O papel da via de reparo por excis?o de nucleot?deos na resposta celular ao estresse oxidativo e o estudo de altera??es neuronais in vitro associadas a s?ndrome de Cockayne

Leal, Ang?lica Maria de Sousa

29 September 2016

Submitted by Automa??o e Estat?stica (sst@bczm.ufrn.br) on 2017-04-17T23:12:49Z No. of bitstreams: 1 AngelicaMariaDeSousaLeal_TESE.pdf: 6582579 bytes, checksum: 5f557c13b6008a7677f62167674670fe (MD5) / Approved for entry into archive by Arlan Eloi Leite Silva (eloihistoriador@yahoo.com.br) on 2017-04-20T22:14:08Z (GMT) No. of bitstreams: 1 AngelicaMariaDeSousaLeal_TESE.pdf: 6582579 bytes, checksum: 5f557c13b6008a7677f62167674670fe (MD5) / Made available in DSpace on 2017-04-20T22:14:08Z (GMT). No. of bitstreams: 1 AngelicaMariaDeSousaLeal_TESE.pdf: 6582579 bytes, checksum: 5f557c13b6008a7677f62167674670fe (MD5) Previous issue date: 2016-09-29 / Coordena??o de Aperfei?oamento de Pessoal de N?vel Superior (CAPES) / No contexto da resposta ao estresse oxidativo, o reparo por excis?o de bases (BER) ? considerado a principal via para o reparo de les?es oxidadas. Entretanto, estudos indicam o papel do reparo por excis?o de nucleot?deos (NER) na corre??o dessas les?es. Al?m disso, fatores do NER j? tiveram fun??es descritas em outros processos biol?gicos, sendo importante que se busque novas fun??es biol?gicas que possam ser associadas aos fen?tipos das s?ndromes causadas por muta??es nos genes da via NER, dentre elas a Xeroderma pigmentoso grupo de complementa??o A, associada a muta??es em XPA, al?m da s?ndrome de Cockayne, ocasionada por muta??es no gene CSB. Nesse contexto, c?lulas deficientes em XPA (XP12RO) ou CSB (CS1AN) foram submetidas ao estresse oxidativo com per?xido de hidrog?nio (H2O2) e apresentaram um perfil de sensibilidade ao agente, indicando que a aus?ncia dessas prote?nas sensibilizou as linhagens a essa condi??o. A an?lise do transcriptoma de c?lulas XP12RO indicou a diminui??o na express?o de genes com papel na resposta ao dano no DNA e que promovem a sobreviv?ncia celular em resposta ao estresse oxidativo. Nesse cen?rio, os resultados indicaram que XPA pode atuar na regula??o da express?o de genes essenciais ? resposta ao dano no DNA e na sobreviv?ncia ao estresse oxidativo (EGR1, GADD45A, GADD45B e XPC). Por outro lado, a an?lise do transcriptoma de c?lulas CS1AN indicaram a diminui??o na express?o de genes-chave nos processos biol?gicos como transcri??o, processamento de mRNA, prote?lise via ubiquitina-proteassoma ou respira??o celular, indicando um poss?vel papel central da prote?na CSB na regula??o desses processos, em resposta ao estresse oxidativo. Al?m disso, dado o fen?tipo de neurodegenera??o associada a s?ndrome de Cockayne, c?lulas progenitoras neurais (NPCs) e neur?nios derivados de c?lulas-tronco pluripotentes induzidas (iPSCs) deficientes em CSB foram utilizados como modelos de estudo de altera??es neuronais in vitro, de modo que os resultados indicaram que assim como observado nos fibroblastos, c?lulas NPCs deficientes em CSB tamb?m apresentaram sensibilidade a agentes oxidantes. Ainda, os resultados mostraram que assim como observado no transcriptoma de fibroblastos CS1AN, dada a diminui??o na express?o de genes com papel na respira??o celular, as an?lises do consumo de oxig?nio em neur?nios deficientes em CSB indicaram uma poss?vel disfun??o mitocondrial, caracterizada pelo decr?scimo na taxa de consumo de oxig?nio basal e pela diminui??o das capacidades respirat?rias m?xima ou de reserva dessas c?lulas, sugerindo o papel de CSB no metabolismo mitocondrial em ambos os modelos celulares utilizados neste estudo. / In oxidative stress response, the base excision repair (BER) is considered the major pathway for repair of oxidative lesions. However, an increasing number of studies have indicated the role of nucleotide excision (NER) in the repair of these lesions. In addition, some NER factors had functions beyond the role in repair already described and it is important to search for new molecular functions that can be associated to the classical phenotypes of the syndromes caused by mutations in NER genes: Xeroderma pigmentosum complementation group A, caused by mutations in XPA and Cockayne syndrome, caused by mutations in CSB. In this context, XPA (XP12RO) or CSB (CS1AN) deficient cells were submitted to oxidative stress induced by Hydrogen peroxide (H2O2) and the results indicated that both cell lines showed sensitivity to this agent. Furthermore, the transcriptome of XP12RO cells revealed the downregulation of genes that play a role in DNA damage response and promote cell survival in response to oxidative stress. In this scenario, the results indicated that XPA regulates the expression of genes that play a key role in DNA damage response and promote survival in response to stress (EGR1, GADD45A, GADD45B and XPC). On the other hand, the transcriptome analysis of CS1AN cells showed the downregulation of genes that play a key role in biological processes such as transcription, mRNA processing, protein degradation by the ubiquitin?proteasome pathway proteolysis or cellular respiration, indicating a possible role for CSB protein in the regulation of these processes, in response to oxidative stress. In adittion, given the neurodegeneration phenotype associated to Cockayne syndrome, neural progenitor cells (NPCs) and neurons derived from CSB deficient induced pluripotent stem cells (iPSCs) were used as cellular models to analyse neuronal changes in vitro. The results showed that, as observed in fibroblasts CS1AN, NPCs also presented sensitivity to oxidizing agents. Furthermore, as indicated in the transcriptome data from CS1AN fibroblasts, given the downregulation of genes that play a pivotal role in cellular respiration, the analysis of oxygen consumption rates in CSB deficient neurons also indicated a mitochondrial dysfunction characterized by the decrease in oxygen consumption basal rate and a lower maximum respiratory and reserve capacities, suggesting that the lack of functional CSB leads to a mitochondrial dysfunction in both cellular models used in this study. / 2017-12-09

CNPQ::CIENCIAS BIOLOGICAS::BIOQUIMICA

Estresse oxidativo

Reparo por excis?o de bases (BER)

Reparo por excis?o de nucleot?deos (NER)

XPA

CSB

S?ndrome de Cockayne

NPCs

Neur?nios

Respira??o celular

Altera??es na linhagem celular e organiza??o neuronal do giro denteado em dois modelos animais de epilepsia

Moura, Daniela Maria de Sousa

30 August 2017

Submitted by Automa??o e Estat?stica (sst@bczm.ufrn.br) on 2017-10-18T21:17:40Z No. of bitstreams: 1 DanielaMariaDeSousaMoura_TESE.pdf: 5064072 bytes, checksum: ff797a9a6f4cca34baad638e77a8a3f2 (MD5) / Approved for entry into archive by Arlan Eloi Leite Silva (eloihistoriador@yahoo.com.br) on 2017-10-30T19:11:36Z (GMT) No. of bitstreams: 1 DanielaMariaDeSousaMoura_TESE.pdf: 5064072 bytes, checksum: ff797a9a6f4cca34baad638e77a8a3f2 (MD5) / Made available in DSpace on 2017-10-30T19:11:36Z (GMT). No. of bitstreams: 1 DanielaMariaDeSousaMoura_TESE.pdf: 5064072 bytes, checksum: ff797a9a6f4cca34baad638e77a8a3f2 (MD5) Previous issue date: 2017-08-30 / As c?lulas granulares do hipocampo s?o um dos poucos tipos de neur?nios gerados no sistema nervoso central de mam?feros adultos. O modelo atual de neurog?nese no hipocampo adulto assume que c?lulas tronco neurais (CTN) geram progenitores com potencial restrito ? gera??o de neur?nios ou astr?citos. Est?mulos ambientais e condi??es patol?gicas podem alterar a progress?o da linhagem, modulando a prolifera??o, diferencia??o, sobreviv?ncia e integra??o sin?ptica dos neur?nios gerados. Por exemplo, a Epilepsia do Lobo Temporal mesial (ELT), a forma mais comum de epilepsia em adultos, est? associada a altera??es na taxa de neurog?nese hipocampal adulta. Neste trabalho, n?s utilizamos dois modelos experimentais de ELT para avaliar os efeitos de um insulto epileptog?nico (i.e., status epilepticus, SE) sobre a linhagem e amadurecimento celular no giro denteado adulto. Atrav?s da t?cnica de fate-mapping utilizando animais Dcx-CreERT2/CAG-CAT-GFP, n?s acompanhamos o destino de c?lulas que apresentavam o promotor do gene doublecortin (DCX) ativado antes ou depois da inje??o intrahipocampal dos agentes convulsivantes ?cido ca?nico ou pilocarpina. Desta forma, pudemos avaliar o efeito destas drogas sobre progenitores e neur?nios imaturos DCX+ gerados antes ou ap?s o tratamento. Em ambos os modelos, foram observados um aumento de neurog?nese e altera??es no posicionamento e morfologia de c?lulas granulares, conforme descri??es pr?vias na literatura. Altera??es neuronais, tais como localiza??o ect?pica e presen?a de dendritos basais, foram observadas tanto em c?lulas geradas antes quanto ap?s a indu??o do SE, embora com frequ?ncias distintas. No entanto, apenas no hipocampo ipsilateral ? inje??o de ?cido ca?nico n?s observamos dispers?o da camada granular e morte neuronal em CA1 e CA3, apesar da atividade parox?stica epil?ptica ocorrer em ambos os hipocampos. Surpreendentemente, o aumento da neurog?nese em animais que receberam ?cido ca?nico foi restrito ao hipocampo contralateral, enquanto no lado ipsilateral foi observado um significativo aumento na gera??o de astr?citos a partir dos progenitores DCX+. Al?m disso, tamb?m observamos neste modelo a presen?a de c?lulas com morfologia e marcadores de CTNs, sugerindo que progenitores DCX+ poderiam regredir para estados mais primitivos na linhagem celular do hipocampo adulto. O aumento da astrogliog?nese no lado ipsilateral ? inje??o de ?cido ca?nico foi associado a uma degenera??o de interneur?nios parvalbumina (PV)+ no hipocampo, sugerindo que a atividade gaba?rgica poderia estar contribuindo para o redirecionamento da linhagem celular. Em conjunto, nossos dados indicam que a linhagem celular no giro denteado n?o ? unidirecional e irrevers?vel, e que o aumento da atividade el?trica neuronal induzida por ?cido ca?nico e pilocarpina t?m efeitos diferentes sobre a diferencia??o celular e destino fenot?pico dos progenitores e neur?nios nessa regi?o. Esses resultados imp?em a necessidade de revermos o modelo atual de neurog?nese hipocampal adulta e tamb?m indicam que diferentes modelos animais de epilepsia produzem altera??es celulares distintas no hipocampo adulto e, portanto, poderiam representar diferentes graus/est?gios da patologia. / The granular cells of the hippocampus are one of the few types of neurons generated in the central nervous system of adult mammals. The current model of neurogenesis in the adult hippocampus assumes that neural stem cells (NSCs) give rise to progenitors restricted to the generation of neurons or astrocytes. Environmental stimuli and pathological conditions can alter the lineage progression, modulating cell proliferation, differentiation, survival and synaptic integration of newly generated neurons. For example, mesial Temporal Lobe Epilepsy (TLE), the most common form of epilepsy in adults, is associated with changes in the rate of adult hippocampal neurogenesis. In this work, we used two experimental TLE models to evaluate the effects of an epileptogenic insult (i.e., status epilepticus, SE) on the cell lineage and neuronal maturation in the adult dentate gyrus. Using Dcx-CreERT2 / CAG-CAT-GFP animals, we fate mapped the fate of cells expressing the doublecortin gene (DCX) either before or after intrahippocampal injection of the convulsive agents kainic acid or pilocarpine. In this way, we could evaluate the effect of these drugs on DCX+ progenitors and immature neurons generated before or after treatment. In both models, we observed an increase in neurogenesis and changes in the positioning and morphology of granular cells, according to previous descriptions in the literature. Neuronal aberrations, such as ectopic localization and presence of basal dendrites, were observed both in cells generated before and after induction of SE, albeit at different frequencies. However, only in the hippocampus ipsilateral to the injection of kainic acid we observed granule cell dispersion and neuronal death in CA1 and CA3, although the paroxysmal epileptic activity occurred in both hippocampi. Surprisingly, the increase in neurogenesis in animals that received kainic acid was restricted to the contralateral hippocampus, whereas on the ipsilateral side a significant increase in astrocyte generation was observed within the DCX+ progenitor lineage. In addition, we also observed the presence of cells with NSC hallmarks, suggesting that DCX+ progenitors could regress to more primitive states in the adult hippocampal cell lineage. The increased astrogliogenesis on the ipsilateral side to the injection of kainic acid was associated with a degeneration of parvalbumin (PV)+ interneurons in the hippocampus, suggesting that GABAergic activity could be contributing to the rerouting of the DCX+ progenitor cell lineage. Taken together, our data indicates that the cell lineage in the dentate gyrus is neither unidirectional nor irreversible, and that the increased neuronal electrical activity induced by kainic acid and pilocarpine have different effects on cell differentiation, as well as on the fate of progenitors and neurons in that region. These results highlight the need to review the current model of adult hippocampal neurogenesis and also indicate that different animal models of epilepsy produce distinct cellular alterations in the adult hippocampus and could therefore represent different degrees / stages of the pathology.

CNPQ::OUTROS::CIENCIAS: NEUROCI?NCIAS

Hipocampo adulto

Neurog?nese

Astrogliog?nese

Epilepsia

?cido ca?nico

Pilocarpina

Interneur?nios gaba?rgicos

Dirpers?o das c?lulas granulares

Neur?nios ect?picos

Dendritos basais hilares

Camundongo