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Elucidating the early events of protein aggregation using biophysical techniquesCole, Harriet Lucy January 2013 (has links)
Proteins and peptides can convert from their native form into insoluble highly ordered fibrillar aggregates, known as amyloid fibrils. The process of fibrillogenesis is implicated in the pathogenic mechanisms of many diseases and, although mature fibrils are well characterised by a plethora of biophysical techniques, the initiation and early steps remain, to date, ambiguous. Mass spectrometry can provide invaluable insights into these early events as it can identify the low populated and transient oligomeric species present in the lag phase by their mass to charge ratio. Recent evidence has shown that oligomers formed early in the aggregation process are cytotoxic and may additionally be central to the progression of diseases associated with amyloid fibril presence. The hybrid technique of ion mobility mass spectrometry can be employed to provide conformational details of monomeric and multimeric species present and elucidate the presence of oligomers which possess coincident mass to charge ratios. Molecular modelling, in conjunction with experimental results, can suggest probable monomeric and oligomeric structural arrangements. In this thesis three aggregating systems are investigated: amyloidogenic transthyretin fragment (105-115), insulin and two Aβ peptides. Initially amyloidogenic endecapeptide transthyretin (105-115) is studied as it has been widely utilised as a model system for investigating amyloid formation due to its small size. Secondly insulin, a key hormone in metabolic processes, is investigated as extensive research has been carried out into its aggregation into amyloid fibrils. The formation of insulin amyloid fibrils rarely occurs in vivo; however localised amyloidosis at the site of injection and the aggregation of pharmaceutical insulin stocks present problems. Thirdly the aggregation of A β peptides Aβ (1-40) and Aβ (1-42) and their interactions with an aggregation inhibitor, RI-OR2, are characterised. A (1-42), although less commonly produced in vivo, is more cytotoxic and has a faster aggregation mechanism than Aβ (1-40). Both Aβ peptides are implicated in the aetiology of Alzheimer’s disease whilst RI-OR2 has been reported to prevent the production of high molecular weight oligomers, with particular suppression of Aβ (1-42) aggregation.
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Estudos estruturais do processo de agregação entre proteínas amilóides em solução / Structural studies of the process of aggregation between amyloid proteins in solutionSales, Elisa Morandé 02 April 2012 (has links)
Septinas fazem parte de uma família de proteínas de ligação ao nucleotídeo guanina que atuam no ciclo de divisão celular e também são amplamente encontradas em doenças neurodegenerativas tais como mal de Parkinson e Alzheimer e em alguns tipos de câncer como leucemia, linfoma e tumores sólidos. Neste trabalho investigamos como a temperatura e a concentração impactam na agregação do domínio GTPase da septina 2 (SEPT2G), podendo levar a formação de bras amilóides, por espalhamento de luz (DLS) e Raios-X a baixos ângulos (SAXS). Resultados de DLS revelaram que a cinética de agregação da proteína é da ordem de segundos para temperaturas maiores que 25ºC. Os dados de SAXS da proteina a 0,5 mg/ml mostraram que a SETP2G é um dímero em solução aquosa a 4ºC e esta conguração se mantém estável por cerca de 1 hora de observação experimental. A 15ºC, os resultados de SAXS revelaram uma coexistência de três populações em solução compostas por 88% de dímeros, 10% de agregados pequenos tipo-cilindros (protobrilas), e 2% de agregados grandes maiores que a resolução da técnica. Após cerca de 30 minutos existe um rearranjo preferencial de dímeros em favor de agregados muito grandes cuja contribuição à curva de espalhamento torna-se 8%. A 25ºC, a porcentagem de dímeros decresce para 70% com uma contribuição de cerca de 30% de agregados grandes já no início das medidas experimentais. Nas temperaturas de 37ºC e 45ºC, dímeros e agregados muito grandes coexistem em solução desde o início das medidas experimentais, cujo equilíbrio se desloca rapidamente tal que após 20 minutos de observação a solução é composta majoritariamente por agregados muito grandes, identicados como estruturas amilóides pela técnica de uorescência da tioavina, que se intercala em estruturas cross-. A 1 mg/mL e temperatura de 4ºC, a proteína permaneceu estável durante cerca de 1 hora de observação sendo que existe um equilíbrio de dímeros (93%) com agregados alongados (contendo cerca de 80 monômeros) em solução. Com o aumento da temperatura para 15ºC, a maioria da população ainda é dimérica. Já a 25ºC, a presença de agregados muito grandes é bem significativa (da ordem de 30% coexistindo com dímeros e oligômeros). A 37ºC e 45ºC existe a formação de grandes agregados similar ao observado para a SEPT2G a 0,5 mg/mL. Em suma, os resultados de SAXS demonstraram que a SEPT2G tem uma cinética muito rápida de agregação a temperatura siológica, acentuada com o aumento de concentração da proteína em solução. / Septins are proteins from the GTP-binding family and participate in cell division cycle performing functions such as secretion and cytoskeletal division. They can also be found in neurodegenerative conditions as Alzheimer\'s and Parkinson\'s diseases and some kinds of cancer as leukemia, lymphoma and solid tumors. In this work, we investigated the influence of temperature and concentration on the septin 2 GTPase domain (SEPT2G) aggregation using dynamic light scattering (DLS) and small angle x-ray scattering (SAXS). DLS results revealed the protein aggregation kinetic is around seconds for temperatures above 25ºC. SAXS data of the protein at 0.5 mg/mL showed that SEPT2G is a dimer in aqueous solution at 4_C and this condition is kept stable for approximately one hour of experimental observation. At 15ºC, SAXS results revealed the coexistence of three populations in solution composed by 88% of dimers, 10% of cylinder-like smaller aggregates (protofibrils) and 2% of aggregates bigger than the technique detection. After 30 minutes there is a preferential rearrangement of dimers into very large aggregates which contribution on the scattering curve becomes 8%. At 25ºC, the dimers percentage decreases to 70% with a contribution of circa 30% of bigger aggregates, even at the beginning of data acquisition. At temperatures of 37ºC and 45ºC, dimers and very large aggregates coexist in solution since the beginning of data acquisition, which equilibrium quickly shifts in such a way that after 20 minutes of observation the solution is mostly composed by very large aggregates, indented as amyloid structures by the thioflavine fluorescence technique, which intercalates in the cross- structures. At 1 mg/mL and 4ºC, the protein was stable over 1 hour of observation where an equilibrium of dimers (93%) and elongated structures (composed by approximately 80 monomers) in solution takes place. Increasing the temperature to 15ºC, most of the protein remains dimeric. On the other hand, at 25ºC the very large aggregates contribution is around 30% coexisting with dimers and oligomers. At 37ºC and 45ºC there is the formation of large aggregates, similar to what was observed at 0.5 mg/mL. In conclusion, our SAXS results indicated that the aggregation process of SEPT2G in solution may follow different pathways depending on concentration and temperature.
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Estudos estruturais do processo de agregação entre proteínas amilóides em solução / Structural studies of the process of aggregation between amyloid proteins in solutionElisa Morandé Sales 02 April 2012 (has links)
Septinas fazem parte de uma família de proteínas de ligação ao nucleotídeo guanina que atuam no ciclo de divisão celular e também são amplamente encontradas em doenças neurodegenerativas tais como mal de Parkinson e Alzheimer e em alguns tipos de câncer como leucemia, linfoma e tumores sólidos. Neste trabalho investigamos como a temperatura e a concentração impactam na agregação do domínio GTPase da septina 2 (SEPT2G), podendo levar a formação de bras amilóides, por espalhamento de luz (DLS) e Raios-X a baixos ângulos (SAXS). Resultados de DLS revelaram que a cinética de agregação da proteína é da ordem de segundos para temperaturas maiores que 25ºC. Os dados de SAXS da proteina a 0,5 mg/ml mostraram que a SETP2G é um dímero em solução aquosa a 4ºC e esta conguração se mantém estável por cerca de 1 hora de observação experimental. A 15ºC, os resultados de SAXS revelaram uma coexistência de três populações em solução compostas por 88% de dímeros, 10% de agregados pequenos tipo-cilindros (protobrilas), e 2% de agregados grandes maiores que a resolução da técnica. Após cerca de 30 minutos existe um rearranjo preferencial de dímeros em favor de agregados muito grandes cuja contribuição à curva de espalhamento torna-se 8%. A 25ºC, a porcentagem de dímeros decresce para 70% com uma contribuição de cerca de 30% de agregados grandes já no início das medidas experimentais. Nas temperaturas de 37ºC e 45ºC, dímeros e agregados muito grandes coexistem em solução desde o início das medidas experimentais, cujo equilíbrio se desloca rapidamente tal que após 20 minutos de observação a solução é composta majoritariamente por agregados muito grandes, identicados como estruturas amilóides pela técnica de uorescência da tioavina, que se intercala em estruturas cross-. A 1 mg/mL e temperatura de 4ºC, a proteína permaneceu estável durante cerca de 1 hora de observação sendo que existe um equilíbrio de dímeros (93%) com agregados alongados (contendo cerca de 80 monômeros) em solução. Com o aumento da temperatura para 15ºC, a maioria da população ainda é dimérica. Já a 25ºC, a presença de agregados muito grandes é bem significativa (da ordem de 30% coexistindo com dímeros e oligômeros). A 37ºC e 45ºC existe a formação de grandes agregados similar ao observado para a SEPT2G a 0,5 mg/mL. Em suma, os resultados de SAXS demonstraram que a SEPT2G tem uma cinética muito rápida de agregação a temperatura siológica, acentuada com o aumento de concentração da proteína em solução. / Septins are proteins from the GTP-binding family and participate in cell division cycle performing functions such as secretion and cytoskeletal division. They can also be found in neurodegenerative conditions as Alzheimer\'s and Parkinson\'s diseases and some kinds of cancer as leukemia, lymphoma and solid tumors. In this work, we investigated the influence of temperature and concentration on the septin 2 GTPase domain (SEPT2G) aggregation using dynamic light scattering (DLS) and small angle x-ray scattering (SAXS). DLS results revealed the protein aggregation kinetic is around seconds for temperatures above 25ºC. SAXS data of the protein at 0.5 mg/mL showed that SEPT2G is a dimer in aqueous solution at 4_C and this condition is kept stable for approximately one hour of experimental observation. At 15ºC, SAXS results revealed the coexistence of three populations in solution composed by 88% of dimers, 10% of cylinder-like smaller aggregates (protofibrils) and 2% of aggregates bigger than the technique detection. After 30 minutes there is a preferential rearrangement of dimers into very large aggregates which contribution on the scattering curve becomes 8%. At 25ºC, the dimers percentage decreases to 70% with a contribution of circa 30% of bigger aggregates, even at the beginning of data acquisition. At temperatures of 37ºC and 45ºC, dimers and very large aggregates coexist in solution since the beginning of data acquisition, which equilibrium quickly shifts in such a way that after 20 minutes of observation the solution is mostly composed by very large aggregates, indented as amyloid structures by the thioflavine fluorescence technique, which intercalates in the cross- structures. At 1 mg/mL and 4ºC, the protein was stable over 1 hour of observation where an equilibrium of dimers (93%) and elongated structures (composed by approximately 80 monomers) in solution takes place. Increasing the temperature to 15ºC, most of the protein remains dimeric. On the other hand, at 25ºC the very large aggregates contribution is around 30% coexisting with dimers and oligomers. At 37ºC and 45ºC there is the formation of large aggregates, similar to what was observed at 0.5 mg/mL. In conclusion, our SAXS results indicated that the aggregation process of SEPT2G in solution may follow different pathways depending on concentration and temperature.
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Insights into Mechanisms of Amyloid Toxicity: Molecular Dynamics Simulations of the Amyloid andbeta-peptide (Aandbeta) and Islet Amyloid Polypeptide (IAPP)Brown, Anne M. 07 April 2016 (has links)
Aggregation of proteins into amyloid deposits is a common feature among dozens of diseases. Two such diseases that feature amyloid deposits are Alzheimer's disease (AD) and type 2 diabetes (T2D). AD toxicity has been associated with the aggregation and accumulation of the amyloid β-peptide (Aβ); Aβ exerts its toxic effects through interactions with neuronal cell membranes. A characteristic feature of T2D is the deposition of the islet amyloid polypeptide (IAPP) in the pancreatic islets of Langerhans. It is currently unknown if IAPP aggregation is a cause or consequence of T2D, but it does lead to β-cell dysfunction and death, exacerbating the effects of diabetes. Characterizing the fundamental interactions between both Aβ and IAPP with lipid membranes and in solution will give greater insight into mechanisms of toxicity exhibited by amyloid proteins. In this work, molecular dynamics (MD) simulations were used to study the secondary, tertiary, and quatnary structure of Aβ and IAPP, in addition to peptide-membrane interactions and membrane perturbation as independently caused by both peptides. Studies were conducted to address the following questions: (1) what influence do solution conditions and oxidation state have on monomeric Aβ] (2) how and in what way does monomeric Aβ interact with model lipid membranes and what role does sequence play on these peptide-membrane interactions; (3) can MD simulations be utilized to understand Aβ tetramer formation, rearrangement, and tetramer-membrane interactions; (4) how does IAP interact with model membranes and how does that vary from non-toxic (rat) IAPP peptide-membrane interactions. These studies led to conclusions that showed variance in lipid affinity and degree of perturbation as based on peptide sequence, in addition to insight into the type of perturbation caused to membranes by these amyloid peptides. Understanding the differences in peptide-membrane interactions of amyloidogenic and non-amyloidogenic (rat) peptides gave insight into the overall mechanism of amyloidogenicity, leading to the detection of specific amino acids essential in peptide-membrane perturbation. These residues can then be targeted for novel therapeutic design to attenuate the perturbation and potential cell death as caused by these peptides. / Ph. D.
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Investigating the Electrostatic Properties and Dynamics of Amyloidogenic Proteins with Polarizable Molecular Dynamics SimulationsDavidson, Darcy Shanley 14 April 2022 (has links)
Amyloidogenic diseases, such as Alzheimer's disease (AD) and Type II Diabetes (T2D), are characterized by the accumulation of amyloid aggregates. Despite having very different amino-acid sequences, the underlying amyloidogenic proteins form similar supramolecular fibril structures that are highly stable and resistant to physical and chemical denaturation. AD is characterized by two toxic lesions: extracellular amyloid β-peptide (Aβ) plaques and intracellular neurofibrillary tangles composed of microtubule-associated protein tau. Similarly, a feature of T2D is the deposition of islet amyloid polypeptide (IAPP) aggregates in and around the pancreas. The mechanisms by which Aβ, tau, and IAPP aggregate, and cause cell death is unknown; thus, gaining greater insight into the stabilizing forces and initial unfolding events is crucial to our understanding of these amyloidogenic diseases. This work uses molecular dynamics (MD) simulations to study the secondary, tertiary, and quaternary structure of Aβ, tau, and IAPP. Specifically, this work used the Drude polarizable force field (FF), which explicitly represents electronic polarization allowing charge distributions to change in response to perturbations in local electric fields. This model allows us to describe the role charge plays on protein folding and stability and how perturbations to the charge state drive pathology. Studies were conducted to address the following questions: 1) What are the stabilizing forces of fibril and oligomeric structures? 2) How do charge-altering mutations modulate the conformational ensemble and thermodynamic properties of Aβ? 3) How do charge-altering post-translational modifications of Aβ and tau modulate changes in the conformational ensembles? These studies establish that shifts in local microenvironments play a role in fibril and oligomer stability. Furthermore, these studies found that changes in protein sequence and charge are sufficient to disrupt and change the secondary and tertiary structure of these amyloidogenic proteins. Overall, this dissertation describes how charge modulates protein unfolding and characterizes the mechanism of those changes. In the long term, this work will help in the development of therapeutics that can target these changes to prevent protein aggregation that leads to cell death. / Doctor of Philosophy / Protein aggregation is the hallmark of many chronic diseases, such as Alzheimer's disease (AD) and Type II Diabetes (T2D). The formation of two toxic aggregates: amyloid β-peptide (Aβ) plaques and neurofibrillary tangles composed of microtubule-associated protein tau are some of the key characteristics of AD. In addition, the formation of islet amyloid polypeptide (IAPP) aggregates in the pancreas is thought to play a role in the development of T2D. The pathways by which the proteins Aβ, tau, and IAPP aggregate are unknown; thus, gaining a greater insight into the properties that may cause these diseases is necessary to develop treatments. By studying these proteins at the atomistic level, we can understand how small changes to these proteins alter how they misfold in a way that promotes toxicity. Herein, we used a computational technique called molecular dynamics (MD) simulations to gain new insights into how protein structure changes. We explored the dynamics of these proteins and investigated the role that charge plays in protein folding and described how charge modulates protein folding and characterized the mechanism of those changes. This work serves as a characterization of protein folding and sets the ground for future structural studies and drug development.
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Études des premières étapes d’oligomérisation de la région Non-Aβ Component de l’a-synucléine et de Aβ1-40Eugene, Cindie 04 1900 (has links)
Les protéines amyloïdes sont retrouvées sous forme de fibres dans de nombreuses maladies neurodégénératives. En tentant d’élucider le mécanisme de fibrillation, les chercheurs ont découvert que cette réaction se fait par un phénomène de nucléation passant par des oligomères. Il semblerait que ces espèces soient la principale cause de la toxicité observée dans les cellules des patients atteints d’amyloïdose. C’est pourquoi un intérêt particulier est donc porté aux premières étapes d’oligomérisation. Dans ce mémoire, nous nous intéressons à une séquence d’acide aminé fortement hydrophobe de l’α-synucléine appelée composante non β -amyloïde (Non-Amyloid β Component ou NAC). Cette dernière est retrouvée sous forme de fibres dans les corps et les neurites de Lewy des patients atteints de la maladie de Parkinson. De plus, elle constitue une composante minoritaire des fibres impliquées dans la maladie d’Alzheimer. Nous avons observé les changements structuraux qui ont lieu pour le monomère, le dimère et le trimère de la séquence NAC de l’α-synucléine. Nous nous sommes aussi intéressés aux conséquences structurelles observées dans des oligomères hétérogènes qui impliqueraient, Aβ1−40. Pour cela nous utilisons des dynamiques moléculaires, d’échange de répliques couplées au potentiel gros-grain, OPEP. Nous constatons une disparition des hélices α au profit des feuillets β , ainsi que le polymorphisme caractéristique des fibres amyloïdes. Certaines régions se sont démarquées par leurs capacités à former des feuillets β . La disparition de ces régions lorsque NAC est combinée à Aβ laisse entrevoir l’importance de l’emplacement des résidus hydrophobes dans des structures susceptibles de former des fibres amyloïdes. / Amyloid proteins are found in fiber form in many neurodegenerative diseases. In attempting to elucidate the mechanism of fibrillation, researchers have found that fibril formation occurs by a nucleation mechanisms involving oligomers. It seems, in particular, that the latter species are responsible for the toxicity observed in the cells of patients suffering from amyloidosis. That is why special interest is focused in the early stages of oligomerization. In this this work, we focus on a highly hydrophobic amino acid sequence of the α-synuclein called Non-Amyloid β Component (NAC). The NAC is recovered in the form of fibers in the body and Lewy neurites in patients with Parkin- son’s disease. Moreover, it is a minority component of the fibers involved in Alzheimer’s disease. In particular, we observe the structural changes taking place for the monomer, dimer and trimer of the NAC region of α-synuclein. We are also interested in the structural consequences observed in heterogeneous oligomers which involve Aβ1−40. We use Hamiltonian and temperature replica exchange molecular dynamics (HT-REMD) simulations combined with the coarse-grained OPEP potential. We observe a loss of α-helices in favor of β -strands and the characteristic polymorphism of amyloid fibers. We also find that some regions are distinguished by their ability to form β -strands. The disappearance of these regions when combined Aβ with NAC suggests the importance of the location of hydrophobic residues in amyloid fibers structures.
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