Dissertations / Theses on the topic 'Tbc1D3'
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Penisson, Maxime. "Mécanismes de LIS1 dans les progéniteurs neuraux contribuant aux malformations de développement du cortex." Electronic Thesis or Diss., Sorbonne université, 2020. http://www.theses.fr/2020SORUS415.
Full textHuman cortical malformations are associated with progenitor proliferation and neuronal migration abnormalities. Basal radial glia (bRGs), a type of progenitor cells, are limited in lissencephalic species (e.g. the mouse) but abundant in gyrencephalic brains. The LIS1 gene coding for a dynein regulator, is mutated in human lissencephaly, associated also in some cases with microcephaly. LIS1 was shown to be important during cell division and neuronal migration. Here, we generated bRG-like cells in the mouse embryonic brain, investigating the role of Lis1 in their formation. This was achieved by in utero electroporation of a hominoid-specific gene TBC1D3 at mouse embryonic day (E) 14.5. We first confirmed that TBC1D3 overexpression in WT brain generates numerous Pax6+ bRG-like cells that are basally localized. Second, we assessed the formation of these cells in heterozygote Lis1 mutant brains. Our novel results show that Lis1 depletion in the forebrain from E9.5 prevented subsequent TBC1D3-induced bRG-like cell amplification. Lis1 depletion changed mitotic spindle orientations at the ventricular surface, increased the proportion of abventricular mitoses, and altered N-Cadherin expression, altering TBC1D3 function. We conclude that perturbation of Lis1/LIS1 dosage is likely to be detrimental for appropriate progenitor number and position, contributing to lissencephaly pathogenesis
Benninghoff, Tim [Verfasser], Michael [Gutachter] Feldbrügge, and Hadi [Gutachter] Al-Hasani. "Role of the Rab GTPase activating proteins TBC1D1 and TBC1D4 in the regulation of skeletal muscle fatty acid metabolism / Tim Benninghoff ; Gutachter: Michael Feldbrügge, Hadi Al-Hasani." Düsseldorf : Universitäts- und Landesbibliothek der Heinrich-Heine-Universität Düsseldorf, 2020. http://d-nb.info/1208505483/34.
Full textLeicht, Katja. "Positionelle Klonierung von Tbc1d1 als Kandidatengen für Adipositas." Phd thesis, Universität Potsdam, 2008. http://opus.kobv.de/ubp/volltexte/2009/3461/.
Full textNob1 (New Zealand obese 1) has been identified as an obesity QTL on chromosome 5 (LODBMI >3,3) in a backcross experiment of obese NZO and lean SJL mice. To identify candidate genes for obesity expression profiling experiments with RNA from metabolic tissues were performed with more than 300 Nob1-genes. Seven genes showed differences in mRNA expression levels between both strains: 2310045A20Rik, Tbc1d1, Ppp1cb, Mll5, Insig1, Abhd1, and Alox5ap. Sequencing of the coding regions of these genes revealed a SJL-specific deletion of seven basepairs in the Tbc1d1 gene that is located in the peak region of Nob1. This mutation leads to a frameshift resulting in a truncated protein that lacks the important Rab-GAP-domain (Loss-of-Function-mutation). Interestingly, linkage analysis of the R125W-variant of TBC1D1 has been recently associated with human obesity. TBC1D1 shows high homology to TBC1D4 (AS160) that plays an important role in the insulin signaling pathway. No other SJL-specific mutations were detected in 17 further genes in the Nob1 peak region. In NZO mice Tbc1d1 mRNA is predominantly expressed in glycolytic fibres of skeletal muscle. Two isoformes were identified differing in alternative spliced exons 12 and 13 and showing a tissue specific mRNA expression. The results presented in this work make Tbc1d1 a very feasible candidate gene to be causal for Nob1. The function of Tbc1d1 in the metabolism of carbohydrates and fat has yet to be analyzed.
Dash, Satya. "Analysis of TBC1D4 genetic variants in patients with severe insulin resistance." Thesis, University of Cambridge, 2011. http://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.609172.
Full textCâmara, Ana Isabel Rodrigues. "Estudo de padrões de expressão de transcritos alternativos do gene tbccd1 em tecidos humanos e linhas celulares cancerígenas." Master's thesis, Escola Superior de Saúde Egas Moniz, 2013. http://hdl.handle.net/10400.26/6142.
Full textO centrossoma é um organito essencial nos eucariotas sendo o principal centro organizador de microtúbulos nas células animais. É composto por um par de centríolos e rodeado por uma matriz pericentriolar. Em células em interfase, os centrossomas estão envolvidos na nucleação/organização dos microtúbulos, no posicionamento dos organitos, e.g. o complexo de Golgi, no estabelecimento da polaridade e ainda na migração e adesão, por sua vez em mitose facilitam a formação dos fusos mitóticos.
Estudos realizados pelo nosso grupo, identificaram uma nova proteína humana, que contem o domínio TBCC (TBCCD1), a qual está relacionada com o cofator C da tubulina, o qual participa na via de folding da tubulina apresentando uma atividade GAP (GTPase activating protein) para a β-tubulina. O TBCCD1 é um componente centrossomal, localizando-se também na zona mediana do fuso, corpo médio e corpos basais/zona de transição de cílios primários e móveis. O silenciamento do TBCCD1 em células RPE-1 provocou um aumento acentuado da distância núcleo-centrossoma, um atraso no ciclo celular, desorganização do complexo de Golgi e baixa eficiência para formar cílios primários. Através de técnicas de análise mutacional identificou-se o domínio mínimo necessário à localização do TBCCD1 no centrossoma, o qual corresponde aos 20 primeiros resíduos de aminoácidos da sua região N-terminal.
O splicing alternativo do pré-mRNA é um passo crítico para a expressão de genes sendo a principal fonte para a diversidade de proteínas nos eucariotas superiores. Atualmente pensa-se que ocorre em mais de 90% dos genes humanos. A proteína TBCCD1 humana é codificada por um gene localizado no cromossoma 3 (3q27.3) e apresenta a sua região codificante interrompida por 7 intrões. O presente estudo permitiu verificar que este gene origina três transcritos diferentes pelo processo de splicing alternativo. Um destes transcritos resulta do facto que existem dois primeiros exões alternativos, que originam duas proteínas putativas diferindo nos primeiros resíduos de aminoácidos da sua N-terminal. Esta sequência de aminoácidos alternativos corresponde no TBCCD1 ao domínio envolvido na sua localização centrossomal. De facto, as duas novas variantes apresentam uma localização citoplasmática não se localizando no centrossoma.
Longatti, Andrea D. "The RabGAP TBC1D14 regulates autophagosome formation via recycling endosomes and Rab11." Thesis, University College London (University of London), 2010. http://discovery.ucl.ac.uk/642300/.
Full textNegra, Maria Lúcia Mourão Barriga. "" Caracterização da proteína centrossomal TBCCD1 durante o desenvolvimento embrionário do peixe zebra"." Master's thesis, Instituto de Ciências Biomédicas Abel Salazar, 2010. http://hdl.handle.net/10216/62269.
Full textNegra, Maria Lúcia Mourão Barriga. "" Caracterização da proteína centrossomal TBCCD1 durante o desenvolvimento embrionário do peixe zebra"." Dissertação, Instituto de Ciências Biomédicas Abel Salazar, 2010. http://hdl.handle.net/10216/62269.
Full textStermann, Torben [Verfasser], Hadi [Akademischer Betreuer] Al-Hasani, and Eckhard [Gutachter] Lammert. "The role of TBC1D1 in insulin secretion from mouse pancreatic islets / Torben Stermann ; Gutachter: Eckhard Lammert ; Betreuer: Hadi Al-Hasani." Düsseldorf : Universitäts- und Landesbibliothek der Heinrich-Heine-Universität Düsseldorf, 2016. http://d-nb.info/1121745598/34.
Full textRoy, Michèle. "Étude de l'expression et du rôle de TBC1D25 et de ses isoformes dans les ostéoclastes humains." Mémoire, Université de Sherbrooke, 2017. http://hdl.handle.net/11143/10639.
Full textAbstract : Paget’s disease of bone (PDB) is characterized by increases in bone turnover starting with excessive resorption followed by disorganized bone formation. Because the initial phase of PDB involves excessive bone resorption, osteoclasts have been identified as the cells primarily affected in PDB. Pagetic osteoclasts are overactive, resistant to apoptosis and exhibit defects in autophagy, but the mechanisms involved are still unclear. While genetic and environmental factors associated with PDB may partially account for the osteoclast phenotype, other genetic contributors have been identified. Recent work from our laboratory has identified six alternative splicing events associated with PDB. Among those genes, TBC1D25 and its two known isoforms have never been studied in osteoclasts. The two functional domains of TBC1D25 (TBC and LIR) are only present in the long isoform. The highly conserved TBC domain regulates small Rab GTPases in vesicular transport and the LIR domain interacts with LC3 during autophagy. Our research hypothesis is that altered alternative splicing of TBC1D25 in pagetic osteoclasts could contribute to phenotype. Differential isoform expression could affect osteoclast autophagy and bone resorption. The aim of the study is to characterize the expression and function of TBC1D25 proteins in human osteoclasts. Osteoclasts differentiated from cord blood monocytes were used to investigate the function of TBC1D25 in autophagy, apoptosis and bone resorption. First, the localization of the protein has been characterized in conditions maintaining basal autophagy and in rapamycin-induced autophagy. Interactions between TBC1D25 and Rab34 have been observed for the first time in osteoclasts. Moreover, changes in the interaction were observed with autophagy induction. Preliminary results suggest increases in LC3II/LC3I ratio with decreasing TBC1D25 expression when autophagy induction is stimulated. On the other hand, preliminary results showed that decreased expression of TBC1D25 did not affect bone resorption, nor apoptosis. In conclusion, preliminary results show that in osteoclasts, TBC1D25 could prevent the increase of LC3II/LC3I ratio by inhibiting autophagy induction or by promoting the clearance of autophagosomes through its action on Rab34.
Feldmann, Anne [Verfasser]. "Die Warburg-Mikro-Syndrom-assoziierten Proteine RAB3GAP1/2, RAB18 und TBC1D20 modulieren die Autophagie / Anne Feldmann." Mainz : Universitätsbibliothek Mainz, 2017. http://d-nb.info/1140556398/34.
Full textTona, Risa. "The Phenotypic Landscape of a Tbc1d24 Mutant Mouse Includes Convulsive Seizures Resembling Human Early Infantile Epileptic Encephalopathy." Kyoto University, 2019. http://hdl.handle.net/2433/242396.
Full textNormandin, Caroline. "Identification et caractérisation de GTPases Activating Proteins spécifiques à la petite GTPase RAB21." Mémoire, Université de Sherbrooke, 2017. http://hdl.handle.net/11143/11544.
Full textAbstract : Autophagy is defined as the lysosomal degradation and recycling of cellular constituents. At basal levels, autophagy eliminates protein aggregates or damaged organelles. In condition of stress, such as in condition of nutritional deficiency, hypoxia or cancer treatments, autophagy allow cells to adapt and survive. Therefore, autophagy is an essential system required for survival and maintenance of cellular homeostasis. It is thus essential to identify the cellular entities and mechanisms regulating this process. RAB GTPases were identified as master regulators of autophagy. These particular proteins act as molecular switches for the rapid execution of cellular responses. RABs are activated by Guanine Nucleotide Exchange Factors (GEF) whereas GTPase Activating Proteins (GAP) accelerates RAB deactivation. RAB21 is essential in the late stages of autophagy. Indeed, RAB21 is activated by nutritional deficiency, via its GEF MTMTR13, to allow trafficking of a SNARE required for autophagic flux. During starvation, RAB21 is deactivated which suggest that a GAP could negatively regulate RAB21 activity. However, to date no GAP for RAB21 has been identified. An eye modifier genetic screen in Drosophila was performed to identify potential RAB21 GAPs and some candidates were identified. As a result of this screen, the GAP TBC1D25 was identified as interacting with RAB21. Moreover, this interaction was increased by starvation. Proximity ligation assays revealed that the RAB21-TBC1D25 interaction partially localized at early endosomes. Moreover, prolonged activation of RAB5, located at early endosomes, inhibited RAB21-TBC1D25 interaction. Further experiments will be carried out to explain these results. With respect to the roles of autophagy in cancer, RAB21 was shown to be overexpressed in cells with high autophagic flux as well as in some colon cancer tumors. Importantly, the expression of Tbc1d25 in these same tumors does not appear to be increased, indicating that TBC1D25 could be an autophagic inhibitor specific to cells with a high autophagic flow. My work suggests that TBC1D25 could function as a GAP to negatively regulate RAB21 activity in condition of prolonged starvation.
Nakken, Gary N. "The Effects of Excess Corticosterone on LKB1 and AMPK Signaling in Skeletal Muscle of Rats." BYU ScholarsArchive, 2008. https://scholarsarchive.byu.edu/etd/1963.
Full textFazakerley, Daniel John. "Investigating GLUT4 trafficking in muscle." Thesis, University of Bath, 2010. https://ethos.bl.uk/OrderDetails.do?uin=uk.bl.ethos.518302.
Full textMori, R. "The tubulin folding pathway : roles of cofactor C/Tbc1 and small GTPase Arl2/Alp41." Thesis, University College London (University of London), 2013. http://discovery.ucl.ac.uk/1383787/.
Full textRowlands, Jordan Gareth David. "The role of the microtubule manufacturing chaperone TBCD in neuronal development and brain disorders." Thesis, Curtin University, 2021. http://hdl.handle.net/20.500.11937/85546.
Full textEsslinger, Susanne. "Hexabromcyclododecan." Doctoral thesis, Humboldt-Universität zu Berlin, Mathematisch-Naturwissenschaftliche Fakultät I, 2013. http://dx.doi.org/10.18452/16845.
Full textThe main emphasis of this thesis was on the enantio-specific environmental behaviour of the polybrominated flame retardant hexabromocyclododecane (HBCD). Initially, an enantio-specific analytical method for the determination of HBCD in biota was optimised and validated. The calculated mean recoveries ranged from 100 to 102 % and the limits of detection are in the range of 0.131 to 0.255 pg g-1. First investigations of the ubiquitous environmental distribution of HBCD were performed using herring gull eggs from different islands in the North and Baltic Sea (sampling 1988 to 2008). In all cases alpha-HBCD was the predominant diastereomer. Significant deviations from the racemic mixture revealed a preferred enrichment of the first eluting (-)-alpha-HBCD. In addition, a temporal trend of HBCD levels was observed. To clarify the issue of accumulation as well as bioisomerisation of HBCD stereoisomers, a long-term feeding study with mirror carps was performed. The results showed an accumulation of each initially fed HBCD enantiomer, but hypothesis of a bioisomerisation could not be confirmed. Another important focus of this work was to study the cytochrome-dependent enantio-specific biotransformation of HBCD enantiomers in various species of liver microsomes. It was shown that HBCD is subject to phase I metabolism. In the course of this process, HBCD is metabolised to hydroxylated products, whereas each HBCD enantiomer results in a specific metabolite pattern allowing the allocation of the corresponding hydroxylated compounds. Investigation of time series as well as the calculation of half-lives, the hypothesis of an enantio-specific metabolism towards an enrichment of (-)-alpha- and (+)-gamma-HBCD could be confirmed. Incubation mixtures with pure cytochrome (CYP) isoforms, as well as molecular mechanic calculations suggest that CYP3A4 plays a key role in the biotransformation processes of HBCD.
Leicht, Katja [Verfasser]. "Positionelle Klonierung von Tbc1d1 als Kandidatengen für Adipositas / vorgelegt von Katja Leicht." 2008. http://d-nb.info/996571175/34.
Full textPereira, Inês Domingos Feio. "Estudo da proteína humana centrossomal TBCCD1: determinação de domínios funcionais." Master's thesis, 2011. http://hdl.handle.net/10451/7960.
Full textO centrossoma é o principal centro organizador de microtúbulos das células animais, desempenhando funções celulares essenciais no processo de divisão celular, uma vez que regula a nucleação e organização espacial dos microtúbulos, estando também implicado no posicionamento de organelos na célula, como o complexo de Golgi, no estabelecimento da polaridade celular, na migração e adesão celulares e na ciliogénese. Nas células animais o centrossoma encontra-se posicionado no centro da célula em estreita associação com o núcleo. Os cofactores da tubulina (TBCA-E) são proteínas que participam na via de folding da tubulina e possuem funções relacionadas com o citoesqueleto, desempenhando papéis essenciais nas células eucariotas. A proteína TBCCD1 (TBCC-domain containing protein 1) é uma proteína centrossomal relacionada com o TBCC e com a proteína RP2, uma vez que possui os domínios funcionais TBCC e CARP, porém não parece possuir actividade de GAP para a tubulina. O TBCCD1 é um potencial regulador do posicionamento do centrossoma em estreita interacção com o núcleo e da organização citoplasmática. Neste trabalho descrevemos a identificação do domínio responsável pela localização centrossomal da proteína TBCCD1 humana, constituído pelos primeiros 20 resíduos de aminoácidos da sua região N-terminal. Em células humanas observámos que a expressão da proteína TBCCD1 com uma mutação pontual no resíduo de prolina na posição 24 leva à deslocalização da γ-tubulina do centrossoma. Verificámos também que três mutações pontuais distintas nos motivos VxPX e KRAK da proteína causam uma menor eficiência na formação de cílios primários. Concluindo, a proteína centrossomal TBCCD1 humana parece ter uma ligação à γ-tubulina, contudo ainda não está esclarecido se esta interacção é directa ou indirecta, podendo a γ-tubulina ser um parceiro molecular do TBCCD1. O TBCCD1 deverá também ter um papel essencial in vivo resultante do seu envolvimento na manutenção da ligação do centrossoma ao núcleo e no processo de ciliogénese.
The centrosome is the major microtubule organizing center in animal cells, playing an essential role in cellular processes such cell division, since it regulates the nucleation and spatial organization of microtubules, and is also implicated in organelle positioning in the cell, such as the Golgi apparatus, cell polarity establishment, cell migration and adhesion and ciliogenesis. In animal cells, the centrosome is positioned in the center of the cell in close association with the nucleus. The tubulin cofactors (TBCA-E) are proteins involved in tubulin folding pathway that have emerged as proteins with crucial roles in eukaryotic cells related to the cytoskeleton. The TBCCD1 protein (TBCC domain-containing protein 1) is a centrossomal protein related to TBCC and RP2 protein, since it contains the TBCC and CARP domains. However, TBCCD1 probably doesn’t have a GAP activity towards tubulin. The TBCCD1 is a potential regulator of the positioning of the centrosome and cytoplasmic organization. In this work we described the identification of the centrosome targeting motif of the human TBCCD1, corresponding to the first 20 amino acid residues of its N-terminus region. Our studies performed in mammalian cell lines revealed that the expression of TBCCD1 with a point mutation in the proline residue at position 24 leads to the mis-localization of γ-tubulin from the centrosome. Furthermore, we also found that three distinct point mutations in the motifs VxPX and KRAK lead to a lower efficiency of transfected cells to assemble primary cilia. Also, the obtained results clearly show that the human centrossomal TBCCD1 protein seems to have an interaction with γ-tubulin, but whether this is direct or indirect is still not clear. However, our results support the idea that γ-tubulin will probably be a molecular partner of TBCCD1. The TBCCD1 should also have an essential role in vivo resulting from their involvement in maintaining the nucleus-centrosome association and its involvement in ciliogenesis.
Mucha-Le, Ny Bettina E. "Clarification of the role of the TBC1D24 gene in human genetic conditions." Thesis, 2020. http://hdl.handle.net/1866/25193.
Full textPathogenic variants in the TBC1D24 gene are associated with genetic disorders, the majority of which are transmitted in an autosomal recessive manner. The phenotypes are variable in terms of clinical presentation and severity. The most severe forms cause epileptic encephalopathy (EIEE16) or DOORS syndrome which is marked by deafness, abnormalities of the nails and fingers, intellectual deficit and convulsions which are often difficult to control. Other forms of epilepsy include EPRPDC (Rolandic epilepsy with paroxysmal exercise-induce dystonia and writer's cramp), FIME (familial infantile myoclonic epilepsy), and PME (progressive myoclonus epilepsy). A specific missense variant is associated with autosomal dominant deafness (DFNA65) which develops in adulthood. A review of the literature of the published phenotypes observed in individuals with pathogenic variants in the TBC1D24 gene is presented here with recommendations for the clinical management of these patients. In addition, a group of eight patients with intellectual disability and epilepsy who share a microdeletion on chromosome 1613.3 containing the TBC1D24 gene were characterized in order to define a new genetic syndrome. The critical region contains TBC1D24, ATP6V0C and PDPK1. The significantly similar phenotype shared by the eight individuals suggests that haploinsufficiency for TBC1D24, ATP6V0C and PDPK1 causes a new genetic syndrome. Knowledge of the genes essential for the phenotype in this cohort helps in the identification of new candidate genes for intellectual disability and epilepsy.
Chiang, Chiajung, and 蔣佳蓉. "To Evaluate Of Timeliness Of TBcID From Sputum Smear Results." Thesis, 2012. http://ndltd.ncl.edu.tw/handle/83137562692806859699.
Full text中華醫事科技大學
醫學檢驗生物技術系碩士班
100
In this study,we use both Immuno-chromatography (ICA) assay,which detects MPB-64 antigen of TB,and Nucleic acid amplification test,which detects IS 6110 gene of TB.The samples were processed with tuberculisos culture from MGIT,and checking cord formation by Ziehl-Neelsen stain,sequentially.The result shows that the time to identify takes 6.9,9.2,10.6,13.8,11.6,17.1 days while the smear of sputum was4+,3+,2+,1+,scanty and negative,respectively. The sensitivity, specificity, false negatives (FN), false positives (FP), positive predictive value (PPV), negative predictive value (NPV), and accuracy of Immuno-chromatography assay were 91.9%, 98.2%, 8.1%, 1.8%, 96.6%, 95.7%, and 96.0%, respectively. On the other hand, Nucleic acid amplification test was 95.9%, 91.1%, 4.0%, 8.8%, 85.6%, 97.6%, and 92.9%, respectively. According the results, the NAA had more false positives than ICA (8.8% v.s. 1.8%, p<0.05), consequently ICA showed higher specificity and positive predictive value than NAA (98.2%, 96.6% v.s. 91.1%, 85.6%; p<0.05).Above all results got significant difference (p<0.05), but sensitivity, FN, NPV, and accuracy didn’t (91.9%, 8.1%, 95.7%, 96.0% v.s. 95.9%, 4.0%, 97.6%, 92.9%, p>0.05). Therefore, Immuno-chromatography assay (ICA) will be an excellent tool for MTB identification because of its rapidity, easiness, device-free, and lower cost. In strong smear-positive case, the identification results will be reported about 1 week by MGIT culture, checking cord formation, and ICA test. In conclusion, ICA could be a good choice other than NAA to provide tuberculosis diagnosis and identification.
Veiga, Joaquim Maria Iglésias Pereira da Mota. "Funções celulares da proteína centrossomal humana TBCCD1: validação da interação com proteínas previamente identificadas." Master's thesis, 2019. http://hdl.handle.net/10451/42075.
Full textO centrossoma é o principal centro organizador de microtúbulos nas células animais. Este desempenha diversas funções celulares como a organização espacial do citoplasma e dos organelos, bem como na formação do fuso mitótico durante a divisão, na migração celular, no estabelecimento do eixo de polaridade intrínseco da célula “Núcleo-Centrossoma-Complexo de Golgi” e na ciliogénese. O nosso grupo tem-se focado no estudo da proteína centrossomal TBCCD1 (TBCC domain-containing protein 1) e nas funções que esta desempenha. Nos seus primeiros estudos, o nosso grupo desvendou um fenótipo característico quando a proteína TBCCD1 era depletada (Gonçalves, 2010). O mesmo determinou recentemente que a proteína TBCCD1 estabelecia uma vasta rede de interações com outras proteínas, após a realização de BioID (Camelo, 2015). Como tal, identificaram-se cerca de 82 proteínas pertencentes a este interatoma da TBCCD1. Nestas 82 proteínas, destacou-se um grupo de seis proteínas, devido a sua capacidade de estabelecerem interações entre si, bem como com as restantes proteínas deste interatoma da TBCCD1 (dados ainda não publicados). As proteínas reunidas nesse grupo são essencialmente proteínas codificadas por genes envolvidos em ciliopatias, isto é, doenças associadas a defeitos relacionados com a biogénese de cílios primários. Uma das proteínas associadas a ciliopatias encontrada neste grupo foi a proteína OFD1 (Oral-Facial-Digital-1). Esta proteína localiza-se principalmente na região distal do centríolo-mãe e nos satélites centriolares. A proteína é traduzida pelo gene ofd1 localizado no cromossoma X. Mutações deste gene levam à manifestação da síndrome Oral-Facial-Digital, que se caracteriza por anormalidade orais, dimorfismo facial e defeitos no sistema nervoso central (SNC) tais como microcefalias (Lopes, et al., 2011). Neste trabalho estudámos as interações entre a proteína TBCCD1 e a proteína OFD1 e a influência desta interação no posicionamento do centrossoma, e nos satélites centriolares. Diversos ensaios de depleção ou de sobre-expressão da proteína TBCCD1 foram realizados e, seguidamente, observados por imunofluorescência e immunoblotting, de modo a estudar o impacto que diferentes níveis fisiológicos da TBCCD1 teriam na proteína OFD1. Com este trabalho foi possível concluir que as proteínas TBCCD1 e OFD1 estabelecem algum tipo de relação, dado que, tanto nos ensaios de depleção ou de sobre-expressão de TBCCD1 se verifica uma diminuição da proteína OFD1. Também se concluiu que parece existir um intervalo de níveis fisiológicos da proteína TBCCD1 que, sendo ultrapassados, têm uma influência direta na proteína OFD1, provocando uma diminuição da mesma na célula. Por fim, foi ainda possível estabelecer a hipótese de que a proteína TBCCD1 estabelece uma interação com os complexos proteicos constituídos com a proteína OFD1 (Chevrier, et al., 2015), ou ainda que, possivelmente, a própria proteína TBCCD1 se associa a um dos complexos formados pela proteína OFD1.
The centrosome is the main organizing center for microtubules in animal cells. It performs several cellular functions such as the spatial organization of the cytoplasm and organelles, as well as the formation of the mitotic spindle during division, cell migration, establishment of the intrinsic cell polarity axis "Nucleus-Centrosome-Golgi Complex" and in ciliogenesis. Our group has been focused on studying the centrosomal protein TBCCD1 (TBCC domain-containing human protein 1) and its functions. In our early studies, the group uncovered a characteristic phenotype when the TBCCD1 protein was depleted (Gonçalves, 2010). It was recently determined through BioID analysis that the TBCCD1 protein established a vast network of interactions with other proteins (Camelo, 2015). As such, about 82 proteins belonging to this TBCCD1 interatom were identified. Out of those 82 proteins, a group of six proteins was highlighted due to their ability to establish interactions among themselves, as well as with the remaining proteins of this TBCCD1 interatoma (data yet not published). The proteins included in this group are essentially proteins encoded by genes involved in ciliopathies, i.e., diseases associated with defects related to the biogenesis of primary cilia. One of these ciliopathy-associated proteins found in the referred group of interest was OFD1 (Oral-Facial-Digital-1). This protein is mainly located in the distal region of the mother centriole and centriolar satellites. The protein is transduced by the gene ofd1 located on the X chromosome. Mutations of this gene lead to the manifestation of the Oral-Facial-Digital syndrome, which is characterized by oral abnormalities, facial dimorphism and central nervous system (CNS) defects such as microcephaly (Lopes, et al., 2011). In this work we studied the interactions between the TBCCD1 protein and the OFD1 protein and the influence of this interaction on centrosome position and on the centriolar satellites. Several assays of depletion or of overexpression of the TBCCD1 protein were performed and then observed by immunofluorescence and immunoblotting, in order to study the impact that different physiological levels of TBCCD1 would have on the OFD1 protein. This work allowed us to conclude that the TBCCD1 and OFD1 proteins establish some type of relationship, since in both TBCCD1 depletion or overexpression assays occurs a decrease of OFD1 protein. It was also concluded that there appears to be a range of physiological levels of the protein TBCCD1, which if overtaken has a direct influence on the OFD1 protein, causing a decrease of the later in the cell. At last, it was also formulated the hypothesis that the TBCCD1 protein interacted with protein complexes constituted with OFD1 protein (Chevrier, et al., 2015), or even possibly the TBCCD1 protein itself associates with one of the complexes formed by the OFD1 protein.
Camelo, Carolina Santos Fernandes Lasbarrères. "Funções celulares da proteína centrossomal humana TBCCD1: proteínas interatuantes e papel na dinâmica dos microtúbulos." Master's thesis, 2015. http://hdl.handle.net/10451/22281.
Full textA proteína humana centrossomal TBCCD1 está envolvida na ligação do centrossoma ao núcleo. A diminuição dos níveis do TBCCD1 causa a quebra do eixo de polaridade intrínseca “Núcleo-Centrossoma-Complexo de Golgi” em consequência da anormal localização do centrossoma na periferia da célula a qual é acompanhada por uma desorganização do complexo de Golgi. Recentemente, foram identificadas variantes de splicing alternativo desta proteína que se localizam exclusivamente no citoplasma. Neste trabalho pretendeu-se esclarecer as funções da proteína TBCCD1 e da TBCCD1 variante 2, através i) do estudo do efeito da depleção da TBCCD1 na dinâmica dos microtúbulos e no citoesqueleto de actina e ii) da identificação das suas proteínas interatuantes, recorrendo ao método de BioID. Apesar de a TBCCD1 ter um domínio que a associa com a actina e interagir com várias proteínas que têm como funções polimerizar os filamentos de actina, em particular nas junções célula-célula e de adesão, não foi possível identificar nenhuma relação clara entre a TBCCD1 e os filamentos de actina nas células depletadas de TBCCD1. Este trabalho permitiu concluir que a TBCCD1 tem um papel importante na estabilização dos microtúbulos em células hTERT-RPE-1, em particular de uma subpopulação de microtúbulos que rodeia o núcleo e que se localiza preferencialmente do lado do centrossoma. Esta subpopulação de microtúbulos regula parcialmente o posicionamento do centrossoma em relação ao núcleo nestas células. Observou-se ainda que a depleção da TBCCD1 causa a dispersão da proteína centrossomal CEP170, que se associa a esta subpopulação de microtúbulos, e fica dispersa no citoplasma das células depletadas de TBCCD1. Neste trabalho foi também possível estabelecer o interatoma da TBCCD1 e da TBCCD1 variante 2. Assim, observou-se que a TBCCD1 interatua com proteínas com distintas funções celulares, estando principalmente envolvida na dinâmica dos microtúbulos, com a integridade do centrossoma e na polaridade celular, particularmente no estabelecimento e manutenção das junções celulares. A análise do interatoma, conjuntamente com os resultados obtidos no estudo da dinâmica dos microtúbulos, sugere que a TBCCD1 seja uma proteína adaptadora que promove a interação entre diferentes proteínas. A TBCCD1 variante 2, por outro lado, interage sobretudo com chaperones moleculares, proteínas mitocondriais e centroméricas. Embora à primeira vista estas interações possam parecer não estar relacionadas, uma análise mais detalhada mostra que a TBCCD1 variante 2 poderá estar envolvida na montagem e organização de estruturas complexas como os cinetocoros e a organização do genoma mitocondrial através da interação direta com os diferentes componentes ou através da interação com chaperones moleculares.
The human centrosomal protein TBCCD is involved in the connection between the centrosome and the nucleus. Lower TBCCD1 levels lead to a disrupture of the intrinsic cell polarity axis “Nucleus-Centrosome-Golgi Apparatus” due to an abnormal localization of the centrosome in the cell periphery, which is accompanied by the fragmentation of the Golgi apparatus. Recently, TBCCD1 splicing variants that localize exclusively in the cytoplasm have been identified. In this work we aimed at clarifying what are the cellular functions of TBCCD1 and TBCCD1 variant 2 by i) studying the effect of TBCCD1 depletion in the microtubule network and actin cytoskeletons dynamics and ii) identifying their interacting proteins using the BioID method. Although TBCCD1 has a domain able to associate this protein with actin and TBCCD1 interacts with several proteins that have a role in actin polymerization, particularly in cell-cell and adhesion junctions, it was not possible to identify a clear relationship between TBCCD1 and the actin filaments in TBCCD1-depleted cells. This work allowed us to conclude that TBCCD1 has an important role in microtubule stabilization in hTERT-RPE-1 cells, in particularly in a microtubule subpopulation surrounding the nucleus which is localized preferentially near the centrosome. This microtubule subpopulation partially regulates the centrosome-nucleus positioning. We also observed that TBCCD1 depletion causes cytoplasmic dispersion of the centrosomal protein CEP170, which is associated with this microtubule subpopulation. In this work we also established the TBCCD1 and TBCCD1 variant 2 interactomes. TBCCD1 interacts with several proteins with distinct functions, mainly involved in microtubule dynamics, centrosome integrity and cell polarity, and also in the establishment and maintenance of cell junctions. Both the interactome analysis and the results obtained with the microtubule dynamic studies suggest that TBCCD1 may function as a promoter of the interaction between distinct proteins. TBCCD1 variant 2, in other hand, interacts mainly with molecular chaperones and mitochondrial and centromeric proteins. Although it may seem that these interactions are not related with which other, a more detailed analysis shows that TBCCD1 variant 2 protein can be involved in the assembly and organization of complex structures, such as the kinetochores and the organization of the mitochondrial genome either through the direct interaction with the different components or through the interaction with molecular chaperones.
Gonçalves, João António Lourenço 1981. "Caracterização da proteína centrossomal TBCCD1, em linhas celulares humanas e durante o desenvolvimento de Danio rerio." Doctoral thesis, 2010. http://hdl.handle.net/10451/2231.
Full textO centrossoma é o principal organizador de microtúbulos das células animais e desempenha funções celulares fundamentais estando implicado por exemplo, na organização espacial do citoplasma, no posicionamento de organelos como o complexo de Golgi, na formação do fuso mitótico, no estabelecimento da polaridade celular, na migração celular e na ciliogénese. O centrossoma encontra-se activamente associado com o núcleo na célula em interfase. Contudo, os mecanismos subjacentes a este posicionamento não se encontram totalmente esclarecidos. Os cofactores da tubulina (TBCA-E), proteínas que participam na via de “folding” da tubulina, têm vindo a ser descritos como tendo papéis cruciais na célula, nem sempre directamente relacionados com o “folding”. Um dos cofactores menos estudado, o TBCC, actua como uma GAP (de “GTPase activating protein”) para a -tubulina. A proteína RP2 (de “retinitis pigmentosa protein”), relacionada com o TBCC nos seus domínios funcionais, também actua como GAP para a -tubulina e para a proteína Arl3 (de “ADP-ribosylation factor-like 3”). Neste trabalho descrevemos a primeira caracterização da proteína humana TBCCD1 (de “TBCC-domain containing protein”), que possui os domínios TBCC e CARP, sendo portanto relacionada com o TBCC e a proteína RP2. Porém, o TBCCD1 não parece possuir actividade de GAP para a tubulina, uma vez que um ensaio de complementação em Saccharomyces cerevisae, mostrou que o TBCCD1 é incapaz de reverter os fenótipos da delecção do gene cin2 (homólogo do tbcc). Em células humanas observámos que o TBCCD1 se localiza no centrossoma, na zona mediana do fuso mitótico, no “midbody” e no corpo basal de cílios primários e motores. Com o silenciamento do tbccd1 em células RPE-1 observou-se: i) um aumento do tamanho das células e um atraso/paragem do ciclo celular em G1; ii) um afastamento do centrossoma em relação ao núcleo; iii) a desorganização do complexo de Golgi; iv) uma diminuição da eficiência de produção de cílios primários; v) uma migração celular dirigida mais lenta. Concluindo, a proteína TBCCD1 humana deverá ter um papel crucial in vivo resultante do seu papel na manutenção da associação do centrossoma ao núcleo o que afecta a divisão celular, a organização do Golgi, a ciliogénese e a migração celular. Esta hipótese é suportada por resultados preliminares obtidos com o silenciamento do gene tbccd1 em embriões de peixe zebra que resulta em problemas no desenvolvimento embrionário como a curvatura dos embriões e edema cardíaco. Curiosamente, estes fenótipos têm vindo a ser correlacionados com problemas ciliares.
Fundação para a Ciência e a Tecnologia (FCT)-bolsa de Doutoramento (SFRH/BD/24532/2005); Instituto Gulbenkian de Ciência (IGC)
Calapez, Mariana de Amaral Figueira Guerreiro. "Estudo da proteína humana centrossomal TBCCD1 em condições de stress oxidativo causado por H2O2 em estado estacionário." Master's thesis, 2013. http://hdl.handle.net/10400.26/14380.
Full textNos últimos anos têm sido realizados inúmeros estudos sobre espécies reactivas de oxigénio (EROs), devido ao seu envolvimento em processos como o cancro e envelhecimento. Contudo, as EROs são subprodutos normais do metabolismo celular, podendo também ter origem em fontes exógenas à célula. As ERO, como o peróxido de hidrogénio (H2O2), são espécies muito instáveis e quimicamente bastante reactivas, com capacidade de causar vários danos graves nas diferentes biomoléculas. O H2O2 é in vivo um oxidante suave contudo, devido à sua permeabilidade através das membranas celulares tem sido alvo de grande interesse, estando implicado em processos de desencadeamento e modulação de vias de sinalização celulares. O interesse de estudar o H2O2 como um possível regulador de algumas proteínas centrossomais surgiu através de um estudo retrospectivo, em que foi verificada a associação entre altos níveis de H2O2, bolus addiction, e a hiperamplificação dos centrossomas e formação de fusos mitóticos multipolares. Posto isto, como consequência foi verificado um aumento de células multinucleadas, este que por sua vez está associado a vários processos patológicos. Face a estes resultados, propôs-se como hipótese que o H2O2 em baixas concentrações, semelhantes às encontradas fisiologicamente, poderia modelar os níveis de algumas proteínas centrossomais, como o TBCCD1 (de TBCC-domain containing protein 1), a γ-tubulina e a pericentrina. O TBCCD1 é um potencial regulador do posicionamento do centrossoma e por consequência da organização interna da célula. A γ-tubulina e a pericentrina desempenham funções específicas ao nível da nucleação dos microtúbulos. Neste estudo, foram usadas duas linhagens celulares (hTERT- RPE-1 e HeLa) as quais foram expostas, através do método de titulação de H2O2 em estado estacionário a uma concentração constante de 10 e 25μM de H2O2 , respectivamente, durante um determinado período de tempo. Os níveis das proteínas em estudo foram analisados por Western blotting. Como resultados, não foram identificadas alterações significativas nos níveis da proteína TBCCD1, em ambas as linhagens, e na γ-tubulina em h-TERT-RPE-1. No caso da pericentrina (hTERT- RPE-1 e HeLa), foi observada uma diminuição dos níveis proteicos, podendo estar relacionado com uma diminuição da capacidade nucleadora do centrossoma, uma vez que a pericentrina recruta os complexos γ- TuRC para esta estrutura.
Carvalhal, Sara Isabel Guerra. "Estudo da proteína humana centrossomal TBCCD1 em condições de stress oxidativo causadas por H202 em estado estacionário." Master's thesis, 2010. http://hdl.handle.net/10451/5364.
Full textO peróxido de hidrogénio (H2O2) embora seja um oxidante relativamente fraco, é capaz de alterar o nível de oxidação dos grupos tióis ao reagir com resíduos de cisteínas. Essas propriedades tornam o H2O2 uma das espécies reactivas de oxigénio (ERO) com potencialidade para participar em vias de sinalização. Deste modo, o desencadeamento de uma determinada via de sinalização, ou a sua modulação, deverá ocorrer pelo aumento temporário das concentrações de H2O2, como por exemplo, durante a resposta inflamatória. Por outro lado, a exposição prolongada a algumas ERO têm vindo a ser relacionada com o início, progressão e desenvolvimento tumoral. Muitos dos tumores são caracterizados por aneuploidia e anormalidades centrossomais. Por exemplo, células de mamífero expostas a H2O2, por bolus addition, apresentam centrossomas supra-numerários. Neste contexto iniciou-se o estudo da influência de concentrações sinalizadoras de H2O2 nos níveis de duas proteínas centrossomais, a proteína TBCCD1 (TBCC-domain containing protein 1) e a y−tubulina nas linhas celulares humanas HeLa e hTERT-RPE-1. O TBCCD1 é um potencial regulador do posicionamento do centrossoma e da organização citoplasmática, a y−tubulina é uma proteína chave na nucleação dos microtúbulos nos centros organizadores de microtúbulos, como o centrossoma. Por western blot mostrou-se, em ambas as linhas celulares, o aumento dos níveis de TBCCD1 ao longo do tempo de exposição de H2O2 em estado estacionário. A análise da velocidade de consumo de H2O2 em células hTERT-RPE-1 que sobre-expressam a proteína de fusão TBCCD1-GFP mostrou um relação directa desta com o aumento dos níveis de TBCCD1-GFP. Esta proteína, na presença de H2O2, varia de modo análogo à proteína endógena. Estudos similares mostraram a diminuição dos níveis de y−tubulina ao longo do tempo de exposição de H2O2. Por microscopia de imunofluorescência indirecta observou-se também a diminuição dos níveis desta proteína no centrossoma em células HeLa. Observou-se ainda uma alteração da capacidade de nucleação dos microtúbulos pelo centrossoma e uma modificação na organização destes após repolimerização em células previamente tratadas com nocodazole e após remoção desta. No conjunto, estes resultados mostram que ambos os níveis destas proteínas variam na presença de baixos concentrações de H2O2, constituindo este trabalho uma abordagem inicial do efeito do H2O2 em concentrações reguladoras no centrossoma.
The hydrogen peroxide (H2O2) although a relatively weak oxidant, is highly reactive with sulfhydryl groups. These properties make the H2O2 a reactive oxygen species (ROS) with the potential to participate as a regulator in signaling pathways. Thus, the temporary increase in the concentrations of H2O2 should trigger or modulate a signal pathway, such as during the inflammatory response. Moreover, prolonged exposure to some ROS has been related with the initiation, progression and tumor development. Many tumors are characterized by aneuploidy and centrosomal abnormalities. For example, mammalian cells exposed to H2O2 by bolus addition showed supra-numerary centrosomes. In this context we began the study of the influence of signaling concentrations of H2O2 in the levels of two centrosomal proteins, protein TBCCD1 (TBCC domain-containing protein 1) and y − tubulin in HeLa and hTERT-RPE-1 human cell lines. The TBCCD1 is a potential regulator of the positioning of the centrosome and cytoplasmic organization and the y − tubulin is a key protein in the nucleation of microtubules on microtubule organizing centers, such as the centrosome. By western blot, we detected in both cell lines, increased levels of TBCCD1 over time of exposure to a steady state of H2O2. The analysis of H2O2 consumption by intact hTERT-RPE-1 cells that over-expresses the fusion protein TBCCD1-GFP showed a direct relationship of this with increased levels of TBCCD1-GFP. Noteworthy, in the presence of H2O2, the TBCCD1-GFP levels, showed the same variation that those of the endogenous protein. Similar studies showed that −tubulin levels decreased of upon an exposition to H2O2. By immunolocalization microscopy we observed in HeLa cells a decrease of y − tubulin’s levels at the centrosome. To investigate if this observation has an impact in the ability of centrosomes to nucleate microtubules we have treated HeLa cells, previously exposed to steady-state levels of H2O2, with the antimitotic drug nocodozole. After washing out this microtubule depolymerizing agent we follow microtubule repolymerization by immunofluorescence microscopy. We observed that cells treated with H2O2 present a different ability to nucleate microtubules in comparison to control cells. At end these cells presented a distinct organization of the microtubule cytoskeleton. Taken together the results presented in this work show that a low concentration of H2O2 promotes a variation of the TBCCD1 and y − tubulin’s levels. Therefore, this work constitutes an initial approach to the study of the impact at the centrosome of H2O2 at levels expected for a signaling role.
Peneda, Catarina Sofia de Araújo. "Estudo da função das proteínas variantes da TBCCD1 humana, uma proteína chave na ligação do centrossoma ao núcleo." Master's thesis, 2015. http://hdl.handle.net/10451/22454.
Full textCom a identificação e o estudo do gene humano tbccd1, foi identificada uma proteína, a TBCCD1, por ele codificada. Esta proteína foi então descrita como sendo uma proteína centrossomal, que se localiza também nos corpos basais de cílios primários e no corpo médio. Foram identificados dois novos transcritos do tbccd1 resultantes de splicing alternativo, nomeadamente, variante 2 e variante 3, sendo que o transcrito variante 1 codifica a proteína TBCCD1 variante 1 inicialmente descrita. O knockdown do tbccd1 utilizando siRNAs provoca vários fenótipos em células hTERT RPE-1, como o aumento da distância centrossoma-núcleo, a fragmentação do complexo de Golgi e a diminuição na velocidade de migração em ensaios de fecho da ferida. Assim, este trabalho teve como principal objetivo o estudo da função biológica de cada uma das variantes identificadas. Estudou-se a localização celular de cada uma das variantes identificadas em diferentes linhas celulares humanas. Observou-se que as proteínas TBCCD1 variante 2 e TBCCD1 variante 3 têm uma localização citoplasmática em todas as situações analisadas. Pelo contrário, como tinha já sido observado, a proteína TBCCD1 variante 1 localiza-se no centrossoma, no corpo médio e nos corpos basais de cílios primários. Curiosamente, observou-se que a localização desta proteína no corpo médio é dependente dos microtúbulos, ao contrário do que acontece com a sua localização centrossomal. Esta observação sugere então uma interação com microtúbulos do corpo médio onde existe uma acumulação de microtúbulos acetilados. Observou-se também que a sobre expressão das proteínas TBCCD1 variante 1 ou TBCCD1 variante 2 provoca uma diminuição nos níveis de α-tubulina acetilada, assim como de γ-tubulina e de β-actina. Já a sobre expressão da proteína TBCCD1 variante 3 não parece afetar os níveis dos componentes do citoesqueleto analisados. Estudou-se também se o fenótipo do aumento da distância centrossoma-núcleo pode ser provocado por apenas uma das variantes ou resulta da ação combinada de mais do que uma variante. Para isso, realizaram-se ensaios de recuperação do fenótipo, tendo-se observado que as proteínas TBCCD1 variante 1 e TBCCD1 variante 2 revertem parcialmente o fenótipo em estudo. Para além disso, realizou-se um estudo recorrendo a RT-qPCR no qual se observou que as variantes têm uma função de regulação entre si. A sobre expressão das proteínas TBCCD1 variante 1 ou TBCCD1 variante 2 leva À alteração dos níveis dos transcritos das variantes 1, 2 e 3. Já a sobre expressão da proteína TBCCD1 variante 3 afeta apenas os níveis do transcrito variante 3 endógeno. Em conjunto, os resultados obtidos neste estudo indicam que as proteínas codificadas pelos três transcritos identificados deverão ter diferentes funções celulares. Para além disso, as proteínas TBCCD1 variante 1 e TBCCD1 variante 2 afetam os níveis de α-tubulina acetilada, γ-tubulina e β-actina, o que pode afetar, por exemplo, a organização do complexo de Golgi e a migração celular, através da regulação da dinâmica dos microtúbulos. Assim, estes resultados contribuem de forma decisiva para a compreensão dos fenótipos observados nas experiências do knockdown do tbccd1.
When the human gene tbccd1 was identified and studied, a protein, TBCCD1, that it encoded was also identified. This protein was then described as a centrossomal protein that also localizes at the basal bodies of primary cilia and to the midbody. Two new transcripts of tbccd1 originated by alternative splicing were identified, namely, variant 2 and variant 3, and it is now known that variant 1 encodes the TBCCD1 protein initially described. The knockdown of tbccd1 using siRNAs causes several phenotypes in hTERT RPE-1 cells, such as the increase in centrosome-nucleus distance, fragmentation of the Golgi apparatus and a decrease of the cell migration in wound healing assays. The main goal of this work was to study the biological function of each of the identified tbccd1 variants. In this study, the cellular localization of each of the variants in different human cell lines was accessed. TBCCD1 variant 2 and TBCCD1 variant 3 proteins have a cytoplasmic localization in all the situations analyzed. As it has already been described, TBCCD1 variant 1 protein localizes at the centrosome, the basal bodies of primary cilia and to the midbody. Interestingly, it was shown that the midbody localization of this protein is dependent on microtubules, while its centrossomal localization is not. This observation suggested an interaction of this protein with a population of microtubules in the midbody where they are highly acetylated. Overexpression of TBCCD1 variant 1 or TBCCD1 variant 2 causes a decrease on acetylated α-tubulin levels, and also on γ-tubulin and β-actin levels. The overexpression of TBCCD1 variant 3 does not seem to affect the levels of any of the cytoskeleton components analyzed. It was also studied if the increased centrosome. Nucleus distance phenotype is caused by only one or a combination of the identified variants. In order to do this, we performed phenotype rescue assays, and it was shown that overexpression of TBCCD1 variant 1 or TBCCD1 variant 2 can partially rescue this phenotype. Moreover, we used RT-qPCR to study whether the identified variants have a regulatory function between them, and showed that TBCCD1 variant 1 or TBCCD1 variant 2 overexpression affects the levels of the three transcripts. On the other hand, the overexpression of TBCCD1 variant 3 only affects variant 3 endogenous transcript levels. Taken together, the results obtained in this study indicate that the proteins encoded by the three transcripts might have different cellular functions. Furthermore, TBCCD1 variant 1 and TBCCD1 variant 2 affect acetylated α-tubulin, γ-tubulin and β-actin levels which may be implicated on, for example, Golgi apparatus organization and cell migration by the regulation of microtubules dynamics. Therefore, this results contributed to the comprehension of the causes of the tbccd1 knockdown phenotypes.
Capo-Chichi, José-Mario. "Exploration génomique de la déficience intellectuelle." Thèse, 2014. http://hdl.handle.net/1866/11768.
Full textIntellectual disability (ID) regroups greatly heterogeneous conditions that are characterized by early-onset cognitive impairment. ID affects about 1-3% of Western populations; but its prevalence is much higher in deprived regions of the world where socio-demographic factors like poor healthcare, lack of resources and parental consanguinity prevail. Non-genetic factors are involved in the etiology of ID; approximately 25% of ID cases are of genetic origin. Traditionally, the molecular basis of ID have been assessed through cytogenetic analyses, genetic mapping and candidate gene approaches. These classical genetic tools are still put to the test in the study of complex diseases like ID. Until recently, X-linked ID cases were the main focus of studies on ID with more than hundred ID genes identified only on the X chromosome. Compound heterozygous mutations are identified in autosomal forms of ID, in the context of non-consanguineous unions. However, the occurrence of such mutations is rare in outbred populations, so that dominant de novo mutations are most common in unrelated individuals. Homozygous mutations are expected in consanguineous unions or in populations marked by a founder effect. In fact, the molecular bases of autosomic recessive ID have been almost exclusively studied in populations with high consanguinity rates. ID remains unsolved in more than 60% of patients. In the absence of environmental factors associated with ID in these individuals, it is possible to consider that unidentified genetic factors are involved in these unexplained ID cases. In this research project, we used next generation sequencing technologies to highlight the genetic causes of ID in twenty families were an autosomal recessive mode of inheritance is expected. We prioritized the use of whole-exome sequencing, namely all coding exons in the genome of this individual. In our analyses, we filtered out variants that were too common in control individuals to describe a rare condition like ID. We focussed our attention on rare autosomic recessive varaiants (homozygous and compound heterozygous), these mutations were confirmed by Sanger re-sequencing to segregate with an autosomal recessive mode of inheritance in the family. We identified mutations in candidate genes for ID in some of the family analysed, we validated the functional impact of the mutations in these genes to confirm their involvement in the pathophysiology of ID in the family studied. We explained the molecular basis of ID in eight of the families studied. We identified the second case of Warsaw-Breakage-Syndrome, a rare genetic disorder characterised by dysfunction of the RNA helicase DDX11. We showed that disruption in TBC1D7, a functional subunit of the TSC1-TSC2 protein complex, cause ID and megalencephaly. We demonstrated that ASNS, the Asparagine Synthetase gene, is defective in patients with congenital microcephaly and progressive encephalopathy. We showed that the gene coding for the mitochondrial protein MAGMAS is involved in the pathophysiology of a condition characterised by developmental delay and severe skeletal dysplasia. We identified a truncating mutation in SPTBN2, encoding for the spinocerebellar ataxia 5 proteins, in a family with ID and spinocerellar ataxia. We also identified a mutation in a gene involved in the biosynthetic pathway of glycosylphosphatidylinositol anchors; the mutation in PIGN may cause the epilepsy and hypotonia features observed in the affected individuals of that family. Finally, we identified a loss of function mutation in CLPB, coding for a mitochondrial chaperone, in individuals with severe encephalopathy, hypereklexia and 3-methylglutaconic aciduria. The diagnostic potential of next generation sequencing technologies is undeniable. These technologies will revolutionize the world of molecular genetics; they will help deciphering the molecular basis of complex diseases like ID.
Ferreira, David Flávio Carmelino. "Ciliopatias, doenças humanas em expansão: o papel da proteína KIAA0753." Master's thesis, 2019. http://hdl.handle.net/10451/40607.
Full textAlthough poorly studied so far, the centrosomal protein KIAA0753, also known as Moonraker or OFIP, has been implied in the recruitment of other proteins to the centrosome, being involved in various cellular functions, such as centriolar duplication and microtubule stabilization. Moreover, there are mutated versions of the gene that codifies for this protein associated with a group of rare diseases called ciliopathies. Ciliopathies are typified by clinical manifestations that often overlap, such as infertility, obesity, problems regarding cerebral and skeleton development, blindness and polycystic kidneys. Thus, it is assumed that KIAA0753 also has a role in ciliogenesis. In this work, we aimed at clarifying the role of KIAA0753 in the centrosome, by studying the effect of KIAA0753 depletion both in centrosome and in the dynamics of the microtubule cytoskeleton. Our study allowed us to conclude that KIAA0753 may be involved in the maintenance of the centrosome structure and, consequently, in the organization of the microtubule skeleton. Moreover, it was also possible to show that KIAA0753 may, in fact, be involved in the assembly and regulation of cilia length. The protein KIAA0753, as well as other proteins encoded by genes associated with ciliopathies, was identified in work done by our research group as belonging to the interactome of the human centrosomal protein containing the TBCC domain (TBCCD1), which is involved in the correct positioning of the centrosome and in the biogenesis of cilia. Thus, in a parallel study, we also aimed to study whether TBCCD1 interacts with KIAA0753 because TBCCD1 is also a component of the ternary complex that KIAA0753 is part of, or whether this interaction involves an indirect mechanism. Although it was not possible to obtain any evidence for TBCCD1 being one of the constituents of the complex, it was possible to conclude that a functional relationship between the two proteins exists, and that TBCCD1 may have a role in the recruitment of KIAA0753 to the centrosome, which supports the hypothesis of tbccd1 being a new ciliopathic gene.
Stefanov, Anguel Neykov. "Bulked segregant analysis as a new tool for identification and cloning of genes in Chlamydomonas reinhardtii. Identification of TBC1." Thesis, 2006. http://spectrum.library.concordia.ca/9009/1/MR20726.pdf.
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