Probing the Molecular Mechanisms Underlying Familial Amyotrophic Lateral Sclerosis: New Insight into Unfolding and Misfolding Mechanisms of the Cu, Zn Superoxide Dismutase

Mulligan, Vikram

18 December 2012

While great strides have been made in treating many classes of human disease, the late-onset neurodegenerative diseases continue to elude modern medicine. These diseases, which include Alzheimer's disease (AD), Parkinson's disease (PD), Huntington's disease (HD), the transmissible spongiform encephalopathies (TSEs), and amyotrophic lateral sclerosis (ALS), involve accumulation of insoluble aggregates of one or more causative proteins, leading to progressive loss of central nervous system neurons, progressively worsening neurological symptoms, and eventual patient death. All of these diseases are currently incurable and fatal. In the case of ALS, progressive death of upper and lower motor neurons leads to full-body paralysis, respiratory difficulty, and patient death. Of the subset of ALS cases showing familial inheritance, approximately 20% are caused by mutations in the SOD1 gene, encoding the Cu, Zn superoxide dismutase (SOD1). These mutations do not have the common property of impairing SOD1's normal function as a free radical scavenger. Instead, they are thought to increase the protein's likelihood of misfolding and aggregating via a poorly-understood aggregation cascade. It is believed that species populated along the misfolding and aggregation pathway may prove to be good targets for therapies designed to block accumulation of downstream toxic species, or to prevent aberrant protein-protein interactions responsible for neurotoxicity. In this thesis, several new techniques are developed to enable detailed elucidation of the SOD1 unfolding and misfolding pathways. Time-resolved measurements collected during SOD1 unfolding or misfolding of release of bound Cu and Zn, of changes in intrinsic fluorescence, of exposure of hydrophobic surface area, and of alterations in the chemical environment of histidine residues, are presented. A new mathematical analysis technique named the Analytical Laplace Inversion Algorithm is developed for rapid extraction of mechanistic information from these time-resolved signals. These tools are applied to the construction of the most detailed models to date of the unfolding and misfolding mechanisms of WT and ALS-causing mutant SOD1. The models presented identify several well-populated unfolding and misfolding intermediates that could serve as good targets for therapies designed to address the fundamental molecular mechanisms underlying SOD1-associated ALS, and to treat what is currently a devastating and incurable disease.

amyotrophic lateral sclerosis

protein folding

neurodegeneration

conformational disease

inverse Laplace transform

superoxide dismutase

protein misfolding

metalloproteins

kinetics

protein aggregation

0487

0760

0317

Generation of human dopaminergic neurons from induced pluripotent stem cells to model Parkinson's disease

Sánchez Danés, Adriana, 1984-

21 May 2012

Parkinson’s disease (PD) is an incurable, chronically progressive neurodegenerative disease leading to premature invalidity and death. The locomotor disability of PD patients is mainly rooted in the gradual and insidious degeneration of dopaminergic neurons (DA) projecting from the midbrain substantia nigra (SN) to the basal ganglia striatum, a pathological process highlighted microscopically by the formation of insoluble cytosolic protein aggregates, known as Lewy bodies and Lewy neurites. The pathogenic mechanisms leading to PD remain poorly understood, arguably owing to the lack of suitable animal and cellular experimental models of the disease. Therefore, there is an urgent need for developing reliable experimental models that recapitulate the key features of PD. The recent development of induced pluripotent stem cell (iPSC) technology has enabled the generation of patient-specific iPSC and their use to model human diseases, although it is currently unclear whether this approach could be useful to successfully model age-related conditions. Importantly, disease modeling using iPSC largely relies on the existence of efficient protocols for the differentiation of disease-relevant cell types. Here, we first developed an efficient protocol for the differentiation of iPSC to authentic midbrain-specific DA neurons with SN properties by forced expression of LMX1A using a lentivirus-mediated gene delivery system. Next, we generated an iPSC-based cellular model of PD that recapitulates key phenotypic features of PD, such as DA neuron loss and α-synuclein accumulation in DA neurons from PD patients. Overall, our results demonstrate that we have developed a valuable tool for elucidating the pathogenic mechanisms leading to PD, as well as an experimental platform for screening new drugs that may prevent or rescue neurodegeneration in PD. / La malaltia de Parkinson (MP) és una malaltia neurodegenerativa incurable que causa invalidesa i mort prematura. Els pacients de la malaltia de Parkinson presenten alteracions motores degudes a una degeneració gradual de les neurones dopaminèrgiques que projecten des de la substància nigra fins a l’estriat. A nivell microscòpic s’observa la presència d’agregats proteics insolubles en el citosol de les neurones coneguts com cossos o neurites de Lewy. Els mecanismes patològics responsables de la MP no es coneixen bé, possiblement a causa de la manca de models animals i cel•lulars adequats. Per tant, existeix una gran necessitat de desenvolupar models experimentals fiables que recapitulin les característiques bàsiques de la MP. El recent desenvolupament de les cèl•lules mare pluripotents induïdes (iPSC) ha permès la generació de iPSC específiques de pacient i el seu ús per modelar malalties humanes, ara bé, no és clar si aquesta estratègia es pot utilitzar per modelar exitosament malalties d’origen tardà, com ara la MP. És important destacar que el modelatge de malalties utilitzant iPSC, es basa, en gran mesura en l'existència de protocols eficients per a la diferenciació de les iPSC cap al tipus cel•lular rellevant per a la malaltia. Durant aquest període, per primera vegada, s’ha desenvolupat un protocol per a l’eficient diferenciació de les iPSC cap a neurones dopaminèrgiques amb les propietats característiques de neurones dopaminèrgiques nigrostriatals, mitjançant l’expressió forçada de LMX1A utilitzant vectors lentivirals. A continuació, s’ha generat un model cel•lular usant iPSC derivades de pacients de MP que recapitula les principals característiques fenotípiques de la malaltia, com ara la pèrdua de neurones dopaminèrgiques i l'acumulació de α-sinucleïna en les neurones dopaminèrgiques. En general, els nostres resultats demostren que hem desenvolupat una eina valuosa per a l’estudi dels mecanismes patològics que condueixen a la MP, així com una nova plataforma pel descobriment de nous fàrmacs encaminats a prevenir o evitar la neurodegeneració.

Pluripotent stem cells

Parkinson’s Disease

Dopaminergic neurons

LMX1A

Disease modeling

Neurodegeneration

Cèl•lules mare pluripotents

Malaltia de Parkinson

Neurones dopaminèrgiques

LMX1A

Modelatge de malalties

Neurodegeneració

616.8

Development and application of correlative STED and AFM to investigate neuronal cells

Curry, Nathan

January 2018

Over the past three decades in cellular neuroscience there has been a shift towards the view of the 'tripartite synapse', where, astrocytes -- as well as the pre-synapse and post-synapse -- are involved in synaptic signalling. The migration of astrocytes to form branched networks in the brain is, therefore, of great interest in understanding brain development and neuronal function. Migration is a complex interplay between cytoskeletal reorganisation and cell mechanical stiffness. In order to improve understanding of this process, correlative measurements of cytoskeletal organisation and mechanical stiffness are required. To investigate astrocyte migration a technique combining atomic force microscopy (AFM) with stimulated emission depletion (STED) microscopy was developed. First a custom STED microscope was developed. To facilitate the design of this system the theoretical performance of a range of STED techniques (cw-STED, time-gated STED, pulsed STED and RESOLFT) were compared, identifying that pulsed STED theoretically has the highest photon efficiency. A pulsed STED microscope, which uses adaptive optics, was then designed, developed and characterised. The microscope was found to achieve resolutions below 50 nm. The STED microscope was combined with a commercial AFM to study live cells. Using the recently developed SiR-actin and SiR-tubulin dyes and AFM probes optimised for live cell mechanical property studies, images of the actin and tubulin cytoskeleton were correlated with AFM topography and mechanical stiffness measurements. It was found that, in astrocytes, actin contributes significantly both to astrocyte stiffness and topography. Investigations of migrating cells showed differences in actin organisation and mechanical stiffness between the basis and leading edge of migration. A further study was performed, investigating the effects of the gap-junction protein connexin30, which is expressed during the early stages of brain development, on migration. This protein was found to inhibit the actin reorganisation and mechanical stiffness changes observed in basal conditions. Overall the combination of mechanosensitive AFM measurements with advanced microscopy, such as super-resolution, on live cells is a promising approach which will enable a range of investigations, for instance when studying cell structural remodeling during brain development or tumorigenesis.

Models of neurodegeneration using computational approaches

Khabirova, Eleonora

January 2016

Alzheimer's disease (AD), as one of the most common neurodegenerative diseases, is characterized by the loss of neuronal dysfunction and death resulting in progressive cognitive impairment. The main histopathological hallmark of AD is the accumulation and deposition of misfolded Aβ peptide as amyloid plaques, however the precise role of Aβ toxicity in the disease pathogenesis is still unclear. Moreover, at early stages of the disease the important clinical features of the disorder, in addition to memory loss, are the disruptions of circadian rhythms and spatial disorientation. In the present work I first studied the role of Aβ toxicity by comparing the findings of genome-wide association studies in sporadic AD with the results of an RNAi screen in a transgenic C. elegans model of Aβ toxicity. The initial finding was that none of the human orthologues of these worm genes are associated with risk for sporadic Alzheimer’s disease, indicating that Aβ toxicity in the worm model may not be equivalent to sporadic AD. Nevertheless, comparing the first degree physical interactors (+1 interactome) of the GWAS and worm screen-derived gene products have uncovered 4 worm genes that have a +1 interactome overlap with the GWAS genes that is larger than one would expect by chance. Three of these genes form a chaperonin complex and the fourth gene codes for actin, a major substrate of the same chaperonin. Next I have evaluated the circadian disruptions in AD by developing a new system to simultaneously monitor the oscillations of the peripheral molecular clock and behavioural rhythms in single Drosophila. Experiments were undertaken on wild- type and Aβ-expressing flies. The results indicate the robustness of the peripheral clock is not correlated with the robustness of the circadian sleep and locomotor behaviours, indicating that the molecular clock does not directly drive behaviour. This is despite period length correlations that indicate that the underlying molecular mechanisms that generate both molecular and behavioural rhythms are the same. Rhythmicity in Aβ-expressing flies is worse than in controls. I further investigated the mechanism of spatial orientation in Drosophila. It was established that in the absence of visual stimuli the flies use self-motion cues to orientate themselves within the tubes and that in a Drosophila model of Aβ toxicity this control function is disrupted.

In vivo approach to myelin turnover and oligodendrocyte-dependent axonal integrity

Lüders, Katja

21 August 2018

No description available.

570

Proteolipid protein (PLP)

Oligodendrocyte

Axonopathy

Glia-axonal support

Myelin

Neurodegeneration

Neuroinflammation

Tamoxifen

Biologie (PPN619462639)

Proteomics studies of protein homeostasis and aggregation in ageing and neurodegeneration

Vecchi, Giulia

January 2018

Upon ageing, a progressive disruption of protein homeostasis often leads to extensive protein aggregation and neurodegeneration. It is therefore important to study at the proteome level the origins and consequences of such disruption, which so far have remained elusive. Addressing this problem has recently become possible by major advances in mass spectrometry-based (MS) proteomics, which allows the identifications and quantification of thousands of proteins in a variety of biological samples. In the first part of this thesis, I analyse proteome-wide MS data for the nematode worm C. elegans upon ageing, in wild type (WT), long-lived and short-lived mutant strains. By comparing the total abundance and the soluble abundance for nearly 4000 proteins, I provide extensive evidence that proteins are expressed in adult worms at levels close to their solubility limits. With the use of sequence-based prediction tools, I then identify specific physico-chemical properties associated with this age-related protein homeostasis impairment. The results that I obtained reveal that the total intracellular protein content remains constant, in spite of the fact that the proteome undergoes wide remodeling upon ageing, resulting into severe protein homeostasis disruption and widespread protein aggregation. These results suggest a protein-dependent decrease in solubility associated with the protein homeostasis failure. In the second part of the thesis, I determine and classify potential interactions of misfolded protein oligomers with other proteins. This phenomenon is widely believed to give rise to cytotoxicity, although the mechanisms by which this happens are not fully understood. To address this question, I process and analyse MS data from structurally different oligomers (toxic type A and nontoxic type B) of the protein HypF-N, incubated in vitro with proteins extracted from murine cell cultures. I find that more than 2500 proteins are pulled down with the misfolded oligomers. These results indicate that the two types of oligomers interact with the same pool of proteins and differ only in the degree of binding. Functional annotation analysis on the groups reveals a preference of the oligomers to bind proteins in specific biological pathways and categories, including in particular mitochondrial membrane proteins, RNA-binding proteins and molecular chaperones. Overall, in this study I complement the powerful and high-throughput experimental approach of MS proteomics with bioinformatics analyses and prediction algorithms to define the physical, chemical and biological features of protein homeostasis disruption upon ageing and the interactome of misfolded oligomers.

Mechanisms of Dopaminergic Neurodegeneration in Parkinson's Disease

Verma, Aditi

January 2018

Parkinson’s disease (PD) is a debilitating movement disorder. The cardinal symptoms of PD are bradykinesia, resting tremors and rigidity. PD is characterized by degeneration of dopaminergic neurons of A9 region, substantia nigra pars compacta (SNpc) and loss of dopaminergic terminals in striatum while the dopaminergic neurons of A10 region, ventral tegmental area (VTA) are relatively protected. Putative mechanisms, such as mitochondrial dysfunction, dysregulation of the ubiquitin proteasome system and increased oxidative stress have been hypothesized to mediate PD pathology. However, precise mechanisms that underlie selective vulnerability of SNpc dopaminergic neurons to degeneration are unknown. The aim of this thesis was to evaluate the pathological mechanisms that may contribute to degeneration of SNpc dopaminergic neurons in PD. Dopaminergic neurons of SNpc are pacemakers and constant calcium entry through L-type calcium channel, Cav1.3 has been reported in these neurons during pacemaking. In addition, these neurons have poor calcium buffering capacity. Together, this leads to dysregulation of calcium homeostasis in the SNpc dopaminergic neurons leading to increased oxidative stress. Gene expression of the full length channel and the variant was investigated in the mouse midbrain and further their presence was verified in mouse SNpc and VTA and also in SNpc and VTA in the MPTP mouse model of PD. Gene expression of Cav1.3 -42 and its variant was also studied in SNpc from autopsy tissue from PD patients and age matched controls. Having studied differential expression of the calcium channels, global changes in gene expression in SNpc from the MPTP mouse model of PD and PD autopsy tissues were next examined. This is the first report of transcriptome profile alterations from SNpc in mouse model and PD tissue performed using RNA-seq. Gene expression profiles were examined from SNpc 1 day post single exposure to MPTP, in which case there is no neuronal death and 14 days after daily MPTP treatment where SNpc has undergone ~50% cell death. Further, RNA- seq was performed to study gene expression alterations in SNpc from human PD patients and age- matched controls. The RNA-seq data was taken through extensive analyses; analysed for differential gene expression, gene-set enrichment analysis, pathway analysis and network analysis. Glutaredoxin 1 (Grx1) is a thiol disulfide oxidoreductase that catalyses the deglutathionylation of proteins and is important for regulation of cellular protein thiol redox homeostasis. Down-regulation of Grx1 has been established to exacerbate neurodegeneration through impairment of cell survival signalling. Previous work from our laboratory has demonstrated that perturbation of protein thiol redox homeostasis through diamide injection into SNpc leads to development of PD pathology and motor deficits. It was therefore investigated if Grx1 down-regulation in vivo, leading to increased glutathionylation and protein thiol oxidation, could result in PD pathology. This work is thus the first study of RNA-seq based transcriptomic profile alterations in SNpc from human PD patients. This work also highlights several differences between mouse model and human PD tissue indicating that the underlying mechanisms of PD pathogenesis differ from mouse to humans in addition to developing a novel model for PD.

Neurodegenerative Disorders

Parkinson's Disease

Dopaminergic Neurodegeneration

Epidemiology

Huntington’s Disease

Parkinson's Disease - Pathology

PD Pathogenesis

Glutaredoxin 1

Dopaminergic Neuron Degeneration

Dopaminergic Neurons

Neuroscience

Os produtos dos genes Tsc1 e Tsc2 em processos neurodegenerativos / Tsc1 and Tsc2 gene products in neurodegenerative processes

Deborah Azzi-Nogueira

04 August 2016

O complexo da esclerose tuberosa (TSC) é uma doença genética que pode afetar órgãos específicos de qualquer sistema do organismo humano. Em geral, as lesões surgem pela inativação bialélica de um dos genes supressores tumorais Tuberous Sclerosis Complex 1 (TSC1) ou 2 (TSC2). Por outro lado, nas regiões corticais e subcorticais do cérebro, as lesões decorrentes de falhas de migração neuronal e sua arborização podem ser explicadas pela haploinsuficiência de TSC1 ou TSC2. As lesões do córtex cerebral apresentam-se comumente com epilepsia refratária, a qual, por sua vez, pode se associar a deficiência intelectual e transtornos do comportamento. Estes quadros clínicos podem estar presentes em pacientes com TSC sem lesão anatômica detectável à ressonância nuclear magnética do crânio. As proteínas hamartina ou tuberina, conhecidas também como TSC1 e TSC2, são codificadas respectivamente pelos genes TSC1 e TSC2. Elas agem juntas em um complexo molecular citosólico que inativa a pequena GTPase Rheb, a qual tem ação ativadora da cinase alvo da rapamicina em mamíferos (mTOR), regulando diversos processos celulares, como proliferação, diferenciação, crescimento, migração e metabolismo. Com a hipótese de que a quantidade de TSC1 ou TSC2 no neurônio pode alterar suas funções de forma dependente do estado metabólico, tivemos, neste trabalho, o objetivo geral de caracterizar os padrões de expressão e atividade de TSC1 e TSC2 em dois modelos de neurodegeneração induzida no camundongo adulto e verificar se a redução de quantidade de TSC1 tem efeito sobre a extensão da lesão de neurônios dopaminérgicos em modelo de hemiparkinsonismo. No primeiro modelo empregado, cinco estruturas encefálicas de camundongos submetidos a dieta hiperlipídica mostraram alteração da quantidade de RNAm de Tsc1 e/ou Tsc2 ou sinais de estresse oxidativo. A redução de transcritos de Tsc1 e Tsc2 no córtex cerebral foi dependente de jejum realizado imediatamente antes da eutanásia. No córtex cingulado, houve evidência de estresse oxidativo. O aumento específico de RNAm foi observado no hipocampo (Tsc1 e Tsc2) e no estriado e hipotálamo (Tsc1), embora de forma independente do jejum, sugerindo se tratar de alterações relacionadas à dieta hiperlipídica. No modelo de hemiparkinsonismo, camundongos adultos submetidos a injeção intracerebral de 6-hidroxidopamina apresentaram redução da quantidade total de proteína S6 no lado encefálico tratado quando comparado ao segmento contralateral (p =0,004, r=0,8795; teste de Pearson, IC: 95%), sem alteração de TSC1 ou TSC2. Em análises de imunoperoxidase do encéfalo, descrevemos, de forma independente da lesão, a expressão de TSC1 no estriado, núcleos entopeduncular e arqueado e de TSC2 no tálamo e hipotálamo. Com o objetivo de obter um modelo de camundongo sem expressão pós-natal de Tsc1 em várias regiões encefálicas, de forma independente do tipo celular, realizamos cruzamentos entre uma linhagem de camundongo transgênico em que o gene Tsc1 contém sequências lox nos íntrons 16 e 18 e outra linhagem com Tsc1 tipo-selvagem (WT) em homozigose e o transgene para expressão da recombinase Cre em fusão ao domínio de ligação ao ligante do receptor de estrógeno humano (ESR1) sob o controle de expressão do promotor de ubiquitina C (UBC). Em F1, obtivemos camundongos portadores do transgene UBC-CreESR1 e heterozigotos para Tsc1 (Tsc1WT/Flox). Em F2, entre os animais homozigotos Tsc1Flox/Flox (N = 153) gerados por retrocruzamento, nenhum era portador do transgene (Nesperado = 85; Nobservado = 0; X2 = 348,185; p < 0,0001) É possível que o segmento genômico em que houve inserção do vetor lentiviral que carrega o transgene UBC-CreESR1 esteja ligado ao loco de Tsc1 no cromossomo 2 do camundongo, segregando juntos. O tratamento com 4-hidroxitamoxifeno de animais heterozigotos e portadores do transgene aumentou a quantidade de TSC1 no estriado (p < 0,05) e o cerebelo não apresentou alteração. É possível que mecanismos transcricionais ou traducionais, funcionais no estriado, tenham favorecido o aumento de TSC1 de forma dependente de 4-hidroxitamoxifeno / Tuberous sclerosis complex (TSC) is a genetic disorder that can affect any specific organs. In general, lesions are caused by biallelic inactivation of the tumor suppressor genes Tuberous Sclerosis Complex 1 (TSC1) or 2 (TSC2). On the other hand, in cortical and subcortical brain regions, lesions associated with neuronal migration and arborization failures can be explained by TSC1 or TSC2 haploinsufficiency. Brain cortical lesions commonly cause refractory epilepsy, which, in turn, may be associated with intellectual disabilities and behavioral disorders. These medical conditions may be present in TSC patients without detectable anatomic lesion on magnetic resonance images. TSC1 and TSC2 genes encode hamartin and tuberin, also known as TSC1 and TSC2, respectively. They act together in a cytosolic molecular complex that inactivates small GTPase Rheb, which is a mammalian target of rapamycin (mTOR) activator, regulating diverse cellular processes such as proliferation, differentiation, growth, migration and metabolism. With the hypothesis that the amount of TSC1 or TSC2 in the neuron can change its function depending on the metabolic state, the overall objective of this study was to characterize TSC1 and TSC2 expression patterns and activity in two mice models of induced neurodegeneration; and check whether TSC1 reduction changes dopaminergic neurons damage extent in a hemiparkinsonins model. For the first model, five brain structures from mice fed with high fat diet showed alterations in Tsc1 and/or Tsc2 mRNA, or oxidative stress signals. Reduction of Tsc1 and Tsc2 transcripts in the cerebral cortex was dependent on fasting performed immediately prior to euthanasiaThere was evidence of oxidative stress in the cingulate cortex. Increase in mRNA was observed in the hippocampus (Tsc1 and Tsc2) and striatum and hypothalamus (Tsc1), although independent of the fasting, suggesting that this effect is related to the high fat diet. In hemiparkinsonism model, adult mice subjected to intracerebral injection of 6-hydroxydopamine had decreased levels of S6 in the brain treated side compared to the contralateral segment (p = 0.004, r = 0.8795; Pearson test, CI: 95 %), without alterations in TSC1 nor TSC2. Using imunoperoxidase analysis, we described TSC1 expression in the striatum, entopeduncular and arcuate nuclei, and TSC2 in the thalamus and hypothalamus, independently from the 6-OHDA lesion. To obtain a mouse model without TSC1 postnatal expression in different brain regions, independently of the cell type, we performed crosses between transgenic mouse strain in which the Tsc1 gene contains lox sequences in introns 16 and 18 and strain with Tsc1 wild-type (WT) and the transgene for expression of Cre recombinase fused to the binding domain of the human estrogen receptor (ESR1) ligand, controlled by ubiquitin C (UBC) promoter expression. In F1, we obtained mice carrying the transgene UBC-CreESR1 and heterozygous for Tsc1 (Tsc1WT/flox). In F2, among animals homozygous Tsc1Flox/Flox (N=153) generated by backcrossing, none was carrying the transgene (Nexpected = 85; Nobserved = 0; X2= 348.185, p <0.0001) It is possible that the genomic segment containing the lentiviral vector insertion bearing UBC-CreESR1 transgene is linked to the TSC1 region on mouse chromosome 2, and they segregate together. Treatment with 4-hydroxytamoxifen in animals heterozygous and positive for the transgene showed increased TSC1 in the striatum (p <0.05), while there was no change in the cerebellum. It is possible that transcriptional or translational functional striatum mechanisms favored TSC1 increasing, in a 4-hydroxytamoxifen-dependent manner

Complexo da esclerose tuberosa

Dieta hiperlipídica

Doença de Parkinson

Expressão Gênica

Neurodegeneração

TSC1

TSC2

Gene expression

High fat diet

Neurodegeneration

Parkinson's disease

TSC1

TSC2

Tuberous sclerosis complex

Impacto da ausência do interferon gama na plasticidade sináptica após lesão do nervo isquiático / Interferon of impact gamma in the of synaptic plasticity after sciatic nerve lesion

Victorio, Sheila Cristina da Silva

17 August 2018

Orientador: Alexandre Leite Rodrigues de Oliveira / Tese (doutorado) - Universidade Estadual de Campinas, Instituto de Biologia / Made available in DSpace on 2018-08-17T18:11:52Z (GMT). No. of bitstreams: 1 Victorio_SheilaCristinadaSilva_D.pdf: 20891355 bytes, checksum: a0e7d9b08b387848f356367e4f3c8d86 (MD5) Previous issue date: 2011 / Resumo: Na medula espinal, o estabelecimento das sinapses é, provavelmente, coordenado pelos próprios neurônios. Contudo, as células da glia circunjacentes e o microambiente formado entre neurônios/glia, desempenham papel importante na modulação da excitabilidade neural, influenciando na transmissão e plasticidade sináptica. Em situações de injúria ou inflamação, há um aumento da reatividade glial e mudança do estado funcional dos neurônios, levando a uma consequente cascata de eventos visando a homeostase do tecido. Neste sentido, o IFN? está envolvido na regulação da expressão do MHC I, o qual tem recentemente mostrado exercer um papel importante nos processos de plasticidade sináptica após axotomia. Além disso, existem evidências de que o IFN? pode interferir na diferenciação e sobrevivência das células neurais. No entanto, pouco se sabe sobre os efeitos da ausência do IFN? nos neurônios espinais após lesão. Portanto, o objetivo deste trabalho foi investigar os fenômenos de plasticidade sináptica e da reatividade glial em camundongos mutantes para IFN?, a fim de analisar a dinâmica das sinapses na medula após a lesão do nervo isquiático em animais incapazes de regular a expressão de MHC I pela produção de IFN?. Para isso, camundongos mutantes para IFN? e do tipo selvagem C57BL/6J foram submetidos à transecção ou esmagamento unilateral do nervo isquiático (5animais/grupo/experimento) e o material foi processado para imunohistoquímica, Western blotting, microscopia de luz e de transmissão (MET). Além disso, a avaliação motora dos animais também foi investigada por meio do índice funcional do nervo isquiático. Secções da medula espinal de camundongos sem lesão foram também utilizados para análise de sobrevivência neuronal e presença de apoptose por TUNEL e imunomarcação para caspase 3. Camundongos neonatos foram utilizados para os experimentos com cultura primária de astrócitos. A ausência do IFN? nos animais mutantes levou à redução da expressão de MHC I após uma semana de lesão. Os motoneurônios encontrados no corno ventral destes animais exibiram menor tamanho do soma e maior número de células degeneradas comparado aos animais selvagens. A perda neuronal não foi agravada pela axotomia do nervo isquiático nos animais mutantes. A morte por apoptose foi sugerida baseado nos resultados positivos para TUNEL e caspase 3. A análise ultraestrutural mostrou menor retração de terminais sinápticos nos animais mutantes uma semana após lesão periférica. Além disso, a ausência do IFN? não prejudicou a recuperação motora dos animais mutantes. Em cultura, os astrócitos dos animais mutantes mostraram um atraso na taxa de proliferação provavelmente em razão da ausência do IFN?. Com base nestes resultados, sugerimos que o IFN? pode exercer um papel neuroprotetor e que sua ausência resulta na morte neuronal, a qual não é agravada pela lesão periférica. / Abstract: In the spinal cord, the establishment of synapses is probably coordinated by the neurons. However, the glial cells and surrounding microenvironment formed between neurons/glia play an important role in modulating neural excitability, influencing the transmission and synaptic plasticity. In situations of injury or inflammation, there is an increase in glial reactivity and changes in functional status of neurons, with a consequent cascade of events aimed at restoration of homeostasis. In this regard, IFN? is involved in regulating the expression of MHC I, which has recently been shown to play an important role in the synaptic plasticity processes following axotomy. Also, there is evidence that IFN? absence on spinal cord neurons after injury. The aim of this study was to investigate the phenomena of synaptic plasticity and glial reactivity in mice mutant for IFN? in order to analyze the dynamics of spinal synapses after injury of the sciatic nerve in animals unable to regulate the expression of MHC I due the absence of IFN?. In this sense, mutant mice for IFN? and wild type C57BL/6J were subjected to unilateral transection or crushing of the sciatic nerve (5animals/group/experiment), and the specimens were processed for immunohistochemistry, Western blotting, light and transmission electron microscopy (TEM). In addition, the motor evaluation of the mice was investigated by the sciatic functional index. Spinal cord sections from non-lesioned animals were also used to investigate neuronal survival and the presence of apoptosis with TUNEL and caspase 3 immunostaining. Astrocytes from mutant and wild type newborn mice were also investigated in primary cell culture. The absence of IFN? in the mutant animals produced reduced expression of MHC I after one week from injury. Motoneurons in the lower lumbar ventral horn exhibited a smaller soma size and increased number of degenerated cells?when compared to wild type mice. Sciatic nerve axotomy did not further aggravate the neuronal loss in the mutant mice. Apoptotic death is suggested on TUNEL and caspase 3 positive immunostaining. The electron microscopy showed a smaller retraction of pre-synaptic terminals apposing to motoneurons in mutant mice one week after lesion. The absence of IFN? did not impair motor recovery of the mutant animals. In culture, astrocytes from mutant animals showed a delay in the rate of proliferation probably due to the absence of IFN?. Altogether, these results suggest that IFN? may be neuroprotective and its absence results in neuronal death, which is not further increased by peripheral axotomy. / Doutorado / Biologia Celular / Doutor em Biologia Celular e Estrutural

Interferon gama

Axotomia

Neurônios

Degeneração neural

Interferon-gamma

MHC class I Genes

Axotomy

Neurons

Neurodegeneration

Disfunção mitocondrial induzida por metilmalonato e 3-nitropropionato / Mitochondrial dysfunction induced by methylmalonate and 3-nitropropionate

Mirandola, Sandra Regina

08 June 2004

Orientador: Roger Frigerio Castilho / Tese (doutorado) - Universidade Estadual de Campinas, Faculdade de Ciências Médicas / Made available in DSpace on 2018-08-11T10:41:34Z (GMT). No. of bitstreams: 1 Mirandola_SandraRegina_D.pdf: 3705031 bytes, checksum: e1e34dd5e1b3949d9c308b3c20a19787 (MD5) Previous issue date: 2008 / Resumo: A acidemia metilmalônica (MMAemia) é uma desordem metabólica hereditária do metabolismo de aminoácidos com cadeia ramificada e de ácidos graxos com cadeia ímpar, envolvendo um defeito na conversão de metilmalonil-CoA a succinil-CoA. Manifestações sistêmicas e neurológicas nesta doença são relacionadas com o acúmulo de metilmalonato (MMA) em tecidos e fluidos biológicos e com o comprometimento do metabolismo energético. Neste trabalho, verificou-se que o MMA inibiu com grande intensidade a conversão de lactato a piruvato catalisada pela enzima lactato desidrogenase (LDH) em homogenatos de fígado e cérebro de rato. A conversão de piruvato a lactato, catalisada pela LDH, foi menos sensível à inibição por MMA. Estudos de cinética enzimática sobre a inibição da LDH de cérebro, utilizando-se lactato como substrato, indicaram que o MMA inibe esta enzima competitivamente (Ki = 3,02 ± 0,59 mM). Propôs-se que a inibição da conversão lactato/piruvato por MMA contribui para a fisiopatologia da MMAemia, resultando, dentre outras alterações, em acúmulo de lactato e acidemia metabólica. Mostrou-se que, em mitocôndrias isoladas de cérebro e músculo de rato, concentrações milimolares de MMA inibiram o consumo de O2 mantido por succinato, enquanto nenhum efeito inibitório foi observado quando substratos para os complexos I ou IV foram utilizados. Notadamente, o efeito inibitório de MMA, mas não de malonato, no consumo mitocondrial de O2 mantido por succinato foi minimizado quando uma permeabilização não-seletiva das mitocôndrias foi induzida por alameticina. Em adição, o MMA apresentou apenas um pequeno efeito inibitório no consumo de O2 por partículas submitocondriais invertidas na presença de succinato. Não se obteve evidência de produção de malonato nas mitocôndrias tratadas com MMA. Conclui-se que o MMA inibe o consumo mitocondrial de O2 na presença de succinato por interferir na captação deste substrato pela mitocôndria. A inibição do transporte mitocondrial de substratos, induzida pelo MMA, através do carreador de dicarboxilatos, pode ter importantes implicações fisiopatológicas na MMAemia. Comparou-se a suscetibilidade de mitocôndrias isoladas de fígado, rim e coração de rato, assim como de diferentes subregiões cerebrais quanto à transição de permeabilidade mitocondrial (MPT) induzida por 3-nitropropionato (3-NP) e Ca2+. A MPT foi estimada pela queda do potencial elétrico transmembrana e inchamento mitocondrial sensíveis à ciclosporina A. Mitocôndrias de cérebro e coração foram mais suscetíveis à MPT induzida por 3-NP e Ca2+ que organelas isoladas de fígado e rim. A comparação de mitocôndrias de diferentes regiões cerebrais indicou que uma inibição parcial da respiração por 3-NP resultou em MPT mais rapidamente em organelas estriatais que corticais ou cerebelares. Em ratos tratados sistemicamente com 3-NP, verificou-se uma inibição de mesma magnitude da succinato desidrogenase em todos os tecidos estudados. Notadamente, mitocôndrias isoladas de cérebro de ratos tratados sistemicamente com 3-NP apresentaram uma maior suscetibilidade à MPT induzida por Ca2+ quanto comparadas a controles. Propôs-se que a maior suscetibilidade do estriado à neurodegeneração induzida por 3-NP pode ser, pelo menos em parte, explicada por uma maior vulnerabilidade desta região cerebral à MPT, juntamente com a vulnerabilidade desta região ao influxo de Ca2+ citosólico mediado pelo estímulo de receptores de glutamato / Abstract: Methylmalonic acidemia (MMAemia) is an inherited metabolic disorder of branched amino acid and odd-chain fatty acid metabolism, involving a defect in the conversion of methylmalonyl-coenzyme A to succinyl-coenzyme A. Systemic and neurological manifestations in this disease are thought to be associated with the accumulation of methylmalonate (MMA) in tissues and biological fluids with consequent impairment of energy metabolism. In the present work it was observed that MMA potently inhibited lactate dehydrogenase (LDH)-catalyzed conversion of lactate to pyruvate in liver and brain homogenates. LDH was about one order of magnitude less sensitive to inhibition by MMA when catalyzing the conversion of pyruvate to lactate. Kinetic studies on the inhibition of brain LDH indicated that MMA inhibits this enzyme competitively with lactate as a substrate (Ki = 3.02 ± ?0.59 mM). We proposed that inhibition of the lactate/pyruvate conversion by MMA contributes to the MMAemia physiophatology, leading to lactate accumulation and metabolic acidemia. While millimolar concentrations of MMA inhibit succinate-supported O2 consumption by isolated rat brain or muscle mitochondria, there is no effect when either a pool of NADH-linked substrates or N,N,N',N'-tetramethyl-p-phenylendiamine (TMPD)/ascorbate were used as electron donors. Interestingly, the inhibitory effect of MMA, but not of malonate, on succinate-supported brain mitochondrial O2 consumption was minimized when nonselective permeabilization of mitochondrial membranes was induced by alamethicin. In addition, only a slight inhibitory effect of MMA was observed on succinate-supported O2 consumption by inside-out submitochondrial particles. Under our experimental conditions, there was no evidence of malonate production in MMA-treated mitochondria. We conclude that MMA inhibits succinate-supported mitochondrial O2 consumption by interfering with the uptake of this substrate. MMA-induced inhibition of substrate transport by the mitochondrial dicarboxylate carrier may have important physiopatological implications. The susceptibility of isolated mitochondria from liver, kidney and heart and different rat brain regions (striatum, cortex and cerebellum) was compared regarding to mitochondrial permeability transition (MPT) evoked by 3-nitropropionate (3-NP) and Ca2+ ions. In general, isolated brain mitochondria from different regions were more sensitive to 3-NP and Ca2+ toxicity than mitochondria from liver and kidney as estimated by decrease in the transmembrane electrical potential and mitochondrial swelling. The comparision of different brain regions revealed that the inhibition of 50% of the mitochondrial succinate-supported respiration elicited by 3-NP resulted in a Ca2+-induced MPT pore opening, inhibited by cyclosporin A, faster in striatal than in cortical and cerebellar mitochondria. It was verified an inhibition of succinate dehydrogenase activity from the same magnitude in all tissues studied after a 3-NP systemic treatment. Interestingly, isolated forebrain mitochondria obtained from rats systemically treated with 3-NP showed a more pronounced susceptibility to Ca2+-induced MPT pore opening when compared to control rats. We proposed that the increased susceptibility of rat striatum to 3-NP-induced neurodegeneration could be in part explain by a region-specific susceptibility to MPT together with increase vulnerability of this brain region to glutamate receptors-mediated cytosolic Ca2+ influx / Doutorado / Biologia Estrutural, Celular, Molecular e do Desenvolvimento / Doutor em Fisiopatologia Medica

Succinato

Cálcio

Erros inatos do metabolismo

Lactato desidrogenase

Ácido metilmalônico

Degeneração neural

Calcium

Succinate

Metabolism, Inborn Errors

Lactate Dehydrogenase

Methylmalonic acid

Neurodegeneration