Global ETD Search

21	Finding novel Neural Crest regulators : Pfkfb4, a key glycolysis partner, controls Neural Crest early patterning in Xenopus laevis / A la découverte de nouveaux régulateurs de la Crête Neurale : Pfkfb4, un régulateur de la glycolyse, contrôle aussi le développement précoce de la Crête Neurale chez l’amphibien. Pegoraro, Caterina 12 December 2012 (has links) La crête neurale (CN) est une population transitoire de cellules multipotentes qui émerge à la frontière entre l’ectoderme neural et non-neural, dans une région appelée la bordure neurale (BN). Lorsque la BN se soulève pour former le tube neural, les cellules de la CN subissent une transition épithélium-mésenchyme (TEM), et migrent de façon intensive dans l’ensemble de l’embryon pour atteindre leur destination finale et se différencier. Elles sont à l’origine de nombreux types de dérivés : neurones, cellules gliales, cartilage de la tête, os et tissus connectifs, cellules pigmentaires, cellules sympatho-adrenales. Tous ces processus sont régulés par l’action coordonnée de nombreux gènes qui forment un réseau de régulations génétiques complexe, au sein duquel de nombreuses interactions ont été décrites, même si de nombreuses relations restent à élucider à ce jour. Une mauvaise régulation de gènes normalement impliqués dans la formation de la CN provoque des malformations congénitales appelées neurocristopathies. Par ailleurs, la TEM subie par les cellules de CN avant leur migration est également observée dans les cellules cancéreuses acquérant des propriétés métastatiques. Les événements moléculaires et de nombreux gènes impliqués dans la TEM sont communs au développement de la CN et au cancer.Les liens existant entre le développement de la CN et les neurocristopathies, ainsi que les métastases, soulignent l’importance de l’étude du réseau de régulations génétiques permettant la formation de la CN et l’EMT.Au laboratoire, nous nous intéressons aux événements précoces d’induction et de spécification de la CN. Dans le but d’identifier les gènes préférentiellement impliqués dans le développement précoce de la CN et non dans la formation de l’ectoderme neural et non-neural, un crible a été effectué sur le transcriptome de différents tissus embryonnaires micro-disséqués. La validation des résultats de ce crible a permis d’identifier plusieurs gènes intéressants possédant une fonction potentielle dans la formation de la CN. Nous nous sommes particulièrement intéressés à deux d’entre eux, en raison de leur fonction originale comparée à la majorité des gènes impliqués dans le développement de la CN : serca1 et pfkfb4, un régulateur de l’homéostasie calcique et un régulateur de la glycolyse respectivement.Nous avons analysé les patrons d’expression des gènes des familles serca et pfkfb au cours du développement de Xenopus laevis. En raison de son expression spécifique dans la CN, nous avons étudié plus en détails le rôle de pfkfb4 dans la formation de la CN. Cette analyse a montré que pfkfb4 est nécessaire pour la spécification neurale et de la crête neurale.Toutefois, malgré son rôle documenté dans la glycolyse, le phénotype des morphants pfkfb4 dans l’embryon de Xenopus laevis n’est pas dû à une altération de la glycolyse.En conclusion, nos résultats démontrent l’existence d’un nouveau rôle non glycolytique pour Pfkfb4 au cours du développement embryonnaire de Xenopus Laevis. / Neural Crest (NC) is a transient population of multipotent cells that arises at the border between neural and non-neural ectoderm, in a region named the neural border (NB). As the neural border elevates to form the neural tube, NC cells undergo an Epithelial-To-Mesenchymal Transition (EMT), migrate extensively into the whole body to reach their final destinations and differentiate. They give rise to multiple derivatives: neurons and glia, head cartilage, bones and connective tissue, pigment cells, sympatho-adrenal cells. All these processes are regulated by the concerted actions of several genes that form a complex Gene Regulatory Network (GRN), in which many interactions have been elucidated, but even more relationships still need to be understood. Misregulation of genes normally involved in NC formation causes birth defects called neurocristopathies. Moreover, the EMT that NC cells undergo before migration also takes place when cancer cells become metastatic: the molecular events and many of the genes involved in EMT and migration are shared between NC development and cancer. The links with metastasis, neurocristopathies and the fact that still little is known about the earliest steps of NC formation, highlight the importance and the interest in understanding the Gene Regulatory Network (GRN) leading to NC formation and EMT.In the laboratory, we are interested in the early steps of NC induction and specification. In order to identify genes preferentially involved in early NC development compared to genes involved in neural and non-neural ectoderm formation, a transcriptome screen on different microdissected embryonic tissues has been performed. The validation of the results of the screen revealed several interesting genes with a potential function in NC formation. We focused particularly on two of them, due to their original function compared to the majority of the genes involved in NC development: serca1 and pfkfb4, a calcium homeostasis regulator and a glycolysis regulator respectively. We analysed the expression patterns of serca and pfkfb family genes during Xenopus laevis development. Then, due to its specific expression in NC, we studied more in details the role of pfkfb4 in NC formation. This analysis revealed that pfkfb4 is necessary for neural and neural crest specification. However, despite its known role in glycolysis, pfkfb4 morphant phenotype in Xenopus laevis embryos is not due to an alteration of the glycolytic pathway.In conclusion, our results reveal a novel extra-glycolytic role for Pfkfb4 during Xenopus laevis embryonic development. Crête Neurale Xénope Glycolyse Pfkfb4 Pfk1 Serca Métabolisme Plan d’organisation de l’embryon Neural Crest Xenopus Glycolysis Pfkfb4 Pfk1 Serca Metabolism Embryonic patterning.
22	Human muscle spindles : complex morphology and structural organisation Liu, Jing-Xia January 2004 (has links) Muscle spindles are skeletal muscle mechanoreceptors that mediate the stretch reflex and provide axial and limb position information to the central nervous system. They have been proposed to play a major role in the pathophysiology of muscle pain. Knowledge about the normal human muscle spindles is needed in order to understand their role in muscle disease or dysfunction. The aim of this study was to investigate the fiber content and MyHC composition of the muscle spindles in the human biceps brachii (BB) and deep muscles of the neck (DN); to determine whether there are age-related changes in human muscle spindles with respect to structure and MyHC composition; to investigate the distribution of SERCA isoforms and to evaluate whether there is a coordinated expression of SERCA and MyHC isoforms in intrafusal fibers. The myosin heavy chain (MyHC) content correlates to contraction velocity and force and the sarcoplasmic reticulum Ca2+ ATPase (SERCA) is a major determinant of muscle fiber relaxation velocity. Muscle specimens obtained from young and old subjects were serially sectioned and the pattern of distribution of different proteins along the length of the intrafusal fibers was revealed by immunocytochemistry. The MyHC content of single muscle spindles was assessed with SDS-PAGE and immunoblots. There were clear differences between BB and DN with regard to the morphology and MyHC composition of muscle spindles. Virtually each muscle spindle in the BB, but not in the DN, had a unique allotment of numbers of bag1, bag2 and chain fibers. In DN, a number of muscle spindles lacked either bag1 or bag2 fibers. Four major MyHC isoforms (MyHCI, IIa, α-cardiac and intrafusal) were detected by SDS-PAGE. In both BB and DN, immunocytochemistry revealed co-expression of several MyHC isoforms in each intrafusal fiber and regional heterogeneity. Both nuclear bag1 and bag2 fibers contained slow tonic MyHC uniformly and MyHCI, α-cardiac, embryonic and fetal with regional variations. Nuclear chain fibers contained MyHCIIa, embryonic and fetal and in the BB also MyHCIIx. The total number of intrafusal fibers per spindle decreased significantly with aging, due to a significant reduction in the number of nuclear chain fibers. The patterns of MyHC expression were also affected by aging. The bag1 fibers predominantly contained both SERCA isoforms in the encapsulated region. The bag2 fibers were more heterogeneous in their SERCA composition and 16-27% of them lacked both isoforms. Chain fibers contained SERCA1. There was a poor correlation between the MyHC and SERCA isoforms in nuclear bag fibers, whereas a strong correlation existed between MyHCIIa and SERCA1 in the nuclear chain fibers. Human muscle spindles, each being unique, proved to be more complex than anticipated. The clear differences shown between the BB and DN muscle spindles suggest functional specialization in the control of movement among different human muscles. Aging apparently had profound effects on intrafusal fiber content and MyHC composition. The age-related changes in muscle spindle phenotype may reflect deterioration in sensory and motor innervation and are likely to have a detrimental impact on motor control in the elderly. human muscle spindle intrafusal fiber aging biceps brachii deep muscles of the neck MyHC mATPase SERCA
23	Examining the role of the adenosine monophosphate-activated protein kinase α2 (AMPKα2) subunit on sarcoplasmic reticulum calcium-ATPase (SERCA) expression and function in sedentary and exercise-trained mice. Morissette, Marc 03 April 2013 (has links) This thesis determined whether changes in adenosine monophosphate-activated protein kinase (AMPK) activity would influence sarcoplasmic reticulum Ca2+-ATPase (SERCA) content and function in left ventricle (LV) and skeletal muscle isolated from sedentary or exercise trained mice. The data indicate that AMPKα2 kinase dead transgenic (KD) mice, as compared to wild-type (WT) mice, were characterized by reduced SERCA1a, SERCA2a and higher phospholamban (PLN) protein levels in both cardiac and skeletal muscle. Notably, exercise-training up-regulated myocardial SERCA2a protein content by 43%, as compared to sedentary WT mice. In contrast, exercise-training did not alter myocardial SERCA2a protein content in KD mice. Even so, exercise-training up-regulated SERCA1a protein content in skeletal muscle in both WT and KD mice. Based on these data, it appears that an AMPKα2-mediated mechanism influences SERCA2a content and function in the heart and skeletal muscle, which may contribute to the pathophysiology of models characterized by impaired AMPK activity and impaired calcium-cycling. physiology kinesiology AMPK AMPKα2 SERCA SERCA1a SERCA2a exercise exercise-training skeletal muscle cardiac muscle fiber-type
24	Human extraocular muscles : molecular diversity of a unique muscle allotype Kjellgren, Daniel January 2004 (has links) Introduction: The extraocular muscles (EOMs) are considered a separate class of skeletal muscle, allotype. Myosin is the major contractile protein in muscle. The myosin heavy chain (MyHC) isoforms are the best molecular markers of functional heterogeneity of muscle fibers. The relaxation rate, reflects the rate at which Ca2+ is transported back into the sarcoplasmic reticulum (SR) mostly by SR Ca2+ATPase (SERCA). Myosin binding protein C (MyBP-C), plays a physiological role in regulating contraction. The laminins (Ln) are the major non-collagenous components of the basement membrane (BM) surrounding muscle fibers and are important for muscle fiber integrity. Methods: Adult human EOMs were studied with SDS-PAGE, immunoblots and immunocytochemistry, the latter with antibodies against six MyHC, 2 SERCA, 2 MyBP-C and 8 laminin chain isoforms. The capillary density was also determined. Results: Most fibers contained a mixture of MyHC isoforms. Three major groups of fibers could be distinguished. Fast fibers that stained with anti-MyHCIIa, slow fibers that stained with anti-MyHCI and MyHCeompos/MyHCIIaneg-fibers that stained with neither of these antibodies but with anti-MyHCI+IIa+eom and anti-MyHCeom. A majority of the fibers contained both SERCA1 and 2 whereas 1% were unstained with both antibodies. Biochemically SERCA2 was more abundant than SERCA1. MyBP-Cfast was not present in the EOMs and MyBP-Cslow was only detected immunocytochemically. The extrasynaptical BM of the EOM muscle fibers contained Lna2, b1, b2, g1, a4 and a5 chains. The capillary density in the EOMs was very high (1050 +/-190 capillaries/mm2) and significantly (p<0.05) higher in the orbital than in the global layer. Conclusions: The co-existence of complex mixtures of several crucial protein isoforms provide the human EOMs with a unique molecular portfolio that a) allows a highly specific fine-tuning regime of contraction and relaxation, and b) imparts structural properties that are likely to contribute to protection against certain neuromuscular diseases. Ophtalmology extraocular muscle myosin protein c laminin serca immunocytochemistry human Oftalmiatrik Ophtalmology Oftalmologi
25	Examining the role of the adenosine monophosphate-activated protein kinase α2 (AMPKα2) subunit on sarcoplasmic reticulum calcium-ATPase (SERCA) expression and function in sedentary and exercise-trained mice. Morissette, Marc 03 April 2013 (has links) This thesis determined whether changes in adenosine monophosphate-activated protein kinase (AMPK) activity would influence sarcoplasmic reticulum Ca2+-ATPase (SERCA) content and function in left ventricle (LV) and skeletal muscle isolated from sedentary or exercise trained mice. The data indicate that AMPKα2 kinase dead transgenic (KD) mice, as compared to wild-type (WT) mice, were characterized by reduced SERCA1a, SERCA2a and higher phospholamban (PLN) protein levels in both cardiac and skeletal muscle. Notably, exercise-training up-regulated myocardial SERCA2a protein content by 43%, as compared to sedentary WT mice. In contrast, exercise-training did not alter myocardial SERCA2a protein content in KD mice. Even so, exercise-training up-regulated SERCA1a protein content in skeletal muscle in both WT and KD mice. Based on these data, it appears that an AMPKα2-mediated mechanism influences SERCA2a content and function in the heart and skeletal muscle, which may contribute to the pathophysiology of models characterized by impaired AMPK activity and impaired calcium-cycling. physiology kinesiology AMPK AMPKα2 SERCA SERCA1a SERCA2a exercise exercise-training skeletal muscle cardiac muscle fiber-type
26	ATP Dynamics in Pancreatic α- and β-cells Li, Jia January 2014 (has links) Glucose metabolism in pancreatic α- and β-cells is believed to regulate secretion of glucagon and insulin, respectively. In β-cells, ATP links glucose metabolism to electrical activity and insulin secretion. In α-cells, ATP has been attributed various roles in glucose-regulated glucagon release, but the underlying mechanisms are poorly understood. Despite its importance in insulin and glucagon secretion little is known about ATP kinetics in α- and β-cells. In this thesis, the novel fluorescent ATP biosensor Perceval was used to monitor physiologically relevant ATP concentrations with little influence of ADP. Glucose stimulation of β-cells within mouse and human pancreatic islets induced pronounced rise of ATP with superimposed oscillations. Simultaneous measurements of the sub-plasma membrane ATP and Ca2+ concentrations revealed glucose-induced oscillations in opposite phase. ATP increased further and the oscillations ceased when voltage-dependent Ca2+ influx was prevented. In contrast, ATP promptly decreased in response to K+-depolarization-induced elevation of Ca2+. Also mobilization of Ca2+ from intracellular stores lowered ATP, but the negative effect was not due to increased ATP consumption by the sarco/endoplasmic reticulum Ca2+-ATPase. Store-operated Ca2+ entry alone had little effect but markedly elevated ATP when combined with muscarinic receptor activation. When comparing ATP and Ca2+ responses in α- and β-cells within the same islet, glucose-induced ATP generation was much less pronounced and the dose-response relationship left-shifted in the α-cells. At basal glucose, individual α-cells showed Ca2+ and concomitant ATP oscillations in opposite-phase with variable frequency. These oscillations largely cancelled out when averaging data from several α-cells. At high glucose, the Ca2+ and ATP oscillations in α-cells tended to synchronize with the corresponding β-cell oscillations. Since β-cell Ca2+ oscillations drive pulsatile insulin secretion, which is antiparallel to pulsatile glucagon secretion, there seems to be an inverse relationship between changes in α-cell Ca2+ and glucagon release. This paradox is attributed to paracrine inhibition overriding Ca2+ stimulation, since somatostatin receptor blockade potently stimulated glucagon release with little effect on α-cell Ca2+ signalling. The data indicate that complex ATP-Ca2+ interactions in α- and β-cells underlie cell-intrinsic regulation of glucagon and insulin secretion and that paracrine inhibition of glucagon release becomes important in hyperglycaemia. ATP Ca2+ β-cell α-cell SERCA SOCE muscarinic receptor insulin secretion glucagon secretion
27	Contextual Induction of Non-Shivering Thermogenesis and Skeletal Muscle Futile Calcium Cycling in Two Rat Models Heemstra, Lydia A. 27 July 2021 (has links) No description available. Biology Sarcolipin SERCA calcium cycling muscle thermogenesis non-shivering thermogenesis obesity calcium
28	Investigating the molecular mechanism of phospholamban regulation of the Ca²-pump of cardiac sarcoplasmic reticulum Akin, Brandy Lee 16 March 2011 (has links) Indiana University-Purdue University Indianapolis (IUPUI) / The Ca2+ pump or Ca2+-ATPase of cardiac sarcoplasmic reticulum, SERCA2a, is regulated by phospholamban (PLB), a small inhibitory phosphoprotein that decreases the apparent Ca2+ affinity of the enzyme. We propose that PLB decreases Ca2+ affinity by stabilizing the Ca2+-free, E2·ATP state of the enzyme, thus blocking the transition to E1, the high Ca2+ affinity state required for Ca2+ binding and ATP hydrolysis. The purpose of this dissertation research is to critically evaluate this idea using series of cross-linkable PLB mutants of increasing inhibitory strength (N30C-PLB < PLB3 < PLB4). Three hypotheses were tested; each specifically designed to address a fundamental point in the mechanism of PLB action. Hypothesis 1: SERCA2a with PLB bound is catalytically inactive. The catalytic activity of SERCA2a irreversibly cross-linked to PLB (PLB/SER) was assessed. Ca2+-ATPase activity, and formation of the phosphorylated intermediates were all completely inhibited. Thus, PLB/SER is entirely catalytically inactive. Hypothesis 2: PLB decreases the Ca2+ affinity of SERCA2a by competing with Ca2+ for binding to SERCA2a. The functional effects of N30C-PLB, PLB3, and PLB4 on Ca2+-ATPase activity and phosphoenzyme formation were measured, and correlated with their binding interactions with SERCA2a measured by chemical cross-linking. Successively higher Ca2+ concentrations were required to both activate the enzyme co-expressed with N30C-PLB, PLB3, and PLB4 and to dissociate N30C-PLB, PLB3, and PLB4 from SERCA2a, suggesting competition between PLB and Ca2+ for binding to SERCA2a. This was confirmed with the Ca2+ pump mutant, D351A, which is catalytically inactive but retains strong Ca2+ binding. Increasingly higher Ca2+ concentrations were also required to dissociate N30C-PLB, PLB3, and PLB4 from D351A, demonstrating directly that PLB competes with Ca2+ for binding to the Ca2+ pump. Hypothesis 3: PLB binds exclusively to the Ca2+-free E2 state with bound nucleotide (E2·ATP). Thapsigargin, vanadate, and nucleotide effects on PLB cross-linking to SERCA2a were determined. All three PLB mutants bound preferentially to E2 state with bound nucleotide (E2·ATP), and not at all to the thapsigargin or vanadate bound states. We conclude that PLB inhibits SERCA2a activity by stabilizing a unique E2·ATP conformation that cannot bind Ca2+. Ca-ATPase SERCA phospholamban calcium sarcoplasmic reticulum Phosphoproteins Sarcoplasmic reticulum Calcium
29	Cardiovascular Complications of Ischemic Renal Disease: The Effect of Renal Dysfunction on Cardiac Disease and the Central Role of Cardiotonic Steroids in the Pathogenesis of Uremic Cardiomyopathy Kennedy, David Joseph 17 April 2006 (has links) No description available. Renal Failure Cardiomyopathy Reactive Oxygen species Cardiotonic Steroids
30	Regulation of the Sarco-endoplasmic Reticulum Calcium ATPase by Sarcolipin Shaikh, Sana Ashfaque 21 May 2015 (has links) No description available. Biochemistry Physiology SERCA Sarcolipin Phospholamban Calcium Transport Membrane Proteins Protein Interaction

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