Multidisniplinary study of Alzheimer's disease-related peptides : from amyloid precursor protein (APP) to amyloid β-oligomers and γ-secretase modulators / Étude pluridisciplinaire de peptides liés à la maladie d'Alzheimer : de la protéine précurseur de l'amyloïde (APP) aux oligomères de bêta-amyloïde et aux inhibiteurs de gamma-sécrétase

Itkin, Anna

14 May 2012

Une des caractéristiques histopathologiques de la maladie d'Alzheimer (AD) est la présence de plaques amyloïdes formées par les peptides amyloïdes β (Aβ) de 40 et 42 résidus, qui sont les produits de clivage par des protéases de l'APP. Afin de comprendre le rôle des variations structurelles du TM dans le traitement de l'APP, les peptides APP_TM4K ont été étudiés dans la bicouche lipidique en utilisant l’ATR-FTIR et ssNMR. Tandis que la structure secondaire globale du peptide APP_TM4K est hélicoidale, hétérogénéité de conformation et d'orientation a été observée pour le site de clivage γ et , que peuvent avoir des implications dans le mécanisme de clivage et donc dans la production d’Aβ. Les peptides Aβ s'agrègent pour produire des fibrilles et aussi de manière transitoire d'oligomères neurotoxiques. Nous avons constaté qu'en présence de Ca2+, l’Aβ (1-40) forme de préférence des oligomères, tandis qu'en absence de Ca2+ l'Aβ (1-40) s’agrège sous forme de fibrilles. Dans les échantillons sans Ca2+, l’ATR-FTIR révèle la conversion des oligomères en feuillets β antiparallèles en la conformation caractéristique des fibrilles en feuillets β parallèles. Ces résultats nous ont amené à conclure que les Ca2+ stimulent la formation d'oligomères d'Aβ (1-40), qui sont impliqués dans l’AD. Les positions et une orientation précise de deux nouveaux médicaments puissants modulateurs de la γ-sécrétase - le benzyl-carprofen et le sulfonyl-carprofen  dans la bicouche lipidique, ont été obtenus à partir des expériences des ssNMR. Ces résultats indiquent que le mécanisme probable de modulation du clivage par la y-sécrétase est une interaction directe avec le domaine TM de l’APP. / A histopathological characteristic of Alzheimer’s disease (AD) is the presence of amyloid plaques formed by amyloid β(A) peptides of 40 and 42 residues-long, which are the cleavage products of APP by proteases. To understand the role of structural changes in the TM domain of APP, APP_TM4K peptides were studied in the lipid bilayer using ATR-FTIR and ssNMR. While the overall secondary structure of the APP_TM4K peptide is helical, conformational and orientational heterogeneity was observed for the y- and for the -cleavage sites, which may have implications for the cleavage mechanism and therefore the production of Aβ. Starting from its monomeric form, Aβ peptides aggregate into fibrils and / or oligomers, the latter being the most neurotoxic. We found that in the presence of Ca2 +, Aβ (1-40) preferably forms oligomers, whereas in the absence of a2 + Aβ (1-40) aggregates into fibrils. In samples without Ca2 +, ATR-FTIR shows conversion from antiparallel β sheet conformation of oligomers into parallel β sheets, characteristic of fibrils. These results led us to conclude that Ca2 +stimulates the formation of oligomers of Aβ (1-40), that have been implicated in the pathogenesis of AD. Position and precise orientation of two new drugs  powerful modulators of γ-secretase  benzyl-carprofen and carprofen sulfonyl  in the lipid bilayer were obtained from neutron scattering and ssNMR experiments. These results indicate that carprofen-derivatives can directly interact with APP. Such interaction would interfere with proper APP-dimer formation, which is necessary for the sequential cleavage by β -secretase, diminishing or greatly reducing Aβ42 production.

La maladie d'Alzheimer (AD)

Modulateurs de la γ-sécrétase

Le peptide bêta-amyloïde (Abeta)

Oligomères de l’Abeta

Gamma-sécrétase

Alzheimer disease (AD)

Amyloid precursor protein (APP)

Gamma-secretase modulators

Amyloid beta-peptide (Abeta)

Abeta oligomers

Gamma-secretase

572.6

535.8

Characterizing Microglial Response to Amyloid: From New Tools to New Molecules

Priya Prakash (10725291)

29 April 2021

<p>Microglia are a population of specialized, tissue-resident immune cells that make up around 10% of total cells in our brain. They actively prune neuronal synapses, engulf cellular debris, and misfolded protein aggregates such as the Alzheimer’s Disease (AD)-associated amyloid-beta (Aβ) by the process of phagocytosis. During AD, microglia are unable to phagocytose Aβ, perhaps due to the several disease-associated changes affecting their normal function. Functional molecules such as lipids and metabolites also influence microglial behavior but have primarily remained uncharacterized to date. The overarching question of this work is, <i>How do microglia become dysfunctional in chronic inflammation</i>? To this end, we developed new chemical tools to better understand and investigate the microglial response to Aβ <i>in vitro</i> and <i>in vivo</i>. Specifically, we introduce three new tools. (1) Recombinant human Aβ was developed via a rapid, refined, and robust method for expressing, purifying, and characterizing the protein. (2) A pH-sensitive fluorophore conjugate of Aβ (called Aβ^pH) was developed to identify and separate Aβ-specific phagocytic and non-phagocytic glial cells <i>ex vivo</i> and <i>in vivo</i>. (3) New lysosomal, mitochondrial, and nuclei-targeting pH-activable fluorescent probes (called LysoShine, MitoShine, and NucShine, respectively) to visualize subcellular organelles in live microglia. Next, we asked, <i>What changes occur to the global lipid and metabolite profiles of microglia in the presence of Aβ in vitro and in vivo</i>? We screened 1500 lipids comprising 10 lipid classes and 700 metabolites in microglia exposed to Aβ. We found significant changes in specific lipid classes with acute and prolonged Aβ exposure. We also identified a lipid-related protein that was differentially regulated due to Aβ <i>in vivo</i>. This new lipid reprogramming mechanism “turned on” in the presence of cellular stress was also present in microglia in the brains of the 5xFAD mouse model, suggesting a generic response to inflammation and toxicity. It is well known that activated microglia induce reactive astrocytes during inflammation. Therefore, we asked, <i>What changes in proteins, lipids, and metabolites occur in astrocytes due to their reactive state? </i>We provide a comprehensive characterization of reactive astrocytes comprising 3660 proteins, 1500 lipids, and 700 metabolites. These microglia and astrocytes datasets will be available to the scientific community as a web application. We propose a final model wherein the molecules secreted by reactive astrocytes may also induce lipid-related changes to the microglial cell state in inflammation. In conclusion, this thesis highlights chemical neuroimmunology as the new frontier of neuroscience propelled by the development of new chemical tools and techniques to characterize glial cell states and function in neurodegeneration.</p>

Cell Biology

Neuroscience

Medical Biochemistry: Lipids

Cellular Immunology

Analytical Biochemistry

Cell Neurochemistry

Immunological and Bioassay Methods

Biologically Active Molecules

Microglia

Alzheimer's disease

Lipidomics

Proteomics

Metabolomics

Phagocytosis

Amyloid Beta

Astrocytes

Reactive Astrocytes

Chemical Tools

Chemical Biology

Neuroinflammation

Neurodegeneration

Glia

Neuroscience

Neuroimmunology

Novel regulation of neuronal genes implicated in Alzheimer disease by microRNA

Long, Justin M.

11 December 2013

Indiana University-Purdue University Indianapolis (IUPUI) / Alzheimer disease (AD) results, in part, from the excess accumulation of the amyloid-β peptide (Aβ) as neuritic plaques in the brain. The short Aβ peptide is derived from a large transmembrane precursor protein, APP. Two different proteolytic enzymes, BACE1 and the gamma-secretase complex, are responsible for cleaving Aβ peptide from APP through an intricate processing pathway. Dysregulation of APP and BACE1 levels leading to excess Aβ deposition has been implicated in various forms of AD. Thus, a major goal in this dissertation was to discover novel regulatory pathways that control APP and BACE1 expression as a means to identify novel drug targets central to the Aβ-generating process. MicroRNAs (miRNA) are short, non-coding RNAs that act as post-transcriptional regulators of gene expression through specific interactions with target mRNAs. Global analyses predict that over sixty percent of human transcripts contain evolutionarily conserved miRNA target sites. Therefore, the specific hypothesis tested was that miRNA are relevant regulators of APP and BACE1 expression. In this work, several specific miRNA were identified that regulate APP protein expression (miR-101, miR-153 and miR-346) or BACE1 expression (miR-339-5p). These miRNAs mediated their post-transcriptional effects via interactions with specific target sites in the APP and BACE1 transcripts. Importantly, these miRNA also altered secretion of Aβ peptides in primary human fetal brain cultures. Surprisingly, miR-346 stimulated APP expression via target sites in the APP 5’-UTR. The mechanism of this effect appears to involve other RNA-binding proteins that bind to the APP 5’-UTR. Expression analyses demonstrated that these miRNAs are expressed to varying degrees in the human brain. Notably, miR-101, miR-153 and miR-339-5p are dysregulated in the AD brain at various stages of the disease. The work in this dissertation supports the hypothesis that miRNAs are important regulators of APP and BACE1 expression and are capable of altering Aβ homeostasis. Therefore, these miRNA may possibly serve as novel therapeutic targets for AD.

Alzheimer

APP

BACE1

microRNA

post-transcriptional

gene regulation

amyloid

fetal neurons

Alzheimer's disease -- Molecular aspects

Alzheimer's disease -- Research

Amyloid beta-protein -- Research

Alzheimer's disease -- Pathophysiology

Small interfering RNA -- Therapeutic use

Proteins -- Physiological transport

Cellular signal transduction

Nervous system -- Degeneration

Protein precursors -- Research

Cognitive neuroscience -- Research

Genetic translation -- Regulation

Neuroplasticity -- Research

Pathways to dementia: genetic predictors of cognitive and brain imaging endophenotypes in Alzheimer's disease

Ramanan, Vijay K

03 January 2014

Indiana University-Purdue University Indianapolis (IUPUI) / Alzheimer's disease (AD) is a national priority, with nearly six million Americans affected at an annual cost of $200 billion and no available cure. A better understanding of the mechanisms underlying AD is crucial to combat its high and rising incidence and burdens. Most cases of AD are thought to have a complex etiology with numerous genetic and environmental factors influencing susceptibility. Recent genome-wide association studies (GWAS) have confirmed roles for several hypothesized genes and have discovered novel loci associated with disease risk. However, most GWAS-implicated genetic variants have displayed modest individual effects on disease risk and together leave substantial heritability and pathophysiology unexplained. As a result, new paradigms focusing on biological pathways have emerged, drawing on the hypothesis that complex diseases may be influenced by collective effects of multiple variants – of a variety of effect sizes, directions, and frequencies – within key biological pathways. A variety of tools have been developed for pathway-based statistical analysis of GWAS data, but consensus approaches have not been systematically determined. We critically review strategies for genetic pathway analysis, synthesizing extant concepts and methodologies to guide application and future development. We then apply pathway-based approaches to complement GWAS of key AD-related endophenotypes, focusing on two early, hallmark features of disease, episodic memory impairment and brain deposition of amyloid-β. Using GWAS and pathway analysis, we confirmed the association of APOE (apolipoprotein E) and discovered additional genetic modulators of memory functioning and amyloid-β deposition in AD, including pathways related to long-term potentiation, cell adhesion, inflammation, and NOTCH signaling. We also identified genetic associations to amyloid-β deposition that have classically been understood to mediate learning and memory, including the BCHE gene and signaling through the epidermal growth factor receptor. These findings validate the use of pathway analysis in complex diseases and illuminate novel genetic mechanisms of AD, including several pathways at the intersection of disease-related pathology and cognitive decline which represent targets for future studies. The complexity of the AD genetic architecture also suggests that biomarker and treatment strategies may require simultaneous targeting of multiple pathways to effectively combat disease onset and progression.

Alzheimer's disease (AD)

Genome-wide association study (GWAS)

Biological pathway analysis

Episodic memory

Amyloid plaque

Senile dementia

Brain -- Pathophysiology -- Research

Cognition -- Pathophysiology -- Research

Memory -- Pathophysiology -- Research

Cell adhesion -- Molecular aspects

Notch genes

Epidermal growth factor -- Research

Inflammation -- Molecular aspects

Phenotype -- Research

Molecular genetics -- Research

The combined role of amyloid precursor protein intracellular domain and amyloid-beta on synaptic transmission

Prozorov, Arsenii

08 1900

Ces dernières années, de nombreuses études ont prouvé que la protéine précurseur de l'amyloïde (APP) joue un rôle clé dans le processus de formation de la mémoire, le développement des connexions synaptiques et la régulation de la force synaptique. L’importance d’APP naît du fait que son clivage protéolytique produit le peptide bêta-amyloïde (Aβ), considéré comme l'un des facteurs cruciaux dans le développement de la maladie d'Alzheimer. Les recherches se sont donc concentrées sur Aβ plutôt que sur le domaine intracellulaire APP (APP-ICD). Récemment, il a été démontré qu’APP-ICD affecte l'induction de la plasticité synaptique, et Aβ à haute concentration est connu pour induire une dépression synaptique. Ici, nous montrons qu’APP-ICD et Aβ fonctionnent ensemble et induisent une dépression synaptique en modifiant la transmission synaptique par effet additif. L’activation de la caspase-3 clivant APP-ICD est nécessaire pour la dépression à long terme. Nous constatons que l’activation de la caspase-3 et son site de clivage d’APP-ICD, ainsi que le clivage d’APP par la gamma-sécrétase sont nécessaires à la dépression synaptique dépendante d’Aβ. La microglie assure la clairance d’Aβ et certains effets de plasticité. Nous démontrons qu’elle médie partiellement la dépression synaptique dépendante d’Aβ. Les mécanismes par lesquels APP-ICD et Aβ médient la dépression synaptique ne sont pas connus. Ici, nous discutons de pistes possibles pour la recherche future, notamment des changements dans l'homéostasie du calcium en tant que cible thérapeutique potentielle. Comprendre comment APP-ICD et Aβ travaillent ensemble pour induire une dépression synaptique aiderait à développer de meilleurs traitements pour la maladie d'Alzheimer. / In recent years, more and more evidence has proven that the amyloid precursor protein (APP) plays a key role in the process of memory formation, the development of synaptic connections, and the regulation of synaptic strength. APP rose to prominence since its proteolytic cleavage produces the amyloid-beta (Aβ) peptide, which is believed to be one of the crucial factors in the development of Alzheimer disease. Therefore, most of the research focused on Aβ, while APP intracellular domain (APP-ICD) received much less attention. In a recent study, APP-ICD was shown to affect the induction of synaptic plasticity, and Aβ at high concentration is known to induce synaptic depression. Here we show that APP-ICD works together with Aβ to induce synaptic depression, meaning they have an additive effect that changes synaptic transmission. Caspase-3 cleaves APP-ICD, and its activation is required for long-term depression. We found that the caspase-3 cleavage site of APP-ICD and caspase-3 activation are needed for Aβ-dependent synaptic depression. We also show that cleavage of APP by gamma-secretase is needed for the effect. Microglia mediate clearance of Aβ as well as some plasticity effects. We demonstrate that microglia partially mediate Aβ-dependent synaptic depression. The mechanisms of how APP-ICD and Aβ mediate synaptic depression are not known, here, we discuss possible avenues for future research, specifically changes in calcium homeostasis as a potential therapeutic target. Hence, understanding how APP-ICD and Aβ work together to induce synaptic depression would aid in developing better treatments for Alzheimer disease.

Maladie d'Alzheimer

Protéine précurseur de l'amyloïde

Bêta-amyloïde (Aβ)

Plasticité synaptique

Clivage de la caspase

Métaplasticité

Réserves de calcium intracellulaires

Microglie

Alzheimer disease

Amyloid Precursor Protein

Amyloid-beta (Aβ)

Aβ-dependent synaptic depression

Synaptic plasticity

Caspase cleavage

Metaplasticity

Intracellular calcium stores

Microglia

ApoE3 mediated poly(butyl) cyanoacrylate nanoparticles containing curcumin: study of enhanced activity of curcumin against beta amyloid induced cytotoxicity using in vitro cell culture model

Mulik, R.S., Monkkonen, J., Juvonen, R.O., Mahadik, K.R., Paradkar, Anant R

January 2010

No / Beta amyloid plays a main role in the pathophysiology of Alzheimer's disease by inducing oxidative stress in the brain. Curcumin, a natural antioxidant, is known to inhibit beta amyloid and beta amyloid induced oxidative stress. However, low bioavailability and photodegradation are the major concerns for the use of curcumin. In the present study, we have formulated apolipoprotein E3 mediated poly(butyl) cyanoacrylate nanoparticles containing curcumin (ApoE3-C-PBCA) to provide photostability and enhanced cell uptake of curcumin by targeting. Prepared nanoparticles were characterized for particle size, zeta potential, entrapment efficiency and in vitro drug release. The entrapment of curcumin inside the nanoparticles was confirmed by X-ray diffraction analysis. Physicochemical characterization confirmed the suitability of the method of preparation. The photostability of curcumin was increased significantly in nanoparticles compared to plain curcumin. In vitro cell culture study showed enhanced therapeutic efficacy of ApoE3-C-PBCA against beta amyloid induced cytotoxicity in SH-SY5Y neuroblastoma cells compared to plain curcumin solution. Beta amyloid is known to induce apoptosis in neuronal cells, therefore antiapoptotic activity of curcumin was studied using flow cytometry assays. From all the experiments, it was found that the activity of curcumin was enhanced with ApoE3-C-PBCA compared to plain curcumin solution suggesting enhanced cell uptake and a sustained drug release effect. The synergistic effect of ApoE3 and curcumin was also studied, since ApoE3 also possesses both antioxidant and antiamyloidogenic activity. It was found that ApoE3 did indeed have activity against beta amyloid induced cytotoxicity along with curcumin. Hence, ApoE3-C-PBCA offers great advantage in the treatment of beta amyloid induced cytotoxicity in Alzheimer's disease.

Alzheimer disease

Amyloid beta-Peptides

Apolipoprotein E3

Apoptosis

Caspase 3/metabolism

Cell cycle

Cell line

Curcumin

Enbucrilate

Flow cytometry

Humans

Models

Nanoparticles

Polymers

Reactive oxygen species

X-Ray diffraction

REF 2014

Drug therapy

Metabolism

Physiology

Chemistry

Drug effects

Beta amyloid

Tumor

Therapeutic use

Theoretical

Targeted nanoparticles

Estudo da degradação da proteína Tau hiperfosforilada por vias independentes do proteassoma, em modelo experimental de neurodegeneração / Study of hyperphosphorylated Tau protein degradation by proteasome-independent pathways, in an experimental model of neurodegeneration

Farizatto, Karen Lisneiva Garcia

28 April 2014

O desenvolvimento das doenças neurodegenerativas, como a doença de Alzheimer, está associado à presença de agregados proteicos contendo Tau hiperfosforilada (p-Tau). Esta disfunção da Tau leva a prejuízos na homeostase celular. Um mecanismo chave para diminuir e/ou prevenir os danos promovidos pelos agregados contendo Tau seria o estímulo de sua degradação. Neste sentido, a proposta do presente estudo foi analisar a degradação da proteína Tau após aumento da expressão exógena da cochaperona Bag-2, a qual influencia o sistema proteassomal de degradação; bem como avaliar a ativação dos sistemas de degradação, a fim de correlacionar estes sistemas em cultura de células primárias e organotípica do hipocampo de ratos. Os resultados mostraram que a rotenona foi capaz de aumentar os níveis de p-Tau e que a superexpressão de Bag-2, foi eficiente em prevenir e degradar a p-Tau. O mecanismo envolvido neste processo envolve a coordenação dos sistemas proteassomal e lisossomal, já que a Rab7 e a Rab24 (envolvidas na via lisossomal) mostraram-se diminuídas na fase que antecede a agregação proteica, enquanto houve aumento da Rab24 na presença dos agregados proteicos. Com relação ao peptídeo beta amiloide, foi demonstrado tendência de aumento de p-Tau acompanhado de diminuição da atividade proteassomal e lisossomal. O tratamento com PADK (ativador lisossomal) foi capaz de reverter este efeito nestas diferentes condições. A análise da interrelação entre os sistemas mostrou que uma inibição do proteassoma favorece a via lisossomal e que o inverso não se repete. Os resultados sugerem que a modulação das vias de degradação pode ser interessante para o estudo, prevenção e tratamento das doenças neurodegenerativas associadas à agregação de proteínas / Neurodegenerative diseases, such as Alzheimer\'s, are associated to protein inclusions containing hyperphosphorylated Tau (p-Tau). It is well established that Tau dysfunction impairs cell homeostasis. A key mechanism to prevent and/or reduce the damage promoted by aggregates of Tau might be its degradation. In view of this, the aims of the present study are to evaluate p- Tau clearance following exogenous expression of Bag-2, which stimulates proteasome; as well as to analyze the activation of both lysosome and proteasome pathways in order to understand the crosstalk between these two systems in primary and organotypic cultures of rat hippocampus. Results showed that rotenone was able of increasing p-Tau that was prevented and degraded by Bag-2 overexpression. Mechanisms involved in this process involve the coordination of cell degradation systems, depending upon aggregation status, since Rab7 and Rab24 (involved in lysosomal pathway) were decreased before protein aggregation, while Rab24 increased in the presence of protein inclusions. Amyloid-beta peptide also increased p-Tau accompanied by decreased proteasome and lysosome activity. PADK (lysosomal activator) treatment reverted the inhibition promoted by amyloidbeta peptide. Inhibition of proteasome leads to activation of lysosome, but lysosome inhibition does not affect proteasome. Overall, results suggest that targeting degradation pathways might be useful to understand, prevent and treat neurodegenerative diseases associated with protein deposits

Doenças neurodegenerativas

Envelhecimento/efeito de drogas

Hipocampo

Hippocampus, Aging

Lisossomos

Lysosomes

Modelos animais

Models animal

Molecular chaperones

Neurodegenerative diseases

Proteínas Tau

Rab GTP-binding proteins

Ratos endogâmicos Lewis

Ratos Sprague-Dawley

Rats inbreed Lewis

Rats Sprague-Dawley

Rotenona/farmacologia

Rotenone/pharmacology

Tau proteins

Estudo da degradação da proteína Tau hiperfosforilada por vias independentes do proteassoma, em modelo experimental de neurodegeneração / Study of hyperphosphorylated Tau protein degradation by proteasome-independent pathways, in an experimental model of neurodegeneration

Karen Lisneiva Garcia Farizatto

28 April 2014

O desenvolvimento das doenças neurodegenerativas, como a doença de Alzheimer, está associado à presença de agregados proteicos contendo Tau hiperfosforilada (p-Tau). Esta disfunção da Tau leva a prejuízos na homeostase celular. Um mecanismo chave para diminuir e/ou prevenir os danos promovidos pelos agregados contendo Tau seria o estímulo de sua degradação. Neste sentido, a proposta do presente estudo foi analisar a degradação da proteína Tau após aumento da expressão exógena da cochaperona Bag-2, a qual influencia o sistema proteassomal de degradação; bem como avaliar a ativação dos sistemas de degradação, a fim de correlacionar estes sistemas em cultura de células primárias e organotípica do hipocampo de ratos. Os resultados mostraram que a rotenona foi capaz de aumentar os níveis de p-Tau e que a superexpressão de Bag-2, foi eficiente em prevenir e degradar a p-Tau. O mecanismo envolvido neste processo envolve a coordenação dos sistemas proteassomal e lisossomal, já que a Rab7 e a Rab24 (envolvidas na via lisossomal) mostraram-se diminuídas na fase que antecede a agregação proteica, enquanto houve aumento da Rab24 na presença dos agregados proteicos. Com relação ao peptídeo beta amiloide, foi demonstrado tendência de aumento de p-Tau acompanhado de diminuição da atividade proteassomal e lisossomal. O tratamento com PADK (ativador lisossomal) foi capaz de reverter este efeito nestas diferentes condições. A análise da interrelação entre os sistemas mostrou que uma inibição do proteassoma favorece a via lisossomal e que o inverso não se repete. Os resultados sugerem que a modulação das vias de degradação pode ser interessante para o estudo, prevenção e tratamento das doenças neurodegenerativas associadas à agregação de proteínas / Neurodegenerative diseases, such as Alzheimer\'s, are associated to protein inclusions containing hyperphosphorylated Tau (p-Tau). It is well established that Tau dysfunction impairs cell homeostasis. A key mechanism to prevent and/or reduce the damage promoted by aggregates of Tau might be its degradation. In view of this, the aims of the present study are to evaluate p- Tau clearance following exogenous expression of Bag-2, which stimulates proteasome; as well as to analyze the activation of both lysosome and proteasome pathways in order to understand the crosstalk between these two systems in primary and organotypic cultures of rat hippocampus. Results showed that rotenone was able of increasing p-Tau that was prevented and degraded by Bag-2 overexpression. Mechanisms involved in this process involve the coordination of cell degradation systems, depending upon aggregation status, since Rab7 and Rab24 (involved in lysosomal pathway) were decreased before protein aggregation, while Rab24 increased in the presence of protein inclusions. Amyloid-beta peptide also increased p-Tau accompanied by decreased proteasome and lysosome activity. PADK (lysosomal activator) treatment reverted the inhibition promoted by amyloidbeta peptide. Inhibition of proteasome leads to activation of lysosome, but lysosome inhibition does not affect proteasome. Overall, results suggest that targeting degradation pathways might be useful to understand, prevent and treat neurodegenerative diseases associated with protein deposits

Doenças neurodegenerativas

Envelhecimento/efeito de drogas

Hipocampo

Lisossomos

Modelos animais

Proteínas Tau

Ratos endogâmicos Lewis

Ratos Sprague-Dawley

Rotenona/farmacologia

Hippocampus, Aging

Lysosomes

Models animal

Molecular chaperones

Neurodegenerative diseases

Rab GTP-binding proteins

Rats inbreed Lewis

Rats Sprague-Dawley

Rotenone/pharmacology

Tau proteins

Synthesis of Thiophene-Vinyl-Benzothiazole Based Ligand Analogues for Detection of Aβ and Tau Pathology in Alzheimer's Disease

Johansson, Joel

January 2024

As of today, Alzheimer’s disease is the leading cause of dementia among neurodegenerative disorders, affecting many millions of people worldwide. As the average life span of populations increase, more and more people succumb to the illness each year. Like other neurodegenerative disorders, Alzheimer’s disease can be attributed to the accumulation of protein aggregates in the brain. These amyloid-β peptides and tau proteins can presumably be detected in the brain many years before the onset of clinical symptoms. Development of fluorescent ligands, capable of binding to these neuropathological hallmarks and highlighting them, could serve as molecular diagnostic tools and facilitate an early diagnosis of the disease. The method could also be useful in studying disease progression and evaluating the effects of novel treatments. One such ligand is HS-259. The aim of this project was to synthetize different analogues of HS-259, and test their selectivity towards the aforementioned aggregates in brain tissue from an individual with Alzheimer’s disease. Staining of tissue samples with analogue solution enables visualization of aggregate sites through fluorescence imaging. In the end, five analogues were synthetized, albeit in relatively low overall yields. Synthetic methods included Suzuki-Miyara cross-couplings, Ullmann-type arylations and condensations. Liquid Chromatography-Mass Spectrometry (LC-MS) and Nuclear Magnetic Resonance (NMR) were used for analysis of the compounds. Two of the five analogues could be tested for staining of aggregates and assessed for photophysical characteristics, i.e. absorption- and emission spectra. One analogue stained both amyloid-β aggregates and some tau aggregates, whereas the other stained neither. Since only two analogues were tested and rendered inconsistent results, further studies are needed to assess the binding properties of HS-259 analogues in general.

Alzheimer's disease

neurodegenerative disorders

protein aggregates

molecular ligands

amyloid-β

Aβ

amyloid-beta

tau

diagnosis

HS-259

staining

brain tissue

Suzuki coupling

Ullmann arylation

condensation

NMR

nuclear magnetic resonance

LC-MS

liquid chromatography

neuropathological hallmarks

absorption spectra

emission spectra

synthesis

plaques

symptoms

neuropathology

thiophene-vinyl-benzothiazole

TVBT

ligand analogues

N-arylation

Knoevenagel

preparative LC

PBS

phosphate buffered saline

treatments

AD

mechanisms

thiophene

benzothiazolium

fluorescence imaging

bTVBT

bi-thiophene-vinyl-benzothiazole

detection

Suzuki-Miyara

Organic Chemistry

Organisk kemi

Study of the pathophysiological role of nitric oxide on the amyloid-induced toxicity attending to the biochemical modifications and cellular damages

Guix Ràfols, Francesc Xavier

22 January 2009

Aquesta tesi demostra que el peroxinitrit produït com a conseqüència del pèptid beta-amiloide (A&#61538;) contribueix l'augment de la relació A&#61538;42/A&#61538;40 que ocorre a la malaltia d'Alzheimer. L'A&#61538;42 contribueix a l'aparició de la malaltia degut a la seva major toxicitat (quan es compara amb l'A&#61538;40) que resulta d'una gran estabilitat i capacitat agregativa. A més el peroxinitrit incrementa la toxicitat d'aquest degut a què potencia la seva agregació en forma d'oligomers altament tòxics. De fet els oligomers formats de nitro-A&#61538;42 presenten una major toxicitat que aquells formats de A&#61538;42 . En conjunt aquest resultats senyalen l'important paper que l'A&#61538;42 té en la malaltia d'Alzheimer. Per altra banda, des de la identificació dels agregats d'A&#61538; i la subseqüent formació dels cabdells neurofibrilars (NFT) com a els dos trets distintius de la malaltia, un gran esforç s'ha dedicat a establir els mecanismes moleculars que uneixen ambdós processos. Aquesta tesi demostra que el peroxinitrit format a partir de l'agregació de d'A&#61538;&#61472;i la conseqüent nitrotirosinació de proteïnes, potencia l'agregació de la proteïna tau en forma de fibres. D'aquesta forma, la nitrotirosinació de la proteïna triosafosfat isomerasa (TPI) podria ser el vincle entre la toxicitat derivada del agregats d'A&#61538;&#61472;i la patologia derivada de la proteïna tau. Per tant, la nitrotirosinació de la TPI podria explicar la progressió temporal que ocorre als cervells de pacients amb la malaltia d'Alzheimer des de la toxicitat induïda per l'A&#61538;&#61472;i l'aparició dels NFT. Els resultats presentats en aquesta tesi podrien obrir nous aspectes en la recerca de la malaltia d'Alzheimer així com en altres malalties que cursin amb estrès oxidatiu i plegament erroni de proteïnes. / This thesis demonstrates that amyloid ß-peptide (Aß)-induced peroxynitrite contributes to the switch of the A&#946;42/A&#946;40 ratio that occurs in Alzheimer's disease (AD). Since A&#946;42 is more toxic due to its higher aggregation and stability, it contributes to the trigger of the disease. In addition the aggregation of A&#946;42 in form of the highly toxic oligomers is incremented by the presence of peroxynitrite. Moreover, these nitro-Aß42 oligomers are more toxic than those non-nitrated. All these results support the important role of peroxynitrite in AD etiology. Furthermore, since the identification of Aß accumulation and the subsequent formation of neurofibrillary tangles (NFT) as the two defining pathological hallmarks of AD, a fair amount of research on AD has been driven by the need to find the molecular mechanism linking Aß and NFT. This thesis shows the Aß-induced peroxynitrite, and the consequent nitrotyrosination of proteins, promotes tau fibrillization. Thus triosephosphate isomerase (TPI) nitrotyrosination could be the link between Aß-induced toxicity and tau pathology. Therefore, TPI nitrotyrosination may explain the temporal progression from Aß toxicity to NFT formation in AD brain. The work presented in this thesis could open a novel angle in the research of the pathophysiology of AD and could also have an impact to the research in other neurodegenerative diseases involving oxidative stress and protein misfolding.

GAP

free radicals

fibrils

familiar AD

DHAP

cerebral cortex

BACE1

APH-1

antioxidants

amyloid-beta peptide

protein

amyloid precursor

alzheimer's disease

advanced glycation end products

acetylcholine

plaques

peroxinitrite

peròxid d'hidrogen

pèptid beta-amiloide

Pen2

òxid nítric sintasa

òxid nítric

oligomers

nitrotirosinasa

nicastrina

neurona

metilglioxal

malaltia d'alzheimer

hipocamp

glioxalase

glicolisis

GAP

helicoidals aparellats

filaments

fibriles

èstres oxidatiu

DHAP

cortex cerebral

cabdells neurofibrilars

BACE1

APH-1

antioxidants

anió superòxid

AD familiar

AD esporàdic

acetilcolina

glycolysis

glyoxalase

hippocampus

hydrogen peroxide

methylglyoxal

neurofibrillary tangles

neuron

nicastrin

nitric oxide

nitric oxide synthase

nitrotyrosination

oligomers

oxidative stress

pair helical filaments

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