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1	Estudo genético-molecular de pacientes discordantes de Paraplegia Espástica Hereditária do tipo 4 / Molecular-genetic study of discordant patients with Hereditary Spastic Paraplegia type 4 Cavaçana, Natale 07 November 2014 (has links) As doenças neuromusculares incluem um grupo muito heterogêneo de patologias que atingem 1 em cada 1.000 indivíduos nascidos vivos. Dentre as doenças neuromusculares destacam-se as paraplegias espásticas hereditárias que acometem, aproximadamente, cerca de 1 em cada 10.000. As paraplegias espásticas hereditárias (PEH) são caracterizadas pela espasticidade e fraqueza muscular dos membros inferiores. São muito heterogêneas tanto em clínica como geneticamente. Diversas formas já foram descritas e a mais comum delas, acometendo por volta de 40% dos casos autossômicos dominantes, causada por mutações no gene SPAST (PEH do tipo 4 ou SPG4). Estudos de correlação genótipo: fenótipo têm mostrado que indivíduos da mesma família carregando a mesma mutação patogênica, podem ter quadro clínico muito distinto. A explicação para esta questão pode estar na procura por genes modificadores, no padrão de expressão, na análise proteômica (seja por ligantes a proteínas ou no dobramento das mesmas), ou em mecanismos epigenéticos. Além disso, em algumas formas observa-se uma diferença na porcentagem de pessoas afetadas de acordo com o sexo. Essa desproporção foi observada numa grande família de com PEH na qual existe um predomínio de afetados do sexo masculino. O objetivo do presente trabalho foi a análise de pacientes discordantes, ou seja, que possuam a mesma mutação, porém com quadro clínico discordante de uma grande família brasileira com SGP4. Para isso foi feito um estudo da abundância de transcritos (mRNA) e de genótipo (polimorfismos de base única) em relação a um fenótipo (sintomático ou assintomático). Os resultados sugerem que o principal sistema envolvido, que poderia explicar as diferenças entre os pacientes discordantes, é o sistema imune, com a principal atuação dos genes C2, HLA-DRB1 e LY6G6C. Esses genes podem ter papel protetor ou tóxico no desenvolvimento do quadro clínico dos pacientes analisados / The hereditary spastic paraplegia (HSP) is characterized by muscle weakness and lower limb spasticity. They are very heterogeneous both clinically and genetically. Several forms have been described and the most common one, affecting around 40% of autosomal dominant cases, is caused by mutations in the SPAST gene (HSP type 4 or SPG4). Genotype: phenotype correlation studies have shown that affected individuals from the same family, who carry the same pathogenic mutation, can have very distinct phenotypes. The underlying explanation behind this clinical heterogeneity may be found in the search for modifier genes, in expression patterns observed proteomic analyses (either by protein binding or folding), or epigenetic mechanisms. As is observed in other motor neurodisease, there is a disproportion between the number of affected males and females, with males being the predominantly affected. The objective of this study was to analyze discordant patients, i.e., those that possess the same mutation, but show discordant phenotypes, from a large Brazilian family with SGP4. For this study, the abundance of transcripts (mRNA) and genotype (single nucleotide polymorphisms) relative to a phenotype (symptomatic or asymptomatic) were analyzed. The results suggest that the main system involved, which could explain the differences between discordant patients, is the immune system, with the main activity of C2, LY6G6C and HLA-DRB1 genes. These genes may have a protective or toxic role in the development of the analyzed patients\' clinical features Hereditary spastic paraplegia Microarranjo Microarray Paraplegia espástica hereditária SPG4 SPG4
2	Estudo genético-molecular de pacientes discordantes de Paraplegia Espástica Hereditária do tipo 4 / Molecular-genetic study of discordant patients with Hereditary Spastic Paraplegia type 4 Natale Cavaçana 07 November 2014 (has links) As doenças neuromusculares incluem um grupo muito heterogêneo de patologias que atingem 1 em cada 1.000 indivíduos nascidos vivos. Dentre as doenças neuromusculares destacam-se as paraplegias espásticas hereditárias que acometem, aproximadamente, cerca de 1 em cada 10.000. As paraplegias espásticas hereditárias (PEH) são caracterizadas pela espasticidade e fraqueza muscular dos membros inferiores. São muito heterogêneas tanto em clínica como geneticamente. Diversas formas já foram descritas e a mais comum delas, acometendo por volta de 40% dos casos autossômicos dominantes, causada por mutações no gene SPAST (PEH do tipo 4 ou SPG4). Estudos de correlação genótipo: fenótipo têm mostrado que indivíduos da mesma família carregando a mesma mutação patogênica, podem ter quadro clínico muito distinto. A explicação para esta questão pode estar na procura por genes modificadores, no padrão de expressão, na análise proteômica (seja por ligantes a proteínas ou no dobramento das mesmas), ou em mecanismos epigenéticos. Além disso, em algumas formas observa-se uma diferença na porcentagem de pessoas afetadas de acordo com o sexo. Essa desproporção foi observada numa grande família de com PEH na qual existe um predomínio de afetados do sexo masculino. O objetivo do presente trabalho foi a análise de pacientes discordantes, ou seja, que possuam a mesma mutação, porém com quadro clínico discordante de uma grande família brasileira com SGP4. Para isso foi feito um estudo da abundância de transcritos (mRNA) e de genótipo (polimorfismos de base única) em relação a um fenótipo (sintomático ou assintomático). Os resultados sugerem que o principal sistema envolvido, que poderia explicar as diferenças entre os pacientes discordantes, é o sistema imune, com a principal atuação dos genes C2, HLA-DRB1 e LY6G6C. Esses genes podem ter papel protetor ou tóxico no desenvolvimento do quadro clínico dos pacientes analisados / The hereditary spastic paraplegia (HSP) is characterized by muscle weakness and lower limb spasticity. They are very heterogeneous both clinically and genetically. Several forms have been described and the most common one, affecting around 40% of autosomal dominant cases, is caused by mutations in the SPAST gene (HSP type 4 or SPG4). Genotype: phenotype correlation studies have shown that affected individuals from the same family, who carry the same pathogenic mutation, can have very distinct phenotypes. The underlying explanation behind this clinical heterogeneity may be found in the search for modifier genes, in expression patterns observed proteomic analyses (either by protein binding or folding), or epigenetic mechanisms. As is observed in other motor neurodisease, there is a disproportion between the number of affected males and females, with males being the predominantly affected. The objective of this study was to analyze discordant patients, i.e., those that possess the same mutation, but show discordant phenotypes, from a large Brazilian family with SGP4. For this study, the abundance of transcripts (mRNA) and genotype (single nucleotide polymorphisms) relative to a phenotype (symptomatic or asymptomatic) were analyzed. The results suggest that the main system involved, which could explain the differences between discordant patients, is the immune system, with the main activity of C2, LY6G6C and HLA-DRB1 genes. These genes may have a protective or toxic role in the development of the analyzed patients\' clinical features Microarranjo Paraplegia espástica hereditária SPG4 Hereditary spastic paraplegia Microarray SPG4
3	An investigation of the function of adaptor protein complex 4 (AP-4) Davies, Alexandra Katherine January 2019 (has links) Vesicle trafficking provides the solution to the 'sorting problem' - how the eukaryotic cell maintains the distinct identities, and thus functional properties, of its membrane-bound organelles. During vesicle trafficking, proteins are selectively sorted into membrane bound transport intermediates by vesicle adaptors, which include those of the highly conserved adaptor protein (AP) complex family. Each AP complex has a distinct subcellular localisation and functions in the sorting of a specific subset of transmembrane cargo proteins. Adaptor protein complex 4 (AP-4) is one of the more recently identified AP complexes, whose function has largely remained elusive. In humans, AP-4 deficiency causes a severe neurological disorder, suggesting an important role in neuronal development and homeostasis. However, the pathomechanisms that underly the neuronal pathology in AP-4 deficiency are currently unknown. AP-4 is proposed to function in protein sorting at the trans-Golgi network (TGN), so AP-4 deficiency can be thought of as a disease of missorting. The aim of this study was to apply unbiased global proteomic approaches to define the composition of AP-4 vesicles and to identify physiological cargo proteins of the AP-4 pathway. Using 'Dynamic Organellar Maps' and comparative analysis of vesicle-enriched fractions from wild-type and AP-4-depleted cells, three ubiquitously expressed transmembrane cargo proteins, ATG9A, SERINC1 and SERINC3, were found to be mislocalised in AP-4-deficient cells. Two novel cytosolic AP-4 accessory proteins, RUSC1 and RUSC2, were also identified. Further proteomic analyses confirmed the interactions between these proteins. AP-4 deficiency was found to cause missorting of ATG9A in diverse cell types, including patient derived cells, as well as dysregulation of autophagy. RUSC2 facilitates the transport of AP-4-derived, ATG9A and SERINC-positive vesicles from the TGN to the cell periphery. These vesicles cluster in close association with autophagosomes, suggesting they are the 'ATG9 reservoir' required for autophagosome biogenesis. This study uncovers ATG9A trafficking as a ubiquitous function of the AP-4 pathway. Furthermore, it provides a potential molecular pathomechanism of AP-4 deficiency, through dysregulated spatial control of autophagy.
4	WASH and WAVE Actin Regulators of the Wiskott-Aldrich Syndrome Protein (WASP) Family Are Controlled by Analogous Structurally Related Complexes Jia, Da, Gomez, Timothy S., Metlagel, Zoltan, Umetani, Junko, Otwinowski, Zbyszek, Rosen, Michael K., Billadeau, Daniel D. 08 June 2010 (has links) We recently showed that the Wiskott-Aldrich syndrome protein (WASP) family member,WASH, localizes to endosomal subdomains and regulates endocytic vesicle scission in an Arp2/3-dependent manner. Mechanisms regulating WASH activity are unknown. Here we show that WASH functions in cells within a 500 kDa core complex containing Strumpellin, FAM21, KIAA1033 (SWIP), and CCDC53. Although recombinant WASH is constitutively active toward the Arp2/3 complex, the reconstituted core assembly is inhibited, suggesting that it functions in cells to regulate actin dynamics through WASH. FAM21 interacts directly with CAPZ and inhibits its actin-capping activity. Four of the five core components show distant (approximately 15% amino acid sequence identify) but significant structural homology to components of a complex that negatively regulates the WASP family member, WAVE. Moreover, biochemical and electron microscopic analyses show that the WASH and WAVE complexes are structurally similar. Thus, these two distantly related WASP family members are controlled by analogous structurally related mechanisms. Strumpellin is mutated in the human disease hereditary spastic paraplegia, and its link to WASH suggests that misregulation of actin dynamics on endosomes may play a role in this disorder. actin dynamics and capping endosome hereditary spastic paraplegia WASH regulatory complex WAVE regulatory complex
5	Mechanism of endoplasmic reticulum membrane fusion mediated by the Atlastin GTPase Liu, Tina Yu January 2014 (has links) How organelles acquire their unique shapes is a fundamental question of cell biology. The peripheral endoplasmic reticulum (ER) consists of a vast network of membrane sheets and tubules, the formation of which requires homotypic membrane fusion. Previous studies suggest that the dynamin-like GTPase, atlastin (ATL), mediates ER fusion, but the mechanism by which this occurs is unclear. In this study, I investigate 1) the role of dimerization and conformational changes in the N-terminal domain of ATL, 2) how the C-terminal amphipathic helix and the transmembrane domain of ATL cooperate with the N-terminal domain, and 3) the formation of cis and trans ATL dimers in the fusion mechanism. ATL has a cytosolic N-terminal domain, consisting of a GTPase domain and three-helix bundle (3HB), followed by two transmembrane segments (TMs) and a cytosolic C-terminal tail (CT). Crystal structures of ATL and biochemical experiments suggest that nucleotide-dependent dimerization between ATL molecules sitting in different membranes can tether the membranes together. A subsequent conformational change triggered by GTP hydrolysis could pull the membranes toward one another for fusion. This mechanism is supported by in vitro membrane tethering and fusion assays using vesicles containing full-length Drosophila ATL. The CT and TMs of ATL are also required for efficient membrane fusion. A synthetic peptide corresponding to a conserved amphipathic helix in the CT can act in trans to restore the fusion activity of a tailless ATL mutant. We characterize CT mutants to show that the C-terminal helix promotes fusion by perturbing the lipid bilayer. The TMs of ATL also mediate nucleotide-independent oligomerization, which may allow ATL molecules in the same membrane to synchronously undergo the conformational change leading to fusion. Lastly, we show that continuous GTP hydrolysis is required for membrane tethering, occasionally resulting in fusion. The N-terminal cytosolic domain mediates trans dimer formation between ATL molecules on different membranes. GTP binding induces dimerization through the GTPase domains and 3HBs. We propose that GTP hydrolysis and phosphate release are required not just to drive fusion, but also to dissociate cis dimers that form on the same membrane, thus allowing ATL molecules to form trans dimers. Cellular biology Biochemistry Biophysics endoplasmic reticulum membrane fusion endoplasmic reticulum morphology hereditary spastic paraplegia protein structure reconstituted proteoliposomes SPG3A
6	In vivo approach to myelin turnover and oligodendrocyte-dependent axonal integrity Lüders, Katja 21 August 2018 (has links) No description available. 570 Proteolipid protein (PLP) Oligodendrocyte Axonopathy Glia-axonal support Myelin Neurodegeneration Neuroinflammation Tamoxifen Biologie (PPN619462639)
7	Modélisations de maladies des motoneurones en utilisant le poisson zébré Lissouba, Alexandra 08 1900 (has links) No description available. Sclérose latérale amyotrophique paraplégie spastique familiale poisson zébré stress RE TDP-43 FUS spastin CRISPR/Cas9 calpain 1 Amyotrophic lateral sclerosis hereditary spastic paraplegia zebrafish ER stress
8	Souffle/Spastizin regulates secretory granule maturation by sorting lysosomal cargo from immature secretory granule during zebrafish oogenesis Palsamy, Kanagaraj 18 November 2014 (has links) No description available. 570 Kanagaraj Zebrafish Souffle/spastizin/spg15/fyve-cent HSP-hereditary spastic paraplegia Oogenesis Yolk endocytosis and degradation Vesicle fission and fusion Lysosome and autophagy Maternal protein Vesicle trafficking and transport Motor neuron degeneration Germplasm/balbiani body Biologie (PPN619462639)
9	Molekulare Charakterisierung des COPS5-Gens und seines Genproduktes als Kandidat für die Spastische Spinalparalyse / Molecular characterisation of the COPS5 Gen and its Gen Product as a candidate for the spastic paraplegia Eisenberg, André 07 March 2011 (has links) No description available. 610 Medizin, Gesundheit Medicine hereditäre spastische Paraplegie HSP Spastin SPG4 COPS5 Immunfluoreszenz Co-Immunpräzipitation SPG5 Yeast Two Hybrid Y2H hereditary spastic paraplegia HSP Spastin SPG4 COPS5 immunofluorescence co-immunoprecipitation SPG5 Yeast Two Hybrid Y2H 42.13 44.48 MED 283: Molekularbiologie {Medizin}
10	The Study of Hereditary Spastic Paraplegia-Causing Gene DDHD2 Using Cell Models Mongeon, Kevin 13 April 2018 (has links) Hereditary spastic paraplegia type 54 is a rare autosomal recessive neurological gait disorder characterized by paraplegia, muscle spasticity, and intellectual disability. This length-dependent distal axonopathy is caused by mutations in the DDHD2 gene, which encodes the intracellular phospholipase A1 DDHD2. Little is known about the molecular function of the DDHD2 protein, especially in the context of HSP54. Thus, there is a need to further investigate its molecular functions and investigate the impact of DDHD2 deficiency in disease-relevant cells. Here, lipidomic profiling of dermal fibroblasts derived from three unrelated patients has revealed 19 glycerophosphoethanolamine species at differential levels in patients relative to unaffected controls. However, patient cells appear to have an unaffected Golgi apparatus morphology and lipid droplet formation, despite DDHD2’s proposed roles in these processes. To study the gene function in neuronal cells, I transdifferentiated the fibroblasts into induced neuronal precursor cells and found all the patient cells arrested in the G0/G1 phase of upon conversion. Given that these cell lines are unsustainable, I generated a stable knockdown cell line in the highly proliferative HEK293A to study the molecular biology of DDHD2. The knockdown cells had a reduced growth, were delayed in the G2/M phase of the cell cycle, and became multinucleated. I then treated the cells with antineoplastic compounds paclitaxel and nocodazole and found more knockdown cells in G0/G1 than controls, suggesting the possible occurrence of mitotic slippage. Lastly, I report a novel subcellular localization for DDHD2 at the microtubule organization center. Hereditary Spastic Paraplegia DDHD2 Cell Model Golgi Lipid droplet Lipidomics Microtubules Microtubule organization center Cell cycle Mitotic slippage Induced neuronal precursor cells Transdifferentiation Genetics Neuromuscular disease Neurodegenerative Gait disorder

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