finalidade de dar continuidade a caracterização da GRF9 e para realização de testes com relação a sua função no direcionamento de proteínas organelares foi gerada uma linhagem homozigota que superexpressa GRF9. Plantas expressando o transgene TH-1 fusionado a Green Fluorescent Protein (GFP) em genótipo deficiente na TH-1 (CS3469/TH-1-GFP) foram obtidas para a geração de população mutante que possibilitará a descoberta de componentes genéticos ainda desconhecidos e responsáveis pelo direcionamento de proteínas aos cloroplastos. / In Eukaryotes, the evolution of molecular transport in the cell was essential due to their increase in compartmentalization, which requires more specific mechanisms for the correct localization of proteins. With the establishment of mitochondria and plastids as organelles, a great number of their genes, either specific for their metabolic functions or maintenance of their own transcription/translation processes, were transferred to the nucleus of the cell. These transfers caused most of the organellar proteins to be coded by the nucleus, then synthesized in the cytosol and targeted to the organelles by a complex machinery which involves membrane receptors in the organelles, targeting sequences in the proteins, and cytosolic proteins which assist them with the transport. Protein import depends greatly on an N-terminal sequence in proteins which has recognizable signals for the organellar membrane receptors. However, much is still not understood about the transport of organellar proteins, and unknown factors may still influence subcellular targeting. The goal of this work was the characterization of General Regulatory Factor 9 (GRF9), a protein of the 14-3-3 family in Arabidopsis thaliana potentially involved in the targeting of organellar proteins, and generating a genotype to be used in obtaining a mutant population for genes affecting the targeting of the protein Thiamine Requiring 1 (TH-1). After in vivo and in planta experiments it was observed that GRF9 interacts with the dual-targeted proteins Mercaptopyruvate Sulfurtransferase1 (MST1) and Thiazole Biosynthetic Enzyme (THI1), and with the chloroplast targeted protein TH-1. Deletion experiments followed by in vivo interaction assays showed that Box 1 region of GRF9 is essential for the interaction with THI1 and MST1. For the continuing characterization of GRF9 and for following tests of its function in the targeting of organellar proteins, a homozygous line was generated overexpressing GRF9. Plants expressing the transgene TH-1 fused to the Green Fluorescent Protein (GFP) in a TH-1 deficient genotype (CS3469/TH-1-GFP) were obtained for the generation of a mutant population which will allow the discovery of genetic components still unknown responsible for targeting proteins to the chloroplasts.
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Componentes genéticos que afetam a via de direcionamento de proteínas organelares em Arabidopsis thaliana / Genetic components affecting organelar protein targeting in Arabidopsis thalianaLarissa Spoladore 18 April 2016 (has links)
Nos eucariotos, a evolução dos sistemas de transporte molecular foi essencial pois seu alto grau de compartimentalização requer mecanismos com maior especificidade para a localização de proteínas. Com o estabelecimento das mitocôndrias e plastídeos como organelas da célula eucariota, grande parte dos genes específicos para sua atividade e manutenção foram transferidos ao núcleo. Após a transferência gênica, a maioria das proteínas passaram a ser codificadas pelo núcleo, sintetizadas no citosol e direcionadas às organelas por uma maquinaria complexa que envolve receptores nas membranas das organelas, sequências de direcionamento nas proteínas e proteínas citossólicas que auxiliam o transporte. A importação depende em grande parte de uma sequência na região N-terminal das proteínas que contém sinais reconhecidos pelas membranas organelares. No entanto, muito ainda não é compreendido sobre o transporte de proteínas organelares e fatores ainda desconhecidos podem influenciar o direcionamento sub-celular. O objetivo deste trabalho foi a caracterização da General Regulatory Factor 9 (GRF9), uma proteína da família 14-3-3 de Arabidopsis thaliana potencialmente envolvida no direcionamento de proteínas organelares, e a geração de um genótipo para ser utilizado na obtenção de uma população mutante para genes que afetam o direcionamento da proteína Tiamina Monofosfato Sintetase (TH-1). Após experimentos in vivo e in planta, foi observado que GRF9 interage com as proteínas duplo-direcionadas Mercaptopyruvate Sulfurtransferase1 (MST1) e a Thiazole Biosynthetic Enzyme (THI1), e com a proteína direcionada aos cloroplastos TH-1. Experimentos de deleção e interação in vivo mostraram que a região Box1 de GRF9 é essencial para a interação com THI1 e MST1. Com a finalidade de dar continuidade a caracterização da GRF9 e para realização de testes com relação a sua função no direcionamento de proteínas organelares foi gerada uma linhagem homozigota que superexpressa GRF9. Plantas expressando o transgene TH-1 fusionado a Green Fluorescent Protein (GFP) em genótipo deficiente na TH-1 (CS3469/TH-1-GFP) foram obtidas para a geração de população mutante que possibilitará a descoberta de componentes genéticos ainda desconhecidos e responsáveis pelo direcionamento de proteínas aos cloroplastos. / In Eukaryotes, the evolution of molecular transport in the cell was essential due to their increase in compartmentalization, which requires more specific mechanisms for the correct localization of proteins. With the establishment of mitochondria and plastids as organelles, a great number of their genes, either specific for their metabolic functions or maintenance of their own transcription/translation processes, were transferred to the nucleus of the cell. These transfers caused most of the organellar proteins to be coded by the nucleus, then synthesized in the cytosol and targeted to the organelles by a complex machinery which involves membrane receptors in the organelles, targeting sequences in the proteins, and cytosolic proteins which assist them with the transport. Protein import depends greatly on an N-terminal sequence in proteins which has recognizable signals for the organellar membrane receptors. However, much is still not understood about the transport of organellar proteins, and unknown factors may still influence subcellular targeting. The goal of this work was the characterization of General Regulatory Factor 9 (GRF9), a protein of the 14-3-3 family in Arabidopsis thaliana potentially involved in the targeting of organellar proteins, and generating a genotype to be used in obtaining a mutant population for genes affecting the targeting of the protein Thiamine Requiring 1 (TH-1). After in vivo and in planta experiments it was observed that GRF9 interacts with the dual-targeted proteins Mercaptopyruvate Sulfurtransferase1 (MST1) and Thiazole Biosynthetic Enzyme (THI1), and with the chloroplast targeted protein TH-1. Deletion experiments followed by in vivo interaction assays showed that Box 1 region of GRF9 is essential for the interaction with THI1 and MST1. For the continuing characterization of GRF9 and for following tests of its function in the targeting of organellar proteins, a homozygous line was generated overexpressing GRF9. Plants expressing the transgene TH-1 fused to the Green Fluorescent Protein (GFP) in a TH-1 deficient genotype (CS3469/TH-1-GFP) were obtained for the generation of a mutant population which will allow the discovery of genetic components still unknown responsible for targeting proteins to the chloroplasts.
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14-3-3ζ overexpression improves tolerance to acute and chronic cold exposure in male miceDiallo, Kadidia 08 1900 (has links)
La thermogenèse adaptative est un mécanisme de production de chaleur médié par les adipocytes bruns. En réponse au froid, ou à un stimulus adrénergique, les adipocytes blancs peuvent être convertis en adipocytes beiges lors d’un processus que l’on nomme le « beiging ». Contrairement aux adipocytes blancs, les adipocytes beiges et bruns expriment des taux élevés de la protéine de découplage 1 (UCP1) et dissipent l'énergie sous forme de chaleur grâce à l'oxydation des lipides. Il a été démontré chez les rongeurs que l’activation des adipocytes bruns et beiges entraîne une réduction significative du poids corporel et l’activation de ces adipocytes chez l’humain semble être un traitement prometteur contre l’obésité et le diabète. Nous avons précédemment identifié un rôle essentiel de la protéine d’échafaudage 14-3-3ζ dans l'adipogenèse, mais son rôle dans d'autres processus adipocytaires reste incertain. Une des premières fonctions identifiées de la 14-3-3ζ est sa capacité à réguler l'activité enzymatique de la tyrosine hydroxylase, indispensable à la production de norépinephrine pour la thermogenèse. Notre étude vise donc à déterminer si la 14-3-3ζ influence le développement et la fonction des adipocytes beiges et bruns.
Nos données montrent que la délétion d’un allèle du gène de la 14-3-3ζ n’affecte pas la tolérance au froid aiguë. Comparées aux souris de type sauvage (WT), les souris transgéniques mâles surexprimant la 14-3-3ζ (TAP) ont une meilleure tolérance au froid aiguë (3 heures, 4 °C) et chronique (3 jours, 4 °C). On observe chez les TAP une augmentation du beiging due à une élévation significative de l'ARNm et de la protéine UCP1 dans le tissu adipeux blanc inguinal (iWAT). Par ailleurs, les souris TAP présentent également une réduction significative de la conductance thermique lors d’exposition au froid leur permettant de mieux conserver la chaleur. Collectivement, nos résultats soulignent le rôle novateur de la 14-3-3ζ dans le beiging et nous permettent de mieux comprendre comment la thermogenèse adaptative est régulée. / Adaptive thermogenesis is a mechanism of heat production primarily mediated by brown fat. In some instances, cold exposure or adrenergic stimuli can convert white adipocytes into brown-like or beige adipocytes during a process termed “beiging”. Both beige and brown adipocytes express higher levels of uncoupling protein 1 (UCP1) and can release energy in the form of heat following lipid oxidation. The activation of these thermogenic adipocytes increases energy expenditure to reduce body weight in rodents, and it has been postulated to be a promising therapy for the treatment of obesity and diabetes. We previously identified an essential role of the molecular scaffold, 14-3-3ζ, in adipogenesis, but its roles in other adipocyte processes is uncertain. An early identified function of 14-3-3 was its ability to regulate the enzymatic activity of tyrosine hydroxylase, which is indispensable in the production of norepinephrine for thermogenesis. Thus, our study aims to investigate whether 14-3-3ζ influences the development and function of beige and brown adipocytes.
We report here that one allele deletion of the gene of 14-3-3ζ did not affect acute cold tolerance. On the other hand, transgenic overexpression of 14-3-3ζ in male mice (TAP) improves cold tolerance due to enhanced beiging with a remarkable increase in Ucp1 mRNA and protein in inguinal white adipose tissue (iWAT). Interestingly, beiging is increased in the TAP mice without any changes in sensitivity to beta-adrenergic stimuli, sympathetic innervation, or norepinephrine content being detected between WT and TAP mice. TAP mice also displayed significantly lower thermal conductance decreasing heat loss during the chronic cold challenge. Collectively, our results point to a novel role of 14-3-3ζ in beiging and increases our understanding of how adaptive thermogenesis is regulated.
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