Global ETD Search

141	Reconditionnement musculaire dans un modèle murin de myopathie centronucléaire autosomique dominante par inactivation du gène myostatine / Targeting myostatin to combat autosomal dominant centronuclear myopathy Arnould, David 02 May 2018 (has links) La myopathie centronucléaire autosomique dominante (MCN-AD) est une maladie congénitale rare liée à des mutations principalement retrouvées dans le gène dynamine-2. La majorité des patients atteints de MCN-AD présente une évolution lentement progressive, avec une perte de masse et de force musculaire. A ce jour, aucune thérapie n’est disponible pour la MCN-AD. Des interventions thérapeutiques visant à limiter la progression et la sévérité de l’atteinte musculaire ainsi qu’à améliorer la qualité de vie des patients, sont donc nécessaires. Nous faisons l’hypothèse qu’une hypertrophie induite par l’invalidation de la myostatine (mstn), régulateur négatif majeur de la masse musculaire, pourrait être bénéfique pour la souris modèle de cette pathologie (KI-Dnm2R465W/+), permettant notamment le maintien de la masse et de la force musculaire. Nous avons généré un modèle doublement muté résultant du croisement de souris KI-Dnm2R465W/+ myopathe avec des souris KO-mstn hypermusclées. Notre étude démontre que l'inactivation du gène mstn permet une amélioration de la masse et du volume musculaire, limite la perte de force et de motricité. Nos données suggèrent également que cette amélioration est majoritairement due à une diminution du niveau d’expression de certains acteurs impliqués dans le système catabolique ubiquitine-protéasome. De plus, nous montrons une accélèration de la diminution de la fréquence des anomalies histologiques caractéristiques de la myopathie chez les souris KI-Dnm2R465W/+. Nous proposons que ces anomalies pourraient être dues à une altération de la structure et/ou de la fonction mitochondriale. / Autosomal dominant centronuclear myopathy (AD-CNM) is a rare congenital muscle disease caused by mutations predominantly found in the dynamin 2 gene (DNM2). The clinical features generally reported are progressive muscle atrophy and weakness. To date, no treatment is available. The mouse model for AD-CNM harboring a mutation of the dynamin-2 gene (KI-Dnm2R465W/+) reproduces some of the human clinical features, notably muscle atrophy and weakness. Mstn, is a master negative regulator of skeletal muscle mass. We hypothesized that inactivation of mstn could limit muscle atrophy and weakness reported in the AD-CNM mouse model (KI-dnm2R465W/+). To test this hypothesis, we intercrossed KI-Dnm2R465W/+ mice with mice inactivated for mstn (KO-mstn) to generate a double mutated lineage (KIKO). The present study demonstrates that mstn gene inactivation allows for an improvement of muscle weight and volume, prevents muscle weakness and motor skill alterations. Our data also reveal that inactivation of mstn essentially downregulates some actors implicated in the catabolic ubiquitin-proteasome system. Furthermore, we show that inactivation of mstn decreases the frequency of of histological abnormalities characteristical in KI mice. We hypothesize that these abnormalities could be due to an alteration of mitochondrial function and network. The perspective to this work is to verify this hypothesis in the mouse model, which will contribute to a better understanding of the physiopathological mechanisms and can open new insight in the therapeutical approach to AD-CNM. Atrophie musculaire Faiblesse musculaire MCN-AD Dynamine-2 Myostatine Hypertrophie musculaire Souris Muscular atrophy Muscular weakness AD-CNM Dynamin 2 Myostatin Muscular hypertrophy Mouse
142	Estudo do envolvimento da neuraminidase 1 no processo de autofagia na musculatura esquelética / Larina Neto R. Neuraminidase 1 involvement in the autophagy process in the skeletal muscles Larina Neto, Rubens de 18 July 2019 (has links) INTRODUÇÃO:A neuraminidase 1 (chamada a seguir por Neu1) regula o catabolismo de sialoglicoconjugados nos lisossomos. A deficiência congênita da Neu1 é a base da sialidose, doença neurossomática grave associada a deformidades osteoesqueléticas, hipotonia e fraqueza muscular. Camundongos com deficiência de Neu1 desenvolvem uma forma atípica de degeneração muscular caracterizada porproliferação anormal de fibroblastoslevando a invasão nas fibras musculares, expansão da matriz extracelular (MEC), fragmentação do citoplasma, formação vacuolar e atrofia muscular. A ocorrência de atrofia muscular indica que a deficiência da Neu1 podeestar relacionada com o controle da massa muscular, a qual é dependente do equilíbrio entre síntese e degradação proteica.Uma característica principalnaMacroautofagia (denominada a seguir por autofagia) é a principal via de degradação intracelular sendo expressamente essencial para a homeostase celular e remoção de materiais citoplasmáticos. Objetivos: Avaliarseos efeitos da deficiência da Neuraminidase 1 afetama indução de autofagia e a formação de autofagossomos e determinar os efeitos do bloqueio da função lisossomal sobre o fenótipo muscular na deficiência da Neuraminidase1.Metodologia:Camundongos Neu1+/-foram cruzados e os filhotes genotipados, onde camundongos Neu1-/-(nocaute) e Neu1+/+(normal),foram utilizados no estudon total=90, sendo 10 em padronizações, 20 para coleta de fibroblastos e 60 para procedimentos in vivo, os grupos experimentais foram divididos em privação alimentar por 2 dias que, por meio da inibição do mTOR, induz a autofagia;grupo detratamento com Colchicina por 4 dias onde irá impedir a junção autofagossomo/lisossomonão havendo a degradaçãolisossomaleadicionado nos dois últimos dias de privação alimentar e o grupo de tratamento comRapamicina por 7 dias, droga com função de inibir seletivamente o mTOR.Após os tratamentos, os animais foram eutanasiadospara coleta dos músculos gastrocnêmios e tibiais anterior. Os músculos foram analisados apósas coloraçõeshistológicas porHematoxilina & Eosina e Fosfatase Ácida; Imunofluorescência de LC3-I/II; Western Blottingdas proteínas LC3-I/II, Lamp-1 e p62/SQSTM e a análise Ultra-estrutural. Além disso, foi realizada cultura de fibroblastos, os quais foram submetidos à privação de nutrientes e ao tratamento com Rapamicina, seguidos dasmesmas metodologias de análise invivo. Resultados:As análises histológicas através de H&E e Fosfatase Ácida não revelaram alterações consistentes na musculatura esquelética de animais submetidos aos tratamentos, mostrando em animais com deficiência de Neu1 um aumento anormal do espaço endomisial, e aumento da atividade lisossomalintracitoplasmáticos. Na análise ultra-estruturalobservou-se em todos os grupos, a presença de diversas estruturas com aspecto autofágico, de diferentes tamanhos, formas e constituintes. Naanálise da expressão do LC3 através de Western Blottingmostrou importante ativação do LC3-II na privação alimentar (com e sem administração de Colchicina) tanto em animais controles quanto em animais com deficiência de Neu1 e uma importante ativação do LC3-I em Rapamicina em ambos os grupos mostrando assim que houve um aumento da via da autofagia através do bloqueio do mTOR. Já na análise de Imunofluorescência não foi possível observar diferença consistenteentre os grupos.A análise in vitrode Western Blottingmostrou que tal ativação foi similar entre fibroblastos Neu1+/+e Neu1-/-. Conclusão:Os experimentos relacionados com a ativação ou inibição da autofagia, não resultaram em diferenças consideráveis entre músculos normais e músculos com deficiência de Neu1. Desta forma, podemos concluir com estes experimentos que aparentemente a Neu1, apesar de ser uma importante enzima lisossomal, não interfere com o processo de autofagia / Introduction:Neuraminidase 1 (hereinafter Neu1) regulates the catabolism of sialoglycoconjugates in lysosomes. The congenital deficiency of Neu1 is the basis of sialidosis, a severe neurosomatic disease associated with osteo-skeletal deformities, hypotonia, and muscle weakness. Mice with Neu1deficient develop an atypical form of muscle degeneration characterized by abnormal fibroblast proliferation leading to muscle fiber invasion, extracellular matrix expansion (ECM), cytoplasm fragmentation, vacuolar formation, and muscle atrophy. The occurrence of muscle atrophy indicates that deficiencyofNeu1 may be related to the control of muscle mass, which is dependent on the balance between synthesis and protein degradation. A major feature in Macroautophagy (hereinafter referred to as autophagy) is the main pathway of intracellular degradation being expressly essential for cellular homeostasis and removal of cytoplasmic materials. Objectives:To evaluate whether the effects of neuraminidase 1 deficiency affect autophagy induction and autophagosome formation and to determine the effects of lysosomal function block on muscle phenotype in neuraminidase 1 deficiency. Methodos:Mice Neu1+/-were crossbred and the genotyped pups, where mice Neu1-/-(knockout) and Neu1+/+(normal), were used in the study ntotal = 90, 10 for standardization, 20 for fibroblast collection and 60 for in vivo procedures, experimental groups were divided into food deprivation for 2 days that, through mTOR inhibition, induces autophagy; Colchicine treatment group for 4 days whereit will prevent autophagosome/lysosome junction without lysosomal degradation and added in the last two days of food deprivation and Rapamycin treatment group for 7 days, drug with function to selectively inhibit mTOR. After the treatments, the animals were euthanized to collect the anterior gastrocnemius and tibial muscles. The muscles were analyzed after histological staining by Hematoxylin & Eosin and Acid Phosphatase; LC3-I/II immunofluorescence; Western Blottingof LC3-I/II, Lamp-1 and p62/SQSTM proteins and Ultra-structural analysis. In addition, fibroblasts were cultured and subjected to nutrient deprivation and Rapamycin treatment, followed by the same in vivo analysis methodologies. Results:Histological analyzes by H&E and Acid Phosphatase did notreveal consistent changes in skeletal muscle of animals submitted to treatments, showing in animals with Neu1 deficiency an abnormal increase in endomysial space and increased intracytoplasmic lysosomal activity.In ultrastructural analysis, it was observed in all groups, the presence of several structures with autophagic aspect, of different sizes, shapes and constituents. The analysis of LC3 expression by Western Blottingshowed important activation of LC3-II in food deprivation (with and without Colchicine administration) in both control and Neu1 deficient animals and an important activation of LC3-I in Rapamycininboth groups,thus showing an increase in the autophagy pathway through mTOR blockade. In the immunofluorescence analysis, it was not possible to observe consistent difference between the groups. In vitro Western Blottinganalysis showed that such activation was similar between Neu1+/+and Neu1-/-fibroblasts. Conclusion: Experiments related to activation or inhibition of autophagy did not result in considerable differencesbetween normal muscles and Neu1 deficient muscles. Thus, we can conclude from these experiments that apparently Neu1, despite being an important lysosomal enzyme, does not interfere with the autophagy process Atrofia muscular Autofagia Autophagy Colchicina Colchicine Exocitose lisossomal Food deprivation Lysosomal exocytosis Mucolipidases Mucolipidoses Muscular atrophy Neuraminidase Neuraminidase Privação de alimentos Sialidase Sialidosis Sirolimo Sirolimus
143	Identification of Novel Roles for the Survival Motor Neuron (Smn) Protein: Implications on Spinal Muscular Atrophy (SMA) Pathogenesis and Therapy Bowerman, Melissa 18 April 2012 (has links) Spinal muscular atrophy (SMA) is the leading genetic cause of death of young children. It is an autosomal recessive disease caused by the mutation and/or the deletion within the ubiquitously expressed survival motor neuron 1 (SMN1) gene. SMA pathology is characterized by spinal cord motor neuron degeneration, neuromuscular junction (NMJ) defects and muscular atrophy. Upon disease onset, SMA patients progressively become paralyzed and in the most severe cases, they die due to respiratory complications. Over the years, it has become clear that SMN is a multi-functional protein with important roles in small nuclear ribonucleoprotein (snRNP) assembly, RNA metabolism, axonal outgrowth and pathfinding, mRNA transport as well as in the functional development of NMJs, skeletal muscle and cardiac muscle. However, it remains unclear which of these functions, and the respective perturbed molecular pathways, dictate SMA pathogenesis. Here, we have established Smn-depleted PC12 cells and an intermediate SMA mouse model to characterize a role for Smn in the regulation of actin cytoskeleton dynamics. We find that Smn depletion results in the increased expression of profilin IIa and active RhoA (RhoA-GTP) as well as the decreased expression of plastin 3 and Cdc42. Importantly, the inhibition of rho-kinase (ROCK), a direct downstream regulator of RhoA, significantly increased the lifespan of SMA mice and shows beneficial potential as a therapeutic strategy for SMA. In an addition, we have uncovered a muscle- and motor neuron-independent role for SMN in the regulation of pancreatic development and glucose metabolism in SMA mice and type 1 SMA patients. This finding highlights the importance of combining a glucose tolerance assessment of SMA patients with their existing clinical care management. Thus, our work has uncovered two novel and equally important roles for the SMN protein, both of which contribute significantly to SMA pathogenesis. spinal muscular atrophy survival motor neuron protein actin cytoskeletal dynamics Rho GTPases motor neuron skeletal muscle neuromuscular junctions Rho-kinase inhibitors glucose metabolism pancreatic islet profilin plastin 3
144	Stories from a Chair: A Life Exquisite Blinkhorn, Jessica Elaine 04 April 2010 (has links) Exquisite is defined as carefully selected or sought out. I believe myself to be a selected soul placed in a body of circumstance. My work is self-explorative and telling of those circumstances in hopes of evoking empathy. Our bodies function and exist on many different levels. What I understand as normal for most differs vastly from what is normal for me. I aim to offer my perspective on the world, establish understanding, and blur the lines of normalcy. Muscular Dystrophy Spinal Muscular Atrophy Disability Performance art Creative writing Figurative Graphite Small scale Drawing Graduate thesis Jessica Elaine Blinkhorn Art and Design
145	Caracterització fenotípica i assaig terapèutic en models murins transgènics d'atròfia muscular espinal Dachs i Cabanas, Elisabet 19 June 2012 (has links) L’atròfia muscular espinal (AME) és una malaltia d’origen genètic que afecta, majoritàriament a la població infantil. La malaltia cursa amb una mort de les motoneurones  i atròfia muscular. El gen implicat és el survival motor neuron (SMN) que està delecionat en un 95% dels casos. El nostre estudi està dividit en dues parts: 1- l’aprofundiment de les alteracions musculars en dos models animals murins transgènics que pateixen les formes més greus d’AME (Tipus 1-2) i 2- estudi dels possibles efectes terapèutics del liti en un d’aquests models d’AME. S’ha trobat alteracions greus en les unions neuromusculars d’animals nounats i prenatals en marcadors relacionats amb l’ancoratge de les vesícules a la membrana presinàptica, organització dels canals de calci presinàptics i altres proteïnes presinàptiques, desorganització i apoptosi de les cèl•lules musculars, apoptosi massiva del timus i alteracions generalitzades en els òrgans limfoides. L’estudi ultraestructural del múscul ens indica que hi ha una mort, per apoptosi, de les cèl•lules satèl•lit, confirmat amb la tècnica de TUNEL. L’augment de les apoptosi, però no es reflexa en un increment, per altra banda esperat, de la densitat dels macròfags. El tractament amb concentracions terapèutiques del liti no millora l’evolució de la malaltia en els ratolins que manifesten l’AME, s’observa una acumulació progressiva dels nivells de liti, provocant toxicitat en l’animal. L’efecte del liti inhibint la GSK3 no es tradueix en el increment d’expressió de SMN, tal com s’ha deduït d’alguns experiments publicats. / La atrofia muscular espinal (AME) es una enfermedad de origen genético que afecta, mayoritariamente a la población infantil. La enfermedad cursa con muerte de las motoneuronas y atrofia muscular. El gen implicado es el “survival motor neuron” (SMN) que está delecionado en un 95% de los casos. Nuestro estudio está dividido en dos partes: 1 - la caracterización de las alteraciones musculares en dos modelos animales murinos transgénicos que sufren las formas más graves de AME (Tipo 1-2) y 2 - estudio de los posibles efectos terapéuticos del litio en uno de estos modelos. Se han encontrado alteraciones pre y postnatales graves en las sinapsis neuromusculares a nivel de marcadores relacionados con el anclaje de las vesículas en la membrana presináptica, en la organización de los canales de calcio presinápticos y en otras proteínas presinápticas, Asimismo se ha hallado desorganización y apoptosis de las células musculares, apoptosis masiva del timo y alteraciones generalizadas en los órganos linfoides. El estudio ultraestructural del músculo nos revela muerte, por apoptosis, de las células satélite, confirmado con la técnica de TUNEL. El aumento de las apoptosis muscular no conlleva un incremento, por otra parte esperado, de la densidad de los macrófagos. El tratamiento con litio no mejora la evolución de la enfermedad en los ratones con AME. Se observa un incremento progresivo de los niveles de litio, provocando toxicidad en el animal. Por otra parte, el efecto del litio inhibiendo la GSK3 no se traduce en un aumento de la expresión de SMN, tal como se ha deducido de algunos experimentos publicados. / The spinal muscular atrophy (SMA) is a pediatric genetic disease. The SMA is a motor neuron disease that affects the motor neurons causing its death and muscle atrophy. The gene involved is the survival motor neuron (SMN) that is mutated in the 95% of the cases. Our study is divided into two parts: 1 – studies of the neuromuscular junction in two transgenic SMA murine models that develop the most severe forms of SMA (type 1-2) and 2 - study of the possible therapeutic effects of lithium on one of these models of SMA. We found severe alterations in the neuromuscular junctions of newborn animals and also in prenatal markers related to the vesicle docking at the presynaptic membrane, lack of organization of presynaptic calcium channels and defects in the expression of other presynaptic proteins. We found also, disruption and apoptosis of muscular cells, massive apoptosis of the thymus and widespread alterations in lymphoid organs. The ultrastructural study of muscle identifies apoptotic satellite cells that was confirmed by the TUNEL technique. The increase in apoptosis is not followed by the expected increase, in the macrophage density. Treatment with therapeutic concentrations of lithium does not improve the course of the disease in SMA mice. There was a progressive accumulation of lithium, causing toxicity in the animal. The effect of lithium inhibiting GSK3 does not determine an increased expression of SMN, as could be deduced from some published experiments. Atròfia muscular espinal Unió neuromuscular SMN Motoneurona Apoptosi Atrofia muscular espinal Unión neuromuscular Motoneurona Apoptosis Spinal muscular atrophy Neuromuscular junction Motorneuron Neurobiologia cel·lular 616.8
146	Identification of Novel Roles for the Survival Motor Neuron (Smn) Protein: Implications on Spinal Muscular Atrophy (SMA) Pathogenesis and Therapy Bowerman, Melissa 18 April 2012 (has links) Spinal muscular atrophy (SMA) is the leading genetic cause of death of young children. It is an autosomal recessive disease caused by the mutation and/or the deletion within the ubiquitously expressed survival motor neuron 1 (SMN1) gene. SMA pathology is characterized by spinal cord motor neuron degeneration, neuromuscular junction (NMJ) defects and muscular atrophy. Upon disease onset, SMA patients progressively become paralyzed and in the most severe cases, they die due to respiratory complications. Over the years, it has become clear that SMN is a multi-functional protein with important roles in small nuclear ribonucleoprotein (snRNP) assembly, RNA metabolism, axonal outgrowth and pathfinding, mRNA transport as well as in the functional development of NMJs, skeletal muscle and cardiac muscle. However, it remains unclear which of these functions, and the respective perturbed molecular pathways, dictate SMA pathogenesis. Here, we have established Smn-depleted PC12 cells and an intermediate SMA mouse model to characterize a role for Smn in the regulation of actin cytoskeleton dynamics. We find that Smn depletion results in the increased expression of profilin IIa and active RhoA (RhoA-GTP) as well as the decreased expression of plastin 3 and Cdc42. Importantly, the inhibition of rho-kinase (ROCK), a direct downstream regulator of RhoA, significantly increased the lifespan of SMA mice and shows beneficial potential as a therapeutic strategy for SMA. In an addition, we have uncovered a muscle- and motor neuron-independent role for SMN in the regulation of pancreatic development and glucose metabolism in SMA mice and type 1 SMA patients. This finding highlights the importance of combining a glucose tolerance assessment of SMA patients with their existing clinical care management. Thus, our work has uncovered two novel and equally important roles for the SMN protein, both of which contribute significantly to SMA pathogenesis. spinal muscular atrophy survival motor neuron protein actin cytoskeletal dynamics Rho GTPases motor neuron skeletal muscle neuromuscular junctions Rho-kinase inhibitors glucose metabolism pancreatic islet profilin plastin 3
147	Problematika ošetřovatelské péče o dítě se spinální muskulární atrofií / Problems of nursing care for a child with spinal muscular atrophy BUBALOVÁ, Petra January 2015 (has links) Spinal muscular atrophy (SMA) is a hereditary disease characterized by progressive loss of -motoneurons of the spinal front corners, the consequence of which atrofizaci of muscles occurs. As a result, children become disabled and infirm dependent on the help and care of others at an early age. This is a relatively rare disease, the prevalence is about 1: 6,000 children. Spinal muscular atrophy is divided into 4 types according to its severity and time of onset of symptoms. Despite significant longtime research, it has failed to find a drug that could cure this disease so far. To the present date, there are only methods that slow the progression. The survey also contained 4 research questions, namely: What are the principles of treating a child with spinal muscular atrophy ? What are the most common problems in the care of a child with spinal muscular atrophy ? Are parents adequately educated on the issue of child with spinal muscular atrophy ? What impact has the presence of a child with spinal muscular atrophy in his family? Qualitative research was used in the implementation of the empirical part . Two qualitative methods were used to collect the data, a semi-structured interview and a hidden observation of the participant . Interviews were conducted with 3 research files, with 11 general nurses from the České Budejovice Hospital and University Hospital Motol, 7 mothers of children with I and II. type SMA of a summer camp for children with SMA and with 5 personal assistants. This thesis should help nurses and the public to gain awareness of the disease of Spinal Muscular Atrophy. It refers to all aspects of care of such a sick child, with which their parents daily struggle. Caring for a child with SMA is very difficult for their caregivers and requires considerable restrictions for the whole family. Information observed during the research were presented at a seminar for nurses in the České Budejovice Hospital in January 2015.
148	Understanding the role of UBA1 in the pathogenesis of spinal muscular atrophy Shorrock, Hannah Karen January 2018 (has links) Spinal muscular atrophy (SMA) is an autosomal recessive neuromuscular disorder characterized by widespread loss of lower motor neurons from the spinal cord. Lower motor neuron degeneration leads to a progressive decline in motor development, manifesting as muscle atrophy and weakness. It is now well characterised that ubiquitin homeostasis is altered in SMA and that reduction of the ubiquitin-like modifier-activating enzyme 1 (UBA1) is central to this disruption. UBA1 is responsible for activating ubiquitin as the first step in the ubiquitin conjugation process, marking unwanted proteins for degradation by the proteasome. While it is known that therapies targeting UBA1 rescue neuromuscular phenotypes in SMA models, the mechanism by which UBA1 mediates neurodegeneration is unclear. In fact, very little is known about the function of UBA1 beyond its canonical role in the ubiquitin proteasome system. To better understand the role of UBA1 in motor neuron degeneration, a robust set of antibodies for both in vivo and in vitro work to study UBA1 have been identified. This enabled a novel characterisation of UBA1 distribution throughout disease progression in SMA spinal motor neurons to be performed, revealing that UBA1 reduction is an important pre-symptomatic molecular feature of SMA. To identify downstream targets of UBA1 critical for UBA1-mediated degeneration in SMA, label-free proteomics was performed on HEK293 cells after overexpression or knockdown of UBA1. The proteomics data was analysed across multiple platforms, including Biolayout, IPA and DAVID to identify UBA1-dependent pathways and demonstrated that modulation of UBA1 levels lead to disruption of key cellular pathways including translation elongation, nuclear transport, and tRNA synthetases. Validation of target proteins from these UBA1-dependent pathways identified that the tRNA synthetease GARS behaves in a UBA1-dependent manner across a range of model systems in vitro and in vivo. It was then identified that GARS expression is significantly dysregulated across a range of neuronal tissues in a mouse model of SMA. Interestingly, mutations in GARS cause Charcot-Marie-Tooth disease type 2D (CMT2D), an axonal neuropathy, in which a disruption to sensory neuron fate in dorsal root ganglia has recently been identified. In a mouse model of SMA we identified a phenotype consistent with that in the CMT2D mouse model and showed that disruption to sensory neuron fate is reversible and dependent on changes in UBA1 and GARS expression in SMA. In conclusion, modulation of UBA1 levels leads to disruption of key cellular pathways, with dysregulation of tRNA synthetases a prominent feature that is likely to play a role in the pathogenesis of SMA.
149	Concentrações séricas diminuídas de IGF-I e IGFBP-3, atrofia muscular e alterações no desempenho neuromuscular contribuem para a fraqueza muscular em indivíduos hemiparéticos crônicos Couto, Marcela de Abreu Silva 22 February 2013 (has links) Made available in DSpace on 2016-06-02T20:19:20Z (GMT). No. of bitstreams: 1 4910.pdf: 3408018 bytes, checksum: 4034688ddb3183a38d1f9c8b45afa4e8 (MD5) Previous issue date: 2013-02-22 / Universidade Federal de Sao Carlos / Muscle weakness is characterized as a significant cause of reduced physical capacity and functionality, this limitation is due to the decreased ability to produce voluntary contraction of the muscle groups in the affected hemisphere. It is a consequence of morphological and functional changes related to neural and muscular aspects. The aim of this study was to evaluate the neuromuscular performance, muscle volume and Growth Factor Insulin-like I (IGF-I) serum concentration (SC) and its Binding Protein, IGFBP-3, in subjects with chronic hemiparesis. For such, a cross-sectional study was designed. Fourteen subjects with chronic hemiparesis were evaluated for functionality performed by assessment tools Berg Balance Scale Test, Timed Up Go Adapted, Walk test 10 meters, Functional Reach Test, Fugl- Meyer Assessment, Barthel Index, Assessment of Quality of Life, Medical Outcomes Study- 36 Health Status Measurement. The subjects were allocated in the hemiparetic group (HG, 12 men). Healthy subjects (control group, CG) were paired for age, gender, height and body mass index with HG. Rectus femoris (RF), vastus medialis (VM), vastus intermedius (VI), vastus lateralis (VL), biceps femoris (BF) and semitendinosus / semimembranosus (SS) muscle volume was measured. The SC IGF-I and IGFBP-3 was quantified by ELISA. The peak torque (PT), work and power during concentric and eccentric contractions of knee extensors and flexors were evaluated using an isokinetic dynamometer at 60°/s, synchronously to record muscle activation RF, VM, VL, BF and semitendinosus (ST). For parametric data, the unpaired t test and ANOVA two-way followed by Tukey test were applied to identify statistical differences between groups and factors (dominance and condition; paretic limb: PL, non-paretic limb: NPL and control group CG). For nonparametric data was used the Mann Whitney U test followed by Bonferroni adjustment. The significance level of 5% was considered. The HG presented functional levels and CSs of IGF-I and IGFBP-3 reduced compared to the CG. The HG showed selective muscle atrophy of VM, VI, BF and SS, and also altered muscle activation between agonist and antagonist against the CG. There was a significant decrease in PT, work and power of the knee extensors and flexors for concentric and eccentric actions in the PL and NPL compared to the CG. In conclusion, hemiparetic group show weakness in the PL due to changes in neuromuscular performance, including decreased PT, power and work, and also due to changes in the agonist and antagonist muscle recruitment. These neural changes are accompanied by selective atrophy of quadriceps and hamstrings muscles and CSs decrease in IGF-I and IGFBP-3 serum concentrations. / A fraqueza muscular é caracterizada como uma importante causa da redução da capacidade física e funcionalidade, esta limitação ocorre devido à diminuição da capacidade de gerar contração voluntária dos grupamentos musculares no hemicorpo afetado. E consequência de alterações morfofuncionais relacionadas aos aspectos neurais e musculares. O objetivo deste estudo foi avaliar o desempenho neuromuscular, o volume muscular e a concentração sérica (CS) do fator de crescimento semelhante à insulina 1 (IGF-1) e de sua proteína ligante, IGFBP-3, em indivíduos hemiparéticos crônicos. Para tal, um estudo transversal foi delineado. Quatorze sujeitos com hemiparesia crônica foram submetidos a avaliações de funcionalidade realizada pelas ferramentas Escala de Equilíbrio de Berg,Teste Timed Up Go (TUG) Adaptado, Teste de caminhada de 10 metros, Teste de Alcance Funcional, índice de Desempenho Motor de Fugl-Meyer, índice de atividade de vida diária de Barthel, Escala de Avaliação da Qualidade de Vida, Medical Outcomes Study-36 Health Status Measurement. Foram alocados no Grupo Hemiparético (GH; 12 homens). Sujeitos saudáveis (Grupo Controle, GC) foram pareados por idade, gênero, altura e índice de massa corpórea com o GH. Foram mensurados o volume dos músculos reto femoral (RF), vasto medial (VM), vasto intermédio (VI), vasto lateral (VL), bíceps femoral (BF) e semitendinoso/ semimembranoso (SS). A CS de IGF-I e IGFBP-3 foi quantificada pelo método de ELISA. O pico de torque (PT), trabalho e potência concêntricos e excêntricos, dos flexores e extensores do joelho, foram avaliados em dinamômetro isocinético a 60o/s, de forma sincrônica ao registro da ativação dos músculos RF, VM, VL, BF e semitendinoso (ST). Para dados paramétricos, o teste T não pareado e Anova two-way seguida de Tukey foram utilizados para identificar diferenças estatísticas entre grupos e fatores (dominância e condição; membro parético: MP, membro não parético: MNP e membro controle: MC). Para dados não paramétricos foram utilizados o teste U de Mann Whitney seguido do ajuste de Bonferroni. O nível de significância de 5% foi considerado. O GH apresentou níveis funcionais e as CSs de IGF-I e IGFBP-3 reduzidos em relação ao GC. O GH apresentou atrofia seletiva dos músculos VM, VI, BF e SS e também demonstrou a ativação muscular alterada entre agonistas e antagonistas em relação ao GC. Houve uma diminuição significativa do PT, trabalho e potência dos flexores e extensores do joelho em ações concêntricas e excêntricas no MP em relação ao MNP e ao MC. Em conclusão, indivíduos hemiparéticos apresentam fraqueza no MP decorrente de alterações no desempenho neuromuscular, incluindo diminuição do PT, potência e trabalho, e também devido a alterações no recrutamento de músculos agonistas e antagonistas do movimento. Estas modificações neurais são acompanhadas por atrofia seletiva de músculos do quadríceps e dos isquiotibiais e por menores CSs de IGF-I e IGFBP-3. Fisioterapia Reabilitação neurológica Hemiparesia Atrofia muscular Marcadores biológicos Eletromiografia Neurological rehabilitation Physical therapy Muscular atrophy Functionality Biomarkers Electromyography
150	Les facteurs de transcription de la famille p53 dans l’atrophie musculaire : implications dans la Sclérose Latérale Amyotrophique et la cachéxie / The p53 family of transcription factors in muscular atrophy : involvements in amyotrophic lateral sclerosis and cachexia Von Grabowiecki, Yannick 14 November 2013 (has links) Les facteurs de transcription de la famille p53 dans l’atrophie musculaire - Implications dans la Sclérose Latérale Amyotrophique et la cachéxie. L’atrophie musculaire est un symptôme dangereux retrouvé dans plusieurs maladies. Dans la sclérose latérale amyotrophique (SLA), une maladie neuromusculaire rare, ainsi que dans le cancer (phénomène de cachexie), l’atrophie musculaire cause le décès des patients. Les facteurs de transcription de la famille p53 sont impliqués dans de nombreux processus cellulaires, faisant face à des situations de « stress » pour les cellules. Notamment, ils peuvent induire la mort cellulaire ou promouvoir la différentiation.Nous avons constaté, à partir de modèles cellulaire et animaux de SLA et cachéxie cancéreuse, que des membres de la famille p53 sont activés dans les muscles atrophiques. Cette activation entraine l’expression de gènes cibles impliqués dans la mort cellulaire. De manière intéressante, TAp73, mais surtout TAp63, sont capables d’activer la transcription d’un effecteur de l’atrophie musculaire appelé MuRF1, démontrant que la famille p53 peut participer activement à l’atrophie en induisant la dégradation des fibres musculaires.De plus, nous avons utilisé nos modèles animaux pour identifier une nouvelle approche contre l’atrophie musculaire. Ainsi, nous avons identifié un dérivé de tocophérol avec des propriétés thérapeutiques intéressantes. / The p53 family of transcription factors in muscular atrophy - Involvements in Amyotrophic Lateral Sclerosis and cachexia Muscular atrophy is a dangerous condition found in several diseases. In amyotrophic lateral sclerosis (ALS), a rare neuromuscular disease, as well as in cancer (phenomenon of cachexia), muscular atrophy can be fatal to patients.The transcription factors from the p53 family are involved in several cellular processes, facing cellular “stress” situations. Most notably, they can induce dell death or promote differentiation.We found, using cellular and mouse models of ALS and cachexia, that members of the p53 family are induced during muscular atrophy. This induction leads to the expression of canonnic target genes involved in cell death. Interestingly, TAp73, but especially TAp63, are able to activate the transcription of an effector or muscular atrophy called MuRF1. This proves that the p53 family cand participate in muscular atrophy by promoting the breakdown of muscle fibres.In addition, we used our mouse models to identifiy a new approach agains muscular atrophy.Indeed, we identified a derivative of tocopherol with interesting therapeutical proprieties. Atrophie musculaire Sclérose latérale amyotrophique Cachexie P63 Régulation transcriptionelle MuRF1 Muscular atrophy Amyotrophic lateral sclerosis Cachexia P63 Transcriptional regulation MuRF1 572.8 616.7 616.8

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